//-----------------------------------------------------------------------
void GLSLESProgramPipeline::updatePassIterationUniforms(GpuProgramParametersSharedPtr params)
{
if (params->hasPassIterationNumber())
{
size_t index = params->getPassIterationNumberIndex();
GLUniformReferenceIterator currentUniform = mGLUniformReferences.begin();
GLUniformReferenceIterator endUniform = mGLUniformReferences.end();
// Need to find the uniform that matches the multi pass entry
for (; currentUniform != endUniform; ++currentUniform)
{
// Get the index in the parameter real list
if (index == currentUniform->mConstantDef->physicalIndex)
{
#if GL_EXT_separate_shader_objects && OGRE_PLATFORM != OGRE_PLATFORM_NACL
GLuint progID = 0;
if (mVertexProgram && currentUniform->mSourceProgType == GPT_VERTEX_PROGRAM)
{
if(!mVertexProgram->getUniformCache()->updateUniform(currentUniform->mLocation,
params->getFloatPointer(index),
currentUniform->mConstantDef->elementSize *
currentUniform->mConstantDef->arraySize *
sizeof(float)))
return;
progID = mVertexProgram->getGLSLProgram()->getGLProgramHandle();
OGRE_CHECK_GL_ERROR(glProgramUniform1fvEXT(progID, currentUniform->mLocation, 1, params->getFloatPointer(index)));
}
if (mFragmentProgram && currentUniform->mSourceProgType == GPT_FRAGMENT_PROGRAM)
{
if(!mFragmentProgram->getUniformCache()->updateUniform(currentUniform->mLocation,
params->getFloatPointer(index),
currentUniform->mConstantDef->elementSize *
currentUniform->mConstantDef->arraySize *
sizeof(float)))
return;
progID = mFragmentProgram->getGLSLProgram()->getGLProgramHandle();
OGRE_CHECK_GL_ERROR(glProgramUniform1fvEXT(progID, currentUniform->mLocation, 1, params->getFloatPointer(index)));
}
#endif
// There will only be one multipass entry
return;
}
}
}
}
void ATI_FS_GLGpuProgram::bindProgramPassIterationParameters(GpuProgramParametersSharedPtr params)
{
if (params->hasPassIterationNumber())
{
size_t physicalIndex = params->getPassIterationNumberIndex();
size_t logicalIndex = params->getFloatLogicalIndexForPhysicalIndex(physicalIndex);
const float* pFloat = params->getFloatPointer(physicalIndex);
glSetFragmentShaderConstantATI( GL_CON_0_ATI + (GLuint)logicalIndex, pFloat);
}
}
void FixedFuncPrograms::_updateParameter( GpuProgramParametersSharedPtr & programParameters, const String paramName, const void * value, const size_t sizeInBytes )
{
const GpuConstantDefinition& def = programParameters->getConstantDefinition(paramName);
if (def.isFloat())
{
memcpy((programParameters->getFloatPointer(def.physicalIndex)), value, sizeInBytes);
}
else
{
memcpy((programParameters->getIntPointer(def.physicalIndex)), value, sizeInBytes);
}
}
void GLArbGpuProgram::bindProgramPassIterationParameters(GpuProgramParametersSharedPtr params)
{
if (params->hasPassIterationNumber())
{
GLenum type = getGLShaderType(mType);
size_t physicalIndex = params->getPassIterationNumberIndex();
size_t logicalIndex = params->getFloatLogicalIndexForPhysicalIndex(physicalIndex);
const float* pFloat = params->getFloatPointer(physicalIndex);
glProgramLocalParameter4fvARB(type, (GLuint)logicalIndex, pFloat);
}
}
void GLArbGpuProgram::bindProgramPassIterationParameters(GpuProgramParametersSharedPtr params)
{
if (params->hasPassIterationNumber())
{
GLenum type = (mType == GPT_VERTEX_PROGRAM) ?
GL_VERTEX_PROGRAM_ARB : GL_FRAGMENT_PROGRAM_ARB;
size_t physicalIndex = params->getPassIterationNumberIndex();
size_t logicalIndex = params->getFloatLogicalIndexForPhysicalIndex(physicalIndex);
const float* pFloat = params->getFloatPointer(physicalIndex);
glProgramLocalParameter4fvARB(type, (GLuint)logicalIndex, pFloat);
}
}
void ATI_FS_GLGpuProgram::bindProgramParameters(GpuProgramParametersSharedPtr params)
{
// only supports float constants
const GpuLogicalBufferStruct* floatStruct = params->getFloatLogicalBufferStruct();
for (GpuLogicalIndexUseMap::const_iterator i = floatStruct->map.begin();
i != floatStruct->map.end(); ++i)
{
size_t logicalIndex = i->first;
const float* pFloat = params->getFloatPointer(i->second.physicalIndex);
// Iterate over the params, set in 4-float chunks (low-level)
for (size_t j = 0; j < i->second.currentSize; j+=4)
{
glSetFragmentShaderConstantATI(GL_CON_0_ATI + logicalIndex, pFloat);
pFloat += 4;
++logicalIndex;
}
}
}
void GLArbGpuProgram::bindProgramParameters(GpuProgramParametersSharedPtr params)
{
GLenum type = (mType == GPT_VERTEX_PROGRAM) ?
GL_VERTEX_PROGRAM_ARB : GL_FRAGMENT_PROGRAM_ARB;
// only supports float constants
const GpuLogicalBufferStruct* floatStruct = params->getFloatLogicalBufferStruct();
for (GpuLogicalIndexUseMap::const_iterator i = floatStruct->map.begin();
i != floatStruct->map.end(); ++i)
{
size_t logicalIndex = i->first;
const float* pFloat = params->getFloatPointer(i->second.physicalIndex);
// Iterate over the params, set in 4-float chunks (low-level)
for (size_t j = 0; j < i->second.currentSize; j+=4)
{
glProgramLocalParameter4fvARB(type, logicalIndex, pFloat);
pFloat += 4;
++logicalIndex;
}
}
}
//-----------------------------------------------------------------------
void GLSLLinkProgram::updatePassIterationUniforms(GpuProgramParametersSharedPtr params)
{
if (params->hasPassIterationNumber())
{
size_t index = params->getPassIterationNumberIndex();
GLUniformReferenceIterator currentUniform = mGLUniformReferences.begin();
GLUniformReferenceIterator endUniform = mGLUniformReferences.end();
// Need to find the uniform that matches the multi pass entry
for (;currentUniform != endUniform; ++currentUniform)
{
// Get the index in the parameter real list
if (index == currentUniform->mConstantDef->physicalIndex)
{
OGRE_CHECK_GL_ERROR(glUniform1fv(currentUniform->mLocation, 1, params->getFloatPointer(index)));
// There will only be one multipass entry
return;
}
}
}
}
void GLArbGpuProgram::bindProgramParameters(GpuProgramParametersSharedPtr params, uint16 mask)
{
GLenum type = getGLShaderType(mType);
// only supports float constants
GpuLogicalBufferStructPtr floatStruct = params->getFloatLogicalBufferStruct();
for (GpuLogicalIndexUseMap::const_iterator i = floatStruct->map.begin();
i != floatStruct->map.end(); ++i)
{
if (i->second.variability & mask)
{
size_t logicalIndex = i->first;
const float* pFloat = params->getFloatPointer(i->second.physicalIndex);
// Iterate over the params, set in 4-float chunks (low-level)
for (size_t j = 0; j < i->second.currentSize; j+=4)
{
glProgramLocalParameter4fvARB(type, logicalIndex, pFloat);
pFloat += 4;
++logicalIndex;
}
}
}
}
//-----------------------------------------------------------------------
void GLSLESProgramPipeline::updateUniforms(GpuProgramParametersSharedPtr params,
uint16 mask, GpuProgramType fromProgType)
{
// Iterate through uniform reference list and update uniform values
GLUniformReferenceIterator currentUniform = mGLUniformReferences.begin();
GLUniformReferenceIterator endUniform = mGLUniformReferences.end();
#if OGRE_PLATFORM != OGRE_PLATFORM_NACL
GLuint progID = 0;
GLUniformCache* uniformCache=0;
if(fromProgType == GPT_VERTEX_PROGRAM)
{
progID = getVertexProgram()->getGLProgramHandle();
uniformCache = getVertexProgram()->getUniformCache();
}
else if(fromProgType == GPT_FRAGMENT_PROGRAM)
{
progID = mFragmentProgram->getGLProgramHandle();
uniformCache = mFragmentProgram->getUniformCache();
}
for (;currentUniform != endUniform; ++currentUniform)
{
// Only pull values from buffer it's supposed to be in (vertex or fragment)
// This method will be called twice, once for vertex program params,
// and once for fragment program params.
if (fromProgType == currentUniform->mSourceProgType)
{
const GpuConstantDefinition* def = currentUniform->mConstantDef;
if (def->variability & mask)
{
GLsizei glArraySize = (GLsizei)def->arraySize;
bool shouldUpdate = true;
switch (def->constType)
{
case GCT_INT1:
case GCT_INT2:
case GCT_INT3:
case GCT_INT4:
case GCT_SAMPLER1D:
case GCT_SAMPLER1DSHADOW:
case GCT_SAMPLER2D:
case GCT_SAMPLER2DSHADOW:
case GCT_SAMPLER3D:
case GCT_SAMPLERCUBE:
#if OGRE_NO_GLES3_SUPPORT == 0
case GCT_SAMPLER2DARRAY:
#endif
shouldUpdate = uniformCache->updateUniform(currentUniform->mLocation,
params->getIntPointer(def->physicalIndex),
static_cast<GLsizei>(def->elementSize * def->arraySize * sizeof(int)));
break;
default:
shouldUpdate = uniformCache->updateUniform(currentUniform->mLocation,
params->getFloatPointer(def->physicalIndex),
static_cast<GLsizei>(def->elementSize * def->arraySize * sizeof(float)));
break;
}
if(!shouldUpdate)
continue;
// Get the index in the parameter real list
switch (def->constType)
{
case GCT_FLOAT1:
OGRE_CHECK_GL_ERROR(glProgramUniform1fvEXT(progID, currentUniform->mLocation, glArraySize,
params->getFloatPointer(def->physicalIndex)));
break;
case GCT_FLOAT2:
OGRE_CHECK_GL_ERROR(glProgramUniform2fvEXT(progID, currentUniform->mLocation, glArraySize,
params->getFloatPointer(def->physicalIndex)));
break;
case GCT_FLOAT3:
OGRE_CHECK_GL_ERROR(glProgramUniform3fvEXT(progID, currentUniform->mLocation, glArraySize,
params->getFloatPointer(def->physicalIndex)));
break;
case GCT_FLOAT4:
OGRE_CHECK_GL_ERROR(glProgramUniform4fvEXT(progID, currentUniform->mLocation, glArraySize,
params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_2X2:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix2fvEXT(progID, currentUniform->mLocation, glArraySize,
GL_FALSE, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_3X3:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix3fvEXT(progID, currentUniform->mLocation, glArraySize,
GL_FALSE, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_4X4:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix4fvEXT(progID, currentUniform->mLocation, glArraySize,
GL_FALSE, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_INT1:
OGRE_CHECK_GL_ERROR(glProgramUniform1ivEXT(progID, currentUniform->mLocation, glArraySize,
params->getIntPointer(def->physicalIndex)));
break;
case GCT_INT2:
OGRE_CHECK_GL_ERROR(glProgramUniform2ivEXT(progID, currentUniform->mLocation, glArraySize,
params->getIntPointer(def->physicalIndex)));
break;
case GCT_INT3:
OGRE_CHECK_GL_ERROR(glProgramUniform3ivEXT(progID, currentUniform->mLocation, glArraySize,
params->getIntPointer(def->physicalIndex)));
break;
case GCT_INT4:
OGRE_CHECK_GL_ERROR(glProgramUniform4ivEXT(progID, currentUniform->mLocation, glArraySize,
params->getIntPointer(def->physicalIndex)));
break;
case GCT_SAMPLER1D:
case GCT_SAMPLER1DSHADOW:
case GCT_SAMPLER2D:
case GCT_SAMPLER2DSHADOW:
case GCT_SAMPLER3D:
case GCT_SAMPLERCUBE:
#if OGRE_NO_GLES3_SUPPORT == 0
case GCT_SAMPLER2DARRAY:
#endif
// Samplers handled like 1-element ints
OGRE_CHECK_GL_ERROR(glProgramUniform1ivEXT(progID, currentUniform->mLocation, 1,
params->getIntPointer(def->physicalIndex)));
break;
#if OGRE_NO_GLES3_SUPPORT == 0
case GCT_MATRIX_2X3:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix2x3fvEXT(progID, currentUniform->mLocation, glArraySize,
GL_FALSE, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_2X4:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix2x4fvEXT(progID, currentUniform->mLocation, glArraySize,
GL_FALSE, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_3X2:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix3x2fvEXT(progID, currentUniform->mLocation, glArraySize,
GL_FALSE, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_3X4:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix3x4fvEXT(progID, currentUniform->mLocation, glArraySize,
GL_FALSE, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_4X2:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix4x2fvEXT(progID, currentUniform->mLocation, glArraySize,
GL_FALSE, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_4X3:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix4x3fvEXT(progID, currentUniform->mLocation, glArraySize,
GL_FALSE, params->getFloatPointer(def->physicalIndex)));
break;
#else
case GCT_MATRIX_2X3:
case GCT_MATRIX_2X4:
case GCT_MATRIX_3X2:
case GCT_MATRIX_3X4:
case GCT_MATRIX_4X2:
case GCT_MATRIX_4X3:
case GCT_SAMPLER2DARRAY:
#endif
case GCT_UNKNOWN:
case GCT_SUBROUTINE:
case GCT_DOUBLE1:
case GCT_DOUBLE2:
case GCT_DOUBLE3:
case GCT_DOUBLE4:
case GCT_SAMPLERRECT:
case GCT_MATRIX_DOUBLE_2X2:
case GCT_MATRIX_DOUBLE_2X3:
case GCT_MATRIX_DOUBLE_2X4:
case GCT_MATRIX_DOUBLE_3X2:
case GCT_MATRIX_DOUBLE_3X3:
case GCT_MATRIX_DOUBLE_3X4:
case GCT_MATRIX_DOUBLE_4X2:
case GCT_MATRIX_DOUBLE_4X3:
case GCT_MATRIX_DOUBLE_4X4:
default:
break;
} // End switch
} // Variability & mask
} // fromProgType == currentUniform->mSourceProgType
} // End for
#endif
}
void GLSLSeparableProgram::updatePassIterationUniforms(GpuProgramParametersSharedPtr params)
{
if (params->hasPassIterationNumber())
{
size_t index = params->getPassIterationNumberIndex();
GLUniformReferenceIterator currentUniform = mGLUniformReferences.begin();
GLUniformReferenceIterator endUniform = mGLUniformReferences.end();
// Need to find the uniform that matches the multi pass entry
for (;currentUniform != endUniform; ++currentUniform)
{
// Get the index in the parameter real list
if (index == currentUniform->mConstantDef->physicalIndex)
{
GLuint progID = 0;
if (mVertexShader && currentUniform->mSourceProgType == GPT_VERTEX_PROGRAM)
{
progID = mVertexShader->getGLProgramHandle();
}
if (mFragmentShader && currentUniform->mSourceProgType == GPT_FRAGMENT_PROGRAM)
{
progID = mFragmentShader->getGLProgramHandle();
}
if (mGeometryShader && currentUniform->mSourceProgType == GPT_GEOMETRY_PROGRAM)
{
progID = mGeometryShader->getGLProgramHandle();
}
if (mDomainShader && currentUniform->mSourceProgType == GPT_DOMAIN_PROGRAM)
{
progID = mDomainShader->getGLProgramHandle();
}
if (mHullShader && currentUniform->mSourceProgType == GPT_HULL_PROGRAM)
{
progID = mHullShader->getGLProgramHandle();
}
if (mComputeShader && currentUniform->mSourceProgType == GPT_COMPUTE_PROGRAM)
{
progID = mComputeShader->getGLProgramHandle();
}
OGRE_CHECK_GL_ERROR(glProgramUniform1fv(progID, currentUniform->mLocation, 1, params->getFloatPointer(index)));
// There will only be one multipass entry
return;
}
}
}
}
void GLSLSeparableProgram::updateUniforms(GpuProgramParametersSharedPtr params,
uint16 mask, GpuProgramType fromProgType)
{
// Iterate through uniform reference list and update uniform values
GLUniformReferenceIterator currentUniform = mGLUniformReferences.begin();
GLUniformReferenceIterator endUniform = mGLUniformReferences.end();
// determine if we need to transpose matrices when binding
int transpose = GL_TRUE;
if ((fromProgType == GPT_FRAGMENT_PROGRAM && mVertexShader && (!mVertexShader->getColumnMajorMatrices())) ||
(fromProgType == GPT_VERTEX_PROGRAM && mFragmentShader && (!mFragmentShader->getColumnMajorMatrices())) ||
(fromProgType == GPT_GEOMETRY_PROGRAM && mGeometryShader && (!mGeometryShader->getColumnMajorMatrices())) ||
(fromProgType == GPT_HULL_PROGRAM && mHullShader && (!mHullShader->getColumnMajorMatrices())) ||
(fromProgType == GPT_DOMAIN_PROGRAM && mDomainShader && (!mDomainShader->getColumnMajorMatrices())) ||
(fromProgType == GPT_COMPUTE_PROGRAM && mComputeShader && (!mComputeShader->getColumnMajorMatrices())))
{
transpose = GL_FALSE;
}
GLuint progID = 0;
if (fromProgType == GPT_VERTEX_PROGRAM)
{
progID = mVertexShader->getGLProgramHandle();
}
else if (fromProgType == GPT_FRAGMENT_PROGRAM)
{
progID = mFragmentShader->getGLProgramHandle();
}
else if (fromProgType == GPT_GEOMETRY_PROGRAM)
{
progID = mGeometryShader->getGLProgramHandle();
}
else if (fromProgType == GPT_HULL_PROGRAM)
{
progID = mHullShader->getGLProgramHandle();
}
else if (fromProgType == GPT_DOMAIN_PROGRAM)
{
progID = mDomainShader->getGLProgramHandle();
}
else if (fromProgType == GPT_COMPUTE_PROGRAM)
{
progID = mComputeShader->getGLProgramHandle();
}
for (; currentUniform != endUniform; ++currentUniform)
{
// Only pull values from buffer it's supposed to be in (vertex or fragment)
// This method will be called once per shader stage.
if (fromProgType == currentUniform->mSourceProgType)
{
const GpuConstantDefinition* def = currentUniform->mConstantDef;
if (def->variability & mask)
{
GLsizei glArraySize = (GLsizei)def->arraySize;
// Get the index in the parameter real list
switch (def->constType)
{
case GCT_FLOAT1:
OGRE_CHECK_GL_ERROR(glProgramUniform1fv(progID, currentUniform->mLocation, glArraySize,
params->getFloatPointer(def->physicalIndex)));
break;
case GCT_FLOAT2:
OGRE_CHECK_GL_ERROR(glProgramUniform2fv(progID, currentUniform->mLocation, glArraySize,
params->getFloatPointer(def->physicalIndex)));
break;
case GCT_FLOAT3:
OGRE_CHECK_GL_ERROR(glProgramUniform3fv(progID, currentUniform->mLocation, glArraySize,
params->getFloatPointer(def->physicalIndex)));
break;
case GCT_FLOAT4:
OGRE_CHECK_GL_ERROR(glProgramUniform4fv(progID, currentUniform->mLocation, glArraySize,
params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_2X2:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix2fv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_3X3:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix3fv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_4X4:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix4fv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_INT1:
OGRE_CHECK_GL_ERROR(glProgramUniform1iv(progID, currentUniform->mLocation, glArraySize,
params->getIntPointer(def->physicalIndex)));
break;
case GCT_INT2:
OGRE_CHECK_GL_ERROR(glProgramUniform2iv(progID, currentUniform->mLocation, glArraySize,
params->getIntPointer(def->physicalIndex)));
break;
case GCT_INT3:
OGRE_CHECK_GL_ERROR(glProgramUniform3iv(progID, currentUniform->mLocation, glArraySize,
params->getIntPointer(def->physicalIndex)));
break;
case GCT_INT4:
OGRE_CHECK_GL_ERROR(glProgramUniform4iv(progID, currentUniform->mLocation, glArraySize,
params->getIntPointer(def->physicalIndex)));
break;
case GCT_MATRIX_2X3:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix2x3fv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_2X4:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix2x4fv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_3X2:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix3x2fv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_3X4:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix3x4fv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_4X2:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix4x2fv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_MATRIX_4X3:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix4x3fv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getFloatPointer(def->physicalIndex)));
break;
case GCT_DOUBLE1:
OGRE_CHECK_GL_ERROR(glProgramUniform1dv(progID, currentUniform->mLocation, glArraySize,
params->getDoublePointer(def->physicalIndex)));
break;
case GCT_DOUBLE2:
OGRE_CHECK_GL_ERROR(glProgramUniform2dv(progID, currentUniform->mLocation, glArraySize,
params->getDoublePointer(def->physicalIndex)));
break;
case GCT_DOUBLE3:
OGRE_CHECK_GL_ERROR(glProgramUniform3dv(progID, currentUniform->mLocation, glArraySize,
params->getDoublePointer(def->physicalIndex)));
break;
case GCT_DOUBLE4:
OGRE_CHECK_GL_ERROR(glProgramUniform4dv(progID, currentUniform->mLocation, glArraySize,
params->getDoublePointer(def->physicalIndex)));
break;
case GCT_MATRIX_DOUBLE_2X2:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix2dv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getDoublePointer(def->physicalIndex)));
break;
case GCT_MATRIX_DOUBLE_3X3:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix3dv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getDoublePointer(def->physicalIndex)));
break;
case GCT_MATRIX_DOUBLE_4X4:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix4dv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getDoublePointer(def->physicalIndex)));
break;
case GCT_MATRIX_DOUBLE_2X3:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix2x3dv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getDoublePointer(def->physicalIndex)));
break;
case GCT_MATRIX_DOUBLE_2X4:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix2x4dv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getDoublePointer(def->physicalIndex)));
break;
case GCT_MATRIX_DOUBLE_3X2:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix3x2dv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getDoublePointer(def->physicalIndex)));
break;
case GCT_MATRIX_DOUBLE_3X4:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix3x4dv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getDoublePointer(def->physicalIndex)));
break;
case GCT_MATRIX_DOUBLE_4X2:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix4x2dv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getDoublePointer(def->physicalIndex)));
break;
case GCT_MATRIX_DOUBLE_4X3:
OGRE_CHECK_GL_ERROR(glProgramUniformMatrix4x3dv(progID, currentUniform->mLocation, glArraySize,
transpose, params->getDoublePointer(def->physicalIndex)));
break;
case GCT_UINT1:
case GCT_BOOL1:
OGRE_CHECK_GL_ERROR(glProgramUniform1uiv(progID, currentUniform->mLocation, glArraySize,
params->getUnsignedIntPointer(def->physicalIndex)));
break;
case GCT_UINT2:
case GCT_BOOL2:
OGRE_CHECK_GL_ERROR(glProgramUniform2uiv(progID, currentUniform->mLocation, glArraySize,
params->getUnsignedIntPointer(def->physicalIndex)));
break;
case GCT_UINT3:
case GCT_BOOL3:
OGRE_CHECK_GL_ERROR(glProgramUniform3uiv(progID, currentUniform->mLocation, glArraySize,
params->getUnsignedIntPointer(def->physicalIndex)));
break;
case GCT_UINT4:
case GCT_BOOL4:
OGRE_CHECK_GL_ERROR(glProgramUniform4uiv(progID, currentUniform->mLocation, glArraySize,
params->getUnsignedIntPointer(def->physicalIndex)));
break;
case GCT_SAMPLER1D:
case GCT_SAMPLER1DSHADOW:
case GCT_SAMPLER2D:
case GCT_SAMPLER2DSHADOW:
case GCT_SAMPLER2DARRAY:
case GCT_SAMPLER3D:
case GCT_SAMPLERCUBE:
case GCT_SAMPLERRECT:
// Samplers handled like 1-element ints
OGRE_CHECK_GL_ERROR(glProgramUniform1iv(progID, currentUniform->mLocation, 1,
params->getIntPointer(def->physicalIndex)));
break;
case GCT_UNKNOWN:
case GCT_SUBROUTINE:
break;
} // End switch
} // Variability & mask
} // fromProgType == currentUniform->mSourceProgType
} // End for
}
//-----------------------------------------------------------------------
void GLSLLinkProgram::updateUniforms(GpuProgramParametersSharedPtr params,
uint16 mask, GpuProgramType fromProgType)
{
// iterate through uniform reference list and update uniform values
GLUniformReferenceIterator currentUniform = mGLUniformReferences.begin();
GLUniformReferenceIterator endUniform = mGLUniformReferences.end();
for (; currentUniform != endUniform; ++currentUniform)
{
// Only pull values from buffer it's supposed to be in (vertex or fragment)
// This method will be called twice, once for vertex program params,
// and once for fragment program params.
if (fromProgType == currentUniform->mSourceProgType)
{
const GpuConstantDefinition* def = currentUniform->mConstantDef;
if (def->variability & mask)
{
GLsizei glArraySize = (GLsizei)def->arraySize;
// get the index in the parameter real list
switch (def->constType)
{
case GCT_FLOAT1:
glUniform1fvARB(currentUniform->mLocation, glArraySize,
params->getFloatPointer(def->physicalIndex));
break;
case GCT_FLOAT2:
glUniform2fvARB(currentUniform->mLocation, glArraySize,
params->getFloatPointer(def->physicalIndex));
break;
case GCT_FLOAT3:
glUniform3fvARB(currentUniform->mLocation, glArraySize,
params->getFloatPointer(def->physicalIndex));
break;
case GCT_FLOAT4:
glUniform4fvARB(currentUniform->mLocation, glArraySize,
params->getFloatPointer(def->physicalIndex));
break;
case GCT_MATRIX_2X2:
glUniformMatrix2fvARB(currentUniform->mLocation, glArraySize,
GL_TRUE, params->getFloatPointer(def->physicalIndex));
break;
case GCT_MATRIX_2X3:
if (GLEW_VERSION_2_1)
{
glUniformMatrix2x3fv(currentUniform->mLocation, glArraySize,
GL_TRUE, params->getFloatPointer(def->physicalIndex));
}
break;
case GCT_MATRIX_2X4:
if (GLEW_VERSION_2_1)
{
glUniformMatrix2x4fv(currentUniform->mLocation, glArraySize,
GL_TRUE, params->getFloatPointer(def->physicalIndex));
}
break;
case GCT_MATRIX_3X2:
if (GLEW_VERSION_2_1)
{
glUniformMatrix3x2fv(currentUniform->mLocation, glArraySize,
GL_TRUE, params->getFloatPointer(def->physicalIndex));
}
break;
case GCT_MATRIX_3X3:
glUniformMatrix3fvARB(currentUniform->mLocation, glArraySize,
GL_TRUE, params->getFloatPointer(def->physicalIndex));
break;
case GCT_MATRIX_3X4:
if (GLEW_VERSION_2_1)
{
glUniformMatrix3x4fv(currentUniform->mLocation, glArraySize,
GL_TRUE, params->getFloatPointer(def->physicalIndex));
}
break;
case GCT_MATRIX_4X2:
if (GLEW_VERSION_2_1)
{
glUniformMatrix4x2fv(currentUniform->mLocation, glArraySize,
GL_TRUE, params->getFloatPointer(def->physicalIndex));
}
break;
case GCT_MATRIX_4X3:
if (GLEW_VERSION_2_1)
{
glUniformMatrix4x3fv(currentUniform->mLocation, glArraySize,
GL_TRUE, params->getFloatPointer(def->physicalIndex));
}
break;
case GCT_MATRIX_4X4:
glUniformMatrix4fvARB(currentUniform->mLocation, glArraySize,
GL_TRUE, params->getFloatPointer(def->physicalIndex));
break;
case GCT_INT1:
glUniform1ivARB(currentUniform->mLocation, glArraySize,
(GLint*)params->getIntPointer(def->physicalIndex));
break;
case GCT_INT2:
glUniform2ivARB(currentUniform->mLocation, glArraySize,
(GLint*)params->getIntPointer(def->physicalIndex));
break;
case GCT_INT3:
glUniform3ivARB(currentUniform->mLocation, glArraySize,
(GLint*)params->getIntPointer(def->physicalIndex));
break;
case GCT_INT4:
glUniform4ivARB(currentUniform->mLocation, glArraySize,
(GLint*)params->getIntPointer(def->physicalIndex));
break;
case GCT_SAMPLER1D:
case GCT_SAMPLER1DSHADOW:
case GCT_SAMPLER2D:
case GCT_SAMPLER2DSHADOW:
case GCT_SAMPLER3D:
case GCT_SAMPLERCUBE:
// samplers handled like 1-element ints
glUniform1ivARB(currentUniform->mLocation, 1,
(GLint*)params->getIntPointer(def->physicalIndex));
break;
case GCT_UNKNOWN:
break;
} // end switch
#if OGRE_DEBUG_MODE
checkForGLSLError( "GLSLLinkProgram::updateUniforms", "Error updating uniform", 0 );
#endif
} // variability & mask
} // fromProgType == currentUniform->mSourceProgType
} // end for
}
