#include #include #include #include #include #include #include #include /* this is a hack for elf builds since their data section is below 0x10000000 * and thus can't be accessed by the GX2 hardware */ #ifndef GX2_CAN_ACCESS_DATA_SECTION typedef struct { void *vs_program; void *ps_program; void *gs_program; void *gs_copy_program; } org_programs_t; #endif void GX2InitShader(GX2Shader *shader) { if (shader->fs.program) return; shader->fs.size = GX2CalcFetchShaderSizeEx(shader->vs.attribVarCount, GX2_FETCH_SHADER_TESSELLATION_NONE, GX2_TESSELLATION_MODE_DISCRETE); #ifdef GX2_CAN_ACCESS_DATA_SECTION shader->fs.program = MEM2_alloc(shader->fs.size, GX2_SHADER_ALIGNMENT); #else shader->fs.program = MEM2_alloc(shader->fs.size + sizeof(org_programs_t), GX2_SHADER_ALIGNMENT); #endif GX2InitFetchShaderEx(&shader->fs, (uint8_t *)shader->fs.program, shader->vs.attribVarCount, shader->attribute_stream, GX2_FETCH_SHADER_TESSELLATION_NONE, GX2_TESSELLATION_MODE_DISCRETE); GX2Invalidate(GX2_INVALIDATE_MODE_CPU_SHADER, shader->fs.program, shader->fs.size); #ifndef GX2_CAN_ACCESS_DATA_SECTION org_programs_t *org = (org_programs_t *)(shader->fs.program + shader->fs.size); org->vs_program = shader->vs.program; org->ps_program = shader->ps.program; org->gs_program = shader->gs.program; org->gs_copy_program = shader->gs.copyProgram; shader->vs.program = MEM2_alloc(shader->vs.size, GX2_SHADER_ALIGNMENT); memcpy(shader->vs.program, org->vs_program, shader->vs.size); GX2Invalidate(GX2_INVALIDATE_MODE_CPU_SHADER, shader->vs.program, shader->vs.size); shader->ps.program = MEM2_alloc(shader->ps.size, GX2_SHADER_ALIGNMENT); memcpy(shader->ps.program, org->ps_program, shader->ps.size); GX2Invalidate(GX2_INVALIDATE_MODE_CPU_SHADER, shader->ps.program, shader->ps.size); if (org->gs_program) { shader->gs.program = MEM2_alloc(shader->gs.size, GX2_SHADER_ALIGNMENT); memcpy(shader->gs.program, org->gs_program, shader->gs.size); GX2Invalidate(GX2_INVALIDATE_MODE_CPU_SHADER, shader->gs.program, shader->gs.size); shader->gs.copyProgram = MEM2_alloc(shader->gs.copyProgramSize, GX2_SHADER_ALIGNMENT); memcpy(shader->gs.copyProgram, org->gs_copy_program, shader->gs.copyProgramSize); GX2Invalidate(GX2_INVALIDATE_MODE_CPU_SHADER, shader->gs.copyProgram, shader->gs.copyProgramSize); } #endif } void GX2DestroyShader(GX2Shader *shader) { #ifndef GX2_CAN_ACCESS_DATA_SECTION MEM2_free(shader->vs.program); MEM2_free(shader->ps.program); MEM2_free(shader->gs.program); MEM2_free(shader->gs.copyProgram); org_programs_t *org = (org_programs_t *)(shader->fs.program + shader->fs.size); shader->vs.program = org->vs_program; shader->ps.program = org->ps_program; shader->gs.program = org->gs_program; shader->gs.copyProgram = org->gs_copy_program; #endif MEM2_free(shader->fs.program); shader->fs.program = NULL; } void GX2SetShader(GX2Shader *shader) { GX2SetVertexShader(&shader->vs); GX2SetPixelShader(&shader->ps); GX2SetFetchShader(&shader->fs); if (shader->gs.program) GX2SetGeometryShader(&shader->gs); } void dump_vs_data(GX2VertexShader* vs) { unsigned i; DEBUG_INT(vs->size); DEBUG_VAR(vs->mode); DEBUG_INT(vs->uniformBlockCount); for (i = 0; i < vs->uniformBlockCount; i++) { DEBUG_STR(vs->uniformBlocks[i].name); DEBUG_INT(vs->uniformBlocks[i].offset); DEBUG_INT(vs->uniformBlocks[i].size); } DEBUG_INT(vs->uniformVarCount); for (i = 0; i < vs->uniformVarCount; i++) { DEBUG_STR(vs->uniformVars[i].name); DEBUG_INT(vs->uniformVars[i].offset); DEBUG_INT(vs->uniformVars[i].type); DEBUG_INT(vs->uniformVars[i].count); DEBUG_INT(vs->uniformVars[i].block); } DEBUG_INT(vs->initialValueCount); for (i = 0; i < vs->initialValueCount; i++) { DEBUG_INT(vs->initialValues[i].offset); DEBUG_FLOAT(vs->initialValues[i].value[0]); DEBUG_FLOAT(vs->initialValues[i].value[1]); DEBUG_FLOAT(vs->initialValues[i].value[2]); DEBUG_FLOAT(vs->initialValues[i].value[3]); } DEBUG_INT(vs->loopVarCount); for (i = 0; i < vs->loopVarCount; i++) { DEBUG_INT(vs->loopVars[i].offset); DEBUG_VAR(vs->loopVars[i].value); } DEBUG_INT(vs->samplerVarCount); for (i = 0; i < vs->samplerVarCount; i++) { DEBUG_STR(vs->samplerVars[i].name); DEBUG_INT(vs->samplerVars[i].type); DEBUG_INT(vs->samplerVars[i].location); } for (i = 0; i < vs->attribVarCount; i++) { DEBUG_STR(vs->attribVars[i].name); DEBUG_VAR(vs->attribVars[i].type); DEBUG_INT(vs->attribVars[i].location); DEBUG_INT(vs->attribVars[i].count); } } void dump_ps_data(GX2PixelShader* ps) { unsigned i; DEBUG_INT(ps->size); DEBUG_VAR(ps->mode); DEBUG_INT(ps->uniformBlockCount); for (i = 0; i < ps->uniformBlockCount; i++) { DEBUG_STR(ps->uniformBlocks[i].name); DEBUG_INT(ps->uniformBlocks[i].offset); DEBUG_INT(ps->uniformBlocks[i].size); } DEBUG_INT(ps->uniformVarCount); for (i = 0; i < ps->uniformVarCount; i++) { DEBUG_STR(ps->uniformVars[i].name); DEBUG_INT(ps->uniformVars[i].offset); DEBUG_INT(ps->uniformVars[i].type); DEBUG_INT(ps->uniformVars[i].count); DEBUG_INT(ps->uniformVars[i].block); } DEBUG_INT(ps->initialValueCount); for (i = 0; i < ps->initialValueCount; i++) { DEBUG_INT(ps->initialValues[i].offset); DEBUG_FLOAT(ps->initialValues[i].value[0]); DEBUG_FLOAT(ps->initialValues[i].value[1]); DEBUG_FLOAT(ps->initialValues[i].value[2]); DEBUG_FLOAT(ps->initialValues[i].value[3]); } DEBUG_INT(ps->loopVarCount); for (i = 0; i < ps->loopVarCount; i++) { DEBUG_INT(ps->loopVars[i].offset); DEBUG_VAR(ps->loopVars[i].value); } DEBUG_INT(ps->samplerVarCount); for (i = 0; i < ps->samplerVarCount; i++) { DEBUG_STR(ps->samplerVars[i].name); DEBUG_INT(ps->samplerVars[i].type); DEBUG_INT(ps->samplerVars[i].location); } } void check_shader_verbose(u32 *shader, u32 shader_size, u32 *org, u32 org_size, const char *name) { unsigned i; printf("%s :\n", name); DEBUG_VAR(shader_size); DEBUG_VAR(org_size); if (shader_size != org_size) printf("size mismatch : 0x%08lX should be 0x%08lX\n", shader_size, org_size); for (i = 0; i < shader_size / 4; i += 4) { printf("0x%08lX 0x%08lX 0x%08lX 0x%08lX 0x%08lX 0x%08lX 0x%08lX 0x%08lX\n", shader[i], shader[i + 1], shader[i + 2], shader[i + 3], org[i], org[i + 1], org[i + 2], org[i + 3]); } for (i = 0; i < shader_size / 4; i++) { if (shader[i] != org[i]) printf("%i(%X): 0x%08lX(0x%08lX) should be 0x%08lX(0x%08lX) \n", i, i, shader[i], __builtin_bswap32(shader[i]), org[i], __builtin_bswap32(org[i])); } } void check_shader(const void *shader_, u32 shader_size, const void *org_, u32 org_size, const char *name) { unsigned i; bool different = false; u32 *shader = (u32 *)shader_; u32 *org = (u32 *)org_; printf("%-20s : ", name); if (shader_size != org_size) { different = true; printf("\nsize mismatch : 0x%08lX should be 0x%08lX", shader_size, org_size); } for (i = 0; i < shader_size / 4; i++) { if (shader[i] != org[i]) { different = true; printf("\n%i(%X): 0x%08lX(0x%08lX) should be 0x%08lX(0x%08lX)", i, i, shader[i], __builtin_bswap32(shader[i]), org[i], __builtin_bswap32(org[i])); } } if (!different) printf("no errors"); printf("\n"); } #define MAKE_MAGIC(c0,c1,c2,c3) ((c0 << 24) |(c1 << 16) |(c2 << 8) |(c3 << 0)) #define GFD_FILE_MAJOR_VERSION 7 #define GFD_FILE_GPU_VERSION 2 #define GFD_BLOCK_MAJOR_VERSION 1 #define GFD_FILE_MAGIC MAKE_MAGIC('G','f','x','2') #define GFD_BLOCK_MAGIC MAKE_MAGIC('B','L','K','{') #define GFD_BLOCK_RELOCATIONS_MAGIC MAKE_MAGIC('}','B','L','K') #define GFD_RELOCATIONS_TYPE_MASK 0xFFF00000 #define GFD_RELOCATIONS_VALUE_MASK (~GFD_RELOCATIONS_TYPE_MASK) #define GFD_RELOCATIONS_DATA 0xD0600000 #define GFD_RELOCATIONS_TEXT 0xCA700000 typedef enum { GFD_BLOCK_TYPE_END_OF_FILE = 1, GFD_BLOCK_TYPE_PADDING = 2, GFD_BLOCK_TYPE_VERTEX_SHADER_HEADER = 3, GFD_BLOCK_TYPE_VERTEX_SHADER_PROGRAM = 5, GFD_BLOCK_TYPE_PIXEL_SHADER_HEADER = 6, GFD_BLOCK_TYPE_PIXEL_SHADER_PROGRAM = 7, } GFDBlockType; typedef struct { uint32_t magic; uint32_t headerSize; uint32_t majorVersion; uint32_t minorVersion; uint32_t gpuVersion; uint32_t align; uint32_t unk1; uint32_t unk2; } GFDFileHeader; typedef struct { uint32_t magic; uint32_t headerSize; uint32_t majorVersion; uint32_t minorVersion; GFDBlockType type; uint32_t dataSize; uint32_t id; uint32_t index; } GFDBlockHeader; typedef struct { uint32_t magic; uint32_t headerSize; uint32_t unk1; uint32_t dataSize; uint32_t dataOffset; uint32_t textSize; uint32_t textOffset; uint32_t patchBase; uint32_t patchCount; uint32_t patchOffset; } GFDRelocationHeader; typedef struct { GFDBlockHeader header; u8 data[]; } GFDBlock; void gfd_free(GFDFile* gfd) { if(gfd) { MEM2_free(gfd->data); free(gfd); } } static bool gfd_relocate_block(GFDBlock* block) { unsigned i; GFDRelocationHeader* rel = (GFDRelocationHeader*)(block->data + block->header.dataSize) - 1; if (rel->magic != GFD_BLOCK_RELOCATIONS_MAGIC) { printf("wrong relocations magic number.\n"); return false; } if((rel->patchOffset & GFD_RELOCATIONS_TYPE_MASK) != GFD_RELOCATIONS_DATA) { printf("wrong data relocations mask.\n"); return false; } u32* patches = (u32*)(block->data + (rel->patchOffset & GFD_RELOCATIONS_VALUE_MASK)); for (i = 0; i < rel->patchCount; i++) { if(patches[i]) { if((patches[i] & GFD_RELOCATIONS_TYPE_MASK) != GFD_RELOCATIONS_DATA) { printf("wrong patch relocations mask.\n"); return false; } u32* ptr = (u32*)(block->data + (patches[i] & GFD_RELOCATIONS_VALUE_MASK)); if((((*ptr) & GFD_RELOCATIONS_TYPE_MASK) != GFD_RELOCATIONS_DATA) && (((*ptr) & GFD_RELOCATIONS_TYPE_MASK) != GFD_RELOCATIONS_TEXT)) { printf("wrong relocations mask.\n"); return false; } *ptr = (u32)block->data + ((*ptr) & GFD_RELOCATIONS_VALUE_MASK); } } return true; } GFDFile *gfd_open(const char *filename) { GFDFile* gfd = calloc(1, sizeof(*gfd)); FILE *fp = fopen(filename, "rb"); if (!fp) goto error; fseek(fp, 0, SEEK_END); int size = ftell(fp); fseek(fp, 0, SEEK_SET); gfd->data = MEM2_alloc(size, GX2_SHADER_ALIGNMENT); fread(gfd->data, 1, size, fp); fclose(fp); GFDFileHeader *header = (GFDFileHeader *)gfd->data; if (header->magic != GFD_FILE_MAGIC) { printf("wrong file magic number.\n"); goto error; } if (header->headerSize != sizeof(GFDFileHeader)) { printf("wrong file header size.\n"); goto error; } if (header->majorVersion != GFD_FILE_MAJOR_VERSION) { printf("file version not supported.\n"); goto error; } if (header->gpuVersion != GFD_FILE_GPU_VERSION) { printf("gpu version not supported.\n"); goto error; } if (!header->align) { printf("data is not aligned.\n"); goto error; } GFDBlock *block = (GFDBlock *)(gfd->data + header->headerSize); while (block->header.type != GFD_BLOCK_TYPE_END_OF_FILE) { if (block->header.magic != GFD_BLOCK_MAGIC) { printf("wrong block magic number.\n"); goto error; } if (block->header.headerSize != sizeof(GFDBlockHeader)) { printf("wrong block header size.\n"); goto error; } if (block->header.majorVersion != GFD_BLOCK_MAJOR_VERSION) { printf("block version not supported.\n"); goto error; } switch (block->header.type) { case GFD_BLOCK_TYPE_VERTEX_SHADER_HEADER: if (gfd->vs) continue; gfd->vs = (GX2VertexShader*)block->data; if(!gfd_relocate_block(block)) goto error; break; case GFD_BLOCK_TYPE_VERTEX_SHADER_PROGRAM: if(gfd->vs->program) continue; GX2Invalidate(GX2_INVALIDATE_MODE_CPU_SHADER, block->data, block->header.dataSize); gfd->vs->program = block->data; break; case GFD_BLOCK_TYPE_PIXEL_SHADER_HEADER: if (gfd->ps) continue; gfd->ps = (GX2PixelShader*)block->data; if(!gfd_relocate_block(block)) goto error; break; case GFD_BLOCK_TYPE_PIXEL_SHADER_PROGRAM: if(gfd->ps->program) continue; GX2Invalidate(GX2_INVALIDATE_MODE_CPU_SHADER, block->data, block->header.dataSize); gfd->ps->program = block->data; break; default: break; } block = (GFDBlock *)((u8 *)block + block->header.headerSize + block->header.dataSize); } if(!gfd->vs) { printf("vertex shader is missing.\n"); goto error; } if(!gfd->vs->program) { printf("vertex shader program is missing.\n"); goto error; } if(!gfd->ps) { printf("pixel shader is missing.\n"); goto error; } if(!gfd->ps->program) { printf("pixel shader program is missing.\n"); goto error; } return gfd; error: printf("failed to open file : %s\n", filename); gfd_free(gfd); return NULL; }