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glslcc: Cross-compiler for GLSL shader language (GLSL->HLSL,METAL,GLES,GLSLv3)

@septag

glslcc is a command line tool that converts GLSL code to HLSL, GLES (version 2.0 and 3.0), Metal (MSL) and also other GLSL versions (GLSL 330, GLSL 400, etc..).
It uses glslang for parsing GLSL and compiling SPIR-V. And SPIRV-cross for converting the code from SPIR-V to the target language.

Features

Build

glslcc uses CMake. built and tested on:

How to build on Windows

Note: These instructions assume you already have Git and CMake installed.

I assume that terminal users are using a Linux-style terminal for Windows; therefore '/' is used in file paths. If you're running Windows cmd all '/' need to replaced with '\'

  1. Get the code
git clone https://github.com/septag/glslcc.git
  1. Run CMake
./cmake -S path/to/glslcc/ -B path/to/glslcc/build

If you don't include the -B flag, the build files will instead be written to wherever cmake.exe is, which you probably don't want

  1. Build and Run the executable from the terminal and enjoy! See below for further examples of command line args
./glslcc.exe --vert=path/to/shader.vert --frag=path/to/shader.frag --output=path/to/shader.hlsl --lang=hlsl --reflect

Usage

I'll have to write a more detailed documentation but for these are the arguments: (glslcc --help)

-h --help                           - Print this help text
-V --version                        - Print version
-v --vert=<Filepath>                - Vertex shader source file
-f --frag=<Filepath>                - Fragment shader source file
-c --compute=<Filepath>             - Compute shader source file
-o --output=<Filepath>              - Output file
-l --lang=<gles/msl/hlsl/glsl>      - Convert to shader language
-D --defines(=Defines)              - Preprocessor definitions, seperated by comma or ';'
-Y --invert-y                       - Invert position.y in vertex shader
-p --profile=<ProfileVersion>       - Shader profile version (HLSL: 40, 50, 60), (ES: 200, 300), (GLSL: 330, 400, 420)
-C --dumpc                          - Dump shader limits configuration
-I --include-dirs=<Directory(s)>    - Set include directory for <system> files, seperated by ';'
-P --preprocess                     - Dump preprocessed result to terminal
-N --cvar=<VariableName>            - Outputs Hex data to a C include file with a variable name
-F --flatten-ubos                   - Flatten UBOs, useful for ES2 shaders
-r --reflect(=Filepath)             - Output shader reflection information to a json file
-G --sgs                            - Output file should be packed SGS format
-b --bin                            - Compile to bytecode instead of source. requires ENABLE_D3D11_COMPILER build flag
-g --debug                          - Generate debug info for binary compilation, should come with --bin
-O --optimize                       - Optimize shader for release compilation
-S --silent                         - Does not output filename(s) after compile success
-i --input=<(null)>                 - Input shader source file. determined by extension (.vert/.frag/.comp)
-0 --validate                       - Only performs shader validatation and error checking
-E --err-format=<glslang/msvc>      - Output error format
-L --list-includes                  - List include files in shaders, does not generate any output files

Current supported shader stages are:
        - Vertex shader (--vert)
        - Fragment shader (--frag)
        - Compute shader (--compute)

Here's some examples:

Example shader (write shaders GLSL 4.5) : You can also use #include. The compiler automatically inserts #extension GL_GOOGLE_include_directive : require at the begining of any shader.

Vertex Shader (shader.vert):

#version 450

layout (location = POSITION) in vec3 aPos;
layout (location = COLOR0) in vec4 aColor;
layout (location = TEXCOORD0) in vec2 aCoord;

layout (std140, binding=0) uniform matrices
{
    mat4 projection;
    mat4 view;
    mat4 model;
};

layout (location = COLOR0) out flat vec4 outColor;
layout (location = TEXCOORD0) out vec2 outCoord;

void main()
{
    gl_Position = projection * view * model * vec4(aPos, 1.0);
    outColor = aColor;
    outCoord = aCoord;
}  

Fragment shader (shader.frag):

#version 450

precision mediump float;

layout (location = COLOR0) in flat vec4 inColor;
layout (location = TEXCOORD0) in vec2 inCoord;

layout (location = SV_Target0) out vec4 fragColor;

layout (binding = 0) uniform sampler2D colorMap;

void main() 
{
    lowp vec4 c = texture(colorMap, inCoord);
    fragColor = inColor * c;
}

Cross-compiles the vertex-shader and fragment-shader to HLSL files with reflection Json data Output files will be shader_vs.hlsl, shader_fs.hlsl for HLSL code, and shader_vs.hlsl.json, shader_fs.hlsl.json for their reflection data.

glslcc --vert=shader.vert --frag=shader.frag --output=shader.hlsl --lang=hlsl --reflect

This command does the same thing, but outputs all the data to a C header file shader.h, with specified variable names g_shader_vs, g_shader_fs, g_shader_vs_refl and g_shader_fs_refl which are the same data in files in hex representation. Also sets preprocessor values HLSL=1 and USE_TEXTURE3D=1 for both shaders.

glslcc --vert=shader.vert --frag=shader.frag --output=shader.h --lang=hlsl --reflect --cvar=g_shader --defines=HLSL=1;USE_TEXTURE3D=1

You can also pass files without explicitly defining input shaders in arguments. their shader type will be resolved by checking their file extensions. So .vert=vertex-shader, .frag=fragment-shader, .comp=compute-shader

glslcc shader.vert shader.frag --output=shader --lang=hlsl

To only validate a specific shader (useful for tools and IDEs), use --validate flag, with your specified output error format. By default, on windows, it outputs msvc's error format and on other platforms outputs gcc's error format, and only glslang's format if explicitly defined:

glslcc shader.vert --validate --err-format=glslang

Embed multiple sources into a single file

To to this, you can use the special tags and write your vertex/fragment sources inside of them. Tags are //@begin_vert for vertex shader and //@begin_frag for fragment shader. Also remember to end the block with //@end. The compiler will extract the blocks and compile each source separately just like individual files.

Note that this only works with .glsl files and no other extension:

//@begin_vert
    #version 450

    layout (location = POSITION)  in  vec3 a_pos;
    layout (location = TEXCOORD0) in  vec2 a_coord;
    layout (location = TEXCOORD0) out vec2 f_coord;

    layout (binding=0, std140) uniform matrices {
        mat4 mvp;
    };
        
    void main() {
        gl_Position = mvp * vec4(a_pos, 1.0);
        f_coord = a_coord;
    }
//@end

//@begin_frag
    #version 450

    precision mediump float;

    layout (location = TEXCOORD0)  in  vec2 f_coord;
    layout (location = SV_Target0) out vec4 frag_color;

    layout (binding = 0) uniform sampler2D tex_image;

    void main() {
        frag_color = texture(tex_image, f_coord);
    }
//@end

Reflection data

Reflection data comes in form of json files and activated with --reflect option. It includes all the information that you need to link your 3d Api to the shader

HLSL semantics

As you can see in the above example, I have used HLSL shader semantics for input and output layout. This must done for compatibility with HLSL shaders and also proper vertex assembly creation in D3D application. The reflection data also emits proper semantics for each vertex input for the application.
Here are supported HLSL semantics that you should use with layout (location = SEMANTIC):

POSITION, NORMAL, TEXCOORD0, TEXCOORD1, TEXCOORD2, TEXCOORD3, TEXCOORD4, TEXCOORD5, TEXCOORD6, TEXCOORD7, COLOR0, COLOR1, COLOR2, COLOR3, TANGENT, BINORMAL, BLENDINDICES, BLENDWEIGHT

SV_Target0, SV_Target1, SV_Target2, SV_Target3

SGS file format

There is also an option for exporting to .sgs files (--sgs) which is a simple IFF like binary format to hold all shaders (vs + fs + cs) with their reflection inside a binary blob. Check out sgs-file.h for the file format spec and headers. The blocks are layed out like this:

The blocks are composed of a uint32_t fourcc code + uint32_t variable defining the size of the block. So each block header is 8 bytes. For each header structure, check out the header file.

MSVC Linter

If you happen to work with msvc 2017 and higher, there is this extension called GLSL language integration (github) that this compiler is compatible with, so it can perform automating error checking in your editor. use these parameters in extensions's config:

glslcc -0 -E glslang

VSCode Linter

For visual studio code linting, I have modified existing GLSL Lint extension to work with this tool instead. you can find it here.

Just install the tool manually in vscode, and add these options to vscode:

    "glsllint.glslangValidatorPath": "/path/to/glslcc.exe",
    "glsllint.glslangValidatorArgs": "--validate --err-format=glslang"

D3D11 Compiler

There is a support for compiling d3d11 shaders (ps_5_0, vs_5_0, cs_5_0) into D3D11 byte-code instead of HLSL source code. On windows with Windows SDK, set ENABLE_D3D11_COMPILER=ON flag for cmake, build the project and use --bin in the command line arguments to generate binary byte-code file.

CMake module

I've added glslcc.cmake module, to facilitate shader compilation in cmake projects. here's an example on how you can use it in your CMakeLists.txt to make shaders as C header files:

include(glslcc)
set(shaders test.vert test.frag)
set_source_files_properties(${shaders} PROPERTIES GLSLCC_OUTPUT_DIRECTORY "shaders_inc")
glslcc_target_compile_shaders_h(project_name "${shaders}")

These properties can be assigned to shaders source files:

TODO

License (BSD 2-clause)

<a href="http://opensource.org/licenses/BSD-2-Clause" target="_blank"> <img align="right" src="http://opensource.org/trademarks/opensource/OSI-Approved-License-100x137.png"> </a>
Copyright 2018 Sepehr Taghdisian. All rights reserved.

https://github.com/septag/glslcc

Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are met:

   1. Redistributions of source code must retain the above copyright notice,
      this list of conditions and the following disclaimer.

   2. Redistributions in binary form must reproduce the above copyright notice,
      this list of conditions and the following disclaimer in the documentation
      and/or other materials provided with the distribution.

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IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO
EVENT SHALL COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT,
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