/* * Copyright (C) 2008-2009 Advanced Micro Devices, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included * in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE COPYRIGHT HOLDER(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN * AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ /* * Authors: * Richard Li , */ #include #include #include #include #include #include "main/imports.h" #include "main/mtypes.h" #include "tnl/t_context.h" #include "program/program.h" #include "program/prog_parameter.h" #include "program/prog_statevars.h" #include "radeon_debug.h" #include "r600_context.h" #include "r600_cmdbuf.h" #include "r600_emit.h" #include "program/programopt.h" #include "evergreen_vertprog.h" unsigned int evergreen_Map_Vertex_Output(r700_AssemblerBase *pAsm, struct gl_vertex_program *mesa_vp, unsigned int unStart) { unsigned int i; unsigned int unBit; unsigned int unTotal = unStart; //!!!!!!! THE ORDER MATCH FS INPUT unBit = 1 << VERT_RESULT_HPOS; if(mesa_vp->Base.OutputsWritten & unBit) { pAsm->ucVP_OutputMap[VERT_RESULT_HPOS] = unTotal++; } unBit = 1 << VERT_RESULT_COL0; if(mesa_vp->Base.OutputsWritten & unBit) { pAsm->ucVP_OutputMap[VERT_RESULT_COL0] = unTotal++; } unBit = 1 << VERT_RESULT_COL1; if(mesa_vp->Base.OutputsWritten & unBit) { pAsm->ucVP_OutputMap[VERT_RESULT_COL1] = unTotal++; } //TODO : dealing back face. unBit = 1 << VERT_RESULT_BFC0; if(mesa_vp->Base.OutputsWritten & unBit) { pAsm->ucVP_OutputMap[VERT_RESULT_BFC0] = unTotal++; } unBit = 1 << VERT_RESULT_BFC1; if(mesa_vp->Base.OutputsWritten & unBit) { pAsm->ucVP_OutputMap[VERT_RESULT_BFC1] = unTotal++; } //TODO : dealing fog. unBit = 1 << VERT_RESULT_FOGC; if(mesa_vp->Base.OutputsWritten & unBit) { pAsm->ucVP_OutputMap[VERT_RESULT_FOGC] = unTotal++; } //TODO : dealing point size. unBit = 1 << VERT_RESULT_PSIZ; if(mesa_vp->Base.OutputsWritten & unBit) { pAsm->ucVP_OutputMap[VERT_RESULT_PSIZ] = unTotal++; } for(i=0; i<8; i++) { unBit = 1 << (VERT_RESULT_TEX0 + i); if(mesa_vp->Base.OutputsWritten & unBit) { pAsm->ucVP_OutputMap[VERT_RESULT_TEX0 + i] = unTotal++; } } for(i=VERT_RESULT_VAR0; iBase.OutputsWritten & unBit) { pAsm->ucVP_OutputMap[i] = unTotal++; } } return (unTotal - unStart); } unsigned int evergreen_Map_Vertex_Input(r700_AssemblerBase *pAsm, struct gl_vertex_program *mesa_vp, unsigned int unStart) { int i; unsigned int unBit; unsigned int unTotal = unStart; for(i=0; iBase.InputsRead & unBit) { pAsm->ucVP_AttributeMap[i] = unTotal++; } } return (unTotal - unStart); } GLboolean evergreen_Process_Vertex_Program_Vfetch_Instructions( struct evergreen_vertex_program *vp, struct gl_vertex_program *mesa_vp) { int i; unsigned int unBit; VTX_FETCH_METHOD vtxFetchMethod; vtxFetchMethod.bEnableMini = GL_FALSE; vtxFetchMethod.mega_fetch_remainder = 0; for(i=0; iBase.InputsRead & unBit) { assemble_vfetch_instruction(&vp->r700AsmCode, i, vp->r700AsmCode.ucVP_AttributeMap[i], vp->aos_desc[i].size, vp->aos_desc[i].type, &vtxFetchMethod); } } return GL_TRUE; } GLboolean evergreen_Process_Vertex_Program_Vfetch_Instructions2( struct gl_context *ctx, struct evergreen_vertex_program *vp, struct gl_vertex_program *mesa_vp) { int i; context_t *context = R700_CONTEXT(ctx); VTX_FETCH_METHOD vtxFetchMethod; vtxFetchMethod.bEnableMini = GL_FALSE; vtxFetchMethod.mega_fetch_remainder = 0; for(i=0; inNumActiveAos; i++) { EG_assemble_vfetch_instruction(&vp->r700AsmCode, vp->r700AsmCode.ucVP_AttributeMap[context->stream_desc[i].element], context->stream_desc[i].type, context->stream_desc[i].size, context->stream_desc[i].element, context->stream_desc[i]._signed, context->stream_desc[i].normalize, context->stream_desc[i].format, &vtxFetchMethod); } return GL_TRUE; } void evergreen_Map_Vertex_Program(struct gl_context *ctx, struct evergreen_vertex_program *vp, struct gl_vertex_program *mesa_vp) { r700_AssemblerBase *pAsm = &(vp->r700AsmCode); unsigned int num_inputs; // R0 will always be used for index into vertex buffer pAsm->number_used_registers = 1; pAsm->starting_vfetch_register_number = pAsm->number_used_registers; // Map Inputs: Add 1 to mapping since R0 is used for index num_inputs = evergreen_Map_Vertex_Input(pAsm, mesa_vp, pAsm->number_used_registers); pAsm->number_used_registers += num_inputs; // Create VFETCH instructions for inputs if (GL_TRUE != evergreen_Process_Vertex_Program_Vfetch_Instructions2(ctx, vp, mesa_vp) ) { radeon_error("Calling evergreen_Process_Vertex_Program_Vfetch_Instructions2 return error. \n"); return; } // Map Outputs pAsm->number_of_exports = evergreen_Map_Vertex_Output(pAsm, mesa_vp, pAsm->number_used_registers); pAsm->starting_export_register_number = pAsm->number_used_registers; pAsm->number_used_registers += pAsm->number_of_exports; /* Map temporary registers (GPRs) */ pAsm->starting_temp_register_number = pAsm->number_used_registers; if(mesa_vp->Base.NumNativeTemporaries >= mesa_vp->Base.NumTemporaries) { /* arb uses NumNativeTemporaries */ pAsm->number_used_registers += mesa_vp->Base.NumNativeTemporaries; } else { /* fix func t_vp uses NumTemporaries */ pAsm->number_used_registers += mesa_vp->Base.NumTemporaries; } pAsm->flag_reg_index = pAsm->number_used_registers++; pAsm->uFirstHelpReg = pAsm->number_used_registers; } GLboolean evergreen_Find_Instruction_Dependencies_vp(struct evergreen_vertex_program *vp, struct gl_vertex_program *mesa_vp) { GLuint i, j; GLint * puiTEMPwrites; struct prog_instruction *pILInst; InstDeps *pInstDeps; puiTEMPwrites = (GLint*) MALLOC(sizeof(GLuint)*mesa_vp->Base.NumTemporaries); for(i=0; iBase.NumTemporaries; i++) { puiTEMPwrites[i] = -1; } pInstDeps = (InstDeps*)MALLOC(sizeof(InstDeps)*mesa_vp->Base.NumInstructions); for(i=0; iBase.NumInstructions; i++) { pInstDeps[i].nDstDep = -1; pILInst = &(mesa_vp->Base.Instructions[i]); //Dst if(pILInst->DstReg.File == PROGRAM_TEMPORARY) { //Set lastwrite for the temp puiTEMPwrites[pILInst->DstReg.Index] = i; } //Src for(j=0; j<3; j++) { if(pILInst->SrcReg[j].File == PROGRAM_TEMPORARY) { //Set dep. pInstDeps[i].nSrcDeps[j] = puiTEMPwrites[pILInst->SrcReg[j].Index]; } else { pInstDeps[i].nSrcDeps[j] = -1; } } } vp->r700AsmCode.pInstDeps = pInstDeps; FREE(puiTEMPwrites); return GL_TRUE; } struct evergreen_vertex_program* evergreenTranslateVertexShader(struct gl_context *ctx, struct gl_vertex_program *mesa_vp) { context_t *context = EVERGREEN_CONTEXT(ctx); struct evergreen_vertex_program *vp; unsigned int i; vp = calloc(1, sizeof(*vp)); vp->mesa_program = _mesa_clone_vertex_program(ctx, mesa_vp); vp->constbo0 = NULL; if (mesa_vp->IsPositionInvariant) { _mesa_insert_mvp_code(ctx, vp->mesa_program); } for(i=0; inNumActiveAos; i++) { vp->aos_desc[i].size = context->stream_desc[i].size; vp->aos_desc[i].stride = context->stream_desc[i].stride; vp->aos_desc[i].type = context->stream_desc[i].type; vp->aos_desc[i].format = context->stream_desc[i].format; } if (context->radeon.radeonScreen->chip_family < CHIP_FAMILY_RV770) { vp->r700AsmCode.bR6xx = 1; } //Init_Program Init_r700_AssemblerBase(SPT_VP, &(vp->r700AsmCode), &(vp->r700Shader) ); vp->r700AsmCode.bUseMemConstant = GL_TRUE; vp->r700AsmCode.unAsic = 8; evergreen_Map_Vertex_Program(ctx, vp, vp->mesa_program ); if(GL_FALSE == evergreen_Find_Instruction_Dependencies_vp(vp, vp->mesa_program)) { return NULL; } InitShaderProgram(&(vp->r700AsmCode)); for(i=0; i < MAX_SAMPLERS; i++) { vp->r700AsmCode.SamplerUnits[i] = vp->mesa_program->Base.SamplerUnits[i]; } vp->r700AsmCode.unCurNumILInsts = vp->mesa_program->Base.NumInstructions; if(GL_FALSE == AssembleInstr(0, 0, vp->mesa_program->Base.NumInstructions, &(vp->mesa_program->Base.Instructions[0]), &(vp->r700AsmCode)) ) { return NULL; } if(GL_FALSE == Process_Vertex_Exports(&(vp->r700AsmCode), vp->mesa_program->Base.OutputsWritten) ) { return NULL; } if( GL_FALSE == RelocProgram(&(vp->r700AsmCode), &(vp->mesa_program->Base)) ) { return GL_FALSE; } vp->r700Shader.nRegs = (vp->r700AsmCode.number_used_registers == 0) ? 0 : (vp->r700AsmCode.number_used_registers - 1); vp->r700Shader.nParamExports = vp->r700AsmCode.number_of_exports; vp->translated = GL_TRUE; return vp; } void evergreenSelectVertexShader(struct gl_context *ctx) { context_t *context = EVERGREEN_CONTEXT(ctx); struct evergreen_vertex_program_cont *vpc; struct evergreen_vertex_program *vp; unsigned int i; GLboolean match; GLbitfield InputsRead; vpc = (struct evergreen_vertex_program_cont *)ctx->VertexProgram._Current; InputsRead = vpc->mesa_program.Base.InputsRead; if (vpc->mesa_program.IsPositionInvariant) { InputsRead |= VERT_BIT_POS; } for (vp = vpc->progs; vp; vp = vp->next) { match = GL_TRUE; for(i=0; inNumActiveAos; i++) { if (vp->aos_desc[i].size != context->stream_desc[i].size || vp->aos_desc[i].format != context->stream_desc[i].format) { match = GL_FALSE; break; } } if (match) { context->selected_vp = vp; return; } } vp = evergreenTranslateVertexShader(ctx, &(vpc->mesa_program)); if(!vp) { radeon_error("Failed to translate vertex shader. \n"); return; } vp->next = vpc->progs; vpc->progs = vp; context->selected_vp = vp; return; } int evergreen_getTypeSize(GLenum type) { switch (type) { case GL_DOUBLE: return sizeof(GLdouble); case GL_FLOAT: return sizeof(GLfloat); case GL_INT: return sizeof(GLint); case GL_UNSIGNED_INT: return sizeof(GLuint); case GL_SHORT: return sizeof(GLshort); case GL_UNSIGNED_SHORT: return sizeof(GLushort); case GL_BYTE: return sizeof(GLbyte); case GL_UNSIGNED_BYTE: return sizeof(GLubyte); default: assert(0); return 0; } } static void evergreenTranslateAttrib(struct gl_context *ctx, GLuint unLoc, int count, const struct gl_client_array *input) { context_t *context = EVERGREEN_CONTEXT(ctx); StreamDesc * pStreamDesc = &(context->stream_desc[context->nNumActiveAos]); GLuint stride; stride = (input->StrideB == 0) ? evergreen_getTypeSize(input->Type) * input->Size : input->StrideB; if (input->Type == GL_DOUBLE || input->Type == GL_UNSIGNED_INT || input->Type == GL_INT #if MESA_BIG_ENDIAN || evergreen_getTypeSize(input->Type) != 4 #endif ) { pStreamDesc->type = GL_FLOAT; if (input->StrideB == 0) { pStreamDesc->stride = 0; } else { pStreamDesc->stride = sizeof(GLfloat) * input->Size; } pStreamDesc->dwords = input->Size; pStreamDesc->is_named_bo = GL_FALSE; } else { pStreamDesc->type = input->Type; pStreamDesc->dwords = (evergreen_getTypeSize(input->Type) * input->Size + 3)/ 4; if (!input->BufferObj->Name) { if (input->StrideB == 0) { pStreamDesc->stride = 0; } else { pStreamDesc->stride = (evergreen_getTypeSize(pStreamDesc->type) * input->Size + 3) & ~3; } pStreamDesc->is_named_bo = GL_FALSE; } } pStreamDesc->size = input->Size; pStreamDesc->dst_loc = context->nNumActiveAos; pStreamDesc->element = unLoc; pStreamDesc->format = input->Format; switch (pStreamDesc->type) { //GetSurfaceFormat case GL_FLOAT: pStreamDesc->_signed = 0; pStreamDesc->normalize = GL_FALSE; break; case GL_SHORT: pStreamDesc->_signed = 1; pStreamDesc->normalize = input->Normalized; break; case GL_BYTE: pStreamDesc->_signed = 1; pStreamDesc->normalize = input->Normalized; break; case GL_UNSIGNED_SHORT: pStreamDesc->_signed = 0; pStreamDesc->normalize = input->Normalized; break; case GL_UNSIGNED_BYTE: pStreamDesc->_signed = 0; pStreamDesc->normalize = input->Normalized; break; default: case GL_INT: case GL_UNSIGNED_INT: case GL_DOUBLE: assert(0); break; } context->nNumActiveAos++; } void evergreenSetVertexFormat(struct gl_context *ctx, const struct gl_client_array *arrays[], int count) { context_t *context = EVERGREEN_CONTEXT(ctx); struct evergreen_vertex_program *vpc = (struct evergreen_vertex_program *)ctx->VertexProgram._Current; struct gl_vertex_program * mesa_vp = (struct gl_vertex_program *)&(vpc->mesa_program); unsigned int unLoc = 0; unsigned int unBit = mesa_vp->Base.InputsRead; context->nNumActiveAos = 0; if (mesa_vp->IsPositionInvariant) { unBit |= VERT_BIT_POS; } while(unBit) { if(unBit & 1) { evergreenTranslateAttrib(ctx, unLoc, count, arrays[unLoc]); } unBit >>= 1; ++unLoc; } context->radeon.tcl.aos_count = context->nNumActiveAos; } void * evergreenGetActiveVpShaderBo(struct gl_context * ctx) { context_t *context = EVERGREEN_CONTEXT(ctx); struct evergreen_vertex_program *vp = context->selected_vp;; if (vp) return vp->shaderbo; else return NULL; } void * evergreenGetActiveVpShaderConstBo(struct gl_context * ctx) { context_t *context = EVERGREEN_CONTEXT(ctx); struct evergreen_vertex_program *vp = context->selected_vp;; if (vp) return vp->constbo0; else return NULL; } GLboolean evergreenSetupVertexProgram(struct gl_context * ctx) { context_t *context = EVERGREEN_CONTEXT(ctx); EVERGREEN_CHIP_CONTEXT *evergreen = GET_EVERGREEN_CHIP(context); struct evergreen_vertex_program *vp = context->selected_vp; if(GL_FALSE == vp->loaded) { if(vp->r700Shader.bNeedsAssembly == GL_TRUE) { Assemble( &(vp->r700Shader) ); } /* Load vp to gpu */ r600EmitShader(ctx, &(vp->shaderbo), (GLvoid *)(vp->r700Shader.pProgram), vp->r700Shader.uShaderBinaryDWORDSize, "VS"); vp->loaded = GL_TRUE; } EVERGREEN_STATECHANGE(context, vs); /* TODO : enable this after MemUse fixed *= (context->chipobj.MemUse)(context, vp->shadercode.buf->id); */ evergreen->SQ_PGM_RESOURCES_VS.u32All = 0; SETbit(evergreen->SQ_PGM_RESOURCES_VS.u32All, PGM_RESOURCES__PRIME_CACHE_ON_DRAW_bit); evergreen->vs.SQ_ALU_CONST_CACHE_VS_0.u32All = 0; /* set from buffer object. */ evergreen->vs.SQ_PGM_START_VS.u32All = 0; SETfield(evergreen->SQ_PGM_RESOURCES_VS.u32All, vp->r700Shader.nRegs + 1, NUM_GPRS_shift, NUM_GPRS_mask); if(vp->r700Shader.uStackSize) /* we don't use branch for now, it should be zero. */ { SETfield(evergreen->SQ_PGM_RESOURCES_VS.u32All, vp->r700Shader.uStackSize, STACK_SIZE_shift, STACK_SIZE_mask); } EVERGREEN_STATECHANGE(context, spi); SETfield(evergreen->SPI_VS_OUT_CONFIG.u32All, vp->r700Shader.nParamExports ? (vp->r700Shader.nParamExports - 1) : 0, VS_EXPORT_COUNT_shift, VS_EXPORT_COUNT_mask); SETfield(evergreen->SPI_PS_IN_CONTROL_0.u32All, vp->r700Shader.nParamExports, NUM_INTERP_shift, NUM_INTERP_mask); /* SETbit(evergreen->SPI_PS_IN_CONTROL_0.u32All, PERSP_GRADIENT_ENA_bit); CLEARbit(evergreen->SPI_PS_IN_CONTROL_0.u32All, LINEAR_GRADIENT_ENA_bit); */ return GL_TRUE; } GLboolean evergreenSetupVPconstants(struct gl_context * ctx) { context_t *context = EVERGREEN_CONTEXT(ctx); EVERGREEN_CHIP_CONTEXT *evergreen = GET_EVERGREEN_CHIP(context); struct evergreen_vertex_program *vp = context->selected_vp; struct gl_program_parameter_list *paramList; unsigned int unNumParamData; unsigned int ui; int alloc_size; /* sent out shader constants. */ paramList = vp->mesa_program->Base.Parameters; if(NULL != paramList) { /* vp->mesa_program was cloned, not updated by glsl shader api. */ /* _mesa_reference_program has already checked glsl shProg is ok and set ctx->VertexProgem._Current */ /* so, use ctx->VertexProgem._Current */ struct gl_program_parameter_list *paramListOrginal = ctx->VertexProgram._Current->Base.Parameters; _mesa_load_state_parameters(ctx, paramList); if (paramList->NumParameters > EVERGREEN_MAX_DX9_CONSTS) return GL_FALSE; EVERGREEN_STATECHANGE(context, vs); evergreen->vs.num_consts = paramList->NumParameters; unNumParamData = paramList->NumParameters; /* alloc multiple of 16 constants */ alloc_size = ((unNumParamData * 4 * 4) + 255) & ~255; for(ui=0; uiParameters[ui].Type == PROGRAM_UNIFORM) { evergreen->vs.consts[ui][0].f32All = paramListOrginal->ParameterValues[ui][0]; evergreen->vs.consts[ui][1].f32All = paramListOrginal->ParameterValues[ui][1]; evergreen->vs.consts[ui][2].f32All = paramListOrginal->ParameterValues[ui][2]; evergreen->vs.consts[ui][3].f32All = paramListOrginal->ParameterValues[ui][3]; } else { evergreen->vs.consts[ui][0].f32All = paramList->ParameterValues[ui][0]; evergreen->vs.consts[ui][1].f32All = paramList->ParameterValues[ui][1]; evergreen->vs.consts[ui][2].f32All = paramList->ParameterValues[ui][2]; evergreen->vs.consts[ui][3].f32All = paramList->ParameterValues[ui][3]; } } radeonAllocDmaRegion(&context->radeon, &context->vp_Constbo, &context->vp_bo_offset, alloc_size, 256); r600EmitShaderConsts(ctx, context->vp_Constbo, context->vp_bo_offset, (GLvoid *)&(evergreen->vs.consts[0][0]), unNumParamData * 4 * 4); } else evergreen->vs.num_consts = 0; COMPILED_SUB * pCompiledSub; GLuint uj; GLuint unConstOffset = evergreen->vs.num_consts; for(ui=0; uir700AsmCode.unNumPresub; ui++) { pCompiledSub = vp->r700AsmCode.presubs[ui].pCompiledSub; evergreen->vs.num_consts += pCompiledSub->NumParameters; for(uj=0; ujNumParameters; uj++) { evergreen->vs.consts[uj + unConstOffset][0].f32All = pCompiledSub->ParameterValues[uj][0]; evergreen->vs.consts[uj + unConstOffset][1].f32All = pCompiledSub->ParameterValues[uj][1]; evergreen->vs.consts[uj + unConstOffset][2].f32All = pCompiledSub->ParameterValues[uj][2]; evergreen->vs.consts[uj + unConstOffset][3].f32All = pCompiledSub->ParameterValues[uj][3]; } unConstOffset += pCompiledSub->NumParameters; } return GL_TRUE; }