| /* |
| * Copyright (C) 2020 Collabora Ltd. |
| * |
| * 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. |
| * |
| * Authors (Collabora): |
| * Alyssa Rosenzweig <alyssa.rosenzweig@collabora.com> |
| */ |
| |
| #ifndef __BIFROST_COMPILER_H |
| #define __BIFROST_COMPILER_H |
| |
| #include "bifrost.h" |
| #include "compiler/nir/nir.h" |
| #include "panfrost/util/pan_ir.h" |
| |
| /* Bifrost opcodes are tricky -- the same op may exist on both FMA and |
| * ADD with two completely different opcodes, and opcodes can be varying |
| * length in some cases. Then we have different opcodes for int vs float |
| * and then sometimes even for different typesizes. Further, virtually |
| * every op has a number of flags which depend on the op. In constrast |
| * to Midgard where you have a strict ALU/LDST/TEX division and within |
| * ALU you have strict int/float and that's it... here it's a *lot* more |
| * involved. As such, we use something much higher level for our IR, |
| * encoding "classes" of operations, letting the opcode details get |
| * sorted out at emit time. |
| * |
| * Please keep this list alphabetized. Please use a dictionary if you |
| * don't know how to do that. |
| */ |
| |
| enum bi_class { |
| BI_ADD, |
| BI_ATEST, |
| BI_BRANCH, |
| BI_CMP, |
| BI_BLEND, |
| BI_BITWISE, |
| BI_CONVERT, |
| BI_CSEL, |
| BI_DISCARD, |
| BI_FMA, |
| BI_FMOV, |
| BI_FREXP, |
| BI_ISUB, |
| BI_LOAD, |
| BI_LOAD_UNIFORM, |
| BI_LOAD_ATTR, |
| BI_LOAD_VAR, |
| BI_LOAD_VAR_ADDRESS, |
| BI_MINMAX, |
| BI_MOV, |
| BI_SHIFT, |
| BI_STORE, |
| BI_STORE_VAR, |
| BI_SPECIAL, /* _FAST, _TABLE on supported GPUs */ |
| BI_SWIZZLE, |
| BI_TEX, |
| BI_ROUND, |
| BI_NUM_CLASSES |
| }; |
| |
| /* Properties of a class... */ |
| extern unsigned bi_class_props[BI_NUM_CLASSES]; |
| |
| /* abs/neg/outmod valid for a float op */ |
| #define BI_MODS (1 << 0) |
| |
| /* Generic enough that little class-specific information is required. In other |
| * words, it acts as a "normal" ALU op, even if the encoding ends up being |
| * irregular enough to warrant a separate class */ |
| #define BI_GENERIC (1 << 1) |
| |
| /* Accepts a bifrost_roundmode */ |
| #define BI_ROUNDMODE (1 << 2) |
| |
| /* Can be scheduled to FMA */ |
| #define BI_SCHED_FMA (1 << 3) |
| |
| /* Can be scheduled to ADD */ |
| #define BI_SCHED_ADD (1 << 4) |
| |
| /* Most ALU ops can do either, actually */ |
| #define BI_SCHED_ALL (BI_SCHED_FMA | BI_SCHED_ADD) |
| |
| /* Along with setting BI_SCHED_ADD, eats up the entire cycle, so FMA must be |
| * nopped out. Used for _FAST operations. */ |
| #define BI_SCHED_SLOW (1 << 5) |
| |
| /* Swizzling allowed for the 8/16-bit source */ |
| #define BI_SWIZZLABLE (1 << 6) |
| |
| /* For scheduling purposes this is a high latency instruction and must be at |
| * the end of a clause. Implies ADD */ |
| #define BI_SCHED_HI_LATENCY (1 << 7) |
| |
| /* Intrinsic is vectorized and should read 4 components regardless of writemask */ |
| #define BI_VECTOR (1 << 8) |
| |
| /* Use a data register for src0/dest respectively, bypassing the usual |
| * register accessor. Mutually exclusive. */ |
| #define BI_DATA_REG_SRC (1 << 9) |
| #define BI_DATA_REG_DEST (1 << 10) |
| |
| /* It can't get any worse than csel4... can it? */ |
| #define BIR_SRC_COUNT 4 |
| |
| /* BI_LD_VARY */ |
| struct bi_load_vary { |
| enum bifrost_interp_mode interp_mode; |
| bool reuse; |
| bool flat; |
| }; |
| |
| /* BI_BRANCH encoding the details of the branch itself as well as a pointer to |
| * the target. We forward declare bi_block since this is mildly circular (not |
| * strictly, but this order of the file makes more sense I think) |
| * |
| * We define our own enum of conditions since the conditions in the hardware |
| * packed in crazy ways that would make manipulation unweildly (meaning changes |
| * based on port swapping, etc), so we defer dealing with that until emit time. |
| * Likewise, we expose NIR types instead of the crazy branch types, although |
| * the restrictions do eventually apply of course. */ |
| |
| struct bi_block; |
| |
| enum bi_cond { |
| BI_COND_ALWAYS, |
| BI_COND_LT, |
| BI_COND_LE, |
| BI_COND_GE, |
| BI_COND_GT, |
| BI_COND_EQ, |
| BI_COND_NE, |
| }; |
| |
| struct bi_branch { |
| /* Types are specified in src_types and must be compatible (either both |
| * int, or both float, 16/32, and same size or 32/16 if float. Types |
| * ignored if BI_COND_ALWAYS is set for an unconditional branch. */ |
| |
| enum bi_cond cond; |
| struct bi_block *target; |
| }; |
| |
| /* Opcodes within a class */ |
| enum bi_minmax_op { |
| BI_MINMAX_MIN, |
| BI_MINMAX_MAX |
| }; |
| |
| enum bi_bitwise_op { |
| BI_BITWISE_AND, |
| BI_BITWISE_OR, |
| BI_BITWISE_XOR |
| }; |
| |
| enum bi_round_op { |
| BI_ROUND_MODE, /* use round mode */ |
| BI_ROUND_ROUND /* i.e.: fround() */ |
| }; |
| |
| enum bi_special_op { |
| BI_SPECIAL_FRCP, |
| BI_SPECIAL_FRSQ, |
| BI_SPECIAL_FATAN, |
| BI_SPECIAL_FSIN, |
| BI_SPECIAL_FCOS, |
| BI_SPECIAL_FEXP, |
| BI_SPECIAL_FLOG2, |
| BI_SPECIAL_FLOGE |
| }; |
| |
| typedef struct { |
| struct list_head link; /* Must be first */ |
| enum bi_class type; |
| |
| /* Indices, see bir_ssa_index etc. Note zero is special cased |
| * to "no argument" */ |
| unsigned dest; |
| unsigned src[BIR_SRC_COUNT]; |
| |
| /* If one of the sources has BIR_INDEX_CONSTANT */ |
| union { |
| uint64_t u64; |
| uint32_t u32; |
| uint16_t u16[2]; |
| uint8_t u8[4]; |
| } constant; |
| |
| /* Floating-point modifiers, type/class permitting. If not |
| * allowed for the type/class, these are ignored. */ |
| enum bifrost_outmod outmod; |
| bool src_abs[BIR_SRC_COUNT]; |
| bool src_neg[BIR_SRC_COUNT]; |
| |
| /* Round mode (requires BI_ROUNDMODE) */ |
| enum bifrost_roundmode roundmode; |
| |
| /* Writemask (bit for each affected byte). This is quite restricted -- |
| * ALU ops can only write to a single channel (exception: <32 in which |
| * you can write to 32/N contiguous aligned channels). Load/store can |
| * only write to all channels at once, in a sense. But it's still |
| * better to use this generic form than have synthetic ops flying |
| * about, since we're not essentially vector for RA purposes. */ |
| uint16_t writemask; |
| |
| /* Destination type. Usually the type of the instruction |
| * itself, but if sources and destination have different |
| * types, the type of the destination wins (so f2i would be |
| * int). Zero if there is no destination. Bitsize included */ |
| nir_alu_type dest_type; |
| |
| /* Source types if required by the class */ |
| nir_alu_type src_types[BIR_SRC_COUNT]; |
| |
| /* If the source type is 8-bit or 16-bit such that SIMD is possible, |
| * and the class has BI_SWIZZLABLE, this is a swizzle in the usual |
| * sense. On non-SIMD instructions, it can be used for component |
| * selection, so we don't have to special case extraction. */ |
| uint8_t swizzle[BIR_SRC_COUNT][NIR_MAX_VEC_COMPONENTS]; |
| |
| /* A class-specific op from which the actual opcode can be derived |
| * (along with the above information) */ |
| |
| union { |
| enum bi_minmax_op minmax; |
| enum bi_bitwise_op bitwise; |
| enum bi_round_op round; |
| enum bi_special_op special; |
| enum bi_cond compare; |
| } op; |
| |
| /* Union for class-specific information */ |
| union { |
| enum bifrost_minmax_mode minmax; |
| struct bi_load_vary load_vary; |
| struct bi_branch branch; |
| |
| /* For CSEL, the comparison op. BI_COND_ALWAYS doesn't make |
| * sense here but you can always just use a move for that */ |
| enum bi_cond csel_cond; |
| |
| /* For BLEND -- the location 0-7 */ |
| unsigned blend_location; |
| }; |
| } bi_instruction; |
| |
| /* Scheduling takes place in two steps. Step 1 groups instructions within a |
| * block into distinct clauses (bi_clause). Step 2 schedules instructions |
| * within a clause into FMA/ADD pairs (bi_bundle). |
| * |
| * A bi_bundle contains two paired instruction pointers. If a slot is unfilled, |
| * leave it NULL; the emitter will fill in a nop. |
| */ |
| |
| typedef struct { |
| bi_instruction *fma; |
| bi_instruction *add; |
| } bi_bundle; |
| |
| typedef struct { |
| struct list_head link; |
| |
| /* A clause can have 8 instructions in bundled FMA/ADD sense, so there |
| * can be 8 bundles. But each bundle can have both an FMA and an ADD, |
| * so a clause can have up to 16 bi_instructions. Whether bundles or |
| * instructions are used depends on where in scheduling we are. */ |
| |
| unsigned instruction_count; |
| unsigned bundle_count; |
| |
| union { |
| bi_instruction *instructions[16]; |
| bi_bundle bundles[8]; |
| }; |
| |
| /* For scoreboarding -- the clause ID (this is not globally unique!) |
| * and its dependencies in terms of other clauses, computed during |
| * scheduling and used when emitting code. Dependencies expressed as a |
| * bitfield matching the hardware, except shifted by a clause (the |
| * shift back to the ISA's off-by-one encoding is worked out when |
| * emitting clauses) */ |
| unsigned scoreboard_id; |
| uint8_t dependencies; |
| |
| /* Back-to-back corresponds directly to the back-to-back bit. Branch |
| * conditional corresponds to the branch conditional bit except that in |
| * the emitted code it's always set if back-to-bit is, whereas we use |
| * the actual value (without back-to-back so to speak) internally */ |
| bool back_to_back; |
| bool branch_conditional; |
| |
| /* Assigned data register */ |
| unsigned data_register; |
| |
| /* Corresponds to the usual bit but shifted by a clause */ |
| bool data_register_write_barrier; |
| |
| /* Constants read by this clause. ISA limit. */ |
| uint64_t constants[8]; |
| unsigned constant_count; |
| |
| /* What type of high latency instruction is here, basically */ |
| unsigned clause_type; |
| } bi_clause; |
| |
| typedef struct bi_block { |
| pan_block base; /* must be first */ |
| |
| /* If true, uses clauses; if false, uses instructions */ |
| bool scheduled; |
| struct list_head clauses; /* list of bi_clause */ |
| } bi_block; |
| |
| typedef struct { |
| nir_shader *nir; |
| gl_shader_stage stage; |
| struct list_head blocks; /* list of bi_block */ |
| struct panfrost_sysvals sysvals; |
| uint32_t quirks; |
| |
| /* During NIR->BIR */ |
| nir_function_impl *impl; |
| bi_block *current_block; |
| unsigned block_name_count; |
| bi_block *after_block; |
| bi_block *break_block; |
| bi_block *continue_block; |
| bool emitted_atest; |
| |
| /* For creating temporaries */ |
| unsigned temp_alloc; |
| |
| /* Analysis results */ |
| bool has_liveness; |
| |
| /* Stats for shader-db */ |
| unsigned instruction_count; |
| unsigned loop_count; |
| } bi_context; |
| |
| static inline bi_instruction * |
| bi_emit(bi_context *ctx, bi_instruction ins) |
| { |
| bi_instruction *u = rzalloc(ctx, bi_instruction); |
| memcpy(u, &ins, sizeof(ins)); |
| list_addtail(&u->link, &ctx->current_block->base.instructions); |
| return u; |
| } |
| |
| static inline void |
| bi_remove_instruction(bi_instruction *ins) |
| { |
| list_del(&ins->link); |
| } |
| |
| /* So we can distinguish between SSA/reg/sentinel quickly */ |
| #define BIR_NO_ARG (0) |
| #define BIR_IS_REG (1) |
| |
| /* If high bits are set, instead of SSA/registers, we have specials indexed by |
| * the low bits if necessary. |
| * |
| * Fixed register: do not allocate register, do not collect $200. |
| * Uniform: access a uniform register given by low bits. |
| * Constant: access the specified constant |
| * Zero: special cased to avoid wasting a constant |
| * Passthrough: a bifrost_packed_src to passthrough T/T0/T1 |
| */ |
| |
| #define BIR_INDEX_REGISTER (1 << 31) |
| #define BIR_INDEX_UNIFORM (1 << 30) |
| #define BIR_INDEX_CONSTANT (1 << 29) |
| #define BIR_INDEX_ZERO (1 << 28) |
| #define BIR_INDEX_PASS (1 << 27) |
| |
| /* Keep me synced please so we can check src & BIR_SPECIAL */ |
| |
| #define BIR_SPECIAL ((BIR_INDEX_REGISTER | BIR_INDEX_UNIFORM) | \ |
| (BIR_INDEX_CONSTANT | BIR_INDEX_ZERO | BIR_INDEX_PASS)) |
| |
| static inline unsigned |
| bi_max_temp(bi_context *ctx) |
| { |
| unsigned alloc = MAX2(ctx->impl->reg_alloc, ctx->impl->ssa_alloc); |
| return ((alloc + 2 + ctx->temp_alloc) << 1); |
| } |
| |
| static inline unsigned |
| bi_make_temp(bi_context *ctx) |
| { |
| return (ctx->impl->ssa_alloc + 1 + ctx->temp_alloc++) << 1; |
| } |
| |
| static inline unsigned |
| bi_make_temp_reg(bi_context *ctx) |
| { |
| return ((ctx->impl->reg_alloc + ctx->temp_alloc++) << 1) | BIR_IS_REG; |
| } |
| |
| static inline unsigned |
| bir_ssa_index(nir_ssa_def *ssa) |
| { |
| /* Off-by-one ensures BIR_NO_ARG is skipped */ |
| return ((ssa->index + 1) << 1) | 0; |
| } |
| |
| static inline unsigned |
| bir_src_index(nir_src *src) |
| { |
| if (src->is_ssa) |
| return bir_ssa_index(src->ssa); |
| else { |
| assert(!src->reg.indirect); |
| return (src->reg.reg->index << 1) | BIR_IS_REG; |
| } |
| } |
| |
| static inline unsigned |
| bir_dest_index(nir_dest *dst) |
| { |
| if (dst->is_ssa) |
| return bir_ssa_index(&dst->ssa); |
| else { |
| assert(!dst->reg.indirect); |
| return (dst->reg.reg->index << 1) | BIR_IS_REG; |
| } |
| } |
| |
| /* Iterators for Bifrost IR */ |
| |
| #define bi_foreach_block(ctx, v) \ |
| list_for_each_entry(pan_block, v, &ctx->blocks, link) |
| |
| #define bi_foreach_block_from(ctx, from, v) \ |
| list_for_each_entry_from(pan_block, v, from, &ctx->blocks, link) |
| |
| #define bi_foreach_instr_in_block(block, v) \ |
| list_for_each_entry(bi_instruction, v, &(block)->base.instructions, link) |
| |
| #define bi_foreach_instr_in_block_rev(block, v) \ |
| list_for_each_entry_rev(bi_instruction, v, &(block)->base.instructions, link) |
| |
| #define bi_foreach_instr_in_block_safe(block, v) \ |
| list_for_each_entry_safe(bi_instruction, v, &(block)->base.instructions, link) |
| |
| #define bi_foreach_instr_in_block_safe_rev(block, v) \ |
| list_for_each_entry_safe_rev(bi_instruction, v, &(block)->base.instructions, link) |
| |
| #define bi_foreach_instr_in_block_from(block, v, from) \ |
| list_for_each_entry_from(bi_instruction, v, from, &(block)->base.instructions, link) |
| |
| #define bi_foreach_instr_in_block_from_rev(block, v, from) \ |
| list_for_each_entry_from_rev(bi_instruction, v, from, &(block)->base.instructions, link) |
| |
| #define bi_foreach_clause_in_block(block, v) \ |
| list_for_each_entry(bi_clause, v, &(block)->clauses, link) |
| |
| #define bi_foreach_instr_global(ctx, v) \ |
| bi_foreach_block(ctx, v_block) \ |
| bi_foreach_instr_in_block((bi_block *) v_block, v) |
| |
| #define bi_foreach_instr_global_safe(ctx, v) \ |
| bi_foreach_block(ctx, v_block) \ |
| bi_foreach_instr_in_block_safe((bi_block *) v_block, v) |
| |
| /* Based on set_foreach, expanded with automatic type casts */ |
| |
| #define bi_foreach_predecessor(blk, v) \ |
| struct set_entry *_entry_##v; \ |
| bi_block *v; \ |
| for (_entry_##v = _mesa_set_next_entry(blk->base.predecessors, NULL), \ |
| v = (bi_block *) (_entry_##v ? _entry_##v->key : NULL); \ |
| _entry_##v != NULL; \ |
| _entry_##v = _mesa_set_next_entry(blk->base.predecessors, _entry_##v), \ |
| v = (bi_block *) (_entry_##v ? _entry_##v->key : NULL)) |
| |
| #define bi_foreach_src(ins, v) \ |
| for (unsigned v = 0; v < ARRAY_SIZE(ins->src); ++v) |
| |
| static inline bi_instruction * |
| bi_prev_op(bi_instruction *ins) |
| { |
| return list_last_entry(&(ins->link), bi_instruction, link); |
| } |
| |
| static inline bi_instruction * |
| bi_next_op(bi_instruction *ins) |
| { |
| return list_first_entry(&(ins->link), bi_instruction, link); |
| } |
| |
| static inline pan_block * |
| pan_next_block(pan_block *block) |
| { |
| return list_first_entry(&(block->link), pan_block, link); |
| } |
| |
| /* BIR manipulation */ |
| |
| bool bi_has_outmod(bi_instruction *ins); |
| bool bi_has_source_mods(bi_instruction *ins); |
| bool bi_is_src_swizzled(bi_instruction *ins, unsigned s); |
| bool bi_has_arg(bi_instruction *ins, unsigned arg); |
| uint16_t bi_from_bytemask(uint16_t bytemask, unsigned bytes); |
| unsigned bi_get_component_count(bi_instruction *ins); |
| uint16_t bi_bytemask_of_read_components(bi_instruction *ins, unsigned node); |
| |
| /* BIR passes */ |
| |
| bool bi_opt_dead_code_eliminate(bi_context *ctx, bi_block *block); |
| void bi_schedule(bi_context *ctx); |
| void bi_register_allocate(bi_context *ctx); |
| |
| /* Liveness */ |
| |
| void bi_compute_liveness(bi_context *ctx); |
| void bi_liveness_ins_update(uint16_t *live, bi_instruction *ins, unsigned max); |
| void bi_invalidate_liveness(bi_context *ctx); |
| bool bi_is_live_after(bi_context *ctx, bi_block *block, bi_instruction *start, int src); |
| |
| /* Code emit */ |
| |
| void bi_pack(bi_context *ctx, struct util_dynarray *emission); |
| |
| #endif |