/* * Copyright © 2020 Valve Corporation * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (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 NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS 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 "helpers.h" #include using namespace aco; BEGIN_TEST(validate.sdwa.allow) for (unsigned i = GFX8; i <= GFX10; i++) { //>> v1: %a, v1: %b, s1: %c, s1: %d = p_startpgm if (!setup_cs("v1 v1 s1 s1", (chip_class)i)) continue; //>> Validation results: //! Validation passed SDWA_instruction *sdwa = &bld.vop2_sdwa(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]).instr->sdwa(); sdwa->neg[0] = sdwa->neg[1] = sdwa->abs[0] = sdwa->abs[1] = true; sdwa = &bld.vop2_sdwa(aco_opcode::v_mul_f32, bld.def(v1b), inputs[0], inputs[1]).instr->sdwa(); sdwa = &bld.vop2_sdwa(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]).instr->sdwa(); sdwa->sel[0] = SubdwordSel::sbyte2; sdwa->sel[1] = SubdwordSel::uword1; finish_validator_test(); } END_TEST BEGIN_TEST(validate.sdwa.support) for (unsigned i = GFX7; i <= GFX10; i++) { //>> v1: %a, v1: %b, s1: %c, s1: %d = p_startpgm if (!setup_cs("v1 v1 s1 s1", (chip_class)i)) continue; //>> Validation results: //~gfx7! SDWA is GFX8+ only: v1: %t0 = v_mul_f32 %a, %b dst_sel:dword src0_sel:dword src1_sel:dword //~gfx7! Validation failed //~gfx([89]|10)! Validation passed bld.vop2_sdwa(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]); finish_validator_test(); } END_TEST BEGIN_TEST(validate.sdwa.operands) for (unsigned i = GFX8; i <= GFX10; i++) { //>> v1: %vgpr0, v1: %vgp1, s1: %sgpr0, s1: %sgpr1 = p_startpgm if (!setup_cs("v1 v1 s1 s1", (chip_class)i)) continue; //>> Validation results: //~gfx8! Wrong source position for SGPR argument: v1: %_ = v_mul_f32 %sgpr0, %vgpr1 dst_sel:dword src0_sel:dword src1_sel:dword //~gfx8! Wrong source position for SGPR argument: v1: %_ = v_mul_f32 %vgpr0, %sgpr1 dst_sel:dword src0_sel:dword src1_sel:dword bld.vop2_sdwa(aco_opcode::v_mul_f32, bld.def(v1), inputs[2], inputs[1]); bld.vop2_sdwa(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[3]); //~gfx8! Wrong source position for constant argument: v1: %_ = v_mul_f32 4, %vgpr1 dst_sel:dword src0_sel:dword src1_sel:dword //~gfx8! Wrong source position for constant argument: v1: %_ = v_mul_f32 %vgpr0, 4 dst_sel:dword src0_sel:dword src1_sel:dword bld.vop2_sdwa(aco_opcode::v_mul_f32, bld.def(v1), Operand::c32(4u), inputs[1]); bld.vop2_sdwa(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], Operand::c32(4u)); //! Literal applied on wrong instruction format: v1: %_ = v_mul_f32 0x1234, %vgpr1 dst_sel:dword src0_sel:dword src1_sel:dword //! Literal applied on wrong instruction format: v1: %_ = v_mul_f32 %vgpr0, 0x1234 dst_sel:dword src0_sel:dword src1_sel:dword //! Wrong source position for Literal argument: v1: %_ = v_mul_f32 %vgpr0, 0x1234 dst_sel:dword src0_sel:dword src1_sel:dword bld.vop2_sdwa(aco_opcode::v_mul_f32, bld.def(v1), Operand::c32(0x1234u), inputs[1]); bld.vop2_sdwa(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], Operand::c32(0x1234u)); //! Validation failed finish_validator_test(); } END_TEST BEGIN_TEST(validate.sdwa.vopc) for (unsigned i = GFX8; i <= GFX10; i++) { //>> v1: %vgpr0, v1: %vgp1, s1: %sgpr0, s1: %sgpr1 = p_startpgm if (!setup_cs("v1 v1 s1 s1", (chip_class)i)) continue; //>> Validation results: bld.vopc_sdwa(aco_opcode::v_cmp_gt_f32, bld.def(bld.lm, vcc), inputs[0], inputs[1]); //~gfx8! SDWA+VOPC definition must be fixed to vcc on GFX8: s2: %_ = v_cmp_lt_f32 %vgpr0, %vgpr1 src0_sel:dword src1_sel:dword bld.vopc_sdwa(aco_opcode::v_cmp_lt_f32, bld.def(bld.lm), inputs[0], inputs[1]); //~gfx(9|10)! SDWA VOPC clamp only supported on GFX8: s2: %_:vcc = v_cmp_eq_f32 %vgpr0, %vgpr1 clamp src0_sel:dword src1_sel:dword bld.vopc_sdwa(aco_opcode::v_cmp_eq_f32, bld.def(bld.lm, vcc), inputs[0], inputs[1]).instr->sdwa().clamp = true; //! Validation failed finish_validator_test(); } END_TEST BEGIN_TEST(validate.sdwa.omod) for (unsigned i = GFX8; i <= GFX10; i++) { //>> v1: %vgpr0, v1: %vgp1, s1: %sgpr0, s1: %sgpr1 = p_startpgm if (!setup_cs("v1 v1 s1 s1", (chip_class)i)) continue; //>> Validation results: //~gfx8! SDWA omod only supported on GFX9+: v1: %_ = v_mul_f32 %vgpr0, %vgpr1 *2 dst_sel:dword src0_sel:dword src1_sel:dword //~gfx8! Validation failed //~gfx(9|10)! Validation passed bld.vop2_sdwa(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]).instr->sdwa().omod = 1; finish_validator_test(); } END_TEST BEGIN_TEST(validate.sdwa.vcc) for (unsigned i = GFX8; i <= GFX10; i++) { //>> v1: %vgpr0, v1: %vgpr1, s2: %sgpr0 = p_startpgm if (!setup_cs("v1 v1 s2", (chip_class)i)) continue; //>> Validation results: //! 3rd operand must be fixed to vcc with SDWA: v1: %_ = v_cndmask_b32 %vgpr0, %vgpr1, %_ dst_sel:dword src0_sel:dword src1_sel:dword bld.vop2_sdwa(aco_opcode::v_cndmask_b32, bld.def(v1), inputs[0], inputs[1], inputs[2]); bld.vop2_sdwa(aco_opcode::v_cndmask_b32, bld.def(v1), inputs[0], inputs[1], bld.vcc(inputs[2])); //! 2nd definition must be fixed to vcc with SDWA: v1: %_, s2: %_ = v_add_co_u32 %vgpr0, %vgpr1 dst_sel:dword src0_sel:dword src1_sel:dword bld.vop2_sdwa(aco_opcode::v_add_co_u32, bld.def(v1), bld.def(bld.lm), inputs[0], inputs[1]); bld.vop2_sdwa(aco_opcode::v_add_co_u32, bld.def(v1), bld.def(bld.lm, vcc), inputs[0], inputs[1]); //! Validation failed finish_validator_test(); } END_TEST BEGIN_TEST(optimize.sdwa.extract) for (unsigned i = GFX7; i <= GFX10; i++) { for (unsigned is_signed = 0; is_signed <= 1; is_signed++) { //>> v1: %a, v1: %b, s1: %c, s1: %d = p_startpgm if (!setup_cs("v1 v1 s1 s1", (chip_class)i, CHIP_UNKNOWN, is_signed ? "_signed" : "_unsigned")) continue; //; def standard_test(index, sel): //; res = 'v1: %%res%s = v_mul_f32 %%a, %%b dst_sel:dword src0_sel:dword src1_sel:%c%s\n' % (index, 's' if variant.endswith('_signed') else 'u', sel) //; res += 'p_unit_test %s, %%res%s' % (index, index) //; return res //; funcs['standard_test'] = lambda a: standard_test(*(v for v in a.split(','))) aco_opcode ext = aco_opcode::p_extract; aco_opcode ins = aco_opcode::p_insert; { //~gfx[^7].*! @standard_test(0,byte0) Temp bfe_byte0_b = bld.pseudo(ext, bld.def(v1), inputs[1], Operand::zero(), Operand::c32(8u), Operand::c32(is_signed)); writeout(0, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], bfe_byte0_b)); //~gfx[^7].*! @standard_test(1,byte1) Temp bfe_byte1_b = bld.pseudo(ext, bld.def(v1), inputs[1], Operand::c32(1u), Operand::c32(8u), Operand::c32(is_signed)); writeout(1, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], bfe_byte1_b)); //~gfx[^7].*! @standard_test(2,byte2) Temp bfe_byte2_b = bld.pseudo(ext, bld.def(v1), inputs[1], Operand::c32(2u), Operand::c32(8u), Operand::c32(is_signed)); writeout(2, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], bfe_byte2_b)); //~gfx[^7].*! @standard_test(3,byte3) Temp bfe_byte3_b = bld.pseudo(ext, bld.def(v1), inputs[1], Operand::c32(3u), Operand::c32(8u), Operand::c32(is_signed)); writeout(3, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], bfe_byte3_b)); //~gfx[^7].*! @standard_test(4,word0) Temp bfe_word0_b = bld.pseudo(ext, bld.def(v1), inputs[1], Operand::zero(), Operand::c32(16u), Operand::c32(is_signed)); writeout(4, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], bfe_word0_b)); //~gfx[^7].*! @standard_test(5,word1) Temp bfe_word1_b = bld.pseudo(ext, bld.def(v1), inputs[1], Operand::c32(1u), Operand::c32(16u), Operand::c32(is_signed)); writeout(5, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], bfe_word1_b)); //~gfx[^7]_unsigned! @standard_test(6,byte0) Temp bfi_byte0_b = bld.pseudo(ins, bld.def(v1), inputs[1], Operand::zero(), Operand::c32(8u)); writeout(6, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], bfi_byte0_b)); //~gfx[^7]_unsigned! @standard_test(7,word0) Temp bfi_word0_b = bld.pseudo(ins, bld.def(v1), inputs[1], Operand::zero(), Operand::c32(16u)); writeout(7, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], bfi_word0_b)); } //>> p_unit_test 63 writeout(63); { //! v1: %tmp8 = p_insert %b, 1, 8 //! v1: %res8 = v_mul_f32 %a, %tmp8 //! p_unit_test 8, %res8 Temp bfi_byte1_b = bld.pseudo(ins, bld.def(v1), inputs[1], Operand::c32(1u), Operand::c32(8u)); writeout(8, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], bfi_byte1_b)); /* v_cvt_f32_ubyte[0-3] can be used instead of v_cvt_f32_u32+sdwa */ //~gfx7_signed! v1: %bfe_byte0_b = p_extract %b, 0, 8, 1 //~gfx7_signed! v1: %res9 = v_cvt_f32_u32 %bfe_byte0_b //~gfx[^7]+_signed! v1: %res9 = v_cvt_f32_u32 %b dst_sel:dword src0_sel:sbyte0 //~gfx\d+_unsigned! v1: %res9 = v_cvt_f32_ubyte0 %b //! p_unit_test 9, %res9 Temp bfe_byte0_b = bld.pseudo(ext, bld.def(v1), inputs[1], Operand::zero(), Operand::c32(8u), Operand::c32(is_signed)); writeout(9, bld.vop1(aco_opcode::v_cvt_f32_u32, bld.def(v1), bfe_byte0_b)); //~gfx7_signed! v1: %bfe_byte1_b = p_extract %b, 1, 8, 1 //~gfx7_signed! v1: %res10 = v_cvt_f32_u32 %bfe_byte1_b //~gfx[^7]+_signed! v1: %res10 = v_cvt_f32_u32 %b dst_sel:dword src0_sel:sbyte1 //~gfx\d+_unsigned! v1: %res10 = v_cvt_f32_ubyte1 %b //! p_unit_test 10, %res10 Temp bfe_byte1_b = bld.pseudo(ext, bld.def(v1), inputs[1], Operand::c32(1u), Operand::c32(8u), Operand::c32(is_signed)); writeout(10, bld.vop1(aco_opcode::v_cvt_f32_u32, bld.def(v1), bfe_byte1_b)); //~gfx7_signed! v1: %bfe_byte2_b = p_extract %b, 2, 8, 1 //~gfx7_signed! v1: %res11 = v_cvt_f32_u32 %bfe_byte2_b //~gfx[^7]+_signed! v1: %res11 = v_cvt_f32_u32 %b dst_sel:dword src0_sel:sbyte2 //~gfx\d+_unsigned! v1: %res11 = v_cvt_f32_ubyte2 %b //! p_unit_test 11, %res11 Temp bfe_byte2_b = bld.pseudo(ext, bld.def(v1), inputs[1], Operand::c32(2u), Operand::c32(8u), Operand::c32(is_signed)); writeout(11, bld.vop1(aco_opcode::v_cvt_f32_u32, bld.def(v1), bfe_byte2_b)); //~gfx7_signed! v1: %bfe_byte3_b = p_extract %b, 3, 8, 1 //~gfx7_signed! v1: %res12 = v_cvt_f32_u32 %bfe_byte3_b //~gfx[^7]+_signed! v1: %res12 = v_cvt_f32_u32 %b dst_sel:dword src0_sel:sbyte3 //~gfx\d+_unsigned! v1: %res12 = v_cvt_f32_ubyte3 %b //! p_unit_test 12, %res12 Temp bfe_byte3_b = bld.pseudo(ext, bld.def(v1), inputs[1], Operand::c32(3u), Operand::c32(8u), Operand::c32(is_signed)); writeout(12, bld.vop1(aco_opcode::v_cvt_f32_u32, bld.def(v1), bfe_byte3_b)); //! v1: %res13 = v_add_i16 %a, %b //! p_unit_test 13, %res13 Temp bfe_word0_b = bld.pseudo(ext, bld.def(v1), inputs[1], Operand::zero(), Operand::c32(16u), Operand::c32(is_signed)); writeout(13, bld.vop3(aco_opcode::v_add_i16, bld.def(v1), inputs[0], bfe_word0_b)); /* VOP3-only instructions can't use SDWA but they can use opsel instead */ //~gfx(9|10).*! v1: %res14 = v_add_i16 %a, hi(%b) //~gfx(9|10).*! p_unit_test 14, %res14 Temp bfe_word1_b = bld.pseudo(ext, bld.def(v1), inputs[1], Operand::c32(1u), Operand::c32(16u), Operand::c32(is_signed)); writeout(14, bld.vop3(aco_opcode::v_add_i16, bld.def(v1), inputs[0], bfe_word1_b)); } finish_opt_test(); } } END_TEST BEGIN_TEST(optimize.sdwa.extract_modifiers) for (unsigned i = GFX8; i <= GFX10; i++) { //>> v1: %a, v1: %b, s1: %c, s1: %d = p_startpgm if (!setup_cs("v1 v1 s1 s1", (chip_class)i)) continue; aco_opcode ext = aco_opcode::p_extract; //! v1: %res0 = v_mul_f32 %a, -%b dst_sel:dword src0_sel:dword src1_sel:ubyte0 //! p_unit_test 0, %res0 Temp byte0 = bld.pseudo(ext, bld.def(v1), inputs[1], Operand::zero(), Operand::c32(8u), Operand::zero()); Temp neg_byte0 = fneg(byte0); writeout(0, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], neg_byte0)); //~gfx8! v1: %neg = v_mul_f32 -1.0, %b //~gfx8! v1: %res1 = v_mul_f32 %a, %neg dst_sel:dword src0_sel:dword src1_sel:ubyte0 //~gfx(9|10)! v1: %neg_byte0 = v_mul_f32 -1.0, %b dst_sel:ubyte0 src0_sel:dword src1_sel:dword //~gfx(9|10)! v1: %res1 = v_mul_f32 %a, %neg_byte0 //! p_unit_test 1, %res1 Temp neg = fneg(inputs[1]); Temp byte0_neg = bld.pseudo(ext, bld.def(v1), neg, Operand::zero(), Operand::c32(8u), Operand::zero()); writeout(1, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], byte0_neg)); //! v1: %res2 = v_mul_f32 %a, |%b| dst_sel:dword src0_sel:dword src1_sel:ubyte0 //! p_unit_test 2, %res2 Temp abs_byte0 = fabs(byte0); writeout(2, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], abs_byte0)); //! v1: %abs = v_mul_f32 1.0, |%b| //! v1: %res3 = v_mul_f32 %a, %abs dst_sel:dword src0_sel:dword src1_sel:ubyte0 //! p_unit_test 3, %res3 Temp abs = fabs(inputs[1]); Temp byte0_abs = bld.pseudo(ext, bld.def(v1), abs, Operand::zero(), Operand::c32(8u), Operand::zero()); writeout(3, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], byte0_abs)); //! v1: %res4 = v_mul_f32 %1, -|%2| dst_sel:dword src0_sel:dword src1_sel:ubyte0 //! p_unit_test 4, %res4 Temp neg_abs_byte0 = fneg(abs_byte0); writeout(4, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], neg_abs_byte0)); //~gfx8! v1: %neg_abs = v_mul_f32 -1.0, %abs //~gfx8! v1: %res5 = v_mul_f32 %a, %neg_abs dst_sel:dword src0_sel:dword src1_sel:ubyte0 //~gfx(9|10)! v1: %neg_abs_byte0 = v_mul_f32 -1.0, %abs dst_sel:ubyte0 src0_sel:dword src1_sel:dword //~gfx(9|10)! v1: %res5 = v_mul_f32 %a, %neg_abs_byte0 //! p_unit_test 5, %res5 Temp neg_abs = fneg(abs); Temp byte0_neg_abs = bld.pseudo(ext, bld.def(v1), neg_abs, Operand::zero(), Operand::c32(8u), Operand::zero()); writeout(5, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], byte0_neg_abs)); finish_opt_test(); } END_TEST BEGIN_TEST(optimize.sdwa.extract.sgpr) for (unsigned i = GFX8; i <= GFX10; i++) { //>> v1: %a, v1: %b, s1: %c, s1: %d = p_startpgm if (!setup_cs("v1 v1 s1 s1", (chip_class)i)) continue; aco_opcode ext = aco_opcode::p_extract; //~gfx8! v1: %byte0_b = p_extract %b, 0, 8, 0 //~gfx8! v1: %res1 = v_mul_f32 %c, %byte0_b //~gfx(9|10)! v1: %res1 = v_mul_f32 %c, %b dst_sel:dword src0_sel:dword src1_sel:ubyte0 //! p_unit_test 1, %res1 Temp byte0_b = bld.pseudo(ext, bld.def(v1), inputs[1], Operand::zero(), Operand::c32(8u), Operand::zero()); writeout(1, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[2], byte0_b)); //~gfx8! v1: %byte0_c = p_extract %c, 0, 8, 0 //~gfx8! v1: %res2 = v_mul_f32 %a, %byte0_c //~gfx(9|10)! v1: %res2 = v_mul_f32 %a, %c dst_sel:dword src0_sel:dword src1_sel:ubyte0 //! p_unit_test 2, %res2 Temp byte0_c = bld.pseudo(ext, bld.def(v1), inputs[2], Operand::zero(), Operand::c32(8u), Operand::zero()); writeout(2, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], byte0_c)); //~gfx8! v1: %byte0_c_2 = p_extract %c, 0, 8, 0 //~gfx8! v1: %res3 = v_mul_f32 %c, %byte0_c_2 //~gfx(9|10)! v1: %res3 = v_mul_f32 %c, %c dst_sel:dword src0_sel:dword src1_sel:ubyte0 //! p_unit_test 3, %res3 byte0_c = bld.pseudo(ext, bld.def(v1), inputs[2], Operand::zero(), Operand::c32(8u), Operand::zero()); writeout(3, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[2], byte0_c)); //~gfx(8|9)! v1: %byte0_c_3 = p_extract %c, 0, 8, 0 //~gfx(8|9)! v1: %res4 = v_mul_f32 %d, %byte0_c_3 //~gfx10! v1: %res4 = v_mul_f32 %d, %c dst_sel:dword src0_sel:dword src1_sel:ubyte0 //! p_unit_test 4, %res4 byte0_c = bld.pseudo(ext, bld.def(v1), inputs[2], Operand::zero(), Operand::c32(8u), Operand::zero()); writeout(4, bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[3], byte0_c)); finish_opt_test(); } END_TEST BEGIN_TEST(optimize.sdwa.from_vop3) for (unsigned i = GFX8; i <= GFX10; i++) { //>> v1: %a, v1: %b, s1: %c, s1: %d = p_startpgm if (!setup_cs("v1 v1 s1 s1", (chip_class)i)) continue; //! v1: %res0 = v_mul_f32 -|%a|, %b dst_sel:dword src0_sel:dword src1_sel:ubyte0 //! p_unit_test 0, %res0 Temp byte0_b = bld.pseudo(aco_opcode::p_extract, bld.def(v1), inputs[1], Operand::zero(), Operand::c32(8u), Operand::zero()); VOP3_instruction *mul = &bld.vop2_e64(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], byte0_b).instr->vop3(); mul->neg[0] = true; mul->abs[0] = true; writeout(0, mul->definitions[0].getTemp()); //~gfx8! v1: %byte0_b_0 = p_extract %b, 0, 8, 0 //~gfx8! v1: %res1 = v_mul_f32 %a, %byte0_b_0 *4 //~gfx(9|10)! v1: %res1 = v_mul_f32 %a, %b *4 dst_sel:dword src0_sel:dword src1_sel:ubyte0 //! p_unit_test 1, %res1 byte0_b = bld.pseudo(aco_opcode::p_extract, bld.def(v1), inputs[1], Operand::zero(), Operand::c32(8u), Operand::zero()); mul = &bld.vop2_e64(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], byte0_b).instr->vop3(); mul->omod = 2; writeout(1, mul->definitions[0].getTemp()); //~gfx8! v1: %byte0_b_1 = p_extract %b, 0, 8, 0 //~gfx8! v1: %res2 = v_mul_f32 %byte0_b_1, %c //~gfx(9|10)! v1: %res2 = v_mul_f32 %b, %c dst_sel:dword src0_sel:ubyte0 src1_sel:dword //! p_unit_test 2, %res2 byte0_b = bld.pseudo(aco_opcode::p_extract, bld.def(v1), inputs[1], Operand::zero(), Operand::c32(8u), Operand::zero()); writeout(2, bld.vop2_e64(aco_opcode::v_mul_f32, bld.def(v1), byte0_b, inputs[2])); if (i >= GFX10) { //~gfx10! v1: %byte0_b_2 = p_extract %b, 0, 8, 0 //~gfx10! v1: %res3 = v_mul_f32 %byte0_b_2, 0x1234 //~gfx10! p_unit_test 3, %res3 byte0_b = bld.pseudo(aco_opcode::p_extract, bld.def(v1), inputs[1], Operand::zero(), Operand::c32(8u), Operand::zero()); writeout(3, bld.vop2_e64(aco_opcode::v_mul_f32, bld.def(v1), byte0_b, Operand::c32(0x1234u))); } finish_opt_test(); } END_TEST BEGIN_TEST(optimize.sdwa.insert) for (unsigned i = GFX7; i <= GFX10; i++) { //>> v1: %a, v1: %b = p_startpgm if (!setup_cs("v1 v1", (chip_class)i)) continue; aco_opcode ext = aco_opcode::p_extract; aco_opcode ins = aco_opcode::p_insert; //~gfx[^7]! v1: %res0 = v_mul_f32 %a, %b dst_sel:ubyte0 src0_sel:dword src1_sel:dword //~gfx[^7]! p_unit_test 0, %res0 Temp val = bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]); writeout(0, bld.pseudo(ins, bld.def(v1), val, Operand::zero(), Operand::c32(8u))); //~gfx[^7]! v1: %res1 = v_mul_f32 %a, %b dst_sel:ubyte1 src0_sel:dword src1_sel:dword //~gfx[^7]! p_unit_test 1, %res1 val = bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]); writeout(1, bld.pseudo(ins, bld.def(v1), val, Operand::c32(1u), Operand::c32(8u))); //~gfx[^7]! v1: %res2 = v_mul_f32 %a, %b dst_sel:ubyte2 src0_sel:dword src1_sel:dword //~gfx[^7]! p_unit_test 2, %res2 val = bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]); writeout(2, bld.pseudo(ins, bld.def(v1), val, Operand::c32(2u), Operand::c32(8u))); //~gfx[^7]! v1: %res3 = v_mul_f32 %a, %b dst_sel:ubyte3 src0_sel:dword src1_sel:dword //~gfx[^7]! p_unit_test 3, %res3 val = bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]); writeout(3, bld.pseudo(ins, bld.def(v1), val, Operand::c32(3u), Operand::c32(8u))); //~gfx[^7]! v1: %res4 = v_mul_f32 %a, %b dst_sel:uword0 src0_sel:dword src1_sel:dword //~gfx[^7]! p_unit_test 4, %res4 val = bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]); writeout(4, bld.pseudo(ins, bld.def(v1), val, Operand::zero(), Operand::c32(16u))); //~gfx[^7]! v1: %res5 = v_mul_f32 %a, %b dst_sel:uword1 src0_sel:dword src1_sel:dword //~gfx[^7]! p_unit_test 5, %res5 val = bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]); writeout(5, bld.pseudo(ins, bld.def(v1), val, Operand::c32(1u), Operand::c32(16u))); //~gfx[^7]! v1: %res6 = v_mul_f32 %a, %b dst_sel:ubyte0 src0_sel:dword src1_sel:dword //~gfx[^7]! p_unit_test 6, %res6 val = bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]); writeout( 6, bld.pseudo(ext, bld.def(v1), val, Operand::zero(), Operand::c32(8u), Operand::zero())); //~gfx[^7]! v1: %res7 = v_mul_f32 %a, %b dst_sel:uword0 src0_sel:dword src1_sel:dword //~gfx[^7]! p_unit_test 7, %res7 val = bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]); writeout( 7, bld.pseudo(ext, bld.def(v1), val, Operand::zero(), Operand::c32(16u), Operand::zero())); //~gfx[^7]! v1: %tmp8 = v_mul_f32 %a, %b //~gfx[^7]! v1: %res8 = p_extract %tmp8, 2, 8, 0 //~gfx[^7]! p_unit_test 8, %res8 val = bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]); writeout( 8, bld.pseudo(ext, bld.def(v1), val, Operand::c32(2u), Operand::c32(8u), Operand::zero())); //~gfx[^7]! v1: %tmp9 = v_mul_f32 %a, %b //~gfx[^7]! v1: %res9 = p_extract %tmp9, 0, 8, 1 //~gfx[^7]! p_unit_test 9, %res9 val = bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]); writeout( 9, bld.pseudo(ext, bld.def(v1), val, Operand::zero(), Operand::c32(8u), Operand::c32(1u))); //>> p_unit_test 63 writeout(63); //! v1: %res10 = v_mul_f32 %a, %b //! p_unit_test 10, %res10 val = bld.vop2(aco_opcode::v_mul_f32, bld.def(v1), inputs[0], inputs[1]); bld.pseudo(ins, bld.def(v1), val, Operand::c32(1u), Operand::c32(16u)); writeout(10, val); //! v1: %res11 = v_sub_i16 %a, %b //! p_unit_test 11, %res11 val = bld.vop3(aco_opcode::v_sub_i16, bld.def(v1), inputs[0], inputs[1]); writeout(11, bld.pseudo(ins, bld.def(v1), val, Operand::zero(), Operand::c32(16u))); //~gfx[78]! v1: %tmp12 = v_sub_i16 %a, %b //~gfx[78]! v1: %res12 = p_insert %tmp11, 1, 16 //~gfx(9|10)! v1: %res12 = v_sub_i16 %a, %b opsel_hi //! p_unit_test 12, %res12 val = bld.vop3(aco_opcode::v_sub_i16, bld.def(v1), inputs[0], inputs[1]); writeout(12, bld.pseudo(ins, bld.def(v1), val, Operand::c32(1u), Operand::c32(16u))); //! v1: %tmp13 = v_sub_i16 %a, %b //! v1: %res13 = p_insert %tmp13, 0, 8 //! p_unit_test 13, %res13 val = bld.vop3(aco_opcode::v_sub_i16, bld.def(v1), inputs[0], inputs[1]); writeout(13, bld.pseudo(ins, bld.def(v1), val, Operand::zero(), Operand::c32(8u))); finish_opt_test(); } END_TEST BEGIN_TEST(optimize.sdwa.insert_modifiers) for (unsigned i = GFX8; i <= GFX9; i++) { //>> v1: %a = p_startpgm if (!setup_cs("v1", (chip_class)i)) continue; aco_opcode ins = aco_opcode::p_insert; //~gfx8! v1: %tmp0 = v_rcp_f32 %a *2 //~gfx8! v1: %res0 = p_insert %tmp0, 0, 8 //~gfx9! v1: %res0 = v_rcp_f32 %a *2 dst_sel:ubyte0 src0_sel:dword //! p_unit_test 0, %res0 Temp val = bld.vop1(aco_opcode::v_rcp_f32, bld.def(v1), inputs[0]); val = bld.vop2_e64(aco_opcode::v_mul_f32, bld.def(v1), val, Operand::c32(0x40000000u)); writeout(0, bld.pseudo(ins, bld.def(v1), val, Operand::zero(), Operand::c32(8u))); //! v1: %res1 = v_rcp_f32 %a clamp dst_sel:ubyte0 src0_sel:dword //! p_unit_test 1, %res1 val = bld.vop1(aco_opcode::v_rcp_f32, bld.def(v1), inputs[0]); val = bld.vop3(aco_opcode::v_med3_f32, bld.def(v1), val, Operand::zero(), Operand::c32(0x3f800000u)); writeout(1, bld.pseudo(ins, bld.def(v1), val, Operand::zero(), Operand::c32(8u))); //! v1: %tmp2 = v_rcp_f32 %a dst_sel:ubyte0 src0_sel:dword //! v1: %res2 = v_mul_f32 %tmp2, 2.0 //! p_unit_test 2, %res2 val = bld.vop1(aco_opcode::v_rcp_f32, bld.def(v1), inputs[0]); val = bld.pseudo(ins, bld.def(v1), val, Operand::zero(), Operand::c32(8u)); val = bld.vop2_e64(aco_opcode::v_mul_f32, bld.def(v1), val, Operand::c32(0x40000000u)); writeout(2, val); //! v1: %tmp3 = v_rcp_f32 %a dst_sel:ubyte0 src0_sel:dword //! v1: %res3 = v_med3_f32 %tmp3, 0, 1.0 //! p_unit_test 3, %res3 val = bld.vop1(aco_opcode::v_rcp_f32, bld.def(v1), inputs[0]); val = bld.pseudo(ins, bld.def(v1), val, Operand::zero(), Operand::c32(8u)); val = bld.vop3(aco_opcode::v_med3_f32, bld.def(v1), val, Operand::zero(), Operand::c32(0x3f800000u)); writeout(3, val); //~gfx8! v1: %tmp4 = v_rcp_f32 %a *2 clamp //~gfx8! v1: %res4 = p_insert %tmp4, 0, 8 //~gfx9! v1: %res4 = v_rcp_f32 %a *2 clamp dst_sel:ubyte0 src0_sel:dword //! p_unit_test 4, %res4 val = bld.vop1(aco_opcode::v_rcp_f32, bld.def(v1), inputs[0]); val = bld.vop2_e64(aco_opcode::v_mul_f32, bld.def(v1), val, Operand::c32(0x40000000u)); val = bld.vop3(aco_opcode::v_med3_f32, bld.def(v1), val, Operand::zero(), Operand::c32(0x3f800000u)); writeout(4, bld.pseudo(ins, bld.def(v1), val, Operand::zero(), Operand::c32(8u))); finish_opt_test(); } END_TEST