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n0rdye
2024-12-01 22:06:02 +00:00
parent d1c12a08b0
commit e6ce63d19c
1511 changed files with 248810 additions and 2 deletions
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__pycache__/screen.cpython-312.pyc Normal file
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server.py
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@ -33,6 +33,11 @@ def views():
global watchers_last_seen
return str(len(watchers_last_seen))
@api.route("/mode", methods=["GET"])
def mode():
global watchers_last_seen
return str(stream)
def ws_server(websocket):
global stream, watchers_last_seen
@ -60,7 +65,7 @@ def ws_server(websocket):
if debug: print("Internal Server Error.")
def run_ws_server():
with serve(ws_server, "0.0.0.0", 7890) as server:
with serve(ws_server, "0.0.0.0", 5621) as server:
server.serve_forever()
def timeout_task():
@ -76,7 +81,7 @@ def timeout_task():
sleep(10)
def run_flask_server():
api.run()
api.run(host="0.0.0.0", port=5622)
def main():
t1 = threading.Thread(target=run_ws_server)

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venv/bin/Activate.ps1 Normal file
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@ -0,0 +1,247 @@
<#
.Synopsis
Activate a Python virtual environment for the current PowerShell session.
.Description
Pushes the python executable for a virtual environment to the front of the
$Env:PATH environment variable and sets the prompt to signify that you are
in a Python virtual environment. Makes use of the command line switches as
well as the `pyvenv.cfg` file values present in the virtual environment.
.Parameter VenvDir
Path to the directory that contains the virtual environment to activate. The
default value for this is the parent of the directory that the Activate.ps1
script is located within.
.Parameter Prompt
The prompt prefix to display when this virtual environment is activated. By
default, this prompt is the name of the virtual environment folder (VenvDir)
surrounded by parentheses and followed by a single space (ie. '(.venv) ').
.Example
Activate.ps1
Activates the Python virtual environment that contains the Activate.ps1 script.
.Example
Activate.ps1 -Verbose
Activates the Python virtual environment that contains the Activate.ps1 script,
and shows extra information about the activation as it executes.
.Example
Activate.ps1 -VenvDir C:\Users\MyUser\Common\.venv
Activates the Python virtual environment located in the specified location.
.Example
Activate.ps1 -Prompt "MyPython"
Activates the Python virtual environment that contains the Activate.ps1 script,
and prefixes the current prompt with the specified string (surrounded in
parentheses) while the virtual environment is active.
.Notes
On Windows, it may be required to enable this Activate.ps1 script by setting the
execution policy for the user. You can do this by issuing the following PowerShell
command:
PS C:\> Set-ExecutionPolicy -ExecutionPolicy RemoteSigned -Scope CurrentUser
For more information on Execution Policies:
https://go.microsoft.com/fwlink/?LinkID=135170
#>
Param(
[Parameter(Mandatory = $false)]
[String]
$VenvDir,
[Parameter(Mandatory = $false)]
[String]
$Prompt
)
<# Function declarations --------------------------------------------------- #>
<#
.Synopsis
Remove all shell session elements added by the Activate script, including the
addition of the virtual environment's Python executable from the beginning of
the PATH variable.
.Parameter NonDestructive
If present, do not remove this function from the global namespace for the
session.
#>
function global:deactivate ([switch]$NonDestructive) {
# Revert to original values
# The prior prompt:
if (Test-Path -Path Function:_OLD_VIRTUAL_PROMPT) {
Copy-Item -Path Function:_OLD_VIRTUAL_PROMPT -Destination Function:prompt
Remove-Item -Path Function:_OLD_VIRTUAL_PROMPT
}
# The prior PYTHONHOME:
if (Test-Path -Path Env:_OLD_VIRTUAL_PYTHONHOME) {
Copy-Item -Path Env:_OLD_VIRTUAL_PYTHONHOME -Destination Env:PYTHONHOME
Remove-Item -Path Env:_OLD_VIRTUAL_PYTHONHOME
}
# The prior PATH:
if (Test-Path -Path Env:_OLD_VIRTUAL_PATH) {
Copy-Item -Path Env:_OLD_VIRTUAL_PATH -Destination Env:PATH
Remove-Item -Path Env:_OLD_VIRTUAL_PATH
}
# Just remove the VIRTUAL_ENV altogether:
if (Test-Path -Path Env:VIRTUAL_ENV) {
Remove-Item -Path env:VIRTUAL_ENV
}
# Just remove VIRTUAL_ENV_PROMPT altogether.
if (Test-Path -Path Env:VIRTUAL_ENV_PROMPT) {
Remove-Item -Path env:VIRTUAL_ENV_PROMPT
}
# Just remove the _PYTHON_VENV_PROMPT_PREFIX altogether:
if (Get-Variable -Name "_PYTHON_VENV_PROMPT_PREFIX" -ErrorAction SilentlyContinue) {
Remove-Variable -Name _PYTHON_VENV_PROMPT_PREFIX -Scope Global -Force
}
# Leave deactivate function in the global namespace if requested:
if (-not $NonDestructive) {
Remove-Item -Path function:deactivate
}
}
<#
.Description
Get-PyVenvConfig parses the values from the pyvenv.cfg file located in the
given folder, and returns them in a map.
For each line in the pyvenv.cfg file, if that line can be parsed into exactly
two strings separated by `=` (with any amount of whitespace surrounding the =)
then it is considered a `key = value` line. The left hand string is the key,
the right hand is the value.
If the value starts with a `'` or a `"` then the first and last character is
stripped from the value before being captured.
.Parameter ConfigDir
Path to the directory that contains the `pyvenv.cfg` file.
#>
function Get-PyVenvConfig(
[String]
$ConfigDir
) {
Write-Verbose "Given ConfigDir=$ConfigDir, obtain values in pyvenv.cfg"
# Ensure the file exists, and issue a warning if it doesn't (but still allow the function to continue).
$pyvenvConfigPath = Join-Path -Resolve -Path $ConfigDir -ChildPath 'pyvenv.cfg' -ErrorAction Continue
# An empty map will be returned if no config file is found.
$pyvenvConfig = @{ }
if ($pyvenvConfigPath) {
Write-Verbose "File exists, parse `key = value` lines"
$pyvenvConfigContent = Get-Content -Path $pyvenvConfigPath
$pyvenvConfigContent | ForEach-Object {
$keyval = $PSItem -split "\s*=\s*", 2
if ($keyval[0] -and $keyval[1]) {
$val = $keyval[1]
# Remove extraneous quotations around a string value.
if ("'""".Contains($val.Substring(0, 1))) {
$val = $val.Substring(1, $val.Length - 2)
}
$pyvenvConfig[$keyval[0]] = $val
Write-Verbose "Adding Key: '$($keyval[0])'='$val'"
}
}
}
return $pyvenvConfig
}
<# Begin Activate script --------------------------------------------------- #>
# Determine the containing directory of this script
$VenvExecPath = Split-Path -Parent $MyInvocation.MyCommand.Definition
$VenvExecDir = Get-Item -Path $VenvExecPath
Write-Verbose "Activation script is located in path: '$VenvExecPath'"
Write-Verbose "VenvExecDir Fullname: '$($VenvExecDir.FullName)"
Write-Verbose "VenvExecDir Name: '$($VenvExecDir.Name)"
# Set values required in priority: CmdLine, ConfigFile, Default
# First, get the location of the virtual environment, it might not be
# VenvExecDir if specified on the command line.
if ($VenvDir) {
Write-Verbose "VenvDir given as parameter, using '$VenvDir' to determine values"
}
else {
Write-Verbose "VenvDir not given as a parameter, using parent directory name as VenvDir."
$VenvDir = $VenvExecDir.Parent.FullName.TrimEnd("\\/")
Write-Verbose "VenvDir=$VenvDir"
}
# Next, read the `pyvenv.cfg` file to determine any required value such
# as `prompt`.
$pyvenvCfg = Get-PyVenvConfig -ConfigDir $VenvDir
# Next, set the prompt from the command line, or the config file, or
# just use the name of the virtual environment folder.
if ($Prompt) {
Write-Verbose "Prompt specified as argument, using '$Prompt'"
}
else {
Write-Verbose "Prompt not specified as argument to script, checking pyvenv.cfg value"
if ($pyvenvCfg -and $pyvenvCfg['prompt']) {
Write-Verbose " Setting based on value in pyvenv.cfg='$($pyvenvCfg['prompt'])'"
$Prompt = $pyvenvCfg['prompt'];
}
else {
Write-Verbose " Setting prompt based on parent's directory's name. (Is the directory name passed to venv module when creating the virtual environment)"
Write-Verbose " Got leaf-name of $VenvDir='$(Split-Path -Path $venvDir -Leaf)'"
$Prompt = Split-Path -Path $venvDir -Leaf
}
}
Write-Verbose "Prompt = '$Prompt'"
Write-Verbose "VenvDir='$VenvDir'"
# Deactivate any currently active virtual environment, but leave the
# deactivate function in place.
deactivate -nondestructive
# Now set the environment variable VIRTUAL_ENV, used by many tools to determine
# that there is an activated venv.
$env:VIRTUAL_ENV = $VenvDir
if (-not $Env:VIRTUAL_ENV_DISABLE_PROMPT) {
Write-Verbose "Setting prompt to '$Prompt'"
# Set the prompt to include the env name
# Make sure _OLD_VIRTUAL_PROMPT is global
function global:_OLD_VIRTUAL_PROMPT { "" }
Copy-Item -Path function:prompt -Destination function:_OLD_VIRTUAL_PROMPT
New-Variable -Name _PYTHON_VENV_PROMPT_PREFIX -Description "Python virtual environment prompt prefix" -Scope Global -Option ReadOnly -Visibility Public -Value $Prompt
function global:prompt {
Write-Host -NoNewline -ForegroundColor Green "($_PYTHON_VENV_PROMPT_PREFIX) "
_OLD_VIRTUAL_PROMPT
}
$env:VIRTUAL_ENV_PROMPT = $Prompt
}
# Clear PYTHONHOME
if (Test-Path -Path Env:PYTHONHOME) {
Copy-Item -Path Env:PYTHONHOME -Destination Env:_OLD_VIRTUAL_PYTHONHOME
Remove-Item -Path Env:PYTHONHOME
}
# Add the venv to the PATH
Copy-Item -Path Env:PATH -Destination Env:_OLD_VIRTUAL_PATH
$Env:PATH = "$VenvExecDir$([System.IO.Path]::PathSeparator)$Env:PATH"

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venv/bin/activate Normal file
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@ -0,0 +1,70 @@
# This file must be used with "source bin/activate" *from bash*
# You cannot run it directly
deactivate () {
# reset old environment variables
if [ -n "${_OLD_VIRTUAL_PATH:-}" ] ; then
PATH="${_OLD_VIRTUAL_PATH:-}"
export PATH
unset _OLD_VIRTUAL_PATH
fi
if [ -n "${_OLD_VIRTUAL_PYTHONHOME:-}" ] ; then
PYTHONHOME="${_OLD_VIRTUAL_PYTHONHOME:-}"
export PYTHONHOME
unset _OLD_VIRTUAL_PYTHONHOME
fi
# Call hash to forget past commands. Without forgetting
# past commands the $PATH changes we made may not be respected
hash -r 2> /dev/null
if [ -n "${_OLD_VIRTUAL_PS1:-}" ] ; then
PS1="${_OLD_VIRTUAL_PS1:-}"
export PS1
unset _OLD_VIRTUAL_PS1
fi
unset VIRTUAL_ENV
unset VIRTUAL_ENV_PROMPT
if [ ! "${1:-}" = "nondestructive" ] ; then
# Self destruct!
unset -f deactivate
fi
}
# unset irrelevant variables
deactivate nondestructive
# on Windows, a path can contain colons and backslashes and has to be converted:
if [ "${OSTYPE:-}" = "cygwin" ] || [ "${OSTYPE:-}" = "msys" ] ; then
# transform D:\path\to\venv to /d/path/to/venv on MSYS
# and to /cygdrive/d/path/to/venv on Cygwin
export VIRTUAL_ENV=$(cygpath "/home/n0rdye/Documents/cons/python_screen_share/venv")
else
# use the path as-is
export VIRTUAL_ENV="/home/n0rdye/Documents/cons/python_screen_share/venv"
fi
_OLD_VIRTUAL_PATH="$PATH"
PATH="$VIRTUAL_ENV/bin:$PATH"
export PATH
# unset PYTHONHOME if set
# this will fail if PYTHONHOME is set to the empty string (which is bad anyway)
# could use `if (set -u; : $PYTHONHOME) ;` in bash
if [ -n "${PYTHONHOME:-}" ] ; then
_OLD_VIRTUAL_PYTHONHOME="${PYTHONHOME:-}"
unset PYTHONHOME
fi
if [ -z "${VIRTUAL_ENV_DISABLE_PROMPT:-}" ] ; then
_OLD_VIRTUAL_PS1="${PS1:-}"
PS1="(venv) ${PS1:-}"
export PS1
VIRTUAL_ENV_PROMPT="(venv) "
export VIRTUAL_ENV_PROMPT
fi
# Call hash to forget past commands. Without forgetting
# past commands the $PATH changes we made may not be respected
hash -r 2> /dev/null

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venv/bin/activate.csh Normal file
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@ -0,0 +1,27 @@
# This file must be used with "source bin/activate.csh" *from csh*.
# You cannot run it directly.
# Created by Davide Di Blasi <davidedb@gmail.com>.
# Ported to Python 3.3 venv by Andrew Svetlov <andrew.svetlov@gmail.com>
alias deactivate 'test $?_OLD_VIRTUAL_PATH != 0 && setenv PATH "$_OLD_VIRTUAL_PATH" && unset _OLD_VIRTUAL_PATH; rehash; test $?_OLD_VIRTUAL_PROMPT != 0 && set prompt="$_OLD_VIRTUAL_PROMPT" && unset _OLD_VIRTUAL_PROMPT; unsetenv VIRTUAL_ENV; unsetenv VIRTUAL_ENV_PROMPT; test "\!:*" != "nondestructive" && unalias deactivate'
# Unset irrelevant variables.
deactivate nondestructive
setenv VIRTUAL_ENV "/home/n0rdye/Documents/cons/python_screen_share/venv"
set _OLD_VIRTUAL_PATH="$PATH"
setenv PATH "$VIRTUAL_ENV/bin:$PATH"
set _OLD_VIRTUAL_PROMPT="$prompt"
if (! "$?VIRTUAL_ENV_DISABLE_PROMPT") then
set prompt = "(venv) $prompt"
setenv VIRTUAL_ENV_PROMPT "(venv) "
endif
alias pydoc python -m pydoc
rehash

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venv/bin/activate.fish Normal file
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@ -0,0 +1,69 @@
# This file must be used with "source <venv>/bin/activate.fish" *from fish*
# (https://fishshell.com/). You cannot run it directly.
function deactivate -d "Exit virtual environment and return to normal shell environment"
# reset old environment variables
if test -n "$_OLD_VIRTUAL_PATH"
set -gx PATH $_OLD_VIRTUAL_PATH
set -e _OLD_VIRTUAL_PATH
end
if test -n "$_OLD_VIRTUAL_PYTHONHOME"
set -gx PYTHONHOME $_OLD_VIRTUAL_PYTHONHOME
set -e _OLD_VIRTUAL_PYTHONHOME
end
if test -n "$_OLD_FISH_PROMPT_OVERRIDE"
set -e _OLD_FISH_PROMPT_OVERRIDE
# prevents error when using nested fish instances (Issue #93858)
if functions -q _old_fish_prompt
functions -e fish_prompt
functions -c _old_fish_prompt fish_prompt
functions -e _old_fish_prompt
end
end
set -e VIRTUAL_ENV
set -e VIRTUAL_ENV_PROMPT
if test "$argv[1]" != "nondestructive"
# Self-destruct!
functions -e deactivate
end
end
# Unset irrelevant variables.
deactivate nondestructive
set -gx VIRTUAL_ENV "/home/n0rdye/Documents/cons/python_screen_share/venv"
set -gx _OLD_VIRTUAL_PATH $PATH
set -gx PATH "$VIRTUAL_ENV/bin" $PATH
# Unset PYTHONHOME if set.
if set -q PYTHONHOME
set -gx _OLD_VIRTUAL_PYTHONHOME $PYTHONHOME
set -e PYTHONHOME
end
if test -z "$VIRTUAL_ENV_DISABLE_PROMPT"
# fish uses a function instead of an env var to generate the prompt.
# Save the current fish_prompt function as the function _old_fish_prompt.
functions -c fish_prompt _old_fish_prompt
# With the original prompt function renamed, we can override with our own.
function fish_prompt
# Save the return status of the last command.
set -l old_status $status
# Output the venv prompt; color taken from the blue of the Python logo.
printf "%s%s%s" (set_color 4B8BBE) "(venv) " (set_color normal)
# Restore the return status of the previous command.
echo "exit $old_status" | .
# Output the original/"old" prompt.
_old_fish_prompt
end
set -gx _OLD_FISH_PROMPT_OVERRIDE "$VIRTUAL_ENV"
set -gx VIRTUAL_ENV_PROMPT "(venv) "
end

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venv/bin/flask Executable file
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#!/home/n0rdye/Documents/cons/python_screen_share/venv/bin/python
# -*- coding: utf-8 -*-
import re
import sys
from flask.cli import main
if __name__ == '__main__':
sys.argv[0] = re.sub(r'(-script\.pyw|\.exe)?$', '', sys.argv[0])
sys.exit(main())

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venv/bin/pip Executable file
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#!/home/n0rdye/Documents/cons/python_screen_share/venv/bin/python
# -*- coding: utf-8 -*-
import re
import sys
from pip._internal.cli.main import main
if __name__ == '__main__':
sys.argv[0] = re.sub(r'(-script\.pyw|\.exe)?$', '', sys.argv[0])
sys.exit(main())

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venv/bin/pip3 Executable file
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@ -0,0 +1,8 @@
#!/home/n0rdye/Documents/cons/python_screen_share/venv/bin/python
# -*- coding: utf-8 -*-
import re
import sys
from pip._internal.cli.main import main
if __name__ == '__main__':
sys.argv[0] = re.sub(r'(-script\.pyw|\.exe)?$', '', sys.argv[0])
sys.exit(main())

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venv/bin/pip3.12 Executable file
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#!/home/n0rdye/Documents/cons/python_screen_share/venv/bin/python
# -*- coding: utf-8 -*-
import re
import sys
from pip._internal.cli.main import main
if __name__ == '__main__':
sys.argv[0] = re.sub(r'(-script\.pyw|\.exe)?$', '', sys.argv[0])
sys.exit(main())

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venv/bin/python Symbolic link
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/sbin/python

1
venv/bin/python3 Symbolic link
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@ -0,0 +1 @@
python

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venv/bin/python3.12 Symbolic link
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@ -0,0 +1 @@
python

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venv/lib/python3.12/site-packages/MarkupSafe-3.0.2.dist-info/INSTALLER Normal file
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@ -0,0 +1 @@
pip

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venv/lib/python3.12/site-packages/MarkupSafe-3.0.2.dist-info/LICENSE.txt Normal file
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@ -0,0 +1,28 @@
Copyright 2010 Pallets
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. Neither the name of the copyright holder nor the names of its
contributors may be used to endorse or promote products derived from
this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

92
venv/lib/python3.12/site-packages/MarkupSafe-3.0.2.dist-info/METADATA Normal file
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@ -0,0 +1,92 @@
Metadata-Version: 2.1
Name: MarkupSafe
Version: 3.0.2
Summary: Safely add untrusted strings to HTML/XML markup.
Maintainer-email: Pallets <contact@palletsprojects.com>
License: Copyright 2010 Pallets
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. Neither the name of the copyright holder nor the names of its
contributors may be used to endorse or promote products derived from
this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
Project-URL: Donate, https://palletsprojects.com/donate
Project-URL: Documentation, https://markupsafe.palletsprojects.com/
Project-URL: Changes, https://markupsafe.palletsprojects.com/changes/
Project-URL: Source, https://github.com/pallets/markupsafe/
Project-URL: Chat, https://discord.gg/pallets
Classifier: Development Status :: 5 - Production/Stable
Classifier: Environment :: Web Environment
Classifier: Intended Audience :: Developers
Classifier: License :: OSI Approved :: BSD License
Classifier: Operating System :: OS Independent
Classifier: Programming Language :: Python
Classifier: Topic :: Internet :: WWW/HTTP :: Dynamic Content
Classifier: Topic :: Text Processing :: Markup :: HTML
Classifier: Typing :: Typed
Requires-Python: >=3.9
Description-Content-Type: text/markdown
License-File: LICENSE.txt
# MarkupSafe
MarkupSafe implements a text object that escapes characters so it is
safe to use in HTML and XML. Characters that have special meanings are
replaced so that they display as the actual characters. This mitigates
injection attacks, meaning untrusted user input can safely be displayed
on a page.
## Examples
```pycon
>>> from markupsafe import Markup, escape
>>> # escape replaces special characters and wraps in Markup
>>> escape("<script>alert(document.cookie);</script>")
Markup('&lt;script&gt;alert(document.cookie);&lt;/script&gt;')
>>> # wrap in Markup to mark text "safe" and prevent escaping
>>> Markup("<strong>Hello</strong>")
Markup('<strong>hello</strong>')
>>> escape(Markup("<strong>Hello</strong>"))
Markup('<strong>hello</strong>')
>>> # Markup is a str subclass
>>> # methods and operators escape their arguments
>>> template = Markup("Hello <em>{name}</em>")
>>> template.format(name='"World"')
Markup('Hello <em>&#34;World&#34;</em>')
```
## Donate
The Pallets organization develops and supports MarkupSafe and other
popular packages. In order to grow the community of contributors and
users, and allow the maintainers to devote more time to the projects,
[please donate today][].
[please donate today]: https://palletsprojects.com/donate

14
venv/lib/python3.12/site-packages/MarkupSafe-3.0.2.dist-info/RECORD Normal file
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@ -0,0 +1,14 @@
MarkupSafe-3.0.2.dist-info/INSTALLER,sha256=zuuue4knoyJ-UwPPXg8fezS7VCrXJQrAP7zeNuwvFQg,4
MarkupSafe-3.0.2.dist-info/LICENSE.txt,sha256=SJqOEQhQntmKN7uYPhHg9-HTHwvY-Zp5yESOf_N9B-o,1475
MarkupSafe-3.0.2.dist-info/METADATA,sha256=aAwbZhSmXdfFuMM-rEHpeiHRkBOGESyVLJIuwzHP-nw,3975
MarkupSafe-3.0.2.dist-info/RECORD,,
MarkupSafe-3.0.2.dist-info/WHEEL,sha256=OVgtqZzfzIXXtylXP90gxCZ6CKBCwKYyHM8PpMEjN1M,151
MarkupSafe-3.0.2.dist-info/top_level.txt,sha256=qy0Plje5IJuvsCBjejJyhDCjEAdcDLK_2agVcex8Z6U,11
markupsafe/__init__.py,sha256=sr-U6_27DfaSrj5jnHYxWN-pvhM27sjlDplMDPZKm7k,13214
markupsafe/__pycache__/__init__.cpython-312.pyc,,
markupsafe/__pycache__/_native.cpython-312.pyc,,
markupsafe/_native.py,sha256=hSLs8Jmz5aqayuengJJ3kdT5PwNpBWpKrmQSdipndC8,210
markupsafe/_speedups.c,sha256=O7XulmTo-epI6n2FtMVOrJXl8EAaIwD2iNYmBI5SEoQ,4149
markupsafe/_speedups.cpython-312-x86_64-linux-gnu.so,sha256=t1DBZlpsjFA30BOOvXfXfT1wvO_4cS16VbHz1-49q5U,43432
markupsafe/_speedups.pyi,sha256=ENd1bYe7gbBUf2ywyYWOGUpnXOHNJ-cgTNqetlW8h5k,41
markupsafe/py.typed,sha256=47DEQpj8HBSa-_TImW-5JCeuQeRkm5NMpJWZG3hSuFU,0

6
venv/lib/python3.12/site-packages/MarkupSafe-3.0.2.dist-info/WHEEL Normal file
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Wheel-Version: 1.0
Generator: setuptools (75.2.0)
Root-Is-Purelib: false
Tag: cp312-cp312-manylinux_2_17_x86_64
Tag: cp312-cp312-manylinux2014_x86_64

1
venv/lib/python3.12/site-packages/MarkupSafe-3.0.2.dist-info/top_level.txt Normal file
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markupsafe

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venv/lib/python3.12/site-packages/PIL/BdfFontFile.py Normal file
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#
# The Python Imaging Library
# $Id$
#
# bitmap distribution font (bdf) file parser
#
# history:
# 1996-05-16 fl created (as bdf2pil)
# 1997-08-25 fl converted to FontFile driver
# 2001-05-25 fl removed bogus __init__ call
# 2002-11-20 fl robustification (from Kevin Cazabon, Dmitry Vasiliev)
# 2003-04-22 fl more robustification (from Graham Dumpleton)
#
# Copyright (c) 1997-2003 by Secret Labs AB.
# Copyright (c) 1997-2003 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
"""
Parse X Bitmap Distribution Format (BDF)
"""
from __future__ import annotations
from typing import BinaryIO
from . import FontFile, Image
bdf_slant = {
"R": "Roman",
"I": "Italic",
"O": "Oblique",
"RI": "Reverse Italic",
"RO": "Reverse Oblique",
"OT": "Other",
}
bdf_spacing = {"P": "Proportional", "M": "Monospaced", "C": "Cell"}
def bdf_char(
f: BinaryIO,
) -> (
tuple[
str,
int,
tuple[tuple[int, int], tuple[int, int, int, int], tuple[int, int, int, int]],
Image.Image,
]
| None
):
# skip to STARTCHAR
while True:
s = f.readline()
if not s:
return None
if s[:9] == b"STARTCHAR":
break
id = s[9:].strip().decode("ascii")
# load symbol properties
props = {}
while True:
s = f.readline()
if not s or s[:6] == b"BITMAP":
break
i = s.find(b" ")
props[s[:i].decode("ascii")] = s[i + 1 : -1].decode("ascii")
# load bitmap
bitmap = bytearray()
while True:
s = f.readline()
if not s or s[:7] == b"ENDCHAR":
break
bitmap += s[:-1]
# The word BBX
# followed by the width in x (BBw), height in y (BBh),
# and x and y displacement (BBxoff0, BByoff0)
# of the lower left corner from the origin of the character.
width, height, x_disp, y_disp = (int(p) for p in props["BBX"].split())
# The word DWIDTH
# followed by the width in x and y of the character in device pixels.
dwx, dwy = (int(p) for p in props["DWIDTH"].split())
bbox = (
(dwx, dwy),
(x_disp, -y_disp - height, width + x_disp, -y_disp),
(0, 0, width, height),
)
try:
im = Image.frombytes("1", (width, height), bitmap, "hex", "1")
except ValueError:
# deal with zero-width characters
im = Image.new("1", (width, height))
return id, int(props["ENCODING"]), bbox, im
class BdfFontFile(FontFile.FontFile):
"""Font file plugin for the X11 BDF format."""
def __init__(self, fp: BinaryIO) -> None:
super().__init__()
s = fp.readline()
if s[:13] != b"STARTFONT 2.1":
msg = "not a valid BDF file"
raise SyntaxError(msg)
props = {}
comments = []
while True:
s = fp.readline()
if not s or s[:13] == b"ENDPROPERTIES":
break
i = s.find(b" ")
props[s[:i].decode("ascii")] = s[i + 1 : -1].decode("ascii")
if s[:i] in [b"COMMENT", b"COPYRIGHT"]:
if s.find(b"LogicalFontDescription") < 0:
comments.append(s[i + 1 : -1].decode("ascii"))
while True:
c = bdf_char(fp)
if not c:
break
id, ch, (xy, dst, src), im = c
if 0 <= ch < len(self.glyph):
self.glyph[ch] = xy, dst, src, im

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venv/lib/python3.12/site-packages/PIL/BlpImagePlugin.py Normal file
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"""
Blizzard Mipmap Format (.blp)
Jerome Leclanche <jerome@leclan.ch>
The contents of this file are hereby released in the public domain (CC0)
Full text of the CC0 license:
https://creativecommons.org/publicdomain/zero/1.0/
BLP1 files, used mostly in Warcraft III, are not fully supported.
All types of BLP2 files used in World of Warcraft are supported.
The BLP file structure consists of a header, up to 16 mipmaps of the
texture
Texture sizes must be powers of two, though the two dimensions do
not have to be equal; 512x256 is valid, but 512x200 is not.
The first mipmap (mipmap #0) is the full size image; each subsequent
mipmap halves both dimensions. The final mipmap should be 1x1.
BLP files come in many different flavours:
* JPEG-compressed (type == 0) - only supported for BLP1.
* RAW images (type == 1, encoding == 1). Each mipmap is stored as an
array of 8-bit values, one per pixel, left to right, top to bottom.
Each value is an index to the palette.
* DXT-compressed (type == 1, encoding == 2):
- DXT1 compression is used if alpha_encoding == 0.
- An additional alpha bit is used if alpha_depth == 1.
- DXT3 compression is used if alpha_encoding == 1.
- DXT5 compression is used if alpha_encoding == 7.
"""
from __future__ import annotations
import abc
import os
import struct
from enum import IntEnum
from io import BytesIO
from typing import IO
from . import Image, ImageFile
class Format(IntEnum):
JPEG = 0
class Encoding(IntEnum):
UNCOMPRESSED = 1
DXT = 2
UNCOMPRESSED_RAW_BGRA = 3
class AlphaEncoding(IntEnum):
DXT1 = 0
DXT3 = 1
DXT5 = 7
def unpack_565(i: int) -> tuple[int, int, int]:
return ((i >> 11) & 0x1F) << 3, ((i >> 5) & 0x3F) << 2, (i & 0x1F) << 3
def decode_dxt1(
data: bytes, alpha: bool = False
) -> tuple[bytearray, bytearray, bytearray, bytearray]:
"""
input: one "row" of data (i.e. will produce 4*width pixels)
"""
blocks = len(data) // 8 # number of blocks in row
ret = (bytearray(), bytearray(), bytearray(), bytearray())
for block_index in range(blocks):
# Decode next 8-byte block.
idx = block_index * 8
color0, color1, bits = struct.unpack_from("<HHI", data, idx)
r0, g0, b0 = unpack_565(color0)
r1, g1, b1 = unpack_565(color1)
# Decode this block into 4x4 pixels
# Accumulate the results onto our 4 row accumulators
for j in range(4):
for i in range(4):
# get next control op and generate a pixel
control = bits & 3
bits = bits >> 2
a = 0xFF
if control == 0:
r, g, b = r0, g0, b0
elif control == 1:
r, g, b = r1, g1, b1
elif control == 2:
if color0 > color1:
r = (2 * r0 + r1) // 3
g = (2 * g0 + g1) // 3
b = (2 * b0 + b1) // 3
else:
r = (r0 + r1) // 2
g = (g0 + g1) // 2
b = (b0 + b1) // 2
elif control == 3:
if color0 > color1:
r = (2 * r1 + r0) // 3
g = (2 * g1 + g0) // 3
b = (2 * b1 + b0) // 3
else:
r, g, b, a = 0, 0, 0, 0
if alpha:
ret[j].extend([r, g, b, a])
else:
ret[j].extend([r, g, b])
return ret
def decode_dxt3(data: bytes) -> tuple[bytearray, bytearray, bytearray, bytearray]:
"""
input: one "row" of data (i.e. will produce 4*width pixels)
"""
blocks = len(data) // 16 # number of blocks in row
ret = (bytearray(), bytearray(), bytearray(), bytearray())
for block_index in range(blocks):
idx = block_index * 16
block = data[idx : idx + 16]
# Decode next 16-byte block.
bits = struct.unpack_from("<8B", block)
color0, color1 = struct.unpack_from("<HH", block, 8)
(code,) = struct.unpack_from("<I", block, 12)
r0, g0, b0 = unpack_565(color0)
r1, g1, b1 = unpack_565(color1)
for j in range(4):
high = False # Do we want the higher bits?
for i in range(4):
alphacode_index = (4 * j + i) // 2
a = bits[alphacode_index]
if high:
high = False
a >>= 4
else:
high = True
a &= 0xF
a *= 17 # We get a value between 0 and 15
color_code = (code >> 2 * (4 * j + i)) & 0x03
if color_code == 0:
r, g, b = r0, g0, b0
elif color_code == 1:
r, g, b = r1, g1, b1
elif color_code == 2:
r = (2 * r0 + r1) // 3
g = (2 * g0 + g1) // 3
b = (2 * b0 + b1) // 3
elif color_code == 3:
r = (2 * r1 + r0) // 3
g = (2 * g1 + g0) // 3
b = (2 * b1 + b0) // 3
ret[j].extend([r, g, b, a])
return ret
def decode_dxt5(data: bytes) -> tuple[bytearray, bytearray, bytearray, bytearray]:
"""
input: one "row" of data (i.e. will produce 4 * width pixels)
"""
blocks = len(data) // 16 # number of blocks in row
ret = (bytearray(), bytearray(), bytearray(), bytearray())
for block_index in range(blocks):
idx = block_index * 16
block = data[idx : idx + 16]
# Decode next 16-byte block.
a0, a1 = struct.unpack_from("<BB", block)
bits = struct.unpack_from("<6B", block, 2)
alphacode1 = bits[2] | (bits[3] << 8) | (bits[4] << 16) | (bits[5] << 24)
alphacode2 = bits[0] | (bits[1] << 8)
color0, color1 = struct.unpack_from("<HH", block, 8)
(code,) = struct.unpack_from("<I", block, 12)
r0, g0, b0 = unpack_565(color0)
r1, g1, b1 = unpack_565(color1)
for j in range(4):
for i in range(4):
# get next control op and generate a pixel
alphacode_index = 3 * (4 * j + i)
if alphacode_index <= 12:
alphacode = (alphacode2 >> alphacode_index) & 0x07
elif alphacode_index == 15:
alphacode = (alphacode2 >> 15) | ((alphacode1 << 1) & 0x06)
else: # alphacode_index >= 18 and alphacode_index <= 45
alphacode = (alphacode1 >> (alphacode_index - 16)) & 0x07
if alphacode == 0:
a = a0
elif alphacode == 1:
a = a1
elif a0 > a1:
a = ((8 - alphacode) * a0 + (alphacode - 1) * a1) // 7
elif alphacode == 6:
a = 0
elif alphacode == 7:
a = 255
else:
a = ((6 - alphacode) * a0 + (alphacode - 1) * a1) // 5
color_code = (code >> 2 * (4 * j + i)) & 0x03
if color_code == 0:
r, g, b = r0, g0, b0
elif color_code == 1:
r, g, b = r1, g1, b1
elif color_code == 2:
r = (2 * r0 + r1) // 3
g = (2 * g0 + g1) // 3
b = (2 * b0 + b1) // 3
elif color_code == 3:
r = (2 * r1 + r0) // 3
g = (2 * g1 + g0) // 3
b = (2 * b1 + b0) // 3
ret[j].extend([r, g, b, a])
return ret
class BLPFormatError(NotImplementedError):
pass
def _accept(prefix: bytes) -> bool:
return prefix[:4] in (b"BLP1", b"BLP2")
class BlpImageFile(ImageFile.ImageFile):
"""
Blizzard Mipmap Format
"""
format = "BLP"
format_description = "Blizzard Mipmap Format"
def _open(self) -> None:
self.magic = self.fp.read(4)
self.fp.seek(5, os.SEEK_CUR)
(self._blp_alpha_depth,) = struct.unpack("<b", self.fp.read(1))
self.fp.seek(2, os.SEEK_CUR)
self._size = struct.unpack("<II", self.fp.read(8))
if self.magic in (b"BLP1", b"BLP2"):
decoder = self.magic.decode()
else:
msg = f"Bad BLP magic {repr(self.magic)}"
raise BLPFormatError(msg)
self._mode = "RGBA" if self._blp_alpha_depth else "RGB"
self.tile = [ImageFile._Tile(decoder, (0, 0) + self.size, 0, (self.mode, 0, 1))]
class _BLPBaseDecoder(ImageFile.PyDecoder):
_pulls_fd = True
def decode(self, buffer: bytes | Image.SupportsArrayInterface) -> tuple[int, int]:
try:
self._read_blp_header()
self._load()
except struct.error as e:
msg = "Truncated BLP file"
raise OSError(msg) from e
return -1, 0
@abc.abstractmethod
def _load(self) -> None:
pass
def _read_blp_header(self) -> None:
assert self.fd is not None
self.fd.seek(4)
(self._blp_compression,) = struct.unpack("<i", self._safe_read(4))
(self._blp_encoding,) = struct.unpack("<b", self._safe_read(1))
(self._blp_alpha_depth,) = struct.unpack("<b", self._safe_read(1))
(self._blp_alpha_encoding,) = struct.unpack("<b", self._safe_read(1))
self.fd.seek(1, os.SEEK_CUR) # mips
self.size = struct.unpack("<II", self._safe_read(8))
if isinstance(self, BLP1Decoder):
# Only present for BLP1
(self._blp_encoding,) = struct.unpack("<i", self._safe_read(4))
self.fd.seek(4, os.SEEK_CUR) # subtype
self._blp_offsets = struct.unpack("<16I", self._safe_read(16 * 4))
self._blp_lengths = struct.unpack("<16I", self._safe_read(16 * 4))
def _safe_read(self, length: int) -> bytes:
assert self.fd is not None
return ImageFile._safe_read(self.fd, length)
def _read_palette(self) -> list[tuple[int, int, int, int]]:
ret = []
for i in range(256):
try:
b, g, r, a = struct.unpack("<4B", self._safe_read(4))
except struct.error:
break
ret.append((b, g, r, a))
return ret
def _read_bgra(self, palette: list[tuple[int, int, int, int]]) -> bytearray:
data = bytearray()
_data = BytesIO(self._safe_read(self._blp_lengths[0]))
while True:
try:
(offset,) = struct.unpack("<B", _data.read(1))
except struct.error:
break
b, g, r, a = palette[offset]
d: tuple[int, ...] = (r, g, b)
if self._blp_alpha_depth:
d += (a,)
data.extend(d)
return data
class BLP1Decoder(_BLPBaseDecoder):
def _load(self) -> None:
if self._blp_compression == Format.JPEG:
self._decode_jpeg_stream()
elif self._blp_compression == 1:
if self._blp_encoding in (4, 5):
palette = self._read_palette()
data = self._read_bgra(palette)
self.set_as_raw(data)
else:
msg = f"Unsupported BLP encoding {repr(self._blp_encoding)}"
raise BLPFormatError(msg)
else:
msg = f"Unsupported BLP compression {repr(self._blp_encoding)}"
raise BLPFormatError(msg)
def _decode_jpeg_stream(self) -> None:
from .JpegImagePlugin import JpegImageFile
(jpeg_header_size,) = struct.unpack("<I", self._safe_read(4))
jpeg_header = self._safe_read(jpeg_header_size)
assert self.fd is not None
self._safe_read(self._blp_offsets[0] - self.fd.tell()) # What IS this?
data = self._safe_read(self._blp_lengths[0])
data = jpeg_header + data
image = JpegImageFile(BytesIO(data))
Image._decompression_bomb_check(image.size)
if image.mode == "CMYK":
decoder_name, extents, offset, args = image.tile[0]
assert isinstance(args, tuple)
image.tile = [
ImageFile._Tile(decoder_name, extents, offset, (args[0], "CMYK"))
]
r, g, b = image.convert("RGB").split()
reversed_image = Image.merge("RGB", (b, g, r))
self.set_as_raw(reversed_image.tobytes())
class BLP2Decoder(_BLPBaseDecoder):
def _load(self) -> None:
palette = self._read_palette()
assert self.fd is not None
self.fd.seek(self._blp_offsets[0])
if self._blp_compression == 1:
# Uncompressed or DirectX compression
if self._blp_encoding == Encoding.UNCOMPRESSED:
data = self._read_bgra(palette)
elif self._blp_encoding == Encoding.DXT:
data = bytearray()
if self._blp_alpha_encoding == AlphaEncoding.DXT1:
linesize = (self.size[0] + 3) // 4 * 8
for yb in range((self.size[1] + 3) // 4):
for d in decode_dxt1(
self._safe_read(linesize), alpha=bool(self._blp_alpha_depth)
):
data += d
elif self._blp_alpha_encoding == AlphaEncoding.DXT3:
linesize = (self.size[0] + 3) // 4 * 16
for yb in range((self.size[1] + 3) // 4):
for d in decode_dxt3(self._safe_read(linesize)):
data += d
elif self._blp_alpha_encoding == AlphaEncoding.DXT5:
linesize = (self.size[0] + 3) // 4 * 16
for yb in range((self.size[1] + 3) // 4):
for d in decode_dxt5(self._safe_read(linesize)):
data += d
else:
msg = f"Unsupported alpha encoding {repr(self._blp_alpha_encoding)}"
raise BLPFormatError(msg)
else:
msg = f"Unknown BLP encoding {repr(self._blp_encoding)}"
raise BLPFormatError(msg)
else:
msg = f"Unknown BLP compression {repr(self._blp_compression)}"
raise BLPFormatError(msg)
self.set_as_raw(data)
class BLPEncoder(ImageFile.PyEncoder):
_pushes_fd = True
def _write_palette(self) -> bytes:
data = b""
assert self.im is not None
palette = self.im.getpalette("RGBA", "RGBA")
for i in range(len(palette) // 4):
r, g, b, a = palette[i * 4 : (i + 1) * 4]
data += struct.pack("<4B", b, g, r, a)
while len(data) < 256 * 4:
data += b"\x00" * 4
return data
def encode(self, bufsize: int) -> tuple[int, int, bytes]:
palette_data = self._write_palette()
offset = 20 + 16 * 4 * 2 + len(palette_data)
data = struct.pack("<16I", offset, *((0,) * 15))
assert self.im is not None
w, h = self.im.size
data += struct.pack("<16I", w * h, *((0,) * 15))
data += palette_data
for y in range(h):
for x in range(w):
data += struct.pack("<B", self.im.getpixel((x, y)))
return len(data), 0, data
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
if im.mode != "P":
msg = "Unsupported BLP image mode"
raise ValueError(msg)
magic = b"BLP1" if im.encoderinfo.get("blp_version") == "BLP1" else b"BLP2"
fp.write(magic)
assert im.palette is not None
fp.write(struct.pack("<i", 1)) # Uncompressed or DirectX compression
fp.write(struct.pack("<b", Encoding.UNCOMPRESSED))
fp.write(struct.pack("<b", 1 if im.palette.mode == "RGBA" else 0))
fp.write(struct.pack("<b", 0)) # alpha encoding
fp.write(struct.pack("<b", 0)) # mips
fp.write(struct.pack("<II", *im.size))
if magic == b"BLP1":
fp.write(struct.pack("<i", 5))
fp.write(struct.pack("<i", 0))
ImageFile._save(im, fp, [ImageFile._Tile("BLP", (0, 0) + im.size, 0, im.mode)])
Image.register_open(BlpImageFile.format, BlpImageFile, _accept)
Image.register_extension(BlpImageFile.format, ".blp")
Image.register_decoder("BLP1", BLP1Decoder)
Image.register_decoder("BLP2", BLP2Decoder)
Image.register_save(BlpImageFile.format, _save)
Image.register_encoder("BLP", BLPEncoder)

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venv/lib/python3.12/site-packages/PIL/BmpImagePlugin.py Normal file
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#
# The Python Imaging Library.
# $Id$
#
# BMP file handler
#
# Windows (and OS/2) native bitmap storage format.
#
# history:
# 1995-09-01 fl Created
# 1996-04-30 fl Added save
# 1997-08-27 fl Fixed save of 1-bit images
# 1998-03-06 fl Load P images as L where possible
# 1998-07-03 fl Load P images as 1 where possible
# 1998-12-29 fl Handle small palettes
# 2002-12-30 fl Fixed load of 1-bit palette images
# 2003-04-21 fl Fixed load of 1-bit monochrome images
# 2003-04-23 fl Added limited support for BI_BITFIELDS compression
#
# Copyright (c) 1997-2003 by Secret Labs AB
# Copyright (c) 1995-2003 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import os
from typing import IO, Any
from . import Image, ImageFile, ImagePalette
from ._binary import i16le as i16
from ._binary import i32le as i32
from ._binary import o8
from ._binary import o16le as o16
from ._binary import o32le as o32
#
# --------------------------------------------------------------------
# Read BMP file
BIT2MODE = {
# bits => mode, rawmode
1: ("P", "P;1"),
4: ("P", "P;4"),
8: ("P", "P"),
16: ("RGB", "BGR;15"),
24: ("RGB", "BGR"),
32: ("RGB", "BGRX"),
}
def _accept(prefix: bytes) -> bool:
return prefix[:2] == b"BM"
def _dib_accept(prefix: bytes) -> bool:
return i32(prefix) in [12, 40, 52, 56, 64, 108, 124]
# =============================================================================
# Image plugin for the Windows BMP format.
# =============================================================================
class BmpImageFile(ImageFile.ImageFile):
"""Image plugin for the Windows Bitmap format (BMP)"""
# ------------------------------------------------------------- Description
format_description = "Windows Bitmap"
format = "BMP"
# -------------------------------------------------- BMP Compression values
COMPRESSIONS = {"RAW": 0, "RLE8": 1, "RLE4": 2, "BITFIELDS": 3, "JPEG": 4, "PNG": 5}
for k, v in COMPRESSIONS.items():
vars()[k] = v
def _bitmap(self, header: int = 0, offset: int = 0) -> None:
"""Read relevant info about the BMP"""
read, seek = self.fp.read, self.fp.seek
if header:
seek(header)
# read bmp header size @offset 14 (this is part of the header size)
file_info: dict[str, bool | int | tuple[int, ...]] = {
"header_size": i32(read(4)),
"direction": -1,
}
# -------------------- If requested, read header at a specific position
# read the rest of the bmp header, without its size
assert isinstance(file_info["header_size"], int)
header_data = ImageFile._safe_read(self.fp, file_info["header_size"] - 4)
# ------------------------------- Windows Bitmap v2, IBM OS/2 Bitmap v1
# ----- This format has different offsets because of width/height types
# 12: BITMAPCOREHEADER/OS21XBITMAPHEADER
if file_info["header_size"] == 12:
file_info["width"] = i16(header_data, 0)
file_info["height"] = i16(header_data, 2)
file_info["planes"] = i16(header_data, 4)
file_info["bits"] = i16(header_data, 6)
file_info["compression"] = self.COMPRESSIONS["RAW"]
file_info["palette_padding"] = 3
# --------------------------------------------- Windows Bitmap v3 to v5
# 40: BITMAPINFOHEADER
# 52: BITMAPV2HEADER
# 56: BITMAPV3HEADER
# 64: BITMAPCOREHEADER2/OS22XBITMAPHEADER
# 108: BITMAPV4HEADER
# 124: BITMAPV5HEADER
elif file_info["header_size"] in (40, 52, 56, 64, 108, 124):
file_info["y_flip"] = header_data[7] == 0xFF
file_info["direction"] = 1 if file_info["y_flip"] else -1
file_info["width"] = i32(header_data, 0)
file_info["height"] = (
i32(header_data, 4)
if not file_info["y_flip"]
else 2**32 - i32(header_data, 4)
)
file_info["planes"] = i16(header_data, 8)
file_info["bits"] = i16(header_data, 10)
file_info["compression"] = i32(header_data, 12)
# byte size of pixel data
file_info["data_size"] = i32(header_data, 16)
file_info["pixels_per_meter"] = (
i32(header_data, 20),
i32(header_data, 24),
)
file_info["colors"] = i32(header_data, 28)
file_info["palette_padding"] = 4
assert isinstance(file_info["pixels_per_meter"], tuple)
self.info["dpi"] = tuple(x / 39.3701 for x in file_info["pixels_per_meter"])
if file_info["compression"] == self.COMPRESSIONS["BITFIELDS"]:
masks = ["r_mask", "g_mask", "b_mask"]
if len(header_data) >= 48:
if len(header_data) >= 52:
masks.append("a_mask")
else:
file_info["a_mask"] = 0x0
for idx, mask in enumerate(masks):
file_info[mask] = i32(header_data, 36 + idx * 4)
else:
# 40 byte headers only have the three components in the
# bitfields masks, ref:
# https://msdn.microsoft.com/en-us/library/windows/desktop/dd183376(v=vs.85).aspx
# See also
# https://github.com/python-pillow/Pillow/issues/1293
# There is a 4th component in the RGBQuad, in the alpha
# location, but it is listed as a reserved component,
# and it is not generally an alpha channel
file_info["a_mask"] = 0x0
for mask in masks:
file_info[mask] = i32(read(4))
assert isinstance(file_info["r_mask"], int)
assert isinstance(file_info["g_mask"], int)
assert isinstance(file_info["b_mask"], int)
assert isinstance(file_info["a_mask"], int)
file_info["rgb_mask"] = (
file_info["r_mask"],
file_info["g_mask"],
file_info["b_mask"],
)
file_info["rgba_mask"] = (
file_info["r_mask"],
file_info["g_mask"],
file_info["b_mask"],
file_info["a_mask"],
)
else:
msg = f"Unsupported BMP header type ({file_info['header_size']})"
raise OSError(msg)
# ------------------ Special case : header is reported 40, which
# ---------------------- is shorter than real size for bpp >= 16
assert isinstance(file_info["width"], int)
assert isinstance(file_info["height"], int)
self._size = file_info["width"], file_info["height"]
# ------- If color count was not found in the header, compute from bits
assert isinstance(file_info["bits"], int)
file_info["colors"] = (
file_info["colors"]
if file_info.get("colors", 0)
else (1 << file_info["bits"])
)
assert isinstance(file_info["colors"], int)
if offset == 14 + file_info["header_size"] and file_info["bits"] <= 8:
offset += 4 * file_info["colors"]
# ---------------------- Check bit depth for unusual unsupported values
self._mode, raw_mode = BIT2MODE.get(file_info["bits"], ("", ""))
if not self.mode:
msg = f"Unsupported BMP pixel depth ({file_info['bits']})"
raise OSError(msg)
# ---------------- Process BMP with Bitfields compression (not palette)
decoder_name = "raw"
if file_info["compression"] == self.COMPRESSIONS["BITFIELDS"]:
SUPPORTED: dict[int, list[tuple[int, ...]]] = {
32: [
(0xFF0000, 0xFF00, 0xFF, 0x0),
(0xFF000000, 0xFF0000, 0xFF00, 0x0),
(0xFF000000, 0xFF00, 0xFF, 0x0),
(0xFF000000, 0xFF0000, 0xFF00, 0xFF),
(0xFF, 0xFF00, 0xFF0000, 0xFF000000),
(0xFF0000, 0xFF00, 0xFF, 0xFF000000),
(0xFF000000, 0xFF00, 0xFF, 0xFF0000),
(0x0, 0x0, 0x0, 0x0),
],
24: [(0xFF0000, 0xFF00, 0xFF)],
16: [(0xF800, 0x7E0, 0x1F), (0x7C00, 0x3E0, 0x1F)],
}
MASK_MODES = {
(32, (0xFF0000, 0xFF00, 0xFF, 0x0)): "BGRX",
(32, (0xFF000000, 0xFF0000, 0xFF00, 0x0)): "XBGR",
(32, (0xFF000000, 0xFF00, 0xFF, 0x0)): "BGXR",
(32, (0xFF000000, 0xFF0000, 0xFF00, 0xFF)): "ABGR",
(32, (0xFF, 0xFF00, 0xFF0000, 0xFF000000)): "RGBA",
(32, (0xFF0000, 0xFF00, 0xFF, 0xFF000000)): "BGRA",
(32, (0xFF000000, 0xFF00, 0xFF, 0xFF0000)): "BGAR",
(32, (0x0, 0x0, 0x0, 0x0)): "BGRA",
(24, (0xFF0000, 0xFF00, 0xFF)): "BGR",
(16, (0xF800, 0x7E0, 0x1F)): "BGR;16",
(16, (0x7C00, 0x3E0, 0x1F)): "BGR;15",
}
if file_info["bits"] in SUPPORTED:
if (
file_info["bits"] == 32
and file_info["rgba_mask"] in SUPPORTED[file_info["bits"]]
):
assert isinstance(file_info["rgba_mask"], tuple)
raw_mode = MASK_MODES[(file_info["bits"], file_info["rgba_mask"])]
self._mode = "RGBA" if "A" in raw_mode else self.mode
elif (
file_info["bits"] in (24, 16)
and file_info["rgb_mask"] in SUPPORTED[file_info["bits"]]
):
assert isinstance(file_info["rgb_mask"], tuple)
raw_mode = MASK_MODES[(file_info["bits"], file_info["rgb_mask"])]
else:
msg = "Unsupported BMP bitfields layout"
raise OSError(msg)
else:
msg = "Unsupported BMP bitfields layout"
raise OSError(msg)
elif file_info["compression"] == self.COMPRESSIONS["RAW"]:
if file_info["bits"] == 32 and header == 22: # 32-bit .cur offset
raw_mode, self._mode = "BGRA", "RGBA"
elif file_info["compression"] in (
self.COMPRESSIONS["RLE8"],
self.COMPRESSIONS["RLE4"],
):
decoder_name = "bmp_rle"
else:
msg = f"Unsupported BMP compression ({file_info['compression']})"
raise OSError(msg)
# --------------- Once the header is processed, process the palette/LUT
if self.mode == "P": # Paletted for 1, 4 and 8 bit images
# ---------------------------------------------------- 1-bit images
if not (0 < file_info["colors"] <= 65536):
msg = f"Unsupported BMP Palette size ({file_info['colors']})"
raise OSError(msg)
else:
assert isinstance(file_info["palette_padding"], int)
padding = file_info["palette_padding"]
palette = read(padding * file_info["colors"])
grayscale = True
indices = (
(0, 255)
if file_info["colors"] == 2
else list(range(file_info["colors"]))
)
# ----------------- Check if grayscale and ignore palette if so
for ind, val in enumerate(indices):
rgb = palette[ind * padding : ind * padding + 3]
if rgb != o8(val) * 3:
grayscale = False
# ------- If all colors are gray, white or black, ditch palette
if grayscale:
self._mode = "1" if file_info["colors"] == 2 else "L"
raw_mode = self.mode
else:
self._mode = "P"
self.palette = ImagePalette.raw(
"BGRX" if padding == 4 else "BGR", palette
)
# ---------------------------- Finally set the tile data for the plugin
self.info["compression"] = file_info["compression"]
args: list[Any] = [raw_mode]
if decoder_name == "bmp_rle":
args.append(file_info["compression"] == self.COMPRESSIONS["RLE4"])
else:
assert isinstance(file_info["width"], int)
args.append(((file_info["width"] * file_info["bits"] + 31) >> 3) & (~3))
args.append(file_info["direction"])
self.tile = [
ImageFile._Tile(
decoder_name,
(0, 0, file_info["width"], file_info["height"]),
offset or self.fp.tell(),
tuple(args),
)
]
def _open(self) -> None:
"""Open file, check magic number and read header"""
# read 14 bytes: magic number, filesize, reserved, header final offset
head_data = self.fp.read(14)
# choke if the file does not have the required magic bytes
if not _accept(head_data):
msg = "Not a BMP file"
raise SyntaxError(msg)
# read the start position of the BMP image data (u32)
offset = i32(head_data, 10)
# load bitmap information (offset=raster info)
self._bitmap(offset=offset)
class BmpRleDecoder(ImageFile.PyDecoder):
_pulls_fd = True
def decode(self, buffer: bytes | Image.SupportsArrayInterface) -> tuple[int, int]:
assert self.fd is not None
rle4 = self.args[1]
data = bytearray()
x = 0
dest_length = self.state.xsize * self.state.ysize
while len(data) < dest_length:
pixels = self.fd.read(1)
byte = self.fd.read(1)
if not pixels or not byte:
break
num_pixels = pixels[0]
if num_pixels:
# encoded mode
if x + num_pixels > self.state.xsize:
# Too much data for row
num_pixels = max(0, self.state.xsize - x)
if rle4:
first_pixel = o8(byte[0] >> 4)
second_pixel = o8(byte[0] & 0x0F)
for index in range(num_pixels):
if index % 2 == 0:
data += first_pixel
else:
data += second_pixel
else:
data += byte * num_pixels
x += num_pixels
else:
if byte[0] == 0:
# end of line
while len(data) % self.state.xsize != 0:
data += b"\x00"
x = 0
elif byte[0] == 1:
# end of bitmap
break
elif byte[0] == 2:
# delta
bytes_read = self.fd.read(2)
if len(bytes_read) < 2:
break
right, up = self.fd.read(2)
data += b"\x00" * (right + up * self.state.xsize)
x = len(data) % self.state.xsize
else:
# absolute mode
if rle4:
# 2 pixels per byte
byte_count = byte[0] // 2
bytes_read = self.fd.read(byte_count)
for byte_read in bytes_read:
data += o8(byte_read >> 4)
data += o8(byte_read & 0x0F)
else:
byte_count = byte[0]
bytes_read = self.fd.read(byte_count)
data += bytes_read
if len(bytes_read) < byte_count:
break
x += byte[0]
# align to 16-bit word boundary
if self.fd.tell() % 2 != 0:
self.fd.seek(1, os.SEEK_CUR)
rawmode = "L" if self.mode == "L" else "P"
self.set_as_raw(bytes(data), rawmode, (0, self.args[-1]))
return -1, 0
# =============================================================================
# Image plugin for the DIB format (BMP alias)
# =============================================================================
class DibImageFile(BmpImageFile):
format = "DIB"
format_description = "Windows Bitmap"
def _open(self) -> None:
self._bitmap()
#
# --------------------------------------------------------------------
# Write BMP file
SAVE = {
"1": ("1", 1, 2),
"L": ("L", 8, 256),
"P": ("P", 8, 256),
"RGB": ("BGR", 24, 0),
"RGBA": ("BGRA", 32, 0),
}
def _dib_save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
_save(im, fp, filename, False)
def _save(
im: Image.Image, fp: IO[bytes], filename: str | bytes, bitmap_header: bool = True
) -> None:
try:
rawmode, bits, colors = SAVE[im.mode]
except KeyError as e:
msg = f"cannot write mode {im.mode} as BMP"
raise OSError(msg) from e
info = im.encoderinfo
dpi = info.get("dpi", (96, 96))
# 1 meter == 39.3701 inches
ppm = tuple(int(x * 39.3701 + 0.5) for x in dpi)
stride = ((im.size[0] * bits + 7) // 8 + 3) & (~3)
header = 40 # or 64 for OS/2 version 2
image = stride * im.size[1]
if im.mode == "1":
palette = b"".join(o8(i) * 4 for i in (0, 255))
elif im.mode == "L":
palette = b"".join(o8(i) * 4 for i in range(256))
elif im.mode == "P":
palette = im.im.getpalette("RGB", "BGRX")
colors = len(palette) // 4
else:
palette = None
# bitmap header
if bitmap_header:
offset = 14 + header + colors * 4
file_size = offset + image
if file_size > 2**32 - 1:
msg = "File size is too large for the BMP format"
raise ValueError(msg)
fp.write(
b"BM" # file type (magic)
+ o32(file_size) # file size
+ o32(0) # reserved
+ o32(offset) # image data offset
)
# bitmap info header
fp.write(
o32(header) # info header size
+ o32(im.size[0]) # width
+ o32(im.size[1]) # height
+ o16(1) # planes
+ o16(bits) # depth
+ o32(0) # compression (0=uncompressed)
+ o32(image) # size of bitmap
+ o32(ppm[0]) # resolution
+ o32(ppm[1]) # resolution
+ o32(colors) # colors used
+ o32(colors) # colors important
)
fp.write(b"\0" * (header - 40)) # padding (for OS/2 format)
if palette:
fp.write(palette)
ImageFile._save(
im, fp, [ImageFile._Tile("raw", (0, 0) + im.size, 0, (rawmode, stride, -1))]
)
#
# --------------------------------------------------------------------
# Registry
Image.register_open(BmpImageFile.format, BmpImageFile, _accept)
Image.register_save(BmpImageFile.format, _save)
Image.register_extension(BmpImageFile.format, ".bmp")
Image.register_mime(BmpImageFile.format, "image/bmp")
Image.register_decoder("bmp_rle", BmpRleDecoder)
Image.register_open(DibImageFile.format, DibImageFile, _dib_accept)
Image.register_save(DibImageFile.format, _dib_save)
Image.register_extension(DibImageFile.format, ".dib")
Image.register_mime(DibImageFile.format, "image/bmp")

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#
# The Python Imaging Library
# $Id$
#
# BUFR stub adapter
#
# Copyright (c) 1996-2003 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from typing import IO
from . import Image, ImageFile
_handler = None
def register_handler(handler: ImageFile.StubHandler | None) -> None:
"""
Install application-specific BUFR image handler.
:param handler: Handler object.
"""
global _handler
_handler = handler
# --------------------------------------------------------------------
# Image adapter
def _accept(prefix: bytes) -> bool:
return prefix[:4] == b"BUFR" or prefix[:4] == b"ZCZC"
class BufrStubImageFile(ImageFile.StubImageFile):
format = "BUFR"
format_description = "BUFR"
def _open(self) -> None:
offset = self.fp.tell()
if not _accept(self.fp.read(4)):
msg = "Not a BUFR file"
raise SyntaxError(msg)
self.fp.seek(offset)
# make something up
self._mode = "F"
self._size = 1, 1
loader = self._load()
if loader:
loader.open(self)
def _load(self) -> ImageFile.StubHandler | None:
return _handler
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
if _handler is None or not hasattr(_handler, "save"):
msg = "BUFR save handler not installed"
raise OSError(msg)
_handler.save(im, fp, filename)
# --------------------------------------------------------------------
# Registry
Image.register_open(BufrStubImageFile.format, BufrStubImageFile, _accept)
Image.register_save(BufrStubImageFile.format, _save)
Image.register_extension(BufrStubImageFile.format, ".bufr")

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#
# The Python Imaging Library.
# $Id$
#
# a class to read from a container file
#
# History:
# 1995-06-18 fl Created
# 1995-09-07 fl Added readline(), readlines()
#
# Copyright (c) 1997-2001 by Secret Labs AB
# Copyright (c) 1995 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import io
from collections.abc import Iterable
from typing import IO, AnyStr, NoReturn
class ContainerIO(IO[AnyStr]):
"""
A file object that provides read access to a part of an existing
file (for example a TAR file).
"""
def __init__(self, file: IO[AnyStr], offset: int, length: int) -> None:
"""
Create file object.
:param file: Existing file.
:param offset: Start of region, in bytes.
:param length: Size of region, in bytes.
"""
self.fh: IO[AnyStr] = file
self.pos = 0
self.offset = offset
self.length = length
self.fh.seek(offset)
##
# Always false.
def isatty(self) -> bool:
return False
def seekable(self) -> bool:
return True
def seek(self, offset: int, mode: int = io.SEEK_SET) -> int:
"""
Move file pointer.
:param offset: Offset in bytes.
:param mode: Starting position. Use 0 for beginning of region, 1
for current offset, and 2 for end of region. You cannot move
the pointer outside the defined region.
:returns: Offset from start of region, in bytes.
"""
if mode == 1:
self.pos = self.pos + offset
elif mode == 2:
self.pos = self.length + offset
else:
self.pos = offset
# clamp
self.pos = max(0, min(self.pos, self.length))
self.fh.seek(self.offset + self.pos)
return self.pos
def tell(self) -> int:
"""
Get current file pointer.
:returns: Offset from start of region, in bytes.
"""
return self.pos
def readable(self) -> bool:
return True
def read(self, n: int = -1) -> AnyStr:
"""
Read data.
:param n: Number of bytes to read. If omitted, zero or negative,
read until end of region.
:returns: An 8-bit string.
"""
if n > 0:
n = min(n, self.length - self.pos)
else:
n = self.length - self.pos
if n <= 0: # EOF
return b"" if "b" in self.fh.mode else "" # type: ignore[return-value]
self.pos = self.pos + n
return self.fh.read(n)
def readline(self, n: int = -1) -> AnyStr:
"""
Read a line of text.
:param n: Number of bytes to read. If omitted, zero or negative,
read until end of line.
:returns: An 8-bit string.
"""
s: AnyStr = b"" if "b" in self.fh.mode else "" # type: ignore[assignment]
newline_character = b"\n" if "b" in self.fh.mode else "\n"
while True:
c = self.read(1)
if not c:
break
s = s + c
if c == newline_character or len(s) == n:
break
return s
def readlines(self, n: int | None = -1) -> list[AnyStr]:
"""
Read multiple lines of text.
:param n: Number of lines to read. If omitted, zero, negative or None,
read until end of region.
:returns: A list of 8-bit strings.
"""
lines = []
while True:
s = self.readline()
if not s:
break
lines.append(s)
if len(lines) == n:
break
return lines
def writable(self) -> bool:
return False
def write(self, b: AnyStr) -> NoReturn:
raise NotImplementedError()
def writelines(self, lines: Iterable[AnyStr]) -> NoReturn:
raise NotImplementedError()
def truncate(self, size: int | None = None) -> int:
raise NotImplementedError()
def __enter__(self) -> ContainerIO[AnyStr]:
return self
def __exit__(self, *args: object) -> None:
self.close()
def __iter__(self) -> ContainerIO[AnyStr]:
return self
def __next__(self) -> AnyStr:
line = self.readline()
if not line:
msg = "end of region"
raise StopIteration(msg)
return line
def fileno(self) -> int:
return self.fh.fileno()
def flush(self) -> None:
self.fh.flush()
def close(self) -> None:
self.fh.close()

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#
# The Python Imaging Library.
# $Id$
#
# Windows Cursor support for PIL
#
# notes:
# uses BmpImagePlugin.py to read the bitmap data.
#
# history:
# 96-05-27 fl Created
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1996.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from . import BmpImagePlugin, Image, ImageFile
from ._binary import i16le as i16
from ._binary import i32le as i32
#
# --------------------------------------------------------------------
def _accept(prefix: bytes) -> bool:
return prefix[:4] == b"\0\0\2\0"
##
# Image plugin for Windows Cursor files.
class CurImageFile(BmpImagePlugin.BmpImageFile):
format = "CUR"
format_description = "Windows Cursor"
def _open(self) -> None:
offset = self.fp.tell()
# check magic
s = self.fp.read(6)
if not _accept(s):
msg = "not a CUR file"
raise SyntaxError(msg)
# pick the largest cursor in the file
m = b""
for i in range(i16(s, 4)):
s = self.fp.read(16)
if not m:
m = s
elif s[0] > m[0] and s[1] > m[1]:
m = s
if not m:
msg = "No cursors were found"
raise TypeError(msg)
# load as bitmap
self._bitmap(i32(m, 12) + offset)
# patch up the bitmap height
self._size = self.size[0], self.size[1] // 2
d, e, o, a = self.tile[0]
self.tile[0] = ImageFile._Tile(d, (0, 0) + self.size, o, a)
#
# --------------------------------------------------------------------
Image.register_open(CurImageFile.format, CurImageFile, _accept)
Image.register_extension(CurImageFile.format, ".cur")

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#
# The Python Imaging Library.
# $Id$
#
# DCX file handling
#
# DCX is a container file format defined by Intel, commonly used
# for fax applications. Each DCX file consists of a directory
# (a list of file offsets) followed by a set of (usually 1-bit)
# PCX files.
#
# History:
# 1995-09-09 fl Created
# 1996-03-20 fl Properly derived from PcxImageFile.
# 1998-07-15 fl Renamed offset attribute to avoid name clash
# 2002-07-30 fl Fixed file handling
#
# Copyright (c) 1997-98 by Secret Labs AB.
# Copyright (c) 1995-96 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from . import Image
from ._binary import i32le as i32
from .PcxImagePlugin import PcxImageFile
MAGIC = 0x3ADE68B1 # QUIZ: what's this value, then?
def _accept(prefix: bytes) -> bool:
return len(prefix) >= 4 and i32(prefix) == MAGIC
##
# Image plugin for the Intel DCX format.
class DcxImageFile(PcxImageFile):
format = "DCX"
format_description = "Intel DCX"
_close_exclusive_fp_after_loading = False
def _open(self) -> None:
# Header
s = self.fp.read(4)
if not _accept(s):
msg = "not a DCX file"
raise SyntaxError(msg)
# Component directory
self._offset = []
for i in range(1024):
offset = i32(self.fp.read(4))
if not offset:
break
self._offset.append(offset)
self._fp = self.fp
self.frame = -1
self.n_frames = len(self._offset)
self.is_animated = self.n_frames > 1
self.seek(0)
def seek(self, frame: int) -> None:
if not self._seek_check(frame):
return
self.frame = frame
self.fp = self._fp
self.fp.seek(self._offset[frame])
PcxImageFile._open(self)
def tell(self) -> int:
return self.frame
Image.register_open(DcxImageFile.format, DcxImageFile, _accept)
Image.register_extension(DcxImageFile.format, ".dcx")

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"""
A Pillow loader for .dds files (S3TC-compressed aka DXTC)
Jerome Leclanche <jerome@leclan.ch>
Documentation:
https://web.archive.org/web/20170802060935/http://oss.sgi.com/projects/ogl-sample/registry/EXT/texture_compression_s3tc.txt
The contents of this file are hereby released in the public domain (CC0)
Full text of the CC0 license:
https://creativecommons.org/publicdomain/zero/1.0/
"""
from __future__ import annotations
import io
import struct
import sys
from enum import IntEnum, IntFlag
from typing import IO
from . import Image, ImageFile, ImagePalette
from ._binary import i32le as i32
from ._binary import o8
from ._binary import o32le as o32
# Magic ("DDS ")
DDS_MAGIC = 0x20534444
# DDS flags
class DDSD(IntFlag):
CAPS = 0x1
HEIGHT = 0x2
WIDTH = 0x4
PITCH = 0x8
PIXELFORMAT = 0x1000
MIPMAPCOUNT = 0x20000
LINEARSIZE = 0x80000
DEPTH = 0x800000
# DDS caps
class DDSCAPS(IntFlag):
COMPLEX = 0x8
TEXTURE = 0x1000
MIPMAP = 0x400000
class DDSCAPS2(IntFlag):
CUBEMAP = 0x200
CUBEMAP_POSITIVEX = 0x400
CUBEMAP_NEGATIVEX = 0x800
CUBEMAP_POSITIVEY = 0x1000
CUBEMAP_NEGATIVEY = 0x2000
CUBEMAP_POSITIVEZ = 0x4000
CUBEMAP_NEGATIVEZ = 0x8000
VOLUME = 0x200000
# Pixel Format
class DDPF(IntFlag):
ALPHAPIXELS = 0x1
ALPHA = 0x2
FOURCC = 0x4
PALETTEINDEXED8 = 0x20
RGB = 0x40
LUMINANCE = 0x20000
# dxgiformat.h
class DXGI_FORMAT(IntEnum):
UNKNOWN = 0
R32G32B32A32_TYPELESS = 1
R32G32B32A32_FLOAT = 2
R32G32B32A32_UINT = 3
R32G32B32A32_SINT = 4
R32G32B32_TYPELESS = 5
R32G32B32_FLOAT = 6
R32G32B32_UINT = 7
R32G32B32_SINT = 8
R16G16B16A16_TYPELESS = 9
R16G16B16A16_FLOAT = 10
R16G16B16A16_UNORM = 11
R16G16B16A16_UINT = 12
R16G16B16A16_SNORM = 13
R16G16B16A16_SINT = 14
R32G32_TYPELESS = 15
R32G32_FLOAT = 16
R32G32_UINT = 17
R32G32_SINT = 18
R32G8X24_TYPELESS = 19
D32_FLOAT_S8X24_UINT = 20
R32_FLOAT_X8X24_TYPELESS = 21
X32_TYPELESS_G8X24_UINT = 22
R10G10B10A2_TYPELESS = 23
R10G10B10A2_UNORM = 24
R10G10B10A2_UINT = 25
R11G11B10_FLOAT = 26
R8G8B8A8_TYPELESS = 27
R8G8B8A8_UNORM = 28
R8G8B8A8_UNORM_SRGB = 29
R8G8B8A8_UINT = 30
R8G8B8A8_SNORM = 31
R8G8B8A8_SINT = 32
R16G16_TYPELESS = 33
R16G16_FLOAT = 34
R16G16_UNORM = 35
R16G16_UINT = 36
R16G16_SNORM = 37
R16G16_SINT = 38
R32_TYPELESS = 39
D32_FLOAT = 40
R32_FLOAT = 41
R32_UINT = 42
R32_SINT = 43
R24G8_TYPELESS = 44
D24_UNORM_S8_UINT = 45
R24_UNORM_X8_TYPELESS = 46
X24_TYPELESS_G8_UINT = 47
R8G8_TYPELESS = 48
R8G8_UNORM = 49
R8G8_UINT = 50
R8G8_SNORM = 51
R8G8_SINT = 52
R16_TYPELESS = 53
R16_FLOAT = 54
D16_UNORM = 55
R16_UNORM = 56
R16_UINT = 57
R16_SNORM = 58
R16_SINT = 59
R8_TYPELESS = 60
R8_UNORM = 61
R8_UINT = 62
R8_SNORM = 63
R8_SINT = 64
A8_UNORM = 65
R1_UNORM = 66
R9G9B9E5_SHAREDEXP = 67
R8G8_B8G8_UNORM = 68
G8R8_G8B8_UNORM = 69
BC1_TYPELESS = 70
BC1_UNORM = 71
BC1_UNORM_SRGB = 72
BC2_TYPELESS = 73
BC2_UNORM = 74
BC2_UNORM_SRGB = 75
BC3_TYPELESS = 76
BC3_UNORM = 77
BC3_UNORM_SRGB = 78
BC4_TYPELESS = 79
BC4_UNORM = 80
BC4_SNORM = 81
BC5_TYPELESS = 82
BC5_UNORM = 83
BC5_SNORM = 84
B5G6R5_UNORM = 85
B5G5R5A1_UNORM = 86
B8G8R8A8_UNORM = 87
B8G8R8X8_UNORM = 88
R10G10B10_XR_BIAS_A2_UNORM = 89
B8G8R8A8_TYPELESS = 90
B8G8R8A8_UNORM_SRGB = 91
B8G8R8X8_TYPELESS = 92
B8G8R8X8_UNORM_SRGB = 93
BC6H_TYPELESS = 94
BC6H_UF16 = 95
BC6H_SF16 = 96
BC7_TYPELESS = 97
BC7_UNORM = 98
BC7_UNORM_SRGB = 99
AYUV = 100
Y410 = 101
Y416 = 102
NV12 = 103
P010 = 104
P016 = 105
OPAQUE_420 = 106
YUY2 = 107
Y210 = 108
Y216 = 109
NV11 = 110
AI44 = 111
IA44 = 112
P8 = 113
A8P8 = 114
B4G4R4A4_UNORM = 115
P208 = 130
V208 = 131
V408 = 132
SAMPLER_FEEDBACK_MIN_MIP_OPAQUE = 189
SAMPLER_FEEDBACK_MIP_REGION_USED_OPAQUE = 190
class D3DFMT(IntEnum):
UNKNOWN = 0
R8G8B8 = 20
A8R8G8B8 = 21
X8R8G8B8 = 22
R5G6B5 = 23
X1R5G5B5 = 24
A1R5G5B5 = 25
A4R4G4B4 = 26
R3G3B2 = 27
A8 = 28
A8R3G3B2 = 29
X4R4G4B4 = 30
A2B10G10R10 = 31
A8B8G8R8 = 32
X8B8G8R8 = 33
G16R16 = 34
A2R10G10B10 = 35
A16B16G16R16 = 36
A8P8 = 40
P8 = 41
L8 = 50
A8L8 = 51
A4L4 = 52
V8U8 = 60
L6V5U5 = 61
X8L8V8U8 = 62
Q8W8V8U8 = 63
V16U16 = 64
A2W10V10U10 = 67
D16_LOCKABLE = 70
D32 = 71
D15S1 = 73
D24S8 = 75
D24X8 = 77
D24X4S4 = 79
D16 = 80
D32F_LOCKABLE = 82
D24FS8 = 83
D32_LOCKABLE = 84
S8_LOCKABLE = 85
L16 = 81
VERTEXDATA = 100
INDEX16 = 101
INDEX32 = 102
Q16W16V16U16 = 110
R16F = 111
G16R16F = 112
A16B16G16R16F = 113
R32F = 114
G32R32F = 115
A32B32G32R32F = 116
CxV8U8 = 117
A1 = 118
A2B10G10R10_XR_BIAS = 119
BINARYBUFFER = 199
UYVY = i32(b"UYVY")
R8G8_B8G8 = i32(b"RGBG")
YUY2 = i32(b"YUY2")
G8R8_G8B8 = i32(b"GRGB")
DXT1 = i32(b"DXT1")
DXT2 = i32(b"DXT2")
DXT3 = i32(b"DXT3")
DXT4 = i32(b"DXT4")
DXT5 = i32(b"DXT5")
DX10 = i32(b"DX10")
BC4S = i32(b"BC4S")
BC4U = i32(b"BC4U")
BC5S = i32(b"BC5S")
BC5U = i32(b"BC5U")
ATI1 = i32(b"ATI1")
ATI2 = i32(b"ATI2")
MULTI2_ARGB8 = i32(b"MET1")
# Backward compatibility layer
module = sys.modules[__name__]
for item in DDSD:
assert item.name is not None
setattr(module, f"DDSD_{item.name}", item.value)
for item1 in DDSCAPS:
assert item1.name is not None
setattr(module, f"DDSCAPS_{item1.name}", item1.value)
for item2 in DDSCAPS2:
assert item2.name is not None
setattr(module, f"DDSCAPS2_{item2.name}", item2.value)
for item3 in DDPF:
assert item3.name is not None
setattr(module, f"DDPF_{item3.name}", item3.value)
DDS_FOURCC = DDPF.FOURCC
DDS_RGB = DDPF.RGB
DDS_RGBA = DDPF.RGB | DDPF.ALPHAPIXELS
DDS_LUMINANCE = DDPF.LUMINANCE
DDS_LUMINANCEA = DDPF.LUMINANCE | DDPF.ALPHAPIXELS
DDS_ALPHA = DDPF.ALPHA
DDS_PAL8 = DDPF.PALETTEINDEXED8
DDS_HEADER_FLAGS_TEXTURE = DDSD.CAPS | DDSD.HEIGHT | DDSD.WIDTH | DDSD.PIXELFORMAT
DDS_HEADER_FLAGS_MIPMAP = DDSD.MIPMAPCOUNT
DDS_HEADER_FLAGS_VOLUME = DDSD.DEPTH
DDS_HEADER_FLAGS_PITCH = DDSD.PITCH
DDS_HEADER_FLAGS_LINEARSIZE = DDSD.LINEARSIZE
DDS_HEIGHT = DDSD.HEIGHT
DDS_WIDTH = DDSD.WIDTH
DDS_SURFACE_FLAGS_TEXTURE = DDSCAPS.TEXTURE
DDS_SURFACE_FLAGS_MIPMAP = DDSCAPS.COMPLEX | DDSCAPS.MIPMAP
DDS_SURFACE_FLAGS_CUBEMAP = DDSCAPS.COMPLEX
DDS_CUBEMAP_POSITIVEX = DDSCAPS2.CUBEMAP | DDSCAPS2.CUBEMAP_POSITIVEX
DDS_CUBEMAP_NEGATIVEX = DDSCAPS2.CUBEMAP | DDSCAPS2.CUBEMAP_NEGATIVEX
DDS_CUBEMAP_POSITIVEY = DDSCAPS2.CUBEMAP | DDSCAPS2.CUBEMAP_POSITIVEY
DDS_CUBEMAP_NEGATIVEY = DDSCAPS2.CUBEMAP | DDSCAPS2.CUBEMAP_NEGATIVEY
DDS_CUBEMAP_POSITIVEZ = DDSCAPS2.CUBEMAP | DDSCAPS2.CUBEMAP_POSITIVEZ
DDS_CUBEMAP_NEGATIVEZ = DDSCAPS2.CUBEMAP | DDSCAPS2.CUBEMAP_NEGATIVEZ
DXT1_FOURCC = D3DFMT.DXT1
DXT3_FOURCC = D3DFMT.DXT3
DXT5_FOURCC = D3DFMT.DXT5
DXGI_FORMAT_R8G8B8A8_TYPELESS = DXGI_FORMAT.R8G8B8A8_TYPELESS
DXGI_FORMAT_R8G8B8A8_UNORM = DXGI_FORMAT.R8G8B8A8_UNORM
DXGI_FORMAT_R8G8B8A8_UNORM_SRGB = DXGI_FORMAT.R8G8B8A8_UNORM_SRGB
DXGI_FORMAT_BC5_TYPELESS = DXGI_FORMAT.BC5_TYPELESS
DXGI_FORMAT_BC5_UNORM = DXGI_FORMAT.BC5_UNORM
DXGI_FORMAT_BC5_SNORM = DXGI_FORMAT.BC5_SNORM
DXGI_FORMAT_BC6H_UF16 = DXGI_FORMAT.BC6H_UF16
DXGI_FORMAT_BC6H_SF16 = DXGI_FORMAT.BC6H_SF16
DXGI_FORMAT_BC7_TYPELESS = DXGI_FORMAT.BC7_TYPELESS
DXGI_FORMAT_BC7_UNORM = DXGI_FORMAT.BC7_UNORM
DXGI_FORMAT_BC7_UNORM_SRGB = DXGI_FORMAT.BC7_UNORM_SRGB
class DdsImageFile(ImageFile.ImageFile):
format = "DDS"
format_description = "DirectDraw Surface"
def _open(self) -> None:
if not _accept(self.fp.read(4)):
msg = "not a DDS file"
raise SyntaxError(msg)
(header_size,) = struct.unpack("<I", self.fp.read(4))
if header_size != 124:
msg = f"Unsupported header size {repr(header_size)}"
raise OSError(msg)
header_bytes = self.fp.read(header_size - 4)
if len(header_bytes) != 120:
msg = f"Incomplete header: {len(header_bytes)} bytes"
raise OSError(msg)
header = io.BytesIO(header_bytes)
flags, height, width = struct.unpack("<3I", header.read(12))
self._size = (width, height)
extents = (0, 0) + self.size
pitch, depth, mipmaps = struct.unpack("<3I", header.read(12))
struct.unpack("<11I", header.read(44)) # reserved
# pixel format
pfsize, pfflags, fourcc, bitcount = struct.unpack("<4I", header.read(16))
n = 0
rawmode = None
if pfflags & DDPF.RGB:
# Texture contains uncompressed RGB data
if pfflags & DDPF.ALPHAPIXELS:
self._mode = "RGBA"
mask_count = 4
else:
self._mode = "RGB"
mask_count = 3
masks = struct.unpack(f"<{mask_count}I", header.read(mask_count * 4))
self.tile = [ImageFile._Tile("dds_rgb", extents, 0, (bitcount, masks))]
return
elif pfflags & DDPF.LUMINANCE:
if bitcount == 8:
self._mode = "L"
elif bitcount == 16 and pfflags & DDPF.ALPHAPIXELS:
self._mode = "LA"
else:
msg = f"Unsupported bitcount {bitcount} for {pfflags}"
raise OSError(msg)
elif pfflags & DDPF.PALETTEINDEXED8:
self._mode = "P"
self.palette = ImagePalette.raw("RGBA", self.fp.read(1024))
self.palette.mode = "RGBA"
elif pfflags & DDPF.FOURCC:
offset = header_size + 4
if fourcc == D3DFMT.DXT1:
self._mode = "RGBA"
self.pixel_format = "DXT1"
n = 1
elif fourcc == D3DFMT.DXT3:
self._mode = "RGBA"
self.pixel_format = "DXT3"
n = 2
elif fourcc == D3DFMT.DXT5:
self._mode = "RGBA"
self.pixel_format = "DXT5"
n = 3
elif fourcc in (D3DFMT.BC4U, D3DFMT.ATI1):
self._mode = "L"
self.pixel_format = "BC4"
n = 4
elif fourcc == D3DFMT.BC5S:
self._mode = "RGB"
self.pixel_format = "BC5S"
n = 5
elif fourcc in (D3DFMT.BC5U, D3DFMT.ATI2):
self._mode = "RGB"
self.pixel_format = "BC5"
n = 5
elif fourcc == D3DFMT.DX10:
offset += 20
# ignoring flags which pertain to volume textures and cubemaps
(dxgi_format,) = struct.unpack("<I", self.fp.read(4))
self.fp.read(16)
if dxgi_format in (
DXGI_FORMAT.BC1_UNORM,
DXGI_FORMAT.BC1_TYPELESS,
):
self._mode = "RGBA"
self.pixel_format = "BC1"
n = 1
elif dxgi_format in (DXGI_FORMAT.BC4_TYPELESS, DXGI_FORMAT.BC4_UNORM):
self._mode = "L"
self.pixel_format = "BC4"
n = 4
elif dxgi_format in (DXGI_FORMAT.BC5_TYPELESS, DXGI_FORMAT.BC5_UNORM):
self._mode = "RGB"
self.pixel_format = "BC5"
n = 5
elif dxgi_format == DXGI_FORMAT.BC5_SNORM:
self._mode = "RGB"
self.pixel_format = "BC5S"
n = 5
elif dxgi_format == DXGI_FORMAT.BC6H_UF16:
self._mode = "RGB"
self.pixel_format = "BC6H"
n = 6
elif dxgi_format == DXGI_FORMAT.BC6H_SF16:
self._mode = "RGB"
self.pixel_format = "BC6HS"
n = 6
elif dxgi_format in (
DXGI_FORMAT.BC7_TYPELESS,
DXGI_FORMAT.BC7_UNORM,
DXGI_FORMAT.BC7_UNORM_SRGB,
):
self._mode = "RGBA"
self.pixel_format = "BC7"
n = 7
if dxgi_format == DXGI_FORMAT.BC7_UNORM_SRGB:
self.info["gamma"] = 1 / 2.2
elif dxgi_format in (
DXGI_FORMAT.R8G8B8A8_TYPELESS,
DXGI_FORMAT.R8G8B8A8_UNORM,
DXGI_FORMAT.R8G8B8A8_UNORM_SRGB,
):
self._mode = "RGBA"
if dxgi_format == DXGI_FORMAT.R8G8B8A8_UNORM_SRGB:
self.info["gamma"] = 1 / 2.2
else:
msg = f"Unimplemented DXGI format {dxgi_format}"
raise NotImplementedError(msg)
else:
msg = f"Unimplemented pixel format {repr(fourcc)}"
raise NotImplementedError(msg)
else:
msg = f"Unknown pixel format flags {pfflags}"
raise NotImplementedError(msg)
if n:
self.tile = [
ImageFile._Tile("bcn", extents, offset, (n, self.pixel_format))
]
else:
self.tile = [ImageFile._Tile("raw", extents, 0, rawmode or self.mode)]
def load_seek(self, pos: int) -> None:
pass
class DdsRgbDecoder(ImageFile.PyDecoder):
_pulls_fd = True
def decode(self, buffer: bytes | Image.SupportsArrayInterface) -> tuple[int, int]:
assert self.fd is not None
bitcount, masks = self.args
# Some masks will be padded with zeros, e.g. R 0b11 G 0b1100
# Calculate how many zeros each mask is padded with
mask_offsets = []
# And the maximum value of each channel without the padding
mask_totals = []
for mask in masks:
offset = 0
if mask != 0:
while mask >> (offset + 1) << (offset + 1) == mask:
offset += 1
mask_offsets.append(offset)
mask_totals.append(mask >> offset)
data = bytearray()
bytecount = bitcount // 8
dest_length = self.state.xsize * self.state.ysize * len(masks)
while len(data) < dest_length:
value = int.from_bytes(self.fd.read(bytecount), "little")
for i, mask in enumerate(masks):
masked_value = value & mask
# Remove the zero padding, and scale it to 8 bits
data += o8(
int(((masked_value >> mask_offsets[i]) / mask_totals[i]) * 255)
)
self.set_as_raw(data)
return -1, 0
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
if im.mode not in ("RGB", "RGBA", "L", "LA"):
msg = f"cannot write mode {im.mode} as DDS"
raise OSError(msg)
alpha = im.mode[-1] == "A"
if im.mode[0] == "L":
pixel_flags = DDPF.LUMINANCE
rawmode = im.mode
if alpha:
rgba_mask = [0x000000FF, 0x000000FF, 0x000000FF]
else:
rgba_mask = [0xFF000000, 0xFF000000, 0xFF000000]
else:
pixel_flags = DDPF.RGB
rawmode = im.mode[::-1]
rgba_mask = [0x00FF0000, 0x0000FF00, 0x000000FF]
if alpha:
r, g, b, a = im.split()
im = Image.merge("RGBA", (a, r, g, b))
if alpha:
pixel_flags |= DDPF.ALPHAPIXELS
rgba_mask.append(0xFF000000 if alpha else 0)
flags = DDSD.CAPS | DDSD.HEIGHT | DDSD.WIDTH | DDSD.PITCH | DDSD.PIXELFORMAT
bitcount = len(im.getbands()) * 8
pitch = (im.width * bitcount + 7) // 8
fp.write(
o32(DDS_MAGIC)
+ struct.pack(
"<7I",
124, # header size
flags, # flags
im.height,
im.width,
pitch,
0, # depth
0, # mipmaps
)
+ struct.pack("11I", *((0,) * 11)) # reserved
# pfsize, pfflags, fourcc, bitcount
+ struct.pack("<4I", 32, pixel_flags, 0, bitcount)
+ struct.pack("<4I", *rgba_mask) # dwRGBABitMask
+ struct.pack("<5I", DDSCAPS.TEXTURE, 0, 0, 0, 0)
)
ImageFile._save(
im, fp, [ImageFile._Tile("raw", (0, 0) + im.size, 0, (rawmode, 0, 1))]
)
def _accept(prefix: bytes) -> bool:
return prefix[:4] == b"DDS "
Image.register_open(DdsImageFile.format, DdsImageFile, _accept)
Image.register_decoder("dds_rgb", DdsRgbDecoder)
Image.register_save(DdsImageFile.format, _save)
Image.register_extension(DdsImageFile.format, ".dds")

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#
# The Python Imaging Library.
# $Id$
#
# EPS file handling
#
# History:
# 1995-09-01 fl Created (0.1)
# 1996-05-18 fl Don't choke on "atend" fields, Ghostscript interface (0.2)
# 1996-08-22 fl Don't choke on floating point BoundingBox values
# 1996-08-23 fl Handle files from Macintosh (0.3)
# 2001-02-17 fl Use 're' instead of 'regex' (Python 2.1) (0.4)
# 2003-09-07 fl Check gs.close status (from Federico Di Gregorio) (0.5)
# 2014-05-07 e Handling of EPS with binary preview and fixed resolution
# resizing
#
# Copyright (c) 1997-2003 by Secret Labs AB.
# Copyright (c) 1995-2003 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import io
import os
import re
import subprocess
import sys
import tempfile
from typing import IO
from . import Image, ImageFile
from ._binary import i32le as i32
# --------------------------------------------------------------------
split = re.compile(r"^%%([^:]*):[ \t]*(.*)[ \t]*$")
field = re.compile(r"^%[%!\w]([^:]*)[ \t]*$")
gs_binary: str | bool | None = None
gs_windows_binary = None
def has_ghostscript() -> bool:
global gs_binary, gs_windows_binary
if gs_binary is None:
if sys.platform.startswith("win"):
if gs_windows_binary is None:
import shutil
for binary in ("gswin32c", "gswin64c", "gs"):
if shutil.which(binary) is not None:
gs_windows_binary = binary
break
else:
gs_windows_binary = False
gs_binary = gs_windows_binary
else:
try:
subprocess.check_call(["gs", "--version"], stdout=subprocess.DEVNULL)
gs_binary = "gs"
except OSError:
gs_binary = False
return gs_binary is not False
def Ghostscript(
tile: list[ImageFile._Tile],
size: tuple[int, int],
fp: IO[bytes],
scale: int = 1,
transparency: bool = False,
) -> Image.core.ImagingCore:
"""Render an image using Ghostscript"""
global gs_binary
if not has_ghostscript():
msg = "Unable to locate Ghostscript on paths"
raise OSError(msg)
assert isinstance(gs_binary, str)
# Unpack decoder tile
args = tile[0].args
assert isinstance(args, tuple)
length, bbox = args
# Hack to support hi-res rendering
scale = int(scale) or 1
width = size[0] * scale
height = size[1] * scale
# resolution is dependent on bbox and size
res_x = 72.0 * width / (bbox[2] - bbox[0])
res_y = 72.0 * height / (bbox[3] - bbox[1])
out_fd, outfile = tempfile.mkstemp()
os.close(out_fd)
infile_temp = None
if hasattr(fp, "name") and os.path.exists(fp.name):
infile = fp.name
else:
in_fd, infile_temp = tempfile.mkstemp()
os.close(in_fd)
infile = infile_temp
# Ignore length and offset!
# Ghostscript can read it
# Copy whole file to read in Ghostscript
with open(infile_temp, "wb") as f:
# fetch length of fp
fp.seek(0, io.SEEK_END)
fsize = fp.tell()
# ensure start position
# go back
fp.seek(0)
lengthfile = fsize
while lengthfile > 0:
s = fp.read(min(lengthfile, 100 * 1024))
if not s:
break
lengthfile -= len(s)
f.write(s)
if transparency:
# "RGBA"
device = "pngalpha"
else:
# "pnmraw" automatically chooses between
# PBM ("1"), PGM ("L"), and PPM ("RGB").
device = "pnmraw"
# Build Ghostscript command
command = [
gs_binary,
"-q", # quiet mode
f"-g{width:d}x{height:d}", # set output geometry (pixels)
f"-r{res_x:f}x{res_y:f}", # set input DPI (dots per inch)
"-dBATCH", # exit after processing
"-dNOPAUSE", # don't pause between pages
"-dSAFER", # safe mode
f"-sDEVICE={device}",
f"-sOutputFile={outfile}", # output file
# adjust for image origin
"-c",
f"{-bbox[0]} {-bbox[1]} translate",
"-f",
infile, # input file
# showpage (see https://bugs.ghostscript.com/show_bug.cgi?id=698272)
"-c",
"showpage",
]
# push data through Ghostscript
try:
startupinfo = None
if sys.platform.startswith("win"):
startupinfo = subprocess.STARTUPINFO()
startupinfo.dwFlags |= subprocess.STARTF_USESHOWWINDOW
subprocess.check_call(command, startupinfo=startupinfo)
with Image.open(outfile) as out_im:
out_im.load()
return out_im.im.copy()
finally:
try:
os.unlink(outfile)
if infile_temp:
os.unlink(infile_temp)
except OSError:
pass
def _accept(prefix: bytes) -> bool:
return prefix[:4] == b"%!PS" or (len(prefix) >= 4 and i32(prefix) == 0xC6D3D0C5)
##
# Image plugin for Encapsulated PostScript. This plugin supports only
# a few variants of this format.
class EpsImageFile(ImageFile.ImageFile):
"""EPS File Parser for the Python Imaging Library"""
format = "EPS"
format_description = "Encapsulated Postscript"
mode_map = {1: "L", 2: "LAB", 3: "RGB", 4: "CMYK"}
def _open(self) -> None:
(length, offset) = self._find_offset(self.fp)
# go to offset - start of "%!PS"
self.fp.seek(offset)
self._mode = "RGB"
# When reading header comments, the first comment is used.
# When reading trailer comments, the last comment is used.
bounding_box: list[int] | None = None
imagedata_size: tuple[int, int] | None = None
byte_arr = bytearray(255)
bytes_mv = memoryview(byte_arr)
bytes_read = 0
reading_header_comments = True
reading_trailer_comments = False
trailer_reached = False
def check_required_header_comments() -> None:
"""
The EPS specification requires that some headers exist.
This should be checked when the header comments formally end,
when image data starts, or when the file ends, whichever comes first.
"""
if "PS-Adobe" not in self.info:
msg = 'EPS header missing "%!PS-Adobe" comment'
raise SyntaxError(msg)
if "BoundingBox" not in self.info:
msg = 'EPS header missing "%%BoundingBox" comment'
raise SyntaxError(msg)
def read_comment(s: str) -> bool:
nonlocal bounding_box, reading_trailer_comments
try:
m = split.match(s)
except re.error as e:
msg = "not an EPS file"
raise SyntaxError(msg) from e
if not m:
return False
k, v = m.group(1, 2)
self.info[k] = v
if k == "BoundingBox":
if v == "(atend)":
reading_trailer_comments = True
elif not bounding_box or (trailer_reached and reading_trailer_comments):
try:
# Note: The DSC spec says that BoundingBox
# fields should be integers, but some drivers
# put floating point values there anyway.
bounding_box = [int(float(i)) for i in v.split()]
except Exception:
pass
return True
while True:
byte = self.fp.read(1)
if byte == b"":
# if we didn't read a byte we must be at the end of the file
if bytes_read == 0:
if reading_header_comments:
check_required_header_comments()
break
elif byte in b"\r\n":
# if we read a line ending character, ignore it and parse what
# we have already read. if we haven't read any other characters,
# continue reading
if bytes_read == 0:
continue
else:
# ASCII/hexadecimal lines in an EPS file must not exceed
# 255 characters, not including line ending characters
if bytes_read >= 255:
# only enforce this for lines starting with a "%",
# otherwise assume it's binary data
if byte_arr[0] == ord("%"):
msg = "not an EPS file"
raise SyntaxError(msg)
else:
if reading_header_comments:
check_required_header_comments()
reading_header_comments = False
# reset bytes_read so we can keep reading
# data until the end of the line
bytes_read = 0
byte_arr[bytes_read] = byte[0]
bytes_read += 1
continue
if reading_header_comments:
# Load EPS header
# if this line doesn't start with a "%",
# or does start with "%%EndComments",
# then we've reached the end of the header/comments
if byte_arr[0] != ord("%") or bytes_mv[:13] == b"%%EndComments":
check_required_header_comments()
reading_header_comments = False
continue
s = str(bytes_mv[:bytes_read], "latin-1")
if not read_comment(s):
m = field.match(s)
if m:
k = m.group(1)
if k[:8] == "PS-Adobe":
self.info["PS-Adobe"] = k[9:]
else:
self.info[k] = ""
elif s[0] == "%":
# handle non-DSC PostScript comments that some
# tools mistakenly put in the Comments section
pass
else:
msg = "bad EPS header"
raise OSError(msg)
elif bytes_mv[:11] == b"%ImageData:":
# Check for an "ImageData" descriptor
# https://www.adobe.com/devnet-apps/photoshop/fileformatashtml/#50577413_pgfId-1035096
# If we've already read an "ImageData" descriptor,
# don't read another one.
if imagedata_size:
bytes_read = 0
continue
# Values:
# columns
# rows
# bit depth (1 or 8)
# mode (1: L, 2: LAB, 3: RGB, 4: CMYK)
# number of padding channels
# block size (number of bytes per row per channel)
# binary/ascii (1: binary, 2: ascii)
# data start identifier (the image data follows after a single line
# consisting only of this quoted value)
image_data_values = byte_arr[11:bytes_read].split(None, 7)
columns, rows, bit_depth, mode_id = (
int(value) for value in image_data_values[:4]
)
if bit_depth == 1:
self._mode = "1"
elif bit_depth == 8:
try:
self._mode = self.mode_map[mode_id]
except ValueError:
break
else:
break
# Parse the columns and rows after checking the bit depth and mode
# in case the bit depth and/or mode are invalid.
imagedata_size = columns, rows
elif bytes_mv[:5] == b"%%EOF":
break
elif trailer_reached and reading_trailer_comments:
# Load EPS trailer
s = str(bytes_mv[:bytes_read], "latin-1")
read_comment(s)
elif bytes_mv[:9] == b"%%Trailer":
trailer_reached = True
bytes_read = 0
# A "BoundingBox" is always required,
# even if an "ImageData" descriptor size exists.
if not bounding_box:
msg = "cannot determine EPS bounding box"
raise OSError(msg)
# An "ImageData" size takes precedence over the "BoundingBox".
self._size = imagedata_size or (
bounding_box[2] - bounding_box[0],
bounding_box[3] - bounding_box[1],
)
self.tile = [
ImageFile._Tile("eps", (0, 0) + self.size, offset, (length, bounding_box))
]
def _find_offset(self, fp: IO[bytes]) -> tuple[int, int]:
s = fp.read(4)
if s == b"%!PS":
# for HEAD without binary preview
fp.seek(0, io.SEEK_END)
length = fp.tell()
offset = 0
elif i32(s) == 0xC6D3D0C5:
# FIX for: Some EPS file not handled correctly / issue #302
# EPS can contain binary data
# or start directly with latin coding
# more info see:
# https://web.archive.org/web/20160528181353/http://partners.adobe.com/public/developer/en/ps/5002.EPSF_Spec.pdf
s = fp.read(8)
offset = i32(s)
length = i32(s, 4)
else:
msg = "not an EPS file"
raise SyntaxError(msg)
return length, offset
def load(
self, scale: int = 1, transparency: bool = False
) -> Image.core.PixelAccess | None:
# Load EPS via Ghostscript
if self.tile:
self.im = Ghostscript(self.tile, self.size, self.fp, scale, transparency)
self._mode = self.im.mode
self._size = self.im.size
self.tile = []
return Image.Image.load(self)
def load_seek(self, pos: int) -> None:
# we can't incrementally load, so force ImageFile.parser to
# use our custom load method by defining this method.
pass
# --------------------------------------------------------------------
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes, eps: int = 1) -> None:
"""EPS Writer for the Python Imaging Library."""
# make sure image data is available
im.load()
# determine PostScript image mode
if im.mode == "L":
operator = (8, 1, b"image")
elif im.mode == "RGB":
operator = (8, 3, b"false 3 colorimage")
elif im.mode == "CMYK":
operator = (8, 4, b"false 4 colorimage")
else:
msg = "image mode is not supported"
raise ValueError(msg)
if eps:
# write EPS header
fp.write(b"%!PS-Adobe-3.0 EPSF-3.0\n")
fp.write(b"%%Creator: PIL 0.1 EpsEncode\n")
# fp.write("%%CreationDate: %s"...)
fp.write(b"%%%%BoundingBox: 0 0 %d %d\n" % im.size)
fp.write(b"%%Pages: 1\n")
fp.write(b"%%EndComments\n")
fp.write(b"%%Page: 1 1\n")
fp.write(b"%%ImageData: %d %d " % im.size)
fp.write(b'%d %d 0 1 1 "%s"\n' % operator)
# image header
fp.write(b"gsave\n")
fp.write(b"10 dict begin\n")
fp.write(b"/buf %d string def\n" % (im.size[0] * operator[1]))
fp.write(b"%d %d scale\n" % im.size)
fp.write(b"%d %d 8\n" % im.size) # <= bits
fp.write(b"[%d 0 0 -%d 0 %d]\n" % (im.size[0], im.size[1], im.size[1]))
fp.write(b"{ currentfile buf readhexstring pop } bind\n")
fp.write(operator[2] + b"\n")
if hasattr(fp, "flush"):
fp.flush()
ImageFile._save(im, fp, [ImageFile._Tile("eps", (0, 0) + im.size, 0, None)])
fp.write(b"\n%%%%EndBinary\n")
fp.write(b"grestore end\n")
if hasattr(fp, "flush"):
fp.flush()
# --------------------------------------------------------------------
Image.register_open(EpsImageFile.format, EpsImageFile, _accept)
Image.register_save(EpsImageFile.format, _save)
Image.register_extensions(EpsImageFile.format, [".ps", ".eps"])
Image.register_mime(EpsImageFile.format, "application/postscript")

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#
# The Python Imaging Library.
# $Id$
#
# EXIF tags
#
# Copyright (c) 2003 by Secret Labs AB
#
# See the README file for information on usage and redistribution.
#
"""
This module provides constants and clear-text names for various
well-known EXIF tags.
"""
from __future__ import annotations
from enum import IntEnum
class Base(IntEnum):
# possibly incomplete
InteropIndex = 0x0001
ProcessingSoftware = 0x000B
NewSubfileType = 0x00FE
SubfileType = 0x00FF
ImageWidth = 0x0100
ImageLength = 0x0101
BitsPerSample = 0x0102
Compression = 0x0103
PhotometricInterpretation = 0x0106
Thresholding = 0x0107
CellWidth = 0x0108
CellLength = 0x0109
FillOrder = 0x010A
DocumentName = 0x010D
ImageDescription = 0x010E
Make = 0x010F
Model = 0x0110
StripOffsets = 0x0111
Orientation = 0x0112
SamplesPerPixel = 0x0115
RowsPerStrip = 0x0116
StripByteCounts = 0x0117
MinSampleValue = 0x0118
MaxSampleValue = 0x0119
XResolution = 0x011A
YResolution = 0x011B
PlanarConfiguration = 0x011C
PageName = 0x011D
FreeOffsets = 0x0120
FreeByteCounts = 0x0121
GrayResponseUnit = 0x0122
GrayResponseCurve = 0x0123
T4Options = 0x0124
T6Options = 0x0125
ResolutionUnit = 0x0128
PageNumber = 0x0129
TransferFunction = 0x012D
Software = 0x0131
DateTime = 0x0132
Artist = 0x013B
HostComputer = 0x013C
Predictor = 0x013D
WhitePoint = 0x013E
PrimaryChromaticities = 0x013F
ColorMap = 0x0140
HalftoneHints = 0x0141
TileWidth = 0x0142
TileLength = 0x0143
TileOffsets = 0x0144
TileByteCounts = 0x0145
SubIFDs = 0x014A
InkSet = 0x014C
InkNames = 0x014D
NumberOfInks = 0x014E
DotRange = 0x0150
TargetPrinter = 0x0151
ExtraSamples = 0x0152
SampleFormat = 0x0153
SMinSampleValue = 0x0154
SMaxSampleValue = 0x0155
TransferRange = 0x0156
ClipPath = 0x0157
XClipPathUnits = 0x0158
YClipPathUnits = 0x0159
Indexed = 0x015A
JPEGTables = 0x015B
OPIProxy = 0x015F
JPEGProc = 0x0200
JpegIFOffset = 0x0201
JpegIFByteCount = 0x0202
JpegRestartInterval = 0x0203
JpegLosslessPredictors = 0x0205
JpegPointTransforms = 0x0206
JpegQTables = 0x0207
JpegDCTables = 0x0208
JpegACTables = 0x0209
YCbCrCoefficients = 0x0211
YCbCrSubSampling = 0x0212
YCbCrPositioning = 0x0213
ReferenceBlackWhite = 0x0214
XMLPacket = 0x02BC
RelatedImageFileFormat = 0x1000
RelatedImageWidth = 0x1001
RelatedImageLength = 0x1002
Rating = 0x4746
RatingPercent = 0x4749
ImageID = 0x800D
CFARepeatPatternDim = 0x828D
BatteryLevel = 0x828F
Copyright = 0x8298
ExposureTime = 0x829A
FNumber = 0x829D
IPTCNAA = 0x83BB
ImageResources = 0x8649
ExifOffset = 0x8769
InterColorProfile = 0x8773
ExposureProgram = 0x8822
SpectralSensitivity = 0x8824
GPSInfo = 0x8825
ISOSpeedRatings = 0x8827
OECF = 0x8828
Interlace = 0x8829
TimeZoneOffset = 0x882A
SelfTimerMode = 0x882B
SensitivityType = 0x8830
StandardOutputSensitivity = 0x8831
RecommendedExposureIndex = 0x8832
ISOSpeed = 0x8833
ISOSpeedLatitudeyyy = 0x8834
ISOSpeedLatitudezzz = 0x8835
ExifVersion = 0x9000
DateTimeOriginal = 0x9003
DateTimeDigitized = 0x9004
OffsetTime = 0x9010
OffsetTimeOriginal = 0x9011
OffsetTimeDigitized = 0x9012
ComponentsConfiguration = 0x9101
CompressedBitsPerPixel = 0x9102
ShutterSpeedValue = 0x9201
ApertureValue = 0x9202
BrightnessValue = 0x9203
ExposureBiasValue = 0x9204
MaxApertureValue = 0x9205
SubjectDistance = 0x9206
MeteringMode = 0x9207
LightSource = 0x9208
Flash = 0x9209
FocalLength = 0x920A
Noise = 0x920D
ImageNumber = 0x9211
SecurityClassification = 0x9212
ImageHistory = 0x9213
TIFFEPStandardID = 0x9216
MakerNote = 0x927C
UserComment = 0x9286
SubsecTime = 0x9290
SubsecTimeOriginal = 0x9291
SubsecTimeDigitized = 0x9292
AmbientTemperature = 0x9400
Humidity = 0x9401
Pressure = 0x9402
WaterDepth = 0x9403
Acceleration = 0x9404
CameraElevationAngle = 0x9405
XPTitle = 0x9C9B
XPComment = 0x9C9C
XPAuthor = 0x9C9D
XPKeywords = 0x9C9E
XPSubject = 0x9C9F
FlashPixVersion = 0xA000
ColorSpace = 0xA001
ExifImageWidth = 0xA002
ExifImageHeight = 0xA003
RelatedSoundFile = 0xA004
ExifInteroperabilityOffset = 0xA005
FlashEnergy = 0xA20B
SpatialFrequencyResponse = 0xA20C
FocalPlaneXResolution = 0xA20E
FocalPlaneYResolution = 0xA20F
FocalPlaneResolutionUnit = 0xA210
SubjectLocation = 0xA214
ExposureIndex = 0xA215
SensingMethod = 0xA217
FileSource = 0xA300
SceneType = 0xA301
CFAPattern = 0xA302
CustomRendered = 0xA401
ExposureMode = 0xA402
WhiteBalance = 0xA403
DigitalZoomRatio = 0xA404
FocalLengthIn35mmFilm = 0xA405
SceneCaptureType = 0xA406
GainControl = 0xA407
Contrast = 0xA408
Saturation = 0xA409
Sharpness = 0xA40A
DeviceSettingDescription = 0xA40B
SubjectDistanceRange = 0xA40C
ImageUniqueID = 0xA420
CameraOwnerName = 0xA430
BodySerialNumber = 0xA431
LensSpecification = 0xA432
LensMake = 0xA433
LensModel = 0xA434
LensSerialNumber = 0xA435
CompositeImage = 0xA460
CompositeImageCount = 0xA461
CompositeImageExposureTimes = 0xA462
Gamma = 0xA500
PrintImageMatching = 0xC4A5
DNGVersion = 0xC612
DNGBackwardVersion = 0xC613
UniqueCameraModel = 0xC614
LocalizedCameraModel = 0xC615
CFAPlaneColor = 0xC616
CFALayout = 0xC617
LinearizationTable = 0xC618
BlackLevelRepeatDim = 0xC619
BlackLevel = 0xC61A
BlackLevelDeltaH = 0xC61B
BlackLevelDeltaV = 0xC61C
WhiteLevel = 0xC61D
DefaultScale = 0xC61E
DefaultCropOrigin = 0xC61F
DefaultCropSize = 0xC620
ColorMatrix1 = 0xC621
ColorMatrix2 = 0xC622
CameraCalibration1 = 0xC623
CameraCalibration2 = 0xC624
ReductionMatrix1 = 0xC625
ReductionMatrix2 = 0xC626
AnalogBalance = 0xC627
AsShotNeutral = 0xC628
AsShotWhiteXY = 0xC629
BaselineExposure = 0xC62A
BaselineNoise = 0xC62B
BaselineSharpness = 0xC62C
BayerGreenSplit = 0xC62D
LinearResponseLimit = 0xC62E
CameraSerialNumber = 0xC62F
LensInfo = 0xC630
ChromaBlurRadius = 0xC631
AntiAliasStrength = 0xC632
ShadowScale = 0xC633
DNGPrivateData = 0xC634
MakerNoteSafety = 0xC635
CalibrationIlluminant1 = 0xC65A
CalibrationIlluminant2 = 0xC65B
BestQualityScale = 0xC65C
RawDataUniqueID = 0xC65D
OriginalRawFileName = 0xC68B
OriginalRawFileData = 0xC68C
ActiveArea = 0xC68D
MaskedAreas = 0xC68E
AsShotICCProfile = 0xC68F
AsShotPreProfileMatrix = 0xC690
CurrentICCProfile = 0xC691
CurrentPreProfileMatrix = 0xC692
ColorimetricReference = 0xC6BF
CameraCalibrationSignature = 0xC6F3
ProfileCalibrationSignature = 0xC6F4
AsShotProfileName = 0xC6F6
NoiseReductionApplied = 0xC6F7
ProfileName = 0xC6F8
ProfileHueSatMapDims = 0xC6F9
ProfileHueSatMapData1 = 0xC6FA
ProfileHueSatMapData2 = 0xC6FB
ProfileToneCurve = 0xC6FC
ProfileEmbedPolicy = 0xC6FD
ProfileCopyright = 0xC6FE
ForwardMatrix1 = 0xC714
ForwardMatrix2 = 0xC715
PreviewApplicationName = 0xC716
PreviewApplicationVersion = 0xC717
PreviewSettingsName = 0xC718
PreviewSettingsDigest = 0xC719
PreviewColorSpace = 0xC71A
PreviewDateTime = 0xC71B
RawImageDigest = 0xC71C
OriginalRawFileDigest = 0xC71D
SubTileBlockSize = 0xC71E
RowInterleaveFactor = 0xC71F
ProfileLookTableDims = 0xC725
ProfileLookTableData = 0xC726
OpcodeList1 = 0xC740
OpcodeList2 = 0xC741
OpcodeList3 = 0xC74E
NoiseProfile = 0xC761
"""Maps EXIF tags to tag names."""
TAGS = {
**{i.value: i.name for i in Base},
0x920C: "SpatialFrequencyResponse",
0x9214: "SubjectLocation",
0x9215: "ExposureIndex",
0x828E: "CFAPattern",
0x920B: "FlashEnergy",
0x9216: "TIFF/EPStandardID",
}
class GPS(IntEnum):
GPSVersionID = 0
GPSLatitudeRef = 1
GPSLatitude = 2
GPSLongitudeRef = 3
GPSLongitude = 4
GPSAltitudeRef = 5
GPSAltitude = 6
GPSTimeStamp = 7
GPSSatellites = 8
GPSStatus = 9
GPSMeasureMode = 10
GPSDOP = 11
GPSSpeedRef = 12
GPSSpeed = 13
GPSTrackRef = 14
GPSTrack = 15
GPSImgDirectionRef = 16
GPSImgDirection = 17
GPSMapDatum = 18
GPSDestLatitudeRef = 19
GPSDestLatitude = 20
GPSDestLongitudeRef = 21
GPSDestLongitude = 22
GPSDestBearingRef = 23
GPSDestBearing = 24
GPSDestDistanceRef = 25
GPSDestDistance = 26
GPSProcessingMethod = 27
GPSAreaInformation = 28
GPSDateStamp = 29
GPSDifferential = 30
GPSHPositioningError = 31
"""Maps EXIF GPS tags to tag names."""
GPSTAGS = {i.value: i.name for i in GPS}
class Interop(IntEnum):
InteropIndex = 1
InteropVersion = 2
RelatedImageFileFormat = 4096
RelatedImageWidth = 4097
RelatedImageHeight = 4098
class IFD(IntEnum):
Exif = 34665
GPSInfo = 34853
Makernote = 37500
Interop = 40965
IFD1 = -1
class LightSource(IntEnum):
Unknown = 0
Daylight = 1
Fluorescent = 2
Tungsten = 3
Flash = 4
Fine = 9
Cloudy = 10
Shade = 11
DaylightFluorescent = 12
DayWhiteFluorescent = 13
CoolWhiteFluorescent = 14
WhiteFluorescent = 15
StandardLightA = 17
StandardLightB = 18
StandardLightC = 19
D55 = 20
D65 = 21
D75 = 22
D50 = 23
ISO = 24
Other = 255

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#
# The Python Imaging Library
# $Id$
#
# FITS file handling
#
# Copyright (c) 1998-2003 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import gzip
import math
from . import Image, ImageFile
def _accept(prefix: bytes) -> bool:
return prefix[:6] == b"SIMPLE"
class FitsImageFile(ImageFile.ImageFile):
format = "FITS"
format_description = "FITS"
def _open(self) -> None:
assert self.fp is not None
headers: dict[bytes, bytes] = {}
header_in_progress = False
decoder_name = ""
while True:
header = self.fp.read(80)
if not header:
msg = "Truncated FITS file"
raise OSError(msg)
keyword = header[:8].strip()
if keyword in (b"SIMPLE", b"XTENSION"):
header_in_progress = True
elif headers and not header_in_progress:
# This is now a data unit
break
elif keyword == b"END":
# Seek to the end of the header unit
self.fp.seek(math.ceil(self.fp.tell() / 2880) * 2880)
if not decoder_name:
decoder_name, offset, args = self._parse_headers(headers)
header_in_progress = False
continue
if decoder_name:
# Keep going to read past the headers
continue
value = header[8:].split(b"/")[0].strip()
if value.startswith(b"="):
value = value[1:].strip()
if not headers and (not _accept(keyword) or value != b"T"):
msg = "Not a FITS file"
raise SyntaxError(msg)
headers[keyword] = value
if not decoder_name:
msg = "No image data"
raise ValueError(msg)
offset += self.fp.tell() - 80
self.tile = [ImageFile._Tile(decoder_name, (0, 0) + self.size, offset, args)]
def _get_size(
self, headers: dict[bytes, bytes], prefix: bytes
) -> tuple[int, int] | None:
naxis = int(headers[prefix + b"NAXIS"])
if naxis == 0:
return None
if naxis == 1:
return 1, int(headers[prefix + b"NAXIS1"])
else:
return int(headers[prefix + b"NAXIS1"]), int(headers[prefix + b"NAXIS2"])
def _parse_headers(
self, headers: dict[bytes, bytes]
) -> tuple[str, int, tuple[str | int, ...]]:
prefix = b""
decoder_name = "raw"
offset = 0
if (
headers.get(b"XTENSION") == b"'BINTABLE'"
and headers.get(b"ZIMAGE") == b"T"
and headers[b"ZCMPTYPE"] == b"'GZIP_1 '"
):
no_prefix_size = self._get_size(headers, prefix) or (0, 0)
number_of_bits = int(headers[b"BITPIX"])
offset = no_prefix_size[0] * no_prefix_size[1] * (number_of_bits // 8)
prefix = b"Z"
decoder_name = "fits_gzip"
size = self._get_size(headers, prefix)
if not size:
return "", 0, ()
self._size = size
number_of_bits = int(headers[prefix + b"BITPIX"])
if number_of_bits == 8:
self._mode = "L"
elif number_of_bits == 16:
self._mode = "I;16"
elif number_of_bits == 32:
self._mode = "I"
elif number_of_bits in (-32, -64):
self._mode = "F"
args: tuple[str | int, ...]
if decoder_name == "raw":
args = (self.mode, 0, -1)
else:
args = (number_of_bits,)
return decoder_name, offset, args
class FitsGzipDecoder(ImageFile.PyDecoder):
_pulls_fd = True
def decode(self, buffer: bytes | Image.SupportsArrayInterface) -> tuple[int, int]:
assert self.fd is not None
value = gzip.decompress(self.fd.read())
rows = []
offset = 0
number_of_bits = min(self.args[0] // 8, 4)
for y in range(self.state.ysize):
row = bytearray()
for x in range(self.state.xsize):
row += value[offset + (4 - number_of_bits) : offset + 4]
offset += 4
rows.append(row)
self.set_as_raw(bytes([pixel for row in rows[::-1] for pixel in row]))
return -1, 0
# --------------------------------------------------------------------
# Registry
Image.register_open(FitsImageFile.format, FitsImageFile, _accept)
Image.register_decoder("fits_gzip", FitsGzipDecoder)
Image.register_extensions(FitsImageFile.format, [".fit", ".fits"])

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#
# The Python Imaging Library.
# $Id$
#
# FLI/FLC file handling.
#
# History:
# 95-09-01 fl Created
# 97-01-03 fl Fixed parser, setup decoder tile
# 98-07-15 fl Renamed offset attribute to avoid name clash
#
# Copyright (c) Secret Labs AB 1997-98.
# Copyright (c) Fredrik Lundh 1995-97.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import os
from . import Image, ImageFile, ImagePalette
from ._binary import i16le as i16
from ._binary import i32le as i32
from ._binary import o8
#
# decoder
def _accept(prefix: bytes) -> bool:
return (
len(prefix) >= 6
and i16(prefix, 4) in [0xAF11, 0xAF12]
and i16(prefix, 14) in [0, 3] # flags
)
##
# Image plugin for the FLI/FLC animation format. Use the <b>seek</b>
# method to load individual frames.
class FliImageFile(ImageFile.ImageFile):
format = "FLI"
format_description = "Autodesk FLI/FLC Animation"
_close_exclusive_fp_after_loading = False
def _open(self) -> None:
# HEAD
s = self.fp.read(128)
if not (_accept(s) and s[20:22] == b"\x00\x00"):
msg = "not an FLI/FLC file"
raise SyntaxError(msg)
# frames
self.n_frames = i16(s, 6)
self.is_animated = self.n_frames > 1
# image characteristics
self._mode = "P"
self._size = i16(s, 8), i16(s, 10)
# animation speed
duration = i32(s, 16)
magic = i16(s, 4)
if magic == 0xAF11:
duration = (duration * 1000) // 70
self.info["duration"] = duration
# look for palette
palette = [(a, a, a) for a in range(256)]
s = self.fp.read(16)
self.__offset = 128
if i16(s, 4) == 0xF100:
# prefix chunk; ignore it
self.__offset = self.__offset + i32(s)
self.fp.seek(self.__offset)
s = self.fp.read(16)
if i16(s, 4) == 0xF1FA:
# look for palette chunk
number_of_subchunks = i16(s, 6)
chunk_size: int | None = None
for _ in range(number_of_subchunks):
if chunk_size is not None:
self.fp.seek(chunk_size - 6, os.SEEK_CUR)
s = self.fp.read(6)
chunk_type = i16(s, 4)
if chunk_type in (4, 11):
self._palette(palette, 2 if chunk_type == 11 else 0)
break
chunk_size = i32(s)
if not chunk_size:
break
self.palette = ImagePalette.raw(
"RGB", b"".join(o8(r) + o8(g) + o8(b) for (r, g, b) in palette)
)
# set things up to decode first frame
self.__frame = -1
self._fp = self.fp
self.__rewind = self.fp.tell()
self.seek(0)
def _palette(self, palette: list[tuple[int, int, int]], shift: int) -> None:
# load palette
i = 0
for e in range(i16(self.fp.read(2))):
s = self.fp.read(2)
i = i + s[0]
n = s[1]
if n == 0:
n = 256
s = self.fp.read(n * 3)
for n in range(0, len(s), 3):
r = s[n] << shift
g = s[n + 1] << shift
b = s[n + 2] << shift
palette[i] = (r, g, b)
i += 1
def seek(self, frame: int) -> None:
if not self._seek_check(frame):
return
if frame < self.__frame:
self._seek(0)
for f in range(self.__frame + 1, frame + 1):
self._seek(f)
def _seek(self, frame: int) -> None:
if frame == 0:
self.__frame = -1
self._fp.seek(self.__rewind)
self.__offset = 128
else:
# ensure that the previous frame was loaded
self.load()
if frame != self.__frame + 1:
msg = f"cannot seek to frame {frame}"
raise ValueError(msg)
self.__frame = frame
# move to next frame
self.fp = self._fp
self.fp.seek(self.__offset)
s = self.fp.read(4)
if not s:
msg = "missing frame size"
raise EOFError(msg)
framesize = i32(s)
self.decodermaxblock = framesize
self.tile = [ImageFile._Tile("fli", (0, 0) + self.size, self.__offset, None)]
self.__offset += framesize
def tell(self) -> int:
return self.__frame
#
# registry
Image.register_open(FliImageFile.format, FliImageFile, _accept)
Image.register_extensions(FliImageFile.format, [".fli", ".flc"])

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#
# The Python Imaging Library
# $Id$
#
# base class for raster font file parsers
#
# history:
# 1997-06-05 fl created
# 1997-08-19 fl restrict image width
#
# Copyright (c) 1997-1998 by Secret Labs AB
# Copyright (c) 1997-1998 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import os
from typing import BinaryIO
from . import Image, _binary
WIDTH = 800
def puti16(
fp: BinaryIO, values: tuple[int, int, int, int, int, int, int, int, int, int]
) -> None:
"""Write network order (big-endian) 16-bit sequence"""
for v in values:
if v < 0:
v += 65536
fp.write(_binary.o16be(v))
class FontFile:
"""Base class for raster font file handlers."""
bitmap: Image.Image | None = None
def __init__(self) -> None:
self.info: dict[bytes, bytes | int] = {}
self.glyph: list[
tuple[
tuple[int, int],
tuple[int, int, int, int],
tuple[int, int, int, int],
Image.Image,
]
| None
] = [None] * 256
def __getitem__(self, ix: int) -> (
tuple[
tuple[int, int],
tuple[int, int, int, int],
tuple[int, int, int, int],
Image.Image,
]
| None
):
return self.glyph[ix]
def compile(self) -> None:
"""Create metrics and bitmap"""
if self.bitmap:
return
# create bitmap large enough to hold all data
h = w = maxwidth = 0
lines = 1
for glyph in self.glyph:
if glyph:
d, dst, src, im = glyph
h = max(h, src[3] - src[1])
w = w + (src[2] - src[0])
if w > WIDTH:
lines += 1
w = src[2] - src[0]
maxwidth = max(maxwidth, w)
xsize = maxwidth
ysize = lines * h
if xsize == 0 and ysize == 0:
return
self.ysize = h
# paste glyphs into bitmap
self.bitmap = Image.new("1", (xsize, ysize))
self.metrics: list[
tuple[tuple[int, int], tuple[int, int, int, int], tuple[int, int, int, int]]
| None
] = [None] * 256
x = y = 0
for i in range(256):
glyph = self[i]
if glyph:
d, dst, src, im = glyph
xx = src[2] - src[0]
x0, y0 = x, y
x = x + xx
if x > WIDTH:
x, y = 0, y + h
x0, y0 = x, y
x = xx
s = src[0] + x0, src[1] + y0, src[2] + x0, src[3] + y0
self.bitmap.paste(im.crop(src), s)
self.metrics[i] = d, dst, s
def save(self, filename: str) -> None:
"""Save font"""
self.compile()
# font data
if not self.bitmap:
msg = "No bitmap created"
raise ValueError(msg)
self.bitmap.save(os.path.splitext(filename)[0] + ".pbm", "PNG")
# font metrics
with open(os.path.splitext(filename)[0] + ".pil", "wb") as fp:
fp.write(b"PILfont\n")
fp.write(f";;;;;;{self.ysize};\n".encode("ascii")) # HACK!!!
fp.write(b"DATA\n")
for id in range(256):
m = self.metrics[id]
if not m:
puti16(fp, (0,) * 10)
else:
puti16(fp, m[0] + m[1] + m[2])

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#
# THIS IS WORK IN PROGRESS
#
# The Python Imaging Library.
# $Id$
#
# FlashPix support for PIL
#
# History:
# 97-01-25 fl Created (reads uncompressed RGB images only)
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1997.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import olefile
from . import Image, ImageFile
from ._binary import i32le as i32
# we map from colour field tuples to (mode, rawmode) descriptors
MODES = {
# opacity
(0x00007FFE,): ("A", "L"),
# monochrome
(0x00010000,): ("L", "L"),
(0x00018000, 0x00017FFE): ("RGBA", "LA"),
# photo YCC
(0x00020000, 0x00020001, 0x00020002): ("RGB", "YCC;P"),
(0x00028000, 0x00028001, 0x00028002, 0x00027FFE): ("RGBA", "YCCA;P"),
# standard RGB (NIFRGB)
(0x00030000, 0x00030001, 0x00030002): ("RGB", "RGB"),
(0x00038000, 0x00038001, 0x00038002, 0x00037FFE): ("RGBA", "RGBA"),
}
#
# --------------------------------------------------------------------
def _accept(prefix: bytes) -> bool:
return prefix[:8] == olefile.MAGIC
##
# Image plugin for the FlashPix images.
class FpxImageFile(ImageFile.ImageFile):
format = "FPX"
format_description = "FlashPix"
def _open(self) -> None:
#
# read the OLE directory and see if this is a likely
# to be a FlashPix file
try:
self.ole = olefile.OleFileIO(self.fp)
except OSError as e:
msg = "not an FPX file; invalid OLE file"
raise SyntaxError(msg) from e
root = self.ole.root
if not root or root.clsid != "56616700-C154-11CE-8553-00AA00A1F95B":
msg = "not an FPX file; bad root CLSID"
raise SyntaxError(msg)
self._open_index(1)
def _open_index(self, index: int = 1) -> None:
#
# get the Image Contents Property Set
prop = self.ole.getproperties(
[f"Data Object Store {index:06d}", "\005Image Contents"]
)
# size (highest resolution)
assert isinstance(prop[0x1000002], int)
assert isinstance(prop[0x1000003], int)
self._size = prop[0x1000002], prop[0x1000003]
size = max(self.size)
i = 1
while size > 64:
size = size // 2
i += 1
self.maxid = i - 1
# mode. instead of using a single field for this, flashpix
# requires you to specify the mode for each channel in each
# resolution subimage, and leaves it to the decoder to make
# sure that they all match. for now, we'll cheat and assume
# that this is always the case.
id = self.maxid << 16
s = prop[0x2000002 | id]
if not isinstance(s, bytes) or (bands := i32(s, 4)) > 4:
msg = "Invalid number of bands"
raise OSError(msg)
# note: for now, we ignore the "uncalibrated" flag
colors = tuple(i32(s, 8 + i * 4) & 0x7FFFFFFF for i in range(bands))
self._mode, self.rawmode = MODES[colors]
# load JPEG tables, if any
self.jpeg = {}
for i in range(256):
id = 0x3000001 | (i << 16)
if id in prop:
self.jpeg[i] = prop[id]
self._open_subimage(1, self.maxid)
def _open_subimage(self, index: int = 1, subimage: int = 0) -> None:
#
# setup tile descriptors for a given subimage
stream = [
f"Data Object Store {index:06d}",
f"Resolution {subimage:04d}",
"Subimage 0000 Header",
]
fp = self.ole.openstream(stream)
# skip prefix
fp.read(28)
# header stream
s = fp.read(36)
size = i32(s, 4), i32(s, 8)
# tilecount = i32(s, 12)
tilesize = i32(s, 16), i32(s, 20)
# channels = i32(s, 24)
offset = i32(s, 28)
length = i32(s, 32)
if size != self.size:
msg = "subimage mismatch"
raise OSError(msg)
# get tile descriptors
fp.seek(28 + offset)
s = fp.read(i32(s, 12) * length)
x = y = 0
xsize, ysize = size
xtile, ytile = tilesize
self.tile = []
for i in range(0, len(s), length):
x1 = min(xsize, x + xtile)
y1 = min(ysize, y + ytile)
compression = i32(s, i + 8)
if compression == 0:
self.tile.append(
ImageFile._Tile(
"raw",
(x, y, x1, y1),
i32(s, i) + 28,
(self.rawmode,),
)
)
elif compression == 1:
# FIXME: the fill decoder is not implemented
self.tile.append(
ImageFile._Tile(
"fill",
(x, y, x1, y1),
i32(s, i) + 28,
(self.rawmode, s[12:16]),
)
)
elif compression == 2:
internal_color_conversion = s[14]
jpeg_tables = s[15]
rawmode = self.rawmode
if internal_color_conversion:
# The image is stored as usual (usually YCbCr).
if rawmode == "RGBA":
# For "RGBA", data is stored as YCbCrA based on
# negative RGB. The following trick works around
# this problem :
jpegmode, rawmode = "YCbCrK", "CMYK"
else:
jpegmode = None # let the decoder decide
else:
# The image is stored as defined by rawmode
jpegmode = rawmode
self.tile.append(
ImageFile._Tile(
"jpeg",
(x, y, x1, y1),
i32(s, i) + 28,
(rawmode, jpegmode),
)
)
# FIXME: jpeg tables are tile dependent; the prefix
# data must be placed in the tile descriptor itself!
if jpeg_tables:
self.tile_prefix = self.jpeg[jpeg_tables]
else:
msg = "unknown/invalid compression"
raise OSError(msg)
x = x + xtile
if x >= xsize:
x, y = 0, y + ytile
if y >= ysize:
break # isn't really required
self.stream = stream
self._fp = self.fp
self.fp = None
def load(self) -> Image.core.PixelAccess | None:
if not self.fp:
self.fp = self.ole.openstream(self.stream[:2] + ["Subimage 0000 Data"])
return ImageFile.ImageFile.load(self)
def close(self) -> None:
self.ole.close()
super().close()
def __exit__(self, *args: object) -> None:
self.ole.close()
super().__exit__()
#
# --------------------------------------------------------------------
Image.register_open(FpxImageFile.format, FpxImageFile, _accept)
Image.register_extension(FpxImageFile.format, ".fpx")

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"""
A Pillow loader for .ftc and .ftu files (FTEX)
Jerome Leclanche <jerome@leclan.ch>
The contents of this file are hereby released in the public domain (CC0)
Full text of the CC0 license:
https://creativecommons.org/publicdomain/zero/1.0/
Independence War 2: Edge Of Chaos - Texture File Format - 16 October 2001
The textures used for 3D objects in Independence War 2: Edge Of Chaos are in a
packed custom format called FTEX. This file format uses file extensions FTC
and FTU.
* FTC files are compressed textures (using standard texture compression).
* FTU files are not compressed.
Texture File Format
The FTC and FTU texture files both use the same format. This
has the following structure:
{header}
{format_directory}
{data}
Where:
{header} = {
u32:magic,
u32:version,
u32:width,
u32:height,
u32:mipmap_count,
u32:format_count
}
* The "magic" number is "FTEX".
* "width" and "height" are the dimensions of the texture.
* "mipmap_count" is the number of mipmaps in the texture.
* "format_count" is the number of texture formats (different versions of the
same texture) in this file.
{format_directory} = format_count * { u32:format, u32:where }
The format value is 0 for DXT1 compressed textures and 1 for 24-bit RGB
uncompressed textures.
The texture data for a format starts at the position "where" in the file.
Each set of texture data in the file has the following structure:
{data} = format_count * { u32:mipmap_size, mipmap_size * { u8 } }
* "mipmap_size" is the number of bytes in that mip level. For compressed
textures this is the size of the texture data compressed with DXT1. For 24 bit
uncompressed textures, this is 3 * width * height. Following this are the image
bytes for that mipmap level.
Note: All data is stored in little-Endian (Intel) byte order.
"""
from __future__ import annotations
import struct
from enum import IntEnum
from io import BytesIO
from . import Image, ImageFile
MAGIC = b"FTEX"
class Format(IntEnum):
DXT1 = 0
UNCOMPRESSED = 1
class FtexImageFile(ImageFile.ImageFile):
format = "FTEX"
format_description = "Texture File Format (IW2:EOC)"
def _open(self) -> None:
if not _accept(self.fp.read(4)):
msg = "not an FTEX file"
raise SyntaxError(msg)
struct.unpack("<i", self.fp.read(4)) # version
self._size = struct.unpack("<2i", self.fp.read(8))
mipmap_count, format_count = struct.unpack("<2i", self.fp.read(8))
self._mode = "RGB"
# Only support single-format files.
# I don't know of any multi-format file.
assert format_count == 1
format, where = struct.unpack("<2i", self.fp.read(8))
self.fp.seek(where)
(mipmap_size,) = struct.unpack("<i", self.fp.read(4))
data = self.fp.read(mipmap_size)
if format == Format.DXT1:
self._mode = "RGBA"
self.tile = [ImageFile._Tile("bcn", (0, 0) + self.size, 0, (1,))]
elif format == Format.UNCOMPRESSED:
self.tile = [ImageFile._Tile("raw", (0, 0) + self.size, 0, ("RGB", 0, 1))]
else:
msg = f"Invalid texture compression format: {repr(format)}"
raise ValueError(msg)
self.fp.close()
self.fp = BytesIO(data)
def load_seek(self, pos: int) -> None:
pass
def _accept(prefix: bytes) -> bool:
return prefix[:4] == MAGIC
Image.register_open(FtexImageFile.format, FtexImageFile, _accept)
Image.register_extensions(FtexImageFile.format, [".ftc", ".ftu"])

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#
# The Python Imaging Library
#
# load a GIMP brush file
#
# History:
# 96-03-14 fl Created
# 16-01-08 es Version 2
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1996.
# Copyright (c) Eric Soroos 2016.
#
# See the README file for information on usage and redistribution.
#
#
# See https://github.com/GNOME/gimp/blob/mainline/devel-docs/gbr.txt for
# format documentation.
#
# This code Interprets version 1 and 2 .gbr files.
# Version 1 files are obsolete, and should not be used for new
# brushes.
# Version 2 files are saved by GIMP v2.8 (at least)
# Version 3 files have a format specifier of 18 for 16bit floats in
# the color depth field. This is currently unsupported by Pillow.
from __future__ import annotations
from . import Image, ImageFile
from ._binary import i32be as i32
def _accept(prefix: bytes) -> bool:
return len(prefix) >= 8 and i32(prefix, 0) >= 20 and i32(prefix, 4) in (1, 2)
##
# Image plugin for the GIMP brush format.
class GbrImageFile(ImageFile.ImageFile):
format = "GBR"
format_description = "GIMP brush file"
def _open(self) -> None:
header_size = i32(self.fp.read(4))
if header_size < 20:
msg = "not a GIMP brush"
raise SyntaxError(msg)
version = i32(self.fp.read(4))
if version not in (1, 2):
msg = f"Unsupported GIMP brush version: {version}"
raise SyntaxError(msg)
width = i32(self.fp.read(4))
height = i32(self.fp.read(4))
color_depth = i32(self.fp.read(4))
if width <= 0 or height <= 0:
msg = "not a GIMP brush"
raise SyntaxError(msg)
if color_depth not in (1, 4):
msg = f"Unsupported GIMP brush color depth: {color_depth}"
raise SyntaxError(msg)
if version == 1:
comment_length = header_size - 20
else:
comment_length = header_size - 28
magic_number = self.fp.read(4)
if magic_number != b"GIMP":
msg = "not a GIMP brush, bad magic number"
raise SyntaxError(msg)
self.info["spacing"] = i32(self.fp.read(4))
comment = self.fp.read(comment_length)[:-1]
if color_depth == 1:
self._mode = "L"
else:
self._mode = "RGBA"
self._size = width, height
self.info["comment"] = comment
# Image might not be small
Image._decompression_bomb_check(self.size)
# Data is an uncompressed block of w * h * bytes/pixel
self._data_size = width * height * color_depth
def load(self) -> Image.core.PixelAccess | None:
if self._im is None:
self.im = Image.core.new(self.mode, self.size)
self.frombytes(self.fp.read(self._data_size))
return Image.Image.load(self)
#
# registry
Image.register_open(GbrImageFile.format, GbrImageFile, _accept)
Image.register_extension(GbrImageFile.format, ".gbr")

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#
# The Python Imaging Library.
# $Id$
#
# GD file handling
#
# History:
# 1996-04-12 fl Created
#
# Copyright (c) 1997 by Secret Labs AB.
# Copyright (c) 1996 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
"""
.. note::
This format cannot be automatically recognized, so the
class is not registered for use with :py:func:`PIL.Image.open()`. To open a
gd file, use the :py:func:`PIL.GdImageFile.open()` function instead.
.. warning::
THE GD FORMAT IS NOT DESIGNED FOR DATA INTERCHANGE. This
implementation is provided for convenience and demonstrational
purposes only.
"""
from __future__ import annotations
from typing import IO
from . import ImageFile, ImagePalette, UnidentifiedImageError
from ._binary import i16be as i16
from ._binary import i32be as i32
from ._typing import StrOrBytesPath
class GdImageFile(ImageFile.ImageFile):
"""
Image plugin for the GD uncompressed format. Note that this format
is not supported by the standard :py:func:`PIL.Image.open()` function. To use
this plugin, you have to import the :py:mod:`PIL.GdImageFile` module and
use the :py:func:`PIL.GdImageFile.open()` function.
"""
format = "GD"
format_description = "GD uncompressed images"
def _open(self) -> None:
# Header
assert self.fp is not None
s = self.fp.read(1037)
if i16(s) not in [65534, 65535]:
msg = "Not a valid GD 2.x .gd file"
raise SyntaxError(msg)
self._mode = "L" # FIXME: "P"
self._size = i16(s, 2), i16(s, 4)
true_color = s[6]
true_color_offset = 2 if true_color else 0
# transparency index
tindex = i32(s, 7 + true_color_offset)
if tindex < 256:
self.info["transparency"] = tindex
self.palette = ImagePalette.raw(
"XBGR", s[7 + true_color_offset + 4 : 7 + true_color_offset + 4 + 256 * 4]
)
self.tile = [
ImageFile._Tile(
"raw",
(0, 0) + self.size,
7 + true_color_offset + 4 + 256 * 4,
("L", 0, 1),
)
]
def open(fp: StrOrBytesPath | IO[bytes], mode: str = "r") -> GdImageFile:
"""
Load texture from a GD image file.
:param fp: GD file name, or an opened file handle.
:param mode: Optional mode. In this version, if the mode argument
is given, it must be "r".
:returns: An image instance.
:raises OSError: If the image could not be read.
"""
if mode != "r":
msg = "bad mode"
raise ValueError(msg)
try:
return GdImageFile(fp)
except SyntaxError as e:
msg = "cannot identify this image file"
raise UnidentifiedImageError(msg) from e

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#
# Python Imaging Library
# $Id$
#
# stuff to read (and render) GIMP gradient files
#
# History:
# 97-08-23 fl Created
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1997.
#
# See the README file for information on usage and redistribution.
#
"""
Stuff to translate curve segments to palette values (derived from
the corresponding code in GIMP, written by Federico Mena Quintero.
See the GIMP distribution for more information.)
"""
from __future__ import annotations
from math import log, pi, sin, sqrt
from typing import IO, Callable
from ._binary import o8
EPSILON = 1e-10
"""""" # Enable auto-doc for data member
def linear(middle: float, pos: float) -> float:
if pos <= middle:
if middle < EPSILON:
return 0.0
else:
return 0.5 * pos / middle
else:
pos = pos - middle
middle = 1.0 - middle
if middle < EPSILON:
return 1.0
else:
return 0.5 + 0.5 * pos / middle
def curved(middle: float, pos: float) -> float:
return pos ** (log(0.5) / log(max(middle, EPSILON)))
def sine(middle: float, pos: float) -> float:
return (sin((-pi / 2.0) + pi * linear(middle, pos)) + 1.0) / 2.0
def sphere_increasing(middle: float, pos: float) -> float:
return sqrt(1.0 - (linear(middle, pos) - 1.0) ** 2)
def sphere_decreasing(middle: float, pos: float) -> float:
return 1.0 - sqrt(1.0 - linear(middle, pos) ** 2)
SEGMENTS = [linear, curved, sine, sphere_increasing, sphere_decreasing]
"""""" # Enable auto-doc for data member
class GradientFile:
gradient: (
list[
tuple[
float,
float,
float,
list[float],
list[float],
Callable[[float, float], float],
]
]
| None
) = None
def getpalette(self, entries: int = 256) -> tuple[bytes, str]:
assert self.gradient is not None
palette = []
ix = 0
x0, x1, xm, rgb0, rgb1, segment = self.gradient[ix]
for i in range(entries):
x = i / (entries - 1)
while x1 < x:
ix += 1
x0, x1, xm, rgb0, rgb1, segment = self.gradient[ix]
w = x1 - x0
if w < EPSILON:
scale = segment(0.5, 0.5)
else:
scale = segment((xm - x0) / w, (x - x0) / w)
# expand to RGBA
r = o8(int(255 * ((rgb1[0] - rgb0[0]) * scale + rgb0[0]) + 0.5))
g = o8(int(255 * ((rgb1[1] - rgb0[1]) * scale + rgb0[1]) + 0.5))
b = o8(int(255 * ((rgb1[2] - rgb0[2]) * scale + rgb0[2]) + 0.5))
a = o8(int(255 * ((rgb1[3] - rgb0[3]) * scale + rgb0[3]) + 0.5))
# add to palette
palette.append(r + g + b + a)
return b"".join(palette), "RGBA"
class GimpGradientFile(GradientFile):
"""File handler for GIMP's gradient format."""
def __init__(self, fp: IO[bytes]) -> None:
if fp.readline()[:13] != b"GIMP Gradient":
msg = "not a GIMP gradient file"
raise SyntaxError(msg)
line = fp.readline()
# GIMP 1.2 gradient files don't contain a name, but GIMP 1.3 files do
if line.startswith(b"Name: "):
line = fp.readline().strip()
count = int(line)
self.gradient = []
for i in range(count):
s = fp.readline().split()
w = [float(x) for x in s[:11]]
x0, x1 = w[0], w[2]
xm = w[1]
rgb0 = w[3:7]
rgb1 = w[7:11]
segment = SEGMENTS[int(s[11])]
cspace = int(s[12])
if cspace != 0:
msg = "cannot handle HSV colour space"
raise OSError(msg)
self.gradient.append((x0, x1, xm, rgb0, rgb1, segment))

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#
# Python Imaging Library
# $Id$
#
# stuff to read GIMP palette files
#
# History:
# 1997-08-23 fl Created
# 2004-09-07 fl Support GIMP 2.0 palette files.
#
# Copyright (c) Secret Labs AB 1997-2004. All rights reserved.
# Copyright (c) Fredrik Lundh 1997-2004.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import re
from typing import IO
from ._binary import o8
class GimpPaletteFile:
"""File handler for GIMP's palette format."""
rawmode = "RGB"
def __init__(self, fp: IO[bytes]) -> None:
palette = [o8(i) * 3 for i in range(256)]
if fp.readline()[:12] != b"GIMP Palette":
msg = "not a GIMP palette file"
raise SyntaxError(msg)
for i in range(256):
s = fp.readline()
if not s:
break
# skip fields and comment lines
if re.match(rb"\w+:|#", s):
continue
if len(s) > 100:
msg = "bad palette file"
raise SyntaxError(msg)
v = tuple(map(int, s.split()[:3]))
if len(v) != 3:
msg = "bad palette entry"
raise ValueError(msg)
palette[i] = o8(v[0]) + o8(v[1]) + o8(v[2])
self.palette = b"".join(palette)
def getpalette(self) -> tuple[bytes, str]:
return self.palette, self.rawmode

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#
# The Python Imaging Library
# $Id$
#
# GRIB stub adapter
#
# Copyright (c) 1996-2003 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from typing import IO
from . import Image, ImageFile
_handler = None
def register_handler(handler: ImageFile.StubHandler | None) -> None:
"""
Install application-specific GRIB image handler.
:param handler: Handler object.
"""
global _handler
_handler = handler
# --------------------------------------------------------------------
# Image adapter
def _accept(prefix: bytes) -> bool:
return prefix[:4] == b"GRIB" and prefix[7] == 1
class GribStubImageFile(ImageFile.StubImageFile):
format = "GRIB"
format_description = "GRIB"
def _open(self) -> None:
offset = self.fp.tell()
if not _accept(self.fp.read(8)):
msg = "Not a GRIB file"
raise SyntaxError(msg)
self.fp.seek(offset)
# make something up
self._mode = "F"
self._size = 1, 1
loader = self._load()
if loader:
loader.open(self)
def _load(self) -> ImageFile.StubHandler | None:
return _handler
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
if _handler is None or not hasattr(_handler, "save"):
msg = "GRIB save handler not installed"
raise OSError(msg)
_handler.save(im, fp, filename)
# --------------------------------------------------------------------
# Registry
Image.register_open(GribStubImageFile.format, GribStubImageFile, _accept)
Image.register_save(GribStubImageFile.format, _save)
Image.register_extension(GribStubImageFile.format, ".grib")

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#
# The Python Imaging Library
# $Id$
#
# HDF5 stub adapter
#
# Copyright (c) 2000-2003 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from typing import IO
from . import Image, ImageFile
_handler = None
def register_handler(handler: ImageFile.StubHandler | None) -> None:
"""
Install application-specific HDF5 image handler.
:param handler: Handler object.
"""
global _handler
_handler = handler
# --------------------------------------------------------------------
# Image adapter
def _accept(prefix: bytes) -> bool:
return prefix[:8] == b"\x89HDF\r\n\x1a\n"
class HDF5StubImageFile(ImageFile.StubImageFile):
format = "HDF5"
format_description = "HDF5"
def _open(self) -> None:
offset = self.fp.tell()
if not _accept(self.fp.read(8)):
msg = "Not an HDF file"
raise SyntaxError(msg)
self.fp.seek(offset)
# make something up
self._mode = "F"
self._size = 1, 1
loader = self._load()
if loader:
loader.open(self)
def _load(self) -> ImageFile.StubHandler | None:
return _handler
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
if _handler is None or not hasattr(_handler, "save"):
msg = "HDF5 save handler not installed"
raise OSError(msg)
_handler.save(im, fp, filename)
# --------------------------------------------------------------------
# Registry
Image.register_open(HDF5StubImageFile.format, HDF5StubImageFile, _accept)
Image.register_save(HDF5StubImageFile.format, _save)
Image.register_extensions(HDF5StubImageFile.format, [".h5", ".hdf"])

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#
# The Python Imaging Library.
# $Id$
#
# macOS icns file decoder, based on icns.py by Bob Ippolito.
#
# history:
# 2004-10-09 fl Turned into a PIL plugin; removed 2.3 dependencies.
# 2020-04-04 Allow saving on all operating systems.
#
# Copyright (c) 2004 by Bob Ippolito.
# Copyright (c) 2004 by Secret Labs.
# Copyright (c) 2004 by Fredrik Lundh.
# Copyright (c) 2014 by Alastair Houghton.
# Copyright (c) 2020 by Pan Jing.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import io
import os
import struct
import sys
from typing import IO
from . import Image, ImageFile, PngImagePlugin, features
from ._deprecate import deprecate
enable_jpeg2k = features.check_codec("jpg_2000")
if enable_jpeg2k:
from . import Jpeg2KImagePlugin
MAGIC = b"icns"
HEADERSIZE = 8
def nextheader(fobj: IO[bytes]) -> tuple[bytes, int]:
return struct.unpack(">4sI", fobj.read(HEADERSIZE))
def read_32t(
fobj: IO[bytes], start_length: tuple[int, int], size: tuple[int, int, int]
) -> dict[str, Image.Image]:
# The 128x128 icon seems to have an extra header for some reason.
(start, length) = start_length
fobj.seek(start)
sig = fobj.read(4)
if sig != b"\x00\x00\x00\x00":
msg = "Unknown signature, expecting 0x00000000"
raise SyntaxError(msg)
return read_32(fobj, (start + 4, length - 4), size)
def read_32(
fobj: IO[bytes], start_length: tuple[int, int], size: tuple[int, int, int]
) -> dict[str, Image.Image]:
"""
Read a 32bit RGB icon resource. Seems to be either uncompressed or
an RLE packbits-like scheme.
"""
(start, length) = start_length
fobj.seek(start)
pixel_size = (size[0] * size[2], size[1] * size[2])
sizesq = pixel_size[0] * pixel_size[1]
if length == sizesq * 3:
# uncompressed ("RGBRGBGB")
indata = fobj.read(length)
im = Image.frombuffer("RGB", pixel_size, indata, "raw", "RGB", 0, 1)
else:
# decode image
im = Image.new("RGB", pixel_size, None)
for band_ix in range(3):
data = []
bytesleft = sizesq
while bytesleft > 0:
byte = fobj.read(1)
if not byte:
break
byte_int = byte[0]
if byte_int & 0x80:
blocksize = byte_int - 125
byte = fobj.read(1)
for i in range(blocksize):
data.append(byte)
else:
blocksize = byte_int + 1
data.append(fobj.read(blocksize))
bytesleft -= blocksize
if bytesleft <= 0:
break
if bytesleft != 0:
msg = f"Error reading channel [{repr(bytesleft)} left]"
raise SyntaxError(msg)
band = Image.frombuffer("L", pixel_size, b"".join(data), "raw", "L", 0, 1)
im.im.putband(band.im, band_ix)
return {"RGB": im}
def read_mk(
fobj: IO[bytes], start_length: tuple[int, int], size: tuple[int, int, int]
) -> dict[str, Image.Image]:
# Alpha masks seem to be uncompressed
start = start_length[0]
fobj.seek(start)
pixel_size = (size[0] * size[2], size[1] * size[2])
sizesq = pixel_size[0] * pixel_size[1]
band = Image.frombuffer("L", pixel_size, fobj.read(sizesq), "raw", "L", 0, 1)
return {"A": band}
def read_png_or_jpeg2000(
fobj: IO[bytes], start_length: tuple[int, int], size: tuple[int, int, int]
) -> dict[str, Image.Image]:
(start, length) = start_length
fobj.seek(start)
sig = fobj.read(12)
im: Image.Image
if sig[:8] == b"\x89PNG\x0d\x0a\x1a\x0a":
fobj.seek(start)
im = PngImagePlugin.PngImageFile(fobj)
Image._decompression_bomb_check(im.size)
return {"RGBA": im}
elif (
sig[:4] == b"\xff\x4f\xff\x51"
or sig[:4] == b"\x0d\x0a\x87\x0a"
or sig == b"\x00\x00\x00\x0cjP \x0d\x0a\x87\x0a"
):
if not enable_jpeg2k:
msg = (
"Unsupported icon subimage format (rebuild PIL "
"with JPEG 2000 support to fix this)"
)
raise ValueError(msg)
# j2k, jpc or j2c
fobj.seek(start)
jp2kstream = fobj.read(length)
f = io.BytesIO(jp2kstream)
im = Jpeg2KImagePlugin.Jpeg2KImageFile(f)
Image._decompression_bomb_check(im.size)
if im.mode != "RGBA":
im = im.convert("RGBA")
return {"RGBA": im}
else:
msg = "Unsupported icon subimage format"
raise ValueError(msg)
class IcnsFile:
SIZES = {
(512, 512, 2): [(b"ic10", read_png_or_jpeg2000)],
(512, 512, 1): [(b"ic09", read_png_or_jpeg2000)],
(256, 256, 2): [(b"ic14", read_png_or_jpeg2000)],
(256, 256, 1): [(b"ic08", read_png_or_jpeg2000)],
(128, 128, 2): [(b"ic13", read_png_or_jpeg2000)],
(128, 128, 1): [
(b"ic07", read_png_or_jpeg2000),
(b"it32", read_32t),
(b"t8mk", read_mk),
],
(64, 64, 1): [(b"icp6", read_png_or_jpeg2000)],
(32, 32, 2): [(b"ic12", read_png_or_jpeg2000)],
(48, 48, 1): [(b"ih32", read_32), (b"h8mk", read_mk)],
(32, 32, 1): [
(b"icp5", read_png_or_jpeg2000),
(b"il32", read_32),
(b"l8mk", read_mk),
],
(16, 16, 2): [(b"ic11", read_png_or_jpeg2000)],
(16, 16, 1): [
(b"icp4", read_png_or_jpeg2000),
(b"is32", read_32),
(b"s8mk", read_mk),
],
}
def __init__(self, fobj: IO[bytes]) -> None:
"""
fobj is a file-like object as an icns resource
"""
# signature : (start, length)
self.dct = {}
self.fobj = fobj
sig, filesize = nextheader(fobj)
if not _accept(sig):
msg = "not an icns file"
raise SyntaxError(msg)
i = HEADERSIZE
while i < filesize:
sig, blocksize = nextheader(fobj)
if blocksize <= 0:
msg = "invalid block header"
raise SyntaxError(msg)
i += HEADERSIZE
blocksize -= HEADERSIZE
self.dct[sig] = (i, blocksize)
fobj.seek(blocksize, io.SEEK_CUR)
i += blocksize
def itersizes(self) -> list[tuple[int, int, int]]:
sizes = []
for size, fmts in self.SIZES.items():
for fmt, reader in fmts:
if fmt in self.dct:
sizes.append(size)
break
return sizes
def bestsize(self) -> tuple[int, int, int]:
sizes = self.itersizes()
if not sizes:
msg = "No 32bit icon resources found"
raise SyntaxError(msg)
return max(sizes)
def dataforsize(self, size: tuple[int, int, int]) -> dict[str, Image.Image]:
"""
Get an icon resource as {channel: array}. Note that
the arrays are bottom-up like windows bitmaps and will likely
need to be flipped or transposed in some way.
"""
dct = {}
for code, reader in self.SIZES[size]:
desc = self.dct.get(code)
if desc is not None:
dct.update(reader(self.fobj, desc, size))
return dct
def getimage(
self, size: tuple[int, int] | tuple[int, int, int] | None = None
) -> Image.Image:
if size is None:
size = self.bestsize()
elif len(size) == 2:
size = (size[0], size[1], 1)
channels = self.dataforsize(size)
im = channels.get("RGBA")
if im:
return im
im = channels["RGB"].copy()
try:
im.putalpha(channels["A"])
except KeyError:
pass
return im
##
# Image plugin for Mac OS icons.
class IcnsImageFile(ImageFile.ImageFile):
"""
PIL image support for Mac OS .icns files.
Chooses the best resolution, but will possibly load
a different size image if you mutate the size attribute
before calling 'load'.
The info dictionary has a key 'sizes' that is a list
of sizes that the icns file has.
"""
format = "ICNS"
format_description = "Mac OS icns resource"
def _open(self) -> None:
self.icns = IcnsFile(self.fp)
self._mode = "RGBA"
self.info["sizes"] = self.icns.itersizes()
self.best_size = self.icns.bestsize()
self.size = (
self.best_size[0] * self.best_size[2],
self.best_size[1] * self.best_size[2],
)
@property # type: ignore[override]
def size(self) -> tuple[int, int] | tuple[int, int, int]:
return self._size
@size.setter
def size(self, value: tuple[int, int] | tuple[int, int, int]) -> None:
if len(value) == 3:
deprecate("Setting size to (width, height, scale)", 12, "load(scale)")
if value in self.info["sizes"]:
self._size = value # type: ignore[assignment]
return
else:
# Check that a matching size exists,
# or that there is a scale that would create a size that matches
for size in self.info["sizes"]:
simple_size = size[0] * size[2], size[1] * size[2]
scale = simple_size[0] // value[0]
if simple_size[1] / value[1] == scale:
self._size = value
return
msg = "This is not one of the allowed sizes of this image"
raise ValueError(msg)
def load(self, scale: int | None = None) -> Image.core.PixelAccess | None:
if scale is not None or len(self.size) == 3:
if scale is None and len(self.size) == 3:
scale = self.size[2]
assert scale is not None
width, height = self.size[:2]
self.size = width * scale, height * scale
self.best_size = width, height, scale
px = Image.Image.load(self)
if self._im is not None and self.im.size == self.size:
# Already loaded
return px
self.load_prepare()
# This is likely NOT the best way to do it, but whatever.
im = self.icns.getimage(self.best_size)
# If this is a PNG or JPEG 2000, it won't be loaded yet
px = im.load()
self.im = im.im
self._mode = im.mode
self.size = im.size
return px
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
"""
Saves the image as a series of PNG files,
that are then combined into a .icns file.
"""
if hasattr(fp, "flush"):
fp.flush()
sizes = {
b"ic07": 128,
b"ic08": 256,
b"ic09": 512,
b"ic10": 1024,
b"ic11": 32,
b"ic12": 64,
b"ic13": 256,
b"ic14": 512,
}
provided_images = {im.width: im for im in im.encoderinfo.get("append_images", [])}
size_streams = {}
for size in set(sizes.values()):
image = (
provided_images[size]
if size in provided_images
else im.resize((size, size))
)
temp = io.BytesIO()
image.save(temp, "png")
size_streams[size] = temp.getvalue()
entries = []
for type, size in sizes.items():
stream = size_streams[size]
entries.append((type, HEADERSIZE + len(stream), stream))
# Header
fp.write(MAGIC)
file_length = HEADERSIZE # Header
file_length += HEADERSIZE + 8 * len(entries) # TOC
file_length += sum(entry[1] for entry in entries)
fp.write(struct.pack(">i", file_length))
# TOC
fp.write(b"TOC ")
fp.write(struct.pack(">i", HEADERSIZE + len(entries) * HEADERSIZE))
for entry in entries:
fp.write(entry[0])
fp.write(struct.pack(">i", entry[1]))
# Data
for entry in entries:
fp.write(entry[0])
fp.write(struct.pack(">i", entry[1]))
fp.write(entry[2])
if hasattr(fp, "flush"):
fp.flush()
def _accept(prefix: bytes) -> bool:
return prefix[:4] == MAGIC
Image.register_open(IcnsImageFile.format, IcnsImageFile, _accept)
Image.register_extension(IcnsImageFile.format, ".icns")
Image.register_save(IcnsImageFile.format, _save)
Image.register_mime(IcnsImageFile.format, "image/icns")
if __name__ == "__main__":
if len(sys.argv) < 2:
print("Syntax: python3 IcnsImagePlugin.py [file]")
sys.exit()
with open(sys.argv[1], "rb") as fp:
imf = IcnsImageFile(fp)
for size in imf.info["sizes"]:
width, height, scale = imf.size = size
imf.save(f"out-{width}-{height}-{scale}.png")
with Image.open(sys.argv[1]) as im:
im.save("out.png")
if sys.platform == "windows":
os.startfile("out.png")

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#
# The Python Imaging Library.
# $Id$
#
# Windows Icon support for PIL
#
# History:
# 96-05-27 fl Created
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1996.
#
# See the README file for information on usage and redistribution.
#
# This plugin is a refactored version of Win32IconImagePlugin by Bryan Davis
# <casadebender@gmail.com>.
# https://code.google.com/archive/p/casadebender/wikis/Win32IconImagePlugin.wiki
#
# Icon format references:
# * https://en.wikipedia.org/wiki/ICO_(file_format)
# * https://msdn.microsoft.com/en-us/library/ms997538.aspx
from __future__ import annotations
import warnings
from io import BytesIO
from math import ceil, log
from typing import IO, NamedTuple
from . import BmpImagePlugin, Image, ImageFile, PngImagePlugin
from ._binary import i16le as i16
from ._binary import i32le as i32
from ._binary import o8
from ._binary import o16le as o16
from ._binary import o32le as o32
#
# --------------------------------------------------------------------
_MAGIC = b"\0\0\1\0"
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
fp.write(_MAGIC) # (2+2)
bmp = im.encoderinfo.get("bitmap_format") == "bmp"
sizes = im.encoderinfo.get(
"sizes",
[(16, 16), (24, 24), (32, 32), (48, 48), (64, 64), (128, 128), (256, 256)],
)
frames = []
provided_ims = [im] + im.encoderinfo.get("append_images", [])
width, height = im.size
for size in sorted(set(sizes)):
if size[0] > width or size[1] > height or size[0] > 256 or size[1] > 256:
continue
for provided_im in provided_ims:
if provided_im.size != size:
continue
frames.append(provided_im)
if bmp:
bits = BmpImagePlugin.SAVE[provided_im.mode][1]
bits_used = [bits]
for other_im in provided_ims:
if other_im.size != size:
continue
bits = BmpImagePlugin.SAVE[other_im.mode][1]
if bits not in bits_used:
# Another image has been supplied for this size
# with a different bit depth
frames.append(other_im)
bits_used.append(bits)
break
else:
# TODO: invent a more convenient method for proportional scalings
frame = provided_im.copy()
frame.thumbnail(size, Image.Resampling.LANCZOS, reducing_gap=None)
frames.append(frame)
fp.write(o16(len(frames))) # idCount(2)
offset = fp.tell() + len(frames) * 16
for frame in frames:
width, height = frame.size
# 0 means 256
fp.write(o8(width if width < 256 else 0)) # bWidth(1)
fp.write(o8(height if height < 256 else 0)) # bHeight(1)
bits, colors = BmpImagePlugin.SAVE[frame.mode][1:] if bmp else (32, 0)
fp.write(o8(colors)) # bColorCount(1)
fp.write(b"\0") # bReserved(1)
fp.write(b"\0\0") # wPlanes(2)
fp.write(o16(bits)) # wBitCount(2)
image_io = BytesIO()
if bmp:
frame.save(image_io, "dib")
if bits != 32:
and_mask = Image.new("1", size)
ImageFile._save(
and_mask,
image_io,
[ImageFile._Tile("raw", (0, 0) + size, 0, ("1", 0, -1))],
)
else:
frame.save(image_io, "png")
image_io.seek(0)
image_bytes = image_io.read()
if bmp:
image_bytes = image_bytes[:8] + o32(height * 2) + image_bytes[12:]
bytes_len = len(image_bytes)
fp.write(o32(bytes_len)) # dwBytesInRes(4)
fp.write(o32(offset)) # dwImageOffset(4)
current = fp.tell()
fp.seek(offset)
fp.write(image_bytes)
offset = offset + bytes_len
fp.seek(current)
def _accept(prefix: bytes) -> bool:
return prefix[:4] == _MAGIC
class IconHeader(NamedTuple):
width: int
height: int
nb_color: int
reserved: int
planes: int
bpp: int
size: int
offset: int
dim: tuple[int, int]
square: int
color_depth: int
class IcoFile:
def __init__(self, buf: IO[bytes]) -> None:
"""
Parse image from file-like object containing ico file data
"""
# check magic
s = buf.read(6)
if not _accept(s):
msg = "not an ICO file"
raise SyntaxError(msg)
self.buf = buf
self.entry = []
# Number of items in file
self.nb_items = i16(s, 4)
# Get headers for each item
for i in range(self.nb_items):
s = buf.read(16)
# See Wikipedia
width = s[0] or 256
height = s[1] or 256
# No. of colors in image (0 if >=8bpp)
nb_color = s[2]
bpp = i16(s, 6)
icon_header = IconHeader(
width=width,
height=height,
nb_color=nb_color,
reserved=s[3],
planes=i16(s, 4),
bpp=i16(s, 6),
size=i32(s, 8),
offset=i32(s, 12),
dim=(width, height),
square=width * height,
# See Wikipedia notes about color depth.
# We need this just to differ images with equal sizes
color_depth=bpp or (nb_color != 0 and ceil(log(nb_color, 2))) or 256,
)
self.entry.append(icon_header)
self.entry = sorted(self.entry, key=lambda x: x.color_depth)
# ICO images are usually squares
self.entry = sorted(self.entry, key=lambda x: x.square, reverse=True)
def sizes(self) -> set[tuple[int, int]]:
"""
Get a set of all available icon sizes and color depths.
"""
return {(h.width, h.height) for h in self.entry}
def getentryindex(self, size: tuple[int, int], bpp: int | bool = False) -> int:
for i, h in enumerate(self.entry):
if size == h.dim and (bpp is False or bpp == h.color_depth):
return i
return 0
def getimage(self, size: tuple[int, int], bpp: int | bool = False) -> Image.Image:
"""
Get an image from the icon
"""
return self.frame(self.getentryindex(size, bpp))
def frame(self, idx: int) -> Image.Image:
"""
Get an image from frame idx
"""
header = self.entry[idx]
self.buf.seek(header.offset)
data = self.buf.read(8)
self.buf.seek(header.offset)
im: Image.Image
if data[:8] == PngImagePlugin._MAGIC:
# png frame
im = PngImagePlugin.PngImageFile(self.buf)
Image._decompression_bomb_check(im.size)
else:
# XOR + AND mask bmp frame
im = BmpImagePlugin.DibImageFile(self.buf)
Image._decompression_bomb_check(im.size)
# change tile dimension to only encompass XOR image
im._size = (im.size[0], int(im.size[1] / 2))
d, e, o, a = im.tile[0]
im.tile[0] = ImageFile._Tile(d, (0, 0) + im.size, o, a)
# figure out where AND mask image starts
if header.bpp == 32:
# 32-bit color depth icon image allows semitransparent areas
# PIL's DIB format ignores transparency bits, recover them.
# The DIB is packed in BGRX byte order where X is the alpha
# channel.
# Back up to start of bmp data
self.buf.seek(o)
# extract every 4th byte (eg. 3,7,11,15,...)
alpha_bytes = self.buf.read(im.size[0] * im.size[1] * 4)[3::4]
# convert to an 8bpp grayscale image
try:
mask = Image.frombuffer(
"L", # 8bpp
im.size, # (w, h)
alpha_bytes, # source chars
"raw", # raw decoder
("L", 0, -1), # 8bpp inverted, unpadded, reversed
)
except ValueError:
if ImageFile.LOAD_TRUNCATED_IMAGES:
mask = None
else:
raise
else:
# get AND image from end of bitmap
w = im.size[0]
if (w % 32) > 0:
# bitmap row data is aligned to word boundaries
w += 32 - (im.size[0] % 32)
# the total mask data is
# padded row size * height / bits per char
total_bytes = int((w * im.size[1]) / 8)
and_mask_offset = header.offset + header.size - total_bytes
self.buf.seek(and_mask_offset)
mask_data = self.buf.read(total_bytes)
# convert raw data to image
try:
mask = Image.frombuffer(
"1", # 1 bpp
im.size, # (w, h)
mask_data, # source chars
"raw", # raw decoder
("1;I", int(w / 8), -1), # 1bpp inverted, padded, reversed
)
except ValueError:
if ImageFile.LOAD_TRUNCATED_IMAGES:
mask = None
else:
raise
# now we have two images, im is XOR image and mask is AND image
# apply mask image as alpha channel
if mask:
im = im.convert("RGBA")
im.putalpha(mask)
return im
##
# Image plugin for Windows Icon files.
class IcoImageFile(ImageFile.ImageFile):
"""
PIL read-only image support for Microsoft Windows .ico files.
By default the largest resolution image in the file will be loaded. This
can be changed by altering the 'size' attribute before calling 'load'.
The info dictionary has a key 'sizes' that is a list of the sizes available
in the icon file.
Handles classic, XP and Vista icon formats.
When saving, PNG compression is used. Support for this was only added in
Windows Vista. If you are unable to view the icon in Windows, convert the
image to "RGBA" mode before saving.
This plugin is a refactored version of Win32IconImagePlugin by Bryan Davis
<casadebender@gmail.com>.
https://code.google.com/archive/p/casadebender/wikis/Win32IconImagePlugin.wiki
"""
format = "ICO"
format_description = "Windows Icon"
def _open(self) -> None:
self.ico = IcoFile(self.fp)
self.info["sizes"] = self.ico.sizes()
self.size = self.ico.entry[0].dim
self.load()
@property
def size(self) -> tuple[int, int]:
return self._size
@size.setter
def size(self, value: tuple[int, int]) -> None:
if value not in self.info["sizes"]:
msg = "This is not one of the allowed sizes of this image"
raise ValueError(msg)
self._size = value
def load(self) -> Image.core.PixelAccess | None:
if self._im is not None and self.im.size == self.size:
# Already loaded
return Image.Image.load(self)
im = self.ico.getimage(self.size)
# if tile is PNG, it won't really be loaded yet
im.load()
self.im = im.im
self._mode = im.mode
if im.palette:
self.palette = im.palette
if im.size != self.size:
warnings.warn("Image was not the expected size")
index = self.ico.getentryindex(self.size)
sizes = list(self.info["sizes"])
sizes[index] = im.size
self.info["sizes"] = set(sizes)
self.size = im.size
return None
def load_seek(self, pos: int) -> None:
# Flag the ImageFile.Parser so that it
# just does all the decode at the end.
pass
#
# --------------------------------------------------------------------
Image.register_open(IcoImageFile.format, IcoImageFile, _accept)
Image.register_save(IcoImageFile.format, _save)
Image.register_extension(IcoImageFile.format, ".ico")
Image.register_mime(IcoImageFile.format, "image/x-icon")

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#
# The Python Imaging Library.
# $Id$
#
# IFUNC IM file handling for PIL
#
# history:
# 1995-09-01 fl Created.
# 1997-01-03 fl Save palette images
# 1997-01-08 fl Added sequence support
# 1997-01-23 fl Added P and RGB save support
# 1997-05-31 fl Read floating point images
# 1997-06-22 fl Save floating point images
# 1997-08-27 fl Read and save 1-bit images
# 1998-06-25 fl Added support for RGB+LUT images
# 1998-07-02 fl Added support for YCC images
# 1998-07-15 fl Renamed offset attribute to avoid name clash
# 1998-12-29 fl Added I;16 support
# 2001-02-17 fl Use 're' instead of 'regex' (Python 2.1) (0.7)
# 2003-09-26 fl Added LA/PA support
#
# Copyright (c) 1997-2003 by Secret Labs AB.
# Copyright (c) 1995-2001 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import os
import re
from typing import IO, Any
from . import Image, ImageFile, ImagePalette
# --------------------------------------------------------------------
# Standard tags
COMMENT = "Comment"
DATE = "Date"
EQUIPMENT = "Digitalization equipment"
FRAMES = "File size (no of images)"
LUT = "Lut"
NAME = "Name"
SCALE = "Scale (x,y)"
SIZE = "Image size (x*y)"
MODE = "Image type"
TAGS = {
COMMENT: 0,
DATE: 0,
EQUIPMENT: 0,
FRAMES: 0,
LUT: 0,
NAME: 0,
SCALE: 0,
SIZE: 0,
MODE: 0,
}
OPEN = {
# ifunc93/p3cfunc formats
"0 1 image": ("1", "1"),
"L 1 image": ("1", "1"),
"Greyscale image": ("L", "L"),
"Grayscale image": ("L", "L"),
"RGB image": ("RGB", "RGB;L"),
"RLB image": ("RGB", "RLB"),
"RYB image": ("RGB", "RLB"),
"B1 image": ("1", "1"),
"B2 image": ("P", "P;2"),
"B4 image": ("P", "P;4"),
"X 24 image": ("RGB", "RGB"),
"L 32 S image": ("I", "I;32"),
"L 32 F image": ("F", "F;32"),
# old p3cfunc formats
"RGB3 image": ("RGB", "RGB;T"),
"RYB3 image": ("RGB", "RYB;T"),
# extensions
"LA image": ("LA", "LA;L"),
"PA image": ("LA", "PA;L"),
"RGBA image": ("RGBA", "RGBA;L"),
"RGBX image": ("RGB", "RGBX;L"),
"CMYK image": ("CMYK", "CMYK;L"),
"YCC image": ("YCbCr", "YCbCr;L"),
}
# ifunc95 extensions
for i in ["8", "8S", "16", "16S", "32", "32F"]:
OPEN[f"L {i} image"] = ("F", f"F;{i}")
OPEN[f"L*{i} image"] = ("F", f"F;{i}")
for i in ["16", "16L", "16B"]:
OPEN[f"L {i} image"] = (f"I;{i}", f"I;{i}")
OPEN[f"L*{i} image"] = (f"I;{i}", f"I;{i}")
for i in ["32S"]:
OPEN[f"L {i} image"] = ("I", f"I;{i}")
OPEN[f"L*{i} image"] = ("I", f"I;{i}")
for j in range(2, 33):
OPEN[f"L*{j} image"] = ("F", f"F;{j}")
# --------------------------------------------------------------------
# Read IM directory
split = re.compile(rb"^([A-Za-z][^:]*):[ \t]*(.*)[ \t]*$")
def number(s: Any) -> float:
try:
return int(s)
except ValueError:
return float(s)
##
# Image plugin for the IFUNC IM file format.
class ImImageFile(ImageFile.ImageFile):
format = "IM"
format_description = "IFUNC Image Memory"
_close_exclusive_fp_after_loading = False
def _open(self) -> None:
# Quick rejection: if there's not an LF among the first
# 100 bytes, this is (probably) not a text header.
if b"\n" not in self.fp.read(100):
msg = "not an IM file"
raise SyntaxError(msg)
self.fp.seek(0)
n = 0
# Default values
self.info[MODE] = "L"
self.info[SIZE] = (512, 512)
self.info[FRAMES] = 1
self.rawmode = "L"
while True:
s = self.fp.read(1)
# Some versions of IFUNC uses \n\r instead of \r\n...
if s == b"\r":
continue
if not s or s == b"\0" or s == b"\x1A":
break
# FIXME: this may read whole file if not a text file
s = s + self.fp.readline()
if len(s) > 100:
msg = "not an IM file"
raise SyntaxError(msg)
if s[-2:] == b"\r\n":
s = s[:-2]
elif s[-1:] == b"\n":
s = s[:-1]
try:
m = split.match(s)
except re.error as e:
msg = "not an IM file"
raise SyntaxError(msg) from e
if m:
k, v = m.group(1, 2)
# Don't know if this is the correct encoding,
# but a decent guess (I guess)
k = k.decode("latin-1", "replace")
v = v.decode("latin-1", "replace")
# Convert value as appropriate
if k in [FRAMES, SCALE, SIZE]:
v = v.replace("*", ",")
v = tuple(map(number, v.split(",")))
if len(v) == 1:
v = v[0]
elif k == MODE and v in OPEN:
v, self.rawmode = OPEN[v]
# Add to dictionary. Note that COMMENT tags are
# combined into a list of strings.
if k == COMMENT:
if k in self.info:
self.info[k].append(v)
else:
self.info[k] = [v]
else:
self.info[k] = v
if k in TAGS:
n += 1
else:
msg = f"Syntax error in IM header: {s.decode('ascii', 'replace')}"
raise SyntaxError(msg)
if not n:
msg = "Not an IM file"
raise SyntaxError(msg)
# Basic attributes
self._size = self.info[SIZE]
self._mode = self.info[MODE]
# Skip forward to start of image data
while s and s[:1] != b"\x1A":
s = self.fp.read(1)
if not s:
msg = "File truncated"
raise SyntaxError(msg)
if LUT in self.info:
# convert lookup table to palette or lut attribute
palette = self.fp.read(768)
greyscale = 1 # greyscale palette
linear = 1 # linear greyscale palette
for i in range(256):
if palette[i] == palette[i + 256] == palette[i + 512]:
if palette[i] != i:
linear = 0
else:
greyscale = 0
if self.mode in ["L", "LA", "P", "PA"]:
if greyscale:
if not linear:
self.lut = list(palette[:256])
else:
if self.mode in ["L", "P"]:
self._mode = self.rawmode = "P"
elif self.mode in ["LA", "PA"]:
self._mode = "PA"
self.rawmode = "PA;L"
self.palette = ImagePalette.raw("RGB;L", palette)
elif self.mode == "RGB":
if not greyscale or not linear:
self.lut = list(palette)
self.frame = 0
self.__offset = offs = self.fp.tell()
self._fp = self.fp # FIXME: hack
if self.rawmode[:2] == "F;":
# ifunc95 formats
try:
# use bit decoder (if necessary)
bits = int(self.rawmode[2:])
if bits not in [8, 16, 32]:
self.tile = [
ImageFile._Tile(
"bit", (0, 0) + self.size, offs, (bits, 8, 3, 0, -1)
)
]
return
except ValueError:
pass
if self.rawmode in ["RGB;T", "RYB;T"]:
# Old LabEye/3PC files. Would be very surprised if anyone
# ever stumbled upon such a file ;-)
size = self.size[0] * self.size[1]
self.tile = [
ImageFile._Tile("raw", (0, 0) + self.size, offs, ("G", 0, -1)),
ImageFile._Tile("raw", (0, 0) + self.size, offs + size, ("R", 0, -1)),
ImageFile._Tile(
"raw", (0, 0) + self.size, offs + 2 * size, ("B", 0, -1)
),
]
else:
# LabEye/IFUNC files
self.tile = [
ImageFile._Tile("raw", (0, 0) + self.size, offs, (self.rawmode, 0, -1))
]
@property
def n_frames(self) -> int:
return self.info[FRAMES]
@property
def is_animated(self) -> bool:
return self.info[FRAMES] > 1
def seek(self, frame: int) -> None:
if not self._seek_check(frame):
return
self.frame = frame
if self.mode == "1":
bits = 1
else:
bits = 8 * len(self.mode)
size = ((self.size[0] * bits + 7) // 8) * self.size[1]
offs = self.__offset + frame * size
self.fp = self._fp
self.tile = [
ImageFile._Tile("raw", (0, 0) + self.size, offs, (self.rawmode, 0, -1))
]
def tell(self) -> int:
return self.frame
#
# --------------------------------------------------------------------
# Save IM files
SAVE = {
# mode: (im type, raw mode)
"1": ("0 1", "1"),
"L": ("Greyscale", "L"),
"LA": ("LA", "LA;L"),
"P": ("Greyscale", "P"),
"PA": ("LA", "PA;L"),
"I": ("L 32S", "I;32S"),
"I;16": ("L 16", "I;16"),
"I;16L": ("L 16L", "I;16L"),
"I;16B": ("L 16B", "I;16B"),
"F": ("L 32F", "F;32F"),
"RGB": ("RGB", "RGB;L"),
"RGBA": ("RGBA", "RGBA;L"),
"RGBX": ("RGBX", "RGBX;L"),
"CMYK": ("CMYK", "CMYK;L"),
"YCbCr": ("YCC", "YCbCr;L"),
}
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
try:
image_type, rawmode = SAVE[im.mode]
except KeyError as e:
msg = f"Cannot save {im.mode} images as IM"
raise ValueError(msg) from e
frames = im.encoderinfo.get("frames", 1)
fp.write(f"Image type: {image_type} image\r\n".encode("ascii"))
if filename:
# Each line must be 100 characters or less,
# or: SyntaxError("not an IM file")
# 8 characters are used for "Name: " and "\r\n"
# Keep just the filename, ditch the potentially overlong path
if isinstance(filename, bytes):
filename = filename.decode("ascii")
name, ext = os.path.splitext(os.path.basename(filename))
name = "".join([name[: 92 - len(ext)], ext])
fp.write(f"Name: {name}\r\n".encode("ascii"))
fp.write(("Image size (x*y): %d*%d\r\n" % im.size).encode("ascii"))
fp.write(f"File size (no of images): {frames}\r\n".encode("ascii"))
if im.mode in ["P", "PA"]:
fp.write(b"Lut: 1\r\n")
fp.write(b"\000" * (511 - fp.tell()) + b"\032")
if im.mode in ["P", "PA"]:
im_palette = im.im.getpalette("RGB", "RGB;L")
colors = len(im_palette) // 3
palette = b""
for i in range(3):
palette += im_palette[colors * i : colors * (i + 1)]
palette += b"\x00" * (256 - colors)
fp.write(palette) # 768 bytes
ImageFile._save(
im, fp, [ImageFile._Tile("raw", (0, 0) + im.size, 0, (rawmode, 0, -1))]
)
#
# --------------------------------------------------------------------
# Registry
Image.register_open(ImImageFile.format, ImImageFile)
Image.register_save(ImImageFile.format, _save)
Image.register_extension(ImImageFile.format, ".im")

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#
# The Python Imaging Library.
# $Id$
#
# standard channel operations
#
# History:
# 1996-03-24 fl Created
# 1996-08-13 fl Added logical operations (for "1" images)
# 2000-10-12 fl Added offset method (from Image.py)
#
# Copyright (c) 1997-2000 by Secret Labs AB
# Copyright (c) 1996-2000 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from . import Image
def constant(image: Image.Image, value: int) -> Image.Image:
"""Fill a channel with a given gray level.
:rtype: :py:class:`~PIL.Image.Image`
"""
return Image.new("L", image.size, value)
def duplicate(image: Image.Image) -> Image.Image:
"""Copy a channel. Alias for :py:meth:`PIL.Image.Image.copy`.
:rtype: :py:class:`~PIL.Image.Image`
"""
return image.copy()
def invert(image: Image.Image) -> Image.Image:
"""
Invert an image (channel). ::
out = MAX - image
:rtype: :py:class:`~PIL.Image.Image`
"""
image.load()
return image._new(image.im.chop_invert())
def lighter(image1: Image.Image, image2: Image.Image) -> Image.Image:
"""
Compares the two images, pixel by pixel, and returns a new image containing
the lighter values. ::
out = max(image1, image2)
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_lighter(image2.im))
def darker(image1: Image.Image, image2: Image.Image) -> Image.Image:
"""
Compares the two images, pixel by pixel, and returns a new image containing
the darker values. ::
out = min(image1, image2)
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_darker(image2.im))
def difference(image1: Image.Image, image2: Image.Image) -> Image.Image:
"""
Returns the absolute value of the pixel-by-pixel difference between the two
images. ::
out = abs(image1 - image2)
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_difference(image2.im))
def multiply(image1: Image.Image, image2: Image.Image) -> Image.Image:
"""
Superimposes two images on top of each other.
If you multiply an image with a solid black image, the result is black. If
you multiply with a solid white image, the image is unaffected. ::
out = image1 * image2 / MAX
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_multiply(image2.im))
def screen(image1: Image.Image, image2: Image.Image) -> Image.Image:
"""
Superimposes two inverted images on top of each other. ::
out = MAX - ((MAX - image1) * (MAX - image2) / MAX)
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_screen(image2.im))
def soft_light(image1: Image.Image, image2: Image.Image) -> Image.Image:
"""
Superimposes two images on top of each other using the Soft Light algorithm
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_soft_light(image2.im))
def hard_light(image1: Image.Image, image2: Image.Image) -> Image.Image:
"""
Superimposes two images on top of each other using the Hard Light algorithm
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_hard_light(image2.im))
def overlay(image1: Image.Image, image2: Image.Image) -> Image.Image:
"""
Superimposes two images on top of each other using the Overlay algorithm
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_overlay(image2.im))
def add(
image1: Image.Image, image2: Image.Image, scale: float = 1.0, offset: float = 0
) -> Image.Image:
"""
Adds two images, dividing the result by scale and adding the
offset. If omitted, scale defaults to 1.0, and offset to 0.0. ::
out = ((image1 + image2) / scale + offset)
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_add(image2.im, scale, offset))
def subtract(
image1: Image.Image, image2: Image.Image, scale: float = 1.0, offset: float = 0
) -> Image.Image:
"""
Subtracts two images, dividing the result by scale and adding the offset.
If omitted, scale defaults to 1.0, and offset to 0.0. ::
out = ((image1 - image2) / scale + offset)
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_subtract(image2.im, scale, offset))
def add_modulo(image1: Image.Image, image2: Image.Image) -> Image.Image:
"""Add two images, without clipping the result. ::
out = ((image1 + image2) % MAX)
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_add_modulo(image2.im))
def subtract_modulo(image1: Image.Image, image2: Image.Image) -> Image.Image:
"""Subtract two images, without clipping the result. ::
out = ((image1 - image2) % MAX)
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_subtract_modulo(image2.im))
def logical_and(image1: Image.Image, image2: Image.Image) -> Image.Image:
"""Logical AND between two images.
Both of the images must have mode "1". If you would like to perform a
logical AND on an image with a mode other than "1", try
:py:meth:`~PIL.ImageChops.multiply` instead, using a black-and-white mask
as the second image. ::
out = ((image1 and image2) % MAX)
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_and(image2.im))
def logical_or(image1: Image.Image, image2: Image.Image) -> Image.Image:
"""Logical OR between two images.
Both of the images must have mode "1". ::
out = ((image1 or image2) % MAX)
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_or(image2.im))
def logical_xor(image1: Image.Image, image2: Image.Image) -> Image.Image:
"""Logical XOR between two images.
Both of the images must have mode "1". ::
out = ((bool(image1) != bool(image2)) % MAX)
:rtype: :py:class:`~PIL.Image.Image`
"""
image1.load()
image2.load()
return image1._new(image1.im.chop_xor(image2.im))
def blend(image1: Image.Image, image2: Image.Image, alpha: float) -> Image.Image:
"""Blend images using constant transparency weight. Alias for
:py:func:`PIL.Image.blend`.
:rtype: :py:class:`~PIL.Image.Image`
"""
return Image.blend(image1, image2, alpha)
def composite(
image1: Image.Image, image2: Image.Image, mask: Image.Image
) -> Image.Image:
"""Create composite using transparency mask. Alias for
:py:func:`PIL.Image.composite`.
:rtype: :py:class:`~PIL.Image.Image`
"""
return Image.composite(image1, image2, mask)
def offset(image: Image.Image, xoffset: int, yoffset: int | None = None) -> Image.Image:
"""Returns a copy of the image where data has been offset by the given
distances. Data wraps around the edges. If ``yoffset`` is omitted, it
is assumed to be equal to ``xoffset``.
:param image: Input image.
:param xoffset: The horizontal distance.
:param yoffset: The vertical distance. If omitted, both
distances are set to the same value.
:rtype: :py:class:`~PIL.Image.Image`
"""
if yoffset is None:
yoffset = xoffset
image.load()
return image._new(image.im.offset(xoffset, yoffset))

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#
# The Python Imaging Library
# $Id$
#
# map CSS3-style colour description strings to RGB
#
# History:
# 2002-10-24 fl Added support for CSS-style color strings
# 2002-12-15 fl Added RGBA support
# 2004-03-27 fl Fixed remaining int() problems for Python 1.5.2
# 2004-07-19 fl Fixed gray/grey spelling issues
# 2009-03-05 fl Fixed rounding error in grayscale calculation
#
# Copyright (c) 2002-2004 by Secret Labs AB
# Copyright (c) 2002-2004 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import re
from functools import lru_cache
from . import Image
@lru_cache
def getrgb(color: str) -> tuple[int, int, int] | tuple[int, int, int, int]:
"""
Convert a color string to an RGB or RGBA tuple. If the string cannot be
parsed, this function raises a :py:exc:`ValueError` exception.
.. versionadded:: 1.1.4
:param color: A color string
:return: ``(red, green, blue[, alpha])``
"""
if len(color) > 100:
msg = "color specifier is too long"
raise ValueError(msg)
color = color.lower()
rgb = colormap.get(color, None)
if rgb:
if isinstance(rgb, tuple):
return rgb
rgb_tuple = getrgb(rgb)
assert len(rgb_tuple) == 3
colormap[color] = rgb_tuple
return rgb_tuple
# check for known string formats
if re.match("#[a-f0-9]{3}$", color):
return int(color[1] * 2, 16), int(color[2] * 2, 16), int(color[3] * 2, 16)
if re.match("#[a-f0-9]{4}$", color):
return (
int(color[1] * 2, 16),
int(color[2] * 2, 16),
int(color[3] * 2, 16),
int(color[4] * 2, 16),
)
if re.match("#[a-f0-9]{6}$", color):
return int(color[1:3], 16), int(color[3:5], 16), int(color[5:7], 16)
if re.match("#[a-f0-9]{8}$", color):
return (
int(color[1:3], 16),
int(color[3:5], 16),
int(color[5:7], 16),
int(color[7:9], 16),
)
m = re.match(r"rgb\(\s*(\d+)\s*,\s*(\d+)\s*,\s*(\d+)\s*\)$", color)
if m:
return int(m.group(1)), int(m.group(2)), int(m.group(3))
m = re.match(r"rgb\(\s*(\d+)%\s*,\s*(\d+)%\s*,\s*(\d+)%\s*\)$", color)
if m:
return (
int((int(m.group(1)) * 255) / 100.0 + 0.5),
int((int(m.group(2)) * 255) / 100.0 + 0.5),
int((int(m.group(3)) * 255) / 100.0 + 0.5),
)
m = re.match(
r"hsl\(\s*(\d+\.?\d*)\s*,\s*(\d+\.?\d*)%\s*,\s*(\d+\.?\d*)%\s*\)$", color
)
if m:
from colorsys import hls_to_rgb
rgb_floats = hls_to_rgb(
float(m.group(1)) / 360.0,
float(m.group(3)) / 100.0,
float(m.group(2)) / 100.0,
)
return (
int(rgb_floats[0] * 255 + 0.5),
int(rgb_floats[1] * 255 + 0.5),
int(rgb_floats[2] * 255 + 0.5),
)
m = re.match(
r"hs[bv]\(\s*(\d+\.?\d*)\s*,\s*(\d+\.?\d*)%\s*,\s*(\d+\.?\d*)%\s*\)$", color
)
if m:
from colorsys import hsv_to_rgb
rgb_floats = hsv_to_rgb(
float(m.group(1)) / 360.0,
float(m.group(2)) / 100.0,
float(m.group(3)) / 100.0,
)
return (
int(rgb_floats[0] * 255 + 0.5),
int(rgb_floats[1] * 255 + 0.5),
int(rgb_floats[2] * 255 + 0.5),
)
m = re.match(r"rgba\(\s*(\d+)\s*,\s*(\d+)\s*,\s*(\d+)\s*,\s*(\d+)\s*\)$", color)
if m:
return int(m.group(1)), int(m.group(2)), int(m.group(3)), int(m.group(4))
msg = f"unknown color specifier: {repr(color)}"
raise ValueError(msg)
@lru_cache
def getcolor(color: str, mode: str) -> int | tuple[int, ...]:
"""
Same as :py:func:`~PIL.ImageColor.getrgb` for most modes. However, if
``mode`` is HSV, converts the RGB value to a HSV value, or if ``mode`` is
not color or a palette image, converts the RGB value to a grayscale value.
If the string cannot be parsed, this function raises a :py:exc:`ValueError`
exception.
.. versionadded:: 1.1.4
:param color: A color string
:param mode: Convert result to this mode
:return: ``graylevel, (graylevel, alpha) or (red, green, blue[, alpha])``
"""
# same as getrgb, but converts the result to the given mode
rgb, alpha = getrgb(color), 255
if len(rgb) == 4:
alpha = rgb[3]
rgb = rgb[:3]
if mode == "HSV":
from colorsys import rgb_to_hsv
r, g, b = rgb
h, s, v = rgb_to_hsv(r / 255, g / 255, b / 255)
return int(h * 255), int(s * 255), int(v * 255)
elif Image.getmodebase(mode) == "L":
r, g, b = rgb
# ITU-R Recommendation 601-2 for nonlinear RGB
# scaled to 24 bits to match the convert's implementation.
graylevel = (r * 19595 + g * 38470 + b * 7471 + 0x8000) >> 16
if mode[-1] == "A":
return graylevel, alpha
return graylevel
elif mode[-1] == "A":
return rgb + (alpha,)
return rgb
colormap: dict[str, str | tuple[int, int, int]] = {
# X11 colour table from https://drafts.csswg.org/css-color-4/, with
# gray/grey spelling issues fixed. This is a superset of HTML 4.0
# colour names used in CSS 1.
"aliceblue": "#f0f8ff",
"antiquewhite": "#faebd7",
"aqua": "#00ffff",
"aquamarine": "#7fffd4",
"azure": "#f0ffff",
"beige": "#f5f5dc",
"bisque": "#ffe4c4",
"black": "#000000",
"blanchedalmond": "#ffebcd",
"blue": "#0000ff",
"blueviolet": "#8a2be2",
"brown": "#a52a2a",
"burlywood": "#deb887",
"cadetblue": "#5f9ea0",
"chartreuse": "#7fff00",
"chocolate": "#d2691e",
"coral": "#ff7f50",
"cornflowerblue": "#6495ed",
"cornsilk": "#fff8dc",
"crimson": "#dc143c",
"cyan": "#00ffff",
"darkblue": "#00008b",
"darkcyan": "#008b8b",
"darkgoldenrod": "#b8860b",
"darkgray": "#a9a9a9",
"darkgrey": "#a9a9a9",
"darkgreen": "#006400",
"darkkhaki": "#bdb76b",
"darkmagenta": "#8b008b",
"darkolivegreen": "#556b2f",
"darkorange": "#ff8c00",
"darkorchid": "#9932cc",
"darkred": "#8b0000",
"darksalmon": "#e9967a",
"darkseagreen": "#8fbc8f",
"darkslateblue": "#483d8b",
"darkslategray": "#2f4f4f",
"darkslategrey": "#2f4f4f",
"darkturquoise": "#00ced1",
"darkviolet": "#9400d3",
"deeppink": "#ff1493",
"deepskyblue": "#00bfff",
"dimgray": "#696969",
"dimgrey": "#696969",
"dodgerblue": "#1e90ff",
"firebrick": "#b22222",
"floralwhite": "#fffaf0",
"forestgreen": "#228b22",
"fuchsia": "#ff00ff",
"gainsboro": "#dcdcdc",
"ghostwhite": "#f8f8ff",
"gold": "#ffd700",
"goldenrod": "#daa520",
"gray": "#808080",
"grey": "#808080",
"green": "#008000",
"greenyellow": "#adff2f",
"honeydew": "#f0fff0",
"hotpink": "#ff69b4",
"indianred": "#cd5c5c",
"indigo": "#4b0082",
"ivory": "#fffff0",
"khaki": "#f0e68c",
"lavender": "#e6e6fa",
"lavenderblush": "#fff0f5",
"lawngreen": "#7cfc00",
"lemonchiffon": "#fffacd",
"lightblue": "#add8e6",
"lightcoral": "#f08080",
"lightcyan": "#e0ffff",
"lightgoldenrodyellow": "#fafad2",
"lightgreen": "#90ee90",
"lightgray": "#d3d3d3",
"lightgrey": "#d3d3d3",
"lightpink": "#ffb6c1",
"lightsalmon": "#ffa07a",
"lightseagreen": "#20b2aa",
"lightskyblue": "#87cefa",
"lightslategray": "#778899",
"lightslategrey": "#778899",
"lightsteelblue": "#b0c4de",
"lightyellow": "#ffffe0",
"lime": "#00ff00",
"limegreen": "#32cd32",
"linen": "#faf0e6",
"magenta": "#ff00ff",
"maroon": "#800000",
"mediumaquamarine": "#66cdaa",
"mediumblue": "#0000cd",
"mediumorchid": "#ba55d3",
"mediumpurple": "#9370db",
"mediumseagreen": "#3cb371",
"mediumslateblue": "#7b68ee",
"mediumspringgreen": "#00fa9a",
"mediumturquoise": "#48d1cc",
"mediumvioletred": "#c71585",
"midnightblue": "#191970",
"mintcream": "#f5fffa",
"mistyrose": "#ffe4e1",
"moccasin": "#ffe4b5",
"navajowhite": "#ffdead",
"navy": "#000080",
"oldlace": "#fdf5e6",
"olive": "#808000",
"olivedrab": "#6b8e23",
"orange": "#ffa500",
"orangered": "#ff4500",
"orchid": "#da70d6",
"palegoldenrod": "#eee8aa",
"palegreen": "#98fb98",
"paleturquoise": "#afeeee",
"palevioletred": "#db7093",
"papayawhip": "#ffefd5",
"peachpuff": "#ffdab9",
"peru": "#cd853f",
"pink": "#ffc0cb",
"plum": "#dda0dd",
"powderblue": "#b0e0e6",
"purple": "#800080",
"rebeccapurple": "#663399",
"red": "#ff0000",
"rosybrown": "#bc8f8f",
"royalblue": "#4169e1",
"saddlebrown": "#8b4513",
"salmon": "#fa8072",
"sandybrown": "#f4a460",
"seagreen": "#2e8b57",
"seashell": "#fff5ee",
"sienna": "#a0522d",
"silver": "#c0c0c0",
"skyblue": "#87ceeb",
"slateblue": "#6a5acd",
"slategray": "#708090",
"slategrey": "#708090",
"snow": "#fffafa",
"springgreen": "#00ff7f",
"steelblue": "#4682b4",
"tan": "#d2b48c",
"teal": "#008080",
"thistle": "#d8bfd8",
"tomato": "#ff6347",
"turquoise": "#40e0d0",
"violet": "#ee82ee",
"wheat": "#f5deb3",
"white": "#ffffff",
"whitesmoke": "#f5f5f5",
"yellow": "#ffff00",
"yellowgreen": "#9acd32",
}

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#
# The Python Imaging Library
# $Id$
#
# WCK-style drawing interface operations
#
# History:
# 2003-12-07 fl created
# 2005-05-15 fl updated; added to PIL as ImageDraw2
# 2005-05-15 fl added text support
# 2005-05-20 fl added arc/chord/pieslice support
#
# Copyright (c) 2003-2005 by Secret Labs AB
# Copyright (c) 2003-2005 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
"""
(Experimental) WCK-style drawing interface operations
.. seealso:: :py:mod:`PIL.ImageDraw`
"""
from __future__ import annotations
from typing import Any, AnyStr, BinaryIO
from . import Image, ImageColor, ImageDraw, ImageFont, ImagePath
from ._typing import Coords, StrOrBytesPath
class Pen:
"""Stores an outline color and width."""
def __init__(self, color: str, width: int = 1, opacity: int = 255) -> None:
self.color = ImageColor.getrgb(color)
self.width = width
class Brush:
"""Stores a fill color"""
def __init__(self, color: str, opacity: int = 255) -> None:
self.color = ImageColor.getrgb(color)
class Font:
"""Stores a TrueType font and color"""
def __init__(
self, color: str, file: StrOrBytesPath | BinaryIO, size: float = 12
) -> None:
# FIXME: add support for bitmap fonts
self.color = ImageColor.getrgb(color)
self.font = ImageFont.truetype(file, size)
class Draw:
"""
(Experimental) WCK-style drawing interface
"""
def __init__(
self,
image: Image.Image | str,
size: tuple[int, int] | list[int] | None = None,
color: float | tuple[float, ...] | str | None = None,
) -> None:
if isinstance(image, str):
if size is None:
msg = "If image argument is mode string, size must be a list or tuple"
raise ValueError(msg)
image = Image.new(image, size, color)
self.draw = ImageDraw.Draw(image)
self.image = image
self.transform: tuple[float, float, float, float, float, float] | None = None
def flush(self) -> Image.Image:
return self.image
def render(
self,
op: str,
xy: Coords,
pen: Pen | Brush | None,
brush: Brush | Pen | None = None,
**kwargs: Any,
) -> None:
# handle color arguments
outline = fill = None
width = 1
if isinstance(pen, Pen):
outline = pen.color
width = pen.width
elif isinstance(brush, Pen):
outline = brush.color
width = brush.width
if isinstance(brush, Brush):
fill = brush.color
elif isinstance(pen, Brush):
fill = pen.color
# handle transformation
if self.transform:
path = ImagePath.Path(xy)
path.transform(self.transform)
xy = path
# render the item
if op in ("arc", "line"):
kwargs.setdefault("fill", outline)
else:
kwargs.setdefault("fill", fill)
kwargs.setdefault("outline", outline)
if op == "line":
kwargs.setdefault("width", width)
getattr(self.draw, op)(xy, **kwargs)
def settransform(self, offset: tuple[float, float]) -> None:
"""Sets a transformation offset."""
(xoffset, yoffset) = offset
self.transform = (1, 0, xoffset, 0, 1, yoffset)
def arc(
self,
xy: Coords,
pen: Pen | Brush | None,
start: float,
end: float,
*options: Any,
) -> None:
"""
Draws an arc (a portion of a circle outline) between the start and end
angles, inside the given bounding box.
.. seealso:: :py:meth:`PIL.ImageDraw.ImageDraw.arc`
"""
self.render("arc", xy, pen, *options, start=start, end=end)
def chord(
self,
xy: Coords,
pen: Pen | Brush | None,
start: float,
end: float,
*options: Any,
) -> None:
"""
Same as :py:meth:`~PIL.ImageDraw2.Draw.arc`, but connects the end points
with a straight line.
.. seealso:: :py:meth:`PIL.ImageDraw.ImageDraw.chord`
"""
self.render("chord", xy, pen, *options, start=start, end=end)
def ellipse(self, xy: Coords, pen: Pen | Brush | None, *options: Any) -> None:
"""
Draws an ellipse inside the given bounding box.
.. seealso:: :py:meth:`PIL.ImageDraw.ImageDraw.ellipse`
"""
self.render("ellipse", xy, pen, *options)
def line(self, xy: Coords, pen: Pen | Brush | None, *options: Any) -> None:
"""
Draws a line between the coordinates in the ``xy`` list.
.. seealso:: :py:meth:`PIL.ImageDraw.ImageDraw.line`
"""
self.render("line", xy, pen, *options)
def pieslice(
self,
xy: Coords,
pen: Pen | Brush | None,
start: float,
end: float,
*options: Any,
) -> None:
"""
Same as arc, but also draws straight lines between the end points and the
center of the bounding box.
.. seealso:: :py:meth:`PIL.ImageDraw.ImageDraw.pieslice`
"""
self.render("pieslice", xy, pen, *options, start=start, end=end)
def polygon(self, xy: Coords, pen: Pen | Brush | None, *options: Any) -> None:
"""
Draws a polygon.
The polygon outline consists of straight lines between the given
coordinates, plus a straight line between the last and the first
coordinate.
.. seealso:: :py:meth:`PIL.ImageDraw.ImageDraw.polygon`
"""
self.render("polygon", xy, pen, *options)
def rectangle(self, xy: Coords, pen: Pen | Brush | None, *options: Any) -> None:
"""
Draws a rectangle.
.. seealso:: :py:meth:`PIL.ImageDraw.ImageDraw.rectangle`
"""
self.render("rectangle", xy, pen, *options)
def text(self, xy: tuple[float, float], text: AnyStr, font: Font) -> None:
"""
Draws the string at the given position.
.. seealso:: :py:meth:`PIL.ImageDraw.ImageDraw.text`
"""
if self.transform:
path = ImagePath.Path(xy)
path.transform(self.transform)
xy = path
self.draw.text(xy, text, font=font.font, fill=font.color)
def textbbox(
self, xy: tuple[float, float], text: AnyStr, font: Font
) -> tuple[float, float, float, float]:
"""
Returns bounding box (in pixels) of given text.
:return: ``(left, top, right, bottom)`` bounding box
.. seealso:: :py:meth:`PIL.ImageDraw.ImageDraw.textbbox`
"""
if self.transform:
path = ImagePath.Path(xy)
path.transform(self.transform)
xy = path
return self.draw.textbbox(xy, text, font=font.font)
def textlength(self, text: AnyStr, font: Font) -> float:
"""
Returns length (in pixels) of given text.
This is the amount by which following text should be offset.
.. seealso:: :py:meth:`PIL.ImageDraw.ImageDraw.textlength`
"""
return self.draw.textlength(text, font=font.font)

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#
# The Python Imaging Library.
# $Id$
#
# image enhancement classes
#
# For a background, see "Image Processing By Interpolation and
# Extrapolation", Paul Haeberli and Douglas Voorhies. Available
# at http://www.graficaobscura.com/interp/index.html
#
# History:
# 1996-03-23 fl Created
# 2009-06-16 fl Fixed mean calculation
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1996.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from . import Image, ImageFilter, ImageStat
class _Enhance:
image: Image.Image
degenerate: Image.Image
def enhance(self, factor: float) -> Image.Image:
"""
Returns an enhanced image.
:param factor: A floating point value controlling the enhancement.
Factor 1.0 always returns a copy of the original image,
lower factors mean less color (brightness, contrast,
etc), and higher values more. There are no restrictions
on this value.
:rtype: :py:class:`~PIL.Image.Image`
"""
return Image.blend(self.degenerate, self.image, factor)
class Color(_Enhance):
"""Adjust image color balance.
This class can be used to adjust the colour balance of an image, in
a manner similar to the controls on a colour TV set. An enhancement
factor of 0.0 gives a black and white image. A factor of 1.0 gives
the original image.
"""
def __init__(self, image: Image.Image) -> None:
self.image = image
self.intermediate_mode = "L"
if "A" in image.getbands():
self.intermediate_mode = "LA"
if self.intermediate_mode != image.mode:
image = image.convert(self.intermediate_mode).convert(image.mode)
self.degenerate = image
class Contrast(_Enhance):
"""Adjust image contrast.
This class can be used to control the contrast of an image, similar
to the contrast control on a TV set. An enhancement factor of 0.0
gives a solid gray image. A factor of 1.0 gives the original image.
"""
def __init__(self, image: Image.Image) -> None:
self.image = image
if image.mode != "L":
image = image.convert("L")
mean = int(ImageStat.Stat(image).mean[0] + 0.5)
self.degenerate = Image.new("L", image.size, mean)
if self.degenerate.mode != self.image.mode:
self.degenerate = self.degenerate.convert(self.image.mode)
if "A" in self.image.getbands():
self.degenerate.putalpha(self.image.getchannel("A"))
class Brightness(_Enhance):
"""Adjust image brightness.
This class can be used to control the brightness of an image. An
enhancement factor of 0.0 gives a black image. A factor of 1.0 gives the
original image.
"""
def __init__(self, image: Image.Image) -> None:
self.image = image
self.degenerate = Image.new(image.mode, image.size, 0)
if "A" in image.getbands():
self.degenerate.putalpha(image.getchannel("A"))
class Sharpness(_Enhance):
"""Adjust image sharpness.
This class can be used to adjust the sharpness of an image. An
enhancement factor of 0.0 gives a blurred image, a factor of 1.0 gives the
original image, and a factor of 2.0 gives a sharpened image.
"""
def __init__(self, image: Image.Image) -> None:
self.image = image
self.degenerate = image.filter(ImageFilter.SMOOTH)
if "A" in image.getbands():
self.degenerate.putalpha(image.getchannel("A"))

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#
# The Python Imaging Library.
# $Id$
#
# base class for image file handlers
#
# history:
# 1995-09-09 fl Created
# 1996-03-11 fl Fixed load mechanism.
# 1996-04-15 fl Added pcx/xbm decoders.
# 1996-04-30 fl Added encoders.
# 1996-12-14 fl Added load helpers
# 1997-01-11 fl Use encode_to_file where possible
# 1997-08-27 fl Flush output in _save
# 1998-03-05 fl Use memory mapping for some modes
# 1999-02-04 fl Use memory mapping also for "I;16" and "I;16B"
# 1999-05-31 fl Added image parser
# 2000-10-12 fl Set readonly flag on memory-mapped images
# 2002-03-20 fl Use better messages for common decoder errors
# 2003-04-21 fl Fall back on mmap/map_buffer if map is not available
# 2003-10-30 fl Added StubImageFile class
# 2004-02-25 fl Made incremental parser more robust
#
# Copyright (c) 1997-2004 by Secret Labs AB
# Copyright (c) 1995-2004 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import abc
import io
import itertools
import os
import struct
import sys
from typing import IO, TYPE_CHECKING, Any, NamedTuple, cast
from . import Image
from ._deprecate import deprecate
from ._util import is_path
if TYPE_CHECKING:
from ._typing import StrOrBytesPath
MAXBLOCK = 65536
SAFEBLOCK = 1024 * 1024
LOAD_TRUNCATED_IMAGES = False
"""Whether or not to load truncated image files. User code may change this."""
ERRORS = {
-1: "image buffer overrun error",
-2: "decoding error",
-3: "unknown error",
-8: "bad configuration",
-9: "out of memory error",
}
"""
Dict of known error codes returned from :meth:`.PyDecoder.decode`,
:meth:`.PyEncoder.encode` :meth:`.PyEncoder.encode_to_pyfd` and
:meth:`.PyEncoder.encode_to_file`.
"""
#
# --------------------------------------------------------------------
# Helpers
def _get_oserror(error: int, *, encoder: bool) -> OSError:
try:
msg = Image.core.getcodecstatus(error)
except AttributeError:
msg = ERRORS.get(error)
if not msg:
msg = f"{'encoder' if encoder else 'decoder'} error {error}"
msg += f" when {'writing' if encoder else 'reading'} image file"
return OSError(msg)
def raise_oserror(error: int) -> OSError:
deprecate(
"raise_oserror",
12,
action="It is only useful for translating error codes returned by a codec's "
"decode() method, which ImageFile already does automatically.",
)
raise _get_oserror(error, encoder=False)
def _tilesort(t: _Tile) -> int:
# sort on offset
return t[2]
class _Tile(NamedTuple):
codec_name: str
extents: tuple[int, int, int, int] | None
offset: int
args: tuple[Any, ...] | str | None
#
# --------------------------------------------------------------------
# ImageFile base class
class ImageFile(Image.Image):
"""Base class for image file format handlers."""
def __init__(
self, fp: StrOrBytesPath | IO[bytes], filename: str | bytes | None = None
) -> None:
super().__init__()
self._min_frame = 0
self.custom_mimetype: str | None = None
self.tile: list[_Tile] = []
""" A list of tile descriptors, or ``None`` """
self.readonly = 1 # until we know better
self.decoderconfig: tuple[Any, ...] = ()
self.decodermaxblock = MAXBLOCK
if is_path(fp):
# filename
self.fp = open(fp, "rb")
self.filename = os.path.realpath(os.fspath(fp))
self._exclusive_fp = True
else:
# stream
self.fp = cast(IO[bytes], fp)
self.filename = filename if filename is not None else ""
# can be overridden
self._exclusive_fp = False
try:
try:
self._open()
except (
IndexError, # end of data
TypeError, # end of data (ord)
KeyError, # unsupported mode
EOFError, # got header but not the first frame
struct.error,
) as v:
raise SyntaxError(v) from v
if not self.mode or self.size[0] <= 0 or self.size[1] <= 0:
msg = "not identified by this driver"
raise SyntaxError(msg)
except BaseException:
# close the file only if we have opened it this constructor
if self._exclusive_fp:
self.fp.close()
raise
def _open(self) -> None:
pass
def get_format_mimetype(self) -> str | None:
if self.custom_mimetype:
return self.custom_mimetype
if self.format is not None:
return Image.MIME.get(self.format.upper())
return None
def __setstate__(self, state: list[Any]) -> None:
self.tile = []
super().__setstate__(state)
def verify(self) -> None:
"""Check file integrity"""
# raise exception if something's wrong. must be called
# directly after open, and closes file when finished.
if self._exclusive_fp:
self.fp.close()
self.fp = None
def load(self) -> Image.core.PixelAccess | None:
"""Load image data based on tile list"""
if not self.tile and self._im is None:
msg = "cannot load this image"
raise OSError(msg)
pixel = Image.Image.load(self)
if not self.tile:
return pixel
self.map: mmap.mmap | None = None
use_mmap = self.filename and len(self.tile) == 1
# As of pypy 2.1.0, memory mapping was failing here.
use_mmap = use_mmap and not hasattr(sys, "pypy_version_info")
readonly = 0
# look for read/seek overrides
if hasattr(self, "load_read"):
read = self.load_read
# don't use mmap if there are custom read/seek functions
use_mmap = False
else:
read = self.fp.read
if hasattr(self, "load_seek"):
seek = self.load_seek
use_mmap = False
else:
seek = self.fp.seek
if use_mmap:
# try memory mapping
decoder_name, extents, offset, args = self.tile[0]
if isinstance(args, str):
args = (args, 0, 1)
if (
decoder_name == "raw"
and isinstance(args, tuple)
and len(args) >= 3
and args[0] == self.mode
and args[0] in Image._MAPMODES
):
try:
# use mmap, if possible
import mmap
with open(self.filename) as fp:
self.map = mmap.mmap(fp.fileno(), 0, access=mmap.ACCESS_READ)
if offset + self.size[1] * args[1] > self.map.size():
msg = "buffer is not large enough"
raise OSError(msg)
self.im = Image.core.map_buffer(
self.map, self.size, decoder_name, offset, args
)
readonly = 1
# After trashing self.im,
# we might need to reload the palette data.
if self.palette:
self.palette.dirty = 1
except (AttributeError, OSError, ImportError):
self.map = None
self.load_prepare()
err_code = -3 # initialize to unknown error
if not self.map:
# sort tiles in file order
self.tile.sort(key=_tilesort)
# FIXME: This is a hack to handle TIFF's JpegTables tag.
prefix = getattr(self, "tile_prefix", b"")
# Remove consecutive duplicates that only differ by their offset
self.tile = [
list(tiles)[-1]
for _, tiles in itertools.groupby(
self.tile, lambda tile: (tile[0], tile[1], tile[3])
)
]
for decoder_name, extents, offset, args in self.tile:
seek(offset)
decoder = Image._getdecoder(
self.mode, decoder_name, args, self.decoderconfig
)
try:
decoder.setimage(self.im, extents)
if decoder.pulls_fd:
decoder.setfd(self.fp)
err_code = decoder.decode(b"")[1]
else:
b = prefix
while True:
try:
s = read(self.decodermaxblock)
except (IndexError, struct.error) as e:
# truncated png/gif
if LOAD_TRUNCATED_IMAGES:
break
else:
msg = "image file is truncated"
raise OSError(msg) from e
if not s: # truncated jpeg
if LOAD_TRUNCATED_IMAGES:
break
else:
msg = (
"image file is truncated "
f"({len(b)} bytes not processed)"
)
raise OSError(msg)
b = b + s
n, err_code = decoder.decode(b)
if n < 0:
break
b = b[n:]
finally:
# Need to cleanup here to prevent leaks
decoder.cleanup()
self.tile = []
self.readonly = readonly
self.load_end()
if self._exclusive_fp and self._close_exclusive_fp_after_loading:
self.fp.close()
self.fp = None
if not self.map and not LOAD_TRUNCATED_IMAGES and err_code < 0:
# still raised if decoder fails to return anything
raise _get_oserror(err_code, encoder=False)
return Image.Image.load(self)
def load_prepare(self) -> None:
# create image memory if necessary
if self._im is None:
self.im = Image.core.new(self.mode, self.size)
# create palette (optional)
if self.mode == "P":
Image.Image.load(self)
def load_end(self) -> None:
# may be overridden
pass
# may be defined for contained formats
# def load_seek(self, pos: int) -> None:
# pass
# may be defined for blocked formats (e.g. PNG)
# def load_read(self, read_bytes: int) -> bytes:
# pass
def _seek_check(self, frame: int) -> bool:
if (
frame < self._min_frame
# Only check upper limit on frames if additional seek operations
# are not required to do so
or (
not (hasattr(self, "_n_frames") and self._n_frames is None)
and frame >= getattr(self, "n_frames") + self._min_frame
)
):
msg = "attempt to seek outside sequence"
raise EOFError(msg)
return self.tell() != frame
class StubHandler:
def open(self, im: StubImageFile) -> None:
pass
@abc.abstractmethod
def load(self, im: StubImageFile) -> Image.Image:
pass
class StubImageFile(ImageFile):
"""
Base class for stub image loaders.
A stub loader is an image loader that can identify files of a
certain format, but relies on external code to load the file.
"""
def _open(self) -> None:
msg = "StubImageFile subclass must implement _open"
raise NotImplementedError(msg)
def load(self) -> Image.core.PixelAccess | None:
loader = self._load()
if loader is None:
msg = f"cannot find loader for this {self.format} file"
raise OSError(msg)
image = loader.load(self)
assert image is not None
# become the other object (!)
self.__class__ = image.__class__ # type: ignore[assignment]
self.__dict__ = image.__dict__
return image.load()
def _load(self) -> StubHandler | None:
"""(Hook) Find actual image loader."""
msg = "StubImageFile subclass must implement _load"
raise NotImplementedError(msg)
class Parser:
"""
Incremental image parser. This class implements the standard
feed/close consumer interface.
"""
incremental = None
image: Image.Image | None = None
data: bytes | None = None
decoder: Image.core.ImagingDecoder | PyDecoder | None = None
offset = 0
finished = 0
def reset(self) -> None:
"""
(Consumer) Reset the parser. Note that you can only call this
method immediately after you've created a parser; parser
instances cannot be reused.
"""
assert self.data is None, "cannot reuse parsers"
def feed(self, data: bytes) -> None:
"""
(Consumer) Feed data to the parser.
:param data: A string buffer.
:exception OSError: If the parser failed to parse the image file.
"""
# collect data
if self.finished:
return
if self.data is None:
self.data = data
else:
self.data = self.data + data
# parse what we have
if self.decoder:
if self.offset > 0:
# skip header
skip = min(len(self.data), self.offset)
self.data = self.data[skip:]
self.offset = self.offset - skip
if self.offset > 0 or not self.data:
return
n, e = self.decoder.decode(self.data)
if n < 0:
# end of stream
self.data = None
self.finished = 1
if e < 0:
# decoding error
self.image = None
raise _get_oserror(e, encoder=False)
else:
# end of image
return
self.data = self.data[n:]
elif self.image:
# if we end up here with no decoder, this file cannot
# be incrementally parsed. wait until we've gotten all
# available data
pass
else:
# attempt to open this file
try:
with io.BytesIO(self.data) as fp:
im = Image.open(fp)
except OSError:
pass # not enough data
else:
flag = hasattr(im, "load_seek") or hasattr(im, "load_read")
if flag or len(im.tile) != 1:
# custom load code, or multiple tiles
self.decode = None
else:
# initialize decoder
im.load_prepare()
d, e, o, a = im.tile[0]
im.tile = []
self.decoder = Image._getdecoder(im.mode, d, a, im.decoderconfig)
self.decoder.setimage(im.im, e)
# calculate decoder offset
self.offset = o
if self.offset <= len(self.data):
self.data = self.data[self.offset :]
self.offset = 0
self.image = im
def __enter__(self) -> Parser:
return self
def __exit__(self, *args: object) -> None:
self.close()
def close(self) -> Image.Image:
"""
(Consumer) Close the stream.
:returns: An image object.
:exception OSError: If the parser failed to parse the image file either
because it cannot be identified or cannot be
decoded.
"""
# finish decoding
if self.decoder:
# get rid of what's left in the buffers
self.feed(b"")
self.data = self.decoder = None
if not self.finished:
msg = "image was incomplete"
raise OSError(msg)
if not self.image:
msg = "cannot parse this image"
raise OSError(msg)
if self.data:
# incremental parsing not possible; reopen the file
# not that we have all data
with io.BytesIO(self.data) as fp:
try:
self.image = Image.open(fp)
finally:
self.image.load()
return self.image
# --------------------------------------------------------------------
def _save(im: Image.Image, fp: IO[bytes], tile: list[_Tile], bufsize: int = 0) -> None:
"""Helper to save image based on tile list
:param im: Image object.
:param fp: File object.
:param tile: Tile list.
:param bufsize: Optional buffer size
"""
im.load()
if not hasattr(im, "encoderconfig"):
im.encoderconfig = ()
tile.sort(key=_tilesort)
# FIXME: make MAXBLOCK a configuration parameter
# It would be great if we could have the encoder specify what it needs
# But, it would need at least the image size in most cases. RawEncode is
# a tricky case.
bufsize = max(MAXBLOCK, bufsize, im.size[0] * 4) # see RawEncode.c
try:
fh = fp.fileno()
fp.flush()
_encode_tile(im, fp, tile, bufsize, fh)
except (AttributeError, io.UnsupportedOperation) as exc:
_encode_tile(im, fp, tile, bufsize, None, exc)
if hasattr(fp, "flush"):
fp.flush()
def _encode_tile(
im: Image.Image,
fp: IO[bytes],
tile: list[_Tile],
bufsize: int,
fh: int | None,
exc: BaseException | None = None,
) -> None:
for encoder_name, extents, offset, args in tile:
if offset > 0:
fp.seek(offset)
encoder = Image._getencoder(im.mode, encoder_name, args, im.encoderconfig)
try:
encoder.setimage(im.im, extents)
if encoder.pushes_fd:
encoder.setfd(fp)
errcode = encoder.encode_to_pyfd()[1]
else:
if exc:
# compress to Python file-compatible object
while True:
errcode, data = encoder.encode(bufsize)[1:]
fp.write(data)
if errcode:
break
else:
# slight speedup: compress to real file object
assert fh is not None
errcode = encoder.encode_to_file(fh, bufsize)
if errcode < 0:
raise _get_oserror(errcode, encoder=True) from exc
finally:
encoder.cleanup()
def _safe_read(fp: IO[bytes], size: int) -> bytes:
"""
Reads large blocks in a safe way. Unlike fp.read(n), this function
doesn't trust the user. If the requested size is larger than
SAFEBLOCK, the file is read block by block.
:param fp: File handle. Must implement a <b>read</b> method.
:param size: Number of bytes to read.
:returns: A string containing <i>size</i> bytes of data.
Raises an OSError if the file is truncated and the read cannot be completed
"""
if size <= 0:
return b""
if size <= SAFEBLOCK:
data = fp.read(size)
if len(data) < size:
msg = "Truncated File Read"
raise OSError(msg)
return data
blocks: list[bytes] = []
remaining_size = size
while remaining_size > 0:
block = fp.read(min(remaining_size, SAFEBLOCK))
if not block:
break
blocks.append(block)
remaining_size -= len(block)
if sum(len(block) for block in blocks) < size:
msg = "Truncated File Read"
raise OSError(msg)
return b"".join(blocks)
class PyCodecState:
def __init__(self) -> None:
self.xsize = 0
self.ysize = 0
self.xoff = 0
self.yoff = 0
def extents(self) -> tuple[int, int, int, int]:
return self.xoff, self.yoff, self.xoff + self.xsize, self.yoff + self.ysize
class PyCodec:
fd: IO[bytes] | None
def __init__(self, mode: str, *args: Any) -> None:
self.im: Image.core.ImagingCore | None = None
self.state = PyCodecState()
self.fd = None
self.mode = mode
self.init(args)
def init(self, args: tuple[Any, ...]) -> None:
"""
Override to perform codec specific initialization
:param args: Tuple of arg items from the tile entry
:returns: None
"""
self.args = args
def cleanup(self) -> None:
"""
Override to perform codec specific cleanup
:returns: None
"""
pass
def setfd(self, fd: IO[bytes]) -> None:
"""
Called from ImageFile to set the Python file-like object
:param fd: A Python file-like object
:returns: None
"""
self.fd = fd
def setimage(
self,
im: Image.core.ImagingCore,
extents: tuple[int, int, int, int] | None = None,
) -> None:
"""
Called from ImageFile to set the core output image for the codec
:param im: A core image object
:param extents: a 4 tuple of (x0, y0, x1, y1) defining the rectangle
for this tile
:returns: None
"""
# following c code
self.im = im
if extents:
(x0, y0, x1, y1) = extents
else:
(x0, y0, x1, y1) = (0, 0, 0, 0)
if x0 == 0 and x1 == 0:
self.state.xsize, self.state.ysize = self.im.size
else:
self.state.xoff = x0
self.state.yoff = y0
self.state.xsize = x1 - x0
self.state.ysize = y1 - y0
if self.state.xsize <= 0 or self.state.ysize <= 0:
msg = "Size cannot be negative"
raise ValueError(msg)
if (
self.state.xsize + self.state.xoff > self.im.size[0]
or self.state.ysize + self.state.yoff > self.im.size[1]
):
msg = "Tile cannot extend outside image"
raise ValueError(msg)
class PyDecoder(PyCodec):
"""
Python implementation of a format decoder. Override this class and
add the decoding logic in the :meth:`decode` method.
See :ref:`Writing Your Own File Codec in Python<file-codecs-py>`
"""
_pulls_fd = False
@property
def pulls_fd(self) -> bool:
return self._pulls_fd
def decode(self, buffer: bytes | Image.SupportsArrayInterface) -> tuple[int, int]:
"""
Override to perform the decoding process.
:param buffer: A bytes object with the data to be decoded.
:returns: A tuple of ``(bytes consumed, errcode)``.
If finished with decoding return -1 for the bytes consumed.
Err codes are from :data:`.ImageFile.ERRORS`.
"""
msg = "unavailable in base decoder"
raise NotImplementedError(msg)
def set_as_raw(
self, data: bytes, rawmode: str | None = None, extra: tuple[Any, ...] = ()
) -> None:
"""
Convenience method to set the internal image from a stream of raw data
:param data: Bytes to be set
:param rawmode: The rawmode to be used for the decoder.
If not specified, it will default to the mode of the image
:param extra: Extra arguments for the decoder.
:returns: None
"""
if not rawmode:
rawmode = self.mode
d = Image._getdecoder(self.mode, "raw", rawmode, extra)
assert self.im is not None
d.setimage(self.im, self.state.extents())
s = d.decode(data)
if s[0] >= 0:
msg = "not enough image data"
raise ValueError(msg)
if s[1] != 0:
msg = "cannot decode image data"
raise ValueError(msg)
class PyEncoder(PyCodec):
"""
Python implementation of a format encoder. Override this class and
add the decoding logic in the :meth:`encode` method.
See :ref:`Writing Your Own File Codec in Python<file-codecs-py>`
"""
_pushes_fd = False
@property
def pushes_fd(self) -> bool:
return self._pushes_fd
def encode(self, bufsize: int) -> tuple[int, int, bytes]:
"""
Override to perform the encoding process.
:param bufsize: Buffer size.
:returns: A tuple of ``(bytes encoded, errcode, bytes)``.
If finished with encoding return 1 for the error code.
Err codes are from :data:`.ImageFile.ERRORS`.
"""
msg = "unavailable in base encoder"
raise NotImplementedError(msg)
def encode_to_pyfd(self) -> tuple[int, int]:
"""
If ``pushes_fd`` is ``True``, then this method will be used,
and ``encode()`` will only be called once.
:returns: A tuple of ``(bytes consumed, errcode)``.
Err codes are from :data:`.ImageFile.ERRORS`.
"""
if not self.pushes_fd:
return 0, -8 # bad configuration
bytes_consumed, errcode, data = self.encode(0)
if data:
assert self.fd is not None
self.fd.write(data)
return bytes_consumed, errcode
def encode_to_file(self, fh: int, bufsize: int) -> int:
"""
:param fh: File handle.
:param bufsize: Buffer size.
:returns: If finished successfully, return 0.
Otherwise, return an error code. Err codes are from
:data:`.ImageFile.ERRORS`.
"""
errcode = 0
while errcode == 0:
status, errcode, buf = self.encode(bufsize)
if status > 0:
os.write(fh, buf[status:])
return errcode

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venv/lib/python3.12/site-packages/PIL/ImageFilter.py Normal file
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@ -0,0 +1,605 @@
#
# The Python Imaging Library.
# $Id$
#
# standard filters
#
# History:
# 1995-11-27 fl Created
# 2002-06-08 fl Added rank and mode filters
# 2003-09-15 fl Fixed rank calculation in rank filter; added expand call
#
# Copyright (c) 1997-2003 by Secret Labs AB.
# Copyright (c) 1995-2002 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import abc
import functools
from collections.abc import Sequence
from types import ModuleType
from typing import TYPE_CHECKING, Any, Callable, cast
if TYPE_CHECKING:
from . import _imaging
from ._typing import NumpyArray
class Filter:
@abc.abstractmethod
def filter(self, image: _imaging.ImagingCore) -> _imaging.ImagingCore:
pass
class MultibandFilter(Filter):
pass
class BuiltinFilter(MultibandFilter):
filterargs: tuple[Any, ...]
def filter(self, image: _imaging.ImagingCore) -> _imaging.ImagingCore:
if image.mode == "P":
msg = "cannot filter palette images"
raise ValueError(msg)
return image.filter(*self.filterargs)
class Kernel(BuiltinFilter):
"""
Create a convolution kernel. This only supports 3x3 and 5x5 integer and floating
point kernels.
Kernels can only be applied to "L" and "RGB" images.
:param size: Kernel size, given as (width, height). This must be (3,3) or (5,5).
:param kernel: A sequence containing kernel weights. The kernel will be flipped
vertically before being applied to the image.
:param scale: Scale factor. If given, the result for each pixel is divided by this
value. The default is the sum of the kernel weights.
:param offset: Offset. If given, this value is added to the result, after it has
been divided by the scale factor.
"""
name = "Kernel"
def __init__(
self,
size: tuple[int, int],
kernel: Sequence[float],
scale: float | None = None,
offset: float = 0,
) -> None:
if scale is None:
# default scale is sum of kernel
scale = functools.reduce(lambda a, b: a + b, kernel)
if size[0] * size[1] != len(kernel):
msg = "not enough coefficients in kernel"
raise ValueError(msg)
self.filterargs = size, scale, offset, kernel
class RankFilter(Filter):
"""
Create a rank filter. The rank filter sorts all pixels in
a window of the given size, and returns the ``rank``'th value.
:param size: The kernel size, in pixels.
:param rank: What pixel value to pick. Use 0 for a min filter,
``size * size / 2`` for a median filter, ``size * size - 1``
for a max filter, etc.
"""
name = "Rank"
def __init__(self, size: int, rank: int) -> None:
self.size = size
self.rank = rank
def filter(self, image: _imaging.ImagingCore) -> _imaging.ImagingCore:
if image.mode == "P":
msg = "cannot filter palette images"
raise ValueError(msg)
image = image.expand(self.size // 2, self.size // 2)
return image.rankfilter(self.size, self.rank)
class MedianFilter(RankFilter):
"""
Create a median filter. Picks the median pixel value in a window with the
given size.
:param size: The kernel size, in pixels.
"""
name = "Median"
def __init__(self, size: int = 3) -> None:
self.size = size
self.rank = size * size // 2
class MinFilter(RankFilter):
"""
Create a min filter. Picks the lowest pixel value in a window with the
given size.
:param size: The kernel size, in pixels.
"""
name = "Min"
def __init__(self, size: int = 3) -> None:
self.size = size
self.rank = 0
class MaxFilter(RankFilter):
"""
Create a max filter. Picks the largest pixel value in a window with the
given size.
:param size: The kernel size, in pixels.
"""
name = "Max"
def __init__(self, size: int = 3) -> None:
self.size = size
self.rank = size * size - 1
class ModeFilter(Filter):
"""
Create a mode filter. Picks the most frequent pixel value in a box with the
given size. Pixel values that occur only once or twice are ignored; if no
pixel value occurs more than twice, the original pixel value is preserved.
:param size: The kernel size, in pixels.
"""
name = "Mode"
def __init__(self, size: int = 3) -> None:
self.size = size
def filter(self, image: _imaging.ImagingCore) -> _imaging.ImagingCore:
return image.modefilter(self.size)
class GaussianBlur(MultibandFilter):
"""Blurs the image with a sequence of extended box filters, which
approximates a Gaussian kernel. For details on accuracy see
<https://www.mia.uni-saarland.de/Publications/gwosdek-ssvm11.pdf>
:param radius: Standard deviation of the Gaussian kernel. Either a sequence of two
numbers for x and y, or a single number for both.
"""
name = "GaussianBlur"
def __init__(self, radius: float | Sequence[float] = 2) -> None:
self.radius = radius
def filter(self, image: _imaging.ImagingCore) -> _imaging.ImagingCore:
xy = self.radius
if isinstance(xy, (int, float)):
xy = (xy, xy)
if xy == (0, 0):
return image.copy()
return image.gaussian_blur(xy)
class BoxBlur(MultibandFilter):
"""Blurs the image by setting each pixel to the average value of the pixels
in a square box extending radius pixels in each direction.
Supports float radius of arbitrary size. Uses an optimized implementation
which runs in linear time relative to the size of the image
for any radius value.
:param radius: Size of the box in a direction. Either a sequence of two numbers for
x and y, or a single number for both.
Radius 0 does not blur, returns an identical image.
Radius 1 takes 1 pixel in each direction, i.e. 9 pixels in total.
"""
name = "BoxBlur"
def __init__(self, radius: float | Sequence[float]) -> None:
xy = radius if isinstance(radius, (tuple, list)) else (radius, radius)
if xy[0] < 0 or xy[1] < 0:
msg = "radius must be >= 0"
raise ValueError(msg)
self.radius = radius
def filter(self, image: _imaging.ImagingCore) -> _imaging.ImagingCore:
xy = self.radius
if isinstance(xy, (int, float)):
xy = (xy, xy)
if xy == (0, 0):
return image.copy()
return image.box_blur(xy)
class UnsharpMask(MultibandFilter):
"""Unsharp mask filter.
See Wikipedia's entry on `digital unsharp masking`_ for an explanation of
the parameters.
:param radius: Blur Radius
:param percent: Unsharp strength, in percent
:param threshold: Threshold controls the minimum brightness change that
will be sharpened
.. _digital unsharp masking: https://en.wikipedia.org/wiki/Unsharp_masking#Digital_unsharp_masking
"""
name = "UnsharpMask"
def __init__(
self, radius: float = 2, percent: int = 150, threshold: int = 3
) -> None:
self.radius = radius
self.percent = percent
self.threshold = threshold
def filter(self, image: _imaging.ImagingCore) -> _imaging.ImagingCore:
return image.unsharp_mask(self.radius, self.percent, self.threshold)
class BLUR(BuiltinFilter):
name = "Blur"
# fmt: off
filterargs = (5, 5), 16, 0, (
1, 1, 1, 1, 1,
1, 0, 0, 0, 1,
1, 0, 0, 0, 1,
1, 0, 0, 0, 1,
1, 1, 1, 1, 1,
)
# fmt: on
class CONTOUR(BuiltinFilter):
name = "Contour"
# fmt: off
filterargs = (3, 3), 1, 255, (
-1, -1, -1,
-1, 8, -1,
-1, -1, -1,
)
# fmt: on
class DETAIL(BuiltinFilter):
name = "Detail"
# fmt: off
filterargs = (3, 3), 6, 0, (
0, -1, 0,
-1, 10, -1,
0, -1, 0,
)
# fmt: on
class EDGE_ENHANCE(BuiltinFilter):
name = "Edge-enhance"
# fmt: off
filterargs = (3, 3), 2, 0, (
-1, -1, -1,
-1, 10, -1,
-1, -1, -1,
)
# fmt: on
class EDGE_ENHANCE_MORE(BuiltinFilter):
name = "Edge-enhance More"
# fmt: off
filterargs = (3, 3), 1, 0, (
-1, -1, -1,
-1, 9, -1,
-1, -1, -1,
)
# fmt: on
class EMBOSS(BuiltinFilter):
name = "Emboss"
# fmt: off
filterargs = (3, 3), 1, 128, (
-1, 0, 0,
0, 1, 0,
0, 0, 0,
)
# fmt: on
class FIND_EDGES(BuiltinFilter):
name = "Find Edges"
# fmt: off
filterargs = (3, 3), 1, 0, (
-1, -1, -1,
-1, 8, -1,
-1, -1, -1,
)
# fmt: on
class SHARPEN(BuiltinFilter):
name = "Sharpen"
# fmt: off
filterargs = (3, 3), 16, 0, (
-2, -2, -2,
-2, 32, -2,
-2, -2, -2,
)
# fmt: on
class SMOOTH(BuiltinFilter):
name = "Smooth"
# fmt: off
filterargs = (3, 3), 13, 0, (
1, 1, 1,
1, 5, 1,
1, 1, 1,
)
# fmt: on
class SMOOTH_MORE(BuiltinFilter):
name = "Smooth More"
# fmt: off
filterargs = (5, 5), 100, 0, (
1, 1, 1, 1, 1,
1, 5, 5, 5, 1,
1, 5, 44, 5, 1,
1, 5, 5, 5, 1,
1, 1, 1, 1, 1,
)
# fmt: on
class Color3DLUT(MultibandFilter):
"""Three-dimensional color lookup table.
Transforms 3-channel pixels using the values of the channels as coordinates
in the 3D lookup table and interpolating the nearest elements.
This method allows you to apply almost any color transformation
in constant time by using pre-calculated decimated tables.
.. versionadded:: 5.2.0
:param size: Size of the table. One int or tuple of (int, int, int).
Minimal size in any dimension is 2, maximum is 65.
:param table: Flat lookup table. A list of ``channels * size**3``
float elements or a list of ``size**3`` channels-sized
tuples with floats. Channels are changed first,
then first dimension, then second, then third.
Value 0.0 corresponds lowest value of output, 1.0 highest.
:param channels: Number of channels in the table. Could be 3 or 4.
Default is 3.
:param target_mode: A mode for the result image. Should have not less
than ``channels`` channels. Default is ``None``,
which means that mode wouldn't be changed.
"""
name = "Color 3D LUT"
def __init__(
self,
size: int | tuple[int, int, int],
table: Sequence[float] | Sequence[Sequence[int]] | NumpyArray,
channels: int = 3,
target_mode: str | None = None,
**kwargs: bool,
) -> None:
if channels not in (3, 4):
msg = "Only 3 or 4 output channels are supported"
raise ValueError(msg)
self.size = size = self._check_size(size)
self.channels = channels
self.mode = target_mode
# Hidden flag `_copy_table=False` could be used to avoid extra copying
# of the table if the table is specially made for the constructor.
copy_table = kwargs.get("_copy_table", True)
items = size[0] * size[1] * size[2]
wrong_size = False
numpy: ModuleType | None = None
if hasattr(table, "shape"):
try:
import numpy
except ImportError:
pass
if numpy and isinstance(table, numpy.ndarray):
numpy_table: NumpyArray = table
if copy_table:
numpy_table = numpy_table.copy()
if numpy_table.shape in [
(items * channels,),
(items, channels),
(size[2], size[1], size[0], channels),
]:
table = numpy_table.reshape(items * channels)
else:
wrong_size = True
else:
if copy_table:
table = list(table)
# Convert to a flat list
if table and isinstance(table[0], (list, tuple)):
raw_table = cast(Sequence[Sequence[int]], table)
flat_table: list[int] = []
for pixel in raw_table:
if len(pixel) != channels:
msg = (
"The elements of the table should "
f"have a length of {channels}."
)
raise ValueError(msg)
flat_table.extend(pixel)
table = flat_table
if wrong_size or len(table) != items * channels:
msg = (
"The table should have either channels * size**3 float items "
"or size**3 items of channels-sized tuples with floats. "
f"Table should be: {channels}x{size[0]}x{size[1]}x{size[2]}. "
f"Actual length: {len(table)}"
)
raise ValueError(msg)
self.table = table
@staticmethod
def _check_size(size: Any) -> tuple[int, int, int]:
try:
_, _, _ = size
except ValueError as e:
msg = "Size should be either an integer or a tuple of three integers."
raise ValueError(msg) from e
except TypeError:
size = (size, size, size)
size = tuple(int(x) for x in size)
for size_1d in size:
if not 2 <= size_1d <= 65:
msg = "Size should be in [2, 65] range."
raise ValueError(msg)
return size
@classmethod
def generate(
cls,
size: int | tuple[int, int, int],
callback: Callable[[float, float, float], tuple[float, ...]],
channels: int = 3,
target_mode: str | None = None,
) -> Color3DLUT:
"""Generates new LUT using provided callback.
:param size: Size of the table. Passed to the constructor.
:param callback: Function with three parameters which correspond
three color channels. Will be called ``size**3``
times with values from 0.0 to 1.0 and should return
a tuple with ``channels`` elements.
:param channels: The number of channels which should return callback.
:param target_mode: Passed to the constructor of the resulting
lookup table.
"""
size_1d, size_2d, size_3d = cls._check_size(size)
if channels not in (3, 4):
msg = "Only 3 or 4 output channels are supported"
raise ValueError(msg)
table: list[float] = [0] * (size_1d * size_2d * size_3d * channels)
idx_out = 0
for b in range(size_3d):
for g in range(size_2d):
for r in range(size_1d):
table[idx_out : idx_out + channels] = callback(
r / (size_1d - 1), g / (size_2d - 1), b / (size_3d - 1)
)
idx_out += channels
return cls(
(size_1d, size_2d, size_3d),
table,
channels=channels,
target_mode=target_mode,
_copy_table=False,
)
def transform(
self,
callback: Callable[..., tuple[float, ...]],
with_normals: bool = False,
channels: int | None = None,
target_mode: str | None = None,
) -> Color3DLUT:
"""Transforms the table values using provided callback and returns
a new LUT with altered values.
:param callback: A function which takes old lookup table values
and returns a new set of values. The number
of arguments which function should take is
``self.channels`` or ``3 + self.channels``
if ``with_normals`` flag is set.
Should return a tuple of ``self.channels`` or
``channels`` elements if it is set.
:param with_normals: If true, ``callback`` will be called with
coordinates in the color cube as the first
three arguments. Otherwise, ``callback``
will be called only with actual color values.
:param channels: The number of channels in the resulting lookup table.
:param target_mode: Passed to the constructor of the resulting
lookup table.
"""
if channels not in (None, 3, 4):
msg = "Only 3 or 4 output channels are supported"
raise ValueError(msg)
ch_in = self.channels
ch_out = channels or ch_in
size_1d, size_2d, size_3d = self.size
table = [0] * (size_1d * size_2d * size_3d * ch_out)
idx_in = 0
idx_out = 0
for b in range(size_3d):
for g in range(size_2d):
for r in range(size_1d):
values = self.table[idx_in : idx_in + ch_in]
if with_normals:
values = callback(
r / (size_1d - 1),
g / (size_2d - 1),
b / (size_3d - 1),
*values,
)
else:
values = callback(*values)
table[idx_out : idx_out + ch_out] = values
idx_in += ch_in
idx_out += ch_out
return type(self)(
self.size,
table,
channels=ch_out,
target_mode=target_mode or self.mode,
_copy_table=False,
)
def __repr__(self) -> str:
r = [
f"{self.__class__.__name__} from {self.table.__class__.__name__}",
"size={:d}x{:d}x{:d}".format(*self.size),
f"channels={self.channels:d}",
]
if self.mode:
r.append(f"target_mode={self.mode}")
return "<{}>".format(" ".join(r))
def filter(self, image: _imaging.ImagingCore) -> _imaging.ImagingCore:
from . import Image
return image.color_lut_3d(
self.mode or image.mode,
Image.Resampling.BILINEAR,
self.channels,
self.size[0],
self.size[1],
self.size[2],
self.table,
)

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venv/lib/python3.12/site-packages/PIL/ImageGrab.py Normal file
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#
# The Python Imaging Library
# $Id$
#
# screen grabber
#
# History:
# 2001-04-26 fl created
# 2001-09-17 fl use builtin driver, if present
# 2002-11-19 fl added grabclipboard support
#
# Copyright (c) 2001-2002 by Secret Labs AB
# Copyright (c) 2001-2002 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import io
import os
import shutil
import subprocess
import sys
import tempfile
from . import Image
def grab(
bbox: tuple[int, int, int, int] | None = None,
include_layered_windows: bool = False,
all_screens: bool = False,
xdisplay: str | None = None,
) -> Image.Image:
im: Image.Image
if xdisplay is None:
if sys.platform == "darwin":
fh, filepath = tempfile.mkstemp(".png")
os.close(fh)
args = ["screencapture"]
if bbox:
left, top, right, bottom = bbox
args += ["-R", f"{left},{top},{right-left},{bottom-top}"]
subprocess.call(args + ["-x", filepath])
im = Image.open(filepath)
im.load()
os.unlink(filepath)
if bbox:
im_resized = im.resize((right - left, bottom - top))
im.close()
return im_resized
return im
elif sys.platform == "win32":
offset, size, data = Image.core.grabscreen_win32(
include_layered_windows, all_screens
)
im = Image.frombytes(
"RGB",
size,
data,
# RGB, 32-bit line padding, origin lower left corner
"raw",
"BGR",
(size[0] * 3 + 3) & -4,
-1,
)
if bbox:
x0, y0 = offset
left, top, right, bottom = bbox
im = im.crop((left - x0, top - y0, right - x0, bottom - y0))
return im
# Cast to Optional[str] needed for Windows and macOS.
display_name: str | None = xdisplay
try:
if not Image.core.HAVE_XCB:
msg = "Pillow was built without XCB support"
raise OSError(msg)
size, data = Image.core.grabscreen_x11(display_name)
except OSError:
if (
display_name is None
and sys.platform not in ("darwin", "win32")
and shutil.which("gnome-screenshot")
):
fh, filepath = tempfile.mkstemp(".png")
os.close(fh)
subprocess.call(["gnome-screenshot", "-f", filepath])
im = Image.open(filepath)
im.load()
os.unlink(filepath)
if bbox:
im_cropped = im.crop(bbox)
im.close()
return im_cropped
return im
else:
raise
else:
im = Image.frombytes("RGB", size, data, "raw", "BGRX", size[0] * 4, 1)
if bbox:
im = im.crop(bbox)
return im
def grabclipboard() -> Image.Image | list[str] | None:
if sys.platform == "darwin":
fh, filepath = tempfile.mkstemp(".png")
os.close(fh)
commands = [
'set theFile to (open for access POSIX file "'
+ filepath
+ '" with write permission)',
"try",
" write (the clipboard as «class PNGf») to theFile",
"end try",
"close access theFile",
]
script = ["osascript"]
for command in commands:
script += ["-e", command]
subprocess.call(script)
im = None
if os.stat(filepath).st_size != 0:
im = Image.open(filepath)
im.load()
os.unlink(filepath)
return im
elif sys.platform == "win32":
fmt, data = Image.core.grabclipboard_win32()
if fmt == "file": # CF_HDROP
import struct
o = struct.unpack_from("I", data)[0]
if data[16] != 0:
files = data[o:].decode("utf-16le").split("\0")
else:
files = data[o:].decode("mbcs").split("\0")
return files[: files.index("")]
if isinstance(data, bytes):
data = io.BytesIO(data)
if fmt == "png":
from . import PngImagePlugin
return PngImagePlugin.PngImageFile(data)
elif fmt == "DIB":
from . import BmpImagePlugin
return BmpImagePlugin.DibImageFile(data)
return None
else:
if os.getenv("WAYLAND_DISPLAY"):
session_type = "wayland"
elif os.getenv("DISPLAY"):
session_type = "x11"
else: # Session type check failed
session_type = None
if shutil.which("wl-paste") and session_type in ("wayland", None):
args = ["wl-paste", "-t", "image"]
elif shutil.which("xclip") and session_type in ("x11", None):
args = ["xclip", "-selection", "clipboard", "-t", "image/png", "-o"]
else:
msg = "wl-paste or xclip is required for ImageGrab.grabclipboard() on Linux"
raise NotImplementedError(msg)
p = subprocess.run(args, capture_output=True)
if p.returncode != 0:
err = p.stderr
for silent_error in [
# wl-paste, when the clipboard is empty
b"Nothing is copied",
# Ubuntu/Debian wl-paste, when the clipboard is empty
b"No selection",
# Ubuntu/Debian wl-paste, when an image isn't available
b"No suitable type of content copied",
# wl-paste or Ubuntu/Debian xclip, when an image isn't available
b" not available",
# xclip, when an image isn't available
b"cannot convert ",
# xclip, when the clipboard isn't initialized
b"xclip: Error: There is no owner for the ",
]:
if silent_error in err:
return None
msg = f"{args[0]} error"
if err:
msg += f": {err.strip().decode()}"
raise ChildProcessError(msg)
data = io.BytesIO(p.stdout)
im = Image.open(data)
im.load()
return im

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#
# The Python Imaging Library
# $Id$
#
# a simple math add-on for the Python Imaging Library
#
# History:
# 1999-02-15 fl Original PIL Plus release
# 2005-05-05 fl Simplified and cleaned up for PIL 1.1.6
# 2005-09-12 fl Fixed int() and float() for Python 2.4.1
#
# Copyright (c) 1999-2005 by Secret Labs AB
# Copyright (c) 2005 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import builtins
from types import CodeType
from typing import Any, Callable
from . import Image, _imagingmath
from ._deprecate import deprecate
class _Operand:
"""Wraps an image operand, providing standard operators"""
def __init__(self, im: Image.Image):
self.im = im
def __fixup(self, im1: _Operand | float) -> Image.Image:
# convert image to suitable mode
if isinstance(im1, _Operand):
# argument was an image.
if im1.im.mode in ("1", "L"):
return im1.im.convert("I")
elif im1.im.mode in ("I", "F"):
return im1.im
else:
msg = f"unsupported mode: {im1.im.mode}"
raise ValueError(msg)
else:
# argument was a constant
if isinstance(im1, (int, float)) and self.im.mode in ("1", "L", "I"):
return Image.new("I", self.im.size, im1)
else:
return Image.new("F", self.im.size, im1)
def apply(
self,
op: str,
im1: _Operand | float,
im2: _Operand | float | None = None,
mode: str | None = None,
) -> _Operand:
im_1 = self.__fixup(im1)
if im2 is None:
# unary operation
out = Image.new(mode or im_1.mode, im_1.size, None)
try:
op = getattr(_imagingmath, f"{op}_{im_1.mode}")
except AttributeError as e:
msg = f"bad operand type for '{op}'"
raise TypeError(msg) from e
_imagingmath.unop(op, out.getim(), im_1.getim())
else:
# binary operation
im_2 = self.__fixup(im2)
if im_1.mode != im_2.mode:
# convert both arguments to floating point
if im_1.mode != "F":
im_1 = im_1.convert("F")
if im_2.mode != "F":
im_2 = im_2.convert("F")
if im_1.size != im_2.size:
# crop both arguments to a common size
size = (
min(im_1.size[0], im_2.size[0]),
min(im_1.size[1], im_2.size[1]),
)
if im_1.size != size:
im_1 = im_1.crop((0, 0) + size)
if im_2.size != size:
im_2 = im_2.crop((0, 0) + size)
out = Image.new(mode or im_1.mode, im_1.size, None)
try:
op = getattr(_imagingmath, f"{op}_{im_1.mode}")
except AttributeError as e:
msg = f"bad operand type for '{op}'"
raise TypeError(msg) from e
_imagingmath.binop(op, out.getim(), im_1.getim(), im_2.getim())
return _Operand(out)
# unary operators
def __bool__(self) -> bool:
# an image is "true" if it contains at least one non-zero pixel
return self.im.getbbox() is not None
def __abs__(self) -> _Operand:
return self.apply("abs", self)
def __pos__(self) -> _Operand:
return self
def __neg__(self) -> _Operand:
return self.apply("neg", self)
# binary operators
def __add__(self, other: _Operand | float) -> _Operand:
return self.apply("add", self, other)
def __radd__(self, other: _Operand | float) -> _Operand:
return self.apply("add", other, self)
def __sub__(self, other: _Operand | float) -> _Operand:
return self.apply("sub", self, other)
def __rsub__(self, other: _Operand | float) -> _Operand:
return self.apply("sub", other, self)
def __mul__(self, other: _Operand | float) -> _Operand:
return self.apply("mul", self, other)
def __rmul__(self, other: _Operand | float) -> _Operand:
return self.apply("mul", other, self)
def __truediv__(self, other: _Operand | float) -> _Operand:
return self.apply("div", self, other)
def __rtruediv__(self, other: _Operand | float) -> _Operand:
return self.apply("div", other, self)
def __mod__(self, other: _Operand | float) -> _Operand:
return self.apply("mod", self, other)
def __rmod__(self, other: _Operand | float) -> _Operand:
return self.apply("mod", other, self)
def __pow__(self, other: _Operand | float) -> _Operand:
return self.apply("pow", self, other)
def __rpow__(self, other: _Operand | float) -> _Operand:
return self.apply("pow", other, self)
# bitwise
def __invert__(self) -> _Operand:
return self.apply("invert", self)
def __and__(self, other: _Operand | float) -> _Operand:
return self.apply("and", self, other)
def __rand__(self, other: _Operand | float) -> _Operand:
return self.apply("and", other, self)
def __or__(self, other: _Operand | float) -> _Operand:
return self.apply("or", self, other)
def __ror__(self, other: _Operand | float) -> _Operand:
return self.apply("or", other, self)
def __xor__(self, other: _Operand | float) -> _Operand:
return self.apply("xor", self, other)
def __rxor__(self, other: _Operand | float) -> _Operand:
return self.apply("xor", other, self)
def __lshift__(self, other: _Operand | float) -> _Operand:
return self.apply("lshift", self, other)
def __rshift__(self, other: _Operand | float) -> _Operand:
return self.apply("rshift", self, other)
# logical
def __eq__(self, other: _Operand | float) -> _Operand: # type: ignore[override]
return self.apply("eq", self, other)
def __ne__(self, other: _Operand | float) -> _Operand: # type: ignore[override]
return self.apply("ne", self, other)
def __lt__(self, other: _Operand | float) -> _Operand:
return self.apply("lt", self, other)
def __le__(self, other: _Operand | float) -> _Operand:
return self.apply("le", self, other)
def __gt__(self, other: _Operand | float) -> _Operand:
return self.apply("gt", self, other)
def __ge__(self, other: _Operand | float) -> _Operand:
return self.apply("ge", self, other)
# conversions
def imagemath_int(self: _Operand) -> _Operand:
return _Operand(self.im.convert("I"))
def imagemath_float(self: _Operand) -> _Operand:
return _Operand(self.im.convert("F"))
# logical
def imagemath_equal(self: _Operand, other: _Operand | float | None) -> _Operand:
return self.apply("eq", self, other, mode="I")
def imagemath_notequal(self: _Operand, other: _Operand | float | None) -> _Operand:
return self.apply("ne", self, other, mode="I")
def imagemath_min(self: _Operand, other: _Operand | float | None) -> _Operand:
return self.apply("min", self, other)
def imagemath_max(self: _Operand, other: _Operand | float | None) -> _Operand:
return self.apply("max", self, other)
def imagemath_convert(self: _Operand, mode: str) -> _Operand:
return _Operand(self.im.convert(mode))
ops = {
"int": imagemath_int,
"float": imagemath_float,
"equal": imagemath_equal,
"notequal": imagemath_notequal,
"min": imagemath_min,
"max": imagemath_max,
"convert": imagemath_convert,
}
def lambda_eval(
expression: Callable[[dict[str, Any]], Any],
options: dict[str, Any] = {},
**kw: Any,
) -> Any:
"""
Returns the result of an image function.
:py:mod:`~PIL.ImageMath` only supports single-layer images. To process multi-band
images, use the :py:meth:`~PIL.Image.Image.split` method or
:py:func:`~PIL.Image.merge` function.
:param expression: A function that receives a dictionary.
:param options: Values to add to the function's dictionary. Deprecated.
You can instead use one or more keyword arguments.
:param **kw: Values to add to the function's dictionary.
:return: The expression result. This is usually an image object, but can
also be an integer, a floating point value, or a pixel tuple,
depending on the expression.
"""
if options:
deprecate(
"ImageMath.lambda_eval options",
12,
"ImageMath.lambda_eval keyword arguments",
)
args: dict[str, Any] = ops.copy()
args.update(options)
args.update(kw)
for k, v in args.items():
if isinstance(v, Image.Image):
args[k] = _Operand(v)
out = expression(args)
try:
return out.im
except AttributeError:
return out
def unsafe_eval(
expression: str,
options: dict[str, Any] = {},
**kw: Any,
) -> Any:
"""
Evaluates an image expression. This uses Python's ``eval()`` function to process
the expression string, and carries the security risks of doing so. It is not
recommended to process expressions without considering this.
:py:meth:`~lambda_eval` is a more secure alternative.
:py:mod:`~PIL.ImageMath` only supports single-layer images. To process multi-band
images, use the :py:meth:`~PIL.Image.Image.split` method or
:py:func:`~PIL.Image.merge` function.
:param expression: A string containing a Python-style expression.
:param options: Values to add to the evaluation context. Deprecated.
You can instead use one or more keyword arguments.
:param **kw: Values to add to the evaluation context.
:return: The evaluated expression. This is usually an image object, but can
also be an integer, a floating point value, or a pixel tuple,
depending on the expression.
"""
if options:
deprecate(
"ImageMath.unsafe_eval options",
12,
"ImageMath.unsafe_eval keyword arguments",
)
# build execution namespace
args: dict[str, Any] = ops.copy()
for k in list(options.keys()) + list(kw.keys()):
if "__" in k or hasattr(builtins, k):
msg = f"'{k}' not allowed"
raise ValueError(msg)
args.update(options)
args.update(kw)
for k, v in args.items():
if isinstance(v, Image.Image):
args[k] = _Operand(v)
compiled_code = compile(expression, "<string>", "eval")
def scan(code: CodeType) -> None:
for const in code.co_consts:
if type(const) is type(compiled_code):
scan(const)
for name in code.co_names:
if name not in args and name != "abs":
msg = f"'{name}' not allowed"
raise ValueError(msg)
scan(compiled_code)
out = builtins.eval(expression, {"__builtins": {"abs": abs}}, args)
try:
return out.im
except AttributeError:
return out
def eval(
expression: str,
_dict: dict[str, Any] = {},
**kw: Any,
) -> Any:
"""
Evaluates an image expression.
Deprecated. Use lambda_eval() or unsafe_eval() instead.
:param expression: A string containing a Python-style expression.
:param _dict: Values to add to the evaluation context. You
can either use a dictionary, or one or more keyword
arguments.
:return: The evaluated expression. This is usually an image object, but can
also be an integer, a floating point value, or a pixel tuple,
depending on the expression.
.. deprecated:: 10.3.0
"""
deprecate(
"ImageMath.eval",
12,
"ImageMath.lambda_eval or ImageMath.unsafe_eval",
)
return unsafe_eval(expression, _dict, **kw)

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#
# The Python Imaging Library.
# $Id$
#
# standard mode descriptors
#
# History:
# 2006-03-20 fl Added
#
# Copyright (c) 2006 by Secret Labs AB.
# Copyright (c) 2006 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import sys
from functools import lru_cache
from typing import NamedTuple
from ._deprecate import deprecate
class ModeDescriptor(NamedTuple):
"""Wrapper for mode strings."""
mode: str
bands: tuple[str, ...]
basemode: str
basetype: str
typestr: str
def __str__(self) -> str:
return self.mode
@lru_cache
def getmode(mode: str) -> ModeDescriptor:
"""Gets a mode descriptor for the given mode."""
endian = "<" if sys.byteorder == "little" else ">"
modes = {
# core modes
# Bits need to be extended to bytes
"1": ("L", "L", ("1",), "|b1"),
"L": ("L", "L", ("L",), "|u1"),
"I": ("L", "I", ("I",), f"{endian}i4"),
"F": ("L", "F", ("F",), f"{endian}f4"),
"P": ("P", "L", ("P",), "|u1"),
"RGB": ("RGB", "L", ("R", "G", "B"), "|u1"),
"RGBX": ("RGB", "L", ("R", "G", "B", "X"), "|u1"),
"RGBA": ("RGB", "L", ("R", "G", "B", "A"), "|u1"),
"CMYK": ("RGB", "L", ("C", "M", "Y", "K"), "|u1"),
"YCbCr": ("RGB", "L", ("Y", "Cb", "Cr"), "|u1"),
# UNDONE - unsigned |u1i1i1
"LAB": ("RGB", "L", ("L", "A", "B"), "|u1"),
"HSV": ("RGB", "L", ("H", "S", "V"), "|u1"),
# extra experimental modes
"RGBa": ("RGB", "L", ("R", "G", "B", "a"), "|u1"),
"BGR;15": ("RGB", "L", ("B", "G", "R"), "|u1"),
"BGR;16": ("RGB", "L", ("B", "G", "R"), "|u1"),
"BGR;24": ("RGB", "L", ("B", "G", "R"), "|u1"),
"LA": ("L", "L", ("L", "A"), "|u1"),
"La": ("L", "L", ("L", "a"), "|u1"),
"PA": ("RGB", "L", ("P", "A"), "|u1"),
}
if mode in modes:
if mode in ("BGR;15", "BGR;16", "BGR;24"):
deprecate(mode, 12)
base_mode, base_type, bands, type_str = modes[mode]
return ModeDescriptor(mode, bands, base_mode, base_type, type_str)
mapping_modes = {
# I;16 == I;16L, and I;32 == I;32L
"I;16": "<u2",
"I;16S": "<i2",
"I;16L": "<u2",
"I;16LS": "<i2",
"I;16B": ">u2",
"I;16BS": ">i2",
"I;16N": f"{endian}u2",
"I;16NS": f"{endian}i2",
"I;32": "<u4",
"I;32B": ">u4",
"I;32L": "<u4",
"I;32S": "<i4",
"I;32BS": ">i4",
"I;32LS": "<i4",
}
type_str = mapping_modes[mode]
return ModeDescriptor(mode, ("I",), "L", "L", type_str)

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# A binary morphology add-on for the Python Imaging Library
#
# History:
# 2014-06-04 Initial version.
#
# Copyright (c) 2014 Dov Grobgeld <dov.grobgeld@gmail.com>
from __future__ import annotations
import re
from . import Image, _imagingmorph
LUT_SIZE = 1 << 9
# fmt: off
ROTATION_MATRIX = [
6, 3, 0,
7, 4, 1,
8, 5, 2,
]
MIRROR_MATRIX = [
2, 1, 0,
5, 4, 3,
8, 7, 6,
]
# fmt: on
class LutBuilder:
"""A class for building a MorphLut from a descriptive language
The input patterns is a list of a strings sequences like these::
4:(...
.1.
111)->1
(whitespaces including linebreaks are ignored). The option 4
describes a series of symmetry operations (in this case a
4-rotation), the pattern is described by:
- . or X - Ignore
- 1 - Pixel is on
- 0 - Pixel is off
The result of the operation is described after "->" string.
The default is to return the current pixel value, which is
returned if no other match is found.
Operations:
- 4 - 4 way rotation
- N - Negate
- 1 - Dummy op for no other operation (an op must always be given)
- M - Mirroring
Example::
lb = LutBuilder(patterns = ["4:(... .1. 111)->1"])
lut = lb.build_lut()
"""
def __init__(
self, patterns: list[str] | None = None, op_name: str | None = None
) -> None:
if patterns is not None:
self.patterns = patterns
else:
self.patterns = []
self.lut: bytearray | None = None
if op_name is not None:
known_patterns = {
"corner": ["1:(... ... ...)->0", "4:(00. 01. ...)->1"],
"dilation4": ["4:(... .0. .1.)->1"],
"dilation8": ["4:(... .0. .1.)->1", "4:(... .0. ..1)->1"],
"erosion4": ["4:(... .1. .0.)->0"],
"erosion8": ["4:(... .1. .0.)->0", "4:(... .1. ..0)->0"],
"edge": [
"1:(... ... ...)->0",
"4:(.0. .1. ...)->1",
"4:(01. .1. ...)->1",
],
}
if op_name not in known_patterns:
msg = f"Unknown pattern {op_name}!"
raise Exception(msg)
self.patterns = known_patterns[op_name]
def add_patterns(self, patterns: list[str]) -> None:
self.patterns += patterns
def build_default_lut(self) -> None:
symbols = [0, 1]
m = 1 << 4 # pos of current pixel
self.lut = bytearray(symbols[(i & m) > 0] for i in range(LUT_SIZE))
def get_lut(self) -> bytearray | None:
return self.lut
def _string_permute(self, pattern: str, permutation: list[int]) -> str:
"""string_permute takes a pattern and a permutation and returns the
string permuted according to the permutation list.
"""
assert len(permutation) == 9
return "".join(pattern[p] for p in permutation)
def _pattern_permute(
self, basic_pattern: str, options: str, basic_result: int
) -> list[tuple[str, int]]:
"""pattern_permute takes a basic pattern and its result and clones
the pattern according to the modifications described in the $options
parameter. It returns a list of all cloned patterns."""
patterns = [(basic_pattern, basic_result)]
# rotations
if "4" in options:
res = patterns[-1][1]
for i in range(4):
patterns.append(
(self._string_permute(patterns[-1][0], ROTATION_MATRIX), res)
)
# mirror
if "M" in options:
n = len(patterns)
for pattern, res in patterns[:n]:
patterns.append((self._string_permute(pattern, MIRROR_MATRIX), res))
# negate
if "N" in options:
n = len(patterns)
for pattern, res in patterns[:n]:
# Swap 0 and 1
pattern = pattern.replace("0", "Z").replace("1", "0").replace("Z", "1")
res = 1 - int(res)
patterns.append((pattern, res))
return patterns
def build_lut(self) -> bytearray:
"""Compile all patterns into a morphology lut.
TBD :Build based on (file) morphlut:modify_lut
"""
self.build_default_lut()
assert self.lut is not None
patterns = []
# Parse and create symmetries of the patterns strings
for p in self.patterns:
m = re.search(r"(\w*):?\s*\((.+?)\)\s*->\s*(\d)", p.replace("\n", ""))
if not m:
msg = 'Syntax error in pattern "' + p + '"'
raise Exception(msg)
options = m.group(1)
pattern = m.group(2)
result = int(m.group(3))
# Get rid of spaces
pattern = pattern.replace(" ", "").replace("\n", "")
patterns += self._pattern_permute(pattern, options, result)
# compile the patterns into regular expressions for speed
compiled_patterns = []
for pattern in patterns:
p = pattern[0].replace(".", "X").replace("X", "[01]")
compiled_patterns.append((re.compile(p), pattern[1]))
# Step through table and find patterns that match.
# Note that all the patterns are searched. The last one
# caught overrides
for i in range(LUT_SIZE):
# Build the bit pattern
bitpattern = bin(i)[2:]
bitpattern = ("0" * (9 - len(bitpattern)) + bitpattern)[::-1]
for pattern, r in compiled_patterns:
if pattern.match(bitpattern):
self.lut[i] = [0, 1][r]
return self.lut
class MorphOp:
"""A class for binary morphological operators"""
def __init__(
self,
lut: bytearray | None = None,
op_name: str | None = None,
patterns: list[str] | None = None,
) -> None:
"""Create a binary morphological operator"""
self.lut = lut
if op_name is not None:
self.lut = LutBuilder(op_name=op_name).build_lut()
elif patterns is not None:
self.lut = LutBuilder(patterns=patterns).build_lut()
def apply(self, image: Image.Image) -> tuple[int, Image.Image]:
"""Run a single morphological operation on an image
Returns a tuple of the number of changed pixels and the
morphed image"""
if self.lut is None:
msg = "No operator loaded"
raise Exception(msg)
if image.mode != "L":
msg = "Image mode must be L"
raise ValueError(msg)
outimage = Image.new(image.mode, image.size, None)
count = _imagingmorph.apply(bytes(self.lut), image.getim(), outimage.getim())
return count, outimage
def match(self, image: Image.Image) -> list[tuple[int, int]]:
"""Get a list of coordinates matching the morphological operation on
an image.
Returns a list of tuples of (x,y) coordinates
of all matching pixels. See :ref:`coordinate-system`."""
if self.lut is None:
msg = "No operator loaded"
raise Exception(msg)
if image.mode != "L":
msg = "Image mode must be L"
raise ValueError(msg)
return _imagingmorph.match(bytes(self.lut), image.getim())
def get_on_pixels(self, image: Image.Image) -> list[tuple[int, int]]:
"""Get a list of all turned on pixels in a binary image
Returns a list of tuples of (x,y) coordinates
of all matching pixels. See :ref:`coordinate-system`."""
if image.mode != "L":
msg = "Image mode must be L"
raise ValueError(msg)
return _imagingmorph.get_on_pixels(image.getim())
def load_lut(self, filename: str) -> None:
"""Load an operator from an mrl file"""
with open(filename, "rb") as f:
self.lut = bytearray(f.read())
if len(self.lut) != LUT_SIZE:
self.lut = None
msg = "Wrong size operator file!"
raise Exception(msg)
def save_lut(self, filename: str) -> None:
"""Save an operator to an mrl file"""
if self.lut is None:
msg = "No operator loaded"
raise Exception(msg)
with open(filename, "wb") as f:
f.write(self.lut)
def set_lut(self, lut: bytearray | None) -> None:
"""Set the lut from an external source"""
self.lut = lut

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#
# The Python Imaging Library.
# $Id$
#
# standard image operations
#
# History:
# 2001-10-20 fl Created
# 2001-10-23 fl Added autocontrast operator
# 2001-12-18 fl Added Kevin's fit operator
# 2004-03-14 fl Fixed potential division by zero in equalize
# 2005-05-05 fl Fixed equalize for low number of values
#
# Copyright (c) 2001-2004 by Secret Labs AB
# Copyright (c) 2001-2004 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import functools
import operator
import re
from collections.abc import Sequence
from typing import Protocol, cast
from . import ExifTags, Image, ImagePalette
#
# helpers
def _border(border: int | tuple[int, ...]) -> tuple[int, int, int, int]:
if isinstance(border, tuple):
if len(border) == 2:
left, top = right, bottom = border
elif len(border) == 4:
left, top, right, bottom = border
else:
left = top = right = bottom = border
return left, top, right, bottom
def _color(color: str | int | tuple[int, ...], mode: str) -> int | tuple[int, ...]:
if isinstance(color, str):
from . import ImageColor
color = ImageColor.getcolor(color, mode)
return color
def _lut(image: Image.Image, lut: list[int]) -> Image.Image:
if image.mode == "P":
# FIXME: apply to lookup table, not image data
msg = "mode P support coming soon"
raise NotImplementedError(msg)
elif image.mode in ("L", "RGB"):
if image.mode == "RGB" and len(lut) == 256:
lut = lut + lut + lut
return image.point(lut)
else:
msg = f"not supported for mode {image.mode}"
raise OSError(msg)
#
# actions
def autocontrast(
image: Image.Image,
cutoff: float | tuple[float, float] = 0,
ignore: int | Sequence[int] | None = None,
mask: Image.Image | None = None,
preserve_tone: bool = False,
) -> Image.Image:
"""
Maximize (normalize) image contrast. This function calculates a
histogram of the input image (or mask region), removes ``cutoff`` percent of the
lightest and darkest pixels from the histogram, and remaps the image
so that the darkest pixel becomes black (0), and the lightest
becomes white (255).
:param image: The image to process.
:param cutoff: The percent to cut off from the histogram on the low and
high ends. Either a tuple of (low, high), or a single
number for both.
:param ignore: The background pixel value (use None for no background).
:param mask: Histogram used in contrast operation is computed using pixels
within the mask. If no mask is given the entire image is used
for histogram computation.
:param preserve_tone: Preserve image tone in Photoshop-like style autocontrast.
.. versionadded:: 8.2.0
:return: An image.
"""
if preserve_tone:
histogram = image.convert("L").histogram(mask)
else:
histogram = image.histogram(mask)
lut = []
for layer in range(0, len(histogram), 256):
h = histogram[layer : layer + 256]
if ignore is not None:
# get rid of outliers
if isinstance(ignore, int):
h[ignore] = 0
else:
for ix in ignore:
h[ix] = 0
if cutoff:
# cut off pixels from both ends of the histogram
if not isinstance(cutoff, tuple):
cutoff = (cutoff, cutoff)
# get number of pixels
n = 0
for ix in range(256):
n = n + h[ix]
# remove cutoff% pixels from the low end
cut = int(n * cutoff[0] // 100)
for lo in range(256):
if cut > h[lo]:
cut = cut - h[lo]
h[lo] = 0
else:
h[lo] -= cut
cut = 0
if cut <= 0:
break
# remove cutoff% samples from the high end
cut = int(n * cutoff[1] // 100)
for hi in range(255, -1, -1):
if cut > h[hi]:
cut = cut - h[hi]
h[hi] = 0
else:
h[hi] -= cut
cut = 0
if cut <= 0:
break
# find lowest/highest samples after preprocessing
for lo in range(256):
if h[lo]:
break
for hi in range(255, -1, -1):
if h[hi]:
break
if hi <= lo:
# don't bother
lut.extend(list(range(256)))
else:
scale = 255.0 / (hi - lo)
offset = -lo * scale
for ix in range(256):
ix = int(ix * scale + offset)
if ix < 0:
ix = 0
elif ix > 255:
ix = 255
lut.append(ix)
return _lut(image, lut)
def colorize(
image: Image.Image,
black: str | tuple[int, ...],
white: str | tuple[int, ...],
mid: str | int | tuple[int, ...] | None = None,
blackpoint: int = 0,
whitepoint: int = 255,
midpoint: int = 127,
) -> Image.Image:
"""
Colorize grayscale image.
This function calculates a color wedge which maps all black pixels in
the source image to the first color and all white pixels to the
second color. If ``mid`` is specified, it uses three-color mapping.
The ``black`` and ``white`` arguments should be RGB tuples or color names;
optionally you can use three-color mapping by also specifying ``mid``.
Mapping positions for any of the colors can be specified
(e.g. ``blackpoint``), where these parameters are the integer
value corresponding to where the corresponding color should be mapped.
These parameters must have logical order, such that
``blackpoint <= midpoint <= whitepoint`` (if ``mid`` is specified).
:param image: The image to colorize.
:param black: The color to use for black input pixels.
:param white: The color to use for white input pixels.
:param mid: The color to use for midtone input pixels.
:param blackpoint: an int value [0, 255] for the black mapping.
:param whitepoint: an int value [0, 255] for the white mapping.
:param midpoint: an int value [0, 255] for the midtone mapping.
:return: An image.
"""
# Initial asserts
assert image.mode == "L"
if mid is None:
assert 0 <= blackpoint <= whitepoint <= 255
else:
assert 0 <= blackpoint <= midpoint <= whitepoint <= 255
# Define colors from arguments
rgb_black = cast(Sequence[int], _color(black, "RGB"))
rgb_white = cast(Sequence[int], _color(white, "RGB"))
rgb_mid = cast(Sequence[int], _color(mid, "RGB")) if mid is not None else None
# Empty lists for the mapping
red = []
green = []
blue = []
# Create the low-end values
for i in range(0, blackpoint):
red.append(rgb_black[0])
green.append(rgb_black[1])
blue.append(rgb_black[2])
# Create the mapping (2-color)
if rgb_mid is None:
range_map = range(0, whitepoint - blackpoint)
for i in range_map:
red.append(
rgb_black[0] + i * (rgb_white[0] - rgb_black[0]) // len(range_map)
)
green.append(
rgb_black[1] + i * (rgb_white[1] - rgb_black[1]) // len(range_map)
)
blue.append(
rgb_black[2] + i * (rgb_white[2] - rgb_black[2]) // len(range_map)
)
# Create the mapping (3-color)
else:
range_map1 = range(0, midpoint - blackpoint)
range_map2 = range(0, whitepoint - midpoint)
for i in range_map1:
red.append(
rgb_black[0] + i * (rgb_mid[0] - rgb_black[0]) // len(range_map1)
)
green.append(
rgb_black[1] + i * (rgb_mid[1] - rgb_black[1]) // len(range_map1)
)
blue.append(
rgb_black[2] + i * (rgb_mid[2] - rgb_black[2]) // len(range_map1)
)
for i in range_map2:
red.append(rgb_mid[0] + i * (rgb_white[0] - rgb_mid[0]) // len(range_map2))
green.append(
rgb_mid[1] + i * (rgb_white[1] - rgb_mid[1]) // len(range_map2)
)
blue.append(rgb_mid[2] + i * (rgb_white[2] - rgb_mid[2]) // len(range_map2))
# Create the high-end values
for i in range(0, 256 - whitepoint):
red.append(rgb_white[0])
green.append(rgb_white[1])
blue.append(rgb_white[2])
# Return converted image
image = image.convert("RGB")
return _lut(image, red + green + blue)
def contain(
image: Image.Image, size: tuple[int, int], method: int = Image.Resampling.BICUBIC
) -> Image.Image:
"""
Returns a resized version of the image, set to the maximum width and height
within the requested size, while maintaining the original aspect ratio.
:param image: The image to resize.
:param size: The requested output size in pixels, given as a
(width, height) tuple.
:param method: Resampling method to use. Default is
:py:attr:`~PIL.Image.Resampling.BICUBIC`.
See :ref:`concept-filters`.
:return: An image.
"""
im_ratio = image.width / image.height
dest_ratio = size[0] / size[1]
if im_ratio != dest_ratio:
if im_ratio > dest_ratio:
new_height = round(image.height / image.width * size[0])
if new_height != size[1]:
size = (size[0], new_height)
else:
new_width = round(image.width / image.height * size[1])
if new_width != size[0]:
size = (new_width, size[1])
return image.resize(size, resample=method)
def cover(
image: Image.Image, size: tuple[int, int], method: int = Image.Resampling.BICUBIC
) -> Image.Image:
"""
Returns a resized version of the image, so that the requested size is
covered, while maintaining the original aspect ratio.
:param image: The image to resize.
:param size: The requested output size in pixels, given as a
(width, height) tuple.
:param method: Resampling method to use. Default is
:py:attr:`~PIL.Image.Resampling.BICUBIC`.
See :ref:`concept-filters`.
:return: An image.
"""
im_ratio = image.width / image.height
dest_ratio = size[0] / size[1]
if im_ratio != dest_ratio:
if im_ratio < dest_ratio:
new_height = round(image.height / image.width * size[0])
if new_height != size[1]:
size = (size[0], new_height)
else:
new_width = round(image.width / image.height * size[1])
if new_width != size[0]:
size = (new_width, size[1])
return image.resize(size, resample=method)
def pad(
image: Image.Image,
size: tuple[int, int],
method: int = Image.Resampling.BICUBIC,
color: str | int | tuple[int, ...] | None = None,
centering: tuple[float, float] = (0.5, 0.5),
) -> Image.Image:
"""
Returns a resized and padded version of the image, expanded to fill the
requested aspect ratio and size.
:param image: The image to resize and crop.
:param size: The requested output size in pixels, given as a
(width, height) tuple.
:param method: Resampling method to use. Default is
:py:attr:`~PIL.Image.Resampling.BICUBIC`.
See :ref:`concept-filters`.
:param color: The background color of the padded image.
:param centering: Control the position of the original image within the
padded version.
(0.5, 0.5) will keep the image centered
(0, 0) will keep the image aligned to the top left
(1, 1) will keep the image aligned to the bottom
right
:return: An image.
"""
resized = contain(image, size, method)
if resized.size == size:
out = resized
else:
out = Image.new(image.mode, size, color)
if resized.palette:
palette = resized.getpalette()
if palette is not None:
out.putpalette(palette)
if resized.width != size[0]:
x = round((size[0] - resized.width) * max(0, min(centering[0], 1)))
out.paste(resized, (x, 0))
else:
y = round((size[1] - resized.height) * max(0, min(centering[1], 1)))
out.paste(resized, (0, y))
return out
def crop(image: Image.Image, border: int = 0) -> Image.Image:
"""
Remove border from image. The same amount of pixels are removed
from all four sides. This function works on all image modes.
.. seealso:: :py:meth:`~PIL.Image.Image.crop`
:param image: The image to crop.
:param border: The number of pixels to remove.
:return: An image.
"""
left, top, right, bottom = _border(border)
return image.crop((left, top, image.size[0] - right, image.size[1] - bottom))
def scale(
image: Image.Image, factor: float, resample: int = Image.Resampling.BICUBIC
) -> Image.Image:
"""
Returns a rescaled image by a specific factor given in parameter.
A factor greater than 1 expands the image, between 0 and 1 contracts the
image.
:param image: The image to rescale.
:param factor: The expansion factor, as a float.
:param resample: Resampling method to use. Default is
:py:attr:`~PIL.Image.Resampling.BICUBIC`.
See :ref:`concept-filters`.
:returns: An :py:class:`~PIL.Image.Image` object.
"""
if factor == 1:
return image.copy()
elif factor <= 0:
msg = "the factor must be greater than 0"
raise ValueError(msg)
else:
size = (round(factor * image.width), round(factor * image.height))
return image.resize(size, resample)
class SupportsGetMesh(Protocol):
"""
An object that supports the ``getmesh`` method, taking an image as an
argument, and returning a list of tuples. Each tuple contains two tuples,
the source box as a tuple of 4 integers, and a tuple of 8 integers for the
final quadrilateral, in order of top left, bottom left, bottom right, top
right.
"""
def getmesh(
self, image: Image.Image
) -> list[
tuple[tuple[int, int, int, int], tuple[int, int, int, int, int, int, int, int]]
]: ...
def deform(
image: Image.Image,
deformer: SupportsGetMesh,
resample: int = Image.Resampling.BILINEAR,
) -> Image.Image:
"""
Deform the image.
:param image: The image to deform.
:param deformer: A deformer object. Any object that implements a
``getmesh`` method can be used.
:param resample: An optional resampling filter. Same values possible as
in the PIL.Image.transform function.
:return: An image.
"""
return image.transform(
image.size, Image.Transform.MESH, deformer.getmesh(image), resample
)
def equalize(image: Image.Image, mask: Image.Image | None = None) -> Image.Image:
"""
Equalize the image histogram. This function applies a non-linear
mapping to the input image, in order to create a uniform
distribution of grayscale values in the output image.
:param image: The image to equalize.
:param mask: An optional mask. If given, only the pixels selected by
the mask are included in the analysis.
:return: An image.
"""
if image.mode == "P":
image = image.convert("RGB")
h = image.histogram(mask)
lut = []
for b in range(0, len(h), 256):
histo = [_f for _f in h[b : b + 256] if _f]
if len(histo) <= 1:
lut.extend(list(range(256)))
else:
step = (functools.reduce(operator.add, histo) - histo[-1]) // 255
if not step:
lut.extend(list(range(256)))
else:
n = step // 2
for i in range(256):
lut.append(n // step)
n = n + h[i + b]
return _lut(image, lut)
def expand(
image: Image.Image,
border: int | tuple[int, ...] = 0,
fill: str | int | tuple[int, ...] = 0,
) -> Image.Image:
"""
Add border to the image
:param image: The image to expand.
:param border: Border width, in pixels.
:param fill: Pixel fill value (a color value). Default is 0 (black).
:return: An image.
"""
left, top, right, bottom = _border(border)
width = left + image.size[0] + right
height = top + image.size[1] + bottom
color = _color(fill, image.mode)
if image.palette:
palette = ImagePalette.ImagePalette(palette=image.getpalette())
if isinstance(color, tuple) and (len(color) == 3 or len(color) == 4):
color = palette.getcolor(color)
else:
palette = None
out = Image.new(image.mode, (width, height), color)
if palette:
out.putpalette(palette.palette)
out.paste(image, (left, top))
return out
def fit(
image: Image.Image,
size: tuple[int, int],
method: int = Image.Resampling.BICUBIC,
bleed: float = 0.0,
centering: tuple[float, float] = (0.5, 0.5),
) -> Image.Image:
"""
Returns a resized and cropped version of the image, cropped to the
requested aspect ratio and size.
This function was contributed by Kevin Cazabon.
:param image: The image to resize and crop.
:param size: The requested output size in pixels, given as a
(width, height) tuple.
:param method: Resampling method to use. Default is
:py:attr:`~PIL.Image.Resampling.BICUBIC`.
See :ref:`concept-filters`.
:param bleed: Remove a border around the outside of the image from all
four edges. The value is a decimal percentage (use 0.01 for
one percent). The default value is 0 (no border).
Cannot be greater than or equal to 0.5.
:param centering: Control the cropping position. Use (0.5, 0.5) for
center cropping (e.g. if cropping the width, take 50% off
of the left side, and therefore 50% off the right side).
(0.0, 0.0) will crop from the top left corner (i.e. if
cropping the width, take all of the crop off of the right
side, and if cropping the height, take all of it off the
bottom). (1.0, 0.0) will crop from the bottom left
corner, etc. (i.e. if cropping the width, take all of the
crop off the left side, and if cropping the height take
none from the top, and therefore all off the bottom).
:return: An image.
"""
# by Kevin Cazabon, Feb 17/2000
# kevin@cazabon.com
# https://www.cazabon.com
centering_x, centering_y = centering
if not 0.0 <= centering_x <= 1.0:
centering_x = 0.5
if not 0.0 <= centering_y <= 1.0:
centering_y = 0.5
if not 0.0 <= bleed < 0.5:
bleed = 0.0
# calculate the area to use for resizing and cropping, subtracting
# the 'bleed' around the edges
# number of pixels to trim off on Top and Bottom, Left and Right
bleed_pixels = (bleed * image.size[0], bleed * image.size[1])
live_size = (
image.size[0] - bleed_pixels[0] * 2,
image.size[1] - bleed_pixels[1] * 2,
)
# calculate the aspect ratio of the live_size
live_size_ratio = live_size[0] / live_size[1]
# calculate the aspect ratio of the output image
output_ratio = size[0] / size[1]
# figure out if the sides or top/bottom will be cropped off
if live_size_ratio == output_ratio:
# live_size is already the needed ratio
crop_width = live_size[0]
crop_height = live_size[1]
elif live_size_ratio >= output_ratio:
# live_size is wider than what's needed, crop the sides
crop_width = output_ratio * live_size[1]
crop_height = live_size[1]
else:
# live_size is taller than what's needed, crop the top and bottom
crop_width = live_size[0]
crop_height = live_size[0] / output_ratio
# make the crop
crop_left = bleed_pixels[0] + (live_size[0] - crop_width) * centering_x
crop_top = bleed_pixels[1] + (live_size[1] - crop_height) * centering_y
crop = (crop_left, crop_top, crop_left + crop_width, crop_top + crop_height)
# resize the image and return it
return image.resize(size, method, box=crop)
def flip(image: Image.Image) -> Image.Image:
"""
Flip the image vertically (top to bottom).
:param image: The image to flip.
:return: An image.
"""
return image.transpose(Image.Transpose.FLIP_TOP_BOTTOM)
def grayscale(image: Image.Image) -> Image.Image:
"""
Convert the image to grayscale.
:param image: The image to convert.
:return: An image.
"""
return image.convert("L")
def invert(image: Image.Image) -> Image.Image:
"""
Invert (negate) the image.
:param image: The image to invert.
:return: An image.
"""
lut = list(range(255, -1, -1))
return image.point(lut) if image.mode == "1" else _lut(image, lut)
def mirror(image: Image.Image) -> Image.Image:
"""
Flip image horizontally (left to right).
:param image: The image to mirror.
:return: An image.
"""
return image.transpose(Image.Transpose.FLIP_LEFT_RIGHT)
def posterize(image: Image.Image, bits: int) -> Image.Image:
"""
Reduce the number of bits for each color channel.
:param image: The image to posterize.
:param bits: The number of bits to keep for each channel (1-8).
:return: An image.
"""
mask = ~(2 ** (8 - bits) - 1)
lut = [i & mask for i in range(256)]
return _lut(image, lut)
def solarize(image: Image.Image, threshold: int = 128) -> Image.Image:
"""
Invert all pixel values above a threshold.
:param image: The image to solarize.
:param threshold: All pixels above this grayscale level are inverted.
:return: An image.
"""
lut = []
for i in range(256):
if i < threshold:
lut.append(i)
else:
lut.append(255 - i)
return _lut(image, lut)
def exif_transpose(image: Image.Image, *, in_place: bool = False) -> Image.Image | None:
"""
If an image has an EXIF Orientation tag, other than 1, transpose the image
accordingly, and remove the orientation data.
:param image: The image to transpose.
:param in_place: Boolean. Keyword-only argument.
If ``True``, the original image is modified in-place, and ``None`` is returned.
If ``False`` (default), a new :py:class:`~PIL.Image.Image` object is returned
with the transposition applied. If there is no transposition, a copy of the
image will be returned.
"""
image.load()
image_exif = image.getexif()
orientation = image_exif.get(ExifTags.Base.Orientation, 1)
method = {
2: Image.Transpose.FLIP_LEFT_RIGHT,
3: Image.Transpose.ROTATE_180,
4: Image.Transpose.FLIP_TOP_BOTTOM,
5: Image.Transpose.TRANSPOSE,
6: Image.Transpose.ROTATE_270,
7: Image.Transpose.TRANSVERSE,
8: Image.Transpose.ROTATE_90,
}.get(orientation)
if method is not None:
transposed_image = image.transpose(method)
if in_place:
image.im = transposed_image.im
image._size = transposed_image._size
exif_image = image if in_place else transposed_image
exif = exif_image.getexif()
if ExifTags.Base.Orientation in exif:
del exif[ExifTags.Base.Orientation]
if "exif" in exif_image.info:
exif_image.info["exif"] = exif.tobytes()
elif "Raw profile type exif" in exif_image.info:
exif_image.info["Raw profile type exif"] = exif.tobytes().hex()
for key in ("XML:com.adobe.xmp", "xmp"):
if key in exif_image.info:
for pattern in (
r'tiff:Orientation="([0-9])"',
r"<tiff:Orientation>([0-9])</tiff:Orientation>",
):
value = exif_image.info[key]
exif_image.info[key] = (
re.sub(pattern, "", value)
if isinstance(value, str)
else re.sub(pattern.encode(), b"", value)
)
if not in_place:
return transposed_image
elif not in_place:
return image.copy()
return None

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#
# The Python Imaging Library.
# $Id$
#
# image palette object
#
# History:
# 1996-03-11 fl Rewritten.
# 1997-01-03 fl Up and running.
# 1997-08-23 fl Added load hack
# 2001-04-16 fl Fixed randint shadow bug in random()
#
# Copyright (c) 1997-2001 by Secret Labs AB
# Copyright (c) 1996-1997 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import array
from collections.abc import Sequence
from typing import IO, TYPE_CHECKING
from . import GimpGradientFile, GimpPaletteFile, ImageColor, PaletteFile
if TYPE_CHECKING:
from . import Image
class ImagePalette:
"""
Color palette for palette mapped images
:param mode: The mode to use for the palette. See:
:ref:`concept-modes`. Defaults to "RGB"
:param palette: An optional palette. If given, it must be a bytearray,
an array or a list of ints between 0-255. The list must consist of
all channels for one color followed by the next color (e.g. RGBRGBRGB).
Defaults to an empty palette.
"""
def __init__(
self,
mode: str = "RGB",
palette: Sequence[int] | bytes | bytearray | None = None,
) -> None:
self.mode = mode
self.rawmode: str | None = None # if set, palette contains raw data
self.palette = palette or bytearray()
self.dirty: int | None = None
@property
def palette(self) -> Sequence[int] | bytes | bytearray:
return self._palette
@palette.setter
def palette(self, palette: Sequence[int] | bytes | bytearray) -> None:
self._colors: dict[tuple[int, ...], int] | None = None
self._palette = palette
@property
def colors(self) -> dict[tuple[int, ...], int]:
if self._colors is None:
mode_len = len(self.mode)
self._colors = {}
for i in range(0, len(self.palette), mode_len):
color = tuple(self.palette[i : i + mode_len])
if color in self._colors:
continue
self._colors[color] = i // mode_len
return self._colors
@colors.setter
def colors(self, colors: dict[tuple[int, ...], int]) -> None:
self._colors = colors
def copy(self) -> ImagePalette:
new = ImagePalette()
new.mode = self.mode
new.rawmode = self.rawmode
if self.palette is not None:
new.palette = self.palette[:]
new.dirty = self.dirty
return new
def getdata(self) -> tuple[str, Sequence[int] | bytes | bytearray]:
"""
Get palette contents in format suitable for the low-level
``im.putpalette`` primitive.
.. warning:: This method is experimental.
"""
if self.rawmode:
return self.rawmode, self.palette
return self.mode, self.tobytes()
def tobytes(self) -> bytes:
"""Convert palette to bytes.
.. warning:: This method is experimental.
"""
if self.rawmode:
msg = "palette contains raw palette data"
raise ValueError(msg)
if isinstance(self.palette, bytes):
return self.palette
arr = array.array("B", self.palette)
return arr.tobytes()
# Declare tostring as an alias for tobytes
tostring = tobytes
def _new_color_index(
self, image: Image.Image | None = None, e: Exception | None = None
) -> int:
if not isinstance(self.palette, bytearray):
self._palette = bytearray(self.palette)
index = len(self.palette) // 3
special_colors: tuple[int | tuple[int, ...] | None, ...] = ()
if image:
special_colors = (
image.info.get("background"),
image.info.get("transparency"),
)
while index in special_colors:
index += 1
if index >= 256:
if image:
# Search for an unused index
for i, count in reversed(list(enumerate(image.histogram()))):
if count == 0 and i not in special_colors:
index = i
break
if index >= 256:
msg = "cannot allocate more than 256 colors"
raise ValueError(msg) from e
return index
def getcolor(
self,
color: tuple[int, ...],
image: Image.Image | None = None,
) -> int:
"""Given an rgb tuple, allocate palette entry.
.. warning:: This method is experimental.
"""
if self.rawmode:
msg = "palette contains raw palette data"
raise ValueError(msg)
if isinstance(color, tuple):
if self.mode == "RGB":
if len(color) == 4:
if color[3] != 255:
msg = "cannot add non-opaque RGBA color to RGB palette"
raise ValueError(msg)
color = color[:3]
elif self.mode == "RGBA":
if len(color) == 3:
color += (255,)
try:
return self.colors[color]
except KeyError as e:
# allocate new color slot
index = self._new_color_index(image, e)
assert isinstance(self._palette, bytearray)
self.colors[color] = index
if index * 3 < len(self.palette):
self._palette = (
self._palette[: index * 3]
+ bytes(color)
+ self._palette[index * 3 + 3 :]
)
else:
self._palette += bytes(color)
self.dirty = 1
return index
else:
msg = f"unknown color specifier: {repr(color)}" # type: ignore[unreachable]
raise ValueError(msg)
def save(self, fp: str | IO[str]) -> None:
"""Save palette to text file.
.. warning:: This method is experimental.
"""
if self.rawmode:
msg = "palette contains raw palette data"
raise ValueError(msg)
if isinstance(fp, str):
fp = open(fp, "w")
fp.write("# Palette\n")
fp.write(f"# Mode: {self.mode}\n")
for i in range(256):
fp.write(f"{i}")
for j in range(i * len(self.mode), (i + 1) * len(self.mode)):
try:
fp.write(f" {self.palette[j]}")
except IndexError:
fp.write(" 0")
fp.write("\n")
fp.close()
# --------------------------------------------------------------------
# Internal
def raw(rawmode: str, data: Sequence[int] | bytes | bytearray) -> ImagePalette:
palette = ImagePalette()
palette.rawmode = rawmode
palette.palette = data
palette.dirty = 1
return palette
# --------------------------------------------------------------------
# Factories
def make_linear_lut(black: int, white: float) -> list[int]:
if black == 0:
return [int(white * i // 255) for i in range(256)]
msg = "unavailable when black is non-zero"
raise NotImplementedError(msg) # FIXME
def make_gamma_lut(exp: float) -> list[int]:
return [int(((i / 255.0) ** exp) * 255.0 + 0.5) for i in range(256)]
def negative(mode: str = "RGB") -> ImagePalette:
palette = list(range(256 * len(mode)))
palette.reverse()
return ImagePalette(mode, [i // len(mode) for i in palette])
def random(mode: str = "RGB") -> ImagePalette:
from random import randint
palette = [randint(0, 255) for _ in range(256 * len(mode))]
return ImagePalette(mode, palette)
def sepia(white: str = "#fff0c0") -> ImagePalette:
bands = [make_linear_lut(0, band) for band in ImageColor.getrgb(white)]
return ImagePalette("RGB", [bands[i % 3][i // 3] for i in range(256 * 3)])
def wedge(mode: str = "RGB") -> ImagePalette:
palette = list(range(256 * len(mode)))
return ImagePalette(mode, [i // len(mode) for i in palette])
def load(filename: str) -> tuple[bytes, str]:
# FIXME: supports GIMP gradients only
with open(filename, "rb") as fp:
paletteHandlers: list[
type[
GimpPaletteFile.GimpPaletteFile
| GimpGradientFile.GimpGradientFile
| PaletteFile.PaletteFile
]
] = [
GimpPaletteFile.GimpPaletteFile,
GimpGradientFile.GimpGradientFile,
PaletteFile.PaletteFile,
]
for paletteHandler in paletteHandlers:
try:
fp.seek(0)
lut = paletteHandler(fp).getpalette()
if lut:
break
except (SyntaxError, ValueError):
pass
else:
msg = "cannot load palette"
raise OSError(msg)
return lut # data, rawmode

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#
# The Python Imaging Library
# $Id$
#
# path interface
#
# History:
# 1996-11-04 fl Created
# 2002-04-14 fl Added documentation stub class
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1996.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from . import Image
Path = Image.core.path

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#
# The Python Imaging Library.
# $Id$
#
# a simple Qt image interface.
#
# history:
# 2006-06-03 fl: created
# 2006-06-04 fl: inherit from QImage instead of wrapping it
# 2006-06-05 fl: removed toimage helper; move string support to ImageQt
# 2013-11-13 fl: add support for Qt5 (aurelien.ballier@cyclonit.com)
#
# Copyright (c) 2006 by Secret Labs AB
# Copyright (c) 2006 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import sys
from io import BytesIO
from typing import TYPE_CHECKING, Any, Callable, Union
from . import Image
from ._util import is_path
if TYPE_CHECKING:
import PyQt6
import PySide6
from . import ImageFile
QBuffer: type
QByteArray = Union[PyQt6.QtCore.QByteArray, PySide6.QtCore.QByteArray]
QIODevice = Union[PyQt6.QtCore.QIODevice, PySide6.QtCore.QIODevice]
QImage = Union[PyQt6.QtGui.QImage, PySide6.QtGui.QImage]
QPixmap = Union[PyQt6.QtGui.QPixmap, PySide6.QtGui.QPixmap]
qt_version: str | None
qt_versions = [
["6", "PyQt6"],
["side6", "PySide6"],
]
# If a version has already been imported, attempt it first
qt_versions.sort(key=lambda version: version[1] in sys.modules, reverse=True)
for version, qt_module in qt_versions:
try:
qRgba: Callable[[int, int, int, int], int]
if qt_module == "PyQt6":
from PyQt6.QtCore import QBuffer, QIODevice
from PyQt6.QtGui import QImage, QPixmap, qRgba
elif qt_module == "PySide6":
from PySide6.QtCore import QBuffer, QIODevice
from PySide6.QtGui import QImage, QPixmap, qRgba
except (ImportError, RuntimeError):
continue
qt_is_installed = True
qt_version = version
break
else:
qt_is_installed = False
qt_version = None
def rgb(r: int, g: int, b: int, a: int = 255) -> int:
"""(Internal) Turns an RGB color into a Qt compatible color integer."""
# use qRgb to pack the colors, and then turn the resulting long
# into a negative integer with the same bitpattern.
return qRgba(r, g, b, a) & 0xFFFFFFFF
def fromqimage(im: QImage | QPixmap) -> ImageFile.ImageFile:
"""
:param im: QImage or PIL ImageQt object
"""
buffer = QBuffer()
qt_openmode: object
if qt_version == "6":
try:
qt_openmode = getattr(QIODevice, "OpenModeFlag")
except AttributeError:
qt_openmode = getattr(QIODevice, "OpenMode")
else:
qt_openmode = QIODevice
buffer.open(getattr(qt_openmode, "ReadWrite"))
# preserve alpha channel with png
# otherwise ppm is more friendly with Image.open
if im.hasAlphaChannel():
im.save(buffer, "png")
else:
im.save(buffer, "ppm")
b = BytesIO()
b.write(buffer.data())
buffer.close()
b.seek(0)
return Image.open(b)
def fromqpixmap(im: QPixmap) -> ImageFile.ImageFile:
return fromqimage(im)
def align8to32(bytes: bytes, width: int, mode: str) -> bytes:
"""
converts each scanline of data from 8 bit to 32 bit aligned
"""
bits_per_pixel = {"1": 1, "L": 8, "P": 8, "I;16": 16}[mode]
# calculate bytes per line and the extra padding if needed
bits_per_line = bits_per_pixel * width
full_bytes_per_line, remaining_bits_per_line = divmod(bits_per_line, 8)
bytes_per_line = full_bytes_per_line + (1 if remaining_bits_per_line else 0)
extra_padding = -bytes_per_line % 4
# already 32 bit aligned by luck
if not extra_padding:
return bytes
new_data = [
bytes[i * bytes_per_line : (i + 1) * bytes_per_line] + b"\x00" * extra_padding
for i in range(len(bytes) // bytes_per_line)
]
return b"".join(new_data)
def _toqclass_helper(im: Image.Image | str | QByteArray) -> dict[str, Any]:
data = None
colortable = None
exclusive_fp = False
# handle filename, if given instead of image name
if hasattr(im, "toUtf8"):
# FIXME - is this really the best way to do this?
im = str(im.toUtf8(), "utf-8")
if is_path(im):
im = Image.open(im)
exclusive_fp = True
assert isinstance(im, Image.Image)
qt_format = getattr(QImage, "Format") if qt_version == "6" else QImage
if im.mode == "1":
format = getattr(qt_format, "Format_Mono")
elif im.mode == "L":
format = getattr(qt_format, "Format_Indexed8")
colortable = [rgb(i, i, i) for i in range(256)]
elif im.mode == "P":
format = getattr(qt_format, "Format_Indexed8")
palette = im.getpalette()
assert palette is not None
colortable = [rgb(*palette[i : i + 3]) for i in range(0, len(palette), 3)]
elif im.mode == "RGB":
# Populate the 4th channel with 255
im = im.convert("RGBA")
data = im.tobytes("raw", "BGRA")
format = getattr(qt_format, "Format_RGB32")
elif im.mode == "RGBA":
data = im.tobytes("raw", "BGRA")
format = getattr(qt_format, "Format_ARGB32")
elif im.mode == "I;16":
im = im.point(lambda i: i * 256)
format = getattr(qt_format, "Format_Grayscale16")
else:
if exclusive_fp:
im.close()
msg = f"unsupported image mode {repr(im.mode)}"
raise ValueError(msg)
size = im.size
__data = data or align8to32(im.tobytes(), size[0], im.mode)
if exclusive_fp:
im.close()
return {"data": __data, "size": size, "format": format, "colortable": colortable}
if qt_is_installed:
class ImageQt(QImage): # type: ignore[misc]
def __init__(self, im: Image.Image | str | QByteArray) -> None:
"""
An PIL image wrapper for Qt. This is a subclass of PyQt's QImage
class.
:param im: A PIL Image object, or a file name (given either as
Python string or a PyQt string object).
"""
im_data = _toqclass_helper(im)
# must keep a reference, or Qt will crash!
# All QImage constructors that take data operate on an existing
# buffer, so this buffer has to hang on for the life of the image.
# Fixes https://github.com/python-pillow/Pillow/issues/1370
self.__data = im_data["data"]
super().__init__(
self.__data,
im_data["size"][0],
im_data["size"][1],
im_data["format"],
)
if im_data["colortable"]:
self.setColorTable(im_data["colortable"])
def toqimage(im: Image.Image | str | QByteArray) -> ImageQt:
return ImageQt(im)
def toqpixmap(im: Image.Image | str | QByteArray) -> QPixmap:
qimage = toqimage(im)
return getattr(QPixmap, "fromImage")(qimage)

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#
# The Python Imaging Library.
# $Id$
#
# sequence support classes
#
# history:
# 1997-02-20 fl Created
#
# Copyright (c) 1997 by Secret Labs AB.
# Copyright (c) 1997 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
##
from __future__ import annotations
from typing import Callable
from . import Image
class Iterator:
"""
This class implements an iterator object that can be used to loop
over an image sequence.
You can use the ``[]`` operator to access elements by index. This operator
will raise an :py:exc:`IndexError` if you try to access a nonexistent
frame.
:param im: An image object.
"""
def __init__(self, im: Image.Image) -> None:
if not hasattr(im, "seek"):
msg = "im must have seek method"
raise AttributeError(msg)
self.im = im
self.position = getattr(self.im, "_min_frame", 0)
def __getitem__(self, ix: int) -> Image.Image:
try:
self.im.seek(ix)
return self.im
except EOFError as e:
msg = "end of sequence"
raise IndexError(msg) from e
def __iter__(self) -> Iterator:
return self
def __next__(self) -> Image.Image:
try:
self.im.seek(self.position)
self.position += 1
return self.im
except EOFError as e:
msg = "end of sequence"
raise StopIteration(msg) from e
def all_frames(
im: Image.Image | list[Image.Image],
func: Callable[[Image.Image], Image.Image] | None = None,
) -> list[Image.Image]:
"""
Applies a given function to all frames in an image or a list of images.
The frames are returned as a list of separate images.
:param im: An image, or a list of images.
:param func: The function to apply to all of the image frames.
:returns: A list of images.
"""
if not isinstance(im, list):
im = [im]
ims = []
for imSequence in im:
current = imSequence.tell()
ims += [im_frame.copy() for im_frame in Iterator(imSequence)]
imSequence.seek(current)
return [func(im) for im in ims] if func else ims

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#
# The Python Imaging Library.
# $Id$
#
# im.show() drivers
#
# History:
# 2008-04-06 fl Created
#
# Copyright (c) Secret Labs AB 2008.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import abc
import os
import shutil
import subprocess
import sys
from shlex import quote
from typing import Any
from . import Image
_viewers = []
def register(viewer: type[Viewer] | Viewer, order: int = 1) -> None:
"""
The :py:func:`register` function is used to register additional viewers::
from PIL import ImageShow
ImageShow.register(MyViewer()) # MyViewer will be used as a last resort
ImageShow.register(MySecondViewer(), 0) # MySecondViewer will be prioritised
ImageShow.register(ImageShow.XVViewer(), 0) # XVViewer will be prioritised
:param viewer: The viewer to be registered.
:param order:
Zero or a negative integer to prepend this viewer to the list,
a positive integer to append it.
"""
if isinstance(viewer, type) and issubclass(viewer, Viewer):
viewer = viewer()
if order > 0:
_viewers.append(viewer)
else:
_viewers.insert(0, viewer)
def show(image: Image.Image, title: str | None = None, **options: Any) -> bool:
r"""
Display a given image.
:param image: An image object.
:param title: Optional title. Not all viewers can display the title.
:param \**options: Additional viewer options.
:returns: ``True`` if a suitable viewer was found, ``False`` otherwise.
"""
for viewer in _viewers:
if viewer.show(image, title=title, **options):
return True
return False
class Viewer:
"""Base class for viewers."""
# main api
def show(self, image: Image.Image, **options: Any) -> int:
"""
The main function for displaying an image.
Converts the given image to the target format and displays it.
"""
if not (
image.mode in ("1", "RGBA")
or (self.format == "PNG" and image.mode in ("I;16", "LA"))
):
base = Image.getmodebase(image.mode)
if image.mode != base:
image = image.convert(base)
return self.show_image(image, **options)
# hook methods
format: str | None = None
"""The format to convert the image into."""
options: dict[str, Any] = {}
"""Additional options used to convert the image."""
def get_format(self, image: Image.Image) -> str | None:
"""Return format name, or ``None`` to save as PGM/PPM."""
return self.format
def get_command(self, file: str, **options: Any) -> str:
"""
Returns the command used to display the file.
Not implemented in the base class.
"""
msg = "unavailable in base viewer"
raise NotImplementedError(msg)
def save_image(self, image: Image.Image) -> str:
"""Save to temporary file and return filename."""
return image._dump(format=self.get_format(image), **self.options)
def show_image(self, image: Image.Image, **options: Any) -> int:
"""Display the given image."""
return self.show_file(self.save_image(image), **options)
def show_file(self, path: str, **options: Any) -> int:
"""
Display given file.
"""
if not os.path.exists(path):
raise FileNotFoundError
os.system(self.get_command(path, **options)) # nosec
return 1
# --------------------------------------------------------------------
class WindowsViewer(Viewer):
"""The default viewer on Windows is the default system application for PNG files."""
format = "PNG"
options = {"compress_level": 1, "save_all": True}
def get_command(self, file: str, **options: Any) -> str:
return (
f'start "Pillow" /WAIT "{file}" '
"&& ping -n 4 127.0.0.1 >NUL "
f'&& del /f "{file}"'
)
def show_file(self, path: str, **options: Any) -> int:
"""
Display given file.
"""
if not os.path.exists(path):
raise FileNotFoundError
subprocess.Popen(
self.get_command(path, **options),
shell=True,
creationflags=getattr(subprocess, "CREATE_NO_WINDOW"),
) # nosec
return 1
if sys.platform == "win32":
register(WindowsViewer)
class MacViewer(Viewer):
"""The default viewer on macOS using ``Preview.app``."""
format = "PNG"
options = {"compress_level": 1, "save_all": True}
def get_command(self, file: str, **options: Any) -> str:
# on darwin open returns immediately resulting in the temp
# file removal while app is opening
command = "open -a Preview.app"
command = f"({command} {quote(file)}; sleep 20; rm -f {quote(file)})&"
return command
def show_file(self, path: str, **options: Any) -> int:
"""
Display given file.
"""
if not os.path.exists(path):
raise FileNotFoundError
subprocess.call(["open", "-a", "Preview.app", path])
executable = sys.executable or shutil.which("python3")
if executable:
subprocess.Popen(
[
executable,
"-c",
"import os, sys, time; time.sleep(20); os.remove(sys.argv[1])",
path,
]
)
return 1
if sys.platform == "darwin":
register(MacViewer)
class UnixViewer(Viewer):
format = "PNG"
options = {"compress_level": 1, "save_all": True}
@abc.abstractmethod
def get_command_ex(self, file: str, **options: Any) -> tuple[str, str]:
pass
def get_command(self, file: str, **options: Any) -> str:
command = self.get_command_ex(file, **options)[0]
return f"{command} {quote(file)}"
class XDGViewer(UnixViewer):
"""
The freedesktop.org ``xdg-open`` command.
"""
def get_command_ex(self, file: str, **options: Any) -> tuple[str, str]:
command = executable = "xdg-open"
return command, executable
def show_file(self, path: str, **options: Any) -> int:
"""
Display given file.
"""
if not os.path.exists(path):
raise FileNotFoundError
subprocess.Popen(["xdg-open", path])
return 1
class DisplayViewer(UnixViewer):
"""
The ImageMagick ``display`` command.
This viewer supports the ``title`` parameter.
"""
def get_command_ex(
self, file: str, title: str | None = None, **options: Any
) -> tuple[str, str]:
command = executable = "display"
if title:
command += f" -title {quote(title)}"
return command, executable
def show_file(self, path: str, **options: Any) -> int:
"""
Display given file.
"""
if not os.path.exists(path):
raise FileNotFoundError
args = ["display"]
title = options.get("title")
if title:
args += ["-title", title]
args.append(path)
subprocess.Popen(args)
return 1
class GmDisplayViewer(UnixViewer):
"""The GraphicsMagick ``gm display`` command."""
def get_command_ex(self, file: str, **options: Any) -> tuple[str, str]:
executable = "gm"
command = "gm display"
return command, executable
def show_file(self, path: str, **options: Any) -> int:
"""
Display given file.
"""
if not os.path.exists(path):
raise FileNotFoundError
subprocess.Popen(["gm", "display", path])
return 1
class EogViewer(UnixViewer):
"""The GNOME Image Viewer ``eog`` command."""
def get_command_ex(self, file: str, **options: Any) -> tuple[str, str]:
executable = "eog"
command = "eog -n"
return command, executable
def show_file(self, path: str, **options: Any) -> int:
"""
Display given file.
"""
if not os.path.exists(path):
raise FileNotFoundError
subprocess.Popen(["eog", "-n", path])
return 1
class XVViewer(UnixViewer):
"""
The X Viewer ``xv`` command.
This viewer supports the ``title`` parameter.
"""
def get_command_ex(
self, file: str, title: str | None = None, **options: Any
) -> tuple[str, str]:
# note: xv is pretty outdated. most modern systems have
# imagemagick's display command instead.
command = executable = "xv"
if title:
command += f" -name {quote(title)}"
return command, executable
def show_file(self, path: str, **options: Any) -> int:
"""
Display given file.
"""
if not os.path.exists(path):
raise FileNotFoundError
args = ["xv"]
title = options.get("title")
if title:
args += ["-name", title]
args.append(path)
subprocess.Popen(args)
return 1
if sys.platform not in ("win32", "darwin"): # unixoids
if shutil.which("xdg-open"):
register(XDGViewer)
if shutil.which("display"):
register(DisplayViewer)
if shutil.which("gm"):
register(GmDisplayViewer)
if shutil.which("eog"):
register(EogViewer)
if shutil.which("xv"):
register(XVViewer)
class IPythonViewer(Viewer):
"""The viewer for IPython frontends."""
def show_image(self, image: Image.Image, **options: Any) -> int:
ipython_display(image)
return 1
try:
from IPython.display import display as ipython_display
except ImportError:
pass
else:
register(IPythonViewer)
if __name__ == "__main__":
if len(sys.argv) < 2:
print("Syntax: python3 ImageShow.py imagefile [title]")
sys.exit()
with Image.open(sys.argv[1]) as im:
print(show(im, *sys.argv[2:]))

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#
# The Python Imaging Library.
# $Id$
#
# global image statistics
#
# History:
# 1996-04-05 fl Created
# 1997-05-21 fl Added mask; added rms, var, stddev attributes
# 1997-08-05 fl Added median
# 1998-07-05 hk Fixed integer overflow error
#
# Notes:
# This class shows how to implement delayed evaluation of attributes.
# To get a certain value, simply access the corresponding attribute.
# The __getattr__ dispatcher takes care of the rest.
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1996-97.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import math
from functools import cached_property
from . import Image
class Stat:
def __init__(
self, image_or_list: Image.Image | list[int], mask: Image.Image | None = None
) -> None:
"""
Calculate statistics for the given image. If a mask is included,
only the regions covered by that mask are included in the
statistics. You can also pass in a previously calculated histogram.
:param image: A PIL image, or a precalculated histogram.
.. note::
For a PIL image, calculations rely on the
:py:meth:`~PIL.Image.Image.histogram` method. The pixel counts are
grouped into 256 bins, even if the image has more than 8 bits per
channel. So ``I`` and ``F`` mode images have a maximum ``mean``,
``median`` and ``rms`` of 255, and cannot have an ``extrema`` maximum
of more than 255.
:param mask: An optional mask.
"""
if isinstance(image_or_list, Image.Image):
self.h = image_or_list.histogram(mask)
elif isinstance(image_or_list, list):
self.h = image_or_list
else:
msg = "first argument must be image or list" # type: ignore[unreachable]
raise TypeError(msg)
self.bands = list(range(len(self.h) // 256))
@cached_property
def extrema(self) -> list[tuple[int, int]]:
"""
Min/max values for each band in the image.
.. note::
This relies on the :py:meth:`~PIL.Image.Image.histogram` method, and
simply returns the low and high bins used. This is correct for
images with 8 bits per channel, but fails for other modes such as
``I`` or ``F``. Instead, use :py:meth:`~PIL.Image.Image.getextrema` to
return per-band extrema for the image. This is more correct and
efficient because, for non-8-bit modes, the histogram method uses
:py:meth:`~PIL.Image.Image.getextrema` to determine the bins used.
"""
def minmax(histogram: list[int]) -> tuple[int, int]:
res_min, res_max = 255, 0
for i in range(256):
if histogram[i]:
res_min = i
break
for i in range(255, -1, -1):
if histogram[i]:
res_max = i
break
return res_min, res_max
return [minmax(self.h[i:]) for i in range(0, len(self.h), 256)]
@cached_property
def count(self) -> list[int]:
"""Total number of pixels for each band in the image."""
return [sum(self.h[i : i + 256]) for i in range(0, len(self.h), 256)]
@cached_property
def sum(self) -> list[float]:
"""Sum of all pixels for each band in the image."""
v = []
for i in range(0, len(self.h), 256):
layer_sum = 0.0
for j in range(256):
layer_sum += j * self.h[i + j]
v.append(layer_sum)
return v
@cached_property
def sum2(self) -> list[float]:
"""Squared sum of all pixels for each band in the image."""
v = []
for i in range(0, len(self.h), 256):
sum2 = 0.0
for j in range(256):
sum2 += (j**2) * float(self.h[i + j])
v.append(sum2)
return v
@cached_property
def mean(self) -> list[float]:
"""Average (arithmetic mean) pixel level for each band in the image."""
return [self.sum[i] / self.count[i] for i in self.bands]
@cached_property
def median(self) -> list[int]:
"""Median pixel level for each band in the image."""
v = []
for i in self.bands:
s = 0
half = self.count[i] // 2
b = i * 256
for j in range(256):
s = s + self.h[b + j]
if s > half:
break
v.append(j)
return v
@cached_property
def rms(self) -> list[float]:
"""RMS (root-mean-square) for each band in the image."""
return [math.sqrt(self.sum2[i] / self.count[i]) for i in self.bands]
@cached_property
def var(self) -> list[float]:
"""Variance for each band in the image."""
return [
(self.sum2[i] - (self.sum[i] ** 2.0) / self.count[i]) / self.count[i]
for i in self.bands
]
@cached_property
def stddev(self) -> list[float]:
"""Standard deviation for each band in the image."""
return [math.sqrt(self.var[i]) for i in self.bands]
Global = Stat # compatibility

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#
# The Python Imaging Library.
# $Id$
#
# a Tk display interface
#
# History:
# 96-04-08 fl Created
# 96-09-06 fl Added getimage method
# 96-11-01 fl Rewritten, removed image attribute and crop method
# 97-05-09 fl Use PyImagingPaste method instead of image type
# 97-05-12 fl Minor tweaks to match the IFUNC95 interface
# 97-05-17 fl Support the "pilbitmap" booster patch
# 97-06-05 fl Added file= and data= argument to image constructors
# 98-03-09 fl Added width and height methods to Image classes
# 98-07-02 fl Use default mode for "P" images without palette attribute
# 98-07-02 fl Explicitly destroy Tkinter image objects
# 99-07-24 fl Support multiple Tk interpreters (from Greg Couch)
# 99-07-26 fl Automatically hook into Tkinter (if possible)
# 99-08-15 fl Hook uses _imagingtk instead of _imaging
#
# Copyright (c) 1997-1999 by Secret Labs AB
# Copyright (c) 1996-1997 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import tkinter
from io import BytesIO
from typing import TYPE_CHECKING, Any, cast
from . import Image, ImageFile
if TYPE_CHECKING:
from ._typing import CapsuleType
# --------------------------------------------------------------------
# Check for Tkinter interface hooks
def _get_image_from_kw(kw: dict[str, Any]) -> ImageFile.ImageFile | None:
source = None
if "file" in kw:
source = kw.pop("file")
elif "data" in kw:
source = BytesIO(kw.pop("data"))
if not source:
return None
return Image.open(source)
def _pyimagingtkcall(
command: str, photo: PhotoImage | tkinter.PhotoImage, ptr: CapsuleType
) -> None:
tk = photo.tk
try:
tk.call(command, photo, repr(ptr))
except tkinter.TclError:
# activate Tkinter hook
# may raise an error if it cannot attach to Tkinter
from . import _imagingtk
_imagingtk.tkinit(tk.interpaddr())
tk.call(command, photo, repr(ptr))
# --------------------------------------------------------------------
# PhotoImage
class PhotoImage:
"""
A Tkinter-compatible photo image. This can be used
everywhere Tkinter expects an image object. If the image is an RGBA
image, pixels having alpha 0 are treated as transparent.
The constructor takes either a PIL image, or a mode and a size.
Alternatively, you can use the ``file`` or ``data`` options to initialize
the photo image object.
:param image: Either a PIL image, or a mode string. If a mode string is
used, a size must also be given.
:param size: If the first argument is a mode string, this defines the size
of the image.
:keyword file: A filename to load the image from (using
``Image.open(file)``).
:keyword data: An 8-bit string containing image data (as loaded from an
image file).
"""
def __init__(
self,
image: Image.Image | str | None = None,
size: tuple[int, int] | None = None,
**kw: Any,
) -> None:
# Tk compatibility: file or data
if image is None:
image = _get_image_from_kw(kw)
if image is None:
msg = "Image is required"
raise ValueError(msg)
elif isinstance(image, str):
mode = image
image = None
if size is None:
msg = "If first argument is mode, size is required"
raise ValueError(msg)
else:
# got an image instead of a mode
mode = image.mode
if mode == "P":
# palette mapped data
image.apply_transparency()
image.load()
mode = image.palette.mode if image.palette else "RGB"
size = image.size
kw["width"], kw["height"] = size
if mode not in ["1", "L", "RGB", "RGBA"]:
mode = Image.getmodebase(mode)
self.__mode = mode
self.__size = size
self.__photo = tkinter.PhotoImage(**kw)
self.tk = self.__photo.tk
if image:
self.paste(image)
def __del__(self) -> None:
try:
name = self.__photo.name
except AttributeError:
return
self.__photo.name = None
try:
self.__photo.tk.call("image", "delete", name)
except Exception:
pass # ignore internal errors
def __str__(self) -> str:
"""
Get the Tkinter photo image identifier. This method is automatically
called by Tkinter whenever a PhotoImage object is passed to a Tkinter
method.
:return: A Tkinter photo image identifier (a string).
"""
return str(self.__photo)
def width(self) -> int:
"""
Get the width of the image.
:return: The width, in pixels.
"""
return self.__size[0]
def height(self) -> int:
"""
Get the height of the image.
:return: The height, in pixels.
"""
return self.__size[1]
def paste(self, im: Image.Image) -> None:
"""
Paste a PIL image into the photo image. Note that this can
be very slow if the photo image is displayed.
:param im: A PIL image. The size must match the target region. If the
mode does not match, the image is converted to the mode of
the bitmap image.
"""
# convert to blittable
ptr = im.getim()
image = im.im
if not image.isblock() or im.mode != self.__mode:
block = Image.core.new_block(self.__mode, im.size)
image.convert2(block, image) # convert directly between buffers
ptr = block.ptr
_pyimagingtkcall("PyImagingPhoto", self.__photo, ptr)
# --------------------------------------------------------------------
# BitmapImage
class BitmapImage:
"""
A Tkinter-compatible bitmap image. This can be used everywhere Tkinter
expects an image object.
The given image must have mode "1". Pixels having value 0 are treated as
transparent. Options, if any, are passed on to Tkinter. The most commonly
used option is ``foreground``, which is used to specify the color for the
non-transparent parts. See the Tkinter documentation for information on
how to specify colours.
:param image: A PIL image.
"""
def __init__(self, image: Image.Image | None = None, **kw: Any) -> None:
# Tk compatibility: file or data
if image is None:
image = _get_image_from_kw(kw)
if image is None:
msg = "Image is required"
raise ValueError(msg)
self.__mode = image.mode
self.__size = image.size
self.__photo = tkinter.BitmapImage(data=image.tobitmap(), **kw)
def __del__(self) -> None:
try:
name = self.__photo.name
except AttributeError:
return
self.__photo.name = None
try:
self.__photo.tk.call("image", "delete", name)
except Exception:
pass # ignore internal errors
def width(self) -> int:
"""
Get the width of the image.
:return: The width, in pixels.
"""
return self.__size[0]
def height(self) -> int:
"""
Get the height of the image.
:return: The height, in pixels.
"""
return self.__size[1]
def __str__(self) -> str:
"""
Get the Tkinter bitmap image identifier. This method is automatically
called by Tkinter whenever a BitmapImage object is passed to a Tkinter
method.
:return: A Tkinter bitmap image identifier (a string).
"""
return str(self.__photo)
def getimage(photo: PhotoImage) -> Image.Image:
"""Copies the contents of a PhotoImage to a PIL image memory."""
im = Image.new("RGBA", (photo.width(), photo.height()))
_pyimagingtkcall("PyImagingPhotoGet", photo, im.getim())
return im
def _show(image: Image.Image, title: str | None) -> None:
"""Helper for the Image.show method."""
class UI(tkinter.Label):
def __init__(self, master: tkinter.Toplevel, im: Image.Image) -> None:
self.image: BitmapImage | PhotoImage
if im.mode == "1":
self.image = BitmapImage(im, foreground="white", master=master)
else:
self.image = PhotoImage(im, master=master)
if TYPE_CHECKING:
image = cast(tkinter._Image, self.image)
else:
image = self.image
super().__init__(master, image=image, bg="black", bd=0)
if not getattr(tkinter, "_default_root"):
msg = "tkinter not initialized"
raise OSError(msg)
top = tkinter.Toplevel()
if title:
top.title(title)
UI(top, image).pack()

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#
# The Python Imaging Library.
# $Id$
#
# transform wrappers
#
# History:
# 2002-04-08 fl Created
#
# Copyright (c) 2002 by Secret Labs AB
# Copyright (c) 2002 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from collections.abc import Sequence
from typing import Any
from . import Image
class Transform(Image.ImageTransformHandler):
"""Base class for other transforms defined in :py:mod:`~PIL.ImageTransform`."""
method: Image.Transform
def __init__(self, data: Sequence[Any]) -> None:
self.data = data
def getdata(self) -> tuple[Image.Transform, Sequence[int]]:
return self.method, self.data
def transform(
self,
size: tuple[int, int],
image: Image.Image,
**options: Any,
) -> Image.Image:
"""Perform the transform. Called from :py:meth:`.Image.transform`."""
# can be overridden
method, data = self.getdata()
return image.transform(size, method, data, **options)
class AffineTransform(Transform):
"""
Define an affine image transform.
This function takes a 6-tuple (a, b, c, d, e, f) which contain the first
two rows from an affine transform matrix. For each pixel (x, y) in the
output image, the new value is taken from a position (a x + b y + c,
d x + e y + f) in the input image, rounded to nearest pixel.
This function can be used to scale, translate, rotate, and shear the
original image.
See :py:meth:`.Image.transform`
:param matrix: A 6-tuple (a, b, c, d, e, f) containing the first two rows
from an affine transform matrix.
"""
method = Image.Transform.AFFINE
class PerspectiveTransform(Transform):
"""
Define a perspective image transform.
This function takes an 8-tuple (a, b, c, d, e, f, g, h). For each pixel
(x, y) in the output image, the new value is taken from a position
((a x + b y + c) / (g x + h y + 1), (d x + e y + f) / (g x + h y + 1)) in
the input image, rounded to nearest pixel.
This function can be used to scale, translate, rotate, and shear the
original image.
See :py:meth:`.Image.transform`
:param matrix: An 8-tuple (a, b, c, d, e, f, g, h).
"""
method = Image.Transform.PERSPECTIVE
class ExtentTransform(Transform):
"""
Define a transform to extract a subregion from an image.
Maps a rectangle (defined by two corners) from the image to a rectangle of
the given size. The resulting image will contain data sampled from between
the corners, such that (x0, y0) in the input image will end up at (0,0) in
the output image, and (x1, y1) at size.
This method can be used to crop, stretch, shrink, or mirror an arbitrary
rectangle in the current image. It is slightly slower than crop, but about
as fast as a corresponding resize operation.
See :py:meth:`.Image.transform`
:param bbox: A 4-tuple (x0, y0, x1, y1) which specifies two points in the
input image's coordinate system. See :ref:`coordinate-system`.
"""
method = Image.Transform.EXTENT
class QuadTransform(Transform):
"""
Define a quad image transform.
Maps a quadrilateral (a region defined by four corners) from the image to a
rectangle of the given size.
See :py:meth:`.Image.transform`
:param xy: An 8-tuple (x0, y0, x1, y1, x2, y2, x3, y3) which contain the
upper left, lower left, lower right, and upper right corner of the
source quadrilateral.
"""
method = Image.Transform.QUAD
class MeshTransform(Transform):
"""
Define a mesh image transform. A mesh transform consists of one or more
individual quad transforms.
See :py:meth:`.Image.transform`
:param data: A list of (bbox, quad) tuples.
"""
method = Image.Transform.MESH

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#
# The Python Imaging Library.
# $Id$
#
# a Windows DIB display interface
#
# History:
# 1996-05-20 fl Created
# 1996-09-20 fl Fixed subregion exposure
# 1997-09-21 fl Added draw primitive (for tzPrint)
# 2003-05-21 fl Added experimental Window/ImageWindow classes
# 2003-09-05 fl Added fromstring/tostring methods
#
# Copyright (c) Secret Labs AB 1997-2003.
# Copyright (c) Fredrik Lundh 1996-2003.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from . import Image
class HDC:
"""
Wraps an HDC integer. The resulting object can be passed to the
:py:meth:`~PIL.ImageWin.Dib.draw` and :py:meth:`~PIL.ImageWin.Dib.expose`
methods.
"""
def __init__(self, dc: int) -> None:
self.dc = dc
def __int__(self) -> int:
return self.dc
class HWND:
"""
Wraps an HWND integer. The resulting object can be passed to the
:py:meth:`~PIL.ImageWin.Dib.draw` and :py:meth:`~PIL.ImageWin.Dib.expose`
methods, instead of a DC.
"""
def __init__(self, wnd: int) -> None:
self.wnd = wnd
def __int__(self) -> int:
return self.wnd
class Dib:
"""
A Windows bitmap with the given mode and size. The mode can be one of "1",
"L", "P", or "RGB".
If the display requires a palette, this constructor creates a suitable
palette and associates it with the image. For an "L" image, 128 graylevels
are allocated. For an "RGB" image, a 6x6x6 colour cube is used, together
with 20 graylevels.
To make sure that palettes work properly under Windows, you must call the
``palette`` method upon certain events from Windows.
:param image: Either a PIL image, or a mode string. If a mode string is
used, a size must also be given. The mode can be one of "1",
"L", "P", or "RGB".
:param size: If the first argument is a mode string, this
defines the size of the image.
"""
def __init__(
self, image: Image.Image | str, size: tuple[int, int] | None = None
) -> None:
if isinstance(image, str):
mode = image
image = ""
if size is None:
msg = "If first argument is mode, size is required"
raise ValueError(msg)
else:
mode = image.mode
size = image.size
if mode not in ["1", "L", "P", "RGB"]:
mode = Image.getmodebase(mode)
self.image = Image.core.display(mode, size)
self.mode = mode
self.size = size
if image:
assert not isinstance(image, str)
self.paste(image)
def expose(self, handle: int | HDC | HWND) -> None:
"""
Copy the bitmap contents to a device context.
:param handle: Device context (HDC), cast to a Python integer, or an
HDC or HWND instance. In PythonWin, you can use
``CDC.GetHandleAttrib()`` to get a suitable handle.
"""
handle_int = int(handle)
if isinstance(handle, HWND):
dc = self.image.getdc(handle_int)
try:
self.image.expose(dc)
finally:
self.image.releasedc(handle_int, dc)
else:
self.image.expose(handle_int)
def draw(
self,
handle: int | HDC | HWND,
dst: tuple[int, int, int, int],
src: tuple[int, int, int, int] | None = None,
) -> None:
"""
Same as expose, but allows you to specify where to draw the image, and
what part of it to draw.
The destination and source areas are given as 4-tuple rectangles. If
the source is omitted, the entire image is copied. If the source and
the destination have different sizes, the image is resized as
necessary.
"""
if src is None:
src = (0, 0) + self.size
handle_int = int(handle)
if isinstance(handle, HWND):
dc = self.image.getdc(handle_int)
try:
self.image.draw(dc, dst, src)
finally:
self.image.releasedc(handle_int, dc)
else:
self.image.draw(handle_int, dst, src)
def query_palette(self, handle: int | HDC | HWND) -> int:
"""
Installs the palette associated with the image in the given device
context.
This method should be called upon **QUERYNEWPALETTE** and
**PALETTECHANGED** events from Windows. If this method returns a
non-zero value, one or more display palette entries were changed, and
the image should be redrawn.
:param handle: Device context (HDC), cast to a Python integer, or an
HDC or HWND instance.
:return: The number of entries that were changed (if one or more entries,
this indicates that the image should be redrawn).
"""
handle_int = int(handle)
if isinstance(handle, HWND):
handle = self.image.getdc(handle_int)
try:
result = self.image.query_palette(handle)
finally:
self.image.releasedc(handle, handle)
else:
result = self.image.query_palette(handle_int)
return result
def paste(
self, im: Image.Image, box: tuple[int, int, int, int] | None = None
) -> None:
"""
Paste a PIL image into the bitmap image.
:param im: A PIL image. The size must match the target region.
If the mode does not match, the image is converted to the
mode of the bitmap image.
:param box: A 4-tuple defining the left, upper, right, and
lower pixel coordinate. See :ref:`coordinate-system`. If
None is given instead of a tuple, all of the image is
assumed.
"""
im.load()
if self.mode != im.mode:
im = im.convert(self.mode)
if box:
self.image.paste(im.im, box)
else:
self.image.paste(im.im)
def frombytes(self, buffer: bytes) -> None:
"""
Load display memory contents from byte data.
:param buffer: A buffer containing display data (usually
data returned from :py:func:`~PIL.ImageWin.Dib.tobytes`)
"""
self.image.frombytes(buffer)
def tobytes(self) -> bytes:
"""
Copy display memory contents to bytes object.
:return: A bytes object containing display data.
"""
return self.image.tobytes()
class Window:
"""Create a Window with the given title size."""
def __init__(
self, title: str = "PIL", width: int | None = None, height: int | None = None
) -> None:
self.hwnd = Image.core.createwindow(
title, self.__dispatcher, width or 0, height or 0
)
def __dispatcher(self, action: str, *args: int) -> None:
getattr(self, f"ui_handle_{action}")(*args)
def ui_handle_clear(self, dc: int, x0: int, y0: int, x1: int, y1: int) -> None:
pass
def ui_handle_damage(self, x0: int, y0: int, x1: int, y1: int) -> None:
pass
def ui_handle_destroy(self) -> None:
pass
def ui_handle_repair(self, dc: int, x0: int, y0: int, x1: int, y1: int) -> None:
pass
def ui_handle_resize(self, width: int, height: int) -> None:
pass
def mainloop(self) -> None:
Image.core.eventloop()
class ImageWindow(Window):
"""Create an image window which displays the given image."""
def __init__(self, image: Image.Image | Dib, title: str = "PIL") -> None:
if not isinstance(image, Dib):
image = Dib(image)
self.image = image
width, height = image.size
super().__init__(title, width=width, height=height)
def ui_handle_repair(self, dc: int, x0: int, y0: int, x1: int, y1: int) -> None:
self.image.draw(dc, (x0, y0, x1, y1))

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#
# The Python Imaging Library.
# $Id$
#
# IM Tools support for PIL
#
# history:
# 1996-05-27 fl Created (read 8-bit images only)
# 2001-02-17 fl Use 're' instead of 'regex' (Python 2.1) (0.2)
#
# Copyright (c) Secret Labs AB 1997-2001.
# Copyright (c) Fredrik Lundh 1996-2001.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import re
from . import Image, ImageFile
#
# --------------------------------------------------------------------
field = re.compile(rb"([a-z]*) ([^ \r\n]*)")
##
# Image plugin for IM Tools images.
class ImtImageFile(ImageFile.ImageFile):
format = "IMT"
format_description = "IM Tools"
def _open(self) -> None:
# Quick rejection: if there's not a LF among the first
# 100 bytes, this is (probably) not a text header.
assert self.fp is not None
buffer = self.fp.read(100)
if b"\n" not in buffer:
msg = "not an IM file"
raise SyntaxError(msg)
xsize = ysize = 0
while True:
if buffer:
s = buffer[:1]
buffer = buffer[1:]
else:
s = self.fp.read(1)
if not s:
break
if s == b"\x0C":
# image data begins
self.tile = [
ImageFile._Tile(
"raw",
(0, 0) + self.size,
self.fp.tell() - len(buffer),
(self.mode, 0, 1),
)
]
break
else:
# read key/value pair
if b"\n" not in buffer:
buffer += self.fp.read(100)
lines = buffer.split(b"\n")
s += lines.pop(0)
buffer = b"\n".join(lines)
if len(s) == 1 or len(s) > 100:
break
if s[0] == ord(b"*"):
continue # comment
m = field.match(s)
if not m:
break
k, v = m.group(1, 2)
if k == b"width":
xsize = int(v)
self._size = xsize, ysize
elif k == b"height":
ysize = int(v)
self._size = xsize, ysize
elif k == b"pixel" and v == b"n8":
self._mode = "L"
#
# --------------------------------------------------------------------
Image.register_open(ImtImageFile.format, ImtImageFile)
#
# no extension registered (".im" is simply too common)

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#
# The Python Imaging Library.
# $Id$
#
# IPTC/NAA file handling
#
# history:
# 1995-10-01 fl Created
# 1998-03-09 fl Cleaned up and added to PIL
# 2002-06-18 fl Added getiptcinfo helper
#
# Copyright (c) Secret Labs AB 1997-2002.
# Copyright (c) Fredrik Lundh 1995.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from collections.abc import Sequence
from io import BytesIO
from typing import cast
from . import Image, ImageFile
from ._binary import i16be as i16
from ._binary import i32be as i32
from ._deprecate import deprecate
COMPRESSION = {1: "raw", 5: "jpeg"}
def __getattr__(name: str) -> bytes:
if name == "PAD":
deprecate("IptcImagePlugin.PAD", 12)
return b"\0\0\0\0"
msg = f"module '{__name__}' has no attribute '{name}'"
raise AttributeError(msg)
#
# Helpers
def _i(c: bytes) -> int:
return i32((b"\0\0\0\0" + c)[-4:])
def _i8(c: int | bytes) -> int:
return c if isinstance(c, int) else c[0]
def i(c: bytes) -> int:
""".. deprecated:: 10.2.0"""
deprecate("IptcImagePlugin.i", 12)
return _i(c)
def dump(c: Sequence[int | bytes]) -> None:
""".. deprecated:: 10.2.0"""
deprecate("IptcImagePlugin.dump", 12)
for i in c:
print(f"{_i8(i):02x}", end=" ")
print()
##
# Image plugin for IPTC/NAA datastreams. To read IPTC/NAA fields
# from TIFF and JPEG files, use the <b>getiptcinfo</b> function.
class IptcImageFile(ImageFile.ImageFile):
format = "IPTC"
format_description = "IPTC/NAA"
def getint(self, key: tuple[int, int]) -> int:
return _i(self.info[key])
def field(self) -> tuple[tuple[int, int] | None, int]:
#
# get a IPTC field header
s = self.fp.read(5)
if not s.strip(b"\x00"):
return None, 0
tag = s[1], s[2]
# syntax
if s[0] != 0x1C or tag[0] not in [1, 2, 3, 4, 5, 6, 7, 8, 9, 240]:
msg = "invalid IPTC/NAA file"
raise SyntaxError(msg)
# field size
size = s[3]
if size > 132:
msg = "illegal field length in IPTC/NAA file"
raise OSError(msg)
elif size == 128:
size = 0
elif size > 128:
size = _i(self.fp.read(size - 128))
else:
size = i16(s, 3)
return tag, size
def _open(self) -> None:
# load descriptive fields
while True:
offset = self.fp.tell()
tag, size = self.field()
if not tag or tag == (8, 10):
break
if size:
tagdata = self.fp.read(size)
else:
tagdata = None
if tag in self.info:
if isinstance(self.info[tag], list):
self.info[tag].append(tagdata)
else:
self.info[tag] = [self.info[tag], tagdata]
else:
self.info[tag] = tagdata
# mode
layers = self.info[(3, 60)][0]
component = self.info[(3, 60)][1]
if (3, 65) in self.info:
id = self.info[(3, 65)][0] - 1
else:
id = 0
if layers == 1 and not component:
self._mode = "L"
elif layers == 3 and component:
self._mode = "RGB"[id]
elif layers == 4 and component:
self._mode = "CMYK"[id]
# size
self._size = self.getint((3, 20)), self.getint((3, 30))
# compression
try:
compression = COMPRESSION[self.getint((3, 120))]
except KeyError as e:
msg = "Unknown IPTC image compression"
raise OSError(msg) from e
# tile
if tag == (8, 10):
self.tile = [
ImageFile._Tile("iptc", (0, 0) + self.size, offset, compression)
]
def load(self) -> Image.core.PixelAccess | None:
if len(self.tile) != 1 or self.tile[0][0] != "iptc":
return ImageFile.ImageFile.load(self)
offset, compression = self.tile[0][2:]
self.fp.seek(offset)
# Copy image data to temporary file
o = BytesIO()
if compression == "raw":
# To simplify access to the extracted file,
# prepend a PPM header
o.write(b"P5\n%d %d\n255\n" % self.size)
while True:
type, size = self.field()
if type != (8, 10):
break
while size > 0:
s = self.fp.read(min(size, 8192))
if not s:
break
o.write(s)
size -= len(s)
with Image.open(o) as _im:
_im.load()
self.im = _im.im
return None
Image.register_open(IptcImageFile.format, IptcImageFile)
Image.register_extension(IptcImageFile.format, ".iim")
def getiptcinfo(
im: ImageFile.ImageFile,
) -> dict[tuple[int, int], bytes | list[bytes]] | None:
"""
Get IPTC information from TIFF, JPEG, or IPTC file.
:param im: An image containing IPTC data.
:returns: A dictionary containing IPTC information, or None if
no IPTC information block was found.
"""
from . import JpegImagePlugin, TiffImagePlugin
data = None
info: dict[tuple[int, int], bytes | list[bytes]] = {}
if isinstance(im, IptcImageFile):
# return info dictionary right away
for k, v in im.info.items():
if isinstance(k, tuple):
info[k] = v
return info
elif isinstance(im, JpegImagePlugin.JpegImageFile):
# extract the IPTC/NAA resource
photoshop = im.info.get("photoshop")
if photoshop:
data = photoshop.get(0x0404)
elif isinstance(im, TiffImagePlugin.TiffImageFile):
# get raw data from the IPTC/NAA tag (PhotoShop tags the data
# as 4-byte integers, so we cannot use the get method...)
try:
data = im.tag_v2[TiffImagePlugin.IPTC_NAA_CHUNK]
except KeyError:
pass
if data is None:
return None # no properties
# create an IptcImagePlugin object without initializing it
class FakeImage:
pass
fake_im = FakeImage()
fake_im.__class__ = IptcImageFile # type: ignore[assignment]
iptc_im = cast(IptcImageFile, fake_im)
# parse the IPTC information chunk
iptc_im.info = {}
iptc_im.fp = BytesIO(data)
try:
iptc_im._open()
except (IndexError, KeyError):
pass # expected failure
for k, v in iptc_im.info.items():
if isinstance(k, tuple):
info[k] = v
return info

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#
# The Python Imaging Library
# $Id$
#
# JPEG2000 file handling
#
# History:
# 2014-03-12 ajh Created
# 2021-06-30 rogermb Extract dpi information from the 'resc' header box
#
# Copyright (c) 2014 Coriolis Systems Limited
# Copyright (c) 2014 Alastair Houghton
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import io
import os
import struct
from collections.abc import Callable
from typing import IO, cast
from . import Image, ImageFile, ImagePalette, _binary
class BoxReader:
"""
A small helper class to read fields stored in JPEG2000 header boxes
and to easily step into and read sub-boxes.
"""
def __init__(self, fp: IO[bytes], length: int = -1) -> None:
self.fp = fp
self.has_length = length >= 0
self.length = length
self.remaining_in_box = -1
def _can_read(self, num_bytes: int) -> bool:
if self.has_length and self.fp.tell() + num_bytes > self.length:
# Outside box: ensure we don't read past the known file length
return False
if self.remaining_in_box >= 0:
# Inside box contents: ensure read does not go past box boundaries
return num_bytes <= self.remaining_in_box
else:
return True # No length known, just read
def _read_bytes(self, num_bytes: int) -> bytes:
if not self._can_read(num_bytes):
msg = "Not enough data in header"
raise SyntaxError(msg)
data = self.fp.read(num_bytes)
if len(data) < num_bytes:
msg = f"Expected to read {num_bytes} bytes but only got {len(data)}."
raise OSError(msg)
if self.remaining_in_box > 0:
self.remaining_in_box -= num_bytes
return data
def read_fields(self, field_format: str) -> tuple[int | bytes, ...]:
size = struct.calcsize(field_format)
data = self._read_bytes(size)
return struct.unpack(field_format, data)
def read_boxes(self) -> BoxReader:
size = self.remaining_in_box
data = self._read_bytes(size)
return BoxReader(io.BytesIO(data), size)
def has_next_box(self) -> bool:
if self.has_length:
return self.fp.tell() + self.remaining_in_box < self.length
else:
return True
def next_box_type(self) -> bytes:
# Skip the rest of the box if it has not been read
if self.remaining_in_box > 0:
self.fp.seek(self.remaining_in_box, os.SEEK_CUR)
self.remaining_in_box = -1
# Read the length and type of the next box
lbox, tbox = cast(tuple[int, bytes], self.read_fields(">I4s"))
if lbox == 1:
lbox = cast(int, self.read_fields(">Q")[0])
hlen = 16
else:
hlen = 8
if lbox < hlen or not self._can_read(lbox - hlen):
msg = "Invalid header length"
raise SyntaxError(msg)
self.remaining_in_box = lbox - hlen
return tbox
def _parse_codestream(fp: IO[bytes]) -> tuple[tuple[int, int], str]:
"""Parse the JPEG 2000 codestream to extract the size and component
count from the SIZ marker segment, returning a PIL (size, mode) tuple."""
hdr = fp.read(2)
lsiz = _binary.i16be(hdr)
siz = hdr + fp.read(lsiz - 2)
lsiz, rsiz, xsiz, ysiz, xosiz, yosiz, _, _, _, _, csiz = struct.unpack_from(
">HHIIIIIIIIH", siz
)
size = (xsiz - xosiz, ysiz - yosiz)
if csiz == 1:
ssiz = struct.unpack_from(">B", siz, 38)
if (ssiz[0] & 0x7F) + 1 > 8:
mode = "I;16"
else:
mode = "L"
elif csiz == 2:
mode = "LA"
elif csiz == 3:
mode = "RGB"
elif csiz == 4:
mode = "RGBA"
else:
msg = "unable to determine J2K image mode"
raise SyntaxError(msg)
return size, mode
def _res_to_dpi(num: int, denom: int, exp: int) -> float | None:
"""Convert JPEG2000's (numerator, denominator, exponent-base-10) resolution,
calculated as (num / denom) * 10^exp and stored in dots per meter,
to floating-point dots per inch."""
if denom == 0:
return None
return (254 * num * (10**exp)) / (10000 * denom)
def _parse_jp2_header(
fp: IO[bytes],
) -> tuple[
tuple[int, int],
str,
str | None,
tuple[float, float] | None,
ImagePalette.ImagePalette | None,
]:
"""Parse the JP2 header box to extract size, component count,
color space information, and optionally DPI information,
returning a (size, mode, mimetype, dpi) tuple."""
# Find the JP2 header box
reader = BoxReader(fp)
header = None
mimetype = None
while reader.has_next_box():
tbox = reader.next_box_type()
if tbox == b"jp2h":
header = reader.read_boxes()
break
elif tbox == b"ftyp":
if reader.read_fields(">4s")[0] == b"jpx ":
mimetype = "image/jpx"
assert header is not None
size = None
mode = None
bpc = None
nc = None
dpi = None # 2-tuple of DPI info, or None
palette = None
while header.has_next_box():
tbox = header.next_box_type()
if tbox == b"ihdr":
height, width, nc, bpc = header.read_fields(">IIHB")
assert isinstance(height, int)
assert isinstance(width, int)
assert isinstance(bpc, int)
size = (width, height)
if nc == 1 and (bpc & 0x7F) > 8:
mode = "I;16"
elif nc == 1:
mode = "L"
elif nc == 2:
mode = "LA"
elif nc == 3:
mode = "RGB"
elif nc == 4:
mode = "RGBA"
elif tbox == b"colr" and nc == 4:
meth, _, _, enumcs = header.read_fields(">BBBI")
if meth == 1 and enumcs == 12:
mode = "CMYK"
elif tbox == b"pclr" and mode in ("L", "LA"):
ne, npc = header.read_fields(">HB")
assert isinstance(ne, int)
assert isinstance(npc, int)
max_bitdepth = 0
for bitdepth in header.read_fields(">" + ("B" * npc)):
assert isinstance(bitdepth, int)
if bitdepth > max_bitdepth:
max_bitdepth = bitdepth
if max_bitdepth <= 8:
palette = ImagePalette.ImagePalette("RGBA" if npc == 4 else "RGB")
for i in range(ne):
color: list[int] = []
for value in header.read_fields(">" + ("B" * npc)):
assert isinstance(value, int)
color.append(value)
palette.getcolor(tuple(color))
mode = "P" if mode == "L" else "PA"
elif tbox == b"res ":
res = header.read_boxes()
while res.has_next_box():
tres = res.next_box_type()
if tres == b"resc":
vrcn, vrcd, hrcn, hrcd, vrce, hrce = res.read_fields(">HHHHBB")
assert isinstance(vrcn, int)
assert isinstance(vrcd, int)
assert isinstance(hrcn, int)
assert isinstance(hrcd, int)
assert isinstance(vrce, int)
assert isinstance(hrce, int)
hres = _res_to_dpi(hrcn, hrcd, hrce)
vres = _res_to_dpi(vrcn, vrcd, vrce)
if hres is not None and vres is not None:
dpi = (hres, vres)
break
if size is None or mode is None:
msg = "Malformed JP2 header"
raise SyntaxError(msg)
return size, mode, mimetype, dpi, palette
##
# Image plugin for JPEG2000 images.
class Jpeg2KImageFile(ImageFile.ImageFile):
format = "JPEG2000"
format_description = "JPEG 2000 (ISO 15444)"
def _open(self) -> None:
sig = self.fp.read(4)
if sig == b"\xff\x4f\xff\x51":
self.codec = "j2k"
self._size, self._mode = _parse_codestream(self.fp)
else:
sig = sig + self.fp.read(8)
if sig == b"\x00\x00\x00\x0cjP \x0d\x0a\x87\x0a":
self.codec = "jp2"
header = _parse_jp2_header(self.fp)
self._size, self._mode, self.custom_mimetype, dpi, self.palette = header
if dpi is not None:
self.info["dpi"] = dpi
if self.fp.read(12).endswith(b"jp2c\xff\x4f\xff\x51"):
self._parse_comment()
else:
msg = "not a JPEG 2000 file"
raise SyntaxError(msg)
self._reduce = 0
self.layers = 0
fd = -1
length = -1
try:
fd = self.fp.fileno()
length = os.fstat(fd).st_size
except Exception:
fd = -1
try:
pos = self.fp.tell()
self.fp.seek(0, io.SEEK_END)
length = self.fp.tell()
self.fp.seek(pos)
except Exception:
length = -1
self.tile = [
ImageFile._Tile(
"jpeg2k",
(0, 0) + self.size,
0,
(self.codec, self._reduce, self.layers, fd, length),
)
]
def _parse_comment(self) -> None:
hdr = self.fp.read(2)
length = _binary.i16be(hdr)
self.fp.seek(length - 2, os.SEEK_CUR)
while True:
marker = self.fp.read(2)
if not marker:
break
typ = marker[1]
if typ in (0x90, 0xD9):
# Start of tile or end of codestream
break
hdr = self.fp.read(2)
length = _binary.i16be(hdr)
if typ == 0x64:
# Comment
self.info["comment"] = self.fp.read(length - 2)[2:]
break
else:
self.fp.seek(length - 2, os.SEEK_CUR)
@property # type: ignore[override]
def reduce(
self,
) -> (
Callable[[int | tuple[int, int], tuple[int, int, int, int] | None], Image.Image]
| int
):
# https://github.com/python-pillow/Pillow/issues/4343 found that the
# new Image 'reduce' method was shadowed by this plugin's 'reduce'
# property. This attempts to allow for both scenarios
return self._reduce or super().reduce
@reduce.setter
def reduce(self, value: int) -> None:
self._reduce = value
def load(self) -> Image.core.PixelAccess | None:
if self.tile and self._reduce:
power = 1 << self._reduce
adjust = power >> 1
self._size = (
int((self.size[0] + adjust) / power),
int((self.size[1] + adjust) / power),
)
# Update the reduce and layers settings
t = self.tile[0]
assert isinstance(t[3], tuple)
t3 = (t[3][0], self._reduce, self.layers, t[3][3], t[3][4])
self.tile = [ImageFile._Tile(t[0], (0, 0) + self.size, t[2], t3)]
return ImageFile.ImageFile.load(self)
def _accept(prefix: bytes) -> bool:
return (
prefix[:4] == b"\xff\x4f\xff\x51"
or prefix[:12] == b"\x00\x00\x00\x0cjP \x0d\x0a\x87\x0a"
)
# ------------------------------------------------------------
# Save support
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
# Get the keyword arguments
info = im.encoderinfo
if isinstance(filename, str):
filename = filename.encode()
if filename.endswith(b".j2k") or info.get("no_jp2", False):
kind = "j2k"
else:
kind = "jp2"
offset = info.get("offset", None)
tile_offset = info.get("tile_offset", None)
tile_size = info.get("tile_size", None)
quality_mode = info.get("quality_mode", "rates")
quality_layers = info.get("quality_layers", None)
if quality_layers is not None and not (
isinstance(quality_layers, (list, tuple))
and all(
isinstance(quality_layer, (int, float)) for quality_layer in quality_layers
)
):
msg = "quality_layers must be a sequence of numbers"
raise ValueError(msg)
num_resolutions = info.get("num_resolutions", 0)
cblk_size = info.get("codeblock_size", None)
precinct_size = info.get("precinct_size", None)
irreversible = info.get("irreversible", False)
progression = info.get("progression", "LRCP")
cinema_mode = info.get("cinema_mode", "no")
mct = info.get("mct", 0)
signed = info.get("signed", False)
comment = info.get("comment")
if isinstance(comment, str):
comment = comment.encode()
plt = info.get("plt", False)
fd = -1
if hasattr(fp, "fileno"):
try:
fd = fp.fileno()
except Exception:
fd = -1
im.encoderconfig = (
offset,
tile_offset,
tile_size,
quality_mode,
quality_layers,
num_resolutions,
cblk_size,
precinct_size,
irreversible,
progression,
cinema_mode,
mct,
signed,
fd,
comment,
plt,
)
ImageFile._save(im, fp, [ImageFile._Tile("jpeg2k", (0, 0) + im.size, 0, kind)])
# ------------------------------------------------------------
# Registry stuff
Image.register_open(Jpeg2KImageFile.format, Jpeg2KImageFile, _accept)
Image.register_save(Jpeg2KImageFile.format, _save)
Image.register_extensions(
Jpeg2KImageFile.format, [".jp2", ".j2k", ".jpc", ".jpf", ".jpx", ".j2c"]
)
Image.register_mime(Jpeg2KImageFile.format, "image/jp2")

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#
# The Python Imaging Library.
# $Id$
#
# JPEG (JFIF) file handling
#
# See "Digital Compression and Coding of Continuous-Tone Still Images,
# Part 1, Requirements and Guidelines" (CCITT T.81 / ISO 10918-1)
#
# History:
# 1995-09-09 fl Created
# 1995-09-13 fl Added full parser
# 1996-03-25 fl Added hack to use the IJG command line utilities
# 1996-05-05 fl Workaround Photoshop 2.5 CMYK polarity bug
# 1996-05-28 fl Added draft support, JFIF version (0.1)
# 1996-12-30 fl Added encoder options, added progression property (0.2)
# 1997-08-27 fl Save mode 1 images as BW (0.3)
# 1998-07-12 fl Added YCbCr to draft and save methods (0.4)
# 1998-10-19 fl Don't hang on files using 16-bit DQT's (0.4.1)
# 2001-04-16 fl Extract DPI settings from JFIF files (0.4.2)
# 2002-07-01 fl Skip pad bytes before markers; identify Exif files (0.4.3)
# 2003-04-25 fl Added experimental EXIF decoder (0.5)
# 2003-06-06 fl Added experimental EXIF GPSinfo decoder
# 2003-09-13 fl Extract COM markers
# 2009-09-06 fl Added icc_profile support (from Florian Hoech)
# 2009-03-06 fl Changed CMYK handling; always use Adobe polarity (0.6)
# 2009-03-08 fl Added subsampling support (from Justin Huff).
#
# Copyright (c) 1997-2003 by Secret Labs AB.
# Copyright (c) 1995-1996 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import array
import io
import math
import os
import struct
import subprocess
import sys
import tempfile
import warnings
from typing import IO, TYPE_CHECKING, Any
from . import Image, ImageFile
from ._binary import i16be as i16
from ._binary import i32be as i32
from ._binary import o8
from ._binary import o16be as o16
from ._deprecate import deprecate
from .JpegPresets import presets
if TYPE_CHECKING:
from .MpoImagePlugin import MpoImageFile
#
# Parser
def Skip(self: JpegImageFile, marker: int) -> None:
n = i16(self.fp.read(2)) - 2
ImageFile._safe_read(self.fp, n)
def APP(self: JpegImageFile, marker: int) -> None:
#
# Application marker. Store these in the APP dictionary.
# Also look for well-known application markers.
n = i16(self.fp.read(2)) - 2
s = ImageFile._safe_read(self.fp, n)
app = "APP%d" % (marker & 15)
self.app[app] = s # compatibility
self.applist.append((app, s))
if marker == 0xFFE0 and s[:4] == b"JFIF":
# extract JFIF information
self.info["jfif"] = version = i16(s, 5) # version
self.info["jfif_version"] = divmod(version, 256)
# extract JFIF properties
try:
jfif_unit = s[7]
jfif_density = i16(s, 8), i16(s, 10)
except Exception:
pass
else:
if jfif_unit == 1:
self.info["dpi"] = jfif_density
self.info["jfif_unit"] = jfif_unit
self.info["jfif_density"] = jfif_density
elif marker == 0xFFE1 and s[:6] == b"Exif\0\0":
# extract EXIF information
if "exif" in self.info:
self.info["exif"] += s[6:]
else:
self.info["exif"] = s
self._exif_offset = self.fp.tell() - n + 6
elif marker == 0xFFE1 and s[:29] == b"http://ns.adobe.com/xap/1.0/\x00":
self.info["xmp"] = s.split(b"\x00", 1)[1]
elif marker == 0xFFE2 and s[:5] == b"FPXR\0":
# extract FlashPix information (incomplete)
self.info["flashpix"] = s # FIXME: value will change
elif marker == 0xFFE2 and s[:12] == b"ICC_PROFILE\0":
# Since an ICC profile can be larger than the maximum size of
# a JPEG marker (64K), we need provisions to split it into
# multiple markers. The format defined by the ICC specifies
# one or more APP2 markers containing the following data:
# Identifying string ASCII "ICC_PROFILE\0" (12 bytes)
# Marker sequence number 1, 2, etc (1 byte)
# Number of markers Total of APP2's used (1 byte)
# Profile data (remainder of APP2 data)
# Decoders should use the marker sequence numbers to
# reassemble the profile, rather than assuming that the APP2
# markers appear in the correct sequence.
self.icclist.append(s)
elif marker == 0xFFED and s[:14] == b"Photoshop 3.0\x00":
# parse the image resource block
offset = 14
photoshop = self.info.setdefault("photoshop", {})
while s[offset : offset + 4] == b"8BIM":
try:
offset += 4
# resource code
code = i16(s, offset)
offset += 2
# resource name (usually empty)
name_len = s[offset]
# name = s[offset+1:offset+1+name_len]
offset += 1 + name_len
offset += offset & 1 # align
# resource data block
size = i32(s, offset)
offset += 4
data = s[offset : offset + size]
if code == 0x03ED: # ResolutionInfo
photoshop[code] = {
"XResolution": i32(data, 0) / 65536,
"DisplayedUnitsX": i16(data, 4),
"YResolution": i32(data, 8) / 65536,
"DisplayedUnitsY": i16(data, 12),
}
else:
photoshop[code] = data
offset += size
offset += offset & 1 # align
except struct.error:
break # insufficient data
elif marker == 0xFFEE and s[:5] == b"Adobe":
self.info["adobe"] = i16(s, 5)
# extract Adobe custom properties
try:
adobe_transform = s[11]
except IndexError:
pass
else:
self.info["adobe_transform"] = adobe_transform
elif marker == 0xFFE2 and s[:4] == b"MPF\0":
# extract MPO information
self.info["mp"] = s[4:]
# offset is current location minus buffer size
# plus constant header size
self.info["mpoffset"] = self.fp.tell() - n + 4
def COM(self: JpegImageFile, marker: int) -> None:
#
# Comment marker. Store these in the APP dictionary.
n = i16(self.fp.read(2)) - 2
s = ImageFile._safe_read(self.fp, n)
self.info["comment"] = s
self.app["COM"] = s # compatibility
self.applist.append(("COM", s))
def SOF(self: JpegImageFile, marker: int) -> None:
#
# Start of frame marker. Defines the size and mode of the
# image. JPEG is colour blind, so we use some simple
# heuristics to map the number of layers to an appropriate
# mode. Note that this could be made a bit brighter, by
# looking for JFIF and Adobe APP markers.
n = i16(self.fp.read(2)) - 2
s = ImageFile._safe_read(self.fp, n)
self._size = i16(s, 3), i16(s, 1)
self.bits = s[0]
if self.bits != 8:
msg = f"cannot handle {self.bits}-bit layers"
raise SyntaxError(msg)
self.layers = s[5]
if self.layers == 1:
self._mode = "L"
elif self.layers == 3:
self._mode = "RGB"
elif self.layers == 4:
self._mode = "CMYK"
else:
msg = f"cannot handle {self.layers}-layer images"
raise SyntaxError(msg)
if marker in [0xFFC2, 0xFFC6, 0xFFCA, 0xFFCE]:
self.info["progressive"] = self.info["progression"] = 1
if self.icclist:
# fixup icc profile
self.icclist.sort() # sort by sequence number
if self.icclist[0][13] == len(self.icclist):
profile = [p[14:] for p in self.icclist]
icc_profile = b"".join(profile)
else:
icc_profile = None # wrong number of fragments
self.info["icc_profile"] = icc_profile
self.icclist = []
for i in range(6, len(s), 3):
t = s[i : i + 3]
# 4-tuples: id, vsamp, hsamp, qtable
self.layer.append((t[0], t[1] // 16, t[1] & 15, t[2]))
def DQT(self: JpegImageFile, marker: int) -> None:
#
# Define quantization table. Note that there might be more
# than one table in each marker.
# FIXME: The quantization tables can be used to estimate the
# compression quality.
n = i16(self.fp.read(2)) - 2
s = ImageFile._safe_read(self.fp, n)
while len(s):
v = s[0]
precision = 1 if (v // 16 == 0) else 2 # in bytes
qt_length = 1 + precision * 64
if len(s) < qt_length:
msg = "bad quantization table marker"
raise SyntaxError(msg)
data = array.array("B" if precision == 1 else "H", s[1:qt_length])
if sys.byteorder == "little" and precision > 1:
data.byteswap() # the values are always big-endian
self.quantization[v & 15] = [data[i] for i in zigzag_index]
s = s[qt_length:]
#
# JPEG marker table
MARKER = {
0xFFC0: ("SOF0", "Baseline DCT", SOF),
0xFFC1: ("SOF1", "Extended Sequential DCT", SOF),
0xFFC2: ("SOF2", "Progressive DCT", SOF),
0xFFC3: ("SOF3", "Spatial lossless", SOF),
0xFFC4: ("DHT", "Define Huffman table", Skip),
0xFFC5: ("SOF5", "Differential sequential DCT", SOF),
0xFFC6: ("SOF6", "Differential progressive DCT", SOF),
0xFFC7: ("SOF7", "Differential spatial", SOF),
0xFFC8: ("JPG", "Extension", None),
0xFFC9: ("SOF9", "Extended sequential DCT (AC)", SOF),
0xFFCA: ("SOF10", "Progressive DCT (AC)", SOF),
0xFFCB: ("SOF11", "Spatial lossless DCT (AC)", SOF),
0xFFCC: ("DAC", "Define arithmetic coding conditioning", Skip),
0xFFCD: ("SOF13", "Differential sequential DCT (AC)", SOF),
0xFFCE: ("SOF14", "Differential progressive DCT (AC)", SOF),
0xFFCF: ("SOF15", "Differential spatial (AC)", SOF),
0xFFD0: ("RST0", "Restart 0", None),
0xFFD1: ("RST1", "Restart 1", None),
0xFFD2: ("RST2", "Restart 2", None),
0xFFD3: ("RST3", "Restart 3", None),
0xFFD4: ("RST4", "Restart 4", None),
0xFFD5: ("RST5", "Restart 5", None),
0xFFD6: ("RST6", "Restart 6", None),
0xFFD7: ("RST7", "Restart 7", None),
0xFFD8: ("SOI", "Start of image", None),
0xFFD9: ("EOI", "End of image", None),
0xFFDA: ("SOS", "Start of scan", Skip),
0xFFDB: ("DQT", "Define quantization table", DQT),
0xFFDC: ("DNL", "Define number of lines", Skip),
0xFFDD: ("DRI", "Define restart interval", Skip),
0xFFDE: ("DHP", "Define hierarchical progression", SOF),
0xFFDF: ("EXP", "Expand reference component", Skip),
0xFFE0: ("APP0", "Application segment 0", APP),
0xFFE1: ("APP1", "Application segment 1", APP),
0xFFE2: ("APP2", "Application segment 2", APP),
0xFFE3: ("APP3", "Application segment 3", APP),
0xFFE4: ("APP4", "Application segment 4", APP),
0xFFE5: ("APP5", "Application segment 5", APP),
0xFFE6: ("APP6", "Application segment 6", APP),
0xFFE7: ("APP7", "Application segment 7", APP),
0xFFE8: ("APP8", "Application segment 8", APP),
0xFFE9: ("APP9", "Application segment 9", APP),
0xFFEA: ("APP10", "Application segment 10", APP),
0xFFEB: ("APP11", "Application segment 11", APP),
0xFFEC: ("APP12", "Application segment 12", APP),
0xFFED: ("APP13", "Application segment 13", APP),
0xFFEE: ("APP14", "Application segment 14", APP),
0xFFEF: ("APP15", "Application segment 15", APP),
0xFFF0: ("JPG0", "Extension 0", None),
0xFFF1: ("JPG1", "Extension 1", None),
0xFFF2: ("JPG2", "Extension 2", None),
0xFFF3: ("JPG3", "Extension 3", None),
0xFFF4: ("JPG4", "Extension 4", None),
0xFFF5: ("JPG5", "Extension 5", None),
0xFFF6: ("JPG6", "Extension 6", None),
0xFFF7: ("JPG7", "Extension 7", None),
0xFFF8: ("JPG8", "Extension 8", None),
0xFFF9: ("JPG9", "Extension 9", None),
0xFFFA: ("JPG10", "Extension 10", None),
0xFFFB: ("JPG11", "Extension 11", None),
0xFFFC: ("JPG12", "Extension 12", None),
0xFFFD: ("JPG13", "Extension 13", None),
0xFFFE: ("COM", "Comment", COM),
}
def _accept(prefix: bytes) -> bool:
# Magic number was taken from https://en.wikipedia.org/wiki/JPEG
return prefix[:3] == b"\xFF\xD8\xFF"
##
# Image plugin for JPEG and JFIF images.
class JpegImageFile(ImageFile.ImageFile):
format = "JPEG"
format_description = "JPEG (ISO 10918)"
def _open(self) -> None:
s = self.fp.read(3)
if not _accept(s):
msg = "not a JPEG file"
raise SyntaxError(msg)
s = b"\xFF"
# Create attributes
self.bits = self.layers = 0
self._exif_offset = 0
# JPEG specifics (internal)
self.layer: list[tuple[int, int, int, int]] = []
self._huffman_dc: dict[Any, Any] = {}
self._huffman_ac: dict[Any, Any] = {}
self.quantization: dict[int, list[int]] = {}
self.app: dict[str, bytes] = {} # compatibility
self.applist: list[tuple[str, bytes]] = []
self.icclist: list[bytes] = []
while True:
i = s[0]
if i == 0xFF:
s = s + self.fp.read(1)
i = i16(s)
else:
# Skip non-0xFF junk
s = self.fp.read(1)
continue
if i in MARKER:
name, description, handler = MARKER[i]
if handler is not None:
handler(self, i)
if i == 0xFFDA: # start of scan
rawmode = self.mode
if self.mode == "CMYK":
rawmode = "CMYK;I" # assume adobe conventions
self.tile = [
ImageFile._Tile("jpeg", (0, 0) + self.size, 0, (rawmode, ""))
]
# self.__offset = self.fp.tell()
break
s = self.fp.read(1)
elif i in {0, 0xFFFF}:
# padded marker or junk; move on
s = b"\xff"
elif i == 0xFF00: # Skip extraneous data (escaped 0xFF)
s = self.fp.read(1)
else:
msg = "no marker found"
raise SyntaxError(msg)
self._read_dpi_from_exif()
def __getattr__(self, name: str) -> Any:
if name in ("huffman_ac", "huffman_dc"):
deprecate(name, 12)
return getattr(self, "_" + name)
raise AttributeError(name)
def load_read(self, read_bytes: int) -> bytes:
"""
internal: read more image data
For premature EOF and LOAD_TRUNCATED_IMAGES adds EOI marker
so libjpeg can finish decoding
"""
s = self.fp.read(read_bytes)
if not s and ImageFile.LOAD_TRUNCATED_IMAGES and not hasattr(self, "_ended"):
# Premature EOF.
# Pretend file is finished adding EOI marker
self._ended = True
return b"\xFF\xD9"
return s
def draft(
self, mode: str | None, size: tuple[int, int] | None
) -> tuple[str, tuple[int, int, float, float]] | None:
if len(self.tile) != 1:
return None
# Protect from second call
if self.decoderconfig:
return None
d, e, o, a = self.tile[0]
scale = 1
original_size = self.size
assert isinstance(a, tuple)
if a[0] == "RGB" and mode in ["L", "YCbCr"]:
self._mode = mode
a = mode, ""
if size:
scale = min(self.size[0] // size[0], self.size[1] // size[1])
for s in [8, 4, 2, 1]:
if scale >= s:
break
assert e is not None
e = (
e[0],
e[1],
(e[2] - e[0] + s - 1) // s + e[0],
(e[3] - e[1] + s - 1) // s + e[1],
)
self._size = ((self.size[0] + s - 1) // s, (self.size[1] + s - 1) // s)
scale = s
self.tile = [ImageFile._Tile(d, e, o, a)]
self.decoderconfig = (scale, 0)
box = (0, 0, original_size[0] / scale, original_size[1] / scale)
return self.mode, box
def load_djpeg(self) -> None:
# ALTERNATIVE: handle JPEGs via the IJG command line utilities
f, path = tempfile.mkstemp()
os.close(f)
if os.path.exists(self.filename):
subprocess.check_call(["djpeg", "-outfile", path, self.filename])
else:
try:
os.unlink(path)
except OSError:
pass
msg = "Invalid Filename"
raise ValueError(msg)
try:
with Image.open(path) as _im:
_im.load()
self.im = _im.im
finally:
try:
os.unlink(path)
except OSError:
pass
self._mode = self.im.mode
self._size = self.im.size
self.tile = []
def _getexif(self) -> dict[int, Any] | None:
return _getexif(self)
def _read_dpi_from_exif(self) -> None:
# If DPI isn't in JPEG header, fetch from EXIF
if "dpi" in self.info or "exif" not in self.info:
return
try:
exif = self.getexif()
resolution_unit = exif[0x0128]
x_resolution = exif[0x011A]
try:
dpi = float(x_resolution[0]) / x_resolution[1]
except TypeError:
dpi = x_resolution
if math.isnan(dpi):
msg = "DPI is not a number"
raise ValueError(msg)
if resolution_unit == 3: # cm
# 1 dpcm = 2.54 dpi
dpi *= 2.54
self.info["dpi"] = dpi, dpi
except (
struct.error, # truncated EXIF
KeyError, # dpi not included
SyntaxError, # invalid/unreadable EXIF
TypeError, # dpi is an invalid float
ValueError, # dpi is an invalid float
ZeroDivisionError, # invalid dpi rational value
):
self.info["dpi"] = 72, 72
def _getmp(self) -> dict[int, Any] | None:
return _getmp(self)
def _getexif(self: JpegImageFile) -> dict[int, Any] | None:
if "exif" not in self.info:
return None
return self.getexif()._get_merged_dict()
def _getmp(self: JpegImageFile) -> dict[int, Any] | None:
# Extract MP information. This method was inspired by the "highly
# experimental" _getexif version that's been in use for years now,
# itself based on the ImageFileDirectory class in the TIFF plugin.
# The MP record essentially consists of a TIFF file embedded in a JPEG
# application marker.
try:
data = self.info["mp"]
except KeyError:
return None
file_contents = io.BytesIO(data)
head = file_contents.read(8)
endianness = ">" if head[:4] == b"\x4d\x4d\x00\x2a" else "<"
# process dictionary
from . import TiffImagePlugin
try:
info = TiffImagePlugin.ImageFileDirectory_v2(head)
file_contents.seek(info.next)
info.load(file_contents)
mp = dict(info)
except Exception as e:
msg = "malformed MP Index (unreadable directory)"
raise SyntaxError(msg) from e
# it's an error not to have a number of images
try:
quant = mp[0xB001]
except KeyError as e:
msg = "malformed MP Index (no number of images)"
raise SyntaxError(msg) from e
# get MP entries
mpentries = []
try:
rawmpentries = mp[0xB002]
for entrynum in range(0, quant):
unpackedentry = struct.unpack_from(
f"{endianness}LLLHH", rawmpentries, entrynum * 16
)
labels = ("Attribute", "Size", "DataOffset", "EntryNo1", "EntryNo2")
mpentry = dict(zip(labels, unpackedentry))
mpentryattr = {
"DependentParentImageFlag": bool(mpentry["Attribute"] & (1 << 31)),
"DependentChildImageFlag": bool(mpentry["Attribute"] & (1 << 30)),
"RepresentativeImageFlag": bool(mpentry["Attribute"] & (1 << 29)),
"Reserved": (mpentry["Attribute"] & (3 << 27)) >> 27,
"ImageDataFormat": (mpentry["Attribute"] & (7 << 24)) >> 24,
"MPType": mpentry["Attribute"] & 0x00FFFFFF,
}
if mpentryattr["ImageDataFormat"] == 0:
mpentryattr["ImageDataFormat"] = "JPEG"
else:
msg = "unsupported picture format in MPO"
raise SyntaxError(msg)
mptypemap = {
0x000000: "Undefined",
0x010001: "Large Thumbnail (VGA Equivalent)",
0x010002: "Large Thumbnail (Full HD Equivalent)",
0x020001: "Multi-Frame Image (Panorama)",
0x020002: "Multi-Frame Image: (Disparity)",
0x020003: "Multi-Frame Image: (Multi-Angle)",
0x030000: "Baseline MP Primary Image",
}
mpentryattr["MPType"] = mptypemap.get(mpentryattr["MPType"], "Unknown")
mpentry["Attribute"] = mpentryattr
mpentries.append(mpentry)
mp[0xB002] = mpentries
except KeyError as e:
msg = "malformed MP Index (bad MP Entry)"
raise SyntaxError(msg) from e
# Next we should try and parse the individual image unique ID list;
# we don't because I've never seen this actually used in a real MPO
# file and so can't test it.
return mp
# --------------------------------------------------------------------
# stuff to save JPEG files
RAWMODE = {
"1": "L",
"L": "L",
"RGB": "RGB",
"RGBX": "RGB",
"CMYK": "CMYK;I", # assume adobe conventions
"YCbCr": "YCbCr",
}
# fmt: off
zigzag_index = (
0, 1, 5, 6, 14, 15, 27, 28,
2, 4, 7, 13, 16, 26, 29, 42,
3, 8, 12, 17, 25, 30, 41, 43,
9, 11, 18, 24, 31, 40, 44, 53,
10, 19, 23, 32, 39, 45, 52, 54,
20, 22, 33, 38, 46, 51, 55, 60,
21, 34, 37, 47, 50, 56, 59, 61,
35, 36, 48, 49, 57, 58, 62, 63,
)
samplings = {
(1, 1, 1, 1, 1, 1): 0,
(2, 1, 1, 1, 1, 1): 1,
(2, 2, 1, 1, 1, 1): 2,
}
# fmt: on
def get_sampling(im: Image.Image) -> int:
# There's no subsampling when images have only 1 layer
# (grayscale images) or when they are CMYK (4 layers),
# so set subsampling to the default value.
#
# NOTE: currently Pillow can't encode JPEG to YCCK format.
# If YCCK support is added in the future, subsampling code will have
# to be updated (here and in JpegEncode.c) to deal with 4 layers.
if not isinstance(im, JpegImageFile) or im.layers in (1, 4):
return -1
sampling = im.layer[0][1:3] + im.layer[1][1:3] + im.layer[2][1:3]
return samplings.get(sampling, -1)
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
if im.width == 0 or im.height == 0:
msg = "cannot write empty image as JPEG"
raise ValueError(msg)
try:
rawmode = RAWMODE[im.mode]
except KeyError as e:
msg = f"cannot write mode {im.mode} as JPEG"
raise OSError(msg) from e
info = im.encoderinfo
dpi = [round(x) for x in info.get("dpi", (0, 0))]
quality = info.get("quality", -1)
subsampling = info.get("subsampling", -1)
qtables = info.get("qtables")
if quality == "keep":
quality = -1
subsampling = "keep"
qtables = "keep"
elif quality in presets:
preset = presets[quality]
quality = -1
subsampling = preset.get("subsampling", -1)
qtables = preset.get("quantization")
elif not isinstance(quality, int):
msg = "Invalid quality setting"
raise ValueError(msg)
else:
if subsampling in presets:
subsampling = presets[subsampling].get("subsampling", -1)
if isinstance(qtables, str) and qtables in presets:
qtables = presets[qtables].get("quantization")
if subsampling == "4:4:4":
subsampling = 0
elif subsampling == "4:2:2":
subsampling = 1
elif subsampling == "4:2:0":
subsampling = 2
elif subsampling == "4:1:1":
# For compatibility. Before Pillow 4.3, 4:1:1 actually meant 4:2:0.
# Set 4:2:0 if someone is still using that value.
subsampling = 2
elif subsampling == "keep":
if im.format != "JPEG":
msg = "Cannot use 'keep' when original image is not a JPEG"
raise ValueError(msg)
subsampling = get_sampling(im)
def validate_qtables(
qtables: (
str | tuple[list[int], ...] | list[list[int]] | dict[int, list[int]] | None
)
) -> list[list[int]] | None:
if qtables is None:
return qtables
if isinstance(qtables, str):
try:
lines = [
int(num)
for line in qtables.splitlines()
for num in line.split("#", 1)[0].split()
]
except ValueError as e:
msg = "Invalid quantization table"
raise ValueError(msg) from e
else:
qtables = [lines[s : s + 64] for s in range(0, len(lines), 64)]
if isinstance(qtables, (tuple, list, dict)):
if isinstance(qtables, dict):
qtables = [
qtables[key] for key in range(len(qtables)) if key in qtables
]
elif isinstance(qtables, tuple):
qtables = list(qtables)
if not (0 < len(qtables) < 5):
msg = "None or too many quantization tables"
raise ValueError(msg)
for idx, table in enumerate(qtables):
try:
if len(table) != 64:
msg = "Invalid quantization table"
raise TypeError(msg)
table_array = array.array("H", table)
except TypeError as e:
msg = "Invalid quantization table"
raise ValueError(msg) from e
else:
qtables[idx] = list(table_array)
return qtables
if qtables == "keep":
if im.format != "JPEG":
msg = "Cannot use 'keep' when original image is not a JPEG"
raise ValueError(msg)
qtables = getattr(im, "quantization", None)
qtables = validate_qtables(qtables)
extra = info.get("extra", b"")
MAX_BYTES_IN_MARKER = 65533
xmp = info.get("xmp", im.info.get("xmp"))
if xmp:
overhead_len = 29 # b"http://ns.adobe.com/xap/1.0/\x00"
max_data_bytes_in_marker = MAX_BYTES_IN_MARKER - overhead_len
if len(xmp) > max_data_bytes_in_marker:
msg = "XMP data is too long"
raise ValueError(msg)
size = o16(2 + overhead_len + len(xmp))
extra += b"\xFF\xE1" + size + b"http://ns.adobe.com/xap/1.0/\x00" + xmp
icc_profile = info.get("icc_profile")
if icc_profile:
overhead_len = 14 # b"ICC_PROFILE\0" + o8(i) + o8(len(markers))
max_data_bytes_in_marker = MAX_BYTES_IN_MARKER - overhead_len
markers = []
while icc_profile:
markers.append(icc_profile[:max_data_bytes_in_marker])
icc_profile = icc_profile[max_data_bytes_in_marker:]
i = 1
for marker in markers:
size = o16(2 + overhead_len + len(marker))
extra += (
b"\xFF\xE2"
+ size
+ b"ICC_PROFILE\0"
+ o8(i)
+ o8(len(markers))
+ marker
)
i += 1
comment = info.get("comment", im.info.get("comment"))
# "progressive" is the official name, but older documentation
# says "progression"
# FIXME: issue a warning if the wrong form is used (post-1.1.7)
progressive = info.get("progressive", False) or info.get("progression", False)
optimize = info.get("optimize", False)
exif = info.get("exif", b"")
if isinstance(exif, Image.Exif):
exif = exif.tobytes()
if len(exif) > MAX_BYTES_IN_MARKER:
msg = "EXIF data is too long"
raise ValueError(msg)
# get keyword arguments
im.encoderconfig = (
quality,
progressive,
info.get("smooth", 0),
optimize,
info.get("keep_rgb", False),
info.get("streamtype", 0),
dpi[0],
dpi[1],
subsampling,
info.get("restart_marker_blocks", 0),
info.get("restart_marker_rows", 0),
qtables,
comment,
extra,
exif,
)
# if we optimize, libjpeg needs a buffer big enough to hold the whole image
# in a shot. Guessing on the size, at im.size bytes. (raw pixel size is
# channels*size, this is a value that's been used in a django patch.
# https://github.com/matthewwithanm/django-imagekit/issues/50
bufsize = 0
if optimize or progressive:
# CMYK can be bigger
if im.mode == "CMYK":
bufsize = 4 * im.size[0] * im.size[1]
# keep sets quality to -1, but the actual value may be high.
elif quality >= 95 or quality == -1:
bufsize = 2 * im.size[0] * im.size[1]
else:
bufsize = im.size[0] * im.size[1]
if exif:
bufsize += len(exif) + 5
if extra:
bufsize += len(extra) + 1
else:
# The EXIF info needs to be written as one block, + APP1, + one spare byte.
# Ensure that our buffer is big enough. Same with the icc_profile block.
bufsize = max(bufsize, len(exif) + 5, len(extra) + 1)
ImageFile._save(
im, fp, [ImageFile._Tile("jpeg", (0, 0) + im.size, 0, rawmode)], bufsize
)
def _save_cjpeg(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
# ALTERNATIVE: handle JPEGs via the IJG command line utilities.
tempfile = im._dump()
subprocess.check_call(["cjpeg", "-outfile", filename, tempfile])
try:
os.unlink(tempfile)
except OSError:
pass
##
# Factory for making JPEG and MPO instances
def jpeg_factory(
fp: IO[bytes], filename: str | bytes | None = None
) -> JpegImageFile | MpoImageFile:
im = JpegImageFile(fp, filename)
try:
mpheader = im._getmp()
if mpheader is not None and mpheader[45057] > 1:
for segment, content in im.applist:
if segment == "APP1" and b' hdrgm:Version="' in content:
# Ultra HDR images are not yet supported
return im
# It's actually an MPO
from .MpoImagePlugin import MpoImageFile
# Don't reload everything, just convert it.
im = MpoImageFile.adopt(im, mpheader)
except (TypeError, IndexError):
# It is really a JPEG
pass
except SyntaxError:
warnings.warn(
"Image appears to be a malformed MPO file, it will be "
"interpreted as a base JPEG file"
)
return im
# ---------------------------------------------------------------------
# Registry stuff
Image.register_open(JpegImageFile.format, jpeg_factory, _accept)
Image.register_save(JpegImageFile.format, _save)
Image.register_extensions(JpegImageFile.format, [".jfif", ".jpe", ".jpg", ".jpeg"])
Image.register_mime(JpegImageFile.format, "image/jpeg")

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"""
JPEG quality settings equivalent to the Photoshop settings.
Can be used when saving JPEG files.
The following presets are available by default:
``web_low``, ``web_medium``, ``web_high``, ``web_very_high``, ``web_maximum``,
``low``, ``medium``, ``high``, ``maximum``.
More presets can be added to the :py:data:`presets` dict if needed.
To apply the preset, specify::
quality="preset_name"
To apply only the quantization table::
qtables="preset_name"
To apply only the subsampling setting::
subsampling="preset_name"
Example::
im.save("image_name.jpg", quality="web_high")
Subsampling
-----------
Subsampling is the practice of encoding images by implementing less resolution
for chroma information than for luma information.
(ref.: https://en.wikipedia.org/wiki/Chroma_subsampling)
Possible subsampling values are 0, 1 and 2 that correspond to 4:4:4, 4:2:2 and
4:2:0.
You can get the subsampling of a JPEG with the
:func:`.JpegImagePlugin.get_sampling` function.
In JPEG compressed data a JPEG marker is used instead of an EXIF tag.
(ref.: https://exiv2.org/tags.html)
Quantization tables
-------------------
They are values use by the DCT (Discrete cosine transform) to remove
*unnecessary* information from the image (the lossy part of the compression).
(ref.: https://en.wikipedia.org/wiki/Quantization_matrix#Quantization_matrices,
https://en.wikipedia.org/wiki/JPEG#Quantization)
You can get the quantization tables of a JPEG with::
im.quantization
This will return a dict with a number of lists. You can pass this dict
directly as the qtables argument when saving a JPEG.
The quantization table format in presets is a list with sublists. These formats
are interchangeable.
Libjpeg ref.:
https://web.archive.org/web/20120328125543/http://www.jpegcameras.com/libjpeg/libjpeg-3.html
"""
from __future__ import annotations
# fmt: off
presets = {
'web_low': {'subsampling': 2, # "4:2:0"
'quantization': [
[20, 16, 25, 39, 50, 46, 62, 68,
16, 18, 23, 38, 38, 53, 65, 68,
25, 23, 31, 38, 53, 65, 68, 68,
39, 38, 38, 53, 65, 68, 68, 68,
50, 38, 53, 65, 68, 68, 68, 68,
46, 53, 65, 68, 68, 68, 68, 68,
62, 65, 68, 68, 68, 68, 68, 68,
68, 68, 68, 68, 68, 68, 68, 68],
[21, 25, 32, 38, 54, 68, 68, 68,
25, 28, 24, 38, 54, 68, 68, 68,
32, 24, 32, 43, 66, 68, 68, 68,
38, 38, 43, 53, 68, 68, 68, 68,
54, 54, 66, 68, 68, 68, 68, 68,
68, 68, 68, 68, 68, 68, 68, 68,
68, 68, 68, 68, 68, 68, 68, 68,
68, 68, 68, 68, 68, 68, 68, 68]
]},
'web_medium': {'subsampling': 2, # "4:2:0"
'quantization': [
[16, 11, 11, 16, 23, 27, 31, 30,
11, 12, 12, 15, 20, 23, 23, 30,
11, 12, 13, 16, 23, 26, 35, 47,
16, 15, 16, 23, 26, 37, 47, 64,
23, 20, 23, 26, 39, 51, 64, 64,
27, 23, 26, 37, 51, 64, 64, 64,
31, 23, 35, 47, 64, 64, 64, 64,
30, 30, 47, 64, 64, 64, 64, 64],
[17, 15, 17, 21, 20, 26, 38, 48,
15, 19, 18, 17, 20, 26, 35, 43,
17, 18, 20, 22, 26, 30, 46, 53,
21, 17, 22, 28, 30, 39, 53, 64,
20, 20, 26, 30, 39, 48, 64, 64,
26, 26, 30, 39, 48, 63, 64, 64,
38, 35, 46, 53, 64, 64, 64, 64,
48, 43, 53, 64, 64, 64, 64, 64]
]},
'web_high': {'subsampling': 0, # "4:4:4"
'quantization': [
[6, 4, 4, 6, 9, 11, 12, 16,
4, 5, 5, 6, 8, 10, 12, 12,
4, 5, 5, 6, 10, 12, 14, 19,
6, 6, 6, 11, 12, 15, 19, 28,
9, 8, 10, 12, 16, 20, 27, 31,
11, 10, 12, 15, 20, 27, 31, 31,
12, 12, 14, 19, 27, 31, 31, 31,
16, 12, 19, 28, 31, 31, 31, 31],
[7, 7, 13, 24, 26, 31, 31, 31,
7, 12, 16, 21, 31, 31, 31, 31,
13, 16, 17, 31, 31, 31, 31, 31,
24, 21, 31, 31, 31, 31, 31, 31,
26, 31, 31, 31, 31, 31, 31, 31,
31, 31, 31, 31, 31, 31, 31, 31,
31, 31, 31, 31, 31, 31, 31, 31,
31, 31, 31, 31, 31, 31, 31, 31]
]},
'web_very_high': {'subsampling': 0, # "4:4:4"
'quantization': [
[2, 2, 2, 2, 3, 4, 5, 6,
2, 2, 2, 2, 3, 4, 5, 6,
2, 2, 2, 2, 4, 5, 7, 9,
2, 2, 2, 4, 5, 7, 9, 12,
3, 3, 4, 5, 8, 10, 12, 12,
4, 4, 5, 7, 10, 12, 12, 12,
5, 5, 7, 9, 12, 12, 12, 12,
6, 6, 9, 12, 12, 12, 12, 12],
[3, 3, 5, 9, 13, 15, 15, 15,
3, 4, 6, 11, 14, 12, 12, 12,
5, 6, 9, 14, 12, 12, 12, 12,
9, 11, 14, 12, 12, 12, 12, 12,
13, 14, 12, 12, 12, 12, 12, 12,
15, 12, 12, 12, 12, 12, 12, 12,
15, 12, 12, 12, 12, 12, 12, 12,
15, 12, 12, 12, 12, 12, 12, 12]
]},
'web_maximum': {'subsampling': 0, # "4:4:4"
'quantization': [
[1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 2,
1, 1, 1, 1, 1, 1, 2, 2,
1, 1, 1, 1, 1, 2, 2, 3,
1, 1, 1, 1, 2, 2, 3, 3,
1, 1, 1, 2, 2, 3, 3, 3,
1, 1, 2, 2, 3, 3, 3, 3],
[1, 1, 1, 2, 2, 3, 3, 3,
1, 1, 1, 2, 3, 3, 3, 3,
1, 1, 1, 3, 3, 3, 3, 3,
2, 2, 3, 3, 3, 3, 3, 3,
2, 3, 3, 3, 3, 3, 3, 3,
3, 3, 3, 3, 3, 3, 3, 3,
3, 3, 3, 3, 3, 3, 3, 3,
3, 3, 3, 3, 3, 3, 3, 3]
]},
'low': {'subsampling': 2, # "4:2:0"
'quantization': [
[18, 14, 14, 21, 30, 35, 34, 17,
14, 16, 16, 19, 26, 23, 12, 12,
14, 16, 17, 21, 23, 12, 12, 12,
21, 19, 21, 23, 12, 12, 12, 12,
30, 26, 23, 12, 12, 12, 12, 12,
35, 23, 12, 12, 12, 12, 12, 12,
34, 12, 12, 12, 12, 12, 12, 12,
17, 12, 12, 12, 12, 12, 12, 12],
[20, 19, 22, 27, 20, 20, 17, 17,
19, 25, 23, 14, 14, 12, 12, 12,
22, 23, 14, 14, 12, 12, 12, 12,
27, 14, 14, 12, 12, 12, 12, 12,
20, 14, 12, 12, 12, 12, 12, 12,
20, 12, 12, 12, 12, 12, 12, 12,
17, 12, 12, 12, 12, 12, 12, 12,
17, 12, 12, 12, 12, 12, 12, 12]
]},
'medium': {'subsampling': 2, # "4:2:0"
'quantization': [
[12, 8, 8, 12, 17, 21, 24, 17,
8, 9, 9, 11, 15, 19, 12, 12,
8, 9, 10, 12, 19, 12, 12, 12,
12, 11, 12, 21, 12, 12, 12, 12,
17, 15, 19, 12, 12, 12, 12, 12,
21, 19, 12, 12, 12, 12, 12, 12,
24, 12, 12, 12, 12, 12, 12, 12,
17, 12, 12, 12, 12, 12, 12, 12],
[13, 11, 13, 16, 20, 20, 17, 17,
11, 14, 14, 14, 14, 12, 12, 12,
13, 14, 14, 14, 12, 12, 12, 12,
16, 14, 14, 12, 12, 12, 12, 12,
20, 14, 12, 12, 12, 12, 12, 12,
20, 12, 12, 12, 12, 12, 12, 12,
17, 12, 12, 12, 12, 12, 12, 12,
17, 12, 12, 12, 12, 12, 12, 12]
]},
'high': {'subsampling': 0, # "4:4:4"
'quantization': [
[6, 4, 4, 6, 9, 11, 12, 16,
4, 5, 5, 6, 8, 10, 12, 12,
4, 5, 5, 6, 10, 12, 12, 12,
6, 6, 6, 11, 12, 12, 12, 12,
9, 8, 10, 12, 12, 12, 12, 12,
11, 10, 12, 12, 12, 12, 12, 12,
12, 12, 12, 12, 12, 12, 12, 12,
16, 12, 12, 12, 12, 12, 12, 12],
[7, 7, 13, 24, 20, 20, 17, 17,
7, 12, 16, 14, 14, 12, 12, 12,
13, 16, 14, 14, 12, 12, 12, 12,
24, 14, 14, 12, 12, 12, 12, 12,
20, 14, 12, 12, 12, 12, 12, 12,
20, 12, 12, 12, 12, 12, 12, 12,
17, 12, 12, 12, 12, 12, 12, 12,
17, 12, 12, 12, 12, 12, 12, 12]
]},
'maximum': {'subsampling': 0, # "4:4:4"
'quantization': [
[2, 2, 2, 2, 3, 4, 5, 6,
2, 2, 2, 2, 3, 4, 5, 6,
2, 2, 2, 2, 4, 5, 7, 9,
2, 2, 2, 4, 5, 7, 9, 12,
3, 3, 4, 5, 8, 10, 12, 12,
4, 4, 5, 7, 10, 12, 12, 12,
5, 5, 7, 9, 12, 12, 12, 12,
6, 6, 9, 12, 12, 12, 12, 12],
[3, 3, 5, 9, 13, 15, 15, 15,
3, 4, 6, 10, 14, 12, 12, 12,
5, 6, 9, 14, 12, 12, 12, 12,
9, 10, 14, 12, 12, 12, 12, 12,
13, 14, 12, 12, 12, 12, 12, 12,
15, 12, 12, 12, 12, 12, 12, 12,
15, 12, 12, 12, 12, 12, 12, 12,
15, 12, 12, 12, 12, 12, 12, 12]
]},
}
# fmt: on

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#
# The Python Imaging Library.
# $Id$
#
# Basic McIdas support for PIL
#
# History:
# 1997-05-05 fl Created (8-bit images only)
# 2009-03-08 fl Added 16/32-bit support.
#
# Thanks to Richard Jones and Craig Swank for specs and samples.
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1997.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import struct
from . import Image, ImageFile
def _accept(prefix: bytes) -> bool:
return prefix[:8] == b"\x00\x00\x00\x00\x00\x00\x00\x04"
##
# Image plugin for McIdas area images.
class McIdasImageFile(ImageFile.ImageFile):
format = "MCIDAS"
format_description = "McIdas area file"
def _open(self) -> None:
# parse area file directory
assert self.fp is not None
s = self.fp.read(256)
if not _accept(s) or len(s) != 256:
msg = "not an McIdas area file"
raise SyntaxError(msg)
self.area_descriptor_raw = s
self.area_descriptor = w = [0] + list(struct.unpack("!64i", s))
# get mode
if w[11] == 1:
mode = rawmode = "L"
elif w[11] == 2:
# FIXME: add memory map support
mode = "I"
rawmode = "I;16B"
elif w[11] == 4:
# FIXME: add memory map support
mode = "I"
rawmode = "I;32B"
else:
msg = "unsupported McIdas format"
raise SyntaxError(msg)
self._mode = mode
self._size = w[10], w[9]
offset = w[34] + w[15]
stride = w[15] + w[10] * w[11] * w[14]
self.tile = [
ImageFile._Tile("raw", (0, 0) + self.size, offset, (rawmode, stride, 1))
]
# --------------------------------------------------------------------
# registry
Image.register_open(McIdasImageFile.format, McIdasImageFile, _accept)
# no default extension

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#
# The Python Imaging Library.
# $Id$
#
# Microsoft Image Composer support for PIL
#
# Notes:
# uses TiffImagePlugin.py to read the actual image streams
#
# History:
# 97-01-20 fl Created
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1997.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import olefile
from . import Image, TiffImagePlugin
#
# --------------------------------------------------------------------
def _accept(prefix: bytes) -> bool:
return prefix[:8] == olefile.MAGIC
##
# Image plugin for Microsoft's Image Composer file format.
class MicImageFile(TiffImagePlugin.TiffImageFile):
format = "MIC"
format_description = "Microsoft Image Composer"
_close_exclusive_fp_after_loading = False
def _open(self) -> None:
# read the OLE directory and see if this is a likely
# to be a Microsoft Image Composer file
try:
self.ole = olefile.OleFileIO(self.fp)
except OSError as e:
msg = "not an MIC file; invalid OLE file"
raise SyntaxError(msg) from e
# find ACI subfiles with Image members (maybe not the
# best way to identify MIC files, but what the... ;-)
self.images = [
path
for path in self.ole.listdir()
if path[1:] and path[0][-4:] == ".ACI" and path[1] == "Image"
]
# if we didn't find any images, this is probably not
# an MIC file.
if not self.images:
msg = "not an MIC file; no image entries"
raise SyntaxError(msg)
self.frame = -1
self._n_frames = len(self.images)
self.is_animated = self._n_frames > 1
self.__fp = self.fp
self.seek(0)
def seek(self, frame: int) -> None:
if not self._seek_check(frame):
return
try:
filename = self.images[frame]
except IndexError as e:
msg = "no such frame"
raise EOFError(msg) from e
self.fp = self.ole.openstream(filename)
TiffImagePlugin.TiffImageFile._open(self)
self.frame = frame
def tell(self) -> int:
return self.frame
def close(self) -> None:
self.__fp.close()
self.ole.close()
super().close()
def __exit__(self, *args: object) -> None:
self.__fp.close()
self.ole.close()
super().__exit__()
#
# --------------------------------------------------------------------
Image.register_open(MicImageFile.format, MicImageFile, _accept)
Image.register_extension(MicImageFile.format, ".mic")

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#
# The Python Imaging Library.
# $Id$
#
# MPEG file handling
#
# History:
# 95-09-09 fl Created
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1995.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from . import Image, ImageFile
from ._binary import i8
from ._typing import SupportsRead
#
# Bitstream parser
class BitStream:
def __init__(self, fp: SupportsRead[bytes]) -> None:
self.fp = fp
self.bits = 0
self.bitbuffer = 0
def next(self) -> int:
return i8(self.fp.read(1))
def peek(self, bits: int) -> int:
while self.bits < bits:
c = self.next()
if c < 0:
self.bits = 0
continue
self.bitbuffer = (self.bitbuffer << 8) + c
self.bits += 8
return self.bitbuffer >> (self.bits - bits) & (1 << bits) - 1
def skip(self, bits: int) -> None:
while self.bits < bits:
self.bitbuffer = (self.bitbuffer << 8) + i8(self.fp.read(1))
self.bits += 8
self.bits = self.bits - bits
def read(self, bits: int) -> int:
v = self.peek(bits)
self.bits = self.bits - bits
return v
def _accept(prefix: bytes) -> bool:
return prefix[:4] == b"\x00\x00\x01\xb3"
##
# Image plugin for MPEG streams. This plugin can identify a stream,
# but it cannot read it.
class MpegImageFile(ImageFile.ImageFile):
format = "MPEG"
format_description = "MPEG"
def _open(self) -> None:
assert self.fp is not None
s = BitStream(self.fp)
if s.read(32) != 0x1B3:
msg = "not an MPEG file"
raise SyntaxError(msg)
self._mode = "RGB"
self._size = s.read(12), s.read(12)
# --------------------------------------------------------------------
# Registry stuff
Image.register_open(MpegImageFile.format, MpegImageFile, _accept)
Image.register_extensions(MpegImageFile.format, [".mpg", ".mpeg"])
Image.register_mime(MpegImageFile.format, "video/mpeg")

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#
# The Python Imaging Library.
# $Id$
#
# MPO file handling
#
# See "Multi-Picture Format" (CIPA DC-007-Translation 2009, Standard of the
# Camera & Imaging Products Association)
#
# The multi-picture object combines multiple JPEG images (with a modified EXIF
# data format) into a single file. While it can theoretically be used much like
# a GIF animation, it is commonly used to represent 3D photographs and is (as
# of this writing) the most commonly used format by 3D cameras.
#
# History:
# 2014-03-13 Feneric Created
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import itertools
import os
import struct
from typing import IO, Any, cast
from . import (
Image,
ImageFile,
ImageSequence,
JpegImagePlugin,
TiffImagePlugin,
)
from ._binary import o32le
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
JpegImagePlugin._save(im, fp, filename)
def _save_all(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
append_images = im.encoderinfo.get("append_images", [])
if not append_images and not getattr(im, "is_animated", False):
_save(im, fp, filename)
return
mpf_offset = 28
offsets: list[int] = []
for imSequence in itertools.chain([im], append_images):
for im_frame in ImageSequence.Iterator(imSequence):
if not offsets:
# APP2 marker
im_frame.encoderinfo["extra"] = (
b"\xFF\xE2" + struct.pack(">H", 6 + 82) + b"MPF\0" + b" " * 82
)
exif = im_frame.encoderinfo.get("exif")
if isinstance(exif, Image.Exif):
exif = exif.tobytes()
im_frame.encoderinfo["exif"] = exif
if exif:
mpf_offset += 4 + len(exif)
JpegImagePlugin._save(im_frame, fp, filename)
offsets.append(fp.tell())
else:
im_frame.save(fp, "JPEG")
offsets.append(fp.tell() - offsets[-1])
ifd = TiffImagePlugin.ImageFileDirectory_v2()
ifd[0xB000] = b"0100"
ifd[0xB001] = len(offsets)
mpentries = b""
data_offset = 0
for i, size in enumerate(offsets):
if i == 0:
mptype = 0x030000 # Baseline MP Primary Image
else:
mptype = 0x000000 # Undefined
mpentries += struct.pack("<LLLHH", mptype, size, data_offset, 0, 0)
if i == 0:
data_offset -= mpf_offset
data_offset += size
ifd[0xB002] = mpentries
fp.seek(mpf_offset)
fp.write(b"II\x2A\x00" + o32le(8) + ifd.tobytes(8))
fp.seek(0, os.SEEK_END)
##
# Image plugin for MPO images.
class MpoImageFile(JpegImagePlugin.JpegImageFile):
format = "MPO"
format_description = "MPO (CIPA DC-007)"
_close_exclusive_fp_after_loading = False
def _open(self) -> None:
self.fp.seek(0) # prep the fp in order to pass the JPEG test
JpegImagePlugin.JpegImageFile._open(self)
self._after_jpeg_open()
def _after_jpeg_open(self, mpheader: dict[int, Any] | None = None) -> None:
self.mpinfo = mpheader if mpheader is not None else self._getmp()
if self.mpinfo is None:
msg = "Image appears to be a malformed MPO file"
raise ValueError(msg)
self.n_frames = self.mpinfo[0xB001]
self.__mpoffsets = [
mpent["DataOffset"] + self.info["mpoffset"] for mpent in self.mpinfo[0xB002]
]
self.__mpoffsets[0] = 0
# Note that the following assertion will only be invalid if something
# gets broken within JpegImagePlugin.
assert self.n_frames == len(self.__mpoffsets)
del self.info["mpoffset"] # no longer needed
self.is_animated = self.n_frames > 1
self._fp = self.fp # FIXME: hack
self._fp.seek(self.__mpoffsets[0]) # get ready to read first frame
self.__frame = 0
self.offset = 0
# for now we can only handle reading and individual frame extraction
self.readonly = 1
def load_seek(self, pos: int) -> None:
self._fp.seek(pos)
def seek(self, frame: int) -> None:
if not self._seek_check(frame):
return
self.fp = self._fp
self.offset = self.__mpoffsets[frame]
original_exif = self.info.get("exif")
if "exif" in self.info:
del self.info["exif"]
self.fp.seek(self.offset + 2) # skip SOI marker
if not self.fp.read(2):
msg = "No data found for frame"
raise ValueError(msg)
self.fp.seek(self.offset)
JpegImagePlugin.JpegImageFile._open(self)
if self.info.get("exif") != original_exif:
self._reload_exif()
self.tile = [
ImageFile._Tile("jpeg", (0, 0) + self.size, self.offset, self.tile[0][-1])
]
self.__frame = frame
def tell(self) -> int:
return self.__frame
@staticmethod
def adopt(
jpeg_instance: JpegImagePlugin.JpegImageFile,
mpheader: dict[int, Any] | None = None,
) -> MpoImageFile:
"""
Transform the instance of JpegImageFile into
an instance of MpoImageFile.
After the call, the JpegImageFile is extended
to be an MpoImageFile.
This is essentially useful when opening a JPEG
file that reveals itself as an MPO, to avoid
double call to _open.
"""
jpeg_instance.__class__ = MpoImageFile
mpo_instance = cast(MpoImageFile, jpeg_instance)
mpo_instance._after_jpeg_open(mpheader)
return mpo_instance
# ---------------------------------------------------------------------
# Registry stuff
# Note that since MPO shares a factory with JPEG, we do not need to do a
# separate registration for it here.
# Image.register_open(MpoImageFile.format,
# JpegImagePlugin.jpeg_factory, _accept)
Image.register_save(MpoImageFile.format, _save)
Image.register_save_all(MpoImageFile.format, _save_all)
Image.register_extension(MpoImageFile.format, ".mpo")
Image.register_mime(MpoImageFile.format, "image/mpo")

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#
# The Python Imaging Library.
#
# MSP file handling
#
# This is the format used by the Paint program in Windows 1 and 2.
#
# History:
# 95-09-05 fl Created
# 97-01-03 fl Read/write MSP images
# 17-02-21 es Fixed RLE interpretation
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1995-97.
# Copyright (c) Eric Soroos 2017.
#
# See the README file for information on usage and redistribution.
#
# More info on this format: https://archive.org/details/gg243631
# Page 313:
# Figure 205. Windows Paint Version 1: "DanM" Format
# Figure 206. Windows Paint Version 2: "LinS" Format. Used in Windows V2.03
#
# See also: https://www.fileformat.info/format/mspaint/egff.htm
from __future__ import annotations
import io
import struct
from typing import IO
from . import Image, ImageFile
from ._binary import i16le as i16
from ._binary import o16le as o16
#
# read MSP files
def _accept(prefix: bytes) -> bool:
return prefix[:4] in [b"DanM", b"LinS"]
##
# Image plugin for Windows MSP images. This plugin supports both
# uncompressed (Windows 1.0).
class MspImageFile(ImageFile.ImageFile):
format = "MSP"
format_description = "Windows Paint"
def _open(self) -> None:
# Header
assert self.fp is not None
s = self.fp.read(32)
if not _accept(s):
msg = "not an MSP file"
raise SyntaxError(msg)
# Header checksum
checksum = 0
for i in range(0, 32, 2):
checksum = checksum ^ i16(s, i)
if checksum != 0:
msg = "bad MSP checksum"
raise SyntaxError(msg)
self._mode = "1"
self._size = i16(s, 4), i16(s, 6)
if s[:4] == b"DanM":
self.tile = [ImageFile._Tile("raw", (0, 0) + self.size, 32, ("1", 0, 1))]
else:
self.tile = [ImageFile._Tile("MSP", (0, 0) + self.size, 32, None)]
class MspDecoder(ImageFile.PyDecoder):
# The algo for the MSP decoder is from
# https://www.fileformat.info/format/mspaint/egff.htm
# cc-by-attribution -- That page references is taken from the
# Encyclopedia of Graphics File Formats and is licensed by
# O'Reilly under the Creative Common/Attribution license
#
# For RLE encoded files, the 32byte header is followed by a scan
# line map, encoded as one 16bit word of encoded byte length per
# line.
#
# NOTE: the encoded length of the line can be 0. This was not
# handled in the previous version of this encoder, and there's no
# mention of how to handle it in the documentation. From the few
# examples I've seen, I've assumed that it is a fill of the
# background color, in this case, white.
#
#
# Pseudocode of the decoder:
# Read a BYTE value as the RunType
# If the RunType value is zero
# Read next byte as the RunCount
# Read the next byte as the RunValue
# Write the RunValue byte RunCount times
# If the RunType value is non-zero
# Use this value as the RunCount
# Read and write the next RunCount bytes literally
#
# e.g.:
# 0x00 03 ff 05 00 01 02 03 04
# would yield the bytes:
# 0xff ff ff 00 01 02 03 04
#
# which are then interpreted as a bit packed mode '1' image
_pulls_fd = True
def decode(self, buffer: bytes | Image.SupportsArrayInterface) -> tuple[int, int]:
assert self.fd is not None
img = io.BytesIO()
blank_line = bytearray((0xFF,) * ((self.state.xsize + 7) // 8))
try:
self.fd.seek(32)
rowmap = struct.unpack_from(
f"<{self.state.ysize}H", self.fd.read(self.state.ysize * 2)
)
except struct.error as e:
msg = "Truncated MSP file in row map"
raise OSError(msg) from e
for x, rowlen in enumerate(rowmap):
try:
if rowlen == 0:
img.write(blank_line)
continue
row = self.fd.read(rowlen)
if len(row) != rowlen:
msg = f"Truncated MSP file, expected {rowlen} bytes on row {x}"
raise OSError(msg)
idx = 0
while idx < rowlen:
runtype = row[idx]
idx += 1
if runtype == 0:
(runcount, runval) = struct.unpack_from("Bc", row, idx)
img.write(runval * runcount)
idx += 2
else:
runcount = runtype
img.write(row[idx : idx + runcount])
idx += runcount
except struct.error as e:
msg = f"Corrupted MSP file in row {x}"
raise OSError(msg) from e
self.set_as_raw(img.getvalue(), "1")
return -1, 0
Image.register_decoder("MSP", MspDecoder)
#
# write MSP files (uncompressed only)
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
if im.mode != "1":
msg = f"cannot write mode {im.mode} as MSP"
raise OSError(msg)
# create MSP header
header = [0] * 16
header[0], header[1] = i16(b"Da"), i16(b"nM") # version 1
header[2], header[3] = im.size
header[4], header[5] = 1, 1
header[6], header[7] = 1, 1
header[8], header[9] = im.size
checksum = 0
for h in header:
checksum = checksum ^ h
header[12] = checksum # FIXME: is this the right field?
# header
for h in header:
fp.write(o16(h))
# image body
ImageFile._save(im, fp, [ImageFile._Tile("raw", (0, 0) + im.size, 32, ("1", 0, 1))])
#
# registry
Image.register_open(MspImageFile.format, MspImageFile, _accept)
Image.register_save(MspImageFile.format, _save)
Image.register_extension(MspImageFile.format, ".msp")

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#
# The Python Imaging Library
# $Id$
#
# Simple PostScript graphics interface
#
# History:
# 1996-04-20 fl Created
# 1999-01-10 fl Added gsave/grestore to image method
# 2005-05-04 fl Fixed floating point issue in image (from Eric Etheridge)
#
# Copyright (c) 1997-2005 by Secret Labs AB. All rights reserved.
# Copyright (c) 1996 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import sys
from typing import IO, TYPE_CHECKING
from . import EpsImagePlugin
##
# Simple PostScript graphics interface.
class PSDraw:
"""
Sets up printing to the given file. If ``fp`` is omitted,
``sys.stdout.buffer`` is assumed.
"""
def __init__(self, fp: IO[bytes] | None = None) -> None:
if not fp:
fp = sys.stdout.buffer
self.fp = fp
def begin_document(self, id: str | None = None) -> None:
"""Set up printing of a document. (Write PostScript DSC header.)"""
# FIXME: incomplete
self.fp.write(
b"%!PS-Adobe-3.0\n"
b"save\n"
b"/showpage { } def\n"
b"%%EndComments\n"
b"%%BeginDocument\n"
)
# self.fp.write(ERROR_PS) # debugging!
self.fp.write(EDROFF_PS)
self.fp.write(VDI_PS)
self.fp.write(b"%%EndProlog\n")
self.isofont: dict[bytes, int] = {}
def end_document(self) -> None:
"""Ends printing. (Write PostScript DSC footer.)"""
self.fp.write(b"%%EndDocument\nrestore showpage\n%%End\n")
if hasattr(self.fp, "flush"):
self.fp.flush()
def setfont(self, font: str, size: int) -> None:
"""
Selects which font to use.
:param font: A PostScript font name
:param size: Size in points.
"""
font_bytes = bytes(font, "UTF-8")
if font_bytes not in self.isofont:
# reencode font
self.fp.write(
b"/PSDraw-%s ISOLatin1Encoding /%s E\n" % (font_bytes, font_bytes)
)
self.isofont[font_bytes] = 1
# rough
self.fp.write(b"/F0 %d /PSDraw-%s F\n" % (size, font_bytes))
def line(self, xy0: tuple[int, int], xy1: tuple[int, int]) -> None:
"""
Draws a line between the two points. Coordinates are given in
PostScript point coordinates (72 points per inch, (0, 0) is the lower
left corner of the page).
"""
self.fp.write(b"%d %d %d %d Vl\n" % (*xy0, *xy1))
def rectangle(self, box: tuple[int, int, int, int]) -> None:
"""
Draws a rectangle.
:param box: A tuple of four integers, specifying left, bottom, width and
height.
"""
self.fp.write(b"%d %d M 0 %d %d Vr\n" % box)
def text(self, xy: tuple[int, int], text: str) -> None:
"""
Draws text at the given position. You must use
:py:meth:`~PIL.PSDraw.PSDraw.setfont` before calling this method.
"""
text_bytes = bytes(text, "UTF-8")
text_bytes = b"\\(".join(text_bytes.split(b"("))
text_bytes = b"\\)".join(text_bytes.split(b")"))
self.fp.write(b"%d %d M (%s) S\n" % (xy + (text_bytes,)))
if TYPE_CHECKING:
from . import Image
def image(
self, box: tuple[int, int, int, int], im: Image.Image, dpi: int | None = None
) -> None:
"""Draw a PIL image, centered in the given box."""
# default resolution depends on mode
if not dpi:
if im.mode == "1":
dpi = 200 # fax
else:
dpi = 100 # grayscale
# image size (on paper)
x = im.size[0] * 72 / dpi
y = im.size[1] * 72 / dpi
# max allowed size
xmax = float(box[2] - box[0])
ymax = float(box[3] - box[1])
if x > xmax:
y = y * xmax / x
x = xmax
if y > ymax:
x = x * ymax / y
y = ymax
dx = (xmax - x) / 2 + box[0]
dy = (ymax - y) / 2 + box[1]
self.fp.write(b"gsave\n%f %f translate\n" % (dx, dy))
if (x, y) != im.size:
# EpsImagePlugin._save prints the image at (0,0,xsize,ysize)
sx = x / im.size[0]
sy = y / im.size[1]
self.fp.write(b"%f %f scale\n" % (sx, sy))
EpsImagePlugin._save(im, self.fp, "", 0)
self.fp.write(b"\ngrestore\n")
# --------------------------------------------------------------------
# PostScript driver
#
# EDROFF.PS -- PostScript driver for Edroff 2
#
# History:
# 94-01-25 fl: created (edroff 2.04)
#
# Copyright (c) Fredrik Lundh 1994.
#
EDROFF_PS = b"""\
/S { show } bind def
/P { moveto show } bind def
/M { moveto } bind def
/X { 0 rmoveto } bind def
/Y { 0 exch rmoveto } bind def
/E { findfont
dup maxlength dict begin
{
1 index /FID ne { def } { pop pop } ifelse
} forall
/Encoding exch def
dup /FontName exch def
currentdict end definefont pop
} bind def
/F { findfont exch scalefont dup setfont
[ exch /setfont cvx ] cvx bind def
} bind def
"""
#
# VDI.PS -- PostScript driver for VDI meta commands
#
# History:
# 94-01-25 fl: created (edroff 2.04)
#
# Copyright (c) Fredrik Lundh 1994.
#
VDI_PS = b"""\
/Vm { moveto } bind def
/Va { newpath arcn stroke } bind def
/Vl { moveto lineto stroke } bind def
/Vc { newpath 0 360 arc closepath } bind def
/Vr { exch dup 0 rlineto
exch dup 0 exch rlineto
exch neg 0 rlineto
0 exch neg rlineto
setgray fill } bind def
/Tm matrix def
/Ve { Tm currentmatrix pop
translate scale newpath 0 0 .5 0 360 arc closepath
Tm setmatrix
} bind def
/Vf { currentgray exch setgray fill setgray } bind def
"""
#
# ERROR.PS -- Error handler
#
# History:
# 89-11-21 fl: created (pslist 1.10)
#
ERROR_PS = b"""\
/landscape false def
/errorBUF 200 string def
/errorNL { currentpoint 10 sub exch pop 72 exch moveto } def
errordict begin /handleerror {
initmatrix /Courier findfont 10 scalefont setfont
newpath 72 720 moveto $error begin /newerror false def
(PostScript Error) show errorNL errorNL
(Error: ) show
/errorname load errorBUF cvs show errorNL errorNL
(Command: ) show
/command load dup type /stringtype ne { errorBUF cvs } if show
errorNL errorNL
(VMstatus: ) show
vmstatus errorBUF cvs show ( bytes available, ) show
errorBUF cvs show ( bytes used at level ) show
errorBUF cvs show errorNL errorNL
(Operand stargck: ) show errorNL /ostargck load {
dup type /stringtype ne { errorBUF cvs } if 72 0 rmoveto show errorNL
} forall errorNL
(Execution stargck: ) show errorNL /estargck load {
dup type /stringtype ne { errorBUF cvs } if 72 0 rmoveto show errorNL
} forall
end showpage
} def end
"""

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#
# Python Imaging Library
# $Id$
#
# stuff to read simple, teragon-style palette files
#
# History:
# 97-08-23 fl Created
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1997.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from typing import IO
from ._binary import o8
class PaletteFile:
"""File handler for Teragon-style palette files."""
rawmode = "RGB"
def __init__(self, fp: IO[bytes]) -> None:
palette = [o8(i) * 3 for i in range(256)]
while True:
s = fp.readline()
if not s:
break
if s[:1] == b"#":
continue
if len(s) > 100:
msg = "bad palette file"
raise SyntaxError(msg)
v = [int(x) for x in s.split()]
try:
[i, r, g, b] = v
except ValueError:
[i, r] = v
g = b = r
if 0 <= i <= 255:
palette[i] = o8(r) + o8(g) + o8(b)
self.palette = b"".join(palette)
def getpalette(self) -> tuple[bytes, str]:
return self.palette, self.rawmode

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#
# The Python Imaging Library.
# $Id$
#
##
# Image plugin for Palm pixmap images (output only).
##
from __future__ import annotations
from typing import IO
from . import Image, ImageFile
from ._binary import o8
from ._binary import o16be as o16b
# fmt: off
_Palm8BitColormapValues = (
(255, 255, 255), (255, 204, 255), (255, 153, 255), (255, 102, 255),
(255, 51, 255), (255, 0, 255), (255, 255, 204), (255, 204, 204),
(255, 153, 204), (255, 102, 204), (255, 51, 204), (255, 0, 204),
(255, 255, 153), (255, 204, 153), (255, 153, 153), (255, 102, 153),
(255, 51, 153), (255, 0, 153), (204, 255, 255), (204, 204, 255),
(204, 153, 255), (204, 102, 255), (204, 51, 255), (204, 0, 255),
(204, 255, 204), (204, 204, 204), (204, 153, 204), (204, 102, 204),
(204, 51, 204), (204, 0, 204), (204, 255, 153), (204, 204, 153),
(204, 153, 153), (204, 102, 153), (204, 51, 153), (204, 0, 153),
(153, 255, 255), (153, 204, 255), (153, 153, 255), (153, 102, 255),
(153, 51, 255), (153, 0, 255), (153, 255, 204), (153, 204, 204),
(153, 153, 204), (153, 102, 204), (153, 51, 204), (153, 0, 204),
(153, 255, 153), (153, 204, 153), (153, 153, 153), (153, 102, 153),
(153, 51, 153), (153, 0, 153), (102, 255, 255), (102, 204, 255),
(102, 153, 255), (102, 102, 255), (102, 51, 255), (102, 0, 255),
(102, 255, 204), (102, 204, 204), (102, 153, 204), (102, 102, 204),
(102, 51, 204), (102, 0, 204), (102, 255, 153), (102, 204, 153),
(102, 153, 153), (102, 102, 153), (102, 51, 153), (102, 0, 153),
(51, 255, 255), (51, 204, 255), (51, 153, 255), (51, 102, 255),
(51, 51, 255), (51, 0, 255), (51, 255, 204), (51, 204, 204),
(51, 153, 204), (51, 102, 204), (51, 51, 204), (51, 0, 204),
(51, 255, 153), (51, 204, 153), (51, 153, 153), (51, 102, 153),
(51, 51, 153), (51, 0, 153), (0, 255, 255), (0, 204, 255),
(0, 153, 255), (0, 102, 255), (0, 51, 255), (0, 0, 255),
(0, 255, 204), (0, 204, 204), (0, 153, 204), (0, 102, 204),
(0, 51, 204), (0, 0, 204), (0, 255, 153), (0, 204, 153),
(0, 153, 153), (0, 102, 153), (0, 51, 153), (0, 0, 153),
(255, 255, 102), (255, 204, 102), (255, 153, 102), (255, 102, 102),
(255, 51, 102), (255, 0, 102), (255, 255, 51), (255, 204, 51),
(255, 153, 51), (255, 102, 51), (255, 51, 51), (255, 0, 51),
(255, 255, 0), (255, 204, 0), (255, 153, 0), (255, 102, 0),
(255, 51, 0), (255, 0, 0), (204, 255, 102), (204, 204, 102),
(204, 153, 102), (204, 102, 102), (204, 51, 102), (204, 0, 102),
(204, 255, 51), (204, 204, 51), (204, 153, 51), (204, 102, 51),
(204, 51, 51), (204, 0, 51), (204, 255, 0), (204, 204, 0),
(204, 153, 0), (204, 102, 0), (204, 51, 0), (204, 0, 0),
(153, 255, 102), (153, 204, 102), (153, 153, 102), (153, 102, 102),
(153, 51, 102), (153, 0, 102), (153, 255, 51), (153, 204, 51),
(153, 153, 51), (153, 102, 51), (153, 51, 51), (153, 0, 51),
(153, 255, 0), (153, 204, 0), (153, 153, 0), (153, 102, 0),
(153, 51, 0), (153, 0, 0), (102, 255, 102), (102, 204, 102),
(102, 153, 102), (102, 102, 102), (102, 51, 102), (102, 0, 102),
(102, 255, 51), (102, 204, 51), (102, 153, 51), (102, 102, 51),
(102, 51, 51), (102, 0, 51), (102, 255, 0), (102, 204, 0),
(102, 153, 0), (102, 102, 0), (102, 51, 0), (102, 0, 0),
(51, 255, 102), (51, 204, 102), (51, 153, 102), (51, 102, 102),
(51, 51, 102), (51, 0, 102), (51, 255, 51), (51, 204, 51),
(51, 153, 51), (51, 102, 51), (51, 51, 51), (51, 0, 51),
(51, 255, 0), (51, 204, 0), (51, 153, 0), (51, 102, 0),
(51, 51, 0), (51, 0, 0), (0, 255, 102), (0, 204, 102),
(0, 153, 102), (0, 102, 102), (0, 51, 102), (0, 0, 102),
(0, 255, 51), (0, 204, 51), (0, 153, 51), (0, 102, 51),
(0, 51, 51), (0, 0, 51), (0, 255, 0), (0, 204, 0),
(0, 153, 0), (0, 102, 0), (0, 51, 0), (17, 17, 17),
(34, 34, 34), (68, 68, 68), (85, 85, 85), (119, 119, 119),
(136, 136, 136), (170, 170, 170), (187, 187, 187), (221, 221, 221),
(238, 238, 238), (192, 192, 192), (128, 0, 0), (128, 0, 128),
(0, 128, 0), (0, 128, 128), (0, 0, 0), (0, 0, 0),
(0, 0, 0), (0, 0, 0), (0, 0, 0), (0, 0, 0),
(0, 0, 0), (0, 0, 0), (0, 0, 0), (0, 0, 0),
(0, 0, 0), (0, 0, 0), (0, 0, 0), (0, 0, 0),
(0, 0, 0), (0, 0, 0), (0, 0, 0), (0, 0, 0),
(0, 0, 0), (0, 0, 0), (0, 0, 0), (0, 0, 0),
(0, 0, 0), (0, 0, 0), (0, 0, 0), (0, 0, 0))
# fmt: on
# so build a prototype image to be used for palette resampling
def build_prototype_image() -> Image.Image:
image = Image.new("L", (1, len(_Palm8BitColormapValues)))
image.putdata(list(range(len(_Palm8BitColormapValues))))
palettedata: tuple[int, ...] = ()
for colormapValue in _Palm8BitColormapValues:
palettedata += colormapValue
palettedata += (0, 0, 0) * (256 - len(_Palm8BitColormapValues))
image.putpalette(palettedata)
return image
Palm8BitColormapImage = build_prototype_image()
# OK, we now have in Palm8BitColormapImage,
# a "P"-mode image with the right palette
#
# --------------------------------------------------------------------
_FLAGS = {"custom-colormap": 0x4000, "is-compressed": 0x8000, "has-transparent": 0x2000}
_COMPRESSION_TYPES = {"none": 0xFF, "rle": 0x01, "scanline": 0x00}
#
# --------------------------------------------------------------------
##
# (Internal) Image save plugin for the Palm format.
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
if im.mode == "P":
# we assume this is a color Palm image with the standard colormap,
# unless the "info" dict has a "custom-colormap" field
rawmode = "P"
bpp = 8
version = 1
elif im.mode == "L":
if im.encoderinfo.get("bpp") in (1, 2, 4):
# this is 8-bit grayscale, so we shift it to get the high-order bits,
# and invert it because
# Palm does grayscale from white (0) to black (1)
bpp = im.encoderinfo["bpp"]
maxval = (1 << bpp) - 1
shift = 8 - bpp
im = im.point(lambda x: maxval - (x >> shift))
elif im.info.get("bpp") in (1, 2, 4):
# here we assume that even though the inherent mode is 8-bit grayscale,
# only the lower bpp bits are significant.
# We invert them to match the Palm.
bpp = im.info["bpp"]
maxval = (1 << bpp) - 1
im = im.point(lambda x: maxval - (x & maxval))
else:
msg = f"cannot write mode {im.mode} as Palm"
raise OSError(msg)
# we ignore the palette here
im._mode = "P"
rawmode = f"P;{bpp}"
version = 1
elif im.mode == "1":
# monochrome -- write it inverted, as is the Palm standard
rawmode = "1;I"
bpp = 1
version = 0
else:
msg = f"cannot write mode {im.mode} as Palm"
raise OSError(msg)
#
# make sure image data is available
im.load()
# write header
cols = im.size[0]
rows = im.size[1]
rowbytes = int((cols + (16 // bpp - 1)) / (16 // bpp)) * 2
transparent_index = 0
compression_type = _COMPRESSION_TYPES["none"]
flags = 0
if im.mode == "P" and "custom-colormap" in im.info:
assert im.palette is not None
flags = flags & _FLAGS["custom-colormap"]
colormapsize = 4 * 256 + 2
colormapmode = im.palette.mode
colormap = im.getdata().getpalette()
else:
colormapsize = 0
if "offset" in im.info:
offset = (rowbytes * rows + 16 + 3 + colormapsize) // 4
else:
offset = 0
fp.write(o16b(cols) + o16b(rows) + o16b(rowbytes) + o16b(flags))
fp.write(o8(bpp))
fp.write(o8(version))
fp.write(o16b(offset))
fp.write(o8(transparent_index))
fp.write(o8(compression_type))
fp.write(o16b(0)) # reserved by Palm
# now write colormap if necessary
if colormapsize > 0:
fp.write(o16b(256))
for i in range(256):
fp.write(o8(i))
if colormapmode == "RGB":
fp.write(
o8(colormap[3 * i])
+ o8(colormap[3 * i + 1])
+ o8(colormap[3 * i + 2])
)
elif colormapmode == "RGBA":
fp.write(
o8(colormap[4 * i])
+ o8(colormap[4 * i + 1])
+ o8(colormap[4 * i + 2])
)
# now convert data to raw form
ImageFile._save(
im, fp, [ImageFile._Tile("raw", (0, 0) + im.size, 0, (rawmode, rowbytes, 1))]
)
if hasattr(fp, "flush"):
fp.flush()
#
# --------------------------------------------------------------------
Image.register_save("Palm", _save)
Image.register_extension("Palm", ".palm")
Image.register_mime("Palm", "image/palm")

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#
# The Python Imaging Library.
# $Id$
#
# PCD file handling
#
# History:
# 96-05-10 fl Created
# 96-05-27 fl Added draft mode (128x192, 256x384)
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1996.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from . import Image, ImageFile
##
# Image plugin for PhotoCD images. This plugin only reads the 768x512
# image from the file; higher resolutions are encoded in a proprietary
# encoding.
class PcdImageFile(ImageFile.ImageFile):
format = "PCD"
format_description = "Kodak PhotoCD"
def _open(self) -> None:
# rough
assert self.fp is not None
self.fp.seek(2048)
s = self.fp.read(2048)
if s[:4] != b"PCD_":
msg = "not a PCD file"
raise SyntaxError(msg)
orientation = s[1538] & 3
self.tile_post_rotate = None
if orientation == 1:
self.tile_post_rotate = 90
elif orientation == 3:
self.tile_post_rotate = -90
self._mode = "RGB"
self._size = 768, 512 # FIXME: not correct for rotated images!
self.tile = [ImageFile._Tile("pcd", (0, 0) + self.size, 96 * 2048, None)]
def load_end(self) -> None:
if self.tile_post_rotate:
# Handle rotated PCDs
self.im = self.im.rotate(self.tile_post_rotate)
self._size = self.im.size
#
# registry
Image.register_open(PcdImageFile.format, PcdImageFile)
Image.register_extension(PcdImageFile.format, ".pcd")

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#
# THIS IS WORK IN PROGRESS
#
# The Python Imaging Library
# $Id$
#
# portable compiled font file parser
#
# history:
# 1997-08-19 fl created
# 2003-09-13 fl fixed loading of unicode fonts
#
# Copyright (c) 1997-2003 by Secret Labs AB.
# Copyright (c) 1997-2003 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import io
from typing import BinaryIO, Callable
from . import FontFile, Image
from ._binary import i8
from ._binary import i16be as b16
from ._binary import i16le as l16
from ._binary import i32be as b32
from ._binary import i32le as l32
# --------------------------------------------------------------------
# declarations
PCF_MAGIC = 0x70636601 # "\x01fcp"
PCF_PROPERTIES = 1 << 0
PCF_ACCELERATORS = 1 << 1
PCF_METRICS = 1 << 2
PCF_BITMAPS = 1 << 3
PCF_INK_METRICS = 1 << 4
PCF_BDF_ENCODINGS = 1 << 5
PCF_SWIDTHS = 1 << 6
PCF_GLYPH_NAMES = 1 << 7
PCF_BDF_ACCELERATORS = 1 << 8
BYTES_PER_ROW: list[Callable[[int], int]] = [
lambda bits: ((bits + 7) >> 3),
lambda bits: ((bits + 15) >> 3) & ~1,
lambda bits: ((bits + 31) >> 3) & ~3,
lambda bits: ((bits + 63) >> 3) & ~7,
]
def sz(s: bytes, o: int) -> bytes:
return s[o : s.index(b"\0", o)]
class PcfFontFile(FontFile.FontFile):
"""Font file plugin for the X11 PCF format."""
name = "name"
def __init__(self, fp: BinaryIO, charset_encoding: str = "iso8859-1"):
self.charset_encoding = charset_encoding
magic = l32(fp.read(4))
if magic != PCF_MAGIC:
msg = "not a PCF file"
raise SyntaxError(msg)
super().__init__()
count = l32(fp.read(4))
self.toc = {}
for i in range(count):
type = l32(fp.read(4))
self.toc[type] = l32(fp.read(4)), l32(fp.read(4)), l32(fp.read(4))
self.fp = fp
self.info = self._load_properties()
metrics = self._load_metrics()
bitmaps = self._load_bitmaps(metrics)
encoding = self._load_encoding()
#
# create glyph structure
for ch, ix in enumerate(encoding):
if ix is not None:
(
xsize,
ysize,
left,
right,
width,
ascent,
descent,
attributes,
) = metrics[ix]
self.glyph[ch] = (
(width, 0),
(left, descent - ysize, xsize + left, descent),
(0, 0, xsize, ysize),
bitmaps[ix],
)
def _getformat(
self, tag: int
) -> tuple[BinaryIO, int, Callable[[bytes], int], Callable[[bytes], int]]:
format, size, offset = self.toc[tag]
fp = self.fp
fp.seek(offset)
format = l32(fp.read(4))
if format & 4:
i16, i32 = b16, b32
else:
i16, i32 = l16, l32
return fp, format, i16, i32
def _load_properties(self) -> dict[bytes, bytes | int]:
#
# font properties
properties = {}
fp, format, i16, i32 = self._getformat(PCF_PROPERTIES)
nprops = i32(fp.read(4))
# read property description
p = [(i32(fp.read(4)), i8(fp.read(1)), i32(fp.read(4))) for _ in range(nprops)]
if nprops & 3:
fp.seek(4 - (nprops & 3), io.SEEK_CUR) # pad
data = fp.read(i32(fp.read(4)))
for k, s, v in p:
property_value: bytes | int = sz(data, v) if s else v
properties[sz(data, k)] = property_value
return properties
def _load_metrics(self) -> list[tuple[int, int, int, int, int, int, int, int]]:
#
# font metrics
metrics: list[tuple[int, int, int, int, int, int, int, int]] = []
fp, format, i16, i32 = self._getformat(PCF_METRICS)
append = metrics.append
if (format & 0xFF00) == 0x100:
# "compressed" metrics
for i in range(i16(fp.read(2))):
left = i8(fp.read(1)) - 128
right = i8(fp.read(1)) - 128
width = i8(fp.read(1)) - 128
ascent = i8(fp.read(1)) - 128
descent = i8(fp.read(1)) - 128
xsize = right - left
ysize = ascent + descent
append((xsize, ysize, left, right, width, ascent, descent, 0))
else:
# "jumbo" metrics
for i in range(i32(fp.read(4))):
left = i16(fp.read(2))
right = i16(fp.read(2))
width = i16(fp.read(2))
ascent = i16(fp.read(2))
descent = i16(fp.read(2))
attributes = i16(fp.read(2))
xsize = right - left
ysize = ascent + descent
append((xsize, ysize, left, right, width, ascent, descent, attributes))
return metrics
def _load_bitmaps(
self, metrics: list[tuple[int, int, int, int, int, int, int, int]]
) -> list[Image.Image]:
#
# bitmap data
fp, format, i16, i32 = self._getformat(PCF_BITMAPS)
nbitmaps = i32(fp.read(4))
if nbitmaps != len(metrics):
msg = "Wrong number of bitmaps"
raise OSError(msg)
offsets = [i32(fp.read(4)) for _ in range(nbitmaps)]
bitmap_sizes = [i32(fp.read(4)) for _ in range(4)]
# byteorder = format & 4 # non-zero => MSB
bitorder = format & 8 # non-zero => MSB
padindex = format & 3
bitmapsize = bitmap_sizes[padindex]
offsets.append(bitmapsize)
data = fp.read(bitmapsize)
pad = BYTES_PER_ROW[padindex]
mode = "1;R"
if bitorder:
mode = "1"
bitmaps = []
for i in range(nbitmaps):
xsize, ysize = metrics[i][:2]
b, e = offsets[i : i + 2]
bitmaps.append(
Image.frombytes("1", (xsize, ysize), data[b:e], "raw", mode, pad(xsize))
)
return bitmaps
def _load_encoding(self) -> list[int | None]:
fp, format, i16, i32 = self._getformat(PCF_BDF_ENCODINGS)
first_col, last_col = i16(fp.read(2)), i16(fp.read(2))
first_row, last_row = i16(fp.read(2)), i16(fp.read(2))
i16(fp.read(2)) # default
nencoding = (last_col - first_col + 1) * (last_row - first_row + 1)
# map character code to bitmap index
encoding: list[int | None] = [None] * min(256, nencoding)
encoding_offsets = [i16(fp.read(2)) for _ in range(nencoding)]
for i in range(first_col, len(encoding)):
try:
encoding_offset = encoding_offsets[
ord(bytearray([i]).decode(self.charset_encoding))
]
if encoding_offset != 0xFFFF:
encoding[i] = encoding_offset
except UnicodeDecodeError:
# character is not supported in selected encoding
pass
return encoding

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#
# The Python Imaging Library.
# $Id$
#
# PCX file handling
#
# This format was originally used by ZSoft's popular PaintBrush
# program for the IBM PC. It is also supported by many MS-DOS and
# Windows applications, including the Windows PaintBrush program in
# Windows 3.
#
# history:
# 1995-09-01 fl Created
# 1996-05-20 fl Fixed RGB support
# 1997-01-03 fl Fixed 2-bit and 4-bit support
# 1999-02-03 fl Fixed 8-bit support (broken in 1.0b1)
# 1999-02-07 fl Added write support
# 2002-06-09 fl Made 2-bit and 4-bit support a bit more robust
# 2002-07-30 fl Seek from to current position, not beginning of file
# 2003-06-03 fl Extract DPI settings (info["dpi"])
#
# Copyright (c) 1997-2003 by Secret Labs AB.
# Copyright (c) 1995-2003 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import io
import logging
from typing import IO
from . import Image, ImageFile, ImagePalette
from ._binary import i16le as i16
from ._binary import o8
from ._binary import o16le as o16
logger = logging.getLogger(__name__)
def _accept(prefix: bytes) -> bool:
return prefix[0] == 10 and prefix[1] in [0, 2, 3, 5]
##
# Image plugin for Paintbrush images.
class PcxImageFile(ImageFile.ImageFile):
format = "PCX"
format_description = "Paintbrush"
def _open(self) -> None:
# header
assert self.fp is not None
s = self.fp.read(128)
if not _accept(s):
msg = "not a PCX file"
raise SyntaxError(msg)
# image
bbox = i16(s, 4), i16(s, 6), i16(s, 8) + 1, i16(s, 10) + 1
if bbox[2] <= bbox[0] or bbox[3] <= bbox[1]:
msg = "bad PCX image size"
raise SyntaxError(msg)
logger.debug("BBox: %s %s %s %s", *bbox)
# format
version = s[1]
bits = s[3]
planes = s[65]
provided_stride = i16(s, 66)
logger.debug(
"PCX version %s, bits %s, planes %s, stride %s",
version,
bits,
planes,
provided_stride,
)
self.info["dpi"] = i16(s, 12), i16(s, 14)
if bits == 1 and planes == 1:
mode = rawmode = "1"
elif bits == 1 and planes in (2, 4):
mode = "P"
rawmode = "P;%dL" % planes
self.palette = ImagePalette.raw("RGB", s[16:64])
elif version == 5 and bits == 8 and planes == 1:
mode = rawmode = "L"
# FIXME: hey, this doesn't work with the incremental loader !!!
self.fp.seek(-769, io.SEEK_END)
s = self.fp.read(769)
if len(s) == 769 and s[0] == 12:
# check if the palette is linear grayscale
for i in range(256):
if s[i * 3 + 1 : i * 3 + 4] != o8(i) * 3:
mode = rawmode = "P"
break
if mode == "P":
self.palette = ImagePalette.raw("RGB", s[1:])
self.fp.seek(128)
elif version == 5 and bits == 8 and planes == 3:
mode = "RGB"
rawmode = "RGB;L"
else:
msg = "unknown PCX mode"
raise OSError(msg)
self._mode = mode
self._size = bbox[2] - bbox[0], bbox[3] - bbox[1]
# Don't trust the passed in stride.
# Calculate the approximate position for ourselves.
# CVE-2020-35653
stride = (self._size[0] * bits + 7) // 8
# While the specification states that this must be even,
# not all images follow this
if provided_stride != stride:
stride += stride % 2
bbox = (0, 0) + self.size
logger.debug("size: %sx%s", *self.size)
self.tile = [
ImageFile._Tile("pcx", bbox, self.fp.tell(), (rawmode, planes * stride))
]
# --------------------------------------------------------------------
# save PCX files
SAVE = {
# mode: (version, bits, planes, raw mode)
"1": (2, 1, 1, "1"),
"L": (5, 8, 1, "L"),
"P": (5, 8, 1, "P"),
"RGB": (5, 8, 3, "RGB;L"),
}
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
try:
version, bits, planes, rawmode = SAVE[im.mode]
except KeyError as e:
msg = f"Cannot save {im.mode} images as PCX"
raise ValueError(msg) from e
# bytes per plane
stride = (im.size[0] * bits + 7) // 8
# stride should be even
stride += stride % 2
# Stride needs to be kept in sync with the PcxEncode.c version.
# Ideally it should be passed in in the state, but the bytes value
# gets overwritten.
logger.debug(
"PcxImagePlugin._save: xwidth: %d, bits: %d, stride: %d",
im.size[0],
bits,
stride,
)
# under windows, we could determine the current screen size with
# "Image.core.display_mode()[1]", but I think that's overkill...
screen = im.size
dpi = 100, 100
# PCX header
fp.write(
o8(10)
+ o8(version)
+ o8(1)
+ o8(bits)
+ o16(0)
+ o16(0)
+ o16(im.size[0] - 1)
+ o16(im.size[1] - 1)
+ o16(dpi[0])
+ o16(dpi[1])
+ b"\0" * 24
+ b"\xFF" * 24
+ b"\0"
+ o8(planes)
+ o16(stride)
+ o16(1)
+ o16(screen[0])
+ o16(screen[1])
+ b"\0" * 54
)
assert fp.tell() == 128
ImageFile._save(
im, fp, [ImageFile._Tile("pcx", (0, 0) + im.size, 0, (rawmode, bits * planes))]
)
if im.mode == "P":
# colour palette
fp.write(o8(12))
palette = im.im.getpalette("RGB", "RGB")
palette += b"\x00" * (768 - len(palette))
fp.write(palette) # 768 bytes
elif im.mode == "L":
# grayscale palette
fp.write(o8(12))
for i in range(256):
fp.write(o8(i) * 3)
# --------------------------------------------------------------------
# registry
Image.register_open(PcxImageFile.format, PcxImageFile, _accept)
Image.register_save(PcxImageFile.format, _save)
Image.register_extension(PcxImageFile.format, ".pcx")
Image.register_mime(PcxImageFile.format, "image/x-pcx")

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#
# The Python Imaging Library.
# $Id$
#
# PDF (Acrobat) file handling
#
# History:
# 1996-07-16 fl Created
# 1997-01-18 fl Fixed header
# 2004-02-21 fl Fixes for 1/L/CMYK images, etc.
# 2004-02-24 fl Fixes for 1 and P images.
#
# Copyright (c) 1997-2004 by Secret Labs AB. All rights reserved.
# Copyright (c) 1996-1997 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
##
# Image plugin for PDF images (output only).
##
from __future__ import annotations
import io
import math
import os
import time
from typing import IO, Any
from . import Image, ImageFile, ImageSequence, PdfParser, __version__, features
#
# --------------------------------------------------------------------
# object ids:
# 1. catalogue
# 2. pages
# 3. image
# 4. page
# 5. page contents
def _save_all(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
_save(im, fp, filename, save_all=True)
##
# (Internal) Image save plugin for the PDF format.
def _write_image(
im: Image.Image,
filename: str | bytes,
existing_pdf: PdfParser.PdfParser,
image_refs: list[PdfParser.IndirectReference],
) -> tuple[PdfParser.IndirectReference, str]:
# FIXME: Should replace ASCIIHexDecode with RunLengthDecode
# (packbits) or LZWDecode (tiff/lzw compression). Note that
# PDF 1.2 also supports Flatedecode (zip compression).
params = None
decode = None
#
# Get image characteristics
width, height = im.size
dict_obj: dict[str, Any] = {"BitsPerComponent": 8}
if im.mode == "1":
if features.check("libtiff"):
decode_filter = "CCITTFaxDecode"
dict_obj["BitsPerComponent"] = 1
params = PdfParser.PdfArray(
[
PdfParser.PdfDict(
{
"K": -1,
"BlackIs1": True,
"Columns": width,
"Rows": height,
}
)
]
)
else:
decode_filter = "DCTDecode"
dict_obj["ColorSpace"] = PdfParser.PdfName("DeviceGray")
procset = "ImageB" # grayscale
elif im.mode == "L":
decode_filter = "DCTDecode"
# params = f"<< /Predictor 15 /Columns {width-2} >>"
dict_obj["ColorSpace"] = PdfParser.PdfName("DeviceGray")
procset = "ImageB" # grayscale
elif im.mode == "LA":
decode_filter = "JPXDecode"
# params = f"<< /Predictor 15 /Columns {width-2} >>"
procset = "ImageB" # grayscale
dict_obj["SMaskInData"] = 1
elif im.mode == "P":
decode_filter = "ASCIIHexDecode"
palette = im.getpalette()
assert palette is not None
dict_obj["ColorSpace"] = [
PdfParser.PdfName("Indexed"),
PdfParser.PdfName("DeviceRGB"),
len(palette) // 3 - 1,
PdfParser.PdfBinary(palette),
]
procset = "ImageI" # indexed color
if "transparency" in im.info:
smask = im.convert("LA").getchannel("A")
smask.encoderinfo = {}
image_ref = _write_image(smask, filename, existing_pdf, image_refs)[0]
dict_obj["SMask"] = image_ref
elif im.mode == "RGB":
decode_filter = "DCTDecode"
dict_obj["ColorSpace"] = PdfParser.PdfName("DeviceRGB")
procset = "ImageC" # color images
elif im.mode == "RGBA":
decode_filter = "JPXDecode"
procset = "ImageC" # color images
dict_obj["SMaskInData"] = 1
elif im.mode == "CMYK":
decode_filter = "DCTDecode"
dict_obj["ColorSpace"] = PdfParser.PdfName("DeviceCMYK")
procset = "ImageC" # color images
decode = [1, 0, 1, 0, 1, 0, 1, 0]
else:
msg = f"cannot save mode {im.mode}"
raise ValueError(msg)
#
# image
op = io.BytesIO()
if decode_filter == "ASCIIHexDecode":
ImageFile._save(im, op, [ImageFile._Tile("hex", (0, 0) + im.size, 0, im.mode)])
elif decode_filter == "CCITTFaxDecode":
im.save(
op,
"TIFF",
compression="group4",
# use a single strip
strip_size=math.ceil(width / 8) * height,
)
elif decode_filter == "DCTDecode":
Image.SAVE["JPEG"](im, op, filename)
elif decode_filter == "JPXDecode":
del dict_obj["BitsPerComponent"]
Image.SAVE["JPEG2000"](im, op, filename)
else:
msg = f"unsupported PDF filter ({decode_filter})"
raise ValueError(msg)
stream = op.getvalue()
filter: PdfParser.PdfArray | PdfParser.PdfName
if decode_filter == "CCITTFaxDecode":
stream = stream[8:]
filter = PdfParser.PdfArray([PdfParser.PdfName(decode_filter)])
else:
filter = PdfParser.PdfName(decode_filter)
image_ref = image_refs.pop(0)
existing_pdf.write_obj(
image_ref,
stream=stream,
Type=PdfParser.PdfName("XObject"),
Subtype=PdfParser.PdfName("Image"),
Width=width, # * 72.0 / x_resolution,
Height=height, # * 72.0 / y_resolution,
Filter=filter,
Decode=decode,
DecodeParms=params,
**dict_obj,
)
return image_ref, procset
def _save(
im: Image.Image, fp: IO[bytes], filename: str | bytes, save_all: bool = False
) -> None:
is_appending = im.encoderinfo.get("append", False)
filename_str = filename.decode() if isinstance(filename, bytes) else filename
if is_appending:
existing_pdf = PdfParser.PdfParser(f=fp, filename=filename_str, mode="r+b")
else:
existing_pdf = PdfParser.PdfParser(f=fp, filename=filename_str, mode="w+b")
dpi = im.encoderinfo.get("dpi")
if dpi:
x_resolution = dpi[0]
y_resolution = dpi[1]
else:
x_resolution = y_resolution = im.encoderinfo.get("resolution", 72.0)
info = {
"title": (
None if is_appending else os.path.splitext(os.path.basename(filename))[0]
),
"author": None,
"subject": None,
"keywords": None,
"creator": None,
"producer": None,
"creationDate": None if is_appending else time.gmtime(),
"modDate": None if is_appending else time.gmtime(),
}
for k, default in info.items():
v = im.encoderinfo.get(k) if k in im.encoderinfo else default
if v:
existing_pdf.info[k[0].upper() + k[1:]] = v
#
# make sure image data is available
im.load()
existing_pdf.start_writing()
existing_pdf.write_header()
existing_pdf.write_comment(f"created by Pillow {__version__} PDF driver")
#
# pages
ims = [im]
if save_all:
append_images = im.encoderinfo.get("append_images", [])
for append_im in append_images:
append_im.encoderinfo = im.encoderinfo.copy()
ims.append(append_im)
number_of_pages = 0
image_refs = []
page_refs = []
contents_refs = []
for im in ims:
im_number_of_pages = 1
if save_all:
im_number_of_pages = getattr(im, "n_frames", 1)
number_of_pages += im_number_of_pages
for i in range(im_number_of_pages):
image_refs.append(existing_pdf.next_object_id(0))
if im.mode == "P" and "transparency" in im.info:
image_refs.append(existing_pdf.next_object_id(0))
page_refs.append(existing_pdf.next_object_id(0))
contents_refs.append(existing_pdf.next_object_id(0))
existing_pdf.pages.append(page_refs[-1])
#
# catalog and list of pages
existing_pdf.write_catalog()
page_number = 0
for im_sequence in ims:
im_pages: ImageSequence.Iterator | list[Image.Image] = (
ImageSequence.Iterator(im_sequence) if save_all else [im_sequence]
)
for im in im_pages:
image_ref, procset = _write_image(im, filename, existing_pdf, image_refs)
#
# page
existing_pdf.write_page(
page_refs[page_number],
Resources=PdfParser.PdfDict(
ProcSet=[PdfParser.PdfName("PDF"), PdfParser.PdfName(procset)],
XObject=PdfParser.PdfDict(image=image_ref),
),
MediaBox=[
0,
0,
im.width * 72.0 / x_resolution,
im.height * 72.0 / y_resolution,
],
Contents=contents_refs[page_number],
)
#
# page contents
page_contents = b"q %f 0 0 %f 0 0 cm /image Do Q\n" % (
im.width * 72.0 / x_resolution,
im.height * 72.0 / y_resolution,
)
existing_pdf.write_obj(contents_refs[page_number], stream=page_contents)
page_number += 1
#
# trailer
existing_pdf.write_xref_and_trailer()
if hasattr(fp, "flush"):
fp.flush()
existing_pdf.close()
#
# --------------------------------------------------------------------
Image.register_save("PDF", _save)
Image.register_save_all("PDF", _save_all)
Image.register_extension("PDF", ".pdf")
Image.register_mime("PDF", "application/pdf")

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#
# The Python Imaging Library.
# $Id$
#
# PIXAR raster support for PIL
#
# history:
# 97-01-29 fl Created
#
# notes:
# This is incomplete; it is based on a few samples created with
# Photoshop 2.5 and 3.0, and a summary description provided by
# Greg Coats <gcoats@labiris.er.usgs.gov>. Hopefully, "L" and
# "RGBA" support will be added in future versions.
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1997.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from . import Image, ImageFile
from ._binary import i16le as i16
#
# helpers
def _accept(prefix: bytes) -> bool:
return prefix[:4] == b"\200\350\000\000"
##
# Image plugin for PIXAR raster images.
class PixarImageFile(ImageFile.ImageFile):
format = "PIXAR"
format_description = "PIXAR raster image"
def _open(self) -> None:
# assuming a 4-byte magic label
assert self.fp is not None
s = self.fp.read(4)
if not _accept(s):
msg = "not a PIXAR file"
raise SyntaxError(msg)
# read rest of header
s = s + self.fp.read(508)
self._size = i16(s, 418), i16(s, 416)
# get channel/depth descriptions
mode = i16(s, 424), i16(s, 426)
if mode == (14, 2):
self._mode = "RGB"
# FIXME: to be continued...
# create tile descriptor (assuming "dumped")
self.tile = [
ImageFile._Tile("raw", (0, 0) + self.size, 1024, (self.mode, 0, 1))
]
#
# --------------------------------------------------------------------
Image.register_open(PixarImageFile.format, PixarImageFile, _accept)
Image.register_extension(PixarImageFile.format, ".pxr")

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#
# The Python Imaging Library.
# $Id$
#
# PPM support for PIL
#
# History:
# 96-03-24 fl Created
# 98-03-06 fl Write RGBA images (as RGB, that is)
#
# Copyright (c) Secret Labs AB 1997-98.
# Copyright (c) Fredrik Lundh 1996.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import math
from typing import IO
from . import Image, ImageFile
from ._binary import i16be as i16
from ._binary import o8
from ._binary import o32le as o32
#
# --------------------------------------------------------------------
b_whitespace = b"\x20\x09\x0a\x0b\x0c\x0d"
MODES = {
# standard
b"P1": "1",
b"P2": "L",
b"P3": "RGB",
b"P4": "1",
b"P5": "L",
b"P6": "RGB",
# extensions
b"P0CMYK": "CMYK",
b"Pf": "F",
# PIL extensions (for test purposes only)
b"PyP": "P",
b"PyRGBA": "RGBA",
b"PyCMYK": "CMYK",
}
def _accept(prefix: bytes) -> bool:
return prefix[0:1] == b"P" and prefix[1] in b"0123456fy"
##
# Image plugin for PBM, PGM, and PPM images.
class PpmImageFile(ImageFile.ImageFile):
format = "PPM"
format_description = "Pbmplus image"
def _read_magic(self) -> bytes:
assert self.fp is not None
magic = b""
# read until whitespace or longest available magic number
for _ in range(6):
c = self.fp.read(1)
if not c or c in b_whitespace:
break
magic += c
return magic
def _read_token(self) -> bytes:
assert self.fp is not None
token = b""
while len(token) <= 10: # read until next whitespace or limit of 10 characters
c = self.fp.read(1)
if not c:
break
elif c in b_whitespace: # token ended
if not token:
# skip whitespace at start
continue
break
elif c == b"#":
# ignores rest of the line; stops at CR, LF or EOF
while self.fp.read(1) not in b"\r\n":
pass
continue
token += c
if not token:
# Token was not even 1 byte
msg = "Reached EOF while reading header"
raise ValueError(msg)
elif len(token) > 10:
msg = f"Token too long in file header: {token.decode()}"
raise ValueError(msg)
return token
def _open(self) -> None:
assert self.fp is not None
magic_number = self._read_magic()
try:
mode = MODES[magic_number]
except KeyError:
msg = "not a PPM file"
raise SyntaxError(msg)
self._mode = mode
if magic_number in (b"P1", b"P4"):
self.custom_mimetype = "image/x-portable-bitmap"
elif magic_number in (b"P2", b"P5"):
self.custom_mimetype = "image/x-portable-graymap"
elif magic_number in (b"P3", b"P6"):
self.custom_mimetype = "image/x-portable-pixmap"
self._size = int(self._read_token()), int(self._read_token())
decoder_name = "raw"
if magic_number in (b"P1", b"P2", b"P3"):
decoder_name = "ppm_plain"
args: str | tuple[str | int, ...]
if mode == "1":
args = "1;I"
elif mode == "F":
scale = float(self._read_token())
if scale == 0.0 or not math.isfinite(scale):
msg = "scale must be finite and non-zero"
raise ValueError(msg)
self.info["scale"] = abs(scale)
rawmode = "F;32F" if scale < 0 else "F;32BF"
args = (rawmode, 0, -1)
else:
maxval = int(self._read_token())
if not 0 < maxval < 65536:
msg = "maxval must be greater than 0 and less than 65536"
raise ValueError(msg)
if maxval > 255 and mode == "L":
self._mode = "I"
rawmode = mode
if decoder_name != "ppm_plain":
# If maxval matches a bit depth, use the raw decoder directly
if maxval == 65535 and mode == "L":
rawmode = "I;16B"
elif maxval != 255:
decoder_name = "ppm"
args = rawmode if decoder_name == "raw" else (rawmode, maxval)
self.tile = [
ImageFile._Tile(decoder_name, (0, 0) + self.size, self.fp.tell(), args)
]
#
# --------------------------------------------------------------------
class PpmPlainDecoder(ImageFile.PyDecoder):
_pulls_fd = True
_comment_spans: bool
def _read_block(self) -> bytes:
assert self.fd is not None
return self.fd.read(ImageFile.SAFEBLOCK)
def _find_comment_end(self, block: bytes, start: int = 0) -> int:
a = block.find(b"\n", start)
b = block.find(b"\r", start)
return min(a, b) if a * b > 0 else max(a, b) # lowest nonnegative index (or -1)
def _ignore_comments(self, block: bytes) -> bytes:
if self._comment_spans:
# Finish current comment
while block:
comment_end = self._find_comment_end(block)
if comment_end != -1:
# Comment ends in this block
# Delete tail of comment
block = block[comment_end + 1 :]
break
else:
# Comment spans whole block
# So read the next block, looking for the end
block = self._read_block()
# Search for any further comments
self._comment_spans = False
while True:
comment_start = block.find(b"#")
if comment_start == -1:
# No comment found
break
comment_end = self._find_comment_end(block, comment_start)
if comment_end != -1:
# Comment ends in this block
# Delete comment
block = block[:comment_start] + block[comment_end + 1 :]
else:
# Comment continues to next block(s)
block = block[:comment_start]
self._comment_spans = True
break
return block
def _decode_bitonal(self) -> bytearray:
"""
This is a separate method because in the plain PBM format, all data tokens are
exactly one byte, so the inter-token whitespace is optional.
"""
data = bytearray()
total_bytes = self.state.xsize * self.state.ysize
while len(data) != total_bytes:
block = self._read_block() # read next block
if not block:
# eof
break
block = self._ignore_comments(block)
tokens = b"".join(block.split())
for token in tokens:
if token not in (48, 49):
msg = b"Invalid token for this mode: %s" % bytes([token])
raise ValueError(msg)
data = (data + tokens)[:total_bytes]
invert = bytes.maketrans(b"01", b"\xFF\x00")
return data.translate(invert)
def _decode_blocks(self, maxval: int) -> bytearray:
data = bytearray()
max_len = 10
out_byte_count = 4 if self.mode == "I" else 1
out_max = 65535 if self.mode == "I" else 255
bands = Image.getmodebands(self.mode)
total_bytes = self.state.xsize * self.state.ysize * bands * out_byte_count
half_token = b""
while len(data) != total_bytes:
block = self._read_block() # read next block
if not block:
if half_token:
block = bytearray(b" ") # flush half_token
else:
# eof
break
block = self._ignore_comments(block)
if half_token:
block = half_token + block # stitch half_token to new block
half_token = b""
tokens = block.split()
if block and not block[-1:].isspace(): # block might split token
half_token = tokens.pop() # save half token for later
if len(half_token) > max_len: # prevent buildup of half_token
msg = (
b"Token too long found in data: %s" % half_token[: max_len + 1]
)
raise ValueError(msg)
for token in tokens:
if len(token) > max_len:
msg = b"Token too long found in data: %s" % token[: max_len + 1]
raise ValueError(msg)
value = int(token)
if value < 0:
msg_str = f"Channel value is negative: {value}"
raise ValueError(msg_str)
if value > maxval:
msg_str = f"Channel value too large for this mode: {value}"
raise ValueError(msg_str)
value = round(value / maxval * out_max)
data += o32(value) if self.mode == "I" else o8(value)
if len(data) == total_bytes: # finished!
break
return data
def decode(self, buffer: bytes | Image.SupportsArrayInterface) -> tuple[int, int]:
self._comment_spans = False
if self.mode == "1":
data = self._decode_bitonal()
rawmode = "1;8"
else:
maxval = self.args[-1]
data = self._decode_blocks(maxval)
rawmode = "I;32" if self.mode == "I" else self.mode
self.set_as_raw(bytes(data), rawmode)
return -1, 0
class PpmDecoder(ImageFile.PyDecoder):
_pulls_fd = True
def decode(self, buffer: bytes | Image.SupportsArrayInterface) -> tuple[int, int]:
assert self.fd is not None
data = bytearray()
maxval = self.args[-1]
in_byte_count = 1 if maxval < 256 else 2
out_byte_count = 4 if self.mode == "I" else 1
out_max = 65535 if self.mode == "I" else 255
bands = Image.getmodebands(self.mode)
dest_length = self.state.xsize * self.state.ysize * bands * out_byte_count
while len(data) < dest_length:
pixels = self.fd.read(in_byte_count * bands)
if len(pixels) < in_byte_count * bands:
# eof
break
for b in range(bands):
value = (
pixels[b] if in_byte_count == 1 else i16(pixels, b * in_byte_count)
)
value = min(out_max, round(value / maxval * out_max))
data += o32(value) if self.mode == "I" else o8(value)
rawmode = "I;32" if self.mode == "I" else self.mode
self.set_as_raw(bytes(data), rawmode)
return -1, 0
#
# --------------------------------------------------------------------
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
if im.mode == "1":
rawmode, head = "1;I", b"P4"
elif im.mode == "L":
rawmode, head = "L", b"P5"
elif im.mode in ("I", "I;16"):
rawmode, head = "I;16B", b"P5"
elif im.mode in ("RGB", "RGBA"):
rawmode, head = "RGB", b"P6"
elif im.mode == "F":
rawmode, head = "F;32F", b"Pf"
else:
msg = f"cannot write mode {im.mode} as PPM"
raise OSError(msg)
fp.write(head + b"\n%d %d\n" % im.size)
if head == b"P6":
fp.write(b"255\n")
elif head == b"P5":
if rawmode == "L":
fp.write(b"255\n")
else:
fp.write(b"65535\n")
elif head == b"Pf":
fp.write(b"-1.0\n")
row_order = -1 if im.mode == "F" else 1
ImageFile._save(
im, fp, [ImageFile._Tile("raw", (0, 0) + im.size, 0, (rawmode, 0, row_order))]
)
#
# --------------------------------------------------------------------
Image.register_open(PpmImageFile.format, PpmImageFile, _accept)
Image.register_save(PpmImageFile.format, _save)
Image.register_decoder("ppm", PpmDecoder)
Image.register_decoder("ppm_plain", PpmPlainDecoder)
Image.register_extensions(PpmImageFile.format, [".pbm", ".pgm", ".ppm", ".pnm", ".pfm"])
Image.register_mime(PpmImageFile.format, "image/x-portable-anymap")

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#
# The Python Imaging Library
# $Id$
#
# Adobe PSD 2.5/3.0 file handling
#
# History:
# 1995-09-01 fl Created
# 1997-01-03 fl Read most PSD images
# 1997-01-18 fl Fixed P and CMYK support
# 2001-10-21 fl Added seek/tell support (for layers)
#
# Copyright (c) 1997-2001 by Secret Labs AB.
# Copyright (c) 1995-2001 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import io
from functools import cached_property
from typing import IO
from . import Image, ImageFile, ImagePalette
from ._binary import i8
from ._binary import i16be as i16
from ._binary import i32be as i32
from ._binary import si16be as si16
from ._binary import si32be as si32
MODES = {
# (photoshop mode, bits) -> (pil mode, required channels)
(0, 1): ("1", 1),
(0, 8): ("L", 1),
(1, 8): ("L", 1),
(2, 8): ("P", 1),
(3, 8): ("RGB", 3),
(4, 8): ("CMYK", 4),
(7, 8): ("L", 1), # FIXME: multilayer
(8, 8): ("L", 1), # duotone
(9, 8): ("LAB", 3),
}
# --------------------------------------------------------------------.
# read PSD images
def _accept(prefix: bytes) -> bool:
return prefix[:4] == b"8BPS"
##
# Image plugin for Photoshop images.
class PsdImageFile(ImageFile.ImageFile):
format = "PSD"
format_description = "Adobe Photoshop"
_close_exclusive_fp_after_loading = False
def _open(self) -> None:
read = self.fp.read
#
# header
s = read(26)
if not _accept(s) or i16(s, 4) != 1:
msg = "not a PSD file"
raise SyntaxError(msg)
psd_bits = i16(s, 22)
psd_channels = i16(s, 12)
psd_mode = i16(s, 24)
mode, channels = MODES[(psd_mode, psd_bits)]
if channels > psd_channels:
msg = "not enough channels"
raise OSError(msg)
if mode == "RGB" and psd_channels == 4:
mode = "RGBA"
channels = 4
self._mode = mode
self._size = i32(s, 18), i32(s, 14)
#
# color mode data
size = i32(read(4))
if size:
data = read(size)
if mode == "P" and size == 768:
self.palette = ImagePalette.raw("RGB;L", data)
#
# image resources
self.resources = []
size = i32(read(4))
if size:
# load resources
end = self.fp.tell() + size
while self.fp.tell() < end:
read(4) # signature
id = i16(read(2))
name = read(i8(read(1)))
if not (len(name) & 1):
read(1) # padding
data = read(i32(read(4)))
if len(data) & 1:
read(1) # padding
self.resources.append((id, name, data))
if id == 1039: # ICC profile
self.info["icc_profile"] = data
#
# layer and mask information
self._layers_position = None
size = i32(read(4))
if size:
end = self.fp.tell() + size
size = i32(read(4))
if size:
self._layers_position = self.fp.tell()
self._layers_size = size
self.fp.seek(end)
self._n_frames: int | None = None
#
# image descriptor
self.tile = _maketile(self.fp, mode, (0, 0) + self.size, channels)
# keep the file open
self._fp = self.fp
self.frame = 1
self._min_frame = 1
@cached_property
def layers(
self,
) -> list[tuple[str, str, tuple[int, int, int, int], list[ImageFile._Tile]]]:
layers = []
if self._layers_position is not None:
self._fp.seek(self._layers_position)
_layer_data = io.BytesIO(ImageFile._safe_read(self._fp, self._layers_size))
layers = _layerinfo(_layer_data, self._layers_size)
self._n_frames = len(layers)
return layers
@property
def n_frames(self) -> int:
if self._n_frames is None:
self._n_frames = len(self.layers)
return self._n_frames
@property
def is_animated(self) -> bool:
return len(self.layers) > 1
def seek(self, layer: int) -> None:
if not self._seek_check(layer):
return
# seek to given layer (1..max)
try:
_, mode, _, tile = self.layers[layer - 1]
self._mode = mode
self.tile = tile
self.frame = layer
self.fp = self._fp
except IndexError as e:
msg = "no such layer"
raise EOFError(msg) from e
def tell(self) -> int:
# return layer number (0=image, 1..max=layers)
return self.frame
def _layerinfo(
fp: IO[bytes], ct_bytes: int
) -> list[tuple[str, str, tuple[int, int, int, int], list[ImageFile._Tile]]]:
# read layerinfo block
layers = []
def read(size: int) -> bytes:
return ImageFile._safe_read(fp, size)
ct = si16(read(2))
# sanity check
if ct_bytes < (abs(ct) * 20):
msg = "Layer block too short for number of layers requested"
raise SyntaxError(msg)
for _ in range(abs(ct)):
# bounding box
y0 = si32(read(4))
x0 = si32(read(4))
y1 = si32(read(4))
x1 = si32(read(4))
# image info
bands = []
ct_types = i16(read(2))
if ct_types > 4:
fp.seek(ct_types * 6 + 12, io.SEEK_CUR)
size = i32(read(4))
fp.seek(size, io.SEEK_CUR)
continue
for _ in range(ct_types):
type = i16(read(2))
if type == 65535:
b = "A"
else:
b = "RGBA"[type]
bands.append(b)
read(4) # size
# figure out the image mode
bands.sort()
if bands == ["R"]:
mode = "L"
elif bands == ["B", "G", "R"]:
mode = "RGB"
elif bands == ["A", "B", "G", "R"]:
mode = "RGBA"
else:
mode = "" # unknown
# skip over blend flags and extra information
read(12) # filler
name = ""
size = i32(read(4)) # length of the extra data field
if size:
data_end = fp.tell() + size
length = i32(read(4))
if length:
fp.seek(length - 16, io.SEEK_CUR)
length = i32(read(4))
if length:
fp.seek(length, io.SEEK_CUR)
length = i8(read(1))
if length:
# Don't know the proper encoding,
# Latin-1 should be a good guess
name = read(length).decode("latin-1", "replace")
fp.seek(data_end)
layers.append((name, mode, (x0, y0, x1, y1)))
# get tiles
layerinfo = []
for i, (name, mode, bbox) in enumerate(layers):
tile = []
for m in mode:
t = _maketile(fp, m, bbox, 1)
if t:
tile.extend(t)
layerinfo.append((name, mode, bbox, tile))
return layerinfo
def _maketile(
file: IO[bytes], mode: str, bbox: tuple[int, int, int, int], channels: int
) -> list[ImageFile._Tile]:
tiles = []
read = file.read
compression = i16(read(2))
xsize = bbox[2] - bbox[0]
ysize = bbox[3] - bbox[1]
offset = file.tell()
if compression == 0:
#
# raw compression
for channel in range(channels):
layer = mode[channel]
if mode == "CMYK":
layer += ";I"
tiles.append(ImageFile._Tile("raw", bbox, offset, layer))
offset = offset + xsize * ysize
elif compression == 1:
#
# packbits compression
i = 0
bytecount = read(channels * ysize * 2)
offset = file.tell()
for channel in range(channels):
layer = mode[channel]
if mode == "CMYK":
layer += ";I"
tiles.append(ImageFile._Tile("packbits", bbox, offset, layer))
for y in range(ysize):
offset = offset + i16(bytecount, i)
i += 2
file.seek(offset)
if offset & 1:
read(1) # padding
return tiles
# --------------------------------------------------------------------
# registry
Image.register_open(PsdImageFile.format, PsdImageFile, _accept)
Image.register_extension(PsdImageFile.format, ".psd")
Image.register_mime(PsdImageFile.format, "image/vnd.adobe.photoshop")

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#
# The Python Imaging Library.
#
# QOI support for PIL
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import os
from . import Image, ImageFile
from ._binary import i32be as i32
def _accept(prefix: bytes) -> bool:
return prefix[:4] == b"qoif"
class QoiImageFile(ImageFile.ImageFile):
format = "QOI"
format_description = "Quite OK Image"
def _open(self) -> None:
if not _accept(self.fp.read(4)):
msg = "not a QOI file"
raise SyntaxError(msg)
self._size = i32(self.fp.read(4)), i32(self.fp.read(4))
channels = self.fp.read(1)[0]
self._mode = "RGB" if channels == 3 else "RGBA"
self.fp.seek(1, os.SEEK_CUR) # colorspace
self.tile = [ImageFile._Tile("qoi", (0, 0) + self._size, self.fp.tell(), None)]
class QoiDecoder(ImageFile.PyDecoder):
_pulls_fd = True
_previous_pixel: bytes | bytearray | None = None
_previously_seen_pixels: dict[int, bytes | bytearray] = {}
def _add_to_previous_pixels(self, value: bytes | bytearray) -> None:
self._previous_pixel = value
r, g, b, a = value
hash_value = (r * 3 + g * 5 + b * 7 + a * 11) % 64
self._previously_seen_pixels[hash_value] = value
def decode(self, buffer: bytes | Image.SupportsArrayInterface) -> tuple[int, int]:
assert self.fd is not None
self._previously_seen_pixels = {}
self._add_to_previous_pixels(bytearray((0, 0, 0, 255)))
data = bytearray()
bands = Image.getmodebands(self.mode)
dest_length = self.state.xsize * self.state.ysize * bands
while len(data) < dest_length:
byte = self.fd.read(1)[0]
value: bytes | bytearray
if byte == 0b11111110 and self._previous_pixel: # QOI_OP_RGB
value = bytearray(self.fd.read(3)) + self._previous_pixel[3:]
elif byte == 0b11111111: # QOI_OP_RGBA
value = self.fd.read(4)
else:
op = byte >> 6
if op == 0: # QOI_OP_INDEX
op_index = byte & 0b00111111
value = self._previously_seen_pixels.get(
op_index, bytearray((0, 0, 0, 0))
)
elif op == 1 and self._previous_pixel: # QOI_OP_DIFF
value = bytearray(
(
(self._previous_pixel[0] + ((byte & 0b00110000) >> 4) - 2)
% 256,
(self._previous_pixel[1] + ((byte & 0b00001100) >> 2) - 2)
% 256,
(self._previous_pixel[2] + (byte & 0b00000011) - 2) % 256,
self._previous_pixel[3],
)
)
elif op == 2 and self._previous_pixel: # QOI_OP_LUMA
second_byte = self.fd.read(1)[0]
diff_green = (byte & 0b00111111) - 32
diff_red = ((second_byte & 0b11110000) >> 4) - 8
diff_blue = (second_byte & 0b00001111) - 8
value = bytearray(
tuple(
(self._previous_pixel[i] + diff_green + diff) % 256
for i, diff in enumerate((diff_red, 0, diff_blue))
)
)
value += self._previous_pixel[3:]
elif op == 3 and self._previous_pixel: # QOI_OP_RUN
run_length = (byte & 0b00111111) + 1
value = self._previous_pixel
if bands == 3:
value = value[:3]
data += value * run_length
continue
self._add_to_previous_pixels(value)
if bands == 3:
value = value[:3]
data += value
self.set_as_raw(data)
return -1, 0
Image.register_open(QoiImageFile.format, QoiImageFile, _accept)
Image.register_decoder("qoi", QoiDecoder)
Image.register_extension(QoiImageFile.format, ".qoi")

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#
# The Python Imaging Library.
# $Id$
#
# SGI image file handling
#
# See "The SGI Image File Format (Draft version 0.97)", Paul Haeberli.
# <ftp://ftp.sgi.com/graphics/SGIIMAGESPEC>
#
#
# History:
# 2017-22-07 mb Add RLE decompression
# 2016-16-10 mb Add save method without compression
# 1995-09-10 fl Created
#
# Copyright (c) 2016 by Mickael Bonfill.
# Copyright (c) 2008 by Karsten Hiddemann.
# Copyright (c) 1997 by Secret Labs AB.
# Copyright (c) 1995 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import os
import struct
from typing import IO
from . import Image, ImageFile
from ._binary import i16be as i16
from ._binary import o8
def _accept(prefix: bytes) -> bool:
return len(prefix) >= 2 and i16(prefix) == 474
MODES = {
(1, 1, 1): "L",
(1, 2, 1): "L",
(2, 1, 1): "L;16B",
(2, 2, 1): "L;16B",
(1, 3, 3): "RGB",
(2, 3, 3): "RGB;16B",
(1, 3, 4): "RGBA",
(2, 3, 4): "RGBA;16B",
}
##
# Image plugin for SGI images.
class SgiImageFile(ImageFile.ImageFile):
format = "SGI"
format_description = "SGI Image File Format"
def _open(self) -> None:
# HEAD
assert self.fp is not None
headlen = 512
s = self.fp.read(headlen)
if not _accept(s):
msg = "Not an SGI image file"
raise ValueError(msg)
# compression : verbatim or RLE
compression = s[2]
# bpc : 1 or 2 bytes (8bits or 16bits)
bpc = s[3]
# dimension : 1, 2 or 3 (depending on xsize, ysize and zsize)
dimension = i16(s, 4)
# xsize : width
xsize = i16(s, 6)
# ysize : height
ysize = i16(s, 8)
# zsize : channels count
zsize = i16(s, 10)
# layout
layout = bpc, dimension, zsize
# determine mode from bits/zsize
rawmode = ""
try:
rawmode = MODES[layout]
except KeyError:
pass
if rawmode == "":
msg = "Unsupported SGI image mode"
raise ValueError(msg)
self._size = xsize, ysize
self._mode = rawmode.split(";")[0]
if self.mode == "RGB":
self.custom_mimetype = "image/rgb"
# orientation -1 : scanlines begins at the bottom-left corner
orientation = -1
# decoder info
if compression == 0:
pagesize = xsize * ysize * bpc
if bpc == 2:
self.tile = [
ImageFile._Tile(
"SGI16",
(0, 0) + self.size,
headlen,
(self.mode, 0, orientation),
)
]
else:
self.tile = []
offset = headlen
for layer in self.mode:
self.tile.append(
ImageFile._Tile(
"raw", (0, 0) + self.size, offset, (layer, 0, orientation)
)
)
offset += pagesize
elif compression == 1:
self.tile = [
ImageFile._Tile(
"sgi_rle", (0, 0) + self.size, headlen, (rawmode, orientation, bpc)
)
]
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
if im.mode not in {"RGB", "RGBA", "L"}:
msg = "Unsupported SGI image mode"
raise ValueError(msg)
# Get the keyword arguments
info = im.encoderinfo
# Byte-per-pixel precision, 1 = 8bits per pixel
bpc = info.get("bpc", 1)
if bpc not in (1, 2):
msg = "Unsupported number of bytes per pixel"
raise ValueError(msg)
# Flip the image, since the origin of SGI file is the bottom-left corner
orientation = -1
# Define the file as SGI File Format
magic_number = 474
# Run-Length Encoding Compression - Unsupported at this time
rle = 0
# Number of dimensions (x,y,z)
dim = 3
# X Dimension = width / Y Dimension = height
x, y = im.size
if im.mode == "L" and y == 1:
dim = 1
elif im.mode == "L":
dim = 2
# Z Dimension: Number of channels
z = len(im.mode)
if dim in {1, 2}:
z = 1
# assert we've got the right number of bands.
if len(im.getbands()) != z:
msg = f"incorrect number of bands in SGI write: {z} vs {len(im.getbands())}"
raise ValueError(msg)
# Minimum Byte value
pinmin = 0
# Maximum Byte value (255 = 8bits per pixel)
pinmax = 255
# Image name (79 characters max, truncated below in write)
img_name = os.path.splitext(os.path.basename(filename))[0]
if isinstance(img_name, str):
img_name = img_name.encode("ascii", "ignore")
# Standard representation of pixel in the file
colormap = 0
fp.write(struct.pack(">h", magic_number))
fp.write(o8(rle))
fp.write(o8(bpc))
fp.write(struct.pack(">H", dim))
fp.write(struct.pack(">H", x))
fp.write(struct.pack(">H", y))
fp.write(struct.pack(">H", z))
fp.write(struct.pack(">l", pinmin))
fp.write(struct.pack(">l", pinmax))
fp.write(struct.pack("4s", b"")) # dummy
fp.write(struct.pack("79s", img_name)) # truncates to 79 chars
fp.write(struct.pack("s", b"")) # force null byte after img_name
fp.write(struct.pack(">l", colormap))
fp.write(struct.pack("404s", b"")) # dummy
rawmode = "L"
if bpc == 2:
rawmode = "L;16B"
for channel in im.split():
fp.write(channel.tobytes("raw", rawmode, 0, orientation))
if hasattr(fp, "flush"):
fp.flush()
class SGI16Decoder(ImageFile.PyDecoder):
_pulls_fd = True
def decode(self, buffer: bytes | Image.SupportsArrayInterface) -> tuple[int, int]:
assert self.fd is not None
assert self.im is not None
rawmode, stride, orientation = self.args
pagesize = self.state.xsize * self.state.ysize
zsize = len(self.mode)
self.fd.seek(512)
for band in range(zsize):
channel = Image.new("L", (self.state.xsize, self.state.ysize))
channel.frombytes(
self.fd.read(2 * pagesize), "raw", "L;16B", stride, orientation
)
self.im.putband(channel.im, band)
return -1, 0
#
# registry
Image.register_decoder("SGI16", SGI16Decoder)
Image.register_open(SgiImageFile.format, SgiImageFile, _accept)
Image.register_save(SgiImageFile.format, _save)
Image.register_mime(SgiImageFile.format, "image/sgi")
Image.register_extensions(SgiImageFile.format, [".bw", ".rgb", ".rgba", ".sgi"])
# End of file

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#
# The Python Imaging Library.
#
# SPIDER image file handling
#
# History:
# 2004-08-02 Created BB
# 2006-03-02 added save method
# 2006-03-13 added support for stack images
#
# Copyright (c) 2004 by Health Research Inc. (HRI) RENSSELAER, NY 12144.
# Copyright (c) 2004 by William Baxter.
# Copyright (c) 2004 by Secret Labs AB.
# Copyright (c) 2004 by Fredrik Lundh.
#
##
# Image plugin for the Spider image format. This format is used
# by the SPIDER software, in processing image data from electron
# microscopy and tomography.
##
#
# SpiderImagePlugin.py
#
# The Spider image format is used by SPIDER software, in processing
# image data from electron microscopy and tomography.
#
# Spider home page:
# https://spider.wadsworth.org/spider_doc/spider/docs/spider.html
#
# Details about the Spider image format:
# https://spider.wadsworth.org/spider_doc/spider/docs/image_doc.html
#
from __future__ import annotations
import os
import struct
import sys
from typing import IO, TYPE_CHECKING, Any, cast
from . import Image, ImageFile
def isInt(f: Any) -> int:
try:
i = int(f)
if f - i == 0:
return 1
else:
return 0
except (ValueError, OverflowError):
return 0
iforms = [1, 3, -11, -12, -21, -22]
# There is no magic number to identify Spider files, so just check a
# series of header locations to see if they have reasonable values.
# Returns no. of bytes in the header, if it is a valid Spider header,
# otherwise returns 0
def isSpiderHeader(t: tuple[float, ...]) -> int:
h = (99,) + t # add 1 value so can use spider header index start=1
# header values 1,2,5,12,13,22,23 should be integers
for i in [1, 2, 5, 12, 13, 22, 23]:
if not isInt(h[i]):
return 0
# check iform
iform = int(h[5])
if iform not in iforms:
return 0
# check other header values
labrec = int(h[13]) # no. records in file header
labbyt = int(h[22]) # total no. of bytes in header
lenbyt = int(h[23]) # record length in bytes
if labbyt != (labrec * lenbyt):
return 0
# looks like a valid header
return labbyt
def isSpiderImage(filename: str) -> int:
with open(filename, "rb") as fp:
f = fp.read(92) # read 23 * 4 bytes
t = struct.unpack(">23f", f) # try big-endian first
hdrlen = isSpiderHeader(t)
if hdrlen == 0:
t = struct.unpack("<23f", f) # little-endian
hdrlen = isSpiderHeader(t)
return hdrlen
class SpiderImageFile(ImageFile.ImageFile):
format = "SPIDER"
format_description = "Spider 2D image"
_close_exclusive_fp_after_loading = False
def _open(self) -> None:
# check header
n = 27 * 4 # read 27 float values
f = self.fp.read(n)
try:
self.bigendian = 1
t = struct.unpack(">27f", f) # try big-endian first
hdrlen = isSpiderHeader(t)
if hdrlen == 0:
self.bigendian = 0
t = struct.unpack("<27f", f) # little-endian
hdrlen = isSpiderHeader(t)
if hdrlen == 0:
msg = "not a valid Spider file"
raise SyntaxError(msg)
except struct.error as e:
msg = "not a valid Spider file"
raise SyntaxError(msg) from e
h = (99,) + t # add 1 value : spider header index starts at 1
iform = int(h[5])
if iform != 1:
msg = "not a Spider 2D image"
raise SyntaxError(msg)
self._size = int(h[12]), int(h[2]) # size in pixels (width, height)
self.istack = int(h[24])
self.imgnumber = int(h[27])
if self.istack == 0 and self.imgnumber == 0:
# stk=0, img=0: a regular 2D image
offset = hdrlen
self._nimages = 1
elif self.istack > 0 and self.imgnumber == 0:
# stk>0, img=0: Opening the stack for the first time
self.imgbytes = int(h[12]) * int(h[2]) * 4
self.hdrlen = hdrlen
self._nimages = int(h[26])
# Point to the first image in the stack
offset = hdrlen * 2
self.imgnumber = 1
elif self.istack == 0 and self.imgnumber > 0:
# stk=0, img>0: an image within the stack
offset = hdrlen + self.stkoffset
self.istack = 2 # So Image knows it's still a stack
else:
msg = "inconsistent stack header values"
raise SyntaxError(msg)
if self.bigendian:
self.rawmode = "F;32BF"
else:
self.rawmode = "F;32F"
self._mode = "F"
self.tile = [
ImageFile._Tile("raw", (0, 0) + self.size, offset, (self.rawmode, 0, 1))
]
self._fp = self.fp # FIXME: hack
@property
def n_frames(self) -> int:
return self._nimages
@property
def is_animated(self) -> bool:
return self._nimages > 1
# 1st image index is zero (although SPIDER imgnumber starts at 1)
def tell(self) -> int:
if self.imgnumber < 1:
return 0
else:
return self.imgnumber - 1
def seek(self, frame: int) -> None:
if self.istack == 0:
msg = "attempt to seek in a non-stack file"
raise EOFError(msg)
if not self._seek_check(frame):
return
self.stkoffset = self.hdrlen + frame * (self.hdrlen + self.imgbytes)
self.fp = self._fp
self.fp.seek(self.stkoffset)
self._open()
# returns a byte image after rescaling to 0..255
def convert2byte(self, depth: int = 255) -> Image.Image:
extrema = self.getextrema()
assert isinstance(extrema[0], float)
minimum, maximum = cast(tuple[float, float], extrema)
m: float = 1
if maximum != minimum:
m = depth / (maximum - minimum)
b = -m * minimum
return self.point(lambda i: i * m + b).convert("L")
if TYPE_CHECKING:
from . import ImageTk
# returns a ImageTk.PhotoImage object, after rescaling to 0..255
def tkPhotoImage(self) -> ImageTk.PhotoImage:
from . import ImageTk
return ImageTk.PhotoImage(self.convert2byte(), palette=256)
# --------------------------------------------------------------------
# Image series
# given a list of filenames, return a list of images
def loadImageSeries(filelist: list[str] | None = None) -> list[SpiderImageFile] | None:
"""create a list of :py:class:`~PIL.Image.Image` objects for use in a montage"""
if filelist is None or len(filelist) < 1:
return None
imglist = []
for img in filelist:
if not os.path.exists(img):
print(f"unable to find {img}")
continue
try:
with Image.open(img) as im:
im = im.convert2byte()
except Exception:
if not isSpiderImage(img):
print(f"{img} is not a Spider image file")
continue
im.info["filename"] = img
imglist.append(im)
return imglist
# --------------------------------------------------------------------
# For saving images in Spider format
def makeSpiderHeader(im: Image.Image) -> list[bytes]:
nsam, nrow = im.size
lenbyt = nsam * 4 # There are labrec records in the header
labrec = int(1024 / lenbyt)
if 1024 % lenbyt != 0:
labrec += 1
labbyt = labrec * lenbyt
nvalues = int(labbyt / 4)
if nvalues < 23:
return []
hdr = [0.0] * nvalues
# NB these are Fortran indices
hdr[1] = 1.0 # nslice (=1 for an image)
hdr[2] = float(nrow) # number of rows per slice
hdr[3] = float(nrow) # number of records in the image
hdr[5] = 1.0 # iform for 2D image
hdr[12] = float(nsam) # number of pixels per line
hdr[13] = float(labrec) # number of records in file header
hdr[22] = float(labbyt) # total number of bytes in header
hdr[23] = float(lenbyt) # record length in bytes
# adjust for Fortran indexing
hdr = hdr[1:]
hdr.append(0.0)
# pack binary data into a string
return [struct.pack("f", v) for v in hdr]
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
if im.mode[0] != "F":
im = im.convert("F")
hdr = makeSpiderHeader(im)
if len(hdr) < 256:
msg = "Error creating Spider header"
raise OSError(msg)
# write the SPIDER header
fp.writelines(hdr)
rawmode = "F;32NF" # 32-bit native floating point
ImageFile._save(
im, fp, [ImageFile._Tile("raw", (0, 0) + im.size, 0, (rawmode, 0, 1))]
)
def _save_spider(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
# get the filename extension and register it with Image
filename_ext = os.path.splitext(filename)[1]
ext = filename_ext.decode() if isinstance(filename_ext, bytes) else filename_ext
Image.register_extension(SpiderImageFile.format, ext)
_save(im, fp, filename)
# --------------------------------------------------------------------
Image.register_open(SpiderImageFile.format, SpiderImageFile)
Image.register_save(SpiderImageFile.format, _save_spider)
if __name__ == "__main__":
if len(sys.argv) < 2:
print("Syntax: python3 SpiderImagePlugin.py [infile] [outfile]")
sys.exit()
filename = sys.argv[1]
if not isSpiderImage(filename):
print("input image must be in Spider format")
sys.exit()
with Image.open(filename) as im:
print(f"image: {im}")
print(f"format: {im.format}")
print(f"size: {im.size}")
print(f"mode: {im.mode}")
print("max, min: ", end=" ")
print(im.getextrema())
if len(sys.argv) > 2:
outfile = sys.argv[2]
# perform some image operation
im = im.transpose(Image.Transpose.FLIP_LEFT_RIGHT)
print(
f"saving a flipped version of {os.path.basename(filename)} "
f"as {outfile} "
)
im.save(outfile, SpiderImageFile.format)

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#
# The Python Imaging Library.
# $Id$
#
# Sun image file handling
#
# History:
# 1995-09-10 fl Created
# 1996-05-28 fl Fixed 32-bit alignment
# 1998-12-29 fl Import ImagePalette module
# 2001-12-18 fl Fixed palette loading (from Jean-Claude Rimbault)
#
# Copyright (c) 1997-2001 by Secret Labs AB
# Copyright (c) 1995-1996 by Fredrik Lundh
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
from . import Image, ImageFile, ImagePalette
from ._binary import i32be as i32
def _accept(prefix: bytes) -> bool:
return len(prefix) >= 4 and i32(prefix) == 0x59A66A95
##
# Image plugin for Sun raster files.
class SunImageFile(ImageFile.ImageFile):
format = "SUN"
format_description = "Sun Raster File"
def _open(self) -> None:
# The Sun Raster file header is 32 bytes in length
# and has the following format:
# typedef struct _SunRaster
# {
# DWORD MagicNumber; /* Magic (identification) number */
# DWORD Width; /* Width of image in pixels */
# DWORD Height; /* Height of image in pixels */
# DWORD Depth; /* Number of bits per pixel */
# DWORD Length; /* Size of image data in bytes */
# DWORD Type; /* Type of raster file */
# DWORD ColorMapType; /* Type of color map */
# DWORD ColorMapLength; /* Size of the color map in bytes */
# } SUNRASTER;
assert self.fp is not None
# HEAD
s = self.fp.read(32)
if not _accept(s):
msg = "not an SUN raster file"
raise SyntaxError(msg)
offset = 32
self._size = i32(s, 4), i32(s, 8)
depth = i32(s, 12)
# data_length = i32(s, 16) # unreliable, ignore.
file_type = i32(s, 20)
palette_type = i32(s, 24) # 0: None, 1: RGB, 2: Raw/arbitrary
palette_length = i32(s, 28)
if depth == 1:
self._mode, rawmode = "1", "1;I"
elif depth == 4:
self._mode, rawmode = "L", "L;4"
elif depth == 8:
self._mode = rawmode = "L"
elif depth == 24:
if file_type == 3:
self._mode, rawmode = "RGB", "RGB"
else:
self._mode, rawmode = "RGB", "BGR"
elif depth == 32:
if file_type == 3:
self._mode, rawmode = "RGB", "RGBX"
else:
self._mode, rawmode = "RGB", "BGRX"
else:
msg = "Unsupported Mode/Bit Depth"
raise SyntaxError(msg)
if palette_length:
if palette_length > 1024:
msg = "Unsupported Color Palette Length"
raise SyntaxError(msg)
if palette_type != 1:
msg = "Unsupported Palette Type"
raise SyntaxError(msg)
offset = offset + palette_length
self.palette = ImagePalette.raw("RGB;L", self.fp.read(palette_length))
if self.mode == "L":
self._mode = "P"
rawmode = rawmode.replace("L", "P")
# 16 bit boundaries on stride
stride = ((self.size[0] * depth + 15) // 16) * 2
# file type: Type is the version (or flavor) of the bitmap
# file. The following values are typically found in the Type
# field:
# 0000h Old
# 0001h Standard
# 0002h Byte-encoded
# 0003h RGB format
# 0004h TIFF format
# 0005h IFF format
# FFFFh Experimental
# Old and standard are the same, except for the length tag.
# byte-encoded is run-length-encoded
# RGB looks similar to standard, but RGB byte order
# TIFF and IFF mean that they were converted from T/IFF
# Experimental means that it's something else.
# (https://www.fileformat.info/format/sunraster/egff.htm)
if file_type in (0, 1, 3, 4, 5):
self.tile = [
ImageFile._Tile("raw", (0, 0) + self.size, offset, (rawmode, stride))
]
elif file_type == 2:
self.tile = [
ImageFile._Tile("sun_rle", (0, 0) + self.size, offset, rawmode)
]
else:
msg = "Unsupported Sun Raster file type"
raise SyntaxError(msg)
#
# registry
Image.register_open(SunImageFile.format, SunImageFile, _accept)
Image.register_extension(SunImageFile.format, ".ras")

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#
# The Python Imaging Library.
# $Id$
#
# read files from within a tar file
#
# History:
# 95-06-18 fl Created
# 96-05-28 fl Open files in binary mode
#
# Copyright (c) Secret Labs AB 1997.
# Copyright (c) Fredrik Lundh 1995-96.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import io
from . import ContainerIO
class TarIO(ContainerIO.ContainerIO[bytes]):
"""A file object that provides read access to a given member of a TAR file."""
def __init__(self, tarfile: str, file: str) -> None:
"""
Create file object.
:param tarfile: Name of TAR file.
:param file: Name of member file.
"""
self.fh = open(tarfile, "rb")
while True:
s = self.fh.read(512)
if len(s) != 512:
msg = "unexpected end of tar file"
raise OSError(msg)
name = s[:100].decode("utf-8")
i = name.find("\0")
if i == 0:
msg = "cannot find subfile"
raise OSError(msg)
if i > 0:
name = name[:i]
size = int(s[124:135], 8)
if file == name:
break
self.fh.seek((size + 511) & (~511), io.SEEK_CUR)
# Open region
super().__init__(self.fh, self.fh.tell(), size)

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#
# The Python Imaging Library.
# $Id$
#
# TGA file handling
#
# History:
# 95-09-01 fl created (reads 24-bit files only)
# 97-01-04 fl support more TGA versions, including compressed images
# 98-07-04 fl fixed orientation and alpha layer bugs
# 98-09-11 fl fixed orientation for runlength decoder
#
# Copyright (c) Secret Labs AB 1997-98.
# Copyright (c) Fredrik Lundh 1995-97.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations
import warnings
from typing import IO
from . import Image, ImageFile, ImagePalette
from ._binary import i16le as i16
from ._binary import o8
from ._binary import o16le as o16
#
# --------------------------------------------------------------------
# Read RGA file
MODES = {
# map imagetype/depth to rawmode
(1, 8): "P",
(3, 1): "1",
(3, 8): "L",
(3, 16): "LA",
(2, 16): "BGRA;15Z",
(2, 24): "BGR",
(2, 32): "BGRA",
}
##
# Image plugin for Targa files.
class TgaImageFile(ImageFile.ImageFile):
format = "TGA"
format_description = "Targa"
def _open(self) -> None:
# process header
assert self.fp is not None
s = self.fp.read(18)
id_len = s[0]
colormaptype = s[1]
imagetype = s[2]
depth = s[16]
flags = s[17]
self._size = i16(s, 12), i16(s, 14)
# validate header fields
if (
colormaptype not in (0, 1)
or self.size[0] <= 0
or self.size[1] <= 0
or depth not in (1, 8, 16, 24, 32)
):
msg = "not a TGA file"
raise SyntaxError(msg)
# image mode
if imagetype in (3, 11):
self._mode = "L"
if depth == 1:
self._mode = "1" # ???
elif depth == 16:
self._mode = "LA"
elif imagetype in (1, 9):
self._mode = "P" if colormaptype else "L"
elif imagetype in (2, 10):
self._mode = "RGB" if depth == 24 else "RGBA"
else:
msg = "unknown TGA mode"
raise SyntaxError(msg)
# orientation
orientation = flags & 0x30
self._flip_horizontally = orientation in [0x10, 0x30]
if orientation in [0x20, 0x30]:
orientation = 1
elif orientation in [0, 0x10]:
orientation = -1
else:
msg = "unknown TGA orientation"
raise SyntaxError(msg)
self.info["orientation"] = orientation
if imagetype & 8:
self.info["compression"] = "tga_rle"
if id_len:
self.info["id_section"] = self.fp.read(id_len)
if colormaptype:
# read palette
start, size, mapdepth = i16(s, 3), i16(s, 5), s[7]
if mapdepth == 16:
self.palette = ImagePalette.raw(
"BGRA;15Z", bytes(2 * start) + self.fp.read(2 * size)
)
self.palette.mode = "RGBA"
elif mapdepth == 24:
self.palette = ImagePalette.raw(
"BGR", bytes(3 * start) + self.fp.read(3 * size)
)
elif mapdepth == 32:
self.palette = ImagePalette.raw(
"BGRA", bytes(4 * start) + self.fp.read(4 * size)
)
else:
msg = "unknown TGA map depth"
raise SyntaxError(msg)
# setup tile descriptor
try:
rawmode = MODES[(imagetype & 7, depth)]
if imagetype & 8:
# compressed
self.tile = [
ImageFile._Tile(
"tga_rle",
(0, 0) + self.size,
self.fp.tell(),
(rawmode, orientation, depth),
)
]
else:
self.tile = [
ImageFile._Tile(
"raw",
(0, 0) + self.size,
self.fp.tell(),
(rawmode, 0, orientation),
)
]
except KeyError:
pass # cannot decode
def load_end(self) -> None:
if self._flip_horizontally:
self.im = self.im.transpose(Image.Transpose.FLIP_LEFT_RIGHT)
#
# --------------------------------------------------------------------
# Write TGA file
SAVE = {
"1": ("1", 1, 0, 3),
"L": ("L", 8, 0, 3),
"LA": ("LA", 16, 0, 3),
"P": ("P", 8, 1, 1),
"RGB": ("BGR", 24, 0, 2),
"RGBA": ("BGRA", 32, 0, 2),
}
def _save(im: Image.Image, fp: IO[bytes], filename: str | bytes) -> None:
try:
rawmode, bits, colormaptype, imagetype = SAVE[im.mode]
except KeyError as e:
msg = f"cannot write mode {im.mode} as TGA"
raise OSError(msg) from e
if "rle" in im.encoderinfo:
rle = im.encoderinfo["rle"]
else:
compression = im.encoderinfo.get("compression", im.info.get("compression"))
rle = compression == "tga_rle"
if rle:
imagetype += 8
id_section = im.encoderinfo.get("id_section", im.info.get("id_section", ""))
id_len = len(id_section)
if id_len > 255:
id_len = 255
id_section = id_section[:255]
warnings.warn("id_section has been trimmed to 255 characters")
if colormaptype:
palette = im.im.getpalette("RGB", "BGR")
colormaplength, colormapentry = len(palette) // 3, 24
else:
colormaplength, colormapentry = 0, 0
if im.mode in ("LA", "RGBA"):
flags = 8
else:
flags = 0
orientation = im.encoderinfo.get("orientation", im.info.get("orientation", -1))
if orientation > 0:
flags = flags | 0x20
fp.write(
o8(id_len)
+ o8(colormaptype)
+ o8(imagetype)
+ o16(0) # colormapfirst
+ o16(colormaplength)
+ o8(colormapentry)
+ o16(0)
+ o16(0)
+ o16(im.size[0])
+ o16(im.size[1])
+ o8(bits)
+ o8(flags)
)
if id_section:
fp.write(id_section)
if colormaptype:
fp.write(palette)
if rle:
ImageFile._save(
im,
fp,
[ImageFile._Tile("tga_rle", (0, 0) + im.size, 0, (rawmode, orientation))],
)
else:
ImageFile._save(
im,
fp,
[ImageFile._Tile("raw", (0, 0) + im.size, 0, (rawmode, 0, orientation))],
)
# write targa version 2 footer
fp.write(b"\000" * 8 + b"TRUEVISION-XFILE." + b"\000")
#
# --------------------------------------------------------------------
# Registry
Image.register_open(TgaImageFile.format, TgaImageFile)
Image.register_save(TgaImageFile.format, _save)
Image.register_extensions(TgaImageFile.format, [".tga", ".icb", ".vda", ".vst"])
Image.register_mime(TgaImageFile.format, "image/x-tga")

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#
# The Python Imaging Library.
# $Id$
#
# TIFF tags
#
# This module provides clear-text names for various well-known
# TIFF tags. the TIFF codec works just fine without it.
#
# Copyright (c) Secret Labs AB 1999.
#
# See the README file for information on usage and redistribution.
#
##
# This module provides constants and clear-text names for various
# well-known TIFF tags.
##
from __future__ import annotations
from typing import NamedTuple
class _TagInfo(NamedTuple):
value: int | None
name: str
type: int | None
length: int | None
enum: dict[str, int]
class TagInfo(_TagInfo):
__slots__: list[str] = []
def __new__(
cls,
value: int | None = None,
name: str = "unknown",
type: int | None = None,
length: int | None = None,
enum: dict[str, int] | None = None,
) -> TagInfo:
return super().__new__(cls, value, name, type, length, enum or {})
def cvt_enum(self, value: str) -> int | str:
# Using get will call hash(value), which can be expensive
# for some types (e.g. Fraction). Since self.enum is rarely
# used, it's usually better to test it first.
return self.enum.get(value, value) if self.enum else value
def lookup(tag: int, group: int | None = None) -> TagInfo:
"""
:param tag: Integer tag number
:param group: Which :py:data:`~PIL.TiffTags.TAGS_V2_GROUPS` to look in
.. versionadded:: 8.3.0
:returns: Taginfo namedtuple, From the ``TAGS_V2`` info if possible,
otherwise just populating the value and name from ``TAGS``.
If the tag is not recognized, "unknown" is returned for the name
"""
if group is not None:
info = TAGS_V2_GROUPS[group].get(tag) if group in TAGS_V2_GROUPS else None
else:
info = TAGS_V2.get(tag)
return info or TagInfo(tag, TAGS.get(tag, "unknown"))
##
# Map tag numbers to tag info.
#
# id: (Name, Type, Length[, enum_values])
#
# The length here differs from the length in the tiff spec. For
# numbers, the tiff spec is for the number of fields returned. We
# agree here. For string-like types, the tiff spec uses the length of
# field in bytes. In Pillow, we are using the number of expected
# fields, in general 1 for string-like types.
BYTE = 1
ASCII = 2
SHORT = 3
LONG = 4
RATIONAL = 5
SIGNED_BYTE = 6
UNDEFINED = 7
SIGNED_SHORT = 8
SIGNED_LONG = 9
SIGNED_RATIONAL = 10
FLOAT = 11
DOUBLE = 12
IFD = 13
LONG8 = 16
_tags_v2: dict[int, tuple[str, int, int] | tuple[str, int, int, dict[str, int]]] = {
254: ("NewSubfileType", LONG, 1),
255: ("SubfileType", SHORT, 1),
256: ("ImageWidth", LONG, 1),
257: ("ImageLength", LONG, 1),
258: ("BitsPerSample", SHORT, 0),
259: (
"Compression",
SHORT,
1,
{
"Uncompressed": 1,
"CCITT 1d": 2,
"Group 3 Fax": 3,
"Group 4 Fax": 4,
"LZW": 5,
"JPEG": 6,
"PackBits": 32773,
},
),
262: (
"PhotometricInterpretation",
SHORT,
1,
{
"WhiteIsZero": 0,
"BlackIsZero": 1,
"RGB": 2,
"RGB Palette": 3,
"Transparency Mask": 4,
"CMYK": 5,
"YCbCr": 6,
"CieLAB": 8,
"CFA": 32803, # TIFF/EP, Adobe DNG
"LinearRaw": 32892, # Adobe DNG
},
),
263: ("Threshholding", SHORT, 1),
264: ("CellWidth", SHORT, 1),
265: ("CellLength", SHORT, 1),
266: ("FillOrder", SHORT, 1),
269: ("DocumentName", ASCII, 1),
270: ("ImageDescription", ASCII, 1),
271: ("Make", ASCII, 1),
272: ("Model", ASCII, 1),
273: ("StripOffsets", LONG, 0),
274: ("Orientation", SHORT, 1),
277: ("SamplesPerPixel", SHORT, 1),
278: ("RowsPerStrip", LONG, 1),
279: ("StripByteCounts", LONG, 0),
280: ("MinSampleValue", SHORT, 0),
281: ("MaxSampleValue", SHORT, 0),
282: ("XResolution", RATIONAL, 1),
283: ("YResolution", RATIONAL, 1),
284: ("PlanarConfiguration", SHORT, 1, {"Contiguous": 1, "Separate": 2}),
285: ("PageName", ASCII, 1),
286: ("XPosition", RATIONAL, 1),
287: ("YPosition", RATIONAL, 1),
288: ("FreeOffsets", LONG, 1),
289: ("FreeByteCounts", LONG, 1),
290: ("GrayResponseUnit", SHORT, 1),
291: ("GrayResponseCurve", SHORT, 0),
292: ("T4Options", LONG, 1),
293: ("T6Options", LONG, 1),
296: ("ResolutionUnit", SHORT, 1, {"none": 1, "inch": 2, "cm": 3}),
297: ("PageNumber", SHORT, 2),
301: ("TransferFunction", SHORT, 0),
305: ("Software", ASCII, 1),
306: ("DateTime", ASCII, 1),
315: ("Artist", ASCII, 1),
316: ("HostComputer", ASCII, 1),
317: ("Predictor", SHORT, 1, {"none": 1, "Horizontal Differencing": 2}),
318: ("WhitePoint", RATIONAL, 2),
319: ("PrimaryChromaticities", RATIONAL, 6),
320: ("ColorMap", SHORT, 0),
321: ("HalftoneHints", SHORT, 2),
322: ("TileWidth", LONG, 1),
323: ("TileLength", LONG, 1),
324: ("TileOffsets", LONG, 0),
325: ("TileByteCounts", LONG, 0),
330: ("SubIFDs", LONG, 0),
332: ("InkSet", SHORT, 1),
333: ("InkNames", ASCII, 1),
334: ("NumberOfInks", SHORT, 1),
336: ("DotRange", SHORT, 0),
337: ("TargetPrinter", ASCII, 1),
338: ("ExtraSamples", SHORT, 0),
339: ("SampleFormat", SHORT, 0),
340: ("SMinSampleValue", DOUBLE, 0),
341: ("SMaxSampleValue", DOUBLE, 0),
342: ("TransferRange", SHORT, 6),
347: ("JPEGTables", UNDEFINED, 1),
# obsolete JPEG tags
512: ("JPEGProc", SHORT, 1),
513: ("JPEGInterchangeFormat", LONG, 1),
514: ("JPEGInterchangeFormatLength", LONG, 1),
515: ("JPEGRestartInterval", SHORT, 1),
517: ("JPEGLosslessPredictors", SHORT, 0),
518: ("JPEGPointTransforms", SHORT, 0),
519: ("JPEGQTables", LONG, 0),
520: ("JPEGDCTables", LONG, 0),
521: ("JPEGACTables", LONG, 0),
529: ("YCbCrCoefficients", RATIONAL, 3),
530: ("YCbCrSubSampling", SHORT, 2),
531: ("YCbCrPositioning", SHORT, 1),
532: ("ReferenceBlackWhite", RATIONAL, 6),
700: ("XMP", BYTE, 0),
33432: ("Copyright", ASCII, 1),
33723: ("IptcNaaInfo", UNDEFINED, 1),
34377: ("PhotoshopInfo", BYTE, 0),
# FIXME add more tags here
34665: ("ExifIFD", LONG, 1),
34675: ("ICCProfile", UNDEFINED, 1),
34853: ("GPSInfoIFD", LONG, 1),
36864: ("ExifVersion", UNDEFINED, 1),
37724: ("ImageSourceData", UNDEFINED, 1),
40965: ("InteroperabilityIFD", LONG, 1),
41730: ("CFAPattern", UNDEFINED, 1),
# MPInfo
45056: ("MPFVersion", UNDEFINED, 1),
45057: ("NumberOfImages", LONG, 1),
45058: ("MPEntry", UNDEFINED, 1),
45059: ("ImageUIDList", UNDEFINED, 0), # UNDONE, check
45060: ("TotalFrames", LONG, 1),
45313: ("MPIndividualNum", LONG, 1),
45569: ("PanOrientation", LONG, 1),
45570: ("PanOverlap_H", RATIONAL, 1),
45571: ("PanOverlap_V", RATIONAL, 1),
45572: ("BaseViewpointNum", LONG, 1),
45573: ("ConvergenceAngle", SIGNED_RATIONAL, 1),
45574: ("BaselineLength", RATIONAL, 1),
45575: ("VerticalDivergence", SIGNED_RATIONAL, 1),
45576: ("AxisDistance_X", SIGNED_RATIONAL, 1),
45577: ("AxisDistance_Y", SIGNED_RATIONAL, 1),
45578: ("AxisDistance_Z", SIGNED_RATIONAL, 1),
45579: ("YawAngle", SIGNED_RATIONAL, 1),
45580: ("PitchAngle", SIGNED_RATIONAL, 1),
45581: ("RollAngle", SIGNED_RATIONAL, 1),
40960: ("FlashPixVersion", UNDEFINED, 1),
50741: ("MakerNoteSafety", SHORT, 1, {"Unsafe": 0, "Safe": 1}),
50780: ("BestQualityScale", RATIONAL, 1),
50838: ("ImageJMetaDataByteCounts", LONG, 0), # Can be more than one
50839: ("ImageJMetaData", UNDEFINED, 1), # see Issue #2006
}
_tags_v2_groups = {
# ExifIFD
34665: {
36864: ("ExifVersion", UNDEFINED, 1),
40960: ("FlashPixVersion", UNDEFINED, 1),
40965: ("InteroperabilityIFD", LONG, 1),
41730: ("CFAPattern", UNDEFINED, 1),
},
# GPSInfoIFD
34853: {
0: ("GPSVersionID", BYTE, 4),
1: ("GPSLatitudeRef", ASCII, 2),
2: ("GPSLatitude", RATIONAL, 3),
3: ("GPSLongitudeRef", ASCII, 2),
4: ("GPSLongitude", RATIONAL, 3),
5: ("GPSAltitudeRef", BYTE, 1),
6: ("GPSAltitude", RATIONAL, 1),
7: ("GPSTimeStamp", RATIONAL, 3),
8: ("GPSSatellites", ASCII, 0),
9: ("GPSStatus", ASCII, 2),
10: ("GPSMeasureMode", ASCII, 2),
11: ("GPSDOP", RATIONAL, 1),
12: ("GPSSpeedRef", ASCII, 2),
13: ("GPSSpeed", RATIONAL, 1),
14: ("GPSTrackRef", ASCII, 2),
15: ("GPSTrack", RATIONAL, 1),
16: ("GPSImgDirectionRef", ASCII, 2),
17: ("GPSImgDirection", RATIONAL, 1),
18: ("GPSMapDatum", ASCII, 0),
19: ("GPSDestLatitudeRef", ASCII, 2),
20: ("GPSDestLatitude", RATIONAL, 3),
21: ("GPSDestLongitudeRef", ASCII, 2),
22: ("GPSDestLongitude", RATIONAL, 3),
23: ("GPSDestBearingRef", ASCII, 2),
24: ("GPSDestBearing", RATIONAL, 1),
25: ("GPSDestDistanceRef", ASCII, 2),
26: ("GPSDestDistance", RATIONAL, 1),
27: ("GPSProcessingMethod", UNDEFINED, 0),
28: ("GPSAreaInformation", UNDEFINED, 0),
29: ("GPSDateStamp", ASCII, 11),
30: ("GPSDifferential", SHORT, 1),
},
# InteroperabilityIFD
40965: {1: ("InteropIndex", ASCII, 1), 2: ("InteropVersion", UNDEFINED, 1)},
}
# Legacy Tags structure
# these tags aren't included above, but were in the previous versions
TAGS: dict[int | tuple[int, int], str] = {
347: "JPEGTables",
700: "XMP",
# Additional Exif Info
32932: "Wang Annotation",
33434: "ExposureTime",
33437: "FNumber",
33445: "MD FileTag",
33446: "MD ScalePixel",
33447: "MD ColorTable",
33448: "MD LabName",
33449: "MD SampleInfo",
33450: "MD PrepDate",
33451: "MD PrepTime",
33452: "MD FileUnits",
33550: "ModelPixelScaleTag",
33723: "IptcNaaInfo",
33918: "INGR Packet Data Tag",
33919: "INGR Flag Registers",
33920: "IrasB Transformation Matrix",
33922: "ModelTiepointTag",
34264: "ModelTransformationTag",
34377: "PhotoshopInfo",
34735: "GeoKeyDirectoryTag",
34736: "GeoDoubleParamsTag",
34737: "GeoAsciiParamsTag",
34850: "ExposureProgram",
34852: "SpectralSensitivity",
34855: "ISOSpeedRatings",
34856: "OECF",
34864: "SensitivityType",
34865: "StandardOutputSensitivity",
34866: "RecommendedExposureIndex",
34867: "ISOSpeed",
34868: "ISOSpeedLatitudeyyy",
34869: "ISOSpeedLatitudezzz",
34908: "HylaFAX FaxRecvParams",
34909: "HylaFAX FaxSubAddress",
34910: "HylaFAX FaxRecvTime",
36864: "ExifVersion",
36867: "DateTimeOriginal",
36868: "DateTimeDigitized",
37121: "ComponentsConfiguration",
37122: "CompressedBitsPerPixel",
37724: "ImageSourceData",
37377: "ShutterSpeedValue",
37378: "ApertureValue",
37379: "BrightnessValue",
37380: "ExposureBiasValue",
37381: "MaxApertureValue",
37382: "SubjectDistance",
37383: "MeteringMode",
37384: "LightSource",
37385: "Flash",
37386: "FocalLength",
37396: "SubjectArea",
37500: "MakerNote",
37510: "UserComment",
37520: "SubSec",
37521: "SubSecTimeOriginal",
37522: "SubsecTimeDigitized",
40960: "FlashPixVersion",
40961: "ColorSpace",
40962: "PixelXDimension",
40963: "PixelYDimension",
40964: "RelatedSoundFile",
40965: "InteroperabilityIFD",
41483: "FlashEnergy",
41484: "SpatialFrequencyResponse",
41486: "FocalPlaneXResolution",
41487: "FocalPlaneYResolution",
41488: "FocalPlaneResolutionUnit",
41492: "SubjectLocation",
41493: "ExposureIndex",
41495: "SensingMethod",
41728: "FileSource",
41729: "SceneType",
41730: "CFAPattern",
41985: "CustomRendered",
41986: "ExposureMode",
41987: "WhiteBalance",
41988: "DigitalZoomRatio",
41989: "FocalLengthIn35mmFilm",
41990: "SceneCaptureType",
41991: "GainControl",
41992: "Contrast",
41993: "Saturation",
41994: "Sharpness",
41995: "DeviceSettingDescription",
41996: "SubjectDistanceRange",
42016: "ImageUniqueID",
42032: "CameraOwnerName",
42033: "BodySerialNumber",
42034: "LensSpecification",
42035: "LensMake",
42036: "LensModel",
42037: "LensSerialNumber",
42112: "GDAL_METADATA",
42113: "GDAL_NODATA",
42240: "Gamma",
50215: "Oce Scanjob Description",
50216: "Oce Application Selector",
50217: "Oce Identification Number",
50218: "Oce ImageLogic Characteristics",
# Adobe DNG
50706: "DNGVersion",
50707: "DNGBackwardVersion",
50708: "UniqueCameraModel",
50709: "LocalizedCameraModel",
50710: "CFAPlaneColor",
50711: "CFALayout",
50712: "LinearizationTable",
50713: "BlackLevelRepeatDim",
50714: "BlackLevel",
50715: "BlackLevelDeltaH",
50716: "BlackLevelDeltaV",
50717: "WhiteLevel",
50718: "DefaultScale",
50719: "DefaultCropOrigin",
50720: "DefaultCropSize",
50721: "ColorMatrix1",
50722: "ColorMatrix2",
50723: "CameraCalibration1",
50724: "CameraCalibration2",
50725: "ReductionMatrix1",
50726: "ReductionMatrix2",
50727: "AnalogBalance",
50728: "AsShotNeutral",
50729: "AsShotWhiteXY",
50730: "BaselineExposure",
50731: "BaselineNoise",
50732: "BaselineSharpness",
50733: "BayerGreenSplit",
50734: "LinearResponseLimit",
50735: "CameraSerialNumber",
50736: "LensInfo",
50737: "ChromaBlurRadius",
50738: "AntiAliasStrength",
50740: "DNGPrivateData",
50778: "CalibrationIlluminant1",
50779: "CalibrationIlluminant2",
50784: "Alias Layer Metadata",
}
TAGS_V2: dict[int, TagInfo] = {}
TAGS_V2_GROUPS: dict[int, dict[int, TagInfo]] = {}
def _populate() -> None:
for k, v in _tags_v2.items():
# Populate legacy structure.
TAGS[k] = v[0]
if len(v) == 4:
for sk, sv in v[3].items():
TAGS[(k, sv)] = sk
TAGS_V2[k] = TagInfo(k, *v)
for group, tags in _tags_v2_groups.items():
TAGS_V2_GROUPS[group] = {k: TagInfo(k, *v) for k, v in tags.items()}
_populate()
##
# Map type numbers to type names -- defined in ImageFileDirectory.
TYPES: dict[int, str] = {}
#
# These tags are handled by default in libtiff, without
# adding to the custom dictionary. From tif_dir.c, searching for
# case TIFFTAG in the _TIFFVSetField function:
# Line: item.
# 148: case TIFFTAG_SUBFILETYPE:
# 151: case TIFFTAG_IMAGEWIDTH:
# 154: case TIFFTAG_IMAGELENGTH:
# 157: case TIFFTAG_BITSPERSAMPLE:
# 181: case TIFFTAG_COMPRESSION:
# 202: case TIFFTAG_PHOTOMETRIC:
# 205: case TIFFTAG_THRESHHOLDING:
# 208: case TIFFTAG_FILLORDER:
# 214: case TIFFTAG_ORIENTATION:
# 221: case TIFFTAG_SAMPLESPERPIXEL:
# 228: case TIFFTAG_ROWSPERSTRIP:
# 238: case TIFFTAG_MINSAMPLEVALUE:
# 241: case TIFFTAG_MAXSAMPLEVALUE:
# 244: case TIFFTAG_SMINSAMPLEVALUE:
# 247: case TIFFTAG_SMAXSAMPLEVALUE:
# 250: case TIFFTAG_XRESOLUTION:
# 256: case TIFFTAG_YRESOLUTION:
# 262: case TIFFTAG_PLANARCONFIG:
# 268: case TIFFTAG_XPOSITION:
# 271: case TIFFTAG_YPOSITION:
# 274: case TIFFTAG_RESOLUTIONUNIT:
# 280: case TIFFTAG_PAGENUMBER:
# 284: case TIFFTAG_HALFTONEHINTS:
# 288: case TIFFTAG_COLORMAP:
# 294: case TIFFTAG_EXTRASAMPLES:
# 298: case TIFFTAG_MATTEING:
# 305: case TIFFTAG_TILEWIDTH:
# 316: case TIFFTAG_TILELENGTH:
# 327: case TIFFTAG_TILEDEPTH:
# 333: case TIFFTAG_DATATYPE:
# 344: case TIFFTAG_SAMPLEFORMAT:
# 361: case TIFFTAG_IMAGEDEPTH:
# 364: case TIFFTAG_SUBIFD:
# 376: case TIFFTAG_YCBCRPOSITIONING:
# 379: case TIFFTAG_YCBCRSUBSAMPLING:
# 383: case TIFFTAG_TRANSFERFUNCTION:
# 389: case TIFFTAG_REFERENCEBLACKWHITE:
# 393: case TIFFTAG_INKNAMES:
# Following pseudo-tags are also handled by default in libtiff:
# TIFFTAG_JPEGQUALITY 65537
# some of these are not in our TAGS_V2 dict and were included from tiff.h
# This list also exists in encode.c
LIBTIFF_CORE = {
255,
256,
257,
258,
259,
262,
263,
266,
274,
277,
278,
280,
281,
340,
341,
282,
283,
284,
286,
287,
296,
297,
321,
320,
338,
32995,
322,
323,
32998,
32996,
339,
32997,
330,
531,
530,
301,
532,
333,
# as above
269, # this has been in our tests forever, and works
65537,
}
LIBTIFF_CORE.remove(255) # We don't have support for subfiletypes
LIBTIFF_CORE.remove(322) # We don't have support for writing tiled images with libtiff
LIBTIFF_CORE.remove(323) # Tiled images
LIBTIFF_CORE.remove(333) # Ink Names either
# Note to advanced users: There may be combinations of these
# parameters and values that when added properly, will work and
# produce valid tiff images that may work in your application.
# It is safe to add and remove tags from this set from Pillow's point
# of view so long as you test against libtiff.

127
venv/lib/python3.12/site-packages/PIL/WalImageFile.py Normal file
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#
# The Python Imaging Library.
# $Id$
#
# WAL file handling
#
# History:
# 2003-04-23 fl created
#
# Copyright (c) 2003 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
"""
This reader is based on the specification available from:
https://www.flipcode.com/archives/Quake_2_BSP_File_Format.shtml
and has been tested with a few sample files found using google.
.. note::
This format cannot be automatically recognized, so the reader
is not registered for use with :py:func:`PIL.Image.open()`.
To open a WAL file, use the :py:func:`PIL.WalImageFile.open()` function instead.
"""
from __future__ import annotations
from typing import IO
from . import Image, ImageFile
from ._binary import i32le as i32
from ._typing import StrOrBytesPath
class WalImageFile(ImageFile.ImageFile):
format = "WAL"
format_description = "Quake2 Texture"
def _open(self) -> None:
self._mode = "P"
# read header fields
header = self.fp.read(32 + 24 + 32 + 12)
self._size = i32(header, 32), i32(header, 36)
Image._decompression_bomb_check(self.size)
# load pixel data
offset = i32(header, 40)
self.fp.seek(offset)
# strings are null-terminated
self.info["name"] = header[:32].split(b"\0", 1)[0]
next_name = header[56 : 56 + 32].split(b"\0", 1)[0]
if next_name:
self.info["next_name"] = next_name
def load(self) -> Image.core.PixelAccess | None:
if self._im is None:
self.im = Image.core.new(self.mode, self.size)
self.frombytes(self.fp.read(self.size[0] * self.size[1]))
self.putpalette(quake2palette)
return Image.Image.load(self)
def open(filename: StrOrBytesPath | IO[bytes]) -> WalImageFile:
"""
Load texture from a Quake2 WAL texture file.
By default, a Quake2 standard palette is attached to the texture.
To override the palette, use the :py:func:`PIL.Image.Image.putpalette()` method.
:param filename: WAL file name, or an opened file handle.
:returns: An image instance.
"""
return WalImageFile(filename)
quake2palette = (
# default palette taken from piffo 0.93 by Hans Häggström
b"\x01\x01\x01\x0b\x0b\x0b\x12\x12\x12\x17\x17\x17\x1b\x1b\x1b\x1e"
b"\x1e\x1e\x22\x22\x22\x26\x26\x26\x29\x29\x29\x2c\x2c\x2c\x2f\x2f"
b"\x2f\x32\x32\x32\x35\x35\x35\x37\x37\x37\x3a\x3a\x3a\x3c\x3c\x3c"
b"\x24\x1e\x13\x22\x1c\x12\x20\x1b\x12\x1f\x1a\x10\x1d\x19\x10\x1b"
b"\x17\x0f\x1a\x16\x0f\x18\x14\x0d\x17\x13\x0d\x16\x12\x0d\x14\x10"
b"\x0b\x13\x0f\x0b\x10\x0d\x0a\x0f\x0b\x0a\x0d\x0b\x07\x0b\x0a\x07"
b"\x23\x23\x26\x22\x22\x25\x22\x20\x23\x21\x1f\x22\x20\x1e\x20\x1f"
b"\x1d\x1e\x1d\x1b\x1c\x1b\x1a\x1a\x1a\x19\x19\x18\x17\x17\x17\x16"
b"\x16\x14\x14\x14\x13\x13\x13\x10\x10\x10\x0f\x0f\x0f\x0d\x0d\x0d"
b"\x2d\x28\x20\x29\x24\x1c\x27\x22\x1a\x25\x1f\x17\x38\x2e\x1e\x31"
b"\x29\x1a\x2c\x25\x17\x26\x20\x14\x3c\x30\x14\x37\x2c\x13\x33\x28"
b"\x12\x2d\x24\x10\x28\x1f\x0f\x22\x1a\x0b\x1b\x14\x0a\x13\x0f\x07"
b"\x31\x1a\x16\x30\x17\x13\x2e\x16\x10\x2c\x14\x0d\x2a\x12\x0b\x27"
b"\x0f\x0a\x25\x0f\x07\x21\x0d\x01\x1e\x0b\x01\x1c\x0b\x01\x1a\x0b"
b"\x01\x18\x0a\x01\x16\x0a\x01\x13\x0a\x01\x10\x07\x01\x0d\x07\x01"
b"\x29\x23\x1e\x27\x21\x1c\x26\x20\x1b\x25\x1f\x1a\x23\x1d\x19\x21"
b"\x1c\x18\x20\x1b\x17\x1e\x19\x16\x1c\x18\x14\x1b\x17\x13\x19\x14"
b"\x10\x17\x13\x0f\x14\x10\x0d\x12\x0f\x0b\x0f\x0b\x0a\x0b\x0a\x07"
b"\x26\x1a\x0f\x23\x19\x0f\x20\x17\x0f\x1c\x16\x0f\x19\x13\x0d\x14"
b"\x10\x0b\x10\x0d\x0a\x0b\x0a\x07\x33\x22\x1f\x35\x29\x26\x37\x2f"
b"\x2d\x39\x35\x34\x37\x39\x3a\x33\x37\x39\x30\x34\x36\x2b\x31\x34"
b"\x27\x2e\x31\x22\x2b\x2f\x1d\x28\x2c\x17\x25\x2a\x0f\x20\x26\x0d"
b"\x1e\x25\x0b\x1c\x22\x0a\x1b\x20\x07\x19\x1e\x07\x17\x1b\x07\x14"
b"\x18\x01\x12\x16\x01\x0f\x12\x01\x0b\x0d\x01\x07\x0a\x01\x01\x01"
b"\x2c\x21\x21\x2a\x1f\x1f\x29\x1d\x1d\x27\x1c\x1c\x26\x1a\x1a\x24"
b"\x18\x18\x22\x17\x17\x21\x16\x16\x1e\x13\x13\x1b\x12\x12\x18\x10"
b"\x10\x16\x0d\x0d\x12\x0b\x0b\x0d\x0a\x0a\x0a\x07\x07\x01\x01\x01"
b"\x2e\x30\x29\x2d\x2e\x27\x2b\x2c\x26\x2a\x2a\x24\x28\x29\x23\x27"
b"\x27\x21\x26\x26\x1f\x24\x24\x1d\x22\x22\x1c\x1f\x1f\x1a\x1c\x1c"
b"\x18\x19\x19\x16\x17\x17\x13\x13\x13\x10\x0f\x0f\x0d\x0b\x0b\x0a"
b"\x30\x1e\x1b\x2d\x1c\x19\x2c\x1a\x17\x2a\x19\x14\x28\x17\x13\x26"
b"\x16\x10\x24\x13\x0f\x21\x12\x0d\x1f\x10\x0b\x1c\x0f\x0a\x19\x0d"
b"\x0a\x16\x0b\x07\x12\x0a\x07\x0f\x07\x01\x0a\x01\x01\x01\x01\x01"
b"\x28\x29\x38\x26\x27\x36\x25\x26\x34\x24\x24\x31\x22\x22\x2f\x20"
b"\x21\x2d\x1e\x1f\x2a\x1d\x1d\x27\x1b\x1b\x25\x19\x19\x21\x17\x17"
b"\x1e\x14\x14\x1b\x13\x12\x17\x10\x0f\x13\x0d\x0b\x0f\x0a\x07\x07"
b"\x2f\x32\x29\x2d\x30\x26\x2b\x2e\x24\x29\x2c\x21\x27\x2a\x1e\x25"
b"\x28\x1c\x23\x26\x1a\x21\x25\x18\x1e\x22\x14\x1b\x1f\x10\x19\x1c"
b"\x0d\x17\x1a\x0a\x13\x17\x07\x10\x13\x01\x0d\x0f\x01\x0a\x0b\x01"
b"\x01\x3f\x01\x13\x3c\x0b\x1b\x39\x10\x20\x35\x14\x23\x31\x17\x23"
b"\x2d\x18\x23\x29\x18\x3f\x3f\x3f\x3f\x3f\x39\x3f\x3f\x31\x3f\x3f"
b"\x2a\x3f\x3f\x20\x3f\x3f\x14\x3f\x3c\x12\x3f\x39\x0f\x3f\x35\x0b"
b"\x3f\x32\x07\x3f\x2d\x01\x3d\x2a\x01\x3b\x26\x01\x39\x21\x01\x37"
b"\x1d\x01\x34\x1a\x01\x32\x16\x01\x2f\x12\x01\x2d\x0f\x01\x2a\x0b"
b"\x01\x27\x07\x01\x23\x01\x01\x1d\x01\x01\x17\x01\x01\x10\x01\x01"
b"\x3d\x01\x01\x19\x19\x3f\x3f\x01\x01\x01\x01\x3f\x16\x16\x13\x10"
b"\x10\x0f\x0d\x0d\x0b\x3c\x2e\x2a\x36\x27\x20\x30\x21\x18\x29\x1b"
b"\x10\x3c\x39\x37\x37\x32\x2f\x31\x2c\x28\x2b\x26\x21\x30\x22\x20"
)

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