/* * 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 */ #include "bi_builder.h" #include "compiler.h" bool bi_has_arg(const bi_instr *ins, bi_index arg) { if (!ins) return false; bi_foreach_src(ins, s) { if (bi_is_equiv(ins->src[s], arg)) return true; } return false; } /* Precondition: valid 16-bit or 32-bit register format. Returns whether it is * 32-bit. Note auto reads to 32-bit registers even if the memory format is * 16-bit, so is considered as such here */ bool bi_is_regfmt_16(enum bi_register_format fmt) { switch (fmt) { case BI_REGISTER_FORMAT_F16: case BI_REGISTER_FORMAT_S16: case BI_REGISTER_FORMAT_U16: return true; case BI_REGISTER_FORMAT_F32: case BI_REGISTER_FORMAT_S32: case BI_REGISTER_FORMAT_U32: case BI_REGISTER_FORMAT_AUTO: return false; default: unreachable("Invalid register format"); } } static unsigned bi_count_staging_registers(const bi_instr *ins) { enum bi_sr_count count = bi_opcode_props[ins->op].sr_count; unsigned vecsize = ins->vecsize + 1; /* XXX: off-by-one */ switch (count) { case BI_SR_COUNT_0 ... BI_SR_COUNT_4: return count; case BI_SR_COUNT_FORMAT: return bi_is_regfmt_16(ins->register_format) ? DIV_ROUND_UP(vecsize, 2) : vecsize; case BI_SR_COUNT_VECSIZE: return vecsize; case BI_SR_COUNT_SR_COUNT: return ins->sr_count; } unreachable("Invalid sr_count"); } unsigned bi_count_read_registers(const bi_instr *ins, unsigned s) { /* ATOM reads 1 but writes 2. Exception for ACMPXCHG */ if (s == 0 && ins->op == BI_OPCODE_ATOM_RETURN_I32) return (ins->atom_opc == BI_ATOM_OPC_ACMPXCHG) ? 2 : 1; else if (s == 0 && bi_opcode_props[ins->op].sr_read) return bi_count_staging_registers(ins); else if (s == 4 && ins->op == BI_OPCODE_BLEND) return ins->sr_count_2; /* Dual source blending */ else if (s == 0 && ins->op == BI_OPCODE_SPLIT_I32) return ins->nr_dests; else return 1; } unsigned bi_count_write_registers(const bi_instr *ins, unsigned d) { if (d == 0 && bi_opcode_props[ins->op].sr_write) { switch (ins->op) { case BI_OPCODE_TEXC: case BI_OPCODE_TEXC_DUAL: if (ins->sr_count_2) return ins->sr_count; else return bi_is_regfmt_16(ins->register_format) ? 2 : 4; case BI_OPCODE_TEX_SINGLE: case BI_OPCODE_TEX_FETCH: case BI_OPCODE_TEX_GATHER: { unsigned chans = util_bitcount(ins->write_mask); return bi_is_regfmt_16(ins->register_format) ? DIV_ROUND_UP(chans, 2) : chans; } case BI_OPCODE_ACMPXCHG_I32: /* Reads 2 but writes 1 */ return 1; case BI_OPCODE_ATOM1_RETURN_I32: /* Allow omitting the destination for plain ATOM1 */ return bi_is_null(ins->dest[0]) ? 0 : ins->sr_count; default: return bi_count_staging_registers(ins); } } else if (ins->op == BI_OPCODE_SEG_ADD_I64) { return 2; } else if (ins->op == BI_OPCODE_TEXC_DUAL && d == 1) { return ins->sr_count_2; } else if (ins->op == BI_OPCODE_COLLECT_I32 && d == 0) { return ins->nr_srcs; } return 1; } unsigned bi_writemask(const bi_instr *ins, unsigned d) { unsigned mask = BITFIELD_MASK(bi_count_write_registers(ins, d)); unsigned shift = ins->dest[d].offset; return (mask << shift); } bi_clause * bi_next_clause(bi_context *ctx, bi_block *block, bi_clause *clause) { if (!block && !clause) return NULL; /* Try the first clause in this block if we're starting from scratch */ if (!clause && !list_is_empty(&block->clauses)) return list_first_entry(&block->clauses, bi_clause, link); /* Try the next clause in this block */ if (clause && clause->link.next != &block->clauses) return list_first_entry(&(clause->link), bi_clause, link); /* Try the next block, or the one after that if it's empty, etc .*/ bi_block *next_block = bi_next_block(block); bi_foreach_block_from(ctx, next_block, block) { if (!list_is_empty(&block->clauses)) return list_first_entry(&block->clauses, bi_clause, link); } return NULL; } /* Does an instruction have a side effect not captured by its register * destination? Applies to certain message-passing instructions, +DISCARD, and * branching only, used in dead code elimation. Branches are characterized by * `last` which applies to them and some atomics, +BARRIER, +BLEND which * implies no loss of generality */ bool bi_side_effects(const bi_instr *I) { if (bi_opcode_props[I->op].last) return true; switch (I->op) { case BI_OPCODE_DISCARD_F32: case BI_OPCODE_DISCARD_B32: return true; default: break; } switch (bi_opcode_props[I->op].message) { case BIFROST_MESSAGE_NONE: case BIFROST_MESSAGE_VARYING: case BIFROST_MESSAGE_ATTRIBUTE: case BIFROST_MESSAGE_TEX: case BIFROST_MESSAGE_VARTEX: case BIFROST_MESSAGE_LOAD: case BIFROST_MESSAGE_64BIT: return false; case BIFROST_MESSAGE_STORE: case BIFROST_MESSAGE_ATOMIC: case BIFROST_MESSAGE_BARRIER: case BIFROST_MESSAGE_BLEND: case BIFROST_MESSAGE_Z_STENCIL: case BIFROST_MESSAGE_ATEST: case BIFROST_MESSAGE_JOB: return true; case BIFROST_MESSAGE_TILE: return (I->op != BI_OPCODE_LD_TILE); } unreachable("Invalid message type"); } /* Branch reconvergence is required when the execution mask may change * between adjacent instructions (clauses). This occurs for conditional * branches and for the last instruction (clause) in a block whose * fallthrough successor has multiple predecessors. */ bool bi_reconverge_branches(bi_block *block) { if (bi_num_successors(block) == 1) return bi_num_predecessors(block->successors[0]) > 1; else return true; } /* * When MUX.i32 or MUX.v2i16 is used to multiplex entire sources, they can be * replaced by CSEL as follows: * * MUX.neg(x, y, b) -> CSEL.s.lt(b, 0, x, y) * MUX.int_zero(x, y, b) -> CSEL.i.eq(b, 0, x, y) * MUX.fp_zero(x, y, b) -> CSEL.f.eq(b, 0, x, y) * * MUX.bit cannot be transformed like this. * * Note that MUX.v2i16 has partial support for swizzles, which CSEL.v2i16 lacks. * So we must check the swizzles too. */ bool bi_can_replace_with_csel(bi_instr *I) { return ((I->op == BI_OPCODE_MUX_I32) || (I->op == BI_OPCODE_MUX_V2I16)) && (I->mux != BI_MUX_BIT) && (I->src[0].swizzle == BI_SWIZZLE_H01) && (I->src[1].swizzle == BI_SWIZZLE_H01) && (I->src[2].swizzle == BI_SWIZZLE_H01); } static enum bi_opcode bi_csel_for_mux(bool must_sign, bool b32, enum bi_mux mux) { switch (mux) { case BI_MUX_INT_ZERO: if (must_sign) return b32 ? BI_OPCODE_CSEL_U32 : BI_OPCODE_CSEL_V2U16; else return b32 ? BI_OPCODE_CSEL_I32 : BI_OPCODE_CSEL_V2I16; case BI_MUX_NEG: return b32 ? BI_OPCODE_CSEL_S32 : BI_OPCODE_CSEL_V2S16; case BI_MUX_FP_ZERO: return b32 ? BI_OPCODE_CSEL_F32 : BI_OPCODE_CSEL_V2F16; default: unreachable("No CSEL for MUX.bit"); } } bi_instr * bi_csel_from_mux(bi_builder *b, const bi_instr *I, bool must_sign) { assert(I->op == BI_OPCODE_MUX_I32 || I->op == BI_OPCODE_MUX_V2I16); /* Build a new CSEL */ enum bi_cmpf cmpf = (I->mux == BI_MUX_NEG) ? BI_CMPF_LT : BI_CMPF_EQ; bi_instr *csel = bi_csel_u32_to(b, I->dest[0], I->src[2], bi_zero(), I->src[0], I->src[1], cmpf); /* Fixup the opcode and use it */ csel->op = bi_csel_for_mux(must_sign, I->op == BI_OPCODE_MUX_I32, I->mux); return csel; }