/* * Copyright © 2010 Intel Corporation * * 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: * Eric Anholt * */ /** @file register_allocate.c * * Graph-coloring register allocator. */ #include #include "main/imports.h" #include "main/macros.h" #include "main/mtypes.h" #include "register_allocate.h" struct ra_reg { GLboolean *conflicts; unsigned int *conflict_list; unsigned int conflict_list_size; unsigned int num_conflicts; }; struct ra_regs { struct ra_reg *regs; unsigned int count; struct ra_class **classes; unsigned int class_count; }; struct ra_class { GLboolean *regs; /** * p_B in Runeson/Nyström paper. * * This is "how many regs are in the set." */ unsigned int p; /** * q_B,C in Runeson/Nyström paper. */ unsigned int *q; }; struct ra_node { GLboolean *adjacency; unsigned int *adjacency_list; unsigned int class; unsigned int adjacency_count; unsigned int reg; GLboolean in_stack; float spill_cost; }; struct ra_graph { struct ra_regs *regs; /** * the variables that need register allocation. */ struct ra_node *nodes; unsigned int count; /**< count of nodes. */ unsigned int *stack; unsigned int stack_count; }; struct ra_regs * ra_alloc_reg_set(unsigned int count) { unsigned int i; struct ra_regs *regs; regs = rzalloc(NULL, struct ra_regs); regs->count = count; regs->regs = rzalloc_array(regs, struct ra_reg, count); for (i = 0; i < count; i++) { regs->regs[i].conflicts = rzalloc_array(regs->regs, GLboolean, count); regs->regs[i].conflicts[i] = GL_TRUE; regs->regs[i].conflict_list = ralloc_array(regs->regs, unsigned int, 4); regs->regs[i].conflict_list_size = 4; regs->regs[i].conflict_list[0] = i; regs->regs[i].num_conflicts = 1; } return regs; } static void ra_add_conflict_list(struct ra_regs *regs, unsigned int r1, unsigned int r2) { struct ra_reg *reg1 = ®s->regs[r1]; if (reg1->conflict_list_size == reg1->num_conflicts) { reg1->conflict_list_size *= 2; reg1->conflict_list = reralloc(regs->regs, reg1->conflict_list, unsigned int, reg1->conflict_list_size); } reg1->conflict_list[reg1->num_conflicts++] = r2; reg1->conflicts[r2] = GL_TRUE; } void ra_add_reg_conflict(struct ra_regs *regs, unsigned int r1, unsigned int r2) { if (!regs->regs[r1].conflicts[r2]) { ra_add_conflict_list(regs, r1, r2); ra_add_conflict_list(regs, r2, r1); } } unsigned int ra_alloc_reg_class(struct ra_regs *regs) { struct ra_class *class; regs->classes = reralloc(regs->regs, regs->classes, struct ra_class *, regs->class_count + 1); class = rzalloc(regs, struct ra_class); regs->classes[regs->class_count] = class; class->regs = rzalloc_array(class, GLboolean, regs->count); return regs->class_count++; } void ra_class_add_reg(struct ra_regs *regs, unsigned int c, unsigned int r) { struct ra_class *class = regs->classes[c]; class->regs[r] = GL_TRUE; class->p++; } /** * Must be called after all conflicts and register classes have been * set up and before the register set is used for allocation. */ void ra_set_finalize(struct ra_regs *regs) { unsigned int b, c; for (b = 0; b < regs->class_count; b++) { regs->classes[b]->q = ralloc_array(regs, unsigned int, regs->class_count); } /* Compute, for each class B and C, how many regs of B an * allocation to C could conflict with. */ for (b = 0; b < regs->class_count; b++) { for (c = 0; c < regs->class_count; c++) { unsigned int rc; int max_conflicts = 0; for (rc = 0; rc < regs->count; rc++) { int conflicts = 0; int i; if (!regs->classes[c]->regs[rc]) continue; for (i = 0; i < regs->regs[rc].num_conflicts; i++) { unsigned int rb = regs->regs[rc].conflict_list[i]; if (regs->classes[b]->regs[rb]) conflicts++; } max_conflicts = MAX2(max_conflicts, conflicts); } regs->classes[b]->q[c] = max_conflicts; } } } static void ra_add_node_adjacency(struct ra_graph *g, unsigned int n1, unsigned int n2) { g->nodes[n1].adjacency[n2] = GL_TRUE; g->nodes[n1].adjacency_list[g->nodes[n1].adjacency_count] = n2; g->nodes[n1].adjacency_count++; } struct ra_graph * ra_alloc_interference_graph(struct ra_regs *regs, unsigned int count) { struct ra_graph *g; unsigned int i; g = rzalloc(regs, struct ra_graph); g->regs = regs; g->nodes = rzalloc_array(g, struct ra_node, count); g->count = count; g->stack = rzalloc_array(g, unsigned int, count); for (i = 0; i < count; i++) { g->nodes[i].adjacency = rzalloc_array(g, GLboolean, count); g->nodes[i].adjacency_list = ralloc_array(g, unsigned int, count); g->nodes[i].adjacency_count = 0; ra_add_node_adjacency(g, i, i); g->nodes[i].reg = ~0; } return g; } void ra_set_node_class(struct ra_graph *g, unsigned int n, unsigned int class) { g->nodes[n].class = class; } void ra_add_node_interference(struct ra_graph *g, unsigned int n1, unsigned int n2) { if (!g->nodes[n1].adjacency[n2]) { ra_add_node_adjacency(g, n1, n2); ra_add_node_adjacency(g, n2, n1); } } static GLboolean pq_test(struct ra_graph *g, unsigned int n) { unsigned int j; unsigned int q = 0; int n_class = g->nodes[n].class; for (j = 0; j < g->nodes[n].adjacency_count; j++) { unsigned int n2 = g->nodes[n].adjacency_list[j]; unsigned int n2_class = g->nodes[n2].class; if (n != n2 && !g->nodes[n2].in_stack) { q += g->regs->classes[n_class]->q[n2_class]; } } return q < g->regs->classes[n_class]->p; } /** * Simplifies the interference graph by pushing all * trivially-colorable nodes into a stack of nodes to be colored, * removing them from the graph, and rinsing and repeating. * * Returns GL_TRUE if all nodes were removed from the graph. GL_FALSE * means that either spilling will be required, or optimistic coloring * should be applied. */ GLboolean ra_simplify(struct ra_graph *g) { GLboolean progress = GL_TRUE; int i; while (progress) { progress = GL_FALSE; for (i = g->count - 1; i >= 0; i--) { if (g->nodes[i].in_stack) continue; if (pq_test(g, i)) { g->stack[g->stack_count] = i; g->stack_count++; g->nodes[i].in_stack = GL_TRUE; progress = GL_TRUE; } } } for (i = 0; i < g->count; i++) { if (!g->nodes[i].in_stack) return GL_FALSE; } return GL_TRUE; } /** * Pops nodes from the stack back into the graph, coloring them with * registers as they go. * * If all nodes were trivially colorable, then this must succeed. If * not (optimistic coloring), then it may return GL_FALSE; */ GLboolean ra_select(struct ra_graph *g) { int i; while (g->stack_count != 0) { unsigned int r; int n = g->stack[g->stack_count - 1]; struct ra_class *c = g->regs->classes[g->nodes[n].class]; /* Find the lowest-numbered reg which is not used by a member * of the graph adjacent to us. */ for (r = 0; r < g->regs->count; r++) { if (!c->regs[r]) continue; /* Check if any of our neighbors conflict with this register choice. */ for (i = 0; i < g->nodes[n].adjacency_count; i++) { unsigned int n2 = g->nodes[n].adjacency_list[i]; if (!g->nodes[n2].in_stack && g->regs->regs[r].conflicts[g->nodes[n2].reg]) { break; } } if (i == g->nodes[n].adjacency_count) break; } if (r == g->regs->count) return GL_FALSE; g->nodes[n].reg = r; g->nodes[n].in_stack = GL_FALSE; g->stack_count--; } return GL_TRUE; } /** * Optimistic register coloring: Just push the remaining nodes * on the stack. They'll be colored first in ra_select(), and * if they succeed then the locally-colorable nodes are still * locally-colorable and the rest of the register allocation * will succeed. */ void ra_optimistic_color(struct ra_graph *g) { unsigned int i; for (i = 0; i < g->count; i++) { if (g->nodes[i].in_stack) continue; g->stack[g->stack_count] = i; g->stack_count++; g->nodes[i].in_stack = GL_TRUE; } } GLboolean ra_allocate_no_spills(struct ra_graph *g) { if (!ra_simplify(g)) { ra_optimistic_color(g); } return ra_select(g); } unsigned int ra_get_node_reg(struct ra_graph *g, unsigned int n) { return g->nodes[n].reg; } static float ra_get_spill_benefit(struct ra_graph *g, unsigned int n) { int j; float benefit = 0; int n_class = g->nodes[n].class; /* Define the benefit of eliminating an interference between n, n2 * through spilling as q(C, B) / p(C). This is similar to the * "count number of edges" approach of traditional graph coloring, * but takes classes into account. */ for (j = 0; j < g->nodes[n].adjacency_count; j++) { unsigned int n2 = g->nodes[n].adjacency_list[j]; if (n != n2) { unsigned int n2_class = g->nodes[n2].class; benefit += ((float)g->regs->classes[n_class]->q[n2_class] / g->regs->classes[n_class]->p); } } return benefit; } /** * Returns a node number to be spilled according to the cost/benefit using * the pq test, or -1 if there are no spillable nodes. */ int ra_get_best_spill_node(struct ra_graph *g) { unsigned int best_node = -1; unsigned int best_benefit = 0.0; unsigned int n; for (n = 0; n < g->count; n++) { float cost = g->nodes[n].spill_cost; float benefit; if (cost <= 0.0) continue; benefit = ra_get_spill_benefit(g, n); if (benefit / cost > best_benefit) { best_benefit = benefit / cost; best_node = n; } } return best_node; } /** * Only nodes with a spill cost set (cost != 0.0) will be considered * for register spilling. */ void ra_set_node_spill_cost(struct ra_graph *g, unsigned int n, float cost) { g->nodes[n].spill_cost = cost; }