/* * Copyright (C) 2014-2018 Advanced Micro Devices, Inc. All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * 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 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 "IsaGenerator_Gfx72.hpp" #include #include const std::string IsaGenerator_Gfx72::ASIC_NAME = "CI"; const uint32_t IsaGenerator_Gfx72::NOOP_ISA[] = { 0xbf810000 // S_ENDPGM }; /* The below arrays are filled with hex values in order not to reference * proprietary header files, but we still leave the code here for future * reference. */ #if 0 const uint32_t IsaGenerator_Gfx72::COPY_DWORD_ISA[] = { (63u << SQ_VOP1__ENCODING__SHIFT) | (0 << SQ_VOP1__VDST__SHIFT) | (SQ_V_MOV_B32 << SQ_VOP1__OP__SHIFT) | (0 << SQ_VOP1__SRC0__SHIFT), // v_mov_b32 v0, s0 (VOP1) (63u << SQ_VOP1__ENCODING__SHIFT) | (1 << SQ_VOP1__VDST__SHIFT) | (SQ_V_MOV_B32 << SQ_VOP1__OP__SHIFT) | (1 << SQ_VOP1__SRC0__SHIFT), // v_mov_b32 v1, s1 (VOP1) (63u << SQ_VOP1__ENCODING__SHIFT) | (2 << SQ_VOP1__VDST__SHIFT) | (SQ_V_MOV_B32 << SQ_VOP1__OP__SHIFT) | (2 << SQ_VOP1__SRC0__SHIFT), // v_mov_b32 v2, s2 (VOP1) (63u << SQ_VOP1__ENCODING__SHIFT) | (3 << SQ_VOP1__VDST__SHIFT) | (SQ_V_MOV_B32 << SQ_VOP1__OP__SHIFT) | (3 << SQ_VOP1__SRC0__SHIFT), // v_mov_b32 v3, s3 (VOP1) (55u << SQ_FLAT_0__ENCODING__SHIFT) | (SQ_FLAT_LOAD_DWORD << SQ_FLAT_0__OP__SHIFT) | (1 << SQ_FLAT_0__SLC__SHIFT) | (1 << SQ_FLAT_0__GLC__SHIFT)/*(3 << 16)*/, // SQ_FLAT_0, flat_load_dword, slc = 1, glc = 1 (FLAT_0) (4u << SQ_FLAT_1__VDST__SHIFT) | (0 << SQ_FLAT_1__ADDR__SHIFT), // ADDR = V0:V1, VDST = V4 (FLAT_1) (383u << SQ_SOPP__ENCODING__SHIFT) | (SQ_S_WAITCNT << SQ_SOPP__OP__SHIFT) | (0 << SQ_SOPP__SIMM16__SHIFT), // s_waitcnt 0 (SOPP) (55u << SQ_FLAT_0__ENCODING__SHIFT) | (SQ_FLAT_STORE_DWORD << SQ_FLAT_0__OP__SHIFT) | (1 << SQ_FLAT_0__SLC__SHIFT) | (1 << SQ_FLAT_0__GLC__SHIFT), // SQ_FLAT_0, flat_store_dword, slc = 1, glc = 1 (FLAT_0) (4u << SQ_FLAT_1__DATA__SHIFT) | (2 << SQ_FLAT_1__ADDR__SHIFT), // ADDR = V2:V3, DATA = V4 (FLAT_1) 0xBF810000u // s_endpgm, note that we rely on the implicit s_waitcnt 0,0,0 }; const uint32_t IsaGenerator_Gfx72::INFINITE_LOOP_ISA[] = { (0x17F << SQ_SOPP__ENCODING__SHIFT) | (SQ_S_BRANCH << SQ_SOPP__OP__SHIFT) | ( (const uint32_t)-1 << SQ_SOPP__SIMM16__SHIFT), // s_branch -1 (PC <- PC + SIMM*4)+4 0xBF810000u // S_ENDPGM }; const uint32_t IsaGenerator_Gfx72::ATOMIC_INC_ISA[] = { (63u << SQ_VOP1__ENCODING__SHIFT) | (0 << SQ_VOP1__VDST__SHIFT) | (SQ_V_MOV_B32 << SQ_VOP1__OP__SHIFT) | (0 << SQ_VOP1__SRC0__SHIFT), // v_mov_b32 v0, s0 (VOP1) (63u << SQ_VOP1__ENCODING__SHIFT) | (1 << SQ_VOP1__VDST__SHIFT) | (SQ_V_MOV_B32 << SQ_VOP1__OP__SHIFT) | (1 << SQ_VOP1__SRC0__SHIFT), // v_mov_b32 v1, s1 (VOP1) (63u << SQ_VOP1__ENCODING__SHIFT) | (2 << SQ_VOP1__VDST__SHIFT) | (SQ_V_MOV_B32 << SQ_VOP1__OP__SHIFT) | (0xC1 << SQ_VOP1__SRC0__SHIFT), // v_mov_b32 0xFFFFFFFF, s2 (VOP1) (55u << SQ_FLAT_0__ENCODING__SHIFT) | (SQ_FLAT_ATOMIC_INC << SQ_FLAT_0__OP__SHIFT) | (1 << SQ_FLAT_0__SLC__SHIFT) | (0 << SQ_FLAT_0__GLC__SHIFT), // SQ_FLAT_0, flat_atomic_inc, slc = 1, glc = 0 (FLAT_0) (3u << SQ_FLAT_1__VDST__SHIFT) | (2u << SQ_FLAT_1__DATA__SHIFT) | (0 << SQ_FLAT_1__ADDR__SHIFT), // ADDR/dst = V0:V1, VDST/ret = V3, DATA/src=V2 (FLAT_1) 0xBF810000u // s_endpgm, note that we rely on the implicit s_waitcnt 0,0,0 }; #endif const uint32_t IsaGenerator_Gfx72::COPY_DWORD_ISA[] = { 0x7e000200, // v_mov_b32 v0, s0 (VOP1) 0x7e020201, // v_mov_b32 v1, s1 (VOP1) 0x7e040202, // v_mov_b32 v2, s2 (VOP1) 0x7e060203, // v_mov_b32 v3, s3 (VOP1) 0xdc330000, // SQ_FLAT_0, flat_load_dword, slc = 1, glc = 1 (FLAT_0) 0x04000000, // ADDR = V0:V1, VDST = V4 (FLAT_1) 0xbf8c0000, // s_waitcnt 0 (SOPP) 0xdc730000, // SQ_FLAT_0, flat_store_dword, slc = 1, glc = 1 (FLAT_0) 0x00000402, // ADDR = V2:V3, DATA = V4 (FLAT_1) 0xbf810000 // s_endpgm, note that we rely on the implicit s_waitcnt 0,0,0 }; const uint32_t IsaGenerator_Gfx72::INFINITE_LOOP_ISA[] = { 0xbf82ffff, // s_branch -1 (PC <- PC + SIMM*4)+4 0xbf810000 // S_ENDPGM }; const uint32_t IsaGenerator_Gfx72::ATOMIC_INC_ISA[] = { 0x7e000200, // v_mov_b32 v0, s0 (VOP1) 0x7e020201, // v_mov_b32 v1, s1 (VOP1) 0x7e0402c1, // v_mov_b32 0xFFFFFFFF, s2 (VOP1) 0xdcf20000, // SQ_FLAT_0, flat_atomic_inc, slc = 1, glc = 0 (FLAT_0) 0x03000200, // ADDR/dst = V0:V1, VDST/ret = V3, DATA/src=V2 (FLAT_1) 0xbf810000 // s_endpgm, note that we rely on the implicit s_waitcnt 0,0,0 }; void IsaGenerator_Gfx72::GetNoopIsa(HsaMemoryBuffer& rBuf) { std::copy(NOOP_ISA, NOOP_ISA+ARRAY_SIZE(NOOP_ISA), rBuf.As()); } void IsaGenerator_Gfx72::GetCopyDwordIsa(HsaMemoryBuffer& rBuf) { std::copy(COPY_DWORD_ISA, COPY_DWORD_ISA+ARRAY_SIZE(COPY_DWORD_ISA), rBuf.As()); } void IsaGenerator_Gfx72::GetInfiniteLoopIsa(HsaMemoryBuffer& rBuf) { std::copy(INFINITE_LOOP_ISA, INFINITE_LOOP_ISA+ARRAY_SIZE(INFINITE_LOOP_ISA), rBuf.As()); } void IsaGenerator_Gfx72::GetAtomicIncIsa(HsaMemoryBuffer& rBuf) { std::copy(ATOMIC_INC_ISA, ATOMIC_INC_ISA+ARRAY_SIZE(ATOMIC_INC_ISA), rBuf.As()); } const std::string& IsaGenerator_Gfx72::GetAsicName() { return ASIC_NAME; }