php-src/Zend/Optimizer/zend_inference.c
George Peter Banyard d8696f9216
[RFC] Path to Saner Increment/Decrement operators (#10358)
* Add behavioural tests for incdec operators

* Add support to ++/-- for objects castable to _IS_NUMBER

* Add str_increment() function

* Add str_decrement() function

RFC: https://wiki.php.net/rfc/saner-inc-dec-operators

Co-authored-by: Ilija Tovilo <ilija.tovilo@me.com>
Co-authored-by: Arnaud Le Blanc <arnaud.lb@gmail.com>
2023-07-17 15:51:24 +01:00

4912 lines
149 KiB
C

/*
+----------------------------------------------------------------------+
| Zend Engine, e-SSA based Type & Range Inference |
+----------------------------------------------------------------------+
| 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: |
| https://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 <dmitry@php.net> |
+----------------------------------------------------------------------+
*/
#include "zend_compile.h"
#include "zend_generators.h"
#include "zend_inference.h"
#include "zend_func_info.h"
#include "zend_call_graph.h"
#include "zend_closures.h"
#include "zend_worklist.h"
#include "zend_optimizer_internal.h"
/* The used range inference algorithm is described in:
* V. Campos, R. Rodrigues, I. de Assis Costa and F. Pereira.
* "Speed and Precision in Range Analysis", SBLP'12.
*
* There are a couple degrees of freedom, we use:
* * Propagation on SCCs.
* * e-SSA for live range splitting.
* * Only intra-procedural inference.
* * Widening with warmup passes, but without jump sets.
*/
/* Whether to handle symbolic range constraints */
#define SYM_RANGE
/* Whether to handle negative range constraints */
/* Negative range inference is buggy, so disabled for now */
#undef NEG_RANGE
/* Number of warmup passes to use prior to widening */
#define RANGE_WARMUP_PASSES 16
/* Logging for range inference in general */
#if 0
#define LOG_SSA_RANGE(...) fprintf(stderr, __VA_ARGS__)
#else
#define LOG_SSA_RANGE(...)
#endif
/* Logging for negative range constraints */
#if 0
#define LOG_NEG_RANGE(...) fprintf(stderr, __VA_ARGS__)
#else
#define LOG_NEG_RANGE(...)
#endif
/* Pop elements in unspecified order from worklist until it is empty */
#define WHILE_WORKLIST(worklist, len, i) do { \
bool _done = 0; \
while (!_done) { \
_done = 1; \
ZEND_BITSET_FOREACH(worklist, len, i) { \
zend_bitset_excl(worklist, i); \
_done = 0;
#define WHILE_WORKLIST_END() \
} ZEND_BITSET_FOREACH_END(); \
} \
} while (0)
#define CHECK_SCC_VAR(var2) \
do { \
if (!ssa->vars[var2].no_val) { \
if (dfs[var2] < 0) { \
zend_ssa_check_scc_var(op_array, ssa, var2, index, dfs, root, stack); \
} \
if (ssa->vars[var2].scc < 0 && dfs[root[var]] >= dfs[root[var2]]) { \
root[var] = root[var2]; \
} \
} \
} while (0)
#define CHECK_SCC_ENTRY(var2) \
do { \
if (ssa->vars[var2].scc != ssa->vars[var].scc) { \
ssa->vars[var2].scc_entry = 1; \
} \
} while (0)
#define ADD_SCC_VAR(_var) \
do { \
if (ssa->vars[_var].scc == scc && \
!(ssa->var_info[_var].type & MAY_BE_REF)) { \
zend_bitset_incl(worklist, _var); \
} \
} while (0)
#define ADD_SCC_VAR_1(_var) \
do { \
if (ssa->vars[_var].scc == scc && \
!(ssa->var_info[_var].type & MAY_BE_REF) && \
!zend_bitset_in(visited, _var)) { \
zend_bitset_incl(worklist, _var); \
} \
} while (0)
#define FOR_EACH_DEFINED_VAR(line, MACRO) \
do { \
if (ssa->ops[line].op1_def >= 0) { \
MACRO(ssa->ops[line].op1_def); \
} \
if (ssa->ops[line].op2_def >= 0) { \
MACRO(ssa->ops[line].op2_def); \
} \
if (ssa->ops[line].result_def >= 0) { \
MACRO(ssa->ops[line].result_def); \
} \
if (op_array->opcodes[line].opcode == ZEND_OP_DATA) { \
if (ssa->ops[line-1].op1_def >= 0) { \
MACRO(ssa->ops[line-1].op1_def); \
} \
if (ssa->ops[line-1].op2_def >= 0) { \
MACRO(ssa->ops[line-1].op2_def); \
} \
if (ssa->ops[line-1].result_def >= 0) { \
MACRO(ssa->ops[line-1].result_def); \
} \
} else if ((uint32_t)line+1 < op_array->last && \
op_array->opcodes[line+1].opcode == ZEND_OP_DATA) { \
if (ssa->ops[line+1].op1_def >= 0) { \
MACRO(ssa->ops[line+1].op1_def); \
} \
if (ssa->ops[line+1].op2_def >= 0) { \
MACRO(ssa->ops[line+1].op2_def); \
} \
if (ssa->ops[line+1].result_def >= 0) { \
MACRO(ssa->ops[line+1].result_def); \
} \
} \
} while (0)
#define FOR_EACH_VAR_USAGE(_var, MACRO) \
do { \
zend_ssa_phi *p = ssa->vars[_var].phi_use_chain; \
int use = ssa->vars[_var].use_chain; \
while (use >= 0) { \
FOR_EACH_DEFINED_VAR(use, MACRO); \
use = zend_ssa_next_use(ssa->ops, _var, use); \
} \
p = ssa->vars[_var].phi_use_chain; \
while (p) { \
MACRO(p->ssa_var); \
p = zend_ssa_next_use_phi(ssa, _var, p); \
} \
} while (0)
static inline bool add_will_overflow(zend_long a, zend_long b) {
return (b > 0 && a > ZEND_LONG_MAX - b)
|| (b < 0 && a < ZEND_LONG_MIN - b);
}
#if 0
static inline bool sub_will_overflow(zend_long a, zend_long b) {
return (b > 0 && a < ZEND_LONG_MIN + b)
|| (b < 0 && a > ZEND_LONG_MAX + b);
}
#endif
static void zend_ssa_check_scc_var(const zend_op_array *op_array, zend_ssa *ssa, int var, int *index, int *dfs, int *root, zend_worklist_stack *stack) /* {{{ */
{
#ifdef SYM_RANGE
zend_ssa_phi *p;
#endif
dfs[var] = *index;
(*index)++;
root[var] = var;
FOR_EACH_VAR_USAGE(var, CHECK_SCC_VAR);
#ifdef SYM_RANGE
/* Process symbolic control-flow constraints */
p = ssa->vars[var].sym_use_chain;
while (p) {
CHECK_SCC_VAR(p->ssa_var);
p = p->sym_use_chain;
}
#endif
if (root[var] == var) {
ssa->vars[var].scc = ssa->sccs;
while (stack->len > 0) {
int var2 = zend_worklist_stack_peek(stack);
if (dfs[var2] <= dfs[var]) {
break;
}
zend_worklist_stack_pop(stack);
ssa->vars[var2].scc = ssa->sccs;
}
ssa->sccs++;
} else {
zend_worklist_stack_push(stack, var);
}
}
/* }}} */
ZEND_API void zend_ssa_find_sccs(const zend_op_array *op_array, zend_ssa *ssa) /* {{{ */
{
int index = 0, *dfs, *root;
zend_worklist_stack stack;
int j;
ALLOCA_FLAG(dfs_use_heap)
ALLOCA_FLAG(root_use_heap)
ALLOCA_FLAG(stack_use_heap)
dfs = do_alloca(sizeof(int) * ssa->vars_count, dfs_use_heap);
memset(dfs, -1, sizeof(int) * ssa->vars_count);
root = do_alloca(sizeof(int) * ssa->vars_count, root_use_heap);
ZEND_WORKLIST_STACK_ALLOCA(&stack, ssa->vars_count, stack_use_heap);
/* Find SCCs using Tarjan's algorithm. */
for (j = 0; j < ssa->vars_count; j++) {
if (!ssa->vars[j].no_val && dfs[j] < 0) {
zend_ssa_check_scc_var(op_array, ssa, j, &index, dfs, root, &stack);
}
}
/* Revert SCC order. This results in a topological order. */
for (j = 0; j < ssa->vars_count; j++) {
if (ssa->vars[j].scc >= 0) {
ssa->vars[j].scc = ssa->sccs - (ssa->vars[j].scc + 1);
}
}
for (j = 0; j < ssa->vars_count; j++) {
if (ssa->vars[j].scc >= 0) {
int var = j;
if (root[j] == j) {
ssa->vars[j].scc_entry = 1;
}
FOR_EACH_VAR_USAGE(var, CHECK_SCC_ENTRY);
}
}
ZEND_WORKLIST_STACK_FREE_ALLOCA(&stack, stack_use_heap);
free_alloca(root, root_use_heap);
free_alloca(dfs, dfs_use_heap);
}
/* }}} */
ZEND_API void zend_ssa_find_false_dependencies(const zend_op_array *op_array, zend_ssa *ssa) /* {{{ */
{
zend_ssa_var *ssa_vars = ssa->vars;
zend_ssa_op *ssa_ops = ssa->ops;
int ssa_vars_count = ssa->vars_count;
zend_bitset worklist;
int i, j, use;
zend_ssa_phi *p;
ALLOCA_FLAG(use_heap);
if (!op_array->function_name || !ssa->vars || !ssa->ops) {
return;
}
worklist = do_alloca(sizeof(zend_ulong) * zend_bitset_len(ssa_vars_count), use_heap);
memset(worklist, 0, sizeof(zend_ulong) * zend_bitset_len(ssa_vars_count));
for (i = 0; i < ssa_vars_count; i++) {
ssa_vars[i].no_val = 1; /* mark as unused */
use = ssa->vars[i].use_chain;
while (use >= 0) {
if (!zend_ssa_is_no_val_use(&op_array->opcodes[use], &ssa->ops[use], i)) {
ssa_vars[i].no_val = 0; /* used directly */
zend_bitset_incl(worklist, i);
break;
}
use = zend_ssa_next_use(ssa_ops, i, use);
}
}
WHILE_WORKLIST(worklist, zend_bitset_len(ssa_vars_count), i) {
if (ssa_vars[i].definition_phi) {
/* mark all possible sources as used */
p = ssa_vars[i].definition_phi;
if (p->pi >= 0) {
if (ssa_vars[p->sources[0]].no_val) {
ssa_vars[p->sources[0]].no_val = 0; /* used indirectly */
zend_bitset_incl(worklist, p->sources[0]);
}
} else {
for (j = 0; j < ssa->cfg.blocks[p->block].predecessors_count; j++) {
ZEND_ASSERT(p->sources[j] >= 0);
if (ssa->vars[p->sources[j]].no_val) {
ssa_vars[p->sources[j]].no_val = 0; /* used indirectly */
zend_bitset_incl(worklist, p->sources[j]);
}
}
}
}
} WHILE_WORKLIST_END();
free_alloca(worklist, use_heap);
}
/* }}} */
/* From "Hacker's Delight" */
zend_ulong minOR(zend_ulong a, zend_ulong b, zend_ulong c, zend_ulong d)
{
zend_ulong m, temp;
m = Z_UL(1) << (sizeof(zend_ulong) * 8 - 1);
while (m != 0) {
if (~a & c & m) {
temp = (a | m) & -m;
if (temp <= b) {
a = temp;
break;
}
} else if (a & ~c & m) {
temp = (c | m) & -m;
if (temp <= d) {
c = temp;
break;
}
}
m = m >> 1;
}
return a | c;
}
zend_ulong maxOR(zend_ulong a, zend_ulong b, zend_ulong c, zend_ulong d)
{
zend_ulong m, temp;
m = Z_UL(1) << (sizeof(zend_ulong) * 8 - 1);
while (m != 0) {
if (b & d & m) {
temp = (b - m) | (m - 1);
if (temp >= a) {
b = temp;
break;
}
temp = (d - m) | (m - 1);
if (temp >= c) {
d = temp;
break;
}
}
m = m >> 1;
}
return b | d;
}
zend_ulong minAND(zend_ulong a, zend_ulong b, zend_ulong c, zend_ulong d)
{
zend_ulong m, temp;
m = Z_UL(1) << (sizeof(zend_ulong) * 8 - 1);
while (m != 0) {
if (~a & ~c & m) {
temp = (a | m) & -m;
if (temp <= b) {
a = temp;
break;
}
temp = (c | m) & -m;
if (temp <= d) {
c = temp;
break;
}
}
m = m >> 1;
}
return a & c;
}
zend_ulong maxAND(zend_ulong a, zend_ulong b, zend_ulong c, zend_ulong d)
{
zend_ulong m, temp;
m = Z_UL(1) << (sizeof(zend_ulong) * 8 - 1);
while (m != 0) {
if (b & ~d & m) {
temp = (b | ~m) | (m - 1);
if (temp >= a) {
b = temp;
break;
}
} else if (~b & d & m) {
temp = (d | ~m) | (m - 1);
if (temp >= c) {
d = temp;
break;
}
}
m = m >> 1;
}
return b & d;
}
zend_ulong minXOR(zend_ulong a, zend_ulong b, zend_ulong c, zend_ulong d)
{
return minAND(a, b, ~d, ~c) | minAND(~b, ~a, c, d);
}
zend_ulong maxXOR(zend_ulong a, zend_ulong b, zend_ulong c, zend_ulong d)
{
return maxOR(0, maxAND(a, b, ~d, ~c), 0, maxAND(~b, ~a, c, d));
}
/* Based on "Hacker's Delight" */
/*
0: + + + + 0 0 0 0 => 0 0 + min/max
2: + + - + 0 0 1 0 => 1 0 ? min(a,b,c,-1)/max(a,b,0,d)
3: + + - - 0 0 1 1 => 1 1 - min/max
8: - + + + 1 0 0 0 => 1 0 ? min(a,-1,b,d)/max(0,b,c,d)
a: - + - + 1 0 1 0 => 1 0 ? MIN(a,c)/max(0,b,0,d)
b: - + - - 1 0 1 1 => 1 1 - c/-1
c: - - + + 1 1 0 0 => 1 1 - min/max
e: - - - + 1 1 1 0 => 1 1 - a/-1
f - - - - 1 1 1 1 => 1 1 - min/max
*/
static void zend_ssa_range_or(zend_long a, zend_long b, zend_long c, zend_long d, zend_ssa_range *tmp)
{
int x = ((a < 0) ? 8 : 0) |
((b < 0) ? 4 : 0) |
((c < 0) ? 2 : 0) |
((d < 0) ? 1 : 0);
switch (x) {
case 0x0:
case 0x3:
case 0xc:
case 0xf:
tmp->min = minOR(a, b, c, d);
tmp->max = maxOR(a, b, c, d);
break;
case 0x2:
tmp->min = minOR(a, b, c, -1);
tmp->max = maxOR(a, b, 0, d);
break;
case 0x8:
tmp->min = minOR(a, -1, c, d);
tmp->max = maxOR(0, b, c, d);
break;
case 0xa:
tmp->min = MIN(a, c);
tmp->max = maxOR(0, b, 0, d);
break;
case 0xb:
tmp->min = c;
tmp->max = -1;
break;
case 0xe:
tmp->min = a;
tmp->max = -1;
break;
}
}
/*
0: + + + + 0 0 0 0 => 0 0 + min/max
2: + + - + 0 0 1 0 => 0 0 + 0/b
3: + + - - 0 0 1 1 => 0 0 + min/max
8: - + + + 1 0 0 0 => 0 0 + 0/d
a: - + - + 1 0 1 0 => 1 0 ? min(a,-1,c,-1)/NAX(b,d)
b: - + - - 1 0 1 1 => 1 0 ? min(a,-1,c,d)/max(0,b,c,d)
c: - - + + 1 1 0 0 => 1 1 - min/max
e: - - - + 1 1 1 0 => 1 0 ? min(a,b,c,-1)/max(a,b,0,d)
f - - - - 1 1 1 1 => 1 1 - min/max
*/
static void zend_ssa_range_and(zend_long a, zend_long b, zend_long c, zend_long d, zend_ssa_range *tmp)
{
int x = ((a < 0) ? 8 : 0) |
((b < 0) ? 4 : 0) |
((c < 0) ? 2 : 0) |
((d < 0) ? 1 : 0);
switch (x) {
case 0x0:
case 0x3:
case 0xc:
case 0xf:
tmp->min = minAND(a, b, c, d);
tmp->max = maxAND(a, b, c, d);
break;
case 0x2:
tmp->min = 0;
tmp->max = b;
break;
case 0x8:
tmp->min = 0;
tmp->max = d;
break;
case 0xa:
tmp->min = minAND(a, -1, c, -1);
tmp->max = MAX(b, d);
break;
case 0xb:
tmp->min = minAND(a, -1, c, d);
tmp->max = maxAND(0, b, c, d);
break;
case 0xe:
tmp->min = minAND(a, b, c, -1);
tmp->max = maxAND(a, b, 0, d);
break;
}
}
static inline bool zend_abs_range(
zend_long min, zend_long max, zend_long *abs_min, zend_long *abs_max) {
if (min == ZEND_LONG_MIN) {
/* Cannot take absolute value of LONG_MIN */
return 0;
}
if (min >= 0) {
*abs_min = min;
*abs_max = max;
} else if (max <= 0) {
*abs_min = -max;
*abs_max = -min;
} else {
/* Range crossing zero */
*abs_min = 0;
*abs_max = MAX(max, -min);
}
return 1;
}
static inline zend_long safe_shift_left(zend_long n, zend_long s) {
return (zend_long) ((zend_ulong) n << (zend_ulong) s);
}
static inline bool shift_left_overflows(zend_long n, zend_long s) {
/* This considers shifts that shift in the sign bit to be overflowing as well */
if (n >= 0) {
return s >= SIZEOF_ZEND_LONG * 8 - 1 || safe_shift_left(n, s) < n;
} else {
return s >= SIZEOF_ZEND_LONG * 8 || safe_shift_left(n, s) > n;
}
}
/* If b does not divide a exactly, return the two adjacent values between which the real result
* lies. */
static void float_div(zend_long a, zend_long b, zend_long *r1, zend_long *r2) {
*r1 = *r2 = a / b;
if (a % b != 0) {
if (*r2 < 0) {
(*r2)--;
} else {
(*r2)++;
}
}
}
static bool zend_inference_calc_binary_op_range(
const zend_op_array *op_array, const zend_ssa *ssa,
const zend_op *opline, const zend_ssa_op *ssa_op, uint8_t opcode, zend_ssa_range *tmp) {
zend_long op1_min, op2_min, op1_max, op2_max, t1, t2, t3, t4;
switch (opcode) {
case ZEND_ADD:
if (OP1_HAS_RANGE() && OP2_HAS_RANGE()) {
op1_min = OP1_MIN_RANGE();
op2_min = OP2_MIN_RANGE();
op1_max = OP1_MAX_RANGE();
op2_max = OP2_MAX_RANGE();
if (OP1_RANGE_UNDERFLOW() ||
OP2_RANGE_UNDERFLOW() ||
zend_add_will_overflow(op1_min, op2_min)) {
tmp->underflow = 1;
tmp->min = ZEND_LONG_MIN;
} else {
tmp->min = op1_min + op2_min;
}
if (OP1_RANGE_OVERFLOW() ||
OP2_RANGE_OVERFLOW() ||
zend_add_will_overflow(op1_max, op2_max)) {
tmp->overflow = 1;
tmp->max = ZEND_LONG_MAX;
} else {
tmp->max = op1_max + op2_max;
}
return 1;
}
break;
case ZEND_SUB:
if (OP1_HAS_RANGE() && OP2_HAS_RANGE()) {
op1_min = OP1_MIN_RANGE();
op2_min = OP2_MIN_RANGE();
op1_max = OP1_MAX_RANGE();
op2_max = OP2_MAX_RANGE();
if (OP1_RANGE_UNDERFLOW() ||
OP2_RANGE_OVERFLOW() ||
zend_sub_will_overflow(op1_min, op2_max)) {
tmp->underflow = 1;
tmp->min = ZEND_LONG_MIN;
} else {
tmp->min = op1_min - op2_max;
}
if (OP1_RANGE_OVERFLOW() ||
OP2_RANGE_UNDERFLOW() ||
zend_sub_will_overflow(op1_max, op2_min)) {
tmp->overflow = 1;
tmp->max = ZEND_LONG_MAX;
} else {
tmp->max = op1_max - op2_min;
}
return 1;
}
break;
case ZEND_MUL:
if (OP1_HAS_RANGE() && OP2_HAS_RANGE()) {
double dummy;
zend_long t1_overflow, t2_overflow, t3_overflow, t4_overflow;
op1_min = OP1_MIN_RANGE();
op2_min = OP2_MIN_RANGE();
op1_max = OP1_MAX_RANGE();
op2_max = OP2_MAX_RANGE();
/* Suppress uninit variable warnings, these will only be used if the overflow
* flags are all false. */
t1 = t2 = t3 = t4 = 0;
ZEND_SIGNED_MULTIPLY_LONG(op1_min, op2_min, t1, dummy, t1_overflow);
ZEND_SIGNED_MULTIPLY_LONG(op1_min, op2_max, t2, dummy, t2_overflow);
ZEND_SIGNED_MULTIPLY_LONG(op1_max, op2_min, t3, dummy, t3_overflow);
ZEND_SIGNED_MULTIPLY_LONG(op1_max, op2_max, t4, dummy, t4_overflow);
(void) dummy;
// FIXME: more careful overflow checks?
if (OP1_RANGE_UNDERFLOW() || OP2_RANGE_UNDERFLOW() ||
OP1_RANGE_OVERFLOW() || OP2_RANGE_OVERFLOW() ||
t1_overflow || t2_overflow || t3_overflow || t4_overflow
) {
tmp->underflow = 1;
tmp->overflow = 1;
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
} else {
tmp->min = MIN(MIN(t1, t2), MIN(t3, t4));
tmp->max = MAX(MAX(t1, t2), MAX(t3, t4));
}
return 1;
}
break;
case ZEND_DIV:
if (OP1_HAS_RANGE() && OP2_HAS_RANGE()) {
op1_min = OP1_MIN_RANGE();
op2_min = OP2_MIN_RANGE();
op1_max = OP1_MAX_RANGE();
op2_max = OP2_MAX_RANGE();
/* If op2 crosses zero, then floating point values close to zero might be
* possible, which will result in arbitrarily large results (overflow). Also
* avoid dividing LONG_MIN by -1, which is UB. */
if (OP1_RANGE_UNDERFLOW() || OP2_RANGE_UNDERFLOW() ||
OP1_RANGE_OVERFLOW() || OP2_RANGE_OVERFLOW() ||
(op2_min <= 0 && op2_max >= 0) ||
(op1_min == ZEND_LONG_MIN && op2_max == -1)
) {
tmp->underflow = 1;
tmp->overflow = 1;
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
} else {
zend_long t1_, t2_, t3_, t4_;
float_div(op1_min, op2_min, &t1, &t1_);
float_div(op1_min, op2_max, &t2, &t2_);
float_div(op1_max, op2_min, &t3, &t3_);
float_div(op1_max, op2_max, &t4, &t4_);
tmp->min = MIN(MIN(MIN(t1, t2), MIN(t3, t4)), MIN(MIN(t1_, t2_), MIN(t3_, t4_)));
tmp->max = MAX(MAX(MAX(t1, t2), MAX(t3, t4)), MAX(MAX(t1_, t2_), MAX(t3_, t4_)));
}
return 1;
}
break;
case ZEND_MOD:
if (OP1_HAS_RANGE() && OP2_HAS_RANGE()) {
if (OP1_RANGE_UNDERFLOW() ||
OP2_RANGE_UNDERFLOW() ||
OP1_RANGE_OVERFLOW() ||
OP2_RANGE_OVERFLOW()) {
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
} else {
zend_long op2_abs_min, op2_abs_max;
op1_min = OP1_MIN_RANGE();
op2_min = OP2_MIN_RANGE();
op1_max = OP1_MAX_RANGE();
op2_max = OP2_MAX_RANGE();
if (!zend_abs_range(op2_min, op2_max, &op2_abs_min, &op2_abs_max)) {
break;
}
if (op2_abs_max == 0) {
/* Always modulus by zero, nothing we can do */
break;
}
if (op2_abs_min == 0) {
/* Ignore the modulus by zero case, which will throw */
op2_abs_min++;
}
if (op1_min >= 0) {
tmp->min = op1_max < op2_abs_min ? op1_min : 0;
tmp->max = MIN(op1_max, op2_abs_max - 1);
} else if (op1_max <= 0) {
tmp->min = MAX(op1_min, -op2_abs_max + 1);
tmp->max = op1_min > -op2_abs_min ? op1_max : 0;
} else {
tmp->min = MAX(op1_min, -op2_abs_max + 1);
tmp->max = MIN(op1_max, op2_abs_max - 1);
}
}
return 1;
}
break;
case ZEND_SL:
if (OP1_HAS_RANGE() && OP2_HAS_RANGE()) {
if (OP1_RANGE_UNDERFLOW() ||
OP2_RANGE_UNDERFLOW() ||
OP1_RANGE_OVERFLOW() ||
OP2_RANGE_OVERFLOW()) {
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
} else {
op1_min = OP1_MIN_RANGE();
op2_min = OP2_MIN_RANGE();
op1_max = OP1_MAX_RANGE();
op2_max = OP2_MAX_RANGE();
/* Shifts by negative numbers will throw, ignore them */
if (op2_min < 0) {
op2_min = 0;
}
if (op2_max < 0) {
op2_max = 0;
}
if (shift_left_overflows(op1_min, op2_max)
|| shift_left_overflows(op1_max, op2_max)) {
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
} else {
t1 = safe_shift_left(op1_min, op2_min);
t2 = safe_shift_left(op1_min, op2_max);
t3 = safe_shift_left(op1_max, op2_min);
t4 = safe_shift_left(op1_max, op2_max);
tmp->min = MIN(MIN(t1, t2), MIN(t3, t4));
tmp->max = MAX(MAX(t1, t2), MAX(t3, t4));
}
}
return 1;
}
break;
case ZEND_SR:
if (OP1_HAS_RANGE() && OP2_HAS_RANGE()) {
if (OP1_RANGE_UNDERFLOW() ||
OP2_RANGE_UNDERFLOW() ||
OP1_RANGE_OVERFLOW() ||
OP2_RANGE_OVERFLOW()) {
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
} else {
op1_min = OP1_MIN_RANGE();
op2_min = OP2_MIN_RANGE();
op1_max = OP1_MAX_RANGE();
op2_max = OP2_MAX_RANGE();
/* Shifts by negative numbers will throw, ignore them */
if (op2_min < 0) {
op2_min = 0;
}
if (op2_max < 0) {
op2_max = 0;
}
/* Shifts by more than the integer size will be 0 or -1 */
if (op2_min >= SIZEOF_ZEND_LONG * 8) {
op2_min = SIZEOF_ZEND_LONG * 8 - 1;
}
if (op2_max >= SIZEOF_ZEND_LONG * 8) {
op2_max = SIZEOF_ZEND_LONG * 8 - 1;
}
t1 = op1_min >> op2_min;
t2 = op1_min >> op2_max;
t3 = op1_max >> op2_min;
t4 = op1_max >> op2_max;
tmp->min = MIN(MIN(t1, t2), MIN(t3, t4));
tmp->max = MAX(MAX(t1, t2), MAX(t3, t4));
}
return 1;
}
break;
case ZEND_BW_OR:
if (OP1_HAS_RANGE() && OP2_HAS_RANGE()) {
if (OP1_RANGE_UNDERFLOW() ||
OP2_RANGE_UNDERFLOW() ||
OP1_RANGE_OVERFLOW() ||
OP2_RANGE_OVERFLOW()) {
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
} else {
op1_min = OP1_MIN_RANGE();
op2_min = OP2_MIN_RANGE();
op1_max = OP1_MAX_RANGE();
op2_max = OP2_MAX_RANGE();
zend_ssa_range_or(op1_min, op1_max, op2_min, op2_max, tmp);
}
return 1;
}
break;
case ZEND_BW_AND:
if (OP1_HAS_RANGE() && OP2_HAS_RANGE()) {
if (OP1_RANGE_UNDERFLOW() ||
OP2_RANGE_UNDERFLOW() ||
OP1_RANGE_OVERFLOW() ||
OP2_RANGE_OVERFLOW()) {
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
} else {
op1_min = OP1_MIN_RANGE();
op2_min = OP2_MIN_RANGE();
op1_max = OP1_MAX_RANGE();
op2_max = OP2_MAX_RANGE();
zend_ssa_range_and(op1_min, op1_max, op2_min, op2_max, tmp);
}
return 1;
}
break;
case ZEND_BW_XOR:
// TODO
break;
EMPTY_SWITCH_DEFAULT_CASE()
}
return 0;
}
static bool zend_inference_calc_range(const zend_op_array *op_array, const zend_ssa *ssa, int var, int widening, int narrowing, zend_ssa_range *tmp)
{
uint32_t line;
const zend_op *opline;
const zend_ssa_op *ssa_op;
if (ssa->vars[var].definition_phi) {
const zend_ssa_phi *p = ssa->vars[var].definition_phi;
int i;
tmp->underflow = 0;
tmp->min = ZEND_LONG_MAX;
tmp->max = ZEND_LONG_MIN;
tmp->overflow = 0;
if (p->pi >= 0 && p->has_range_constraint) {
const zend_ssa_range_constraint *constraint = &p->constraint.range;
if (constraint->negative) {
int src1 = p->sources[0];
if (ssa->var_info[src1].has_range) {
*tmp = ssa->var_info[src1].range;
if (constraint->range.min == constraint->range.max
&& !constraint->range.underflow
&& !constraint->range.overflow
&& p->constraint.range.min_ssa_var < 0
&& p->constraint.range.max_ssa_var < 0
&& ssa->vars[src1].definition >= 0) {
/* Check for constrained induction variable */
line = ssa->vars[src1].definition;
opline = op_array->opcodes + line;
switch (opline->opcode) {
case ZEND_PRE_DEC:
case ZEND_POST_DEC:
if (!tmp->underflow) {
const zend_ssa_phi *p = ssa->vars[ssa->ops[line].op1_use].definition_phi;
if (p && p->pi < 0
&& ssa->cfg.blocks[p->block].predecessors_count == 2
&& p->sources[1] == var
&& ssa->var_info[p->sources[0]].has_range
&& ssa->var_info[p->sources[0]].range.min > constraint->range.max) {
tmp->min = constraint->range.max + 1;
}
}
break;
case ZEND_PRE_INC:
case ZEND_POST_INC:
if (!tmp->overflow) {
const zend_ssa_phi *p = ssa->vars[ssa->ops[line].op1_use].definition_phi;
if (p && p->pi < 0
&& ssa->cfg.blocks[p->block].predecessors_count == 2
&& p->sources[1] == var
&& ssa->var_info[p->sources[0]].has_range
&& ssa->var_info[p->sources[0]].range.max < constraint->range.min) {
tmp->max = constraint->range.min - 1;
}
}
break;
}
}
} else if (narrowing) {
tmp->underflow = 1;
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
tmp->overflow = 1;
}
#ifdef NEG_RANGE
if (constraint->min_ssa_var < 0 &&
constraint->max_ssa_var < 0 &&
ssa->var_info[p->ssa_var].has_range) {
LOG_NEG_RANGE("%s() #%d [%ld..%ld] -> [%ld..%ld]?\n",
ZSTR_VAL(op_array->function_name),
p->ssa_var,
ssa->var_info[p->ssa_var].range.min,
ssa->var_info[p->ssa_var].range.max,
tmp->min,
tmp->max);
if (constraint->negative == NEG_USE_LT &&
tmp->max >= constraint->range.min) {
tmp->overflow = 0;
tmp->max = constraint->range.min - 1;
LOG_NEG_RANGE(" => [%ld..%ld]\n", tmp->min, tmp->max);
} else if (constraint->negative == NEG_USE_GT &&
tmp->min <= constraint->range.max) {
tmp->underflow = 0;
tmp->min = constraint->range.max + 1;
LOG_NEG_RANGE(" => [%ld..%ld]\n", tmp->min, tmp->max);
}
}
#endif
} else if (ssa->var_info[p->sources[0]].has_range) {
/* intersection */
*tmp = ssa->var_info[p->sources[0]].range;
if (constraint->min_ssa_var < 0) {
tmp->underflow = constraint->range.underflow && tmp->underflow;
tmp->min = MAX(constraint->range.min, tmp->min);
#ifdef SYM_RANGE
} else if (narrowing && ssa->var_info[constraint->min_ssa_var].has_range) {
tmp->underflow = ssa->var_info[constraint->min_ssa_var].range.underflow && tmp->underflow;
if (!add_will_overflow(ssa->var_info[constraint->min_ssa_var].range.min, constraint->range.min)) {
tmp->min = MAX(ssa->var_info[constraint->min_ssa_var].range.min + constraint->range.min, tmp->min);
}
#endif
}
if (constraint->max_ssa_var < 0) {
tmp->max = MIN(constraint->range.max, tmp->max);
tmp->overflow = constraint->range.overflow && tmp->overflow;
#ifdef SYM_RANGE
} else if (narrowing && ssa->var_info[constraint->max_ssa_var].has_range) {
if (!add_will_overflow(ssa->var_info[constraint->max_ssa_var].range.max, constraint->range.max)) {
tmp->max = MIN(ssa->var_info[constraint->max_ssa_var].range.max + constraint->range.max, tmp->max);
}
tmp->overflow = ssa->var_info[constraint->max_ssa_var].range.overflow && tmp->overflow;
#endif
}
} else if (narrowing) {
if (constraint->min_ssa_var < 0) {
tmp->underflow = constraint->range.underflow;
tmp->min = constraint->range.min;
#ifdef SYM_RANGE
} else if (narrowing && ssa->var_info[constraint->min_ssa_var].has_range) {
if (add_will_overflow(ssa->var_info[constraint->min_ssa_var].range.min, constraint->range.min)) {
tmp->underflow = 1;
tmp->min = ZEND_LONG_MIN;
} else {
tmp->underflow = ssa->var_info[constraint->min_ssa_var].range.underflow;
tmp->min = ssa->var_info[constraint->min_ssa_var].range.min + constraint->range.min;
}
#endif
} else {
tmp->underflow = 1;
tmp->min = ZEND_LONG_MIN;
}
if (constraint->max_ssa_var < 0) {
tmp->max = constraint->range.max;
tmp->overflow = constraint->range.overflow;
#ifdef SYM_RANGE
} else if (narrowing && ssa->var_info[constraint->max_ssa_var].has_range) {
if (add_will_overflow(ssa->var_info[constraint->max_ssa_var].range.max, constraint->range.max)) {
tmp->overflow = 1;
tmp->max = ZEND_LONG_MAX;
} else {
tmp->max = ssa->var_info[constraint->max_ssa_var].range.max + constraint->range.max;
tmp->overflow = ssa->var_info[constraint->max_ssa_var].range.overflow;
}
#endif
} else {
tmp->max = ZEND_LONG_MAX;
tmp->overflow = 1;
}
}
} else {
for (i = 0; i < ssa->cfg.blocks[p->block].predecessors_count; i++) {
ZEND_ASSERT(p->sources[i] >= 0);
if (ssa->var_info[p->sources[i]].has_range) {
/* union */
tmp->underflow |= ssa->var_info[p->sources[i]].range.underflow;
tmp->min = MIN(tmp->min, ssa->var_info[p->sources[i]].range.min);
tmp->max = MAX(tmp->max, ssa->var_info[p->sources[i]].range.max);
tmp->overflow |= ssa->var_info[p->sources[i]].range.overflow;
} else if (narrowing) {
tmp->underflow = 1;
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
tmp->overflow = 1;
}
}
}
return (tmp->min <= tmp->max);
} else if (ssa->vars[var].definition < 0) {
return 0;
}
line = ssa->vars[var].definition;
opline = op_array->opcodes + line;
ssa_op = &ssa->ops[line];
return zend_inference_propagate_range(op_array, ssa, opline, ssa_op, var, tmp);
}
ZEND_API bool zend_inference_propagate_range(const zend_op_array *op_array, const zend_ssa *ssa, const zend_op *opline, const zend_ssa_op* ssa_op, int var, zend_ssa_range *tmp)
{
tmp->underflow = 0;
tmp->overflow = 0;
switch (opline->opcode) {
case ZEND_ADD:
case ZEND_SUB:
case ZEND_MUL:
case ZEND_DIV:
case ZEND_MOD:
case ZEND_SL:
case ZEND_SR:
case ZEND_BW_OR:
case ZEND_BW_AND:
case ZEND_BW_XOR:
if (ssa_op->result_def == var) {
return zend_inference_calc_binary_op_range(
op_array, ssa, opline, ssa_op, opline->opcode, tmp);
}
break;
case ZEND_BW_NOT:
if (ssa_op->result_def == var) {
if (OP1_HAS_RANGE()) {
if (OP1_RANGE_UNDERFLOW() ||
OP1_RANGE_OVERFLOW()) {
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
} else {
zend_long op1_min = OP1_MIN_RANGE();
zend_long op1_max = OP1_MAX_RANGE();
tmp->min = ~op1_max;
tmp->max = ~op1_min;
}
return 1;
}
}
break;
case ZEND_CAST:
if (ssa_op->op1_def == var) {
if (ssa_op->op1_def >= 0) {
if (OP1_HAS_RANGE()) {
tmp->underflow = OP1_RANGE_UNDERFLOW();
tmp->min = OP1_MIN_RANGE();
tmp->max = OP1_MAX_RANGE();
tmp->overflow = OP1_RANGE_OVERFLOW();
return 1;
}
}
} else if (ssa_op->result_def == var) {
if (opline->extended_value == IS_LONG) {
if (OP1_HAS_RANGE()) {
tmp->min = OP1_MIN_RANGE();
tmp->max = OP1_MAX_RANGE();
return 1;
} else {
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
return 1;
}
}
}
break;
case ZEND_QM_ASSIGN:
case ZEND_JMP_SET:
case ZEND_COALESCE:
case ZEND_COPY_TMP:
if (ssa_op->op1_def == var) {
if (ssa_op->op1_def >= 0) {
if (OP1_HAS_RANGE()) {
tmp->underflow = OP1_RANGE_UNDERFLOW();
tmp->min = OP1_MIN_RANGE();
tmp->max = OP1_MAX_RANGE();
tmp->overflow = OP1_RANGE_OVERFLOW();
return 1;
}
}
}
if (ssa_op->result_def == var) {
if (OP1_HAS_RANGE()) {
tmp->min = OP1_MIN_RANGE();
tmp->max = OP1_MAX_RANGE();
tmp->underflow = OP1_RANGE_UNDERFLOW();
tmp->overflow = OP1_RANGE_OVERFLOW();
return 1;
}
}
break;
case ZEND_SEND_VAR:
if (ssa_op->op1_def == var) {
if (ssa_op->op1_def >= 0) {
if (OP1_HAS_RANGE()) {
tmp->underflow = OP1_RANGE_UNDERFLOW();
tmp->min = OP1_MIN_RANGE();
tmp->max = OP1_MAX_RANGE();
tmp->overflow = OP1_RANGE_OVERFLOW();
return 1;
}
}
}
break;
case ZEND_PRE_INC:
if (ssa_op->op1_def == var || ssa_op->result_def == var) {
if (OP1_HAS_RANGE()) {
tmp->min = OP1_MIN_RANGE();
tmp->max = OP1_MAX_RANGE();
tmp->underflow = OP1_RANGE_UNDERFLOW();
tmp->overflow = OP1_RANGE_OVERFLOW();
if (tmp->max < ZEND_LONG_MAX) {
tmp->max++;
} else {
tmp->overflow = 1;
}
if (tmp->min < ZEND_LONG_MAX && !tmp->underflow) {
tmp->min++;
}
return 1;
}
}
break;
case ZEND_PRE_DEC:
if (ssa_op->op1_def == var || ssa_op->result_def == var) {
if (OP1_HAS_RANGE()) {
tmp->min = OP1_MIN_RANGE();
tmp->max = OP1_MAX_RANGE();
tmp->underflow = OP1_RANGE_UNDERFLOW();
tmp->overflow = OP1_RANGE_OVERFLOW();
if (tmp->min > ZEND_LONG_MIN) {
tmp->min--;
} else {
tmp->underflow = 1;
}
if (tmp->max > ZEND_LONG_MIN && !tmp->overflow) {
tmp->max--;
}
return 1;
}
}
break;
case ZEND_POST_INC:
if (ssa_op->op1_def == var || ssa_op->result_def == var) {
if (OP1_HAS_RANGE()) {
tmp->min = OP1_MIN_RANGE();
tmp->max = OP1_MAX_RANGE();
tmp->underflow = OP1_RANGE_UNDERFLOW();
tmp->overflow = OP1_RANGE_OVERFLOW();
if (ssa_op->result_def == var) {
return 1;
}
if (tmp->max < ZEND_LONG_MAX) {
tmp->max++;
} else {
tmp->overflow = 1;
}
if (tmp->min < ZEND_LONG_MAX && !tmp->underflow) {
tmp->min++;
}
return 1;
}
}
break;
case ZEND_POST_DEC:
if (ssa_op->op1_def == var || ssa_op->result_def == var) {
if (OP1_HAS_RANGE()) {
tmp->min = OP1_MIN_RANGE();
tmp->max = OP1_MAX_RANGE();
tmp->underflow = OP1_RANGE_UNDERFLOW();
tmp->overflow = OP1_RANGE_OVERFLOW();
if (ssa_op->result_def == var) {
return 1;
}
if (tmp->min > ZEND_LONG_MIN) {
tmp->min--;
} else {
tmp->underflow = 1;
}
if (tmp->max > ZEND_LONG_MIN && !tmp->overflow) {
tmp->max--;
}
return 1;
}
}
break;
case ZEND_UNSET_DIM:
case ZEND_UNSET_OBJ:
if (ssa_op->op1_def == var) {
/* If op1 is scalar, UNSET_DIM and UNSET_OBJ have no effect, so we can keep
* the previous ranges. */
if (OP1_HAS_RANGE()) {
tmp->min = OP1_MIN_RANGE();
tmp->max = OP1_MAX_RANGE();
tmp->underflow = OP1_RANGE_UNDERFLOW();
tmp->overflow = OP1_RANGE_OVERFLOW();
return 1;
}
}
break;
case ZEND_ASSIGN:
if (ssa_op->op1_def == var || ssa_op->op2_def == var || ssa_op->result_def == var) {
if (OP2_HAS_RANGE()) {
tmp->min = OP2_MIN_RANGE();
tmp->max = OP2_MAX_RANGE();
tmp->underflow = OP2_RANGE_UNDERFLOW();
tmp->overflow = OP2_RANGE_OVERFLOW();
return 1;
}
}
break;
case ZEND_ASSIGN_DIM:
case ZEND_ASSIGN_OBJ:
case ZEND_ASSIGN_STATIC_PROP:
case ZEND_ASSIGN_DIM_OP:
case ZEND_ASSIGN_OBJ_OP:
case ZEND_ASSIGN_STATIC_PROP_OP:
if ((ssa_op+1)->op1_def == var) {
opline++;
ssa_op++;
if (OP1_HAS_RANGE()) {
tmp->min = OP1_MIN_RANGE();
tmp->max = OP1_MAX_RANGE();
tmp->underflow = OP1_RANGE_UNDERFLOW();
tmp->overflow = OP1_RANGE_OVERFLOW();
}
return 1;
}
break;
case ZEND_ASSIGN_OP:
if (opline->extended_value != ZEND_CONCAT
&& opline->extended_value != ZEND_POW) {
if (ssa_op->op1_def == var || ssa_op->result_def == var) {
return zend_inference_calc_binary_op_range(
op_array, ssa, opline, ssa_op,
opline->extended_value, tmp);
}
}
break;
case ZEND_OP_DATA:
if (ssa_op->op1_def == var) {
if ((opline-1)->opcode == ZEND_ASSIGN_DIM ||
(opline-1)->opcode == ZEND_ASSIGN_OBJ ||
(opline-1)->opcode == ZEND_ASSIGN_STATIC_PROP ||
(opline-1)->opcode == ZEND_ASSIGN_DIM_OP ||
(opline-1)->opcode == ZEND_ASSIGN_OBJ_OP ||
(opline-1)->opcode == ZEND_ASSIGN_STATIC_PROP_OP) {
if (OP1_HAS_RANGE()) {
tmp->min = OP1_MIN_RANGE();
tmp->max = OP1_MAX_RANGE();
tmp->underflow = OP1_RANGE_UNDERFLOW();
tmp->overflow = OP1_RANGE_OVERFLOW();
return 1;
}
}
break;
}
break;
case ZEND_RECV:
case ZEND_RECV_INIT:
if (ssa_op->result_def == var) {
if (op_array->arg_info &&
opline->op1.num <= op_array->num_args) {
zend_type type = op_array->arg_info[opline->op1.num-1].type;
uint32_t mask = ZEND_TYPE_PURE_MASK_WITHOUT_NULL(type);
if (mask == MAY_BE_LONG) {
tmp->underflow = 0;
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
tmp->overflow = 0;
return 1;
}
}
}
break;
case ZEND_STRLEN:
if (ssa_op->result_def == var) {
#if SIZEOF_ZEND_LONG == 4
/* The length of a string is a non-negative integer. However, on 32-bit
* platforms overflows into negative lengths may occur, so it's better
* to not assume any particular range. */
tmp->min = ZEND_LONG_MIN;
#else
tmp->min = 0;
#endif
tmp->max = ZEND_LONG_MAX;
return 1;
}
break;
case ZEND_FUNC_NUM_ARGS:
tmp->min = 0;
tmp->max = ZEND_LONG_MAX;
return 1;
case ZEND_COUNT:
/* count() on Countable objects may return negative numbers */
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
return 1;
case ZEND_DO_FCALL:
case ZEND_DO_ICALL:
case ZEND_DO_UCALL:
case ZEND_DO_FCALL_BY_NAME:
if (ssa_op->result_def == var) {
const zend_func_info *func_info = ZEND_FUNC_INFO(op_array);
const zend_call_info *call_info;
if (!func_info || !func_info->call_map) {
break;
}
call_info = func_info->call_map[opline - op_array->opcodes];
if (!call_info || call_info->is_prototype) {
break;
}
if (call_info->callee_func->type == ZEND_USER_FUNCTION) {
func_info = ZEND_FUNC_INFO(&call_info->callee_func->op_array);
if (func_info && func_info->return_info.has_range) {
*tmp = func_info->return_info.range;
return 1;
}
}
//TODO: we can't use type inference for internal functions at this point ???
#if 0
uint32_t type;
type = zend_get_func_info(call_info, ssa);
if (!(type & (MAY_BE_ANY - (MAY_BE_NULL|MAY_BE_FALSE|MAY_BE_TRUE|MAY_BE_LONG)))) {
tmp->underflow = 0;
tmp->min = 0;
tmp->max = 0;
tmp->overflow = 0;
if (type & MAY_BE_LONG) {
tmp->min = ZEND_LONG_MIN;
tmp->max = ZEND_LONG_MAX;
} else if (type & MAY_BE_TRUE) {
if (!(type & (MAY_BE_NULL|MAY_BE_FALSE))) {
tmp->min = 1;
}
tmp->max = 1;
}
return 1;
}
#endif
}
break;
// FIXME: support for more opcodes
default:
break;
}
return 0;
}
static void zend_inference_init_range(const zend_op_array *op_array, zend_ssa *ssa, int var, bool underflow, zend_long min, zend_long max, bool overflow)
{
if (underflow) {
min = ZEND_LONG_MIN;
}
if (overflow) {
max = ZEND_LONG_MAX;
}
ssa->var_info[var].has_range = 1;
ssa->var_info[var].range.underflow = underflow;
ssa->var_info[var].range.min = min;
ssa->var_info[var].range.max = max;
ssa->var_info[var].range.overflow = overflow;
LOG_SSA_RANGE(" change range (init SCC %2d) %2d [%s%ld..%ld%s]\n", ssa->vars[var].scc, var, (underflow?"-- ":""), min, max, (overflow?" ++":""));
}
static bool zend_inference_widening_meet(zend_ssa_var_info *var_info, zend_ssa_range *r)
{
if (!var_info->has_range) {
var_info->has_range = 1;
} else {
if (r->underflow ||
var_info->range.underflow ||
r->min < var_info->range.min) {
r->underflow = 1;
r->min = ZEND_LONG_MIN;
}
if (r->overflow ||
var_info->range.overflow ||
r->max > var_info->range.max) {
r->overflow = 1;
r->max = ZEND_LONG_MAX;
}
if (var_info->range.min == r->min &&
var_info->range.max == r->max &&
var_info->range.underflow == r->underflow &&
var_info->range.overflow == r->overflow) {
return 0;
}
}
var_info->range = *r;
return 1;
}
static bool zend_ssa_range_widening(const zend_op_array *op_array, zend_ssa *ssa, int var, int scc)
{
zend_ssa_range tmp;
if (zend_inference_calc_range(op_array, ssa, var, 1, 0, &tmp)) {
if (zend_inference_widening_meet(&ssa->var_info[var], &tmp)) {
LOG_SSA_RANGE(" change range (widening SCC %2d) %2d [%s%ld..%ld%s]\n", scc, var, (tmp.underflow?"-- ":""), tmp.min, tmp.max, (tmp.overflow?" ++":""));
return 1;
}
}
return 0;
}
static bool zend_inference_narrowing_meet(zend_ssa_var_info *var_info, zend_ssa_range *r)
{
if (!var_info->has_range) {
var_info->has_range = 1;
} else {
if (!r->underflow &&
!var_info->range.underflow &&
var_info->range.min < r->min) {
r->min = var_info->range.min;
}
if (!r->overflow &&
!var_info->range.overflow &&
var_info->range.max > r->max) {
r->max = var_info->range.max;
}
if (r->underflow) {
r->min = ZEND_LONG_MIN;
}
if (r->overflow) {
r->max = ZEND_LONG_MAX;
}
if (var_info->range.min == r->min &&
var_info->range.max == r->max &&
var_info->range.underflow == r->underflow &&
var_info->range.overflow == r->overflow) {
return 0;
}
}
var_info->range = *r;
return 1;
}
static bool zend_ssa_range_narrowing(const zend_op_array *op_array, zend_ssa *ssa, int var, int scc)
{
zend_ssa_range tmp;
if (zend_inference_calc_range(op_array, ssa, var, 0, 1, &tmp)) {
if (zend_inference_narrowing_meet(&ssa->var_info[var], &tmp)) {
LOG_SSA_RANGE(" change range (narrowing SCC %2d) %2d [%s%ld..%ld%s]\n", scc, var, (tmp.underflow?"-- ":""), tmp.min, tmp.max, (tmp.overflow?" ++":""));
return 1;
}
}
return 0;
}
#ifdef NEG_RANGE
# define CHECK_INNER_CYCLE(var2) \
do { \
if (ssa->vars[var2].scc == ssa->vars[var].scc && \
!ssa->vars[var2].scc_entry && \
!zend_bitset_in(visited, var2) && \
zend_check_inner_cycles(op_array, ssa, worklist, visited, var2)) { \
return 1; \
} \
} while (0)
static bool zend_check_inner_cycles(const zend_op_array *op_array, zend_ssa *ssa, zend_bitset worklist, zend_bitset visited, int var)
{
if (zend_bitset_in(worklist, var)) {
return 1;
}
zend_bitset_incl(worklist, var);
FOR_EACH_VAR_USAGE(var, CHECK_INNER_CYCLE);
zend_bitset_incl(visited, var);
return 0;
}
#endif
static void zend_infer_ranges_warmup(const zend_op_array *op_array, zend_ssa *ssa, const int *scc_var, const int *next_scc_var, int scc)
{
int worklist_len = zend_bitset_len(ssa->vars_count);
int j, n;
zend_ssa_range tmp;
ALLOCA_FLAG(use_heap)
zend_bitset worklist = do_alloca(sizeof(zend_ulong) * worklist_len * 2, use_heap);
zend_bitset visited = worklist + worklist_len;
#ifdef NEG_RANGE
int has_inner_cycles = 0;
memset(worklist, 0, sizeof(zend_ulong) * worklist_len);
memset(visited, 0, sizeof(zend_ulong) * worklist_len);
j = scc_var[scc];
while (j >= 0) {
if (!zend_bitset_in(visited, j) &&
zend_check_inner_cycles(op_array, ssa, worklist, visited, j)) {
has_inner_cycles = 1;
break;
}
j = next_scc_var[j];
}
#endif
memset(worklist, 0, sizeof(zend_ulong) * worklist_len);
for (n = 0; n < RANGE_WARMUP_PASSES; n++) {
j= scc_var[scc];
while (j >= 0) {
if (ssa->vars[j].scc_entry
&& !(ssa->var_info[j].type & MAY_BE_REF)) {
zend_bitset_incl(worklist, j);
}
j = next_scc_var[j];
}
memset(visited, 0, sizeof(zend_ulong) * worklist_len);
WHILE_WORKLIST(worklist, worklist_len, j) {
if (zend_inference_calc_range(op_array, ssa, j, 0, 0, &tmp)) {
#ifdef NEG_RANGE
if (!has_inner_cycles &&
ssa->var_info[j].has_range &&
ssa->vars[j].definition_phi &&
ssa->vars[j].definition_phi->pi >= 0 &&
ssa->vars[j].definition_phi->has_range_constraint &&
ssa->vars[j].definition_phi->constraint.range.negative &&
ssa->vars[j].definition_phi->constraint.range.min_ssa_var < 0 &&
ssa->vars[j].definition_phi->constraint.range.max_ssa_var < 0) {
zend_ssa_range_constraint *constraint =
&ssa->vars[j].definition_phi->constraint.range;
if (tmp.min == ssa->var_info[j].range.min &&
tmp.max == ssa->var_info[j].range.max) {
if (constraint->negative == NEG_INIT) {
LOG_NEG_RANGE("#%d INVARIANT\n", j);
constraint->negative = NEG_INVARIANT;
}
} else if (tmp.min == ssa->var_info[j].range.min &&
tmp.max == ssa->var_info[j].range.max + 1 &&
tmp.max < constraint->range.min) {
if (constraint->negative == NEG_INIT ||
constraint->negative == NEG_INVARIANT) {
LOG_NEG_RANGE("#%d LT\n", j);
constraint->negative = NEG_USE_LT;
//???NEG
} else if (constraint->negative == NEG_USE_GT) {
LOG_NEG_RANGE("#%d UNKNOWN\n", j);
constraint->negative = NEG_UNKNOWN;
}
} else if (tmp.max == ssa->var_info[j].range.max &&
tmp.min == ssa->var_info[j].range.min - 1 &&
tmp.min > constraint->range.max) {
if (constraint->negative == NEG_INIT ||
constraint->negative == NEG_INVARIANT) {
LOG_NEG_RANGE("#%d GT\n", j);
constraint->negative = NEG_USE_GT;
//???NEG
} else if (constraint->negative == NEG_USE_LT) {
LOG_NEG_RANGE("#%d UNKNOWN\n", j);
constraint->negative = NEG_UNKNOWN;
}
} else {
LOG_NEG_RANGE("#%d UNKNOWN\n", j);
constraint->negative = NEG_UNKNOWN;
}
}
#endif
if (zend_inference_narrowing_meet(&ssa->var_info[j], &tmp)) {
LOG_SSA_RANGE(" change range (warmup %2d SCC %2d) %2d [%s%ld..%ld%s]\n", n, scc, j, (tmp.underflow?"-- ":""), tmp.min, tmp.max, (tmp.overflow?" ++":""));
zend_bitset_incl(visited, j);
FOR_EACH_VAR_USAGE(j, ADD_SCC_VAR_1);
}
}
} WHILE_WORKLIST_END();
}
free_alloca(worklist, use_heap);
}
static void zend_infer_ranges(const zend_op_array *op_array, zend_ssa *ssa) /* {{{ */
{
int worklist_len = zend_bitset_len(ssa->vars_count);
zend_bitset worklist;
int *next_scc_var;
int *scc_var;
zend_ssa_phi *p;
zend_ssa_range tmp;
int scc, j;
ALLOCA_FLAG(use_heap);
worklist = do_alloca(
ZEND_MM_ALIGNED_SIZE(sizeof(zend_ulong) * worklist_len) +
ZEND_MM_ALIGNED_SIZE(sizeof(int) * ssa->vars_count) +
sizeof(int) * ssa->sccs, use_heap);
next_scc_var = (int*)((char*)worklist + ZEND_MM_ALIGNED_SIZE(sizeof(zend_ulong) * worklist_len));
scc_var = (int*)((char*)next_scc_var + ZEND_MM_ALIGNED_SIZE(sizeof(int) * ssa->vars_count));
LOG_SSA_RANGE("Range Inference\n");
/* Create linked lists of SSA variables for each SCC */
memset(scc_var, -1, sizeof(int) * ssa->sccs);
for (j = 0; j < ssa->vars_count; j++) {
if (ssa->vars[j].scc >= 0) {
next_scc_var[j] = scc_var[ssa->vars[j].scc];
scc_var[ssa->vars[j].scc] = j;
}
}
for (scc = 0; scc < ssa->sccs; scc++) {
j = scc_var[scc];
if (next_scc_var[j] < 0) {
/* SCC with a single element */
if (ssa->var_info[j].type & MAY_BE_REF) {
/* pass */
} else if (zend_inference_calc_range(op_array, ssa, j, 0, 1, &tmp)) {
zend_inference_init_range(op_array, ssa, j, tmp.underflow, tmp.min, tmp.max, tmp.overflow);
} else {
zend_inference_init_range(op_array, ssa, j, 1, ZEND_LONG_MIN, ZEND_LONG_MAX, 1);
}
} else {
/* Find SCC entry points */
memset(worklist, 0, sizeof(zend_ulong) * worklist_len);
do {
if (ssa->vars[j].scc_entry
&& !(ssa->var_info[j].type & MAY_BE_REF)) {
zend_bitset_incl(worklist, j);
}
j = next_scc_var[j];
} while (j >= 0);
#if RANGE_WARMUP_PASSES > 0
zend_infer_ranges_warmup(op_array, ssa, scc_var, next_scc_var, scc);
j = scc_var[scc];
do {
if (!(ssa->var_info[j].type & MAY_BE_REF)) {
zend_bitset_incl(worklist, j);
}
j = next_scc_var[j];
} while (j >= 0);
#endif
/* widening */
WHILE_WORKLIST(worklist, worklist_len, j) {
if (zend_ssa_range_widening(op_array, ssa, j, scc)) {
FOR_EACH_VAR_USAGE(j, ADD_SCC_VAR);
}
} WHILE_WORKLIST_END();
/* initialize missing ranges */
for (j = scc_var[scc]; j >= 0; j = next_scc_var[j]) {
if (!ssa->var_info[j].has_range
&& !(ssa->var_info[j].type & MAY_BE_REF)) {
zend_inference_init_range(op_array, ssa, j, 1, ZEND_LONG_MIN, ZEND_LONG_MAX, 1);
FOR_EACH_VAR_USAGE(j, ADD_SCC_VAR);
}
}
/* widening (second round) */
WHILE_WORKLIST(worklist, worklist_len, j) {
if (zend_ssa_range_widening(op_array, ssa, j, scc)) {
FOR_EACH_VAR_USAGE(j, ADD_SCC_VAR);
}
} WHILE_WORKLIST_END();
/* Add all SCC entry variables into worklist for narrowing */
for (j = scc_var[scc]; j >= 0; j = next_scc_var[j]) {
if (ssa->vars[j].definition_phi
&& ssa->vars[j].definition_phi->pi < 0
&& !(ssa->var_info[j].type & MAY_BE_REF)) {
/* narrowing Phi functions first */
zend_ssa_range_narrowing(op_array, ssa, j, scc);
}
zend_bitset_incl(worklist, j);
}
/* narrowing */
WHILE_WORKLIST(worklist, worklist_len, j) {
if (zend_ssa_range_narrowing(op_array, ssa, j, scc)) {
FOR_EACH_VAR_USAGE(j, ADD_SCC_VAR);
#ifdef SYM_RANGE
/* Process symbolic control-flow constraints */
p = ssa->vars[j].sym_use_chain;
while (p) {
ADD_SCC_VAR(p->ssa_var);
p = p->sym_use_chain;
}
#endif
}
} WHILE_WORKLIST_END();
}
}
free_alloca(worklist, use_heap);
}
/* }}} */
static uint32_t get_ssa_alias_types(zend_ssa_alias_kind alias) {
if (alias == HTTP_RESPONSE_HEADER_ALIAS) {
return MAY_BE_ARRAY | MAY_BE_ARRAY_KEY_LONG | MAY_BE_ARRAY_OF_STRING | MAY_BE_RC1 | MAY_BE_RCN;
} else {
return MAY_BE_UNDEF | MAY_BE_RC1 | MAY_BE_RCN | MAY_BE_REF | MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
}
}
#define UPDATE_SSA_TYPE(_type, _var) \
do { \
uint32_t __type = (_type) & ~MAY_BE_GUARD; \
int __var = (_var); \
if (__type & MAY_BE_REF) { \
__type |= MAY_BE_RC1 | MAY_BE_RCN | MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF; \
} \
if (__var >= 0) { \
zend_ssa_var *__ssa_var = &ssa_vars[__var]; \
if (__ssa_var->var < op_array->last_var) { \
if (__type & (MAY_BE_REF|MAY_BE_RCN)) { \
__type |= MAY_BE_RC1 | MAY_BE_RCN; \
} \
if ((__type & MAY_BE_RC1) && (__type & MAY_BE_STRING)) {\
/* TODO: support for array keys and ($str . "")*/ \
__type |= MAY_BE_RCN; \
} \
if (__ssa_var->alias) { \
__type |= get_ssa_alias_types(__ssa_var->alias); \
} \
} \
if (ssa_var_info[__var].type != __type) { \
ZEND_ASSERT(ssa_opcodes != NULL || \
__ssa_var->var >= op_array->last_var || \
(ssa_var_info[__var].type & MAY_BE_REF) \
== (__type & MAY_BE_REF)); \
if (ssa_var_info[__var].type & ~__type) { \
emit_type_narrowing_warning(op_array, ssa, __var); \
return FAILURE; \
} \
ssa_var_info[__var].type = __type; \
if (update_worklist) { \
add_usages(op_array, ssa, worklist, __var); \
} \
} \
/*zend_bitset_excl(worklist, var);*/ \
} \
} while (0)
#define UPDATE_SSA_OBJ_TYPE(_ce, _is_instanceof, var) \
do { \
if (var >= 0) { \
if (ssa_var_info[var].ce != (_ce) || \
ssa_var_info[var].is_instanceof != (_is_instanceof)) { \
ssa_var_info[var].ce = (_ce); \
ssa_var_info[var].is_instanceof = (_is_instanceof); \
if (update_worklist) { \
add_usages(op_array, ssa, worklist, var); \
} \
} \
/*zend_bitset_excl(worklist, var);*/ \
} \
} while (0)
#define COPY_SSA_OBJ_TYPE(from_var, to_var) do { \
if ((from_var) >= 0 && (ssa_var_info[(from_var)].type & MAY_BE_OBJECT) \
&& ssa_var_info[(from_var)].ce && !(ssa_var_info[(to_var)].type & MAY_BE_REF)) { \
UPDATE_SSA_OBJ_TYPE(ssa_var_info[(from_var)].ce, \
ssa_var_info[(from_var)].is_instanceof, (to_var)); \
} else { \
UPDATE_SSA_OBJ_TYPE(NULL, 0, (to_var)); \
} \
} while (0)
static void add_usages(const zend_op_array *op_array, zend_ssa *ssa, zend_bitset worklist, int var)
{
if (ssa->vars[var].phi_use_chain) {
zend_ssa_phi *p = ssa->vars[var].phi_use_chain;
do {
zend_bitset_incl(worklist, p->ssa_var);
p = zend_ssa_next_use_phi(ssa, var, p);
} while (p);
}
if (ssa->vars[var].use_chain >= 0) {
int use = ssa->vars[var].use_chain;
zend_ssa_op *op;
do {
op = ssa->ops + use;
if (op->result_def >= 0) {
zend_bitset_incl(worklist, op->result_def);
}
if (op->op1_def >= 0) {
zend_bitset_incl(worklist, op->op1_def);
}
if (op->op2_def >= 0) {
zend_bitset_incl(worklist, op->op2_def);
}
if (op_array->opcodes[use].opcode == ZEND_OP_DATA) {
op--;
if (op->result_def >= 0) {
zend_bitset_incl(worklist, op->result_def);
}
if (op->op1_def >= 0) {
zend_bitset_incl(worklist, op->op1_def);
}
if (op->op2_def >= 0) {
zend_bitset_incl(worklist, op->op2_def);
}
} else if (use + 1 < op_array->last
&& op_array->opcodes[use + 1].opcode == ZEND_OP_DATA) {
op++;
if (op->result_def >= 0) {
zend_bitset_incl(worklist, op->result_def);
}
if (op->op1_def >= 0) {
zend_bitset_incl(worklist, op->op1_def);
}
if (op->op2_def >= 0) {
zend_bitset_incl(worklist, op->op2_def);
}
}
use = zend_ssa_next_use(ssa->ops, var, use);
} while (use >= 0);
}
}
static void emit_type_narrowing_warning(const zend_op_array *op_array, zend_ssa *ssa, int var)
{
int def_op_num = ssa->vars[var].definition;
const zend_op *def_opline = def_op_num >= 0 ? &op_array->opcodes[def_op_num] : NULL;
const char *def_op_name = def_opline ? zend_get_opcode_name(def_opline->opcode) : "PHI";
uint32_t lineno = def_opline ? def_opline->lineno : 0;
zend_error_at(
E_WARNING, op_array->filename, lineno,
"Narrowing occurred during type inference of %s. Please file a bug report on https://github.com/php/php-src/issues", def_op_name);
#if ZEND_DEBUG
ZEND_ASSERT(0 && "Narrowing during type inference");
#endif
}
ZEND_API uint32_t ZEND_FASTCALL zend_array_type_info(const zval *zv)
{
HashTable *ht = Z_ARRVAL_P(zv);
uint32_t tmp = MAY_BE_ARRAY;
zend_string *str;
zval *val;
if (Z_REFCOUNTED_P(zv)) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
} else {
tmp |= MAY_BE_RCN;
}
ZEND_HASH_FOREACH_STR_KEY_VAL(ht, str, val) {
if (str) {
tmp |= MAY_BE_ARRAY_KEY_STRING;
} else {
tmp |= MAY_BE_ARRAY_KEY_LONG;
}
tmp |= 1 << (Z_TYPE_P(val) + MAY_BE_ARRAY_SHIFT);
} ZEND_HASH_FOREACH_END();
if (HT_IS_PACKED(ht)) {
tmp &= ~(MAY_BE_ARRAY_NUMERIC_HASH|MAY_BE_ARRAY_STRING_HASH);
}
return tmp;
}
ZEND_API uint32_t zend_array_element_type(uint32_t t1, uint8_t op_type, int write, int insert)
{
uint32_t tmp = 0;
if (t1 & MAY_BE_OBJECT) {
if (!write) {
/* can't be REF because of ZVAL_COPY_DEREF() usage */
tmp |= MAY_BE_ANY | MAY_BE_RC1 | MAY_BE_RCN | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
} else {
tmp |= MAY_BE_ANY | MAY_BE_REF | MAY_BE_RC1 | MAY_BE_RCN | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
}
if (write) {
tmp |= MAY_BE_INDIRECT;
}
}
if (t1 & MAY_BE_ARRAY) {
if (insert) {
tmp |= MAY_BE_NULL;
} else {
tmp |= MAY_BE_NULL | ((t1 & MAY_BE_ARRAY_OF_ANY) >> MAY_BE_ARRAY_SHIFT);
if (tmp & MAY_BE_ARRAY) {
tmp |= MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
}
if (tmp & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) {
if (!write) {
/* can't be REF because of ZVAL_COPY_DEREF() usage */
tmp |= MAY_BE_RCN;
if ((op_type & (IS_VAR|IS_TMP_VAR)) && (t1 & MAY_BE_RC1)) {
tmp |= MAY_BE_RC1;
}
} else if (t1 & MAY_BE_ARRAY_OF_REF) {
tmp |= MAY_BE_REF | MAY_BE_RC1 | MAY_BE_RCN;
} else {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
}
}
}
if (write) {
tmp |= MAY_BE_INDIRECT;
}
}
if (t1 & MAY_BE_STRING) {
tmp |= MAY_BE_STRING | MAY_BE_RC1;
if (write) {
tmp |= MAY_BE_NULL;
}
}
if (t1 & (MAY_BE_UNDEF|MAY_BE_NULL|MAY_BE_FALSE)) {
tmp |= MAY_BE_NULL;
if (write) {
tmp |= MAY_BE_INDIRECT;
}
}
if (t1 & (MAY_BE_TRUE|MAY_BE_LONG|MAY_BE_DOUBLE|MAY_BE_RESOURCE)) {
if (!write) {
tmp |= MAY_BE_NULL;
}
}
return tmp;
}
static uint32_t assign_dim_array_result_type(
uint32_t arr_type, uint32_t dim_type, uint32_t value_type, uint8_t dim_op_type) {
uint32_t tmp = 0;
/* Only add key type if we have a value type. We want to maintain the invariant that a
* key type exists iff a value type exists even in dead code that may use empty types. */
if (value_type & (MAY_BE_ANY|MAY_BE_UNDEF)) {
if (value_type & MAY_BE_UNDEF) {
value_type |= MAY_BE_NULL;
}
if (dim_op_type == IS_UNUSED) {
if (arr_type & (MAY_BE_UNDEF|MAY_BE_NULL|MAY_BE_FALSE)) {
tmp |= MAY_BE_ARRAY_PACKED;
}
tmp |= MAY_BE_HASH_ONLY(arr_type) ? MAY_BE_ARRAY_NUMERIC_HASH : MAY_BE_ARRAY_KEY_LONG;
} else {
if (dim_type & (MAY_BE_LONG|MAY_BE_FALSE|MAY_BE_TRUE|MAY_BE_RESOURCE|MAY_BE_DOUBLE)) {
if (arr_type & (MAY_BE_UNDEF|MAY_BE_NULL|MAY_BE_FALSE)) {
tmp |= MAY_BE_ARRAY_PACKED;
}
tmp |= MAY_BE_HASH_ONLY(arr_type) ? MAY_BE_ARRAY_NUMERIC_HASH : MAY_BE_ARRAY_KEY_LONG;
}
if (dim_type & MAY_BE_STRING) {
tmp |= MAY_BE_ARRAY_KEY_STRING;
if (dim_op_type != IS_CONST) {
// FIXME: numeric string
if (arr_type & (MAY_BE_UNDEF|MAY_BE_NULL|MAY_BE_FALSE)) {
tmp |= MAY_BE_ARRAY_PACKED;
}
tmp |= MAY_BE_HASH_ONLY(arr_type) ? MAY_BE_ARRAY_NUMERIC_HASH : MAY_BE_ARRAY_KEY_LONG;
}
}
if (dim_type & (MAY_BE_UNDEF|MAY_BE_NULL)) {
tmp |= MAY_BE_ARRAY_KEY_STRING;
}
}
}
/* Only add value type if we have a key type. It might be that the key type is illegal
* for arrays. */
if (tmp & MAY_BE_ARRAY_KEY_ANY) {
tmp |= (value_type & MAY_BE_ANY) << MAY_BE_ARRAY_SHIFT;
}
return tmp;
}
static uint32_t assign_dim_result_type(
uint32_t arr_type, uint32_t dim_type, uint32_t value_type, uint8_t dim_op_type) {
uint32_t tmp = arr_type & ~(MAY_BE_RC1|MAY_BE_RCN);
if (arr_type & (MAY_BE_UNDEF|MAY_BE_NULL|MAY_BE_FALSE)) {
tmp &= ~(MAY_BE_UNDEF|MAY_BE_NULL|MAY_BE_FALSE);
tmp |= MAY_BE_ARRAY|MAY_BE_RC1;
}
if (tmp & (MAY_BE_ARRAY|MAY_BE_STRING)) {
tmp |= MAY_BE_RC1;
}
if (tmp & (MAY_BE_OBJECT|MAY_BE_RESOURCE)) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
}
if (tmp & MAY_BE_ARRAY) {
tmp |= assign_dim_array_result_type(arr_type, dim_type, value_type, dim_op_type);
}
return tmp;
}
/* For binary ops that have compound assignment operators */
static uint32_t binary_op_result_type(
zend_ssa *ssa, uint8_t opcode, uint32_t t1, uint32_t t2, int result_var,
zend_long optimization_level) {
uint32_t tmp = 0;
uint32_t t1_type = (t1 & MAY_BE_ANY) | (t1 & MAY_BE_UNDEF ? MAY_BE_NULL : 0);
uint32_t t2_type = (t2 & MAY_BE_ANY) | (t2 & MAY_BE_UNDEF ? MAY_BE_NULL : 0);
if (!(ZEND_OPTIMIZER_IGNORE_OVERLOADING & optimization_level)) {
/* Handle potentially overloaded operators.
* This could be made more precise by checking the class type, if known. */
if ((t1_type & MAY_BE_OBJECT) || (t2_type & MAY_BE_OBJECT)) {
/* This is somewhat GMP specific. */
tmp |= MAY_BE_OBJECT | MAY_BE_FALSE | MAY_BE_RC1;
}
}
switch (opcode) {
case ZEND_ADD:
if (t1_type == MAY_BE_LONG && t2_type == MAY_BE_LONG) {
if (result_var < 0 ||
!ssa->var_info[result_var].has_range ||
ssa->var_info[result_var].range.underflow ||
ssa->var_info[result_var].range.overflow) {
/* may overflow */
tmp |= MAY_BE_LONG | MAY_BE_DOUBLE;
} else {
tmp |= MAY_BE_LONG;
}
} else if (t1_type == MAY_BE_DOUBLE || t2_type == MAY_BE_DOUBLE) {
tmp |= MAY_BE_DOUBLE;
} else if (t1_type == MAY_BE_ARRAY && t2_type == MAY_BE_ARRAY) {
tmp |= MAY_BE_ARRAY | MAY_BE_RC1;
tmp |= t1 & (MAY_BE_ARRAY_KEY_ANY|MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF);
tmp |= t2 & (MAY_BE_ARRAY_KEY_ANY|MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF);
} else {
tmp |= MAY_BE_LONG | MAY_BE_DOUBLE;
if ((t1_type & MAY_BE_ARRAY) && (t2_type & MAY_BE_ARRAY)) {
tmp |= MAY_BE_ARRAY | MAY_BE_RC1;
tmp |= t1 & (MAY_BE_ARRAY_KEY_ANY|MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF);
tmp |= t2 & (MAY_BE_ARRAY_KEY_ANY|MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF);
}
}
break;
case ZEND_SUB:
case ZEND_MUL:
if (t1_type == MAY_BE_LONG && t2_type == MAY_BE_LONG) {
if (result_var < 0 ||
!ssa->var_info[result_var].has_range ||
ssa->var_info[result_var].range.underflow ||
ssa->var_info[result_var].range.overflow) {
/* may overflow */
tmp |= MAY_BE_LONG | MAY_BE_DOUBLE;
} else {
tmp |= MAY_BE_LONG;
}
} else if (t1_type == MAY_BE_DOUBLE || t2_type == MAY_BE_DOUBLE) {
tmp |= MAY_BE_DOUBLE;
} else {
tmp |= MAY_BE_LONG | MAY_BE_DOUBLE;
}
break;
case ZEND_DIV:
case ZEND_POW:
if (t1_type == MAY_BE_DOUBLE || t2_type == MAY_BE_DOUBLE) {
tmp |= MAY_BE_DOUBLE;
} else {
tmp |= MAY_BE_LONG | MAY_BE_DOUBLE;
}
/* Division by zero results in Inf/-Inf/Nan (double), so it doesn't need any special
* handling */
break;
case ZEND_MOD:
tmp |= MAY_BE_LONG;
/* Division by zero results in an exception, so it doesn't need any special handling */
break;
case ZEND_BW_OR:
case ZEND_BW_AND:
case ZEND_BW_XOR:
if ((t1_type & MAY_BE_STRING) && (t2_type & MAY_BE_STRING)) {
tmp |= MAY_BE_STRING | MAY_BE_RC1 | MAY_BE_RCN;
}
if ((t1_type & ~MAY_BE_STRING) || (t2_type & ~MAY_BE_STRING)) {
tmp |= MAY_BE_LONG;
}
break;
case ZEND_SL:
case ZEND_SR:
tmp |= MAY_BE_LONG;
break;
case ZEND_CONCAT:
case ZEND_FAST_CONCAT:
/* TODO: +MAY_BE_OBJECT ??? */
tmp = MAY_BE_STRING | MAY_BE_RC1 | MAY_BE_RCN;
break;
EMPTY_SWITCH_DEFAULT_CASE()
}
return tmp;
}
static uint32_t zend_convert_type_declaration_mask(uint32_t type_mask) {
uint32_t result_mask = type_mask & MAY_BE_ANY;
if (type_mask & MAY_BE_VOID) {
result_mask |= MAY_BE_NULL;
}
if (type_mask & MAY_BE_CALLABLE) {
result_mask |= MAY_BE_STRING|MAY_BE_OBJECT|MAY_BE_ARRAY|MAY_BE_ARRAY_KEY_ANY|MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF;
}
if (type_mask & MAY_BE_STATIC) {
result_mask |= MAY_BE_OBJECT;
}
if (type_mask & MAY_BE_ARRAY) {
result_mask |= MAY_BE_ARRAY_KEY_ANY|MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF;
}
return result_mask;
}
static uint32_t zend_convert_type(const zend_script *script, zend_type type, zend_class_entry **pce)
{
if (pce) {
*pce = NULL;
}
if (!ZEND_TYPE_IS_SET(type)) {
return MAY_BE_ANY|MAY_BE_ARRAY_KEY_ANY|MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF|MAY_BE_RC1|MAY_BE_RCN;
}
uint32_t tmp = zend_convert_type_declaration_mask(ZEND_TYPE_PURE_MASK(type));
if (ZEND_TYPE_IS_COMPLEX(type)) {
tmp |= MAY_BE_OBJECT;
if (pce) {
/* As we only have space to store one CE,
* we use a plain object type for class unions. */
if (ZEND_TYPE_HAS_NAME(type)) {
zend_string *lcname = zend_string_tolower(ZEND_TYPE_NAME(type));
// TODO: Pass through op_array.
*pce = zend_optimizer_get_class_entry(script, NULL, lcname);
zend_string_release_ex(lcname, 0);
}
}
}
if (tmp & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
}
return tmp;
}
ZEND_API uint32_t zend_fetch_arg_info_type(const zend_script *script, const zend_arg_info *arg_info, zend_class_entry **pce)
{
return zend_convert_type(script, arg_info->type, pce);
}
static const zend_property_info *lookup_prop_info(const zend_class_entry *ce, zend_string *name, zend_class_entry *scope) {
const zend_property_info *prop_info;
/* If the class is linked, reuse the precise runtime logic. */
if ((ce->ce_flags & ZEND_ACC_LINKED)
&& (!scope || (scope->ce_flags & ZEND_ACC_LINKED))) {
zend_class_entry *prev_scope = EG(fake_scope);
EG(fake_scope) = scope;
prop_info = zend_get_property_info(ce, name, 1);
EG(fake_scope) = prev_scope;
if (prop_info && prop_info != ZEND_WRONG_PROPERTY_INFO) {
return prop_info;
}
return NULL;
}
/* Otherwise, handle only some safe cases */
prop_info = zend_hash_find_ptr(&ce->properties_info, name);
if (prop_info &&
((prop_info->ce == scope) ||
(!scope && (prop_info->flags & ZEND_ACC_PUBLIC)))
) {
return prop_info;
}
return NULL;
}
static const zend_property_info *zend_fetch_prop_info(const zend_op_array *op_array, zend_ssa *ssa, const zend_op *opline, const zend_ssa_op *ssa_op)
{
const zend_property_info *prop_info = NULL;
if (opline->op2_type == IS_CONST) {
const zend_class_entry *ce = NULL;
if (opline->op1_type == IS_UNUSED) {
ce = op_array->scope;
} else if (ssa_op->op1_use >= 0) {
ce = ssa->var_info[ssa_op->op1_use].ce;
}
if (ce) {
prop_info = lookup_prop_info(ce,
Z_STR_P(CRT_CONSTANT(opline->op2)),
op_array->scope);
if (prop_info && (prop_info->flags & ZEND_ACC_STATIC)) {
prop_info = NULL;
}
}
}
return prop_info;
}
static const zend_property_info *zend_fetch_static_prop_info(const zend_script *script, const zend_op_array *op_array, const zend_ssa *ssa, const zend_op *opline)
{
const zend_property_info *prop_info = NULL;
if (opline->op1_type == IS_CONST) {
zend_class_entry *ce = NULL;
if (opline->op2_type == IS_UNUSED) {
int fetch_type = opline->op2.num & ZEND_FETCH_CLASS_MASK;
switch (fetch_type) {
case ZEND_FETCH_CLASS_SELF:
case ZEND_FETCH_CLASS_STATIC:
/* We enforce that static property types cannot change during inheritance, so
* handling static the same way as self here is legal. */
ce = op_array->scope;
break;
case ZEND_FETCH_CLASS_PARENT:
if (op_array->scope && (op_array->scope->ce_flags & ZEND_ACC_LINKED)) {
ce = op_array->scope->parent;
}
break;
}
} else if (opline->op2_type == IS_CONST) {
zval *zv = CRT_CONSTANT(opline->op2);
ce = zend_optimizer_get_class_entry(script, op_array, Z_STR_P(zv + 1));
}
if (ce) {
zval *zv = CRT_CONSTANT(opline->op1);
prop_info = lookup_prop_info(ce, Z_STR_P(zv), op_array->scope);
if (prop_info && !(prop_info->flags & ZEND_ACC_STATIC)) {
prop_info = NULL;
}
}
}
return prop_info;
}
static uint32_t zend_fetch_prop_type(const zend_script *script, const zend_property_info *prop_info, zend_class_entry **pce)
{
if (!prop_info) {
if (pce) {
*pce = NULL;
}
return MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF | MAY_BE_RC1 | MAY_BE_RCN;
}
return zend_convert_type(script, prop_info->type, pce);
}
static bool result_may_be_separated(zend_ssa *ssa, zend_ssa_op *ssa_op)
{
int tmp_var = ssa_op->result_def;
if (ssa->vars[tmp_var].use_chain >= 0
&& !ssa->vars[tmp_var].phi_use_chain) {
zend_ssa_op *use_op = &ssa->ops[ssa->vars[tmp_var].use_chain];
/* TODO: analyze instructions between ssa_op and use_op */
if (use_op == ssa_op + 1) {
if ((use_op->op1_use == tmp_var && use_op->op1_use_chain < 0)
|| (use_op->op2_use == tmp_var && use_op->op2_use_chain < 0)) {
return 0;
}
}
}
return 1;
}
static zend_always_inline zend_result _zend_update_type_info(
const zend_op_array *op_array,
zend_ssa *ssa,
const zend_script *script,
zend_bitset worklist,
const zend_op *opline,
zend_ssa_op *ssa_op,
const zend_op **ssa_opcodes,
zend_long optimization_level,
bool update_worklist)
{
uint32_t t1, t2;
uint32_t tmp, orig;
zend_ssa_var *ssa_vars = ssa->vars;
zend_ssa_var_info *ssa_var_info = ssa->var_info;
zend_class_entry *ce;
int j;
if (opline->opcode == ZEND_OP_DATA) {
opline--;
ssa_op--;
}
t1 = OP1_INFO();
t2 = OP2_INFO();
/* If one of the operands cannot have any type, this means the operand derives from
* unreachable code. Propagate the empty result early, so that that the following
* code may assume that operands have at least one type. */
if (!(t1 & (MAY_BE_ANY|MAY_BE_UNDEF|MAY_BE_CLASS))
|| !(t2 & (MAY_BE_ANY|MAY_BE_UNDEF|MAY_BE_CLASS))
|| ((opline->opcode == ZEND_ASSIGN_DIM_OP
|| opline->opcode == ZEND_ASSIGN_OBJ_OP
|| opline->opcode == ZEND_ASSIGN_STATIC_PROP_OP
|| opline->opcode == ZEND_ASSIGN_DIM
|| opline->opcode == ZEND_ASSIGN_OBJ)
&& !(OP1_DATA_INFO() & (MAY_BE_ANY|MAY_BE_UNDEF|MAY_BE_CLASS)) /*&& 0*/)) {
tmp = 0;
if (ssa_op->result_def >= 0 && !(ssa_var_info[ssa_op->result_def].type & MAY_BE_REF)) {
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
}
if (ssa_op->op1_def >= 0 && !(ssa_var_info[ssa_op->op1_def].type & MAY_BE_REF)) {
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
if (ssa_op->op2_def >= 0 && !(ssa_var_info[ssa_op->op2_def].type & MAY_BE_REF)) {
UPDATE_SSA_TYPE(tmp, ssa_op->op2_def);
}
if (opline->opcode == ZEND_ASSIGN_DIM_OP
|| opline->opcode == ZEND_ASSIGN_OBJ_OP
|| opline->opcode == ZEND_ASSIGN_STATIC_PROP_OP
|| opline->opcode == ZEND_ASSIGN_DIM
|| opline->opcode == ZEND_ASSIGN_OBJ) {
if ((ssa_op+1)->op1_def >= 0 && !(ssa_var_info[(ssa_op+1)->op1_def].type & MAY_BE_REF)) {
UPDATE_SSA_TYPE(tmp, (ssa_op+1)->op1_def);
}
}
return SUCCESS;
}
switch (opline->opcode) {
case ZEND_ADD:
case ZEND_SUB:
case ZEND_MUL:
case ZEND_DIV:
case ZEND_POW:
case ZEND_MOD:
case ZEND_BW_OR:
case ZEND_BW_AND:
case ZEND_BW_XOR:
case ZEND_SL:
case ZEND_SR:
case ZEND_CONCAT:
tmp = binary_op_result_type(ssa, opline->opcode, t1, t2, ssa_op->result_def, optimization_level);
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
break;
case ZEND_BW_NOT:
tmp = 0;
if (t1 & MAY_BE_STRING) {
tmp |= MAY_BE_STRING | MAY_BE_RC1 | MAY_BE_RCN;
}
if (t1 & (MAY_BE_ANY-MAY_BE_STRING)) {
tmp |= MAY_BE_LONG;
}
if (!(ZEND_OPTIMIZER_IGNORE_OVERLOADING & optimization_level)) {
if (t1 & MAY_BE_OBJECT) {
/* Potentially overloaded operator. */
tmp |= MAY_BE_OBJECT | MAY_BE_RC1;
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
break;
case ZEND_BEGIN_SILENCE:
UPDATE_SSA_TYPE(MAY_BE_LONG, ssa_op->result_def);
break;
case ZEND_BOOL_NOT:
case ZEND_BOOL_XOR:
case ZEND_IS_IDENTICAL:
case ZEND_IS_NOT_IDENTICAL:
case ZEND_IS_EQUAL:
case ZEND_IS_NOT_EQUAL:
case ZEND_IS_SMALLER:
case ZEND_IS_SMALLER_OR_EQUAL:
case ZEND_INSTANCEOF:
case ZEND_JMPZ_EX:
case ZEND_JMPNZ_EX:
case ZEND_CASE:
case ZEND_CASE_STRICT:
case ZEND_BOOL:
case ZEND_ISSET_ISEMPTY_CV:
case ZEND_ISSET_ISEMPTY_VAR:
case ZEND_ISSET_ISEMPTY_DIM_OBJ:
case ZEND_ISSET_ISEMPTY_PROP_OBJ:
case ZEND_ISSET_ISEMPTY_STATIC_PROP:
case ZEND_ASSERT_CHECK:
case ZEND_IN_ARRAY:
case ZEND_ARRAY_KEY_EXISTS:
UPDATE_SSA_TYPE(MAY_BE_FALSE|MAY_BE_TRUE, ssa_op->result_def);
break;
case ZEND_CAST:
if (ssa_op->op1_def >= 0) {
tmp = t1;
if ((t1 & (MAY_BE_ARRAY|MAY_BE_OBJECT)) &&
(opline->extended_value == IS_ARRAY ||
opline->extended_value == IS_OBJECT)) {
tmp |= MAY_BE_RCN;
} else if ((t1 & MAY_BE_STRING) &&
opline->extended_value == IS_STRING) {
tmp |= MAY_BE_RCN;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->op1_def);
}
tmp = 1 << opline->extended_value;
if (tmp & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) {
if ((tmp & MAY_BE_ANY) == (t1 & MAY_BE_ANY)) {
tmp |= (t1 & MAY_BE_RC1) | MAY_BE_RCN;
} else if ((opline->extended_value == IS_ARRAY ||
opline->extended_value == IS_OBJECT) &&
(t1 & (MAY_BE_ARRAY|MAY_BE_OBJECT))) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
} else if (opline->extended_value == IS_STRING &&
(t1 & (MAY_BE_STRING|MAY_BE_OBJECT))) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
} else {
tmp |= MAY_BE_RC1;
if (opline->extended_value == IS_ARRAY
&& (t1 & (MAY_BE_UNDEF|MAY_BE_NULL))) {
tmp |= MAY_BE_RCN;
}
}
}
if (opline->extended_value == IS_ARRAY) {
if (t1 & MAY_BE_ARRAY) {
tmp |= t1 & (MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF);
}
if (t1 & MAY_BE_OBJECT) {
tmp |= MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
} else if (t1 & (MAY_BE_ANY - MAY_BE_NULL)) {
tmp |= ((t1 & (MAY_BE_ANY - MAY_BE_NULL)) << MAY_BE_ARRAY_SHIFT) | ((t1 & MAY_BE_NULL) ? MAY_BE_ARRAY_KEY_LONG : MAY_BE_ARRAY_PACKED);
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
break;
case ZEND_QM_ASSIGN:
case ZEND_JMP_SET:
case ZEND_COALESCE:
case ZEND_COPY_TMP:
if (ssa_op->op1_def >= 0) {
tmp = t1;
if (t1 & (MAY_BE_RC1|MAY_BE_REF)) {
tmp |= MAY_BE_RCN;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->op1_def);
}
tmp = t1 & ~(MAY_BE_UNDEF|MAY_BE_REF);
if (t1 & MAY_BE_UNDEF) {
tmp |= MAY_BE_NULL;
}
if (t1 & (MAY_BE_RC1|MAY_BE_RCN)) {
tmp |= (t1 & (MAY_BE_RC1|MAY_BE_RCN));
if (opline->opcode == ZEND_COPY_TMP || opline->op1_type == IS_CV) {
tmp |= MAY_BE_RCN;
}
}
if (opline->opcode == ZEND_COALESCE || opline->opcode == ZEND_JMP_SET) {
/* COALESCE and JMP_SET result can't be null */
tmp &= ~MAY_BE_NULL;
if (opline->opcode == ZEND_JMP_SET) {
/* JMP_SET result can't be false either */
tmp &= ~MAY_BE_FALSE;
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->result_def);
break;
case ZEND_JMP_NULL:
{
uint32_t short_circuiting_type = opline->extended_value & ZEND_SHORT_CIRCUITING_CHAIN_MASK;
if (short_circuiting_type == ZEND_SHORT_CIRCUITING_CHAIN_EXPR) {
tmp = MAY_BE_NULL;
} else if (short_circuiting_type == ZEND_SHORT_CIRCUITING_CHAIN_ISSET) {
tmp = MAY_BE_FALSE;
} else {
ZEND_ASSERT(short_circuiting_type == ZEND_SHORT_CIRCUITING_CHAIN_EMPTY);
tmp = MAY_BE_TRUE;
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
break;
}
case ZEND_ASSIGN_OP:
case ZEND_ASSIGN_DIM_OP:
case ZEND_ASSIGN_OBJ_OP:
case ZEND_ASSIGN_STATIC_PROP_OP:
{
const zend_property_info *prop_info = NULL;
orig = 0;
tmp = 0;
if (opline->opcode == ZEND_ASSIGN_OBJ_OP) {
prop_info = zend_fetch_prop_info(op_array, ssa, opline, ssa_op);
orig = t1;
t1 = zend_fetch_prop_type(script, prop_info, NULL);
t2 = OP1_DATA_INFO();
} else if (opline->opcode == ZEND_ASSIGN_DIM_OP) {
if (t1 & MAY_BE_ARRAY_OF_REF) {
tmp |= MAY_BE_REF;
}
orig = t1;
t1 = zend_array_element_type(t1, opline->op1_type, 1, 0);
t2 = OP1_DATA_INFO();
} else if (opline->opcode == ZEND_ASSIGN_STATIC_PROP_OP) {
prop_info = zend_fetch_static_prop_info(script, op_array, ssa, opline);
t1 = zend_fetch_prop_type(script, prop_info, NULL);
t2 = OP1_DATA_INFO();
} else {
if (t1 & MAY_BE_REF) {
tmp |= MAY_BE_REF;
}
}
tmp |= binary_op_result_type(
ssa, opline->extended_value, t1, t2,
opline->opcode == ZEND_ASSIGN_OP ? ssa_op->op1_def : -1, optimization_level);
if (tmp & (MAY_BE_STRING|MAY_BE_ARRAY)) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
}
if (tmp & (MAY_BE_OBJECT|MAY_BE_RESOURCE)) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
}
if (opline->opcode == ZEND_ASSIGN_DIM_OP) {
if (opline->op1_type == IS_CV) {
orig = assign_dim_result_type(orig, OP2_INFO(), tmp, opline->op2_type);
UPDATE_SSA_TYPE(orig, ssa_op->op1_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->op1_def);
}
} else if (opline->opcode == ZEND_ASSIGN_OBJ_OP) {
if (opline->op1_type == IS_CV) {
orig = (orig & (MAY_BE_REF|MAY_BE_OBJECT))|MAY_BE_RC1|MAY_BE_RCN;
UPDATE_SSA_TYPE(orig, ssa_op->op1_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->op1_def);
}
} else if (opline->opcode == ZEND_ASSIGN_STATIC_PROP_OP) {
/* Nothing to do */
} else {
if (opline->opcode == ZEND_ASSIGN_OP && ssa_op->result_def >= 0 && (tmp & MAY_BE_RC1)) {
tmp |= MAY_BE_RCN;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
if (ssa_op->result_def >= 0) {
ce = NULL;
if (opline->opcode == ZEND_ASSIGN_DIM_OP) {
if (opline->op2_type == IS_UNUSED) {
/* When appending to an array and the LONG_MAX key is already used
* null will be returned. */
tmp |= MAY_BE_NULL;
}
if (t2 & (MAY_BE_ARRAY | MAY_BE_OBJECT)) {
/* Arrays and objects cannot be used as keys. */
tmp |= MAY_BE_NULL;
}
if (t1 & (MAY_BE_ANY - (MAY_BE_NULL | MAY_BE_FALSE | MAY_BE_STRING | MAY_BE_ARRAY))) {
/* null and false are implicitly converted to array, anything else
* results in a null return value. */
tmp |= MAY_BE_NULL;
}
if (tmp & MAY_BE_REF) {
/* Typed reference may cause auto conversion */
tmp |= MAY_BE_ANY;
}
} else if (opline->opcode == ZEND_ASSIGN_OBJ_OP) {
/* The return value must also satisfy the property type */
if (prop_info) {
t1 = zend_fetch_prop_type(script, prop_info, &ce);
if ((t1 & (MAY_BE_LONG|MAY_BE_DOUBLE)) == MAY_BE_LONG
&& (tmp & (MAY_BE_LONG|MAY_BE_DOUBLE)) == MAY_BE_DOUBLE) {
/* DOUBLE may be auto-converted to LONG */
tmp |= MAY_BE_LONG;
tmp &= ~MAY_BE_DOUBLE;
}
tmp &= t1;
}
} else if (opline->opcode == ZEND_ASSIGN_STATIC_PROP_OP) {
/* The return value must also satisfy the property type */
if (prop_info) {
t1 = zend_fetch_prop_type(script, prop_info, &ce);
if ((t1 & (MAY_BE_LONG|MAY_BE_DOUBLE)) == MAY_BE_LONG
&& (tmp & (MAY_BE_LONG|MAY_BE_DOUBLE)) == MAY_BE_DOUBLE) {
/* DOUBLE may be auto-converted to LONG */
tmp |= MAY_BE_LONG;
tmp &= ~MAY_BE_DOUBLE;
}
tmp &= t1;
}
} else {
if (tmp & MAY_BE_REF) {
/* Typed reference may cause auto conversion */
tmp |= MAY_BE_ANY;
}
}
tmp &= ~MAY_BE_REF;
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
if (ce) {
UPDATE_SSA_OBJ_TYPE(ce, 1, ssa_op->result_def);
}
}
break;
}
case ZEND_PRE_INC:
case ZEND_PRE_DEC:
tmp = 0;
if (t1 & (MAY_BE_RC1|MAY_BE_RCN)) {
tmp |= MAY_BE_RC1;
if (ssa_op->result_def >= 0) {
tmp |= MAY_BE_RCN;
}
}
if ((t1 & (MAY_BE_ANY|MAY_BE_UNDEF)) == MAY_BE_LONG) {
if (!ssa_var_info[ssa_op->op1_use].has_range ||
(opline->opcode == ZEND_PRE_DEC &&
(ssa_var_info[ssa_op->op1_use].range.underflow ||
ssa_var_info[ssa_op->op1_use].range.min == ZEND_LONG_MIN)) ||
(opline->opcode == ZEND_PRE_INC &&
(ssa_var_info[ssa_op->op1_use].range.overflow ||
ssa_var_info[ssa_op->op1_use].range.max == ZEND_LONG_MAX))) {
/* may overflow */
tmp |= MAY_BE_LONG | MAY_BE_DOUBLE;
} else {
tmp |= MAY_BE_LONG;
}
} else {
if (t1 & (MAY_BE_UNDEF | MAY_BE_NULL)) {
if (opline->opcode == ZEND_PRE_INC) {
tmp |= MAY_BE_LONG;
} else {
tmp |= MAY_BE_NULL;
}
}
if (t1 & MAY_BE_LONG) {
tmp |= MAY_BE_LONG | MAY_BE_DOUBLE;
}
if (t1 & MAY_BE_DOUBLE) {
tmp |= MAY_BE_DOUBLE;
}
if (t1 & MAY_BE_STRING) {
tmp |= MAY_BE_STRING | MAY_BE_LONG | MAY_BE_DOUBLE;
}
tmp |= t1 & (MAY_BE_FALSE | MAY_BE_TRUE | MAY_BE_OBJECT);
}
if (ssa_op->result_def >= 0) {
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
}
if (ssa_op->op1_def >= 0) {
if (t1 & MAY_BE_REF) {
tmp |= MAY_BE_REF;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
break;
case ZEND_POST_INC:
case ZEND_POST_DEC:
if (ssa_op->result_def >= 0) {
tmp = 0;
if (t1 & (MAY_BE_RC1|MAY_BE_RCN)) {
tmp |= MAY_BE_RC1|MAY_BE_RCN;
}
tmp |= t1 & ~(MAY_BE_UNDEF|MAY_BE_REF|MAY_BE_RCN);
if (t1 & MAY_BE_UNDEF) {
tmp |= MAY_BE_NULL;
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
}
tmp = 0;
if (t1 & MAY_BE_REF) {
tmp |= MAY_BE_REF;
}
if (t1 & (MAY_BE_RC1|MAY_BE_RCN)) {
tmp |= MAY_BE_RC1;
}
if ((t1 & (MAY_BE_ANY|MAY_BE_UNDEF)) == MAY_BE_LONG) {
if (!ssa_var_info[ssa_op->op1_use].has_range ||
(opline->opcode == ZEND_POST_DEC &&
(ssa_var_info[ssa_op->op1_use].range.underflow ||
ssa_var_info[ssa_op->op1_use].range.min == ZEND_LONG_MIN)) ||
(opline->opcode == ZEND_POST_INC &&
(ssa_var_info[ssa_op->op1_use].range.overflow ||
ssa_var_info[ssa_op->op1_use].range.max == ZEND_LONG_MAX))) {
/* may overflow */
tmp |= MAY_BE_LONG | MAY_BE_DOUBLE;
} else {
tmp |= MAY_BE_LONG;
}
} else {
if (t1 & (MAY_BE_UNDEF | MAY_BE_NULL)) {
if (opline->opcode == ZEND_POST_INC) {
tmp |= MAY_BE_LONG;
} else {
tmp |= MAY_BE_NULL;
}
}
if (t1 & MAY_BE_LONG) {
tmp |= MAY_BE_LONG | MAY_BE_DOUBLE;
}
if (t1 & MAY_BE_DOUBLE) {
tmp |= MAY_BE_DOUBLE;
}
if (t1 & MAY_BE_STRING) {
tmp |= MAY_BE_STRING | MAY_BE_LONG | MAY_BE_DOUBLE;
}
tmp |= t1 & (MAY_BE_FALSE | MAY_BE_TRUE | MAY_BE_RESOURCE | MAY_BE_ARRAY | MAY_BE_OBJECT | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF | MAY_BE_ARRAY_KEY_ANY);
}
if (ssa_op->op1_def >= 0) {
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
break;
case ZEND_ASSIGN_DIM:
if (opline->op1_type == IS_CV) {
tmp = assign_dim_result_type(t1, t2, OP1_DATA_INFO(), opline->op2_type);
tmp |= ssa->var_info[ssa_op->op1_def].type & (MAY_BE_ARRAY_PACKED|MAY_BE_ARRAY_NUMERIC_HASH|MAY_BE_ARRAY_STRING_HASH);
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->op1_def);
}
if (ssa_op->result_def >= 0) {
tmp = 0;
if (t1 & MAY_BE_STRING) {
tmp |= MAY_BE_STRING | MAY_BE_NULL;
}
if (t1 & MAY_BE_OBJECT) {
tmp |= (MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF);
}
if (t1 & (MAY_BE_ARRAY|MAY_BE_FALSE|MAY_BE_NULL|MAY_BE_UNDEF)) {
tmp |= (OP1_DATA_INFO() & (MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF));
if (OP1_DATA_INFO() & MAY_BE_UNDEF) {
tmp |= MAY_BE_NULL;
}
if (t1 & MAY_BE_ARRAY_OF_REF) {
/* A scalar type conversion may occur when assigning to a typed reference. */
tmp |= MAY_BE_NULL|MAY_BE_FALSE|MAY_BE_TRUE|MAY_BE_LONG|MAY_BE_DOUBLE|MAY_BE_STRING;
}
}
if (t1 & (MAY_BE_TRUE|MAY_BE_LONG|MAY_BE_DOUBLE|MAY_BE_RESOURCE)) {
tmp |= MAY_BE_NULL;
}
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
}
if ((ssa_op+1)->op1_def >= 0) {
opline++;
ssa_op++;
tmp = OP1_INFO();
if (tmp & (MAY_BE_ANY | MAY_BE_REF)) {
if (tmp & MAY_BE_RC1) {
tmp |= MAY_BE_RCN;
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
break;
case ZEND_ASSIGN_OBJ:
if (opline->op1_type == IS_CV) {
tmp = (t1 & (MAY_BE_REF|MAY_BE_OBJECT))|MAY_BE_RC1|MAY_BE_RCN;
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->op1_def);
}
if (ssa_op->result_def >= 0) {
// TODO: If there is no __set we might do better
tmp = zend_fetch_prop_type(script,
zend_fetch_prop_info(op_array, ssa, opline, ssa_op), &ce);
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
if (ce) {
UPDATE_SSA_OBJ_TYPE(ce, 1, ssa_op->result_def);
}
}
if ((ssa_op+1)->op1_def >= 0) {
opline++;
ssa_op++;
tmp = OP1_INFO();
if (tmp & MAY_BE_RC1) {
tmp |= MAY_BE_RCN;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
break;
case ZEND_ASSIGN_STATIC_PROP:
if (ssa_op->result_def >= 0) {
tmp = MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF | MAY_BE_RC1 | MAY_BE_RCN;
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
}
if ((ssa_op+1)->op1_def >= 0) {
opline++;
ssa_op++;
tmp = OP1_INFO();
if (tmp & MAY_BE_RC1) {
tmp |= MAY_BE_RCN;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
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) {
tmp = (t1 & (MAY_BE_REF|MAY_BE_OBJECT))|MAY_BE_RC1|MAY_BE_RCN;
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->op1_def);
}
if (ssa_op->result_def >= 0) {
// TODO: ???
tmp = MAY_BE_RC1 | MAY_BE_RCN | MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
}
break;
case ZEND_ASSIGN:
if (ssa_op->op2_def >= 0) {
tmp = t2;
if (tmp & MAY_BE_RC1) {
tmp |= MAY_BE_RCN;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op2_def);
}
tmp = t2 & ~(MAY_BE_UNDEF|MAY_BE_REF|MAY_BE_RC1|MAY_BE_RCN);
if (t2 & MAY_BE_UNDEF) {
tmp |= MAY_BE_NULL;
}
if (t1 & MAY_BE_REF) {
tmp |= MAY_BE_REF;
}
if (t2 & MAY_BE_REF) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
} else if (opline->op2_type & (IS_TMP_VAR|IS_VAR)) {
tmp |= t2 & (MAY_BE_RC1|MAY_BE_RCN);
} else if (t2 & (MAY_BE_RC1|MAY_BE_RCN)) {
tmp |= MAY_BE_RCN;
}
if (RETURN_VALUE_USED(opline) && (tmp & MAY_BE_RC1)) {
tmp |= MAY_BE_RCN;
}
if (ssa_op->op1_def >= 0) {
if (ssa_var_info[ssa_op->op1_def].use_as_double) {
tmp &= ~MAY_BE_LONG;
tmp |= MAY_BE_DOUBLE;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
COPY_SSA_OBJ_TYPE(ssa_op->op2_use, ssa_op->op1_def);
}
if (ssa_op->result_def >= 0) {
if (tmp & MAY_BE_REF) {
/* A scalar type conversion may occur when assigning to a typed reference. */
tmp &= ~MAY_BE_REF;
tmp |= MAY_BE_NULL|MAY_BE_FALSE|MAY_BE_TRUE|MAY_BE_LONG|MAY_BE_DOUBLE|MAY_BE_STRING|MAY_BE_RC1|MAY_BE_RCN;
}
if ((tmp & (MAY_BE_RC1|MAY_BE_RCN)) == MAY_BE_RCN) {
/* refcount may be indirectly decremented. Make an exception if the result is used in the next instruction */
if (!ssa_opcodes) {
if (ssa->vars[ssa_op->result_def].use_chain < 0
|| opline + 1 != op_array->opcodes + ssa->vars[ssa_op->result_def].use_chain) {
tmp |= MAY_BE_RC1;
}
} else {
if (ssa->vars[ssa_op->result_def].use_chain < 0
|| opline + 1 != ssa_opcodes[ssa->vars[ssa_op->result_def].use_chain]) {
tmp |= MAY_BE_RC1;
}
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
COPY_SSA_OBJ_TYPE(ssa_op->op2_use, ssa_op->result_def);
}
break;
case ZEND_ASSIGN_REF:
// TODO: ???
if (opline->op2_type == IS_CV) {
tmp = (MAY_BE_REF | t2) & ~(MAY_BE_UNDEF|MAY_BE_RC1|MAY_BE_RCN);
if (t2 & MAY_BE_UNDEF) {
tmp |= MAY_BE_NULL;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op2_def);
}
if (opline->op2_type == IS_VAR && opline->extended_value == ZEND_RETURNS_FUNCTION) {
tmp = (MAY_BE_REF | MAY_BE_RCN | MAY_BE_RC1 | t2) & ~MAY_BE_UNDEF;
} else {
tmp = (MAY_BE_REF | t2) & ~(MAY_BE_UNDEF|MAY_BE_RC1|MAY_BE_RCN);
}
if (t2 & MAY_BE_UNDEF) {
tmp |= MAY_BE_NULL;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
if (ssa_op->result_def >= 0) {
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
}
break;
case ZEND_ASSIGN_OBJ_REF:
if (opline->op1_type == IS_CV) {
tmp = t1;
if (tmp & MAY_BE_OBJECT) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->op1_def);
}
t2 = OP1_DATA_INFO();
if ((opline+1)->op1_type == IS_VAR && (opline->extended_value & ZEND_RETURNS_FUNCTION)) {
tmp = (MAY_BE_REF | MAY_BE_RCN | MAY_BE_RC1 | t2) & ~MAY_BE_UNDEF;
} else {
tmp = (MAY_BE_REF | t2) & ~(MAY_BE_UNDEF|MAY_BE_RC1|MAY_BE_RCN);
}
if (t2 & MAY_BE_UNDEF) {
tmp |= MAY_BE_NULL;
}
if (ssa_op->result_def >= 0) {
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
}
if ((opline+1)->op1_type == IS_CV) {
opline++;
ssa_op++;
tmp = (MAY_BE_REF | t2) & ~(MAY_BE_UNDEF|MAY_BE_RC1|MAY_BE_RCN);
if (t2 & MAY_BE_UNDEF) {
tmp |= MAY_BE_NULL;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
break;
case ZEND_ASSIGN_STATIC_PROP_REF:
if (ssa_op->result_def >= 0) {
UPDATE_SSA_TYPE(MAY_BE_REF, ssa_op->result_def);
}
if ((opline+1)->op1_type == IS_CV) {
opline++;
ssa_op++;
UPDATE_SSA_TYPE(MAY_BE_REF, ssa_op->op1_def);
}
break;
case ZEND_BIND_GLOBAL:
tmp = MAY_BE_REF | MAY_BE_ANY
| MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
break;
case ZEND_BIND_STATIC:
tmp = MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF
| ((opline->extended_value & ZEND_BIND_REF) ? MAY_BE_REF : (MAY_BE_RC1 | MAY_BE_RCN));
if (opline->extended_value & ZEND_BIND_IMPLICIT) {
tmp |= MAY_BE_UNDEF;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
break;
case ZEND_BIND_INIT_STATIC_OR_JMP:
tmp = MAY_BE_UNDEF | MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF | MAY_BE_REF;
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
break;
case ZEND_SEND_VAR:
if (ssa_op->op1_def >= 0) {
tmp = t1;
if (t1 & (MAY_BE_RC1|MAY_BE_REF)) {
tmp |= MAY_BE_RCN;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->op1_def);
}
break;
case ZEND_BIND_LEXICAL:
if (ssa_op->op2_def >= 0) {
if (opline->extended_value & ZEND_BIND_REF) {
tmp = t2 | MAY_BE_REF;
} else {
tmp = t2 & ~(MAY_BE_RC1|MAY_BE_RCN);
if (t2 & (MAY_BE_RC1|MAY_BE_RCN)) {
tmp |= MAY_BE_RCN;
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->op2_def);
COPY_SSA_OBJ_TYPE(ssa_op->op2_use, ssa_op->op2_def);
}
break;
case ZEND_YIELD:
if (ssa_op->op1_def >= 0) {
if (op_array->fn_flags & ZEND_ACC_RETURN_REFERENCE) {
tmp = t1 | MAY_BE_REF;
} else {
tmp = t1 & ~(MAY_BE_RC1|MAY_BE_RCN);
if (t1 & (MAY_BE_RC1|MAY_BE_RCN)) {
tmp |= MAY_BE_RCN;
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->op1_def);
}
if (ssa_op->result_def >= 0) {
tmp = MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF
| MAY_BE_RC1 | MAY_BE_RCN;
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
}
break;
case ZEND_SEND_VAR_EX:
case ZEND_SEND_FUNC_ARG:
if (ssa_op->op1_def >= 0) {
tmp = (t1 & MAY_BE_UNDEF)|MAY_BE_REF|MAY_BE_RC1|MAY_BE_RCN|MAY_BE_ANY|MAY_BE_ARRAY_KEY_ANY|MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF;
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
break;
case ZEND_SEND_REF:
if (ssa_op->op1_def >= 0) {
tmp = MAY_BE_REF|MAY_BE_RC1|MAY_BE_RCN|MAY_BE_ANY|MAY_BE_ARRAY_KEY_ANY|MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF;
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
break;
case ZEND_SEND_UNPACK:
if (ssa_op->op1_def >= 0) {
tmp = t1;
if (t1 & MAY_BE_ARRAY) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
if (t1 & MAY_BE_ARRAY_OF_ANY) {
/* SEND_UNPACK may acquire references into the array */
tmp |= MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
}
}
if (t1 & MAY_BE_OBJECT) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
break;
case ZEND_FAST_CONCAT:
case ZEND_ROPE_INIT:
case ZEND_ROPE_ADD:
case ZEND_ROPE_END:
UPDATE_SSA_TYPE(MAY_BE_STRING|MAY_BE_RC1|MAY_BE_RCN, ssa_op->result_def);
break;
case ZEND_RECV:
case ZEND_RECV_INIT:
case ZEND_RECV_VARIADIC:
{
/* Typehinting */
zend_arg_info *arg_info = &op_array->arg_info[opline->op1.num-1];
ce = NULL;
tmp = zend_fetch_arg_info_type(script, arg_info, &ce);
if (ZEND_ARG_SEND_MODE(arg_info)) {
tmp |= MAY_BE_REF;
ce = NULL;
}
if (opline->opcode == ZEND_RECV_VARIADIC) {
uint32_t elem_type = tmp & MAY_BE_REF
? MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF
: (tmp & MAY_BE_ANY) << MAY_BE_ARRAY_SHIFT;
tmp = MAY_BE_RC1|MAY_BE_RCN|MAY_BE_ARRAY|MAY_BE_ARRAY_KEY_ANY|elem_type;
ce = NULL;
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
if (ce) {
UPDATE_SSA_OBJ_TYPE(ce, 1, ssa_op->result_def);
} else {
UPDATE_SSA_OBJ_TYPE(NULL, 0, ssa_op->result_def);
}
break;
}
case ZEND_DECLARE_ANON_CLASS:
UPDATE_SSA_TYPE(MAY_BE_CLASS, ssa_op->result_def);
if (script && (ce = zend_hash_find_ptr(&script->class_table, Z_STR_P(CRT_CONSTANT(opline->op1)))) != NULL) {
UPDATE_SSA_OBJ_TYPE(ce, 0, ssa_op->result_def);
}
break;
case ZEND_FETCH_CLASS:
UPDATE_SSA_TYPE(MAY_BE_CLASS, ssa_op->result_def);
if (opline->op2_type == IS_UNUSED) {
switch (opline->op1.num & ZEND_FETCH_CLASS_MASK) {
case ZEND_FETCH_CLASS_SELF:
if (op_array->scope) {
UPDATE_SSA_OBJ_TYPE(op_array->scope, 0, ssa_op->result_def);
} else {
UPDATE_SSA_OBJ_TYPE(NULL, 0, ssa_op->result_def);
}
break;
case ZEND_FETCH_CLASS_PARENT:
if (op_array->scope && op_array->scope->parent && (op_array->scope->ce_flags & ZEND_ACC_LINKED)) {
UPDATE_SSA_OBJ_TYPE(op_array->scope->parent, 0, ssa_op->result_def);
} else {
UPDATE_SSA_OBJ_TYPE(NULL, 0, ssa_op->result_def);
}
break;
case ZEND_FETCH_CLASS_STATIC:
default:
UPDATE_SSA_OBJ_TYPE(NULL, 0, ssa_op->result_def);
break;
}
} else if (opline->op2_type == IS_CONST) {
zval *zv = CRT_CONSTANT(opline->op2);
if (Z_TYPE_P(zv) == IS_STRING) {
ce = zend_optimizer_get_class_entry(script, op_array, Z_STR_P(zv+1));
UPDATE_SSA_OBJ_TYPE(ce, 0, ssa_op->result_def);
} else {
UPDATE_SSA_OBJ_TYPE(NULL, 0, ssa_op->result_def);
}
} else {
COPY_SSA_OBJ_TYPE(ssa_op->op2_use, ssa_op->result_def);
}
break;
case ZEND_NEW:
tmp = MAY_BE_RC1|MAY_BE_RCN|MAY_BE_OBJECT;
ce = zend_optimizer_get_class_entry_from_op1(script, op_array, opline);
if (ce) {
UPDATE_SSA_OBJ_TYPE(ce, 0, ssa_op->result_def);
} else if ((t1 & MAY_BE_CLASS) && ssa_op->op1_use >= 0 && ssa_var_info[ssa_op->op1_use].ce) {
UPDATE_SSA_OBJ_TYPE(ssa_var_info[ssa_op->op1_use].ce, ssa_var_info[ssa_op->op1_use].is_instanceof, ssa_op->result_def);
} else {
UPDATE_SSA_OBJ_TYPE(NULL, 0, ssa_op->result_def);
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
break;
case ZEND_CLONE:
UPDATE_SSA_TYPE(MAY_BE_RC1|MAY_BE_RCN|MAY_BE_OBJECT, ssa_op->result_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->result_def);
break;
case ZEND_INIT_ARRAY:
case ZEND_ADD_ARRAY_ELEMENT:
if (ssa_op->op1_def >= 0) {
if (opline->extended_value & ZEND_ARRAY_ELEMENT_REF) {
tmp = (MAY_BE_REF | t1) & ~(MAY_BE_UNDEF|MAY_BE_RC1|MAY_BE_RCN);
if (t1 & MAY_BE_UNDEF) {
tmp |= MAY_BE_NULL;
}
} else if ((t1 & (MAY_BE_REF|MAY_BE_RC1|MAY_BE_RCN)) == MAY_BE_REF) {
tmp = (MAY_BE_REF | t1) & ~(MAY_BE_UNDEF|MAY_BE_RC1|MAY_BE_RCN);
if (t1 & MAY_BE_UNDEF) {
tmp |= MAY_BE_NULL;
}
} else if (t1 & MAY_BE_REF) {
tmp = (MAY_BE_RC1 | MAY_BE_RCN | MAY_BE_REF | t1);
} else {
tmp = t1;
if (t1 & MAY_BE_RC1) {
tmp |= MAY_BE_RCN;
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
if (ssa_op->result_def >= 0) {
uint32_t arr_type;
if (opline->opcode == ZEND_INIT_ARRAY) {
arr_type = 0;
} else {
arr_type = RES_USE_INFO();
}
tmp = MAY_BE_RC1|MAY_BE_ARRAY|arr_type;
if (opline->op1_type != IS_UNUSED
&& (opline->op2_type == IS_UNUSED
|| (t2 & (MAY_BE_UNDEF|MAY_BE_NULL|MAY_BE_FALSE|MAY_BE_TRUE|MAY_BE_LONG|MAY_BE_DOUBLE|MAY_BE_RESOURCE|MAY_BE_STRING)))) {
tmp |= assign_dim_array_result_type(arr_type, t2, t1, opline->op2_type);
if (opline->extended_value & ZEND_ARRAY_ELEMENT_REF) {
tmp |= MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF;
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
}
break;
case ZEND_ADD_ARRAY_UNPACK:
tmp = ssa_var_info[ssa_op->result_use].type;
ZEND_ASSERT(tmp & MAY_BE_ARRAY);
tmp |= t1 & (MAY_BE_ARRAY_KEY_ANY|MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF);
if (t1 & MAY_BE_OBJECT) {
tmp |= MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY;
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
break;
case ZEND_UNSET_CV:
tmp = MAY_BE_UNDEF;
if (!op_array->function_name) {
/* In global scope, we know nothing */
tmp |= MAY_BE_REF;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
break;
case ZEND_UNSET_DIM:
case ZEND_UNSET_OBJ:
if (ssa_op->op1_def >= 0) {
UPDATE_SSA_TYPE(t1, ssa_op->op1_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->op1_def);
}
break;
case ZEND_FE_RESET_R:
case ZEND_FE_RESET_RW:
if (ssa_op->op1_def >= 0) {
tmp = t1;
if (opline->opcode == ZEND_FE_RESET_RW) {
tmp |= MAY_BE_REF;
} else if (t1 & MAY_BE_RC1) {
tmp |= MAY_BE_RCN;
}
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->op1_def);
}
if (opline->opcode == ZEND_FE_RESET_RW) {
//???
tmp = MAY_BE_REF | (t1 & (MAY_BE_ARRAY | MAY_BE_OBJECT));
} else {
tmp = MAY_BE_RC1 | MAY_BE_RCN | (t1 & (MAY_BE_ARRAY | MAY_BE_OBJECT | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF));
}
/* The result is set to UNDEF for invalid foreach inputs. */
if ((t1 & (MAY_BE_ANY | MAY_BE_UNDEF)) & ~(MAY_BE_ARRAY | MAY_BE_OBJECT)) {
tmp |= MAY_BE_UNDEF;
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->result_def);
break;
case ZEND_FE_FETCH_R:
case ZEND_FE_FETCH_RW:
tmp = 0;
if (opline->op2_type == IS_CV) {
tmp = t2 & MAY_BE_REF;
}
if (t1 & MAY_BE_OBJECT) {
if (opline->opcode == ZEND_FE_FETCH_RW) {
tmp |= MAY_BE_REF | MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
} else {
tmp |= MAY_BE_RCN | MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
if (opline->op2_type != IS_CV) {
tmp |= MAY_BE_REF;
}
}
}
if (t1 & MAY_BE_ARRAY) {
if (opline->opcode == ZEND_FE_FETCH_RW) {
tmp |= MAY_BE_REF | MAY_BE_RCN | MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
} else {
tmp |= ((t1 & MAY_BE_ARRAY_OF_ANY) >> MAY_BE_ARRAY_SHIFT);
if (tmp & MAY_BE_ARRAY) {
tmp |= MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
}
if (t1 & MAY_BE_ARRAY_OF_REF) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
if (opline->op2_type != IS_CV) {
tmp |= MAY_BE_REF;
}
} else if (tmp & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
}
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->op2_def);
if (ssa_op->result_def >= 0) {
tmp = (ssa_op->result_use >= 0) ? RES_USE_INFO() : 0;
if (t1 & MAY_BE_OBJECT) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN | MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
}
if (t1 & MAY_BE_ARRAY) {
if (t1 & MAY_BE_ARRAY_KEY_LONG) {
tmp |= MAY_BE_LONG;
}
if (t1 & MAY_BE_ARRAY_KEY_STRING) {
tmp |= MAY_BE_STRING | MAY_BE_RCN;
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
}
break;
case ZEND_FETCH_DIM_R:
case ZEND_FETCH_DIM_IS:
case ZEND_FETCH_DIM_RW:
case ZEND_FETCH_DIM_W:
case ZEND_FETCH_DIM_UNSET:
case ZEND_FETCH_DIM_FUNC_ARG:
case ZEND_FETCH_LIST_R:
case ZEND_FETCH_LIST_W:
if (ssa_op->op1_def >= 0) {
uint32_t key_type = 0;
tmp = t1 & ~(MAY_BE_RC1|MAY_BE_RCN);
if (opline->opcode == ZEND_FETCH_DIM_W ||
opline->opcode == ZEND_FETCH_DIM_RW ||
opline->opcode == ZEND_FETCH_DIM_FUNC_ARG ||
opline->opcode == ZEND_FETCH_LIST_W) {
if (t1 & (MAY_BE_UNDEF|MAY_BE_NULL|MAY_BE_FALSE)) {
if (opline->opcode != ZEND_FETCH_DIM_FUNC_ARG) {
tmp &= ~(MAY_BE_UNDEF|MAY_BE_NULL|MAY_BE_FALSE);
}
tmp |= MAY_BE_ARRAY | MAY_BE_RC1;
}
if (t1 & (MAY_BE_STRING|MAY_BE_ARRAY)) {
tmp |= MAY_BE_RC1;
if (opline->opcode == ZEND_FETCH_DIM_FUNC_ARG) {
tmp |= t1 & MAY_BE_RCN;
}
}
if (t1 & (MAY_BE_OBJECT|MAY_BE_RESOURCE)) {
tmp |= t1 & (MAY_BE_RC1|MAY_BE_RCN);
}
if (opline->op2_type == IS_UNUSED) {
if (t1 & (MAY_BE_UNDEF|MAY_BE_NULL|MAY_BE_FALSE)) {
key_type |= MAY_BE_ARRAY_PACKED;
}
if (t1 & MAY_BE_ARRAY) {
key_type |= MAY_BE_HASH_ONLY(t1) ?
MAY_BE_ARRAY_NUMERIC_HASH : MAY_BE_ARRAY_KEY_LONG;
}
} else {
if (t2 & (MAY_BE_LONG|MAY_BE_FALSE|MAY_BE_TRUE|MAY_BE_RESOURCE|MAY_BE_DOUBLE)) {
if (t1 & (MAY_BE_UNDEF|MAY_BE_NULL|MAY_BE_FALSE)) {
key_type |= MAY_BE_ARRAY_PACKED;
}
if (t1 & MAY_BE_ARRAY) {
key_type |= MAY_BE_HASH_ONLY(t1) ?
MAY_BE_ARRAY_NUMERIC_HASH : MAY_BE_ARRAY_KEY_LONG;
}
}
if (t2 & MAY_BE_STRING) {
key_type |= MAY_BE_ARRAY_KEY_STRING;
if (opline->op2_type != IS_CONST) {
// FIXME: numeric string
if (t1 & (MAY_BE_UNDEF|MAY_BE_NULL|MAY_BE_FALSE)) {
key_type |= MAY_BE_ARRAY_PACKED;
}
if (t1 & MAY_BE_ARRAY) {
key_type |= MAY_BE_HASH_ONLY(t1) ?
MAY_BE_ARRAY_NUMERIC_HASH : MAY_BE_ARRAY_KEY_LONG;
}
}
}
if (t2 & (MAY_BE_UNDEF | MAY_BE_NULL)) {
key_type |= MAY_BE_ARRAY_KEY_STRING;
}
}
} else if (opline->opcode == ZEND_FETCH_DIM_UNSET) {
if (t1 & MAY_BE_ARRAY) {
tmp |= MAY_BE_RC1;
}
if (t1 & (MAY_BE_OBJECT|MAY_BE_RESOURCE)) {
tmp |= t1 & (MAY_BE_RC1|MAY_BE_RCN);
}
}
if ((key_type & (MAY_BE_ARRAY_KEY_LONG|MAY_BE_ARRAY_KEY_STRING))
&& (opline->opcode == ZEND_FETCH_DIM_RW
|| opline->opcode == ZEND_FETCH_DIM_W
|| opline->opcode == ZEND_FETCH_DIM_FUNC_ARG
|| opline->opcode == ZEND_FETCH_LIST_W)) {
j = ssa_vars[ssa_op->result_def].use_chain;
if (j < 0) {
/* no uses */
tmp |= key_type | MAY_BE_ARRAY | MAY_BE_ARRAY_OF_NULL;
}
while (j >= 0) {
uint8_t opcode;
if (!ssa_opcodes) {
ZEND_ASSERT(j == (opline - op_array->opcodes) + 1 && "Use must be in next opline");
opcode = op_array->opcodes[j].opcode;
} else {
ZEND_ASSERT(ssa_opcodes[j] == opline + 1 && "Use must be in next opline");
opcode = ssa_opcodes[j]->opcode;
}
switch (opcode) {
case ZEND_FETCH_DIM_W:
case ZEND_FETCH_DIM_RW:
case ZEND_FETCH_DIM_FUNC_ARG:
case ZEND_FETCH_LIST_W:
case ZEND_ASSIGN_DIM:
case ZEND_ASSIGN_DIM_OP:
tmp |= key_type | MAY_BE_ARRAY | MAY_BE_ARRAY_OF_ARRAY;
break;
case ZEND_SEND_VAR_EX:
case ZEND_SEND_FUNC_ARG:
case ZEND_SEND_VAR_NO_REF:
case ZEND_SEND_VAR_NO_REF_EX:
case ZEND_SEND_REF:
case ZEND_ASSIGN_REF:
case ZEND_YIELD:
case ZEND_INIT_ARRAY:
case ZEND_ADD_ARRAY_ELEMENT:
case ZEND_RETURN_BY_REF:
case ZEND_VERIFY_RETURN_TYPE:
case ZEND_MAKE_REF:
case ZEND_FE_RESET_RW:
tmp |= key_type | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
break;
case ZEND_PRE_INC:
case ZEND_PRE_DEC:
case ZEND_POST_INC:
case ZEND_POST_DEC:
if (tmp & MAY_BE_ARRAY_OF_LONG) {
/* may overflow */
tmp |= key_type | MAY_BE_ARRAY_OF_DOUBLE;
} else if (!(tmp & (MAY_BE_ARRAY_OF_LONG|MAY_BE_ARRAY_OF_DOUBLE))) {
tmp |= key_type | MAY_BE_ARRAY_OF_LONG | MAY_BE_ARRAY_OF_DOUBLE;
}
break;
case ZEND_FETCH_OBJ_W:
case ZEND_FETCH_OBJ_RW:
case ZEND_FETCH_OBJ_FUNC_ARG:
case ZEND_ASSIGN_OBJ:
case ZEND_ASSIGN_OBJ_OP:
case ZEND_ASSIGN_OBJ_REF:
case ZEND_PRE_INC_OBJ:
case ZEND_PRE_DEC_OBJ:
case ZEND_POST_INC_OBJ:
case ZEND_POST_DEC_OBJ:
/* These will result in an error exception, unless the element
* is already an object. */
break;
case ZEND_SEND_VAR:
case ZEND_FETCH_DIM_R:
/* This can occur if a DIM_FETCH_FUNC_ARG with UNUSED op2 is left
* behind, because it can't be converted to DIM_FETCH_R. */
break;
case ZEND_FREE:
/* This may happen if the using opcode is DCEd. */
break;
EMPTY_SWITCH_DEFAULT_CASE()
}
j = zend_ssa_next_use(ssa->ops, ssa_op->result_def, j);
ZEND_ASSERT(j < 0 && "There should only be one use");
}
}
if (((tmp & MAY_BE_ARRAY) && (tmp & MAY_BE_ARRAY_KEY_ANY))
|| opline->opcode == ZEND_FETCH_DIM_FUNC_ARG
|| opline->opcode == ZEND_FETCH_DIM_R
|| opline->opcode == ZEND_FETCH_DIM_IS
|| opline->opcode == ZEND_FETCH_DIM_UNSET
|| opline->opcode == ZEND_FETCH_LIST_R) {
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
} else {
/* invalid key type */
tmp = (tmp & (MAY_BE_RC1|MAY_BE_RCN|MAY_BE_ARRAY)) |
(t1 & ~(MAY_BE_RC1|MAY_BE_RCN|MAY_BE_UNDEF|MAY_BE_NULL|MAY_BE_FALSE));
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
COPY_SSA_OBJ_TYPE(ssa_op->op1_use, ssa_op->op1_def);
}
/* FETCH_LIST on a string behaves like FETCH_R on null */
tmp = zend_array_element_type(
opline->opcode != ZEND_FETCH_LIST_R ? t1 : ((t1 & ~MAY_BE_STRING) | MAY_BE_NULL),
opline->op1_type,
opline->opcode != ZEND_FETCH_DIM_R && opline->opcode != ZEND_FETCH_DIM_IS
&& opline->opcode != ZEND_FETCH_LIST_R,
opline->op2_type == IS_UNUSED);
if (opline->opcode == ZEND_FETCH_DIM_FUNC_ARG && (t1 & (MAY_BE_TRUE|MAY_BE_LONG|MAY_BE_DOUBLE|MAY_BE_RESOURCE))) {
tmp |= MAY_BE_NULL;
}
if (opline->opcode == ZEND_FETCH_DIM_IS && (t1 & MAY_BE_STRING)) {
tmp |= MAY_BE_NULL;
}
if ((tmp & (MAY_BE_RC1|MAY_BE_RCN)) == MAY_BE_RCN && opline->result_type == IS_TMP_VAR) {
/* refcount may be indirectly decremented. Make an exception if the result is used in the next instruction */
if (!ssa_opcodes) {
if (ssa->vars[ssa_op->result_def].use_chain < 0
|| opline + 1 != op_array->opcodes + ssa->vars[ssa_op->result_def].use_chain) {
tmp |= MAY_BE_RC1;
}
} else {
if (ssa->vars[ssa_op->result_def].use_chain < 0
|| opline + 1 != ssa_opcodes[ssa->vars[ssa_op->result_def].use_chain]) {
tmp |= MAY_BE_RC1;
}
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
break;
case ZEND_FETCH_THIS:
UPDATE_SSA_OBJ_TYPE(op_array->scope, 1, ssa_op->result_def);
UPDATE_SSA_TYPE(MAY_BE_RCN|MAY_BE_OBJECT, ssa_op->result_def);
break;
case ZEND_FETCH_OBJ_R:
case ZEND_FETCH_OBJ_IS:
case ZEND_FETCH_OBJ_RW:
case ZEND_FETCH_OBJ_W:
case ZEND_FETCH_OBJ_UNSET:
case ZEND_FETCH_OBJ_FUNC_ARG:
if (ssa_op->result_def >= 0) {
uint32_t tmp = 0;
ce = NULL;
if (opline->op1_type != IS_UNUSED
&& (t1 & (MAY_BE_ANY | MAY_BE_UNDEF) & ~MAY_BE_OBJECT)) {
tmp |= MAY_BE_NULL;
}
if (opline->op1_type == IS_UNUSED || (t1 & MAY_BE_OBJECT)) {
const zend_property_info *prop_info = zend_fetch_prop_info(op_array, ssa, opline, ssa_op);
tmp |= zend_fetch_prop_type(script, prop_info, &ce);
if (opline->opcode != ZEND_FETCH_OBJ_R && opline->opcode != ZEND_FETCH_OBJ_IS) {
tmp |= MAY_BE_REF | MAY_BE_INDIRECT;
if ((opline->extended_value & ZEND_FETCH_OBJ_FLAGS) == ZEND_FETCH_DIM_WRITE) {
tmp |= MAY_BE_UNDEF;
}
ce = NULL;
} else if (!(opline->op1_type & (IS_VAR|IS_TMP_VAR)) || !(t1 & MAY_BE_RC1)) {
const zend_class_entry *ce = NULL;
if (opline->op1_type == IS_UNUSED) {
ce = op_array->scope;
} else if (ssa_op->op1_use >= 0 && !ssa->var_info[ssa_op->op1_use].is_instanceof) {
ce = ssa->var_info[ssa_op->op1_use].ce;
}
/* Unset properties will resort back to __get/__set */
if (ce
&& !ce->create_object
&& !ce->__get
&& !result_may_be_separated(ssa, ssa_op)) {
tmp &= ~MAY_BE_RC1;
}
if (opline->opcode == ZEND_FETCH_OBJ_IS) {
/* IS check may return null for uninitialized typed property. */
tmp |= MAY_BE_NULL;
}
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
if (ce) {
UPDATE_SSA_OBJ_TYPE(ce, 1, ssa_op->result_def);
}
}
break;
case ZEND_FETCH_STATIC_PROP_R:
case ZEND_FETCH_STATIC_PROP_IS:
case ZEND_FETCH_STATIC_PROP_RW:
case ZEND_FETCH_STATIC_PROP_W:
case ZEND_FETCH_STATIC_PROP_UNSET:
case ZEND_FETCH_STATIC_PROP_FUNC_ARG:
tmp = zend_fetch_prop_type(script,
zend_fetch_static_prop_info(script, op_array, ssa, opline), &ce);
if (opline->opcode != ZEND_FETCH_STATIC_PROP_R
&& opline->opcode != ZEND_FETCH_STATIC_PROP_IS) {
tmp |= MAY_BE_REF | MAY_BE_INDIRECT;
if ((opline->extended_value & ZEND_FETCH_OBJ_FLAGS) == ZEND_FETCH_DIM_WRITE) {
tmp |= MAY_BE_UNDEF;
}
ce = NULL;
} else {
if (!result_may_be_separated(ssa, ssa_op)) {
tmp &= ~MAY_BE_RC1;
}
if (opline->opcode == ZEND_FETCH_STATIC_PROP_IS) {
tmp |= MAY_BE_UNDEF;
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
if (ce) {
UPDATE_SSA_OBJ_TYPE(ce, 1, ssa_op->result_def);
}
break;
case ZEND_DO_FCALL:
case ZEND_DO_ICALL:
case ZEND_DO_UCALL:
case ZEND_DO_FCALL_BY_NAME:
if (ssa_op->result_def >= 0) {
zend_func_info *func_info = ZEND_FUNC_INFO(op_array);
zend_call_info *call_info;
if (!func_info || !func_info->call_map) {
goto unknown_opcode;
}
call_info = func_info->call_map[opline - op_array->opcodes];
if (!call_info) {
goto unknown_opcode;
}
zend_class_entry *ce;
bool ce_is_instanceof;
tmp = zend_get_func_info(call_info, ssa, &ce, &ce_is_instanceof);
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
if (ce) {
UPDATE_SSA_OBJ_TYPE(ce, ce_is_instanceof, ssa_op->result_def);
}
}
break;
case ZEND_CALLABLE_CONVERT:
UPDATE_SSA_TYPE(MAY_BE_OBJECT | MAY_BE_RC1 | MAY_BE_RCN, ssa_op->result_def);
UPDATE_SSA_OBJ_TYPE(zend_ce_closure, /* is_instanceof */ false, ssa_op->result_def);
break;
case ZEND_FETCH_CONSTANT:
case ZEND_FETCH_CLASS_CONSTANT:
UPDATE_SSA_TYPE(MAY_BE_RC1|MAY_BE_RCN|MAY_BE_ANY|MAY_BE_ARRAY_KEY_ANY|MAY_BE_ARRAY_OF_ANY, ssa_op->result_def);
break;
case ZEND_STRLEN:
case ZEND_COUNT:
case ZEND_FUNC_NUM_ARGS:
UPDATE_SSA_TYPE(MAY_BE_LONG, ssa_op->result_def);
break;
case ZEND_FUNC_GET_ARGS:
UPDATE_SSA_TYPE(MAY_BE_RC1|MAY_BE_RCN| MAY_BE_ARRAY | MAY_BE_ARRAY_PACKED | MAY_BE_ARRAY_OF_ANY, ssa_op->result_def);
break;
case ZEND_GET_CLASS:
case ZEND_GET_CALLED_CLASS:
UPDATE_SSA_TYPE(MAY_BE_STRING|MAY_BE_RCN, ssa_op->result_def);
break;
case ZEND_GET_TYPE:
UPDATE_SSA_TYPE(MAY_BE_STRING|MAY_BE_RC1|MAY_BE_RCN, ssa_op->result_def);
break;
case ZEND_TYPE_CHECK: {
uint32_t expected_type_mask = opline->extended_value;
if (t1 & MAY_BE_UNDEF) {
t1 |= MAY_BE_NULL;
}
tmp = 0;
if (t1 & expected_type_mask) {
tmp |= MAY_BE_TRUE;
if ((t1 & expected_type_mask) & MAY_BE_RESOURCE) {
tmp |= MAY_BE_FALSE;
}
}
if (t1 & (MAY_BE_ANY - expected_type_mask)) {
tmp |= MAY_BE_FALSE;
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
break;
}
case ZEND_DEFINED:
UPDATE_SSA_TYPE(MAY_BE_FALSE|MAY_BE_TRUE, ssa_op->result_def);
break;
case ZEND_VERIFY_RETURN_TYPE:
if (t1 & MAY_BE_REF) {
tmp = t1;
ce = NULL;
} else {
zend_arg_info *ret_info = op_array->arg_info - 1;
tmp = zend_fetch_arg_info_type(script, ret_info, &ce);
tmp |= (t1 & MAY_BE_INDIRECT);
// TODO: We could model more precisely how illegal types are converted.
uint32_t extra_types = t1 & ~tmp;
if (!extra_types) {
tmp &= t1;
}
}
if (opline->op1_type & (IS_TMP_VAR|IS_VAR|IS_CV)) {
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
if (ce) {
UPDATE_SSA_OBJ_TYPE(ce, 1, ssa_op->op1_def);
} else {
UPDATE_SSA_OBJ_TYPE(NULL, 0, ssa_op->op1_def);
}
} else {
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
if (ce) {
UPDATE_SSA_OBJ_TYPE(ce, 1, ssa_op->result_def);
} else {
UPDATE_SSA_OBJ_TYPE(NULL, 0, ssa_op->result_def);
}
}
break;
case ZEND_MAKE_REF:
tmp = MAY_BE_REF|MAY_BE_RC1|MAY_BE_RCN|MAY_BE_ANY|MAY_BE_ARRAY_KEY_ANY|MAY_BE_ARRAY_OF_ANY|MAY_BE_ARRAY_OF_REF;
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
if (ssa_op->op1_def >= 0) {
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
break;
case ZEND_CATCH:
/* Forbidden opcodes */
ZEND_UNREACHABLE();
break;
default:
unknown_opcode:
if (ssa_op->op1_def >= 0) {
tmp = MAY_BE_ANY | MAY_BE_REF | MAY_BE_RC1 | MAY_BE_RCN | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
UPDATE_SSA_TYPE(tmp, ssa_op->op1_def);
}
if (ssa_op->result_def >= 0) {
tmp = MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
if (opline->result_type == IS_TMP_VAR) {
if (opline->opcode == ZEND_FETCH_R || opline->opcode == ZEND_FETCH_IS) {
/* Variable reference counter may be decremented before use */
/* See: ext/opcache/tests/jit/fetch_r_001.phpt */
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
} else {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
}
} else if (opline->result_type == IS_CV) {
tmp |= MAY_BE_RC1 | MAY_BE_RCN;
} else {
tmp |= MAY_BE_REF | MAY_BE_RC1 | MAY_BE_RCN;
switch (opline->opcode) {
case ZEND_FETCH_W:
case ZEND_FETCH_RW:
case ZEND_FETCH_FUNC_ARG:
case ZEND_FETCH_UNSET:
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_STATIC_PROP_W:
case ZEND_FETCH_STATIC_PROP_RW:
case ZEND_FETCH_STATIC_PROP_FUNC_ARG:
case ZEND_FETCH_STATIC_PROP_UNSET:
tmp |= MAY_BE_INDIRECT;
break;
}
}
UPDATE_SSA_TYPE(tmp, ssa_op->result_def);
}
break;
}
return SUCCESS;
}
ZEND_API zend_result zend_update_type_info(
const zend_op_array *op_array,
zend_ssa *ssa,
const zend_script *script,
zend_op *opline,
zend_ssa_op *ssa_op,
const zend_op **ssa_opcodes,
zend_long optimization_level)
{
return _zend_update_type_info(op_array, ssa, script, NULL, opline, ssa_op, ssa_opcodes, optimization_level, 0);
}
static uint32_t get_class_entry_rank(zend_class_entry *ce) {
uint32_t rank = 0;
if (ce->ce_flags & ZEND_ACC_LINKED) {
while (ce->parent) {
rank++;
ce = ce->parent;
}
}
return rank;
}
/* Compute least common ancestor on class inheritance tree only */
static zend_class_entry *join_class_entries(
zend_class_entry *ce1, zend_class_entry *ce2, int *is_instanceof) {
uint32_t rank1, rank2;
if (ce1 == ce2) {
return ce1;
}
if (!ce1 || !ce2) {
return NULL;
}
rank1 = get_class_entry_rank(ce1);
rank2 = get_class_entry_rank(ce2);
while (rank1 != rank2) {
if (rank1 > rank2) {
ce1 = !(ce1->ce_flags & ZEND_ACC_LINKED) ? NULL : ce1->parent;
rank1--;
} else {
ce2 = !(ce2->ce_flags & ZEND_ACC_LINKED) ? NULL : ce2->parent;
rank2--;
}
}
while (ce1 != ce2) {
ce1 = !(ce1->ce_flags & ZEND_ACC_LINKED) ? NULL : ce1->parent;
ce2 = !(ce2->ce_flags & ZEND_ACC_LINKED) ? NULL : ce2->parent;
}
if (ce1) {
*is_instanceof = 1;
}
return ce1;
}
static bool safe_instanceof(zend_class_entry *ce1, zend_class_entry *ce2) {
if (ce1 == ce2) {
return 1;
}
if (!(ce1->ce_flags & ZEND_ACC_LINKED)) {
/* This case could be generalized, similarly to unlinked_instanceof */
return 0;
}
return instanceof_function(ce1, ce2);
}
static zend_result zend_infer_types_ex(const zend_op_array *op_array, const zend_script *script, zend_ssa *ssa, zend_bitset worklist, zend_long optimization_level)
{
zend_basic_block *blocks = ssa->cfg.blocks;
zend_ssa_var *ssa_vars = ssa->vars;
zend_ssa_var_info *ssa_var_info = ssa->var_info;
int ssa_vars_count = ssa->vars_count;
int i, j;
uint32_t tmp, worklist_len = zend_bitset_len(ssa_vars_count);
bool update_worklist = 1;
const zend_op **ssa_opcodes = NULL;
while (!zend_bitset_empty(worklist, worklist_len)) {
j = zend_bitset_first(worklist, worklist_len);
zend_bitset_excl(worklist, j);
if (ssa_vars[j].definition_phi) {
zend_ssa_phi *p = ssa_vars[j].definition_phi;
if (p->pi >= 0) {
zend_class_entry *ce = ssa_var_info[p->sources[0]].ce;
int is_instanceof = ssa_var_info[p->sources[0]].is_instanceof;
tmp = get_ssa_var_info(ssa, p->sources[0]);
if (!p->has_range_constraint) {
zend_ssa_type_constraint *constraint = &p->constraint.type;
tmp &= constraint->type_mask;
if (!(tmp & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE))) {
tmp &= ~(MAY_BE_RC1|MAY_BE_RCN);
}
if ((tmp & MAY_BE_OBJECT) && constraint->ce && ce != constraint->ce) {
if (!ce) {
ce = constraint->ce;
is_instanceof = 1;
} else if (is_instanceof && safe_instanceof(constraint->ce, ce)) {
ce = constraint->ce;
} else {
/* Ignore the constraint (either ce instanceof constraint->ce or
* they are unrelated, as far as we can statically determine) */
}
}
}
UPDATE_SSA_TYPE(tmp, j);
if (tmp & MAY_BE_REF) {
UPDATE_SSA_OBJ_TYPE(NULL, 0, j);
} else {
UPDATE_SSA_OBJ_TYPE(ce, is_instanceof, j);
}
} else {
int first = 1;
int is_instanceof = 0;
zend_class_entry *ce = NULL;
tmp = 0;
for (i = 0; i < blocks[p->block].predecessors_count; i++) {
tmp |= get_ssa_var_info(ssa, p->sources[i]);
}
UPDATE_SSA_TYPE(tmp, j);
for (i = 0; i < blocks[p->block].predecessors_count; i++) {
zend_ssa_var_info *info;
ZEND_ASSERT(p->sources[i] >= 0);
info = &ssa_var_info[p->sources[i]];
if (info->type & MAY_BE_OBJECT) {
if (first) {
ce = info->ce;
is_instanceof = info->is_instanceof;
first = 0;
} else {
is_instanceof |= info->is_instanceof;
ce = join_class_entries(ce, info->ce, &is_instanceof);
}
}
}
UPDATE_SSA_OBJ_TYPE(ce, ce ? is_instanceof : 0, j);
}
} else if (ssa_vars[j].definition >= 0) {
i = ssa_vars[j].definition;
if (_zend_update_type_info(op_array, ssa, script, worklist, op_array->opcodes + i, ssa->ops + i, NULL, optimization_level, 1) == FAILURE) {
return FAILURE;
}
}
}
return SUCCESS;
}
static bool is_narrowable_instr(zend_op *opline) {
return opline->opcode == ZEND_ADD || opline->opcode == ZEND_SUB
|| opline->opcode == ZEND_MUL || opline->opcode == ZEND_DIV;
}
static bool is_effective_op1_double_cast(zend_op *opline, zval *op2) {
return (opline->opcode == ZEND_ADD && Z_LVAL_P(op2) == 0)
|| (opline->opcode == ZEND_SUB && Z_LVAL_P(op2) == 0)
|| (opline->opcode == ZEND_MUL && Z_LVAL_P(op2) == 1)
|| (opline->opcode == ZEND_DIV && Z_LVAL_P(op2) == 1);
}
static bool is_effective_op2_double_cast(zend_op *opline, zval *op1) {
/* In PHP it holds that (double)(0-$int) is bitwise identical to 0.0-(double)$int,
* so allowing SUB here is fine. */
return (opline->opcode == ZEND_ADD && Z_LVAL_P(op1) == 0)
|| (opline->opcode == ZEND_SUB && Z_LVAL_P(op1) == 0)
|| (opline->opcode == ZEND_MUL && Z_LVAL_P(op1) == 1);
}
/* This function recursively checks whether it's possible to convert an integer variable
* initialization to a double initialization. The basic idea is that if the value is used
* only in add/sub/mul/div ("narrowable" instructions) with a double result value, then it
* will be cast to double at that point anyway, so we may as well do it earlier already.
*
* The tricky case are chains of operations, where it's not necessarily a given that converting
* an integer to double before the chain of operations is the same as converting it after the
* chain. What this function does is detect two cases where it is safe:
* * If the operations only involve constants, then we can simply verify that performing the
* calculation on integers and doubles yields the same value.
* * Even if one operand is not known, we may be able to determine that the operations with the
* integer replaced by a double only acts as an effective double cast on the unknown operand.
* E.g. 0+$i and 0.0+$i only differ by that cast. If then the consuming instruction of this
* result will perform a double cast anyway, the conversion is safe.
*
* The checks happens recursively, while keeping track of which variables are already visited to
* avoid infinite loops. An iterative, worklist driven approach would be possible, but the state
* management more cumbersome to implement, so we don't bother for now.
*/
static bool can_convert_to_double(
const zend_op_array *op_array, zend_ssa *ssa, int var_num,
zval *value, zend_bitset visited) {
zend_ssa_var *var = &ssa->vars[var_num];
zend_ssa_phi *phi;
int use;
uint32_t type;
if (zend_bitset_in(visited, var_num)) {
return 1;
}
zend_bitset_incl(visited, var_num);
for (use = var->use_chain; use >= 0; use = zend_ssa_next_use(ssa->ops, var_num, use)) {
zend_op *opline = &op_array->opcodes[use];
zend_ssa_op *ssa_op = &ssa->ops[use];
if (zend_ssa_is_no_val_use(opline, ssa_op, var_num)) {
continue;
}
if (!is_narrowable_instr(opline)) {
return 0;
}
/* Instruction always returns double, the conversion is certainly fine */
type = ssa->var_info[ssa_op->result_def].type;
if ((type & MAY_BE_ANY) == MAY_BE_DOUBLE) {
continue;
}
/* UNDEF signals that the previous result is an effective double cast, this is only allowed
* if this instruction would have done the cast anyway (previous check). */
if (Z_ISUNDEF_P(value)) {
return 0;
}
/* Check that narrowing can actually be useful */
if ((type & MAY_BE_ANY) & ~(MAY_BE_LONG|MAY_BE_DOUBLE)) {
return 0;
}
{
/* For calculation on original values */
zval orig_op1, orig_op2, orig_result;
/* For calculation with var_num cast to double */
zval dval_op1, dval_op2, dval_result;
ZVAL_UNDEF(&orig_op1);
ZVAL_UNDEF(&dval_op1);
if (ssa_op->op1_use == var_num) {
ZVAL_COPY_VALUE(&orig_op1, value);
ZVAL_DOUBLE(&dval_op1, (double) Z_LVAL_P(value));
} else if (opline->op1_type == IS_CONST) {
zval *zv = CRT_CONSTANT(opline->op1);
if (Z_TYPE_P(zv) == IS_LONG || Z_TYPE_P(zv) == IS_DOUBLE) {
ZVAL_COPY_VALUE(&orig_op1, zv);
ZVAL_COPY_VALUE(&dval_op1, zv);
}
}
ZVAL_UNDEF(&orig_op2);
ZVAL_UNDEF(&dval_op2);
if (ssa_op->op2_use == var_num) {
ZVAL_COPY_VALUE(&orig_op2, value);
ZVAL_DOUBLE(&dval_op2, (double) Z_LVAL_P(value));
} else if (opline->op2_type == IS_CONST) {
zval *zv = CRT_CONSTANT(opline->op2);
if (Z_TYPE_P(zv) == IS_LONG || Z_TYPE_P(zv) == IS_DOUBLE) {
ZVAL_COPY_VALUE(&orig_op2, zv);
ZVAL_COPY_VALUE(&dval_op2, zv);
}
}
ZEND_ASSERT(!Z_ISUNDEF(orig_op1) || !Z_ISUNDEF(orig_op2));
if (Z_ISUNDEF(orig_op1)) {
if (opline->opcode == ZEND_MUL && Z_LVAL(orig_op2) == 0) {
ZVAL_LONG(&orig_result, 0);
} else if (is_effective_op1_double_cast(opline, &orig_op2)) {
ZVAL_UNDEF(&orig_result);
} else {
return 0;
}
} else if (Z_ISUNDEF(orig_op2)) {
if (opline->opcode == ZEND_MUL && Z_LVAL(orig_op1) == 0) {
ZVAL_LONG(&orig_result, 0);
} else if (is_effective_op2_double_cast(opline, &orig_op1)) {
ZVAL_UNDEF(&orig_result);
} else {
return 0;
}
} else {
uint8_t opcode = opline->opcode;
if (opcode == ZEND_ASSIGN_OP) {
opcode = opline->extended_value;
}
/* Avoid division by zero */
if (opcode == ZEND_DIV && zval_get_double(&orig_op2) == 0.0) {
return 0;
}
get_binary_op(opcode)(&orig_result, &orig_op1, &orig_op2);
get_binary_op(opcode)(&dval_result, &dval_op1, &dval_op2);
ZEND_ASSERT(Z_TYPE(dval_result) == IS_DOUBLE);
if (zval_get_double(&orig_result) != Z_DVAL(dval_result)) {
return 0;
}
}
if (!can_convert_to_double(op_array, ssa, ssa_op->result_def, &orig_result, visited)) {
return 0;
}
}
}
for (phi = var->phi_use_chain; phi; phi = zend_ssa_next_use_phi(ssa, var_num, phi)) {
/* Check that narrowing can actually be useful */
type = ssa->var_info[phi->ssa_var].type;
if ((type & MAY_BE_ANY) & ~(MAY_BE_LONG|MAY_BE_DOUBLE)) {
return 0;
}
if (!can_convert_to_double(op_array, ssa, phi->ssa_var, value, visited)) {
return 0;
}
}
return 1;
}
static zend_result zend_type_narrowing(const zend_op_array *op_array, const zend_script *script, zend_ssa *ssa, zend_long optimization_level)
{
uint32_t bitset_len = zend_bitset_len(ssa->vars_count);
zend_bitset visited, worklist;
int i, v;
zend_op *opline;
bool narrowed = 0;
ALLOCA_FLAG(use_heap)
visited = ZEND_BITSET_ALLOCA(2 * bitset_len, use_heap);
worklist = visited + bitset_len;
zend_bitset_clear(worklist, bitset_len);
for (v = op_array->last_var; v < ssa->vars_count; v++) {
if ((ssa->var_info[v].type & (MAY_BE_REF | MAY_BE_ANY | MAY_BE_UNDEF)) != MAY_BE_LONG) continue;
if (ssa->vars[v].definition < 0) continue;
if (ssa->vars[v].no_val) continue;
opline = op_array->opcodes + ssa->vars[v].definition;
/* Go through assignments of literal integers and check if they can be converted to
* doubles instead, in the hope that we'll narrow long|double to double. */
if (opline->opcode == ZEND_ASSIGN && opline->result_type == IS_UNUSED &&
opline->op1_type == IS_CV && opline->op2_type == IS_CONST) {
zval *value = CRT_CONSTANT(opline->op2);
zend_bitset_clear(visited, bitset_len);
if (can_convert_to_double(op_array, ssa, v, value, visited)) {
narrowed = 1;
ssa->var_info[v].use_as_double = 1;
/* The "visited" vars are exactly those which may change their type due to
* narrowing. Reset their types and add them to the type inference worklist */
ZEND_BITSET_FOREACH(visited, bitset_len, i) {
ssa->var_info[i].type &= ~MAY_BE_ANY;
} ZEND_BITSET_FOREACH_END();
zend_bitset_union(worklist, visited, bitset_len);
}
}
}
if (!narrowed) {
free_alloca(visited, use_heap);
return SUCCESS;
}
if (zend_infer_types_ex(op_array, script, ssa, worklist, optimization_level) == FAILURE) {
free_alloca(visited, use_heap);
return FAILURE;
}
free_alloca(visited, use_heap);
return SUCCESS;
}
static bool is_recursive_tail_call(const zend_op_array *op_array,
zend_op *opline)
{
zend_func_info *info = ZEND_FUNC_INFO(op_array);
if (info->ssa.ops && info->ssa.vars && info->call_map &&
info->ssa.ops[opline - op_array->opcodes].op1_use >= 0 &&
info->ssa.vars[info->ssa.ops[opline - op_array->opcodes].op1_use].definition >= 0) {
zend_op *op = op_array->opcodes + info->ssa.vars[info->ssa.ops[opline - op_array->opcodes].op1_use].definition;
if (op->opcode == ZEND_DO_UCALL) {
zend_call_info *call_info = info->call_map[op - op_array->opcodes];
if (call_info && op_array == &call_info->callee_func->op_array) {
return 1;
}
}
}
return 0;
}
uint32_t zend_get_return_info_from_signature_only(
const zend_function *func, const zend_script *script,
zend_class_entry **ce, bool *ce_is_instanceof, bool use_tentative_return_info) {
uint32_t type;
if (func->common.fn_flags & ZEND_ACC_HAS_RETURN_TYPE &&
(use_tentative_return_info || !ZEND_ARG_TYPE_IS_TENTATIVE(func->common.arg_info - 1))
) {
zend_arg_info *ret_info = func->common.arg_info - 1;
type = zend_fetch_arg_info_type(script, ret_info, ce);
*ce_is_instanceof = ce != NULL;
} else {
type = MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF
| MAY_BE_RC1 | MAY_BE_RCN;
*ce = NULL;
*ce_is_instanceof = false;
}
/* For generators RETURN_REFERENCE refers to the yielded values. */
if ((func->common.fn_flags & ZEND_ACC_RETURN_REFERENCE)
&& !(func->common.fn_flags & ZEND_ACC_GENERATOR)) {
type |= MAY_BE_REF;
*ce = NULL;
*ce_is_instanceof = 0;
}
return type;
}
ZEND_API void zend_init_func_return_info(
const zend_op_array *op_array, const zend_script *script, zend_ssa_var_info *ret)
{
ZEND_ASSERT((op_array->fn_flags & ZEND_ACC_HAS_RETURN_TYPE));
zend_ssa_range tmp_range = {0, 0, 0, 0};
bool is_instanceof = false;
ret->type = zend_get_return_info_from_signature_only(
(zend_function *) op_array, script, &ret->ce, &is_instanceof, /* use_tentative_return_info */ 1);
ret->is_instanceof = is_instanceof;
ret->range = tmp_range;
ret->has_range = 0;
}
static void zend_func_return_info(const zend_op_array *op_array,
const zend_script *script,
int recursive,
int widening,
zend_ssa_var_info *ret)
{
zend_func_info *info = ZEND_FUNC_INFO(op_array);
zend_ssa *ssa = &info->ssa;
int blocks_count = info->ssa.cfg.blocks_count;
zend_basic_block *blocks = info->ssa.cfg.blocks;
int j;
uint32_t t1;
uint32_t tmp = 0;
zend_class_entry *tmp_ce = NULL;
int tmp_is_instanceof = -1;
zend_class_entry *arg_ce;
int arg_is_instanceof;
zend_ssa_range tmp_range = {0, 0, 0, 0};
int tmp_has_range = -1;
if (op_array->fn_flags & ZEND_ACC_GENERATOR) {
ret->type = MAY_BE_OBJECT | MAY_BE_RC1 | MAY_BE_RCN;
ret->ce = zend_ce_generator;
ret->is_instanceof = 0;
ret->range = tmp_range;
ret->has_range = 0;
return;
}
if (!ret->type) {
/* We will intersect the type later. */
ret->type = MAY_BE_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF | MAY_BE_ARRAY_KEY_ANY
| MAY_BE_RC1 | MAY_BE_RCN | MAY_BE_REF;
}
for (j = 0; j < blocks_count; j++) {
if ((blocks[j].flags & ZEND_BB_REACHABLE) && blocks[j].len != 0) {
zend_op *opline = op_array->opcodes + blocks[j].start + blocks[j].len - 1;
if (opline->opcode == ZEND_RETURN || opline->opcode == ZEND_RETURN_BY_REF) {
zend_ssa_op *ssa_op = ssa->ops ? &ssa->ops[opline - op_array->opcodes] : NULL;
if (!recursive && ssa_op && info->ssa.var_info &&
ssa_op->op1_use >= 0 &&
info->ssa.var_info[ssa_op->op1_use].recursive) {
continue;
}
if (is_recursive_tail_call(op_array, opline)) {
continue;
}
t1 = OP1_INFO();
if (t1 & MAY_BE_UNDEF) {
t1 |= MAY_BE_NULL;
}
if (opline->opcode == ZEND_RETURN) {
if (t1 & MAY_BE_RC1) {
t1 |= MAY_BE_RCN;
}
t1 &= ~(MAY_BE_UNDEF | MAY_BE_REF);
} else {
t1 |= MAY_BE_REF;
t1 &= ~(MAY_BE_UNDEF | MAY_BE_RC1 | MAY_BE_RCN);
}
tmp |= t1;
if (ssa_op && info->ssa.var_info &&
ssa_op->op1_use >= 0 && !(t1 & MAY_BE_REF) &&
info->ssa.var_info[ssa_op->op1_use].ce) {
arg_ce = info->ssa.var_info[ssa_op->op1_use].ce;
arg_is_instanceof = info->ssa.var_info[ssa_op->op1_use].is_instanceof;
} else {
arg_ce = NULL;
arg_is_instanceof = 0;
}
if (tmp_is_instanceof < 0) {
tmp_ce = arg_ce;
tmp_is_instanceof = arg_is_instanceof;
} else if (arg_ce && arg_ce == tmp_ce) {
if (tmp_is_instanceof != arg_is_instanceof) {
tmp_is_instanceof = 1;
}
} else {
tmp_ce = NULL;
tmp_is_instanceof = 0;
}
if (opline->op1_type == IS_CONST) {
zval *zv = CRT_CONSTANT(opline->op1);
if (Z_TYPE_P(zv) == IS_LONG) {
if (tmp_has_range < 0) {
tmp_has_range = 1;
tmp_range.underflow = 0;
tmp_range.min = Z_LVAL_P(zv);
tmp_range.max = Z_LVAL_P(zv);
tmp_range.overflow = 0;
} else if (tmp_has_range) {
if (!tmp_range.underflow) {
tmp_range.min = MIN(tmp_range.min, Z_LVAL_P(zv));
}
if (!tmp_range.overflow) {
tmp_range.max = MAX(tmp_range.max, Z_LVAL_P(zv));
}
}
} else {
tmp_has_range = 0;
}
} else if (ssa_op && info->ssa.var_info && ssa_op->op1_use >= 0) {
if (info->ssa.var_info[ssa_op->op1_use].has_range) {
if (tmp_has_range < 0) {
tmp_has_range = 1;
tmp_range = info->ssa.var_info[ssa_op->op1_use].range;
} else if (tmp_has_range) {
/* union */
if (info->ssa.var_info[ssa_op->op1_use].range.underflow) {
tmp_range.underflow = 1;
tmp_range.min = ZEND_LONG_MIN;
} else {
tmp_range.min = MIN(tmp_range.min, info->ssa.var_info[ssa_op->op1_use].range.min);
}
if (info->ssa.var_info[ssa_op->op1_use].range.overflow) {
tmp_range.overflow = 1;
tmp_range.max = ZEND_LONG_MAX;
} else {
tmp_range.max = MAX(tmp_range.max, info->ssa.var_info[ssa_op->op1_use].range.max);
}
}
} else if (!widening) {
tmp_has_range = 1;
tmp_range.underflow = 1;
tmp_range.min = ZEND_LONG_MIN;
tmp_range.max = ZEND_LONG_MAX;
tmp_range.overflow = 1;
}
} else {
tmp_has_range = 0;
}
}
}
}
if (!(op_array->fn_flags & ZEND_ACC_HAS_RETURN_TYPE)) {
if (tmp_is_instanceof < 0) {
tmp_is_instanceof = 0;
tmp_ce = NULL;
}
if (tmp_has_range < 0) {
tmp_has_range = 0;
}
ret->ce = tmp_ce;
ret->is_instanceof = tmp_is_instanceof;
}
ret->type &= tmp;
ret->range = tmp_range;
ret->has_range = tmp_has_range;
}
static zend_result zend_infer_types(const zend_op_array *op_array, const zend_script *script, zend_ssa *ssa, zend_long optimization_level)
{
int ssa_vars_count = ssa->vars_count;
int j;
zend_bitset worklist;
ALLOCA_FLAG(use_heap);
worklist = do_alloca(sizeof(zend_ulong) * zend_bitset_len(ssa_vars_count), use_heap);
memset(worklist, 0, sizeof(zend_ulong) * zend_bitset_len(ssa_vars_count));
/* Type Inference */
for (j = op_array->last_var; j < ssa_vars_count; j++) {
zend_bitset_incl(worklist, j);
}
if (zend_infer_types_ex(op_array, script, ssa, worklist, optimization_level) == FAILURE) {
free_alloca(worklist, use_heap);
return FAILURE;
}
if (optimization_level & ZEND_OPTIMIZER_NARROW_TO_DOUBLE) {
/* Narrowing integer initialization to doubles */
zend_type_narrowing(op_array, script, ssa, optimization_level);
}
if (ZEND_FUNC_INFO(op_array)) {
zend_func_return_info(op_array, script, 1, 0, &ZEND_FUNC_INFO(op_array)->return_info);
}
free_alloca(worklist, use_heap);
return SUCCESS;
}
static void zend_mark_cv_references(const zend_op_array *op_array, const zend_script *script, zend_ssa *ssa)
{
int var, def;
const zend_op *opline;
zend_arg_info *arg_info;
uint32_t worklist_len = zend_bitset_len(ssa->vars_count);
zend_bitset worklist;
ALLOCA_FLAG(use_heap);
worklist = do_alloca(sizeof(zend_ulong) * worklist_len, use_heap);
memset(worklist, 0, sizeof(zend_ulong) * worklist_len);
/* Collect SSA variables which definitions creates PHP reference */
for (var = 0; var < ssa->vars_count; var++) {
def = ssa->vars[var].definition;
if (def >= 0 && ssa->vars[var].var < op_array->last_var) {
opline = op_array->opcodes + def;
if (ssa->ops[def].result_def == var) {
switch (opline->opcode) {
case ZEND_RECV:
case ZEND_RECV_INIT:
arg_info = &op_array->arg_info[opline->op1.num-1];
if (!ZEND_ARG_SEND_MODE(arg_info)) {
continue;
}
break;
default:
continue;
}
} else if (ssa->ops[def].op1_def == var) {
switch (opline->opcode) {
case ZEND_ASSIGN_REF:
case ZEND_MAKE_REF:
case ZEND_FE_RESET_RW:
case ZEND_BIND_GLOBAL:
case ZEND_SEND_REF:
case ZEND_SEND_VAR_EX:
case ZEND_SEND_FUNC_ARG:
case ZEND_BIND_INIT_STATIC_OR_JMP:
break;
case ZEND_INIT_ARRAY:
case ZEND_ADD_ARRAY_ELEMENT:
if (!(opline->extended_value & ZEND_ARRAY_ELEMENT_REF)) {
continue;
}
break;
case ZEND_BIND_STATIC:
if (!(opline->extended_value & ZEND_BIND_REF)) {
continue;
}
break;
case ZEND_YIELD:
if (!(op_array->fn_flags & ZEND_ACC_RETURN_REFERENCE)) {
continue;
}
break;
case ZEND_OP_DATA:
switch ((opline-1)->opcode) {
case ZEND_ASSIGN_OBJ_REF:
case ZEND_ASSIGN_STATIC_PROP_REF:
break;
default:
continue;
}
break;
default:
continue;
}
} else if (ssa->ops[def].op2_def == var) {
switch (opline->opcode) {
case ZEND_ASSIGN_REF:
case ZEND_FE_FETCH_RW:
break;
case ZEND_BIND_LEXICAL:
if (!(opline->extended_value & ZEND_BIND_REF)) {
continue;
}
break;
default:
continue;
}
} else {
ZEND_UNREACHABLE();
}
zend_bitset_incl(worklist, var);
} else if (ssa->var_info[var].type & MAY_BE_REF) {
zend_bitset_incl(worklist, var);
} else if (ssa->vars[var].alias == SYMTABLE_ALIAS) {
zend_bitset_incl(worklist, var);
}
}
/* Set and propagate MAY_BE_REF */
WHILE_WORKLIST(worklist, worklist_len, var) {
ssa->var_info[var].type |= MAY_BE_RC1 | MAY_BE_RCN | MAY_BE_REF | MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
if (ssa->vars[var].phi_use_chain) {
zend_ssa_phi *p = ssa->vars[var].phi_use_chain;
do {
if (!(ssa->var_info[p->ssa_var].type & MAY_BE_REF)) {
zend_bitset_incl(worklist, p->ssa_var);
}
p = zend_ssa_next_use_phi(ssa, var, p);
} while (p);
}
if (ssa->vars[var].use_chain >= 0) {
int use = ssa->vars[var].use_chain;
FOREACH_USE(&ssa->vars[var], use) {
zend_ssa_op *op = ssa->ops + use;
if (op->op1_use == var && op->op1_def >= 0) {
if (!(ssa->var_info[op->op1_def].type & MAY_BE_REF)) {
/* Unset breaks references (outside global scope). */
if (op_array->opcodes[use].opcode == ZEND_UNSET_CV
&& op_array->function_name) {
continue;
}
zend_bitset_incl(worklist, op->op1_def);
}
}
if (op->op2_use == var && op->op2_def >= 0) {
if (!(ssa->var_info[op->op2_def].type & MAY_BE_REF)) {
zend_bitset_incl(worklist, op->op2_def);
}
}
if (op->result_use == var && op->result_def >= 0) {
if (!(ssa->var_info[op->result_def].type & MAY_BE_REF)) {
zend_bitset_incl(worklist, op->result_def);
}
}
} FOREACH_USE_END();
}
} WHILE_WORKLIST_END();
free_alloca(worklist, use_heap);
}
ZEND_API zend_result zend_ssa_inference(zend_arena **arena, const zend_op_array *op_array, const zend_script *script, zend_ssa *ssa, zend_long optimization_level) /* {{{ */
{
zend_ssa_var_info *ssa_var_info;
int i;
if (!ssa->var_info) {
ssa->var_info = zend_arena_calloc(arena, ssa->vars_count, sizeof(zend_ssa_var_info));
}
ssa_var_info = ssa->var_info;
if (!op_array->function_name) {
for (i = 0; i < op_array->last_var; i++) {
ssa_var_info[i].type = MAY_BE_UNDEF | MAY_BE_RC1 | MAY_BE_RCN | MAY_BE_REF | MAY_BE_ANY | MAY_BE_ARRAY_KEY_ANY | MAY_BE_ARRAY_OF_ANY | MAY_BE_ARRAY_OF_REF;
ssa_var_info[i].has_range = 0;
}
} else {
for (i = 0; i < op_array->last_var; i++) {
ssa_var_info[i].type = MAY_BE_UNDEF;
ssa_var_info[i].has_range = 0;
if (ssa->vars[i].alias) {
ssa_var_info[i].type |= get_ssa_alias_types(ssa->vars[i].alias);
}
}
}
for (i = op_array->last_var; i < ssa->vars_count; i++) {
ssa_var_info[i].type = 0;
ssa_var_info[i].has_range = 0;
}
zend_mark_cv_references(op_array, script, ssa);
zend_infer_ranges(op_array, ssa);
if (zend_infer_types(op_array, script, ssa, optimization_level) == FAILURE) {
return FAILURE;
}
return SUCCESS;
}
/* }}} */
ZEND_API bool zend_may_throw_ex(const zend_op *opline, const zend_ssa_op *ssa_op, const zend_op_array *op_array, const zend_ssa *ssa, uint32_t t1, uint32_t t2)
{
if (opline->op1_type == IS_CV) {
if (t1 & MAY_BE_UNDEF) {
switch (opline->opcode) {
case ZEND_UNSET_VAR:
case ZEND_ISSET_ISEMPTY_VAR:
return 1;
case ZEND_ISSET_ISEMPTY_DIM_OBJ:
case ZEND_ISSET_ISEMPTY_PROP_OBJ:
case ZEND_ASSIGN:
case ZEND_ASSIGN_DIM:
case ZEND_ASSIGN_REF:
case ZEND_BIND_GLOBAL:
case ZEND_BIND_STATIC:
case ZEND_BIND_INIT_STATIC_OR_JMP:
case ZEND_FETCH_DIM_IS:
case ZEND_FETCH_OBJ_IS:
case ZEND_SEND_REF:
case ZEND_UNSET_CV:
case ZEND_ISSET_ISEMPTY_CV:
case ZEND_MAKE_REF:
case ZEND_FETCH_DIM_W:
break;
default:
/* undefined variable warning */
return 1;
}
}
} else if (opline->op1_type & (IS_TMP_VAR|IS_VAR)) {
if ((t1 & MAY_BE_RC1)
&& (t1 & (MAY_BE_OBJECT|MAY_BE_RESOURCE|MAY_BE_ARRAY_OF_OBJECT|MAY_BE_ARRAY_OF_RESOURCE|MAY_BE_ARRAY_OF_ARRAY))) {
switch (opline->opcode) {
case ZEND_CASE:
case ZEND_CASE_STRICT:
case ZEND_FE_FETCH_R:
case ZEND_FE_FETCH_RW:
case ZEND_FETCH_LIST_R:
case ZEND_QM_ASSIGN:
case ZEND_SEND_VAL:
case ZEND_SEND_VAL_EX:
case ZEND_SEND_VAR:
case ZEND_SEND_VAR_EX:
case ZEND_SEND_FUNC_ARG:
case ZEND_SEND_VAR_NO_REF:
case ZEND_SEND_VAR_NO_REF_EX:
case ZEND_SEND_REF:
case ZEND_SEPARATE:
case ZEND_END_SILENCE:
case ZEND_MAKE_REF:
break;
default:
/* destructor may be called */
return 1;
}
}
}
if (opline->op2_type == IS_CV) {
if (t2 & MAY_BE_UNDEF) {
switch (opline->opcode) {
case ZEND_ASSIGN_REF:
case ZEND_FE_FETCH_R:
case ZEND_FE_FETCH_RW:
break;
default:
/* undefined variable warning */
return 1;
}
}
} else if (opline->op2_type & (IS_TMP_VAR|IS_VAR)) {
if ((t2 & MAY_BE_RC1)
&& (t2 & (MAY_BE_OBJECT|MAY_BE_RESOURCE|MAY_BE_ARRAY_OF_OBJECT|MAY_BE_ARRAY_OF_RESOURCE|MAY_BE_ARRAY_OF_ARRAY))) {
switch (opline->opcode) {
case ZEND_ASSIGN:
case ZEND_FE_FETCH_R:
case ZEND_FE_FETCH_RW:
break;
default:
/* destructor may be called */
return 1;
}
}
}
switch (opline->opcode) {
case ZEND_NOP:
case ZEND_IS_IDENTICAL:
case ZEND_IS_NOT_IDENTICAL:
case ZEND_QM_ASSIGN:
case ZEND_JMP:
case ZEND_CHECK_VAR:
case ZEND_MAKE_REF:
case ZEND_BEGIN_SILENCE:
case ZEND_END_SILENCE:
case ZEND_FREE:
case ZEND_FE_FREE:
case ZEND_SEPARATE:
case ZEND_TYPE_CHECK:
case ZEND_DEFINED:
case ZEND_ISSET_ISEMPTY_THIS:
case ZEND_COALESCE:
case ZEND_SWITCH_LONG:
case ZEND_SWITCH_STRING:
case ZEND_MATCH:
case ZEND_ISSET_ISEMPTY_VAR:
case ZEND_ISSET_ISEMPTY_CV:
case ZEND_FUNC_NUM_ARGS:
case ZEND_FUNC_GET_ARGS:
case ZEND_COPY_TMP:
case ZEND_CASE_STRICT:
case ZEND_JMP_NULL:
return 0;
case ZEND_SEND_VAR:
case ZEND_SEND_VAL:
case ZEND_SEND_REF:
case ZEND_SEND_VAR_EX:
case ZEND_SEND_FUNC_ARG:
case ZEND_CHECK_FUNC_ARG:
/* May throw for named params. */
return opline->op2_type == IS_CONST;
case ZEND_INIT_FCALL:
/* can't throw, because call is resolved at compile time */
return 0;
case ZEND_BIND_GLOBAL:
if ((opline+1)->opcode == ZEND_BIND_GLOBAL) {
return zend_may_throw(opline + 1, ssa_op + 1, op_array, ssa);
}
return 0;
case ZEND_ADD:
if ((t1 & MAY_BE_ANY) == MAY_BE_ARRAY
&& (t2 & MAY_BE_ANY) == MAY_BE_ARRAY) {
return 0;
}
return (t1 & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) ||
(t2 & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE));
case ZEND_DIV:
if (!OP2_HAS_RANGE() ||
(OP2_MIN_RANGE() <= 0 && OP2_MAX_RANGE() >= 0)) {
/* Division by zero */
return 1;
}
ZEND_FALLTHROUGH;
case ZEND_SUB:
case ZEND_MUL:
case ZEND_POW:
return (t1 & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) ||
(t2 & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE));
/* Ops may throw if not an integer */
case ZEND_MOD:
if (!OP2_HAS_RANGE() ||
(OP2_MIN_RANGE() <= 0 && OP2_MAX_RANGE() >= 0)) {
/* Division by zero */
return 1;
}
ZEND_FALLTHROUGH;
case ZEND_SL:
case ZEND_SR:
return (t1 & (MAY_BE_STRING|MAY_BE_DOUBLE|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) ||
(t2 & (MAY_BE_STRING|MAY_BE_DOUBLE|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) ||
!OP2_HAS_RANGE() ||
OP2_MIN_RANGE() < 0;
case ZEND_CONCAT:
case ZEND_FAST_CONCAT:
return (t1 & (MAY_BE_ARRAY|MAY_BE_OBJECT)) ||
(t2 & (MAY_BE_ARRAY|MAY_BE_OBJECT));
case ZEND_BW_OR:
case ZEND_BW_AND:
case ZEND_BW_XOR:
if ((t1 & MAY_BE_ANY) == MAY_BE_STRING
&& (t2 & MAY_BE_ANY) == MAY_BE_STRING) {
return 0;
}
return (t1 & (MAY_BE_STRING|MAY_BE_DOUBLE|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) ||
(t2 & (MAY_BE_STRING|MAY_BE_DOUBLE|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE));
case ZEND_BW_NOT:
return (t1 & (MAY_BE_NULL|MAY_BE_FALSE|MAY_BE_TRUE|MAY_BE_DOUBLE|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE));
case ZEND_PRE_INC:
case ZEND_POST_INC:
return (t1 & (MAY_BE_FALSE|MAY_BE_TRUE|MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE));
/* null emits a warning as it has no effect compared to ++ which converts the value to 1 */
case ZEND_PRE_DEC:
case ZEND_POST_DEC:
return (t1 & (MAY_BE_NULL|MAY_BE_FALSE|MAY_BE_TRUE|MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE));
case ZEND_BOOL_NOT:
case ZEND_JMPZ:
case ZEND_JMPNZ:
case ZEND_JMPZ_EX:
case ZEND_JMPNZ_EX:
case ZEND_BOOL:
case ZEND_JMP_SET:
return (t1 & MAY_BE_OBJECT);
case ZEND_BOOL_XOR:
return (t1 & MAY_BE_OBJECT) || (t2 & MAY_BE_OBJECT);
case ZEND_IS_EQUAL:
case ZEND_IS_NOT_EQUAL:
case ZEND_IS_SMALLER:
case ZEND_IS_SMALLER_OR_EQUAL:
case ZEND_CASE:
case ZEND_SPACESHIP:
if ((t1 & MAY_BE_ANY) == MAY_BE_NULL
|| (t2 & MAY_BE_ANY) == MAY_BE_NULL) {
return 0;
}
return (t1 & (MAY_BE_OBJECT|MAY_BE_ARRAY_OF_ARRAY|MAY_BE_ARRAY_OF_OBJECT)) || (t2 & (MAY_BE_OBJECT|MAY_BE_ARRAY_OF_ARRAY|MAY_BE_ARRAY_OF_OBJECT));
case ZEND_ASSIGN_OP:
if (opline->extended_value == ZEND_ADD) {
if ((t1 & MAY_BE_ANY) == MAY_BE_ARRAY
&& (t2 & MAY_BE_ANY) == MAY_BE_ARRAY) {
return 0;
}
return (t1 & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) ||
(t2 & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE));
} else if (opline->extended_value == ZEND_DIV ||
opline->extended_value == ZEND_MOD) {
if (!OP2_HAS_RANGE() ||
(OP2_MIN_RANGE() <= 0 && OP2_MAX_RANGE() >= 0)) {
/* Division by zero */
return 1;
}
return (t1 & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) ||
(t2 & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE));
} else if (opline->extended_value == ZEND_SUB ||
opline->extended_value == ZEND_MUL ||
opline->extended_value == ZEND_POW) {
return (t1 & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) ||
(t2 & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE));
} else if (opline->extended_value == ZEND_SL ||
opline->extended_value == ZEND_SR) {
return (t1 & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) ||
(t2 & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) ||
!OP2_HAS_RANGE() ||
OP2_MIN_RANGE() < 0;
} else if (opline->extended_value == ZEND_CONCAT) {
return (t1 & (MAY_BE_ARRAY|MAY_BE_OBJECT)) ||
(t2 & (MAY_BE_ARRAY|MAY_BE_OBJECT));
} else if (opline->extended_value == ZEND_BW_OR ||
opline->extended_value == ZEND_BW_AND ||
opline->extended_value == ZEND_BW_XOR) {
if ((t1 & MAY_BE_ANY) == MAY_BE_STRING
&& (t2 & MAY_BE_ANY) == MAY_BE_STRING) {
return 0;
}
return (t1 & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE)) ||
(t2 & (MAY_BE_STRING|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE));
}
return 1;
case ZEND_ASSIGN:
if (t1 & MAY_BE_REF) {
return 1;
}
ZEND_FALLTHROUGH;
case ZEND_UNSET_VAR:
return (t1 & (MAY_BE_OBJECT|MAY_BE_RESOURCE|MAY_BE_ARRAY_OF_OBJECT|MAY_BE_ARRAY_OF_RESOURCE|MAY_BE_ARRAY_OF_ARRAY));
case ZEND_BIND_STATIC:
case ZEND_BIND_INIT_STATIC_OR_JMP:
if (t1 & (MAY_BE_OBJECT|MAY_BE_RESOURCE|MAY_BE_ARRAY_OF_OBJECT|MAY_BE_ARRAY_OF_RESOURCE|MAY_BE_ARRAY_OF_ARRAY)) {
/* Destructor may throw. */
return 1;
}
return 0;
case ZEND_ASSIGN_DIM:
if ((opline+1)->op1_type == IS_CV) {
if (_ssa_op1_info(op_array, ssa, opline+1, ssa_op+1) & MAY_BE_UNDEF) {
return 1;
}
}
return (t1 & (MAY_BE_OBJECT|MAY_BE_RESOURCE|MAY_BE_TRUE|MAY_BE_FALSE|MAY_BE_STRING|MAY_BE_LONG|MAY_BE_DOUBLE)) || opline->op2_type == IS_UNUSED ||
(t2 & (MAY_BE_UNDEF|MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE));
case ZEND_ASSIGN_OBJ:
if (t1 & (MAY_BE_ANY-MAY_BE_OBJECT)) {
return 1;
}
if ((opline+1)->op1_type == IS_CV) {
if (_ssa_op1_info(op_array, ssa, opline+1, ssa_op+1) & MAY_BE_UNDEF) {
return 1;
}
}
if (ssa_op->op1_use) {
const zend_ssa_var_info *var_info = ssa->var_info + ssa_op->op1_use;
const zend_class_entry *ce = var_info->ce;
if (var_info->is_instanceof ||
!ce || ce->create_object || ce->__get || ce->__set || ce->parent) {
return 1;
}
if (opline->op2_type != IS_CONST) {
return 1;
}
zend_string *prop_name = Z_STR_P(CRT_CONSTANT(opline->op2));
if (ZSTR_LEN(prop_name) > 0 && ZSTR_VAL(prop_name)[0] == '\0') {
return 1;
}
zend_property_info *prop_info =
zend_hash_find_ptr(&ce->properties_info, prop_name);
if (prop_info) {
if (ZEND_TYPE_IS_SET(prop_info->type)) {
return 1;
}
return !(prop_info->flags & ZEND_ACC_PUBLIC)
&& prop_info->ce != op_array->scope;
} else {
return !(ce->ce_flags & ZEND_ACC_ALLOW_DYNAMIC_PROPERTIES);
}
}
return 1;
case ZEND_ROPE_INIT:
case ZEND_ROPE_ADD:
case ZEND_ROPE_END:
return t2 & (MAY_BE_ARRAY|MAY_BE_OBJECT);
case ZEND_INIT_ARRAY:
return (opline->op2_type != IS_UNUSED) && (t2 & (MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE));
case ZEND_ADD_ARRAY_ELEMENT:
return (opline->op2_type == IS_UNUSED) || (t2 & (MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE));
case ZEND_STRLEN:
return (t1 & MAY_BE_ANY) != MAY_BE_STRING;
case ZEND_COUNT:
return (t1 & MAY_BE_ANY) != MAY_BE_ARRAY;
case ZEND_RECV_INIT:
if (Z_TYPE_P(CRT_CONSTANT(opline->op2)) == IS_CONSTANT_AST) {
return 1;
}
if (op_array->fn_flags & ZEND_ACC_HAS_TYPE_HINTS) {
uint32_t arg_num = opline->op1.num;
const zend_arg_info *cur_arg_info;
if (EXPECTED(arg_num <= op_array->num_args)) {
cur_arg_info = &op_array->arg_info[arg_num-1];
} else if (UNEXPECTED(op_array->fn_flags & ZEND_ACC_VARIADIC)) {
cur_arg_info = &op_array->arg_info[op_array->num_args];
} else {
return 0;
}
return ZEND_TYPE_IS_SET(cur_arg_info->type);
} else {
return 0;
}
case ZEND_FETCH_IS:
return (t2 & (MAY_BE_ARRAY|MAY_BE_OBJECT));
case ZEND_ISSET_ISEMPTY_DIM_OBJ:
return (t1 & MAY_BE_OBJECT) || (t2 & (MAY_BE_ARRAY|MAY_BE_OBJECT));
case ZEND_FETCH_DIM_IS:
return (t1 & MAY_BE_OBJECT) || (t2 & (MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE));
case ZEND_CAST:
switch (opline->extended_value) {
case IS_LONG:
case IS_DOUBLE:
return (t1 & MAY_BE_OBJECT);
case IS_STRING:
return (t1 & (MAY_BE_ARRAY|MAY_BE_OBJECT));
case IS_ARRAY:
return (t1 & MAY_BE_OBJECT);
case IS_OBJECT:
return 0;
EMPTY_SWITCH_DEFAULT_CASE()
}
/* GCC is getting confused here for the Wimplicit-fallthrough warning with
* EMPTY_SWITCH_DEFAULT_CASE() macro */
return 0;
case ZEND_ARRAY_KEY_EXISTS:
if ((t2 & MAY_BE_ANY) != MAY_BE_ARRAY) {
return 1;
}
if ((t1 & (MAY_BE_ARRAY|MAY_BE_OBJECT|MAY_BE_RESOURCE))) {
return 1;
}
return 0;
case ZEND_FE_RESET_R:
case ZEND_FE_RESET_RW:
if ((t1 & (MAY_BE_ANY|MAY_BE_REF)) != MAY_BE_ARRAY) {
return 1;
}
return 0;
case ZEND_FE_FETCH_R:
if ((t1 & (MAY_BE_ANY|MAY_BE_REF)) != MAY_BE_ARRAY) {
return 1;
}
if (opline->op2_type == IS_CV
&& (t2 & MAY_BE_RC1)
&& (t2 & (MAY_BE_OBJECT|MAY_BE_RESOURCE|MAY_BE_ARRAY_OF_OBJECT|MAY_BE_ARRAY_OF_RESOURCE|MAY_BE_ARRAY_OF_ARRAY))) {
return 1;
}
return 0;
case ZEND_FETCH_DIM_W:
case ZEND_FETCH_LIST_W:
if (t1 & (MAY_BE_FALSE|MAY_BE_TRUE|MAY_BE_LONG|MAY_BE_DOUBLE|MAY_BE_STRING|MAY_BE_OBJECT|MAY_BE_RESOURCE|MAY_BE_REF)) {
return 1;
}
if (t2 & (MAY_BE_RESOURCE|MAY_BE_ARRAY|MAY_BE_OBJECT)) {
return 1;
}
if (opline->op2_type == IS_UNUSED) {
return 1;
}
return 0;
default:
return 1;
}
}
ZEND_API bool zend_may_throw(const zend_op *opline, const zend_ssa_op *ssa_op, const zend_op_array *op_array, const zend_ssa *ssa)
{
return zend_may_throw_ex(opline, ssa_op, op_array, ssa, OP1_INFO(), OP2_INFO());
}