/* * Copyright (C) 2014 Rob Clark * * 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: * Rob Clark */ #include "util/u_math.h" #include "ir3.h" /* * Instruction Scheduling: * * A recursive depth based scheduling algo. Recursively find an eligible * instruction to schedule from the deepest instruction (recursing through * it's unscheduled src instructions). Normally this would result in a * lot of re-traversal of the same instructions, so we cache results in * instr->data (and clear cached results that would be no longer valid * after scheduling an instruction). * * There are a few special cases that need to be handled, since sched * is currently independent of register allocation. Usages of address * register (a0.x) or predicate register (p0.x) must be serialized. Ie. * if you have two pairs of instructions that write the same special * register and then read it, then those pairs cannot be interleaved. * To solve this, when we are in such a scheduling "critical section", * and we encounter a conflicting write to a special register, we try * to schedule any remaining instructions that use that value first. */ struct ir3_sched_ctx { struct ir3_block *block; /* the current block */ struct list_head depth_list; /* depth sorted unscheduled instrs */ struct ir3_instruction *scheduled; /* last scheduled instr XXX remove*/ struct ir3_instruction *addr; /* current a0.x user, if any */ struct ir3_instruction *pred; /* current p0.x user, if any */ int live_values; /* estimate of current live values */ bool error; }; static bool is_sfu_or_mem(struct ir3_instruction *instr) { return is_sfu(instr) || is_mem(instr); } static void unuse_each_src(struct ir3_sched_ctx *ctx, struct ir3_instruction *instr) { struct ir3_instruction *src; foreach_ssa_src_n(src, n, instr) { if (__is_false_dep(instr, n)) continue; if (instr->block != src->block) continue; if ((src->opc == OPC_META_FI) || (src->opc == OPC_META_FO)) { unuse_each_src(ctx, src); } else { debug_assert(src->use_count > 0); if (--src->use_count == 0) { ctx->live_values -= dest_regs(src); debug_assert(ctx->live_values >= 0); } } } } static void use_instr(struct ir3_instruction *instr); static void use_each_src(struct ir3_instruction *instr) { struct ir3_instruction *src; foreach_ssa_src_n(src, n, instr) { if (__is_false_dep(instr, n)) continue; use_instr(src); } } static void use_instr(struct ir3_instruction *instr) { if ((instr->opc == OPC_META_FI) || (instr->opc == OPC_META_FO)) { use_each_src(instr); } else { instr->use_count++; } } static void update_live_values(struct ir3_sched_ctx *ctx, struct ir3_instruction *instr) { if ((instr->opc == OPC_META_FI) || (instr->opc == OPC_META_FO)) return; ctx->live_values += dest_regs(instr); unuse_each_src(ctx, instr); } static void update_use_count(struct ir3 *ir) { list_for_each_entry (struct ir3_block, block, &ir->block_list, node) { list_for_each_entry (struct ir3_instruction, instr, &block->instr_list, node) { instr->use_count = 0; } } list_for_each_entry (struct ir3_block, block, &ir->block_list, node) { list_for_each_entry (struct ir3_instruction, instr, &block->instr_list, node) { if ((instr->opc == OPC_META_FI) || (instr->opc == OPC_META_FO)) continue; use_each_src(instr); } } /* Shader outputs are also used: */ for (unsigned i = 0; i < ir->noutputs; i++) { struct ir3_instruction *out = ir->outputs[i]; if (!out) continue; use_instr(out); } } #define NULL_INSTR ((void *)~0) static void clear_cache(struct ir3_sched_ctx *ctx, struct ir3_instruction *instr) { list_for_each_entry (struct ir3_instruction, instr2, &ctx->depth_list, node) { if ((instr2->data == instr) || (instr2->data == NULL_INSTR) || !instr) instr2->data = NULL; } } static void schedule(struct ir3_sched_ctx *ctx, struct ir3_instruction *instr) { debug_assert(ctx->block == instr->block); /* maybe there is a better way to handle this than just stuffing * a nop.. ideally we'd know about this constraint in the * scheduling and depth calculation.. */ if (ctx->scheduled && is_sfu_or_mem(ctx->scheduled) && is_sfu_or_mem(instr)) ir3_NOP(ctx->block); /* remove from depth list: */ list_delinit(&instr->node); if (writes_addr(instr)) { debug_assert(ctx->addr == NULL); ctx->addr = instr; } if (writes_pred(instr)) { debug_assert(ctx->pred == NULL); ctx->pred = instr; } instr->flags |= IR3_INSTR_MARK; list_addtail(&instr->node, &instr->block->instr_list); ctx->scheduled = instr; update_live_values(ctx, instr); if (writes_addr(instr) || writes_pred(instr) || is_input(instr)) { clear_cache(ctx, NULL); } else { /* invalidate only the necessary entries.. */ clear_cache(ctx, instr); } } static struct ir3_instruction * deepest(struct ir3_instruction **srcs, unsigned nsrcs) { struct ir3_instruction *d = NULL; unsigned i = 0, id = 0; while ((i < nsrcs) && !(d = srcs[id = i])) i++; if (!d) return NULL; for (; i < nsrcs; i++) if (srcs[i] && (srcs[i]->depth > d->depth)) d = srcs[id = i]; srcs[id] = NULL; return d; } /** * @block: the block to search in, starting from end; in first pass, * this will be the block the instruction would be inserted into * (but has not yet, ie. it only contains already scheduled * instructions). For intra-block scheduling (second pass), this * would be one of the predecessor blocks. * @instr: the instruction to search for * @maxd: max distance, bail after searching this # of instruction * slots, since it means the instruction we are looking for is * far enough away * @pred: if true, recursively search into predecessor blocks to * find the worst case (shortest) distance (only possible after * individual blocks are all scheduled */ static unsigned distance(struct ir3_block *block, struct ir3_instruction *instr, unsigned maxd, bool pred) { unsigned d = 0; list_for_each_entry_rev (struct ir3_instruction, n, &block->instr_list, node) { if ((n == instr) || (d >= maxd)) return d; /* NOTE: don't count branch/jump since we don't know yet if they will * be eliminated later in resolve_jumps().. really should do that * earlier so we don't have this constraint. */ if (is_alu(n) || (is_flow(n) && (n->opc != OPC_JUMP) && (n->opc != OPC_BR))) d++; } /* if coming from a predecessor block, assume it is assigned far * enough away.. we'll fix up later. */ if (!pred) return maxd; if (pred && (block->data != block)) { /* Search into predecessor blocks, finding the one with the * shortest distance, since that will be the worst case */ unsigned min = maxd - d; /* (ab)use block->data to prevent recursion: */ block->data = block; for (unsigned i = 0; i < block->predecessors_count; i++) { unsigned n; n = distance(block->predecessors[i], instr, min, pred); min = MIN2(min, n); } block->data = NULL; d += min; } return d; } /* calculate delay for specified src: */ static unsigned delay_calc_srcn(struct ir3_block *block, struct ir3_instruction *assigner, struct ir3_instruction *consumer, unsigned srcn, bool soft, bool pred) { unsigned delay = 0; if (is_meta(assigner)) { struct ir3_instruction *src; foreach_ssa_src(src, assigner) { unsigned d; d = delay_calc_srcn(block, src, consumer, srcn, soft, pred); delay = MAX2(delay, d); } } else { if (soft) { if (is_sfu(assigner)) { delay = 4; } else { delay = ir3_delayslots(assigner, consumer, srcn); } } else { delay = ir3_delayslots(assigner, consumer, srcn); } delay -= distance(block, assigner, delay, pred); } return delay; } /* calculate delay for instruction (maximum of delay for all srcs): */ static unsigned delay_calc(struct ir3_block *block, struct ir3_instruction *instr, bool soft, bool pred) { unsigned delay = 0; struct ir3_instruction *src; foreach_ssa_src_n(src, i, instr) { unsigned d; d = delay_calc_srcn(block, src, instr, i, soft, pred); delay = MAX2(delay, d); } return delay; } struct ir3_sched_notes { /* there is at least one kill which could be scheduled, except * for unscheduled bary.f's: */ bool blocked_kill; /* there is at least one instruction that could be scheduled, * except for conflicting address/predicate register usage: */ bool addr_conflict, pred_conflict; }; static bool is_scheduled(struct ir3_instruction *instr) { return !!(instr->flags & IR3_INSTR_MARK); } /* could an instruction be scheduled if specified ssa src was scheduled? */ static bool could_sched(struct ir3_instruction *instr, struct ir3_instruction *src) { struct ir3_instruction *other_src; foreach_ssa_src(other_src, instr) { /* if dependency not scheduled, we aren't ready yet: */ if ((src != other_src) && !is_scheduled(other_src)) { return false; } } return true; } /* Check if instruction is ok to schedule. Make sure it is not blocked * by use of addr/predicate register, etc. */ static bool check_instr(struct ir3_sched_ctx *ctx, struct ir3_sched_notes *notes, struct ir3_instruction *instr) { /* For instructions that write address register we need to * make sure there is at least one instruction that uses the * addr value which is otherwise ready. * * TODO if any instructions use pred register and have other * src args, we would need to do the same for writes_pred().. */ if (writes_addr(instr)) { struct ir3 *ir = instr->block->shader; bool ready = false; for (unsigned i = 0; (i < ir->indirects_count) && !ready; i++) { struct ir3_instruction *indirect = ir->indirects[i]; if (!indirect) continue; if (indirect->address != instr) continue; ready = could_sched(indirect, instr); } /* nothing could be scheduled, so keep looking: */ if (!ready) return false; } /* if this is a write to address/predicate register, and that * register is currently in use, we need to defer until it is * free: */ if (writes_addr(instr) && ctx->addr) { debug_assert(ctx->addr != instr); notes->addr_conflict = true; return false; } if (writes_pred(instr) && ctx->pred) { debug_assert(ctx->pred != instr); notes->pred_conflict = true; return false; } /* if the instruction is a kill, we need to ensure *every* * bary.f is scheduled. The hw seems unhappy if the thread * gets killed before the end-input (ei) flag is hit. * * We could do this by adding each bary.f instruction as * virtual ssa src for the kill instruction. But we have * fixed length instr->regs[]. * * TODO this wouldn't be quite right if we had multiple * basic blocks, if any block was conditional. We'd need * to schedule the bary.f's outside of any block which * was conditional that contained a kill.. I think.. */ if (is_kill(instr)) { struct ir3 *ir = instr->block->shader; for (unsigned i = 0; i < ir->baryfs_count; i++) { struct ir3_instruction *baryf = ir->baryfs[i]; if (baryf->flags & IR3_INSTR_UNUSED) continue; if (!is_scheduled(baryf)) { notes->blocked_kill = true; return false; } } } return true; } /* Find the best instruction to schedule from specified instruction or * recursively it's ssa sources. */ static struct ir3_instruction * find_instr_recursive(struct ir3_sched_ctx *ctx, struct ir3_sched_notes *notes, struct ir3_instruction *instr) { struct ir3_instruction *srcs[__ssa_src_cnt(instr)]; struct ir3_instruction *src; unsigned nsrcs = 0; if (is_scheduled(instr)) return NULL; /* use instr->data to cache the results of recursing up the * instr src's. Otherwise the recursive algo can scale quite * badly w/ shader size. But this takes some care to clear * the cache appropriately when instructions are scheduled. */ if (instr->data) { if (instr->data == NULL_INSTR) return NULL; return instr->data; } /* find unscheduled srcs: */ foreach_ssa_src(src, instr) { if (!is_scheduled(src) && (src->block == instr->block)) { debug_assert(nsrcs < ARRAY_SIZE(srcs)); srcs[nsrcs++] = src; } } /* if all our src's are already scheduled: */ if (nsrcs == 0) { if (check_instr(ctx, notes, instr)) { instr->data = instr; return instr; } return NULL; } while ((src = deepest(srcs, nsrcs))) { struct ir3_instruction *candidate; candidate = find_instr_recursive(ctx, notes, src); if (!candidate) continue; if (check_instr(ctx, notes, candidate)) { instr->data = candidate; return candidate; } } instr->data = NULL_INSTR; return NULL; } /* find net change to live values if instruction were scheduled: */ static int live_effect(struct ir3_instruction *instr) { struct ir3_instruction *src; int new_live = dest_regs(instr); int old_live = 0; foreach_ssa_src_n(src, n, instr) { if (__is_false_dep(instr, n)) continue; if (instr->block != src->block) continue; /* for fanout/split, just pass things along to the real src: */ if (src->opc == OPC_META_FO) src = ssa(src->regs[1]); /* for fanin/collect, if this is the last use of *each* src, * then it will decrease the live values, since RA treats * them as a whole: */ if (src->opc == OPC_META_FI) { struct ir3_instruction *src2; bool last_use = true; foreach_ssa_src(src2, src) { if (src2->use_count > 1) { last_use = false; break; } } if (last_use) old_live += dest_regs(src); } else { debug_assert(src->use_count > 0); if (src->use_count == 1) { old_live += dest_regs(src); } } } return new_live - old_live; } /* find instruction to schedule: */ static struct ir3_instruction * find_eligible_instr(struct ir3_sched_ctx *ctx, struct ir3_sched_notes *notes, bool soft) { struct ir3_instruction *best_instr = NULL; int best_rank = INT_MAX; /* lower is better */ unsigned deepest = 0; /* TODO we'd really rather use the list/array of block outputs. But we * don't have such a thing. Recursing *every* instruction in the list * will result in a lot of repeated traversal, since instructions will * get traversed both when they appear as ssa src to a later instruction * as well as where they appear in the depth_list. */ list_for_each_entry_rev (struct ir3_instruction, instr, &ctx->depth_list, node) { struct ir3_instruction *candidate; candidate = find_instr_recursive(ctx, notes, instr); if (!candidate) continue; if (is_meta(candidate)) return candidate; deepest = MAX2(deepest, candidate->depth); } /* traverse the list a second time.. but since we cache the result of * find_instr_recursive() it isn't as bad as it looks. */ list_for_each_entry_rev (struct ir3_instruction, instr, &ctx->depth_list, node) { struct ir3_instruction *candidate; candidate = find_instr_recursive(ctx, notes, instr); if (!candidate) continue; /* determine net change to # of live values: */ int le = live_effect(candidate); /* if there is a net increase in # of live values, then apply some * threshold to avoid instructions getting scheduled *too* early * and increasing register pressure. */ if (le >= 1) { unsigned threshold; if (ctx->live_values > 4*4) { threshold = 4; } else { threshold = 6; } /* Filter out any "shallow" instructions which would otherwise * tend to get scheduled too early to fill delay slots even * when they are not needed for a while. There will probably * be later delay slots that they could just as easily fill. * * A classic case where this comes up is frag shaders that * write a constant value (like 1.0f) to one of the channels * of the output color(s). Since the mov from immed has no * dependencies, it would otherwise get scheduled early to * fill delay slots, occupying a register until the end of * the program. */ if ((deepest - candidate->depth) > threshold) continue; } int rank = delay_calc(ctx->block, candidate, soft, false); /* if too many live values, prioritize instructions that reduce the * number of live values: */ if (ctx->live_values > 16*4) { rank = le; } else if (ctx->live_values > 4*4) { rank += le; } if (rank < best_rank) { best_instr = candidate; best_rank = rank; } } return best_instr; } /* "spill" the address register by remapping any unscheduled * instructions which depend on the current address register * to a clone of the instruction which wrote the address reg. */ static struct ir3_instruction * split_addr(struct ir3_sched_ctx *ctx) { struct ir3 *ir; struct ir3_instruction *new_addr = NULL; unsigned i; debug_assert(ctx->addr); ir = ctx->addr->block->shader; for (i = 0; i < ir->indirects_count; i++) { struct ir3_instruction *indirect = ir->indirects[i]; if (!indirect) continue; /* skip instructions already scheduled: */ if (is_scheduled(indirect)) continue; /* remap remaining instructions using current addr * to new addr: */ if (indirect->address == ctx->addr) { if (!new_addr) { new_addr = ir3_instr_clone(ctx->addr); /* original addr is scheduled, but new one isn't: */ new_addr->flags &= ~IR3_INSTR_MARK; } ir3_instr_set_address(indirect, new_addr); } } /* all remaining indirects remapped to new addr: */ ctx->addr = NULL; return new_addr; } /* "spill" the predicate register by remapping any unscheduled * instructions which depend on the current predicate register * to a clone of the instruction which wrote the address reg. */ static struct ir3_instruction * split_pred(struct ir3_sched_ctx *ctx) { struct ir3 *ir; struct ir3_instruction *new_pred = NULL; unsigned i; debug_assert(ctx->pred); ir = ctx->pred->block->shader; for (i = 0; i < ir->predicates_count; i++) { struct ir3_instruction *predicated = ir->predicates[i]; /* skip instructions already scheduled: */ if (is_scheduled(predicated)) continue; /* remap remaining instructions using current pred * to new pred: * * TODO is there ever a case when pred isn't first * (and only) src? */ if (ssa(predicated->regs[1]) == ctx->pred) { if (!new_pred) { new_pred = ir3_instr_clone(ctx->pred); /* original pred is scheduled, but new one isn't: */ new_pred->flags &= ~IR3_INSTR_MARK; } predicated->regs[1]->instr = new_pred; } } /* all remaining predicated remapped to new pred: */ ctx->pred = NULL; return new_pred; } static void sched_block(struct ir3_sched_ctx *ctx, struct ir3_block *block) { struct list_head unscheduled_list; ctx->block = block; /* addr/pred writes are per-block: */ ctx->addr = NULL; ctx->pred = NULL; /* move all instructions to the unscheduled list, and * empty the block's instruction list (to which we will * be inserting). */ list_replace(&block->instr_list, &unscheduled_list); list_inithead(&block->instr_list); list_inithead(&ctx->depth_list); /* first a pre-pass to schedule all meta:input instructions * (which need to appear first so that RA knows the register is * occupied), and move remaining to depth sorted list: */ list_for_each_entry_safe (struct ir3_instruction, instr, &unscheduled_list, node) { if (instr->opc == OPC_META_INPUT) { schedule(ctx, instr); } else { ir3_insert_by_depth(instr, &ctx->depth_list); } } while (!list_empty(&ctx->depth_list)) { struct ir3_sched_notes notes = {0}; struct ir3_instruction *instr; instr = find_eligible_instr(ctx, ¬es, true); if (!instr) instr = find_eligible_instr(ctx, ¬es, false); if (instr) { unsigned delay = delay_calc(ctx->block, instr, false, false); /* and if we run out of instructions that can be scheduled, * then it is time for nop's: */ debug_assert(delay <= 6); while (delay > 0) { ir3_NOP(block); delay--; } schedule(ctx, instr); } else { struct ir3_instruction *new_instr = NULL; /* nothing available to schedule.. if we are blocked on * address/predicate register conflict, then break the * deadlock by cloning the instruction that wrote that * reg: */ if (notes.addr_conflict) { new_instr = split_addr(ctx); } else if (notes.pred_conflict) { new_instr = split_pred(ctx); } else { debug_assert(0); ctx->error = true; return; } if (new_instr) { /* clearing current addr/pred can change what is * available to schedule, so clear cache.. */ clear_cache(ctx, NULL); ir3_insert_by_depth(new_instr, &ctx->depth_list); /* the original instr that wrote addr/pred may have * originated from a different block: */ new_instr->block = block; } } } /* And lastly, insert branch/jump instructions to take us to * the next block. Later we'll strip back out the branches * that simply jump to next instruction. */ if (block->successors[1]) { /* if/else, conditional branches to "then" or "else": */ struct ir3_instruction *br; unsigned delay = 6; debug_assert(ctx->pred); debug_assert(block->condition); delay -= distance(ctx->block, ctx->pred, delay, false); while (delay > 0) { ir3_NOP(block); delay--; } /* create "else" branch first (since "then" block should * frequently/always end up being a fall-thru): */ br = ir3_BR(block); br->cat0.inv = true; br->cat0.target = block->successors[1]; /* NOTE: we have to hard code delay of 6 above, since * we want to insert the nop's before constructing the * branch. Throw in an assert so we notice if this * ever breaks on future generation: */ debug_assert(ir3_delayslots(ctx->pred, br, 0) == 6); br = ir3_BR(block); br->cat0.target = block->successors[0]; } else if (block->successors[0]) { /* otherwise unconditional jump to next block: */ struct ir3_instruction *jmp; jmp = ir3_JUMP(block); jmp->cat0.target = block->successors[0]; } /* NOTE: if we kept track of the predecessors, we could do a better * job w/ (jp) flags.. every node w/ > predecessor is a join point. * Note that as we eliminate blocks which contain only an unconditional * jump we probably need to propagate (jp) flag.. */ } /* After scheduling individual blocks, we still could have cases where * one (or more) paths into a block, a value produced by a previous * has too few delay slots to be legal. We can't deal with this in the * first pass, because loops (ie. we can't ensure all predecessor blocks * are already scheduled in the first pass). All we can really do at * this point is stuff in extra nop's until things are legal. */ static void sched_intra_block(struct ir3_sched_ctx *ctx, struct ir3_block *block) { unsigned n = 0; ctx->block = block; list_for_each_entry_safe (struct ir3_instruction, instr, &block->instr_list, node) { unsigned delay = 0; for (unsigned i = 0; i < block->predecessors_count; i++) { unsigned d = delay_calc(block->predecessors[i], instr, false, true); delay = MAX2(d, delay); } while (delay > n) { struct ir3_instruction *nop = ir3_NOP(block); /* move to before instr: */ list_delinit(&nop->node); list_addtail(&nop->node, &instr->node); n++; } /* we can bail once we hit worst case delay: */ if (++n > 6) break; } } int ir3_sched(struct ir3 *ir) { struct ir3_sched_ctx ctx = {0}; ir3_clear_mark(ir); update_use_count(ir); list_for_each_entry (struct ir3_block, block, &ir->block_list, node) { ctx.live_values = 0; sched_block(&ctx, block); } list_for_each_entry (struct ir3_block, block, &ir->block_list, node) { sched_intra_block(&ctx, block); } if (ctx.error) return -1; return 0; } static unsigned get_array_id(struct ir3_instruction *instr) { /* The expectation is that there is only a single array * src or dst, ir3_cp should enforce this. */ for (unsigned i = 0; i < instr->regs_count; i++) if (instr->regs[i]->flags & IR3_REG_ARRAY) return instr->regs[i]->array.id; unreachable("this was unexpected"); } /* does instruction 'prior' need to be scheduled before 'instr'? */ static bool depends_on(struct ir3_instruction *instr, struct ir3_instruction *prior) { /* TODO for dependencies that are related to a specific object, ie * a specific SSBO/image/array, we could relax this constraint to * make accesses to unrelated objects not depend on each other (at * least as long as not declared coherent) */ if (((instr->barrier_class & IR3_BARRIER_EVERYTHING) && prior->barrier_class) || ((prior->barrier_class & IR3_BARRIER_EVERYTHING) && instr->barrier_class)) return true; if (instr->barrier_class & prior->barrier_conflict) { if (!(instr->barrier_class & ~(IR3_BARRIER_ARRAY_R | IR3_BARRIER_ARRAY_W))) { /* if only array barrier, then we can further limit false-deps * by considering the array-id, ie reads/writes to different * arrays do not depend on each other (no aliasing) */ if (get_array_id(instr) != get_array_id(prior)) { return false; } } return true; } return false; } static void add_barrier_deps(struct ir3_block *block, struct ir3_instruction *instr) { struct list_head *prev = instr->node.prev; struct list_head *next = instr->node.next; /* add dependencies on previous instructions that must be scheduled * prior to the current instruction */ while (prev != &block->instr_list) { struct ir3_instruction *pi = LIST_ENTRY(struct ir3_instruction, prev, node); prev = prev->prev; if (is_meta(pi)) continue; if (instr->barrier_class == pi->barrier_class) { ir3_instr_add_dep(instr, pi); break; } if (depends_on(instr, pi)) ir3_instr_add_dep(instr, pi); } /* add dependencies on this instruction to following instructions * that must be scheduled after the current instruction: */ while (next != &block->instr_list) { struct ir3_instruction *ni = LIST_ENTRY(struct ir3_instruction, next, node); next = next->next; if (is_meta(ni)) continue; if (instr->barrier_class == ni->barrier_class) { ir3_instr_add_dep(ni, instr); break; } if (depends_on(ni, instr)) ir3_instr_add_dep(ni, instr); } } /* before scheduling a block, we need to add any necessary false-dependencies * to ensure that: * * (1) barriers are scheduled in the right order wrt instructions related * to the barrier * * (2) reads that come before a write actually get scheduled before the * write */ static void calculate_deps(struct ir3_block *block) { list_for_each_entry (struct ir3_instruction, instr, &block->instr_list, node) { if (instr->barrier_class) { add_barrier_deps(block, instr); } } } void ir3_sched_add_deps(struct ir3 *ir) { list_for_each_entry (struct ir3_block, block, &ir->block_list, node) { calculate_deps(block); } }