/* -*- mesa-c++ -*- * * Copyright (c) 2018 Collabora LTD * * Author: Gert Wollny * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * on the rights to use, copy, modify, merge, publish, distribute, sub * license, and/or sell copies of the Software, and to permit persons to whom * the Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. IN NO EVENT SHALL * THE AUTHOR(S) AND/OR THEIR SUPPLIERS BE LIABLE FOR ANY CLAIM, * DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR * OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE * USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include "sfn_emittexinstruction.h" #include "sfn_shader_base.h" #include "sfn_instruction_fetch.h" namespace r600 { EmitTexInstruction::EmitTexInstruction(ShaderFromNirProcessor &processor): EmitInstruction (processor) { } bool EmitTexInstruction::do_emit(nir_instr* instr) { nir_tex_instr* ir = nir_instr_as_tex(instr); TexInputs src; if (!get_inputs(*ir, src)) return false; if (ir->sampler_dim == GLSL_SAMPLER_DIM_CUBE) { switch (ir->op) { case nir_texop_tex: return emit_cube_tex(ir, src); case nir_texop_txf: return emit_cube_txf(ir, src); case nir_texop_txb: return emit_cube_txb(ir, src); case nir_texop_txl: return emit_cube_txl(ir, src); case nir_texop_txs: return emit_tex_txs(ir, src, {0,1,2,3}); case nir_texop_txd: return emit_cube_txd(ir, src); case nir_texop_lod: return emit_cube_lod(ir, src); case nir_texop_tg4: return emit_cube_tg4(ir, src); case nir_texop_query_levels: return emit_tex_txs(ir, src, {3,7,7,7}); default: return false; } } else if (ir->sampler_dim == GLSL_SAMPLER_DIM_BUF) { switch (ir->op) { case nir_texop_txf: return emit_buf_txf(ir, src); case nir_texop_txs: return emit_tex_txs(ir, src, {0,1,2,3}); default: return false; } } else { switch (ir->op) { case nir_texop_tex: return emit_tex_tex(ir, src); case nir_texop_txf: return emit_tex_txf(ir, src); case nir_texop_txb: return emit_tex_txb(ir, src); case nir_texop_txl: return emit_tex_txl(ir, src); case nir_texop_txd: return emit_tex_txd(ir, src); case nir_texop_txs: return emit_tex_txs(ir, src, {0,1,2,3}); case nir_texop_lod: return emit_tex_lod(ir, src); case nir_texop_tg4: return emit_tex_tg4(ir, src); case nir_texop_txf_ms: return emit_tex_txf_ms(ir, src); case nir_texop_query_levels: return emit_tex_txs(ir, src, {3,7,7,7}); case nir_texop_texture_samples: return emit_tex_texture_samples(ir, src, {3,7,7,7}); default: return false; } } } bool EmitTexInstruction::emit_cube_txf(UNUSED nir_tex_instr* instr, UNUSED TexInputs &src) { return false; } bool EmitTexInstruction::emit_cube_txd(nir_tex_instr* instr, TexInputs& tex_src) { assert(instr->src[0].src.is_ssa); r600::sfn_log << SfnLog::instr << "emit '" << *reinterpret_cast(instr) << "' (" << __func__ << ")\n"; auto tex_op = TexInstruction::sample_g; std::array v; for (int i = 0; i < 4; ++i) v[i] = from_nir(instr->dest, i); GPRVector cubed(v); emit_cube_prep(tex_src.coord, cubed, instr->is_array); std::array dst_elms; std::array src_elms; const uint16_t lookup[4] = {1, 0, 3, 2}; for (uint16_t i = 0; i < 4; ++i) { dst_elms[i] = v[i]; src_elms[i] = cubed.reg_i(lookup[i]); } GPRVector empty_dst(0, {7,7,7,7}); if (instr->is_shadow) { emit_instruction(new AluInstruction(op1_mov, src_elms[3], tex_src.comperator, {alu_last_instr, alu_write})); tex_op = TexInstruction::sample_c_g; } PValue half(new LiteralValue(0.5f)); for (int i = 0; i < 3; ++i) { emit_instruction(new AluInstruction(op2_mul_ieee, tex_src.ddx.reg_i(i), {tex_src.ddx.reg_i(i), half}, {alu_last_instr, alu_write})); } for (int i = 0; i < 3; ++i) { emit_instruction(new AluInstruction(op2_mul_ieee, tex_src.ddy.reg_i(i), {tex_src.ddy.reg_i(i), half}, {alu_last_instr, alu_write})); } auto sampler = get_samplerr_id(instr->sampler_index, tex_src.sampler_deref); assert(!sampler.indirect); TexInstruction *irgh = new TexInstruction(TexInstruction::set_gradient_h, empty_dst, tex_src.ddx, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, tex_src.sampler_offset); irgh->set_dest_swizzle({7,7,7,7}); TexInstruction *irgv = new TexInstruction(TexInstruction::set_gradient_v, empty_dst, tex_src.ddy, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, tex_src.sampler_offset); irgv->set_dest_swizzle({7,7,7,7}); GPRVector dst(dst_elms); GPRVector src(src_elms); TexInstruction *ir = new TexInstruction(tex_op, dst, src, instr->sampler_index, sampler.id + R600_MAX_CONST_BUFFERS, tex_src.sampler_offset); set_rect_coordinate_flags(instr, ir); //set_offsets(ir, tex_src.offset); emit_instruction(irgh); emit_instruction(irgv); emit_instruction(ir); return true; } bool EmitTexInstruction::emit_cube_txl(nir_tex_instr* instr, TexInputs& tex_src) { assert(instr->src[0].src.is_ssa); if (instr->is_shadow) return false; r600::sfn_log << SfnLog::instr << "emit '" << *reinterpret_cast(instr) << "' (" << __func__ << ")\n"; std::array v; for (int i = 0; i < 4; ++i) v[i] = from_nir(instr->dest, i); GPRVector cubed(v); emit_cube_prep(tex_src.coord, cubed, instr->is_array); std::array dst_elms; std::array src_elms; const uint16_t lookup[4] = {1, 0, 3, 2}; for (uint16_t i = 0; i < 4; ++i) { dst_elms[i] = v[i]; src_elms[i] = cubed.reg_i(lookup[i]); } auto *ir = new AluInstruction(op1_mov, src_elms[3], tex_src.lod, {alu_last_instr, alu_write}); emit_instruction(ir); GPRVector src(src_elms); GPRVector dst(dst_elms); auto sampler = get_samplerr_id(instr->sampler_index, tex_src.sampler_deref); assert(!sampler.indirect); auto tir = new TexInstruction(TexInstruction::sample_l, dst, src, sampler.id,sampler.id + R600_MAX_CONST_BUFFERS, tex_src.sampler_offset); if (instr->is_array) tir->set_flag(TexInstruction::z_unnormalized); emit_instruction(tir); return true; } bool EmitTexInstruction::emit_cube_lod(nir_tex_instr* instr, TexInputs& src) { auto tex_op = TexInstruction::get_tex_lod; std::array v; for (int i = 0; i < 4; ++i) v[i] = from_nir(instr->dest, i); GPRVector cubed(v); emit_cube_prep(src.coord, cubed, instr->is_array); auto sampler = get_samplerr_id(instr->sampler_index, src.sampler_deref); assert(!sampler.indirect); auto dst = make_dest(*instr); auto irt = new TexInstruction(tex_op, dst, cubed, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, src.sampler_offset); emit_instruction(irt); return true; } bool EmitTexInstruction::emit_cube_txb(nir_tex_instr* instr, TexInputs& tex_src) { assert(instr->src[0].src.is_ssa); r600::sfn_log << SfnLog::instr << "emit '" << *reinterpret_cast(instr) << "' (" << __func__ << ")\n"; std::array v; for (int i = 0; i < 4; ++i) v[i] = from_nir(instr->dest, i); GPRVector cubed(v); emit_cube_prep(tex_src.coord, cubed, instr->is_array); std::array dst_elms; std::array src_elms; const uint16_t lookup[4] = {1, 0, 3, 2}; for (uint16_t i = 0; i < 4; ++i) { dst_elms[i] = v[i]; src_elms[i] = v[lookup[i]]; } GPRVector src(src_elms); GPRVector dst(dst_elms); auto tex_op = TexInstruction::sample_lb; if (!instr->is_shadow) { emit_instruction(new AluInstruction(op1_mov, src_elms[3], tex_src.bias, {alu_last_instr, alu_write})); } else { emit_instruction(new AluInstruction(op1_mov, src_elms[3], tex_src.comperator, {alu_last_instr, alu_write})); tex_op = TexInstruction::sample_c_lb; } auto sampler = get_samplerr_id(instr->sampler_index, tex_src.sampler_deref); assert(!sampler.indirect && "Indirect sampler selection not yet supported"); auto tir = new TexInstruction(tex_op, dst, src, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, tex_src.sampler_offset); emit_instruction(tir); return true; } bool EmitTexInstruction::emit_cube_tex(nir_tex_instr* instr, TexInputs& tex_src) { std::array v; for (int i = 0; i < 4; ++i) v[i] = from_nir(instr->dest, i); auto tex_op = TexInstruction::sample; GPRVector cubed(v); emit_cube_prep(tex_src.coord, cubed, instr->is_array); std::array dst_elms; std::array src_elms; const uint16_t lookup[4] = {1, 0, 3, 2}; for (uint16_t i = 0; i < 4; ++i) { dst_elms[i] = v[i]; src_elms[i] = v[lookup[i]]; } if (instr->is_shadow) { emit_instruction(new AluInstruction(op1_mov, src_elms[3], tex_src.comperator, {alu_last_instr, alu_write})); tex_op = TexInstruction::sample_c; } GPRVector dst(dst_elms); GPRVector src(src_elms); auto sampler = get_samplerr_id(instr->sampler_index, tex_src.sampler_deref); assert(!sampler.indirect && "Indirect sampler selection not yet supported"); auto tir = new TexInstruction(tex_op, dst, src, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, tex_src.sampler_offset); if (instr->is_array) tir->set_flag(TexInstruction::z_unnormalized); emit_instruction(tir); return true; } bool EmitTexInstruction::emit_cube_prep(const GPRVector& coord, GPRVector& cubed, bool is_array) { AluInstruction *ir = nullptr; const uint16_t src0_chan[4] = {2, 2, 0, 1}; const uint16_t src1_chan[4] = {1, 0, 2, 2}; for (int i = 0; i < 4; ++i) { ir = new AluInstruction(op2_cube, cubed.reg_i(i), coord.reg_i(src0_chan[i]), coord.reg_i(src1_chan[i]), {alu_write}); emit_instruction(ir); } ir->set_flag(alu_last_instr); ir = new AluInstruction(op1_recip_ieee, cubed.reg_i(2), cubed.reg_i(2), {alu_write, alu_last_instr}); ir->set_flag(alu_src0_abs); emit_instruction(ir); PValue one_p_5(new LiteralValue(1.5f)); for (int i = 0; i < 2; ++i) { ir = new AluInstruction(op3_muladd, cubed.reg_i(i), cubed.reg_i(i), cubed.reg_i(2), one_p_5, {alu_write}); emit_instruction(ir); } ir->set_flag(alu_last_instr); if (is_array) { auto face = cubed.reg_i(3); PValue array_index = get_temp_register(); ir = new AluInstruction(op1_rndne, array_index, coord.reg_i(3), {alu_write, alu_last_instr}); emit_instruction(ir); ir = new AluInstruction(op2_max, array_index, {array_index, Value::zero}, {alu_write, alu_last_instr}); emit_instruction(ir); ir = new AluInstruction(op3_muladd, face, {array_index, PValue (new LiteralValue(8.0f)), face}, {alu_write, alu_last_instr}); emit_instruction(ir); } return true; } bool EmitTexInstruction::emit_buf_txf(nir_tex_instr* instr, TexInputs &src) { auto dst = make_dest(*instr); auto ir = new FetchInstruction(vc_fetch, no_index_offset, dst, src.coord.reg_i(0), 0, instr->texture_index + R600_MAX_CONST_BUFFERS, src.texture_offset, bim_none); ir->set_flag(vtx_use_const_field); emit_instruction(ir); return true; } bool EmitTexInstruction::emit_tex_tex(nir_tex_instr* instr, TexInputs& src) { r600::sfn_log << SfnLog::instr << "emit '" << *reinterpret_cast(instr) << "' (" << __func__ << ")\n"; auto tex_op = TexInstruction::sample; auto sampler = get_samplerr_id(instr->sampler_index, src.sampler_deref); assert(!sampler.indirect); if (instr->is_shadow) { emit_instruction(new AluInstruction(op1_mov, src.coord.reg_i(3), src.comperator, {alu_last_instr, alu_write})); tex_op = TexInstruction::sample_c; } auto dst = make_dest(*instr); auto irt = new TexInstruction(tex_op, dst, src.coord, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, src.sampler_offset); if (instr->is_array) handle_array_index(*instr, src.coord, irt); set_rect_coordinate_flags(instr, irt); set_offsets(irt, src.offset); emit_instruction(irt); return true; } bool EmitTexInstruction::emit_tex_txd(nir_tex_instr* instr, TexInputs& src) { r600::sfn_log << SfnLog::instr << "emit '" << *reinterpret_cast(instr) << "' (" << __func__ << ")\n"; auto tex_op = TexInstruction::sample_g; auto dst = make_dest(*instr); GPRVector empty_dst(0,{7,7,7,7}); if (instr->is_shadow) { emit_instruction(new AluInstruction(op1_mov, src.coord.reg_i(3), src.comperator, {alu_last_instr, alu_write})); tex_op = TexInstruction::sample_c_g; } auto sampler = get_samplerr_id(instr->sampler_index, src.sampler_deref); assert(!sampler.indirect && "Indirect sampler selection not yet supported"); TexInstruction *irgh = new TexInstruction(TexInstruction::set_gradient_h, empty_dst, src.ddx, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, src.sampler_offset); irgh->set_dest_swizzle({7,7,7,7}); TexInstruction *irgv = new TexInstruction(TexInstruction::set_gradient_v, empty_dst, src.ddy, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, src.sampler_offset); irgv->set_dest_swizzle({7,7,7,7}); TexInstruction *ir = new TexInstruction(tex_op, dst, src.coord, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, src.sampler_offset); if (instr->is_array) handle_array_index(*instr, src.coord, ir); set_rect_coordinate_flags(instr, ir); set_offsets(ir, src.offset); emit_instruction(irgh); emit_instruction(irgv); emit_instruction(ir); return true; } bool EmitTexInstruction::emit_tex_txf(nir_tex_instr* instr, TexInputs& src) { r600::sfn_log << SfnLog::instr << "emit '" << *reinterpret_cast(instr) << "' (" << __func__ << ")\n"; auto dst = make_dest(*instr); if (*src.coord.reg_i(3) != *src.lod) { if (src.coord.sel() != src.lod->sel()) emit_instruction(new AluInstruction(op1_mov, src.coord.reg_i(3), src.lod, {alu_write, alu_last_instr})); else src.coord.set_reg_i(3, src.lod); } auto sampler = get_samplerr_id(instr->sampler_index, src.sampler_deref); assert(!sampler.indirect); /* txf doesn't need rounding for the array index, but 1D has the array index * in the z component */ if (instr->is_array && instr->sampler_dim == GLSL_SAMPLER_DIM_1D) src.coord.set_reg_i(2, src.coord.reg_i(1)); auto tex_ir = new TexInstruction(TexInstruction::ld, dst, src.coord, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, src.sampler_offset); if (src.offset) { assert(src.offset->is_ssa); AluInstruction *ir = nullptr; for (unsigned i = 0; i < src.offset->ssa->num_components; ++i) { ir = new AluInstruction(op2_add_int, src.coord.reg_i(i), {src.coord.reg_i(i), from_nir(*src.offset, i, i)}, {alu_write}); emit_instruction(ir); } if (ir) ir->set_flag(alu_last_instr); } emit_instruction(tex_ir); return true; } bool EmitTexInstruction::emit_tex_lod(nir_tex_instr* instr, TexInputs& src) { auto tex_op = TexInstruction::get_tex_lod; auto sampler = get_samplerr_id(instr->sampler_index, src.sampler_deref); assert(!sampler.indirect && "Indirect sampler selection not yet supported"); auto dst = make_dest(*instr); auto irt = new TexInstruction(tex_op, dst, src.coord, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, src.sampler_offset); irt->set_dest_swizzle({1,0,7,7}); emit_instruction(irt); return true; } bool EmitTexInstruction::emit_tex_txl(nir_tex_instr* instr, TexInputs& src) { r600::sfn_log << SfnLog::instr << "emit '" << *reinterpret_cast(instr) << "' (" << __func__ << ")\n"; auto tex_op = TexInstruction::sample_l; if (instr->is_shadow) { if (src.coord.sel() != src.comperator->sel()) emit_instruction(new AluInstruction(op1_mov, src.coord.reg_i(2), src.comperator, {alu_write})); else src.coord.set_reg_i(2, src.comperator); tex_op = TexInstruction::sample_c_l; } if (src.coord.sel() != src.lod->sel()) emit_instruction(new AluInstruction(op1_mov, src.coord.reg_i(3), src.lod, {last_write})); else src.coord.set_reg_i(3, src.lod); auto sampler = get_samplerr_id(instr->sampler_index, src.sampler_deref); assert(!sampler.indirect && "Indirect sampler selection not yet supported"); auto dst = make_dest(*instr); auto irt = new TexInstruction(tex_op, dst, src.coord, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, src.sampler_offset); if (instr->is_array) handle_array_index(*instr, src.coord, irt); set_rect_coordinate_flags(instr, irt); set_offsets(irt, src.offset); emit_instruction(irt); return true; } bool EmitTexInstruction::emit_tex_txb(nir_tex_instr* instr, TexInputs& src) { auto tex_op = TexInstruction::sample_lb; std::array in_swizzle = {0,1,2,3}; if (instr->is_shadow) { if (src.coord.sel() != src.comperator->sel()) emit_instruction(new AluInstruction(op1_mov, src.coord.reg_i(2), src.comperator, {alu_write})); else src.coord.set_reg_i(2, src.comperator); tex_op = TexInstruction::sample_c_lb; } if (src.coord.sel() != src.bias->sel()) emit_instruction(new AluInstruction(op1_mov, src.coord.reg_i(3), src.bias, {last_write})); else src.coord.set_reg_i(3, src.bias); GPRVector tex_src(src.coord, in_swizzle); auto sampler = get_samplerr_id(instr->sampler_index, src.sampler_deref); assert(!sampler.indirect && "Indirect sampler selection not yet supported"); auto dst = make_dest(*instr); auto irt = new TexInstruction(tex_op, dst, tex_src, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, src.sampler_offset); if (instr->is_array) handle_array_index(*instr, tex_src, irt); set_rect_coordinate_flags(instr, irt); set_offsets(irt, src.offset); emit_instruction(irt); return true; } bool EmitTexInstruction::emit_tex_txs(nir_tex_instr* instr, TexInputs& tex_src, const std::array& dest_swz) { std::array dst_elms; std::array src_elms; for (uint16_t i = 0; i < 4; ++i) { dst_elms[i] = from_nir(instr->dest, (i < instr->dest.ssa.num_components) ? i : 7); } GPRVector dst(dst_elms); if (instr->sampler_dim == GLSL_SAMPLER_DIM_BUF) { emit_instruction(new FetchInstruction(dst, PValue(new GPRValue(0, 7)), instr->sampler_index + R600_MAX_CONST_BUFFERS, bim_none)); } else { for (uint16_t i = 0; i < 4; ++i) src_elms[i] = tex_src.lod; GPRVector src(src_elms); auto sampler = get_samplerr_id(instr->sampler_index, tex_src.sampler_deref); assert(!sampler.indirect && "Indirect sampler selection not yet supported"); auto ir = new TexInstruction(TexInstruction::get_resinfo, dst, src, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, tex_src.sampler_offset); ir->set_dest_swizzle(dest_swz); emit_instruction(ir); } return true; } bool EmitTexInstruction::emit_tex_texture_samples(nir_tex_instr* instr, TexInputs& src, const std::array &dest_swz) { GPRVector dest = vec_from_nir(instr->dest, nir_dest_num_components(instr->dest)); GPRVector help{0,{4,4,4,4}}; auto dyn_offset = PValue(); int res_id = R600_MAX_CONST_BUFFERS + instr->sampler_index; auto ir = new TexInstruction(TexInstruction::get_nsampled, dest, help, 0, res_id, src.sampler_offset); ir->set_dest_swizzle(dest_swz); emit_instruction(ir); return true; } bool EmitTexInstruction::emit_tex_tg4(nir_tex_instr* instr, TexInputs& src) { r600::sfn_log << SfnLog::instr << "emit '" << *reinterpret_cast(instr) << "' (" << __func__ << ")\n"; TexInstruction *set_ofs = nullptr; auto tex_op = TexInstruction::gather4; if (instr->is_shadow) { emit_instruction(new AluInstruction(op1_mov, src.coord.reg_i(3), src.comperator, {alu_last_instr, alu_write})); tex_op = TexInstruction::gather4_c; } auto sampler = get_samplerr_id(instr->sampler_index, src.sampler_deref); assert(!sampler.indirect && "Indirect sampler selection not yet supported"); bool literal_offset = false; if (src.offset) { literal_offset = nir_src_as_const_value(*src.offset) != 0; r600::sfn_log << SfnLog::tex << " really have offsets and they are " << (literal_offset ? "literal" : "varying") << "\n"; if (!literal_offset) { GPRVector::Swizzle swizzle = {4,4,4,4}; for (unsigned i = 0; i < instr->coord_components; ++i) swizzle[i] = i; int noffsets = instr->coord_components; if (instr->is_array) --noffsets; auto ofs = vec_from_nir_with_fetch_constant(*src.offset, ( 1 << noffsets) - 1, swizzle); GPRVector dummy(0, {7,7,7,7}); tex_op = (tex_op == TexInstruction::gather4_c) ? TexInstruction::gather4_c_o : TexInstruction::gather4_o; set_ofs = new TexInstruction(TexInstruction::set_offsets, dummy, ofs, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, src.sampler_offset); set_ofs->set_dest_swizzle({7,7,7,7}); } } /* pre CAYMAN needs swizzle */ auto dst = make_dest(*instr); auto irt = new TexInstruction(tex_op, dst, src.coord, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, src.sampler_offset); irt->set_dest_swizzle({1,2,0,3}); irt->set_gather_comp(instr->component); if (instr->is_array) handle_array_index(*instr, src.coord, irt); if (literal_offset) { r600::sfn_log << SfnLog::tex << "emit literal offsets\n"; set_offsets(irt, src.offset); } set_rect_coordinate_flags(instr, irt); if (set_ofs) emit_instruction(set_ofs); emit_instruction(irt); return true; } bool EmitTexInstruction::emit_cube_tg4(nir_tex_instr* instr, TexInputs& tex_src) { std::array v; for (int i = 0; i < 4; ++i) v[i] = from_nir(instr->dest, i); auto tex_op = TexInstruction::gather4; GPRVector cubed(v); emit_cube_prep(tex_src.coord, cubed, instr->is_array); std::array dst_elms; std::array src_elms; const uint16_t lookup[4] = {1, 0, 3, 2}; for (uint16_t i = 0; i < 4; ++i) { dst_elms[i] = v[i]; src_elms[i] = v[lookup[i]]; } if (instr->is_shadow) { emit_instruction(new AluInstruction(op1_mov, src_elms[3], tex_src.comperator, {alu_last_instr, alu_write})); tex_op = TexInstruction::gather4_c; } GPRVector dst(dst_elms); GPRVector src(src_elms); auto sampler = get_samplerr_id(instr->sampler_index, tex_src.sampler_deref); assert(!sampler.indirect && "Indirect sampler selection not yet supported"); auto tir = new TexInstruction(tex_op, dst, src, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, tex_src.sampler_offset); tir->set_gather_comp(instr->component); tir->set_dest_swizzle({1, 2, 0, 3}); if (instr->is_array) tir->set_flag(TexInstruction::z_unnormalized); emit_instruction(tir); return true; } bool EmitTexInstruction::emit_tex_txf_ms(nir_tex_instr* instr, TexInputs& src) { assert(instr->src[0].src.is_ssa); r600::sfn_log << SfnLog::instr << "emit '" << *reinterpret_cast(instr) << "' (" << __func__ << ")\n"; auto sampler = get_samplerr_id(instr->sampler_index, src.sampler_deref); assert(!sampler.indirect && "Indirect sampler selection not yet supported"); int sample_id = allocate_temp_register(); GPRVector sample_id_dest(sample_id, {0,7,7,7}); PValue help(new GPRValue(sample_id, 1)); /* FIXME: Texture destination registers must be handled differently, * because the swizzle identfies which source componnet has to be written * at a certain position, and the target register is actually different. * At this point we just add a helper register, but for later work (scheduling * and optimization on the r600 IR level, this needs to be implemented * differently */ emit_instruction(new AluInstruction(op1_mov, src.coord.reg_i(3), src.ms_index, {alu_write, alu_last_instr})); auto tex_sample_id_ir = new TexInstruction(TexInstruction::ld, sample_id_dest, src.coord, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, src.sampler_offset); tex_sample_id_ir->set_flag(TexInstruction::x_unnormalized); tex_sample_id_ir->set_flag(TexInstruction::y_unnormalized); tex_sample_id_ir->set_flag(TexInstruction::z_unnormalized); tex_sample_id_ir->set_flag(TexInstruction::w_unnormalized); tex_sample_id_ir->set_inst_mode(1); emit_instruction(tex_sample_id_ir); if (src.ms_index->type() != Value::literal || static_cast(*src.ms_index).value() != 0) { emit_instruction(new AluInstruction(op2_lshl_int, help, src.ms_index, literal(2), {alu_write, alu_last_instr})); emit_instruction(new AluInstruction(op2_lshr_int, sample_id_dest.reg_i(0), {sample_id_dest.reg_i(0), help}, {alu_write, alu_last_instr})); } emit_instruction(new AluInstruction(op2_and_int, src.coord.reg_i(3), {sample_id_dest.reg_i(0), PValue(new LiteralValue(15))}, {alu_write, alu_last_instr})); auto dst = make_dest(*instr); /* txf doesn't need rounding for the array index, but 1D has the array index * in the z component */ if (instr->is_array && instr->sampler_dim == GLSL_SAMPLER_DIM_1D) src.coord.set_reg_i(2, src.coord.reg_i(1)); auto tex_ir = new TexInstruction(TexInstruction::ld, dst, src.coord, sampler.id, sampler.id + R600_MAX_CONST_BUFFERS, src.sampler_offset); if (src.offset) { assert(src.offset->is_ssa); AluInstruction *ir = nullptr; for (unsigned i = 0; i < src.offset->ssa->num_components; ++i) { ir = new AluInstruction(op2_add_int, src.coord.reg_i(i), {src.coord.reg_i(i), from_nir(*src.offset, i, i)}, {alu_write}); emit_instruction(ir); } if (ir) ir->set_flag(alu_last_instr); } emit_instruction(tex_ir); return true; } bool EmitTexInstruction::get_inputs(const nir_tex_instr& instr, TexInputs &src) { sfn_log << SfnLog::tex << "Get Inputs with " << instr.coord_components << " components\n"; unsigned grad_components = instr.coord_components; if (instr.is_array) --grad_components; src.offset = nullptr; bool retval = true; for (unsigned i = 0; i < instr.num_srcs; ++i) { switch (instr.src[i].src_type) { case nir_tex_src_bias: src.bias = from_nir(instr.src[i], 0); break; case nir_tex_src_coord: { src.coord = vec_from_nir_with_fetch_constant(instr.src[i].src, (1 << instr.coord_components) - 1, {0,1,2,3}); } break; case nir_tex_src_comparator: src.comperator = from_nir(instr.src[i], 0); break; case nir_tex_src_ddx: { sfn_log << SfnLog::tex << "Get DDX "; src.ddx = vec_from_nir_with_fetch_constant(instr.src[i].src, (1 << grad_components) - 1, swizzle_from_comps(grad_components)); sfn_log << SfnLog::tex << src.ddx << "\n"; } break; case nir_tex_src_ddy:{ sfn_log << SfnLog::tex << "Get DDY "; src.ddy = vec_from_nir_with_fetch_constant(instr.src[i].src, (1 << grad_components) - 1, swizzle_from_comps(grad_components)); sfn_log << SfnLog::tex << src.ddy << "\n"; } break; case nir_tex_src_lod: src.lod = from_nir_with_fetch_constant(instr.src[i].src, 0); break; case nir_tex_src_offset: sfn_log << SfnLog::tex << " -- Find offset\n"; src.offset = &instr.src[i].src; break; case nir_tex_src_sampler_deref: src.sampler_deref = get_deref_location(instr.src[i].src); break; case nir_tex_src_texture_deref: src.texture_deref = get_deref_location(instr.src[i].src); break; case nir_tex_src_ms_index: src.ms_index = from_nir(instr.src[i], 0); break; case nir_tex_src_texture_offset: src.texture_offset = from_nir(instr.src[i], 0); break; case nir_tex_src_sampler_offset: src.sampler_offset = from_nir(instr.src[i], 0); break; case nir_tex_src_plane: case nir_tex_src_projector: case nir_tex_src_min_lod: case nir_tex_src_ms_mcs: default: sfn_log << SfnLog::tex << "Texture source type " << instr.src[i].src_type << " not supported\n"; retval = false; } } return retval; } GPRVector EmitTexInstruction::make_dest(nir_tex_instr& instr) { int num_dest_components = instr.dest.is_ssa ? instr.dest.ssa.num_components : instr.dest.reg.reg->num_components; std::array dst_elms; for (uint16_t i = 0; i < 4; ++i) dst_elms[i] = from_nir(instr.dest, (i < num_dest_components) ? i : 7); return GPRVector(dst_elms); } GPRVector EmitTexInstruction::make_dest(nir_tex_instr& instr, const std::array& swizzle) { int num_dest_components = instr.dest.is_ssa ? instr.dest.ssa.num_components : instr.dest.reg.reg->num_components; std::array dst_elms; for (uint16_t i = 0; i < 4; ++i) { int k = swizzle[i]; dst_elms[i] = from_nir(instr.dest, (k < num_dest_components) ? k : 7); } return GPRVector(dst_elms); } void EmitTexInstruction::set_rect_coordinate_flags(nir_tex_instr* instr, TexInstruction* ir) const { if (instr->sampler_dim == GLSL_SAMPLER_DIM_RECT) { ir->set_flag(TexInstruction::x_unnormalized); ir->set_flag(TexInstruction::y_unnormalized); } } void EmitTexInstruction::set_offsets(TexInstruction* ir, nir_src *offset) { if (!offset) return; assert(offset->is_ssa); auto literal = nir_src_as_const_value(*offset); assert(literal); for (int i = 0; i < offset->ssa->num_components; ++i) { ir->set_offset(i, literal[i].i32); } } void EmitTexInstruction::handle_array_index(const nir_tex_instr& instr, const GPRVector& src, TexInstruction *ir) { int src_idx = instr.sampler_dim == GLSL_SAMPLER_DIM_1D ? 1 : 2; emit_instruction(new AluInstruction(op1_rndne, src.reg_i(2), src.reg_i(src_idx), {alu_last_instr, alu_write})); ir->set_flag(TexInstruction::z_unnormalized); } EmitTexInstruction::SamplerId EmitTexInstruction::get_samplerr_id(int sampler_id, const nir_variable *deref) { EmitTexInstruction::SamplerId result = {sampler_id, false}; if (deref) { assert(glsl_type_is_sampler(deref->type)); result.id = deref->data.binding; } return result; } EmitTexInstruction::TexInputs::TexInputs(): sampler_deref(nullptr), texture_deref(nullptr), offset(nullptr) { } }