/* * Copyright 2016 Advanced Micro Devices, Inc. * All Rights Reserved. * * 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 * on the rights to use, copy, modify, merge, publish, distribute, sub * license, 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 (including the next * paragraph) 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 NON-INFRINGEMENT. IN NO EVENT SHALL * THE AUTHOR(S) AND/OR THEIR SUPPLIERS 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. */ #include "si_shader_internal.h" #include "si_pipe.h" #include "ac_llvm_util.h" #include "util/u_memory.h" enum si_llvm_calling_convention { RADEON_LLVM_AMDGPU_VS = 87, RADEON_LLVM_AMDGPU_GS = 88, RADEON_LLVM_AMDGPU_PS = 89, RADEON_LLVM_AMDGPU_CS = 90, RADEON_LLVM_AMDGPU_HS = 93, }; struct si_llvm_diagnostics { struct pipe_debug_callback *debug; unsigned retval; }; static void si_diagnostic_handler(LLVMDiagnosticInfoRef di, void *context) { struct si_llvm_diagnostics *diag = (struct si_llvm_diagnostics *)context; LLVMDiagnosticSeverity severity = LLVMGetDiagInfoSeverity(di); char *description = LLVMGetDiagInfoDescription(di); const char *severity_str = NULL; switch (severity) { case LLVMDSError: severity_str = "error"; break; case LLVMDSWarning: severity_str = "warning"; break; case LLVMDSRemark: severity_str = "remark"; break; case LLVMDSNote: severity_str = "note"; break; default: severity_str = "unknown"; } pipe_debug_message(diag->debug, SHADER_INFO, "LLVM diagnostic (%s): %s", severity_str, description); if (severity == LLVMDSError) { diag->retval = 1; fprintf(stderr,"LLVM triggered Diagnostic Handler: %s\n", description); } LLVMDisposeMessage(description); } /** * Compile an LLVM module to machine code. * * @returns 0 for success, 1 for failure */ unsigned si_llvm_compile(LLVMModuleRef M, struct ac_shader_binary *binary, struct ac_llvm_compiler *compiler, struct pipe_debug_callback *debug) { struct si_llvm_diagnostics diag; LLVMContextRef llvm_ctx; diag.debug = debug; diag.retval = 0; /* Setup Diagnostic Handler*/ llvm_ctx = LLVMGetModuleContext(M); LLVMContextSetDiagnosticHandler(llvm_ctx, si_diagnostic_handler, &diag); /* Compile IR. */ if (!ac_compile_module_to_binary(compiler->passes, M, binary)) diag.retval = 1; if (diag.retval != 0) pipe_debug_message(debug, SHADER_INFO, "LLVM compile failed"); return diag.retval; } LLVMTypeRef tgsi2llvmtype(struct lp_build_tgsi_context *bld_base, enum tgsi_opcode_type type) { struct si_shader_context *ctx = si_shader_context(bld_base); switch (type) { case TGSI_TYPE_UNSIGNED: case TGSI_TYPE_SIGNED: return ctx->ac.i32; case TGSI_TYPE_UNSIGNED64: case TGSI_TYPE_SIGNED64: return ctx->ac.i64; case TGSI_TYPE_DOUBLE: return ctx->ac.f64; case TGSI_TYPE_UNTYPED: case TGSI_TYPE_FLOAT: return ctx->ac.f32; default: break; } return 0; } LLVMValueRef bitcast(struct lp_build_tgsi_context *bld_base, enum tgsi_opcode_type type, LLVMValueRef value) { struct si_shader_context *ctx = si_shader_context(bld_base); LLVMTypeRef dst_type = tgsi2llvmtype(bld_base, type); if (dst_type) return LLVMBuildBitCast(ctx->ac.builder, value, dst_type, ""); else return value; } /** * Return a value that is equal to the given i32 \p index if it lies in [0,num) * or an undefined value in the same interval otherwise. */ LLVMValueRef si_llvm_bound_index(struct si_shader_context *ctx, LLVMValueRef index, unsigned num) { LLVMBuilderRef builder = ctx->ac.builder; LLVMValueRef c_max = LLVMConstInt(ctx->i32, num - 1, 0); LLVMValueRef cc; if (util_is_power_of_two_or_zero(num)) { index = LLVMBuildAnd(builder, index, c_max, ""); } else { /* In theory, this MAX pattern should result in code that is * as good as the bit-wise AND above. * * In practice, LLVM generates worse code (at the time of * writing), because its value tracking is not strong enough. */ cc = LLVMBuildICmp(builder, LLVMIntULE, index, c_max, ""); index = LLVMBuildSelect(builder, cc, index, c_max, ""); } return index; } static LLVMValueRef emit_swizzle(struct lp_build_tgsi_context *bld_base, LLVMValueRef value, unsigned swizzle_x, unsigned swizzle_y, unsigned swizzle_z, unsigned swizzle_w) { struct si_shader_context *ctx = si_shader_context(bld_base); LLVMValueRef swizzles[4]; swizzles[0] = LLVMConstInt(ctx->i32, swizzle_x, 0); swizzles[1] = LLVMConstInt(ctx->i32, swizzle_y, 0); swizzles[2] = LLVMConstInt(ctx->i32, swizzle_z, 0); swizzles[3] = LLVMConstInt(ctx->i32, swizzle_w, 0); return LLVMBuildShuffleVector(ctx->ac.builder, value, LLVMGetUndef(LLVMTypeOf(value)), LLVMConstVector(swizzles, 4), ""); } /** * Return the description of the array covering the given temporary register * index. */ static unsigned get_temp_array_id(struct lp_build_tgsi_context *bld_base, unsigned reg_index, const struct tgsi_ind_register *reg) { struct si_shader_context *ctx = si_shader_context(bld_base); unsigned num_arrays = ctx->bld_base.info->array_max[TGSI_FILE_TEMPORARY]; unsigned i; if (reg && reg->ArrayID > 0 && reg->ArrayID <= num_arrays) return reg->ArrayID; for (i = 0; i < num_arrays; i++) { const struct tgsi_array_info *array = &ctx->temp_arrays[i]; if (reg_index >= array->range.First && reg_index <= array->range.Last) return i + 1; } return 0; } static struct tgsi_declaration_range get_array_range(struct lp_build_tgsi_context *bld_base, unsigned File, unsigned reg_index, const struct tgsi_ind_register *reg) { struct si_shader_context *ctx = si_shader_context(bld_base); struct tgsi_declaration_range range; if (File == TGSI_FILE_TEMPORARY) { unsigned array_id = get_temp_array_id(bld_base, reg_index, reg); if (array_id) return ctx->temp_arrays[array_id - 1].range; } range.First = 0; range.Last = bld_base->info->file_max[File]; return range; } /** * For indirect registers, construct a pointer directly to the requested * element using getelementptr if possible. * * Returns NULL if the insertelement/extractelement fallback for array access * must be used. */ static LLVMValueRef get_pointer_into_array(struct si_shader_context *ctx, unsigned file, unsigned swizzle, unsigned reg_index, const struct tgsi_ind_register *reg_indirect) { unsigned array_id; struct tgsi_array_info *array; LLVMBuilderRef builder = ctx->ac.builder; LLVMValueRef idxs[2]; LLVMValueRef index; LLVMValueRef alloca; if (file != TGSI_FILE_TEMPORARY) return NULL; array_id = get_temp_array_id(&ctx->bld_base, reg_index, reg_indirect); if (!array_id) return NULL; alloca = ctx->temp_array_allocas[array_id - 1]; if (!alloca) return NULL; array = &ctx->temp_arrays[array_id - 1]; if (!(array->writemask & (1 << swizzle))) return ctx->undef_alloca; index = si_get_indirect_index(ctx, reg_indirect, 1, reg_index - ctx->temp_arrays[array_id - 1].range.First); /* Ensure that the index is within a valid range, to guard against * VM faults and overwriting critical data (e.g. spilled resource * descriptors). * * TODO It should be possible to avoid the additional instructions * if LLVM is changed so that it guarantuees: * 1. the scratch space descriptor isolates the current wave (this * could even save the scratch offset SGPR at the cost of an * additional SALU instruction) * 2. the memory for allocas must be allocated at the _end_ of the * scratch space (after spilled registers) */ index = si_llvm_bound_index(ctx, index, array->range.Last - array->range.First + 1); index = LLVMBuildMul( builder, index, LLVMConstInt(ctx->i32, util_bitcount(array->writemask), 0), ""); index = LLVMBuildAdd( builder, index, LLVMConstInt(ctx->i32, util_bitcount(array->writemask & ((1 << swizzle) - 1)), 0), ""); idxs[0] = ctx->i32_0; idxs[1] = index; return LLVMBuildGEP(ctx->ac.builder, alloca, idxs, 2, ""); } LLVMValueRef si_llvm_emit_fetch_64bit(struct lp_build_tgsi_context *bld_base, LLVMTypeRef type, LLVMValueRef ptr, LLVMValueRef ptr2) { struct si_shader_context *ctx = si_shader_context(bld_base); LLVMValueRef result; result = LLVMGetUndef(LLVMVectorType(ctx->i32, 2)); result = LLVMBuildInsertElement(ctx->ac.builder, result, ac_to_integer(&ctx->ac, ptr), ctx->i32_0, ""); result = LLVMBuildInsertElement(ctx->ac.builder, result, ac_to_integer(&ctx->ac, ptr2), ctx->i32_1, ""); return LLVMBuildBitCast(ctx->ac.builder, result, type, ""); } static LLVMValueRef emit_array_fetch(struct lp_build_tgsi_context *bld_base, unsigned File, enum tgsi_opcode_type type, struct tgsi_declaration_range range, unsigned swizzle) { struct si_shader_context *ctx = si_shader_context(bld_base); unsigned i, size = range.Last - range.First + 1; LLVMTypeRef vec = LLVMVectorType(tgsi2llvmtype(bld_base, type), size); LLVMValueRef result = LLVMGetUndef(vec); struct tgsi_full_src_register tmp_reg = {}; tmp_reg.Register.File = File; for (i = 0; i < size; ++i) { tmp_reg.Register.Index = i + range.First; LLVMValueRef temp = si_llvm_emit_fetch(bld_base, &tmp_reg, type, swizzle); result = LLVMBuildInsertElement(ctx->ac.builder, result, temp, LLVMConstInt(ctx->i32, i, 0), "array_vector"); } return result; } static LLVMValueRef load_value_from_array(struct lp_build_tgsi_context *bld_base, unsigned file, enum tgsi_opcode_type type, unsigned swizzle, unsigned reg_index, const struct tgsi_ind_register *reg_indirect) { struct si_shader_context *ctx = si_shader_context(bld_base); LLVMBuilderRef builder = ctx->ac.builder; LLVMValueRef ptr; ptr = get_pointer_into_array(ctx, file, swizzle, reg_index, reg_indirect); if (ptr) { LLVMValueRef val = LLVMBuildLoad(builder, ptr, ""); if (tgsi_type_is_64bit(type)) { LLVMValueRef ptr_hi, val_hi; ptr_hi = LLVMBuildGEP(builder, ptr, &ctx->i32_1, 1, ""); val_hi = LLVMBuildLoad(builder, ptr_hi, ""); val = si_llvm_emit_fetch_64bit(bld_base, tgsi2llvmtype(bld_base, type), val, val_hi); } return val; } else { struct tgsi_declaration_range range = get_array_range(bld_base, file, reg_index, reg_indirect); LLVMValueRef index = si_get_indirect_index(ctx, reg_indirect, 1, reg_index - range.First); LLVMValueRef array = emit_array_fetch(bld_base, file, type, range, swizzle); return LLVMBuildExtractElement(builder, array, index, ""); } } static void store_value_to_array(struct lp_build_tgsi_context *bld_base, LLVMValueRef value, unsigned file, unsigned chan_index, unsigned reg_index, const struct tgsi_ind_register *reg_indirect) { struct si_shader_context *ctx = si_shader_context(bld_base); LLVMBuilderRef builder = ctx->ac.builder; LLVMValueRef ptr; ptr = get_pointer_into_array(ctx, file, chan_index, reg_index, reg_indirect); if (ptr) { LLVMBuildStore(builder, value, ptr); } else { unsigned i, size; struct tgsi_declaration_range range = get_array_range(bld_base, file, reg_index, reg_indirect); LLVMValueRef index = si_get_indirect_index(ctx, reg_indirect, 1, reg_index - range.First); LLVMValueRef array = emit_array_fetch(bld_base, file, TGSI_TYPE_FLOAT, range, chan_index); LLVMValueRef temp_ptr; array = LLVMBuildInsertElement(builder, array, value, index, ""); size = range.Last - range.First + 1; for (i = 0; i < size; ++i) { switch(file) { case TGSI_FILE_OUTPUT: temp_ptr = ctx->outputs[i + range.First][chan_index]; break; case TGSI_FILE_TEMPORARY: if (range.First + i >= ctx->temps_count) continue; temp_ptr = ctx->temps[(i + range.First) * TGSI_NUM_CHANNELS + chan_index]; break; default: continue; } value = LLVMBuildExtractElement(builder, array, LLVMConstInt(ctx->i32, i, 0), ""); LLVMBuildStore(builder, value, temp_ptr); } } } /* If this is true, preload FS inputs at the beginning of shaders. Otherwise, * reload them at each use. This must be true if the shader is using * derivatives and KILL, because KILL can leave the WQM and then a lazy * input load isn't in the WQM anymore. */ static bool si_preload_fs_inputs(struct si_shader_context *ctx) { struct si_shader_selector *sel = ctx->shader->selector; return sel->info.uses_derivatives && sel->info.uses_kill; } static LLVMValueRef get_output_ptr(struct lp_build_tgsi_context *bld_base, unsigned index, unsigned chan) { struct si_shader_context *ctx = si_shader_context(bld_base); assert(index <= ctx->bld_base.info->file_max[TGSI_FILE_OUTPUT]); return ctx->outputs[index][chan]; } LLVMValueRef si_llvm_emit_fetch(struct lp_build_tgsi_context *bld_base, const struct tgsi_full_src_register *reg, enum tgsi_opcode_type type, unsigned swizzle) { struct si_shader_context *ctx = si_shader_context(bld_base); LLVMBuilderRef builder = ctx->ac.builder; LLVMValueRef result = NULL, ptr, ptr2; if (swizzle == ~0) { LLVMValueRef values[TGSI_NUM_CHANNELS]; unsigned chan; for (chan = 0; chan < TGSI_NUM_CHANNELS; chan++) { values[chan] = si_llvm_emit_fetch(bld_base, reg, type, chan); } return ac_build_gather_values(&ctx->ac, values, TGSI_NUM_CHANNELS); } if (reg->Register.Indirect) { LLVMValueRef load = load_value_from_array(bld_base, reg->Register.File, type, swizzle, reg->Register.Index, ®->Indirect); return bitcast(bld_base, type, load); } switch(reg->Register.File) { case TGSI_FILE_IMMEDIATE: { LLVMTypeRef ctype = tgsi2llvmtype(bld_base, type); if (tgsi_type_is_64bit(type)) { result = LLVMGetUndef(LLVMVectorType(ctx->i32, 2)); result = LLVMConstInsertElement(result, ctx->imms[reg->Register.Index * TGSI_NUM_CHANNELS + swizzle], ctx->i32_0); result = LLVMConstInsertElement(result, ctx->imms[reg->Register.Index * TGSI_NUM_CHANNELS + swizzle + 1], ctx->i32_1); return LLVMConstBitCast(result, ctype); } else { return LLVMConstBitCast(ctx->imms[reg->Register.Index * TGSI_NUM_CHANNELS + swizzle], ctype); } } case TGSI_FILE_INPUT: { unsigned index = reg->Register.Index; LLVMValueRef input[4]; /* I don't think doing this for vertex shaders is beneficial. * For those, we want to make sure the VMEM loads are executed * only once. Fragment shaders don't care much, because * v_interp instructions are much cheaper than VMEM loads. */ if (!si_preload_fs_inputs(ctx) && ctx->bld_base.info->processor == PIPE_SHADER_FRAGMENT) ctx->load_input(ctx, index, &ctx->input_decls[index], input); else memcpy(input, &ctx->inputs[index * 4], sizeof(input)); result = input[swizzle]; if (tgsi_type_is_64bit(type)) { ptr = result; ptr2 = input[swizzle + 1]; return si_llvm_emit_fetch_64bit(bld_base, tgsi2llvmtype(bld_base, type), ptr, ptr2); } break; } case TGSI_FILE_TEMPORARY: if (reg->Register.Index >= ctx->temps_count) return LLVMGetUndef(tgsi2llvmtype(bld_base, type)); ptr = ctx->temps[reg->Register.Index * TGSI_NUM_CHANNELS + swizzle]; if (tgsi_type_is_64bit(type)) { ptr2 = ctx->temps[reg->Register.Index * TGSI_NUM_CHANNELS + swizzle + 1]; return si_llvm_emit_fetch_64bit(bld_base, tgsi2llvmtype(bld_base, type), LLVMBuildLoad(builder, ptr, ""), LLVMBuildLoad(builder, ptr2, "")); } result = LLVMBuildLoad(builder, ptr, ""); break; case TGSI_FILE_OUTPUT: ptr = get_output_ptr(bld_base, reg->Register.Index, swizzle); if (tgsi_type_is_64bit(type)) { ptr2 = get_output_ptr(bld_base, reg->Register.Index, swizzle + 1); return si_llvm_emit_fetch_64bit(bld_base, tgsi2llvmtype(bld_base, type), LLVMBuildLoad(builder, ptr, ""), LLVMBuildLoad(builder, ptr2, "")); } result = LLVMBuildLoad(builder, ptr, ""); break; default: return LLVMGetUndef(tgsi2llvmtype(bld_base, type)); } return bitcast(bld_base, type, result); } static LLVMValueRef fetch_system_value(struct lp_build_tgsi_context *bld_base, const struct tgsi_full_src_register *reg, enum tgsi_opcode_type type, unsigned swizzle) { struct si_shader_context *ctx = si_shader_context(bld_base); LLVMBuilderRef builder = ctx->ac.builder; LLVMValueRef cval = ctx->system_values[reg->Register.Index]; if (tgsi_type_is_64bit(type)) { LLVMValueRef lo, hi; assert(swizzle == 0 || swizzle == 2); lo = LLVMBuildExtractElement( builder, cval, LLVMConstInt(ctx->i32, swizzle, 0), ""); hi = LLVMBuildExtractElement( builder, cval, LLVMConstInt(ctx->i32, swizzle + 1, 0), ""); return si_llvm_emit_fetch_64bit(bld_base, tgsi2llvmtype(bld_base, type), lo, hi); } if (LLVMGetTypeKind(LLVMTypeOf(cval)) == LLVMVectorTypeKind) { cval = LLVMBuildExtractElement( builder, cval, LLVMConstInt(ctx->i32, swizzle, 0), ""); } else { assert(swizzle == 0); } return bitcast(bld_base, type, cval); } static void emit_declaration(struct lp_build_tgsi_context *bld_base, const struct tgsi_full_declaration *decl) { struct si_shader_context *ctx = si_shader_context(bld_base); LLVMBuilderRef builder = ctx->ac.builder; unsigned first, last, i; switch(decl->Declaration.File) { case TGSI_FILE_ADDRESS: { unsigned idx; for (idx = decl->Range.First; idx <= decl->Range.Last; idx++) { unsigned chan; for (chan = 0; chan < TGSI_NUM_CHANNELS; chan++) { ctx->addrs[idx][chan] = ac_build_alloca_undef( &ctx->ac, ctx->i32, ""); } } break; } case TGSI_FILE_TEMPORARY: { char name[18] = ""; LLVMValueRef array_alloca = NULL; unsigned decl_size; unsigned writemask = decl->Declaration.UsageMask; first = decl->Range.First; last = decl->Range.Last; decl_size = 4 * ((last - first) + 1); if (decl->Declaration.Array) { unsigned id = decl->Array.ArrayID - 1; unsigned array_size; writemask &= ctx->temp_arrays[id].writemask; ctx->temp_arrays[id].writemask = writemask; array_size = ((last - first) + 1) * util_bitcount(writemask); /* If the array has more than 16 elements, store it * in memory using an alloca that spans the entire * array. * * Otherwise, store each array element individually. * We will then generate vectors (per-channel, up to * <16 x float> if the usagemask is a single bit) for * indirect addressing. * * Note that 16 is the number of vector elements that * LLVM will store in a register, so theoretically an * array with up to 4 * 16 = 64 elements could be * handled this way, but whether that's a good idea * depends on VGPR register pressure elsewhere. * * FIXME: We shouldn't need to have the non-alloca * code path for arrays. LLVM should be smart enough to * promote allocas into registers when profitable. */ if (array_size > 16 || !ctx->screen->llvm_has_working_vgpr_indexing) { array_alloca = ac_build_alloca_undef(&ctx->ac, LLVMArrayType(ctx->f32, array_size), "array"); ctx->temp_array_allocas[id] = array_alloca; } } if (!ctx->temps_count) { ctx->temps_count = bld_base->info->file_max[TGSI_FILE_TEMPORARY] + 1; ctx->temps = MALLOC(TGSI_NUM_CHANNELS * ctx->temps_count * sizeof(LLVMValueRef)); } if (!array_alloca) { for (i = 0; i < decl_size; ++i) { #ifdef DEBUG snprintf(name, sizeof(name), "TEMP%d.%c", first + i / 4, "xyzw"[i % 4]); #endif ctx->temps[first * TGSI_NUM_CHANNELS + i] = ac_build_alloca_undef(&ctx->ac, ctx->f32, name); } } else { LLVMValueRef idxs[2] = { ctx->i32_0, NULL }; unsigned j = 0; if (writemask != TGSI_WRITEMASK_XYZW && !ctx->undef_alloca) { /* Create a dummy alloca. We use it so that we * have a pointer that is safe to load from if * a shader ever reads from a channel that * it never writes to. */ ctx->undef_alloca = ac_build_alloca_undef( &ctx->ac, ctx->f32, "undef"); } for (i = 0; i < decl_size; ++i) { LLVMValueRef ptr; if (writemask & (1 << (i % 4))) { #ifdef DEBUG snprintf(name, sizeof(name), "TEMP%d.%c", first + i / 4, "xyzw"[i % 4]); #endif idxs[1] = LLVMConstInt(ctx->i32, j, 0); ptr = LLVMBuildGEP(builder, array_alloca, idxs, 2, name); j++; } else { ptr = ctx->undef_alloca; } ctx->temps[first * TGSI_NUM_CHANNELS + i] = ptr; } } break; } case TGSI_FILE_INPUT: { unsigned idx; for (idx = decl->Range.First; idx <= decl->Range.Last; idx++) { if (ctx->load_input && ctx->input_decls[idx].Declaration.File != TGSI_FILE_INPUT) { ctx->input_decls[idx] = *decl; ctx->input_decls[idx].Range.First = idx; ctx->input_decls[idx].Range.Last = idx; ctx->input_decls[idx].Semantic.Index += idx - decl->Range.First; if (si_preload_fs_inputs(ctx) || bld_base->info->processor != PIPE_SHADER_FRAGMENT) ctx->load_input(ctx, idx, &ctx->input_decls[idx], &ctx->inputs[idx * 4]); } } } break; case TGSI_FILE_SYSTEM_VALUE: { unsigned idx; for (idx = decl->Range.First; idx <= decl->Range.Last; idx++) { si_load_system_value(ctx, idx, decl); } } break; case TGSI_FILE_OUTPUT: { char name[16] = ""; unsigned idx; for (idx = decl->Range.First; idx <= decl->Range.Last; idx++) { unsigned chan; assert(idx < RADEON_LLVM_MAX_OUTPUTS); if (ctx->outputs[idx][0]) continue; for (chan = 0; chan < TGSI_NUM_CHANNELS; chan++) { #ifdef DEBUG snprintf(name, sizeof(name), "OUT%d.%c", idx, "xyzw"[chan % 4]); #endif ctx->outputs[idx][chan] = ac_build_alloca_undef( &ctx->ac, ctx->f32, name); } } break; } case TGSI_FILE_MEMORY: si_tgsi_declare_compute_memory(ctx, decl); break; default: break; } } void si_llvm_emit_store(struct lp_build_tgsi_context *bld_base, const struct tgsi_full_instruction *inst, const struct tgsi_opcode_info *info, unsigned index, LLVMValueRef dst[4]) { struct si_shader_context *ctx = si_shader_context(bld_base); const struct tgsi_full_dst_register *reg = &inst->Dst[index]; LLVMBuilderRef builder = ctx->ac.builder; LLVMValueRef temp_ptr, temp_ptr2 = NULL; bool is_vec_store = false; enum tgsi_opcode_type dtype = tgsi_opcode_infer_dst_type(inst->Instruction.Opcode, index); if (dst[0]) { LLVMTypeKind k = LLVMGetTypeKind(LLVMTypeOf(dst[0])); is_vec_store = (k == LLVMVectorTypeKind); } if (is_vec_store) { LLVMValueRef values[4] = {}; uint32_t writemask = reg->Register.WriteMask; while (writemask) { unsigned chan = u_bit_scan(&writemask); LLVMValueRef index = LLVMConstInt(ctx->i32, chan, 0); values[chan] = LLVMBuildExtractElement(ctx->ac.builder, dst[0], index, ""); } bld_base->emit_store(bld_base, inst, info, index, values); return; } uint32_t writemask = reg->Register.WriteMask; while (writemask) { unsigned chan_index = u_bit_scan(&writemask); LLVMValueRef value = dst[chan_index]; if (tgsi_type_is_64bit(dtype) && (chan_index == 1 || chan_index == 3)) continue; if (inst->Instruction.Saturate) value = ac_build_clamp(&ctx->ac, value); if (reg->Register.File == TGSI_FILE_ADDRESS) { temp_ptr = ctx->addrs[reg->Register.Index][chan_index]; LLVMBuildStore(builder, value, temp_ptr); continue; } if (!tgsi_type_is_64bit(dtype)) value = ac_to_float(&ctx->ac, value); if (reg->Register.Indirect) { unsigned file = reg->Register.File; unsigned reg_index = reg->Register.Index; store_value_to_array(bld_base, value, file, chan_index, reg_index, ®->Indirect); } else { switch(reg->Register.File) { case TGSI_FILE_OUTPUT: temp_ptr = ctx->outputs[reg->Register.Index][chan_index]; if (tgsi_type_is_64bit(dtype)) temp_ptr2 = ctx->outputs[reg->Register.Index][chan_index + 1]; break; case TGSI_FILE_TEMPORARY: { if (reg->Register.Index >= ctx->temps_count) continue; temp_ptr = ctx->temps[ TGSI_NUM_CHANNELS * reg->Register.Index + chan_index]; if (tgsi_type_is_64bit(dtype)) temp_ptr2 = ctx->temps[ TGSI_NUM_CHANNELS * reg->Register.Index + chan_index + 1]; break; } default: return; } if (!tgsi_type_is_64bit(dtype)) LLVMBuildStore(builder, value, temp_ptr); else { LLVMValueRef ptr = LLVMBuildBitCast(builder, value, LLVMVectorType(ctx->i32, 2), ""); LLVMValueRef val2; value = LLVMBuildExtractElement(builder, ptr, ctx->i32_0, ""); val2 = LLVMBuildExtractElement(builder, ptr, ctx->i32_1, ""); LLVMBuildStore(builder, ac_to_float(&ctx->ac, value), temp_ptr); LLVMBuildStore(builder, ac_to_float(&ctx->ac, val2), temp_ptr2); } } } } static int get_line(int pc) { /* Subtract 1 so that the number shown is that of the corresponding * opcode in the TGSI dump, e.g. an if block has the same suffix as * the instruction number of the corresponding TGSI IF. */ return pc - 1; } static void bgnloop_emit(const struct lp_build_tgsi_action *action, struct lp_build_tgsi_context *bld_base, struct lp_build_emit_data *emit_data) { struct si_shader_context *ctx = si_shader_context(bld_base); ac_build_bgnloop(&ctx->ac, get_line(bld_base->pc)); } static void brk_emit(const struct lp_build_tgsi_action *action, struct lp_build_tgsi_context *bld_base, struct lp_build_emit_data *emit_data) { struct si_shader_context *ctx = si_shader_context(bld_base); ac_build_break(&ctx->ac); } static void cont_emit(const struct lp_build_tgsi_action *action, struct lp_build_tgsi_context *bld_base, struct lp_build_emit_data *emit_data) { struct si_shader_context *ctx = si_shader_context(bld_base); ac_build_continue(&ctx->ac); } static void else_emit(const struct lp_build_tgsi_action *action, struct lp_build_tgsi_context *bld_base, struct lp_build_emit_data *emit_data) { struct si_shader_context *ctx = si_shader_context(bld_base); ac_build_else(&ctx->ac, get_line(bld_base->pc)); } static void endif_emit(const struct lp_build_tgsi_action *action, struct lp_build_tgsi_context *bld_base, struct lp_build_emit_data *emit_data) { struct si_shader_context *ctx = si_shader_context(bld_base); ac_build_endif(&ctx->ac, get_line(bld_base->pc)); } static void endloop_emit(const struct lp_build_tgsi_action *action, struct lp_build_tgsi_context *bld_base, struct lp_build_emit_data *emit_data) { struct si_shader_context *ctx = si_shader_context(bld_base); ac_build_endloop(&ctx->ac, get_line(bld_base->pc)); } static void if_emit(const struct lp_build_tgsi_action *action, struct lp_build_tgsi_context *bld_base, struct lp_build_emit_data *emit_data) { struct si_shader_context *ctx = si_shader_context(bld_base); ac_build_if(&ctx->ac, emit_data->args[0], get_line(bld_base->pc)); } static void uif_emit(const struct lp_build_tgsi_action *action, struct lp_build_tgsi_context *bld_base, struct lp_build_emit_data *emit_data) { struct si_shader_context *ctx = si_shader_context(bld_base); ac_build_uif(&ctx->ac, emit_data->args[0], get_line(bld_base->pc)); } static void emit_immediate(struct lp_build_tgsi_context *bld_base, const struct tgsi_full_immediate *imm) { unsigned i; struct si_shader_context *ctx = si_shader_context(bld_base); for (i = 0; i < 4; ++i) { ctx->imms[ctx->imms_num * TGSI_NUM_CHANNELS + i] = LLVMConstInt(ctx->i32, imm->u[i].Uint, false ); } ctx->imms_num++; } void si_llvm_context_init(struct si_shader_context *ctx, struct si_screen *sscreen, struct ac_llvm_compiler *compiler) { struct lp_type type; /* Initialize the gallivm object: * We are only using the module, context, and builder fields of this struct. * This should be enough for us to be able to pass our gallivm struct to the * helper functions in the gallivm module. */ memset(ctx, 0, sizeof(*ctx)); ctx->screen = sscreen; ctx->compiler = compiler; ctx->ac.context = LLVMContextCreate(); ac_llvm_context_init(&ctx->ac, ctx->ac.context, sscreen->info.chip_class, sscreen->info.family); ctx->ac.module = ac_create_module(compiler->tm, ctx->ac.context); enum ac_float_mode float_mode = sscreen->debug_flags & DBG(UNSAFE_MATH) ? AC_FLOAT_MODE_UNSAFE_FP_MATH : AC_FLOAT_MODE_NO_SIGNED_ZEROS_FP_MATH; ctx->ac.builder = ac_create_builder(ctx->ac.context, float_mode); ctx->gallivm.context = ctx->ac.context; ctx->gallivm.module = ctx->ac.module; ctx->gallivm.builder = ctx->ac.builder; struct lp_build_tgsi_context *bld_base = &ctx->bld_base; type.floating = true; type.fixed = false; type.sign = true; type.norm = false; type.width = 32; type.length = 1; lp_build_context_init(&bld_base->base, &ctx->gallivm, type); lp_build_context_init(&ctx->bld_base.uint_bld, &ctx->gallivm, lp_uint_type(type)); lp_build_context_init(&ctx->bld_base.int_bld, &ctx->gallivm, lp_int_type(type)); type.width *= 2; lp_build_context_init(&ctx->bld_base.dbl_bld, &ctx->gallivm, type); lp_build_context_init(&ctx->bld_base.uint64_bld, &ctx->gallivm, lp_uint_type(type)); lp_build_context_init(&ctx->bld_base.int64_bld, &ctx->gallivm, lp_int_type(type)); bld_base->soa = 1; bld_base->emit_swizzle = emit_swizzle; bld_base->emit_declaration = emit_declaration; bld_base->emit_immediate = emit_immediate; bld_base->op_actions[TGSI_OPCODE_BGNLOOP].emit = bgnloop_emit; bld_base->op_actions[TGSI_OPCODE_BRK].emit = brk_emit; bld_base->op_actions[TGSI_OPCODE_CONT].emit = cont_emit; bld_base->op_actions[TGSI_OPCODE_IF].emit = if_emit; bld_base->op_actions[TGSI_OPCODE_UIF].emit = uif_emit; bld_base->op_actions[TGSI_OPCODE_ELSE].emit = else_emit; bld_base->op_actions[TGSI_OPCODE_ENDIF].emit = endif_emit; bld_base->op_actions[TGSI_OPCODE_ENDLOOP].emit = endloop_emit; si_shader_context_init_alu(&ctx->bld_base); si_shader_context_init_mem(ctx); ctx->voidt = LLVMVoidTypeInContext(ctx->ac.context); ctx->i1 = LLVMInt1TypeInContext(ctx->ac.context); ctx->i8 = LLVMInt8TypeInContext(ctx->ac.context); ctx->i32 = LLVMInt32TypeInContext(ctx->ac.context); ctx->i64 = LLVMInt64TypeInContext(ctx->ac.context); ctx->i128 = LLVMIntTypeInContext(ctx->ac.context, 128); ctx->f32 = LLVMFloatTypeInContext(ctx->ac.context); ctx->v2i32 = LLVMVectorType(ctx->i32, 2); ctx->v4i32 = LLVMVectorType(ctx->i32, 4); ctx->v4f32 = LLVMVectorType(ctx->f32, 4); ctx->v8i32 = LLVMVectorType(ctx->i32, 8); ctx->i32_0 = LLVMConstInt(ctx->i32, 0, 0); ctx->i32_1 = LLVMConstInt(ctx->i32, 1, 0); } /* Set the context to a certain TGSI shader. Can be called repeatedly * to change the shader. */ void si_llvm_context_set_tgsi(struct si_shader_context *ctx, struct si_shader *shader) { const struct tgsi_shader_info *info = NULL; const struct tgsi_token *tokens = NULL; if (shader && shader->selector) { info = &shader->selector->info; tokens = shader->selector->tokens; } ctx->shader = shader; ctx->type = info ? info->processor : -1; ctx->bld_base.info = info; /* Clean up the old contents. */ FREE(ctx->temp_arrays); ctx->temp_arrays = NULL; FREE(ctx->temp_array_allocas); ctx->temp_array_allocas = NULL; FREE(ctx->imms); ctx->imms = NULL; ctx->imms_num = 0; FREE(ctx->temps); ctx->temps = NULL; ctx->temps_count = 0; if (!info) return; ctx->num_const_buffers = util_last_bit(info->const_buffers_declared); ctx->num_shader_buffers = util_last_bit(info->shader_buffers_declared); ctx->num_samplers = util_last_bit(info->samplers_declared); ctx->num_images = util_last_bit(info->images_declared); if (!tokens) return; if (info->array_max[TGSI_FILE_TEMPORARY] > 0) { int size = info->array_max[TGSI_FILE_TEMPORARY]; ctx->temp_arrays = CALLOC(size, sizeof(ctx->temp_arrays[0])); ctx->temp_array_allocas = CALLOC(size, sizeof(ctx->temp_array_allocas[0])); tgsi_scan_arrays(tokens, TGSI_FILE_TEMPORARY, size, ctx->temp_arrays); } if (info->file_max[TGSI_FILE_IMMEDIATE] >= 0) { int size = info->file_max[TGSI_FILE_IMMEDIATE] + 1; ctx->imms = MALLOC(size * TGSI_NUM_CHANNELS * sizeof(LLVMValueRef)); } /* Re-set these to start with a clean slate. */ ctx->bld_base.num_instructions = 0; ctx->bld_base.pc = 0; memset(ctx->outputs, 0, sizeof(ctx->outputs)); ctx->bld_base.emit_store = si_llvm_emit_store; ctx->bld_base.emit_fetch_funcs[TGSI_FILE_IMMEDIATE] = si_llvm_emit_fetch; ctx->bld_base.emit_fetch_funcs[TGSI_FILE_INPUT] = si_llvm_emit_fetch; ctx->bld_base.emit_fetch_funcs[TGSI_FILE_TEMPORARY] = si_llvm_emit_fetch; ctx->bld_base.emit_fetch_funcs[TGSI_FILE_OUTPUT] = si_llvm_emit_fetch; ctx->bld_base.emit_fetch_funcs[TGSI_FILE_SYSTEM_VALUE] = fetch_system_value; } void si_llvm_create_func(struct si_shader_context *ctx, const char *name, LLVMTypeRef *return_types, unsigned num_return_elems, LLVMTypeRef *ParamTypes, unsigned ParamCount) { LLVMTypeRef main_fn_type, ret_type; LLVMBasicBlockRef main_fn_body; enum si_llvm_calling_convention call_conv; unsigned real_shader_type; if (num_return_elems) ret_type = LLVMStructTypeInContext(ctx->ac.context, return_types, num_return_elems, true); else ret_type = ctx->voidt; /* Setup the function */ ctx->return_type = ret_type; main_fn_type = LLVMFunctionType(ret_type, ParamTypes, ParamCount, 0); ctx->main_fn = LLVMAddFunction(ctx->gallivm.module, name, main_fn_type); main_fn_body = LLVMAppendBasicBlockInContext(ctx->ac.context, ctx->main_fn, "main_body"); LLVMPositionBuilderAtEnd(ctx->ac.builder, main_fn_body); real_shader_type = ctx->type; /* LS is merged into HS (TCS), and ES is merged into GS. */ if (ctx->screen->info.chip_class >= GFX9) { if (ctx->shader->key.as_ls) real_shader_type = PIPE_SHADER_TESS_CTRL; else if (ctx->shader->key.as_es) real_shader_type = PIPE_SHADER_GEOMETRY; } switch (real_shader_type) { case PIPE_SHADER_VERTEX: case PIPE_SHADER_TESS_EVAL: call_conv = RADEON_LLVM_AMDGPU_VS; break; case PIPE_SHADER_TESS_CTRL: call_conv = RADEON_LLVM_AMDGPU_HS; break; case PIPE_SHADER_GEOMETRY: call_conv = RADEON_LLVM_AMDGPU_GS; break; case PIPE_SHADER_FRAGMENT: call_conv = RADEON_LLVM_AMDGPU_PS; break; case PIPE_SHADER_COMPUTE: call_conv = RADEON_LLVM_AMDGPU_CS; break; default: unreachable("Unhandle shader type"); } LLVMSetFunctionCallConv(ctx->main_fn, call_conv); } void si_llvm_optimize_module(struct si_shader_context *ctx) { /* Dump LLVM IR before any optimization passes */ if (ctx->screen->debug_flags & DBG(PREOPT_IR) && si_can_dump_shader(ctx->screen, ctx->type)) LLVMDumpModule(ctx->gallivm.module); /* Run the pass */ LLVMRunPassManager(ctx->compiler->passmgr, ctx->gallivm.module); LLVMDisposeBuilder(ctx->ac.builder); } void si_llvm_dispose(struct si_shader_context *ctx) { LLVMDisposeModule(ctx->gallivm.module); LLVMContextDispose(ctx->gallivm.context); FREE(ctx->temp_arrays); ctx->temp_arrays = NULL; FREE(ctx->temp_array_allocas); ctx->temp_array_allocas = NULL; FREE(ctx->temps); ctx->temps = NULL; ctx->temps_count = 0; FREE(ctx->imms); ctx->imms = NULL; ctx->imms_num = 0; ac_llvm_context_dispose(&ctx->ac); }