/* * Copyright (C) 1995-2010 University of Karlsruhe. All right reserved. * * This file is part of libFirm. * * This file may be distributed and/or modified under the terms of the * GNU General Public License version 2 as published by the Free Software * Foundation and appearing in the file LICENSE.GPL included in the * packaging of this file. * * Licensees holding valid libFirm Professional Edition licenses may use * this file in accordance with the libFirm Commercial License. * Agreement provided with the Software. * * This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE * WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE. */ /** * @file * @brief Various verify routines that check a scheduled graph for correctness. * @author Matthias Braun * @date 05.05.2006 */ #include "config.h" #include #include #include "bitset.h" #include "set.h" #include "array.h" #include "irnode.h" #include "irgraph.h" #include "irgwalk.h" #include "irprintf.h" #include "irdump_t.h" #include "iredges.h" #include "beverify.h" #include "belive.h" #include "besched.h" #include "benode.h" #include "beirg.h" #include "beintlive_t.h" #include "belistsched.h" static int my_values_interfere(const ir_node *a, const ir_node *b); typedef struct be_verify_register_pressure_env_t_ { ir_graph *irg; /**< the irg to verify */ be_lv_t *lv; /**< Liveness information. */ const arch_register_class_t *cls; /**< the register class to check for */ int registers_available; /**< number of available registers */ int problem_found; /**< flag indicating if a problem was found */ } be_verify_register_pressure_env_t; /** * Print all nodes of a pset into a file. */ static void print_living_values(FILE *F, const ir_nodeset_t *live_nodes) { ir_nodeset_iterator_t iter; ir_node *node; ir_fprintf(F, "\t"); foreach_ir_nodeset(live_nodes, node, iter) { ir_fprintf(F, "%+F ", node); } ir_fprintf(F, "\n"); } /** * Check if number of live nodes never exceeds the number of available registers. */ static void verify_liveness_walker(ir_node *block, void *data) { be_verify_register_pressure_env_t *env = (be_verify_register_pressure_env_t *)data; ir_nodeset_t live_nodes; ir_node *irn; int pressure; /* collect register pressure info, start with end of a block */ // ir_fprintf(stderr, "liveness check %+F\n", block); ir_nodeset_init(&live_nodes); be_liveness_end_of_block(env->lv, env->cls, block, &live_nodes); // print_living_values(stderr, &live_nodes); pressure = ir_nodeset_size(&live_nodes); if (pressure > env->registers_available) { ir_fprintf(stderr, "Verify Warning: Register pressure too high at end of block %+F(%s) (%d/%d):\n", block, get_irg_dump_name(env->irg), pressure, env->registers_available); print_living_values(stderr, &live_nodes); env->problem_found = 1; } sched_foreach_reverse(block, irn) { if (is_Phi(irn)) break; // print_living_values(stderr, &live_nodes); be_liveness_transfer(env->cls, irn, &live_nodes); pressure = ir_nodeset_size(&live_nodes); if (pressure > env->registers_available) { ir_fprintf(stderr, "Verify Warning: Register pressure too high before node %+F in %+F(%s) (%d/%d):\n", irn, block, get_irg_dump_name(env->irg), pressure, env->registers_available); print_living_values(stderr, &live_nodes); env->problem_found = 1; assert(0); } } ir_nodeset_destroy(&live_nodes); } /** * Start a walk over the irg and check the register pressure. */ int be_verify_register_pressure(ir_graph *irg, const arch_register_class_t *cls) { be_verify_register_pressure_env_t env; env.lv = be_liveness(irg); env.irg = irg; env.cls = cls; env.registers_available = be_get_n_allocatable_regs(irg, cls); env.problem_found = 0; be_liveness_assure_sets(env.lv); irg_block_walk_graph(irg, verify_liveness_walker, NULL, &env); be_liveness_free(env.lv); return ! env.problem_found; } /*--------------------------------------------------------------------------- */ typedef struct be_verify_schedule_env_t_ { int problem_found; /**< flags indicating a problem */ bitset_t *scheduled; /**< bitset of scheduled nodes */ ir_graph *irg; /**< the irg to check */ } be_verify_schedule_env_t; /** * Simple schedule checker. */ static void verify_schedule_walker(ir_node *block, void *data) { be_verify_schedule_env_t *env = (be_verify_schedule_env_t*) data; ir_node *node; ir_node *non_phi_found = NULL; ir_node *cfchange_found = NULL; int last_timestep = INT_MIN; /* * Tests for the following things: * 1. Make sure that all phi nodes are scheduled at the beginning of the * block * 2. No value is defined after it has been used * 3. mode_T nodes have all projs scheduled behind them followed by Keeps * (except mode_X projs) */ sched_foreach(block, node) { int timestep; /* this node is scheduled */ if (bitset_is_set(env->scheduled, get_irn_idx(node))) { ir_fprintf(stderr, "Verify warning: %+F appears to be schedule twice\n"); env->problem_found = 1; } bitset_set(env->scheduled, get_irn_idx(node)); /* Check that scheduled nodes are in the correct block */ if (get_nodes_block(node) != block) { ir_fprintf(stderr, "Verify warning: %+F is in block %+F but scheduled in %+F\n", node, get_nodes_block(node), block); env->problem_found = 1; } /* Check that timesteps are increasing */ timestep = sched_get_time_step(node); if (timestep <= last_timestep) { ir_fprintf(stderr, "Verify warning: Schedule timestep did not increase at node %+F\n", node); env->problem_found = 1; } last_timestep = timestep; /* Check that phis come before any other node */ if (is_Phi(node)) { if (non_phi_found != NULL) { ir_fprintf(stderr, "Verify Warning: Phi node %+F scheduled after non-Phi nodes (for example %+F) in block %+F (%s)\n", node, non_phi_found, block, get_irg_dump_name(env->irg)); env->problem_found = 1; } } else { non_phi_found = node; } /* Check for control flow changing nodes */ if (is_cfop(node)) { /* check, that only one CF operation is scheduled */ if (cfchange_found != NULL) { ir_fprintf(stderr, "Verify Warning: Additional control flow changing node %+F scheduled after %+F in block %+F (%s)\n", node, block, cfchange_found, get_irg_dump_name(env->irg)); env->problem_found = 1; } else { cfchange_found = node; } } else if (cfchange_found != NULL) { /* proj and keepany aren't real instructions... */ if (!is_Proj(node) && !be_is_Keep(node)) { ir_fprintf(stderr, "Verify Warning: Node %+F scheduled after control flow changing node in block %+F (%s)\n", node, block, get_irg_dump_name(env->irg)); env->problem_found = 1; } } /* Check that all uses come before their definitions */ if (!is_Phi(node)) { int i; int arity; sched_timestep_t nodetime = sched_get_time_step(node); for (i = 0, arity = get_irn_arity(node); i < arity; ++i) { ir_node *arg = get_irn_n(node, i); if (get_nodes_block(arg) != block || !sched_is_scheduled(arg)) continue; if (sched_get_time_step(arg) >= nodetime) { ir_fprintf(stderr, "Verify Warning: Value %+F used by %+F before it was defined in block %+F (%s)\n", arg, node, block, get_irg_dump_name(env->irg)); env->problem_found = 1; } } } /* Check that no dead nodes are scheduled */ if (get_irn_n_edges(node) == 0) { ir_fprintf(stderr, "Verify warning: Node %+F is dead but scheduled in block %+F (%s)\n", node, block, get_irg_dump_name(env->irg)); env->problem_found = 1; } if (be_is_Keep(node) || be_is_CopyKeep(node)) { /* at least 1 of the keep arguments has to be its schedule * predecessor */ int arity = get_irn_arity(node); bool found = false; ir_node *prev = sched_prev(node); while (be_is_Keep(prev) || be_is_CopyKeep(prev)) prev = sched_prev(prev); while (true) { int i; for (i = 0; i < arity; ++i) { ir_node *in = get_irn_n(node, i); in = skip_Proj(in); if (in == prev) found = true; } if (found) break; prev = sched_prev(prev); if (!is_Phi(prev)) break; } if (!found) { ir_fprintf(stderr, "%+F not scheduled after its pred node in block %+F (%s)\n", node, block, get_irg_dump_name(env->irg)); env->problem_found = 1; } } } } static void check_schedule(ir_node *node, void *data) { be_verify_schedule_env_t *env = (be_verify_schedule_env_t*)data; bool should_be = !is_Proj(node) && !(arch_get_irn_flags(node) & arch_irn_flags_not_scheduled); bool scheduled = bitset_is_set(env->scheduled, get_irn_idx(node)); if (should_be != scheduled) { ir_fprintf(stderr, "Verify warning: Node %+F in block %+F(%s) should%s be scheduled\n", node, get_nodes_block(node), get_irg_dump_name(env->irg), should_be ? "" : " not"); env->problem_found = 1; } } /** * Start a walk over the irg and check schedule. */ int be_verify_schedule(ir_graph *irg) { be_verify_schedule_env_t env; env.problem_found = 0; env.irg = irg; env.scheduled = bitset_alloca(get_irg_last_idx(env.irg)); irg_block_walk_graph(irg, verify_schedule_walker, NULL, &env); /* check if all nodes are scheduled */ irg_walk_graph(irg, check_schedule, NULL, &env); return ! env.problem_found; } /*--------------------------------------------------------------------------- */ typedef struct spill_t { ir_node *spill; ir_entity *ent; } spill_t; typedef struct { ir_graph *irg; set *spills; ir_node **reloads; int problem_found; } be_verify_spillslots_env_t; static int cmp_spill(const void* d1, const void* d2, size_t size) { const spill_t* s1 = (const spill_t*)d1; const spill_t* s2 = (const spill_t*)d2; (void) size; return s1->spill != s2->spill; } static spill_t *find_spill(be_verify_spillslots_env_t *env, ir_node *node) { spill_t spill; spill.spill = node; return (spill_t*)set_find(env->spills, &spill, sizeof(spill), HASH_PTR(node)); } static spill_t *get_spill(be_verify_spillslots_env_t *env, ir_node *node, ir_entity *ent) { spill_t spill, *res; int hash = HASH_PTR(node); spill.spill = node; res = (spill_t*)set_find(env->spills, &spill, sizeof(spill), hash); if (res == NULL) { spill.ent = ent; res = (spill_t*)set_insert(env->spills, &spill, sizeof(spill), hash); } return res; } static ir_node *get_memory_edge(const ir_node *node) { int i, arity; ir_node *result = NULL; arity = get_irn_arity(node); for (i = arity - 1; i >= 0; --i) { ir_node *arg = get_irn_n(node, i); if (get_irn_mode(arg) == mode_M) { assert(result == NULL); result = arg; } } return result; } static void collect(be_verify_spillslots_env_t *env, ir_node *node, ir_node *reload, ir_entity* ent); static void be_check_entity(be_verify_spillslots_env_t *env, ir_node *node, ir_entity *ent) { if (ent == NULL) { ir_fprintf(stderr, "Verify warning: Node %+F in block %+F(%s) should have an entity assigned\n", node, get_nodes_block(node), get_irg_dump_name(env->irg)); } } static void collect_spill(be_verify_spillslots_env_t *env, ir_node *node, ir_node *reload, ir_entity* ent) { ir_entity *spillent = arch_get_frame_entity(node); be_check_entity(env, node, spillent); get_spill(env, node, ent); if (spillent != ent) { ir_fprintf(stderr, "Verify warning: Spill %+F has different entity than reload %+F in block %+F(%s)\n", node, reload, get_nodes_block(node), get_irg_dump_name(env->irg)); env->problem_found = 1; } } static void collect_memperm(be_verify_spillslots_env_t *env, ir_node *node, ir_node *reload, ir_entity* ent) { int i, arity; spill_t spill, *res; int hash = HASH_PTR(node); int out; ir_node* memperm; ir_entity *spillent; assert(is_Proj(node)); memperm = get_Proj_pred(node); out = get_Proj_proj(node); spillent = be_get_MemPerm_out_entity(memperm, out); be_check_entity(env, memperm, spillent); if (spillent != ent) { ir_fprintf(stderr, "Verify warning: MemPerm %+F has different entity than reload %+F in block %+F(%s)\n", node, reload, get_nodes_block(node), get_irg_dump_name(env->irg)); env->problem_found = 1; } spill.spill = node; res = (spill_t*)set_find(env->spills, &spill, sizeof(spill), hash); if (res != NULL) { return; } spill.ent = spillent; res = (spill_t*)set_insert(env->spills, &spill, sizeof(spill), hash); for (i = 0, arity = be_get_MemPerm_entity_arity(memperm); i < arity; ++i) { ir_node* arg = get_irn_n(memperm, i + 1); ir_entity* argent = be_get_MemPerm_in_entity(memperm, i); collect(env, arg, memperm, argent); } } static void collect_memphi(be_verify_spillslots_env_t *env, ir_node *node, ir_node *reload, ir_entity *ent) { int i, arity; spill_t spill, *res; int hash = HASH_PTR(node); assert(is_Phi(node)); spill.spill = node; res = (spill_t*)set_find(env->spills, &spill, sizeof(spill), hash); if (res != NULL) { return; } spill.ent = ent; res = (spill_t*)set_insert(env->spills, &spill, sizeof(spill), hash); /* is 1 of the arguments a spill? */ for (i = 0, arity = get_irn_arity(node); i < arity; ++i) { ir_node* arg = get_irn_n(node, i); collect(env, arg, reload, ent); } } static void collect(be_verify_spillslots_env_t *env, ir_node *node, ir_node *reload, ir_entity* ent) { if (be_is_Spill(node)) { collect_spill(env, node, reload, ent); } else if (is_Proj(node)) { collect_memperm(env, node, reload, ent); } else if (is_Phi(node) && get_irn_mode(node) == mode_M) { collect_memphi(env, node, reload, ent); } else { /* Disabled for now, spills might get transformed by the backend */ #if 0 ir_fprintf(stderr, "Verify warning: No spill, memperm or memphi attached to node %+F found from node %+F in block %+F(%s)\n", node, reload, get_nodes_block(node), get_irg_dump_name(env->irg)); env->problem_found = 1; #endif } } /** * This walker function searches for reloads and collects all the spills * and memphis attached to them. */ static void collect_spills_walker(ir_node *node, void *data) { be_verify_spillslots_env_t *env = (be_verify_spillslots_env_t*)data; if (be_is_Reload(node)) { ir_node *spill = get_memory_edge(node); ir_entity *ent; if (spill == NULL) { ir_fprintf(stderr, "Verify warning: No spill attached to reload %+F in block %+F(%s)\n", node, get_nodes_block(node), get_irg_dump_name(env->irg)); env->problem_found = 1; return; } ent = arch_get_frame_entity(node); be_check_entity(env, node, ent); collect(env, spill, node, ent); ARR_APP1(ir_node*, env->reloads, node); } } static void check_spillslot_interference(be_verify_spillslots_env_t *env) { int spillcount = set_count(env->spills); spill_t **spills = ALLOCAN(spill_t*, spillcount); spill_t *spill; int i; i = 0; foreach_set(env->spills, spill_t*, spill) { spills[i++] = spill; } for (i = 0; i < spillcount; ++i) { spill_t *sp1 = spills[i]; int i2; for (i2 = i+1; i2 < spillcount; ++i2) { spill_t *sp2 = spills[i2]; if (sp1->ent != sp2->ent) continue; if (my_values_interfere(sp1->spill, sp2->spill)) { ir_fprintf(stderr, "Verify warning: Spillslots for %+F in block %+F(%s) and %+F in block %+F(%s) interfere\n", sp1->spill, get_nodes_block(sp1->spill), get_irg_dump_name(env->irg), sp2->spill, get_nodes_block(sp2->spill), get_irg_dump_name(env->irg)); env->problem_found = 1; my_values_interfere(sp1->spill, sp2->spill); } } } } static void check_lonely_spills(ir_node *node, void *data) { be_verify_spillslots_env_t *env = (be_verify_spillslots_env_t*)data; if (be_is_Spill(node) || (is_Proj(node) && be_is_MemPerm(get_Proj_pred(node)))) { spill_t *spill = find_spill(env, node); if (be_is_Spill(node)) { ir_entity *ent = arch_get_frame_entity(node); be_check_entity(env, node, ent); } if (spill == NULL) { ir_fprintf(stderr, "Verify warning: Node %+F in block %+F(%s) not connected to a reload\n", node, get_nodes_block(node), get_irg_dump_name(env->irg)); } } } int be_verify_spillslots(ir_graph *irg) { be_verify_spillslots_env_t env; env.irg = irg; env.spills = new_set(cmp_spill, 10); env.reloads = NEW_ARR_F(ir_node*, 0); env.problem_found = 0; irg_walk_graph(irg, collect_spills_walker, NULL, &env); irg_walk_graph(irg, check_lonely_spills, NULL, &env); check_spillslot_interference(&env); DEL_ARR_F(env.reloads); del_set(env.spills); return ! env.problem_found; } /*--------------------------------------------------------------------------- */ /** * Check, if two values interfere. * @param a The first value. * @param b The second value. * @return 1, if a and b interfere, 0 if not. */ static int my_values_interfere(const ir_node *a, const ir_node *b) { const ir_edge_t *edge; ir_node *bb; int a2b = value_dominates(a, b); int b2a = value_dominates(b, a); /* If there is no dominance relation, they do not interfere. */ if (!a2b && !b2a) return 0; /* * Adjust a and b so, that a dominates b if * a dominates b or vice versa. */ if (b2a) { const ir_node *t = a; a = b; b = t; } bb = get_nodes_block(b); /* * Look at all usages of a. * If there's one usage of a in the block of b, then * we check, if this use is dominated by b, if that's true * a and b interfere. Note that b must strictly dominate the user, * since if b is the last user of in the block, b and a do not * interfere. * Uses of a not in b's block can be disobeyed, because the * check for a being live at the end of b's block is already * performed. */ foreach_out_edge(a, edge) { const ir_node *user = get_edge_src_irn(edge); if (b == user) continue; if (get_irn_opcode(user) == iro_End) continue; /* in case of phi arguments we compare with the block the value comes from */ if (is_Phi(user)) { ir_node *phiblock = get_nodes_block(user); if (phiblock == bb) continue; user = get_irn_n(phiblock, get_edge_src_pos(edge)); } if (value_dominates(b, user)) return 1; } return 0; } /*--------------------------------------------------------------------------- */ static const arch_env_t *arch_env; static ir_graph *irg; static be_lv_t *lv; static bool problem_found; static const ir_node **registers; static void check_output_constraints(const ir_node *node) { if (arch_get_irn_reg_class(node) == NULL) return; /* verify output register */ const arch_register_req_t *req = arch_get_irn_register_req(node); const arch_register_t *reg = arch_get_irn_register(node); if (reg == NULL) { ir_fprintf(stderr, "Verify warning: Node %+F in block %+F(%s) should have a register assigned\n", node, get_nodes_block(node), get_irg_dump_name(irg)); problem_found = true; } else if (!arch_reg_is_allocatable(req, reg)) { ir_fprintf(stderr, "Verify warning: Register %s assigned as output of %+F not allowed (register constraint) in block %+F(%s)\n", reg->name, node, get_nodes_block(node), get_irg_dump_name(irg)); problem_found = true; } } static void check_input_constraints(ir_node *node) { const arch_register_t *reg; int i, arity; /* verify input register */ arity = get_irn_arity(node); for (i = 0; i < arity; ++i) { const arch_register_req_t *req = arch_get_irn_register_req_in(node, i); ir_node *pred = get_irn_n(node, i); const arch_register_req_t *pred_req = arch_get_irn_register_req(pred); if (is_Bad(pred)) { ir_fprintf(stderr, "Verify warning: %+F in block %+F(%s) has Bad as input %d\n", node, get_nodes_block(node), get_irg_dump_name(irg), i); problem_found = 1; continue; } if (req->cls == NULL) continue; if (req->width > pred_req->width) { ir_fprintf(stderr, "Verify warning: %+F in block %+F(%s) register width of value at input %d too small\n", node, get_nodes_block(node), get_irg_dump_name(irg), i); problem_found = 1; } reg = arch_get_irn_register(pred); if (req->type & arch_register_req_type_aligned) { if (reg->index % req->width != 0) { ir_fprintf(stderr, "Verify warning: %+F in block %+F(%s) register allignment not fulfilled\n", node, get_nodes_block(node), get_irg_dump_name(irg), i); problem_found = 1; } } if (reg == NULL) { ir_fprintf(stderr, "Verify warning: Node %+F in block %+F(%s) should have a register assigned (%+F input constraint)\n", pred, get_nodes_block(pred), get_irg_dump_name(irg), node); problem_found = 1; continue; } else if (!arch_reg_is_allocatable(req, reg)) { ir_fprintf(stderr, "Verify warning: Register %s as input %d of %+F not allowed (register constraint) in block %+F(%s)\n", reg->name, i, node, get_nodes_block(node), get_irg_dump_name(irg)); problem_found = 1; } } /* phis should be NOPs at this point, which means all input regs * must be the same as the output reg */ if (is_Phi(node)) { reg = arch_get_irn_register(node); arity = get_irn_arity(node); for (i = 0; i < arity; ++i) { ir_node *pred = get_Phi_pred(node, i); const arch_register_t *pred_reg = arch_get_irn_register(pred); if (reg != pred_reg && !(pred_reg->type & arch_register_type_joker)) { const char *pred_name = pred_reg != NULL ? pred_reg->name : "(null)"; const char *reg_name = reg != NULL ? reg->name : "(null)"; ir_fprintf(stderr, "Verify warning: Input %d of %+F in block %+F(%s) uses register %s instead of %s\n", i, node, get_nodes_block(node), get_irg_dump_name(irg), pred_name, reg_name); problem_found = 1; } } } } static void value_used(const ir_node *block, const ir_node *node) { const arch_register_t *reg = arch_get_irn_register(node); const arch_register_req_t *req; unsigned i; unsigned idx; if (reg == NULL || reg->type & arch_register_type_virtual) return; req = arch_get_irn_register_req(node); assert(req->width > 0); idx = reg->global_index; for (i = 0; i < req->width; ++i) { const ir_node *reg_node = registers[idx+i]; if (reg_node != NULL && reg_node != node) { const arch_register_t *realreg = &arch_env->registers[idx+i]; ir_fprintf(stderr, "Verify warning: Register %s assigned more than once in block %+F(%s) (nodes %+F %+F)\n", realreg->name, block, get_irg_dump_name(irg), node, reg_node); problem_found = true; } registers[idx+i] = node; } } static void value_def(const ir_node *node) { const arch_register_t *reg = arch_get_irn_register(node); const arch_register_req_t *req; unsigned idx; unsigned i; if (reg == NULL || reg->type & arch_register_type_virtual) return; req = arch_get_irn_register_req(node); assert(req->width > 0); idx = reg->global_index; for (i = 0; i < req->width; ++i) { const ir_node *reg_node = registers[idx+i]; /* a little cheat, since its so hard to remove all outedges to dead code * in the backend. This particular case should never be a problem. */ if (reg_node == NULL && get_irn_n_edges(node) == 0) return; if (reg_node != node) { const arch_register_t *realreg = &arch_env->registers[idx+i]; ir_fprintf(stderr, "Verify warning: Node %+F not registered as value for Register %s (but %+F) in block %+F(%s)\n", node, realreg->name, reg_node, get_nodes_block(node), get_irg_dump_name(irg)); problem_found = true; } registers[idx+i] = NULL; } } static void verify_block_register_allocation(ir_node *block, void *data) { unsigned i; ir_node *node; unsigned n_regs; int idx; (void) data; assert(lv->nodes && "live sets must be computed"); n_regs = arch_env->n_registers; registers = ALLOCANZ(const ir_node*, n_regs); be_lv_foreach(lv, block, be_lv_state_end, idx) { ir_node *lv_node = be_lv_get_irn(lv, block, idx); value_used(block, lv_node); } sched_foreach_reverse(block, node) { int arity; if (get_irn_mode(node) == mode_T) { const ir_edge_t *edge; foreach_out_edge(node, edge) { ir_node *def = get_edge_src_irn(edge); value_def(def); check_output_constraints(def); } } else { value_def(node); check_output_constraints(node); } check_input_constraints(node); /* process uses. (Phi inputs are no real uses) */ if (!is_Phi(node)) { int in; arity = get_irn_arity(node); for (in = 0; in < arity; ++in) { ir_node *use = get_irn_n(node, in); value_used(block, use); } } } be_lv_foreach(lv, block, be_lv_state_in, idx) { ir_node *lv_node = be_lv_get_irn(lv, block, idx); value_def(lv_node); } /* set must be empty now */ for (i = 0; i < n_regs; ++i) { if (registers[i] == NULL) continue; ir_fprintf(stderr, "Verify warning: Node %+F not live-in and no def found in block %+F(%s)\n", registers[i], block, get_irg_dump_name(irg)); problem_found = true; } } bool be_verify_register_allocation(ir_graph *new_irg) { irg = new_irg; arch_env = be_get_irg_arch_env(irg); lv = be_liveness(irg); problem_found = false; be_liveness_assure_sets(lv); irg_block_walk_graph(irg, verify_block_register_allocation, NULL, NULL); be_liveness_free(lv); return !problem_found; }