/* * Copyright © 2010 Intel Corporation * Copyright © 2014-2017 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. */ /** * @file * * The basic model of the list scheduler is to take a basic block, compute a * DAG of the dependencies, and make a list of the DAG heads. Heuristically * pick a DAG head, then put all the children that are now DAG heads into the * list of things to schedule. * * The goal of scheduling here is to pack pairs of operations together in a * single QPU instruction. */ #include "qpu/qpu_disasm.h" #include "v3d_compiler.h" #include "util/ralloc.h" #include "util/dag.h" static bool debug; struct schedule_node_child; struct schedule_node { struct dag_node dag; struct list_head link; struct qinst *inst; /* Longest cycles + instruction_latency() of any parent of this node. */ uint32_t unblocked_time; /** * Minimum number of cycles from scheduling this instruction until the * end of the program, based on the slowest dependency chain through * the children. */ uint32_t delay; /** * cycles between this instruction being scheduled and when its result * can be consumed. */ uint32_t latency; }; /* When walking the instructions in reverse, we need to swap before/after in * add_dep(). */ enum direction { F, R }; struct schedule_state { const struct v3d_device_info *devinfo; struct dag *dag; struct schedule_node *last_r[6]; struct schedule_node *last_rf[64]; struct schedule_node *last_sf; struct schedule_node *last_vpm_read; struct schedule_node *last_tmu_write; struct schedule_node *last_tmu_config; struct schedule_node *last_tlb; struct schedule_node *last_vpm; struct schedule_node *last_unif; struct schedule_node *last_rtop; enum direction dir; /* Estimated cycle when the current instruction would start. */ uint32_t time; }; static void add_dep(struct schedule_state *state, struct schedule_node *before, struct schedule_node *after, bool write) { bool write_after_read = !write && state->dir == R; void *edge_data = (void *)(uintptr_t)write_after_read; if (!before || !after) return; assert(before != after); if (state->dir == F) dag_add_edge(&before->dag, &after->dag, edge_data); else dag_add_edge(&after->dag, &before->dag, edge_data); } static void add_read_dep(struct schedule_state *state, struct schedule_node *before, struct schedule_node *after) { add_dep(state, before, after, false); } static void add_write_dep(struct schedule_state *state, struct schedule_node **before, struct schedule_node *after) { add_dep(state, *before, after, true); *before = after; } static bool qpu_inst_is_tlb(const struct v3d_qpu_instr *inst) { if (inst->type != V3D_QPU_INSTR_TYPE_ALU) return false; if (inst->alu.add.magic_write && (inst->alu.add.waddr == V3D_QPU_WADDR_TLB || inst->alu.add.waddr == V3D_QPU_WADDR_TLBU)) return true; if (inst->alu.mul.magic_write && (inst->alu.mul.waddr == V3D_QPU_WADDR_TLB || inst->alu.mul.waddr == V3D_QPU_WADDR_TLBU)) return true; return false; } static void process_mux_deps(struct schedule_state *state, struct schedule_node *n, enum v3d_qpu_mux mux) { switch (mux) { case V3D_QPU_MUX_A: add_read_dep(state, state->last_rf[n->inst->qpu.raddr_a], n); break; case V3D_QPU_MUX_B: if (!n->inst->qpu.sig.small_imm) { add_read_dep(state, state->last_rf[n->inst->qpu.raddr_b], n); } break; default: add_read_dep(state, state->last_r[mux - V3D_QPU_MUX_R0], n); break; } } static void process_waddr_deps(struct schedule_state *state, struct schedule_node *n, uint32_t waddr, bool magic) { if (!magic) { add_write_dep(state, &state->last_rf[waddr], n); } else if (v3d_qpu_magic_waddr_is_tmu(waddr)) { /* XXX perf: For V3D 4.x, we could reorder TMU writes other * than the TMUS/TMUD/TMUA to improve scheduling flexibility. */ add_write_dep(state, &state->last_tmu_write, n); switch (waddr) { case V3D_QPU_WADDR_TMUS: case V3D_QPU_WADDR_TMUSCM: case V3D_QPU_WADDR_TMUSF: case V3D_QPU_WADDR_TMUSLOD: add_write_dep(state, &state->last_tmu_config, n); break; default: break; } } else if (v3d_qpu_magic_waddr_is_sfu(waddr)) { /* Handled by v3d_qpu_writes_r4() check. */ } else { switch (waddr) { case V3D_QPU_WADDR_R0: case V3D_QPU_WADDR_R1: case V3D_QPU_WADDR_R2: add_write_dep(state, &state->last_r[waddr - V3D_QPU_WADDR_R0], n); break; case V3D_QPU_WADDR_R3: case V3D_QPU_WADDR_R4: case V3D_QPU_WADDR_R5: /* Handled by v3d_qpu_writes_r*() checks below. */ break; case V3D_QPU_WADDR_VPM: case V3D_QPU_WADDR_VPMU: add_write_dep(state, &state->last_vpm, n); break; case V3D_QPU_WADDR_TLB: case V3D_QPU_WADDR_TLBU: add_write_dep(state, &state->last_tlb, n); break; case V3D_QPU_WADDR_SYNC: case V3D_QPU_WADDR_SYNCB: case V3D_QPU_WADDR_SYNCU: /* For CS barrier(): Sync against any other memory * accesses. There doesn't appear to be any need for * barriers to affect ALU operations. */ add_write_dep(state, &state->last_tmu_write, n); break; case V3D_QPU_WADDR_NOP: break; default: fprintf(stderr, "Unknown waddr %d\n", waddr); abort(); } } } /** * Common code for dependencies that need to be tracked both forward and * backward. * * This is for things like "all reads of r4 have to happen between the r4 * writes that surround them". */ static void calculate_deps(struct schedule_state *state, struct schedule_node *n) { const struct v3d_device_info *devinfo = state->devinfo; struct qinst *qinst = n->inst; struct v3d_qpu_instr *inst = &qinst->qpu; /* If the input and output segments are shared, then all VPM reads to * a location need to happen before all writes. We handle this by * serializing all VPM operations for now. */ bool separate_vpm_segment = false; if (inst->type == V3D_QPU_INSTR_TYPE_BRANCH) { if (inst->branch.cond != V3D_QPU_BRANCH_COND_ALWAYS) add_read_dep(state, state->last_sf, n); /* XXX: BDI */ /* XXX: BDU */ /* XXX: ub */ /* XXX: raddr_a */ add_write_dep(state, &state->last_unif, n); return; } assert(inst->type == V3D_QPU_INSTR_TYPE_ALU); /* XXX: LOAD_IMM */ if (v3d_qpu_add_op_num_src(inst->alu.add.op) > 0) process_mux_deps(state, n, inst->alu.add.a); if (v3d_qpu_add_op_num_src(inst->alu.add.op) > 1) process_mux_deps(state, n, inst->alu.add.b); if (v3d_qpu_mul_op_num_src(inst->alu.mul.op) > 0) process_mux_deps(state, n, inst->alu.mul.a); if (v3d_qpu_mul_op_num_src(inst->alu.mul.op) > 1) process_mux_deps(state, n, inst->alu.mul.b); switch (inst->alu.add.op) { case V3D_QPU_A_VPMSETUP: /* Could distinguish read/write by unpacking the uniform. */ add_write_dep(state, &state->last_vpm, n); add_write_dep(state, &state->last_vpm_read, n); break; case V3D_QPU_A_STVPMV: case V3D_QPU_A_STVPMD: case V3D_QPU_A_STVPMP: add_write_dep(state, &state->last_vpm, n); break; case V3D_QPU_A_LDVPMV_IN: case V3D_QPU_A_LDVPMD_IN: case V3D_QPU_A_LDVPMG_IN: case V3D_QPU_A_LDVPMP: if (!separate_vpm_segment) add_write_dep(state, &state->last_vpm, n); break; case V3D_QPU_A_VPMWT: add_read_dep(state, state->last_vpm, n); break; case V3D_QPU_A_MSF: add_read_dep(state, state->last_tlb, n); break; case V3D_QPU_A_SETMSF: case V3D_QPU_A_SETREVF: add_write_dep(state, &state->last_tlb, n); break; default: break; } switch (inst->alu.mul.op) { case V3D_QPU_M_MULTOP: case V3D_QPU_M_UMUL24: /* MULTOP sets rtop, and UMUL24 implicitly reads rtop and * resets it to 0. We could possibly reorder umul24s relative * to each other, but for now just keep all the MUL parts in * order. */ add_write_dep(state, &state->last_rtop, n); break; default: break; } if (inst->alu.add.op != V3D_QPU_A_NOP) { process_waddr_deps(state, n, inst->alu.add.waddr, inst->alu.add.magic_write); } if (inst->alu.mul.op != V3D_QPU_M_NOP) { process_waddr_deps(state, n, inst->alu.mul.waddr, inst->alu.mul.magic_write); } if (v3d_qpu_sig_writes_address(devinfo, &inst->sig)) { process_waddr_deps(state, n, inst->sig_addr, inst->sig_magic); } if (v3d_qpu_writes_r3(devinfo, inst)) add_write_dep(state, &state->last_r[3], n); if (v3d_qpu_writes_r4(devinfo, inst)) add_write_dep(state, &state->last_r[4], n); if (v3d_qpu_writes_r5(devinfo, inst)) add_write_dep(state, &state->last_r[5], n); if (inst->sig.thrsw) { /* All accumulator contents and flags are undefined after the * switch. */ for (int i = 0; i < ARRAY_SIZE(state->last_r); i++) add_write_dep(state, &state->last_r[i], n); add_write_dep(state, &state->last_sf, n); add_write_dep(state, &state->last_rtop, n); /* Scoreboard-locking operations have to stay after the last * thread switch. */ add_write_dep(state, &state->last_tlb, n); add_write_dep(state, &state->last_tmu_write, n); add_write_dep(state, &state->last_tmu_config, n); } if (v3d_qpu_waits_on_tmu(inst)) { /* TMU loads are coming from a FIFO, so ordering is important. */ add_write_dep(state, &state->last_tmu_write, n); } if (inst->sig.wrtmuc) add_write_dep(state, &state->last_tmu_config, n); if (inst->sig.ldtlb | inst->sig.ldtlbu) add_read_dep(state, state->last_tlb, n); if (inst->sig.ldvpm) { add_write_dep(state, &state->last_vpm_read, n); /* At least for now, we're doing shared I/O segments, so queue * all writes after all reads. */ if (!separate_vpm_segment) add_write_dep(state, &state->last_vpm, n); } /* inst->sig.ldunif or sideband uniform read */ if (vir_has_uniform(qinst)) add_write_dep(state, &state->last_unif, n); if (v3d_qpu_reads_flags(inst)) add_read_dep(state, state->last_sf, n); if (v3d_qpu_writes_flags(inst)) add_write_dep(state, &state->last_sf, n); } static void calculate_forward_deps(struct v3d_compile *c, struct dag *dag, struct list_head *schedule_list) { struct schedule_state state; memset(&state, 0, sizeof(state)); state.dag = dag; state.devinfo = c->devinfo; state.dir = F; list_for_each_entry(struct schedule_node, node, schedule_list, link) calculate_deps(&state, node); } static void calculate_reverse_deps(struct v3d_compile *c, struct dag *dag, struct list_head *schedule_list) { struct schedule_state state; memset(&state, 0, sizeof(state)); state.dag = dag; state.devinfo = c->devinfo; state.dir = R; list_for_each_entry_rev(struct schedule_node, node, schedule_list, link) { calculate_deps(&state, (struct schedule_node *)node); } } struct choose_scoreboard { struct dag *dag; int tick; int last_magic_sfu_write_tick; int last_ldvary_tick; int last_uniforms_reset_tick; int last_thrsw_tick; bool tlb_locked; }; static bool mux_reads_too_soon(struct choose_scoreboard *scoreboard, const struct v3d_qpu_instr *inst, enum v3d_qpu_mux mux) { switch (mux) { case V3D_QPU_MUX_R4: if (scoreboard->tick - scoreboard->last_magic_sfu_write_tick <= 2) return true; break; case V3D_QPU_MUX_R5: if (scoreboard->tick - scoreboard->last_ldvary_tick <= 1) return true; break; default: break; } return false; } static bool reads_too_soon_after_write(struct choose_scoreboard *scoreboard, struct qinst *qinst) { const struct v3d_qpu_instr *inst = &qinst->qpu; /* XXX: Branching off of raddr. */ if (inst->type == V3D_QPU_INSTR_TYPE_BRANCH) return false; assert(inst->type == V3D_QPU_INSTR_TYPE_ALU); if (inst->alu.add.op != V3D_QPU_A_NOP) { if (v3d_qpu_add_op_num_src(inst->alu.add.op) > 0 && mux_reads_too_soon(scoreboard, inst, inst->alu.add.a)) { return true; } if (v3d_qpu_add_op_num_src(inst->alu.add.op) > 1 && mux_reads_too_soon(scoreboard, inst, inst->alu.add.b)) { return true; } } if (inst->alu.mul.op != V3D_QPU_M_NOP) { if (v3d_qpu_mul_op_num_src(inst->alu.mul.op) > 0 && mux_reads_too_soon(scoreboard, inst, inst->alu.mul.a)) { return true; } if (v3d_qpu_mul_op_num_src(inst->alu.mul.op) > 1 && mux_reads_too_soon(scoreboard, inst, inst->alu.mul.b)) { return true; } } /* XXX: imm */ return false; } static bool writes_too_soon_after_write(const struct v3d_device_info *devinfo, struct choose_scoreboard *scoreboard, struct qinst *qinst) { const struct v3d_qpu_instr *inst = &qinst->qpu; /* Don't schedule any other r4 write too soon after an SFU write. * This would normally be prevented by dependency tracking, but might * occur if a dead SFU computation makes it to scheduling. */ if (scoreboard->tick - scoreboard->last_magic_sfu_write_tick < 2 && v3d_qpu_writes_r4(devinfo, inst)) return true; return false; } static bool pixel_scoreboard_too_soon(struct choose_scoreboard *scoreboard, const struct v3d_qpu_instr *inst) { return (scoreboard->tick == 0 && qpu_inst_is_tlb(inst)); } static int get_instruction_priority(const struct v3d_qpu_instr *inst) { uint32_t baseline_score; uint32_t next_score = 0; /* Schedule TLB operations as late as possible, to get more * parallelism between shaders. */ if (qpu_inst_is_tlb(inst)) return next_score; next_score++; /* Schedule texture read results collection late to hide latency. */ if (v3d_qpu_waits_on_tmu(inst)) return next_score; next_score++; /* XXX perf: We should schedule SFU ALU ops so that the reader is 2 * instructions after the producer if possible, not just 1. */ /* Default score for things that aren't otherwise special. */ baseline_score = next_score; next_score++; /* Schedule texture read setup early to hide their latency better. */ if (v3d_qpu_writes_tmu(inst)) return next_score; next_score++; return baseline_score; } static bool qpu_magic_waddr_is_periph(enum v3d_qpu_waddr waddr) { return (v3d_qpu_magic_waddr_is_tmu(waddr) || v3d_qpu_magic_waddr_is_sfu(waddr) || v3d_qpu_magic_waddr_is_tlb(waddr) || v3d_qpu_magic_waddr_is_vpm(waddr) || v3d_qpu_magic_waddr_is_tsy(waddr)); } static bool qpu_accesses_peripheral(const struct v3d_qpu_instr *inst) { if (v3d_qpu_uses_vpm(inst)) return true; if (v3d_qpu_uses_sfu(inst)) return true; if (inst->type == V3D_QPU_INSTR_TYPE_ALU) { if (inst->alu.add.op != V3D_QPU_A_NOP && inst->alu.add.magic_write && qpu_magic_waddr_is_periph(inst->alu.add.waddr)) { return true; } if (inst->alu.add.op == V3D_QPU_A_TMUWT) return true; if (inst->alu.mul.op != V3D_QPU_M_NOP && inst->alu.mul.magic_write && qpu_magic_waddr_is_periph(inst->alu.mul.waddr)) { return true; } } return (inst->sig.ldvpm || inst->sig.ldtmu || inst->sig.ldtlb || inst->sig.ldtlbu || inst->sig.wrtmuc); } static bool qpu_compatible_peripheral_access(const struct v3d_device_info *devinfo, const struct v3d_qpu_instr *a, const struct v3d_qpu_instr *b) { const bool a_uses_peripheral = qpu_accesses_peripheral(a); const bool b_uses_peripheral = qpu_accesses_peripheral(b); /* We can always do one peripheral access per instruction. */ if (!a_uses_peripheral || !b_uses_peripheral) return true; if (devinfo->ver < 41) return false; /* V3D 4.1 and later allow TMU read along with a VPM read or write, and * WRTMUC with a TMU magic register write (other than tmuc). */ if ((a->sig.ldtmu && v3d_qpu_uses_vpm(b)) || (b->sig.ldtmu && v3d_qpu_uses_vpm(a))) { return true; } if ((a->sig.wrtmuc && v3d_qpu_writes_tmu_not_tmuc(b)) || (b->sig.wrtmuc && v3d_qpu_writes_tmu_not_tmuc(a))) { return true; } return false; } static bool qpu_merge_inst(const struct v3d_device_info *devinfo, struct v3d_qpu_instr *result, const struct v3d_qpu_instr *a, const struct v3d_qpu_instr *b) { if (a->type != V3D_QPU_INSTR_TYPE_ALU || b->type != V3D_QPU_INSTR_TYPE_ALU) { return false; } if (!qpu_compatible_peripheral_access(devinfo, a, b)) return false; struct v3d_qpu_instr merge = *a; if (b->alu.add.op != V3D_QPU_A_NOP) { if (a->alu.add.op != V3D_QPU_A_NOP) return false; merge.alu.add = b->alu.add; merge.flags.ac = b->flags.ac; merge.flags.apf = b->flags.apf; merge.flags.auf = b->flags.auf; } if (b->alu.mul.op != V3D_QPU_M_NOP) { if (a->alu.mul.op != V3D_QPU_M_NOP) return false; merge.alu.mul = b->alu.mul; merge.flags.mc = b->flags.mc; merge.flags.mpf = b->flags.mpf; merge.flags.muf = b->flags.muf; } if (v3d_qpu_uses_mux(b, V3D_QPU_MUX_A)) { if (v3d_qpu_uses_mux(a, V3D_QPU_MUX_A) && a->raddr_a != b->raddr_a) { return false; } merge.raddr_a = b->raddr_a; } if (v3d_qpu_uses_mux(b, V3D_QPU_MUX_B)) { if (v3d_qpu_uses_mux(a, V3D_QPU_MUX_B) && (a->raddr_b != b->raddr_b || a->sig.small_imm != b->sig.small_imm)) { return false; } merge.raddr_b = b->raddr_b; } merge.sig.thrsw |= b->sig.thrsw; merge.sig.ldunif |= b->sig.ldunif; merge.sig.ldunifrf |= b->sig.ldunifrf; merge.sig.ldunifa |= b->sig.ldunifa; merge.sig.ldunifarf |= b->sig.ldunifarf; merge.sig.ldtmu |= b->sig.ldtmu; merge.sig.ldvary |= b->sig.ldvary; merge.sig.ldvpm |= b->sig.ldvpm; merge.sig.small_imm |= b->sig.small_imm; merge.sig.ldtlb |= b->sig.ldtlb; merge.sig.ldtlbu |= b->sig.ldtlbu; merge.sig.ucb |= b->sig.ucb; merge.sig.rotate |= b->sig.rotate; merge.sig.wrtmuc |= b->sig.wrtmuc; if (v3d_qpu_sig_writes_address(devinfo, &a->sig) && v3d_qpu_sig_writes_address(devinfo, &b->sig)) return false; merge.sig_addr |= b->sig_addr; merge.sig_magic |= b->sig_magic; uint64_t packed; bool ok = v3d_qpu_instr_pack(devinfo, &merge, &packed); *result = merge; /* No modifying the real instructions on failure. */ assert(ok || (a != result && b != result)); return ok; } static struct schedule_node * choose_instruction_to_schedule(const struct v3d_device_info *devinfo, struct choose_scoreboard *scoreboard, struct schedule_node *prev_inst) { struct schedule_node *chosen = NULL; int chosen_prio = 0; /* Don't pair up anything with a thread switch signal -- emit_thrsw() * will handle pairing it along with filling the delay slots. */ if (prev_inst) { if (prev_inst->inst->qpu.sig.thrsw) return NULL; } list_for_each_entry(struct schedule_node, n, &scoreboard->dag->heads, dag.link) { const struct v3d_qpu_instr *inst = &n->inst->qpu; /* Don't choose the branch instruction until it's the last one * left. We'll move it up to fit its delay slots after we * choose it. */ if (inst->type == V3D_QPU_INSTR_TYPE_BRANCH && !list_is_singular(&scoreboard->dag->heads)) { continue; } /* "An instruction must not read from a location in physical * regfile A or B that was written to by the previous * instruction." */ if (reads_too_soon_after_write(scoreboard, n->inst)) continue; if (writes_too_soon_after_write(devinfo, scoreboard, n->inst)) continue; /* "A scoreboard wait must not occur in the first two * instructions of a fragment shader. This is either the * explicit Wait for Scoreboard signal or an implicit wait * with the first tile-buffer read or write instruction." */ if (pixel_scoreboard_too_soon(scoreboard, inst)) continue; /* ldunif and ldvary both write r5, but ldunif does so a tick * sooner. If the ldvary's r5 wasn't used, then ldunif might * otherwise get scheduled so ldunif and ldvary try to update * r5 in the same tick. * * XXX perf: To get good pipelining of a sequence of varying * loads, we need to figure out how to pair the ldvary signal * up to the instruction before the last r5 user in the * previous ldvary sequence. Currently, it usually pairs with * the last r5 user. */ if ((inst->sig.ldunif || inst->sig.ldunifa) && scoreboard->tick == scoreboard->last_ldvary_tick + 1) { continue; } /* If we're trying to pair with another instruction, check * that they're compatible. */ if (prev_inst) { /* Don't pair up a thread switch signal -- we'll * handle pairing it when we pick it on its own. */ if (inst->sig.thrsw) continue; if (prev_inst->inst->uniform != -1 && n->inst->uniform != -1) continue; /* Don't merge in something that will lock the TLB. * Hopwefully what we have in inst will release some * other instructions, allowing us to delay the * TLB-locking instruction until later. */ if (!scoreboard->tlb_locked && qpu_inst_is_tlb(inst)) continue; struct v3d_qpu_instr merged_inst; if (!qpu_merge_inst(devinfo, &merged_inst, &prev_inst->inst->qpu, inst)) { continue; } } int prio = get_instruction_priority(inst); /* Found a valid instruction. If nothing better comes along, * this one works. */ if (!chosen) { chosen = n; chosen_prio = prio; continue; } if (prio > chosen_prio) { chosen = n; chosen_prio = prio; } else if (prio < chosen_prio) { continue; } if (n->delay > chosen->delay) { chosen = n; chosen_prio = prio; } else if (n->delay < chosen->delay) { continue; } } return chosen; } static void update_scoreboard_for_magic_waddr(struct choose_scoreboard *scoreboard, enum v3d_qpu_waddr waddr) { if (v3d_qpu_magic_waddr_is_sfu(waddr)) scoreboard->last_magic_sfu_write_tick = scoreboard->tick; } static void update_scoreboard_for_chosen(struct choose_scoreboard *scoreboard, const struct v3d_qpu_instr *inst) { if (inst->type == V3D_QPU_INSTR_TYPE_BRANCH) return; assert(inst->type == V3D_QPU_INSTR_TYPE_ALU); if (inst->alu.add.op != V3D_QPU_A_NOP) { if (inst->alu.add.magic_write) { update_scoreboard_for_magic_waddr(scoreboard, inst->alu.add.waddr); } } if (inst->alu.mul.op != V3D_QPU_M_NOP) { if (inst->alu.mul.magic_write) { update_scoreboard_for_magic_waddr(scoreboard, inst->alu.mul.waddr); } } if (inst->sig.ldvary) scoreboard->last_ldvary_tick = scoreboard->tick; if (qpu_inst_is_tlb(inst)) scoreboard->tlb_locked = true; } static void dump_state(const struct v3d_device_info *devinfo, struct dag *dag) { list_for_each_entry(struct schedule_node, n, &dag->heads, dag.link) { fprintf(stderr, " t=%4d: ", n->unblocked_time); v3d_qpu_dump(devinfo, &n->inst->qpu); fprintf(stderr, "\n"); util_dynarray_foreach(&n->dag.edges, struct dag_edge, edge) { struct schedule_node *child = (struct schedule_node *)edge->child; if (!child) continue; fprintf(stderr, " - "); v3d_qpu_dump(devinfo, &child->inst->qpu); fprintf(stderr, " (%d parents, %c)\n", child->dag.parent_count, edge->data ? 'w' : 'r'); } } } static uint32_t magic_waddr_latency(enum v3d_qpu_waddr waddr, const struct v3d_qpu_instr *after) { /* Apply some huge latency between texture fetch requests and getting * their results back. * * FIXME: This is actually pretty bogus. If we do: * * mov tmu0_s, a * * mov tmu0_s, b * load_tmu0 * * load_tmu0 * * we count that as worse than * * mov tmu0_s, a * mov tmu0_s, b * * load_tmu0 * * load_tmu0 * * because we associate the first load_tmu0 with the *second* tmu0_s. */ if (v3d_qpu_magic_waddr_is_tmu(waddr) && v3d_qpu_waits_on_tmu(after)) return 100; /* Assume that anything depending on us is consuming the SFU result. */ if (v3d_qpu_magic_waddr_is_sfu(waddr)) return 3; return 1; } static uint32_t instruction_latency(struct schedule_node *before, struct schedule_node *after) { const struct v3d_qpu_instr *before_inst = &before->inst->qpu; const struct v3d_qpu_instr *after_inst = &after->inst->qpu; uint32_t latency = 1; if (before_inst->type != V3D_QPU_INSTR_TYPE_ALU || after_inst->type != V3D_QPU_INSTR_TYPE_ALU) return latency; if (before_inst->alu.add.magic_write) { latency = MAX2(latency, magic_waddr_latency(before_inst->alu.add.waddr, after_inst)); } if (before_inst->alu.mul.magic_write) { latency = MAX2(latency, magic_waddr_latency(before_inst->alu.mul.waddr, after_inst)); } return latency; } /** Recursive computation of the delay member of a node. */ static void compute_delay(struct dag_node *node, void *state) { struct schedule_node *n = (struct schedule_node *)node; n->delay = 1; util_dynarray_foreach(&n->dag.edges, struct dag_edge, edge) { struct schedule_node *child = (struct schedule_node *)edge->child; n->delay = MAX2(n->delay, (child->delay + instruction_latency(n, child))); } } /* Removes a DAG head, but removing only the WAR edges. (dag_prune_head() * should be called on it later to finish pruning the other edges). */ static void pre_remove_head(struct dag *dag, struct schedule_node *n) { list_delinit(&n->dag.link); util_dynarray_foreach(&n->dag.edges, struct dag_edge, edge) { if (edge->data) dag_remove_edge(dag, edge); } } static void mark_instruction_scheduled(struct dag *dag, uint32_t time, struct schedule_node *node) { if (!node) return; util_dynarray_foreach(&node->dag.edges, struct dag_edge, edge) { struct schedule_node *child = (struct schedule_node *)edge->child; if (!child) continue; uint32_t latency = instruction_latency(node, child); child->unblocked_time = MAX2(child->unblocked_time, time + latency); } dag_prune_head(dag, &node->dag); } static void insert_scheduled_instruction(struct v3d_compile *c, struct qblock *block, struct choose_scoreboard *scoreboard, struct qinst *inst) { list_addtail(&inst->link, &block->instructions); update_scoreboard_for_chosen(scoreboard, &inst->qpu); c->qpu_inst_count++; scoreboard->tick++; } static struct qinst * vir_nop() { struct qreg undef = vir_nop_reg(); struct qinst *qinst = vir_add_inst(V3D_QPU_A_NOP, undef, undef, undef); return qinst; } static void emit_nop(struct v3d_compile *c, struct qblock *block, struct choose_scoreboard *scoreboard) { insert_scheduled_instruction(c, block, scoreboard, vir_nop()); } static bool qpu_instruction_valid_in_thrend_slot(struct v3d_compile *c, const struct qinst *qinst, int slot) { const struct v3d_qpu_instr *inst = &qinst->qpu; /* Only TLB Z writes are prohibited in the last slot, but we don't * have those flagged so prohibit all TLB ops for now. */ if (slot == 2 && qpu_inst_is_tlb(inst)) return false; if (slot > 0 && qinst->uniform != ~0) return false; if (v3d_qpu_uses_vpm(inst)) return false; if (inst->sig.ldvary) return false; if (inst->type == V3D_QPU_INSTR_TYPE_ALU) { /* GFXH-1625: TMUWT not allowed in the final instruction. */ if (slot == 2 && inst->alu.add.op == V3D_QPU_A_TMUWT) return false; /* No writing physical registers at the end. */ if (!inst->alu.add.magic_write || !inst->alu.mul.magic_write) { return false; } if (c->devinfo->ver < 40 && inst->alu.add.op == V3D_QPU_A_SETMSF) return false; /* RF0-2 might be overwritten during the delay slots by * fragment shader setup. */ if (inst->raddr_a < 3 && (inst->alu.add.a == V3D_QPU_MUX_A || inst->alu.add.b == V3D_QPU_MUX_A || inst->alu.mul.a == V3D_QPU_MUX_A || inst->alu.mul.b == V3D_QPU_MUX_A)) { return false; } if (inst->raddr_b < 3 && !inst->sig.small_imm && (inst->alu.add.a == V3D_QPU_MUX_B || inst->alu.add.b == V3D_QPU_MUX_B || inst->alu.mul.a == V3D_QPU_MUX_B || inst->alu.mul.b == V3D_QPU_MUX_B)) { return false; } } return true; } static bool valid_thrsw_sequence(struct v3d_compile *c, struct choose_scoreboard *scoreboard, struct qinst *qinst, int instructions_in_sequence, bool is_thrend) { /* No emitting our thrsw while the previous thrsw hasn't happened yet. */ if (scoreboard->last_thrsw_tick + 3 > scoreboard->tick - instructions_in_sequence) { return false; } for (int slot = 0; slot < instructions_in_sequence; slot++) { /* No scheduling SFU when the result would land in the other * thread. The simulator complains for safety, though it * would only occur for dead code in our case. */ if (slot > 0 && qinst->qpu.type == V3D_QPU_INSTR_TYPE_ALU && (v3d_qpu_magic_waddr_is_sfu(qinst->qpu.alu.add.waddr) || v3d_qpu_magic_waddr_is_sfu(qinst->qpu.alu.mul.waddr))) { return false; } if (slot > 0 && qinst->qpu.sig.ldvary) return false; if (is_thrend && !qpu_instruction_valid_in_thrend_slot(c, qinst, slot)) { return false; } /* Note that the list is circular, so we can only do this up * to instructions_in_sequence. */ qinst = (struct qinst *)qinst->link.next; } return true; } /** * Emits a THRSW signal in the stream, trying to move it up to pair with * another instruction. */ static int emit_thrsw(struct v3d_compile *c, struct qblock *block, struct choose_scoreboard *scoreboard, struct qinst *inst, bool is_thrend) { int time = 0; /* There should be nothing in a thrsw inst being scheduled other than * the signal bits. */ assert(inst->qpu.type == V3D_QPU_INSTR_TYPE_ALU); assert(inst->qpu.alu.add.op == V3D_QPU_A_NOP); assert(inst->qpu.alu.mul.op == V3D_QPU_M_NOP); /* Find how far back into previous instructions we can put the THRSW. */ int slots_filled = 0; struct qinst *merge_inst = NULL; vir_for_each_inst_rev(prev_inst, block) { struct v3d_qpu_sig sig = prev_inst->qpu.sig; sig.thrsw = true; uint32_t packed_sig; if (!v3d_qpu_sig_pack(c->devinfo, &sig, &packed_sig)) break; if (!valid_thrsw_sequence(c, scoreboard, prev_inst, slots_filled + 1, is_thrend)) { break; } merge_inst = prev_inst; if (++slots_filled == 3) break; } bool needs_free = false; if (merge_inst) { merge_inst->qpu.sig.thrsw = true; needs_free = true; scoreboard->last_thrsw_tick = scoreboard->tick - slots_filled; } else { scoreboard->last_thrsw_tick = scoreboard->tick; insert_scheduled_instruction(c, block, scoreboard, inst); time++; slots_filled++; merge_inst = inst; } /* Insert any extra delay slot NOPs we need. */ for (int i = 0; i < 3 - slots_filled; i++) { emit_nop(c, block, scoreboard); time++; } /* If we're emitting the last THRSW (other than program end), then * signal that to the HW by emitting two THRSWs in a row. */ if (inst->is_last_thrsw) { struct qinst *second_inst = (struct qinst *)merge_inst->link.next; second_inst->qpu.sig.thrsw = true; } /* If we put our THRSW into another instruction, free up the * instruction that didn't end up scheduled into the list. */ if (needs_free) free(inst); return time; } static uint32_t schedule_instructions(struct v3d_compile *c, struct choose_scoreboard *scoreboard, struct qblock *block, enum quniform_contents *orig_uniform_contents, uint32_t *orig_uniform_data, uint32_t *next_uniform) { const struct v3d_device_info *devinfo = c->devinfo; uint32_t time = 0; while (!list_empty(&scoreboard->dag->heads)) { struct schedule_node *chosen = choose_instruction_to_schedule(devinfo, scoreboard, NULL); struct schedule_node *merge = NULL; /* If there are no valid instructions to schedule, drop a NOP * in. */ struct qinst *qinst = chosen ? chosen->inst : vir_nop(); struct v3d_qpu_instr *inst = &qinst->qpu; if (debug) { fprintf(stderr, "t=%4d: current list:\n", time); dump_state(devinfo, scoreboard->dag); fprintf(stderr, "t=%4d: chose: ", time); v3d_qpu_dump(devinfo, inst); fprintf(stderr, "\n"); } /* We can't mark_instruction_scheduled() the chosen inst until * we're done identifying instructions to merge, so put the * merged instructions on a list for a moment. */ struct list_head merged_list; list_inithead(&merged_list); /* Schedule this instruction onto the QPU list. Also try to * find an instruction to pair with it. */ if (chosen) { time = MAX2(chosen->unblocked_time, time); pre_remove_head(scoreboard->dag, chosen); while ((merge = choose_instruction_to_schedule(devinfo, scoreboard, chosen))) { time = MAX2(merge->unblocked_time, time); pre_remove_head(scoreboard->dag, chosen); list_addtail(&merge->link, &merged_list); (void)qpu_merge_inst(devinfo, inst, inst, &merge->inst->qpu); if (merge->inst->uniform != -1) { chosen->inst->uniform = merge->inst->uniform; } if (debug) { fprintf(stderr, "t=%4d: merging: ", time); v3d_qpu_dump(devinfo, &merge->inst->qpu); fprintf(stderr, "\n"); fprintf(stderr, " result: "); v3d_qpu_dump(devinfo, inst); fprintf(stderr, "\n"); } } } /* Update the uniform index for the rewritten location -- * branch target updating will still need to change * c->uniform_data[] using this index. */ if (qinst->uniform != -1) { if (inst->type == V3D_QPU_INSTR_TYPE_BRANCH) block->branch_uniform = *next_uniform; c->uniform_data[*next_uniform] = orig_uniform_data[qinst->uniform]; c->uniform_contents[*next_uniform] = orig_uniform_contents[qinst->uniform]; qinst->uniform = *next_uniform; (*next_uniform)++; } if (debug) { fprintf(stderr, "\n"); } /* Now that we've scheduled a new instruction, some of its * children can be promoted to the list of instructions ready to * be scheduled. Update the children's unblocked time for this * DAG edge as we do so. */ mark_instruction_scheduled(scoreboard->dag, time, chosen); list_for_each_entry(struct schedule_node, merge, &merged_list, link) { mark_instruction_scheduled(scoreboard->dag, time, merge); /* The merged VIR instruction doesn't get re-added to the * block, so free it now. */ free(merge->inst); } if (inst->sig.thrsw) { time += emit_thrsw(c, block, scoreboard, qinst, false); } else { insert_scheduled_instruction(c, block, scoreboard, qinst); if (inst->type == V3D_QPU_INSTR_TYPE_BRANCH) { block->branch_qpu_ip = c->qpu_inst_count - 1; /* Fill the delay slots. * * We should fill these with actual instructions, * instead, but that will probably need to be done * after this, once we know what the leading * instructions of the successors are (so we can * handle A/B register file write latency) */ for (int i = 0; i < 3; i++) emit_nop(c, block, scoreboard); } } } return time; } static uint32_t qpu_schedule_instructions_block(struct v3d_compile *c, struct choose_scoreboard *scoreboard, struct qblock *block, enum quniform_contents *orig_uniform_contents, uint32_t *orig_uniform_data, uint32_t *next_uniform) { void *mem_ctx = ralloc_context(NULL); scoreboard->dag = dag_create(mem_ctx); struct list_head setup_list; list_inithead(&setup_list); /* Wrap each instruction in a scheduler structure. */ while (!list_empty(&block->instructions)) { struct qinst *qinst = (struct qinst *)block->instructions.next; struct schedule_node *n = rzalloc(mem_ctx, struct schedule_node); dag_init_node(scoreboard->dag, &n->dag); n->inst = qinst; list_del(&qinst->link); list_addtail(&n->link, &setup_list); } calculate_forward_deps(c, scoreboard->dag, &setup_list); calculate_reverse_deps(c, scoreboard->dag, &setup_list); dag_traverse_bottom_up(scoreboard->dag, compute_delay, NULL); uint32_t cycles = schedule_instructions(c, scoreboard, block, orig_uniform_contents, orig_uniform_data, next_uniform); ralloc_free(mem_ctx); scoreboard->dag = NULL; return cycles; } static void qpu_set_branch_targets(struct v3d_compile *c) { vir_for_each_block(block, c) { /* The end block of the program has no branch. */ if (!block->successors[0]) continue; /* If there was no branch instruction, then the successor * block must follow immediately after this one. */ if (block->branch_qpu_ip == ~0) { assert(block->end_qpu_ip + 1 == block->successors[0]->start_qpu_ip); continue; } /* Walk back through the delay slots to find the branch * instr. */ struct list_head *entry = block->instructions.prev; for (int i = 0; i < 3; i++) entry = entry->prev; struct qinst *branch = container_of(entry, branch, link); assert(branch->qpu.type == V3D_QPU_INSTR_TYPE_BRANCH); /* Make sure that the if-we-don't-jump * successor was scheduled just after the * delay slots. */ assert(!block->successors[1] || block->successors[1]->start_qpu_ip == block->branch_qpu_ip + 4); branch->qpu.branch.offset = ((block->successors[0]->start_qpu_ip - (block->branch_qpu_ip + 4)) * sizeof(uint64_t)); /* Set up the relative offset to jump in the * uniform stream. * * Use a temporary here, because * uniform_data[inst->uniform] may be shared * between multiple instructions. */ assert(c->uniform_contents[branch->uniform] == QUNIFORM_CONSTANT); c->uniform_data[branch->uniform] = (block->successors[0]->start_uniform - (block->branch_uniform + 1)) * 4; } } uint32_t v3d_qpu_schedule_instructions(struct v3d_compile *c) { const struct v3d_device_info *devinfo = c->devinfo; struct qblock *end_block = list_last_entry(&c->blocks, struct qblock, link); /* We reorder the uniforms as we schedule instructions, so save the * old data off and replace it. */ uint32_t *uniform_data = c->uniform_data; enum quniform_contents *uniform_contents = c->uniform_contents; c->uniform_contents = ralloc_array(c, enum quniform_contents, c->num_uniforms); c->uniform_data = ralloc_array(c, uint32_t, c->num_uniforms); c->uniform_array_size = c->num_uniforms; uint32_t next_uniform = 0; struct choose_scoreboard scoreboard; memset(&scoreboard, 0, sizeof(scoreboard)); scoreboard.last_ldvary_tick = -10; scoreboard.last_magic_sfu_write_tick = -10; scoreboard.last_uniforms_reset_tick = -10; scoreboard.last_thrsw_tick = -10; if (debug) { fprintf(stderr, "Pre-schedule instructions\n"); vir_for_each_block(block, c) { fprintf(stderr, "BLOCK %d\n", block->index); list_for_each_entry(struct qinst, qinst, &block->instructions, link) { v3d_qpu_dump(devinfo, &qinst->qpu); fprintf(stderr, "\n"); } } fprintf(stderr, "\n"); } uint32_t cycles = 0; vir_for_each_block(block, c) { block->start_qpu_ip = c->qpu_inst_count; block->branch_qpu_ip = ~0; block->start_uniform = next_uniform; cycles += qpu_schedule_instructions_block(c, &scoreboard, block, uniform_contents, uniform_data, &next_uniform); block->end_qpu_ip = c->qpu_inst_count - 1; } /* Emit the program-end THRSW instruction. */; struct qinst *thrsw = vir_nop(); thrsw->qpu.sig.thrsw = true; emit_thrsw(c, end_block, &scoreboard, thrsw, true); qpu_set_branch_targets(c); assert(next_uniform == c->num_uniforms); return cycles; }