/* * Copyright © 2014 Broadcom * * 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 "util/u_memory.h" #include "util/ralloc.h" #include "vc4_qir.h" #include "vc4_qpu.h" struct qir_op_info { const char *name; uint8_t ndst, nsrc; bool has_side_effects; bool multi_instruction; }; static const struct qir_op_info qir_op_info[] = { [QOP_MOV] = { "mov", 1, 1 }, [QOP_FMOV] = { "fmov", 1, 1 }, [QOP_MMOV] = { "mmov", 1, 1 }, [QOP_FADD] = { "fadd", 1, 2 }, [QOP_FSUB] = { "fsub", 1, 2 }, [QOP_FMUL] = { "fmul", 1, 2 }, [QOP_MUL24] = { "mul24", 1, 2 }, [QOP_V8MULD] = {"v8muld", 1, 2 }, [QOP_V8MIN] = {"v8min", 1, 2 }, [QOP_V8MAX] = {"v8max", 1, 2 }, [QOP_V8ADDS] = {"v8adds", 1, 2 }, [QOP_V8SUBS] = {"v8subs", 1, 2 }, [QOP_FMIN] = { "fmin", 1, 2 }, [QOP_FMAX] = { "fmax", 1, 2 }, [QOP_FMINABS] = { "fminabs", 1, 2 }, [QOP_FMAXABS] = { "fmaxabs", 1, 2 }, [QOP_FTOI] = { "ftoi", 1, 1 }, [QOP_ITOF] = { "itof", 1, 1 }, [QOP_ADD] = { "add", 1, 2 }, [QOP_SUB] = { "sub", 1, 2 }, [QOP_SHR] = { "shr", 1, 2 }, [QOP_ASR] = { "asr", 1, 2 }, [QOP_SHL] = { "shl", 1, 2 }, [QOP_MIN] = { "min", 1, 2 }, [QOP_MAX] = { "max", 1, 2 }, [QOP_AND] = { "and", 1, 2 }, [QOP_OR] = { "or", 1, 2 }, [QOP_XOR] = { "xor", 1, 2 }, [QOP_NOT] = { "not", 1, 1 }, [QOP_RCP] = { "rcp", 1, 1, false, true }, [QOP_RSQ] = { "rsq", 1, 1, false, true }, [QOP_EXP2] = { "exp2", 1, 2, false, true }, [QOP_LOG2] = { "log2", 1, 2, false, true }, [QOP_TLB_DISCARD_SETUP] = { "discard", 0, 1, true }, [QOP_TLB_STENCIL_SETUP] = { "tlb_stencil_setup", 0, 1, true }, [QOP_TLB_Z_WRITE] = { "tlb_z", 0, 1, true }, [QOP_TLB_COLOR_WRITE] = { "tlb_color", 0, 1, true }, [QOP_TLB_COLOR_WRITE_MS] = { "tlb_color_ms", 0, 1, true }, [QOP_TLB_COLOR_READ] = { "tlb_color_read", 1, 0 }, [QOP_MS_MASK] = { "ms_mask", 0, 1, true }, [QOP_VARY_ADD_C] = { "vary_add_c", 1, 1 }, [QOP_FRAG_X] = { "frag_x", 1, 0 }, [QOP_FRAG_Y] = { "frag_y", 1, 0 }, [QOP_FRAG_Z] = { "frag_z", 1, 0 }, [QOP_FRAG_W] = { "frag_w", 1, 0 }, [QOP_FRAG_REV_FLAG] = { "frag_rev_flag", 1, 0 }, [QOP_TEX_S] = { "tex_s", 0, 2 }, [QOP_TEX_T] = { "tex_t", 0, 2 }, [QOP_TEX_R] = { "tex_r", 0, 2 }, [QOP_TEX_B] = { "tex_b", 0, 2 }, [QOP_TEX_DIRECT] = { "tex_direct", 0, 2 }, [QOP_TEX_RESULT] = { "tex_result", 1, 0, true }, }; static const char * qir_get_op_name(enum qop qop) { if (qop < ARRAY_SIZE(qir_op_info) && qir_op_info[qop].name) return qir_op_info[qop].name; else return "???"; } int qir_get_op_nsrc(enum qop qop) { if (qop < ARRAY_SIZE(qir_op_info) && qir_op_info[qop].name) return qir_op_info[qop].nsrc; else abort(); } /** * Returns whether the instruction has any side effects that must be * preserved. */ bool qir_has_side_effects(struct vc4_compile *c, struct qinst *inst) { return qir_op_info[inst->op].has_side_effects; } bool qir_has_side_effect_reads(struct vc4_compile *c, struct qinst *inst) { /* We can dead-code eliminate varyings, because we only tell the VS * about the live ones at the end. But we have to preserve the * point/line coordinates reads, because they're generated by * fixed-function hardware. */ for (int i = 0; i < qir_get_op_nsrc(inst->op); i++) { if (inst->src[i].file == QFILE_VARY && c->input_slots[inst->src[i].index].slot == 0xff) { return true; } if (inst->src[i].file == QFILE_VPM) return true; } if (inst->dst.file == QFILE_VPM) return true; return false; } bool qir_is_multi_instruction(struct qinst *inst) { return qir_op_info[inst->op].multi_instruction; } bool qir_is_mul(struct qinst *inst) { switch (inst->op) { case QOP_MMOV: case QOP_FMUL: case QOP_MUL24: case QOP_V8MULD: case QOP_V8MIN: case QOP_V8MAX: case QOP_V8ADDS: case QOP_V8SUBS: return true; default: return false; } } bool qir_is_float_input(struct qinst *inst) { switch (inst->op) { case QOP_FMOV: case QOP_FMUL: case QOP_FADD: case QOP_FSUB: case QOP_FMIN: case QOP_FMAX: case QOP_FMINABS: case QOP_FMAXABS: case QOP_FTOI: return true; default: return false; } } bool qir_is_raw_mov(struct qinst *inst) { return ((inst->op == QOP_MOV || inst->op == QOP_FMOV || inst->op == QOP_MMOV) && inst->cond == QPU_COND_ALWAYS && !inst->dst.pack && !inst->src[0].pack); } bool qir_is_tex(struct qinst *inst) { return inst->op >= QOP_TEX_S && inst->op <= QOP_TEX_DIRECT; } bool qir_depends_on_flags(struct qinst *inst) { return (inst->cond != QPU_COND_ALWAYS && inst->cond != QPU_COND_NEVER); } bool qir_writes_r4(struct qinst *inst) { switch (inst->op) { case QOP_TEX_RESULT: case QOP_TLB_COLOR_READ: case QOP_RCP: case QOP_RSQ: case QOP_EXP2: case QOP_LOG2: return true; default: return false; } } static void qir_print_reg(struct vc4_compile *c, struct qreg reg, bool write) { static const char *files[] = { [QFILE_TEMP] = "t", [QFILE_VARY] = "v", [QFILE_UNIF] = "u", }; if (reg.file == QFILE_NULL) { fprintf(stderr, "null"); } else if (reg.file == QFILE_SMALL_IMM) { if ((int)reg.index >= -16 && (int)reg.index <= 15) fprintf(stderr, "%d", reg.index); else fprintf(stderr, "%f", uif(reg.index)); } else if (reg.file == QFILE_VPM) { if (write) { fprintf(stderr, "vpm"); } else { fprintf(stderr, "vpm%d.%d", reg.index / 4, reg.index % 4); } } else { fprintf(stderr, "%s%d", files[reg.file], reg.index); } if (reg.file == QFILE_UNIF && c->uniform_contents[reg.index] == QUNIFORM_CONSTANT) { fprintf(stderr, " (0x%08x / %f)", c->uniform_data[reg.index], uif(c->uniform_data[reg.index])); } } void qir_dump_inst(struct vc4_compile *c, struct qinst *inst) { static const char *conditions[] = { [QPU_COND_ALWAYS] = "", [QPU_COND_NEVER] = ".never", [QPU_COND_ZS] = ".zs", [QPU_COND_ZC] = ".zc", [QPU_COND_NS] = ".ns", [QPU_COND_NC] = ".nc", [QPU_COND_CS] = ".cs", [QPU_COND_CC] = ".cc", }; fprintf(stderr, "%s%s%s ", qir_get_op_name(inst->op), conditions[inst->cond], inst->sf ? ".sf" : ""); qir_print_reg(c, inst->dst, true); if (inst->dst.pack) { if (inst->dst.pack) { if (qir_is_mul(inst)) vc4_qpu_disasm_pack_mul(stderr, inst->dst.pack); else vc4_qpu_disasm_pack_a(stderr, inst->dst.pack); } } for (int i = 0; i < qir_get_op_nsrc(inst->op); i++) { fprintf(stderr, ", "); qir_print_reg(c, inst->src[i], false); vc4_qpu_disasm_unpack(stderr, inst->src[i].pack); } } void qir_dump(struct vc4_compile *c) { list_for_each_entry(struct qinst, inst, &c->instructions, link) { qir_dump_inst(c, inst); fprintf(stderr, "\n"); } } struct qreg qir_get_temp(struct vc4_compile *c) { struct qreg reg; reg.file = QFILE_TEMP; reg.index = c->num_temps++; reg.pack = 0; if (c->num_temps > c->defs_array_size) { uint32_t old_size = c->defs_array_size; c->defs_array_size = MAX2(old_size * 2, 16); c->defs = reralloc(c, c->defs, struct qinst *, c->defs_array_size); memset(&c->defs[old_size], 0, sizeof(c->defs[0]) * (c->defs_array_size - old_size)); } return reg; } struct qinst * qir_inst(enum qop op, struct qreg dst, struct qreg src0, struct qreg src1) { struct qinst *inst = CALLOC_STRUCT(qinst); inst->op = op; inst->dst = dst; inst->src = calloc(2, sizeof(inst->src[0])); inst->src[0] = src0; inst->src[1] = src1; inst->cond = QPU_COND_ALWAYS; return inst; } struct qinst * qir_inst4(enum qop op, struct qreg dst, struct qreg a, struct qreg b, struct qreg c, struct qreg d) { struct qinst *inst = CALLOC_STRUCT(qinst); inst->op = op; inst->dst = dst; inst->src = calloc(4, sizeof(*inst->src)); inst->src[0] = a; inst->src[1] = b; inst->src[2] = c; inst->src[3] = d; return inst; } void qir_emit(struct vc4_compile *c, struct qinst *inst) { if (inst->dst.file == QFILE_TEMP) c->defs[inst->dst.index] = inst; qir_emit_nodef(c, inst); } bool qir_reg_equals(struct qreg a, struct qreg b) { return a.file == b.file && a.index == b.index; } struct vc4_compile * qir_compile_init(void) { struct vc4_compile *c = rzalloc(NULL, struct vc4_compile); list_inithead(&c->instructions); c->output_position_index = -1; c->output_color_index = -1; c->output_point_size_index = -1; c->output_sample_mask_index = -1; c->def_ht = _mesa_hash_table_create(c, _mesa_hash_pointer, _mesa_key_pointer_equal); return c; } void qir_remove_instruction(struct vc4_compile *c, struct qinst *qinst) { if (qinst->dst.file == QFILE_TEMP) c->defs[qinst->dst.index] = NULL; list_del(&qinst->link); free(qinst->src); free(qinst); } struct qreg qir_follow_movs(struct vc4_compile *c, struct qreg reg) { int pack = reg.pack; while (reg.file == QFILE_TEMP && c->defs[reg.index] && (c->defs[reg.index]->op == QOP_MOV || c->defs[reg.index]->op == QOP_FMOV || c->defs[reg.index]->op == QOP_MMOV)&& !c->defs[reg.index]->dst.pack && !c->defs[reg.index]->src[0].pack) { reg = c->defs[reg.index]->src[0]; } reg.pack = pack; return reg; } void qir_compile_destroy(struct vc4_compile *c) { while (!list_empty(&c->instructions)) { struct qinst *qinst = (struct qinst *)c->instructions.next; qir_remove_instruction(c, qinst); } ralloc_free(c); } const char * qir_get_stage_name(enum qstage stage) { static const char *names[] = { [QSTAGE_FRAG] = "FS", [QSTAGE_VERT] = "VS", [QSTAGE_COORD] = "CS", }; return names[stage]; } struct qreg qir_uniform(struct vc4_compile *c, enum quniform_contents contents, uint32_t data) { for (int i = 0; i < c->num_uniforms; i++) { if (c->uniform_contents[i] == contents && c->uniform_data[i] == data) { return (struct qreg) { QFILE_UNIF, i }; } } uint32_t uniform = c->num_uniforms++; struct qreg u = { QFILE_UNIF, uniform }; if (uniform >= c->uniform_array_size) { c->uniform_array_size = MAX2(MAX2(16, uniform + 1), c->uniform_array_size * 2); c->uniform_data = reralloc(c, c->uniform_data, uint32_t, c->uniform_array_size); c->uniform_contents = reralloc(c, c->uniform_contents, enum quniform_contents, c->uniform_array_size); } c->uniform_contents[uniform] = contents; c->uniform_data[uniform] = data; return u; } void qir_SF(struct vc4_compile *c, struct qreg src) { struct qinst *last_inst = NULL; if (!list_empty(&c->instructions)) last_inst = (struct qinst *)c->instructions.prev; if (src.file != QFILE_TEMP || !c->defs[src.index] || last_inst != c->defs[src.index] || qir_is_multi_instruction(last_inst)) { src = qir_MOV(c, src); last_inst = (struct qinst *)c->instructions.prev; } last_inst->sf = true; } #define OPTPASS(func) \ do { \ bool stage_progress = func(c); \ if (stage_progress) { \ progress = true; \ if (print_opt_debug) { \ fprintf(stderr, \ "QIR opt pass %2d: %s progress\n", \ pass, #func); \ } \ } \ } while (0) void qir_optimize(struct vc4_compile *c) { bool print_opt_debug = false; int pass = 1; while (true) { bool progress = false; OPTPASS(qir_opt_algebraic); OPTPASS(qir_opt_cse); OPTPASS(qir_opt_constant_folding); OPTPASS(qir_opt_copy_propagation); OPTPASS(qir_opt_dead_code); OPTPASS(qir_opt_small_immediates); OPTPASS(qir_opt_vpm_writes); if (!progress) break; pass++; } }