/* * Copyright 2014 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, 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 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 COPYRIGHT HOLDERS, AUTHORS AND/OR ITS 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. * * The above copyright notice and this permission notice (including the * next paragraph) shall be included in all copies or substantial portions * of the Software. * */ /* based on pieces from si_pipe.c and radeon_llvm_emit.c */ #include "ac_llvm_build.h" #include #include #include "c11/threads.h" #include #include #include "ac_llvm_util.h" #include "ac_shader_util.h" #include "ac_exp_param.h" #include "util/bitscan.h" #include "util/macros.h" #include "util/u_atomic.h" #include "util/u_math.h" #include "sid.h" #include "shader_enums.h" #define AC_LLVM_INITIAL_CF_DEPTH 4 /* Data for if/else/endif and bgnloop/endloop control flow structures. */ struct ac_llvm_flow { /* Loop exit or next part of if/else/endif. */ LLVMBasicBlockRef next_block; LLVMBasicBlockRef loop_entry_block; }; /* Initialize module-independent parts of the context. * * The caller is responsible for initializing ctx::module and ctx::builder. */ void ac_llvm_context_init(struct ac_llvm_context *ctx, struct ac_llvm_compiler *compiler, enum chip_class chip_class, enum radeon_family family, enum ac_float_mode float_mode, unsigned wave_size, unsigned ballot_mask_bits) { LLVMValueRef args[1]; ctx->context = LLVMContextCreate(); ctx->chip_class = chip_class; ctx->family = family; ctx->wave_size = wave_size; ctx->ballot_mask_bits = ballot_mask_bits; ctx->float_mode = float_mode; ctx->module = ac_create_module(wave_size == 32 ? compiler->tm_wave32 : compiler->tm, ctx->context); ctx->builder = ac_create_builder(ctx->context, float_mode); ctx->voidt = LLVMVoidTypeInContext(ctx->context); ctx->i1 = LLVMInt1TypeInContext(ctx->context); ctx->i8 = LLVMInt8TypeInContext(ctx->context); ctx->i16 = LLVMIntTypeInContext(ctx->context, 16); ctx->i32 = LLVMIntTypeInContext(ctx->context, 32); ctx->i64 = LLVMIntTypeInContext(ctx->context, 64); ctx->intptr = ctx->i32; ctx->f16 = LLVMHalfTypeInContext(ctx->context); ctx->f32 = LLVMFloatTypeInContext(ctx->context); ctx->f64 = LLVMDoubleTypeInContext(ctx->context); ctx->v2i16 = LLVMVectorType(ctx->i16, 2); ctx->v2i32 = LLVMVectorType(ctx->i32, 2); ctx->v3i32 = LLVMVectorType(ctx->i32, 3); ctx->v4i32 = LLVMVectorType(ctx->i32, 4); ctx->v2f32 = LLVMVectorType(ctx->f32, 2); ctx->v3f32 = LLVMVectorType(ctx->f32, 3); ctx->v4f32 = LLVMVectorType(ctx->f32, 4); ctx->v8i32 = LLVMVectorType(ctx->i32, 8); ctx->iN_wavemask = LLVMIntTypeInContext(ctx->context, ctx->wave_size); ctx->iN_ballotmask = LLVMIntTypeInContext(ctx->context, ballot_mask_bits); ctx->i8_0 = LLVMConstInt(ctx->i8, 0, false); ctx->i8_1 = LLVMConstInt(ctx->i8, 1, false); ctx->i16_0 = LLVMConstInt(ctx->i16, 0, false); ctx->i16_1 = LLVMConstInt(ctx->i16, 1, false); ctx->i32_0 = LLVMConstInt(ctx->i32, 0, false); ctx->i32_1 = LLVMConstInt(ctx->i32, 1, false); ctx->i64_0 = LLVMConstInt(ctx->i64, 0, false); ctx->i64_1 = LLVMConstInt(ctx->i64, 1, false); ctx->f16_0 = LLVMConstReal(ctx->f16, 0.0); ctx->f16_1 = LLVMConstReal(ctx->f16, 1.0); ctx->f32_0 = LLVMConstReal(ctx->f32, 0.0); ctx->f32_1 = LLVMConstReal(ctx->f32, 1.0); ctx->f64_0 = LLVMConstReal(ctx->f64, 0.0); ctx->f64_1 = LLVMConstReal(ctx->f64, 1.0); ctx->i1false = LLVMConstInt(ctx->i1, 0, false); ctx->i1true = LLVMConstInt(ctx->i1, 1, false); ctx->range_md_kind = LLVMGetMDKindIDInContext(ctx->context, "range", 5); ctx->invariant_load_md_kind = LLVMGetMDKindIDInContext(ctx->context, "invariant.load", 14); ctx->fpmath_md_kind = LLVMGetMDKindIDInContext(ctx->context, "fpmath", 6); args[0] = LLVMConstReal(ctx->f32, 2.5); ctx->fpmath_md_2p5_ulp = LLVMMDNodeInContext(ctx->context, args, 1); ctx->uniform_md_kind = LLVMGetMDKindIDInContext(ctx->context, "amdgpu.uniform", 14); ctx->empty_md = LLVMMDNodeInContext(ctx->context, NULL, 0); ctx->flow = calloc(1, sizeof(*ctx->flow)); } void ac_llvm_context_dispose(struct ac_llvm_context *ctx) { free(ctx->flow->stack); free(ctx->flow); ctx->flow = NULL; } int ac_get_llvm_num_components(LLVMValueRef value) { LLVMTypeRef type = LLVMTypeOf(value); unsigned num_components = LLVMGetTypeKind(type) == LLVMVectorTypeKind ? LLVMGetVectorSize(type) : 1; return num_components; } LLVMValueRef ac_llvm_extract_elem(struct ac_llvm_context *ac, LLVMValueRef value, int index) { if (LLVMGetTypeKind(LLVMTypeOf(value)) != LLVMVectorTypeKind) { assert(index == 0); return value; } return LLVMBuildExtractElement(ac->builder, value, LLVMConstInt(ac->i32, index, false), ""); } int ac_get_elem_bits(struct ac_llvm_context *ctx, LLVMTypeRef type) { if (LLVMGetTypeKind(type) == LLVMVectorTypeKind) type = LLVMGetElementType(type); if (LLVMGetTypeKind(type) == LLVMIntegerTypeKind) return LLVMGetIntTypeWidth(type); if (LLVMGetTypeKind(type) == LLVMPointerTypeKind) { if (LLVMGetPointerAddressSpace(type) == AC_ADDR_SPACE_LDS) return 32; } if (type == ctx->f16) return 16; if (type == ctx->f32) return 32; if (type == ctx->f64) return 64; unreachable("Unhandled type kind in get_elem_bits"); } unsigned ac_get_type_size(LLVMTypeRef type) { LLVMTypeKind kind = LLVMGetTypeKind(type); switch (kind) { case LLVMIntegerTypeKind: return LLVMGetIntTypeWidth(type) / 8; case LLVMHalfTypeKind: return 2; case LLVMFloatTypeKind: return 4; case LLVMDoubleTypeKind: return 8; case LLVMPointerTypeKind: if (LLVMGetPointerAddressSpace(type) == AC_ADDR_SPACE_CONST_32BIT) return 4; return 8; case LLVMVectorTypeKind: return LLVMGetVectorSize(type) * ac_get_type_size(LLVMGetElementType(type)); case LLVMArrayTypeKind: return LLVMGetArrayLength(type) * ac_get_type_size(LLVMGetElementType(type)); default: assert(0); return 0; } } static LLVMTypeRef to_integer_type_scalar(struct ac_llvm_context *ctx, LLVMTypeRef t) { if (t == ctx->i8) return ctx->i8; else if (t == ctx->f16 || t == ctx->i16) return ctx->i16; else if (t == ctx->f32 || t == ctx->i32) return ctx->i32; else if (t == ctx->f64 || t == ctx->i64) return ctx->i64; else unreachable("Unhandled integer size"); } LLVMTypeRef ac_to_integer_type(struct ac_llvm_context *ctx, LLVMTypeRef t) { if (LLVMGetTypeKind(t) == LLVMVectorTypeKind) { LLVMTypeRef elem_type = LLVMGetElementType(t); return LLVMVectorType(to_integer_type_scalar(ctx, elem_type), LLVMGetVectorSize(t)); } if (LLVMGetTypeKind(t) == LLVMPointerTypeKind) { switch (LLVMGetPointerAddressSpace(t)) { case AC_ADDR_SPACE_GLOBAL: return ctx->i64; case AC_ADDR_SPACE_CONST_32BIT: case AC_ADDR_SPACE_LDS: return ctx->i32; default: unreachable("unhandled address space"); } } return to_integer_type_scalar(ctx, t); } LLVMValueRef ac_to_integer(struct ac_llvm_context *ctx, LLVMValueRef v) { LLVMTypeRef type = LLVMTypeOf(v); if (LLVMGetTypeKind(type) == LLVMPointerTypeKind) { return LLVMBuildPtrToInt(ctx->builder, v, ac_to_integer_type(ctx, type), ""); } return LLVMBuildBitCast(ctx->builder, v, ac_to_integer_type(ctx, type), ""); } LLVMValueRef ac_to_integer_or_pointer(struct ac_llvm_context *ctx, LLVMValueRef v) { LLVMTypeRef type = LLVMTypeOf(v); if (LLVMGetTypeKind(type) == LLVMPointerTypeKind) return v; return ac_to_integer(ctx, v); } static LLVMTypeRef to_float_type_scalar(struct ac_llvm_context *ctx, LLVMTypeRef t) { if (t == ctx->i8) return ctx->i8; else if (t == ctx->i16 || t == ctx->f16) return ctx->f16; else if (t == ctx->i32 || t == ctx->f32) return ctx->f32; else if (t == ctx->i64 || t == ctx->f64) return ctx->f64; else unreachable("Unhandled float size"); } LLVMTypeRef ac_to_float_type(struct ac_llvm_context *ctx, LLVMTypeRef t) { if (LLVMGetTypeKind(t) == LLVMVectorTypeKind) { LLVMTypeRef elem_type = LLVMGetElementType(t); return LLVMVectorType(to_float_type_scalar(ctx, elem_type), LLVMGetVectorSize(t)); } return to_float_type_scalar(ctx, t); } LLVMValueRef ac_to_float(struct ac_llvm_context *ctx, LLVMValueRef v) { LLVMTypeRef type = LLVMTypeOf(v); return LLVMBuildBitCast(ctx->builder, v, ac_to_float_type(ctx, type), ""); } LLVMValueRef ac_build_intrinsic(struct ac_llvm_context *ctx, const char *name, LLVMTypeRef return_type, LLVMValueRef *params, unsigned param_count, unsigned attrib_mask) { LLVMValueRef function, call; bool set_callsite_attrs = !(attrib_mask & AC_FUNC_ATTR_LEGACY); function = LLVMGetNamedFunction(ctx->module, name); if (!function) { LLVMTypeRef param_types[32], function_type; unsigned i; assert(param_count <= 32); for (i = 0; i < param_count; ++i) { assert(params[i]); param_types[i] = LLVMTypeOf(params[i]); } function_type = LLVMFunctionType(return_type, param_types, param_count, 0); function = LLVMAddFunction(ctx->module, name, function_type); LLVMSetFunctionCallConv(function, LLVMCCallConv); LLVMSetLinkage(function, LLVMExternalLinkage); if (!set_callsite_attrs) ac_add_func_attributes(ctx->context, function, attrib_mask); } call = LLVMBuildCall(ctx->builder, function, params, param_count, ""); if (set_callsite_attrs) ac_add_func_attributes(ctx->context, call, attrib_mask); return call; } /** * Given the i32 or vNi32 \p type, generate the textual name (e.g. for use with * intrinsic names). */ void ac_build_type_name_for_intr(LLVMTypeRef type, char *buf, unsigned bufsize) { LLVMTypeRef elem_type = type; assert(bufsize >= 8); if (LLVMGetTypeKind(type) == LLVMVectorTypeKind) { int ret = snprintf(buf, bufsize, "v%u", LLVMGetVectorSize(type)); if (ret < 0) { char *type_name = LLVMPrintTypeToString(type); fprintf(stderr, "Error building type name for: %s\n", type_name); LLVMDisposeMessage(type_name); return; } elem_type = LLVMGetElementType(type); buf += ret; bufsize -= ret; } switch (LLVMGetTypeKind(elem_type)) { default: break; case LLVMIntegerTypeKind: snprintf(buf, bufsize, "i%d", LLVMGetIntTypeWidth(elem_type)); break; case LLVMHalfTypeKind: snprintf(buf, bufsize, "f16"); break; case LLVMFloatTypeKind: snprintf(buf, bufsize, "f32"); break; case LLVMDoubleTypeKind: snprintf(buf, bufsize, "f64"); break; } } /** * Helper function that builds an LLVM IR PHI node and immediately adds * incoming edges. */ LLVMValueRef ac_build_phi(struct ac_llvm_context *ctx, LLVMTypeRef type, unsigned count_incoming, LLVMValueRef *values, LLVMBasicBlockRef *blocks) { LLVMValueRef phi = LLVMBuildPhi(ctx->builder, type, ""); LLVMAddIncoming(phi, values, blocks, count_incoming); return phi; } void ac_build_s_barrier(struct ac_llvm_context *ctx) { ac_build_intrinsic(ctx, "llvm.amdgcn.s.barrier", ctx->voidt, NULL, 0, AC_FUNC_ATTR_CONVERGENT); } /* Prevent optimizations (at least of memory accesses) across the current * point in the program by emitting empty inline assembly that is marked as * having side effects. * * Optionally, a value can be passed through the inline assembly to prevent * LLVM from hoisting calls to ReadNone functions. */ void ac_build_optimization_barrier(struct ac_llvm_context *ctx, LLVMValueRef *pvgpr) { static int counter = 0; LLVMBuilderRef builder = ctx->builder; char code[16]; snprintf(code, sizeof(code), "; %d", p_atomic_inc_return(&counter)); if (!pvgpr) { LLVMTypeRef ftype = LLVMFunctionType(ctx->voidt, NULL, 0, false); LLVMValueRef inlineasm = LLVMConstInlineAsm(ftype, code, "", true, false); LLVMBuildCall(builder, inlineasm, NULL, 0, ""); } else { LLVMTypeRef ftype = LLVMFunctionType(ctx->i32, &ctx->i32, 1, false); LLVMValueRef inlineasm = LLVMConstInlineAsm(ftype, code, "=v,0", true, false); LLVMValueRef vgpr = *pvgpr; LLVMTypeRef vgpr_type = LLVMTypeOf(vgpr); unsigned vgpr_size = ac_get_type_size(vgpr_type); LLVMValueRef vgpr0; assert(vgpr_size % 4 == 0); vgpr = LLVMBuildBitCast(builder, vgpr, LLVMVectorType(ctx->i32, vgpr_size / 4), ""); vgpr0 = LLVMBuildExtractElement(builder, vgpr, ctx->i32_0, ""); vgpr0 = LLVMBuildCall(builder, inlineasm, &vgpr0, 1, ""); vgpr = LLVMBuildInsertElement(builder, vgpr, vgpr0, ctx->i32_0, ""); vgpr = LLVMBuildBitCast(builder, vgpr, vgpr_type, ""); *pvgpr = vgpr; } } LLVMValueRef ac_build_shader_clock(struct ac_llvm_context *ctx) { const char *intr = LLVM_VERSION_MAJOR >= 9 && ctx->chip_class >= GFX8 ? "llvm.amdgcn.s.memrealtime" : "llvm.readcyclecounter"; LLVMValueRef tmp = ac_build_intrinsic(ctx, intr, ctx->i64, NULL, 0, 0); return LLVMBuildBitCast(ctx->builder, tmp, ctx->v2i32, ""); } LLVMValueRef ac_build_ballot(struct ac_llvm_context *ctx, LLVMValueRef value) { const char *name; if (LLVM_VERSION_MAJOR >= 9) { if (ctx->wave_size == 64) name = "llvm.amdgcn.icmp.i64.i32"; else name = "llvm.amdgcn.icmp.i32.i32"; } else { name = "llvm.amdgcn.icmp.i32"; } LLVMValueRef args[3] = { value, ctx->i32_0, LLVMConstInt(ctx->i32, LLVMIntNE, 0) }; /* We currently have no other way to prevent LLVM from lifting the icmp * calls to a dominating basic block. */ ac_build_optimization_barrier(ctx, &args[0]); args[0] = ac_to_integer(ctx, args[0]); return ac_build_intrinsic(ctx, name, ctx->iN_wavemask, args, 3, AC_FUNC_ATTR_NOUNWIND | AC_FUNC_ATTR_READNONE | AC_FUNC_ATTR_CONVERGENT); } LLVMValueRef ac_get_i1_sgpr_mask(struct ac_llvm_context *ctx, LLVMValueRef value) { const char *name = LLVM_VERSION_MAJOR >= 9 ? "llvm.amdgcn.icmp.i64.i1" : "llvm.amdgcn.icmp.i1"; LLVMValueRef args[3] = { value, ctx->i1false, LLVMConstInt(ctx->i32, LLVMIntNE, 0), }; return ac_build_intrinsic(ctx, name, ctx->i64, args, 3, AC_FUNC_ATTR_NOUNWIND | AC_FUNC_ATTR_READNONE | AC_FUNC_ATTR_CONVERGENT); } LLVMValueRef ac_build_vote_all(struct ac_llvm_context *ctx, LLVMValueRef value) { LLVMValueRef active_set = ac_build_ballot(ctx, ctx->i32_1); LLVMValueRef vote_set = ac_build_ballot(ctx, value); return LLVMBuildICmp(ctx->builder, LLVMIntEQ, vote_set, active_set, ""); } LLVMValueRef ac_build_vote_any(struct ac_llvm_context *ctx, LLVMValueRef value) { LLVMValueRef vote_set = ac_build_ballot(ctx, value); return LLVMBuildICmp(ctx->builder, LLVMIntNE, vote_set, LLVMConstInt(ctx->iN_wavemask, 0, 0), ""); } LLVMValueRef ac_build_vote_eq(struct ac_llvm_context *ctx, LLVMValueRef value) { LLVMValueRef active_set = ac_build_ballot(ctx, ctx->i32_1); LLVMValueRef vote_set = ac_build_ballot(ctx, value); LLVMValueRef all = LLVMBuildICmp(ctx->builder, LLVMIntEQ, vote_set, active_set, ""); LLVMValueRef none = LLVMBuildICmp(ctx->builder, LLVMIntEQ, vote_set, LLVMConstInt(ctx->iN_wavemask, 0, 0), ""); return LLVMBuildOr(ctx->builder, all, none, ""); } LLVMValueRef ac_build_varying_gather_values(struct ac_llvm_context *ctx, LLVMValueRef *values, unsigned value_count, unsigned component) { LLVMValueRef vec = NULL; if (value_count == 1) { return values[component]; } else if (!value_count) unreachable("value_count is 0"); for (unsigned i = component; i < value_count + component; i++) { LLVMValueRef value = values[i]; if (i == component) vec = LLVMGetUndef( LLVMVectorType(LLVMTypeOf(value), value_count)); LLVMValueRef index = LLVMConstInt(ctx->i32, i - component, false); vec = LLVMBuildInsertElement(ctx->builder, vec, value, index, ""); } return vec; } LLVMValueRef ac_build_gather_values_extended(struct ac_llvm_context *ctx, LLVMValueRef *values, unsigned value_count, unsigned value_stride, bool load, bool always_vector) { LLVMBuilderRef builder = ctx->builder; LLVMValueRef vec = NULL; unsigned i; if (value_count == 1 && !always_vector) { if (load) return LLVMBuildLoad(builder, values[0], ""); return values[0]; } else if (!value_count) unreachable("value_count is 0"); for (i = 0; i < value_count; i++) { LLVMValueRef value = values[i * value_stride]; if (load) value = LLVMBuildLoad(builder, value, ""); if (!i) vec = LLVMGetUndef( LLVMVectorType(LLVMTypeOf(value), value_count)); LLVMValueRef index = LLVMConstInt(ctx->i32, i, false); vec = LLVMBuildInsertElement(builder, vec, value, index, ""); } return vec; } LLVMValueRef ac_build_gather_values(struct ac_llvm_context *ctx, LLVMValueRef *values, unsigned value_count) { return ac_build_gather_values_extended(ctx, values, value_count, 1, false, false); } /* Expand a scalar or vector to by filling the remaining * channels with undef. Extract at most src_channels components from the input. */ static LLVMValueRef ac_build_expand(struct ac_llvm_context *ctx, LLVMValueRef value, unsigned src_channels, unsigned dst_channels) { LLVMTypeRef elemtype; LLVMValueRef chan[dst_channels]; if (LLVMGetTypeKind(LLVMTypeOf(value)) == LLVMVectorTypeKind) { unsigned vec_size = LLVMGetVectorSize(LLVMTypeOf(value)); if (src_channels == dst_channels && vec_size == dst_channels) return value; src_channels = MIN2(src_channels, vec_size); for (unsigned i = 0; i < src_channels; i++) chan[i] = ac_llvm_extract_elem(ctx, value, i); elemtype = LLVMGetElementType(LLVMTypeOf(value)); } else { if (src_channels) { assert(src_channels == 1); chan[0] = value; } elemtype = LLVMTypeOf(value); } for (unsigned i = src_channels; i < dst_channels; i++) chan[i] = LLVMGetUndef(elemtype); return ac_build_gather_values(ctx, chan, dst_channels); } /* Extract components [start, start + channels) from a vector. */ LLVMValueRef ac_extract_components(struct ac_llvm_context *ctx, LLVMValueRef value, unsigned start, unsigned channels) { LLVMValueRef chan[channels]; for (unsigned i = 0; i < channels; i++) chan[i] = ac_llvm_extract_elem(ctx, value, i + start); return ac_build_gather_values(ctx, chan, channels); } /* Expand a scalar or vector to <4 x type> by filling the remaining channels * with undef. Extract at most num_channels components from the input. */ LLVMValueRef ac_build_expand_to_vec4(struct ac_llvm_context *ctx, LLVMValueRef value, unsigned num_channels) { return ac_build_expand(ctx, value, num_channels, 4); } LLVMValueRef ac_build_round(struct ac_llvm_context *ctx, LLVMValueRef value) { unsigned type_size = ac_get_type_size(LLVMTypeOf(value)); const char *name; if (type_size == 2) name = "llvm.rint.f16"; else if (type_size == 4) name = "llvm.rint.f32"; else name = "llvm.rint.f64"; return ac_build_intrinsic(ctx, name, LLVMTypeOf(value), &value, 1, AC_FUNC_ATTR_READNONE); } LLVMValueRef ac_build_fdiv(struct ac_llvm_context *ctx, LLVMValueRef num, LLVMValueRef den) { /* If we do (num / den), LLVM >= 7.0 does: * return num * v_rcp_f32(den * (fabs(den) > 0x1.0p+96f ? 0x1.0p-32f : 1.0f)); * * If we do (num * (1 / den)), LLVM does: * return num * v_rcp_f32(den); */ LLVMValueRef one = LLVMConstReal(LLVMTypeOf(num), 1.0); LLVMValueRef rcp = LLVMBuildFDiv(ctx->builder, one, den, ""); LLVMValueRef ret = LLVMBuildFMul(ctx->builder, num, rcp, ""); /* Use v_rcp_f32 instead of precise division. */ if (!LLVMIsConstant(ret)) LLVMSetMetadata(ret, ctx->fpmath_md_kind, ctx->fpmath_md_2p5_ulp); return ret; } /* See fast_idiv_by_const.h. */ /* Set: increment = util_fast_udiv_info::increment ? multiplier : 0; */ LLVMValueRef ac_build_fast_udiv(struct ac_llvm_context *ctx, LLVMValueRef num, LLVMValueRef multiplier, LLVMValueRef pre_shift, LLVMValueRef post_shift, LLVMValueRef increment) { LLVMBuilderRef builder = ctx->builder; num = LLVMBuildLShr(builder, num, pre_shift, ""); num = LLVMBuildMul(builder, LLVMBuildZExt(builder, num, ctx->i64, ""), LLVMBuildZExt(builder, multiplier, ctx->i64, ""), ""); num = LLVMBuildAdd(builder, num, LLVMBuildZExt(builder, increment, ctx->i64, ""), ""); num = LLVMBuildLShr(builder, num, LLVMConstInt(ctx->i64, 32, 0), ""); num = LLVMBuildTrunc(builder, num, ctx->i32, ""); return LLVMBuildLShr(builder, num, post_shift, ""); } /* See fast_idiv_by_const.h. */ /* If num != UINT_MAX, this more efficient version can be used. */ /* Set: increment = util_fast_udiv_info::increment; */ LLVMValueRef ac_build_fast_udiv_nuw(struct ac_llvm_context *ctx, LLVMValueRef num, LLVMValueRef multiplier, LLVMValueRef pre_shift, LLVMValueRef post_shift, LLVMValueRef increment) { LLVMBuilderRef builder = ctx->builder; num = LLVMBuildLShr(builder, num, pre_shift, ""); num = LLVMBuildNUWAdd(builder, num, increment, ""); num = LLVMBuildMul(builder, LLVMBuildZExt(builder, num, ctx->i64, ""), LLVMBuildZExt(builder, multiplier, ctx->i64, ""), ""); num = LLVMBuildLShr(builder, num, LLVMConstInt(ctx->i64, 32, 0), ""); num = LLVMBuildTrunc(builder, num, ctx->i32, ""); return LLVMBuildLShr(builder, num, post_shift, ""); } /* See fast_idiv_by_const.h. */ /* Both operands must fit in 31 bits and the divisor must not be 1. */ LLVMValueRef ac_build_fast_udiv_u31_d_not_one(struct ac_llvm_context *ctx, LLVMValueRef num, LLVMValueRef multiplier, LLVMValueRef post_shift) { LLVMBuilderRef builder = ctx->builder; num = LLVMBuildMul(builder, LLVMBuildZExt(builder, num, ctx->i64, ""), LLVMBuildZExt(builder, multiplier, ctx->i64, ""), ""); num = LLVMBuildLShr(builder, num, LLVMConstInt(ctx->i64, 32, 0), ""); num = LLVMBuildTrunc(builder, num, ctx->i32, ""); return LLVMBuildLShr(builder, num, post_shift, ""); } /* Coordinates for cube map selection. sc, tc, and ma are as in Table 8.27 * of the OpenGL 4.5 (Compatibility Profile) specification, except ma is * already multiplied by two. id is the cube face number. */ struct cube_selection_coords { LLVMValueRef stc[2]; LLVMValueRef ma; LLVMValueRef id; }; static void build_cube_intrinsic(struct ac_llvm_context *ctx, LLVMValueRef in[3], struct cube_selection_coords *out) { LLVMTypeRef f32 = ctx->f32; out->stc[1] = ac_build_intrinsic(ctx, "llvm.amdgcn.cubetc", f32, in, 3, AC_FUNC_ATTR_READNONE); out->stc[0] = ac_build_intrinsic(ctx, "llvm.amdgcn.cubesc", f32, in, 3, AC_FUNC_ATTR_READNONE); out->ma = ac_build_intrinsic(ctx, "llvm.amdgcn.cubema", f32, in, 3, AC_FUNC_ATTR_READNONE); out->id = ac_build_intrinsic(ctx, "llvm.amdgcn.cubeid", f32, in, 3, AC_FUNC_ATTR_READNONE); } /** * Build a manual selection sequence for cube face sc/tc coordinates and * major axis vector (multiplied by 2 for consistency) for the given * vec3 \p coords, for the face implied by \p selcoords. * * For the major axis, we always adjust the sign to be in the direction of * selcoords.ma; i.e., a positive out_ma means that coords is pointed towards * the selcoords major axis. */ static void build_cube_select(struct ac_llvm_context *ctx, const struct cube_selection_coords *selcoords, const LLVMValueRef *coords, LLVMValueRef *out_st, LLVMValueRef *out_ma) { LLVMBuilderRef builder = ctx->builder; LLVMTypeRef f32 = LLVMTypeOf(coords[0]); LLVMValueRef is_ma_positive; LLVMValueRef sgn_ma; LLVMValueRef is_ma_z, is_not_ma_z; LLVMValueRef is_ma_y; LLVMValueRef is_ma_x; LLVMValueRef sgn; LLVMValueRef tmp; is_ma_positive = LLVMBuildFCmp(builder, LLVMRealUGE, selcoords->ma, LLVMConstReal(f32, 0.0), ""); sgn_ma = LLVMBuildSelect(builder, is_ma_positive, LLVMConstReal(f32, 1.0), LLVMConstReal(f32, -1.0), ""); is_ma_z = LLVMBuildFCmp(builder, LLVMRealUGE, selcoords->id, LLVMConstReal(f32, 4.0), ""); is_not_ma_z = LLVMBuildNot(builder, is_ma_z, ""); is_ma_y = LLVMBuildAnd(builder, is_not_ma_z, LLVMBuildFCmp(builder, LLVMRealUGE, selcoords->id, LLVMConstReal(f32, 2.0), ""), ""); is_ma_x = LLVMBuildAnd(builder, is_not_ma_z, LLVMBuildNot(builder, is_ma_y, ""), ""); /* Select sc */ tmp = LLVMBuildSelect(builder, is_ma_x, coords[2], coords[0], ""); sgn = LLVMBuildSelect(builder, is_ma_y, LLVMConstReal(f32, 1.0), LLVMBuildSelect(builder, is_ma_z, sgn_ma, LLVMBuildFNeg(builder, sgn_ma, ""), ""), ""); out_st[0] = LLVMBuildFMul(builder, tmp, sgn, ""); /* Select tc */ tmp = LLVMBuildSelect(builder, is_ma_y, coords[2], coords[1], ""); sgn = LLVMBuildSelect(builder, is_ma_y, sgn_ma, LLVMConstReal(f32, -1.0), ""); out_st[1] = LLVMBuildFMul(builder, tmp, sgn, ""); /* Select ma */ tmp = LLVMBuildSelect(builder, is_ma_z, coords[2], LLVMBuildSelect(builder, is_ma_y, coords[1], coords[0], ""), ""); tmp = ac_build_intrinsic(ctx, "llvm.fabs.f32", ctx->f32, &tmp, 1, AC_FUNC_ATTR_READNONE); *out_ma = LLVMBuildFMul(builder, tmp, LLVMConstReal(f32, 2.0), ""); } void ac_prepare_cube_coords(struct ac_llvm_context *ctx, bool is_deriv, bool is_array, bool is_lod, LLVMValueRef *coords_arg, LLVMValueRef *derivs_arg) { LLVMBuilderRef builder = ctx->builder; struct cube_selection_coords selcoords; LLVMValueRef coords[3]; LLVMValueRef invma; if (is_array && !is_lod) { LLVMValueRef tmp = ac_build_round(ctx, coords_arg[3]); /* Section 8.9 (Texture Functions) of the GLSL 4.50 spec says: * * "For Array forms, the array layer used will be * * max(0, min(d−1, floor(layer+0.5))) * * where d is the depth of the texture array and layer * comes from the component indicated in the tables below. * Workaroudn for an issue where the layer is taken from a * helper invocation which happens to fall on a different * layer due to extrapolation." * * GFX8 and earlier attempt to implement this in hardware by * clamping the value of coords[2] = (8 * layer) + face. * Unfortunately, this means that the we end up with the wrong * face when clamping occurs. * * Clamp the layer earlier to work around the issue. */ if (ctx->chip_class <= GFX8) { LLVMValueRef ge0; ge0 = LLVMBuildFCmp(builder, LLVMRealOGE, tmp, ctx->f32_0, ""); tmp = LLVMBuildSelect(builder, ge0, tmp, ctx->f32_0, ""); } coords_arg[3] = tmp; } build_cube_intrinsic(ctx, coords_arg, &selcoords); invma = ac_build_intrinsic(ctx, "llvm.fabs.f32", ctx->f32, &selcoords.ma, 1, AC_FUNC_ATTR_READNONE); invma = ac_build_fdiv(ctx, LLVMConstReal(ctx->f32, 1.0), invma); for (int i = 0; i < 2; ++i) coords[i] = LLVMBuildFMul(builder, selcoords.stc[i], invma, ""); coords[2] = selcoords.id; if (is_deriv && derivs_arg) { LLVMValueRef derivs[4]; int axis; /* Convert cube derivatives to 2D derivatives. */ for (axis = 0; axis < 2; axis++) { LLVMValueRef deriv_st[2]; LLVMValueRef deriv_ma; /* Transform the derivative alongside the texture * coordinate. Mathematically, the correct formula is * as follows. Assume we're projecting onto the +Z face * and denote by dx/dh the derivative of the (original) * X texture coordinate with respect to horizontal * window coordinates. The projection onto the +Z face * plane is: * * f(x,z) = x/z * * Then df/dh = df/dx * dx/dh + df/dz * dz/dh * = 1/z * dx/dh - x/z * 1/z * dz/dh. * * This motivatives the implementation below. * * Whether this actually gives the expected results for * apps that might feed in derivatives obtained via * finite differences is anyone's guess. The OpenGL spec * seems awfully quiet about how textureGrad for cube * maps should be handled. */ build_cube_select(ctx, &selcoords, &derivs_arg[axis * 3], deriv_st, &deriv_ma); deriv_ma = LLVMBuildFMul(builder, deriv_ma, invma, ""); for (int i = 0; i < 2; ++i) derivs[axis * 2 + i] = LLVMBuildFSub(builder, LLVMBuildFMul(builder, deriv_st[i], invma, ""), LLVMBuildFMul(builder, deriv_ma, coords[i], ""), ""); } memcpy(derivs_arg, derivs, sizeof(derivs)); } /* Shift the texture coordinate. This must be applied after the * derivative calculation. */ for (int i = 0; i < 2; ++i) coords[i] = LLVMBuildFAdd(builder, coords[i], LLVMConstReal(ctx->f32, 1.5), ""); if (is_array) { /* for cube arrays coord.z = coord.w(array_index) * 8 + face */ /* coords_arg.w component - array_index for cube arrays */ coords[2] = ac_build_fmad(ctx, coords_arg[3], LLVMConstReal(ctx->f32, 8.0), coords[2]); } memcpy(coords_arg, coords, sizeof(coords)); } LLVMValueRef ac_build_fs_interp(struct ac_llvm_context *ctx, LLVMValueRef llvm_chan, LLVMValueRef attr_number, LLVMValueRef params, LLVMValueRef i, LLVMValueRef j) { LLVMValueRef args[5]; LLVMValueRef p1; args[0] = i; args[1] = llvm_chan; args[2] = attr_number; args[3] = params; p1 = ac_build_intrinsic(ctx, "llvm.amdgcn.interp.p1", ctx->f32, args, 4, AC_FUNC_ATTR_READNONE); args[0] = p1; args[1] = j; args[2] = llvm_chan; args[3] = attr_number; args[4] = params; return ac_build_intrinsic(ctx, "llvm.amdgcn.interp.p2", ctx->f32, args, 5, AC_FUNC_ATTR_READNONE); } LLVMValueRef ac_build_fs_interp_f16(struct ac_llvm_context *ctx, LLVMValueRef llvm_chan, LLVMValueRef attr_number, LLVMValueRef params, LLVMValueRef i, LLVMValueRef j) { LLVMValueRef args[6]; LLVMValueRef p1; args[0] = i; args[1] = llvm_chan; args[2] = attr_number; args[3] = ctx->i1false; args[4] = params; p1 = ac_build_intrinsic(ctx, "llvm.amdgcn.interp.p1.f16", ctx->f32, args, 5, AC_FUNC_ATTR_READNONE); args[0] = p1; args[1] = j; args[2] = llvm_chan; args[3] = attr_number; args[4] = ctx->i1false; args[5] = params; return ac_build_intrinsic(ctx, "llvm.amdgcn.interp.p2.f16", ctx->f16, args, 6, AC_FUNC_ATTR_READNONE); } LLVMValueRef ac_build_fs_interp_mov(struct ac_llvm_context *ctx, LLVMValueRef parameter, LLVMValueRef llvm_chan, LLVMValueRef attr_number, LLVMValueRef params) { LLVMValueRef args[4]; args[0] = parameter; args[1] = llvm_chan; args[2] = attr_number; args[3] = params; return ac_build_intrinsic(ctx, "llvm.amdgcn.interp.mov", ctx->f32, args, 4, AC_FUNC_ATTR_READNONE); } LLVMValueRef ac_build_gep_ptr(struct ac_llvm_context *ctx, LLVMValueRef base_ptr, LLVMValueRef index) { return LLVMBuildGEP(ctx->builder, base_ptr, &index, 1, ""); } LLVMValueRef ac_build_gep0(struct ac_llvm_context *ctx, LLVMValueRef base_ptr, LLVMValueRef index) { LLVMValueRef indices[2] = { ctx->i32_0, index, }; return LLVMBuildGEP(ctx->builder, base_ptr, indices, 2, ""); } LLVMValueRef ac_build_pointer_add(struct ac_llvm_context *ctx, LLVMValueRef ptr, LLVMValueRef index) { return LLVMBuildPointerCast(ctx->builder, LLVMBuildGEP(ctx->builder, ptr, &index, 1, ""), LLVMTypeOf(ptr), ""); } void ac_build_indexed_store(struct ac_llvm_context *ctx, LLVMValueRef base_ptr, LLVMValueRef index, LLVMValueRef value) { LLVMBuildStore(ctx->builder, value, ac_build_gep0(ctx, base_ptr, index)); } /** * Build an LLVM bytecode indexed load using LLVMBuildGEP + LLVMBuildLoad. * It's equivalent to doing a load from &base_ptr[index]. * * \param base_ptr Where the array starts. * \param index The element index into the array. * \param uniform Whether the base_ptr and index can be assumed to be * dynamically uniform (i.e. load to an SGPR) * \param invariant Whether the load is invariant (no other opcodes affect it) * \param no_unsigned_wraparound * For all possible re-associations and re-distributions of an expression * "base_ptr + index * elemsize" into "addr + offset" (excluding GEPs * without inbounds in base_ptr), this parameter is true if "addr + offset" * does not result in an unsigned integer wraparound. This is used for * optimal code generation of 32-bit pointer arithmetic. * * For example, a 32-bit immediate offset that causes a 32-bit unsigned * integer wraparound can't be an imm offset in s_load_dword, because * the instruction performs "addr + offset" in 64 bits. * * Expected usage for bindless textures by chaining GEPs: * // possible unsigned wraparound, don't use InBounds: * ptr1 = LLVMBuildGEP(base_ptr, index); * image = load(ptr1); // becomes "s_load ptr1, 0" * * ptr2 = LLVMBuildInBoundsGEP(ptr1, 32 / elemsize); * sampler = load(ptr2); // becomes "s_load ptr1, 32" thanks to InBounds */ static LLVMValueRef ac_build_load_custom(struct ac_llvm_context *ctx, LLVMValueRef base_ptr, LLVMValueRef index, bool uniform, bool invariant, bool no_unsigned_wraparound) { LLVMValueRef pointer, result; if (no_unsigned_wraparound && LLVMGetPointerAddressSpace(LLVMTypeOf(base_ptr)) == AC_ADDR_SPACE_CONST_32BIT) pointer = LLVMBuildInBoundsGEP(ctx->builder, base_ptr, &index, 1, ""); else pointer = LLVMBuildGEP(ctx->builder, base_ptr, &index, 1, ""); if (uniform) LLVMSetMetadata(pointer, ctx->uniform_md_kind, ctx->empty_md); result = LLVMBuildLoad(ctx->builder, pointer, ""); if (invariant) LLVMSetMetadata(result, ctx->invariant_load_md_kind, ctx->empty_md); return result; } LLVMValueRef ac_build_load(struct ac_llvm_context *ctx, LLVMValueRef base_ptr, LLVMValueRef index) { return ac_build_load_custom(ctx, base_ptr, index, false, false, false); } LLVMValueRef ac_build_load_invariant(struct ac_llvm_context *ctx, LLVMValueRef base_ptr, LLVMValueRef index) { return ac_build_load_custom(ctx, base_ptr, index, false, true, false); } /* This assumes that there is no unsigned integer wraparound during the address * computation, excluding all GEPs within base_ptr. */ LLVMValueRef ac_build_load_to_sgpr(struct ac_llvm_context *ctx, LLVMValueRef base_ptr, LLVMValueRef index) { return ac_build_load_custom(ctx, base_ptr, index, true, true, true); } /* See ac_build_load_custom() documentation. */ LLVMValueRef ac_build_load_to_sgpr_uint_wraparound(struct ac_llvm_context *ctx, LLVMValueRef base_ptr, LLVMValueRef index) { return ac_build_load_custom(ctx, base_ptr, index, true, true, false); } static unsigned get_load_cache_policy(struct ac_llvm_context *ctx, unsigned cache_policy) { return cache_policy | (ctx->chip_class >= GFX10 && cache_policy & ac_glc ? ac_dlc : 0); } static void ac_build_buffer_store_common(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef data, LLVMValueRef vindex, LLVMValueRef voffset, LLVMValueRef soffset, unsigned num_channels, LLVMTypeRef return_channel_type, unsigned cache_policy, bool use_format, bool structurized) { LLVMValueRef args[6]; int idx = 0; args[idx++] = data; args[idx++] = LLVMBuildBitCast(ctx->builder, rsrc, ctx->v4i32, ""); if (structurized) args[idx++] = vindex ? vindex : ctx->i32_0; args[idx++] = voffset ? voffset : ctx->i32_0; args[idx++] = soffset ? soffset : ctx->i32_0; args[idx++] = LLVMConstInt(ctx->i32, cache_policy, 0); unsigned func = !ac_has_vec3_support(ctx->chip_class, use_format) && num_channels == 3 ? 4 : num_channels; const char *indexing_kind = structurized ? "struct" : "raw"; char name[256], type_name[8]; LLVMTypeRef type = func > 1 ? LLVMVectorType(return_channel_type, func) : return_channel_type; ac_build_type_name_for_intr(type, type_name, sizeof(type_name)); if (use_format) { snprintf(name, sizeof(name), "llvm.amdgcn.%s.buffer.store.format.%s", indexing_kind, type_name); } else { snprintf(name, sizeof(name), "llvm.amdgcn.%s.buffer.store.%s", indexing_kind, type_name); } ac_build_intrinsic(ctx, name, ctx->voidt, args, idx, AC_FUNC_ATTR_INACCESSIBLE_MEM_ONLY); } void ac_build_buffer_store_format(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef data, LLVMValueRef vindex, LLVMValueRef voffset, unsigned num_channels, unsigned cache_policy) { ac_build_buffer_store_common(ctx, rsrc, data, vindex, voffset, NULL, num_channels, ctx->f32, cache_policy, true, true); } /* TBUFFER_STORE_FORMAT_{X,XY,XYZ,XYZW} <- the suffix is selected by num_channels=1..4. * The type of vdata must be one of i32 (num_channels=1), v2i32 (num_channels=2), * or v4i32 (num_channels=3,4). */ void ac_build_buffer_store_dword(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef vdata, unsigned num_channels, LLVMValueRef voffset, LLVMValueRef soffset, unsigned inst_offset, unsigned cache_policy, bool swizzle_enable_hint) { /* Split 3 channel stores, because only LLVM 9+ support 3-channel * intrinsics. */ if (num_channels == 3 && !ac_has_vec3_support(ctx->chip_class, false)) { LLVMValueRef v[3], v01; for (int i = 0; i < 3; i++) { v[i] = LLVMBuildExtractElement(ctx->builder, vdata, LLVMConstInt(ctx->i32, i, 0), ""); } v01 = ac_build_gather_values(ctx, v, 2); ac_build_buffer_store_dword(ctx, rsrc, v01, 2, voffset, soffset, inst_offset, cache_policy, swizzle_enable_hint); ac_build_buffer_store_dword(ctx, rsrc, v[2], 1, voffset, soffset, inst_offset + 8, cache_policy, swizzle_enable_hint); return; } /* SWIZZLE_ENABLE requires that soffset isn't folded into voffset * (voffset is swizzled, but soffset isn't swizzled). * llvm.amdgcn.buffer.store doesn't have a separate soffset parameter. */ if (!swizzle_enable_hint) { LLVMValueRef offset = soffset; if (inst_offset) offset = LLVMBuildAdd(ctx->builder, offset, LLVMConstInt(ctx->i32, inst_offset, 0), ""); ac_build_buffer_store_common(ctx, rsrc, ac_to_float(ctx, vdata), ctx->i32_0, voffset, offset, num_channels, ctx->f32, cache_policy, false, false); return; } static const unsigned dfmts[] = { V_008F0C_BUF_DATA_FORMAT_32, V_008F0C_BUF_DATA_FORMAT_32_32, V_008F0C_BUF_DATA_FORMAT_32_32_32, V_008F0C_BUF_DATA_FORMAT_32_32_32_32 }; unsigned dfmt = dfmts[num_channels - 1]; unsigned nfmt = V_008F0C_BUF_NUM_FORMAT_UINT; LLVMValueRef immoffset = LLVMConstInt(ctx->i32, inst_offset, 0); ac_build_raw_tbuffer_store(ctx, rsrc, vdata, voffset, soffset, immoffset, num_channels, dfmt, nfmt, cache_policy); } static LLVMValueRef ac_build_buffer_load_common(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef vindex, LLVMValueRef voffset, LLVMValueRef soffset, unsigned num_channels, LLVMTypeRef channel_type, unsigned cache_policy, bool can_speculate, bool use_format, bool structurized) { LLVMValueRef args[5]; int idx = 0; args[idx++] = LLVMBuildBitCast(ctx->builder, rsrc, ctx->v4i32, ""); if (structurized) args[idx++] = vindex ? vindex : ctx->i32_0; args[idx++] = voffset ? voffset : ctx->i32_0; args[idx++] = soffset ? soffset : ctx->i32_0; args[idx++] = LLVMConstInt(ctx->i32, get_load_cache_policy(ctx, cache_policy), 0); unsigned func = !ac_has_vec3_support(ctx->chip_class, use_format) && num_channels == 3 ? 4 : num_channels; const char *indexing_kind = structurized ? "struct" : "raw"; char name[256], type_name[8]; LLVMTypeRef type = func > 1 ? LLVMVectorType(channel_type, func) : channel_type; ac_build_type_name_for_intr(type, type_name, sizeof(type_name)); if (use_format) { snprintf(name, sizeof(name), "llvm.amdgcn.%s.buffer.load.format.%s", indexing_kind, type_name); } else { snprintf(name, sizeof(name), "llvm.amdgcn.%s.buffer.load.%s", indexing_kind, type_name); } return ac_build_intrinsic(ctx, name, type, args, idx, ac_get_load_intr_attribs(can_speculate)); } LLVMValueRef ac_build_buffer_load(struct ac_llvm_context *ctx, LLVMValueRef rsrc, int num_channels, LLVMValueRef vindex, LLVMValueRef voffset, LLVMValueRef soffset, unsigned inst_offset, unsigned cache_policy, bool can_speculate, bool allow_smem) { LLVMValueRef offset = LLVMConstInt(ctx->i32, inst_offset, 0); if (voffset) offset = LLVMBuildAdd(ctx->builder, offset, voffset, ""); if (soffset) offset = LLVMBuildAdd(ctx->builder, offset, soffset, ""); if (allow_smem && !(cache_policy & ac_slc) && (!(cache_policy & ac_glc) || ctx->chip_class >= GFX8)) { assert(vindex == NULL); LLVMValueRef result[8]; for (int i = 0; i < num_channels; i++) { if (i) { offset = LLVMBuildAdd(ctx->builder, offset, LLVMConstInt(ctx->i32, 4, 0), ""); } LLVMValueRef args[3] = { rsrc, offset, LLVMConstInt(ctx->i32, get_load_cache_policy(ctx, cache_policy), 0), }; result[i] = ac_build_intrinsic(ctx, "llvm.amdgcn.s.buffer.load.f32", ctx->f32, args, 3, AC_FUNC_ATTR_READNONE); } if (num_channels == 1) return result[0]; if (num_channels == 3 && !ac_has_vec3_support(ctx->chip_class, false)) result[num_channels++] = LLVMGetUndef(ctx->f32); return ac_build_gather_values(ctx, result, num_channels); } return ac_build_buffer_load_common(ctx, rsrc, vindex, offset, ctx->i32_0, num_channels, ctx->f32, cache_policy, can_speculate, false, false); } LLVMValueRef ac_build_buffer_load_format(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef vindex, LLVMValueRef voffset, unsigned num_channels, unsigned cache_policy, bool can_speculate) { return ac_build_buffer_load_common(ctx, rsrc, vindex, voffset, ctx->i32_0, num_channels, ctx->f32, cache_policy, can_speculate, true, true); } static LLVMValueRef ac_build_tbuffer_load(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef vindex, LLVMValueRef voffset, LLVMValueRef soffset, LLVMValueRef immoffset, unsigned num_channels, unsigned dfmt, unsigned nfmt, unsigned cache_policy, bool can_speculate, bool structurized) { voffset = LLVMBuildAdd(ctx->builder, voffset, immoffset, ""); LLVMValueRef args[6]; int idx = 0; args[idx++] = LLVMBuildBitCast(ctx->builder, rsrc, ctx->v4i32, ""); if (structurized) args[idx++] = vindex ? vindex : ctx->i32_0; args[idx++] = voffset ? voffset : ctx->i32_0; args[idx++] = soffset ? soffset : ctx->i32_0; args[idx++] = LLVMConstInt(ctx->i32, ac_get_tbuffer_format(ctx->chip_class, dfmt, nfmt), 0); args[idx++] = LLVMConstInt(ctx->i32, get_load_cache_policy(ctx, cache_policy), 0); unsigned func = !ac_has_vec3_support(ctx->chip_class, true) && num_channels == 3 ? 4 : num_channels; const char *indexing_kind = structurized ? "struct" : "raw"; char name[256], type_name[8]; LLVMTypeRef type = func > 1 ? LLVMVectorType(ctx->i32, func) : ctx->i32; ac_build_type_name_for_intr(type, type_name, sizeof(type_name)); snprintf(name, sizeof(name), "llvm.amdgcn.%s.tbuffer.load.%s", indexing_kind, type_name); return ac_build_intrinsic(ctx, name, type, args, idx, ac_get_load_intr_attribs(can_speculate)); } LLVMValueRef ac_build_struct_tbuffer_load(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef vindex, LLVMValueRef voffset, LLVMValueRef soffset, LLVMValueRef immoffset, unsigned num_channels, unsigned dfmt, unsigned nfmt, unsigned cache_policy, bool can_speculate) { return ac_build_tbuffer_load(ctx, rsrc, vindex, voffset, soffset, immoffset, num_channels, dfmt, nfmt, cache_policy, can_speculate, true); } LLVMValueRef ac_build_raw_tbuffer_load(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef voffset, LLVMValueRef soffset, LLVMValueRef immoffset, unsigned num_channels, unsigned dfmt, unsigned nfmt, unsigned cache_policy, bool can_speculate) { return ac_build_tbuffer_load(ctx, rsrc, NULL, voffset, soffset, immoffset, num_channels, dfmt, nfmt, cache_policy, can_speculate, false); } LLVMValueRef ac_build_tbuffer_load_short(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef voffset, LLVMValueRef soffset, LLVMValueRef immoffset, unsigned cache_policy) { LLVMValueRef res; if (LLVM_VERSION_MAJOR >= 9) { voffset = LLVMBuildAdd(ctx->builder, voffset, immoffset, ""); /* LLVM 9+ supports i8/i16 with struct/raw intrinsics. */ res = ac_build_buffer_load_common(ctx, rsrc, NULL, voffset, soffset, 1, ctx->i16, cache_policy, false, false, false); } else { unsigned dfmt = V_008F0C_BUF_DATA_FORMAT_16; unsigned nfmt = V_008F0C_BUF_NUM_FORMAT_UINT; res = ac_build_raw_tbuffer_load(ctx, rsrc, voffset, soffset, immoffset, 1, dfmt, nfmt, cache_policy, false); res = LLVMBuildTrunc(ctx->builder, res, ctx->i16, ""); } return res; } LLVMValueRef ac_build_tbuffer_load_byte(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef voffset, LLVMValueRef soffset, LLVMValueRef immoffset, unsigned cache_policy) { LLVMValueRef res; if (LLVM_VERSION_MAJOR >= 9) { voffset = LLVMBuildAdd(ctx->builder, voffset, immoffset, ""); /* LLVM 9+ supports i8/i16 with struct/raw intrinsics. */ res = ac_build_buffer_load_common(ctx, rsrc, NULL, voffset, soffset, 1, ctx->i8, cache_policy, false, false, false); } else { unsigned dfmt = V_008F0C_BUF_DATA_FORMAT_8; unsigned nfmt = V_008F0C_BUF_NUM_FORMAT_UINT; res = ac_build_raw_tbuffer_load(ctx, rsrc, voffset, soffset, immoffset, 1, dfmt, nfmt, cache_policy, false); res = LLVMBuildTrunc(ctx->builder, res, ctx->i8, ""); } return res; } /** * Convert an 11- or 10-bit unsigned floating point number to an f32. * * The input exponent is expected to be biased analogous to IEEE-754, i.e. by * 2^(exp_bits-1) - 1 (as defined in OpenGL and other graphics APIs). */ static LLVMValueRef ac_ufN_to_float(struct ac_llvm_context *ctx, LLVMValueRef src, unsigned exp_bits, unsigned mant_bits) { assert(LLVMTypeOf(src) == ctx->i32); LLVMValueRef tmp; LLVMValueRef mantissa; mantissa = LLVMBuildAnd(ctx->builder, src, LLVMConstInt(ctx->i32, (1 << mant_bits) - 1, false), ""); /* Converting normal numbers is just a shift + correcting the exponent bias */ unsigned normal_shift = 23 - mant_bits; unsigned bias_shift = 127 - ((1 << (exp_bits - 1)) - 1); LLVMValueRef shifted, normal; shifted = LLVMBuildShl(ctx->builder, src, LLVMConstInt(ctx->i32, normal_shift, false), ""); normal = LLVMBuildAdd(ctx->builder, shifted, LLVMConstInt(ctx->i32, bias_shift << 23, false), ""); /* Converting nan/inf numbers is the same, but with a different exponent update */ LLVMValueRef naninf; naninf = LLVMBuildOr(ctx->builder, normal, LLVMConstInt(ctx->i32, 0xff << 23, false), ""); /* Converting denormals is the complex case: determine the leading zeros of the * mantissa to obtain the correct shift for the mantissa and exponent correction. */ LLVMValueRef denormal; LLVMValueRef params[2] = { mantissa, ctx->i1true, /* result can be undef when arg is 0 */ }; LLVMValueRef ctlz = ac_build_intrinsic(ctx, "llvm.ctlz.i32", ctx->i32, params, 2, AC_FUNC_ATTR_READNONE); /* Shift such that the leading 1 ends up as the LSB of the exponent field. */ tmp = LLVMBuildSub(ctx->builder, ctlz, LLVMConstInt(ctx->i32, 8, false), ""); denormal = LLVMBuildShl(ctx->builder, mantissa, tmp, ""); unsigned denormal_exp = bias_shift + (32 - mant_bits) - 1; tmp = LLVMBuildSub(ctx->builder, LLVMConstInt(ctx->i32, denormal_exp, false), ctlz, ""); tmp = LLVMBuildShl(ctx->builder, tmp, LLVMConstInt(ctx->i32, 23, false), ""); denormal = LLVMBuildAdd(ctx->builder, denormal, tmp, ""); /* Select the final result. */ LLVMValueRef result; tmp = LLVMBuildICmp(ctx->builder, LLVMIntUGE, src, LLVMConstInt(ctx->i32, ((1 << exp_bits) - 1) << mant_bits, false), ""); result = LLVMBuildSelect(ctx->builder, tmp, naninf, normal, ""); tmp = LLVMBuildICmp(ctx->builder, LLVMIntUGE, src, LLVMConstInt(ctx->i32, 1 << mant_bits, false), ""); result = LLVMBuildSelect(ctx->builder, tmp, result, denormal, ""); tmp = LLVMBuildICmp(ctx->builder, LLVMIntNE, src, ctx->i32_0, ""); result = LLVMBuildSelect(ctx->builder, tmp, result, ctx->i32_0, ""); return ac_to_float(ctx, result); } /** * Generate a fully general open coded buffer format fetch with all required * fixups suitable for vertex fetch, using non-format buffer loads. * * Some combinations of argument values have special interpretations: * - size = 8 bytes, format = fixed indicates PIPE_FORMAT_R11G11B10_FLOAT * - size = 8 bytes, format != {float,fixed} indicates a 2_10_10_10 data format * * \param log_size log(size of channel in bytes) * \param num_channels number of channels (1 to 4) * \param format AC_FETCH_FORMAT_xxx value * \param reverse whether XYZ channels are reversed * \param known_aligned whether the source is known to be aligned to hardware's * effective element size for loading the given format * (note: this means dword alignment for 8_8_8_8, 16_16, etc.) * \param rsrc buffer resource descriptor * \return the resulting vector of floats or integers bitcast to <4 x i32> */ LLVMValueRef ac_build_opencoded_load_format(struct ac_llvm_context *ctx, unsigned log_size, unsigned num_channels, unsigned format, bool reverse, bool known_aligned, LLVMValueRef rsrc, LLVMValueRef vindex, LLVMValueRef voffset, LLVMValueRef soffset, unsigned cache_policy, bool can_speculate) { LLVMValueRef tmp; unsigned load_log_size = log_size; unsigned load_num_channels = num_channels; if (log_size == 3) { load_log_size = 2; if (format == AC_FETCH_FORMAT_FLOAT) { load_num_channels = 2 * num_channels; } else { load_num_channels = 1; /* 10_11_11 or 2_10_10_10 */ } } int log_recombine = 0; if (ctx->chip_class == GFX6 && !known_aligned) { /* Avoid alignment restrictions by loading one byte at a time. */ load_num_channels <<= load_log_size; log_recombine = load_log_size; load_log_size = 0; } else if (load_num_channels == 2 || load_num_channels == 4) { log_recombine = -util_logbase2(load_num_channels); load_num_channels = 1; load_log_size += -log_recombine; } assert(load_log_size >= 2 || LLVM_VERSION_MAJOR >= 9); LLVMValueRef loads[32]; /* up to 32 bytes */ for (unsigned i = 0; i < load_num_channels; ++i) { tmp = LLVMBuildAdd(ctx->builder, soffset, LLVMConstInt(ctx->i32, i << load_log_size, false), ""); LLVMTypeRef channel_type = load_log_size == 0 ? ctx->i8 : load_log_size == 1 ? ctx->i16 : ctx->i32; unsigned num_channels = 1 << (MAX2(load_log_size, 2) - 2); loads[i] = ac_build_buffer_load_common( ctx, rsrc, vindex, voffset, tmp, num_channels, channel_type, cache_policy, can_speculate, false, true); if (load_log_size >= 2) loads[i] = ac_to_integer(ctx, loads[i]); } if (log_recombine > 0) { /* Recombine bytes if necessary (GFX6 only) */ LLVMTypeRef dst_type = log_recombine == 2 ? ctx->i32 : ctx->i16; for (unsigned src = 0, dst = 0; src < load_num_channels; ++dst) { LLVMValueRef accum = NULL; for (unsigned i = 0; i < (1 << log_recombine); ++i, ++src) { tmp = LLVMBuildZExt(ctx->builder, loads[src], dst_type, ""); if (i == 0) { accum = tmp; } else { tmp = LLVMBuildShl(ctx->builder, tmp, LLVMConstInt(dst_type, 8 * i, false), ""); accum = LLVMBuildOr(ctx->builder, accum, tmp, ""); } } loads[dst] = accum; } } else if (log_recombine < 0) { /* Split vectors of dwords */ if (load_log_size > 2) { assert(load_num_channels == 1); LLVMValueRef loaded = loads[0]; unsigned log_split = load_log_size - 2; log_recombine += log_split; load_num_channels = 1 << log_split; load_log_size = 2; for (unsigned i = 0; i < load_num_channels; ++i) { tmp = LLVMConstInt(ctx->i32, i, false); loads[i] = LLVMBuildExtractElement(ctx->builder, loaded, tmp, ""); } } /* Further split dwords and shorts if required */ if (log_recombine < 0) { for (unsigned src = load_num_channels, dst = load_num_channels << -log_recombine; src > 0; --src) { unsigned dst_bits = 1 << (3 + load_log_size + log_recombine); LLVMTypeRef dst_type = LLVMIntTypeInContext(ctx->context, dst_bits); LLVMValueRef loaded = loads[src - 1]; LLVMTypeRef loaded_type = LLVMTypeOf(loaded); for (unsigned i = 1 << -log_recombine; i > 0; --i, --dst) { tmp = LLVMConstInt(loaded_type, dst_bits * (i - 1), false); tmp = LLVMBuildLShr(ctx->builder, loaded, tmp, ""); loads[dst - 1] = LLVMBuildTrunc(ctx->builder, tmp, dst_type, ""); } } } } if (log_size == 3) { if (format == AC_FETCH_FORMAT_FLOAT) { for (unsigned i = 0; i < num_channels; ++i) { tmp = ac_build_gather_values(ctx, &loads[2 * i], 2); loads[i] = LLVMBuildBitCast(ctx->builder, tmp, ctx->f64, ""); } } else if (format == AC_FETCH_FORMAT_FIXED) { /* 10_11_11_FLOAT */ LLVMValueRef data = loads[0]; LLVMValueRef i32_2047 = LLVMConstInt(ctx->i32, 2047, false); LLVMValueRef r = LLVMBuildAnd(ctx->builder, data, i32_2047, ""); tmp = LLVMBuildLShr(ctx->builder, data, LLVMConstInt(ctx->i32, 11, false), ""); LLVMValueRef g = LLVMBuildAnd(ctx->builder, tmp, i32_2047, ""); LLVMValueRef b = LLVMBuildLShr(ctx->builder, data, LLVMConstInt(ctx->i32, 22, false), ""); loads[0] = ac_to_integer(ctx, ac_ufN_to_float(ctx, r, 5, 6)); loads[1] = ac_to_integer(ctx, ac_ufN_to_float(ctx, g, 5, 6)); loads[2] = ac_to_integer(ctx, ac_ufN_to_float(ctx, b, 5, 5)); num_channels = 3; log_size = 2; format = AC_FETCH_FORMAT_FLOAT; } else { /* 2_10_10_10 data formats */ LLVMValueRef data = loads[0]; LLVMTypeRef i10 = LLVMIntTypeInContext(ctx->context, 10); LLVMTypeRef i2 = LLVMIntTypeInContext(ctx->context, 2); loads[0] = LLVMBuildTrunc(ctx->builder, data, i10, ""); tmp = LLVMBuildLShr(ctx->builder, data, LLVMConstInt(ctx->i32, 10, false), ""); loads[1] = LLVMBuildTrunc(ctx->builder, tmp, i10, ""); tmp = LLVMBuildLShr(ctx->builder, data, LLVMConstInt(ctx->i32, 20, false), ""); loads[2] = LLVMBuildTrunc(ctx->builder, tmp, i10, ""); tmp = LLVMBuildLShr(ctx->builder, data, LLVMConstInt(ctx->i32, 30, false), ""); loads[3] = LLVMBuildTrunc(ctx->builder, tmp, i2, ""); num_channels = 4; } } if (format == AC_FETCH_FORMAT_FLOAT) { if (log_size != 2) { for (unsigned chan = 0; chan < num_channels; ++chan) { tmp = ac_to_float(ctx, loads[chan]); if (log_size == 3) tmp = LLVMBuildFPTrunc(ctx->builder, tmp, ctx->f32, ""); else if (log_size == 1) tmp = LLVMBuildFPExt(ctx->builder, tmp, ctx->f32, ""); loads[chan] = ac_to_integer(ctx, tmp); } } } else if (format == AC_FETCH_FORMAT_UINT) { if (log_size != 2) { for (unsigned chan = 0; chan < num_channels; ++chan) loads[chan] = LLVMBuildZExt(ctx->builder, loads[chan], ctx->i32, ""); } } else if (format == AC_FETCH_FORMAT_SINT) { if (log_size != 2) { for (unsigned chan = 0; chan < num_channels; ++chan) loads[chan] = LLVMBuildSExt(ctx->builder, loads[chan], ctx->i32, ""); } } else { bool unsign = format == AC_FETCH_FORMAT_UNORM || format == AC_FETCH_FORMAT_USCALED || format == AC_FETCH_FORMAT_UINT; for (unsigned chan = 0; chan < num_channels; ++chan) { if (unsign) { tmp = LLVMBuildUIToFP(ctx->builder, loads[chan], ctx->f32, ""); } else { tmp = LLVMBuildSIToFP(ctx->builder, loads[chan], ctx->f32, ""); } LLVMValueRef scale = NULL; if (format == AC_FETCH_FORMAT_FIXED) { assert(log_size == 2); scale = LLVMConstReal(ctx->f32, 1.0 / 0x10000); } else if (format == AC_FETCH_FORMAT_UNORM) { unsigned bits = LLVMGetIntTypeWidth(LLVMTypeOf(loads[chan])); scale = LLVMConstReal(ctx->f32, 1.0 / (((uint64_t)1 << bits) - 1)); } else if (format == AC_FETCH_FORMAT_SNORM) { unsigned bits = LLVMGetIntTypeWidth(LLVMTypeOf(loads[chan])); scale = LLVMConstReal(ctx->f32, 1.0 / (((uint64_t)1 << (bits - 1)) - 1)); } if (scale) tmp = LLVMBuildFMul(ctx->builder, tmp, scale, ""); if (format == AC_FETCH_FORMAT_SNORM) { /* Clamp to [-1, 1] */ LLVMValueRef neg_one = LLVMConstReal(ctx->f32, -1.0); LLVMValueRef clamp = LLVMBuildFCmp(ctx->builder, LLVMRealULT, tmp, neg_one, ""); tmp = LLVMBuildSelect(ctx->builder, clamp, neg_one, tmp, ""); } loads[chan] = ac_to_integer(ctx, tmp); } } while (num_channels < 4) { if (format == AC_FETCH_FORMAT_UINT || format == AC_FETCH_FORMAT_SINT) { loads[num_channels] = num_channels == 3 ? ctx->i32_1 : ctx->i32_0; } else { loads[num_channels] = ac_to_integer(ctx, num_channels == 3 ? ctx->f32_1 : ctx->f32_0); } num_channels++; } if (reverse) { tmp = loads[0]; loads[0] = loads[2]; loads[2] = tmp; } return ac_build_gather_values(ctx, loads, 4); } static void ac_build_tbuffer_store(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef vdata, LLVMValueRef vindex, LLVMValueRef voffset, LLVMValueRef soffset, LLVMValueRef immoffset, unsigned num_channels, unsigned dfmt, unsigned nfmt, unsigned cache_policy, bool structurized) { voffset = LLVMBuildAdd(ctx->builder, voffset ? voffset : ctx->i32_0, immoffset, ""); LLVMValueRef args[7]; int idx = 0; args[idx++] = vdata; args[idx++] = LLVMBuildBitCast(ctx->builder, rsrc, ctx->v4i32, ""); if (structurized) args[idx++] = vindex ? vindex : ctx->i32_0; args[idx++] = voffset ? voffset : ctx->i32_0; args[idx++] = soffset ? soffset : ctx->i32_0; args[idx++] = LLVMConstInt(ctx->i32, ac_get_tbuffer_format(ctx->chip_class, dfmt, nfmt), 0); args[idx++] = LLVMConstInt(ctx->i32, cache_policy, 0); unsigned func = !ac_has_vec3_support(ctx->chip_class, true) && num_channels == 3 ? 4 : num_channels; const char *indexing_kind = structurized ? "struct" : "raw"; char name[256], type_name[8]; LLVMTypeRef type = func > 1 ? LLVMVectorType(ctx->i32, func) : ctx->i32; ac_build_type_name_for_intr(type, type_name, sizeof(type_name)); snprintf(name, sizeof(name), "llvm.amdgcn.%s.tbuffer.store.%s", indexing_kind, type_name); ac_build_intrinsic(ctx, name, ctx->voidt, args, idx, AC_FUNC_ATTR_INACCESSIBLE_MEM_ONLY); } void ac_build_struct_tbuffer_store(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef vdata, LLVMValueRef vindex, LLVMValueRef voffset, LLVMValueRef soffset, LLVMValueRef immoffset, unsigned num_channels, unsigned dfmt, unsigned nfmt, unsigned cache_policy) { ac_build_tbuffer_store(ctx, rsrc, vdata, vindex, voffset, soffset, immoffset, num_channels, dfmt, nfmt, cache_policy, true); } void ac_build_raw_tbuffer_store(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef vdata, LLVMValueRef voffset, LLVMValueRef soffset, LLVMValueRef immoffset, unsigned num_channels, unsigned dfmt, unsigned nfmt, unsigned cache_policy) { ac_build_tbuffer_store(ctx, rsrc, vdata, NULL, voffset, soffset, immoffset, num_channels, dfmt, nfmt, cache_policy, false); } void ac_build_tbuffer_store_short(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef vdata, LLVMValueRef voffset, LLVMValueRef soffset, unsigned cache_policy) { vdata = LLVMBuildBitCast(ctx->builder, vdata, ctx->i16, ""); if (LLVM_VERSION_MAJOR >= 9) { /* LLVM 9+ supports i8/i16 with struct/raw intrinsics. */ ac_build_buffer_store_common(ctx, rsrc, vdata, NULL, voffset, soffset, 1, ctx->i16, cache_policy, false, false); } else { unsigned dfmt = V_008F0C_BUF_DATA_FORMAT_16; unsigned nfmt = V_008F0C_BUF_NUM_FORMAT_UINT; vdata = LLVMBuildZExt(ctx->builder, vdata, ctx->i32, ""); ac_build_raw_tbuffer_store(ctx, rsrc, vdata, voffset, soffset, ctx->i32_0, 1, dfmt, nfmt, cache_policy); } } void ac_build_tbuffer_store_byte(struct ac_llvm_context *ctx, LLVMValueRef rsrc, LLVMValueRef vdata, LLVMValueRef voffset, LLVMValueRef soffset, unsigned cache_policy) { vdata = LLVMBuildBitCast(ctx->builder, vdata, ctx->i8, ""); if (LLVM_VERSION_MAJOR >= 9) { /* LLVM 9+ supports i8/i16 with struct/raw intrinsics. */ ac_build_buffer_store_common(ctx, rsrc, vdata, NULL, voffset, soffset, 1, ctx->i8, cache_policy, false, false); } else { unsigned dfmt = V_008F0C_BUF_DATA_FORMAT_8; unsigned nfmt = V_008F0C_BUF_NUM_FORMAT_UINT; vdata = LLVMBuildZExt(ctx->builder, vdata, ctx->i32, ""); ac_build_raw_tbuffer_store(ctx, rsrc, vdata, voffset, soffset, ctx->i32_0, 1, dfmt, nfmt, cache_policy); } } /** * Set range metadata on an instruction. This can only be used on load and * call instructions. If you know an instruction can only produce the values * 0, 1, 2, you would do set_range_metadata(value, 0, 3); * \p lo is the minimum value inclusive. * \p hi is the maximum value exclusive. */ static void set_range_metadata(struct ac_llvm_context *ctx, LLVMValueRef value, unsigned lo, unsigned hi) { LLVMValueRef range_md, md_args[2]; LLVMTypeRef type = LLVMTypeOf(value); LLVMContextRef context = LLVMGetTypeContext(type); md_args[0] = LLVMConstInt(type, lo, false); md_args[1] = LLVMConstInt(type, hi, false); range_md = LLVMMDNodeInContext(context, md_args, 2); LLVMSetMetadata(value, ctx->range_md_kind, range_md); } LLVMValueRef ac_get_thread_id(struct ac_llvm_context *ctx) { LLVMValueRef tid; LLVMValueRef tid_args[2]; tid_args[0] = LLVMConstInt(ctx->i32, 0xffffffff, false); tid_args[1] = ctx->i32_0; tid_args[1] = ac_build_intrinsic(ctx, "llvm.amdgcn.mbcnt.lo", ctx->i32, tid_args, 2, AC_FUNC_ATTR_READNONE); if (ctx->wave_size == 32) { tid = tid_args[1]; } else { tid = ac_build_intrinsic(ctx, "llvm.amdgcn.mbcnt.hi", ctx->i32, tid_args, 2, AC_FUNC_ATTR_READNONE); } set_range_metadata(ctx, tid, 0, ctx->wave_size); return tid; } /* * AMD GCN implements derivatives using the local data store (LDS) * All writes to the LDS happen in all executing threads at * the same time. TID is the Thread ID for the current * thread and is a value between 0 and 63, representing * the thread's position in the wavefront. * * For the pixel shader threads are grouped into quads of four pixels. * The TIDs of the pixels of a quad are: * * +------+------+ * |4n + 0|4n + 1| * +------+------+ * |4n + 2|4n + 3| * +------+------+ * * So, masking the TID with 0xfffffffc yields the TID of the top left pixel * of the quad, masking with 0xfffffffd yields the TID of the top pixel of * the current pixel's column, and masking with 0xfffffffe yields the TID * of the left pixel of the current pixel's row. * * Adding 1 yields the TID of the pixel to the right of the left pixel, and * adding 2 yields the TID of the pixel below the top pixel. */ LLVMValueRef ac_build_ddxy(struct ac_llvm_context *ctx, uint32_t mask, int idx, LLVMValueRef val) { unsigned tl_lanes[4], trbl_lanes[4]; char name[32], type[8]; LLVMValueRef tl, trbl; LLVMTypeRef result_type; LLVMValueRef result; result_type = ac_to_float_type(ctx, LLVMTypeOf(val)); if (result_type == ctx->f16) val = LLVMBuildZExt(ctx->builder, val, ctx->i32, ""); for (unsigned i = 0; i < 4; ++i) { tl_lanes[i] = i & mask; trbl_lanes[i] = (i & mask) + idx; } tl = ac_build_quad_swizzle(ctx, val, tl_lanes[0], tl_lanes[1], tl_lanes[2], tl_lanes[3]); trbl = ac_build_quad_swizzle(ctx, val, trbl_lanes[0], trbl_lanes[1], trbl_lanes[2], trbl_lanes[3]); if (result_type == ctx->f16) { tl = LLVMBuildTrunc(ctx->builder, tl, ctx->i16, ""); trbl = LLVMBuildTrunc(ctx->builder, trbl, ctx->i16, ""); } tl = LLVMBuildBitCast(ctx->builder, tl, result_type, ""); trbl = LLVMBuildBitCast(ctx->builder, trbl, result_type, ""); result = LLVMBuildFSub(ctx->builder, trbl, tl, ""); ac_build_type_name_for_intr(result_type, type, sizeof(type)); snprintf(name, sizeof(name), "llvm.amdgcn.wqm.%s", type); return ac_build_intrinsic(ctx, name, result_type, &result, 1, 0); } void ac_build_sendmsg(struct ac_llvm_context *ctx, uint32_t msg, LLVMValueRef wave_id) { LLVMValueRef args[2]; args[0] = LLVMConstInt(ctx->i32, msg, false); args[1] = wave_id; ac_build_intrinsic(ctx, "llvm.amdgcn.s.sendmsg", ctx->voidt, args, 2, 0); } LLVMValueRef ac_build_imsb(struct ac_llvm_context *ctx, LLVMValueRef arg, LLVMTypeRef dst_type) { LLVMValueRef msb = ac_build_intrinsic(ctx, "llvm.amdgcn.sffbh.i32", dst_type, &arg, 1, AC_FUNC_ATTR_READNONE); /* The HW returns the last bit index from MSB, but NIR/TGSI wants * the index from LSB. Invert it by doing "31 - msb". */ msb = LLVMBuildSub(ctx->builder, LLVMConstInt(ctx->i32, 31, false), msb, ""); LLVMValueRef all_ones = LLVMConstInt(ctx->i32, -1, true); LLVMValueRef cond = LLVMBuildOr(ctx->builder, LLVMBuildICmp(ctx->builder, LLVMIntEQ, arg, ctx->i32_0, ""), LLVMBuildICmp(ctx->builder, LLVMIntEQ, arg, all_ones, ""), ""); return LLVMBuildSelect(ctx->builder, cond, all_ones, msb, ""); } LLVMValueRef ac_build_umsb(struct ac_llvm_context *ctx, LLVMValueRef arg, LLVMTypeRef dst_type) { const char *intrin_name; LLVMTypeRef type; LLVMValueRef highest_bit; LLVMValueRef zero; unsigned bitsize; bitsize = ac_get_elem_bits(ctx, LLVMTypeOf(arg)); switch (bitsize) { case 64: intrin_name = "llvm.ctlz.i64"; type = ctx->i64; highest_bit = LLVMConstInt(ctx->i64, 63, false); zero = ctx->i64_0; break; case 32: intrin_name = "llvm.ctlz.i32"; type = ctx->i32; highest_bit = LLVMConstInt(ctx->i32, 31, false); zero = ctx->i32_0; break; case 16: intrin_name = "llvm.ctlz.i16"; type = ctx->i16; highest_bit = LLVMConstInt(ctx->i16, 15, false); zero = ctx->i16_0; break; case 8: intrin_name = "llvm.ctlz.i8"; type = ctx->i8; highest_bit = LLVMConstInt(ctx->i8, 7, false); zero = ctx->i8_0; break; default: unreachable(!"invalid bitsize"); break; } LLVMValueRef params[2] = { arg, ctx->i1true, }; LLVMValueRef msb = ac_build_intrinsic(ctx, intrin_name, type, params, 2, AC_FUNC_ATTR_READNONE); /* The HW returns the last bit index from MSB, but TGSI/NIR wants * the index from LSB. Invert it by doing "31 - msb". */ msb = LLVMBuildSub(ctx->builder, highest_bit, msb, ""); if (bitsize == 64) { msb = LLVMBuildTrunc(ctx->builder, msb, ctx->i32, ""); } else if (bitsize < 32) { msb = LLVMBuildSExt(ctx->builder, msb, ctx->i32, ""); } /* check for zero */ return LLVMBuildSelect(ctx->builder, LLVMBuildICmp(ctx->builder, LLVMIntEQ, arg, zero, ""), LLVMConstInt(ctx->i32, -1, true), msb, ""); } LLVMValueRef ac_build_fmin(struct ac_llvm_context *ctx, LLVMValueRef a, LLVMValueRef b) { char name[64]; snprintf(name, sizeof(name), "llvm.minnum.f%d", ac_get_elem_bits(ctx, LLVMTypeOf(a))); LLVMValueRef args[2] = {a, b}; return ac_build_intrinsic(ctx, name, LLVMTypeOf(a), args, 2, AC_FUNC_ATTR_READNONE); } LLVMValueRef ac_build_fmax(struct ac_llvm_context *ctx, LLVMValueRef a, LLVMValueRef b) { char name[64]; snprintf(name, sizeof(name), "llvm.maxnum.f%d", ac_get_elem_bits(ctx, LLVMTypeOf(a))); LLVMValueRef args[2] = {a, b}; return ac_build_intrinsic(ctx, name, LLVMTypeOf(a), args, 2, AC_FUNC_ATTR_READNONE); } LLVMValueRef ac_build_imin(struct ac_llvm_context *ctx, LLVMValueRef a, LLVMValueRef b) { LLVMValueRef cmp = LLVMBuildICmp(ctx->builder, LLVMIntSLE, a, b, ""); return LLVMBuildSelect(ctx->builder, cmp, a, b, ""); } LLVMValueRef ac_build_imax(struct ac_llvm_context *ctx, LLVMValueRef a, LLVMValueRef b) { LLVMValueRef cmp = LLVMBuildICmp(ctx->builder, LLVMIntSGT, a, b, ""); return LLVMBuildSelect(ctx->builder, cmp, a, b, ""); } LLVMValueRef ac_build_umin(struct ac_llvm_context *ctx, LLVMValueRef a, LLVMValueRef b) { LLVMValueRef cmp = LLVMBuildICmp(ctx->builder, LLVMIntULE, a, b, ""); return LLVMBuildSelect(ctx->builder, cmp, a, b, ""); } LLVMValueRef ac_build_umax(struct ac_llvm_context *ctx, LLVMValueRef a, LLVMValueRef b) { LLVMValueRef cmp = LLVMBuildICmp(ctx->builder, LLVMIntUGE, a, b, ""); return LLVMBuildSelect(ctx->builder, cmp, a, b, ""); } LLVMValueRef ac_build_clamp(struct ac_llvm_context *ctx, LLVMValueRef value) { LLVMTypeRef t = LLVMTypeOf(value); return ac_build_fmin(ctx, ac_build_fmax(ctx, value, LLVMConstReal(t, 0.0)), LLVMConstReal(t, 1.0)); } void ac_build_export(struct ac_llvm_context *ctx, struct ac_export_args *a) { LLVMValueRef args[9]; args[0] = LLVMConstInt(ctx->i32, a->target, 0); args[1] = LLVMConstInt(ctx->i32, a->enabled_channels, 0); if (a->compr) { LLVMTypeRef i16 = LLVMInt16TypeInContext(ctx->context); LLVMTypeRef v2i16 = LLVMVectorType(i16, 2); args[2] = LLVMBuildBitCast(ctx->builder, a->out[0], v2i16, ""); args[3] = LLVMBuildBitCast(ctx->builder, a->out[1], v2i16, ""); args[4] = LLVMConstInt(ctx->i1, a->done, 0); args[5] = LLVMConstInt(ctx->i1, a->valid_mask, 0); ac_build_intrinsic(ctx, "llvm.amdgcn.exp.compr.v2i16", ctx->voidt, args, 6, 0); } else { args[2] = a->out[0]; args[3] = a->out[1]; args[4] = a->out[2]; args[5] = a->out[3]; args[6] = LLVMConstInt(ctx->i1, a->done, 0); args[7] = LLVMConstInt(ctx->i1, a->valid_mask, 0); ac_build_intrinsic(ctx, "llvm.amdgcn.exp.f32", ctx->voidt, args, 8, 0); } } void ac_build_export_null(struct ac_llvm_context *ctx) { struct ac_export_args args; args.enabled_channels = 0x0; /* enabled channels */ args.valid_mask = 1; /* whether the EXEC mask is valid */ args.done = 1; /* DONE bit */ args.target = V_008DFC_SQ_EXP_NULL; args.compr = 0; /* COMPR flag (0 = 32-bit export) */ args.out[0] = LLVMGetUndef(ctx->f32); /* R */ args.out[1] = LLVMGetUndef(ctx->f32); /* G */ args.out[2] = LLVMGetUndef(ctx->f32); /* B */ args.out[3] = LLVMGetUndef(ctx->f32); /* A */ ac_build_export(ctx, &args); } static unsigned ac_num_coords(enum ac_image_dim dim) { switch (dim) { case ac_image_1d: return 1; case ac_image_2d: case ac_image_1darray: return 2; case ac_image_3d: case ac_image_cube: case ac_image_2darray: case ac_image_2dmsaa: return 3; case ac_image_2darraymsaa: return 4; default: unreachable("ac_num_coords: bad dim"); } } static unsigned ac_num_derivs(enum ac_image_dim dim) { switch (dim) { case ac_image_1d: case ac_image_1darray: return 2; case ac_image_2d: case ac_image_2darray: case ac_image_cube: return 4; case ac_image_3d: return 6; case ac_image_2dmsaa: case ac_image_2darraymsaa: default: unreachable("derivatives not supported"); } } static const char *get_atomic_name(enum ac_atomic_op op) { switch (op) { case ac_atomic_swap: return "swap"; case ac_atomic_add: return "add"; case ac_atomic_sub: return "sub"; case ac_atomic_smin: return "smin"; case ac_atomic_umin: return "umin"; case ac_atomic_smax: return "smax"; case ac_atomic_umax: return "umax"; case ac_atomic_and: return "and"; case ac_atomic_or: return "or"; case ac_atomic_xor: return "xor"; case ac_atomic_inc_wrap: return "inc"; case ac_atomic_dec_wrap: return "dec"; } unreachable("bad atomic op"); } LLVMValueRef ac_build_image_opcode(struct ac_llvm_context *ctx, struct ac_image_args *a) { const char *overload[3] = { "", "", "" }; unsigned num_overloads = 0; LLVMValueRef args[18]; unsigned num_args = 0; enum ac_image_dim dim = a->dim; assert(!a->lod || a->lod == ctx->i32_0 || a->lod == ctx->f32_0 || !a->level_zero); assert((a->opcode != ac_image_get_resinfo && a->opcode != ac_image_load_mip && a->opcode != ac_image_store_mip) || a->lod); assert(a->opcode == ac_image_sample || a->opcode == ac_image_gather4 || (!a->compare && !a->offset)); assert((a->opcode == ac_image_sample || a->opcode == ac_image_gather4 || a->opcode == ac_image_get_lod) || !a->bias); assert((a->bias ? 1 : 0) + (a->lod ? 1 : 0) + (a->level_zero ? 1 : 0) + (a->derivs[0] ? 1 : 0) <= 1); if (a->opcode == ac_image_get_lod) { switch (dim) { case ac_image_1darray: dim = ac_image_1d; break; case ac_image_2darray: case ac_image_cube: dim = ac_image_2d; break; default: break; } } bool sample = a->opcode == ac_image_sample || a->opcode == ac_image_gather4 || a->opcode == ac_image_get_lod; bool atomic = a->opcode == ac_image_atomic || a->opcode == ac_image_atomic_cmpswap; bool load = a->opcode == ac_image_sample || a->opcode == ac_image_gather4 || a->opcode == ac_image_load || a->opcode == ac_image_load_mip; LLVMTypeRef coord_type = sample ? ctx->f32 : ctx->i32; if (atomic || a->opcode == ac_image_store || a->opcode == ac_image_store_mip) { args[num_args++] = a->data[0]; if (a->opcode == ac_image_atomic_cmpswap) args[num_args++] = a->data[1]; } if (!atomic) args[num_args++] = LLVMConstInt(ctx->i32, a->dmask, false); if (a->offset) args[num_args++] = ac_to_integer(ctx, a->offset); if (a->bias) { args[num_args++] = ac_to_float(ctx, a->bias); overload[num_overloads++] = ".f32"; } if (a->compare) args[num_args++] = ac_to_float(ctx, a->compare); if (a->derivs[0]) { unsigned count = ac_num_derivs(dim); for (unsigned i = 0; i < count; ++i) args[num_args++] = ac_to_float(ctx, a->derivs[i]); overload[num_overloads++] = ".f32"; } unsigned num_coords = a->opcode != ac_image_get_resinfo ? ac_num_coords(dim) : 0; for (unsigned i = 0; i < num_coords; ++i) args[num_args++] = LLVMBuildBitCast(ctx->builder, a->coords[i], coord_type, ""); if (a->lod) args[num_args++] = LLVMBuildBitCast(ctx->builder, a->lod, coord_type, ""); overload[num_overloads++] = sample ? ".f32" : ".i32"; args[num_args++] = a->resource; if (sample) { args[num_args++] = a->sampler; args[num_args++] = LLVMConstInt(ctx->i1, a->unorm, false); } args[num_args++] = ctx->i32_0; /* texfailctrl */ args[num_args++] = LLVMConstInt(ctx->i32, load ? get_load_cache_policy(ctx, a->cache_policy) : a->cache_policy, false); const char *name; const char *atomic_subop = ""; switch (a->opcode) { case ac_image_sample: name = "sample"; break; case ac_image_gather4: name = "gather4"; break; case ac_image_load: name = "load"; break; case ac_image_load_mip: name = "load.mip"; break; case ac_image_store: name = "store"; break; case ac_image_store_mip: name = "store.mip"; break; case ac_image_atomic: name = "atomic."; atomic_subop = get_atomic_name(a->atomic); break; case ac_image_atomic_cmpswap: name = "atomic."; atomic_subop = "cmpswap"; break; case ac_image_get_lod: name = "getlod"; break; case ac_image_get_resinfo: name = "getresinfo"; break; default: unreachable("invalid image opcode"); } const char *dimname; switch (dim) { case ac_image_1d: dimname = "1d"; break; case ac_image_2d: dimname = "2d"; break; case ac_image_3d: dimname = "3d"; break; case ac_image_cube: dimname = "cube"; break; case ac_image_1darray: dimname = "1darray"; break; case ac_image_2darray: dimname = "2darray"; break; case ac_image_2dmsaa: dimname = "2dmsaa"; break; case ac_image_2darraymsaa: dimname = "2darraymsaa"; break; default: unreachable("invalid dim"); } bool lod_suffix = a->lod && (a->opcode == ac_image_sample || a->opcode == ac_image_gather4); char intr_name[96]; snprintf(intr_name, sizeof(intr_name), "llvm.amdgcn.image.%s%s" /* base name */ "%s%s%s" /* sample/gather modifiers */ ".%s.%s%s%s%s", /* dimension and type overloads */ name, atomic_subop, a->compare ? ".c" : "", a->bias ? ".b" : lod_suffix ? ".l" : a->derivs[0] ? ".d" : a->level_zero ? ".lz" : "", a->offset ? ".o" : "", dimname, atomic ? "i32" : "v4f32", overload[0], overload[1], overload[2]); LLVMTypeRef retty; if (atomic) retty = ctx->i32; else if (a->opcode == ac_image_store || a->opcode == ac_image_store_mip) retty = ctx->voidt; else retty = ctx->v4f32; LLVMValueRef result = ac_build_intrinsic(ctx, intr_name, retty, args, num_args, a->attributes); if (!sample && retty == ctx->v4f32) { result = LLVMBuildBitCast(ctx->builder, result, ctx->v4i32, ""); } return result; } LLVMValueRef ac_build_image_get_sample_count(struct ac_llvm_context *ctx, LLVMValueRef rsrc) { LLVMValueRef samples; /* Read the samples from the descriptor directly. * Hardware doesn't have any instruction for this. */ samples = LLVMBuildExtractElement(ctx->builder, rsrc, LLVMConstInt(ctx->i32, 3, 0), ""); samples = LLVMBuildLShr(ctx->builder, samples, LLVMConstInt(ctx->i32, 16, 0), ""); samples = LLVMBuildAnd(ctx->builder, samples, LLVMConstInt(ctx->i32, 0xf, 0), ""); samples = LLVMBuildShl(ctx->builder, ctx->i32_1, samples, ""); return samples; } LLVMValueRef ac_build_cvt_pkrtz_f16(struct ac_llvm_context *ctx, LLVMValueRef args[2]) { LLVMTypeRef v2f16 = LLVMVectorType(LLVMHalfTypeInContext(ctx->context), 2); return ac_build_intrinsic(ctx, "llvm.amdgcn.cvt.pkrtz", v2f16, args, 2, AC_FUNC_ATTR_READNONE); } LLVMValueRef ac_build_cvt_pknorm_i16(struct ac_llvm_context *ctx, LLVMValueRef args[2]) { LLVMValueRef res = ac_build_intrinsic(ctx, "llvm.amdgcn.cvt.pknorm.i16", ctx->v2i16, args, 2, AC_FUNC_ATTR_READNONE); return LLVMBuildBitCast(ctx->builder, res, ctx->i32, ""); } LLVMValueRef ac_build_cvt_pknorm_u16(struct ac_llvm_context *ctx, LLVMValueRef args[2]) { LLVMValueRef res = ac_build_intrinsic(ctx, "llvm.amdgcn.cvt.pknorm.u16", ctx->v2i16, args, 2, AC_FUNC_ATTR_READNONE); return LLVMBuildBitCast(ctx->builder, res, ctx->i32, ""); } /* The 8-bit and 10-bit clamping is for HW workarounds. */ LLVMValueRef ac_build_cvt_pk_i16(struct ac_llvm_context *ctx, LLVMValueRef args[2], unsigned bits, bool hi) { assert(bits == 8 || bits == 10 || bits == 16); LLVMValueRef max_rgb = LLVMConstInt(ctx->i32, bits == 8 ? 127 : bits == 10 ? 511 : 32767, 0); LLVMValueRef min_rgb = LLVMConstInt(ctx->i32, bits == 8 ? -128 : bits == 10 ? -512 : -32768, 0); LLVMValueRef max_alpha = bits != 10 ? max_rgb : ctx->i32_1; LLVMValueRef min_alpha = bits != 10 ? min_rgb : LLVMConstInt(ctx->i32, -2, 0); /* Clamp. */ if (bits != 16) { for (int i = 0; i < 2; i++) { bool alpha = hi && i == 1; args[i] = ac_build_imin(ctx, args[i], alpha ? max_alpha : max_rgb); args[i] = ac_build_imax(ctx, args[i], alpha ? min_alpha : min_rgb); } } LLVMValueRef res = ac_build_intrinsic(ctx, "llvm.amdgcn.cvt.pk.i16", ctx->v2i16, args, 2, AC_FUNC_ATTR_READNONE); return LLVMBuildBitCast(ctx->builder, res, ctx->i32, ""); } /* The 8-bit and 10-bit clamping is for HW workarounds. */ LLVMValueRef ac_build_cvt_pk_u16(struct ac_llvm_context *ctx, LLVMValueRef args[2], unsigned bits, bool hi) { assert(bits == 8 || bits == 10 || bits == 16); LLVMValueRef max_rgb = LLVMConstInt(ctx->i32, bits == 8 ? 255 : bits == 10 ? 1023 : 65535, 0); LLVMValueRef max_alpha = bits != 10 ? max_rgb : LLVMConstInt(ctx->i32, 3, 0); /* Clamp. */ if (bits != 16) { for (int i = 0; i < 2; i++) { bool alpha = hi && i == 1; args[i] = ac_build_umin(ctx, args[i], alpha ? max_alpha : max_rgb); } } LLVMValueRef res = ac_build_intrinsic(ctx, "llvm.amdgcn.cvt.pk.u16", ctx->v2i16, args, 2, AC_FUNC_ATTR_READNONE); return LLVMBuildBitCast(ctx->builder, res, ctx->i32, ""); } LLVMValueRef ac_build_wqm_vote(struct ac_llvm_context *ctx, LLVMValueRef i1) { return ac_build_intrinsic(ctx, "llvm.amdgcn.wqm.vote", ctx->i1, &i1, 1, AC_FUNC_ATTR_READNONE); } void ac_build_kill_if_false(struct ac_llvm_context *ctx, LLVMValueRef i1) { ac_build_intrinsic(ctx, "llvm.amdgcn.kill", ctx->voidt, &i1, 1, 0); } LLVMValueRef ac_build_bfe(struct ac_llvm_context *ctx, LLVMValueRef input, LLVMValueRef offset, LLVMValueRef width, bool is_signed) { LLVMValueRef args[] = { input, offset, width, }; return ac_build_intrinsic(ctx, is_signed ? "llvm.amdgcn.sbfe.i32" : "llvm.amdgcn.ubfe.i32", ctx->i32, args, 3, AC_FUNC_ATTR_READNONE); } LLVMValueRef ac_build_imad(struct ac_llvm_context *ctx, LLVMValueRef s0, LLVMValueRef s1, LLVMValueRef s2) { return LLVMBuildAdd(ctx->builder, LLVMBuildMul(ctx->builder, s0, s1, ""), s2, ""); } LLVMValueRef ac_build_fmad(struct ac_llvm_context *ctx, LLVMValueRef s0, LLVMValueRef s1, LLVMValueRef s2) { /* FMA is better on GFX10, because it has FMA units instead of MUL-ADD units. */ if (ctx->chip_class >= GFX10) { return ac_build_intrinsic(ctx, "llvm.fma.f32", ctx->f32, (LLVMValueRef []) {s0, s1, s2}, 3, AC_FUNC_ATTR_READNONE); } return LLVMBuildFAdd(ctx->builder, LLVMBuildFMul(ctx->builder, s0, s1, ""), s2, ""); } void ac_build_waitcnt(struct ac_llvm_context *ctx, unsigned wait_flags) { if (!wait_flags) return; unsigned lgkmcnt = 63; unsigned vmcnt = ctx->chip_class >= GFX9 ? 63 : 15; unsigned vscnt = 63; if (wait_flags & AC_WAIT_LGKM) lgkmcnt = 0; if (wait_flags & AC_WAIT_VLOAD) vmcnt = 0; if (wait_flags & AC_WAIT_VSTORE) { if (ctx->chip_class >= GFX10) vscnt = 0; else vmcnt = 0; } /* There is no intrinsic for vscnt(0), so use a fence. */ if ((wait_flags & AC_WAIT_LGKM && wait_flags & AC_WAIT_VLOAD && wait_flags & AC_WAIT_VSTORE) || vscnt == 0) { LLVMBuildFence(ctx->builder, LLVMAtomicOrderingRelease, false, ""); return; } unsigned simm16 = (lgkmcnt << 8) | (7 << 4) | /* expcnt */ (vmcnt & 0xf) | ((vmcnt >> 4) << 14); LLVMValueRef args[1] = { LLVMConstInt(ctx->i32, simm16, false), }; ac_build_intrinsic(ctx, "llvm.amdgcn.s.waitcnt", ctx->voidt, args, 1, 0); } LLVMValueRef ac_build_fmed3(struct ac_llvm_context *ctx, LLVMValueRef src0, LLVMValueRef src1, LLVMValueRef src2, unsigned bitsize) { LLVMTypeRef type; char *intr; if (bitsize == 16) { intr = "llvm.amdgcn.fmed3.f16"; type = ctx->f16; } else if (bitsize == 32) { intr = "llvm.amdgcn.fmed3.f32"; type = ctx->f32; } else { intr = "llvm.amdgcn.fmed3.f64"; type = ctx->f64; } LLVMValueRef params[] = { src0, src1, src2, }; return ac_build_intrinsic(ctx, intr, type, params, 3, AC_FUNC_ATTR_READNONE); } LLVMValueRef ac_build_fract(struct ac_llvm_context *ctx, LLVMValueRef src0, unsigned bitsize) { LLVMTypeRef type; char *intr; if (bitsize == 16) { intr = "llvm.amdgcn.fract.f16"; type = ctx->f16; } else if (bitsize == 32) { intr = "llvm.amdgcn.fract.f32"; type = ctx->f32; } else { intr = "llvm.amdgcn.fract.f64"; type = ctx->f64; } LLVMValueRef params[] = { src0, }; return ac_build_intrinsic(ctx, intr, type, params, 1, AC_FUNC_ATTR_READNONE); } LLVMValueRef ac_build_isign(struct ac_llvm_context *ctx, LLVMValueRef src0, unsigned bitsize) { LLVMTypeRef type = LLVMIntTypeInContext(ctx->context, bitsize); LLVMValueRef zero = LLVMConstInt(type, 0, false); LLVMValueRef one = LLVMConstInt(type, 1, false); LLVMValueRef cmp, val; cmp = LLVMBuildICmp(ctx->builder, LLVMIntSGT, src0, zero, ""); val = LLVMBuildSelect(ctx->builder, cmp, one, src0, ""); cmp = LLVMBuildICmp(ctx->builder, LLVMIntSGE, val, zero, ""); val = LLVMBuildSelect(ctx->builder, cmp, val, LLVMConstInt(type, -1, true), ""); return val; } LLVMValueRef ac_build_fsign(struct ac_llvm_context *ctx, LLVMValueRef src0, unsigned bitsize) { LLVMValueRef cmp, val, zero, one; LLVMTypeRef type; if (bitsize == 16) { type = ctx->f16; zero = ctx->f16_0; one = ctx->f16_1; } else if (bitsize == 32) { type = ctx->f32; zero = ctx->f32_0; one = ctx->f32_1; } else { type = ctx->f64; zero = ctx->f64_0; one = ctx->f64_1; } cmp = LLVMBuildFCmp(ctx->builder, LLVMRealOGT, src0, zero, ""); val = LLVMBuildSelect(ctx->builder, cmp, one, src0, ""); cmp = LLVMBuildFCmp(ctx->builder, LLVMRealOGE, val, zero, ""); val = LLVMBuildSelect(ctx->builder, cmp, val, LLVMConstReal(type, -1.0), ""); return val; } LLVMValueRef ac_build_bit_count(struct ac_llvm_context *ctx, LLVMValueRef src0) { LLVMValueRef result; unsigned bitsize; bitsize = ac_get_elem_bits(ctx, LLVMTypeOf(src0)); switch (bitsize) { case 64: result = ac_build_intrinsic(ctx, "llvm.ctpop.i64", ctx->i64, (LLVMValueRef []) { src0 }, 1, AC_FUNC_ATTR_READNONE); result = LLVMBuildTrunc(ctx->builder, result, ctx->i32, ""); break; case 32: result = ac_build_intrinsic(ctx, "llvm.ctpop.i32", ctx->i32, (LLVMValueRef []) { src0 }, 1, AC_FUNC_ATTR_READNONE); break; case 16: result = ac_build_intrinsic(ctx, "llvm.ctpop.i16", ctx->i16, (LLVMValueRef []) { src0 }, 1, AC_FUNC_ATTR_READNONE); result = LLVMBuildZExt(ctx->builder, result, ctx->i32, ""); break; case 8: result = ac_build_intrinsic(ctx, "llvm.ctpop.i8", ctx->i8, (LLVMValueRef []) { src0 }, 1, AC_FUNC_ATTR_READNONE); result = LLVMBuildZExt(ctx->builder, result, ctx->i32, ""); break; default: unreachable(!"invalid bitsize"); break; } return result; } LLVMValueRef ac_build_bitfield_reverse(struct ac_llvm_context *ctx, LLVMValueRef src0) { LLVMValueRef result; unsigned bitsize; bitsize = ac_get_elem_bits(ctx, LLVMTypeOf(src0)); switch (bitsize) { case 64: result = ac_build_intrinsic(ctx, "llvm.bitreverse.i64", ctx->i64, (LLVMValueRef []) { src0 }, 1, AC_FUNC_ATTR_READNONE); result = LLVMBuildTrunc(ctx->builder, result, ctx->i32, ""); break; case 32: result = ac_build_intrinsic(ctx, "llvm.bitreverse.i32", ctx->i32, (LLVMValueRef []) { src0 }, 1, AC_FUNC_ATTR_READNONE); break; case 16: result = ac_build_intrinsic(ctx, "llvm.bitreverse.i16", ctx->i16, (LLVMValueRef []) { src0 }, 1, AC_FUNC_ATTR_READNONE); result = LLVMBuildZExt(ctx->builder, result, ctx->i32, ""); break; case 8: result = ac_build_intrinsic(ctx, "llvm.bitreverse.i8", ctx->i8, (LLVMValueRef []) { src0 }, 1, AC_FUNC_ATTR_READNONE); result = LLVMBuildZExt(ctx->builder, result, ctx->i32, ""); break; default: unreachable(!"invalid bitsize"); break; } return result; } #define AC_EXP_TARGET 0 #define AC_EXP_ENABLED_CHANNELS 1 #define AC_EXP_OUT0 2 enum ac_ir_type { AC_IR_UNDEF, AC_IR_CONST, AC_IR_VALUE, }; struct ac_vs_exp_chan { LLVMValueRef value; float const_float; enum ac_ir_type type; }; struct ac_vs_exp_inst { unsigned offset; LLVMValueRef inst; struct ac_vs_exp_chan chan[4]; }; struct ac_vs_exports { unsigned num; struct ac_vs_exp_inst exp[VARYING_SLOT_MAX]; }; /* Return true if the PARAM export has been eliminated. */ static bool ac_eliminate_const_output(uint8_t *vs_output_param_offset, uint32_t num_outputs, struct ac_vs_exp_inst *exp) { unsigned i, default_val; /* SPI_PS_INPUT_CNTL_i.DEFAULT_VAL */ bool is_zero[4] = {}, is_one[4] = {}; for (i = 0; i < 4; i++) { /* It's a constant expression. Undef outputs are eliminated too. */ if (exp->chan[i].type == AC_IR_UNDEF) { is_zero[i] = true; is_one[i] = true; } else if (exp->chan[i].type == AC_IR_CONST) { if (exp->chan[i].const_float == 0) is_zero[i] = true; else if (exp->chan[i].const_float == 1) is_one[i] = true; else return false; /* other constant */ } else return false; } /* Only certain combinations of 0 and 1 can be eliminated. */ if (is_zero[0] && is_zero[1] && is_zero[2]) default_val = is_zero[3] ? 0 : 1; else if (is_one[0] && is_one[1] && is_one[2]) default_val = is_zero[3] ? 2 : 3; else return false; /* The PARAM export can be represented as DEFAULT_VAL. Kill it. */ LLVMInstructionEraseFromParent(exp->inst); /* Change OFFSET to DEFAULT_VAL. */ for (i = 0; i < num_outputs; i++) { if (vs_output_param_offset[i] == exp->offset) { vs_output_param_offset[i] = AC_EXP_PARAM_DEFAULT_VAL_0000 + default_val; break; } } return true; } static bool ac_eliminate_duplicated_output(struct ac_llvm_context *ctx, uint8_t *vs_output_param_offset, uint32_t num_outputs, struct ac_vs_exports *processed, struct ac_vs_exp_inst *exp) { unsigned p, copy_back_channels = 0; /* See if the output is already in the list of processed outputs. * The LLVMValueRef comparison relies on SSA. */ for (p = 0; p < processed->num; p++) { bool different = false; for (unsigned j = 0; j < 4; j++) { struct ac_vs_exp_chan *c1 = &processed->exp[p].chan[j]; struct ac_vs_exp_chan *c2 = &exp->chan[j]; /* Treat undef as a match. */ if (c2->type == AC_IR_UNDEF) continue; /* If c1 is undef but c2 isn't, we can copy c2 to c1 * and consider the instruction duplicated. */ if (c1->type == AC_IR_UNDEF) { copy_back_channels |= 1 << j; continue; } /* Test whether the channels are not equal. */ if (c1->type != c2->type || (c1->type == AC_IR_CONST && c1->const_float != c2->const_float) || (c1->type == AC_IR_VALUE && c1->value != c2->value)) { different = true; break; } } if (!different) break; copy_back_channels = 0; } if (p == processed->num) return false; /* If a match was found, but the matching export has undef where the new * one has a normal value, copy the normal value to the undef channel. */ struct ac_vs_exp_inst *match = &processed->exp[p]; /* Get current enabled channels mask. */ LLVMValueRef arg = LLVMGetOperand(match->inst, AC_EXP_ENABLED_CHANNELS); unsigned enabled_channels = LLVMConstIntGetZExtValue(arg); while (copy_back_channels) { unsigned chan = u_bit_scan(©_back_channels); assert(match->chan[chan].type == AC_IR_UNDEF); LLVMSetOperand(match->inst, AC_EXP_OUT0 + chan, exp->chan[chan].value); match->chan[chan] = exp->chan[chan]; /* Update number of enabled channels because the original mask * is not always 0xf. */ enabled_channels |= (1 << chan); LLVMSetOperand(match->inst, AC_EXP_ENABLED_CHANNELS, LLVMConstInt(ctx->i32, enabled_channels, 0)); } /* The PARAM export is duplicated. Kill it. */ LLVMInstructionEraseFromParent(exp->inst); /* Change OFFSET to the matching export. */ for (unsigned i = 0; i < num_outputs; i++) { if (vs_output_param_offset[i] == exp->offset) { vs_output_param_offset[i] = match->offset; break; } } return true; } void ac_optimize_vs_outputs(struct ac_llvm_context *ctx, LLVMValueRef main_fn, uint8_t *vs_output_param_offset, uint32_t num_outputs, uint8_t *num_param_exports) { LLVMBasicBlockRef bb; bool removed_any = false; struct ac_vs_exports exports; exports.num = 0; /* Process all LLVM instructions. */ bb = LLVMGetFirstBasicBlock(main_fn); while (bb) { LLVMValueRef inst = LLVMGetFirstInstruction(bb); while (inst) { LLVMValueRef cur = inst; inst = LLVMGetNextInstruction(inst); struct ac_vs_exp_inst exp; if (LLVMGetInstructionOpcode(cur) != LLVMCall) continue; LLVMValueRef callee = ac_llvm_get_called_value(cur); if (!ac_llvm_is_function(callee)) continue; const char *name = LLVMGetValueName(callee); unsigned num_args = LLVMCountParams(callee); /* Check if this is an export instruction. */ if ((num_args != 9 && num_args != 8) || (strcmp(name, "llvm.SI.export") && strcmp(name, "llvm.amdgcn.exp.f32"))) continue; LLVMValueRef arg = LLVMGetOperand(cur, AC_EXP_TARGET); unsigned target = LLVMConstIntGetZExtValue(arg); if (target < V_008DFC_SQ_EXP_PARAM) continue; target -= V_008DFC_SQ_EXP_PARAM; /* Parse the instruction. */ memset(&exp, 0, sizeof(exp)); exp.offset = target; exp.inst = cur; for (unsigned i = 0; i < 4; i++) { LLVMValueRef v = LLVMGetOperand(cur, AC_EXP_OUT0 + i); exp.chan[i].value = v; if (LLVMIsUndef(v)) { exp.chan[i].type = AC_IR_UNDEF; } else if (LLVMIsAConstantFP(v)) { LLVMBool loses_info; exp.chan[i].type = AC_IR_CONST; exp.chan[i].const_float = LLVMConstRealGetDouble(v, &loses_info); } else { exp.chan[i].type = AC_IR_VALUE; } } /* Eliminate constant and duplicated PARAM exports. */ if (ac_eliminate_const_output(vs_output_param_offset, num_outputs, &exp) || ac_eliminate_duplicated_output(ctx, vs_output_param_offset, num_outputs, &exports, &exp)) { removed_any = true; } else { exports.exp[exports.num++] = exp; } } bb = LLVMGetNextBasicBlock(bb); } /* Remove holes in export memory due to removed PARAM exports. * This is done by renumbering all PARAM exports. */ if (removed_any) { uint8_t old_offset[VARYING_SLOT_MAX]; unsigned out, i; /* Make a copy of the offsets. We need the old version while * we are modifying some of them. */ memcpy(old_offset, vs_output_param_offset, sizeof(old_offset)); for (i = 0; i < exports.num; i++) { unsigned offset = exports.exp[i].offset; /* Update vs_output_param_offset. Multiple outputs can * have the same offset. */ for (out = 0; out < num_outputs; out++) { if (old_offset[out] == offset) vs_output_param_offset[out] = i; } /* Change the PARAM offset in the instruction. */ LLVMSetOperand(exports.exp[i].inst, AC_EXP_TARGET, LLVMConstInt(ctx->i32, V_008DFC_SQ_EXP_PARAM + i, 0)); } *num_param_exports = exports.num; } } void ac_init_exec_full_mask(struct ac_llvm_context *ctx) { LLVMValueRef full_mask = LLVMConstInt(ctx->i64, ~0ull, 0); ac_build_intrinsic(ctx, "llvm.amdgcn.init.exec", ctx->voidt, &full_mask, 1, AC_FUNC_ATTR_CONVERGENT); } void ac_declare_lds_as_pointer(struct ac_llvm_context *ctx) { unsigned lds_size = ctx->chip_class >= GFX7 ? 65536 : 32768; ctx->lds = LLVMBuildIntToPtr(ctx->builder, ctx->i32_0, LLVMPointerType(LLVMArrayType(ctx->i32, lds_size / 4), AC_ADDR_SPACE_LDS), "lds"); } LLVMValueRef ac_lds_load(struct ac_llvm_context *ctx, LLVMValueRef dw_addr) { return LLVMBuildLoad(ctx->builder, ac_build_gep0(ctx, ctx->lds, dw_addr), ""); } void ac_lds_store(struct ac_llvm_context *ctx, LLVMValueRef dw_addr, LLVMValueRef value) { value = ac_to_integer(ctx, value); ac_build_indexed_store(ctx, ctx->lds, dw_addr, value); } LLVMValueRef ac_find_lsb(struct ac_llvm_context *ctx, LLVMTypeRef dst_type, LLVMValueRef src0) { unsigned src0_bitsize = ac_get_elem_bits(ctx, LLVMTypeOf(src0)); const char *intrin_name; LLVMTypeRef type; LLVMValueRef zero; switch (src0_bitsize) { case 64: intrin_name = "llvm.cttz.i64"; type = ctx->i64; zero = ctx->i64_0; break; case 32: intrin_name = "llvm.cttz.i32"; type = ctx->i32; zero = ctx->i32_0; break; case 16: intrin_name = "llvm.cttz.i16"; type = ctx->i16; zero = ctx->i16_0; break; case 8: intrin_name = "llvm.cttz.i8"; type = ctx->i8; zero = ctx->i8_0; break; default: unreachable(!"invalid bitsize"); } LLVMValueRef params[2] = { src0, /* The value of 1 means that ffs(x=0) = undef, so LLVM won't * add special code to check for x=0. The reason is that * the LLVM behavior for x=0 is different from what we * need here. However, LLVM also assumes that ffs(x) is * in [0, 31], but GLSL expects that ffs(0) = -1, so * a conditional assignment to handle 0 is still required. * * The hardware already implements the correct behavior. */ ctx->i1true, }; LLVMValueRef lsb = ac_build_intrinsic(ctx, intrin_name, type, params, 2, AC_FUNC_ATTR_READNONE); if (src0_bitsize == 64) { lsb = LLVMBuildTrunc(ctx->builder, lsb, ctx->i32, ""); } else if (src0_bitsize < 32) { lsb = LLVMBuildSExt(ctx->builder, lsb, ctx->i32, ""); } /* TODO: We need an intrinsic to skip this conditional. */ /* Check for zero: */ return LLVMBuildSelect(ctx->builder, LLVMBuildICmp(ctx->builder, LLVMIntEQ, src0, zero, ""), LLVMConstInt(ctx->i32, -1, 0), lsb, ""); } LLVMTypeRef ac_array_in_const_addr_space(LLVMTypeRef elem_type) { return LLVMPointerType(elem_type, AC_ADDR_SPACE_CONST); } LLVMTypeRef ac_array_in_const32_addr_space(LLVMTypeRef elem_type) { return LLVMPointerType(elem_type, AC_ADDR_SPACE_CONST_32BIT); } static struct ac_llvm_flow * get_current_flow(struct ac_llvm_context *ctx) { if (ctx->flow->depth > 0) return &ctx->flow->stack[ctx->flow->depth - 1]; return NULL; } static struct ac_llvm_flow * get_innermost_loop(struct ac_llvm_context *ctx) { for (unsigned i = ctx->flow->depth; i > 0; --i) { if (ctx->flow->stack[i - 1].loop_entry_block) return &ctx->flow->stack[i - 1]; } return NULL; } static struct ac_llvm_flow * push_flow(struct ac_llvm_context *ctx) { struct ac_llvm_flow *flow; if (ctx->flow->depth >= ctx->flow->depth_max) { unsigned new_max = MAX2(ctx->flow->depth << 1, AC_LLVM_INITIAL_CF_DEPTH); ctx->flow->stack = realloc(ctx->flow->stack, new_max * sizeof(*ctx->flow->stack)); ctx->flow->depth_max = new_max; } flow = &ctx->flow->stack[ctx->flow->depth]; ctx->flow->depth++; flow->next_block = NULL; flow->loop_entry_block = NULL; return flow; } static void set_basicblock_name(LLVMBasicBlockRef bb, const char *base, int label_id) { char buf[32]; snprintf(buf, sizeof(buf), "%s%d", base, label_id); LLVMSetValueName(LLVMBasicBlockAsValue(bb), buf); } /* Append a basic block at the level of the parent flow. */ static LLVMBasicBlockRef append_basic_block(struct ac_llvm_context *ctx, const char *name) { assert(ctx->flow->depth >= 1); if (ctx->flow->depth >= 2) { struct ac_llvm_flow *flow = &ctx->flow->stack[ctx->flow->depth - 2]; return LLVMInsertBasicBlockInContext(ctx->context, flow->next_block, name); } LLVMValueRef main_fn = LLVMGetBasicBlockParent(LLVMGetInsertBlock(ctx->builder)); return LLVMAppendBasicBlockInContext(ctx->context, main_fn, name); } /* Emit a branch to the given default target for the current block if * applicable -- that is, if the current block does not already contain a * branch from a break or continue. */ static void emit_default_branch(LLVMBuilderRef builder, LLVMBasicBlockRef target) { if (!LLVMGetBasicBlockTerminator(LLVMGetInsertBlock(builder))) LLVMBuildBr(builder, target); } void ac_build_bgnloop(struct ac_llvm_context *ctx, int label_id) { struct ac_llvm_flow *flow = push_flow(ctx); flow->loop_entry_block = append_basic_block(ctx, "LOOP"); flow->next_block = append_basic_block(ctx, "ENDLOOP"); set_basicblock_name(flow->loop_entry_block, "loop", label_id); LLVMBuildBr(ctx->builder, flow->loop_entry_block); LLVMPositionBuilderAtEnd(ctx->builder, flow->loop_entry_block); } void ac_build_break(struct ac_llvm_context *ctx) { struct ac_llvm_flow *flow = get_innermost_loop(ctx); LLVMBuildBr(ctx->builder, flow->next_block); } void ac_build_continue(struct ac_llvm_context *ctx) { struct ac_llvm_flow *flow = get_innermost_loop(ctx); LLVMBuildBr(ctx->builder, flow->loop_entry_block); } void ac_build_else(struct ac_llvm_context *ctx, int label_id) { struct ac_llvm_flow *current_branch = get_current_flow(ctx); LLVMBasicBlockRef endif_block; assert(!current_branch->loop_entry_block); endif_block = append_basic_block(ctx, "ENDIF"); emit_default_branch(ctx->builder, endif_block); LLVMPositionBuilderAtEnd(ctx->builder, current_branch->next_block); set_basicblock_name(current_branch->next_block, "else", label_id); current_branch->next_block = endif_block; } void ac_build_endif(struct ac_llvm_context *ctx, int label_id) { struct ac_llvm_flow *current_branch = get_current_flow(ctx); assert(!current_branch->loop_entry_block); emit_default_branch(ctx->builder, current_branch->next_block); LLVMPositionBuilderAtEnd(ctx->builder, current_branch->next_block); set_basicblock_name(current_branch->next_block, "endif", label_id); ctx->flow->depth--; } void ac_build_endloop(struct ac_llvm_context *ctx, int label_id) { struct ac_llvm_flow *current_loop = get_current_flow(ctx); assert(current_loop->loop_entry_block); emit_default_branch(ctx->builder, current_loop->loop_entry_block); LLVMPositionBuilderAtEnd(ctx->builder, current_loop->next_block); set_basicblock_name(current_loop->next_block, "endloop", label_id); ctx->flow->depth--; } void ac_build_ifcc(struct ac_llvm_context *ctx, LLVMValueRef cond, int label_id) { struct ac_llvm_flow *flow = push_flow(ctx); LLVMBasicBlockRef if_block; if_block = append_basic_block(ctx, "IF"); flow->next_block = append_basic_block(ctx, "ELSE"); set_basicblock_name(if_block, "if", label_id); LLVMBuildCondBr(ctx->builder, cond, if_block, flow->next_block); LLVMPositionBuilderAtEnd(ctx->builder, if_block); } void ac_build_if(struct ac_llvm_context *ctx, LLVMValueRef value, int label_id) { LLVMValueRef cond = LLVMBuildFCmp(ctx->builder, LLVMRealUNE, value, ctx->f32_0, ""); ac_build_ifcc(ctx, cond, label_id); } void ac_build_uif(struct ac_llvm_context *ctx, LLVMValueRef value, int label_id) { LLVMValueRef cond = LLVMBuildICmp(ctx->builder, LLVMIntNE, ac_to_integer(ctx, value), ctx->i32_0, ""); ac_build_ifcc(ctx, cond, label_id); } LLVMValueRef ac_build_alloca_undef(struct ac_llvm_context *ac, LLVMTypeRef type, const char *name) { LLVMBuilderRef builder = ac->builder; LLVMBasicBlockRef current_block = LLVMGetInsertBlock(builder); LLVMValueRef function = LLVMGetBasicBlockParent(current_block); LLVMBasicBlockRef first_block = LLVMGetEntryBasicBlock(function); LLVMValueRef first_instr = LLVMGetFirstInstruction(first_block); LLVMBuilderRef first_builder = LLVMCreateBuilderInContext(ac->context); LLVMValueRef res; if (first_instr) { LLVMPositionBuilderBefore(first_builder, first_instr); } else { LLVMPositionBuilderAtEnd(first_builder, first_block); } res = LLVMBuildAlloca(first_builder, type, name); LLVMDisposeBuilder(first_builder); return res; } LLVMValueRef ac_build_alloca(struct ac_llvm_context *ac, LLVMTypeRef type, const char *name) { LLVMValueRef ptr = ac_build_alloca_undef(ac, type, name); LLVMBuildStore(ac->builder, LLVMConstNull(type), ptr); return ptr; } LLVMValueRef ac_cast_ptr(struct ac_llvm_context *ctx, LLVMValueRef ptr, LLVMTypeRef type) { int addr_space = LLVMGetPointerAddressSpace(LLVMTypeOf(ptr)); return LLVMBuildBitCast(ctx->builder, ptr, LLVMPointerType(type, addr_space), ""); } LLVMValueRef ac_trim_vector(struct ac_llvm_context *ctx, LLVMValueRef value, unsigned count) { unsigned num_components = ac_get_llvm_num_components(value); if (count == num_components) return value; LLVMValueRef masks[MAX2(count, 2)]; masks[0] = ctx->i32_0; masks[1] = ctx->i32_1; for (unsigned i = 2; i < count; i++) masks[i] = LLVMConstInt(ctx->i32, i, false); if (count == 1) return LLVMBuildExtractElement(ctx->builder, value, masks[0], ""); LLVMValueRef swizzle = LLVMConstVector(masks, count); return LLVMBuildShuffleVector(ctx->builder, value, value, swizzle, ""); } LLVMValueRef ac_unpack_param(struct ac_llvm_context *ctx, LLVMValueRef param, unsigned rshift, unsigned bitwidth) { LLVMValueRef value = param; if (rshift) value = LLVMBuildLShr(ctx->builder, value, LLVMConstInt(ctx->i32, rshift, false), ""); if (rshift + bitwidth < 32) { unsigned mask = (1 << bitwidth) - 1; value = LLVMBuildAnd(ctx->builder, value, LLVMConstInt(ctx->i32, mask, false), ""); } return value; } /* Adjust the sample index according to FMASK. * * For uncompressed MSAA surfaces, FMASK should return 0x76543210, * which is the identity mapping. Each nibble says which physical sample * should be fetched to get that sample. * * For example, 0x11111100 means there are only 2 samples stored and * the second sample covers 3/4 of the pixel. When reading samples 0 * and 1, return physical sample 0 (determined by the first two 0s * in FMASK), otherwise return physical sample 1. * * The sample index should be adjusted as follows: * addr[sample_index] = (fmask >> (addr[sample_index] * 4)) & 0xF; */ void ac_apply_fmask_to_sample(struct ac_llvm_context *ac, LLVMValueRef fmask, LLVMValueRef *addr, bool is_array_tex) { struct ac_image_args fmask_load = {}; fmask_load.opcode = ac_image_load; fmask_load.resource = fmask; fmask_load.dmask = 0xf; fmask_load.dim = is_array_tex ? ac_image_2darray : ac_image_2d; fmask_load.attributes = AC_FUNC_ATTR_READNONE; fmask_load.coords[0] = addr[0]; fmask_load.coords[1] = addr[1]; if (is_array_tex) fmask_load.coords[2] = addr[2]; LLVMValueRef fmask_value = ac_build_image_opcode(ac, &fmask_load); fmask_value = LLVMBuildExtractElement(ac->builder, fmask_value, ac->i32_0, ""); /* Apply the formula. */ unsigned sample_chan = is_array_tex ? 3 : 2; LLVMValueRef final_sample; final_sample = LLVMBuildMul(ac->builder, addr[sample_chan], LLVMConstInt(ac->i32, 4, 0), ""); final_sample = LLVMBuildLShr(ac->builder, fmask_value, final_sample, ""); /* Mask the sample index by 0x7, because 0x8 means an unknown value * with EQAA, so those will map to 0. */ final_sample = LLVMBuildAnd(ac->builder, final_sample, LLVMConstInt(ac->i32, 0x7, 0), ""); /* Don't rewrite the sample index if WORD1.DATA_FORMAT of the FMASK * resource descriptor is 0 (invalid). */ LLVMValueRef tmp; tmp = LLVMBuildBitCast(ac->builder, fmask, ac->v8i32, ""); tmp = LLVMBuildExtractElement(ac->builder, tmp, ac->i32_1, ""); tmp = LLVMBuildICmp(ac->builder, LLVMIntNE, tmp, ac->i32_0, ""); /* Replace the MSAA sample index. */ addr[sample_chan] = LLVMBuildSelect(ac->builder, tmp, final_sample, addr[sample_chan], ""); } static LLVMValueRef _ac_build_readlane(struct ac_llvm_context *ctx, LLVMValueRef src, LLVMValueRef lane) { LLVMTypeRef type = LLVMTypeOf(src); LLVMValueRef result; ac_build_optimization_barrier(ctx, &src); src = LLVMBuildZExt(ctx->builder, src, ctx->i32, ""); if (lane) lane = LLVMBuildZExt(ctx->builder, lane, ctx->i32, ""); result = ac_build_intrinsic(ctx, lane == NULL ? "llvm.amdgcn.readfirstlane" : "llvm.amdgcn.readlane", ctx->i32, (LLVMValueRef []) { src, lane }, lane == NULL ? 1 : 2, AC_FUNC_ATTR_READNONE | AC_FUNC_ATTR_CONVERGENT); return LLVMBuildTrunc(ctx->builder, result, type, ""); } /** * Builds the "llvm.amdgcn.readlane" or "llvm.amdgcn.readfirstlane" intrinsic. * @param ctx * @param src * @param lane - id of the lane or NULL for the first active lane * @return value of the lane */ LLVMValueRef ac_build_readlane(struct ac_llvm_context *ctx, LLVMValueRef src, LLVMValueRef lane) { LLVMTypeRef src_type = LLVMTypeOf(src); src = ac_to_integer(ctx, src); unsigned bits = LLVMGetIntTypeWidth(LLVMTypeOf(src)); LLVMValueRef ret; if (bits > 32) { assert(bits % 32 == 0); LLVMTypeRef vec_type = LLVMVectorType(ctx->i32, bits / 32); LLVMValueRef src_vector = LLVMBuildBitCast(ctx->builder, src, vec_type, ""); ret = LLVMGetUndef(vec_type); for (unsigned i = 0; i < bits / 32; i++) { src = LLVMBuildExtractElement(ctx->builder, src_vector, LLVMConstInt(ctx->i32, i, 0), ""); LLVMValueRef ret_comp = _ac_build_readlane(ctx, src, lane); ret = LLVMBuildInsertElement(ctx->builder, ret, ret_comp, LLVMConstInt(ctx->i32, i, 0), ""); } } else { ret = _ac_build_readlane(ctx, src, lane); } if (LLVMGetTypeKind(src_type) == LLVMPointerTypeKind) return LLVMBuildIntToPtr(ctx->builder, ret, src_type, ""); return LLVMBuildBitCast(ctx->builder, ret, src_type, ""); } LLVMValueRef ac_build_writelane(struct ac_llvm_context *ctx, LLVMValueRef src, LLVMValueRef value, LLVMValueRef lane) { return ac_build_intrinsic(ctx, "llvm.amdgcn.writelane", ctx->i32, (LLVMValueRef []) {value, lane, src}, 3, AC_FUNC_ATTR_READNONE | AC_FUNC_ATTR_CONVERGENT); } LLVMValueRef ac_build_mbcnt(struct ac_llvm_context *ctx, LLVMValueRef mask) { if (ctx->wave_size == 32) { return ac_build_intrinsic(ctx, "llvm.amdgcn.mbcnt.lo", ctx->i32, (LLVMValueRef []) { mask, ctx->i32_0 }, 2, AC_FUNC_ATTR_READNONE); } LLVMValueRef mask_vec = LLVMBuildBitCast(ctx->builder, mask, LLVMVectorType(ctx->i32, 2), ""); LLVMValueRef mask_lo = LLVMBuildExtractElement(ctx->builder, mask_vec, ctx->i32_0, ""); LLVMValueRef mask_hi = LLVMBuildExtractElement(ctx->builder, mask_vec, ctx->i32_1, ""); LLVMValueRef val = ac_build_intrinsic(ctx, "llvm.amdgcn.mbcnt.lo", ctx->i32, (LLVMValueRef []) { mask_lo, ctx->i32_0 }, 2, AC_FUNC_ATTR_READNONE); val = ac_build_intrinsic(ctx, "llvm.amdgcn.mbcnt.hi", ctx->i32, (LLVMValueRef []) { mask_hi, val }, 2, AC_FUNC_ATTR_READNONE); return val; } enum dpp_ctrl { _dpp_quad_perm = 0x000, _dpp_row_sl = 0x100, _dpp_row_sr = 0x110, _dpp_row_rr = 0x120, dpp_wf_sl1 = 0x130, dpp_wf_rl1 = 0x134, dpp_wf_sr1 = 0x138, dpp_wf_rr1 = 0x13C, dpp_row_mirror = 0x140, dpp_row_half_mirror = 0x141, dpp_row_bcast15 = 0x142, dpp_row_bcast31 = 0x143 }; static inline enum dpp_ctrl dpp_quad_perm(unsigned lane0, unsigned lane1, unsigned lane2, unsigned lane3) { assert(lane0 < 4 && lane1 < 4 && lane2 < 4 && lane3 < 4); return _dpp_quad_perm | lane0 | (lane1 << 2) | (lane2 << 4) | (lane3 << 6); } static inline enum dpp_ctrl dpp_row_sl(unsigned amount) { assert(amount > 0 && amount < 16); return _dpp_row_sl | amount; } static inline enum dpp_ctrl dpp_row_sr(unsigned amount) { assert(amount > 0 && amount < 16); return _dpp_row_sr | amount; } static LLVMValueRef _ac_build_dpp(struct ac_llvm_context *ctx, LLVMValueRef old, LLVMValueRef src, enum dpp_ctrl dpp_ctrl, unsigned row_mask, unsigned bank_mask, bool bound_ctrl) { return ac_build_intrinsic(ctx, "llvm.amdgcn.update.dpp.i32", LLVMTypeOf(old), (LLVMValueRef[]) { old, src, LLVMConstInt(ctx->i32, dpp_ctrl, 0), LLVMConstInt(ctx->i32, row_mask, 0), LLVMConstInt(ctx->i32, bank_mask, 0), LLVMConstInt(ctx->i1, bound_ctrl, 0) }, 6, AC_FUNC_ATTR_READNONE | AC_FUNC_ATTR_CONVERGENT); } static LLVMValueRef ac_build_dpp(struct ac_llvm_context *ctx, LLVMValueRef old, LLVMValueRef src, enum dpp_ctrl dpp_ctrl, unsigned row_mask, unsigned bank_mask, bool bound_ctrl) { LLVMTypeRef src_type = LLVMTypeOf(src); src = ac_to_integer(ctx, src); old = ac_to_integer(ctx, old); unsigned bits = LLVMGetIntTypeWidth(LLVMTypeOf(src)); LLVMValueRef ret; if (bits == 32) { ret = _ac_build_dpp(ctx, old, src, dpp_ctrl, row_mask, bank_mask, bound_ctrl); } else { assert(bits % 32 == 0); LLVMTypeRef vec_type = LLVMVectorType(ctx->i32, bits / 32); LLVMValueRef src_vector = LLVMBuildBitCast(ctx->builder, src, vec_type, ""); LLVMValueRef old_vector = LLVMBuildBitCast(ctx->builder, old, vec_type, ""); ret = LLVMGetUndef(vec_type); for (unsigned i = 0; i < bits / 32; i++) { src = LLVMBuildExtractElement(ctx->builder, src_vector, LLVMConstInt(ctx->i32, i, 0), ""); old = LLVMBuildExtractElement(ctx->builder, old_vector, LLVMConstInt(ctx->i32, i, 0), ""); LLVMValueRef ret_comp = _ac_build_dpp(ctx, old, src, dpp_ctrl, row_mask, bank_mask, bound_ctrl); ret = LLVMBuildInsertElement(ctx->builder, ret, ret_comp, LLVMConstInt(ctx->i32, i, 0), ""); } } return LLVMBuildBitCast(ctx->builder, ret, src_type, ""); } static LLVMValueRef _ac_build_permlane16(struct ac_llvm_context *ctx, LLVMValueRef src, uint64_t sel, bool exchange_rows, bool bound_ctrl) { LLVMValueRef args[6] = { src, src, LLVMConstInt(ctx->i32, sel, false), LLVMConstInt(ctx->i32, sel >> 32, false), ctx->i1true, /* fi */ bound_ctrl ? ctx->i1true : ctx->i1false, }; return ac_build_intrinsic(ctx, exchange_rows ? "llvm.amdgcn.permlanex16" : "llvm.amdgcn.permlane16", ctx->i32, args, 6, AC_FUNC_ATTR_READNONE | AC_FUNC_ATTR_CONVERGENT); } static LLVMValueRef ac_build_permlane16(struct ac_llvm_context *ctx, LLVMValueRef src, uint64_t sel, bool exchange_rows, bool bound_ctrl) { LLVMTypeRef src_type = LLVMTypeOf(src); src = ac_to_integer(ctx, src); unsigned bits = LLVMGetIntTypeWidth(LLVMTypeOf(src)); LLVMValueRef ret; if (bits == 32) { ret = _ac_build_permlane16(ctx, src, sel, exchange_rows, bound_ctrl); } else { assert(bits % 32 == 0); LLVMTypeRef vec_type = LLVMVectorType(ctx->i32, bits / 32); LLVMValueRef src_vector = LLVMBuildBitCast(ctx->builder, src, vec_type, ""); ret = LLVMGetUndef(vec_type); for (unsigned i = 0; i < bits / 32; i++) { src = LLVMBuildExtractElement(ctx->builder, src_vector, LLVMConstInt(ctx->i32, i, 0), ""); LLVMValueRef ret_comp = _ac_build_permlane16(ctx, src, sel, exchange_rows, bound_ctrl); ret = LLVMBuildInsertElement(ctx->builder, ret, ret_comp, LLVMConstInt(ctx->i32, i, 0), ""); } } return LLVMBuildBitCast(ctx->builder, ret, src_type, ""); } static inline unsigned ds_pattern_bitmode(unsigned and_mask, unsigned or_mask, unsigned xor_mask) { assert(and_mask < 32 && or_mask < 32 && xor_mask < 32); return and_mask | (or_mask << 5) | (xor_mask << 10); } static LLVMValueRef _ac_build_ds_swizzle(struct ac_llvm_context *ctx, LLVMValueRef src, unsigned mask) { return ac_build_intrinsic(ctx, "llvm.amdgcn.ds.swizzle", LLVMTypeOf(src), (LLVMValueRef []) { src, LLVMConstInt(ctx->i32, mask, 0) }, 2, AC_FUNC_ATTR_READNONE | AC_FUNC_ATTR_CONVERGENT); } LLVMValueRef ac_build_ds_swizzle(struct ac_llvm_context *ctx, LLVMValueRef src, unsigned mask) { LLVMTypeRef src_type = LLVMTypeOf(src); src = ac_to_integer(ctx, src); unsigned bits = LLVMGetIntTypeWidth(LLVMTypeOf(src)); LLVMValueRef ret; if (bits == 32) { ret = _ac_build_ds_swizzle(ctx, src, mask); } else { assert(bits % 32 == 0); LLVMTypeRef vec_type = LLVMVectorType(ctx->i32, bits / 32); LLVMValueRef src_vector = LLVMBuildBitCast(ctx->builder, src, vec_type, ""); ret = LLVMGetUndef(vec_type); for (unsigned i = 0; i < bits / 32; i++) { src = LLVMBuildExtractElement(ctx->builder, src_vector, LLVMConstInt(ctx->i32, i, 0), ""); LLVMValueRef ret_comp = _ac_build_ds_swizzle(ctx, src, mask); ret = LLVMBuildInsertElement(ctx->builder, ret, ret_comp, LLVMConstInt(ctx->i32, i, 0), ""); } } return LLVMBuildBitCast(ctx->builder, ret, src_type, ""); } static LLVMValueRef ac_build_wwm(struct ac_llvm_context *ctx, LLVMValueRef src) { char name[32], type[8]; ac_build_type_name_for_intr(LLVMTypeOf(src), type, sizeof(type)); snprintf(name, sizeof(name), "llvm.amdgcn.wwm.%s", type); return ac_build_intrinsic(ctx, name, LLVMTypeOf(src), (LLVMValueRef []) { src }, 1, AC_FUNC_ATTR_READNONE); } static LLVMValueRef ac_build_set_inactive(struct ac_llvm_context *ctx, LLVMValueRef src, LLVMValueRef inactive) { char name[33], type[8]; LLVMTypeRef src_type = LLVMTypeOf(src); unsigned bitsize = ac_get_elem_bits(ctx, src_type); src = ac_to_integer(ctx, src); inactive = ac_to_integer(ctx, inactive); if (bitsize < 32) { src = LLVMBuildZExt(ctx->builder, src, ctx->i32, ""); inactive = LLVMBuildZExt(ctx->builder, inactive, ctx->i32, ""); } ac_build_type_name_for_intr(LLVMTypeOf(src), type, sizeof(type)); snprintf(name, sizeof(name), "llvm.amdgcn.set.inactive.%s", type); LLVMValueRef ret = ac_build_intrinsic(ctx, name, LLVMTypeOf(src), (LLVMValueRef []) { src, inactive }, 2, AC_FUNC_ATTR_READNONE | AC_FUNC_ATTR_CONVERGENT); if (bitsize < 32) ret = LLVMBuildTrunc(ctx->builder, ret, src_type, ""); return ret; } static LLVMValueRef get_reduction_identity(struct ac_llvm_context *ctx, nir_op op, unsigned type_size) { if (type_size == 4) { switch (op) { case nir_op_iadd: return ctx->i32_0; case nir_op_fadd: return ctx->f32_0; case nir_op_imul: return ctx->i32_1; case nir_op_fmul: return ctx->f32_1; case nir_op_imin: return LLVMConstInt(ctx->i32, INT32_MAX, 0); case nir_op_umin: return LLVMConstInt(ctx->i32, UINT32_MAX, 0); case nir_op_fmin: return LLVMConstReal(ctx->f32, INFINITY); case nir_op_imax: return LLVMConstInt(ctx->i32, INT32_MIN, 0); case nir_op_umax: return ctx->i32_0; case nir_op_fmax: return LLVMConstReal(ctx->f32, -INFINITY); case nir_op_iand: return LLVMConstInt(ctx->i32, -1, 0); case nir_op_ior: return ctx->i32_0; case nir_op_ixor: return ctx->i32_0; default: unreachable("bad reduction intrinsic"); } } else { /* type_size == 64bit */ switch (op) { case nir_op_iadd: return ctx->i64_0; case nir_op_fadd: return ctx->f64_0; case nir_op_imul: return ctx->i64_1; case nir_op_fmul: return ctx->f64_1; case nir_op_imin: return LLVMConstInt(ctx->i64, INT64_MAX, 0); case nir_op_umin: return LLVMConstInt(ctx->i64, UINT64_MAX, 0); case nir_op_fmin: return LLVMConstReal(ctx->f64, INFINITY); case nir_op_imax: return LLVMConstInt(ctx->i64, INT64_MIN, 0); case nir_op_umax: return ctx->i64_0; case nir_op_fmax: return LLVMConstReal(ctx->f64, -INFINITY); case nir_op_iand: return LLVMConstInt(ctx->i64, -1, 0); case nir_op_ior: return ctx->i64_0; case nir_op_ixor: return ctx->i64_0; default: unreachable("bad reduction intrinsic"); } } } static LLVMValueRef ac_build_alu_op(struct ac_llvm_context *ctx, LLVMValueRef lhs, LLVMValueRef rhs, nir_op op) { bool _64bit = ac_get_type_size(LLVMTypeOf(lhs)) == 8; switch (op) { case nir_op_iadd: return LLVMBuildAdd(ctx->builder, lhs, rhs, ""); case nir_op_fadd: return LLVMBuildFAdd(ctx->builder, lhs, rhs, ""); case nir_op_imul: return LLVMBuildMul(ctx->builder, lhs, rhs, ""); case nir_op_fmul: return LLVMBuildFMul(ctx->builder, lhs, rhs, ""); case nir_op_imin: return LLVMBuildSelect(ctx->builder, LLVMBuildICmp(ctx->builder, LLVMIntSLT, lhs, rhs, ""), lhs, rhs, ""); case nir_op_umin: return LLVMBuildSelect(ctx->builder, LLVMBuildICmp(ctx->builder, LLVMIntULT, lhs, rhs, ""), lhs, rhs, ""); case nir_op_fmin: return ac_build_intrinsic(ctx, _64bit ? "llvm.minnum.f64" : "llvm.minnum.f32", _64bit ? ctx->f64 : ctx->f32, (LLVMValueRef[]){lhs, rhs}, 2, AC_FUNC_ATTR_READNONE); case nir_op_imax: return LLVMBuildSelect(ctx->builder, LLVMBuildICmp(ctx->builder, LLVMIntSGT, lhs, rhs, ""), lhs, rhs, ""); case nir_op_umax: return LLVMBuildSelect(ctx->builder, LLVMBuildICmp(ctx->builder, LLVMIntUGT, lhs, rhs, ""), lhs, rhs, ""); case nir_op_fmax: return ac_build_intrinsic(ctx, _64bit ? "llvm.maxnum.f64" : "llvm.maxnum.f32", _64bit ? ctx->f64 : ctx->f32, (LLVMValueRef[]){lhs, rhs}, 2, AC_FUNC_ATTR_READNONE); case nir_op_iand: return LLVMBuildAnd(ctx->builder, lhs, rhs, ""); case nir_op_ior: return LLVMBuildOr(ctx->builder, lhs, rhs, ""); case nir_op_ixor: return LLVMBuildXor(ctx->builder, lhs, rhs, ""); default: unreachable("bad reduction intrinsic"); } } /** * \param maxprefix specifies that the result only needs to be correct for a * prefix of this many threads * * TODO: add inclusive and excluse scan functions for GFX6. */ static LLVMValueRef ac_build_scan(struct ac_llvm_context *ctx, nir_op op, LLVMValueRef src, LLVMValueRef identity, unsigned maxprefix, bool inclusive) { LLVMValueRef result, tmp; if (ctx->chip_class >= GFX10) { result = inclusive ? src : identity; } else { if (!inclusive) src = ac_build_dpp(ctx, identity, src, dpp_wf_sr1, 0xf, 0xf, false); result = src; } if (maxprefix <= 1) return result; tmp = ac_build_dpp(ctx, identity, src, dpp_row_sr(1), 0xf, 0xf, false); result = ac_build_alu_op(ctx, result, tmp, op); if (maxprefix <= 2) return result; tmp = ac_build_dpp(ctx, identity, src, dpp_row_sr(2), 0xf, 0xf, false); result = ac_build_alu_op(ctx, result, tmp, op); if (maxprefix <= 3) return result; tmp = ac_build_dpp(ctx, identity, src, dpp_row_sr(3), 0xf, 0xf, false); result = ac_build_alu_op(ctx, result, tmp, op); if (maxprefix <= 4) return result; tmp = ac_build_dpp(ctx, identity, result, dpp_row_sr(4), 0xf, 0xe, false); result = ac_build_alu_op(ctx, result, tmp, op); if (maxprefix <= 8) return result; tmp = ac_build_dpp(ctx, identity, result, dpp_row_sr(8), 0xf, 0xc, false); result = ac_build_alu_op(ctx, result, tmp, op); if (maxprefix <= 16) return result; if (ctx->chip_class >= GFX10) { /* dpp_row_bcast{15,31} are not supported on gfx10. */ LLVMBuilderRef builder = ctx->builder; LLVMValueRef tid = ac_get_thread_id(ctx); LLVMValueRef cc; /* TODO-GFX10: Can we get better code-gen by putting this into * a branch so that LLVM generates EXEC mask manipulations? */ if (inclusive) tmp = result; else tmp = ac_build_alu_op(ctx, result, src, op); tmp = ac_build_permlane16(ctx, tmp, ~(uint64_t)0, true, false); tmp = ac_build_alu_op(ctx, result, tmp, op); cc = LLVMBuildAnd(builder, tid, LLVMConstInt(ctx->i32, 16, false), ""); cc = LLVMBuildICmp(builder, LLVMIntNE, cc, ctx->i32_0, ""); result = LLVMBuildSelect(builder, cc, tmp, result, ""); if (maxprefix <= 32) return result; if (inclusive) tmp = result; else tmp = ac_build_alu_op(ctx, result, src, op); tmp = ac_build_readlane(ctx, tmp, LLVMConstInt(ctx->i32, 31, false)); tmp = ac_build_alu_op(ctx, result, tmp, op); cc = LLVMBuildICmp(builder, LLVMIntUGE, tid, LLVMConstInt(ctx->i32, 32, false), ""); result = LLVMBuildSelect(builder, cc, tmp, result, ""); return result; } tmp = ac_build_dpp(ctx, identity, result, dpp_row_bcast15, 0xa, 0xf, false); result = ac_build_alu_op(ctx, result, tmp, op); if (maxprefix <= 32) return result; tmp = ac_build_dpp(ctx, identity, result, dpp_row_bcast31, 0xc, 0xf, false); result = ac_build_alu_op(ctx, result, tmp, op); return result; } LLVMValueRef ac_build_inclusive_scan(struct ac_llvm_context *ctx, LLVMValueRef src, nir_op op) { LLVMValueRef result; if (LLVMTypeOf(src) == ctx->i1 && op == nir_op_iadd) { LLVMBuilderRef builder = ctx->builder; src = LLVMBuildZExt(builder, src, ctx->i32, ""); result = ac_build_ballot(ctx, src); result = ac_build_mbcnt(ctx, result); result = LLVMBuildAdd(builder, result, src, ""); return result; } ac_build_optimization_barrier(ctx, &src); LLVMValueRef identity = get_reduction_identity(ctx, op, ac_get_type_size(LLVMTypeOf(src))); result = LLVMBuildBitCast(ctx->builder, ac_build_set_inactive(ctx, src, identity), LLVMTypeOf(identity), ""); result = ac_build_scan(ctx, op, result, identity, ctx->wave_size, true); return ac_build_wwm(ctx, result); } LLVMValueRef ac_build_exclusive_scan(struct ac_llvm_context *ctx, LLVMValueRef src, nir_op op) { LLVMValueRef result; if (LLVMTypeOf(src) == ctx->i1 && op == nir_op_iadd) { LLVMBuilderRef builder = ctx->builder; src = LLVMBuildZExt(builder, src, ctx->i32, ""); result = ac_build_ballot(ctx, src); result = ac_build_mbcnt(ctx, result); return result; } ac_build_optimization_barrier(ctx, &src); LLVMValueRef identity = get_reduction_identity(ctx, op, ac_get_type_size(LLVMTypeOf(src))); result = LLVMBuildBitCast(ctx->builder, ac_build_set_inactive(ctx, src, identity), LLVMTypeOf(identity), ""); result = ac_build_scan(ctx, op, result, identity, ctx->wave_size, false); return ac_build_wwm(ctx, result); } LLVMValueRef ac_build_reduce(struct ac_llvm_context *ctx, LLVMValueRef src, nir_op op, unsigned cluster_size) { if (cluster_size == 1) return src; ac_build_optimization_barrier(ctx, &src); LLVMValueRef result, swap; LLVMValueRef identity = get_reduction_identity(ctx, op, ac_get_type_size(LLVMTypeOf(src))); result = LLVMBuildBitCast(ctx->builder, ac_build_set_inactive(ctx, src, identity), LLVMTypeOf(identity), ""); swap = ac_build_quad_swizzle(ctx, result, 1, 0, 3, 2); result = ac_build_alu_op(ctx, result, swap, op); if (cluster_size == 2) return ac_build_wwm(ctx, result); swap = ac_build_quad_swizzle(ctx, result, 2, 3, 0, 1); result = ac_build_alu_op(ctx, result, swap, op); if (cluster_size == 4) return ac_build_wwm(ctx, result); if (ctx->chip_class >= GFX8) swap = ac_build_dpp(ctx, identity, result, dpp_row_half_mirror, 0xf, 0xf, false); else swap = ac_build_ds_swizzle(ctx, result, ds_pattern_bitmode(0x1f, 0, 0x04)); result = ac_build_alu_op(ctx, result, swap, op); if (cluster_size == 8) return ac_build_wwm(ctx, result); if (ctx->chip_class >= GFX8) swap = ac_build_dpp(ctx, identity, result, dpp_row_mirror, 0xf, 0xf, false); else swap = ac_build_ds_swizzle(ctx, result, ds_pattern_bitmode(0x1f, 0, 0x08)); result = ac_build_alu_op(ctx, result, swap, op); if (cluster_size == 16) return ac_build_wwm(ctx, result); if (ctx->chip_class >= GFX10) swap = ac_build_permlane16(ctx, result, 0, true, false); else if (ctx->chip_class >= GFX8 && cluster_size != 32) swap = ac_build_dpp(ctx, identity, result, dpp_row_bcast15, 0xa, 0xf, false); else swap = ac_build_ds_swizzle(ctx, result, ds_pattern_bitmode(0x1f, 0, 0x10)); result = ac_build_alu_op(ctx, result, swap, op); if (cluster_size == 32) return ac_build_wwm(ctx, result); if (ctx->chip_class >= GFX8) { if (ctx->chip_class >= GFX10) swap = ac_build_readlane(ctx, result, LLVMConstInt(ctx->i32, 31, false)); else swap = ac_build_dpp(ctx, identity, result, dpp_row_bcast31, 0xc, 0xf, false); result = ac_build_alu_op(ctx, result, swap, op); result = ac_build_readlane(ctx, result, LLVMConstInt(ctx->i32, 63, 0)); return ac_build_wwm(ctx, result); } else { swap = ac_build_readlane(ctx, result, ctx->i32_0); result = ac_build_readlane(ctx, result, LLVMConstInt(ctx->i32, 32, 0)); result = ac_build_alu_op(ctx, result, swap, op); return ac_build_wwm(ctx, result); } } /** * "Top half" of a scan that reduces per-wave values across an entire * workgroup. * * The source value must be present in the highest lane of the wave, and the * highest lane must be live. */ void ac_build_wg_wavescan_top(struct ac_llvm_context *ctx, struct ac_wg_scan *ws) { if (ws->maxwaves <= 1) return; const LLVMValueRef last_lane = LLVMConstInt(ctx->i32, ctx->wave_size - 1, false); LLVMBuilderRef builder = ctx->builder; LLVMValueRef tid = ac_get_thread_id(ctx); LLVMValueRef tmp; tmp = LLVMBuildICmp(builder, LLVMIntEQ, tid, last_lane, ""); ac_build_ifcc(ctx, tmp, 1000); LLVMBuildStore(builder, ws->src, LLVMBuildGEP(builder, ws->scratch, &ws->waveidx, 1, "")); ac_build_endif(ctx, 1000); } /** * "Bottom half" of a scan that reduces per-wave values across an entire * workgroup. * * The caller must place a barrier between the top and bottom halves. */ void ac_build_wg_wavescan_bottom(struct ac_llvm_context *ctx, struct ac_wg_scan *ws) { const LLVMTypeRef type = LLVMTypeOf(ws->src); const LLVMValueRef identity = get_reduction_identity(ctx, ws->op, ac_get_type_size(type)); if (ws->maxwaves <= 1) { ws->result_reduce = ws->src; ws->result_inclusive = ws->src; ws->result_exclusive = identity; return; } assert(ws->maxwaves <= 32); LLVMBuilderRef builder = ctx->builder; LLVMValueRef tid = ac_get_thread_id(ctx); LLVMBasicBlockRef bbs[2]; LLVMValueRef phivalues_scan[2]; LLVMValueRef tmp, tmp2; bbs[0] = LLVMGetInsertBlock(builder); phivalues_scan[0] = LLVMGetUndef(type); if (ws->enable_reduce) tmp = LLVMBuildICmp(builder, LLVMIntULT, tid, ws->numwaves, ""); else if (ws->enable_inclusive) tmp = LLVMBuildICmp(builder, LLVMIntULE, tid, ws->waveidx, ""); else tmp = LLVMBuildICmp(builder, LLVMIntULT, tid, ws->waveidx, ""); ac_build_ifcc(ctx, tmp, 1001); { tmp = LLVMBuildLoad(builder, LLVMBuildGEP(builder, ws->scratch, &tid, 1, ""), ""); ac_build_optimization_barrier(ctx, &tmp); bbs[1] = LLVMGetInsertBlock(builder); phivalues_scan[1] = ac_build_scan(ctx, ws->op, tmp, identity, ws->maxwaves, true); } ac_build_endif(ctx, 1001); const LLVMValueRef scan = ac_build_phi(ctx, type, 2, phivalues_scan, bbs); if (ws->enable_reduce) { tmp = LLVMBuildSub(builder, ws->numwaves, ctx->i32_1, ""); ws->result_reduce = ac_build_readlane(ctx, scan, tmp); } if (ws->enable_inclusive) ws->result_inclusive = ac_build_readlane(ctx, scan, ws->waveidx); if (ws->enable_exclusive) { tmp = LLVMBuildSub(builder, ws->waveidx, ctx->i32_1, ""); tmp = ac_build_readlane(ctx, scan, tmp); tmp2 = LLVMBuildICmp(builder, LLVMIntEQ, ws->waveidx, ctx->i32_0, ""); ws->result_exclusive = LLVMBuildSelect(builder, tmp2, identity, tmp, ""); } } /** * Inclusive scan of a per-wave value across an entire workgroup. * * This implies an s_barrier instruction. * * Unlike ac_build_inclusive_scan, the caller \em must ensure that all threads * of the workgroup are live. (This requirement cannot easily be relaxed in a * useful manner because of the barrier in the algorithm.) */ void ac_build_wg_wavescan(struct ac_llvm_context *ctx, struct ac_wg_scan *ws) { ac_build_wg_wavescan_top(ctx, ws); ac_build_s_barrier(ctx); ac_build_wg_wavescan_bottom(ctx, ws); } /** * "Top half" of a scan that reduces per-thread values across an entire * workgroup. * * All lanes must be active when this code runs. */ void ac_build_wg_scan_top(struct ac_llvm_context *ctx, struct ac_wg_scan *ws) { if (ws->enable_exclusive) { ws->extra = ac_build_exclusive_scan(ctx, ws->src, ws->op); if (LLVMTypeOf(ws->src) == ctx->i1 && ws->op == nir_op_iadd) ws->src = LLVMBuildZExt(ctx->builder, ws->src, ctx->i32, ""); ws->src = ac_build_alu_op(ctx, ws->extra, ws->src, ws->op); } else { ws->src = ac_build_inclusive_scan(ctx, ws->src, ws->op); } bool enable_inclusive = ws->enable_inclusive; bool enable_exclusive = ws->enable_exclusive; ws->enable_inclusive = false; ws->enable_exclusive = ws->enable_exclusive || enable_inclusive; ac_build_wg_wavescan_top(ctx, ws); ws->enable_inclusive = enable_inclusive; ws->enable_exclusive = enable_exclusive; } /** * "Bottom half" of a scan that reduces per-thread values across an entire * workgroup. * * The caller must place a barrier between the top and bottom halves. */ void ac_build_wg_scan_bottom(struct ac_llvm_context *ctx, struct ac_wg_scan *ws) { bool enable_inclusive = ws->enable_inclusive; bool enable_exclusive = ws->enable_exclusive; ws->enable_inclusive = false; ws->enable_exclusive = ws->enable_exclusive || enable_inclusive; ac_build_wg_wavescan_bottom(ctx, ws); ws->enable_inclusive = enable_inclusive; ws->enable_exclusive = enable_exclusive; /* ws->result_reduce is already the correct value */ if (ws->enable_inclusive) ws->result_inclusive = ac_build_alu_op(ctx, ws->result_inclusive, ws->src, ws->op); if (ws->enable_exclusive) ws->result_exclusive = ac_build_alu_op(ctx, ws->result_exclusive, ws->extra, ws->op); } /** * A scan that reduces per-thread values across an entire workgroup. * * The caller must ensure that all lanes are active when this code runs * (WWM is insufficient!), because there is an implied barrier. */ void ac_build_wg_scan(struct ac_llvm_context *ctx, struct ac_wg_scan *ws) { ac_build_wg_scan_top(ctx, ws); ac_build_s_barrier(ctx); ac_build_wg_scan_bottom(ctx, ws); } LLVMValueRef ac_build_quad_swizzle(struct ac_llvm_context *ctx, LLVMValueRef src, unsigned lane0, unsigned lane1, unsigned lane2, unsigned lane3) { unsigned mask = dpp_quad_perm(lane0, lane1, lane2, lane3); if (ctx->chip_class >= GFX8) { return ac_build_dpp(ctx, src, src, mask, 0xf, 0xf, false); } else { return ac_build_ds_swizzle(ctx, src, (1 << 15) | mask); } } LLVMValueRef ac_build_shuffle(struct ac_llvm_context *ctx, LLVMValueRef src, LLVMValueRef index) { LLVMTypeRef type = LLVMTypeOf(src); LLVMValueRef result; index = LLVMBuildMul(ctx->builder, index, LLVMConstInt(ctx->i32, 4, 0), ""); src = LLVMBuildZExt(ctx->builder, src, ctx->i32, ""); result = ac_build_intrinsic(ctx, "llvm.amdgcn.ds.bpermute", ctx->i32, (LLVMValueRef []) {index, src}, 2, AC_FUNC_ATTR_READNONE | AC_FUNC_ATTR_CONVERGENT); return LLVMBuildTrunc(ctx->builder, result, type, ""); } LLVMValueRef ac_build_frexp_exp(struct ac_llvm_context *ctx, LLVMValueRef src0, unsigned bitsize) { LLVMTypeRef type; char *intr; if (bitsize == 16) { intr = "llvm.amdgcn.frexp.exp.i16.f16"; type = ctx->i16; } else if (bitsize == 32) { intr = "llvm.amdgcn.frexp.exp.i32.f32"; type = ctx->i32; } else { intr = "llvm.amdgcn.frexp.exp.i32.f64"; type = ctx->i32; } LLVMValueRef params[] = { src0, }; return ac_build_intrinsic(ctx, intr, type, params, 1, AC_FUNC_ATTR_READNONE); } LLVMValueRef ac_build_frexp_mant(struct ac_llvm_context *ctx, LLVMValueRef src0, unsigned bitsize) { LLVMTypeRef type; char *intr; if (bitsize == 16) { intr = "llvm.amdgcn.frexp.mant.f16"; type = ctx->f16; } else if (bitsize == 32) { intr = "llvm.amdgcn.frexp.mant.f32"; type = ctx->f32; } else { intr = "llvm.amdgcn.frexp.mant.f64"; type = ctx->f64; } LLVMValueRef params[] = { src0, }; return ac_build_intrinsic(ctx, intr, type, params, 1, AC_FUNC_ATTR_READNONE); } LLVMValueRef ac_build_canonicalize(struct ac_llvm_context *ctx, LLVMValueRef src0, unsigned bitsize) { LLVMTypeRef type; char *intr; if (bitsize == 16) { intr = "llvm.canonicalize.f16"; type = ctx->f16; } else if (bitsize == 32) { intr = "llvm.canonicalize.f32"; type = ctx->f32; } else if (bitsize == 64) { intr = "llvm.canonicalize.f64"; type = ctx->f64; } LLVMValueRef params[] = { src0, }; return ac_build_intrinsic(ctx, intr, type, params, 1, AC_FUNC_ATTR_READNONE); } /* * this takes an I,J coordinate pair, * and works out the X and Y derivatives. * it returns DDX(I), DDX(J), DDY(I), DDY(J). */ LLVMValueRef ac_build_ddxy_interp(struct ac_llvm_context *ctx, LLVMValueRef interp_ij) { LLVMValueRef result[4], a; unsigned i; for (i = 0; i < 2; i++) { a = LLVMBuildExtractElement(ctx->builder, interp_ij, LLVMConstInt(ctx->i32, i, false), ""); result[i] = ac_build_ddxy(ctx, AC_TID_MASK_TOP_LEFT, 1, a); result[2+i] = ac_build_ddxy(ctx, AC_TID_MASK_TOP_LEFT, 2, a); } return ac_build_gather_values(ctx, result, 4); } LLVMValueRef ac_build_load_helper_invocation(struct ac_llvm_context *ctx) { LLVMValueRef result = ac_build_intrinsic(ctx, "llvm.amdgcn.ps.live", ctx->i1, NULL, 0, AC_FUNC_ATTR_READNONE); result = LLVMBuildNot(ctx->builder, result, ""); return LLVMBuildSExt(ctx->builder, result, ctx->i32, ""); } LLVMValueRef ac_build_call(struct ac_llvm_context *ctx, LLVMValueRef func, LLVMValueRef *args, unsigned num_args) { LLVMValueRef ret = LLVMBuildCall(ctx->builder, func, args, num_args, ""); LLVMSetInstructionCallConv(ret, LLVMGetFunctionCallConv(func)); return ret; } void ac_export_mrt_z(struct ac_llvm_context *ctx, LLVMValueRef depth, LLVMValueRef stencil, LLVMValueRef samplemask, struct ac_export_args *args) { unsigned mask = 0; unsigned format = ac_get_spi_shader_z_format(depth != NULL, stencil != NULL, samplemask != NULL); assert(depth || stencil || samplemask); memset(args, 0, sizeof(*args)); args->valid_mask = 1; /* whether the EXEC mask is valid */ args->done = 1; /* DONE bit */ /* Specify the target we are exporting */ args->target = V_008DFC_SQ_EXP_MRTZ; args->compr = 0; /* COMP flag */ args->out[0] = LLVMGetUndef(ctx->f32); /* R, depth */ args->out[1] = LLVMGetUndef(ctx->f32); /* G, stencil test val[0:7], stencil op val[8:15] */ args->out[2] = LLVMGetUndef(ctx->f32); /* B, sample mask */ args->out[3] = LLVMGetUndef(ctx->f32); /* A, alpha to mask */ if (format == V_028710_SPI_SHADER_UINT16_ABGR) { assert(!depth); args->compr = 1; /* COMPR flag */ if (stencil) { /* Stencil should be in X[23:16]. */ stencil = ac_to_integer(ctx, stencil); stencil = LLVMBuildShl(ctx->builder, stencil, LLVMConstInt(ctx->i32, 16, 0), ""); args->out[0] = ac_to_float(ctx, stencil); mask |= 0x3; } if (samplemask) { /* SampleMask should be in Y[15:0]. */ args->out[1] = samplemask; mask |= 0xc; } } else { if (depth) { args->out[0] = depth; mask |= 0x1; } if (stencil) { args->out[1] = stencil; mask |= 0x2; } if (samplemask) { args->out[2] = samplemask; mask |= 0x4; } } /* GFX6 (except OLAND and HAINAN) has a bug that it only looks * at the X writemask component. */ if (ctx->chip_class == GFX6 && ctx->family != CHIP_OLAND && ctx->family != CHIP_HAINAN) mask |= 0x1; /* Specify which components to enable */ args->enabled_channels = mask; }