This is gd 2.0.1 BETA.

If you have problems, report them in detail, and consider using gd 1.8.4 until gd 2.0 final is out.

The gd 2.0 documentation update is not complete, but most new features are documented to some degree and the what's new section is reasonably complete. Enjoy!

gd 2.0.1

A graphics library for fast image creation

Follow this link to the latest version of this document.

HEY! READ THIS! gd 2.0.1 creates PNG, JPEG and WBMP images, not GIF images. This is a good thing. PNG is a more compact format, and full compression is available. JPEG works well with photographic images, and is still more compatible with the major Web browsers than even PNG is. WBMP is intended for wireless devices (not regular web browsers). Existing code will need modification to call gdImagePng or gdImageJpeg instead of gdImageGif. Please do not ask us to send you the old GIF version of GD. Unisys holds a patent on the LZW compression algorithm, which is used in fully compressed GIF images. The best solution is to move to legally unencumbered, well-compressed, modern image formats such as PNG and JPEG as soon as possible.
gd 2.0.1 requires that the following libraries also be installed:
libpng (see the libpng home page)
zlib (see the info-zip home page) zlib
jpeg-6b or later, if desired (see the Independent JPEG Group home page)
If you want to use the TrueType font support, you must also install the FreeType 2.x library, including the header files. See the Freetype Home Page, or SourceForge. No, I cannot explain why that site is down on a particular day, and no, I can't send you a copy.
If you want to use the Xpm color bitmap loading support, you must also have the X Window System and the Xpm library installed (Xpm is often included in modern X distributions).
Please read the documentation and install the required libraries. Do not send email asking why png.h is not found. Do not send email asking why libgd.so is not found, either. See the requirements section for more information. Thank you!

Credits and license terms
What's new in version "XYZ" of GD?
What is gd?
What if I want to use another programming language?
What else do I need to use gd?
How do I get gd?
How do I build gd?
gd basics: using gd in your program
webpng: a useful example
Function and type reference by category
About the additional .gd image file format
Please tell us you're using gd!
If you have problems
Alphabetical quick index

Up to the Boutell.Com, Inc. Home Page

Credits and license terms

In order to resolve any possible confusion regarding the authorship of gd, the following copyright statement covers all of the authors who have required such a statement. If you are aware of any oversights in this copyright notice, please contact Thomas Boutell who will be pleased to correct them.

COPYRIGHT STATEMENT FOLLOWS THIS LINE

Portions copyright 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001 by Cold Spring Harbor Laboratory. Funded under Grant P41-RR02188 by the National Institutes of Health.
Portions copyright 1996, 1997, 1998, 1999, 2000, 2001 by Boutell.Com, Inc.
Portions relating to GD2 format copyright 1999, 2000 Philip Warner.
Portions relating to PNG copyright 1999, 2000 Greg Roelofs.
Portions relating to libttf copyright 1999, 2000 John Ellson (ellson@lucent.com).
Portions relating to JPEG and to color quantization copyright 2000, Doug Becker and copyright (C) 1994-1998, Thomas G. Lane. This software is based in part on the work of the Independent JPEG Group. See the file README-JPEG.TXT for more information.
Portions relating to WBMP copyright 2000 Maurice Szmurlo and Johan Van den Brande.
Permission has been granted to copy, distribute and modify gd in any context without fee, including a commercial application, provided that this notice is present in user-accessible supporting documentation.
This does not affect your ownership of the derived work itself, and the intent is to assure proper credit for the authors of gd, not to interfere with your productive use of gd. If you have questions, ask. "Derived works" includes all programs that utilize the library. Credit must be given in user-accessible documentation.
This software is provided "AS IS." The copyright holders disclaim all warranties, either express or implied, including but not limited to implied warranties of merchantability and fitness for a particular purpose, with respect to this code and accompanying documentation.
Although their code does not appear in gd 2.0.1, the authors wish to thank David Koblas, David Rowley, and Hutchison Avenue Software Corporation for their prior contributions.

END OF COPYRIGHT STATEMENT

What is gd?

gd is a graphics library. It allows your code to quickly draw images complete with lines, arcs, text, multiple colors, cut and paste from other images, and flood fills, and write out the result as a PNG or JPEG file. This is particularly useful in World Wide Web applications, where PNG and JPEG are two of the formats accepted for inline images by most browsers.

gd is not a paint program. If you are looking for a paint program, you are looking in the wrong place. If you are not a programmer, you are looking in the wrong place, unless you are installing a required library in order to run an application.

gd does not provide for every possible desirable graphics operation. It is not necessary or desirable for gd to become a kitchen-sink graphics package, but version 2.0 does include most frequently requested features, including both truecolor and palette images, resampling (smooth resizing of truecolor images) and so forth.

What if I want to use another programming language?

Not all of these tools are necessarily up to date and fully compatible with 2.0.1.

Perl

gd can also be used from Perl, courtesy of Lincoln Stein's GD.pm library, which uses gd as the basis for a set of Perl 5.x classes. Highly recommended.

Tcl

gd can be used from Tcl with John Ellson's Gdtclft dynamically loaded extension package. (Gdtclft2.0 or later is needed for gd-1.6 and up with PNG output.)

Pascal

Pascal enthusiasts should look into Michael Bradbury's gdfp package.

Haskell

A new gd interface is now available for Haskell programmers.

REXX

A gd interface for the REXX language is available.

Any Language

There are, at the moment, at least three simple interpreters that perform gd operations. You can output the desired commands to a simple text file from whatever scripting language you prefer to use, then invoke the interpreter.

tgd, by Bradley K. Sherman
fly, by Martin Gleeson

What's new in version 2.0.1?

Workaround for a bug in gcc, apparently found in gcc 2.7.2 and up. I reproduced and fixed it while using gcc 2.9.5.2. The bug occurred only when the -g option was in use. This problem caused gcc to spew internal error messages unrelated to the correctness of the code in gd_gd2.c. Howard Jones was first to report it.
gdImageFilledEllipse documented and altered; no longer requires a superfluous style argument. Thanks to Francis James Franklin.
The Makefile now offers the correct syntax for optionally creating a static library. Thanks to Jean-Lous Regez, among others.
A nested comment, an attempt to return the value of a void function, and a potentially significant error in gdImageCopyResampled were fixed thanks to Joseph Shirley.
A bug preventing proper truecolor text rendering was fixed, thanks to Jason Gallagher.
gdImageStringFT (FreeType) should now work better against a transparent or semitransparent background, and should act in a manner consistent with the most recent gdImageAlphaBlending setting. Antialiasing is now done via the alpha channel mechanism if the image is a truecolor image.
Bugs in the output of gdImageArc and gdImageFilledArc were reported by Bruce Verderaime. A simple and correct but inefficient implementation has been substituted until fixes are contributed for the faster code, which is in gd_arc_f_buggy.c along with the test program that reproduces the bug(s).
gdImageFilledArc now offers additional style options, which can be combined to produce various effects.
Masahito Yamaga (ma@yama-ga.com) sent a patch to improve support for Japanese output via gdImageStringFT. He also added a new readme.jpn file.
Zillions of documentation fixes.

What's new in version 2.0?

Support for truecolor images! Version 2.0 can load truecolor PNGs with no loss of color information, and almost no loss of alpha channel information. Version 2.0 can also load truecolor JPEGs with as little loss as possible; however, bear in mind that JPEG is a lossy format, so repeated load/save cycles always reduce image quality. This is not a bug. To create a truecolor image from scratch, call the new gdImageCreateTrueColor function. The gdImageCreate function is still available to create palette images, and may also be referred to as gdImageCreatePalette.
Support for alpha channels! In addition to 24 bits of color information for each pixel (eight bits of red, green, and blue respectively), version 2.0 supports 7 bits of "alpha channel" information. This is used to determine exactly how transparent the pixel should be. There is also support for a full 7 bits of transparency for each individual palette index in a palette-based image. Please note that, as of this writing, only Macintosh Internet Explorer 5.x and Mozilla/Netscape 6.x display partial transparency properly.
The new gdImageAlphaBlending function allows for two different modes of drawing. In blending mode, the alpha channel component of the color supplied to all drawing functions, such as gdImageSetPixel, determines how much of the underlying color should be allowed to shine through. The resulting image is not transparent. In non-blending mode, drawing color is copied literally with the alpha channel information, resulting in a transparent image. Blending mode is not available when drawing on palette images.
The gdImageCopyResampled function provides "smooth" copying from a large image to a smaller one, using a weighted average of the pixels of the source area rather than selecting one representative pixel. This function is identical to gdImageCopyResized when the destination image is a palette image.
The gdImageTrueColorToPalette function converts a truecolor image to a palette image. The code for this function was originally drawn from the Independent JPEG Group library code, which is excellent. The code has been modified to preserve as much alpha channel information as possible in the resulting palette, in addition to preserving colors as well as possible. This does not work as well as might be hoped. It is usually best to simply produce a truecolor output image instead, which guarantees the highest output quality.
A very high degree of backwards compatibility with existing gd 1.x code has been maintained, at both the source code and binary level. Code which directly accesses the pixels array will fail only if it encounters an existing truecolor image, which may happen if the code attempts to open and modify an existing JPEG or truecolor PNG. Such code should be modified to check the trueColor flag of the gdImage structure, and refer to the tpixels array instead when it is set.
gd is now compiled and installed as a shared library. However, gd still does not use autoconf, because I (TBB) have very limited patience with autoconf. These days, most Unix systems provide a fairly POSIX-standard environment, and the provided Makefile is likely to work well if users read it and follow the instructions at the top.
Support for line thickness was added by Michael Schwartz. My apologies to him for sitting on his patches for so long. See the new gdImageSetThickness function, which affects all standard gd functions that draw lines and curves. In addition, Michael added a convenient gdImageEllipse function.
The new gdImageFilledArc function provides a straightforward way to draw filled arcs. Also, gdImageFilledEllipse is a convenient way to fill an ellipse without specifying starting and ending angles. Thanks go out to F J Franklin.
To put an end to the confusion, TrueType 1.x support has been removed in favor of TrueType 2.x support. The old gdImageStringTTF function simply invokes gdImageStringFT.
The specialized .gd and .gd2 file formats have been upgraded to support truecolor. New images written by the versions of these functions found in 2.0 will be rejected, with varying degrees of grace, by older versions of gd. THIS AFFECTS THE .GD and .GD2 FORMATS ONLY. IF YOU ARE CONFUSED BY THIS PARAGRAPH, IT PROBABLY DOESN'T APPLY TO ANYTHING YOU WILL EVER ENCOUNTER. Since these file formats are absolutely, positively *not* designed for distributing images, just for preprocessing them, this should not be a big problem. gd 2.0 should read old .gd and .gd2 files correctly.

What's new in version 1.8.4?

Add support for FreeType2 (John Ellson ellson@lucent.com)
Add support for finding in fonts in a builtin DEFAULT_FONTPATH, or in a path from the GDFONTPATH environment variable.
remove some unused symbols to reduce compiler warnings
bugfix in size comparisons in gdImageCompare
REXX now mentioned
All memory allocation functions are now wrapped within the library; gdFree is exported and recommended for freeing memory returned by the gdImage(Something)Ptr family of functions.

What's new in version 1.8.3?

WBMP output memory leak fixed
#include <gd.h> corrected to #include "gd.h" in gd_wbmp.c
Documented the fact that the source and output images shouldn't match in the WBMP test except for black and white source images

What's new in version 1.8.2?

WBMP support debugged and improved by Johann Van den Brande
WBMP tests added to gdtest.c by Thomas Boutell
Use of platform-dependent 'install' command removed by Thomas Boutell
Comments added to Makefile warning users to juggle the order of the libraries if the linker complains; is there any portable way to do this automatically, short of using autoconf?
Documentation of gdImageCreateFromXpm corrected
Updated links to fast-moving, always dodging libpng and zlib web sites

What's new in version 1.8.1?

Optional components no longer built by default (following the documentation)
JPEG code no longer requires inappropriate header files
Win32 patches from Joe Gregorio
16-bit font support for bdftogd, from Honza Pazdziora

What's new in version 1.8?

Support for JPEG output, courtesy of Doug Becker
A link to Michael Bradbery's Pascal wrapper
Support for WBMP output, courtesy of Maurice Szmurlo
gdImageColorClosestHWB function based on hue, whiteness, blackness, superior to the regular gdImageColorClosest function, courtesy of Philip Warner
License clarification: yes, you can modify gd

Additional JPEG Information

Support for reading and writing JPEG-format images is courtesy of Doug Becker and the Independent JPEG Group / Thomas G. Lane. You can get the latest version of the IJG JPEG software from ftp://ftp.uu.net/graphics/jpeg/ (e.g., the jpegsrc.v6b.tar.gz file). You must use version 6b or later of the IJG JPEG software. You might also consult the JPEG FAQ at http://www.faqs.org/faqs/jpeg-faq/.

What's new in version 1.7.3?

Another attempt at Makefile fixes to permit linking with all libraries required on platforms with order- dependent linkers. Perhaps it will work this time.

What's new in version 1.7.2?

An uninitialized-pointer bug in gdtestttf.c was corrected. This bug caused crashes at the end of each call to gdImageStringTTF on some platforms. Thanks to Wolfgang Haefelinger.

Documentation fixes. Thanks to Dohn Arms.

Makefile fixes to permit linking with all libraries required on platforms with order- dependent linkers.

What's new in version 1.7.1?

A minor buglet in the Makefile was corrected, as well as an inaccurate error message in gdtestttf.c. Thanks to Masahito Yamaga.

What's new in version 1.7?

Version 1.7 contains the following changes:

Japanese language support for the TrueType functions. Thanks to Masahito Yamaga.
autoconf and configure have been removed, in favor of a carefully designed Makefile which produces and properly installs the library and the binaries. System-dependent variables are at the top of the Makefile for easy modification. I'm sorry, folks, but autoconf generated many, many confused email messages from people who didn't have things where autoconf expected to find them. I am not an autoconf/automake wizard, and gd is a simple, very compact library which does not need to be a shared library. I did make many improvements over the old gd 1.3 Makefile, which were directly inspired by the autoconf version found in the 1.6 series (thanks to John Ellson).
Completely ANSI C compliant, according to the -pedantic-errors flag of gcc. Several pieces of not-quite-ANSI-C code were causing problems for those with non-gcc compilers.
gdttf.c patched to allow the use of Windows symbol fonts, when present (thanks to Joseph Peppin).
extern "C" wrappers added to gd.h and the font header files for the convenience of C++ programmers. bdftogd was also modified to automatically insert these wrappers into future font header files. Thanks to John Lindal.
Compiles correctly on platforms that don't define SEEK_SET. Thanks to Robert Bonomi.
Loads Xpm images via the gdImageCreateFromXpm function, if the Xpm library is available. Thanks to Caolan McNamara.

What's new in version 1.6.3?

Version 1.6.3 corrects a memory leak in gd_png.c. This leak caused a significant amount of memory to be allocated and not freed when writing a PNG image.

What's new in version 1.6.2?

Version 1.6.2 from John Ellson adds two new functions:

gdImageStringTTF - scalable, rotatable, anti-aliased, TrueType strings using the FreeType library, but only if libttf is found by configure. We do not provide TrueType fonts. Obtaining them is entirely up to you.

gdImageColorResolve - an efficient alternative for the common code fragment:


      if ((color=gdImageColorExact(im,R,G,B)) < 0)
          if ((color=gdImageColorAllocate(im,R,G,B)) < 0)
              color=gdImageColorClosest(im,R,G,B);

Also in this release the build process has been converted to GNU autoconf/automake/libtool conventions so that both (or either) static and shared libraries can be built.

What's new in version 1.6.1?

Version 1.6.1 incorporates superior PNG reading and writing code from Greg Roelofs, with minor modifications by Tom Boutell. Specifically, I altered his code to read non-palette images (converting them to palette images badly, by dithering them), and to tolerate palette images with types of transparency that gd doesn't actually support (it just ignores the advanced transparency features). Any bugs in this area are therefore my fault, not Greg's.

Unlike gd 1.6, users should have no trouble linking with gd 1.6.1 if they follow the instructions and install all of the pieces. However, If you get undefined symbol errors, be sure to check for older versions of libpng in your library directories!

What's new in version 1.6?

Version 1.6 features the following changes:

Support for 8-bit palette PNG images has been added. Support for GIF has been removed. This step was taken to completely avoid the legal controversy regarding the LZW compression algorithm used in GIF. Unisys holds a patent which is relevant to LZW compression. PNG is a superior image format in any case. Now that PNG is supported by both Microsoft Internet Explorer and Netscape (in their recent releases), we highly recommend that GD users upgrade in order to get well-compressed images in a format which is legally unemcumbered.

What's new in version 1.5?

Version 1.5 featured the following changes:

New GD2 format

An improvement over the GD format, the GD2 format uses the zlib compression library to compress the image in chunks. This results in file sizes comparable to GIFs, with the ability to access parts of large images without having to read the entire image into memory.

This format also supports version numbers and rudimentary validity checks, so it should be more 'supportable' than the previous GD format.

Re-arranged source files

gd.c has been broken into constituant parts: io, gif, gd, gd2 and graphics functions are now in separate files.

Extended I/O capabilities.

The source/sink feature has been extended to support GD2 file formats (which require seek/tell functions), and to allow more general non-file I/O.

Better support for Lincoln Stein's Perl Module

The new gdImage*Ptr function returns the chosen format stored in a block of memory. This can be directly used by the GD perl module.

Added functions

gdImageCreateFromGd2Part - allows retrieval of part of an image (good for huge images, like maps),
gdImagePaletteCopy - Copies a palette from one image to another, doing it's best to match the colors in the target image to the colors in the source palette.
gdImageGd2, gdImageCreateFromGd2 - Support for new format
gdImageCopyMerge - Merges two images (useful to highlight part of an image)
gdImageCopyMergeGray - Similar to gdImageCopyMerge, but tries to preserve source image hue.
gdImagePngPtr, gdImageJpegPtr, gdImageWBMPPtr, gdImageGdPtr, gdImageGd2Ptr - return memory blocks for each type of image.
gdImageCreateFromPngCtx, gdImageCreateFromGdCtx, gdImageCreateFromGd2Ctx, gdImageCreateFromGd2PartCtx - Support for new I/O context.

NOTE: In fairness to Thomas Boutell, any bug/problems with any of the above features should probably be reported to Philip Warner.

What's new in version 1.4?

Version 1.4 features the following changes:

Fixed polygon fill routine (again): Thanks to Kirsten Schulz, version 1.4 is able to fill numerous types of polygons that caused problems with previous releases, including version 1.3.
Support for alternate data sources: Programmers who wish to load a GIF from something other than a stdio FILE * stream can use the new gdImageCreateFromPngSource function.
Support for alternate data destinations: Programmers who wish to write a GIF to something other than a stdio FILE * stream can use the new gdImagePngToSink function.
More tolerant when reading GIFs: Version 1.4 does not crash when reading certain animated GIFs, although it still only reads the first frame. Version 1.4 also has overflow testing code to prevent crashes when reading damaged GIFs.

What's new in version 1.3?

Version 1.3 features the following changes:

Non-LZW-based GIF compression code: Version 1.3 contained GIF compression code that uses simple Run Length Encoding instead of LZW compression, while still retaining compatibility with normal LZW-based GIF decoders (your browser will still like your GIFs). LZW compression is patented by Unisys. We are currently reevaluating the approach taken by gd 1.3. The current release of gd does not support this approach. We recommend that you use the current release, and generate PNG images. Thanks to Hutchison Avenue Software Corporation for contributing the RLE GIF code.
8-bit fonts, and 8-bit font support: This improves support for European languages. Thanks are due to Honza Pazdziora and also to Jan Pazdziora . Also see the provided bdftogd Perl script if you wish to convert fixed-width X11 fonts to gd fonts.
16-bit font support (no fonts provided): Although no such fonts are provided in the distribution, fonts containing more than 256 characters should work if the gdImageString16 and gdImageStringUp16 routines are used.
Improvements to the "webpng" example/utility: The "webpng" utility is now a slightly more useful application. Thanks to Brian Dowling for this code.
Corrections to the color resolution field of GIF output: Thanks to Bruno Aureli.
Fixed polygon fills: A one-line patch for the infamous polygon fill bug, courtesy of Jim Mason. I believe this fix is sufficient. However, if you find a situation where polygon fills still fail to behave properly, please send code that demonstrates the problem, and a fix if you have one. Verifying the fix is important.
Row-major, not column-major: Internally, gd now represents the array of pixels as an array of rows of pixels, rather than an array of columns of pixels. This improves the performance of compression and decompression routines slightly, because horizontally adjacent pixels are now next to each other in memory. This should not affect properly written gd applications, but applications that directly manipulate the pixels array will require changes.

What else do I need to use gd?

To use gd, you will need an ANSI C compiler. All popular Windows 95 and NT C compilers are ANSI C compliant. Any full-ANSI-standard C compiler should be adequate. The cc compiler released with SunOS 4.1.3 is not an ANSI C compiler. Most Unix users who do not already have gcc should get it. gcc is free, ANSI compliant and a de facto industry standard. Ask your ISP why it is missing.

As of version 1.6, you also need the zlib compression library, and the libpng library. As of version 1.6.2, you can draw text using antialiased TrueType fonts if you also have the libttf library installed, but this is not mandatory. zlib is available for a variety of platforms from the zlib web site. libpng is available for a variety of platforms from the PNG web site.

You will also want a PNG viewer, if you do not already have one for your system, since you will need a good way to check the results of your work. Netscape 4.04 and higher, and Microsoft Internet Explorer 4.0 or higher, both support PNG. For some purposes you might be happier with a package like Lview Pro for Windows or xv for X. There are PNG viewers available for every graphics-capable modern operating system, so consult newsgroups relevant to your particular system.

How do I get gd?

By HTTP

By FTP

How do I build gd?

In order to build gd, you must first unpack the archive you have downloaded. If you are not familiar with tar and gunzip (Unix) or ZIP (Windows), please consult with an experienced user of your system. Sorry, we cannot answer questions about basic Internet skills.

Unpacking the archive will produce a directory called "gd-2.0.1".

For Unix

cd to the 2.0.1 directory. Edit the Makefile with your preferred text editor and make any necessary changes to the settings at the top, especially if you want Xpm or TrueType support. Next, type "make install". Because gd 2.0 and above installs as a shared library, it is necessary to install the library properly before running gd-based programs.

If you get errors, edit the Makefile again, paying special attention to the INCLUDEDIRS and LIBDIRS settings.

IF YOU GET LINKER ERRORS, TRY JUGGLING THE ORDER OF THE -l DIRECTIVES IN THE MAKEFILE. Some platforms may prefer that the libraries be listed in the opposite order.

For Windows, Mac, Et Cetera

Create a project using your favorite programming environment. Copy all of the gd files to the project directory. Add gd.c to your project. Add other source files as appropriate. Learning the basic skills of creating projects with your chosen C environment is up to you.

If you wish to test the library, type "make test" AFTER you have successfully executed "make install". This will build several test programs, including "gddemo". Run gddemo to see some of the capabilities of gd.

gddemo should execute without incident, creating the file demoout.png. (Note there is also a file named demoin.png, which is provided in the package as part of the demonstration.)

Display demoout.png in your PNG viewer. The image should be 128x128 pixels and should contain an image of the space shuttle with quite a lot of graphical elements drawn on top of it.

(If you are missing the demoin.png file, the other items should appear anyway.)

Look at demoin.png to see the original space shuttle image which was scaled and copied into the output image.

gd basics: using gd in your program

gd lets you create PNG or JPEG images on the fly. To use gd in your program, include the file gd.h, and link with the libgd.a library produced by "make libgd.a", under Unix. Under other operating systems you will add gd.c to your own project.

If you want to use the provided fonts, include gdfontt.h, gdfonts.h, gdfontmb.h, gdfontl.h and/or gdfontg.h. For more impressive results, install FreeType 2.x and use the new gdImageStringFT function. If you are not using the provided Makefile and/or a library-based approach, be sure to include the source modules as well in your project. (They may be too large for 16-bit memory models, that is, 16-bit DOS and Windows.)

Here is a short example program. (For a more advanced example, see gddemo.c, included in the distribution. gddemo.c is NOT the same program; it demonstrates additional features!)

/* Bring in gd library functions */
#include "gd.h"

/* Bring in standard I/O so we can output the PNG to a file */
#include <stdio.h>

int main() {
	/* Declare the image */
	gdImagePtr im;
	/* Declare output files */
	FILE *pngout, *jpegout;
	/* Declare color indexes */
	int black;
	int white;

	/* Allocate the image: 64 pixels across by 64 pixels tall */
	im = gdImageCreate(64, 64);

	/* Allocate the color black (red, green and blue all minimum).
		Since this is the first color in a new image, it will
		be the background color. */
	black = gdImageColorAllocate(im, 0, 0, 0);	

	/* Allocate the color white (red, green and blue all maximum). */
	white = gdImageColorAllocate(im, 255, 255, 255);	
	
	/* Draw a line from the upper left to the lower right,
		using white color index. */
	gdImageLine(im, 0, 0, 63, 63, white);	

	/* Open a file for writing. "wb" means "write binary", important
		under MSDOS, harmless under Unix. */
	pngout = fopen("test.png", "wb");

	/* Do the same for a JPEG-format file. */
	jpegout = fopen("test.jpg", "wb");

	/* Output the image to the disk file in PNG format. */
	gdImagePng(im, pngout);

	/* Output the same image in JPEG format, using the default
		JPEG quality setting. */
	gdImageJpeg(im, jpegout, -1);

	/* Close the files. */
	fclose(pngout);
	fclose(jpegout);

	/* Destroy the image in memory. */
	gdImageDestroy(im);
}

When executed, this program creates an image, allocates two colors (the first color allocated becomes the background color), draws a diagonal line (note that 0, 0 is the upper left corner), writes the image to PNG and JPEG files, and destroys the image.

The above example program should give you an idea of how the package works. gd provides many additional functions, which are listed in the following reference chapters, complete with code snippets demonstrating each. There is also an alphabetical index.

Webpng: a more powerful gd example

Webpng is a simple utility program to manipulate PNGs from the command line. It is written for Unix and similar command-line systems, but should be easily adapted for other environments. Webpng allows you to set transparency and interlacing and output interesting information about the PNG in question.

webpng.c is provided in the distribution. Unix users can simply type "make webpng" to compile the program. Type "webpng" with no arguments to see the available options.

Function and type reference

Types
Image creation, destruction, loading and saving
Drawing, styling, brushing, tiling and filling functions
Query functions (not color-related)
Font and text-handling functions
Color handling functions
Copying and resizing functions
Miscellaneous Functions
Constants

Types

gdImage(TYPE)

The data structure in which gd stores images. gdImageCreate, gdImageCreateTrueColor and the various image file-loading functions return a pointer to this type, and the other functions expect to receive a pointer to this type as their first argument. It is reasonably safe to examine any of the members of this structure. It is also reasonably safe to modify individual pixels within the pixels or tpixels arrays. If the trueColor flag is set, the tpixels array is valid; otherwise the pixels array is valid.

The colorsTotal, red, green, blue, alpha and open arrays manage the palette. They are valid only when the trueColor flag is not set. The transparent value contains the palette index of the first transparent color as read-only information for backwards compatibility; gd 2.0 stores this information in the alpha array so that variable transparency can be supported for each palette entry. However, for truecolor images, transparent represents a single RGB color which is always 100% transparent, and this feature is generally supported by browsers which do not support full alpha channels.

typedef struct {
	/* Palette-based image pixels */
	unsigned char ** pixels;
	int sx;
	int sy;
	/* These are valid in palette images only. See also
	/* 'alpha', which appears later in the structure to
		preserve binary backwards compatibility */
	int colorsTotal;
	int red[gdMaxColors];
	int green[gdMaxColors];
	int blue[gdMaxColors]; 
	int open[gdMaxColors];
	/* For backwards compatibility, this is set to the
		first palette entry with 100% transparency,
		and is also set and reset by the 
		gdImageColorTransparent function. Newer
		applications can allocate palette entries
		with any desired level of transparency; however,
		bear in mind that many viewers, notably
		many web browsers, fail to implement
		full alpha channel for PNG and provide
		support for full opacity or transparency only. */
	int transparent;
	int *polyInts;
	int polyAllocated;
	struct gdImageStruct *brush;
	struct gdImageStruct *tile;	
	int brushColorMap[gdMaxColors];
	int tileColorMap[gdMaxColors];
	int styleLength;
	int stylePos;
	int *style;
	int interlace;
	/* New in 2.0: alpha channel for palettes. Note that only
		Macintosh Internet Explorer and (possibly) Netscape 6
		really support multiple levels of transparency in
		palettes, to my knowledge, as of 2/15/01. Most
		common browsers will display 100% opaque and
		100% transparent correctly, and do something 
		unpredictable and/or undesirable for levels
		in between. TBB */
	int alpha[gdMaxColors]; 
	/* Truecolor flag and pixels. New 2.0 fields appear here at the
		end to minimize breakage of existing object code. */
	int trueColor;
	int ** tpixels;
	/* Should alpha channel be copied, or applied, each time a
		pixel is drawn? This applies to truecolor images only.
		No attempt is made to alpha-blend in palette images,
		even if semitransparent palette entries exist. 
		To do that, build your image as a truecolor image,
		then quantize down to 8 bits. */
	int alphaBlendingFlag;
	/* Should the alpha channel of the image be saved? This affects
		PNG at the moment; other future formats may also
		have that capability. JPEG doesn't. */
	int saveAlphaFlag;
} gdImage;

The order of the structure members may appear confusing, but was chosen deliberately to increase backwards compatibility with existing gd 1.x-based binary code that references particular structure members.

gdImagePtr (TYPE)

A pointer to an image structure. gdImageCreate returns this type, and the other functions expect it as the first argument.

gdFont (TYPE)

A font structure. Used to declare the characteristics of a font. Plese see the files gdfontl.c and gdfontl.h for an example of the proper declaration of this structure. You can provide your own font data by providing such a structure and the associated pixel array. You can determine the width and height of a single character in a font by examining the w and h members of the structure. If you will not be creating your own fonts, you will not need to concern yourself with the rest of the components of this structure.

typedef struct {
	/* # of characters in font */
	int nchars;
	/* First character is numbered... (usually 32 = space) */
	int offset;
	/* Character width and height */
	int w;
	int h;
	/* Font data; array of characters, one row after another.
		Easily included in code, also easily loaded from
		data files. */
	char *data;
} gdFont;

gdFontPtr (TYPE)

A pointer to a font structure. Text-output functions expect these as their second argument, following the gdImagePtr argument. Two such pointers are declared in the provided include files gdfonts.h and gdfontl.h.

gdPoint (TYPE)

Represents a point in the coordinate space of the image; used by gdImagePolygon and gdImageFilledPolygon.

typedef struct {
        int x, y;
} gdPoint, *gdPointPtr;

gdPointPtr (TYPE)

A pointer to a gdPoint structure; passed as an argument to gdImagePolygon and gdImageFilledPolygon.

gdSource (TYPE)

typedef struct {
        int (*source) (void *context, char *buffer, int len);
        void *context;
} gdSource, *gdSourcePtr;

Represents a source from which a PNG can be read. Programmers who do not wish to read PNGs from a file can provide their own alternate input mechanism, using the gdImageCreateFromPngSource function. See the documentation of that function for an example of the proper use of this type.

gdSink (TYPE)

typedef struct {
        int (*sink) (void *context, char *buffer, int len);
        void *context;
} gdSink, *gdSinkPtr;

Represents a "sink" (destination) to which a PNG can be written. Programmers who do not wish to write PNGs to a file can provide their own alternate output mechanism, using the gdImagePngToSink function. See the documentation of that function for an example of the proper use of this type.

Image creation, destruction, loading and saving

gdImageCreate(sx, sy) (FUNCTION)

gdImageCreate is called to create palette-based images, with no more than 256 colors. Invoke gdImageCreate with the x and y dimensions of the desired image. gdImageCreate returns a gdImagePtr to the new image, or NULL if unable to allocate the image. The image must eventually be destroyed using gdImageDestroy().

... inside a function ...
gdImagePtr im;
im = gdImageCreate(64, 64);
/* ... Use the image ... */
gdImageDestroy(im);

gdImageCreateTrueColor(sx, sy) (FUNCTION)

gdImageCreateTrueColor is called to create truecolor images, with an essentially unlimited number of colors. Invoke gdImageCreateTrueColor with the x and y dimensions of the desired image. gdImageCreateTrueColor returns a gdImagePtr to the new image, or NULL if unable to allocate the image. The image must eventually be destroyed using gdImageDestroy().

Truecolor images are always filled with black at creation time.

... inside a function ...
gdImagePtr im;
im = gdImageCreateTrueColor(64, 64);
/* ... Use the image ... */
gdImageDestroy(im);

gdImageCreateFromJpeg(FILE *in) (FUNCTION)
gdImageCreateFromJpegCtx(FILE *in) (FUNCTION)

gdImageCreateFromJpeg is called to load images from JPEG format files. Invoke gdImageCreateFromJpeg with an already opened pointer to a file containing the desired image. gdImageCreateFromJpeg returns a gdImagePtr to the new truecolor image, or NULL if unable to load the image (most often because the file is corrupt or does not contain a JPEG image). gdImageCreateFromJpeg does not close the file. You can inspect the sx and sy members of the image to determine its size. The image must eventually be destroyed using gdImageDestroy(). The returned image is always a truecolor image.

gdImagePtr im;
... inside a function ...
FILE *in;
in = fopen("myjpeg.jpg", "rb");
im = gdImageCreateFromJpeg(in);
fclose(in);
/* ... Use the image ... */
gdImageDestroy(im);

gdImageCreateFromPng(FILE *in) (FUNCTION)
gdImageCreateFromPngCtx(gdIOCtx *in) (FUNCTION)

gdImageCreateFromPng is called to load images from PNG format files. Invoke gdImageCreateFromPng with an already opened pointer to a file containing the desired image. gdImageCreateFromPng returns a gdImagePtr to the new image, or NULL if unable to load the image (most often because the file is corrupt or does not contain a PNG image). gdImageCreateFromPng does not close the file. You can inspect the sx and sy members of the image to determine its size. The image must eventually be destroyed using gdImageDestroy().

If the PNG image being loaded is a truecolor image, the resulting gdImagePtr will refer to a truecolor image. If the PNG image being loaded is a palette or grayscale image, the resulting gdImagePtr will refer to a palette image. gd retains only 8 bits of resolution for each of the red, green and blue channels, and only 7 bits of resolution for the alpha channel. The former restriction affects only a handful of very rare 48-bit color and 16-bit grayscale PNG images. The second restriction affects all semitransparent PNG images, but the difference is essentially invisible to the eye. 7 bits of alpha channel resolution is, in practice, quite a lot.

gdImagePtr im;
... inside a function ...
FILE *in;
in = fopen("mypng.png", "rb");
im = gdImageCreateFromPng(in);
fclose(in);
/* ... Use the image ... */
gdImageDestroy(im);

gdImageCreateFromPngSource(gdSourcePtr in) (FUNCTION)

gdImageCreateFromPngSource is called to load a PNG from a data source other than a file. Usage is very similar to the gdImageCreateFromPng function, except that the programmer provides a custom data source.

The programmer must write an input function which accepts a context pointer, a buffer, and a number of bytes to be read as arguments. This function must read the number of bytes requested, unless the end of the file has been reached, in which case the function should return zero, or an error has occurred, in which case the function should return -1. The programmer then creates a gdSource structure and sets the source pointer to the input function and the context pointer to any value which is useful to the programmer.

The example below implements gdImageCreateFromPng by creating a custom data source and invoking gdImageCreateFromPngSource.

static int freadWrapper(void *context, char *buf, int len);

gdImagePtr gdImageCreateFromPng(FILE *in)
{
        gdSource s;
        s.source = freadWrapper;
        s.context = in;
        return gdImageCreateFromPngSource(&s);
}

static int freadWrapper(void *context, char *buf, int len)
{
        int got = fread(buf, 1, len, (FILE *) context);
        return got;
}

gdImageCreateFromGd(FILE *in) (FUNCTION)
gdImageCreateFromGdCtx(gdIOCtx *in) (FUNCTION)

gdImageCreateFromGd is called to load images from gd format files. Invoke gdImageCreateFromGd with an already opened pointer to a file containing the desired image in the gd file format, which is specific to gd and intended for very fast loading. (It is not intended for compression; for compression, use PNG or JPEG.) gdImageCreateFromGd returns a gdImagePtr to the new image, or NULL if unable to load the image (most often because the file is corrupt or does not contain a gd format image). gdImageCreateFromGd does not close the file. You can inspect the sx and sy members of the image to determine its size. The image must eventually be destroyed using gdImageDestroy().

... inside a function ...
gdImagePtr im;
FILE *in;
in = fopen("mygd.gd", "rb");
im = gdImageCreateFromGd(in);
fclose(in);
/* ... Use the image ... */
gdImageDestroy(im);

gdImageCreateFromGd2(FILE *in) (FUNCTION)
gdImageCreateFromGd2Ctx(gdIOCtx *in) (FUNCTION)

gdImageCreateFromGd2 is called to load images from gd2 format files. Invoke gdImageCreateFromGd2 with an already opened pointer to a file containing the desired image in the gd2 file format, which is specific to gd2 and intended for fast loading of parts of large images. (It is a compressed format, but generally not as good as maximum compression of the entire image would be.) gdImageCreateFromGd returns a gdImagePtr to the new image, or NULL if unable to load the image (most often because the file is corrupt or does not contain a gd format image). gdImageCreateFromGd2 does not close the file. You can inspect the sx and sy members of the image to determine its size. The image must eventually be destroyed using gdImageDestroy().

... inside a function ...
gdImagePtr im;
FILE *in;
in = fopen("mygd.gd2", "rb");
im = gdImageCreateFromGd2(in);
fclose(in);
/* ... Use the image ... */
gdImageDestroy(im);

gdImageCreateFromGd2Part(FILE *in, int srcX, int srcY, int w, int h) (FUNCTION)
gdImageCreateFromGd2PartCtx(gdIOCtx *in) (FUNCTION)

gdImageCreateFromGd2Part is called to load parts of images from gd2 format files. Invoked in the same way as gdImageCreateFromGd2, but with extra parameters indicating the source (x, y) and width/height of the desired image. gdImageCreateFromGd2Part returns a gdImagePtr to the new image, or NULL if unable to load the image. The image must eventually be destroyed using gdImageDestroy().

gdImageCreateFromXbm(FILE *in) (FUNCTION)

gdImageCreateFromXbm is called to load images from X bitmap format files. Invoke gdImageCreateFromXbm with an already opened pointer to a file containing the desired image. gdImageCreateFromXbm returns a gdImagePtr to the new image, or NULL if unable to load the image (most often because the file is corrupt or does not contain an X bitmap format image). gdImageCreateFromXbm does not close the file. You can inspect the sx and sy members of the image to determine its size. The image must eventually be destroyed using gdImageDestroy().

... inside a function ...
gdImagePtr im;
FILE *in;
in = fopen("myxbm.xbm", "rb");
im = gdImageCreateFromXbm(in);
fclose(in);
/* ... Use the image ... */
gdImageDestroy(im);

gdImageCreateFromXpm(char *filename) (FUNCTION)

gdImageCreateFromXbm is called to load images from XPM X Window System color bitmap format files. This function is available only if HAVE_XPM is selected in the Makefile and the Xpm library is linked with the application. Unlike most gd file functions, the Xpm functions require filenames, not file pointers. gdImageCreateFromXpm returns a gdImagePtr to the new image, or NULL if unable to load the image (most often because the file is corrupt or does not contain an XPM bitmap format image). You can inspect the sx and sy members of the image to determine its size. The image must eventually be destroyed using gdImageDestroy().

... inside a function ...
gdImagePtr im;
FILE *in;
in = fopen("myxpm.xpm", "rb");
im = gdImageCreateFromXpm(in);
fclose(in);
/* ... Use the image ... */
gdImageDestroy(im);

gdImageDestroy(gdImagePtr im) (FUNCTION)

gdImageDestroy is used to free the memory associated with an image. It is important to invoke gdImageDestroy before exiting your program or assigning a new image to a gdImagePtr variable.

... inside a function ...
gdImagePtr im;
im = gdImageCreate(10, 10);
/* ... Use the image ... */
/* Now destroy it */
gdImageDestroy(im);

void gdImageJpeg(gdImagePtr im, FILE *out, int quality) (FUNCTION)
void gdImageJpegCtx(gdImagePtr im, gdIOCtx *out, int quality) (FUNCTION)

gdImageJpeg outputs the specified image to the specified file in JPEG format. The file must be open for writing. Under MSDOS and all versions of Windows, it is important to use "wb" as opposed to simply "w" as the mode when opening the file, and under Unix there is no penalty for doing so. gdImageJpeg does not close the file; your code must do so.

If quality is negative, the default IJG JPEG quality value (which should yield a good general quality / size tradeoff for most situations) is used. Otherwise, for practical purposes, quality should be a value in the range 0-95, higher quality values usually implying both higher quality and larger image sizes.

If you have set image interlacing using gdImageInterlace, this function will interpret that to mean you wish to output a progressive JPEG. Some programs (e.g., Web browsers) can display progressive JPEGs incrementally; this can be useful when browsing over a relatively slow communications link, for example. Progressive JPEGs can also be slightly smaller than sequential (non-progressive) JPEGs.

... inside a function ...
gdImagePtr im;
int black, white;
FILE *out;
/* Create the image */
im = gdImageCreate(100, 100);
/* Allocate background */
white = gdImageColorAllocate(im, 255, 255, 255);
/* Allocate drawing color */
black = gdImageColorAllocate(im, 0, 0, 0);
/* Draw rectangle */
gdImageRectangle(im, 0, 0, 99, 99, black);
/* Open output file in binary mode */
out = fopen("rect.jpg", "wb");
/* Write JPEG using default quality */
gdImageJpeg(im, out, -1);
/* Close file */
fclose(out);
/* Destroy image */
gdImageDestroy(im);

void* gdImageJpegPtr(gdImagePtr im, int *size) (FUNCTION)

Identical to gdImageJpeg except that it returns a pointer to a memory area with the JPEG data. This memory must be freed by the caller when it is no longer needed. The caller must invoke gdFree(), not free(), unless the caller is absolutely certain that the same implementations of malloc, free, etc. are used both at library build time and at application build time. The 'size' parameter receives the total size of the block of memory.

void gdImagePng(gdImagePtr im, FILE *out) (FUNCTION)

gdImagePng outputs the specified image to the specified file in PNG format. The file must be open for writing. Under MSDOS and all versions of Windows, it is important to use "wb" as opposed to simply "w" as the mode when opening the file, and under Unix there is no penalty for doing so. gdImagePng does not close the file; your code must do so.

... inside a function ...
gdImagePtr im;
int black, white;
FILE *out;
/* Create the image */
im = gdImageCreate(100, 100);
/* Allocate background */
white = gdImageColorAllocate(im, 255, 255, 255);
/* Allocate drawing color */
black = gdImageColorAllocate(im, 0, 0, 0);
/* Draw rectangle */
gdImageRectangle(im, 0, 0, 99, 99, black);
/* Open output file in binary mode */
out = fopen("rect.png", "wb");
/* Write PNG */
gdImagePng(im, out);
/* Close file */
fclose(out);
/* Destroy image */
gdImageDestroy(im);

void* gdImagePngPtr(gdImagePtr im, int *size) (FUNCTION)

Identical to gdImagePng except that it returns a pointer to a memory area with the PNG data. This memory must be freed by the caller when it is no longer needed. The caller must invoke gdFree(), not free(), unless the caller is absolutely certain that the same implementations of malloc, free, etc. are used both at library build time and at application build time. The 'size' parameter receives the total size of the block of memory.

gdImagePngToSink(gdImagePtr im, gdSinkPtr out) (FUNCTION)

gdImagePngToSink is called to write a PNG to a data "sink" (destination) other than a file. Usage is very similar to the gdImagePng function, except that the programmer provides a custom data sink.

The programmer must write an output function which accepts a context pointer, a buffer, and a number of bytes to be written as arguments. This function must write the number of bytes requested and return that number, unless an error has occurred, in which case the function should return -1. The programmer then creates a gdSink structure and sets the sink pointer to the output function and the context pointer to any value which is useful to the programmer.

The example below implements gdImagePng by creating a custom data source and invoking gdImagePngFromSink.

static int stdioSink(void *context, char *buffer, int len)
{
	return fwrite(buffer, 1, len, (FILE *) context);
}

void gdImagePng(gdImagePtr im, FILE *out)
{
	gdSink mySink;
	mySink.context = (void *) out;
	mySink.sink = stdioSink;
	gdImagePngToSink(im, &mySink);
}

void gdImageWBMP(gdImagePtr im, int fg, FILE *out)
gdImageWBMPCtx(gdIOCtx *out) (FUNCTION)(FUNCTION)

gdImageWBMP outputs the specified image to the specified file in WBMP format. The file must be open for writing. Under MSDOS and all versions of Windows, it is important to use "wb" as opposed to simply "w" as the mode when opening the file, and under Unix there is no penalty for doing so. gdImageWBMP does not close the file; your code must do so.

WBMP file support is black and white only. The color index specified by the fg argument is the "foreground," and only pixels of this color will be set in the WBMP file. All other pixels will be considered "background."

... inside a function ...
gdImagePtr im;
int black, white;
FILE *out;
/* Create the image */
im = gdImageCreate(100, 100);
/* Allocate background */
white = gdImageColorAllocate(im, 255, 255, 255);
/* Allocate drawing color */
black = gdImageColorAllocate(im, 0, 0, 0);
/* Draw rectangle */
gdImageRectangle(im, 0, 0, 99, 99, black);
/* Open output file in binary mode */
out = fopen("rect.wbmp", "wb");
/* Write WBMP, with black as foreground */
gdImageWBMP(im, black, out);
/* Close file */
fclose(out);
/* Destroy image */
gdImageDestroy(im);

void* gdImageWBMPPtr(gdImagePtr im, int *size) (FUNCTION)

Identical to gdImageWBMP except that it returns a pointer to a memory area with the WBMP data. This memory must be freed by the caller when it is no longer needed. The caller must invoke gdFree(), not free(), unless the caller is absolutely certain that the same implementations of malloc, free, etc. are used both at library build time and at application build time. The 'size' parameter receives the total size of the block of memory.

void gdImageGd(gdImagePtr im, FILE *out) (FUNCTION)

gdImageGd outputs the specified image to the specified file in the gd image format. The file must be open for writing. Under MSDOS and all versions of Windows, it is important to use "wb" as opposed to simply "w" as the mode when opening the file, and under Unix there is no penalty for doing so. gdImagePng does not close the file; your code must do so.

The gd image format is intended for fast reads and writes of images your program will need frequently to build other images. It is not a compressed format, and is not intended for general use.

... inside a function ...
gdImagePtr im;
int black, white;
FILE *out;
/* Create the image */
im = gdImageCreate(100, 100);
/* Allocate background */
white = gdImageColorAllocate(im, 255, 255, 255);
/* Allocate drawing color */
black = gdImageColorAllocate(im, 0, 0, 0);
/* Draw rectangle */
gdImageRectangle(im, 0, 0, 99, 99, black);
/* Open output file in binary mode */
out = fopen("rect.gd", "wb");
/* Write gd format file */
gdImageGd(im, out);
/* Close file */
fclose(out);
/* Destroy image */
gdImageDestroy(im);

void* gdImageGdPtr(gdImagePtr im, int *size) (FUNCTION)

Identical to gdImageGd except that it returns a pointer to a memory area with the GD data. This memory must be freed by the caller when it is no longer needed. The caller must invoke gdFree(), not free(), unless the caller is absolutely certain that the same implementations of malloc, free, etc. are used both at library build time and at application build time. The 'size' parameter receives the total size of the block of memory.

void gdImageGd2(gdImagePtr im, FILE *out, int chunkSize, int fmt) (FUNCTION)

gdImageGd2 outputs the specified image to the specified file in the gd2 image format. The file must be open for writing. Under MSDOS and all versions of Windows, it is important to use "wb" as opposed to simply "w" as the mode when opening the file, and under Unix there is no penalty for doing so. gdImageGd2 does not close the file; your code must do so.

The gd2 image format is intended for fast reads and writes of parts of images. It is a compressed format, and well suited to retrieving smll sections of much larger images. The third and fourth parameters are the 'chunk size' and format resposectively.

The file is stored as a series of compressed subimages, and the Chunk Size determines the sub-image size - a value of zero causes the GD library to use the default.

It is also possible to store GD2 files in an uncompressed format, in which case the fourth parameter should be GD2_FMT_RAW.

... inside a function ...
gdImagePtr im;
int black, white;
FILE *out;
/* Create the image */
im = gdImageCreate(100, 100);
/* Allocate background */
white = gdImageColorAllocate(im, 255, 255, 255);
/* Allocate drawing color */
black = gdImageColorAllocate(im, 0, 0, 0);
/* Draw rectangle */
gdImageRectangle(im, 0, 0, 99, 99, black);
/* Open output file in binary mode */
out = fopen("rect.gd", "wb");
/* Write gd2 format file */
gdImageGd2(im, out, 0, GD2_FMT_COMPRESSED);
/* Close file */
fclose(out);
/* Destroy image */
gdImageDestroy(im);

void* gdImageGd2Ptr(gdImagePtr im, int chunkSize, int fmt, int *size) (FUNCTION)

Identical to gdImageGd2 except that it returns a pointer to a memory area with the GD2 data. This memory must be freed by the caller when it is no longer needed. The caller must invoke gdFree(), not free(), unless the caller is absolutely certain that the same implementations of malloc, free, etc. are used both at library build time and at application build time. The 'size' parameter receives the total size of the block of memory.

Drawing Functions

void gdImageSetPixel(gdImagePtr im, int x, int y, int color) (FUNCTION)

gdImageSetPixel sets a pixel to a particular color index. Always use this function or one of the other drawing functions to access pixels; do not access the pixels of the gdImage structure directly.

... inside a function ...
gdImagePtr im;
int black;
int white;
im = gdImageCreate(100, 100);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Set a pixel near the center. */
gdImageSetPixel(im, 50, 50, white);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageLine(gdImagePtr im, int x1, int y1, int x2, int y2, int color) (FUNCTION)

gdImageLine is used to draw a line between two endpoints (x1,y1 and x2, y2). The line is drawn using the color index specified. Note that the color index can be an actual color returned by gdImageColorAllocate or one of gdStyled, gdBrushed or gdStyledBrushed.

... inside a function ...
gdImagePtr im;
int black;
int white;
im = gdImageCreate(100, 100);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Draw a line from the upper left corner to the lower right corner. */
gdImageLine(im, 0, 0, 99, 99, white);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageDashedLine(gdImagePtr im, int x1, int y1, int x2, int y2, int color) (FUNCTION)

gdImageDashedLine is provided solely for backwards compatibility with gd 1.0. New programs should draw dashed lines using the normal gdImageLine function and the new gdImageSetStyle function.

gdImageDashedLine is used to draw a dashed line between two endpoints (x1,y1 and x2, y2). The line is drawn using the color index specified. The portions of the line that are not drawn are left transparent so the background is visible.

... inside a function ...
gdImagePtr im;
int black;
int white;
im = gdImageCreate(100, 100);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Draw a dashed line from the upper left corner to the lower right corner. */
gdImageDashedLine(im, 0, 0, 99, 99);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImagePolygon(gdImagePtr im, gdPointPtr points, int pointsTotal, int color) (FUNCTION)

gdImagePolygon is used to draw a polygon with the verticies (at least 3) specified, using the color index specified. See also gdImageFilledPolygon.

... inside a function ...
gdImagePtr im;
int black;
int white;
/* Points of polygon */
gdPoint points[3];
im = gdImageCreate(100, 100);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Draw a triangle. */
points[0].x = 50;
points[0].y = 0;
points[1].x = 99;
points[1].y = 99;
points[2].x = 0;
points[2].y = 99;
gdImagePolygon(im, points, 3, white);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageRectangle(gdImagePtr im, int x1, int y1, int x2, int y2, int color) (FUNCTION)

gdImageRectangle is used to draw a rectangle with the two corners (upper left first, then lower right) specified, using the color index specified.

... inside a function ...
gdImagePtr im;
int black;
int white;
im = gdImageCreate(100, 100);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Draw a rectangle occupying the central area. */
gdImageRectangle(im, 25, 25, 74, 74, white);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageFilledPolygon(gdImagePtr im, gdPointPtr points, int pointsTotal, int color) (FUNCTION)

gdImageFilledPolygon is used to fill a polygon with the verticies (at least 3) specified, using the color index specified. See also gdImagePolygon.

... inside a function ...
gdImagePtr im;
int black;
int white;
int red;
/* Points of polygon */
gdPoint points[3];
im = gdImageCreate(100, 100);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Allocate the color red. */
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Draw a triangle. */
points[0].x = 50;
points[0].y = 0;
points[1].x = 99;
points[1].y = 99;
points[2].x = 0;
points[2].y = 99;
/* Paint it in white */
gdImageFilledPolygon(im, points, 3, white);
/* Outline it in red; must be done second */
gdImagePolygon(im, points, 3, red);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageFilledRectangle(gdImagePtr im, int x1, int y1, int x2, int y2, int color) (FUNCTION)

gdImageFilledRectangle is used to draw a solid rectangle with the two corners (upper left first, then lower right) specified, using the color index specified.

... inside a function ...
gdImagePtr im;
int black;
int white;
im = gdImageCreate(100, 100);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = int gdImageColorAllocate(im, 255, 255, 255);	
/* Draw a filled rectangle occupying the central area. */
gdImageFilledRectangle(im, 25, 25, 74, 74, white);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageArc(gdImagePtr im, int cx, int cy, int w, int h, int s, int e, int color) (FUNCTION)

gdImageArc is used to draw a partial ellipse centered at the given point, with the specified width and height in pixels. The arc begins at the position in degrees specified by s and ends at the position specified by e. The arc is drawn in the color specified by the last argument. A circle can be drawn by beginning from 0 degrees and ending at 360 degrees, with width and height being equal. e must be greater than s. Values greater than 360 are interpreted modulo 360.

... inside a function ...
gdImagePtr im;
int black;
int white;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Inscribe an ellipse in the image. */
gdImageArc(im, 50, 25, 98, 48, 0, 360, white);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageFilledArc(gdImagePtr im, int cx, int cy, int w, int h, int s, int e, int color, int style) (FUNCTION)

gdImageFilledArc is used to draw a partial ellipse centered at the given point, with the specified width and height in pixels. The arc begins at the position in degrees specified by s and ends at the position specified by e. The arc is filled in the color specified by the second to last argument. A circle can be drawn by beginning from 0 degrees and ending at 360 degrees, with width and height being equal. e must be greater than s. Values greater than 360 are interpreted modulo 360. The last argument is a bitwise OR of the following possibilities:

gdArc
gdChord
gdPie (synonym for gdChord)
gdNoFill
gdEdged

gdArc and gdChord are mutually exclusive; gdChord just connects the starting and ending angles with a straight line, while gdArc produces a rounded edge. gdPie is a synonym for gdArc. gdNoFill indicates that the arc or chord should be outlined, not filled. gdEdged, used together with gdNoFill, indicates that the beginning and ending angles should be connected to the center; this is a good way to outline (rather than fill) a 'pie slice'.

... inside a function ...
gdImagePtr im;
int black;
int white;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Inscribe a filled pie slice in the image. */
gdImageFilledArc(im, 50, 25, 98, 48, 0, 45, white, gdArc);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageFilledEllipse(gdImagePtr im, int cx, int cy, int w, int h, int s, int e, int color) (FUNCTION)

gdImageFilledEllipse is used to draw an ellipse centered at the given point, with the specified width and height in pixels. The ellipse is filled in the color specified by the last argument. A circle can be drawn by beginning from 0 degrees and ending at 360 degrees, with width and height being equal. e must be greater than s. Values greater than 360 are interpreted modulo 360.

... inside a function ...
gdImagePtr im;
int black;
int white;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Inscribe a filled ellipse in the image. */
gdImageFilledEllipse(im, 50, 25, 98, 48, white);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageFillToBorder(gdImagePtr im, int x, int y, int border, int color) (FUNCTION)

gdImageFillToBorder floods a portion of the image with the specified color, beginning at the specified point and stopping at the specified border color. For a way of flooding an area defined by the color of the starting point, see gdImageFill.

The border color cannot be a special color such as gdTiled; it must be a proper solid color. The fill color can be, however.

Note that gdImageFillToBorder is recursive. It is not the most naive implementation possible, and the implementation is expected to improve, but there will always be degenerate cases in which the stack can become very deep. This can be a problem in MSDOS and MS Windows 3.1 environments. (Of course, in a Unix or Windows 95/98/NT environment with a proper stack, this is not a problem at all.)

... inside a function ...
gdImagePtr im;
int black;
int white;
int red;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Allocate the color red. */
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Inscribe an ellipse in the image. */
gdImageArc(im, 50, 25, 98, 48, 0, 360, white);
/* Flood-fill the ellipse. Fill color is red, border color is
	white (ellipse). */
gdImageFillToBorder(im, 50, 50, white, red);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageFill(gdImagePtr im, int x, int y, int color) (FUNCTION)

gdImageFill floods a portion of the image with the specified color, beginning at the specified point and flooding the surrounding region of the same color as the starting point. For a way of flooding a region defined by a specific border color rather than by its interior color, see gdImageFillToBorder.

The fill color can be gdTiled, resulting in a tile fill using another image as the tile. However, the tile image cannot be transparent. If the image you wish to fill with has a transparent color index, call gdImageTransparent on the tile image and set the transparent color index to -1 to turn off its transparency.

Note that gdImageFill is recursive. It is not the most naive implementation possible, and the implementation is expected to improve, but there will always be degenerate cases in which the stack can become very deep. This can be a problem in MSDOS and MS Windows environments. (Of course, in a Unix or Windows 95/98/NT environment with a proper stack, this is not a problem at all.)

... inside a function ...
gdImagePtr im;
int black;
int white;
int red;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Allocate the color red. */
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Inscribe an ellipse in the image. */
gdImageArc(im, 50, 25, 98, 48, 0, 360, white);
/* Flood-fill the ellipse. Fill color is red, and will replace the
	black interior of the ellipse. */
gdImageFill(im, 50, 50, red);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageSetBrush(gdImagePtr im, gdImagePtr brush) (FUNCTION)

A "brush" is an image used to draw wide, shaped strokes in another image. Just as a paintbrush is not a single point, a brush image need not be a single pixel. Any gd image can be used as a brush, and by setting the transparent color index of the brush image with gdImageColorTransparent, a brush of any shape can be created. All line-drawing functions, such as gdImageLine and gdImagePolygon, will use the current brush if the special "color" gdBrushed or gdStyledBrushed is used when calling them.

gdImageSetBrush is used to specify the brush to be used in a particular image. You can set any image to be the brush. If the brush image does not have the same color map as the first image, any colors missing from the first image will be allocated. If not enough colors can be allocated, the closest colors already available will be used. This allows arbitrary PNGs to be used as brush images. It also means, however, that you should not set a brush unless you will actually use it; if you set a rapid succession of different brush images, you can quickly fill your color map, and the results will not be optimal.

You need not take any special action when you are finished with a brush. As for any other image, if you will not be using the brush image for any further purpose, you should call gdImageDestroy. You must not use the color gdBrushed if the current brush has been destroyed; you can of course set a new brush to replace it.

... inside a function ...
gdImagePtr im, brush;
FILE *in;
int black;
im = gdImageCreate(100, 100);
/* Open the brush PNG. For best results, portions of the
	brush that should be transparent (ie, not part of the
	brush shape) should have the transparent color index. */
in = fopen("star.png", "rb");
brush = gdImageCreateFromPng(in);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
gdImageSetBrush(im, brush);
/* Draw a line from the upper left corner to the lower right corner
	using the brush. */
gdImageLine(im, 0, 0, 99, 99, gdBrushed);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);
/* Destroy the brush image */
gdImageDestroy(brush);

void gdImageSetTile(gdImagePtr im, gdImagePtr tile) (FUNCTION)

A "tile" is an image used to fill an area with a repeated pattern. Any gd image can be used as a tile, and by setting the transparent color index of the tile image with gdImageColorTransparent, a tile that allows certain parts of the underlying area to shine through can be created. All region-filling functions, such as gdImageFill and gdImageFilledPolygon, will use the current tile if the special "color" gdTiled is used when calling them.

gdImageSetTile is used to specify the tile to be used in a particular image. You can set any image to be the tile. If the tile image does not have the same color map as the first image, any colors missing from the first image will be allocated. If not enough colors can be allocated, the closest colors already available will be used. This allows arbitrary PNGs to be used as tile images. It also means, however, that you should not set a tile unless you will actually use it; if you set a rapid succession of different tile images, you can quickly fill your color map, and the results will not be optimal.

You need not take any special action when you are finished with a tile. As for any other image, if you will not be using the tile image for any further purpose, you should call gdImageDestroy. You must not use the color gdTiled if the current tile has been destroyed; you can of course set a new tile to replace it.

... inside a function ...
gdImagePtr im, tile;
FILE *in;
int black;
im = gdImageCreate(100, 100);
/* Open the tile PNG. For best results, portions of the
	tile that should be transparent (ie, allowing the
	background to shine through) should have the transparent
	color index. */
in = fopen("star.png", "rb");
tile = gdImageCreateFromPng(in);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
gdImageSetTile(im, tile);
/* Fill an area using the tile. */
gdImageFilledRectangle(im, 25, 25, 75, 75, gdTiled);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);
/* Destroy the tile image */
gdImageDestroy(tile);

void gdImageSetStyle(gdImagePtr im, int *style, int styleLength) (FUNCTION)

It is often desirable to draw dashed lines, dotted lines, and other variations on a broken line. gdImageSetStyle can be used to set any desired series of colors, including a special color that leaves the background intact, to be repeated during the drawing of a line.

To use gdImageSetStyle, create an array of integers and assign them the desired series of color values to be repeated. You can assign the special color value gdTransparent to indicate that the existing color should be left unchanged for that particular pixel (allowing a dashed line to be attractively drawn over an existing image).

Then, to draw a line using the style, use the normal gdImageLine function with the special color value gdStyled.

As of version 1.1.1, the style array is copied when you set the style, so you need not be concerned with keeping the array around indefinitely. This should not break existing code that assumes styles are not copied.

You can also combine styles and brushes to draw the brush image at intervals instead of in a continuous stroke. When creating a style for use with a brush, the style values are interpreted differently: zero (0) indicates pixels at which the brush should not be drawn, while one (1) indicates pixels at which the brush should be drawn. To draw a styled, brushed line, you must use the special color value gdStyledBrushed. For an example of this feature in use, see gddemo.c (provided in the distribution).

gdImagePtr im;
int styleDotted[2], styleDashed[6];
FILE *in;
int black;
int red;
im = gdImageCreate(100, 100);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Set up dotted style. Leave every other pixel alone. */
styleDotted[0] = red;
styleDotted[1] = gdTransparent;
/* Set up dashed style. Three on, three off. */
styleDashed[0] = red;
styleDashed[1] = red;
styleDashed[2] = red;
styleDashed[3] = gdTransparent;
styleDashed[4] = gdTransparent;
styleDashed[5] = gdTransparent;
/* Set dotted style. Note that we have to specify how many pixels are
	in the style! */
gdImageSetStyle(im, styleDotted, 2);
/* Draw a line from the upper left corner to the lower right corner. */
gdImageLine(im, 0, 0, 99, 99, gdStyled);
/* Now the dashed line. */
gdImageSetStyle(im, styleDashed, 6);
gdImageLine(im, 0, 99, 0, 99, gdStyled);

/* ... Do something with the image, such as saving it to a file ... */

/* Destroy it */
gdImageDestroy(im);

void gdImageAlphaBlending(gdImagePtr im, int blending) (FUNCTION)

The gdImageAlphaBlending function allows for two different modes of drawing on truecolor images. In blending mode, the alpha channel component of the color supplied to all drawing functions, such as gdImageSetPixel, determines how much of the underlying color should be allowed to shine through. As a result, gd automatically blends the existing color at that point with the drawing color, and stores the result in the image. The resulting pixel is opaque. In non-blending mode, the drawing color is copied literally with its alpha channel information, replacing the destination pixel. Blending mode is not available when drawing on palette images.

gdImagePtr im;
int red, blue;
im = gdImageCreateTrueColor(100, 100);
/* Background color */
red = gdTrueColor(255, 0, 0);	
gdImageFilledRectangle(im, 0, 0, 100, 100, red);
/* Drawing color. Full transparency would be an alpha channel value
	of 127 (gd has a 7 bit alpha chnanel). 0 is opaque,
	127 is transparent. So cut gdAlphaTransparent in half to get
	50% blending. */
blue = gdTrueColorAlpha(0, 0, 255, gdAlphaTransparent / 2);	
/* Draw with blending. Result will be 50% red, 50% blue: yellow 
	(emitted light, remember, not reflected light. What you learned 
	in Kindergarten is wrong here). */
gdImageAlphaBlending(im, 1);
gdImageFilledRectangle(im, 0, 0, 25, 25, blue);
/* Draw without blending. Result will be 50% blue, 50%
	the background color of the image viewer or web browser
	used; results in browsers that don't support
	semi-transparent pixels are unpredictable! */
gdImageAlphaBlending(im, 0);
gdImageFilledRectangle(im, 75, 75, 25, 25, blue);
/* Write the image to disk, etc. */

Query Functions

int gdImageAlpha(gdImagePtr im, int color) (MACRO)

gdImageAlpha is a macro which returns the alpha channel component of the specified color index. Alpha channel values vary between 0 (gdAlphaOpaque), which does not blend at all with the background, through 127 (gdAlphaTransparent), which allows the background to shine through 100%. Use this macro rather than accessing the structure members directly. int gdImageBlue(gdImagePtr im, int color) (MACRO)

gdImageBlue is a macro which returns the blue component of the specified color index. Use this macro rather than accessing the structure members directly.

int gdImageGetPixel(gdImagePtr im, int x, int y) (FUNCTION)

gdImageGetPixel() retrieves the color index of a particular pixel. Always use this function to query pixels; do not access the pixels of the gdImage structure directly.

... inside a function ...
FILE *in;
gdImagePtr im;
int c;
in = fopen("mypng.png", "rb");
x s. Values greater
than 360 are interpreted modulo 360.
... inside a function ...
gdImagePtr im;
int black;
int white;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Inscribe a filled ellipse in the image. */
gdImageFilledEllipse(im, 50, 25, 98, 48, white);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageFillToBorder(gdImagePtr im, int x, int y, int border, int color)
 (FUNCTION)

gdImageFillToBorder floods a portion of the image with the specified
color, beginning at the specified point and stopping at
the specified border color. For a way of flooding an
area defined by the color of the starting point, see
gdImageFill.

The border color cannot be a special color
such as gdTiled; it must be a proper
solid color. The fill color can be, however.

Note that gdImageFillToBorder is recursive. It is not the most
naive implementation possible, and the implementation is
expected to improve, but there will always be degenerate
cases in which the stack can become very deep. This can be
a problem in MSDOS and MS Windows 3.1 environments. (Of course,
in a Unix or Windows 95/98/NT environment with a proper stack, this is
not a problem at all.)
... inside a function ...
gdImagePtr im;
int black;
int white;
int red;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Allocate the color red. */
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Inscribe an ellipse in the image. */
gdImageArc(im, 50, 25, 98, 48, 0, 360, white);
/* Flood-fill the ellipse. Fill color is red, border color is
	white (ellipse). */
gdImageFillToBorder(im, 50, 50, white, red);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageFill(gdImagePtr im, int x, int y, int color)
 (FUNCTION)

gdImageFill floods a portion of the image with the specified
color, beginning at the specified point and flooding the
surrounding region of the same color as the starting point.
For a way of flooding a region defined by a specific border
color rather than by its interior color, see
gdImageFillToBorder.

The fill color can be gdTiled, resulting
in a tile fill using another image as the tile. However,
the tile image cannot be transparent. If the image you wish
to fill with has a transparent color index, call
gdImageTransparent on the
tile image and set the transparent color index to -1
to turn off its transparency.

Note that gdImageFill is recursive. It is not the most
naive implementation possible, and the implementation is
expected to improve, but there will always be degenerate
cases in which the stack can become very deep. This can be
a problem in MSDOS and MS Windows environments. (Of course,
in a Unix or Windows 95/98/NT environment with a proper stack, this is
not a problem at all.)
... inside a function ...
gdImagePtr im;
int black;
int white;
int red;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Allocate the color red. */
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Inscribe an ellipse in the image. */
gdImageArc(im, 50, 25, 98, 48, 0, 360, white);
/* Flood-fill the ellipse. Fill color is red, and will replace the
	black interior of the ellipse. */
gdImageFill(im, 50, 50, red);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageSetBrush(gdImagePtr im, gdImagePtr brush)
(FUNCTION)

A "brush" is an image used to draw wide, shaped strokes in another image. Just
as a paintbrush is not a single point, a brush image need not be
a single pixel. Any gd image can be used as a brush, and by
setting the transparent color index of the brush image with
gdImageColorTransparent,
a brush of any shape can be created. All line-drawing functions,
such as gdImageLine and
gdImagePolygon, will use the
current brush if the special "color" 
gdBrushed or gdStyledBrushed
is used when calling them.

gdImageSetBrush is used to specify the brush to be used in a
particular image. You can set any image to be the brush.
If the brush image does not have the same color map as the
first image, any colors missing from the first image
will be allocated. If not enough colors can be allocated,
the closest colors already available will be used. This
allows arbitrary PNGs to be used as brush images. It also
means, however, that you should not set a brush unless you
will actually use it; if you set a rapid succession of
different brush images, you can quickly fill your color map,
and the results will not be optimal.

You need not take any special action when you are finished
with a brush. As for any other image, if you will not
be using the brush image for any further purpose,
you should call gdImageDestroy.
You must not use the color gdBrushed
if the current brush has been destroyed; you can of
course set a new brush to replace it.
... inside a function ...
gdImagePtr im, brush;
FILE *in;
int black;
im = gdImageCreate(100, 100);
/* Open the brush PNG. For best results, portions of the
	brush that should be transparent (ie, not part of the
	brush shape) should have the transparent color index. */
in = fopen("star.png", "rb");
brush = gdImageCreateFromPng(in);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
gdImageSetBrush(im, brush);
/* Draw a line from the upper left corner to the lower right corner
	using the brush. */
gdImageLine(im, 0, 0, 99, 99, gdBrushed);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);
/* Destroy the brush image */
gdImageDestroy(brush);

void gdImageSetTile(gdImagePtr im, gdImagePtr tile)
(FUNCTION)

A "tile" is an image used to fill an area with  a repeated pattern.
Any gd image can be used as a tile, and by
setting the transparent color index of the tile image with
gdImageColorTransparent,
a tile that allows certain parts of the underlying area to shine
through can be created. All region-filling functions,
such as gdImageFill and
gdImageFilledPolygon, will use the
current tile if the special "color" 
gdTiled is used when calling them.

gdImageSetTile is used to specify the tile to be used in a
particular image. You can set any image to be the tile.
If the tile image does not have the same color map as the
first image, any colors missing from the first image
will be allocated. If not enough colors can be allocated,
the closest colors already available will be used. This
allows arbitrary PNGs to be used as tile images. It also
means, however, that you should not set a tile unless you
will actually use it; if you set a rapid succession of
different tile images, you can quickly fill your color map,
and the results will not be optimal.

You need not take any special action when you are finished
with a tile. As for any other image, if you will not
be using the tile image for any further purpose,
you should call gdImageDestroy.
You must not use the color gdTiled
if the current tile has been destroyed; you can of
course set a new tile to replace it.
... inside a function ...
gdImagePtr im, tile;
FILE *in;
int black;
im = gdImageCreate(100, 100);
/* Open the tile PNG. For best results, portions of the
	tile that should be transparent (ie, allowing the
	background to shine through) should have the transparent
	color index. */
in = fopen("star.png", "rb");
tile = gdImageCreateFromPng(in);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
gdImageSetTile(im, tile);
/* Fill an area using the tile. */
gdImageFilledRectangle(im, 25, 25, 75, 75, gdTiled);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);
/* Destroy the tile image */
gdImageDestroy(tile);

void gdImageSetStyle(gdImagePtr im, int *style, int styleLength)
(FUNCTION)

It is often desirable to draw dashed lines, dotted lines, and other
variations on a broken line. gdImageSetStyle can be used to set
any desired series of colors, including a special color that
leaves the background intact, to be repeated during the drawing
of a line.

To use gdImageSetStyle, create an array of integers and assign
them the desired series of color values to be repeated.
You can assign the special color value 
gdTransparent to indicate that the existing color should
be left unchanged for that particular pixel (allowing a dashed
line to be attractively drawn over an existing image).

Then, to draw a line using the style, use the normal
gdImageLine function with the
special color value gdStyled.

As of version 1.1.1, the style
array is copied when you set the style, so you need not
be concerned with keeping the array around indefinitely.
This should not break existing code that assumes styles
are not copied.

You can also combine styles and brushes to draw the brush
image at intervals instead of in a continuous stroke.
When creating a style for use with a brush, the
style values are interpreted differently: zero (0) indicates
pixels at which the brush should not be drawn, while one (1)
indicates pixels at which the brush should be drawn.
To draw a styled, brushed line, you must use the
special color value 
gdStyledBrushed. For an example of this feature
in use, see gddemo.c (provided in the distribution).
gdImagePtr im;
int styleDotted[2], styleDashed[6];
FILE *in;
int black;
int red;
im = gdImageCreate(100, 100);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Set up dotted style. Leave every other pixel alone. */
styleDotted[0] = red;
styleDotted[1] = gdTransparent;
/* Set up dashed style. Three on, three off. */
styleDashed[0] = red;
styleDashed[1] = red;
styleDashed[2] = red;
styleDashed[3] = gdTransparent;
styleDashed[4] = gdTransparent;
styleDashed[5] = gdTransparent;
/* Set dotted style. Note that we have to specify how many pixels are
	in the style! */
gdImageSetStyle(im, styleDotted, 2);
/* Draw a line from the upper left corner to the lower right corner. */
gdImageLine(im, 0, 0, 99, 99, gdStyled);
/* Now the dashed line. */
gdImageSetStyle(im, styleDashed, 6);
gdImageLine(im, 0, 99, 0, 99, gdStyled);

/* ... Do something with the image, such as saving it to a file ... */

/* Destroy it */
gdImageDestroy(im);

void gdImageAlphaBlending(gdImagePtr im, int blending)
(FUNCTION)

The gdImageAlphaBlending
function allows for two different modes of drawing on truecolor
images. In blending mode, the alpha channel component of the color 
supplied to all drawing functions, such as 
gdImageSetPixel, determines how much of 
the underlying color should be allowed to shine through. As a result, 
gd automatically blends the existing color at that point with the
drawing color, and stores the result in the image. The resulting pixel
is opaque. In non-blending mode, the drawing color is copied literally 
with its alpha channel information, replacing the destination pixel.
Blending mode is not available when drawing on palette images. 
gdImagePtr im;
int red, blue;
im = gdImageCreateTrueColor(100, 100);
/* Background color */
red = gdTrueColor(255, 0, 0);	
gdImageFilledRectangle(im, 0, 0, 100, 100, red);
/* Drawing color. Full transparency would be an alpha channel value
	of 127 (gd has a 7 bit alpha chnanel). 0 is opaque,
	127 is transparent. So cut gdAlphaTransparent in half to get
	50% blending. */
blue = gdTrueColorAlpha(0, 0, 255, gdAlphaTransparent / 2);	
/* Draw with blending. Result will be 50% red, 50% blue: yellow 
	(emitted light, remember, not reflected light. What you learned 
	in Kindergarten is wrong here). */
gdImageAlphaBlending(im, 1);
gdImageFilledRectangle(im, 0, 0, 25, 25, blue);
/* Draw without blending. Result will be 50% blue, 50%
	the background color of the image viewer or web browser
	used; results in browsers that don't support
	semi-transparent pixels are unpredictable! */
gdImageAlphaBlending(im, 0);
gdImageFilledRectangle(im, 75, 75, 25, 25, blue);
/* Write the image to disk, etc. */

Query Functions

int gdImageAlpha(gdImagePtr im, int color) (MACRO)

gdImageBlue is a macro which returns the blue component of the specified color index. Use this macro rather than accessing the structure members directly.

int gdImageGetPixel(gdImagePtr im, int x, int y) (FUNCTION)

gdImageGetPixel() retrieves the color index of a particular pixel. Always use this function to query pixels; do not access the pixels of the gdImage structure directly.

... inside a function ...
FILE *in;
gdImagePtr im;
int c;
in = fopen("mypng.png", "rb");
x s. Values greater
than 360 are interpreted modulo 360.
... inside a function ...
gdImagePtr im;
int black;
int white;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Inscribe a filled ellipse in the image. */
gdImageFilledEllipse(im, 50, 25, 98, 48, white);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageFillToBorder(gdImagePtr im, int x, int y, int border, int color)
 (FUNCTION)

gdImageFillToBorder floods a portion of the image with the specified
color, beginning at the specified point and stopping at
the specified border color. For a way of flooding an
area defined by the color of the starting point, see
gdImageFill.

The border color cannot be a special color
such as gdTiled; it must be a proper
solid color. The fill color can be, however.

Note that gdImageFillToBorder is recursive. It is not the most
naive implementation possible, and the implementation is
expected to improve, but there will always be degenerate
cases in which the stack can become very deep. This can be
a problem in MSDOS and MS Windows 3.1 environments. (Of course,
in a Unix or Windows 95/98/NT environment with a proper stack, this is
not a problem at all.)
... inside a function ...
gdImagePtr im;
int black;
int white;
int red;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Allocate the color red. */
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Inscribe an ellipse in the image. */
gdImageArc(im, 50, 25, 98, 48, 0, 360, white);
/* Flood-fill the ellipse. Fill color is red, border color is
	white (ellipse). */
gdImageFillToBorder(im, 50, 50, white, red);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageFill(gdImagePtr im, int x, int y, int color)
 (FUNCTION)

gdImageFill floods a portion of the image with the specified
color, beginning at the specified point and flooding the
surrounding region of the same color as the starting point.
For a way of flooding a region defined by a specific border
color rather than by its interior color, see
gdImageFillToBorder.

The fill color can be gdTiled, resulting
in a tile fill using another image as the tile. However,
the tile image cannot be transparent. If the image you wish
to fill with has a transparent color index, call
gdImageTransparent on the
tile image and set the transparent color index to -1
to turn off its transparency.

Note that gdImageFill is recursive. It is not the most
naive implementation possible, and the implementation is
expected to improve, but there will always be degenerate
cases in which the stack can become very deep. This can be
a problem in MSDOS and MS Windows environments. (Of course,
in a Unix or Windows 95/98/NT environment with a proper stack, this is
not a problem at all.)
... inside a function ...
gdImagePtr im;
int black;
int white;
int red;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Allocate the color red. */
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Inscribe an ellipse in the image. */
gdImageArc(im, 50, 25, 98, 48, 0, 360, white);
/* Flood-fill the ellipse. Fill color is red, and will replace the
	black interior of the ellipse. */
gdImageFill(im, 50, 50, red);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageSetBrush(gdImagePtr im, gdImagePtr brush)
(FUNCTION)

A "brush" is an image used to draw wide, shaped strokes in another image. Just
as a paintbrush is not a single point, a brush image need not be
a single pixel. Any gd image can be used as a brush, and by
setting the transparent color index of the brush image with
gdImageColorTransparent,
a brush of any shape can be created. All line-drawing functions,
such as gdImageLine and
gdImagePolygon, will use the
current brush if the special "color" 
gdBrushed or gdStyledBrushed
is used when calling them.

gdImageSetBrush is used to specify the brush to be used in a
particular image. You can set any image to be the brush.
If the brush image does not have the same color map as the
first image, any colors missing from the first image
will be allocated. If not enough colors can be allocated,
the closest colors already available will be used. This
allows arbitrary PNGs to be used as brush images. It also
means, however, that you should not set a brush unless you
will actually use it; if you set a rapid succession of
different brush images, you can quickly fill your color map,
and the results will not be optimal.

You need not take any special action when you are finished
with a brush. As for any other image, if you will not
be using the brush image for any further purpose,
you should call gdImageDestroy.
You must not use the color gdBrushed
if the current brush has been destroyed; you can of
course set a new brush to replace it.
... inside a function ...
gdImagePtr im, brush;
FILE *in;
int black;
im = gdImageCreate(100, 100);
/* Open the brush PNG. For best results, portions of the
	brush that should be transparent (ie, not part of the
	brush shape) should have the transparent color index. */
in = fopen("star.png", "rb");
brush = gdImageCreateFromPng(in);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
gdImageSetBrush(im, brush);
/* Draw a line from the upper left corner to the lower right corner
	using the brush. */
gdImageLine(im, 0, 0, 99, 99, gdBrushed);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);
/* Destroy the brush image */
gdImageDestroy(brush);

void gdImageSetTile(gdImagePtr im, gdImagePtr tile)
(FUNCTION)

A "tile" is an image used to fill an area with  a repeated pattern.
Any gd image can be used as a tile, and by
setting the transparent color index of the tile image with
gdImageColorTransparent,
a tile that allows certain parts of the underlying area to shine
through can be created. All region-filling functions,
such as gdImageFill and
gdImageFilledPolygon, will use the
current tile if the special "color" 
gdTiled is used when calling them.

gdImageSetTile is used to specify the tile to be used in a
particular image. You can set any image to be the tile.
If the tile image does not have the same color map as the
first image, any colors missing from the first image
will be allocated. If not enough colors can be allocated,
the closest colors already available will be used. This
allows arbitrary PNGs to be used as tile images. It also
means, however, that you should not set a tile unless you
will actually use it; if you set a rapid succession of
different tile images, you can quickly fill your color map,
and the results will not be optimal.

You need not take any special action when you are finished
with a tile. As for any other image, if you will not
be using the tile image for any further purpose,
you should call gdImageDestroy.
You must not use the color gdTiled
if the current tile has been destroyed; you can of
course set a new tile to replace it.
... inside a function ...
gdImagePtr im, tile;
FILE *in;
int black;
im = gdImageCreate(100, 100);
/* Open the tile PNG. For best results, portions of the
	tile that should be transparent (ie, allowing the
	background to shine through) should have the transparent
	color index. */
in = fopen("star.png", "rb");
tile = gdImageCreateFromPng(in);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
gdImageSetTile(im, tile);
/* Fill an area using the tile. */
gdImageFilledRectangle(im, 25, 25, 75, 75, gdTiled);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);
/* Destroy the tile image */
gdImageDestroy(tile);

void gdImageSetStyle(gdImagePtr im, int *style, int styleLength)
(FUNCTION)

It is often desirable to draw dashed lines, dotted lines, and other
variations on a broken line. gdImageSetStyle can be used to set
any desired series of colors, including a special color that
leaves the background intact, to be repeated during the drawing
of a line.

To use gdImageSetStyle, create an array of integers and assign
them the desired series of color values to be repeated.
You can assign the special color value 
gdTransparent to indicate that the existing color should
be left unchanged for that particular pixel (allowing a dashed
line to be attractively drawn over an existing image).

Then, to draw a line using the style, use the normal
gdImageLine function with the
special color value gdStyled.

As of version 1.1.1, the style
array is copied when you set the style, so you need not
be concerned with keeping the array around indefinitely.
This should not break existing code that assumes styles
are not copied.

You can also combine styles and brushes to draw the brush
image at intervals instead of in a continuous stroke.
When creating a style for use with a brush, the
style values are interpreted differently: zero (0) indicates
pixels at which the brush should not be drawn, while one (1)
indicates pixels at which the brush should be drawn.
To draw a styled, brushed line, you must use the
special color value 
gdStyledBrushed. For an example of this feature
in use, see gddemo.c (provided in the distribution).
gdImagePtr im;
int styleDotted[2], styleDashed[6];
FILE *in;
int black;
int red;
im = gdImageCreate(100, 100);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Set up dotted style. Leave every other pixel alone. */
styleDotted[0] = red;
styleDotted[1] = gdTransparent;
/* Set up dashed style. Three on, three off. */
styleDashed[0] = red;
styleDashed[1] = red;
styleDashed[2] = red;
styleDashed[3] = gdTransparent;
styleDashed[4] = gdTransparent;
styleDashed[5] = gdTransparent;
/* Set dotted style. Note that we have to specify how many pixels are
	in the style! */
gdImageSetStyle(im, styleDotted, 2);
/* Draw a line from the upper left corner to the lower right corner. */
gdImageLine(im, 0, 0, 99, 99, gdStyled);
/* Now the dashed line. */
gdImageSetStyle(im, styleDashed, 6);
gdImageLine(im, 0, 99, 0, 99, gdStyled);

/* ... Do something with the image, such as saving it to a file ... */

/* Destroy it */
gdImageDestroy(im);

void gdImageAlphaBlending(gdImagePtr im, int blending)
(FUNCTION)

The gdImageAlphaBlending
function allows for two different modes of drawing on truecolor
images. In blending mode, the alpha channel component of the color 
supplied to all drawing functions, such as 
gdImageSetPixel, determines how much of 
the underlying color should be allowed to shine through. As a result, 
gd automatically blends the existing color at that point with the
drawing color, and stores the result in the image. The resulting pixel
is opaque. In non-blending mode, the drawing color is copied literally 
with its alpha channel information, replacing the destination pixel.
Blending mode is not available when drawing on palette images. 
gdImagePtr im;
int red, blue;
im = gdImageCreateTrueColor(100, 100);
/* Background color */
red = gdTrueColor(255, 0, 0);	
gdImageFilledRectangle(im, 0, 0, 100, 100, red);
/* Drawing color. Full transparency would be an alpha channel value
	of 127 (gd has a 7 bit alpha chnanel). 0 is opaque,
	127 is transparent. So cut gdAlphaTransparent in half to get
	50% blending. */
blue = gdTrueColorAlpha(0, 0, 255, gdAlphaTransparent / 2);	
/* Draw with blending. Result will be 50% red, 50% blue: yellow 
	(emitted light, remember, not reflected light. What you learned 
	in Kindergarten is wrong here). */
gdImageAlphaBlending(im, 1);
gdImageFilledRectangle(im, 0, 0, 25, 25, blue);
/* Draw without blending. Result will be 50% blue, 50%
	the background color of the image viewer or web browser
	used; results in browsers that don't support
	semi-transparent pixels are unpredictable! */
gdImageAlphaBlending(im, 0);
gdImageFilledRectangle(im, 75, 75, 25, 25, blue);
/* Write the image to disk, etc. */

Query Functions

int gdImageAlpha(gdImagePtr im, int color) (MACRO)

gdImageBlue is a macro which returns the blue component of the specified color index. Use this macro rather than accessing the structure members directly.

int gdImageGetPixel(gdImagePtr im, int x, int y) (FUNCTION)

gdImageGetPixel() retrieves the color index of a particular pixel. Always use this function to query pixels; do not access the pixels of the gdImage structure directly.

... inside a function ...
FILE *in;
gdImagePtr im;
int c;
in = fopen("mypng.png", "rb");
x s. Values greater
than 360 are interpreted modulo 360.
... inside a function ...
gdImagePtr im;
int black;
int white;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Inscribe a filled ellipse in the image. */
gdImageFilledEllipse(im, 50, 25, 98, 48, white);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageFillToBorder(gdImagePtr im, int x, int y, int border, int color)
 (FUNCTION)

gdImageFillToBorder floods a portion of the image with the specified
color, beginning at the specified point and stopping at
the specified border color. For a way of flooding an
area defined by the color of the starting point, see
gdImageFill.

The border color cannot be a special color
such as gdTiled; it must be a proper
solid color. The fill color can be, however.

Note that gdImageFillToBorder is recursive. It is not the most
naive implementation possible, and the implementation is
expected to improve, but there will always be degenerate
cases in which the stack can become very deep. This can be
a problem in MSDOS and MS Windows 3.1 environments. (Of course,
in a Unix or Windows 95/98/NT environment with a proper stack, this is
not a problem at all.)
... inside a function ...
gdImagePtr im;
int black;
int white;
int red;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Allocate the color red. */
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Inscribe an ellipse in the image. */
gdImageArc(im, 50, 25, 98, 48, 0, 360, white);
/* Flood-fill the ellipse. Fill color is red, border color is
	white (ellipse). */
gdImageFillToBorder(im, 50, 50, white, red);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageFill(gdImagePtr im, int x, int y, int color)
 (FUNCTION)

gdImageFill floods a portion of the image with the specified
color, beginning at the specified point and flooding the
surrounding region of the same color as the starting point.
For a way of flooding a region defined by a specific border
color rather than by its interior color, see
gdImageFillToBorder.

The fill color can be gdTiled, resulting
in a tile fill using another image as the tile. However,
the tile image cannot be transparent. If the image you wish
to fill with has a transparent color index, call
gdImageTransparent on the
tile image and set the transparent color index to -1
to turn off its transparency.

Note that gdImageFill is recursive. It is not the most
naive implementation possible, and the implementation is
expected to improve, but there will always be degenerate
cases in which the stack can become very deep. This can be
a problem in MSDOS and MS Windows environments. (Of course,
in a Unix or Windows 95/98/NT environment with a proper stack, this is
not a problem at all.)
... inside a function ...
gdImagePtr im;
int black;
int white;
int red;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Allocate the color red. */
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Inscribe an ellipse in the image. */
gdImageArc(im, 50, 25, 98, 48, 0, 360, white);
/* Flood-fill the ellipse. Fill color is red, and will replace the
	black interior of the ellipse. */
gdImageFill(im, 50, 50, red);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageSetBrush(gdImagePtr im, gdImagePtr brush)
(FUNCTION)

A "brush" is an image used to draw wide, shaped strokes in another image. Just
as a paintbrush is not a single point, a brush image need not be
a single pixel. Any gd image can be used as a brush, and by
setting the transparent color index of the brush image with
gdImageColorTransparent,
a brush of any shape can be created. All line-drawing functions,
such as gdImageLine and
gdImagePolygon, will use the
current brush if the special "color" 
gdBrushed or gdStyledBrushed
is used when calling them.

gdImageSetBrush is used to specify the brush to be used in a
particular image. You can set any image to be the brush.
If the brush image does not have the same color map as the
first image, any colors missing from the first image
will be allocated. If not enough colors can be allocated,
the closest colors already available will be used. This
allows arbitrary PNGs to be used as brush images. It also
means, however, that you should not set a brush unless you
will actually use it; if you set a rapid succession of
different brush images, you can quickly fill your color map,
and the results will not be optimal.

You need not take any special action when you are finished
with a brush. As for any other image, if you will not
be using the brush image for any further purpose,
you should call gdImageDestroy.
You must not use the color gdBrushed
if the current brush has been destroyed; you can of
course set a new brush to replace it.
... inside a function ...
gdImagePtr im, brush;
FILE *in;
int black;
im = gdImageCreate(100, 100);
/* Open the brush PNG. For best results, portions of the
	brush that should be transparent (ie, not part of the
	brush shape) should have the transparent color index. */
in = fopen("star.png", "rb");
brush = gdImageCreateFromPng(in);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
gdImageSetBrush(im, brush);
/* Draw a line from the upper left corner to the lower right corner
	using the brush. */
gdImageLine(im, 0, 0, 99, 99, gdBrushed);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);
/* Destroy the brush image */
gdImageDestroy(brush);

void gdImageSetTile(gdImagePtr im, gdImagePtr tile)
(FUNCTION)

A "tile" is an image used to fill an area with  a repeated pattern.
Any gd image can be used as a tile, and by
setting the transparent color index of the tile image with
gdImageColorTransparent,
a tile that allows certain parts of the underlying area to shine
through can be created. All region-filling functions,
such as gdImageFill and
gdImageFilledPolygon, will use the
current tile if the special "color" 
gdTiled is used when calling them.

gdImageSetTile is used to specify the tile to be used in a
particular image. You can set any image to be the tile.
If the tile image does not have the same color map as the
first image, any colors missing from the first image
will be allocated. If not enough colors can be allocated,
the closest colors already available will be used. This
allows arbitrary PNGs to be used as tile images. It also
means, however, that you should not set a tile unless you
will actually use it; if you set a rapid succession of
different tile images, you can quickly fill your color map,
and the results will not be optimal.

You need not take any special action when you are finished
with a tile. As for any other image, if you will not
be using the tile image for any further purpose,
you should call gdImageDestroy.
You must not use the color gdTiled
if the current tile has been destroyed; you can of
course set a new tile to replace it.
... inside a function ...
gdImagePtr im, tile;
FILE *in;
int black;
im = gdImageCreate(100, 100);
/* Open the tile PNG. For best results, portions of the
	tile that should be transparent (ie, allowing the
	background to shine through) should have the transparent
	color index. */
in = fopen("star.png", "rb");
tile = gdImageCreateFromPng(in);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
gdImageSetTile(im, tile);
/* Fill an area using the tile. */
gdImageFilledRectangle(im, 25, 25, 75, 75, gdTiled);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);
/* Destroy the tile image */
gdImageDestroy(tile);

void gdImageSetStyle(gdImagePtr im, int *style, int styleLength)
(FUNCTION)

It is often desirable to draw dashed lines, dotted lines, and other
variations on a broken line. gdImageSetStyle can be used to set
any desired series of colors, including a special color that
leaves the background intact, to be repeated during the drawing
of a line.

To use gdImageSetStyle, create an array of integers and assign
them the desired series of color values to be repeated.
You can assign the special color value 
gdTransparent to indicate that the existing color should
be left unchanged for that particular pixel (allowing a dashed
line to be attractively drawn over an existing image).

Then, to draw a line using the style, use the normal
gdImageLine function with the
special color value gdStyled.

As of version 1.1.1, the style
array is copied when you set the style, so you need not
be concerned with keeping the array around indefinitely.
This should not break existing code that assumes styles
are not copied.

You can also combine styles and brushes to draw the brush
image at intervals instead of in a continuous stroke.
When creating a style for use with a brush, the
style values are interpreted differently: zero (0) indicates
pixels at which the brush should not be drawn, while one (1)
indicates pixels at which the brush should be drawn.
To draw a styled, brushed line, you must use the
special color value 
gdStyledBrushed. For an example of this feature
in use, see gddemo.c (provided in the distribution).
gdImagePtr im;
int styleDotted[2], styleDashed[6];
FILE *in;
int black;
int red;
im = gdImageCreate(100, 100);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Set up dotted style. Leave every other pixel alone. */
styleDotted[0] = red;
styleDotted[1] = gdTransparent;
/* Set up dashed style. Three on, three off. */
styleDashed[0] = red;
styleDashed[1] = red;
styleDashed[2] = red;
styleDashed[3] = gdTransparent;
styleDashed[4] = gdTransparent;
styleDashed[5] = gdTransparent;
/* Set dotted style. Note that we have to specify how many pixels are
	in the style! */
gdImageSetStyle(im, styleDotted, 2);
/* Draw a line from the upper left corner to the lower right corner. */
gdImageLine(im, 0, 0, 99, 99, gdStyled);
/* Now the dashed line. */
gdImageSetStyle(im, styleDashed, 6);
gdImageLine(im, 0, 99, 0, 99, gdStyled);

/* ... Do something with the image, such as saving it to a file ... */

/* Destroy it */
gdImageDestroy(im);

void gdImageAlphaBlending(gdImagePtr im, int blending)
(FUNCTION)

The gdImageAlphaBlending
function allows for two different modes of drawing on truecolor
images. In blending mode, the alpha channel component of the color 
supplied to all drawing functions, such as 
gdImageSetPixel, determines how much of 
the underlying color should be allowed to shine through. As a result, 
gd automatically blends the existing color at that point with the
drawing color, and stores the result in the image. The resulting pixel
is opaque. In non-blending mode, the drawing color is copied literally 
with its alpha channel information, replacing the destination pixel.
Blending mode is not available when drawing on palette images. 
gdImagePtr im;
int red, blue;
im = gdImageCreateTrueColor(100, 100);
/* Background color */
red = gdTrueColor(255, 0, 0);	
gdImageFilledRectangle(im, 0, 0, 100, 100, red);
/* Drawing color. Full transparency would be an alpha channel value
	of 127 (gd has a 7 bit alpha chnanel). 0 is opaque,
	127 is transparent. So cut gdAlphaTransparent in half to get
	50% blending. */
blue = gdTrueColorAlpha(0, 0, 255, gdAlphaTransparent / 2);	
/* Draw with blending. Result will be 50% red, 50% blue: yellow 
	(emitted light, remember, not reflected light. What you learned 
	in Kindergarten is wrong here). */
gdImageAlphaBlending(im, 1);
gdImageFilledRectangle(im, 0, 0, 25, 25, blue);
/* Draw without blending. Result will be 50% blue, 50%
	the background color of the image viewer or web browser
	used; results in browsers that don't support
	semi-transparent pixels are unpredictable! */
gdImageAlphaBlending(im, 0);
gdImageFilledRectangle(im, 75, 75, 25, 25, blue);
/* Write the image to disk, etc. */

Query Functions

int gdImageAlpha(gdImagePtr im, int color) (MACRO)

gdImageBlue is a macro which returns the blue component of the specified color index. Use this macro rather than accessing the structure members directly.

int gdImageGetPixel(gdImagePtr im, int x, int y) (FUNCTION)

gdImageGetPixel() retrieves the color index of a particular pixel. Always use this function to query pixels; do not access the pixels of the gdImage structure directly.

... inside a function ...
FILE *in;
gdImagePtr im;
int c;
in = fopen("mypng.png", "rb");
x s. Values greater
than 360 are interpreted modulo 360.
... inside a function ...
gdImagePtr im;
int black;
int white;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Inscribe a filled ellipse in the image. */
gdImageFilledEllipse(im, 50, 25, 98, 48, white);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageFillToBorder(gdImagePtr im, int x, int y, int border, int color)
 (FUNCTION)

gdImageFillToBorder floods a portion of the image with the specified
color, beginning at the specified point and stopping at
the specified border color. For a way of flooding an
area defined by the color of the starting point, see
gdImageFill.

The border color cannot be a special color
such as gdTiled; it must be a proper
solid color. The fill color can be, however.

Note that gdImageFillToBorder is recursive. It is not the most
naive implementation possible, and the implementation is
expected to improve, but there will always be degenerate
cases in which the stack can become very deep. This can be
a problem in MSDOS and MS Windows 3.1 environments. (Of course,
in a Unix or Windows 95/98/NT environment with a proper stack, this is
not a problem at all.)
... inside a function ...
gdImagePtr im;
int black;
int white;
int red;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Allocate the color red. */
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Inscribe an ellipse in the image. */
gdImageArc(im, 50, 25, 98, 48, 0, 360, white);
/* Flood-fill the ellipse. Fill color is red, border color is
	white (ellipse). */
gdImageFillToBorder(im, 50, 50, white, red);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageFill(gdImagePtr im, int x, int y, int color)
 (FUNCTION)

gdImageFill floods a portion of the image with the specified
color, beginning at the specified point and flooding the
surrounding region of the same color as the starting point.
For a way of flooding a region defined by a specific border
color rather than by its interior color, see
gdImageFillToBorder.

The fill color can be gdTiled, resulting
in a tile fill using another image as the tile. However,
the tile image cannot be transparent. If the image you wish
to fill with has a transparent color index, call
gdImageTransparent on the
tile image and set the transparent color index to -1
to turn off its transparency.

Note that gdImageFill is recursive. It is not the most
naive implementation possible, and the implementation is
expected to improve, but there will always be degenerate
cases in which the stack can become very deep. This can be
a problem in MSDOS and MS Windows environments. (Of course,
in a Unix or Windows 95/98/NT environment with a proper stack, this is
not a problem at all.)
... inside a function ...
gdImagePtr im;
int black;
int white;
int red;
im = gdImageCreate(100, 50);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
/* Allocate the color white (red, green and blue all maximum). */
white = gdImageColorAllocate(im, 255, 255, 255);	
/* Allocate the color red. */
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Inscribe an ellipse in the image. */
gdImageArc(im, 50, 25, 98, 48, 0, 360, white);
/* Flood-fill the ellipse. Fill color is red, and will replace the
	black interior of the ellipse. */
gdImageFill(im, 50, 50, red);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);

void gdImageSetBrush(gdImagePtr im, gdImagePtr brush)
(FUNCTION)

A "brush" is an image used to draw wide, shaped strokes in another image. Just
as a paintbrush is not a single point, a brush image need not be
a single pixel. Any gd image can be used as a brush, and by
setting the transparent color index of the brush image with
gdImageColorTransparent,
a brush of any shape can be created. All line-drawing functions,
such as gdImageLine and
gdImagePolygon, will use the
current brush if the special "color" 
gdBrushed or gdStyledBrushed
is used when calling them.

gdImageSetBrush is used to specify the brush to be used in a
particular image. You can set any image to be the brush.
If the brush image does not have the same color map as the
first image, any colors missing from the first image
will be allocated. If not enough colors can be allocated,
the closest colors already available will be used. This
allows arbitrary PNGs to be used as brush images. It also
means, however, that you should not set a brush unless you
will actually use it; if you set a rapid succession of
different brush images, you can quickly fill your color map,
and the results will not be optimal.

You need not take any special action when you are finished
with a brush. As for any other image, if you will not
be using the brush image for any further purpose,
you should call gdImageDestroy.
You must not use the color gdBrushed
if the current brush has been destroyed; you can of
course set a new brush to replace it.
... inside a function ...
gdImagePtr im, brush;
FILE *in;
int black;
im = gdImageCreate(100, 100);
/* Open the brush PNG. For best results, portions of the
	brush that should be transparent (ie, not part of the
	brush shape) should have the transparent color index. */
in = fopen("star.png", "rb");
brush = gdImageCreateFromPng(in);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
gdImageSetBrush(im, brush);
/* Draw a line from the upper left corner to the lower right corner
	using the brush. */
gdImageLine(im, 0, 0, 99, 99, gdBrushed);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);
/* Destroy the brush image */
gdImageDestroy(brush);

void gdImageSetTile(gdImagePtr im, gdImagePtr tile)
(FUNCTION)

A "tile" is an image used to fill an area with  a repeated pattern.
Any gd image can be used as a tile, and by
setting the transparent color index of the tile image with
gdImageColorTransparent,
a tile that allows certain parts of the underlying area to shine
through can be created. All region-filling functions,
such as gdImageFill and
gdImageFilledPolygon, will use the
current tile if the special "color" 
gdTiled is used when calling them.

gdImageSetTile is used to specify the tile to be used in a
particular image. You can set any image to be the tile.
If the tile image does not have the same color map as the
first image, any colors missing from the first image
will be allocated. If not enough colors can be allocated,
the closest colors already available will be used. This
allows arbitrary PNGs to be used as tile images. It also
means, however, that you should not set a tile unless you
will actually use it; if you set a rapid succession of
different tile images, you can quickly fill your color map,
and the results will not be optimal.

You need not take any special action when you are finished
with a tile. As for any other image, if you will not
be using the tile image for any further purpose,
you should call gdImageDestroy.
You must not use the color gdTiled
if the current tile has been destroyed; you can of
course set a new tile to replace it.
... inside a function ...
gdImagePtr im, tile;
FILE *in;
int black;
im = gdImageCreate(100, 100);
/* Open the tile PNG. For best results, portions of the
	tile that should be transparent (ie, allowing the
	background to shine through) should have the transparent
	color index. */
in = fopen("star.png", "rb");
tile = gdImageCreateFromPng(in);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
gdImageSetTile(im, tile);
/* Fill an area using the tile. */
gdImageFilledRectangle(im, 25, 25, 75, 75, gdTiled);
/* ... Do something with the image, such as saving it to a file... */
/* Destroy it */
gdImageDestroy(im);
/* Destroy the tile image */
gdImageDestroy(tile);

void gdImageSetStyle(gdImagePtr im, int *style, int styleLength)
(FUNCTION)

It is often desirable to draw dashed lines, dotted lines, and other
variations on a broken line. gdImageSetStyle can be used to set
any desired series of colors, including a special color that
leaves the background intact, to be repeated during the drawing
of a line.

To use gdImageSetStyle, create an array of integers and assign
them the desired series of color values to be repeated.
You can assign the special color value 
gdTransparent to indicate that the existing color should
be left unchanged for that particular pixel (allowing a dashed
line to be attractively drawn over an existing image).

Then, to draw a line using the style, use the normal
gdImageLine function with the
special color value gdStyled.

As of version 1.1.1, the style
array is copied when you set the style, so you need not
be concerned with keeping the array around indefinitely.
This should not break existing code that assumes styles
are not copied.

You can also combine styles and brushes to draw the brush
image at intervals instead of in a continuous stroke.
When creating a style for use with a brush, the
style values are interpreted differently: zero (0) indicates
pixels at which the brush should not be drawn, while one (1)
indicates pixels at which the brush should be drawn.
To draw a styled, brushed line, you must use the
special color value 
gdStyledBrushed. For an example of this feature
in use, see gddemo.c (provided in the distribution).
gdImagePtr im;
int styleDotted[2], styleDashed[6];
FILE *in;
int black;
int red;
im = gdImageCreate(100, 100);
/* Background color (first allocated) */
black = gdImageColorAllocate(im, 0, 0, 0);	
red = gdImageColorAllocate(im, 255, 0, 0);	
/* Set up dotted style. Leave every other pixel alone. */
styleDotted[0] = red;
styleDotted[1] = gdTransparent;
/* Set up dashed style. Three on, three off. */
styleDashed[0] = red;
styleDashed[1] = red;
styleDashed[2] = red;
styleDashed[3] = gdTransparent;
styleDashed[4] = gdTransparent;
styleDashed[5] = gdTransparent;
/* Set dotted style. Note that we have to specify how many pixels are
	in the style! */
gdImageSetStyle(im, styleDotted, 2);
/* Draw a line from the upper left corner to the lower right corner. */
gdImageLine(im, 0, 0, 99, 99, gdStyled);
/* Now the dashed line. */
gdImageSetStyle(im, styleDashed, 6);
gdImageLine(im, 0, 99, 0, 99, gdStyled);

/* ... Do something with the image, such as saving it to a file ... */

/* Destroy it */
gdImageDestroy(im);

void gdImageAlphaBlending(gdImagePtr im, int blending)
(FUNCTION)

The gdImageAlphaBlending
function allows for two different modes of drawing on truecolor
images. In blending mode, the alpha channel component of the color 
supplied to all drawing functions, such as 
gdImageSetPixel, determines how much of 
the underlying color should be allowed to shine through. As a result, 
gd automatically blends the existing color at that point with the
drawing color, and stores the result in the image. The resulting pixel
is opaque. In non-blending mode, the drawing color is copied literally 
with its alpha channel information, replacing the destination pixel.
Blending mode is not available when drawing on palette images.

This is gd 2.0.1 BETA.

gd 2.0.1

A graphics library for fast image creation

Follow this link to the latest version of this document.

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