blob: 22fdf33d65fa94dbe88df1963eb0d82360007956 [file] [log] [blame]
//
// Copyright 2002 The ANGLE Project Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
//
#ifndef GLSLANG_SHADERLANG_H_
#define GLSLANG_SHADERLANG_H_
#include <stddef.h>
#include "KHR/khrplatform.h"
#include <array>
#include <map>
#include <set>
#include <string>
#include <vector>
//
// This is the platform independent interface between an OGL driver
// and the shading language compiler.
//
// Note: make sure to increment ANGLE_SH_VERSION when changing ShaderVars.h
#include "ShaderVars.h"
// Version number for shader translation API.
// It is incremented every time the API changes.
#define ANGLE_SH_VERSION 219
enum ShShaderSpec
{
SH_GLES2_SPEC,
SH_WEBGL_SPEC,
SH_GLES3_SPEC,
SH_WEBGL2_SPEC,
SH_GLES3_1_SPEC,
SH_WEBGL3_SPEC,
SH_GL_CORE_SPEC,
SH_GL_COMPATIBILITY_SPEC,
};
enum ShShaderOutput
{
// ESSL output only supported in some configurations.
SH_ESSL_OUTPUT = 0x8B45,
// GLSL output only supported in some configurations.
SH_GLSL_COMPATIBILITY_OUTPUT = 0x8B46,
// Note: GL introduced core profiles in 1.5.
SH_GLSL_130_OUTPUT = 0x8B47,
SH_GLSL_140_OUTPUT = 0x8B80,
SH_GLSL_150_CORE_OUTPUT = 0x8B81,
SH_GLSL_330_CORE_OUTPUT = 0x8B82,
SH_GLSL_400_CORE_OUTPUT = 0x8B83,
SH_GLSL_410_CORE_OUTPUT = 0x8B84,
SH_GLSL_420_CORE_OUTPUT = 0x8B85,
SH_GLSL_430_CORE_OUTPUT = 0x8B86,
SH_GLSL_440_CORE_OUTPUT = 0x8B87,
SH_GLSL_450_CORE_OUTPUT = 0x8B88,
// Prefer using these to specify HLSL output type:
SH_HLSL_3_0_OUTPUT = 0x8B48, // D3D 9
SH_HLSL_4_1_OUTPUT = 0x8B49, // D3D 11
SH_HLSL_4_0_FL9_3_OUTPUT = 0x8B4A, // D3D 11 feature level 9_3
// Output specialized GLSL to be fed to glslang for Vulkan SPIR.
SH_GLSL_VULKAN_OUTPUT = 0x8B4B,
// Output specialized GLSL to be fed to glslang for Vulkan SPIR to be cross compiled to Metal
// later.
SH_GLSL_METAL_OUTPUT = 0x8B4C,
};
// Compile options.
// The Compile options type is defined in ShaderVars.h, to allow ANGLE to import the ShaderVars
// header without needing the ShaderLang header. This avoids some conflicts with glslang.
const ShCompileOptions SH_VALIDATE = 0;
const ShCompileOptions SH_VALIDATE_LOOP_INDEXING = UINT64_C(1) << 0;
const ShCompileOptions SH_INTERMEDIATE_TREE = UINT64_C(1) << 1;
const ShCompileOptions SH_OBJECT_CODE = UINT64_C(1) << 2;
const ShCompileOptions SH_VARIABLES = UINT64_C(1) << 3;
const ShCompileOptions SH_LINE_DIRECTIVES = UINT64_C(1) << 4;
const ShCompileOptions SH_SOURCE_PATH = UINT64_C(1) << 5;
// This flag will keep invariant declaration for input in fragment shader for GLSL >=4.20 on AMD.
// From GLSL >= 4.20, it's optional to add invariant for fragment input, but GPU vendors have
// different implementations about this. Some drivers forbid invariant in fragment for GLSL>= 4.20,
// e.g. Linux Mesa, some drivers treat that as optional, e.g. NVIDIA, some drivers require invariant
// must match between vertex and fragment shader, e.g. AMD. The behavior on AMD is obviously wrong.
// Remove invariant for input in fragment shader to workaround the restriction on Intel Mesa.
// But don't remove on AMD Linux to avoid triggering the bug on AMD.
const ShCompileOptions SH_DONT_REMOVE_INVARIANT_FOR_FRAGMENT_INPUT = UINT64_C(1) << 6;
// Due to spec difference between GLSL 4.1 or lower and ESSL3, some platforms (for example, Mac OSX
// core profile) require a variable's "invariant"/"centroid" qualifiers to match between vertex and
// fragment shader. A simple solution to allow such shaders to link is to omit the two qualifiers.
// AMD driver in Linux requires invariant qualifier to match between vertex and fragment shaders,
// while ESSL3 disallows invariant qualifier in fragment shader and GLSL >= 4.2 doesn't require
// invariant qualifier to match between shaders. Remove invariant qualifier from vertex shader to
// workaround AMD driver bug.
// Note that the two flags take effect on ESSL3 input shaders translated to GLSL 4.1 or lower and to
// GLSL 4.2 or newer on Linux AMD.
// TODO(zmo): This is not a good long-term solution. Simply dropping these qualifiers may break some
// developers' content. A more complex workaround of dynamically generating, compiling, and
// re-linking shaders that use these qualifiers should be implemented.
const ShCompileOptions SH_REMOVE_INVARIANT_AND_CENTROID_FOR_ESSL3 = UINT64_C(1) << 7;
// This flag works around bug in Intel Mac drivers related to abs(i) where
// i is an integer.
const ShCompileOptions SH_EMULATE_ABS_INT_FUNCTION = UINT64_C(1) << 8;
// Enforce the GLSL 1.017 Appendix A section 7 packing restrictions.
// This flag only enforces (and can only enforce) the packing
// restrictions for uniform variables in both vertex and fragment
// shaders. ShCheckVariablesWithinPackingLimits() lets embedders
// enforce the packing restrictions for varying variables during
// program link time.
const ShCompileOptions SH_ENFORCE_PACKING_RESTRICTIONS = UINT64_C(1) << 9;
// This flag ensures all indirect (expression-based) array indexing
// is clamped to the bounds of the array. This ensures, for example,
// that you cannot read off the end of a uniform, whether an array
// vec234, or mat234 type. The ShArrayIndexClampingStrategy enum,
// specified in the ShBuiltInResources when constructing the
// compiler, selects the strategy for the clamping implementation.
const ShCompileOptions SH_CLAMP_INDIRECT_ARRAY_BOUNDS = UINT64_C(1) << 10;
// This flag limits the complexity of an expression.
const ShCompileOptions SH_LIMIT_EXPRESSION_COMPLEXITY = UINT64_C(1) << 11;
// This flag limits the depth of the call stack.
const ShCompileOptions SH_LIMIT_CALL_STACK_DEPTH = UINT64_C(1) << 12;
// This flag initializes gl_Position to vec4(0,0,0,0) at the
// beginning of the vertex shader's main(), and has no effect in the
// fragment shader. It is intended as a workaround for drivers which
// incorrectly fail to link programs if gl_Position is not written.
const ShCompileOptions SH_INIT_GL_POSITION = UINT64_C(1) << 13;
// This flag replaces
// "a && b" with "a ? b : false",
// "a || b" with "a ? true : b".
// This is to work around a MacOSX driver bug that |b| is executed
// independent of |a|'s value.
const ShCompileOptions SH_UNFOLD_SHORT_CIRCUIT = UINT64_C(1) << 14;
// This flag initializes output variables to 0 at the beginning of main().
// It is to avoid undefined behaviors.
const ShCompileOptions SH_INIT_OUTPUT_VARIABLES = UINT64_C(1) << 15;
// This flag scalarizes vec/ivec/bvec/mat constructor args.
// It is intended as a workaround for Linux/Mac driver bugs.
const ShCompileOptions SH_SCALARIZE_VEC_AND_MAT_CONSTRUCTOR_ARGS = UINT64_C(1) << 16;
// This flag overwrites a struct name with a unique prefix.
// It is intended as a workaround for drivers that do not handle
// struct scopes correctly, including all Mac drivers and Linux AMD.
const ShCompileOptions SH_REGENERATE_STRUCT_NAMES = UINT64_C(1) << 17;
// This flag makes the compiler not prune unused function early in the
// compilation process. Pruning coupled with SH_LIMIT_CALL_STACK_DEPTH
// helps avoid bad shaders causing stack overflows.
const ShCompileOptions SH_DONT_PRUNE_UNUSED_FUNCTIONS = UINT64_C(1) << 18;
// This flag works around a bug in NVIDIA 331 series drivers related
// to pow(x, y) where y is a constant vector.
const ShCompileOptions SH_REMOVE_POW_WITH_CONSTANT_EXPONENT = UINT64_C(1) << 19;
// This flag works around bugs in Mac drivers related to do-while by
// transforming them into an other construct.
const ShCompileOptions SH_REWRITE_DO_WHILE_LOOPS = UINT64_C(1) << 20;
// This flag works around a bug in the HLSL compiler optimizer that folds certain
// constant pow expressions incorrectly. Only applies to the HLSL back-end. It works
// by expanding the integer pow expressions into a series of multiplies.
const ShCompileOptions SH_EXPAND_SELECT_HLSL_INTEGER_POW_EXPRESSIONS = UINT64_C(1) << 21;
// Flatten "#pragma STDGL invariant(all)" into the declarations of
// varying variables and built-in GLSL variables. This compiler
// option is enabled automatically when needed.
const ShCompileOptions SH_FLATTEN_PRAGMA_STDGL_INVARIANT_ALL = UINT64_C(1) << 22;
// Some drivers do not take into account the base level of the texture in the results of the
// HLSL GetDimensions builtin. This flag instructs the compiler to manually add the base level
// offsetting.
const ShCompileOptions SH_HLSL_GET_DIMENSIONS_IGNORES_BASE_LEVEL = UINT64_C(1) << 23;
// This flag works around an issue in translating GLSL function texelFetchOffset on
// INTEL drivers. It works by translating texelFetchOffset into texelFetch.
const ShCompileOptions SH_REWRITE_TEXELFETCHOFFSET_TO_TEXELFETCH = UINT64_C(1) << 24;
// This flag works around condition bug of for and while loops in Intel Mac OSX drivers.
// Condition calculation is not correct. Rewrite it from "CONDITION" to "CONDITION && true".
const ShCompileOptions SH_ADD_AND_TRUE_TO_LOOP_CONDITION = UINT64_C(1) << 25;
// This flag works around a bug in evaluating unary minus operator on integer on some INTEL
// drivers. It works by translating -(int) into ~(int) + 1.
const ShCompileOptions SH_REWRITE_INTEGER_UNARY_MINUS_OPERATOR = UINT64_C(1) << 26;
// This flag works around a bug in evaluating isnan() on some INTEL D3D and Mac OSX drivers.
// It works by using an expression to emulate this function.
const ShCompileOptions SH_EMULATE_ISNAN_FLOAT_FUNCTION = UINT64_C(1) << 27;
// This flag will use all uniforms of unused std140 and shared uniform blocks at the
// beginning of the vertex/fragment shader's main(). It is intended as a workaround for Mac
// drivers with shader version 4.10. In those drivers, they will treat unused
// std140 and shared uniform blocks' members as inactive. However, WebGL2.0 based on
// OpenGL ES3.0.4 requires all members of a named uniform block declared with a shared or std140
// layout qualifier to be considered active. The uniform block itself is also considered active.
const ShCompileOptions SH_USE_UNUSED_STANDARD_SHARED_BLOCKS = UINT64_C(1) << 28;
// This flag works around a bug in unary minus operator on float numbers on Intel
// Mac OSX 10.11 drivers. It works by translating -float into 0.0 - float.
const ShCompileOptions SH_REWRITE_FLOAT_UNARY_MINUS_OPERATOR = UINT64_C(1) << 29;
// This flag works around a bug in evaluating atan(y, x) on some NVIDIA OpenGL drivers.
// It works by using an expression to emulate this function.
const ShCompileOptions SH_EMULATE_ATAN2_FLOAT_FUNCTION = UINT64_C(1) << 30;
// Set to initialize uninitialized local and global temporary variables. Should only be used with
// GLSL output. In HLSL output variables are initialized regardless of if this flag is set.
const ShCompileOptions SH_INITIALIZE_UNINITIALIZED_LOCALS = UINT64_C(1) << 31;
// The flag modifies the shader in the following way:
// Every occurrence of gl_InstanceID is replaced by the global temporary variable InstanceID.
// Every occurrence of gl_ViewID_OVR is replaced by the varying variable ViewID_OVR.
// At the beginning of the body of main() in a vertex shader the following initializers are added:
// ViewID_OVR = uint(gl_InstanceID) % num_views;
// InstanceID = gl_InstanceID / num_views;
// ViewID_OVR is added as a varying variable to both the vertex and fragment shaders.
const ShCompileOptions SH_INITIALIZE_BUILTINS_FOR_INSTANCED_MULTIVIEW = UINT64_C(1) << 32;
// With the flag enabled the GLSL/ESSL vertex shader is modified to include code for viewport
// selection in the following way:
// - Code to enable the extension ARB_shader_viewport_layer_array/NV_viewport_array2 is included.
// - Code to select the viewport index or layer is inserted at the beginning of main after
// ViewID_OVR's initialization.
// - A declaration of the uniform multiviewBaseViewLayerIndex.
// Note: The SH_INITIALIZE_BUILTINS_FOR_INSTANCED_MULTIVIEW flag also has to be enabled to have the
// temporary variable ViewID_OVR declared and initialized.
const ShCompileOptions SH_SELECT_VIEW_IN_NV_GLSL_VERTEX_SHADER = UINT64_C(1) << 33;
// If the flag is enabled, gl_PointSize is clamped to the maximum point size specified in
// ShBuiltInResources in vertex shaders.
const ShCompileOptions SH_CLAMP_POINT_SIZE = UINT64_C(1) << 34;
// Turn some arithmetic operations that operate on a float vector-scalar pair into vector-vector
// operations. This is done recursively. Some scalar binary operations inside vector constructors
// are also turned into vector operations.
//
// This is targeted to work around a bug in NVIDIA OpenGL drivers that was reproducible on NVIDIA
// driver version 387.92. It works around the most common occurrences of the bug.
const ShCompileOptions SH_REWRITE_VECTOR_SCALAR_ARITHMETIC = UINT64_C(1) << 35;
// Don't use loops to initialize uninitialized variables. Only has an effect if some kind of
// variable initialization is turned on.
const ShCompileOptions SH_DONT_USE_LOOPS_TO_INITIALIZE_VARIABLES = UINT64_C(1) << 36;
// Don't use D3D constant register zero when allocating space for uniforms. This is targeted to work
// around a bug in NVIDIA D3D driver version 388.59 where in very specific cases the driver would
// not handle constant register zero correctly. Only has an effect on HLSL translation.
const ShCompileOptions SH_SKIP_D3D_CONSTANT_REGISTER_ZERO = UINT64_C(1) << 37;
// Clamp gl_FragDepth to the range [0.0, 1.0] in case it is statically used.
const ShCompileOptions SH_CLAMP_FRAG_DEPTH = UINT64_C(1) << 38;
// Rewrite expressions like "v.x = z = expression;". Works around a bug in NVIDIA OpenGL drivers
// prior to version 397.31.
const ShCompileOptions SH_REWRITE_REPEATED_ASSIGN_TO_SWIZZLED = UINT64_C(1) << 39;
// Rewrite gl_DrawID as a uniform int
const ShCompileOptions SH_EMULATE_GL_DRAW_ID = UINT64_C(1) << 40;
// This flag initializes shared variables to 0.
// It is to avoid ompute shaders being able to read undefined values that could be coming from
// another webpage/application.
const ShCompileOptions SH_INIT_SHARED_VARIABLES = UINT64_C(1) << 41;
// Forces the value returned from an atomic operations to be always be resolved. This is targeted to
// workaround a bug in NVIDIA D3D driver where the return value from
// RWByteAddressBuffer.InterlockedAdd does not get resolved when used in the .yzw components of a
// RWByteAddressBuffer.Store operation. Only has an effect on HLSL translation.
// http://anglebug.com/3246
const ShCompileOptions SH_FORCE_ATOMIC_VALUE_RESOLUTION = UINT64_C(1) << 42;
// Rewrite gl_BaseVertex and gl_BaseInstance as uniform int
const ShCompileOptions SH_EMULATE_GL_BASE_VERTEX_BASE_INSTANCE = UINT64_C(1) << 43;
// Emulate seamful cube map sampling for OpenGL ES2.0. Currently only applies to the Vulkan
// backend, as is done after samplers are moved out of structs. Can likely be made to work on
// the other backends as well.
const ShCompileOptions SH_EMULATE_SEAMFUL_CUBE_MAP_SAMPLING = UINT64_C(1) << 44;
// If requested, validates the AST after every transformation. Useful for debugging.
const ShCompileOptions SH_VALIDATE_AST = UINT64_C(1) << 46;
// Use old version of RewriteStructSamplers, which doesn't produce as many
// sampler arrays in parameters. This causes a few tests to pass on Android.
const ShCompileOptions SH_USE_OLD_REWRITE_STRUCT_SAMPLERS = UINT64_C(1) << 47;
// This flag works around a inconsistent behavior in Mac AMD driver where gl_VertexID doesn't
// include base vertex value. It replaces gl_VertexID with (gl_VertexID + angle_BaseVertex)
// when angle_BaseVertex is available.
const ShCompileOptions SH_ADD_BASE_VERTEX_TO_VERTEX_ID = UINT64_C(1) << 48;
// This works around the dynamic lvalue indexing of swizzled vectors on various platforms.
const ShCompileOptions SH_REMOVE_DYNAMIC_INDEXING_OF_SWIZZLED_VECTOR = UINT64_C(1) << 49;
// Defines alternate strategies for implementing array index clamping.
enum ShArrayIndexClampingStrategy
{
// Use the clamp intrinsic for array index clamping.
SH_CLAMP_WITH_CLAMP_INTRINSIC = 1,
// Use a user-defined function for array index clamping.
SH_CLAMP_WITH_USER_DEFINED_INT_CLAMP_FUNCTION
};
// The 64 bits hash function. The first parameter is the input string; the
// second parameter is the string length.
using ShHashFunction64 = khronos_uint64_t (*)(const char *, size_t);
//
// Implementation dependent built-in resources (constants and extensions).
// The names for these resources has been obtained by stripping gl_/GL_.
//
struct ShBuiltInResources
{
// Constants.
int MaxVertexAttribs;
int MaxVertexUniformVectors;
int MaxVaryingVectors;
int MaxVertexTextureImageUnits;
int MaxCombinedTextureImageUnits;
int MaxTextureImageUnits;
int MaxFragmentUniformVectors;
int MaxDrawBuffers;
// Extensions.
// Set to 1 to enable the extension, else 0.
int OES_standard_derivatives;
int OES_EGL_image_external;
int OES_EGL_image_external_essl3;
int NV_EGL_stream_consumer_external;
int ARB_texture_rectangle;
int EXT_blend_func_extended;
int EXT_draw_buffers;
int EXT_frag_depth;
int EXT_shader_texture_lod;
int WEBGL_debug_shader_precision;
int EXT_shader_framebuffer_fetch;
int NV_shader_framebuffer_fetch;
int ARM_shader_framebuffer_fetch;
int OVR_multiview;
int OVR_multiview2;
int EXT_multisampled_render_to_texture;
int EXT_YUV_target;
int EXT_geometry_shader;
int OES_texture_storage_multisample_2d_array;
int OES_texture_3D;
int ANGLE_texture_multisample;
int ANGLE_multi_draw;
int ANGLE_base_vertex_base_instance;
// Set to 1 to enable replacing GL_EXT_draw_buffers #extension directives
// with GL_NV_draw_buffers in ESSL output. This flag can be used to emulate
// EXT_draw_buffers by using it in combination with GLES3.0 glDrawBuffers
// function. This applies to Tegra K1 devices.
int NV_draw_buffers;
// Set to 1 if highp precision is supported in the ESSL 1.00 version of the
// fragment language. Does not affect versions of the language where highp
// support is mandatory.
// Default is 0.
int FragmentPrecisionHigh;
// GLSL ES 3.0 constants.
int MaxVertexOutputVectors;
int MaxFragmentInputVectors;
int MinProgramTexelOffset;
int MaxProgramTexelOffset;
// Extension constants.
// Value of GL_MAX_DUAL_SOURCE_DRAW_BUFFERS_EXT for OpenGL ES output context.
// Value of GL_MAX_DUAL_SOURCE_DRAW_BUFFERS for OpenGL output context.
// GLES SL version 100 gl_MaxDualSourceDrawBuffersEXT value for EXT_blend_func_extended.
int MaxDualSourceDrawBuffers;
// Value of GL_MAX_VIEWS_OVR.
int MaxViewsOVR;
// Name Hashing.
// Set a 64 bit hash function to enable user-defined name hashing.
// Default is NULL.
ShHashFunction64 HashFunction;
// Selects a strategy to use when implementing array index clamping.
// Default is SH_CLAMP_WITH_CLAMP_INTRINSIC.
ShArrayIndexClampingStrategy ArrayIndexClampingStrategy;
// The maximum complexity an expression can be when SH_LIMIT_EXPRESSION_COMPLEXITY is turned on.
int MaxExpressionComplexity;
// The maximum depth a call stack can be.
int MaxCallStackDepth;
// The maximum number of parameters a function can have when SH_LIMIT_EXPRESSION_COMPLEXITY is
// turned on.
int MaxFunctionParameters;
// GLES 3.1 constants
// texture gather offset constraints.
int MinProgramTextureGatherOffset;
int MaxProgramTextureGatherOffset;
// maximum number of available image units
int MaxImageUnits;
// maximum number of image uniforms in a vertex shader
int MaxVertexImageUniforms;
// maximum number of image uniforms in a fragment shader
int MaxFragmentImageUniforms;
// maximum number of image uniforms in a compute shader
int MaxComputeImageUniforms;
// maximum total number of image uniforms in a program
int MaxCombinedImageUniforms;
// maximum number of uniform locations
int MaxUniformLocations;
// maximum number of ssbos and images in a shader
int MaxCombinedShaderOutputResources;
// maximum number of groups in each dimension
std::array<int, 3> MaxComputeWorkGroupCount;
// maximum number of threads per work group in each dimension
std::array<int, 3> MaxComputeWorkGroupSize;
// maximum number of total uniform components
int MaxComputeUniformComponents;
// maximum number of texture image units in a compute shader
int MaxComputeTextureImageUnits;
// maximum number of atomic counters in a compute shader
int MaxComputeAtomicCounters;
// maximum number of atomic counter buffers in a compute shader
int MaxComputeAtomicCounterBuffers;
// maximum number of atomic counters in a vertex shader
int MaxVertexAtomicCounters;
// maximum number of atomic counters in a fragment shader
int MaxFragmentAtomicCounters;
// maximum number of atomic counters in a program
int MaxCombinedAtomicCounters;
// maximum binding for an atomic counter
int MaxAtomicCounterBindings;
// maximum number of atomic counter buffers in a vertex shader
int MaxVertexAtomicCounterBuffers;
// maximum number of atomic counter buffers in a fragment shader
int MaxFragmentAtomicCounterBuffers;
// maximum number of atomic counter buffers in a program
int MaxCombinedAtomicCounterBuffers;
// maximum number of buffer object storage in machine units
int MaxAtomicCounterBufferSize;
// maximum number of uniform block bindings
int MaxUniformBufferBindings;
// maximum number of shader storage buffer bindings
int MaxShaderStorageBufferBindings;
// maximum point size (higher limit from ALIASED_POINT_SIZE_RANGE)
float MaxPointSize;
// EXT_geometry_shader constants
int MaxGeometryUniformComponents;
int MaxGeometryUniformBlocks;
int MaxGeometryInputComponents;
int MaxGeometryOutputComponents;
int MaxGeometryOutputVertices;
int MaxGeometryTotalOutputComponents;
int MaxGeometryTextureImageUnits;
int MaxGeometryAtomicCounterBuffers;
int MaxGeometryAtomicCounters;
int MaxGeometryShaderStorageBlocks;
int MaxGeometryShaderInvocations;
int MaxGeometryImageUniforms;
// Subpixel bits used in rasterization.
int SubPixelBits;
};
//
// ShHandle held by but opaque to the driver. It is allocated,
// managed, and de-allocated by the compiler. Its contents
// are defined by and used by the compiler.
//
// If handle creation fails, 0 will be returned.
//
using ShHandle = void *;
namespace sh
{
//
// Driver must call this first, once, before doing any other compiler operations.
// If the function succeeds, the return value is true, else false.
//
bool Initialize();
//
// Driver should call this at shutdown.
// If the function succeeds, the return value is true, else false.
//
bool Finalize();
//
// Initialize built-in resources with minimum expected values.
// Parameters:
// resources: The object to initialize. Will be comparable with memcmp.
//
void InitBuiltInResources(ShBuiltInResources *resources);
//
// Returns the a concatenated list of the items in ShBuiltInResources as a null-terminated string.
// This function must be updated whenever ShBuiltInResources is changed.
// Parameters:
// handle: Specifies the handle of the compiler to be used.
const std::string &GetBuiltInResourcesString(const ShHandle handle);
//
// Driver calls these to create and destroy compiler objects.
//
// Returns the handle of constructed compiler, null if the requested compiler is not supported.
// Parameters:
// type: Specifies the type of shader - GL_FRAGMENT_SHADER or GL_VERTEX_SHADER.
// spec: Specifies the language spec the compiler must conform to - SH_GLES2_SPEC or SH_WEBGL_SPEC.
// output: Specifies the output code type - for example SH_ESSL_OUTPUT, SH_GLSL_OUTPUT,
// SH_HLSL_3_0_OUTPUT or SH_HLSL_4_1_OUTPUT. Note: Each output type may only
// be supported in some configurations.
// resources: Specifies the built-in resources.
ShHandle ConstructCompiler(sh::GLenum type,
ShShaderSpec spec,
ShShaderOutput output,
const ShBuiltInResources *resources);
void Destruct(ShHandle handle);
//
// Compiles the given shader source.
// If the function succeeds, the return value is true, else false.
// Parameters:
// handle: Specifies the handle of compiler to be used.
// shaderStrings: Specifies an array of pointers to null-terminated strings containing the shader
// source code.
// numStrings: Specifies the number of elements in shaderStrings array.
// compileOptions: A mask containing the following parameters:
// SH_VALIDATE: Validates shader to ensure that it conforms to the spec
// specified during compiler construction.
// SH_VALIDATE_LOOP_INDEXING: Validates loop and indexing in the shader to
// ensure that they do not exceed the minimum
// functionality mandated in GLSL 1.0 spec,
// Appendix A, Section 4 and 5.
// There is no need to specify this parameter when
// compiling for WebGL - it is implied.
// SH_INTERMEDIATE_TREE: Writes intermediate tree to info log.
// Can be queried by calling sh::GetInfoLog().
// SH_OBJECT_CODE: Translates intermediate tree to glsl or hlsl shader.
// Can be queried by calling sh::GetObjectCode().
// SH_VARIABLES: Extracts attributes, uniforms, and varyings.
// Can be queried by calling ShGetVariableInfo().
//
bool Compile(const ShHandle handle,
const char *const shaderStrings[],
size_t numStrings,
ShCompileOptions compileOptions);
// Clears the results from the previous compilation.
void ClearResults(const ShHandle handle);
// Return the version of the shader language.
int GetShaderVersion(const ShHandle handle);
// Return the currently set language output type.
ShShaderOutput GetShaderOutputType(const ShHandle handle);
// Returns null-terminated information log for a compiled shader.
// Parameters:
// handle: Specifies the compiler
const std::string &GetInfoLog(const ShHandle handle);
// Returns null-terminated object code for a compiled shader.
// Parameters:
// handle: Specifies the compiler
const std::string &GetObjectCode(const ShHandle handle);
// Returns a (original_name, hash) map containing all the user defined names in the shader,
// including variable names, function names, struct names, and struct field names.
// Parameters:
// handle: Specifies the compiler
const std::map<std::string, std::string> *GetNameHashingMap(const ShHandle handle);
// Shader variable inspection.
// Returns a pointer to a list of variables of the designated type.
// (See ShaderVars.h for type definitions, included above)
// Returns NULL on failure.
// Parameters:
// handle: Specifies the compiler
const std::vector<sh::ShaderVariable> *GetUniforms(const ShHandle handle);
const std::vector<sh::ShaderVariable> *GetVaryings(const ShHandle handle);
const std::vector<sh::ShaderVariable> *GetInputVaryings(const ShHandle handle);
const std::vector<sh::ShaderVariable> *GetOutputVaryings(const ShHandle handle);
const std::vector<sh::ShaderVariable> *GetAttributes(const ShHandle handle);
const std::vector<sh::ShaderVariable> *GetOutputVariables(const ShHandle handle);
const std::vector<sh::InterfaceBlock> *GetInterfaceBlocks(const ShHandle handle);
const std::vector<sh::InterfaceBlock> *GetUniformBlocks(const ShHandle handle);
const std::vector<sh::InterfaceBlock> *GetShaderStorageBlocks(const ShHandle handle);
sh::WorkGroupSize GetComputeShaderLocalGroupSize(const ShHandle handle);
// Returns the number of views specified through the num_views layout qualifier. If num_views is
// not set, the function returns -1.
int GetVertexShaderNumViews(const ShHandle handle);
// Returns true if the passed in variables pack in maxVectors followingthe packing rules from the
// GLSL 1.017 spec, Appendix A, section 7.
// Returns false otherwise. Also look at the SH_ENFORCE_PACKING_RESTRICTIONS
// flag above.
// Parameters:
// maxVectors: the available rows of registers.
// variables: an array of variables.
bool CheckVariablesWithinPackingLimits(int maxVectors,
const std::vector<sh::ShaderVariable> &variables);
// Gives the compiler-assigned register for a shader storage block.
// The method writes the value to the output variable "indexOut".
// Returns true if it found a valid shader storage block, false otherwise.
// Parameters:
// handle: Specifies the compiler
// shaderStorageBlockName: Specifies the shader storage block
// indexOut: output variable that stores the assigned register
bool GetShaderStorageBlockRegister(const ShHandle handle,
const std::string &shaderStorageBlockName,
unsigned int *indexOut);
// Gives the compiler-assigned register for a uniform block.
// The method writes the value to the output variable "indexOut".
// Returns true if it found a valid uniform block, false otherwise.
// Parameters:
// handle: Specifies the compiler
// uniformBlockName: Specifies the uniform block
// indexOut: output variable that stores the assigned register
bool GetUniformBlockRegister(const ShHandle handle,
const std::string &uniformBlockName,
unsigned int *indexOut);
// Gives a map from uniform names to compiler-assigned registers in the default uniform block.
// Note that the map contains also registers of samplers that have been extracted from structs.
const std::map<std::string, unsigned int> *GetUniformRegisterMap(const ShHandle handle);
// Sampler, image and atomic counters share registers(t type and u type),
// GetReadonlyImage2DRegisterIndex and GetImage2DRegisterIndex return the first index into
// a range of reserved registers for image2D/iimage2D/uimage2D variables.
// Parameters: handle: Specifies the compiler
unsigned int GetReadonlyImage2DRegisterIndex(const ShHandle handle);
unsigned int GetImage2DRegisterIndex(const ShHandle handle);
// The method records these used function names related with image2D/iimage2D/uimage2D, these
// functions will be dynamically generated.
// Parameters:
// handle: Specifies the compiler
const std::set<std::string> *GetUsedImage2DFunctionNames(const ShHandle handle);
bool HasValidGeometryShaderInputPrimitiveType(const ShHandle handle);
bool HasValidGeometryShaderOutputPrimitiveType(const ShHandle handle);
bool HasValidGeometryShaderMaxVertices(const ShHandle handle);
GLenum GetGeometryShaderInputPrimitiveType(const ShHandle handle);
GLenum GetGeometryShaderOutputPrimitiveType(const ShHandle handle);
int GetGeometryShaderInvocations(const ShHandle handle);
int GetGeometryShaderMaxVertices(const ShHandle handle);
unsigned int GetShaderSharedMemorySize(const ShHandle handle);
//
// Helper function to identify specs that are based on the WebGL spec.
//
inline bool IsWebGLBasedSpec(ShShaderSpec spec)
{
return (spec == SH_WEBGL_SPEC || spec == SH_WEBGL2_SPEC || spec == SH_WEBGL3_SPEC);
}
//
// Helper function to identify DesktopGL specs
//
inline bool IsDesktopGLSpec(ShShaderSpec spec)
{
return spec == SH_GL_CORE_SPEC || spec == SH_GL_COMPATIBILITY_SPEC;
}
} // namespace sh
#endif // GLSLANG_SHADERLANG_H_