-
Notifications
You must be signed in to change notification settings - Fork 0
License
Unknown, Unknown licenses found
Licenses found
Unknown
COPYING
Unknown
COPYING-PLAIN
iplinux/evas
Folders and files
Name | Name | Last commit message | Last commit date | |
---|---|---|---|---|
Repository files navigation
Evas @VERSION@ Evas is a clean display canvas API for several target display systems that can draw anti-aliased text, smooth super and sub-sampled scaled images, alpha-blend objects much and more. Requirements: ------------- Must: libc libm freetype2.1.9+ Recommended: libX11 libXext libXrender fontconfig libpng libjpeg eet libpthread Optional: XCB SDL OpenGL Qtopia librsvg libtiff libgif edb DirectFB -------------------------------------------------------------------------- Evas as of 0.9.9 has a new (and incompatible) API. Why? It's much cleaner and more compact. Designed for portable access to different display systems. It is also much more optimised internally, uses much less ram than previous Evas libraries, and is tiny. Evas when compiled for the Ipaq is a grand total of 191Kb (thats all of Evas minus libjpeg, libpng, libz (required for libpng), and minus freetype (required for font rendering)). I have plans that may involve having an alternative font engine other than freetype to minimise requirements, and having a native (optional) image loader for an image format that may end up being custom to evas, but will minimise code & requirements especially for embedded use. Evas uses very little RAM too (try profiling it in memprof if you want to know) most of the ram allocated, if you look, is for freetype itself, image pixel data, and font glyph data. You can't really avoid this, though evas tries to share this data as much as possible and not duplicate where it can. Feel free to point me at sensible memory optimisations etc. though :) I want this baby to be lean, mean tiny, fast and do everything from your massive multi-cpu desktop with gobs of ram and disk to a tiny watch. Evas also supports full UTF-8 for text object strings, thus allowing for full internationalised text strings (if your font gives you all the characters). I've tested with quite a few fonts and it works quite well. Though this requires a unicode compatible font with unicode charmap support (cyberbit is quite good actually as a font). For now Evas draws the fonts only from left to right, so arabic, hebrew etc. won't display quite right, direction-wise, but the characters do. -------------------------------------------------------------------------- if you want to know what options to enable ./configure --help Notes: the small dither mask is faster on the ipaq, but is not as good looking. on desktop machines it makes no speed difference so only use --enable-small-dither-mask if you are compiling for the ipaq you need at least 1 image loader if you want to load images. gcc 3.0.x on solaris screws up the jpeg code so erroring out doesn't work. use gcc 3.2 on solaris. -------------------------------------------------------------------------- notes on features: SCALING: --enable-scale-sample this enables the sampling scaler code. this is the fastest image scaling code, but also the lowest quality. when scaling up pixels will become blocky and when scaling down you will see shimmering/aliasing artifacts. this is a speed vs. quality tradeoff --enable-scale-smooth this is the nicest looking scaler that is not that much slower than tri-linear, but it looks really good. it also uses mipmaps and is optimised heavily. it is recommended to always use this unless you are really struggling for speed and are qilling to forego the quality DITHERING: --enable-small-dither-mask this uses a 4x4 dither mask instead of 128x128. on desktop boxes these days (pentium, pentium2, amd etc.) the speed difference is not really measurable, but the quality of the 128x128 dither mask is quite a lot better. patterns of dithering are much less noticable, so it is recommended to not enable this unless you are struggling for speed. the compaq ipaq for example shows a slowdown with this large a dither mask so enabling a small dither mask is recommended unless you really want to forego the speed. ENGINES: --enable-software-x11 this enables the software x11 rendering engine that renders to X drawable targets using highly optimised software routines. there is no hardware assist here. this engine requires X11 to be installed to build (and run). This is a godo generic engine that is fast and can run in X for good development and debugging purposes. --enable-software-xcb this enable the software xcb rendering engine. It allows the same features than the software x11 engine. It require the XCB and XCBImage libraries. For the test programs, XCBICCCM is also needed. --enable-fb this is the software framebuffer driving engine. this uses the linux framebuffer device (/dev/fb<x>) and will currently just inherit the current framebuffer settings on the fb device and use them to run in. this engine is almost fully functional except for the fb management itself. i'd be quite happy for people to help out with fixing up the fb init & management code to properly set up a vt and release it etc. this engine is specifically geared towards peoel writing minimalist display systems for embedded devices such as the ipaq, zaurus, etc. it also scales up to high-res desktop systems as well and performs outstandingly. i have measured up to 67% speedup over X11 using the fb driver insetad of X11. --enable-direcfb this is the direct fb engine that uses direcftb (http://www.directfb.org) on linux to access the framebuffer with (or maybe without) acceleration. for people making set-top boxes or just wanting an alternative to X this is really good. it may also be useful for embedded devices supported by directfb that offer acceleration (otherwise the fb driver will likely be faster). --enable-sdl this is the sdl engine that uses sdl library (http://www.libsdl.org). This library should work on many operating system. CPU: --enable-cpu-c this enabled the c code. you can actually build the code withotu the c fallback code and only have the mmx routines for example. it is suggested to always use this regardless uness you have some definite size issues with the code. --enable-cpu-mmx this enables the mmx optimised routines. this works for pentium, pentium2, pentium3, pentium4, athlon and duron processors. it can get quite considerable speedups, souse it if you can. ppc owners just have to live with the c fallback functions unfortunately as no one has provided any ALTIVEC asm routines yet. :) arm owners will also have to rely on the c fallback routines as i haven't managed to come up with any arm assembly that actually can beat the c code (when compiled with all optimisations) in speed. --enable-cpu-sse this enables sse optimizations availbale in he pentium3 and 4 cpus (not athlon and duron or pentium 2 or pentium cpu's). ppc owners just have to live with the c fallback functions unfortunately as no one has provided any ALTIVEC asm routines yet. :) arm owners will also have to rely on the c fallback routines as i haven't managed to come up with any arm assembly that actually can beat the c code (when compiled with all optimizations) in speed. IMAGE LOADERS: --enable-image-loader-png this enables the loader code that loads png files using libpng. there may be call for embedded devices later that have custom written small image loaders that uses less disk space than libpng to load custom format images. for now this is the only loader so you may as well include it. --enable-image-loader-jpeg this enables the loader code that loads jpeg files using libjpeg. CONVERTERS: --enable-convert-16-rgb-565 the most common converter you'll want for 16bpp. this means 5 bits for red, 6 bits for green and 5 bits for blue are used. --enable-convert-16-rgb-555 this is a converter for what many people know as "15 bit" color. you might want to enable this for X output as it used to be common to find many cards that do this. --enable-convert-16-rgb-444 this converter outputs to 12bit packed (int 16 bit WORDS). --enable-convert-16-rgb-ipq this converter was written specifically for the ipaq (and may apply to similarly configured devices) because it lies about its screen depth. it says it is 16bit 565 (that means 5 upper bits of the WORD are red, the next 6 bits are for green abd the next 5 for blue) but in fact only the upper 4 bits of each color component (red green and blue) are significant and work, so effectively the display is 12 bits of color, not 16, but padded out to fill 16bits, with unused bits in the color masks. X on the ipaq advertises it as a full 16bpp 565 display (i can't remember what the linux framebuffer advertised it as) and so many lumps of code can be fooled into rendering data badly because they think the output will look as the expect. This renderer assuems the upper 4 bits fo each color primitie only are significant and renders accordingly. this produces nice quality images on the ipaq and even still works in 16bpp 565 on your pc. it is highly recommended to use this renderer if your target is an ipaq or your device dislpays similar qualities of the ipaq for display purposes. --enable-convert-16-rgb-rot-0 this enables the 16bpp converters to run with 0 degrees rotation - this is normal display and you should really include this (though it is optional if you only ever want to do portrait mode - perhaps like on an ipaq embedded device) --enable-convert-16-rgb-rot-270 this enables the portrait mode (270 degree rotation) converteres for 16bpp. this is the standard display mode for things like pocketpc on the ipaq and the zaurus etc. thsi si a optimized part of the rendering pipeline to allow portrait display with a much lower overhead than doing it through X. --enable-convert-24-rgb-888 To be documented... --enable-convert-24-bgr-888 To be documented... --enable-convert-32-rgb-8888 To be documented... --enable-convert-32-bgr-8888 To be documented... --enable-convert-32-rgb-rot-0 To be documented... --enable-convert-32-rgb-rot-270 To be documented... ... ------------------------------------------------------------------------------ COMPILING AND INSTALLING: ./configure make (as root unless youa re installing in your users directories): make install ------------------------------------------------------------------------------ BUILDING PACKAGES: RPM: To build rpm packages: sudo rpm -ta @PACKAGE@-@[email protected] You will find rpm packages in your system /usr/src/redhat/* dirs (note you may not need to use sudo or root if you have your own ~/.rpmrc. see rpm documents for more details) DEB: To build deb packages: tar zvf @PACKAGE@-@[email protected] cd @PACKAGE@-@VERSION@ dpkg-buildpackage -us -uc -rfakeroot cd .. rm -rf @PACKAGE@-@VERSION@ You will find all the debian source, binary etc. packages put in the directory where you first untarred the source tarball. NOTES: For the arm optimizations you want to try: export CFLAGS="-O2 -march=armv5te -mcpu=arm1136jf-s -fomit-frame-pointer" To enable the async renderer compile with: --enable-async-render and also runtime set this environment variable: export EVAS_RENDER_MODE=non-blocking
About
No description, website, or topics provided.
Resources
License
Unknown, Unknown licenses found
Licenses found
Unknown
COPYING
Unknown
COPYING-PLAIN
Stars
Watchers
Forks
Packages 0
No packages published