/* * Copyright © 2010 Intel Corporation * 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. */ /** * @file vc4_qpu_schedule.c * * 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 "vc4_qir.h" #include "vc4_qpu.h" #include "util/ralloc.h" static bool debug; struct schedule_node_child; struct schedule_node { struct list_head link; struct queued_qpu_inst *inst; struct schedule_node_child *children; uint32_t child_count; uint32_t child_array_size; uint32_t parent_count; /* 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; /** * Which uniform from uniform_data[] this instruction read, or -1 if * not reading a uniform. */ int uniform; }; struct schedule_node_child { struct schedule_node *node; bool write_after_read; }; /* When walking the instructions in reverse, we need to swap before/after in * add_dep(). */ enum direction { F, R }; struct schedule_state { struct schedule_node *last_r[6]; struct schedule_node *last_ra[32]; struct schedule_node *last_rb[32]; struct schedule_node *last_sf; struct schedule_node *last_vpm_read; struct schedule_node *last_tmu_write; struct schedule_node *last_tlb; struct schedule_node *last_vpm; struct schedule_node *last_uniforms_reset; 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; if (!before || !after) return; assert(before != after); if (state->dir == R) { struct schedule_node *t = before; before = after; after = t; } for (int i = 0; i < before->child_count; i++) { if (before->children[i].node == after && (before->children[i].write_after_read == write_after_read)) { return; } } if (before->child_array_size <= before->child_count) { before->child_array_size = MAX2(before->child_array_size * 2, 16); before->children = reralloc(before, before->children, struct schedule_node_child, before->child_array_size); } before->children[before->child_count].node = after; before->children[before->child_count].write_after_read = write_after_read; before->child_count++; after->parent_count++; } 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_writes_r4(uint64_t inst) { uint32_t sig = QPU_GET_FIELD(inst, QPU_SIG); switch(sig) { case QPU_SIG_COLOR_LOAD: case QPU_SIG_LOAD_TMU0: case QPU_SIG_LOAD_TMU1: case QPU_SIG_ALPHA_MASK_LOAD: return true; default: return false; } } static void process_raddr_deps(struct schedule_state *state, struct schedule_node *n, uint32_t raddr, bool is_a) { switch (raddr) { case QPU_R_VARY: add_write_dep(state, &state->last_r[5], n); break; case QPU_R_VPM: add_write_dep(state, &state->last_vpm_read, n); break; case QPU_R_UNIF: add_read_dep(state, state->last_uniforms_reset, n); break; case QPU_R_NOP: case QPU_R_ELEM_QPU: case QPU_R_XY_PIXEL_COORD: case QPU_R_MS_REV_FLAGS: break; default: if (raddr < 32) { if (is_a) add_read_dep(state, state->last_ra[raddr], n); else add_read_dep(state, state->last_rb[raddr], n); } else { fprintf(stderr, "unknown raddr %d\n", raddr); abort(); } break; } } static bool is_tmu_write(uint32_t waddr) { switch (waddr) { case QPU_W_TMU0_S: case QPU_W_TMU0_T: case QPU_W_TMU0_R: case QPU_W_TMU0_B: case QPU_W_TMU1_S: case QPU_W_TMU1_T: case QPU_W_TMU1_R: case QPU_W_TMU1_B: return true; default: return false; } } static bool reads_uniform(uint64_t inst) { if (QPU_GET_FIELD(inst, QPU_SIG) == QPU_SIG_LOAD_IMM) return false; return (QPU_GET_FIELD(inst, QPU_RADDR_A) == QPU_R_UNIF || (QPU_GET_FIELD(inst, QPU_RADDR_B) == QPU_R_UNIF && QPU_GET_FIELD(inst, QPU_SIG) != QPU_SIG_SMALL_IMM) || is_tmu_write(QPU_GET_FIELD(inst, QPU_WADDR_ADD)) || is_tmu_write(QPU_GET_FIELD(inst, QPU_WADDR_MUL))); } static void process_mux_deps(struct schedule_state *state, struct schedule_node *n, uint32_t mux) { if (mux != QPU_MUX_A && mux != QPU_MUX_B) add_read_dep(state, state->last_r[mux], n); } static void process_waddr_deps(struct schedule_state *state, struct schedule_node *n, uint32_t waddr, bool is_add) { uint64_t inst = n->inst->inst; bool is_a = is_add ^ ((inst & QPU_WS) != 0); if (waddr < 32) { if (is_a) { add_write_dep(state, &state->last_ra[waddr], n); } else { add_write_dep(state, &state->last_rb[waddr], n); } } else if (is_tmu_write(waddr)) { add_write_dep(state, &state->last_tmu_write, n); add_read_dep(state, state->last_uniforms_reset, n); } else if (qpu_waddr_is_tlb(waddr) || waddr == QPU_W_MS_FLAGS) { add_write_dep(state, &state->last_tlb, n); } else { switch (waddr) { case QPU_W_ACC0: case QPU_W_ACC1: case QPU_W_ACC2: case QPU_W_ACC3: case QPU_W_ACC5: add_write_dep(state, &state->last_r[waddr - QPU_W_ACC0], n); break; case QPU_W_VPM: add_write_dep(state, &state->last_vpm, n); break; case QPU_W_VPMVCD_SETUP: if (is_a) add_write_dep(state, &state->last_vpm_read, n); else add_write_dep(state, &state->last_vpm, n); break; case QPU_W_SFU_RECIP: case QPU_W_SFU_RECIPSQRT: case QPU_W_SFU_EXP: case QPU_W_SFU_LOG: add_write_dep(state, &state->last_r[4], n); break; case QPU_W_TLB_STENCIL_SETUP: /* This isn't a TLB operation that does things like * implicitly lock the scoreboard, but it does have to * appear before TLB_Z, and each of the TLB_STENCILs * have to schedule in the same order relative to each * other. */ add_write_dep(state, &state->last_tlb, n); break; case QPU_W_MS_FLAGS: add_write_dep(state, &state->last_tlb, n); break; case QPU_W_UNIFORMS_ADDRESS: add_write_dep(state, &state->last_uniforms_reset, n); break; case QPU_W_NOP: break; default: fprintf(stderr, "Unknown waddr %d\n", waddr); abort(); } } } static void process_cond_deps(struct schedule_state *state, struct schedule_node *n, uint32_t cond) { switch (cond) { case QPU_COND_NEVER: case QPU_COND_ALWAYS: break; default: add_read_dep(state, state->last_sf, n); break; } } /** * 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) { uint64_t inst = n->inst->inst; uint32_t add_op = QPU_GET_FIELD(inst, QPU_OP_ADD); uint32_t mul_op = QPU_GET_FIELD(inst, QPU_OP_MUL); uint32_t waddr_add = QPU_GET_FIELD(inst, QPU_WADDR_ADD); uint32_t waddr_mul = QPU_GET_FIELD(inst, QPU_WADDR_MUL); uint32_t raddr_a = QPU_GET_FIELD(inst, QPU_RADDR_A); uint32_t raddr_b = QPU_GET_FIELD(inst, QPU_RADDR_B); uint32_t add_a = QPU_GET_FIELD(inst, QPU_ADD_A); uint32_t add_b = QPU_GET_FIELD(inst, QPU_ADD_B); uint32_t mul_a = QPU_GET_FIELD(inst, QPU_MUL_A); uint32_t mul_b = QPU_GET_FIELD(inst, QPU_MUL_B); uint32_t sig = QPU_GET_FIELD(inst, QPU_SIG); if (sig != QPU_SIG_LOAD_IMM) { process_raddr_deps(state, n, raddr_a, true); if (sig != QPU_SIG_SMALL_IMM && sig != QPU_SIG_BRANCH) process_raddr_deps(state, n, raddr_b, false); } if (add_op != QPU_A_NOP) { process_mux_deps(state, n, add_a); process_mux_deps(state, n, add_b); } if (mul_op != QPU_M_NOP) { process_mux_deps(state, n, mul_a); process_mux_deps(state, n, mul_b); } process_waddr_deps(state, n, waddr_add, true); process_waddr_deps(state, n, waddr_mul, false); if (qpu_writes_r4(inst)) add_write_dep(state, &state->last_r[4], n); switch (sig) { case QPU_SIG_SW_BREAKPOINT: case QPU_SIG_NONE: case QPU_SIG_SMALL_IMM: case QPU_SIG_LOAD_IMM: break; case QPU_SIG_THREAD_SWITCH: case QPU_SIG_LAST_THREAD_SWITCH: /* 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); /* 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); break; case QPU_SIG_LOAD_TMU0: case QPU_SIG_LOAD_TMU1: /* TMU loads are coming from a FIFO, so ordering is important. */ add_write_dep(state, &state->last_tmu_write, n); break; case QPU_SIG_COLOR_LOAD: add_read_dep(state, state->last_tlb, n); break; case QPU_SIG_BRANCH: add_read_dep(state, state->last_sf, n); break; case QPU_SIG_PROG_END: case QPU_SIG_WAIT_FOR_SCOREBOARD: case QPU_SIG_SCOREBOARD_UNLOCK: case QPU_SIG_COVERAGE_LOAD: case QPU_SIG_COLOR_LOAD_END: case QPU_SIG_ALPHA_MASK_LOAD: fprintf(stderr, "Unhandled signal bits %d\n", sig); abort(); } process_cond_deps(state, n, QPU_GET_FIELD(inst, QPU_COND_ADD)); process_cond_deps(state, n, QPU_GET_FIELD(inst, QPU_COND_MUL)); if ((inst & QPU_SF) && sig != QPU_SIG_BRANCH) add_write_dep(state, &state->last_sf, n); } static void calculate_forward_deps(struct vc4_compile *c, struct list_head *schedule_list) { struct schedule_state state; memset(&state, 0, sizeof(state)); state.dir = F; list_for_each_entry(struct schedule_node, node, schedule_list, link) calculate_deps(&state, node); } static void calculate_reverse_deps(struct vc4_compile *c, struct list_head *schedule_list) { struct list_head *node; struct schedule_state state; memset(&state, 0, sizeof(state)); state.dir = R; for (node = schedule_list->prev; schedule_list != node; node = node->prev) { calculate_deps(&state, (struct schedule_node *)node); } } struct choose_scoreboard { int tick; int last_sfu_write_tick; int last_uniforms_reset_tick; uint32_t last_waddr_a, last_waddr_b; bool tlb_locked; }; static bool reads_too_soon_after_write(struct choose_scoreboard *scoreboard, uint64_t inst) { uint32_t raddr_a = QPU_GET_FIELD(inst, QPU_RADDR_A); uint32_t raddr_b = QPU_GET_FIELD(inst, QPU_RADDR_B); uint32_t sig = QPU_GET_FIELD(inst, QPU_SIG); /* Full immediate loads don't read any registers. */ if (sig == QPU_SIG_LOAD_IMM) return false; uint32_t src_muxes[] = { QPU_GET_FIELD(inst, QPU_ADD_A), QPU_GET_FIELD(inst, QPU_ADD_B), QPU_GET_FIELD(inst, QPU_MUL_A), QPU_GET_FIELD(inst, QPU_MUL_B), }; for (int i = 0; i < ARRAY_SIZE(src_muxes); i++) { if ((src_muxes[i] == QPU_MUX_A && raddr_a < 32 && scoreboard->last_waddr_a == raddr_a) || (src_muxes[i] == QPU_MUX_B && sig != QPU_SIG_SMALL_IMM && raddr_b < 32 && scoreboard->last_waddr_b == raddr_b)) { return true; } if (src_muxes[i] == QPU_MUX_R4) { if (scoreboard->tick - scoreboard->last_sfu_write_tick <= 2) { return true; } } } if (sig == QPU_SIG_SMALL_IMM && QPU_GET_FIELD(inst, QPU_SMALL_IMM) >= QPU_SMALL_IMM_MUL_ROT) { uint32_t mux_a = QPU_GET_FIELD(inst, QPU_MUL_A); uint32_t mux_b = QPU_GET_FIELD(inst, QPU_MUL_B); if (scoreboard->last_waddr_a == mux_a + QPU_W_ACC0 || scoreboard->last_waddr_a == mux_b + QPU_W_ACC0 || scoreboard->last_waddr_b == mux_a + QPU_W_ACC0 || scoreboard->last_waddr_b == mux_b + QPU_W_ACC0) { return true; } } if (reads_uniform(inst) && scoreboard->tick - scoreboard->last_uniforms_reset_tick <= 2) { return true; } return false; } static bool pixel_scoreboard_too_soon(struct choose_scoreboard *scoreboard, uint64_t inst) { return (scoreboard->tick < 2 && qpu_inst_is_tlb(inst)); } static int get_instruction_priority(uint64_t inst) { uint32_t waddr_add = QPU_GET_FIELD(inst, QPU_WADDR_ADD); uint32_t waddr_mul = QPU_GET_FIELD(inst, QPU_WADDR_MUL); uint32_t sig = QPU_GET_FIELD(inst, QPU_SIG); 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 (sig == QPU_SIG_LOAD_TMU0 || sig == QPU_SIG_LOAD_TMU1) return next_score; next_score++; /* 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 (is_tmu_write(waddr_add) || is_tmu_write(waddr_mul)) return next_score; next_score++; return baseline_score; } static struct schedule_node * choose_instruction_to_schedule(struct choose_scoreboard *scoreboard, struct list_head *schedule_list, 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) { uint32_t prev_sig = QPU_GET_FIELD(prev_inst->inst->inst, QPU_SIG); if (prev_sig == QPU_SIG_THREAD_SWITCH || prev_sig == QPU_SIG_LAST_THREAD_SWITCH) { return NULL; } } list_for_each_entry(struct schedule_node, n, schedule_list, link) { uint64_t inst = n->inst->inst; uint32_t sig = QPU_GET_FIELD(inst, QPU_SIG); /* Don't choose the branch instruction until it's the last one * left. XXX: We could potentially choose it before it's the * last one, if the remaining instructions fit in the delay * slots. */ if (sig == QPU_SIG_BRANCH && !list_is_singular(schedule_list)) { 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, 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; /* 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 (sig == QPU_SIG_THREAD_SWITCH || sig == QPU_SIG_LAST_THREAD_SWITCH) { continue; } if (prev_inst->uniform != -1 && n->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; inst = qpu_merge_inst(prev_inst->inst->inst, inst); if (!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_chosen(struct choose_scoreboard *scoreboard, uint64_t inst) { uint32_t waddr_add = QPU_GET_FIELD(inst, QPU_WADDR_ADD); uint32_t waddr_mul = QPU_GET_FIELD(inst, QPU_WADDR_MUL); if (!(inst & QPU_WS)) { scoreboard->last_waddr_a = waddr_add; scoreboard->last_waddr_b = waddr_mul; } else { scoreboard->last_waddr_b = waddr_add; scoreboard->last_waddr_a = waddr_mul; } if ((waddr_add >= QPU_W_SFU_RECIP && waddr_add <= QPU_W_SFU_LOG) || (waddr_mul >= QPU_W_SFU_RECIP && waddr_mul <= QPU_W_SFU_LOG)) { scoreboard->last_sfu_write_tick = scoreboard->tick; } if (waddr_add == QPU_W_UNIFORMS_ADDRESS || waddr_mul == QPU_W_UNIFORMS_ADDRESS) { scoreboard->last_uniforms_reset_tick = scoreboard->tick; } if (qpu_inst_is_tlb(inst)) scoreboard->tlb_locked = true; } static void dump_state(struct list_head *schedule_list) { list_for_each_entry(struct schedule_node, n, schedule_list, link) { fprintf(stderr, " t=%4d: ", n->unblocked_time); vc4_qpu_disasm(&n->inst->inst, 1); fprintf(stderr, "\n"); for (int i = 0; i < n->child_count; i++) { struct schedule_node *child = n->children[i].node; if (!child) continue; fprintf(stderr, " - "); vc4_qpu_disasm(&child->inst->inst, 1); fprintf(stderr, " (%d parents, %c)\n", child->parent_count, n->children[i].write_after_read ? 'w' : 'r'); } } } static uint32_t waddr_latency(uint32_t waddr, uint64_t after) { if (waddr < 32) return 2; /* 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 (waddr == QPU_W_TMU0_S) { if (QPU_GET_FIELD(after, QPU_SIG) == QPU_SIG_LOAD_TMU0) return 100; } if (waddr == QPU_W_TMU1_S) { if (QPU_GET_FIELD(after, QPU_SIG) == QPU_SIG_LOAD_TMU1) return 100; } switch(waddr) { case QPU_W_SFU_RECIP: case QPU_W_SFU_RECIPSQRT: case QPU_W_SFU_EXP: case QPU_W_SFU_LOG: return 3; default: return 1; } } static uint32_t instruction_latency(struct schedule_node *before, struct schedule_node *after) { uint64_t before_inst = before->inst->inst; uint64_t after_inst = after->inst->inst; return MAX2(waddr_latency(QPU_GET_FIELD(before_inst, QPU_WADDR_ADD), after_inst), waddr_latency(QPU_GET_FIELD(before_inst, QPU_WADDR_MUL), after_inst)); } /** Recursive computation of the delay member of a node. */ static void compute_delay(struct schedule_node *n) { if (!n->child_count) { n->delay = 1; } else { for (int i = 0; i < n->child_count; i++) { if (!n->children[i].node->delay) compute_delay(n->children[i].node); n->delay = MAX2(n->delay, n->children[i].node->delay + instruction_latency(n, n->children[i].node)); } } } static void mark_instruction_scheduled(struct list_head *schedule_list, uint32_t time, struct schedule_node *node, bool war_only) { if (!node) return; for (int i = node->child_count - 1; i >= 0; i--) { struct schedule_node *child = node->children[i].node; if (!child) continue; if (war_only && !node->children[i].write_after_read) continue; /* If the requirement is only that the node not appear before * the last read of its destination, then it can be scheduled * immediately after (or paired with!) the thing reading the * destination. */ uint32_t latency = 0; if (!war_only) { latency = instruction_latency(node, node->children[i].node); } child->unblocked_time = MAX2(child->unblocked_time, time + latency); child->parent_count--; if (child->parent_count == 0) list_add(&child->link, schedule_list); node->children[i].node = NULL; } } /** * Emits a THRSW/LTHRSW signal in the stream, trying to move it up to pair * with another instruction. */ static void emit_thrsw(struct vc4_compile *c, struct choose_scoreboard *scoreboard, uint64_t inst) { uint32_t sig = QPU_GET_FIELD(inst, QPU_SIG); /* There should be nothing in a thrsw inst being scheduled other than * the signal bits. */ assert(QPU_GET_FIELD(inst, QPU_OP_ADD) == QPU_A_NOP); assert(QPU_GET_FIELD(inst, QPU_OP_MUL) == QPU_M_NOP); /* Try to find an earlier scheduled instruction that we can merge the * thrsw into. */ int thrsw_ip = c->qpu_inst_count; for (int i = 1; i <= MIN2(c->qpu_inst_count, 3); i++) { uint64_t prev_instr = c->qpu_insts[c->qpu_inst_count - i]; uint32_t prev_sig = QPU_GET_FIELD(prev_instr, QPU_SIG); if (prev_sig == QPU_SIG_NONE) thrsw_ip = c->qpu_inst_count - i; } if (thrsw_ip != c->qpu_inst_count) { /* Merge the thrsw into the existing instruction. */ c->qpu_insts[thrsw_ip] = QPU_UPDATE_FIELD(c->qpu_insts[thrsw_ip], sig, QPU_SIG); } else { qpu_serialize_one_inst(c, inst); update_scoreboard_for_chosen(scoreboard, inst); } /* Fill the delay slots. */ while (c->qpu_inst_count < thrsw_ip + 3) { update_scoreboard_for_chosen(scoreboard, qpu_NOP()); qpu_serialize_one_inst(c, qpu_NOP()); } } static uint32_t schedule_instructions(struct vc4_compile *c, struct choose_scoreboard *scoreboard, struct qblock *block, struct list_head *schedule_list, enum quniform_contents *orig_uniform_contents, uint32_t *orig_uniform_data, uint32_t *next_uniform) { uint32_t time = 0; if (debug) { fprintf(stderr, "initial deps:\n"); dump_state(schedule_list); fprintf(stderr, "\n"); } /* Remove non-DAG heads from the list. */ list_for_each_entry_safe(struct schedule_node, n, schedule_list, link) { if (n->parent_count != 0) list_del(&n->link); } while (!list_empty(schedule_list)) { struct schedule_node *chosen = choose_instruction_to_schedule(scoreboard, schedule_list, NULL); struct schedule_node *merge = NULL; /* If there are no valid instructions to schedule, drop a NOP * in. */ uint64_t inst = chosen ? chosen->inst->inst : qpu_NOP(); if (debug) { fprintf(stderr, "t=%4d: current list:\n", time); dump_state(schedule_list); fprintf(stderr, "t=%4d: chose: ", time); vc4_qpu_disasm(&inst, 1); fprintf(stderr, "\n"); } /* 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); list_del(&chosen->link); mark_instruction_scheduled(schedule_list, time, chosen, true); if (chosen->uniform != -1) { c->uniform_data[*next_uniform] = orig_uniform_data[chosen->uniform]; c->uniform_contents[*next_uniform] = orig_uniform_contents[chosen->uniform]; (*next_uniform)++; } merge = choose_instruction_to_schedule(scoreboard, schedule_list, chosen); if (merge) { time = MAX2(merge->unblocked_time, time); list_del(&merge->link); inst = qpu_merge_inst(inst, merge->inst->inst); assert(inst != 0); if (merge->uniform != -1) { c->uniform_data[*next_uniform] = orig_uniform_data[merge->uniform]; c->uniform_contents[*next_uniform] = orig_uniform_contents[merge->uniform]; (*next_uniform)++; } if (debug) { fprintf(stderr, "t=%4d: merging: ", time); vc4_qpu_disasm(&merge->inst->inst, 1); fprintf(stderr, "\n"); fprintf(stderr, " resulting in: "); vc4_qpu_disasm(&inst, 1); fprintf(stderr, "\n"); } } } 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(schedule_list, time, chosen, false); mark_instruction_scheduled(schedule_list, time, merge, false); if (QPU_GET_FIELD(inst, QPU_SIG) == QPU_SIG_THREAD_SWITCH || QPU_GET_FIELD(inst, QPU_SIG) == QPU_SIG_LAST_THREAD_SWITCH) { emit_thrsw(c, scoreboard, inst); } else { qpu_serialize_one_inst(c, inst); update_scoreboard_for_chosen(scoreboard, inst); } scoreboard->tick++; time++; if (QPU_GET_FIELD(inst, QPU_SIG) == QPU_SIG_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) */ inst = qpu_NOP(); update_scoreboard_for_chosen(scoreboard, inst); qpu_serialize_one_inst(c, inst); qpu_serialize_one_inst(c, inst); qpu_serialize_one_inst(c, inst); } } return time; } static uint32_t qpu_schedule_instructions_block(struct vc4_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); struct list_head schedule_list; list_inithead(&schedule_list); /* Wrap each instruction in a scheduler structure. */ uint32_t next_sched_uniform = *next_uniform; while (!list_empty(&block->qpu_inst_list)) { struct queued_qpu_inst *inst = (struct queued_qpu_inst *)block->qpu_inst_list.next; struct schedule_node *n = rzalloc(mem_ctx, struct schedule_node); n->inst = inst; if (reads_uniform(inst->inst)) { n->uniform = next_sched_uniform++; } else { n->uniform = -1; } list_del(&inst->link); list_addtail(&n->link, &schedule_list); } calculate_forward_deps(c, &schedule_list); calculate_reverse_deps(c, &schedule_list); list_for_each_entry(struct schedule_node, n, &schedule_list, link) { compute_delay(n); } uint32_t cycles = schedule_instructions(c, scoreboard, block, &schedule_list, orig_uniform_contents, orig_uniform_data, next_uniform); ralloc_free(mem_ctx); return cycles; } static void qpu_set_branch_targets(struct vc4_compile *c) { qir_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; } /* Set the branch target for the block that doesn't follow * immediately after ours. */ uint64_t *branch_inst = &c->qpu_insts[block->branch_qpu_ip]; assert(QPU_GET_FIELD(*branch_inst, QPU_SIG) == QPU_SIG_BRANCH); assert(QPU_GET_FIELD(*branch_inst, QPU_BRANCH_TARGET) == 0); uint32_t branch_target = (block->successors[0]->start_qpu_ip - (block->branch_qpu_ip + 4)) * sizeof(uint64_t); *branch_inst = (*branch_inst | QPU_SET_FIELD(branch_target, QPU_BRANCH_TARGET)); /* Make sure that the if-we-don't-jump successor was scheduled * just after the delay slots. */ if (block->successors[1]) { assert(block->successors[1]->start_qpu_ip == block->branch_qpu_ip + 4); } } } uint32_t qpu_schedule_instructions(struct vc4_compile *c) { /* 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_waddr_a = ~0; scoreboard.last_waddr_b = ~0; scoreboard.last_sfu_write_tick = -10; scoreboard.last_uniforms_reset_tick = -10; if (debug) { fprintf(stderr, "Pre-schedule instructions\n"); qir_for_each_block(block, c) { fprintf(stderr, "BLOCK %d\n", block->index); list_for_each_entry(struct queued_qpu_inst, q, &block->qpu_inst_list, link) { vc4_qpu_disasm(&q->inst, 1); fprintf(stderr, "\n"); } } fprintf(stderr, "\n"); } uint32_t cycles = 0; qir_for_each_block(block, c) { block->start_qpu_ip = c->qpu_inst_count; block->branch_qpu_ip = ~0; cycles += qpu_schedule_instructions_block(c, &scoreboard, block, uniform_contents, uniform_data, &next_uniform); block->end_qpu_ip = c->qpu_inst_count - 1; } qpu_set_branch_targets(c); assert(next_uniform == c->num_uniforms); if (debug) { fprintf(stderr, "Post-schedule instructions\n"); vc4_qpu_disasm(c->qpu_insts, c->qpu_inst_count); fprintf(stderr, "\n"); } return cycles; }