/* * Copyright © 2014 Intel 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. */ /** * @file * * A representation of i965 EU assembly instructions, with helper methods to * get and set various fields. This is the actual hardware format. */ #ifndef BRW_INST_H #define BRW_INST_H #include #include #include "brw_eu_defines.h" #include "brw_isa_info.h" #include "brw_reg_type.h" #include "dev/intel_device_info.h" #ifdef __cplusplus extern "C" { #endif /* brw_context.h has a forward declaration of brw_inst, so name the struct. */ typedef struct brw_inst { uint64_t data[2]; } brw_inst; static inline uint64_t brw_inst_bits(const brw_inst *inst, unsigned high, unsigned low); static inline void brw_inst_set_bits(brw_inst *inst, unsigned high, unsigned low, uint64_t value); #define FC(name, hi9, lo9, hi12, lo12, assertions) \ static inline void \ brw_inst_set_##name(const struct intel_device_info *devinfo, \ brw_inst *inst, uint64_t v) \ { \ assert(assertions); \ if (devinfo->ver >= 12) \ brw_inst_set_bits(inst, hi12, lo12, v); \ else \ brw_inst_set_bits(inst, hi9, lo9, v); \ } \ static inline uint64_t \ brw_inst_##name(const struct intel_device_info *devinfo, \ const brw_inst *inst) \ { \ assert(assertions); \ if (devinfo->ver >= 12) \ return brw_inst_bits(inst, hi12, lo12); \ else \ return brw_inst_bits(inst, hi9, lo9); \ } /* A simple macro for fields which stay in the same place on all generations, * except for Gfx12! */ #define F(name, hi9, lo9, hi12, lo12) FC(name, hi9, lo9, hi12, lo12, true) /* A simple macro for fields which stay in the same place on all generations, * except for Gfx12 and Gfx20. */ #define F20(name, hi9, lo9, hi12, lo12, hi20, lo20) \ static inline void \ brw_inst_set_##name(const struct intel_device_info *devinfo, \ brw_inst *inst, uint64_t v) \ { \ if (devinfo->ver >= 20) \ brw_inst_set_bits(inst, hi20, lo20, v); \ else if (devinfo->ver >= 12) \ brw_inst_set_bits(inst, hi12, lo12, v); \ else \ brw_inst_set_bits(inst, hi9, lo9, v); \ } \ static inline uint64_t \ brw_inst_##name(const struct intel_device_info *devinfo, \ const brw_inst *inst) \ { \ if (devinfo->ver >= 20) \ return brw_inst_bits(inst, hi20, lo20); \ else if (devinfo->ver >= 12) \ return brw_inst_bits(inst, hi12, lo12); \ else \ return brw_inst_bits(inst, hi9, lo9); \ } #define FV20(name, hi9, lo9, hi12, lo12, hi20, lo20) \ static inline void \ brw_inst_set_##name(const struct intel_device_info *devinfo, \ brw_inst *inst, uint64_t v) \ { \ if (devinfo->ver >= 20) \ brw_inst_set_bits(inst, hi20, lo20, v & 0x7); \ else if (devinfo->ver >= 12) \ brw_inst_set_bits(inst, hi12, lo12, v); \ else \ brw_inst_set_bits(inst, hi9, lo9, v); \ } \ static inline uint64_t \ brw_inst_##name(const struct intel_device_info *devinfo, \ const brw_inst *inst) \ { \ if (devinfo->ver >= 20) \ return brw_inst_bits(inst, hi20, lo20) == 0x7 ? 0xF : \ brw_inst_bits(inst, hi20, lo20); \ else if (devinfo->ver >= 12) \ return brw_inst_bits(inst, hi12, lo12); \ else \ return brw_inst_bits(inst, hi9, lo9); \ } #define FD20(name, hi9, lo9, hi12, lo12, hi20, lo20, zero20) \ static inline void \ brw_inst_set_##name(const struct intel_device_info *devinfo, \ brw_inst *inst, uint64_t v) \ { \ if (devinfo->ver >= 20) { \ brw_inst_set_bits(inst, hi20, lo20, v >> 1); \ if (zero20 == -1) \ assert((v & 1) == 0); \ else \ brw_inst_set_bits(inst, zero20, zero20, v & 1); \ } else if (devinfo->ver >= 12) \ brw_inst_set_bits(inst, hi12, lo12, v); \ else \ brw_inst_set_bits(inst, hi9, lo9, v); \ } \ static inline uint64_t \ brw_inst_##name(const struct intel_device_info *devinfo, \ const brw_inst *inst) \ { \ if (devinfo->ver >= 20) \ return (brw_inst_bits(inst, hi20, lo20) << 1) | \ (zero20 == -1 ? 0 : \ brw_inst_bits(inst, zero20, zero20)); \ else if (devinfo->ver >= 12) \ return brw_inst_bits(inst, hi12, lo12); \ else \ return brw_inst_bits(inst, hi9, lo9); \ } /* Macro for fields that gained extra discontiguous MSBs in Gfx12 (specified * by hi12ex-lo12ex). */ #define FFDC(name, hi9, lo9, hi12ex, lo12ex, hi12, lo12, assertions) \ static inline void \ brw_inst_set_##name(const struct intel_device_info *devinfo, \ brw_inst *inst, uint64_t value) \ { \ assert(assertions); \ if (devinfo->ver >= 12) { \ const unsigned k = hi12 - lo12 + 1; \ if (hi12ex != -1 && lo12ex != -1) \ brw_inst_set_bits(inst, hi12ex, lo12ex, value >> k); \ brw_inst_set_bits(inst, hi12, lo12, value & ((1ull << k) - 1)); \ } else { \ brw_inst_set_bits(inst, hi9, lo9, value); \ } \ } \ static inline uint64_t \ brw_inst_##name(const struct intel_device_info *devinfo, const brw_inst *inst)\ { \ assert(assertions); \ if (devinfo->ver >= 12) { \ const unsigned k = hi12 - lo12 + 1; \ return (hi12ex == -1 || lo12ex == -1 ? 0 : \ brw_inst_bits(inst, hi12ex, lo12ex) << k) | \ brw_inst_bits(inst, hi12, lo12); \ } else { \ return brw_inst_bits(inst, hi9, lo9); \ } \ } #define FD(name, hi9, lo9, hi12ex, lo12ex, hi12, lo12) \ FFDC(name, hi9, lo9, hi12ex, lo12ex, hi12, lo12, true) /* Macro for fields that didn't move across generations until Gfx12, and then * gained extra discontiguous bits. */ #define FDC(name, hi9, lo9, hi12ex, lo12ex, hi12, lo12, assertions) \ FFDC(name, hi9, lo9, hi12ex, lo12ex, hi12, lo12, assertions) static inline uint64_t brw_reg_file_to_hw_reg_file(enum brw_reg_file file) { switch (file) { case ARF: return 0x0; case FIXED_GRF: return 0x1; default: /* Fallthrough. */ case IMM: return 0x3; } } static inline enum brw_reg_file hw_reg_file_to_brw_reg_file(uint64_t v) { switch (v) { case 0x0: return ARF; case 0x1: return FIXED_GRF; default: return IMM; } } /* Macro for storing register file field. See variant FF below for no * assertions. * * In Gfx12+, either a single bit is available (ARF or GRF) or two bits are * available. In that case the register file is stored as the variable length * combination of an IsImm (hi12) bit and an additional file (lo12) bit. * * For some instructions in Gfx11, the encoding uses 0 for GRF, and 1 for * either ARF (for accumulator) or IMM. */ #define FFC(name, hi9, lo9, hi12, lo12, assertions, ...) \ static inline void \ brw_inst_set_##name(const struct intel_device_info *devinfo, \ brw_inst *inst, enum brw_reg_file file) \ { \ assert(assertions); \ const struct { \ bool _; /* Exists to avoid empty initializer. */ \ bool grf_or_imm; \ bool grf_or_acc; \ } args = { ._ = false, __VA_ARGS__ }; \ uint64_t value = brw_reg_file_to_hw_reg_file(file); \ if (devinfo->ver < 12) { \ if (devinfo->ver == 11 && args.grf_or_imm) { \ assert(file == FIXED_GRF || file == IMM); \ value = file == FIXED_GRF ? 0 : 1; \ } else if (devinfo->ver == 11 && args.grf_or_acc) { \ assert(file == FIXED_GRF || file == ARF); \ value = file == FIXED_GRF ? 0 : 1; \ } \ brw_inst_set_bits(inst, hi9, lo9, value); \ } else if (hi12 == lo12) { \ brw_inst_set_bits(inst, hi12, lo12, value); \ } else { \ brw_inst_set_bits(inst, hi12, hi12, value >> 1); \ if ((value >> 1) == 0) \ brw_inst_set_bits(inst, lo12, lo12, value & 1); \ } \ } \ static inline uint64_t \ brw_inst_##name(const struct intel_device_info *devinfo, const brw_inst *inst)\ { \ assert(assertions); \ const struct { \ bool _; /* Exists to avoid empty initializer. */ \ bool grf_or_imm; \ bool grf_or_acc; \ } args = { ._ = false, __VA_ARGS__ }; \ uint64_t value; \ if (devinfo->ver < 12) { \ value = brw_inst_bits(inst, hi9, lo9); \ if (devinfo->ver == 11 && args.grf_or_imm) \ return value ? IMM : FIXED_GRF; \ else if (devinfo->ver == 11 && args.grf_or_acc) \ return value ? ARF : FIXED_GRF; \ } else if (hi12 == lo12) { \ value = brw_inst_bits(inst, hi12, lo12); \ } else { \ value = (brw_inst_bits(inst, hi12, hi12) << 1) | \ (brw_inst_bits(inst, hi12, hi12) == 0 ? \ brw_inst_bits(inst, lo12, lo12) : 1); \ } \ return hw_reg_file_to_brw_reg_file(value); \ } #define FF(name, hi9, lo9, hi12, lo12, ...) FFC(name, hi9, lo9, hi12, lo12, true, __VA_ARGS__) /* Macro for fields that become a constant in Gfx12+ not actually represented * in the instruction. */ #define FK(name, hi9, lo9, const12) \ static inline void \ brw_inst_set_##name(const struct intel_device_info *devinfo, \ brw_inst *inst, uint64_t v) \ { \ if (devinfo->ver >= 12) \ assert(v == (const12)); \ else \ brw_inst_set_bits(inst, hi9, lo9, v); \ } \ static inline uint64_t \ brw_inst_##name(const struct intel_device_info *devinfo, \ const brw_inst *inst) \ { \ if (devinfo->ver >= 12) \ return (const12); \ else \ return brw_inst_bits(inst, hi9, lo9); \ } FV20(src1_vstride, /* 9+ */ 120, 117, /* 12+ */ 119, 116, /* 20+ */ 118, 116) F(src1_width, /* 9+ */ 116, 114, /* 12+ */ 115, 113) F(src1_da16_swiz_w, /* 9+ */ 115, 114, /* 12+ */ -1, -1) F(src1_da16_swiz_z, /* 9+ */ 113, 112, /* 12+ */ -1, -1) F(src1_hstride, /* 9+ */ 113, 112, /* 12+ */ 97, 96) F(src1_address_mode, /* 9+ */ 111, 111, /* 12+ */ 112, 112) /** Src1.SrcMod @{ */ F(src1_negate, /* 9+ */ 110, 110, /* 12+ */ 121, 121) F(src1_abs, /* 9+ */ 109, 109, /* 12+ */ 120, 120) /** @} */ F(src1_ia_subreg_nr, /* 9+ */ 108, 105, /* 12+ */ 111, 108) F(src1_da_reg_nr, /* 9+ */ 108, 101, /* 12+ */ 111, 104) F(src1_da16_subreg_nr, /* 9+ */ 100, 100, /* 12+ */ -1, -1) FD20(src1_da1_subreg_nr, /* 9+ */ 100, 96, /* 12+ */ 103, 99, /* 20+ */ 103, 99, -1) F(src1_da16_swiz_y, /* 9+ */ 99, 98, /* 12+ */ -1, -1) F(src1_da16_swiz_x, /* 9+ */ 97, 96, /* 12+ */ -1, -1) F(src1_reg_hw_type, /* 9+ */ 94, 91, /* 12+ */ 91, 88) FF(src1_reg_file, /* 9+ */ 90, 89, /* 12+ */ 47, 98) F(src1_is_imm, /* 9+ */ -1, -1, /* 12+ */ 47, 47) FV20(src0_vstride, /* 9+ */ 88, 85, /* 12+ */ 87, 84, /* 20+ */ 86, 84) F(src0_width, /* 9+ */ 84, 82, /* 12+ */ 83, 81) F(src0_da16_swiz_w, /* 9+ */ 83, 82, /* 12+ */ -1, -1) F(src0_da16_swiz_z, /* 9+ */ 81, 80, /* 12+ */ -1, -1) F(src0_hstride, /* 9+ */ 81, 80, /* 12+ */ 65, 64) F(src0_address_mode, /* 9+ */ 79, 79, /* 12+ */ 80, 80) /** Src0.SrcMod @{ */ F(src0_negate, /* 9+ */ 78, 78, /* 12+ */ 45, 45) F(src0_abs, /* 9+ */ 77, 77, /* 12+ */ 44, 44) /** @} */ F(src0_ia_subreg_nr, /* 9+ */ 76, 73, /* 12+ */ 79, 76) F(src0_da_reg_nr, /* 9+ */ 76, 69, /* 12+ */ 79, 72) F(src0_da16_subreg_nr, /* 9+ */ 68, 68, /* 12+ */ -1, -1) FD20(src0_da1_subreg_nr, /* 9+ */ 68, 64, /* 12+ */ 71, 67, /* 20+ */ 71, 67, 87) F(src0_da16_swiz_y, /* 9+ */ 67, 66, /* 12+ */ -1, -1) F(src0_da16_swiz_x, /* 9+ */ 65, 64, /* 12+ */ -1, -1) F(dst_address_mode, /* 9+ */ 63, 63, /* 12+ */ 35, 35) F(dst_hstride, /* 9+ */ 62, 61, /* 12+ */ 49, 48) F(dst_ia_subreg_nr, /* 9+ */ 60, 57, /* 12+ */ 63, 60) F(dst_da_reg_nr, /* 9+ */ 60, 53, /* 12+ */ 63, 56) F(dst_da16_subreg_nr, /* 9+ */ 52, 52, /* 12+ */ -1, -1) FD20(dst_da1_subreg_nr, /* 9+ */ 52, 48, /* 12+ */ 55, 51, /* 20+ */ 55, 51, 33) F(da16_writemask, /* 9+ */ 51, 48, /* 12+ */ -1, -1) /* Dst.ChanEn */ F(src0_reg_hw_type, /* 9+ */ 46, 43, /* 12+ */ 43, 40) FF(src0_reg_file, /* 9+ */ 42, 41, /* 12+ */ 46, 66) F(src0_is_imm, /* 9+ */ -1, -1, /* 12+ */ 46, 46) F(dst_reg_hw_type, /* 9+ */ 40, 37, /* 12+ */ 39, 36) FF(dst_reg_file, /* 9+ */ 36, 35, /* 12+ */ 50, 50) F(mask_control, /* 9+ */ 34, 34, /* 12+ */ 31, 31) F20(flag_reg_nr, /* 9+ */ 33, 33, /* 12+ */ 23, 23, /* 20+ */ 23, 22) F20(flag_subreg_nr, /* 9+ */ 32, 32, /* 12+ */ 22, 22, /* 20+ */ 21, 21) F(saturate, /* 9+ */ 31, 31, /* 12+ */ 34, 34) F(debug_control, /* 9+ */ 30, 30, /* 12+ */ 30, 30) F(cmpt_control, /* 9+ */ 29, 29, /* 12+ */ 29, 29) F(branch_control, /* 9+ */ 28, 28, /* 12+ */ 33, 33) FC(acc_wr_control, /* 9+ */ 28, 28, /* 12+ */ 33, 33, devinfo->ver < 20) F(cond_modifier, /* 9+ */ 27, 24, /* 12+ */ 95, 92) F(math_function, /* 9+ */ 27, 24, /* 12+ */ 95, 92) F20(exec_size, /* 9+ */ 23, 21, /* 12+ */ 18, 16, /* 20+ */ 20, 18) F(pred_inv, /* 9+ */ 20, 20, /* 12+ */ 28, 28) F20(pred_control, /* 9+ */ 19, 16, /* 12+ */ 27, 24, /* 20+ */ 27, 26) F(thread_control, /* 9+ */ 15, 14, /* 12+ */ -1, -1) F(atomic_control, /* 9+ */ -1, -1, /* 12+ */ 32, 32) F20(qtr_control, /* 9+ */ 13, 12, /* 12+ */ 21, 20, /* 20+ */ 25, 24) F20(nib_control, /* 9+ */ 11, 11, /* 12+ */ 19, 19, /* 20+ */ -1, -1) F(no_dd_check, /* 9+ */ 10, 10, /* 12+ */ -1, -1) F(no_dd_clear, /* 9+ */ 9, 9, /* 12+ */ -1, -1) F20(swsb, /* 9+ */ -1, -1, /* 12+ */ 15, 8, /* 20+ */ 17, 8) FK(access_mode, /* 9+ */ 8, 8, /* 12+ */ BRW_ALIGN_1) /* Bit 7 is Reserved (for future Opcode expansion) */ F(hw_opcode, /* 9+ */ 6, 0, /* 12+ */ 6, 0) /** * Three-source instructions: * @{ */ F(3src_src2_reg_nr, /* 9+ */ 125, 118, /* 12+ */ 127, 120) /* same in align1 */ F(3src_a16_src2_subreg_nr, /* 9+ */ 117, 115, /* 12+ */ -1, -1) /* Extra discontiguous bit on CHV? */ F(3src_a16_src2_swizzle, /* 9+ */ 114, 107, /* 12+ */ -1, -1) F(3src_a16_src2_rep_ctrl, /* 9+ */ 106, 106, /* 12+ */ -1, -1) F(3src_src1_reg_nr, /* 9+ */ 104, 97, /* 12+ */ 111, 104) /* same in align1 */ F(3src_a16_src1_subreg_nr, /* 9+ */ 96, 94, /* 12+ */ -1, -1) /* Extra discontiguous bit on CHV? */ F(3src_a16_src1_swizzle, /* 9+ */ 93, 86, /* 12+ */ -1, -1) F(3src_a16_src1_rep_ctrl, /* 9+ */ 85, 85, /* 12+ */ -1, -1) F(3src_src0_reg_nr, /* 9+ */ 83, 76, /* 12+ */ 79, 72) /* same in align1 */ F(3src_a16_src0_subreg_nr, /* 9+ */ 75, 73, /* 12+ */ -1, -1) /* Extra discontiguous bit on CHV? */ F(3src_a16_src0_swizzle, /* 9+ */ 72, 65, /* 12+ */ -1, -1) F(3src_a16_src0_rep_ctrl, /* 9+ */ 64, 64, /* 12+ */ -1, -1) F(3src_dst_reg_nr, /* 9+ */ 63, 56, /* 12+ */ 63, 56) /* same in align1 */ F(3src_a16_dst_subreg_nr, /* 9+ */ 55, 53, /* 12+ */ -1, -1) F(3src_a16_dst_writemask, /* 9+ */ 52, 49, /* 12+ */ -1, -1) F(3src_a16_nib_ctrl, /* 9+ */ 11, 11, /* 12+ */ -1, -1) /* only exists on IVB+ */ F(3src_a16_dst_hw_type, /* 9+ */ 48, 46, /* 12+ */ -1, -1) /* only exists on IVB+ */ F(3src_a16_src_hw_type, /* 9+ */ 45, 43, /* 12+ */ -1, -1) F(3src_src2_negate, /* 9+ */ 42, 42, /* 12+ */ 85, 85) F(3src_src2_abs, /* 9+ */ 41, 41, /* 12+ */ 84, 84) F(3src_src1_negate, /* 9+ */ 40, 40, /* 12+ */ 87, 87) F(3src_src1_abs, /* 9+ */ 39, 39, /* 12+ */ 86, 86) F(3src_src0_negate, /* 9+ */ 38, 38, /* 12+ */ 45, 45) F(3src_src0_abs, /* 9+ */ 37, 37, /* 12+ */ 44, 44) F(3src_a16_src1_type, /* 9+ */ 36, 36, /* 12+ */ -1, -1) F(3src_a16_src2_type, /* 9+ */ 35, 35, /* 12+ */ -1, -1) F(3src_a16_flag_reg_nr, /* 9+ */ 33, 33, /* 12+ */ -1, -1) F(3src_a16_flag_subreg_nr, /* 9+ */ 32, 32, /* 12+ */ -1, -1) F(3src_saturate, /* 9+ */ 31, 31, /* 12+ */ 34, 34) F(3src_debug_control, /* 9+ */ 30, 30, /* 12+ */ 30, 30) F(3src_cmpt_control, /* 9+ */ 29, 29, /* 12+ */ 29, 29) FC(3src_acc_wr_control, /* 9+ */ 28, 28, /* 12+ */ 33, 33, devinfo->ver < 20) F(3src_cond_modifier, /* 9+ */ 27, 24, /* 12+ */ 95, 92) F(3src_exec_size, /* 9+ */ 23, 21, /* 12+ */ 18, 16) F(3src_pred_inv, /* 9+ */ 20, 20, /* 12+ */ 28, 28) F20(3src_pred_control, /* 9+ */ 19, 16, /* 12+ */ 27, 24, /* 20+ */ 27, 26) F(3src_thread_control, /* 9+ */ 15, 14, /* 12+ */ -1, -1) F(3src_atomic_control, /* 9+ */ -1, -1, /* 12+ */ 32, 32) F20(3src_qtr_control, /* 9+ */ 13, 12, /* 12+ */ 21, 20, /* 20+ */ 25, 24) F(3src_no_dd_check, /* 9+ */ 10, 10, /* 12+ */ -1, -1) F(3src_no_dd_clear, /* 9+ */ 9, 9, /* 12+ */ -1, -1) F(3src_mask_control, /* 9+ */ 34, 34, /* 12+ */ 31, 31) FK(3src_access_mode, /* 9+ */ 8, 8, /* 12+ */ BRW_ALIGN_1) F(3src_swsb, /* 9+ */ -1, -1, /* 12+ */ 15, 8) /* Bit 7 is Reserved (for future Opcode expansion) */ F(3src_hw_opcode, /* 9+ */ 6, 0, /* 12+ */ 6, 0) /** @} */ #define REG_TYPE(reg) \ static inline void \ brw_inst_set_3src_a16_##reg##_type(const struct intel_device_info *devinfo, \ brw_inst *inst, enum brw_reg_type type) \ { \ unsigned hw_type = brw_type_encode_for_3src(devinfo, type); \ brw_inst_set_3src_a16_##reg##_hw_type(devinfo, inst, hw_type); \ } \ \ static inline enum brw_reg_type \ brw_inst_3src_a16_##reg##_type(const struct intel_device_info *devinfo, \ const brw_inst *inst) \ { \ unsigned hw_type = brw_inst_3src_a16_##reg##_hw_type(devinfo, inst); \ return brw_type_decode_for_3src(devinfo, hw_type, 0); \ } REG_TYPE(dst) REG_TYPE(src) #undef REG_TYPE /** * Three-source align1 instructions: * @{ */ /* Reserved 127:126 */ /* src2_reg_nr same in align16 */ FD20(3src_a1_src2_subreg_nr,/* 9+ */ 117, 113, /* 12+ */ 119, 115, /* 20+ */ 119, 115, -1) FC(3src_a1_src2_hstride, /* 9+ */ 112, 111, /* 12+ */ 113, 112, devinfo->ver >= 10) /* Reserved 110:109. src2 vstride is an implied parameter */ FC(3src_a1_src2_hw_type, /* 9+ */ 108, 106, /* 12+ */ 82, 80, devinfo->ver >= 10) /* Reserved 105 */ /* src1_reg_nr same in align16 */ FD20(3src_a1_src1_subreg_nr, /* 9+ */ 96, 92, /* 12+ */ 103, 99, /* 20+ */ 103, 99, -1) FC(3src_a1_src1_hstride, /* 9+ */ 91, 90, /* 12+ */ 97, 96, devinfo->ver >= 10) FDC(3src_a1_src1_vstride, /* 9+ */ 89, 88, /* 12+ */ 91, 91, 83, 83, devinfo->ver >= 10) FC(3src_a1_src1_hw_type, /* 9+ */ 87, 85, /* 12+ */ 90, 88, devinfo->ver >= 10) /* Reserved 84 */ /* src0_reg_nr same in align16 */ FD20(3src_a1_src0_subreg_nr, /* 9+ */ 75, 71, /* 12+ */ 71, 67, /* 20+ */ 71, 67, -1) FC(3src_a1_src0_hstride, /* 9+ */ 70, 69, /* 12+ */ 65, 64, devinfo->ver >= 10) FDC(3src_a1_src0_vstride, /* 9+ */ 68, 67, /* 12+ */ 43, 43, 35, 35, devinfo->ver >= 10) FC(3src_a1_src0_hw_type, /* 9+ */ 66, 64, /* 12+ */ 42, 40, devinfo->ver >= 10) /* dst_reg_nr same in align16 */ FC(3src_a1_dst_subreg_nr, /* 9+ */ 55, 54, /* 12+ */ 55, 54, devinfo->ver >= 10) FC(3src_a1_special_acc, /* 9+ */ 55, 52, /* 12+ */ 54, 51, devinfo->ver >= 10) /* aliases dst_subreg_nr */ /* Reserved 51:50 */ FC(3src_a1_dst_hstride, /* 9+ */ 49, 49, /* 12+ */ 48, 48, devinfo->ver >= 10) FC(3src_a1_dst_hw_type, /* 9+ */ 48, 46, /* 12+ */ 38, 36, devinfo->ver >= 10) FF(3src_a1_src2_reg_file, /* 9+ */ 45, 45, /* 12+ */ 47, 114, .grf_or_imm = true) FFC(3src_a1_src1_reg_file, /* 9+ */ 44, 44, /* 12+ */ 98, 98, devinfo->ver >= 10, .grf_or_acc = true) FF(3src_a1_src0_reg_file, /* 9+ */ 43, 43, /* 12+ */ 46, 66, .grf_or_imm = true) F(3src_a1_src2_is_imm, /* 9+ */ -1, -1, /* 12+ */ 47, 47) F(3src_a1_src0_is_imm, /* 9+ */ -1, -1, /* 12+ */ 46, 46) /* Source Modifier fields same in align16 */ FFC(3src_a1_dst_reg_file, /* 9+ */ 36, 36, /* 12+ */ 50, 50, devinfo->ver >= 10, .grf_or_acc = true) FC(3src_a1_exec_type, /* 9+ */ 35, 35, /* 12+ */ 39, 39, devinfo->ver >= 10) /* Fields below this same in align16 */ /** @} */ #define REG_TYPE(reg) \ static inline void \ brw_inst_set_3src_a1_##reg##_type(const struct intel_device_info *devinfo, \ brw_inst *inst, enum brw_reg_type type) \ { \ UNUSED enum gfx10_align1_3src_exec_type exec_type = \ (enum gfx10_align1_3src_exec_type) brw_inst_3src_a1_exec_type(devinfo, \ inst); \ if (brw_type_is_float(type)) { \ assert(exec_type == BRW_ALIGN1_3SRC_EXEC_TYPE_FLOAT); \ } else { \ assert(exec_type == BRW_ALIGN1_3SRC_EXEC_TYPE_INT); \ } \ unsigned hw_type = brw_type_encode_for_3src(devinfo, type); \ brw_inst_set_3src_a1_##reg##_hw_type(devinfo, inst, hw_type); \ } \ \ static inline enum brw_reg_type \ brw_inst_3src_a1_##reg##_type(const struct intel_device_info *devinfo, \ const brw_inst *inst) \ { \ enum gfx10_align1_3src_exec_type exec_type = \ (enum gfx10_align1_3src_exec_type) brw_inst_3src_a1_exec_type(devinfo, \ inst); \ unsigned hw_type = brw_inst_3src_a1_##reg##_hw_type(devinfo, inst); \ return brw_type_decode_for_3src(devinfo, hw_type, exec_type); \ } REG_TYPE(dst) REG_TYPE(src0) REG_TYPE(src1) REG_TYPE(src2) #undef REG_TYPE /** * Three-source align1 instruction immediates: * @{ */ static inline uint16_t brw_inst_3src_a1_src0_imm(ASSERTED const struct intel_device_info *devinfo, const brw_inst *insn) { assert(devinfo->ver >= 10); if (devinfo->ver >= 12) return brw_inst_bits(insn, 79, 64); else return brw_inst_bits(insn, 82, 67); } static inline uint16_t brw_inst_3src_a1_src2_imm(ASSERTED const struct intel_device_info *devinfo, const brw_inst *insn) { assert(devinfo->ver >= 10); if (devinfo->ver >= 12) return brw_inst_bits(insn, 127, 112); else return brw_inst_bits(insn, 124, 109); } static inline void brw_inst_set_3src_a1_src0_imm(ASSERTED const struct intel_device_info *devinfo, brw_inst *insn, uint16_t value) { assert(devinfo->ver >= 10); if (devinfo->ver >= 12) brw_inst_set_bits(insn, 79, 64, value); else brw_inst_set_bits(insn, 82, 67, value); } static inline void brw_inst_set_3src_a1_src2_imm(ASSERTED const struct intel_device_info *devinfo, brw_inst *insn, uint16_t value) { assert(devinfo->ver >= 10); if (devinfo->ver >= 12) brw_inst_set_bits(insn, 127, 112, value); else brw_inst_set_bits(insn, 124, 109, value); } /** @} */ /** * Three-source systolic instructions: * @{ */ F(dpas_3src_src2_reg_nr, /* 9+ */ -1, -1, /* 12+ */ 127, 120) F(dpas_3src_src2_subreg_nr, /* 9+ */ -1, -1, /* 12+ */ 119, 115) FF(dpas_3src_src2_reg_file, /* 9+ */ -1, -1, /* 12+ */ 114, 114) F(dpas_3src_src1_reg_nr, /* 9+ */ -1, -1, /* 12+ */ 111, 104) F(dpas_3src_src1_subreg_nr, /* 9+ */ -1, -1, /* 12+ */ 103, 99) FF(dpas_3src_src1_reg_file, /* 9+ */ -1, -1, /* 12+ */ 98, 98) F(dpas_3src_src1_hw_type, /* 9+ */ -1, -1, /* 12+ */ 90, 88) F(dpas_3src_src1_subbyte, /* 9+ */ -1, -1, /* 12+ */ 87, 86) F(dpas_3src_src2_subbyte, /* 9+ */ -1, -1, /* 12+ */ 85, 84) F(dpas_3src_src2_hw_type, /* 9+ */ -1, -1, /* 12+ */ 82, 80) F(dpas_3src_src0_reg_nr, /* 9+ */ -1, -1, /* 12+ */ 79, 72) F(dpas_3src_src0_subreg_nr, /* 9+ */ -1, -1, /* 12+ */ 71, 67) FF(dpas_3src_src0_reg_file, /* 9+ */ -1, -1, /* 12+ */ 66, 66) F(dpas_3src_dst_reg_nr, /* 9+ */ -1, -1, /* 12+ */ 63, 56) F(dpas_3src_dst_subreg_nr, /* 9+ */ -1, -1, /* 12+ */ 55, 51) FF(dpas_3src_dst_reg_file, /* 9+ */ -1, -1, /* 12+ */ 50, 50) F(dpas_3src_sdepth, /* 9+ */ -1, -1, /* 12+ */ 49, 48) F(dpas_3src_rcount, /* 9+ */ -1, -1, /* 12+ */ 45, 43) F(dpas_3src_src0_hw_type, /* 9+ */ -1, -1, /* 12+ */ 42, 40) F(dpas_3src_exec_type, /* 9+ */ -1, -1, /* 12+ */ 39, 39) F(dpas_3src_dst_hw_type, /* 9+ */ -1, -1, /* 12+ */ 38, 36) /** @} */ #define REG_TYPE(reg) \ static inline void \ brw_inst_set_dpas_3src_##reg##_type(const struct intel_device_info *devinfo, \ brw_inst *inst, enum brw_reg_type type) \ { \ UNUSED enum gfx10_align1_3src_exec_type exec_type = \ (enum gfx10_align1_3src_exec_type) brw_inst_dpas_3src_exec_type(devinfo,\ inst); \ if (brw_type_is_float(type)) { \ assert(exec_type == BRW_ALIGN1_3SRC_EXEC_TYPE_FLOAT); \ } else { \ assert(exec_type == BRW_ALIGN1_3SRC_EXEC_TYPE_INT); \ } \ unsigned hw_type = brw_type_encode_for_3src(devinfo, type); \ brw_inst_set_dpas_3src_##reg##_hw_type(devinfo, inst, hw_type); \ } \ \ static inline enum brw_reg_type \ brw_inst_dpas_3src_##reg##_type(const struct intel_device_info *devinfo, \ const brw_inst *inst) \ { \ enum gfx10_align1_3src_exec_type exec_type = \ (enum gfx10_align1_3src_exec_type) brw_inst_dpas_3src_exec_type(devinfo,\ inst); \ unsigned hw_type = brw_inst_dpas_3src_##reg##_hw_type(devinfo, inst); \ return brw_type_decode_for_3src(devinfo, hw_type, exec_type); \ } REG_TYPE(dst) REG_TYPE(src0) REG_TYPE(src1) REG_TYPE(src2) #undef REG_TYPE /** * Flow control instruction bits: * @{ */ static inline void brw_inst_set_uip(const struct intel_device_info *devinfo, brw_inst *inst, int32_t value) { if (devinfo->ver >= 12) brw_inst_set_src1_is_imm(devinfo, inst, 1); brw_inst_set_bits(inst, 95, 64, (uint32_t)value); } static inline int32_t brw_inst_uip(const struct intel_device_info *devinfo, const brw_inst *inst) { return brw_inst_bits(inst, 95, 64); } static inline void brw_inst_set_jip(const struct intel_device_info *devinfo, brw_inst *inst, int32_t value) { if (devinfo->ver >= 12) brw_inst_set_src0_is_imm(devinfo, inst, 1); brw_inst_set_bits(inst, 127, 96, (uint32_t)value); } static inline int32_t brw_inst_jip(const struct intel_device_info *devinfo, const brw_inst *inst) { return brw_inst_bits(inst, 127, 96); } /** @} */ /** * SEND instructions: * @{ */ F(send_ex_desc_ia_subreg_nr, /* 9+ */ 82, 80, /* 12+ */ 42, 40) F(send_src0_address_mode, /* 9+ */ 79, 79, /* 12+ */ -1, -1) F(send_sel_reg32_desc, /* 9+ */ 77, 77, /* 12+ */ 48, 48) F(send_sel_reg32_ex_desc, /* 9+ */ 61, 61, /* 12+ */ 49, 49) FF(send_src0_reg_file, /* 9+ */ 42, 41, /* 12+ */ 66, 66) F(send_src1_reg_nr, /* 9+ */ 51, 44, /* 12+ */ 111, 104) FC(send_src1_len, /* 9+ */ -1, -1, /* 12+ */ 103, 99, devinfo->verx10 >= 125) FF(send_src1_reg_file, /* 9+ */ 36, 36, /* 12+ */ 98, 98) FF(send_dst_reg_file, /* 9+ */ 35, 35, /* 12+ */ 50, 50) FC(send_ex_bso, /* 9+ */ -1, -1, /* 12+ */ 39, 39, devinfo->verx10 >= 125) /** @} */ /* Message descriptor bits */ #define MD(x) ((x) + 96) #define MD12(x) ((x) >= 30 ? (x) - 30 + 122 : \ (x) >= 25 ? (x) - 25 + 67 : \ (x) >= 20 ? (x) - 20 + 51 : \ (x) >= 11 ? (x) - 11 + 113 : \ (x) - 0 + 81) /** * Set the SEND(C) message descriptor immediate. * * This doesn't include the SFID nor the EOT field that were considered to be * part of the message descriptor by ancient versions of the BSpec, because * they are present in the instruction even if the message descriptor is * provided indirectly in the address register, so we want to specify them * separately. */ static inline void brw_inst_set_send_desc(const struct intel_device_info *devinfo, brw_inst *inst, uint32_t value) { if (devinfo->ver >= 12) { brw_inst_set_bits(inst, 123, 122, GET_BITS(value, 31, 30)); brw_inst_set_bits(inst, 71, 67, GET_BITS(value, 29, 25)); brw_inst_set_bits(inst, 55, 51, GET_BITS(value, 24, 20)); brw_inst_set_bits(inst, 121, 113, GET_BITS(value, 19, 11)); brw_inst_set_bits(inst, 91, 81, GET_BITS(value, 10, 0)); } else { brw_inst_set_bits(inst, 126, 96, value); assert(value >> 31 == 0); } } /** * Get the SEND(C) message descriptor immediate. * * \sa brw_inst_set_send_desc(). */ static inline uint32_t brw_inst_send_desc(const struct intel_device_info *devinfo, const brw_inst *inst) { if (devinfo->ver >= 12) { return (brw_inst_bits(inst, 123, 122) << 30 | brw_inst_bits(inst, 71, 67) << 25 | brw_inst_bits(inst, 55, 51) << 20 | brw_inst_bits(inst, 121, 113) << 11 | brw_inst_bits(inst, 91, 81)); } else { return brw_inst_bits(inst, 126, 96); } } /** * Set the SEND(C) message extended descriptor immediate. * * This doesn't include the SFID nor the EOT field that were considered to be * part of the extended message descriptor by some versions of the BSpec, * because they are present in the instruction even if the extended message * descriptor is provided indirectly in a register, so we want to specify them * separately. */ static inline void brw_inst_set_send_ex_desc(const struct intel_device_info *devinfo, brw_inst *inst, uint32_t value) { if (devinfo->ver >= 12) { brw_inst_set_bits(inst, 127, 124, GET_BITS(value, 31, 28)); brw_inst_set_bits(inst, 97, 96, GET_BITS(value, 27, 26)); brw_inst_set_bits(inst, 65, 64, GET_BITS(value, 25, 24)); brw_inst_set_bits(inst, 47, 35, GET_BITS(value, 23, 11)); brw_inst_set_bits(inst, 103, 99, GET_BITS(value, 10, 6)); assert(GET_BITS(value, 5, 0) == 0); } else { assert(devinfo->ver >= 9); brw_inst_set_bits(inst, 94, 91, GET_BITS(value, 31, 28)); brw_inst_set_bits(inst, 88, 85, GET_BITS(value, 27, 24)); brw_inst_set_bits(inst, 83, 80, GET_BITS(value, 23, 20)); brw_inst_set_bits(inst, 67, 64, GET_BITS(value, 19, 16)); assert(GET_BITS(value, 15, 0) == 0); } } /** * Set the SENDS(C) message extended descriptor immediate. * * This doesn't include the SFID nor the EOT field that were considered to be * part of the extended message descriptor by some versions of the BSpec, * because they are present in the instruction even if the extended message * descriptor is provided indirectly in a register, so we want to specify them * separately. */ static inline void brw_inst_set_sends_ex_desc(const struct intel_device_info *devinfo, brw_inst *inst, uint32_t value) { if (devinfo->ver >= 12) { brw_inst_set_send_ex_desc(devinfo, inst, value); } else { brw_inst_set_bits(inst, 95, 80, GET_BITS(value, 31, 16)); assert(GET_BITS(value, 15, 10) == 0); brw_inst_set_bits(inst, 67, 64, GET_BITS(value, 9, 6)); assert(GET_BITS(value, 5, 0) == 0); } } /** * Get the SEND(C) message extended descriptor immediate. * * \sa brw_inst_set_send_ex_desc(). */ static inline uint32_t brw_inst_send_ex_desc(const struct intel_device_info *devinfo, const brw_inst *inst) { if (devinfo->ver >= 12) { return (brw_inst_bits(inst, 127, 124) << 28 | brw_inst_bits(inst, 97, 96) << 26 | brw_inst_bits(inst, 65, 64) << 24 | brw_inst_bits(inst, 47, 35) << 11 | brw_inst_bits(inst, 103, 99) << 6); } else { assert(devinfo->ver >= 9); return (brw_inst_bits(inst, 94, 91) << 28 | brw_inst_bits(inst, 88, 85) << 24 | brw_inst_bits(inst, 83, 80) << 20 | brw_inst_bits(inst, 67, 64) << 16); } } /** * Get the SENDS(C) message extended descriptor immediate. * * \sa brw_inst_set_send_ex_desc(). */ static inline uint32_t brw_inst_sends_ex_desc(const struct intel_device_info *devinfo, const brw_inst *inst) { if (devinfo->ver >= 12) { return brw_inst_send_ex_desc(devinfo, inst); } else { return (brw_inst_bits(inst, 95, 80) << 16 | brw_inst_bits(inst, 67, 64) << 6); } } /** * Fields for SEND messages: * @{ */ F(eot, /* 9+ */ 127, 127, /* 12+ */ 34, 34) F(mlen, /* 9+ */ 124, 121, /* 12+ */ MD12(28), MD12(25)) F(rlen, /* 9+ */ 120, 116, /* 12+ */ MD12(24), MD12(20)) F(header_present, /* 9+ */ 115, 115, /* 12+ */ MD12(19), MD12(19)) F(gateway_notify, /* 9+ */ MD(16), MD(15), /* 12+ */ -1, -1) FD(function_control, /* 9+ */ 114, 96, /* 12+ */ MD12(18), MD12(11), MD12(10), MD12(0)) F(gateway_subfuncid, /* 9+ */ MD(2), MD(0), /* 12+ */ MD12(2), MD12(0)) F(sfid, /* 9+ */ 27, 24, /* 12+ */ 95, 92) F(null_rt, /* 9+ */ 80, 80, /* 12+ */ 44, 44) /* actually only Gfx11+ */ F(send_rta_index, /* 9+ */ -1, -1, /* 12+ */ 38, 36) /** @} */ /** * URB message function control bits: * @{ */ F(urb_per_slot_offset, /* 9+ */ MD(17), MD(17), /* 12+ */ MD12(17), MD12(17)) F(urb_channel_mask_present, /* 9+ */ MD(15), MD(15), /* 12+ */ MD12(15), MD12(15)) F(urb_swizzle_control, /* 9+ */ MD(15), MD(15), /* 12+ */ -1, -1) FD(urb_global_offset, /* 9+ */ MD(14), MD(4), /* 12+ */ MD12(14), MD12(11), MD12(10), MD12(4)) F(urb_opcode, /* 9+ */ MD( 3), MD(0), /* 12+ */ MD12(3), MD12(0)) /** @} */ /** * Sampler message function control bits: * @{ */ F(sampler_simd_mode, /* 9+ */ MD(18), MD(17), /* 12+ */ MD12(18), MD12(17)) F(sampler_msg_type, /* 9+ */ MD(16), MD(12), /* 12+ */ MD12(16), MD12(12)) FD(sampler, /* 9+ */ MD(11), MD(8), /* 12+ */ MD12(11), MD12(11), MD12(10), MD12(8)) F(binding_table_index, /* 9+ */ MD(7), MD(0), /* 12+ */ MD12(7), MD12(0)) /* also used by other messages */ /** @} */ /** * Data port message function control bits: * @{ */ F(dp_category, /* 9+ */ MD(18), MD(18), /* 12+ */ MD12(18), MD12(18)) F(dp_read_msg_type, /* 9+ */ MD(17), MD(14), /* 12+ */ MD12(17), MD12(14)) F(dp_write_msg_type, /* 9+ */ MD(17), MD(14), /* 12+ */ MD12(17), MD12(14)) FD(dp_read_msg_control, /* 9+ */ MD(13), MD( 8), /* 12+ */ MD12(13), MD12(11), MD12(10), MD12(8)) FD(dp_write_msg_control, /* 9+ */ MD(13), MD( 8), /* 12+ */ MD12(13), MD12(11), MD12(10), MD12(8)) F(dp_msg_type, /* 9+ */ MD(18), MD(14), /* 12+ */ MD12(18), MD12(14)) FD(dp_msg_control, /* 9+ */ MD(13), MD( 8), /* 12+ */ MD12(13), MD12(11), MD12(10), MD12(8)) /** @} */ /** * Scratch message bits: * @{ */ F(scratch_read_write, /* 9+ */ MD(17), MD(17), /* 12+ */ MD12(17), MD12(17)) /* 0 = read, 1 = write */ F(scratch_type, /* 9+ */ MD(16), MD(16), /* 12+ */ -1, -1) /* 0 = OWord, 1 = DWord */ F(scratch_invalidate_after_read, /* 9+ */ MD(15), MD(15), /* 12+ */ MD12(15), MD12(15)) F(scratch_block_size, /* 9+ */ MD(13), MD(12), /* 12+ */ MD12(13), MD12(12)) FD(scratch_addr_offset, /* 9: */ MD(11), MD(0), /* 12: */ MD12(11), MD12(11), MD12(10), MD12(0)) /** @} */ /** * Render Target message function control bits: * @{ */ F(rt_last, /* 9+ */ MD(12), MD(12), /* 12+ */ MD12(12), MD12(12)) F(rt_slot_group, /* 9+ */ MD(11), MD(11), /* 12+ */ MD12(11), MD12(11)) F(rt_message_type, /* 9+ */ MD(10), MD( 8), /* 12+ */ MD12(10), MD12(8)) /** @} */ /** * Pixel Interpolator message function control bits: * @{ */ F(pi_simd_mode, /* 9+ */ MD(16), MD(16), /* 12+ */ MD12(16), MD12(16)) F(pi_nopersp, /* 9+ */ MD(14), MD(14), /* 12+ */ MD12(14), MD12(14)) F(pi_message_type, /* 9+ */ MD(13), MD(12), /* 12+ */ MD12(13), MD12(12)) F(pi_slot_group, /* 9+ */ MD(11), MD(11), /* 12+ */ MD12(11), MD12(11)) F(pi_message_data, /* 9+ */ MD(7), MD(0), /* 12+ */ MD12(7), MD12(0)) /** @} */ /** * Immediates: * @{ */ static inline int brw_inst_imm_d(const struct intel_device_info *devinfo, const brw_inst *insn) { (void) devinfo; return brw_inst_bits(insn, 127, 96); } static inline unsigned brw_inst_imm_ud(const struct intel_device_info *devinfo, const brw_inst *insn) { (void) devinfo; return brw_inst_bits(insn, 127, 96); } static inline uint64_t brw_inst_imm_uq(const struct intel_device_info *devinfo, const brw_inst *insn) { if (devinfo->ver >= 12) { return brw_inst_bits(insn, 95, 64) << 32 | brw_inst_bits(insn, 127, 96); } else { return brw_inst_bits(insn, 127, 64); } } static inline float brw_inst_imm_f(const struct intel_device_info *devinfo, const brw_inst *insn) { union { float f; uint32_t u; } ft; (void) devinfo; ft.u = brw_inst_bits(insn, 127, 96); return ft.f; } static inline double brw_inst_imm_df(const struct intel_device_info *devinfo, const brw_inst *insn) { union { double d; uint64_t u; } dt; dt.u = brw_inst_imm_uq(devinfo, insn); return dt.d; } static inline void brw_inst_set_imm_d(const struct intel_device_info *devinfo, brw_inst *insn, int value) { (void) devinfo; return brw_inst_set_bits(insn, 127, 96, value); } static inline void brw_inst_set_imm_ud(const struct intel_device_info *devinfo, brw_inst *insn, unsigned value) { (void) devinfo; return brw_inst_set_bits(insn, 127, 96, value); } static inline void brw_inst_set_imm_f(const struct intel_device_info *devinfo, brw_inst *insn, float value) { union { float f; uint32_t u; } ft; (void) devinfo; ft.f = value; brw_inst_set_bits(insn, 127, 96, ft.u); } static inline void brw_inst_set_imm_df(const struct intel_device_info *devinfo, brw_inst *insn, double value) { union { double d; uint64_t u; } dt; (void) devinfo; dt.d = value; if (devinfo->ver >= 12) { brw_inst_set_bits(insn, 95, 64, dt.u >> 32); brw_inst_set_bits(insn, 127, 96, dt.u & 0xFFFFFFFF); } else { brw_inst_set_bits(insn, 127, 64, dt.u); } } static inline void brw_inst_set_imm_uq(const struct intel_device_info *devinfo, brw_inst *insn, uint64_t value) { (void) devinfo; if (devinfo->ver >= 12) { brw_inst_set_bits(insn, 95, 64, value >> 32); brw_inst_set_bits(insn, 127, 96, value & 0xFFFFFFFF); } else { brw_inst_set_bits(insn, 127, 64, value); } } /** @} */ #define REG_TYPE(reg) \ static inline void \ brw_inst_set_##reg##_file_type(const struct intel_device_info *devinfo, \ brw_inst *inst, enum brw_reg_file file, \ enum brw_reg_type type) \ { \ assert(file <= IMM); \ unsigned hw_type = brw_type_encode(devinfo, file, type); \ brw_inst_set_##reg##_reg_file(devinfo, inst, file); \ brw_inst_set_##reg##_reg_hw_type(devinfo, inst, hw_type); \ } \ \ static inline enum brw_reg_type \ brw_inst_##reg##_type(const struct intel_device_info *devinfo, \ const brw_inst *inst) \ { \ unsigned file = __builtin_strcmp("dst", #reg) == 0 ? \ (unsigned) FIXED_GRF : \ brw_inst_##reg##_reg_file(devinfo, inst); \ unsigned hw_type = brw_inst_##reg##_reg_hw_type(devinfo, inst); \ return brw_type_decode(devinfo, (enum brw_reg_file)file, hw_type); \ } REG_TYPE(dst) REG_TYPE(src0) REG_TYPE(src1) #undef REG_TYPE /* The AddrImm fields are split into two discontiguous sections on Gfx9+ */ #define BRW_IA1_ADDR_IMM(reg, g9_nine, g9_high, g9_low, \ g12_high, g12_low, g20_high, g20_low, g20_zero) \ static inline void \ brw_inst_set_##reg##_ia1_addr_imm(const struct \ intel_device_info *devinfo, \ brw_inst *inst, \ unsigned value) \ { \ if (devinfo->ver >= 20) { \ assert((value & ~0x7ff) == 0); \ brw_inst_set_bits(inst, g20_high, g20_low, value >> 1); \ if (g20_zero == -1) \ assert((value & 1) == 0); \ else \ brw_inst_set_bits(inst, g20_zero, g20_zero, value & 1); \ } else if (devinfo->ver >= 12) { \ assert((value & ~0x3ff) == 0); \ brw_inst_set_bits(inst, g12_high, g12_low, value); \ } else { \ assert((value & ~0x3ff) == 0); \ brw_inst_set_bits(inst, g9_high, g9_low, value & 0x1ff); \ brw_inst_set_bits(inst, g9_nine, g9_nine, value >> 9); \ } \ } \ static inline unsigned \ brw_inst_##reg##_ia1_addr_imm(const struct intel_device_info *devinfo, \ const brw_inst *inst) \ { \ if (devinfo->ver >= 20) { \ return brw_inst_bits(inst, g20_high, g20_low) << 1 | \ (g20_zero == -1 ? 0 : \ brw_inst_bits(inst, g20_zero, g20_zero)); \ } else if (devinfo->ver >= 12) { \ return brw_inst_bits(inst, g12_high, g12_low); \ } else { \ return brw_inst_bits(inst, g9_high, g9_low) | \ (brw_inst_bits(inst, g9_nine, g9_nine) << 9); \ } \ } /* AddrImm for Align1 Indirect Addressing */ /* ----Gfx9---- -Gfx12- ---Gfx20--- */ BRW_IA1_ADDR_IMM(src1, 121, 104, 96, 107, 98, 107, 98, -1) BRW_IA1_ADDR_IMM(src0, 95, 72, 64, 75, 66, 75, 66, 87) BRW_IA1_ADDR_IMM(dst, 47, 56, 48, 59, 50, 59, 50, 33) #define BRW_IA16_ADDR_IMM(reg, g9_nine, g9_high, g9_low) \ static inline void \ brw_inst_set_##reg##_ia16_addr_imm(const struct \ intel_device_info *devinfo, \ brw_inst *inst, unsigned value) \ { \ assert(devinfo->ver < 12); \ assert((value & ~0x3ff) == 0); \ assert(GET_BITS(value, 3, 0) == 0); \ brw_inst_set_bits(inst, g9_high, g9_low, GET_BITS(value, 8, 4)); \ brw_inst_set_bits(inst, g9_nine, g9_nine, GET_BITS(value, 9, 9)); \ } \ static inline unsigned \ brw_inst_##reg##_ia16_addr_imm(const struct intel_device_info *devinfo, \ const brw_inst *inst) \ { \ assert(devinfo->ver < 12); \ return (brw_inst_bits(inst, g9_high, g9_low) << 4) | \ (brw_inst_bits(inst, g9_nine, g9_nine) << 9); \ } /* AddrImm[9:0] for Align16 Indirect Addressing: * Compared to Align1, these are missing the low 4 bits. * ----Gfx9---- */ BRW_IA16_ADDR_IMM(src1, 121, 104, 100) BRW_IA16_ADDR_IMM(src0, 95, 72, 68) BRW_IA16_ADDR_IMM(dst, 47, 56, 52) BRW_IA16_ADDR_IMM(send_src0, 78, 72, 68) BRW_IA16_ADDR_IMM(send_dst, 62, 56, 52) /** * Fetch a set of contiguous bits from the instruction. * * Bits indices range from 0..127; fields may not cross 64-bit boundaries. */ static inline uint64_t brw_inst_bits(const brw_inst *inst, unsigned high, unsigned low) { assume(high < 128); assume(high >= low); /* We assume the field doesn't cross 64-bit boundaries. */ const unsigned word = high / 64; assert(word == low / 64); high %= 64; low %= 64; const uint64_t mask = (~0ull >> (64 - (high - low + 1))); return (inst->data[word] >> low) & mask; } /** * Set bits in the instruction, with proper shifting and masking. * * Bits indices range from 0..127; fields may not cross 64-bit boundaries. */ static inline void brw_inst_set_bits(brw_inst *inst, unsigned high, unsigned low, uint64_t value) { assume(high < 128); assume(high >= low); const unsigned word = high / 64; assert(word == low / 64); high %= 64; low %= 64; const uint64_t mask = (~0ull >> (64 - (high - low + 1))) << low; /* Make sure the supplied value actually fits in the given bitfield. */ assert((value & (mask >> low)) == value); inst->data[word] = (inst->data[word] & ~mask) | (value << low); } #undef BRW_IA16_ADDR_IMM #undef BRW_IA1_ADDR_IMM #undef MD #undef F #undef FC #undef F20 #undef FD20 typedef struct { uint64_t data; } brw_compact_inst; /** * Fetch a set of contiguous bits from the compacted instruction. * * Bits indices range from 0..63. */ static inline unsigned brw_compact_inst_bits(const brw_compact_inst *inst, unsigned high, unsigned low) { assume(high < 64); assume(high >= low); const uint64_t mask = (1ull << (high - low + 1)) - 1; return (inst->data >> low) & mask; } /** * Set bits in the compacted instruction. * * Bits indices range from 0..63. */ static inline void brw_compact_inst_set_bits(brw_compact_inst *inst, unsigned high, unsigned low, uint64_t value) { assume(high < 64); assume(high >= low); const uint64_t mask = ((1ull << (high - low + 1)) - 1) << low; /* Make sure the supplied value actually fits in the given bitfield. */ assert((value & (mask >> low)) == value); inst->data = (inst->data & ~mask) | (value << low); } #define FC(name, hi9, lo9, hi12, lo12, assertions) \ static inline void \ brw_compact_inst_set_##name(const struct \ intel_device_info *devinfo, \ brw_compact_inst *inst, unsigned v) \ { \ assert(assertions); \ if (devinfo->ver >= 12) \ brw_compact_inst_set_bits(inst, hi12, lo12, v); \ else \ brw_compact_inst_set_bits(inst, hi9, lo9, v); \ } \ static inline unsigned \ brw_compact_inst_##name(const struct intel_device_info *devinfo, \ const brw_compact_inst *inst) \ { \ assert(assertions); \ if (devinfo->ver >= 12) \ return brw_compact_inst_bits(inst, hi12, lo12); \ else \ return brw_compact_inst_bits(inst, hi9, lo9); \ } /* A simple macro for fields which stay in the same place on all generations * except for Gfx12. */ #define F(name, hi9, lo9, hi12, lo12) FC(name, hi9, lo9, hi12, lo12, true) /* A macro for fields which moved to several different locations * across generations. */ #define F20(name, hi9, lo9, hi12, lo12, hi20, lo20) \ static inline void \ brw_compact_inst_set_##name(const struct \ intel_device_info *devinfo, \ brw_compact_inst *inst, unsigned v) \ { \ if (devinfo->ver >= 20) \ brw_compact_inst_set_bits(inst, hi20, lo20, v); \ else if (devinfo->ver >= 12) \ brw_compact_inst_set_bits(inst, hi12, lo12, v); \ else \ brw_compact_inst_set_bits(inst, hi9, lo9, v); \ } \ static inline unsigned \ brw_compact_inst_##name(const struct intel_device_info *devinfo, \ const brw_compact_inst *inst) \ { \ if (devinfo->ver >= 20) \ return brw_compact_inst_bits(inst, hi20, lo20); \ else if (devinfo->ver >= 12) \ return brw_compact_inst_bits(inst, hi12, lo12); \ else \ return brw_compact_inst_bits(inst, hi9, lo9); \ } /* A macro for fields which gained extra discontiguous bits in Gfx20 * (specified by hi20ex-lo20ex). */ #define FD20(name, hi9, lo9, hi12, lo12, \ hi20, lo20, hi20ex, lo20ex) \ static inline void \ brw_compact_inst_set_##name(const struct \ intel_device_info *devinfo, \ brw_compact_inst *inst, unsigned v) \ { \ if (devinfo->ver >= 20) { \ const unsigned k = hi20 - lo20 + 1; \ brw_compact_inst_set_bits(inst, hi20ex, lo20ex, v >> k); \ brw_compact_inst_set_bits(inst, hi20, lo20, v & ((1u << k) - 1)); \ } else if (devinfo->ver >= 12) { \ brw_compact_inst_set_bits(inst, hi12, lo12, v); \ } else { \ brw_compact_inst_set_bits(inst, hi9, lo9, v); \ } \ } \ static inline unsigned \ brw_compact_inst_##name(const struct intel_device_info *devinfo, \ const brw_compact_inst *inst) \ { \ if (devinfo->ver >= 20) { \ const unsigned k = hi20 - lo20 + 1; \ return (brw_compact_inst_bits(inst, hi20ex, lo20ex) << k | \ brw_compact_inst_bits(inst, hi20, lo20)); \ } else if (devinfo->ver >= 12) { \ return brw_compact_inst_bits(inst, hi12, lo12); \ } else { \ return brw_compact_inst_bits(inst, hi9, lo9); \ } \ } F(src1_reg_nr, /* 9+ */ 63, 56, /* 12+ */ 63, 56) F(src0_reg_nr, /* 9+ */ 55, 48, /* 12+ */ 47, 40) F20(dst_reg_nr, /* 9+ */ 47, 40, /* 12+ */ 23, 16, /* 20+ */ 39, 32) F(src1_index, /* 9+ */ 39, 35, /* 12+ */ 55, 52) F20(src0_index, /* 9+ */ 34, 30, /* 12+ */ 51, 48, /* 20+ */ 25, 23) F(cmpt_control, /* 9+ */ 29, 29, /* 12+ */ 29, 29) /* Same location as brw_inst */ F(cond_modifier, /* 9+ */ 27, 24, /* 12+ */ -1, -1) /* Same location as brw_inst */ F(acc_wr_control, /* 9+ */ 23, 23, /* 12+ */ -1, -1) F20(subreg_index, /* 9+ */ 22, 18, /* 12+ */ 39, 35, /* 20+ */ 51, 48) FD20(datatype_index, /* 9+ */ 17, 13, /* 12+ */ 34, 30, /* 20+ */ 28, 26, 31, 30) F20(control_index, /* 9+ */ 12, 8, /* 12+ */ 28, 24, /* 20+ */ 22, 18) F20(swsb, /* 9+ */ -1, -1, /* 12+ */ 15, 8, /* 20+ */ 17, 8) F(debug_control, /* 9+ */ 7, 7, /* 12+ */ 7, 7) F(hw_opcode, /* 9+ */ 6, 0, /* 12+ */ 6, 0) /* Same location as brw_inst */ static inline unsigned brw_compact_inst_imm(const struct intel_device_info *devinfo, const brw_compact_inst *inst) { if (devinfo->ver >= 12) { return brw_compact_inst_bits(inst, 63, 52); } else { return (brw_compact_inst_bits(inst, 39, 35) << 8) | (brw_compact_inst_bits(inst, 63, 56)); } } /** * Compacted three-source instructions: * @{ */ F(3src_src2_reg_nr, /* 9+ */ 63, 57, /* 12+ */ 55, 48) F(3src_src1_reg_nr, /* 9+ */ 56, 50, /* 12+ */ 63, 56) F(3src_src0_reg_nr, /* 9+ */ 49, 43, /* 12+ */ 47, 40) F(3src_src2_subreg_nr, /* 9+ */ 42, 40, /* 12+ */ -1, -1) F(3src_src1_subreg_nr, /* 9+ */ 39, 37, /* 12+ */ -1, -1) F(3src_src0_subreg_nr, /* 9+ */ 36, 34, /* 12+ */ -1, -1) F(3src_src2_rep_ctrl, /* 9+ */ 33, 33, /* 12+ */ -1, -1) F(3src_src1_rep_ctrl, /* 9+ */ 32, 32, /* 12+ */ -1, -1) F(3src_saturate, /* 9+ */ 31, 31, /* 12+ */ -1, -1) F(3src_debug_control, /* 9+ */ 30, 30, /* 12+ */ 7, 7) F(3src_cmpt_control, /* 9+ */ 29, 29, /* 12+ */ 29, 29) F(3src_src0_rep_ctrl, /* 9+ */ 28, 28, /* 12+ */ -1, -1) /* Reserved */ F20(3src_dst_reg_nr, /* 9+ */ 18, 12, /* 12+ */ 23, 16, /* 20+ */ 39, 32) F20(3src_source_index, /* 9+ */ 11, 10, /* 12+ */ 34, 30, /* 20+ */ 25, 22) FD20(3src_subreg_index, /* 9+ */ -1, -1, /* 12+ */ 39, 35, /* 20+ */ 28, 26, 31, 30) F20(3src_control_index, /* 9+ */ 9, 8, /* 12+ */ 28, 24, /* 20+ */ 21, 18) F20(3src_swsb, /* 9+ */ -1, -1, /* 12+ */ 15, 8, /* 20+ */ 17, 8) /* Bit 7 is Reserved (for future Opcode expansion) */ F(3src_hw_opcode, /* 9+ */ 6, 0, /* 12+ */ 6, 0) /** @} */ #undef F static inline void brw_inst_set_opcode(const struct brw_isa_info *isa, struct brw_inst *inst, enum opcode opcode) { brw_inst_set_hw_opcode(isa->devinfo, inst, brw_opcode_encode(isa, opcode)); } static inline enum opcode brw_inst_opcode(const struct brw_isa_info *isa, const struct brw_inst *inst) { return brw_opcode_decode(isa, brw_inst_hw_opcode(isa->devinfo, inst)); } #ifdef __cplusplus } #endif #endif