/* +----------------------------------------------------------------------+ | Zend Engine, SSA - Static Single Assignment Form | +----------------------------------------------------------------------+ | Copyright (c) The PHP Group | +----------------------------------------------------------------------+ | This source file is subject to version 3.01 of the PHP license, | | that is bundled with this package in the file LICENSE, and is | | available through the world-wide-web at the following url: | | http://www.php.net/license/3_01.txt | | If you did not receive a copy of the PHP license and are unable to | | obtain it through the world-wide-web, please send a note to | | license@php.net so we can mail you a copy immediately. | +----------------------------------------------------------------------+ | Authors: Dmitry Stogov | | Nikita Popov | +----------------------------------------------------------------------+ */ #include "php.h" #include "zend_compile.h" #include "zend_dfg.h" #include "zend_ssa.h" #include "zend_dump.h" #include "zend_inference.h" #include "Optimizer/zend_optimizer_internal.h" static zend_bool dominates(const zend_basic_block *blocks, int a, int b) { while (blocks[b].level > blocks[a].level) { b = blocks[b].idom; } return a == b; } static zend_bool dominates_other_predecessors( const zend_cfg *cfg, const zend_basic_block *block, int check, int exclude) { int i; for (i = 0; i < block->predecessors_count; i++) { int predecessor = cfg->predecessors[block->predecessor_offset + i]; if (predecessor != exclude && !dominates(cfg->blocks, check, predecessor)) { return 0; } } return 1; } static zend_bool needs_pi(const zend_op_array *op_array, zend_dfg *dfg, zend_ssa *ssa, int from, int to, int var) /* {{{ */ { zend_basic_block *from_block, *to_block; int other_successor; if (!DFG_ISSET(dfg->in, dfg->size, to, var)) { /* Variable is not live, certainly won't benefit from pi */ return 0; } /* Make sure that both sucessors of the from block aren't the same. Pi nodes are associated * with predecessor blocks, so we can't distinguish which edge the pi belongs to. */ from_block = &ssa->cfg.blocks[from]; ZEND_ASSERT(from_block->successors_count == 2); if (from_block->successors[0] == from_block->successors[1]) { return 0; } to_block = &ssa->cfg.blocks[to]; if (to_block->predecessors_count == 1) { /* Always place pi if one predecessor (an if branch) */ return 1; } /* Check that the other successor of the from block does not dominate all other predecessors. * If it does, we'd probably end up annihilating a positive+negative pi assertion. */ other_successor = from_block->successors[0] == to ? from_block->successors[1] : from_block->successors[0]; return !dominates_other_predecessors(&ssa->cfg, to_block, other_successor, from); } /* }}} */ static zend_ssa_phi *add_pi( zend_arena **arena, const zend_op_array *op_array, zend_dfg *dfg, zend_ssa *ssa, int from, int to, int var) /* {{{ */ { zend_ssa_phi *phi; if (!needs_pi(op_array, dfg, ssa, from, to, var)) { return NULL; } phi = zend_arena_calloc(arena, 1, ZEND_MM_ALIGNED_SIZE(sizeof(zend_ssa_phi)) + ZEND_MM_ALIGNED_SIZE(sizeof(int) * ssa->cfg.blocks[to].predecessors_count) + sizeof(void*) * ssa->cfg.blocks[to].predecessors_count); phi->sources = (int*)(((char*)phi) + ZEND_MM_ALIGNED_SIZE(sizeof(zend_ssa_phi))); memset(phi->sources, 0xff, sizeof(int) * ssa->cfg.blocks[to].predecessors_count); phi->use_chains = (zend_ssa_phi**)(((char*)phi->sources) + ZEND_MM_ALIGNED_SIZE(sizeof(int) * ssa->cfg.blocks[to].predecessors_count)); phi->pi = from; phi->var = var; phi->ssa_var = -1; phi->next = ssa->blocks[to].phis; ssa->blocks[to].phis = phi; /* Block "to" now defines "var" via the pi statement, so add it to the "def" set. Note that * this is not entirely accurate, because the pi is actually placed along the edge from->to. * If there is a back-edge to "to" this may result in non-minimal SSA form. */ DFG_SET(dfg->def, dfg->size, to, var); /* If there are multiple predecessors in the target block, we need to place a phi there. * However this can (generally) not be expressed in terms of dominance frontiers, so place it * explicitly. dfg->use here really is dfg->phi, we're reusing the set. */ if (ssa->cfg.blocks[to].predecessors_count > 1) { DFG_SET(dfg->use, dfg->size, to, var); } return phi; } /* }}} */ static void pi_range( zend_ssa_phi *phi, int min_var, int max_var, zend_long min, zend_long max, char underflow, char overflow, char negative) /* {{{ */ { zend_ssa_range_constraint *constraint = &phi->constraint.range; constraint->min_var = min_var; constraint->max_var = max_var; constraint->min_ssa_var = -1; constraint->max_ssa_var = -1; constraint->range.min = min; constraint->range.max = max; constraint->range.underflow = underflow; constraint->range.overflow = overflow; constraint->negative = negative ? NEG_INIT : NEG_NONE; phi->has_range_constraint = 1; } /* }}} */ static inline void pi_range_equals(zend_ssa_phi *phi, int var, zend_long val) { pi_range(phi, var, var, val, val, 0, 0, 0); } static inline void pi_range_not_equals(zend_ssa_phi *phi, int var, zend_long val) { pi_range(phi, var, var, val, val, 0, 0, 1); } static inline void pi_range_min(zend_ssa_phi *phi, int var, zend_long val) { pi_range(phi, var, -1, val, ZEND_LONG_MAX, 0, 1, 0); } static inline void pi_range_max(zend_ssa_phi *phi, int var, zend_long val) { pi_range(phi, -1, var, ZEND_LONG_MIN, val, 1, 0, 0); } static void pi_type_mask(zend_ssa_phi *phi, uint32_t type_mask) { phi->has_range_constraint = 0; phi->constraint.type.ce = NULL; phi->constraint.type.type_mask = MAY_BE_REF|MAY_BE_RC1|MAY_BE_RCN; phi->constraint.type.type_mask |= type_mask; if (type_mask & MAY_BE_NULL) { phi->constraint.type.type_mask |= MAY_BE_UNDEF; } } static inline void pi_not_type_mask(zend_ssa_phi *phi, uint32_t type_mask) { uint32_t relevant = MAY_BE_ANY|MAY_BE_ARRAY_KEY_ANY|MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF; pi_type_mask(phi, ~type_mask & relevant); } static inline uint32_t mask_for_type_check(uint32_t type) { if (type & MAY_BE_ARRAY) { return MAY_BE_ARRAY|MAY_BE_ARRAY_KEY_ANY|MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF; } else { return type; } } /* We can interpret $a + 5 == 0 as $a = 0 - 5, i.e. shift the adjustment to the other operand. * This negated adjustment is what is written into the "adjustment" parameter. */ static int find_adjusted_tmp_var(const zend_op_array *op_array, uint32_t build_flags, zend_op *opline, uint32_t var_num, zend_long *adjustment) /* {{{ */ { zend_op *op = opline; zval *zv; while (op != op_array->opcodes) { op--; if (op->result_type != IS_TMP_VAR || op->result.var != var_num) { continue; } if (op->opcode == ZEND_POST_DEC) { if (op->op1_type == IS_CV) { *adjustment = -1; return EX_VAR_TO_NUM(op->op1.var); } } else if (op->opcode == ZEND_POST_INC) { if (op->op1_type == IS_CV) { *adjustment = 1; return EX_VAR_TO_NUM(op->op1.var); } } else if (op->opcode == ZEND_ADD) { if (op->op1_type == IS_CV && op->op2_type == IS_CONST) { zv = CRT_CONSTANT_EX(op_array, op, op->op2, (build_flags & ZEND_RT_CONSTANTS)); if (Z_TYPE_P(zv) == IS_LONG && Z_LVAL_P(zv) != ZEND_LONG_MIN) { *adjustment = -Z_LVAL_P(zv); return EX_VAR_TO_NUM(op->op1.var); } } else if (op->op2_type == IS_CV && op->op1_type == IS_CONST) { zv = CRT_CONSTANT_EX(op_array, op, op->op1, (build_flags & ZEND_RT_CONSTANTS)); if (Z_TYPE_P(zv) == IS_LONG && Z_LVAL_P(zv) != ZEND_LONG_MIN) { *adjustment = -Z_LVAL_P(zv); return EX_VAR_TO_NUM(op->op2.var); } } } else if (op->opcode == ZEND_SUB) { if (op->op1_type == IS_CV && op->op2_type == IS_CONST) { zv = CRT_CONSTANT_EX(op_array, op, op->op2, (build_flags & ZEND_RT_CONSTANTS)); if (Z_TYPE_P(zv) == IS_LONG) { *adjustment = Z_LVAL_P(zv); return EX_VAR_TO_NUM(op->op1.var); } } } break; } return -1; } /* }}} */ /* e-SSA construction: Pi placement (Pi is actually a Phi with single * source and constraint). * Order of Phis is importent, Pis must be placed before Phis */ static void place_essa_pis( zend_arena **arena, const zend_script *script, const zend_op_array *op_array, uint32_t build_flags, zend_ssa *ssa, zend_dfg *dfg) /* {{{ */ { zend_basic_block *blocks = ssa->cfg.blocks; int j, blocks_count = ssa->cfg.blocks_count; for (j = 0; j < blocks_count; j++) { zend_ssa_phi *pi; zend_op *opline = op_array->opcodes + blocks[j].start + blocks[j].len - 1; int bt; /* successor block number if a condition is true */ int bf; /* successor block number if a condition is false */ if ((blocks[j].flags & ZEND_BB_REACHABLE) == 0 || blocks[j].len == 0) { continue; } /* the last instruction of basic block is conditional branch, * based on comparison of CV(s) */ switch (opline->opcode) { case ZEND_JMPZ: case ZEND_JMPZNZ: bf = blocks[j].successors[0]; bt = blocks[j].successors[1]; break; case ZEND_JMPNZ: bt = blocks[j].successors[0]; bf = blocks[j].successors[1]; break; default: continue; } /* The following patterns all inspect the opline directly before the JMPZ opcode. * Make sure that it is part of the same block, otherwise it might not be a dominating * assignment. */ if (blocks[j].len == 1) { continue; } if (opline->op1_type == IS_TMP_VAR && ((opline-1)->opcode == ZEND_IS_EQUAL || (opline-1)->opcode == ZEND_IS_NOT_EQUAL || (opline-1)->opcode == ZEND_IS_SMALLER || (opline-1)->opcode == ZEND_IS_SMALLER_OR_EQUAL) && opline->op1.var == (opline-1)->result.var) { int var1 = -1; int var2 = -1; zend_long val1 = 0; zend_long val2 = 0; // long val = 0; if ((opline-1)->op1_type == IS_CV) { var1 = EX_VAR_TO_NUM((opline-1)->op1.var); } else if ((opline-1)->op1_type == IS_TMP_VAR) { var1 = find_adjusted_tmp_var( op_array, build_flags, opline, (opline-1)->op1.var, &val2); } if ((opline-1)->op2_type == IS_CV) { var2 = EX_VAR_TO_NUM((opline-1)->op2.var); } else if ((opline-1)->op2_type == IS_TMP_VAR) { var2 = find_adjusted_tmp_var( op_array, build_flags, opline, (opline-1)->op2.var, &val1); } if (var1 >= 0 && var2 >= 0) { if (!zend_sub_will_overflow(val1, val2) && !zend_sub_will_overflow(val2, val1)) { zend_long tmp = val1; val1 -= val2; val2 -= tmp; } else { var1 = -1; var2 = -1; } } else if (var1 >= 0 && var2 < 0) { zend_long add_val2 = 0; if ((opline-1)->op2_type == IS_CONST) { zval *zv = CRT_CONSTANT_EX(op_array, (opline-1), (opline-1)->op2, (build_flags & ZEND_RT_CONSTANTS)); if (Z_TYPE_P(zv) == IS_LONG) { add_val2 = Z_LVAL_P(zv); } else if (Z_TYPE_P(zv) == IS_FALSE) { add_val2 = 0; } else if (Z_TYPE_P(zv) == IS_TRUE) { add_val2 = 1; } else { var1 = -1; } } else { var1 = -1; } if (!zend_add_will_overflow(val2, add_val2)) { val2 += add_val2; } else { var1 = -1; } } else if (var1 < 0 && var2 >= 0) { zend_long add_val1 = 0; if ((opline-1)->op1_type == IS_CONST) { zval *zv = CRT_CONSTANT_EX(op_array, (opline-1), (opline-1)->op1, (build_flags & ZEND_RT_CONSTANTS)); if (Z_TYPE_P(zv) == IS_LONG) { add_val1 = Z_LVAL_P(CRT_CONSTANT_EX(op_array, (opline-1), (opline-1)->op1, (build_flags & ZEND_RT_CONSTANTS))); } else if (Z_TYPE_P(zv) == IS_FALSE) { add_val1 = 0; } else if (Z_TYPE_P(zv) == IS_TRUE) { add_val1 = 1; } else { var2 = -1; } } else { var2 = -1; } if (!zend_add_will_overflow(val1, add_val1)) { val1 += add_val1; } else { var2 = -1; } } if (var1 >= 0) { if ((opline-1)->opcode == ZEND_IS_EQUAL) { if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var1))) { pi_range_equals(pi, var2, val2); } if ((pi = add_pi(arena, op_array, dfg, ssa, j, bf, var1))) { pi_range_not_equals(pi, var2, val2); } } else if ((opline-1)->opcode == ZEND_IS_NOT_EQUAL) { if ((pi = add_pi(arena, op_array, dfg, ssa, j, bf, var1))) { pi_range_equals(pi, var2, val2); } if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var1))) { pi_range_not_equals(pi, var2, val2); } } else if ((opline-1)->opcode == ZEND_IS_SMALLER) { if (val2 > ZEND_LONG_MIN) { if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var1))) { pi_range_max(pi, var2, val2-1); } } if ((pi = add_pi(arena, op_array, dfg, ssa, j, bf, var1))) { pi_range_min(pi, var2, val2); } } else if ((opline-1)->opcode == ZEND_IS_SMALLER_OR_EQUAL) { if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var1))) { pi_range_max(pi, var2, val2); } if (val2 < ZEND_LONG_MAX) { if ((pi = add_pi(arena, op_array, dfg, ssa, j, bf, var1))) { pi_range_min(pi, var2, val2+1); } } } } if (var2 >= 0) { if((opline-1)->opcode == ZEND_IS_EQUAL) { if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var2))) { pi_range_equals(pi, var1, val1); } if ((pi = add_pi(arena, op_array, dfg, ssa, j, bf, var2))) { pi_range_not_equals(pi, var1, val1); } } else if ((opline-1)->opcode == ZEND_IS_NOT_EQUAL) { if ((pi = add_pi(arena, op_array, dfg, ssa, j, bf, var2))) { pi_range_equals(pi, var1, val1); } if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var2))) { pi_range_not_equals(pi, var1, val1); } } else if ((opline-1)->opcode == ZEND_IS_SMALLER) { if (val1 < ZEND_LONG_MAX) { if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var2))) { pi_range_min(pi, var1, val1+1); } } if ((pi = add_pi(arena, op_array, dfg, ssa, j, bf, var2))) { pi_range_max(pi, var1, val1); } } else if ((opline-1)->opcode == ZEND_IS_SMALLER_OR_EQUAL) { if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var2))) { pi_range_min(pi, var1, val1); } if (val1 > ZEND_LONG_MIN) { if ((pi = add_pi(arena, op_array, dfg, ssa, j, bf, var2))) { pi_range_max(pi, var1, val1-1); } } } } } else if (opline->op1_type == IS_TMP_VAR && ((opline-1)->opcode == ZEND_POST_INC || (opline-1)->opcode == ZEND_POST_DEC) && opline->op1.var == (opline-1)->result.var && (opline-1)->op1_type == IS_CV) { int var = EX_VAR_TO_NUM((opline-1)->op1.var); if ((opline-1)->opcode == ZEND_POST_DEC) { if ((pi = add_pi(arena, op_array, dfg, ssa, j, bf, var))) { pi_range_equals(pi, -1, -1); } if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var))) { pi_range_not_equals(pi, -1, -1); } } else if ((opline-1)->opcode == ZEND_POST_INC) { if ((pi = add_pi(arena, op_array, dfg, ssa, j, bf, var))) { pi_range_equals(pi, -1, 1); } if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var))) { pi_range_not_equals(pi, -1, 1); } } } else if (opline->op1_type == IS_VAR && ((opline-1)->opcode == ZEND_PRE_INC || (opline-1)->opcode == ZEND_PRE_DEC) && opline->op1.var == (opline-1)->result.var && (opline-1)->op1_type == IS_CV) { int var = EX_VAR_TO_NUM((opline-1)->op1.var); if ((pi = add_pi(arena, op_array, dfg, ssa, j, bf, var))) { pi_range_equals(pi, -1, 0); } /* speculative */ if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var))) { pi_range_not_equals(pi, -1, 0); } } else if (opline->op1_type == IS_TMP_VAR && (opline-1)->opcode == ZEND_TYPE_CHECK && opline->op1.var == (opline-1)->result.var && (opline-1)->op1_type == IS_CV) { int var = EX_VAR_TO_NUM((opline-1)->op1.var); uint32_t type = (opline-1)->extended_value; if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var))) { pi_type_mask(pi, mask_for_type_check(type)); } if (type != MAY_BE_RESOURCE) { /* is_resource() may return false for closed resources */ if ((pi = add_pi(arena, op_array, dfg, ssa, j, bf, var))) { pi_not_type_mask(pi, mask_for_type_check(type)); } } } else if (opline->op1_type == IS_TMP_VAR && ((opline-1)->opcode == ZEND_IS_IDENTICAL || (opline-1)->opcode == ZEND_IS_NOT_IDENTICAL) && opline->op1.var == (opline-1)->result.var) { int var; zval *val; uint32_t type_mask; if ((opline-1)->op1_type == IS_CV && (opline-1)->op2_type == IS_CONST) { var = EX_VAR_TO_NUM((opline-1)->op1.var); val = CRT_CONSTANT_EX(op_array, (opline-1), (opline-1)->op2, (build_flags & ZEND_RT_CONSTANTS)); } else if ((opline-1)->op1_type == IS_CONST && (opline-1)->op2_type == IS_CV) { var = EX_VAR_TO_NUM((opline-1)->op2.var); val = CRT_CONSTANT_EX(op_array, (opline-1), (opline-1)->op1, (build_flags & ZEND_RT_CONSTANTS)); } else { continue; } /* We're interested in === null/true/false comparisons here, because they eliminate * a type in the false-branch. Other === VAL comparisons are unlikely to be useful. */ if (Z_TYPE_P(val) != IS_NULL && Z_TYPE_P(val) != IS_TRUE && Z_TYPE_P(val) != IS_FALSE) { continue; } type_mask = _const_op_type(val); if ((opline-1)->opcode == ZEND_IS_IDENTICAL) { if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var))) { pi_type_mask(pi, type_mask); } if ((pi = add_pi(arena, op_array, dfg, ssa, j, bf, var))) { pi_not_type_mask(pi, type_mask); } } else { if ((pi = add_pi(arena, op_array, dfg, ssa, j, bf, var))) { pi_type_mask(pi, type_mask); } if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var))) { pi_not_type_mask(pi, type_mask); } } } else if (opline->op1_type == IS_TMP_VAR && (opline-1)->opcode == ZEND_INSTANCEOF && opline->op1.var == (opline-1)->result.var && (opline-1)->op1_type == IS_CV && (opline-1)->op2_type == IS_CONST) { int var = EX_VAR_TO_NUM((opline-1)->op1.var); zend_string *lcname = Z_STR_P(CRT_CONSTANT_EX(op_array, (opline-1), (opline-1)->op2, (build_flags & ZEND_RT_CONSTANTS)) + 1); zend_class_entry *ce = script ? zend_hash_find_ptr(&script->class_table, lcname) : NULL; if (!ce) { ce = zend_hash_find_ptr(CG(class_table), lcname); if (!ce || ce->type != ZEND_INTERNAL_CLASS) { continue; } } if ((pi = add_pi(arena, op_array, dfg, ssa, j, bt, var))) { pi_type_mask(pi, MAY_BE_OBJECT); pi->constraint.type.ce = ce; } } } } /* }}} */ static int zend_ssa_rename(const zend_op_array *op_array, uint32_t build_flags, zend_ssa *ssa, int *var, int n) /* {{{ */ { zend_basic_block *blocks = ssa->cfg.blocks; zend_ssa_block *ssa_blocks = ssa->blocks; zend_ssa_op *ssa_ops = ssa->ops; int ssa_vars_count = ssa->vars_count; int i, j; zend_op *opline, *end; int *tmp = NULL; ALLOCA_FLAG(use_heap = 0); // FIXME: Can we optimize this copying out in some cases? if (blocks[n].next_child >= 0) { tmp = do_alloca(sizeof(int) * (op_array->last_var + op_array->T), use_heap); memcpy(tmp, var, sizeof(int) * (op_array->last_var + op_array->T)); var = tmp; } if (ssa_blocks[n].phis) { zend_ssa_phi *phi = ssa_blocks[n].phis; do { if (phi->ssa_var < 0) { phi->ssa_var = ssa_vars_count; var[phi->var] = ssa_vars_count; ssa_vars_count++; } else { var[phi->var] = phi->ssa_var; } phi = phi->next; } while (phi); } opline = op_array->opcodes + blocks[n].start; end = opline + blocks[n].len; for (; opline < end; opline++) { uint32_t k = opline - op_array->opcodes; if (opline->opcode != ZEND_OP_DATA) { zend_op *next = opline + 1; if (next < end && next->opcode == ZEND_OP_DATA) { if (next->op1_type == IS_CV) { ssa_ops[k + 1].op1_use = var[EX_VAR_TO_NUM(next->op1.var)]; //USE_SSA_VAR(next->op1.var); } else if (next->op1_type & (IS_VAR|IS_TMP_VAR)) { ssa_ops[k + 1].op1_use = var[EX_VAR_TO_NUM(next->op1.var)]; //USE_SSA_VAR(op_array->last_var + next->op1.var); } if (next->op2_type == IS_CV) { ssa_ops[k + 1].op2_use = var[EX_VAR_TO_NUM(next->op2.var)]; //USE_SSA_VAR(next->op2.var); } else if (next->op2_type & (IS_VAR|IS_TMP_VAR)) { ssa_ops[k + 1].op2_use = var[EX_VAR_TO_NUM(next->op2.var)]; //USE_SSA_VAR(op_array->last_var + next->op2.var); } } if (opline->op1_type & (IS_CV|IS_VAR|IS_TMP_VAR)) { ssa_ops[k].op1_use = var[EX_VAR_TO_NUM(opline->op1.var)]; //USE_SSA_VAR(op_array->last_var + opline->op1.var) } if (opline->opcode == ZEND_FE_FETCH_R || opline->opcode == ZEND_FE_FETCH_RW) { if (opline->op2_type == IS_CV) { ssa_ops[k].op2_use = var[EX_VAR_TO_NUM(opline->op2.var)]; } ssa_ops[k].op2_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op2.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op2.var) } else if (opline->op2_type & (IS_CV|IS_VAR|IS_TMP_VAR)) { ssa_ops[k].op2_use = var[EX_VAR_TO_NUM(opline->op2.var)]; //USE_SSA_VAR(op_array->last_var + opline->op2.var) } switch (opline->opcode) { case ZEND_ASSIGN: if ((build_flags & ZEND_SSA_RC_INFERENCE) && opline->op2_type == IS_CV) { ssa_ops[k].op2_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op2.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op2.var) } if (opline->op1_type == IS_CV) { ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op1.var) } break; case ZEND_ASSIGN_REF: //TODO: ??? if (opline->op2_type == IS_CV) { ssa_ops[k].op2_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op2.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op2.var) } if (opline->op1_type == IS_CV) { ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op1.var) } break; case ZEND_BIND_GLOBAL: case ZEND_BIND_STATIC: if (opline->op1_type == IS_CV) { ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op1.var) } break; case ZEND_ASSIGN_DIM: case ZEND_ASSIGN_OBJ: if (opline->op1_type == IS_CV) { ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op1.var) } if ((build_flags & ZEND_SSA_RC_INFERENCE) && next->op1_type == IS_CV) { ssa_ops[k + 1].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(next->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(next->op1.var) } break; case ZEND_ASSIGN_OBJ_REF: if (opline->op1_type == IS_CV) { ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op1.var) } /* break missing intentionally */ case ZEND_ASSIGN_STATIC_PROP_REF: if (next->op1_type == IS_CV) { ssa_ops[k + 1].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(next->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(next->op1.var) } break; case ZEND_PRE_INC_OBJ: case ZEND_PRE_DEC_OBJ: case ZEND_POST_INC_OBJ: case ZEND_POST_DEC_OBJ: if (opline->op1_type == IS_CV) { ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op1.var) } break; case ZEND_ADD_ARRAY_ELEMENT: ssa_ops[k].result_use = var[EX_VAR_TO_NUM(opline->result.var)]; case ZEND_INIT_ARRAY: if (((build_flags & ZEND_SSA_RC_INFERENCE) || (opline->extended_value & ZEND_ARRAY_ELEMENT_REF)) && opline->op1_type == IS_CV) { ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline+->op1.var) } break; case ZEND_ADD_ARRAY_UNPACK: ssa_ops[k].result_use = var[EX_VAR_TO_NUM(opline->result.var)]; break; case ZEND_SEND_VAR: case ZEND_CAST: case ZEND_QM_ASSIGN: case ZEND_JMP_SET: case ZEND_COALESCE: if ((build_flags & ZEND_SSA_RC_INFERENCE) && opline->op1_type == IS_CV) { ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op1.var) } break; case ZEND_SEND_VAR_NO_REF: case ZEND_SEND_VAR_NO_REF_EX: case ZEND_SEND_VAR_EX: case ZEND_SEND_FUNC_ARG: case ZEND_SEND_REF: case ZEND_SEND_UNPACK: case ZEND_FE_RESET_RW: case ZEND_MAKE_REF: if (opline->op1_type == IS_CV) { ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op1.var) } break; case ZEND_FE_RESET_R: if ((build_flags & ZEND_SSA_RC_INFERENCE) && opline->op1_type == IS_CV) { ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op1.var) } break; case ZEND_ASSIGN_OP: case ZEND_ASSIGN_DIM_OP: case ZEND_ASSIGN_OBJ_OP: case ZEND_ASSIGN_STATIC_PROP_OP: case ZEND_PRE_INC: case ZEND_PRE_DEC: case ZEND_POST_INC: case ZEND_POST_DEC: if (opline->op1_type == IS_CV) { ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op1.var) } break; case ZEND_UNSET_CV: ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; break; case ZEND_UNSET_DIM: case ZEND_UNSET_OBJ: case ZEND_FETCH_DIM_W: case ZEND_FETCH_DIM_RW: case ZEND_FETCH_DIM_FUNC_ARG: case ZEND_FETCH_DIM_UNSET: case ZEND_FETCH_OBJ_W: case ZEND_FETCH_OBJ_RW: case ZEND_FETCH_OBJ_FUNC_ARG: case ZEND_FETCH_OBJ_UNSET: case ZEND_FETCH_LIST_W: if (opline->op1_type == IS_CV) { ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op1.var) } break; case ZEND_BIND_LEXICAL: if ((opline->extended_value & ZEND_BIND_REF) || (build_flags & ZEND_SSA_RC_INFERENCE)) { ssa_ops[k].op2_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op2.var)] = ssa_vars_count; ssa_vars_count++; } break; case ZEND_YIELD: if (opline->op1_type == IS_CV && ((op_array->fn_flags & ZEND_ACC_RETURN_REFERENCE) || (build_flags & ZEND_SSA_RC_INFERENCE))) { ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; } break; case ZEND_VERIFY_RETURN_TYPE: if (opline->op1_type & (IS_TMP_VAR|IS_VAR|IS_CV)) { ssa_ops[k].op1_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->op1.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->op1.var) } break; default: break; } if (opline->result_type == IS_CV) { if ((build_flags & ZEND_SSA_USE_CV_RESULTS) && opline->opcode != ZEND_RECV) { ssa_ops[k].result_use = var[EX_VAR_TO_NUM(opline->result.var)]; } ssa_ops[k].result_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->result.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(opline->result.var) } else if (opline->result_type & (IS_VAR|IS_TMP_VAR)) { ssa_ops[k].result_def = ssa_vars_count; var[EX_VAR_TO_NUM(opline->result.var)] = ssa_vars_count; ssa_vars_count++; //NEW_SSA_VAR(op_array->last_var + opline->result.var) } } } for (i = 0; i < blocks[n].successors_count; i++) { int succ = blocks[n].successors[i]; zend_ssa_phi *p; for (p = ssa_blocks[succ].phis; p; p = p->next) { if (p->pi == n) { /* e-SSA Pi */ if (p->has_range_constraint) { if (p->constraint.range.min_var >= 0) { p->constraint.range.min_ssa_var = var[p->constraint.range.min_var]; } if (p->constraint.range.max_var >= 0) { p->constraint.range.max_ssa_var = var[p->constraint.range.max_var]; } } for (j = 0; j < blocks[succ].predecessors_count; j++) { p->sources[j] = var[p->var]; } if (p->ssa_var < 0) { p->ssa_var = ssa_vars_count; ssa_vars_count++; } } else if (p->pi < 0) { /* Normal Phi */ for (j = 0; j < blocks[succ].predecessors_count; j++) if (ssa->cfg.predecessors[blocks[succ].predecessor_offset + j] == n) { break; } ZEND_ASSERT(j < blocks[succ].predecessors_count); p->sources[j] = var[p->var]; } } for (p = ssa_blocks[succ].phis; p && (p->pi >= 0); p = p->next) { if (p->pi == n) { zend_ssa_phi *q = p->next; while (q) { if (q->pi < 0 && q->var == p->var) { for (j = 0; j < blocks[succ].predecessors_count; j++) { if (ssa->cfg.predecessors[blocks[succ].predecessor_offset + j] == n) { break; } } ZEND_ASSERT(j < blocks[succ].predecessors_count); q->sources[j] = p->ssa_var; } q = q->next; } } } } ssa->vars_count = ssa_vars_count; j = blocks[n].children; while (j >= 0) { // FIXME: Tail call optimization? if (zend_ssa_rename(op_array, build_flags, ssa, var, j) != SUCCESS) return FAILURE; j = blocks[j].next_child; } if (tmp) { free_alloca(tmp, use_heap); } return SUCCESS; } /* }}} */ int zend_build_ssa(zend_arena **arena, const zend_script *script, const zend_op_array *op_array, uint32_t build_flags, zend_ssa *ssa) /* {{{ */ { zend_basic_block *blocks = ssa->cfg.blocks; zend_ssa_block *ssa_blocks; int blocks_count = ssa->cfg.blocks_count; uint32_t set_size; zend_bitset def, in, phi; int *var = NULL; int i, j, k, changed; zend_dfg dfg; ALLOCA_FLAG(dfg_use_heap) ALLOCA_FLAG(var_use_heap) if ((blocks_count * (op_array->last_var + op_array->T)) > 4 * 1024 * 1024) { /* Don't buld SSA for very big functions */ return FAILURE; } ssa->rt_constants = (build_flags & ZEND_RT_CONSTANTS); ssa_blocks = zend_arena_calloc(arena, blocks_count, sizeof(zend_ssa_block)); ssa->blocks = ssa_blocks; /* Compute Variable Liveness */ dfg.vars = op_array->last_var + op_array->T; dfg.size = set_size = zend_bitset_len(dfg.vars); dfg.tmp = do_alloca((set_size * sizeof(zend_ulong)) * (blocks_count * 4 + 1), dfg_use_heap); memset(dfg.tmp, 0, (set_size * sizeof(zend_ulong)) * (blocks_count * 4 + 1)); dfg.def = dfg.tmp + set_size; dfg.use = dfg.def + set_size * blocks_count; dfg.in = dfg.use + set_size * blocks_count; dfg.out = dfg.in + set_size * blocks_count; if (zend_build_dfg(op_array, &ssa->cfg, &dfg, build_flags) != SUCCESS) { free_alloca(dfg.tmp, dfg_use_heap); return FAILURE; } if (build_flags & ZEND_SSA_DEBUG_LIVENESS) { zend_dump_dfg(op_array, &ssa->cfg, &dfg); } def = dfg.def; in = dfg.in; /* Reuse the "use" set, as we no longer need it */ phi = dfg.use; zend_bitset_clear(phi, set_size * blocks_count); /* Place e-SSA pis. This will add additional "def" points, so it must * happen before def propagation. */ place_essa_pis(arena, script, op_array, build_flags, ssa, &dfg); /* SSA construction, Step 1: Propagate "def" sets in merge points */ do { changed = 0; for (j = 0; j < blocks_count; j++) { zend_bitset def_j = def + j * set_size, phi_j = phi + j * set_size; if ((blocks[j].flags & ZEND_BB_REACHABLE) == 0) { continue; } if (blocks[j].predecessors_count > 1) { if (blocks[j].flags & ZEND_BB_IRREDUCIBLE_LOOP) { /* Prevent any values from flowing into irreducible loops by replacing all incoming values with explicit phis. The register allocator depends on this property. */ zend_bitset_union(phi_j, in + (j * set_size), set_size); } else { for (k = 0; k < blocks[j].predecessors_count; k++) { i = ssa->cfg.predecessors[blocks[j].predecessor_offset + k]; while (i != -1 && i != blocks[j].idom) { zend_bitset_union_with_intersection( phi_j, phi_j, def + (i * set_size), in + (j * set_size), set_size); i = blocks[i].idom; } } } if (!zend_bitset_subset(phi_j, def_j, set_size)) { zend_bitset_union(def_j, phi_j, set_size); changed = 1; } } } } while (changed); /* SSA construction, Step 2: Phi placement based on Dominance Frontiers */ var = do_alloca(sizeof(int) * (op_array->last_var + op_array->T), var_use_heap); if (!var) { free_alloca(dfg.tmp, dfg_use_heap); return FAILURE; } for (j = 0; j < blocks_count; j++) { if ((blocks[j].flags & ZEND_BB_REACHABLE) == 0) { continue; } if (!zend_bitset_empty(phi + j * set_size, set_size)) { ZEND_BITSET_REVERSE_FOREACH(phi + j * set_size, set_size, i) { zend_ssa_phi *phi = zend_arena_calloc(arena, 1, ZEND_MM_ALIGNED_SIZE(sizeof(zend_ssa_phi)) + ZEND_MM_ALIGNED_SIZE(sizeof(int) * blocks[j].predecessors_count) + sizeof(void*) * blocks[j].predecessors_count); phi->sources = (int*)(((char*)phi) + ZEND_MM_ALIGNED_SIZE(sizeof(zend_ssa_phi))); memset(phi->sources, 0xff, sizeof(int) * blocks[j].predecessors_count); phi->use_chains = (zend_ssa_phi**)(((char*)phi->sources) + ZEND_MM_ALIGNED_SIZE(sizeof(int) * ssa->cfg.blocks[j].predecessors_count)); phi->pi = -1; phi->var = i; phi->ssa_var = -1; /* Place phis after pis */ { zend_ssa_phi **pp = &ssa_blocks[j].phis; while (*pp) { if ((*pp)->pi < 0) { break; } pp = &(*pp)->next; } phi->next = *pp; *pp = phi; } } ZEND_BITSET_FOREACH_END(); } } if (build_flags & ZEND_SSA_DEBUG_PHI_PLACEMENT) { zend_dump_phi_placement(op_array, ssa); } /* SSA construction, Step 3: Renaming */ ssa->ops = zend_arena_calloc(arena, op_array->last, sizeof(zend_ssa_op)); memset(ssa->ops, 0xff, op_array->last * sizeof(zend_ssa_op)); memset(var + op_array->last_var, 0xff, op_array->T * sizeof(int)); /* Create uninitialized SSA variables for each CV */ for (j = 0; j < op_array->last_var; j++) { var[j] = j; } ssa->vars_count = op_array->last_var; if (zend_ssa_rename(op_array, build_flags, ssa, var, 0) != SUCCESS) { free_alloca(var, var_use_heap); free_alloca(dfg.tmp, dfg_use_heap); return FAILURE; } free_alloca(var, var_use_heap); free_alloca(dfg.tmp, dfg_use_heap); return SUCCESS; } /* }}} */ int zend_ssa_compute_use_def_chains(zend_arena **arena, const zend_op_array *op_array, zend_ssa *ssa) /* {{{ */ { zend_ssa_var *ssa_vars; int i; if (!ssa->vars) { ssa->vars = zend_arena_calloc(arena, ssa->vars_count, sizeof(zend_ssa_var)); } ssa_vars = ssa->vars; for (i = 0; i < op_array->last_var; i++) { ssa_vars[i].var = i; ssa_vars[i].scc = -1; ssa_vars[i].definition = -1; ssa_vars[i].use_chain = -1; } for (i = op_array->last_var; i < ssa->vars_count; i++) { ssa_vars[i].var = -1; ssa_vars[i].scc = -1; ssa_vars[i].definition = -1; ssa_vars[i].use_chain = -1; } for (i = op_array->last - 1; i >= 0; i--) { zend_ssa_op *op = ssa->ops + i; if (op->op1_use >= 0) { op->op1_use_chain = ssa_vars[op->op1_use].use_chain; ssa_vars[op->op1_use].use_chain = i; } if (op->op2_use >= 0 && op->op2_use != op->op1_use) { op->op2_use_chain = ssa_vars[op->op2_use].use_chain; ssa_vars[op->op2_use].use_chain = i; } if (op->result_use >= 0 && op->result_use != op->op1_use && op->result_use != op->op2_use) { op->res_use_chain = ssa_vars[op->result_use].use_chain; ssa_vars[op->result_use].use_chain = i; } if (op->op1_def >= 0) { ssa_vars[op->op1_def].var = EX_VAR_TO_NUM(op_array->opcodes[i].op1.var); ssa_vars[op->op1_def].definition = i; } if (op->op2_def >= 0) { ssa_vars[op->op2_def].var = EX_VAR_TO_NUM(op_array->opcodes[i].op2.var); ssa_vars[op->op2_def].definition = i; } if (op->result_def >= 0) { ssa_vars[op->result_def].var = EX_VAR_TO_NUM(op_array->opcodes[i].result.var); ssa_vars[op->result_def].definition = i; } } for (i = 0; i < ssa->cfg.blocks_count; i++) { zend_ssa_phi *phi = ssa->blocks[i].phis; while (phi) { phi->block = i; ssa_vars[phi->ssa_var].var = phi->var; ssa_vars[phi->ssa_var].definition_phi = phi; if (phi->pi >= 0) { zend_ssa_phi *p; ZEND_ASSERT(phi->sources[0] >= 0); p = ssa_vars[phi->sources[0]].phi_use_chain; while (p && p != phi) { p = zend_ssa_next_use_phi(ssa, phi->sources[0], p); } if (!p) { phi->use_chains[0] = ssa_vars[phi->sources[0]].phi_use_chain; ssa_vars[phi->sources[0]].phi_use_chain = phi; } if (phi->has_range_constraint) { /* min and max variables can't be used together */ zend_ssa_range_constraint *constraint = &phi->constraint.range; if (constraint->min_ssa_var >= 0) { phi->sym_use_chain = ssa_vars[constraint->min_ssa_var].sym_use_chain; ssa_vars[constraint->min_ssa_var].sym_use_chain = phi; } else if (constraint->max_ssa_var >= 0) { phi->sym_use_chain = ssa_vars[constraint->max_ssa_var].sym_use_chain; ssa_vars[constraint->max_ssa_var].sym_use_chain = phi; } } } else { int j; for (j = 0; j < ssa->cfg.blocks[i].predecessors_count; j++) { zend_ssa_phi *p; ZEND_ASSERT(phi->sources[j] >= 0); p = ssa_vars[phi->sources[j]].phi_use_chain; while (p && p != phi) { p = zend_ssa_next_use_phi(ssa, phi->sources[j], p); } if (!p) { phi->use_chains[j] = ssa_vars[phi->sources[j]].phi_use_chain; ssa_vars[phi->sources[j]].phi_use_chain = phi; } } } phi = phi->next; } } /* Mark indirectly accessed variables */ for (i = 0; i < op_array->last_var; i++) { if ((ssa->cfg.flags & ZEND_FUNC_INDIRECT_VAR_ACCESS)) { ssa_vars[i].alias = SYMTABLE_ALIAS; } else if (zend_string_equals_literal(op_array->vars[i], "php_errormsg")) { ssa_vars[i].alias = PHP_ERRORMSG_ALIAS; } else if (zend_string_equals_literal(op_array->vars[i], "http_response_header")) { ssa_vars[i].alias = HTTP_RESPONSE_HEADER_ALIAS; } } for (i = op_array->last_var; i < ssa->vars_count; i++) { if (ssa_vars[i].var < op_array->last_var) { ssa_vars[i].alias = ssa_vars[ssa_vars[i].var].alias; } } return SUCCESS; } /* }}} */ int zend_ssa_unlink_use_chain(zend_ssa *ssa, int op, int var) /* {{{ */ { if (ssa->vars[var].use_chain == op) { ssa->vars[var].use_chain = zend_ssa_next_use(ssa->ops, var, op); return 1; } else { int use = ssa->vars[var].use_chain; while (use >= 0) { if (ssa->ops[use].result_use == var) { if (ssa->ops[use].res_use_chain == op) { ssa->ops[use].res_use_chain = zend_ssa_next_use(ssa->ops, var, op); return 1; } else { use = ssa->ops[use].res_use_chain; } } else if (ssa->ops[use].op1_use == var) { if (ssa->ops[use].op1_use_chain == op) { ssa->ops[use].op1_use_chain = zend_ssa_next_use(ssa->ops, var, op); return 1; } else { use = ssa->ops[use].op1_use_chain; } } else if (ssa->ops[use].op2_use == var) { if (ssa->ops[use].op2_use_chain == op) { ssa->ops[use].op2_use_chain = zend_ssa_next_use(ssa->ops, var, op); return 1; } else { use = ssa->ops[use].op2_use_chain; } } else { break; } } /* something wrong */ ZEND_ASSERT(0); return 0; } } /* }}} */ void zend_ssa_remove_instr(zend_ssa *ssa, zend_op *opline, zend_ssa_op *ssa_op) /* {{{ */ { if (ssa_op->result_use >= 0) { zend_ssa_unlink_use_chain(ssa, ssa_op - ssa->ops, ssa_op->result_use); ssa_op->result_use = -1; ssa_op->res_use_chain = -1; } if (ssa_op->op1_use >= 0) { if (ssa_op->op1_use != ssa_op->op2_use) { zend_ssa_unlink_use_chain(ssa, ssa_op - ssa->ops, ssa_op->op1_use); } else { ssa_op->op2_use_chain = ssa_op->op1_use_chain; } ssa_op->op1_use = -1; ssa_op->op1_use_chain = -1; } if (ssa_op->op2_use >= 0) { zend_ssa_unlink_use_chain(ssa, ssa_op - ssa->ops, ssa_op->op2_use); ssa_op->op2_use = -1; ssa_op->op2_use_chain = -1; } /* We let the caller make sure that all defs are gone */ ZEND_ASSERT(ssa_op->result_def == -1); ZEND_ASSERT(ssa_op->op1_def == -1); ZEND_ASSERT(ssa_op->op2_def == -1); MAKE_NOP(opline); } /* }}} */ static inline zend_ssa_phi **zend_ssa_next_use_phi_ptr(zend_ssa *ssa, int var, zend_ssa_phi *p) /* {{{ */ { if (p->pi >= 0) { return &p->use_chains[0]; } else { int j; for (j = 0; j < ssa->cfg.blocks[p->block].predecessors_count; j++) { if (p->sources[j] == var) { return &p->use_chains[j]; } } } ZEND_ASSERT(0); return NULL; } /* }}} */ /* May be called even if source is not used in the phi (useful when removing uses in a phi * with multiple identical operands) */ static inline void zend_ssa_remove_use_of_phi_source(zend_ssa *ssa, zend_ssa_phi *phi, int source, zend_ssa_phi *next_use_phi) /* {{{ */ { zend_ssa_phi **cur = &ssa->vars[source].phi_use_chain; while (*cur && *cur != phi) { cur = zend_ssa_next_use_phi_ptr(ssa, source, *cur); } if (*cur) { *cur = next_use_phi; } } /* }}} */ static void zend_ssa_remove_uses_of_phi_sources(zend_ssa *ssa, zend_ssa_phi *phi) /* {{{ */ { int source; FOREACH_PHI_SOURCE(phi, source) { zend_ssa_remove_use_of_phi_source(ssa, phi, source, zend_ssa_next_use_phi(ssa, source, phi)); } FOREACH_PHI_SOURCE_END(); } /* }}} */ static void zend_ssa_remove_phi_from_block(zend_ssa *ssa, zend_ssa_phi *phi) /* {{{ */ { zend_ssa_block *block = &ssa->blocks[phi->block]; zend_ssa_phi **cur = &block->phis; while (*cur != phi) { ZEND_ASSERT(*cur != NULL); cur = &(*cur)->next; } *cur = (*cur)->next; } /* }}} */ static inline void zend_ssa_remove_defs_of_instr(zend_ssa *ssa, zend_ssa_op *ssa_op) /* {{{ */ { if (ssa_op->op1_def >= 0) { zend_ssa_remove_uses_of_var(ssa, ssa_op->op1_def); zend_ssa_remove_op1_def(ssa, ssa_op); } if (ssa_op->op2_def >= 0) { zend_ssa_remove_uses_of_var(ssa, ssa_op->op2_def); zend_ssa_remove_op2_def(ssa, ssa_op); } if (ssa_op->result_def >= 0) { zend_ssa_remove_uses_of_var(ssa, ssa_op->result_def); zend_ssa_remove_result_def(ssa, ssa_op); } } /* }}} */ static inline void zend_ssa_remove_phi_source(zend_ssa *ssa, zend_ssa_phi *phi, int pred_offset, int predecessors_count) /* {{{ */ { int j, var_num = phi->sources[pred_offset]; zend_ssa_phi *next_phi = phi->use_chains[pred_offset]; predecessors_count--; if (pred_offset < predecessors_count) { memmove(phi->sources + pred_offset, phi->sources + pred_offset + 1, (predecessors_count - pred_offset) * sizeof(uint32_t)); memmove(phi->use_chains + pred_offset, phi->use_chains + pred_offset + 1, (predecessors_count - pred_offset) * sizeof(zend_ssa_phi*)); } /* Check if they same var is used in a different phi operand as well, in this case we don't * need to adjust the use chain (but may have to move the next pointer). */ for (j = 0; j < predecessors_count; j++) { if (phi->sources[j] == var_num) { if (j < pred_offset) { ZEND_ASSERT(next_phi == NULL); } else if (j >= pred_offset) { phi->use_chains[j] = next_phi; } return; } } /* Variable only used in one operand, remove the phi from the use chain. */ zend_ssa_remove_use_of_phi_source(ssa, phi, var_num, next_phi); } /* }}} */ void zend_ssa_remove_phi(zend_ssa *ssa, zend_ssa_phi *phi) /* {{{ */ { ZEND_ASSERT(phi->ssa_var >= 0); ZEND_ASSERT(ssa->vars[phi->ssa_var].use_chain < 0 && ssa->vars[phi->ssa_var].phi_use_chain == NULL); zend_ssa_remove_uses_of_phi_sources(ssa, phi); zend_ssa_remove_phi_from_block(ssa, phi); ssa->vars[phi->ssa_var].definition_phi = NULL; phi->ssa_var = -1; } /* }}} */ void zend_ssa_remove_uses_of_var(zend_ssa *ssa, int var_num) /* {{{ */ { zend_ssa_var *var = &ssa->vars[var_num]; zend_ssa_phi *phi; int use; FOREACH_PHI_USE(var, phi) { int i, end = NUM_PHI_SOURCES(phi); for (i = 0; i < end; i++) { if (phi->sources[i] == var_num) { phi->use_chains[i] = NULL; } } } FOREACH_PHI_USE_END(); var->phi_use_chain = NULL; FOREACH_USE(var, use) { zend_ssa_op *ssa_op = &ssa->ops[use]; if (ssa_op->op1_use == var_num) { ssa_op->op1_use = -1; ssa_op->op1_use_chain = -1; } if (ssa_op->op2_use == var_num) { ssa_op->op2_use = -1; ssa_op->op2_use_chain = -1; } if (ssa_op->result_use == var_num) { ssa_op->result_use = -1; ssa_op->res_use_chain = -1; } } FOREACH_USE_END(); var->use_chain = -1; } /* }}} */ void zend_ssa_remove_predecessor(zend_ssa *ssa, int from, int to) /* {{{ */ { zend_basic_block *next_block = &ssa->cfg.blocks[to]; zend_ssa_block *next_ssa_block = &ssa->blocks[to]; zend_ssa_phi *phi; int j; /* Find at which predecessor offset this block is referenced */ int pred_offset = -1; int *predecessors = &ssa->cfg.predecessors[next_block->predecessor_offset]; for (j = 0; j < next_block->predecessors_count; j++) { if (predecessors[j] == from) { pred_offset = j; break; } } /* If there are duplicate successors, the predecessors may have been removed in * a previous iteration already. */ if (pred_offset == -1) { return; } /* For phis in successor blocks, remove the operands associated with this block */ for (phi = next_ssa_block->phis; phi; phi = phi->next) { if (phi->pi >= 0) { if (phi->pi == from) { zend_ssa_rename_var_uses(ssa, phi->ssa_var, phi->sources[0], /* update_types */ 0); zend_ssa_remove_phi(ssa, phi); } } else { ZEND_ASSERT(phi->sources[pred_offset] >= 0); zend_ssa_remove_phi_source(ssa, phi, pred_offset, next_block->predecessors_count); } } /* Remove this predecessor */ next_block->predecessors_count--; if (pred_offset < next_block->predecessors_count) { predecessors = &ssa->cfg.predecessors[next_block->predecessor_offset + pred_offset]; memmove(predecessors, predecessors + 1, (next_block->predecessors_count - pred_offset) * sizeof(uint32_t)); } } /* }}} */ void zend_ssa_remove_block(zend_op_array *op_array, zend_ssa *ssa, int i) /* {{{ */ { zend_basic_block *block = &ssa->cfg.blocks[i]; zend_ssa_block *ssa_block = &ssa->blocks[i]; int *predecessors; zend_ssa_phi *phi; int j, s; block->flags &= ~ZEND_BB_REACHABLE; /* Removes phis in this block */ for (phi = ssa_block->phis; phi; phi = phi->next) { zend_ssa_remove_uses_of_var(ssa, phi->ssa_var); zend_ssa_remove_phi(ssa, phi); } /* Remove instructions in this block */ for (j = block->start; j < block->start + block->len; j++) { if (op_array->opcodes[j].opcode == ZEND_NOP) { continue; } zend_ssa_remove_defs_of_instr(ssa, &ssa->ops[j]); zend_ssa_remove_instr(ssa, &op_array->opcodes[j], &ssa->ops[j]); } for (s = 0; s < block->successors_count; s++) { zend_ssa_remove_predecessor(ssa, i, block->successors[s]); } /* Remove successors of predecessors */ predecessors = &ssa->cfg.predecessors[block->predecessor_offset]; for (j = 0; j < block->predecessors_count; j++) { if (predecessors[j] >= 0) { zend_basic_block *prev_block = &ssa->cfg.blocks[predecessors[j]]; for (s = 0; s < prev_block->successors_count; s++) { if (prev_block->successors[s] == i) { memmove(prev_block->successors + s, prev_block->successors + s + 1, sizeof(int) * (prev_block->successors_count - s - 1)); prev_block->successors_count--; s--; } } } } block->successors_count = 0; block->predecessors_count = 0; /* Remove from dominators tree */ if (block->idom >= 0) { j = ssa->cfg.blocks[block->idom].children; if (j == i) { ssa->cfg.blocks[block->idom].children = block->next_child; } else if (j >= 0) { while (ssa->cfg.blocks[j].next_child >= 0) { if (ssa->cfg.blocks[j].next_child == i) { ssa->cfg.blocks[j].next_child = block->next_child; break; } j = ssa->cfg.blocks[j].next_child; } } } block->idom = -1; block->level = -1; block->children = -1; block->next_child = -1; } /* }}} */ static void propagate_phi_type_widening(zend_ssa *ssa, int var) /* {{{ */ { zend_ssa_phi *phi; FOREACH_PHI_USE(&ssa->vars[var], phi) { if (ssa->var_info[var].type & ~ssa->var_info[phi->ssa_var].type) { ssa->var_info[phi->ssa_var].type |= ssa->var_info[var].type; propagate_phi_type_widening(ssa, phi->ssa_var); } } FOREACH_PHI_USE_END(); } /* }}} */ void zend_ssa_rename_var_uses(zend_ssa *ssa, int old, int new, zend_bool update_types) /* {{{ */ { zend_ssa_var *old_var = &ssa->vars[old]; zend_ssa_var *new_var = &ssa->vars[new]; int use; zend_ssa_phi *phi; ZEND_ASSERT(old >= 0 && new >= 0); ZEND_ASSERT(old != new); /* Only a no_val is both variables are */ new_var->no_val &= old_var->no_val; /* Update ssa_op use chains */ FOREACH_USE(old_var, use) { zend_ssa_op *ssa_op = &ssa->ops[use]; /* If the op already uses the new var, don't add the op to the use * list again. Instead move the use_chain to the correct operand. */ zend_bool add_to_use_chain = 1; if (ssa_op->result_use == new) { add_to_use_chain = 0; } else if (ssa_op->op1_use == new) { if (ssa_op->result_use == old) { ssa_op->res_use_chain = ssa_op->op1_use_chain; ssa_op->op1_use_chain = -1; } add_to_use_chain = 0; } else if (ssa_op->op2_use == new) { if (ssa_op->result_use == old) { ssa_op->res_use_chain = ssa_op->op2_use_chain; ssa_op->op2_use_chain = -1; } else if (ssa_op->op1_use == old) { ssa_op->op1_use_chain = ssa_op->op2_use_chain; ssa_op->op2_use_chain = -1; } add_to_use_chain = 0; } /* Perform the actual renaming */ if (ssa_op->result_use == old) { ssa_op->result_use = new; } if (ssa_op->op1_use == old) { ssa_op->op1_use = new; } if (ssa_op->op2_use == old) { ssa_op->op2_use = new; } /* Add op to use chain of new var (if it isn't already). We use the * first use chain of (result, op1, op2) that has the new variable. */ if (add_to_use_chain) { if (ssa_op->result_use == new) { ssa_op->res_use_chain = new_var->use_chain; new_var->use_chain = use; } else if (ssa_op->op1_use == new) { ssa_op->op1_use_chain = new_var->use_chain; new_var->use_chain = use; } else { ZEND_ASSERT(ssa_op->op2_use == new); ssa_op->op2_use_chain = new_var->use_chain; new_var->use_chain = use; } } } FOREACH_USE_END(); old_var->use_chain = -1; /* Update phi use chains */ FOREACH_PHI_USE(old_var, phi) { int j; zend_bool after_first_new_source = 0; /* If the phi already uses the new var, find its use chain, as we may * need to move it to a different source operand. */ zend_ssa_phi **existing_use_chain_ptr = NULL; for (j = 0; j < ssa->cfg.blocks[phi->block].predecessors_count; j++) { if (phi->sources[j] == new) { existing_use_chain_ptr = &phi->use_chains[j]; break; } } for (j = 0; j < ssa->cfg.blocks[phi->block].predecessors_count; j++) { if (phi->sources[j] == new) { after_first_new_source = 1; } else if (phi->sources[j] == old) { phi->sources[j] = new; /* Either move existing use chain to this source, or add the phi * to the phi use chain of the new variables. Do this only once. */ if (!after_first_new_source) { if (existing_use_chain_ptr) { phi->use_chains[j] = *existing_use_chain_ptr; *existing_use_chain_ptr = NULL; } else { phi->use_chains[j] = new_var->phi_use_chain; new_var->phi_use_chain = phi; } after_first_new_source = 1; } else { phi->use_chains[j] = NULL; } } } /* Make sure phi result types are not incorrectly narrow after renaming. * This should not normally happen, but can occur if we DCE an assignment * or unset and there is an improper phi-indirected use lateron. */ // TODO Alternatively we could rerun type-inference after DCE if (update_types && (ssa->var_info[new].type & ~ssa->var_info[phi->ssa_var].type)) { ssa->var_info[phi->ssa_var].type |= ssa->var_info[new].type; propagate_phi_type_widening(ssa, phi->ssa_var); } } FOREACH_PHI_USE_END(); old_var->phi_use_chain = NULL; } /* }}} */