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cosmopolitan/third_party/duktape/duk_js_executor.c

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/*
* ECMAScript bytecode executor.
*/
#include "third_party/duktape/duk_internal.h"
/*
* Local declarations.
*/
DUK_LOCAL_DECL void duk__js_execute_bytecode_inner(duk_hthread *entry_thread, duk_activation *entry_act);
/*
* Misc helpers.
*/
/* Replace value stack top to value at 'tv_ptr'. Optimize for
* performance by only applying the net refcount change.
*/
#define DUK__REPLACE_TO_TVPTR(thr,tv_ptr) do { \
duk_hthread *duk__thr; \
duk_tval *duk__tvsrc; \
duk_tval *duk__tvdst; \
duk_tval duk__tvtmp; \
duk__thr = (thr); \
duk__tvsrc = DUK_GET_TVAL_NEGIDX(duk__thr, -1); \
duk__tvdst = (tv_ptr); \
DUK_TVAL_SET_TVAL(&duk__tvtmp, duk__tvdst); \
DUK_TVAL_SET_TVAL(duk__tvdst, duk__tvsrc); \
DUK_TVAL_SET_UNDEFINED(duk__tvsrc); /* value stack init policy */ \
duk__thr->valstack_top = duk__tvsrc; \
DUK_TVAL_DECREF(duk__thr, &duk__tvtmp); \
} while (0)
/* XXX: candidate of being an internal shared API call */
#if 0 /* unused */
DUK_LOCAL void duk__push_tvals_incref_only(duk_hthread *thr, duk_tval *tv_src, duk_small_uint_fast_t count) {
duk_tval *tv_dst;
duk_size_t copy_size;
duk_size_t i;
tv_dst = thr->valstack_top;
copy_size = sizeof(duk_tval) * count;
duk_memcpy((void *) tv_dst, (const void *) tv_src, copy_size);
for (i = 0; i < count; i++) {
DUK_TVAL_INCREF(thr, tv_dst);
tv_dst++;
}
thr->valstack_top = tv_dst;
}
#endif
/*
* Arithmetic, binary, and logical helpers.
*
* Note: there is no opcode for logical AND or logical OR; this is on
* purpose, because the evalution order semantics for them make such
* opcodes pretty pointless: short circuiting means they are most
* comfortably implemented as jumps. However, a logical NOT opcode
* is useful.
*
* Note: careful with duk_tval pointers here: they are potentially
* invalidated by any DECREF and almost any API call. It's still
* preferable to work without making a copy but that's not always
* possible.
*/
DUK_LOCAL DUK_EXEC_ALWAYS_INLINE_PERF duk_double_t duk__compute_mod(duk_double_t d1, duk_double_t d2) {
return (duk_double_t) duk_js_arith_mod((double) d1, (double) d2);
}
#if defined(DUK_USE_ES7_EXP_OPERATOR)
DUK_LOCAL DUK_EXEC_ALWAYS_INLINE_PERF duk_double_t duk__compute_exp(duk_double_t d1, duk_double_t d2) {
return (duk_double_t) duk_js_arith_pow((double) d1, (double) d2);
}
#endif
DUK_LOCAL DUK_EXEC_ALWAYS_INLINE_PERF void duk__vm_arith_add(duk_hthread *thr, duk_tval *tv_x, duk_tval *tv_y, duk_small_uint_fast_t idx_z) {
/*
* Addition operator is different from other arithmetic
* operations in that it also provides string concatenation.
* Hence it is implemented separately.
*
* There is a fast path for number addition. Other cases go
* through potentially multiple coercions as described in the
* E5 specification. It may be possible to reduce the number
* of coercions, but this must be done carefully to preserve
* the exact semantics.
*
* E5 Section 11.6.1.
*
* Custom types also have special behavior implemented here.
*/
duk_double_union du;
DUK_ASSERT(thr != NULL);
DUK_ASSERT(tv_x != NULL); /* may be reg or const */
DUK_ASSERT(tv_y != NULL); /* may be reg or const */
DUK_ASSERT_DISABLE(idx_z >= 0); /* unsigned */
DUK_ASSERT((duk_uint_t) idx_z < (duk_uint_t) duk_get_top(thr));
/*
* Fast paths
*/
#if defined(DUK_USE_FASTINT)
if (DUK_TVAL_IS_FASTINT(tv_x) && DUK_TVAL_IS_FASTINT(tv_y)) {
duk_int64_t v1, v2, v3;
duk_int32_t v3_hi;
duk_tval *tv_z;
/* Input values are signed 48-bit so we can detect overflow
* reliably from high bits or just a comparison.
*/
v1 = DUK_TVAL_GET_FASTINT(tv_x);
v2 = DUK_TVAL_GET_FASTINT(tv_y);
v3 = v1 + v2;
v3_hi = (duk_int32_t) (v3 >> 32);
if (DUK_LIKELY(v3_hi >= DUK_I64_CONSTANT(-0x8000) && v3_hi <= DUK_I64_CONSTANT(0x7fff))) {
tv_z = thr->valstack_bottom + idx_z;
DUK_TVAL_SET_FASTINT_UPDREF(thr, tv_z, v3); /* side effects */
return;
} else {
/* overflow, fall through */
;
}
}
#endif /* DUK_USE_FASTINT */
if (DUK_TVAL_IS_NUMBER(tv_x) && DUK_TVAL_IS_NUMBER(tv_y)) {
#if !defined(DUK_USE_EXEC_PREFER_SIZE)
duk_tval *tv_z;
#endif
du.d = DUK_TVAL_GET_NUMBER(tv_x) + DUK_TVAL_GET_NUMBER(tv_y);
#if defined(DUK_USE_EXEC_PREFER_SIZE)
duk_push_number(thr, du.d); /* will NaN normalize result */
duk_replace(thr, (duk_idx_t) idx_z);
#else /* DUK_USE_EXEC_PREFER_SIZE */
DUK_DBLUNION_NORMALIZE_NAN_CHECK(&du);
DUK_ASSERT(DUK_DBLUNION_IS_NORMALIZED(&du));
tv_z = thr->valstack_bottom + idx_z;
DUK_TVAL_SET_NUMBER_UPDREF(thr, tv_z, du.d); /* side effects */
#endif /* DUK_USE_EXEC_PREFER_SIZE */
return;
}
/*
* Slow path: potentially requires function calls for coercion
*/
duk_push_tval(thr, tv_x);
duk_push_tval(thr, tv_y);
duk_to_primitive(thr, -2, DUK_HINT_NONE); /* side effects -> don't use tv_x, tv_y after */
duk_to_primitive(thr, -1, DUK_HINT_NONE);
/* Since Duktape 2.x plain buffers are treated like ArrayBuffer. */
if (duk_is_string(thr, -2) || duk_is_string(thr, -1)) {
/* Symbols shouldn't technically be handled here, but should
* go into the default ToNumber() coercion path instead and
* fail there with a TypeError. However, there's a ToString()
* in duk_concat_2() which also fails with TypeError so no
* explicit check is needed.
*/
duk_concat_2(thr); /* [... s1 s2] -> [... s1+s2] */
} else {
duk_double_t d1, d2;
d1 = duk_to_number_m2(thr);
d2 = duk_to_number_m1(thr);
DUK_ASSERT(duk_is_number(thr, -2));
DUK_ASSERT(duk_is_number(thr, -1));
DUK_ASSERT_DOUBLE_IS_NORMALIZED(d1);
DUK_ASSERT_DOUBLE_IS_NORMALIZED(d2);
du.d = d1 + d2;
duk_pop_2_unsafe(thr);
duk_push_number(thr, du.d); /* will NaN normalize result */
}
duk_replace(thr, (duk_idx_t) idx_z); /* side effects */
}
DUK_LOCAL DUK_EXEC_ALWAYS_INLINE_PERF void duk__vm_arith_binary_op(duk_hthread *thr, duk_tval *tv_x, duk_tval *tv_y, duk_uint_fast_t idx_z, duk_small_uint_fast_t opcode) {
/*
* Arithmetic operations other than '+' have number-only semantics
* and are implemented here. The separate switch-case here means a
* "double dispatch" of the arithmetic opcode, but saves code space.
*
* E5 Sections 11.5, 11.5.1, 11.5.2, 11.5.3, 11.6, 11.6.1, 11.6.2, 11.6.3.
*/
duk_double_t d1, d2;
duk_double_union du;
duk_small_uint_fast_t opcode_shifted;
#if defined(DUK_USE_FASTINT) || !defined(DUK_USE_EXEC_PREFER_SIZE)
duk_tval *tv_z;
#endif
DUK_ASSERT(thr != NULL);
DUK_ASSERT(tv_x != NULL); /* may be reg or const */
DUK_ASSERT(tv_y != NULL); /* may be reg or const */
DUK_ASSERT_DISABLE(idx_z >= 0); /* unsigned */
DUK_ASSERT((duk_uint_t) idx_z < (duk_uint_t) duk_get_top(thr));
opcode_shifted = opcode >> 2; /* Get base opcode without reg/const modifiers. */
#if defined(DUK_USE_FASTINT)
if (DUK_TVAL_IS_FASTINT(tv_x) && DUK_TVAL_IS_FASTINT(tv_y)) {
duk_int64_t v1, v2, v3;
duk_int32_t v3_hi;
v1 = DUK_TVAL_GET_FASTINT(tv_x);
v2 = DUK_TVAL_GET_FASTINT(tv_y);
switch (opcode_shifted) {
case DUK_OP_SUB >> 2: {
v3 = v1 - v2;
break;
}
case DUK_OP_MUL >> 2: {
/* Must ensure result is 64-bit (no overflow); a
* simple and sufficient fast path is to allow only
* 32-bit inputs. Avoid zero inputs to avoid
* negative zero issues (-1 * 0 = -0, for instance).
*/
if (v1 >= DUK_I64_CONSTANT(-0x80000000) && v1 <= DUK_I64_CONSTANT(0x7fffffff) && v1 != 0 &&
v2 >= DUK_I64_CONSTANT(-0x80000000) && v2 <= DUK_I64_CONSTANT(0x7fffffff) && v2 != 0) {
v3 = v1 * v2;
} else {
goto skip_fastint;
}
break;
}
case DUK_OP_DIV >> 2: {
/* Don't allow a zero divisor. Fast path check by
* "verifying" with multiplication. Also avoid zero
* dividend to avoid negative zero issues (0 / -1 = -0
* for instance).
*/
if (v1 == 0 || v2 == 0) {
goto skip_fastint;
}
v3 = v1 / v2;
if (v3 * v2 != v1) {
goto skip_fastint;
}
break;
}
case DUK_OP_MOD >> 2: {
/* Don't allow a zero divisor. Restrict both v1 and
* v2 to positive values to avoid compiler specific
* behavior.
*/
if (v1 < 1 || v2 < 1) {
goto skip_fastint;
}
v3 = v1 % v2;
DUK_ASSERT(v3 >= 0);
DUK_ASSERT(v3 < v2);
DUK_ASSERT(v1 - (v1 / v2) * v2 == v3);
break;
}
default: {
/* Possible with DUK_OP_EXP. */
goto skip_fastint;
}
}
v3_hi = (duk_int32_t) (v3 >> 32);
if (DUK_LIKELY(v3_hi >= DUK_I64_CONSTANT(-0x8000) && v3_hi <= DUK_I64_CONSTANT(0x7fff))) {
tv_z = thr->valstack_bottom + idx_z;
DUK_TVAL_SET_FASTINT_UPDREF(thr, tv_z, v3); /* side effects */
return;
}
/* fall through if overflow etc */
}
skip_fastint:
#endif /* DUK_USE_FASTINT */
if (DUK_TVAL_IS_NUMBER(tv_x) && DUK_TVAL_IS_NUMBER(tv_y)) {
/* fast path */
d1 = DUK_TVAL_GET_NUMBER(tv_x);
d2 = DUK_TVAL_GET_NUMBER(tv_y);
} else {
duk_push_tval(thr, tv_x);
duk_push_tval(thr, tv_y);
d1 = duk_to_number_m2(thr); /* side effects */
d2 = duk_to_number_m1(thr);
DUK_ASSERT(duk_is_number(thr, -2));
DUK_ASSERT(duk_is_number(thr, -1));
DUK_ASSERT_DOUBLE_IS_NORMALIZED(d1);
DUK_ASSERT_DOUBLE_IS_NORMALIZED(d2);
duk_pop_2_unsafe(thr);
}
switch (opcode_shifted) {
case DUK_OP_SUB >> 2: {
du.d = d1 - d2;
break;
}
case DUK_OP_MUL >> 2: {
du.d = d1 * d2;
break;
}
case DUK_OP_DIV >> 2: {
/* Division-by-zero is undefined behavior, so
* rely on a helper.
*/
du.d = duk_double_div(d1, d2);
break;
}
case DUK_OP_MOD >> 2: {
du.d = duk__compute_mod(d1, d2);
break;
}
#if defined(DUK_USE_ES7_EXP_OPERATOR)
case DUK_OP_EXP >> 2: {
du.d = duk__compute_exp(d1, d2);
break;
}
#endif
default: {
DUK_UNREACHABLE();
du.d = DUK_DOUBLE_NAN; /* should not happen */
break;
}
}
#if defined(DUK_USE_EXEC_PREFER_SIZE)
duk_push_number(thr, du.d); /* will NaN normalize result */
duk_replace(thr, (duk_idx_t) idx_z);
#else /* DUK_USE_EXEC_PREFER_SIZE */
/* important to use normalized NaN with 8-byte tagged types */
DUK_DBLUNION_NORMALIZE_NAN_CHECK(&du);
DUK_ASSERT(DUK_DBLUNION_IS_NORMALIZED(&du));
tv_z = thr->valstack_bottom + idx_z;
DUK_TVAL_SET_NUMBER_UPDREF(thr, tv_z, du.d); /* side effects */
#endif /* DUK_USE_EXEC_PREFER_SIZE */
}
DUK_LOCAL DUK_EXEC_ALWAYS_INLINE_PERF void duk__vm_bitwise_binary_op(duk_hthread *thr, duk_tval *tv_x, duk_tval *tv_y, duk_small_uint_fast_t idx_z, duk_small_uint_fast_t opcode) {
/*
* Binary bitwise operations use different coercions (ToInt32, ToUint32)
* depending on the operation. We coerce the arguments first using
* ToInt32(), and then cast to an 32-bit value if necessary. Note that
* such casts must be correct even if there is no native 32-bit type
* (e.g., duk_int32_t and duk_uint32_t are 64-bit).
*
* E5 Sections 11.10, 11.7.1, 11.7.2, 11.7.3
*/
duk_int32_t i1, i2, i3;
duk_uint32_t u1, u2, u3;
#if defined(DUK_USE_FASTINT)
duk_int64_t fi3;
#else
duk_double_t d3;
#endif
duk_small_uint_fast_t opcode_shifted;
#if defined(DUK_USE_FASTINT) || !defined(DUK_USE_EXEC_PREFER_SIZE)
duk_tval *tv_z;
#endif
DUK_ASSERT(thr != NULL);
DUK_ASSERT(tv_x != NULL); /* may be reg or const */
DUK_ASSERT(tv_y != NULL); /* may be reg or const */
DUK_ASSERT_DISABLE(idx_z >= 0); /* unsigned */
DUK_ASSERT((duk_uint_t) idx_z < (duk_uint_t) duk_get_top(thr));
opcode_shifted = opcode >> 2; /* Get base opcode without reg/const modifiers. */
#if defined(DUK_USE_FASTINT)
if (DUK_TVAL_IS_FASTINT(tv_x) && DUK_TVAL_IS_FASTINT(tv_y)) {
i1 = (duk_int32_t) DUK_TVAL_GET_FASTINT_I32(tv_x);
i2 = (duk_int32_t) DUK_TVAL_GET_FASTINT_I32(tv_y);
}
else
#endif /* DUK_USE_FASTINT */
{
duk_push_tval(thr, tv_x);
duk_push_tval(thr, tv_y);
i1 = duk_to_int32(thr, -2);
i2 = duk_to_int32(thr, -1);
duk_pop_2_unsafe(thr);
}
switch (opcode_shifted) {
case DUK_OP_BAND >> 2: {
i3 = i1 & i2;
break;
}
case DUK_OP_BOR >> 2: {
i3 = i1 | i2;
break;
}
case DUK_OP_BXOR >> 2: {
i3 = i1 ^ i2;
break;
}
case DUK_OP_BASL >> 2: {
/* Signed shift, named "arithmetic" (asl) because the result
* is signed, e.g. 4294967295 << 1 -> -2. Note that result
* must be masked.
*/
u2 = ((duk_uint32_t) i2) & 0xffffffffUL;
i3 = (duk_int32_t) (((duk_uint32_t) i1) << (u2 & 0x1fUL)); /* E5 Section 11.7.1, steps 7 and 8 */
i3 = i3 & ((duk_int32_t) 0xffffffffUL); /* Note: left shift, should mask */
break;
}
case DUK_OP_BASR >> 2: {
/* signed shift */
u2 = ((duk_uint32_t) i2) & 0xffffffffUL;
i3 = i1 >> (u2 & 0x1fUL); /* E5 Section 11.7.2, steps 7 and 8 */
break;
}
case DUK_OP_BLSR >> 2: {
/* unsigned shift */
u1 = ((duk_uint32_t) i1) & 0xffffffffUL;
u2 = ((duk_uint32_t) i2) & 0xffffffffUL;
/* special result value handling */
u3 = u1 >> (u2 & 0x1fUL); /* E5 Section 11.7.2, steps 7 and 8 */
#if defined(DUK_USE_FASTINT)
fi3 = (duk_int64_t) u3;
goto fastint_result_set;
#else
d3 = (duk_double_t) u3;
goto result_set;
#endif
}
default: {
DUK_UNREACHABLE();
i3 = 0; /* should not happen */
break;
}
}
#if defined(DUK_USE_FASTINT)
/* Result is always fastint compatible. */
/* XXX: Set 32-bit result (but must then handle signed and
* unsigned results separately).
*/
fi3 = (duk_int64_t) i3;
fastint_result_set:
tv_z = thr->valstack_bottom + idx_z;
DUK_TVAL_SET_FASTINT_UPDREF(thr, tv_z, fi3); /* side effects */
#else /* DUK_USE_FASTINT */
d3 = (duk_double_t) i3;
result_set:
DUK_ASSERT(!DUK_ISNAN(d3)); /* 'd3' is never NaN, so no need to normalize */
DUK_ASSERT_DOUBLE_IS_NORMALIZED(d3); /* always normalized */
#if defined(DUK_USE_EXEC_PREFER_SIZE)
duk_push_number(thr, d3); /* would NaN normalize result, but unnecessary */
duk_replace(thr, (duk_idx_t) idx_z);
#else /* DUK_USE_EXEC_PREFER_SIZE */
tv_z = thr->valstack_bottom + idx_z;
DUK_TVAL_SET_NUMBER_UPDREF(thr, tv_z, d3); /* side effects */
#endif /* DUK_USE_EXEC_PREFER_SIZE */
#endif /* DUK_USE_FASTINT */
}
/* In-place unary operation. */
DUK_LOCAL DUK_EXEC_ALWAYS_INLINE_PERF void duk__vm_arith_unary_op(duk_hthread *thr, duk_uint_fast_t idx_src, duk_uint_fast_t idx_dst, duk_small_uint_fast_t opcode) {
/*
* Arithmetic operations other than '+' have number-only semantics
* and are implemented here. The separate switch-case here means a
* "double dispatch" of the arithmetic opcode, but saves code space.
*
* E5 Sections 11.5, 11.5.1, 11.5.2, 11.5.3, 11.6, 11.6.1, 11.6.2, 11.6.3.
*/
duk_tval *tv;
duk_double_t d1;
duk_double_union du;
DUK_ASSERT(thr != NULL);
DUK_ASSERT(opcode == DUK_OP_UNM || opcode == DUK_OP_UNP);
DUK_ASSERT_DISABLE(idx_src >= 0);
DUK_ASSERT_DISABLE(idx_dst >= 0);
tv = DUK_GET_TVAL_POSIDX(thr, (duk_idx_t) idx_src);
#if defined(DUK_USE_FASTINT)
if (DUK_TVAL_IS_FASTINT(tv)) {
duk_int64_t v1, v2;
v1 = DUK_TVAL_GET_FASTINT(tv);
if (opcode == DUK_OP_UNM) {
/* The smallest fastint is no longer 48-bit when
* negated. Positive zero becames negative zero
* (cannot be represented) when negated.
*/
if (DUK_LIKELY(v1 != DUK_FASTINT_MIN && v1 != 0)) {
v2 = -v1;
tv = DUK_GET_TVAL_POSIDX(thr, (duk_idx_t) idx_dst);
DUK_TVAL_SET_FASTINT_UPDREF(thr, tv, v2);
return;
}
} else {
/* ToNumber() for a fastint is a no-op. */
DUK_ASSERT(opcode == DUK_OP_UNP);
v2 = v1;
tv = DUK_GET_TVAL_POSIDX(thr, (duk_idx_t) idx_dst);
DUK_TVAL_SET_FASTINT_UPDREF(thr, tv, v2);
return;
}
/* fall through if overflow etc */
}
#endif /* DUK_USE_FASTINT */
if (DUK_TVAL_IS_NUMBER(tv)) {
d1 = DUK_TVAL_GET_NUMBER(tv);
} else {
d1 = duk_to_number_tval(thr, tv); /* side effects */
}
if (opcode == DUK_OP_UNP) {
/* ToNumber() for a double is a no-op, but unary plus is
* used to force a fastint check so do that here.
*/
du.d = d1;
DUK_ASSERT(DUK_DBLUNION_IS_NORMALIZED(&du));
#if defined(DUK_USE_FASTINT)
tv = DUK_GET_TVAL_POSIDX(thr, (duk_idx_t) idx_dst);
DUK_TVAL_SET_NUMBER_CHKFAST_UPDREF(thr, tv, du.d); /* always 'fast', i.e. inlined */
return;
#endif
} else {
DUK_ASSERT(opcode == DUK_OP_UNM);
du.d = -d1;
DUK_DBLUNION_NORMALIZE_NAN_CHECK(&du); /* mandatory if du.d is a NaN */
DUK_ASSERT(DUK_DBLUNION_IS_NORMALIZED(&du));
}
/* XXX: size optimize: push+replace? */
tv = DUK_GET_TVAL_POSIDX(thr, (duk_idx_t) idx_dst);
DUK_TVAL_SET_NUMBER_UPDREF(thr, tv, du.d);
}
DUK_LOCAL DUK_EXEC_ALWAYS_INLINE_PERF void duk__vm_bitwise_not(duk_hthread *thr, duk_uint_fast_t idx_src, duk_uint_fast_t idx_dst) {
/*
* E5 Section 11.4.8
*/
duk_tval *tv;
duk_int32_t i1, i2;
DUK_ASSERT(thr != NULL);
DUK_ASSERT_DISABLE(idx_src >= 0);
DUK_ASSERT_DISABLE(idx_dst >= 0);
DUK_ASSERT((duk_uint_t) idx_src < (duk_uint_t) duk_get_top(thr));
DUK_ASSERT((duk_uint_t) idx_dst < (duk_uint_t) duk_get_top(thr));
tv = DUK_GET_TVAL_POSIDX(thr, (duk_idx_t) idx_src);
#if defined(DUK_USE_FASTINT)
if (DUK_TVAL_IS_FASTINT(tv)) {
i1 = (duk_int32_t) DUK_TVAL_GET_FASTINT_I32(tv);
}
else
#endif /* DUK_USE_FASTINT */
{
duk_push_tval(thr, tv);
i1 = duk_to_int32(thr, -1); /* side effects */
duk_pop_unsafe(thr);
}
/* Result is always fastint compatible. */
i2 = ~i1;
tv = DUK_GET_TVAL_POSIDX(thr, (duk_idx_t) idx_dst);
DUK_TVAL_SET_I32_UPDREF(thr, tv, i2); /* side effects */
}
DUK_LOCAL DUK_EXEC_ALWAYS_INLINE_PERF void duk__vm_logical_not(duk_hthread *thr, duk_uint_fast_t idx_src, duk_uint_fast_t idx_dst) {
/*
* E5 Section 11.4.9
*/
duk_tval *tv;
duk_bool_t res;
DUK_ASSERT(thr != NULL);
DUK_ASSERT_DISABLE(idx_src >= 0);
DUK_ASSERT_DISABLE(idx_dst >= 0);
DUK_ASSERT((duk_uint_t) idx_src < (duk_uint_t) duk_get_top(thr));
DUK_ASSERT((duk_uint_t) idx_dst < (duk_uint_t) duk_get_top(thr));
/* ToBoolean() does not require any operations with side effects so
* we can do it efficiently. For footprint it would be better to use
* duk_js_toboolean() and then push+replace to the result slot.
*/
tv = DUK_GET_TVAL_POSIDX(thr, (duk_idx_t) idx_src);
res = duk_js_toboolean(tv); /* does not modify 'tv' */
DUK_ASSERT(res == 0 || res == 1);
res ^= 1;
tv = DUK_GET_TVAL_POSIDX(thr, (duk_idx_t) idx_dst);
/* XXX: size optimize: push+replace? */
DUK_TVAL_SET_BOOLEAN_UPDREF(thr, tv, res); /* side effects */
}
/* XXX: size optimized variant */
DUK_LOCAL DUK_EXEC_ALWAYS_INLINE_PERF void duk__prepost_incdec_reg_helper(duk_hthread *thr, duk_tval *tv_dst, duk_tval *tv_src, duk_small_uint_t op) {
duk_double_t x, y, z;
/* Two lowest bits of opcode are used to distinguish
* variants. Bit 0 = inc(0)/dec(1), bit 1 = pre(0)/post(1).
*/
DUK_ASSERT((DUK_OP_PREINCR & 0x03) == 0x00);
DUK_ASSERT((DUK_OP_PREDECR & 0x03) == 0x01);
DUK_ASSERT((DUK_OP_POSTINCR & 0x03) == 0x02);
DUK_ASSERT((DUK_OP_POSTDECR & 0x03) == 0x03);
#if defined(DUK_USE_FASTINT)
if (DUK_TVAL_IS_FASTINT(tv_src)) {
duk_int64_t x_fi, y_fi, z_fi;
x_fi = DUK_TVAL_GET_FASTINT(tv_src);
if (op & 0x01) {
if (DUK_UNLIKELY(x_fi == DUK_FASTINT_MIN)) {
goto skip_fastint;
}
y_fi = x_fi - 1;
} else {
if (DUK_UNLIKELY(x_fi == DUK_FASTINT_MAX)) {
goto skip_fastint;
}
y_fi = x_fi + 1;
}
DUK_TVAL_SET_FASTINT(tv_src, y_fi); /* no need for refcount update */
z_fi = (op & 0x02) ? x_fi : y_fi;
DUK_TVAL_SET_FASTINT_UPDREF(thr, tv_dst, z_fi); /* side effects */
return;
}
skip_fastint:
#endif
if (DUK_TVAL_IS_NUMBER(tv_src)) {
/* Fast path for the case where the register
* is a number (e.g. loop counter).
*/
x = DUK_TVAL_GET_NUMBER(tv_src);
if (op & 0x01) {
y = x - 1.0;
} else {
y = x + 1.0;
}
DUK_TVAL_SET_NUMBER(tv_src, y); /* no need for refcount update */
} else {
/* Preserve duk_tval pointer(s) across a potential valstack
* resize by converting them into offsets temporarily.
*/
duk_idx_t bc;
duk_size_t off_dst;
off_dst = (duk_size_t) ((duk_uint8_t *) tv_dst - (duk_uint8_t *) thr->valstack_bottom);
bc = (duk_idx_t) (tv_src - thr->valstack_bottom); /* XXX: pass index explicitly? */
tv_src = NULL; /* no longer referenced */
x = duk_to_number(thr, bc);
if (op & 0x01) {
y = x - 1.0;
} else {
y = x + 1.0;
}
duk_push_number(thr, y);
duk_replace(thr, bc);
tv_dst = (duk_tval *) (void *) (((duk_uint8_t *) thr->valstack_bottom) + off_dst);
}
z = (op & 0x02) ? x : y;
DUK_TVAL_SET_NUMBER_UPDREF(thr, tv_dst, z); /* side effects */
}
DUK_LOCAL DUK_EXEC_ALWAYS_INLINE_PERF void duk__prepost_incdec_var_helper(duk_hthread *thr, duk_small_uint_t idx_dst, duk_tval *tv_id, duk_small_uint_t op, duk_small_uint_t is_strict) {
duk_activation *act;
duk_double_t x, y;
duk_hstring *name;
/* XXX: The pre/post inc/dec for an identifier lookup is
* missing the important fast path where the identifier
* has a storage location e.g. in a scope object so that
* it can be updated in-place. In particular, the case
* where the identifier has a storage location AND the
* previous value is a number should be optimized because
* it's side effect free.
*/
/* Two lowest bits of opcode are used to distinguish
* variants. Bit 0 = inc(0)/dec(1), bit 1 = pre(0)/post(1).
*/
DUK_ASSERT((DUK_OP_PREINCV & 0x03) == 0x00);
DUK_ASSERT((DUK_OP_PREDECV & 0x03) == 0x01);
DUK_ASSERT((DUK_OP_POSTINCV & 0x03) == 0x02);
DUK_ASSERT((DUK_OP_POSTDECV & 0x03) == 0x03);
DUK_ASSERT(DUK_TVAL_IS_STRING(tv_id));
name = DUK_TVAL_GET_STRING(tv_id);
DUK_ASSERT(name != NULL);
act = thr->callstack_curr;
(void) duk_js_getvar_activation(thr, act, name, 1 /*throw*/); /* -> [ ... val this ] */
/* XXX: Fastint fast path would be useful here. Also fastints
* now lose their fastint status in current handling which is
* not intuitive.
*/
x = duk_to_number_m2(thr);
if (op & 0x01) {
y = x - 1.0;
} else {
y = x + 1.0;
}
/* [... x this] */
if (op & 0x02) {
duk_push_number(thr, y); /* -> [ ... x this y ] */
DUK_ASSERT(act == thr->callstack_curr);
duk_js_putvar_activation(thr, act, name, DUK_GET_TVAL_NEGIDX(thr, -1), is_strict);
duk_pop_2_unsafe(thr); /* -> [ ... x ] */
} else {
duk_pop_2_unsafe(thr); /* -> [ ... ] */
duk_push_number(thr, y); /* -> [ ... y ] */
DUK_ASSERT(act == thr->callstack_curr);
duk_js_putvar_activation(thr, act, name, DUK_GET_TVAL_NEGIDX(thr, -1), is_strict);
}
#if defined(DUK_USE_EXEC_PREFER_SIZE)
duk_replace(thr, (duk_idx_t) idx_dst);
#else /* DUK_USE_EXEC_PREFER_SIZE */
DUK__REPLACE_TO_TVPTR(thr, DUK_GET_TVAL_POSIDX(thr, (duk_idx_t) idx_dst));
#endif /* DUK_USE_EXEC_PREFER_SIZE */
}
/*
* Longjmp and other control flow transfer for the bytecode executor.
*
* The longjmp handler can handle all longjmp types: error, yield, and
* resume (pseudotypes are never actually thrown).
*
* Error policy for longjmp: should not ordinarily throw errors; if errors
* occur (e.g. due to out-of-memory) they bubble outwards rather than being
* handled recursively.
*/
#define DUK__LONGJMP_RESTART 0 /* state updated, restart bytecode execution */
#define DUK__LONGJMP_RETHROW 1 /* exit bytecode executor by rethrowing an error to caller */
#define DUK__RETHAND_RESTART 0 /* state updated, restart bytecode execution */
#define DUK__RETHAND_FINISHED 1 /* exit bytecode execution with return value */
/* XXX: optimize reconfig valstack operations so that resize, clamp, and setting
* top are combined into one pass.
*/
/* Reconfigure value stack for return to an ECMAScript function at
* callstack top (caller unwinds).
*/
DUK_LOCAL void duk__reconfig_valstack_ecma_return(duk_hthread *thr) {
duk_activation *act;
duk_hcompfunc *h_func;
duk_idx_t clamp_top;
DUK_ASSERT(thr != NULL);
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
DUK_ASSERT(DUK_ACT_GET_FUNC(act) != NULL);
DUK_ASSERT(DUK_HOBJECT_IS_COMPFUNC(DUK_ACT_GET_FUNC(act)));
/* Clamp so that values at 'clamp_top' and above are wiped and won't
* retain reachable garbage. Then extend to 'nregs' because we're
* returning to an ECMAScript function.
*/
h_func = (duk_hcompfunc *) DUK_ACT_GET_FUNC(act);
thr->valstack_bottom = (duk_tval *) (void *) ((duk_uint8_t *) thr->valstack + act->bottom_byteoff);
DUK_ASSERT(act->retval_byteoff >= act->bottom_byteoff);
clamp_top = (duk_idx_t) ((act->retval_byteoff - act->bottom_byteoff + sizeof(duk_tval)) / sizeof(duk_tval)); /* +1 = one retval */
duk_set_top_and_wipe(thr, h_func->nregs, clamp_top);
DUK_ASSERT((duk_uint8_t *) thr->valstack_end >= (duk_uint8_t *) thr->valstack + act->reserve_byteoff);
thr->valstack_end = (duk_tval *) (void *) ((duk_uint8_t *) thr->valstack + act->reserve_byteoff);
/* XXX: a best effort shrink check would be OK here */
}
/* Reconfigure value stack for an ECMAScript catcher. Use topmost catcher
* in 'act'.
*/
DUK_LOCAL void duk__reconfig_valstack_ecma_catcher(duk_hthread *thr, duk_activation *act) {
duk_catcher *cat;
duk_hcompfunc *h_func;
duk_size_t idx_bottom;
duk_idx_t clamp_top;
DUK_ASSERT(thr != NULL);
DUK_ASSERT(act != NULL);
DUK_ASSERT(DUK_ACT_GET_FUNC(act) != NULL);
DUK_ASSERT(DUK_HOBJECT_IS_COMPFUNC(DUK_ACT_GET_FUNC(act)));
cat = act->cat;
DUK_ASSERT(cat != NULL);
h_func = (duk_hcompfunc *) DUK_ACT_GET_FUNC(act);
thr->valstack_bottom = (duk_tval *) (void *) ((duk_uint8_t *) thr->valstack + act->bottom_byteoff);
idx_bottom = (duk_size_t) (thr->valstack_bottom - thr->valstack);
DUK_ASSERT(cat->idx_base >= idx_bottom);
clamp_top = (duk_idx_t) (cat->idx_base - idx_bottom + 2); /* +2 = catcher value, catcher lj_type */
duk_set_top_and_wipe(thr, h_func->nregs, clamp_top);
DUK_ASSERT((duk_uint8_t *) thr->valstack_end >= (duk_uint8_t *) thr->valstack + act->reserve_byteoff);
thr->valstack_end = (duk_tval *) (void *) ((duk_uint8_t *) thr->valstack + act->reserve_byteoff);
/* XXX: a best effort shrink check would be OK here */
}
/* Set catcher regs: idx_base+0 = value, idx_base+1 = lj_type.
* No side effects.
*/
DUK_LOCAL void duk__set_catcher_regs_norz(duk_hthread *thr, duk_catcher *cat, duk_tval *tv_val_unstable, duk_small_uint_t lj_type) {
duk_tval *tv1;
DUK_ASSERT(thr != NULL);
DUK_ASSERT(tv_val_unstable != NULL);
tv1 = thr->valstack + cat->idx_base;
DUK_ASSERT(tv1 < thr->valstack_top);
DUK_TVAL_SET_TVAL_UPDREF_NORZ(thr, tv1, tv_val_unstable);
tv1++;
DUK_ASSERT(tv1 == thr->valstack + cat->idx_base + 1);
DUK_ASSERT(tv1 < thr->valstack_top);
DUK_TVAL_SET_U32_UPDREF_NORZ(thr, tv1, (duk_uint32_t) lj_type);
}
DUK_LOCAL void duk__handle_catch_part1(duk_hthread *thr, duk_tval *tv_val_unstable, duk_small_uint_t lj_type, volatile duk_bool_t *out_delayed_catch_setup) {
duk_activation *act;
duk_catcher *cat;
DUK_ASSERT(thr != NULL);
DUK_ASSERT(tv_val_unstable != NULL);
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
DUK_DD(DUK_DDPRINT("handle catch, part 1; act=%!A, cat=%!C", act, act->cat));
DUK_ASSERT(act->cat != NULL);
DUK_ASSERT(DUK_CAT_GET_TYPE(act->cat) == DUK_CAT_TYPE_TCF);
/* The part1/part2 split could also be made here at the very top
* of catch handling. Value stack would be reconfigured inside
* part2's protection. Value stack reconfiguration should be free
* of allocs, however.
*/
duk__set_catcher_regs_norz(thr, act->cat, tv_val_unstable, lj_type);
DUK_ASSERT(thr->callstack_top >= 1);
DUK_ASSERT(thr->callstack_curr != NULL);
DUK_ASSERT(DUK_ACT_GET_FUNC(thr->callstack_curr) != NULL);
DUK_ASSERT(DUK_HOBJECT_IS_COMPFUNC(DUK_ACT_GET_FUNC(thr->callstack_curr)));
DUK_ASSERT(thr->callstack_top >= 1);
DUK_ASSERT(act == thr->callstack_curr);
DUK_ASSERT(act != NULL);
duk__reconfig_valstack_ecma_catcher(thr, act);
DUK_ASSERT(thr->callstack_top >= 1);
DUK_ASSERT(act == thr->callstack_curr);
DUK_ASSERT(act != NULL);
cat = act->cat;
DUK_ASSERT(cat != NULL);
act->curr_pc = cat->pc_base + 0; /* +0 = catch */
/*
* If the catch block has an automatic catch variable binding,
* we need to create a lexical environment for it which requires
* allocations. Move out of "error handling state" before the
* allocations to avoid e.g. out-of-memory errors (leading to
* GH-2022 or similar).
*/
if (DUK_CAT_HAS_CATCH_BINDING_ENABLED(cat)) {
DUK_DDD(DUK_DDDPRINT("catcher has an automatic catch binding, handle in part 2"));
*out_delayed_catch_setup = 1;
} else {
DUK_DDD(DUK_DDDPRINT("catcher has no catch binding"));
}
DUK_CAT_CLEAR_CATCH_ENABLED(cat);
}
DUK_LOCAL void duk__handle_catch_part2(duk_hthread *thr) {
duk_activation *act;
duk_catcher *cat;
duk_hdecenv *new_env;
DUK_ASSERT(thr != NULL);
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
DUK_DD(DUK_DDPRINT("handle catch, part 2; act=%!A, cat=%!C", act, act->cat));
DUK_ASSERT(act->cat != NULL);
cat = act->cat;
DUK_ASSERT(cat != NULL);
DUK_ASSERT(DUK_CAT_GET_TYPE(cat) == DUK_CAT_TYPE_TCF);
DUK_ASSERT(DUK_CAT_HAS_CATCH_BINDING_ENABLED(cat));
DUK_ASSERT(thr->valstack + cat->idx_base < thr->valstack_top);
/*
* Create lexical environment for the catch clause, containing
* a binding for the caught value.
*
* The binding is mutable (= writable) but not deletable.
* Step 4 for the catch production in E5 Section 12.14;
* no value is given for CreateMutableBinding 'D' argument,
* which implies the binding is not deletable.
*/
if (act->lex_env == NULL) {
DUK_ASSERT(act->var_env == NULL);
DUK_DDD(DUK_DDDPRINT("delayed environment initialization"));
duk_js_init_activation_environment_records_delayed(thr, act);
DUK_ASSERT(act == thr->callstack_curr);
DUK_ASSERT(act != NULL);
}
DUK_ASSERT(act->lex_env != NULL);
DUK_ASSERT(act->var_env != NULL);
DUK_ASSERT(DUK_ACT_GET_FUNC(act) != NULL);
new_env = duk_hdecenv_alloc(thr,
DUK_HOBJECT_FLAG_EXTENSIBLE |
DUK_HOBJECT_CLASS_AS_FLAGS(DUK_HOBJECT_CLASS_DECENV));
DUK_ASSERT(new_env != NULL);
duk_push_hobject(thr, (duk_hobject *) new_env);
DUK_ASSERT(DUK_HOBJECT_GET_PROTOTYPE(thr->heap, (duk_hobject *) new_env) == NULL);
DUK_DDD(DUK_DDDPRINT("new_env allocated: %!iO", (duk_heaphdr *) new_env));
/* Note: currently the catch binding is handled without a register
* binding because we don't support dynamic register bindings (they
* must be fixed for an entire function). So, there is no need to
* record regbases etc.
*/
/* [ ...env ] */
DUK_ASSERT(cat->h_varname != NULL);
duk_push_hstring(thr, cat->h_varname);
DUK_ASSERT(thr->valstack + cat->idx_base < thr->valstack_top);
duk_push_tval(thr, thr->valstack + cat->idx_base);
duk_xdef_prop(thr, -3, DUK_PROPDESC_FLAGS_W); /* writable, not configurable */
/* [ ... env ] */
DUK_ASSERT(act == thr->callstack_curr);
DUK_ASSERT(act != NULL);
DUK_HOBJECT_SET_PROTOTYPE(thr->heap, (duk_hobject *) new_env, act->lex_env);
act->lex_env = (duk_hobject *) new_env;
DUK_HOBJECT_INCREF(thr, (duk_hobject *) new_env); /* reachable through activation */
/* Net refcount change to act->lex_env is 0: incref for new_env's
* prototype, decref for act->lex_env overwrite.
*/
DUK_CAT_SET_LEXENV_ACTIVE(cat);
duk_pop_unsafe(thr);
DUK_DDD(DUK_DDDPRINT("new_env finished: %!iO", (duk_heaphdr *) new_env));
}
DUK_LOCAL void duk__handle_finally(duk_hthread *thr, duk_tval *tv_val_unstable, duk_small_uint_t lj_type) {
duk_activation *act;
duk_catcher *cat;
DUK_ASSERT(thr != NULL);
DUK_ASSERT(tv_val_unstable != NULL);
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
DUK_ASSERT(act->cat != NULL);
DUK_ASSERT(DUK_CAT_GET_TYPE(act->cat) == DUK_CAT_TYPE_TCF);
duk__set_catcher_regs_norz(thr, act->cat, tv_val_unstable, lj_type);
DUK_ASSERT(thr->callstack_top >= 1);
DUK_ASSERT(thr->callstack_curr != NULL);
DUK_ASSERT(DUK_ACT_GET_FUNC(thr->callstack_curr) != NULL);
DUK_ASSERT(DUK_HOBJECT_IS_COMPFUNC(DUK_ACT_GET_FUNC(thr->callstack_curr)));
DUK_ASSERT(thr->callstack_top >= 1);
DUK_ASSERT(act == thr->callstack_curr);
DUK_ASSERT(act != NULL);
duk__reconfig_valstack_ecma_catcher(thr, act);
DUK_ASSERT(thr->callstack_top >= 1);
DUK_ASSERT(act == thr->callstack_curr);
DUK_ASSERT(act != NULL);
cat = act->cat;
DUK_ASSERT(cat != NULL);
act->curr_pc = cat->pc_base + 1; /* +1 = finally */
DUK_CAT_CLEAR_FINALLY_ENABLED(cat);
}
DUK_LOCAL void duk__handle_label(duk_hthread *thr, duk_small_uint_t lj_type) {
duk_activation *act;
duk_catcher *cat;
DUK_ASSERT(thr != NULL);
DUK_ASSERT(thr->callstack_top >= 1);
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
DUK_ASSERT(DUK_ACT_GET_FUNC(act) != NULL);
DUK_ASSERT(DUK_HOBJECT_HAS_COMPFUNC(DUK_ACT_GET_FUNC(act)));
/* +0 = break, +1 = continue */
cat = act->cat;
DUK_ASSERT(cat != NULL);
DUK_ASSERT(DUK_CAT_GET_TYPE(cat) == DUK_CAT_TYPE_LABEL);
act->curr_pc = cat->pc_base + (lj_type == DUK_LJ_TYPE_CONTINUE ? 1 : 0);
/* valstack should not need changes */
#if defined(DUK_USE_ASSERTIONS)
DUK_ASSERT(thr->callstack_top >= 1);
DUK_ASSERT(act == thr->callstack_curr);
DUK_ASSERT(act != NULL);
DUK_ASSERT((duk_size_t) (thr->valstack_top - thr->valstack_bottom) ==
(duk_size_t) ((duk_hcompfunc *) DUK_ACT_GET_FUNC(act))->nregs);
#endif
}
/* Called for handling both a longjmp() with type DUK_LJ_TYPE_YIELD and
* when a RETURN opcode terminates a thread and yields to the resumer.
* Caller unwinds so that top of callstack is the activation we return to.
*/
#if defined(DUK_USE_COROUTINE_SUPPORT)
DUK_LOCAL void duk__handle_yield(duk_hthread *thr, duk_hthread *resumer, duk_tval *tv_val_unstable) {
duk_activation *act_resumer;
duk_tval *tv1;
DUK_ASSERT(thr != NULL);
DUK_ASSERT(resumer != NULL);
DUK_ASSERT(tv_val_unstable != NULL);
act_resumer = resumer->callstack_curr;
DUK_ASSERT(act_resumer != NULL);
DUK_ASSERT(DUK_ACT_GET_FUNC(act_resumer) != NULL);
DUK_ASSERT(DUK_HOBJECT_IS_COMPFUNC(DUK_ACT_GET_FUNC(act_resumer))); /* resume caller must be an ECMAScript func */
tv1 = (duk_tval *) (void *) ((duk_uint8_t *) resumer->valstack + act_resumer->retval_byteoff); /* return value from Duktape.Thread.resume() */
DUK_TVAL_SET_TVAL_UPDREF(thr, tv1, tv_val_unstable); /* side effects */ /* XXX: avoid side effects */
duk__reconfig_valstack_ecma_return(resumer);
/* caller must change active thread, and set thr->resumer to NULL */
}
#endif /* DUK_USE_COROUTINE_SUPPORT */
DUK_LOCAL duk_small_uint_t duk__handle_longjmp(duk_hthread *thr, duk_activation *entry_act, volatile duk_bool_t *out_delayed_catch_setup) {
duk_small_uint_t retval = DUK__LONGJMP_RESTART;
DUK_ASSERT(thr != NULL);
DUK_ASSERT(entry_act != NULL);
/* 'thr' is the current thread, as no-one resumes except us and we
* switch 'thr' in that case.
*/
DUK_ASSERT(thr == thr->heap->curr_thread);
/*
* (Re)try handling the longjmp.
*
* A longjmp handler may convert the longjmp to a different type and
* "virtually" rethrow by goto'ing to 'check_longjmp'. Before the goto,
* the following must be updated:
* - the heap 'lj' state
* - 'thr' must reflect the "throwing" thread
*/
check_longjmp:
DUK_DD(DUK_DDPRINT("handling longjmp: type=%ld, value1=%!T, value2=%!T, iserror=%ld, top=%ld",
(long) thr->heap->lj.type,
(duk_tval *) &thr->heap->lj.value1,
(duk_tval *) &thr->heap->lj.value2,
(long) thr->heap->lj.iserror,
(long) duk_get_top(thr)));
switch (thr->heap->lj.type) {
#if defined(DUK_USE_COROUTINE_SUPPORT)
case DUK_LJ_TYPE_RESUME: {
/*
* Note: lj.value1 is 'value', lj.value2 is 'resumee'.
* This differs from YIELD.
*/
duk_tval *tv;
duk_tval *tv2;
duk_hthread *resumee;
/* duk_bi_duk_object_yield() and duk_bi_duk_object_resume() ensure all of these are met */
DUK_ASSERT(thr->state == DUK_HTHREAD_STATE_RUNNING); /* unchanged by Duktape.Thread.resume() */
DUK_ASSERT(thr->callstack_top >= 2); /* ECMAScript activation + Duktape.Thread.resume() activation */
DUK_ASSERT(thr->callstack_curr != NULL);
DUK_ASSERT(thr->callstack_curr->parent != NULL);
DUK_ASSERT(DUK_ACT_GET_FUNC(thr->callstack_curr) != NULL &&
DUK_HOBJECT_IS_NATFUNC(DUK_ACT_GET_FUNC(thr->callstack_curr)) &&
((duk_hnatfunc *) DUK_ACT_GET_FUNC(thr->callstack_curr))->func == duk_bi_thread_resume);
tv = &thr->heap->lj.value2; /* resumee */
DUK_ASSERT(DUK_TVAL_IS_OBJECT(tv));
DUK_ASSERT(DUK_TVAL_GET_OBJECT(tv) != NULL);
DUK_ASSERT(DUK_HOBJECT_IS_THREAD(DUK_TVAL_GET_OBJECT(tv)));
resumee = (duk_hthread *) DUK_TVAL_GET_OBJECT(tv);
DUK_ASSERT(resumee != NULL);
DUK_ASSERT(resumee->resumer == NULL);
DUK_ASSERT(resumee->state == DUK_HTHREAD_STATE_INACTIVE ||
resumee->state == DUK_HTHREAD_STATE_YIELDED); /* checked by Duktape.Thread.resume() */
DUK_ASSERT(resumee->state != DUK_HTHREAD_STATE_YIELDED ||
resumee->callstack_top >= 2); /* YIELDED: ECMAScript activation + Duktape.Thread.yield() activation */
DUK_ASSERT(resumee->state != DUK_HTHREAD_STATE_YIELDED ||
(DUK_ACT_GET_FUNC(resumee->callstack_curr) != NULL &&
DUK_HOBJECT_IS_NATFUNC(DUK_ACT_GET_FUNC(resumee->callstack_curr)) &&
((duk_hnatfunc *) DUK_ACT_GET_FUNC(resumee->callstack_curr))->func == duk_bi_thread_yield));
DUK_ASSERT(resumee->state != DUK_HTHREAD_STATE_INACTIVE ||
resumee->callstack_top == 0); /* INACTIVE: no activation, single function value on valstack */
if (thr->heap->lj.iserror) {
/*
* Throw the error in the resumed thread's context; the
* error value is pushed onto the resumee valstack.
*
* Note: the callstack of the target may empty in this case
* too (i.e. the target thread has never been resumed). The
* value stack will contain the initial function in that case,
* which we simply ignore.
*/
DUK_ASSERT(resumee->resumer == NULL);
resumee->resumer = thr;
DUK_HTHREAD_INCREF(thr, thr);
resumee->state = DUK_HTHREAD_STATE_RUNNING;
thr->state = DUK_HTHREAD_STATE_RESUMED;
DUK_HEAP_SWITCH_THREAD(thr->heap, resumee);
thr = resumee;
thr->heap->lj.type = DUK_LJ_TYPE_THROW;
/* thr->heap->lj.value1 is already the value to throw */
/* thr->heap->lj.value2 is 'thread', will be wiped out at the end */
DUK_ASSERT(thr->heap->lj.iserror); /* already set */
DUK_DD(DUK_DDPRINT("-> resume with an error, converted to a throw in the resumee, propagate"));
goto check_longjmp;
} else if (resumee->state == DUK_HTHREAD_STATE_YIELDED) {
/* Unwind previous Duktape.Thread.yield() call. The
* activation remaining must always be an ECMAScript
* call now (yield() accepts calls from ECMAScript
* only).
*/
duk_activation *act_resumee;
DUK_ASSERT(resumee->callstack_top >= 2);
act_resumee = resumee->callstack_curr; /* Duktape.Thread.yield() */
DUK_ASSERT(act_resumee != NULL);
act_resumee = act_resumee->parent; /* ECMAScript call site for yield() */
DUK_ASSERT(act_resumee != NULL);
tv = (duk_tval *) (void *) ((duk_uint8_t *) resumee->valstack + act_resumee->retval_byteoff); /* return value from Duktape.Thread.yield() */
DUK_ASSERT(tv >= resumee->valstack && tv < resumee->valstack_top);
tv2 = &thr->heap->lj.value1;
DUK_TVAL_SET_TVAL_UPDREF(thr, tv, tv2); /* side effects */ /* XXX: avoid side effects */
duk_hthread_activation_unwind_norz(resumee); /* unwind to 'yield' caller */
/* no need to unwind catch stack */
duk__reconfig_valstack_ecma_return(resumee);
DUK_ASSERT(resumee->resumer == NULL);
resumee->resumer = thr;
DUK_HTHREAD_INCREF(thr, thr);
resumee->state = DUK_HTHREAD_STATE_RUNNING;
thr->state = DUK_HTHREAD_STATE_RESUMED;
DUK_HEAP_SWITCH_THREAD(thr->heap, resumee);
#if 0
thr = resumee; /* not needed, as we exit right away */
#endif
DUK_DD(DUK_DDPRINT("-> resume with a value, restart execution in resumee"));
retval = DUK__LONGJMP_RESTART;
goto wipe_and_return;
} else {
/* Initial resume call. */
duk_small_uint_t call_flags;
duk_int_t setup_rc;
/* resumee: [... initial_func] (currently actually: [initial_func]) */
duk_push_undefined(resumee);
tv = &thr->heap->lj.value1;
duk_push_tval(resumee, tv);
/* resumee: [... initial_func undefined(= this) resume_value ] */
call_flags = DUK_CALL_FLAG_ALLOW_ECMATOECMA; /* not tailcall, ecma-to-ecma (assumed to succeed) */
setup_rc = duk_handle_call_unprotected_nargs(resumee, 1 /*nargs*/, call_flags);
if (setup_rc == 0) {
/* This shouldn't happen; Duktape.Thread.resume()
* should make sure of that. If it does happen
* this internal error will propagate out of the
* executor which can be quite misleading.
*/
DUK_ERROR_INTERNAL(thr);
DUK_WO_NORETURN(return 0;);
}
DUK_ASSERT(resumee->resumer == NULL);
resumee->resumer = thr;
DUK_HTHREAD_INCREF(thr, thr);
resumee->state = DUK_HTHREAD_STATE_RUNNING;
thr->state = DUK_HTHREAD_STATE_RESUMED;
DUK_HEAP_SWITCH_THREAD(thr->heap, resumee);
#if 0
thr = resumee; /* not needed, as we exit right away */
#endif
DUK_DD(DUK_DDPRINT("-> resume with a value, restart execution in resumee"));
retval = DUK__LONGJMP_RESTART;
goto wipe_and_return;
}
DUK_UNREACHABLE();
break; /* never here */
}
case DUK_LJ_TYPE_YIELD: {
/*
* Currently only allowed only if yielding thread has only
* ECMAScript activations (except for the Duktape.Thread.yield()
* call at the callstack top) and none of them constructor
* calls.
*
* This excludes the 'entry' thread which will always have
* a preventcount > 0.
*/
duk_hthread *resumer;
/* duk_bi_duk_object_yield() and duk_bi_duk_object_resume() ensure all of these are met */
#if 0 /* entry_thread not available for assert */
DUK_ASSERT(thr != entry_thread); /* Duktape.Thread.yield() should prevent */
#endif
DUK_ASSERT(thr->state == DUK_HTHREAD_STATE_RUNNING); /* unchanged from Duktape.Thread.yield() */
DUK_ASSERT(thr->callstack_top >= 2); /* ECMAScript activation + Duktape.Thread.yield() activation */
DUK_ASSERT(thr->callstack_curr != NULL);
DUK_ASSERT(thr->callstack_curr->parent != NULL);
DUK_ASSERT(DUK_ACT_GET_FUNC(thr->callstack_curr) != NULL &&
DUK_HOBJECT_IS_NATFUNC(DUK_ACT_GET_FUNC(thr->callstack_curr)) &&
((duk_hnatfunc *) DUK_ACT_GET_FUNC(thr->callstack_curr))->func == duk_bi_thread_yield);
DUK_ASSERT(DUK_ACT_GET_FUNC(thr->callstack_curr->parent) != NULL &&
DUK_HOBJECT_IS_COMPFUNC(DUK_ACT_GET_FUNC(thr->callstack_curr->parent))); /* an ECMAScript function */
resumer = thr->resumer;
DUK_ASSERT(resumer != NULL);
DUK_ASSERT(resumer->state == DUK_HTHREAD_STATE_RESUMED); /* written by a previous RESUME handling */
DUK_ASSERT(resumer->callstack_top >= 2); /* ECMAScript activation + Duktape.Thread.resume() activation */
DUK_ASSERT(resumer->callstack_curr != NULL);
DUK_ASSERT(resumer->callstack_curr->parent != NULL);
DUK_ASSERT(DUK_ACT_GET_FUNC(resumer->callstack_curr) != NULL &&
DUK_HOBJECT_IS_NATFUNC(DUK_ACT_GET_FUNC(resumer->callstack_curr)) &&
((duk_hnatfunc *) DUK_ACT_GET_FUNC(resumer->callstack_curr))->func == duk_bi_thread_resume);
DUK_ASSERT(DUK_ACT_GET_FUNC(resumer->callstack_curr->parent) != NULL &&
DUK_HOBJECT_IS_COMPFUNC(DUK_ACT_GET_FUNC(resumer->callstack_curr->parent))); /* an ECMAScript function */
if (thr->heap->lj.iserror) {
thr->state = DUK_HTHREAD_STATE_YIELDED;
thr->resumer = NULL;
DUK_HTHREAD_DECREF_NORZ(thr, resumer);
resumer->state = DUK_HTHREAD_STATE_RUNNING;
DUK_HEAP_SWITCH_THREAD(thr->heap, resumer);
thr = resumer;
thr->heap->lj.type = DUK_LJ_TYPE_THROW;
/* lj.value1 is already set */
DUK_ASSERT(thr->heap->lj.iserror); /* already set */
DUK_DD(DUK_DDPRINT("-> yield an error, converted to a throw in the resumer, propagate"));
goto check_longjmp;
} else {
duk_hthread_activation_unwind_norz(resumer);
duk__handle_yield(thr, resumer, &thr->heap->lj.value1);
thr->state = DUK_HTHREAD_STATE_YIELDED;
thr->resumer = NULL;
DUK_HTHREAD_DECREF_NORZ(thr, resumer);
resumer->state = DUK_HTHREAD_STATE_RUNNING;
DUK_HEAP_SWITCH_THREAD(thr->heap, resumer);
#if 0
thr = resumer; /* not needed, as we exit right away */
#endif
DUK_DD(DUK_DDPRINT("-> yield a value, restart execution in resumer"));
retval = DUK__LONGJMP_RESTART;
goto wipe_and_return;
}
DUK_UNREACHABLE();
break; /* never here */
}
#endif /* DUK_USE_COROUTINE_SUPPORT */
case DUK_LJ_TYPE_THROW: {
/*
* Three possible outcomes:
* * A try or finally catcher is found => resume there.
* (or)
* * The error propagates to the bytecode executor entry
* level (and we're in the entry thread) => rethrow
* with a new longjmp(), after restoring the previous
* catchpoint.
* * The error is not caught in the current thread, so
* the thread finishes with an error. This works like
* a yielded error, except that the thread is finished
* and can no longer be resumed. (There is always a
* resumer in this case.)
*
* Note: until we hit the entry level, there can only be
* ECMAScript activations.
*/
duk_activation *act;
duk_catcher *cat;
duk_hthread *resumer;
for (;;) {
act = thr->callstack_curr;
if (act == NULL) {
break;
}
for (;;) {
cat = act->cat;
if (cat == NULL) {
break;
}
if (DUK_CAT_HAS_CATCH_ENABLED(cat)) {
DUK_ASSERT(DUK_CAT_GET_TYPE(cat) == DUK_CAT_TYPE_TCF);
DUK_DDD(DUK_DDDPRINT("before catch part 1: thr=%p, act=%p, cat=%p",
(void *) thr, (void *) act, (void *) act->cat));
duk__handle_catch_part1(thr,
&thr->heap->lj.value1,
DUK_LJ_TYPE_THROW,
out_delayed_catch_setup);
DUK_DD(DUK_DDPRINT("-> throw caught by a 'catch' clause, restart execution"));
retval = DUK__LONGJMP_RESTART;
goto wipe_and_return;
}
if (DUK_CAT_HAS_FINALLY_ENABLED(cat)) {
DUK_ASSERT(DUK_CAT_GET_TYPE(cat) == DUK_CAT_TYPE_TCF);
DUK_ASSERT(!DUK_CAT_HAS_CATCH_ENABLED(cat));
duk__handle_finally(thr,
&thr->heap->lj.value1,
DUK_LJ_TYPE_THROW);
DUK_DD(DUK_DDPRINT("-> throw caught by a 'finally' clause, restart execution"));
retval = DUK__LONGJMP_RESTART;
goto wipe_and_return;
}
duk_hthread_catcher_unwind_norz(thr, act);
}
if (act == entry_act) {
/* Not caught by anything before entry level; rethrow and let the
* final catcher finish unwinding (esp. value stack).
*/
DUK_D(DUK_DPRINT("-> throw propagated up to entry level, rethrow and exit bytecode executor"));
retval = DUK__LONGJMP_RETHROW;
goto just_return;
}
duk_hthread_activation_unwind_norz(thr);
}
DUK_DD(DUK_DDPRINT("-> throw not caught by current thread, yield error to resumer and recheck longjmp"));
/* Not caught by current thread, thread terminates (yield error to resumer);
* note that this may cause a cascade if the resumer terminates with an uncaught
* exception etc (this is OK, but needs careful testing).
*/
DUK_ASSERT(thr->resumer != NULL);
DUK_ASSERT(thr->resumer->callstack_top >= 2); /* ECMAScript activation + Duktape.Thread.resume() activation */
DUK_ASSERT(thr->resumer->callstack_curr != NULL);
DUK_ASSERT(thr->resumer->callstack_curr->parent != NULL);
DUK_ASSERT(DUK_ACT_GET_FUNC(thr->resumer->callstack_curr->parent) != NULL &&
DUK_HOBJECT_IS_COMPFUNC(DUK_ACT_GET_FUNC(thr->resumer->callstack_curr->parent))); /* an ECMAScript function */
resumer = thr->resumer;
/* reset longjmp */
DUK_ASSERT(thr->heap->lj.type == DUK_LJ_TYPE_THROW); /* already set */
/* lj.value1 already set */
duk_hthread_terminate(thr); /* updates thread state, minimizes its allocations */
DUK_ASSERT(thr->state == DUK_HTHREAD_STATE_TERMINATED);
thr->resumer = NULL;
DUK_HTHREAD_DECREF_NORZ(thr, resumer);
resumer->state = DUK_HTHREAD_STATE_RUNNING;
DUK_HEAP_SWITCH_THREAD(thr->heap, resumer);
thr = resumer;
goto check_longjmp;
}
case DUK_LJ_TYPE_BREAK: /* pseudotypes, not used in actual longjmps */
case DUK_LJ_TYPE_CONTINUE:
case DUK_LJ_TYPE_RETURN:
case DUK_LJ_TYPE_NORMAL:
default: {
/* should never happen, but be robust */
DUK_D(DUK_DPRINT("caught unknown longjmp type %ld, treat as internal error", (long) thr->heap->lj.type));
goto convert_to_internal_error;
}
} /* end switch */
DUK_UNREACHABLE();
wipe_and_return:
DUK_DD(DUK_DDPRINT("handling longjmp done, wipe-and-return, top=%ld",
(long) duk_get_top(thr)));
thr->heap->lj.type = DUK_LJ_TYPE_UNKNOWN;
thr->heap->lj.iserror = 0;
DUK_TVAL_SET_UNDEFINED_UPDREF(thr, &thr->heap->lj.value1); /* side effects */
DUK_TVAL_SET_UNDEFINED_UPDREF(thr, &thr->heap->lj.value2); /* side effects */
DUK_GC_TORTURE(thr->heap);
just_return:
return retval;
convert_to_internal_error:
/* This could also be thrown internally (set the error, goto check_longjmp),
* but it's better for internal errors to bubble outwards so that we won't
* infinite loop in this catchpoint.
*/
DUK_ERROR_INTERNAL(thr);
DUK_WO_NORETURN(return 0;);
}
/* Handle a BREAK/CONTINUE opcode. Avoid using longjmp() for BREAK/CONTINUE
* handling because it has a measurable performance impact in ordinary
* environments and an extreme impact in Emscripten (GH-342).
*/
DUK_LOCAL DUK_EXEC_NOINLINE_PERF void duk__handle_break_or_continue(duk_hthread *thr,
duk_uint_t label_id,
duk_small_uint_t lj_type) {
duk_activation *act;
duk_catcher *cat;
DUK_ASSERT(thr != NULL);
/* Find a matching label catcher or 'finally' catcher in
* the same function, unwinding catchers as we go.
*
* A label catcher must always exist and will match unless
* a 'finally' captures the break/continue first. It is the
* compiler's responsibility to ensure that labels are used
* correctly.
*/
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
for (;;) {
cat = act->cat;
if (cat == NULL) {
break;
}
DUK_DDD(DUK_DDDPRINT("considering catcher %p: type=%ld label=%ld",
(void *) cat,
(long) DUK_CAT_GET_TYPE(cat),
(long) DUK_CAT_GET_LABEL(cat)));
/* XXX: bit mask test; FINALLY <-> TCF, single bit mask would suffice? */
if (DUK_CAT_GET_TYPE(cat) == DUK_CAT_TYPE_TCF &&
DUK_CAT_HAS_FINALLY_ENABLED(cat)) {
duk_tval tv_tmp;
DUK_TVAL_SET_U32(&tv_tmp, (duk_uint32_t) label_id);
duk__handle_finally(thr, &tv_tmp, lj_type);
DUK_DD(DUK_DDPRINT("-> break/continue caught by 'finally', restart execution"));
return;
}
if (DUK_CAT_GET_TYPE(cat) == DUK_CAT_TYPE_LABEL &&
(duk_uint_t) DUK_CAT_GET_LABEL(cat) == label_id) {
duk__handle_label(thr, lj_type);
DUK_DD(DUK_DDPRINT("-> break/continue caught by a label catcher (in the same function), restart execution"));
return;
}
duk_hthread_catcher_unwind_norz(thr, act);
}
/* Should never happen, but be robust. */
DUK_D(DUK_DPRINT("-> break/continue not caught by anything in the current function (should never happen), throw internal error"));
DUK_ERROR_INTERNAL(thr);
DUK_WO_NORETURN(return;);
}
/* Handle a RETURN opcode. Avoid using longjmp() for return handling because
* it has a measurable performance impact in ordinary environments and an extreme
* impact in Emscripten (GH-342). Return value is on value stack top.
*/
DUK_LOCAL duk_small_uint_t duk__handle_return(duk_hthread *thr, duk_activation *entry_act) {
duk_tval *tv1;
duk_tval *tv2;
#if defined(DUK_USE_COROUTINE_SUPPORT)
duk_hthread *resumer;
#endif
duk_activation *act;
duk_catcher *cat;
/* We can directly access value stack here. */
DUK_ASSERT(thr != NULL);
DUK_ASSERT(entry_act != NULL);
DUK_ASSERT(thr->valstack_top - 1 >= thr->valstack_bottom);
tv1 = thr->valstack_top - 1;
DUK_TVAL_CHKFAST_INPLACE_FAST(tv1); /* fastint downgrade check for return values */
/*
* Four possible outcomes:
*
* 1. A 'finally' in the same function catches the 'return'.
* It may continue to propagate when 'finally' is finished,
* or it may be neutralized by 'finally' (both handled by
* ENDFIN).
*
* 2. The return happens at the entry level of the bytecode
* executor, so return from the executor (in C stack).
*
* 3. There is a calling (ECMAScript) activation in the call
* stack => return to it, in the same executor instance.
*
* 4. There is no calling activation, and the thread is
* terminated. There is always a resumer in this case,
* which gets the return value similarly to a 'yield'
* (except that the current thread can no longer be
* resumed).
*/
DUK_ASSERT(thr != NULL);
DUK_ASSERT(thr->callstack_top >= 1);
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
for (;;) {
cat = act->cat;
if (cat == NULL) {
break;
}
if (DUK_CAT_GET_TYPE(cat) == DUK_CAT_TYPE_TCF &&
DUK_CAT_HAS_FINALLY_ENABLED(cat)) {
DUK_ASSERT(thr->valstack_top - 1 >= thr->valstack_bottom);
duk__handle_finally(thr, thr->valstack_top - 1, DUK_LJ_TYPE_RETURN);
DUK_DD(DUK_DDPRINT("-> return caught by 'finally', restart execution"));
return DUK__RETHAND_RESTART;
}
duk_hthread_catcher_unwind_norz(thr, act);
}
if (act == entry_act) {
/* Return to the bytecode executor caller who will unwind stacks
* and handle constructor post-processing.
* Return value is already on the stack top: [ ... retval ].
*/
DUK_DDD(DUK_DDDPRINT("-> return propagated up to entry level, exit bytecode executor"));
return DUK__RETHAND_FINISHED;
}
if (thr->callstack_top >= 2) {
/* There is a caller; it MUST be an ECMAScript caller (otherwise it would
* match entry_act check).
*/
DUK_DDD(DUK_DDDPRINT("return to ECMAScript caller, retval_byteoff=%ld, lj_value1=%!T",
(long) (thr->callstack_curr->parent->retval_byteoff),
(duk_tval *) &thr->heap->lj.value1));
DUK_ASSERT(thr->callstack_curr != NULL);
DUK_ASSERT(thr->callstack_curr->parent != NULL);
DUK_ASSERT(DUK_HOBJECT_IS_COMPFUNC(DUK_ACT_GET_FUNC(thr->callstack_curr->parent))); /* must be ECMAScript */
#if defined(DUK_USE_ES6_PROXY)
if (thr->callstack_curr->flags & (DUK_ACT_FLAG_CONSTRUCT | DUK_ACT_FLAG_CONSTRUCT_PROXY)) {
duk_call_construct_postprocess(thr, thr->callstack_curr->flags & DUK_ACT_FLAG_CONSTRUCT_PROXY); /* side effects */
}
#else
if (thr->callstack_curr->flags & DUK_ACT_FLAG_CONSTRUCT) {
duk_call_construct_postprocess(thr, 0); /* side effects */
}
#endif
tv1 = (duk_tval *) (void *) ((duk_uint8_t *) thr->valstack + thr->callstack_curr->parent->retval_byteoff);
DUK_ASSERT(thr->valstack_top - 1 >= thr->valstack_bottom);
tv2 = thr->valstack_top - 1;
DUK_TVAL_SET_TVAL_UPDREF(thr, tv1, tv2); /* side effects */
/* Catch stack unwind happens inline in callstack unwind. */
duk_hthread_activation_unwind_norz(thr);
duk__reconfig_valstack_ecma_return(thr);
DUK_DD(DUK_DDPRINT("-> return not intercepted, restart execution in caller"));
return DUK__RETHAND_RESTART;
}
#if defined(DUK_USE_COROUTINE_SUPPORT)
DUK_DD(DUK_DDPRINT("no calling activation, thread finishes (similar to yield)"));
DUK_ASSERT(thr->resumer != NULL);
DUK_ASSERT(thr->resumer->callstack_top >= 2); /* ECMAScript activation + Duktape.Thread.resume() activation */
DUK_ASSERT(thr->resumer->callstack_curr != NULL);
DUK_ASSERT(thr->resumer->callstack_curr->parent != NULL);
DUK_ASSERT(DUK_ACT_GET_FUNC(thr->resumer->callstack_curr) != NULL &&
DUK_HOBJECT_IS_NATFUNC(DUK_ACT_GET_FUNC(thr->resumer->callstack_curr)) &&
((duk_hnatfunc *) DUK_ACT_GET_FUNC(thr->resumer->callstack_curr))->func == duk_bi_thread_resume); /* Duktape.Thread.resume() */
DUK_ASSERT(DUK_ACT_GET_FUNC(thr->resumer->callstack_curr->parent) != NULL &&
DUK_HOBJECT_IS_COMPFUNC(DUK_ACT_GET_FUNC(thr->resumer->callstack_curr->parent))); /* an ECMAScript function */
DUK_ASSERT(thr->state == DUK_HTHREAD_STATE_RUNNING);
DUK_ASSERT(thr->resumer->state == DUK_HTHREAD_STATE_RESUMED);
resumer = thr->resumer;
/* Share yield longjmp handler.
*
* This sequence of steps is a bit fragile (see GH-1845):
* - We need the return value from 'thr' (resumed thread) value stack.
* The termination unwinds its value stack, losing the value.
* - We need a refcounted reference for 'thr', which may only exist
* in the caller value stack. We can't unwind or reconfigure the
* caller's value stack without potentially freeing 'thr'.
*
* Current approach is to capture the 'thr' return value and store
* a reference to 'thr' in the caller value stack temporarily. This
* keeps 'thr' reachable until final yield/return handling which
* removes the references atomatically.
*/
DUK_ASSERT(thr->valstack_top - 1 >= thr->valstack_bottom);
duk_hthread_activation_unwind_norz(resumer); /* May remove last reference to 'thr', but is NORZ. */
duk_push_tval(resumer, thr->valstack_top - 1); /* Capture return value, side effect free. */
duk_push_hthread(resumer, thr); /* Make 'thr' reachable again, before side effects. */
duk_hthread_terminate(thr); /* Updates thread state, minimizes its allocations. */
thr->resumer = NULL;
DUK_HTHREAD_DECREF(thr, resumer);
DUK_ASSERT(thr->state == DUK_HTHREAD_STATE_TERMINATED);
resumer->state = DUK_HTHREAD_STATE_RUNNING;
DUK_HEAP_SWITCH_THREAD(thr->heap, resumer);
DUK_ASSERT(resumer->valstack_top - 2 >= resumer->valstack_bottom);
duk__handle_yield(thr, resumer, resumer->valstack_top - 2);
thr = NULL; /* 'thr' invalidated by call */
#if 0
thr = resumer; /* not needed */
#endif
DUK_DD(DUK_DDPRINT("-> return not caught, thread terminated; handle like yield, restart execution in resumer"));
return DUK__RETHAND_RESTART;
#else
/* Without coroutine support this case should never happen. */
DUK_ERROR_INTERNAL(thr);
DUK_WO_NORETURN(return 0;);
#endif
}
/*
* Executor interrupt handling
*
* The handler is called whenever the interrupt countdown reaches zero
* (or below). The handler must perform whatever checks are activated,
* e.g. check for cumulative step count to impose an execution step
* limit or check for breakpoints or other debugger interaction.
*
* When the actions are done, the handler must reinit the interrupt
* init and counter values. The 'init' value must indicate how many
* bytecode instructions are executed before the next interrupt. The
* counter must interface with the bytecode executor loop. Concretely,
* the new init value is normally one higher than the new counter value.
* For instance, to execute exactly one bytecode instruction the init
* value is set to 1 and the counter to 0. If an error is thrown by the
* interrupt handler, the counters are set to the same value (e.g. both
* to 0 to cause an interrupt when the next bytecode instruction is about
* to be executed after error handling).
*
* Maintaining the init/counter value properly is important for accurate
* behavior. For instance, executor step limit needs a cumulative step
* count which is simply computed as a sum of 'init' values. This must
* work accurately even when single stepping.
*/
#if defined(DUK_USE_INTERRUPT_COUNTER)
#define DUK__INT_NOACTION 0 /* no specific action, resume normal execution */
#define DUK__INT_RESTART 1 /* must "goto restart_execution", e.g. breakpoints changed */
#if defined(DUK_USE_DEBUGGER_SUPPORT)
DUK_LOCAL void duk__interrupt_handle_debugger(duk_hthread *thr, duk_bool_t *out_immediate, duk_small_uint_t *out_interrupt_retval) {
duk_activation *act;
duk_breakpoint *bp;
duk_breakpoint **bp_active;
duk_uint_fast32_t line = 0;
duk_bool_t process_messages;
duk_bool_t processed_messages = 0;
DUK_ASSERT(thr->heap->dbg_processing == 0); /* don't re-enter e.g. during Eval */
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
/* It might seem that replacing 'thr->heap' with just 'heap' below
* might be a good idea, but it increases code size slightly
* (probably due to unnecessary spilling) at least on x64.
*/
/*
* Single opcode step check
*/
if (thr->heap->dbg_pause_flags & DUK_PAUSE_FLAG_ONE_OPCODE_ACTIVE) {
DUK_D(DUK_DPRINT("PAUSE TRIGGERED by one opcode step"));
duk_debug_set_paused(thr->heap);
}
/*
* Breakpoint and step state checks
*/
if (act->flags & DUK_ACT_FLAG_BREAKPOINT_ACTIVE ||
(thr->heap->dbg_pause_act == thr->callstack_curr)) {
line = duk_debug_curr_line(thr);
if (act->prev_line != line) {
/* Stepped? Step out is handled by callstack unwind. */
if ((thr->heap->dbg_pause_flags & DUK_PAUSE_FLAG_LINE_CHANGE) &&
(thr->heap->dbg_pause_act == thr->callstack_curr) &&
(line != thr->heap->dbg_pause_startline)) {
DUK_D(DUK_DPRINT("PAUSE TRIGGERED by line change, at line %ld",
(long) line));
duk_debug_set_paused(thr->heap);
}
/* Check for breakpoints only on line transition.
* Breakpoint is triggered when we enter the target
* line from a different line, and the previous line
* was within the same function.
*
* This condition is tricky: the condition used to be
* that transition to -or across- the breakpoint line
* triggered the breakpoint. This seems intuitively
* better because it handles breakpoints on lines with
* no emitted opcodes; but this leads to the issue
* described in: https://github.com/svaarala/duktape/issues/263.
*/
bp_active = thr->heap->dbg_breakpoints_active;
for (;;) {
bp = *bp_active++;
if (bp == NULL) {
break;
}
DUK_ASSERT(bp->filename != NULL);
if (act->prev_line != bp->line && line == bp->line) {
DUK_D(DUK_DPRINT("PAUSE TRIGGERED by breakpoint at %!O:%ld",
(duk_heaphdr *) bp->filename, (long) bp->line));
duk_debug_set_paused(thr->heap);
}
}
} else {
;
}
act->prev_line = (duk_uint32_t) line;
}
/*
* Rate limit check for sending status update or peeking into
* the debug transport. Both can be expensive operations that
* we don't want to do on every opcode.
*
* Making sure the interval remains reasonable on a wide variety
* of targets and bytecode is difficult without a timestamp, so
* we use a Date-provided timestamp for the rate limit check.
* But since it's also expensive to get a timestamp, a bytecode
* counter is used to rate limit getting timestamps.
*/
process_messages = 0;
if (thr->heap->dbg_state_dirty || DUK_HEAP_HAS_DEBUGGER_PAUSED(thr->heap) || thr->heap->dbg_detaching) {
/* Enter message processing loop for sending Status notifys and
* to finish a pending detach.
*/
process_messages = 1;
}
/* XXX: remove heap->dbg_exec_counter, use heap->inst_count_interrupt instead? */
DUK_ASSERT(thr->interrupt_init >= 0);
thr->heap->dbg_exec_counter += (duk_uint_t) thr->interrupt_init;
if (thr->heap->dbg_exec_counter - thr->heap->dbg_last_counter >= DUK_HEAP_DBG_RATELIMIT_OPCODES) {
/* Overflow of the execution counter is fine and doesn't break
* anything here.
*/
duk_double_t now, diff_last;
thr->heap->dbg_last_counter = thr->heap->dbg_exec_counter;
now = duk_time_get_monotonic_time(thr);
diff_last = now - thr->heap->dbg_last_time;
if (diff_last < 0.0 || diff_last >= (duk_double_t) DUK_HEAP_DBG_RATELIMIT_MILLISECS) {
/* Monotonic time should not experience time jumps,
* but the provider may be missing and we're actually
* using ECMAScript time. So, tolerate negative values
* so that a time jump works reasonably.
*
* Same interval is now used for status sending and
* peeking.
*/
thr->heap->dbg_last_time = now;
thr->heap->dbg_state_dirty = 1;
process_messages = 1;
}
}
/*
* Process messages and send status if necessary.
*
* If we're paused, we'll block for new messages. If we're not
* paused, we'll process anything we can peek but won't block
* for more. Detach (and re-attach) handling is all localized
* to duk_debug_process_messages() too.
*
* Debugger writes outside the message loop may cause debugger
* detach1 phase to run, after which dbg_read_cb == NULL and
* dbg_detaching != 0. The message loop will finish the detach
* by running detach2 phase, so enter the message loop also when
* detaching.
*/
if (process_messages) {
DUK_ASSERT(thr->heap->dbg_processing == 0);
processed_messages = duk_debug_process_messages(thr, 0 /*no_block*/);
DUK_ASSERT(thr->heap->dbg_processing == 0);
}
/* Continue checked execution if there are breakpoints or we're stepping.
* Also use checked execution if paused flag is active - it shouldn't be
* because the debug message loop shouldn't terminate if it was. Step out
* is handled by callstack unwind and doesn't need checked execution.
* Note that debugger may have detached due to error or explicit request
* above, so we must recheck attach status.
*/
if (duk_debug_is_attached(thr->heap)) {
DUK_ASSERT(act == thr->callstack_curr);
DUK_ASSERT(act != NULL);
if (act->flags & DUK_ACT_FLAG_BREAKPOINT_ACTIVE ||
(thr->heap->dbg_pause_flags & DUK_PAUSE_FLAG_ONE_OPCODE) ||
((thr->heap->dbg_pause_flags & DUK_PAUSE_FLAG_LINE_CHANGE) &&
thr->heap->dbg_pause_act == thr->callstack_curr) ||
DUK_HEAP_HAS_DEBUGGER_PAUSED(thr->heap)) {
*out_immediate = 1;
}
/* If we processed any debug messages breakpoints may have
* changed; restart execution to re-check active breakpoints.
*/
if (processed_messages) {
DUK_D(DUK_DPRINT("processed debug messages, restart execution to recheck possibly changed breakpoints"));
*out_interrupt_retval = DUK__INT_RESTART;
} else {
if (thr->heap->dbg_pause_flags & DUK_PAUSE_FLAG_ONE_OPCODE) {
/* Set 'pause after one opcode' active only when we're
* actually just about to execute code.
*/
thr->heap->dbg_pause_flags |= DUK_PAUSE_FLAG_ONE_OPCODE_ACTIVE;
}
}
} else {
DUK_D(DUK_DPRINT("debugger became detached, resume normal execution"));
}
}
#endif /* DUK_USE_DEBUGGER_SUPPORT */
DUK_LOCAL DUK_EXEC_NOINLINE_PERF DUK_COLD duk_small_uint_t duk__executor_interrupt(duk_hthread *thr) {
duk_int_t ctr;
duk_activation *act;
duk_hcompfunc *fun;
duk_bool_t immediate = 0;
duk_small_uint_t retval;
DUK_ASSERT(thr != NULL);
DUK_ASSERT(thr->heap != NULL);
DUK_ASSERT(thr->callstack_top > 0);
#if defined(DUK_USE_DEBUG)
thr->heap->inst_count_interrupt += thr->interrupt_init;
DUK_DD(DUK_DDPRINT("execution interrupt, counter=%ld, init=%ld, "
"instruction counts: executor=%ld, interrupt=%ld",
(long) thr->interrupt_counter, (long) thr->interrupt_init,
(long) thr->heap->inst_count_exec, (long) thr->heap->inst_count_interrupt));
#endif
retval = DUK__INT_NOACTION;
ctr = DUK_HTHREAD_INTCTR_DEFAULT;
/*
* Avoid nested calls. Concretely this happens during debugging, e.g.
* when we eval() an expression.
*
* Also don't interrupt if we're currently doing debug processing
* (which can be initiated outside the bytecode executor) as this
* may cause the debugger to be called recursively. Check required
* for correct operation of throw intercept and other "exotic" halting
* scenarios.
*/
#if defined(DUK_USE_DEBUGGER_SUPPORT)
if (DUK_HEAP_HAS_INTERRUPT_RUNNING(thr->heap) || thr->heap->dbg_processing) {
#else
if (DUK_HEAP_HAS_INTERRUPT_RUNNING(thr->heap)) {
#endif
DUK_DD(DUK_DDPRINT("nested executor interrupt, ignoring"));
/* Set a high interrupt counter; the original executor
* interrupt invocation will rewrite before exiting.
*/
thr->interrupt_init = ctr;
thr->interrupt_counter = ctr - 1;
return DUK__INT_NOACTION;
}
DUK_HEAP_SET_INTERRUPT_RUNNING(thr->heap);
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
fun = (duk_hcompfunc *) DUK_ACT_GET_FUNC(act);
DUK_ASSERT(DUK_HOBJECT_HAS_COMPFUNC((duk_hobject *) fun));
DUK_UNREF(fun);
#if defined(DUK_USE_EXEC_TIMEOUT_CHECK)
/*
* Execution timeout check
*/
if (DUK_USE_EXEC_TIMEOUT_CHECK(thr->heap->heap_udata)) {
/* Keep throwing an error whenever we get here. The unusual values
* are set this way because no instruction is ever executed, we just
* throw an error until all try/catch/finally and other catchpoints
* have been exhausted. Duktape/C code gets control at each protected
* call but whenever it enters back into Duktape the RangeError gets
* raised. User exec timeout check must consistently indicate a timeout
* until we've fully bubbled out of Duktape.
*/
DUK_D(DUK_DPRINT("execution timeout, throwing a RangeError"));
thr->interrupt_init = 0;
thr->interrupt_counter = 0;
DUK_HEAP_CLEAR_INTERRUPT_RUNNING(thr->heap);
DUK_ERROR_RANGE(thr, "execution timeout");
DUK_WO_NORETURN(return 0;);
}
#endif /* DUK_USE_EXEC_TIMEOUT_CHECK */
#if defined(DUK_USE_DEBUGGER_SUPPORT)
if (!thr->heap->dbg_processing &&
(thr->heap->dbg_read_cb != NULL || thr->heap->dbg_detaching)) {
/* Avoid recursive re-entry; enter when we're attached or
* detaching (to finish off the pending detach).
*/
duk__interrupt_handle_debugger(thr, &immediate, &retval);
DUK_ASSERT(act == thr->callstack_curr);
}
#endif /* DUK_USE_DEBUGGER_SUPPORT */
/*
* Update the interrupt counter
*/
if (immediate) {
/* Cause an interrupt after executing one instruction. */
ctr = 1;
}
/* The counter value is one less than the init value: init value should
* indicate how many instructions are executed before interrupt. To
* execute 1 instruction (after interrupt handler return), counter must
* be 0.
*/
DUK_ASSERT(ctr >= 1);
thr->interrupt_init = ctr;
thr->interrupt_counter = ctr - 1;
DUK_HEAP_CLEAR_INTERRUPT_RUNNING(thr->heap);
return retval;
}
#endif /* DUK_USE_INTERRUPT_COUNTER */
/*
* Debugger handling for executor restart
*
* Check for breakpoints, stepping, etc, and figure out if we should execute
* in checked or normal mode. Note that we can't do this when an activation
* is created, because breakpoint status (and stepping status) may change
* later, so we must recheck every time we're executing an activation.
* This primitive should be side effect free to avoid changes during check.
*/
#if defined(DUK_USE_DEBUGGER_SUPPORT)
DUK_LOCAL void duk__executor_recheck_debugger(duk_hthread *thr, duk_activation *act, duk_hcompfunc *fun) {
duk_heap *heap;
duk_tval *tv_tmp;
duk_hstring *filename;
duk_small_uint_t bp_idx;
duk_breakpoint **bp_active;
DUK_ASSERT(thr != NULL);
DUK_ASSERT(act != NULL);
DUK_ASSERT(fun != NULL);
heap = thr->heap;
bp_active = heap->dbg_breakpoints_active;
act->flags &= ~DUK_ACT_FLAG_BREAKPOINT_ACTIVE;
tv_tmp = duk_hobject_find_entry_tval_ptr_stridx(thr->heap, (duk_hobject *) fun, DUK_STRIDX_FILE_NAME);
if (tv_tmp && DUK_TVAL_IS_STRING(tv_tmp)) {
filename = DUK_TVAL_GET_STRING(tv_tmp);
/* Figure out all active breakpoints. A breakpoint is
* considered active if the current function's fileName
* matches the breakpoint's fileName, AND there is no
* inner function that has matching line numbers
* (otherwise a breakpoint would be triggered both
* inside and outside of the inner function which would
* be confusing). Example:
*
* function foo() {
* print('foo');
* function bar() { <-. breakpoints in these
* print('bar'); | lines should not affect
* } <-' foo() execution
* bar();
* }
*
* We need a few things that are only available when
* debugger support is enabled: (1) a line range for
* each function, and (2) access to the function
* template to access the inner functions (and their
* line ranges).
*
* It's important to have a narrow match for active
* breakpoints so that we don't enter checked execution
* when that's not necessary. For instance, if we're
* running inside a certain function and there's
* breakpoint outside in (after the call site), we
* don't want to slow down execution of the function.
*/
for (bp_idx = 0; bp_idx < heap->dbg_breakpoint_count; bp_idx++) {
duk_breakpoint *bp = heap->dbg_breakpoints + bp_idx;
duk_hobject **funcs, **funcs_end;
duk_hcompfunc *inner_fun;
duk_bool_t bp_match;
if (bp->filename == filename &&
bp->line >= fun->start_line && bp->line <= fun->end_line) {
bp_match = 1;
DUK_DD(DUK_DDPRINT("breakpoint filename and line match: "
"%s:%ld vs. %s (line %ld vs. %ld-%ld)",
DUK_HSTRING_GET_DATA(bp->filename),
(long) bp->line,
DUK_HSTRING_GET_DATA(filename),
(long) bp->line,
(long) fun->start_line,
(long) fun->end_line));
funcs = DUK_HCOMPFUNC_GET_FUNCS_BASE(thr->heap, fun);
funcs_end = DUK_HCOMPFUNC_GET_FUNCS_END(thr->heap, fun);
while (funcs != funcs_end) {
inner_fun = (duk_hcompfunc *) *funcs;
DUK_ASSERT(DUK_HOBJECT_IS_COMPFUNC((duk_hobject *) inner_fun));
if (bp->line >= inner_fun->start_line && bp->line <= inner_fun->end_line) {
DUK_DD(DUK_DDPRINT("inner function masks ('captures') breakpoint"));
bp_match = 0;
break;
}
funcs++;
}
if (bp_match) {
/* No need to check for size of bp_active list,
* it's always larger than maximum number of
* breakpoints.
*/
act->flags |= DUK_ACT_FLAG_BREAKPOINT_ACTIVE;
*bp_active = heap->dbg_breakpoints + bp_idx;
bp_active++;
}
}
}
}
*bp_active = NULL; /* terminate */
DUK_DD(DUK_DDPRINT("ACTIVE BREAKPOINTS: %ld", (long) (bp_active - thr->heap->dbg_breakpoints_active)));
/* Force pause if we were doing "step into" in another activation. */
if ((thr->heap->dbg_pause_flags & DUK_PAUSE_FLAG_FUNC_ENTRY) &&
thr->heap->dbg_pause_act != thr->callstack_curr) {
DUK_D(DUK_DPRINT("PAUSE TRIGGERED by function entry"));
duk_debug_set_paused(thr->heap);
}
/* Force interrupt right away if we're paused or in "checked mode".
* Step out is handled by callstack unwind.
*/
if ((act->flags & DUK_ACT_FLAG_BREAKPOINT_ACTIVE) ||
DUK_HEAP_HAS_DEBUGGER_PAUSED(thr->heap) ||
((thr->heap->dbg_pause_flags & DUK_PAUSE_FLAG_LINE_CHANGE) &&
thr->heap->dbg_pause_act == thr->callstack_curr)) {
/* We'll need to interrupt early so recompute the init
* counter to reflect the number of bytecode instructions
* executed so that step counts for e.g. debugger rate
* limiting are accurate.
*/
DUK_ASSERT(thr->interrupt_counter <= thr->interrupt_init);
thr->interrupt_init = thr->interrupt_init - thr->interrupt_counter;
thr->interrupt_counter = 0;
}
}
#endif /* DUK_USE_DEBUGGER_SUPPORT */
/*
* Opcode handlers for opcodes with a lot of code and which are relatively
* rare; NOINLINE to reduce amount of code in main bytecode dispatcher.
*/
DUK_LOCAL DUK_EXEC_NOINLINE_PERF void duk__handle_op_initset_initget(duk_hthread *thr, duk_uint_fast32_t ins) {
duk_bool_t is_set = (DUK_DEC_OP(ins) == DUK_OP_INITSET);
duk_uint_fast_t idx;
duk_uint_t defprop_flags;
/* A -> object register (acts as a source)
* BC -> BC+0 contains key, BC+1 closure (value)
*/
/* INITSET/INITGET are only used to initialize object literal keys.
* There may be a previous propery in ES2015 because duplicate property
* names are allowed.
*/
/* This could be made more optimal by accessing internals directly. */
idx = (duk_uint_fast_t) DUK_DEC_BC(ins);
duk_dup(thr, (duk_idx_t) (idx + 0)); /* key */
duk_dup(thr, (duk_idx_t) (idx + 1)); /* getter/setter */
if (is_set) {
defprop_flags = DUK_DEFPROP_HAVE_SETTER |
DUK_DEFPROP_FORCE |
DUK_DEFPROP_SET_ENUMERABLE |
DUK_DEFPROP_SET_CONFIGURABLE;
} else {
defprop_flags = DUK_DEFPROP_HAVE_GETTER |
DUK_DEFPROP_FORCE |
DUK_DEFPROP_SET_ENUMERABLE |
DUK_DEFPROP_SET_CONFIGURABLE;
}
duk_def_prop(thr, (duk_idx_t) DUK_DEC_A(ins), defprop_flags);
}
DUK_LOCAL DUK_EXEC_NOINLINE_PERF void duk__handle_op_trycatch(duk_hthread *thr, duk_uint_fast32_t ins, duk_instr_t *curr_pc) {
duk_activation *act;
duk_catcher *cat;
duk_tval *tv1;
duk_small_uint_fast_t a;
duk_small_uint_fast_t bc;
/* A -> flags
* BC -> reg_catch; base register for two registers used both during
* trycatch setup and when catch is triggered
*
* If DUK_BC_TRYCATCH_FLAG_CATCH_BINDING set:
* reg_catch + 0: catch binding variable name (string).
* Automatic declarative environment is established for
* the duration of the 'catch' clause.
*
* If DUK_BC_TRYCATCH_FLAG_WITH_BINDING set:
* reg_catch + 0: with 'target value', which is coerced to
* an object and then used as a bindind object for an
* environment record. The binding is initialized here, for
* the 'try' clause.
*
* Note that a TRYCATCH generated for a 'with' statement has no
* catch or finally parts.
*/
/* XXX: TRYCATCH handling should be reworked to avoid creating
* an explicit scope unless it is actually needed (e.g. function
* instances or eval is executed inside the catch block). This
* rework is not trivial because the compiler doesn't have an
* intermediate representation. When the rework is done, the
* opcode format can also be made more straightforward.
*/
/* XXX: side effect handling is quite awkward here */
DUK_DDD(DUK_DDDPRINT("TRYCATCH: reg_catch=%ld, have_catch=%ld, "
"have_finally=%ld, catch_binding=%ld, with_binding=%ld (flags=0x%02lx)",
(long) DUK_DEC_BC(ins),
(long) (DUK_DEC_A(ins) & DUK_BC_TRYCATCH_FLAG_HAVE_CATCH ? 1 : 0),
(long) (DUK_DEC_A(ins) & DUK_BC_TRYCATCH_FLAG_HAVE_FINALLY ? 1 : 0),
(long) (DUK_DEC_A(ins) & DUK_BC_TRYCATCH_FLAG_CATCH_BINDING ? 1 : 0),
(long) (DUK_DEC_A(ins) & DUK_BC_TRYCATCH_FLAG_WITH_BINDING ? 1 : 0),
(unsigned long) DUK_DEC_A(ins)));
a = DUK_DEC_A(ins);
bc = DUK_DEC_BC(ins);
/* Registers 'bc' and 'bc + 1' are written in longjmp handling
* and if their previous values (which are temporaries) become
* unreachable -and- have a finalizer, there'll be a function
* call during error handling which is not supported now (GH-287).
* Ensure that both 'bc' and 'bc + 1' have primitive values to
* guarantee no finalizer calls in error handling. Scrubbing also
* ensures finalizers for the previous values run here rather than
* later. Error handling related values are also written to 'bc'
* and 'bc + 1' but those values never become unreachable during
* error handling, so there's no side effect problem even if the
* error value has a finalizer.
*/
duk_dup(thr, (duk_idx_t) bc); /* Stabilize value. */
duk_to_undefined(thr, (duk_idx_t) bc);
duk_to_undefined(thr, (duk_idx_t) (bc + 1));
/* Allocate catcher and populate it. Doesn't have to
* be fully atomic, but the catcher must be in a
* consistent state if side effects (such as finalizer
* calls) occur.
*/
cat = duk_hthread_catcher_alloc(thr);
DUK_ASSERT(cat != NULL);
cat->flags = DUK_CAT_TYPE_TCF;
cat->h_varname = NULL;
cat->pc_base = (duk_instr_t *) curr_pc; /* pre-incremented, points to first jump slot */
cat->idx_base = (duk_size_t) (thr->valstack_bottom - thr->valstack) + bc;
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
cat->parent = act->cat;
act->cat = cat;
if (a & DUK_BC_TRYCATCH_FLAG_HAVE_CATCH) {
cat->flags |= DUK_CAT_FLAG_CATCH_ENABLED;
}
if (a & DUK_BC_TRYCATCH_FLAG_HAVE_FINALLY) {
cat->flags |= DUK_CAT_FLAG_FINALLY_ENABLED;
}
if (a & DUK_BC_TRYCATCH_FLAG_CATCH_BINDING) {
DUK_DDD(DUK_DDDPRINT("catch binding flag set to catcher"));
cat->flags |= DUK_CAT_FLAG_CATCH_BINDING_ENABLED;
tv1 = DUK_GET_TVAL_NEGIDX(thr, -1);
DUK_ASSERT(DUK_TVAL_IS_STRING(tv1));
/* borrowed reference; although 'tv1' comes from a register,
* its value was loaded using LDCONST so the constant will
* also exist and be reachable.
*/
cat->h_varname = DUK_TVAL_GET_STRING(tv1);
} else if (a & DUK_BC_TRYCATCH_FLAG_WITH_BINDING) {
duk_hobjenv *env;
duk_hobject *target;
/* Delayed env initialization for activation (if needed). */
DUK_ASSERT(thr->callstack_top >= 1);
DUK_ASSERT(act == thr->callstack_curr);
DUK_ASSERT(act != NULL);
if (act->lex_env == NULL) {
DUK_DDD(DUK_DDDPRINT("delayed environment initialization"));
DUK_ASSERT(act->var_env == NULL);
duk_js_init_activation_environment_records_delayed(thr, act);
DUK_ASSERT(act == thr->callstack_curr);
DUK_UNREF(act); /* 'act' is no longer accessed, scanbuild fix */
}
DUK_ASSERT(act->lex_env != NULL);
DUK_ASSERT(act->var_env != NULL);
/* Coerce 'with' target. */
target = duk_to_hobject(thr, -1);
DUK_ASSERT(target != NULL);
/* Create an object environment; it is not pushed
* so avoid side effects very carefully until it is
* referenced.
*/
env = duk_hobjenv_alloc(thr,
DUK_HOBJECT_FLAG_EXTENSIBLE |
DUK_HOBJECT_CLASS_AS_FLAGS(DUK_HOBJECT_CLASS_OBJENV));
DUK_ASSERT(env != NULL);
DUK_ASSERT(DUK_HOBJECT_GET_PROTOTYPE(thr->heap, (duk_hobject *) env) == NULL);
env->target = target; /* always provideThis=true */
DUK_HOBJECT_INCREF(thr, target);
env->has_this = 1;
DUK_HOBJENV_ASSERT_VALID(env);
DUK_DDD(DUK_DDDPRINT("environment for with binding: %!iO", env));
DUK_ASSERT(act == thr->callstack_curr);
DUK_ASSERT(DUK_HOBJECT_GET_PROTOTYPE(thr->heap, (duk_hobject *) env) == NULL);
DUK_ASSERT(act->lex_env != NULL);
DUK_HOBJECT_SET_PROTOTYPE(thr->heap, (duk_hobject *) env, act->lex_env);
act->lex_env = (duk_hobject *) env; /* Now reachable. */
DUK_HOBJECT_INCREF(thr, (duk_hobject *) env);
/* Net refcount change to act->lex_env is 0: incref for env's
* prototype, decref for act->lex_env overwrite.
*/
/* Set catcher lex_env active (affects unwind)
* only when the whole setup is complete.
*/
cat = act->cat; /* XXX: better to relookup? not mandatory because 'cat' is stable */
cat->flags |= DUK_CAT_FLAG_LEXENV_ACTIVE;
} else {
;
}
DUK_DDD(DUK_DDDPRINT("TRYCATCH catcher: flags=0x%08lx, pc_base=%ld, "
"idx_base=%ld, h_varname=%!O",
(unsigned long) cat->flags,
(long) cat->pc_base, (long) cat->idx_base, (duk_heaphdr *) cat->h_varname));
duk_pop_unsafe(thr);
}
DUK_LOCAL DUK_EXEC_NOINLINE_PERF duk_instr_t *duk__handle_op_endtry(duk_hthread *thr, duk_uint_fast32_t ins) {
duk_activation *act;
duk_catcher *cat;
duk_tval *tv1;
duk_instr_t *pc_base;
DUK_UNREF(ins);
DUK_ASSERT(thr->callstack_top >= 1);
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
cat = act->cat;
DUK_ASSERT(cat != NULL);
DUK_ASSERT(DUK_CAT_GET_TYPE(act->cat) == DUK_CAT_TYPE_TCF);
DUK_DDD(DUK_DDDPRINT("ENDTRY: clearing catch active flag (regardless of whether it was set or not)"));
DUK_CAT_CLEAR_CATCH_ENABLED(cat);
pc_base = cat->pc_base;
if (DUK_CAT_HAS_FINALLY_ENABLED(cat)) {
DUK_DDD(DUK_DDDPRINT("ENDTRY: finally part is active, jump through 2nd jump slot with 'normal continuation'"));
tv1 = thr->valstack + cat->idx_base;
DUK_ASSERT(tv1 >= thr->valstack && tv1 < thr->valstack_top);
DUK_TVAL_SET_UNDEFINED_UPDREF(thr, tv1); /* side effects */
tv1 = NULL;
tv1 = thr->valstack + cat->idx_base + 1;
DUK_ASSERT(tv1 >= thr->valstack && tv1 < thr->valstack_top);
DUK_TVAL_SET_U32_UPDREF(thr, tv1, (duk_uint32_t) DUK_LJ_TYPE_NORMAL); /* side effects */
tv1 = NULL;
DUK_CAT_CLEAR_FINALLY_ENABLED(cat);
} else {
DUK_DDD(DUK_DDDPRINT("ENDTRY: no finally part, dismantle catcher, jump through 2nd jump slot (to end of statement)"));
duk_hthread_catcher_unwind_norz(thr, act); /* lexenv may be set for 'with' binding */
/* no need to unwind callstack */
}
return pc_base + 1; /* new curr_pc value */
}
DUK_LOCAL DUK_EXEC_NOINLINE_PERF duk_instr_t *duk__handle_op_endcatch(duk_hthread *thr, duk_uint_fast32_t ins) {
duk_activation *act;
duk_catcher *cat;
duk_tval *tv1;
duk_instr_t *pc_base;
DUK_UNREF(ins);
DUK_ASSERT(thr->callstack_top >= 1);
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
cat = act->cat;
DUK_ASSERT(cat != NULL);
DUK_ASSERT(!DUK_CAT_HAS_CATCH_ENABLED(cat)); /* cleared before entering catch part */
if (DUK_CAT_HAS_LEXENV_ACTIVE(cat)) {
duk_hobject *prev_env;
/* 'with' binding has no catch clause, so can't be here unless a normal try-catch */
DUK_ASSERT(DUK_CAT_HAS_CATCH_BINDING_ENABLED(cat));
DUK_ASSERT(act->lex_env != NULL);
DUK_DDD(DUK_DDDPRINT("ENDCATCH: popping catcher part lexical environment"));
prev_env = act->lex_env;
DUK_ASSERT(prev_env != NULL);
act->lex_env = DUK_HOBJECT_GET_PROTOTYPE(thr->heap, prev_env);
DUK_CAT_CLEAR_LEXENV_ACTIVE(cat);
DUK_HOBJECT_INCREF(thr, act->lex_env);
DUK_HOBJECT_DECREF(thr, prev_env); /* side effects */
DUK_ASSERT(act == thr->callstack_curr);
DUK_ASSERT(act != NULL);
}
pc_base = cat->pc_base;
if (DUK_CAT_HAS_FINALLY_ENABLED(cat)) {
DUK_DDD(DUK_DDDPRINT("ENDCATCH: finally part is active, jump through 2nd jump slot with 'normal continuation'"));
tv1 = thr->valstack + cat->idx_base;
DUK_ASSERT(tv1 >= thr->valstack && tv1 < thr->valstack_top);
DUK_TVAL_SET_UNDEFINED_UPDREF(thr, tv1); /* side effects */
tv1 = NULL;
tv1 = thr->valstack + cat->idx_base + 1;
DUK_ASSERT(tv1 >= thr->valstack && tv1 < thr->valstack_top);
DUK_TVAL_SET_U32_UPDREF(thr, tv1, (duk_uint32_t) DUK_LJ_TYPE_NORMAL); /* side effects */
tv1 = NULL;
DUK_CAT_CLEAR_FINALLY_ENABLED(cat);
} else {
DUK_DDD(DUK_DDDPRINT("ENDCATCH: no finally part, dismantle catcher, jump through 2nd jump slot (to end of statement)"));
duk_hthread_catcher_unwind_norz(thr, act);
/* no need to unwind callstack */
}
return pc_base + 1; /* new curr_pc value */
}
DUK_LOCAL DUK_EXEC_NOINLINE_PERF duk_small_uint_t duk__handle_op_endfin(duk_hthread *thr, duk_uint_fast32_t ins, duk_activation *entry_act) {
duk_activation *act;
duk_tval *tv1;
duk_uint_t reg_catch;
duk_small_uint_t cont_type;
duk_small_uint_t ret_result;
DUK_ASSERT(thr->ptr_curr_pc == NULL);
DUK_ASSERT(thr->callstack_top >= 1);
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
reg_catch = DUK_DEC_ABC(ins);
/* CATCH flag may be enabled or disabled here; it may be enabled if
* the statement has a catch block but the try block does not throw
* an error.
*/
DUK_DDD(DUK_DDDPRINT("ENDFIN: completion value=%!T, type=%!T",
(duk_tval *) (thr->valstack_bottom + reg_catch + 0),
(duk_tval *) (thr->valstack_bottom + reg_catch + 1)));
tv1 = thr->valstack_bottom + reg_catch + 1; /* type */
DUK_ASSERT(DUK_TVAL_IS_NUMBER(tv1));
#if defined(DUK_USE_FASTINT)
DUK_ASSERT(DUK_TVAL_IS_FASTINT(tv1));
cont_type = (duk_small_uint_t) DUK_TVAL_GET_FASTINT_U32(tv1);
#else
cont_type = (duk_small_uint_t) DUK_TVAL_GET_NUMBER(tv1);
#endif
tv1--; /* value */
switch (cont_type) {
case DUK_LJ_TYPE_NORMAL: {
DUK_DDD(DUK_DDDPRINT("ENDFIN: finally part finishing with 'normal' (non-abrupt) completion -> "
"dismantle catcher, resume execution after ENDFIN"));
duk_hthread_catcher_unwind_norz(thr, act);
/* no need to unwind callstack */
return 0; /* restart execution */
}
case DUK_LJ_TYPE_RETURN: {
DUK_DDD(DUK_DDDPRINT("ENDFIN: finally part finishing with 'return' complation -> dismantle "
"catcher, handle return, lj.value1=%!T", tv1));
/* Not necessary to unwind catch stack: return handling will
* do it. The finally flag of 'cat' is no longer set. The
* catch flag may be set, but it's not checked by return handling.
*/
duk_push_tval(thr, tv1);
ret_result = duk__handle_return(thr, entry_act);
if (ret_result == DUK__RETHAND_RESTART) {
return 0; /* restart execution */
}
DUK_ASSERT(ret_result == DUK__RETHAND_FINISHED);
DUK_DDD(DUK_DDDPRINT("exiting executor after ENDFIN and RETURN (pseudo) longjmp type"));
return 1; /* exit executor */
}
case DUK_LJ_TYPE_BREAK:
case DUK_LJ_TYPE_CONTINUE: {
duk_uint_t label_id;
duk_small_uint_t lj_type;
/* Not necessary to unwind catch stack: break/continue
* handling will do it. The finally flag of 'cat' is
* no longer set. The catch flag may be set, but it's
* not checked by break/continue handling.
*/
DUK_ASSERT(DUK_TVAL_IS_NUMBER(tv1));
#if defined(DUK_USE_FASTINT)
DUK_ASSERT(DUK_TVAL_IS_FASTINT(tv1));
label_id = (duk_small_uint_t) DUK_TVAL_GET_FASTINT_U32(tv1);
#else
label_id = (duk_small_uint_t) DUK_TVAL_GET_NUMBER(tv1);
#endif
lj_type = cont_type;
duk__handle_break_or_continue(thr, label_id, lj_type);
return 0; /* restart execution */
}
default: {
DUK_DDD(DUK_DDDPRINT("ENDFIN: finally part finishing with abrupt completion, lj_type=%ld -> "
"dismantle catcher, re-throw error",
(long) cont_type));
duk_err_setup_ljstate1(thr, (duk_small_uint_t) cont_type, tv1);
/* No debugger Throw notify check on purpose (rethrow). */
DUK_ASSERT(thr->heap->lj.jmpbuf_ptr != NULL); /* always in executor */
duk_err_longjmp(thr);
DUK_UNREACHABLE();
}
}
DUK_UNREACHABLE();
return 0;
}
DUK_LOCAL DUK_EXEC_NOINLINE_PERF void duk__handle_op_initenum(duk_hthread *thr, duk_uint_fast32_t ins) {
duk_small_uint_t b;
duk_small_uint_t c;
/*
* Enumeration semantics come from for-in statement, E5 Section 12.6.4.
* If called with 'null' or 'undefined', this opcode returns 'null' as
* the enumerator, which is special cased in NEXTENUM. This simplifies
* the compiler part
*/
/* B -> register for writing enumerator object
* C -> value to be enumerated (register)
*/
b = DUK_DEC_B(ins);
c = DUK_DEC_C(ins);
if (duk_is_null_or_undefined(thr, (duk_idx_t) c)) {
duk_push_null(thr);
duk_replace(thr, (duk_idx_t) b);
} else {
duk_dup(thr, (duk_idx_t) c);
duk_to_object(thr, -1);
duk_hobject_enumerator_create(thr, 0 /*enum_flags*/); /* [ ... val ] --> [ ... enum ] */
duk_replace(thr, (duk_idx_t) b);
}
}
DUK_LOCAL DUK_EXEC_NOINLINE_PERF duk_small_uint_t duk__handle_op_nextenum(duk_hthread *thr, duk_uint_fast32_t ins) {
duk_small_uint_t b;
duk_small_uint_t c;
duk_small_uint_t pc_skip = 0;
/*
* NEXTENUM checks whether the enumerator still has unenumerated
* keys. If so, the next key is loaded to the target register
* and the next instruction is skipped. Otherwise the next instruction
* will be executed, jumping out of the enumeration loop.
*/
/* B -> target register for next key
* C -> enum register
*/
b = DUK_DEC_B(ins);
c = DUK_DEC_C(ins);
DUK_DDD(DUK_DDDPRINT("NEXTENUM: b->%!T, c->%!T",
(duk_tval *) duk_get_tval(thr, (duk_idx_t) b),
(duk_tval *) duk_get_tval(thr, (duk_idx_t) c)));
if (duk_is_object(thr, (duk_idx_t) c)) {
/* XXX: assert 'c' is an enumerator */
duk_dup(thr, (duk_idx_t) c);
if (duk_hobject_enumerator_next(thr, 0 /*get_value*/)) {
/* [ ... enum ] -> [ ... next_key ] */
DUK_DDD(DUK_DDDPRINT("enum active, next key is %!T, skip jump slot ",
(duk_tval *) duk_get_tval(thr, -1)));
pc_skip = 1;
} else {
/* [ ... enum ] -> [ ... ] */
DUK_DDD(DUK_DDDPRINT("enum finished, execute jump slot"));
DUK_ASSERT(DUK_TVAL_IS_UNDEFINED(thr->valstack_top)); /* valstack policy */
thr->valstack_top++;
}
duk_replace(thr, (duk_idx_t) b);
} else {
/* 'null' enumerator case -> behave as with an empty enumerator */
DUK_ASSERT(duk_is_null(thr, (duk_idx_t) c));
DUK_DDD(DUK_DDDPRINT("enum is null, execute jump slot"));
}
return pc_skip;
}
/*
* Call handling helpers.
*/
DUK_LOCAL duk_bool_t duk__executor_handle_call(duk_hthread *thr, duk_idx_t idx, duk_idx_t nargs, duk_small_uint_t call_flags) {
duk_bool_t rc;
duk_set_top_unsafe(thr, (duk_idx_t) (idx + nargs + 2)); /* [ ... func this arg1 ... argN ] */
/* Attempt an Ecma-to-Ecma call setup. If the call
* target is (directly or indirectly) Reflect.construct(),
* the call may change into a constructor call on the fly.
*/
rc = (duk_bool_t) duk_handle_call_unprotected(thr, idx, call_flags);
if (rc != 0) {
/* Ecma-to-ecma call possible, may or may not
* be a tail call. Avoid C recursion by
* reusing current executor instance.
*/
DUK_DDD(DUK_DDDPRINT("ecma-to-ecma call setup possible, restart execution"));
/* curr_pc synced by duk_handle_call_unprotected() */
DUK_ASSERT(thr->ptr_curr_pc == NULL);
return rc;
} else {
/* Call was handled inline. */
}
DUK_ASSERT(thr->ptr_curr_pc != NULL);
return rc;
}
/*
* ECMAScript bytecode executor.
*
* Resume execution for the current thread from its current activation.
* Returns when execution would return from the entry level activation,
* leaving a single return value on top of the stack. Function calls
* and thread resumptions are handled internally. If an error occurs,
* a longjmp() with type DUK_LJ_TYPE_THROW is called on the entry level
* setjmp() jmpbuf.
*
* ECMAScript function calls and coroutine resumptions are handled
* internally (by the outer executor function) without recursive C calls.
* Other function calls are handled using duk_handle_call(), increasing
* C recursion depth.
*
* Abrupt completions (= long control tranfers) are handled either
* directly by reconfiguring relevant stacks and restarting execution,
* or via a longjmp. Longjmp-free handling is preferable for performance
* (especially Emscripten performance), and is used for: break, continue,
* and return.
*
* For more detailed notes, see doc/execution.rst.
*
* Also see doc/code-issues.rst for discussion of setjmp(), longjmp(),
* and volatile.
*/
/* Presence of 'fun' is config based, there's a marginal performance
* difference and the best option is architecture dependent.
*/
#if defined(DUK_USE_EXEC_FUN_LOCAL)
#define DUK__FUN() fun
#else
#define DUK__FUN() ((duk_hcompfunc *) DUK_ACT_GET_FUNC((thr)->callstack_curr))
#endif
/* Strict flag. */
#define DUK__STRICT() ((duk_small_uint_t) DUK_HOBJECT_HAS_STRICT((duk_hobject *) DUK__FUN()))
/* Reg/const access macros: these are very footprint and performance sensitive
* so modify with care. Arguments are sometimes evaluated multiple times which
* is not ideal.
*/
#define DUK__REG(x) (*(thr->valstack_bottom + (x)))
#define DUK__REGP(x) (thr->valstack_bottom + (x))
#define DUK__CONST(x) (*(consts + (x)))
#define DUK__CONSTP(x) (consts + (x))
/* Reg/const access macros which take the 32-bit instruction and avoid an
* explicit field decoding step by using shifts and masks. These must be
* kept in sync with duk_js_bytecode.h. The shift/mask values are chosen
* so that 'ins' can be shifted and masked and used as a -byte- offset
* instead of a duk_tval offset which needs further shifting (which is an
* issue on some, but not all, CPUs).
*/
#define DUK__RCBIT_B DUK_BC_REGCONST_B
#define DUK__RCBIT_C DUK_BC_REGCONST_C
#if defined(DUK_USE_EXEC_REGCONST_OPTIMIZE)
#if defined(DUK_USE_PACKED_TVAL)
#define DUK__TVAL_SHIFT 3 /* sizeof(duk_tval) == 8 */
#else
#define DUK__TVAL_SHIFT 4 /* sizeof(duk_tval) == 16; not always the case so also asserted for */
#endif
#define DUK__SHIFT_A (DUK_BC_SHIFT_A - DUK__TVAL_SHIFT)
#define DUK__SHIFT_B (DUK_BC_SHIFT_B - DUK__TVAL_SHIFT)
#define DUK__SHIFT_C (DUK_BC_SHIFT_C - DUK__TVAL_SHIFT)
#define DUK__SHIFT_BC (DUK_BC_SHIFT_BC - DUK__TVAL_SHIFT)
#define DUK__MASK_A (DUK_BC_UNSHIFTED_MASK_A << DUK__TVAL_SHIFT)
#define DUK__MASK_B (DUK_BC_UNSHIFTED_MASK_B << DUK__TVAL_SHIFT)
#define DUK__MASK_C (DUK_BC_UNSHIFTED_MASK_C << DUK__TVAL_SHIFT)
#define DUK__MASK_BC (DUK_BC_UNSHIFTED_MASK_BC << DUK__TVAL_SHIFT)
#define DUK__BYTEOFF_A(ins) (((ins) >> DUK__SHIFT_A) & DUK__MASK_A)
#define DUK__BYTEOFF_B(ins) (((ins) >> DUK__SHIFT_B) & DUK__MASK_B)
#define DUK__BYTEOFF_C(ins) (((ins) >> DUK__SHIFT_C) & DUK__MASK_C)
#define DUK__BYTEOFF_BC(ins) (((ins) >> DUK__SHIFT_BC) & DUK__MASK_BC)
#define DUK__REGP_A(ins) ((duk_tval *) (void *) ((duk_uint8_t *) thr->valstack_bottom + DUK__BYTEOFF_A((ins))))
#define DUK__REGP_B(ins) ((duk_tval *) (void *) ((duk_uint8_t *) thr->valstack_bottom + DUK__BYTEOFF_B((ins))))
#define DUK__REGP_C(ins) ((duk_tval *) (void *) ((duk_uint8_t *) thr->valstack_bottom + DUK__BYTEOFF_C((ins))))
#define DUK__REGP_BC(ins) ((duk_tval *) (void *) ((duk_uint8_t *) thr->valstack_bottom + DUK__BYTEOFF_BC((ins))))
#define DUK__CONSTP_A(ins) ((duk_tval *) (void *) ((duk_uint8_t *) consts + DUK__BYTEOFF_A((ins))))
#define DUK__CONSTP_B(ins) ((duk_tval *) (void *) ((duk_uint8_t *) consts + DUK__BYTEOFF_B((ins))))
#define DUK__CONSTP_C(ins) ((duk_tval *) (void *) ((duk_uint8_t *) consts + DUK__BYTEOFF_C((ins))))
#define DUK__CONSTP_BC(ins) ((duk_tval *) (void *) ((duk_uint8_t *) consts + DUK__BYTEOFF_BC((ins))))
#define DUK__REGCONSTP_B(ins) ((duk_tval *) (void *) ((duk_uint8_t *) (((ins) & DUK__RCBIT_B) ? consts : thr->valstack_bottom) + DUK__BYTEOFF_B((ins))))
#define DUK__REGCONSTP_C(ins) ((duk_tval *) (void *) ((duk_uint8_t *) (((ins) & DUK__RCBIT_C) ? consts : thr->valstack_bottom) + DUK__BYTEOFF_C((ins))))
#else /* DUK_USE_EXEC_REGCONST_OPTIMIZE */
/* Safe alternatives, no assumption about duk_tval size. */
#define DUK__REGP_A(ins) DUK__REGP(DUK_DEC_A((ins)))
#define DUK__REGP_B(ins) DUK__REGP(DUK_DEC_B((ins)))
#define DUK__REGP_C(ins) DUK__REGP(DUK_DEC_C((ins)))
#define DUK__REGP_BC(ins) DUK__REGP(DUK_DEC_BC((ins)))
#define DUK__CONSTP_A(ins) DUK__CONSTP(DUK_DEC_A((ins)))
#define DUK__CONSTP_B(ins) DUK__CONSTP(DUK_DEC_B((ins)))
#define DUK__CONSTP_C(ins) DUK__CONSTP(DUK_DEC_C((ins)))
#define DUK__CONSTP_BC(ins) DUK__CONSTP(DUK_DEC_BC((ins)))
#define DUK__REGCONSTP_B(ins) ((((ins) & DUK__RCBIT_B) ? consts : thr->valstack_bottom) + DUK_DEC_B((ins)))
#define DUK__REGCONSTP_C(ins) ((((ins) & DUK__RCBIT_C) ? consts : thr->valstack_bottom) + DUK_DEC_C((ins)))
#endif /* DUK_USE_EXEC_REGCONST_OPTIMIZE */
#if defined(DUK_USE_VERBOSE_EXECUTOR_ERRORS)
#define DUK__INTERNAL_ERROR(msg) do { \
DUK_ERROR_ERROR(thr, (msg)); \
DUK_WO_NORETURN(return;); \
} while (0)
#else
#define DUK__INTERNAL_ERROR(msg) do { \
goto internal_error; \
} while (0)
#endif
#define DUK__SYNC_CURR_PC() do { \
duk_activation *duk__act; \
duk__act = thr->callstack_curr; \
duk__act->curr_pc = curr_pc; \
} while (0)
#define DUK__SYNC_AND_NULL_CURR_PC() do { \
duk_activation *duk__act; \
duk__act = thr->callstack_curr; \
duk__act->curr_pc = curr_pc; \
thr->ptr_curr_pc = NULL; \
} while (0)
#if defined(DUK_USE_EXEC_PREFER_SIZE)
#define DUK__LOOKUP_INDIRECT(idx) do { \
(idx) = (duk_uint_fast_t) duk_get_uint(thr, (duk_idx_t) (idx)); \
} while (0)
#elif defined(DUK_USE_FASTINT)
#define DUK__LOOKUP_INDIRECT(idx) do { \
duk_tval *tv_ind; \
tv_ind = DUK__REGP((idx)); \
DUK_ASSERT(DUK_TVAL_IS_NUMBER(tv_ind)); \
DUK_ASSERT(DUK_TVAL_IS_FASTINT(tv_ind)); /* compiler guarantees */ \
(idx) = (duk_uint_fast_t) DUK_TVAL_GET_FASTINT_U32(tv_ind); \
} while (0)
#else
#define DUK__LOOKUP_INDIRECT(idx) do { \
duk_tval *tv_ind; \
tv_ind = DUK__REGP(idx); \
DUK_ASSERT(DUK_TVAL_IS_NUMBER(tv_ind)); \
idx = (duk_uint_fast_t) DUK_TVAL_GET_NUMBER(tv_ind); \
} while (0)
#endif
DUK_LOCAL void duk__handle_executor_error(duk_heap *heap,
duk_activation *entry_act,
duk_int_t entry_call_recursion_depth,
duk_jmpbuf *entry_jmpbuf_ptr,
volatile duk_bool_t *out_delayed_catch_setup) {
duk_small_uint_t lj_ret;
/* Longjmp callers are required to sync-and-null thr->ptr_curr_pc
* before longjmp.
*/
DUK_ASSERT(heap->curr_thread != NULL);
DUK_ASSERT(heap->curr_thread->ptr_curr_pc == NULL);
/* XXX: signalling the need to shrink check (only if unwound) */
/* Must be restored here to handle e.g. yields properly. */
heap->call_recursion_depth = entry_call_recursion_depth;
/* Switch to caller's setjmp() catcher so that if an error occurs
* during error handling, it is always propagated outwards instead
* of causing an infinite loop in our own handler.
*/
heap->lj.jmpbuf_ptr = (duk_jmpbuf *) entry_jmpbuf_ptr;
lj_ret = duk__handle_longjmp(heap->curr_thread, entry_act, out_delayed_catch_setup);
/* Error handling complete, remove side effect protections.
*/
#if defined(DUK_USE_ASSERTIONS)
DUK_ASSERT(heap->error_not_allowed == 1);
heap->error_not_allowed = 0;
#endif
DUK_ASSERT(heap->pf_prevent_count > 0);
heap->pf_prevent_count--;
DUK_DD(DUK_DDPRINT("executor error handled, pf_prevent_count updated to %ld", (long) heap->pf_prevent_count));
if (lj_ret == DUK__LONGJMP_RESTART) {
/* Restart bytecode execution, possibly with a changed thread. */
DUK_REFZERO_CHECK_SLOW(heap->curr_thread);
} else {
/* If an error is propagated, don't run refzero checks here.
* The next catcher will deal with that. Pf_prevent_count
* will be re-bumped by the longjmp.
*/
DUK_ASSERT(lj_ret == DUK__LONGJMP_RETHROW); /* Rethrow error to calling state. */
DUK_ASSERT(heap->lj.jmpbuf_ptr == entry_jmpbuf_ptr); /* Longjmp handling has restored jmpbuf_ptr. */
/* Thread may have changed, e.g. YIELD converted to THROW. */
duk_err_longjmp(heap->curr_thread);
DUK_UNREACHABLE();
}
}
/* Outer executor with setjmp/longjmp handling. */
DUK_INTERNAL void duk_js_execute_bytecode(duk_hthread *exec_thr) {
/* Entry level info. */
duk_hthread *entry_thread;
duk_activation *entry_act;
duk_int_t entry_call_recursion_depth;
duk_jmpbuf *entry_jmpbuf_ptr;
duk_jmpbuf our_jmpbuf;
duk_heap *heap;
volatile duk_bool_t delayed_catch_setup = 0;
DUK_ASSERT(exec_thr != NULL);
DUK_ASSERT(exec_thr->heap != NULL);
DUK_ASSERT(exec_thr->heap->curr_thread != NULL);
DUK_ASSERT_REFCOUNT_NONZERO_HEAPHDR((duk_heaphdr *) exec_thr);
DUK_ASSERT(exec_thr->callstack_top >= 1); /* at least one activation, ours */
DUK_ASSERT(exec_thr->callstack_curr != NULL);
DUK_ASSERT(DUK_ACT_GET_FUNC(exec_thr->callstack_curr) != NULL);
DUK_ASSERT(DUK_HOBJECT_IS_COMPFUNC(DUK_ACT_GET_FUNC(exec_thr->callstack_curr)));
DUK_GC_TORTURE(exec_thr->heap);
entry_thread = exec_thr;
heap = entry_thread->heap;
entry_act = entry_thread->callstack_curr;
DUK_ASSERT(entry_act != NULL);
entry_call_recursion_depth = entry_thread->heap->call_recursion_depth;
entry_jmpbuf_ptr = entry_thread->heap->lj.jmpbuf_ptr;
/*
* Note: we currently assume that the setjmp() catchpoint is
* not re-entrant (longjmp() cannot be called more than once
* for a single setjmp()).
*
* See doc/code-issues.rst for notes on variable assignment
* before and after setjmp().
*/
for (;;) {
heap->lj.jmpbuf_ptr = &our_jmpbuf;
DUK_ASSERT(heap->lj.jmpbuf_ptr != NULL);
#if defined(DUK_USE_CPP_EXCEPTIONS)
try {
#else
DUK_ASSERT(heap->lj.jmpbuf_ptr == &our_jmpbuf);
if (DUK_SETJMP(our_jmpbuf.jb) == 0) {
#endif
DUK_DDD(DUK_DDDPRINT("after setjmp, delayed catch setup: %ld\n", (long) delayed_catch_setup));
if (DUK_UNLIKELY(delayed_catch_setup != 0)) {
duk_hthread *thr = entry_thread->heap->curr_thread;
delayed_catch_setup = 0;
duk__handle_catch_part2(thr);
DUK_ASSERT(delayed_catch_setup == 0);
DUK_DDD(DUK_DDDPRINT("top after delayed catch setup: %ld", (long) duk_get_top(entry_thread)));
}
/* Execute bytecode until returned or longjmp(). */
duk__js_execute_bytecode_inner(entry_thread, entry_act);
/* Successful return: restore jmpbuf and return to caller. */
heap->lj.jmpbuf_ptr = entry_jmpbuf_ptr;
return;
#if defined(DUK_USE_CPP_EXCEPTIONS)
} catch (duk_internal_exception &exc) {
#else
} else {
#endif
#if defined(DUK_USE_CPP_EXCEPTIONS)
DUK_UNREF(exc);
#endif
DUK_DDD(DUK_DDDPRINT("longjmp caught by bytecode executor"));
DUK_STATS_INC(exec_thr->heap, stats_exec_throw);
duk__handle_executor_error(heap,
entry_act,
entry_call_recursion_depth,
entry_jmpbuf_ptr,
&delayed_catch_setup);
}
#if defined(DUK_USE_CPP_EXCEPTIONS)
catch (duk_fatal_exception &exc) {
DUK_D(DUK_DPRINT("rethrow duk_fatal_exception"));
DUK_UNREF(exc);
throw;
} catch (std::exception &exc) {
const char *what = exc.what();
if (!what) {
what = "unknown";
}
DUK_D(DUK_DPRINT("unexpected c++ std::exception (perhaps thrown by user code)"));
DUK_STATS_INC(exec_thr->heap, stats_exec_throw);
try {
DUK_ASSERT(heap->curr_thread != NULL);
DUK_ERROR_FMT1(heap->curr_thread, DUK_ERR_TYPE_ERROR, "caught invalid c++ std::exception '%s' (perhaps thrown by user code)", what);
DUK_WO_NORETURN(return;);
} catch (duk_internal_exception exc) {
DUK_D(DUK_DPRINT("caught api error thrown from unexpected c++ std::exception"));
DUK_UNREF(exc);
duk__handle_executor_error(heap,
entry_act,
entry_call_recursion_depth,
entry_jmpbuf_ptr,
&delayed_catch_setup);
}
} catch (...) {
DUK_D(DUK_DPRINT("unexpected c++ exception (perhaps thrown by user code)"));
DUK_STATS_INC(exec_thr->heap, stats_exec_throw);
try {
DUK_ASSERT(heap->curr_thread != NULL);
DUK_ERROR_TYPE(heap->curr_thread, "caught invalid c++ exception (perhaps thrown by user code)");
DUK_WO_NORETURN(return;);
} catch (duk_internal_exception exc) {
DUK_D(DUK_DPRINT("caught api error thrown from unexpected c++ exception"));
DUK_UNREF(exc);
duk__handle_executor_error(heap,
entry_act,
entry_call_recursion_depth,
entry_jmpbuf_ptr,
&delayed_catch_setup);
}
}
#endif
}
DUK_WO_NORETURN(return;);
}
/* Inner executor, performance critical. */
DUK_LOCAL DUK_NOINLINE DUK_HOT void duk__js_execute_bytecode_inner(duk_hthread *entry_thread, duk_activation *entry_act) {
/* Current PC, accessed by other functions through thr->ptr_to_curr_pc.
* Critical for performance. It would be safest to make this volatile,
* but that eliminates performance benefits; aliasing guarantees
* should be enough though.
*/
duk_instr_t *curr_pc; /* bytecode has a stable pointer */
/* Hot variables for interpretation. Critical for performance,
* but must add sparingly to minimize register shuffling.
*/
duk_hthread *thr; /* stable */
duk_tval *consts; /* stable */
duk_uint_fast32_t ins;
/* 'funcs' is quite rarely used, so no local for it */
#if defined(DUK_USE_EXEC_FUN_LOCAL)
duk_hcompfunc *fun;
#else
/* 'fun' is quite rarely used, so no local for it */
#endif
#if defined(DUK_USE_INTERRUPT_COUNTER)
duk_int_t int_ctr;
#endif
#if defined(DUK_USE_ASSERTIONS)
duk_size_t valstack_top_base; /* valstack top, should match before interpreting each op (no leftovers) */
#endif
/* Optimized reg/const access macros assume sizeof(duk_tval) to be
* either 8 or 16. Heap allocation checks this even without asserts
* enabled now because it can't be autodetected in duk_config.h.
*/
#if 1
#if defined(DUK_USE_PACKED_TVAL)
DUK_ASSERT(sizeof(duk_tval) == 8);
#else
DUK_ASSERT(sizeof(duk_tval) == 16);
#endif
#endif
DUK_GC_TORTURE(entry_thread->heap);
/*
* Restart execution by reloading thread state.
*
* Note that 'thr' and any thread configuration may have changed,
* so all local variables are suspect and we need to reinitialize.
*
* The number of local variables should be kept to a minimum: if
* the variables are spilled, they will need to be loaded from
* memory anyway.
*
* Any 'goto restart_execution;' code path in opcode dispatch must
* ensure 'curr_pc' is synced back to act->curr_pc before the goto
* takes place.
*
* The interpreter must be very careful with memory pointers, as
* many pointers are not guaranteed to be 'stable' and may be
* reallocated and relocated on-the-fly quite easily (e.g. by a
* memory allocation or a property access).
*
* The following are assumed to have stable pointers:
* - the current thread
* - the current function
* - the bytecode, constant table, inner function table of the
* current function (as they are a part of the function allocation)
*
* The following are assumed to have semi-stable pointers:
* - the current activation entry: stable as long as callstack
* is not changed (reallocated by growing or shrinking), or
* by any garbage collection invocation (through finalizers)
* - Note in particular that ANY DECREF can invalidate the
* activation pointer, so for the most part a fresh lookup
* is required
*
* The following are not assumed to have stable pointers at all:
* - the value stack (registers) of the current thread
*
* See execution.rst for discussion.
*/
restart_execution:
/* Lookup current thread; use the stable 'entry_thread' for this to
* avoid clobber warnings. Any valid, reachable 'thr' value would be
* fine for this, so using 'entry_thread' is just to silence warnings.
*/
thr = entry_thread->heap->curr_thread;
DUK_ASSERT(thr != NULL);
DUK_ASSERT(thr->callstack_top >= 1);
DUK_ASSERT(thr->callstack_curr != NULL);
DUK_ASSERT(DUK_ACT_GET_FUNC(thr->callstack_curr) != NULL);
DUK_ASSERT(DUK_HOBJECT_IS_COMPFUNC(DUK_ACT_GET_FUNC(thr->callstack_curr)));
DUK_GC_TORTURE(thr->heap);
thr->ptr_curr_pc = &curr_pc;
/* Relookup and initialize dispatch loop variables. Debugger check. */
{
duk_activation *act;
#if !defined(DUK_USE_EXEC_FUN_LOCAL)
duk_hcompfunc *fun;
#endif
/* Assume interrupt init/counter are properly initialized here. */
/* Assume that thr->valstack_bottom has been set-up before getting here. */
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
fun = (duk_hcompfunc *) DUK_ACT_GET_FUNC(act);
DUK_ASSERT(fun != NULL);
DUK_ASSERT(thr->valstack_top - thr->valstack_bottom == fun->nregs);
consts = DUK_HCOMPFUNC_GET_CONSTS_BASE(thr->heap, fun);
DUK_ASSERT(consts != NULL);
#if defined(DUK_USE_DEBUGGER_SUPPORT)
if (DUK_UNLIKELY(duk_debug_is_attached(thr->heap) && !thr->heap->dbg_processing)) {
duk__executor_recheck_debugger(thr, act, fun);
DUK_ASSERT(act == thr->callstack_curr);
DUK_ASSERT(act != NULL);
}
#endif /* DUK_USE_DEBUGGER_SUPPORT */
#if defined(DUK_USE_ASSERTIONS)
valstack_top_base = (duk_size_t) (thr->valstack_top - thr->valstack);
#endif
/* Set up curr_pc for opcode dispatch. */
curr_pc = act->curr_pc;
}
DUK_DD(DUK_DDPRINT("restarting execution, thr %p, act idx %ld, fun %p,"
"consts %p, funcs %p, lev %ld, regbot %ld, regtop %ld, "
"preventcount=%ld",
(void *) thr,
(long) (thr->callstack_top - 1),
(void *) DUK__FUN(),
(void *) DUK_HCOMPFUNC_GET_CONSTS_BASE(thr->heap, DUK__FUN()),
(void *) DUK_HCOMPFUNC_GET_FUNCS_BASE(thr->heap, DUK__FUN()),
(long) (thr->callstack_top - 1),
(long) (thr->valstack_bottom - thr->valstack),
(long) (thr->valstack_top - thr->valstack),
(long) thr->callstack_preventcount));
/* Dispatch loop. */
for (;;) {
duk_uint8_t op;
DUK_ASSERT(thr->callstack_top >= 1);
DUK_ASSERT(thr->valstack_top - thr->valstack_bottom == DUK__FUN()->nregs);
DUK_ASSERT((duk_size_t) (thr->valstack_top - thr->valstack) == valstack_top_base);
/* Executor interrupt counter check, used to implement breakpoints,
* debugging interface, execution timeouts, etc. The counter is heap
* specific but is maintained in the current thread to make the check
* as fast as possible. The counter is copied back to the heap struct
* whenever a thread switch occurs by the DUK_HEAP_SWITCH_THREAD() macro.
*/
#if defined(DUK_USE_INTERRUPT_COUNTER)
int_ctr = thr->interrupt_counter;
if (DUK_LIKELY(int_ctr > 0)) {
thr->interrupt_counter = int_ctr - 1;
} else {
/* Trigger at zero or below */
duk_small_uint_t exec_int_ret;
DUK_STATS_INC(thr->heap, stats_exec_interrupt);
/* Write curr_pc back for the debugger. */
{
duk_activation *act;
DUK_ASSERT(thr->callstack_top > 0);
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
act->curr_pc = (duk_instr_t *) curr_pc;
}
/* Forced restart caused by a function return; must recheck
* debugger breakpoints before checking line transitions,
* see GH-303. Restart and then handle interrupt_counter
* zero again.
*/
#if defined(DUK_USE_DEBUGGER_SUPPORT)
if (thr->heap->dbg_force_restart) {
DUK_DD(DUK_DDPRINT("dbg_force_restart flag forced restart execution")); /* GH-303 */
thr->heap->dbg_force_restart = 0;
goto restart_execution;
}
#endif
exec_int_ret = duk__executor_interrupt(thr);
if (exec_int_ret == DUK__INT_RESTART) {
/* curr_pc synced back above */
goto restart_execution;
}
}
#endif /* DUK_USE_INTERRUPT_COUNTER */
#if defined(DUK_USE_INTERRUPT_COUNTER) && defined(DUK_USE_DEBUG)
/* For cross-checking during development: ensure dispatch count
* matches cumulative interrupt counter init value sums.
*/
thr->heap->inst_count_exec++;
#endif
#if defined(DUK_USE_ASSERTIONS) || defined(DUK_USE_DEBUG)
{
duk_activation *act;
act = thr->callstack_curr;
DUK_ASSERT(curr_pc >= DUK_HCOMPFUNC_GET_CODE_BASE(thr->heap, DUK__FUN()));
DUK_ASSERT(curr_pc < DUK_HCOMPFUNC_GET_CODE_END(thr->heap, DUK__FUN()));
DUK_UNREF(act); /* if debugging disabled */
DUK_DDD(DUK_DDDPRINT("executing bytecode: pc=%ld, ins=0x%08lx, op=%ld, valstack_top=%ld/%ld, nregs=%ld --> %!I",
(long) (curr_pc - DUK_HCOMPFUNC_GET_CODE_BASE(thr->heap, DUK__FUN())),
(unsigned long) *curr_pc,
(long) DUK_DEC_OP(*curr_pc),
(long) (thr->valstack_top - thr->valstack),
(long) (thr->valstack_end - thr->valstack),
(long) (DUK__FUN() ? DUK__FUN()->nregs : -1),
(duk_instr_t) *curr_pc));
}
#endif
#if defined(DUK_USE_ASSERTIONS)
/* Quite heavy assert: check valstack policy. Improper
* shuffle instructions can write beyond valstack_top/end
* so this check catches them in the act.
*/
{
duk_tval *tv;
tv = thr->valstack_top;
while (tv != thr->valstack_end) {
DUK_ASSERT(DUK_TVAL_IS_UNDEFINED(tv));
tv++;
}
}
#endif
ins = *curr_pc++;
DUK_STATS_INC(thr->heap, stats_exec_opcodes);
/* Typing: use duk_small_(u)int_fast_t when decoding small
* opcode fields (op, A, B, C, BC) which fit into 16 bits
* and duk_(u)int_fast_t when decoding larger fields (e.g.
* ABC). Use unsigned variant by default, signed when the
* value is used in signed arithmetic. Using variable names
* such as 'a', 'b', 'c', 'bc', etc makes it easier to spot
* typing mismatches.
*/
/* Switch based on opcode. Cast to 8-bit unsigned value and
* use a fully populated case clauses so that the compiler
* will (at least usually) omit a bounds check.
*/
op = (duk_uint8_t) DUK_DEC_OP(ins);
switch (op) {
/* Some useful macros. These access inner executor variables
* directly so they only apply within the executor.
*/
#if defined(DUK_USE_EXEC_PREFER_SIZE)
#define DUK__REPLACE_TOP_A_BREAK() { goto replace_top_a; }
#define DUK__REPLACE_TOP_BC_BREAK() { goto replace_top_bc; }
#define DUK__REPLACE_BOOL_A_BREAK(bval) { \
duk_bool_t duk__bval; \
duk__bval = (bval); \
DUK_ASSERT(duk__bval == 0 || duk__bval == 1); \
duk_push_boolean(thr, duk__bval); \
DUK__REPLACE_TOP_A_BREAK(); \
}
#else
#define DUK__REPLACE_TOP_A_BREAK() { DUK__REPLACE_TO_TVPTR(thr, DUK__REGP_A(ins)); break; }
#define DUK__REPLACE_TOP_BC_BREAK() { DUK__REPLACE_TO_TVPTR(thr, DUK__REGP_BC(ins)); break; }
#define DUK__REPLACE_BOOL_A_BREAK(bval) { \
duk_bool_t duk__bval; \
duk_tval *duk__tvdst; \
duk__bval = (bval); \
DUK_ASSERT(duk__bval == 0 || duk__bval == 1); \
duk__tvdst = DUK__REGP_A(ins); \
DUK_TVAL_SET_BOOLEAN_UPDREF(thr, duk__tvdst, duk__bval); \
break; \
}
#endif
/* XXX: 12 + 12 bit variant might make sense too, for both reg and
* const loads.
*/
/* For LDREG, STREG, LDCONST footprint optimized variants would just
* duk_dup() + duk_replace(), but because they're used quite a lot
* they're currently intentionally not size optimized.
*/
case DUK_OP_LDREG: {
duk_tval *tv1, *tv2;
tv1 = DUK__REGP_A(ins);
tv2 = DUK__REGP_BC(ins);
DUK_TVAL_SET_TVAL_UPDREF_FAST(thr, tv1, tv2); /* side effects */
break;
}
case DUK_OP_STREG: {
duk_tval *tv1, *tv2;
tv1 = DUK__REGP_A(ins);
tv2 = DUK__REGP_BC(ins);
DUK_TVAL_SET_TVAL_UPDREF_FAST(thr, tv2, tv1); /* side effects */
break;
}
case DUK_OP_LDCONST: {
duk_tval *tv1, *tv2;
tv1 = DUK__REGP_A(ins);
tv2 = DUK__CONSTP_BC(ins);
DUK_TVAL_SET_TVAL_UPDREF_FAST(thr, tv1, tv2); /* side effects */
break;
}
/* LDINT and LDINTX are intended to load an arbitrary signed
* 32-bit value. Only an LDINT+LDINTX sequence is supported.
* This also guarantees all values remain fastints.
*/
#if defined(DUK_USE_EXEC_PREFER_SIZE)
case DUK_OP_LDINT: {
duk_int32_t val;
val = (duk_int32_t) DUK_DEC_BC(ins) - (duk_int32_t) DUK_BC_LDINT_BIAS;
duk_push_int(thr, val);
DUK__REPLACE_TOP_A_BREAK();
}
case DUK_OP_LDINTX: {
duk_int32_t val;
val = (duk_int32_t) duk_get_int(thr, DUK_DEC_A(ins));
val = (val << DUK_BC_LDINTX_SHIFT) + (duk_int32_t) DUK_DEC_BC(ins); /* no bias */
duk_push_int(thr, val);
DUK__REPLACE_TOP_A_BREAK();
}
#else /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_LDINT: {
duk_tval *tv1;
duk_int32_t val;
val = (duk_int32_t) DUK_DEC_BC(ins) - (duk_int32_t) DUK_BC_LDINT_BIAS;
tv1 = DUK__REGP_A(ins);
DUK_TVAL_SET_I32_UPDREF(thr, tv1, val); /* side effects */
break;
}
case DUK_OP_LDINTX: {
duk_tval *tv1;
duk_int32_t val;
tv1 = DUK__REGP_A(ins);
DUK_ASSERT(DUK_TVAL_IS_NUMBER(tv1));
#if defined(DUK_USE_FASTINT)
DUK_ASSERT(DUK_TVAL_IS_FASTINT(tv1));
val = DUK_TVAL_GET_FASTINT_I32(tv1);
#else
/* XXX: fast double-to-int conversion, we know number is integer in [-0x80000000,0xffffffff]. */
val = (duk_int32_t) DUK_TVAL_GET_NUMBER(tv1);
#endif
val = (duk_int32_t) ((duk_uint32_t) val << DUK_BC_LDINTX_SHIFT) + (duk_int32_t) DUK_DEC_BC(ins); /* no bias */
DUK_TVAL_SET_I32_UPDREF(thr, tv1, val); /* side effects */
break;
}
#endif /* DUK_USE_EXEC_PREFER_SIZE */
#if defined(DUK_USE_EXEC_PREFER_SIZE)
case DUK_OP_LDTHIS: {
duk_push_this(thr);
DUK__REPLACE_TOP_BC_BREAK();
}
case DUK_OP_LDUNDEF: {
duk_to_undefined(thr, (duk_idx_t) DUK_DEC_BC(ins));
break;
}
case DUK_OP_LDNULL: {
duk_to_null(thr, (duk_idx_t) DUK_DEC_BC(ins));
break;
}
case DUK_OP_LDTRUE: {
duk_push_true(thr);
DUK__REPLACE_TOP_BC_BREAK();
}
case DUK_OP_LDFALSE: {
duk_push_false(thr);
DUK__REPLACE_TOP_BC_BREAK();
}
#else /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_LDTHIS: {
/* Note: 'this' may be bound to any value, not just an object */
duk_tval *tv1, *tv2;
tv1 = DUK__REGP_BC(ins);
tv2 = thr->valstack_bottom - 1; /* 'this binding' is just under bottom */
DUK_ASSERT(tv2 >= thr->valstack);
DUK_TVAL_SET_TVAL_UPDREF_FAST(thr, tv1, tv2); /* side effects */
break;
}
case DUK_OP_LDUNDEF: {
duk_tval *tv1;
tv1 = DUK__REGP_BC(ins);
DUK_TVAL_SET_UNDEFINED_UPDREF(thr, tv1); /* side effects */
break;
}
case DUK_OP_LDNULL: {
duk_tval *tv1;
tv1 = DUK__REGP_BC(ins);
DUK_TVAL_SET_NULL_UPDREF(thr, tv1); /* side effects */
break;
}
case DUK_OP_LDTRUE: {
duk_tval *tv1;
tv1 = DUK__REGP_BC(ins);
DUK_TVAL_SET_BOOLEAN_UPDREF(thr, tv1, 1); /* side effects */
break;
}
case DUK_OP_LDFALSE: {
duk_tval *tv1;
tv1 = DUK__REGP_BC(ins);
DUK_TVAL_SET_BOOLEAN_UPDREF(thr, tv1, 0); /* side effects */
break;
}
#endif /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_BNOT: {
duk__vm_bitwise_not(thr, DUK_DEC_BC(ins), DUK_DEC_A(ins));
break;
}
case DUK_OP_LNOT: {
duk__vm_logical_not(thr, DUK_DEC_BC(ins), DUK_DEC_A(ins));
break;
}
#if defined(DUK_USE_EXEC_PREFER_SIZE)
case DUK_OP_UNM:
case DUK_OP_UNP: {
duk__vm_arith_unary_op(thr, DUK_DEC_BC(ins), DUK_DEC_A(ins), op);
break;
}
#else /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_UNM: {
duk__vm_arith_unary_op(thr, DUK_DEC_BC(ins), DUK_DEC_A(ins), DUK_OP_UNM);
break;
}
case DUK_OP_UNP: {
duk__vm_arith_unary_op(thr, DUK_DEC_BC(ins), DUK_DEC_A(ins), DUK_OP_UNP);
break;
}
#endif /* DUK_USE_EXEC_PREFER_SIZE */
#if defined(DUK_USE_EXEC_PREFER_SIZE)
case DUK_OP_TYPEOF: {
duk_small_uint_t stridx;
stridx = duk_js_typeof_stridx(DUK__REGP_BC(ins));
DUK_ASSERT_STRIDX_VALID(stridx);
duk_push_hstring_stridx(thr, stridx);
DUK__REPLACE_TOP_A_BREAK();
}
#else /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_TYPEOF: {
duk_tval *tv;
duk_small_uint_t stridx;
duk_hstring *h_str;
tv = DUK__REGP_BC(ins);
stridx = duk_js_typeof_stridx(tv);
DUK_ASSERT_STRIDX_VALID(stridx);
h_str = DUK_HTHREAD_GET_STRING(thr, stridx);
tv = DUK__REGP_A(ins);
DUK_TVAL_SET_STRING_UPDREF(thr, tv, h_str);
break;
}
#endif /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_TYPEOFID: {
duk_small_uint_t stridx;
#if !defined(DUK_USE_EXEC_PREFER_SIZE)
duk_hstring *h_str;
#endif
duk_activation *act;
duk_hstring *name;
duk_tval *tv;
/* A -> target register
* BC -> constant index of identifier name
*/
tv = DUK__CONSTP_BC(ins);
DUK_ASSERT(DUK_TVAL_IS_STRING(tv));
name = DUK_TVAL_GET_STRING(tv);
tv = NULL; /* lookup has side effects */
act = thr->callstack_curr;
if (duk_js_getvar_activation(thr, act, name, 0 /*throw*/)) {
/* -> [... val this] */
tv = DUK_GET_TVAL_NEGIDX(thr, -2);
stridx = duk_js_typeof_stridx(tv);
tv = NULL; /* no longer needed */
duk_pop_2_unsafe(thr);
} else {
/* unresolvable, no stack changes */
stridx = DUK_STRIDX_LC_UNDEFINED;
}
DUK_ASSERT_STRIDX_VALID(stridx);
#if defined(DUK_USE_EXEC_PREFER_SIZE)
duk_push_hstring_stridx(thr, stridx);
DUK__REPLACE_TOP_A_BREAK();
#else /* DUK_USE_EXEC_PREFER_SIZE */
h_str = DUK_HTHREAD_GET_STRING(thr, stridx);
tv = DUK__REGP_A(ins);
DUK_TVAL_SET_STRING_UPDREF(thr, tv, h_str);
break;
#endif /* DUK_USE_EXEC_PREFER_SIZE */
}
/* Equality: E5 Sections 11.9.1, 11.9.3 */
#define DUK__EQ_BODY(barg,carg) { \
duk_bool_t tmp; \
tmp = duk_js_equals(thr, (barg), (carg)); \
DUK_ASSERT(tmp == 0 || tmp == 1); \
DUK__REPLACE_BOOL_A_BREAK(tmp); \
}
#define DUK__NEQ_BODY(barg,carg) { \
duk_bool_t tmp; \
tmp = duk_js_equals(thr, (barg), (carg)); \
DUK_ASSERT(tmp == 0 || tmp == 1); \
tmp ^= 1; \
DUK__REPLACE_BOOL_A_BREAK(tmp); \
}
#define DUK__SEQ_BODY(barg,carg) { \
duk_bool_t tmp; \
tmp = duk_js_strict_equals((barg), (carg)); \
DUK_ASSERT(tmp == 0 || tmp == 1); \
DUK__REPLACE_BOOL_A_BREAK(tmp); \
}
#define DUK__SNEQ_BODY(barg,carg) { \
duk_bool_t tmp; \
tmp = duk_js_strict_equals((barg), (carg)); \
DUK_ASSERT(tmp == 0 || tmp == 1); \
tmp ^= 1; \
DUK__REPLACE_BOOL_A_BREAK(tmp); \
}
#if defined(DUK_USE_EXEC_PREFER_SIZE)
case DUK_OP_EQ_RR:
case DUK_OP_EQ_CR:
case DUK_OP_EQ_RC:
case DUK_OP_EQ_CC:
DUK__EQ_BODY(DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins));
case DUK_OP_NEQ_RR:
case DUK_OP_NEQ_CR:
case DUK_OP_NEQ_RC:
case DUK_OP_NEQ_CC:
DUK__NEQ_BODY(DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins));
case DUK_OP_SEQ_RR:
case DUK_OP_SEQ_CR:
case DUK_OP_SEQ_RC:
case DUK_OP_SEQ_CC:
DUK__SEQ_BODY(DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins));
case DUK_OP_SNEQ_RR:
case DUK_OP_SNEQ_CR:
case DUK_OP_SNEQ_RC:
case DUK_OP_SNEQ_CC:
DUK__SNEQ_BODY(DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins));
#else /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_EQ_RR:
DUK__EQ_BODY(DUK__REGP_B(ins), DUK__REGP_C(ins));
case DUK_OP_EQ_CR:
DUK__EQ_BODY(DUK__CONSTP_B(ins), DUK__REGP_C(ins));
case DUK_OP_EQ_RC:
DUK__EQ_BODY(DUK__REGP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_EQ_CC:
DUK__EQ_BODY(DUK__CONSTP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_NEQ_RR:
DUK__NEQ_BODY(DUK__REGP_B(ins), DUK__REGP_C(ins));
case DUK_OP_NEQ_CR:
DUK__NEQ_BODY(DUK__CONSTP_B(ins), DUK__REGP_C(ins));
case DUK_OP_NEQ_RC:
DUK__NEQ_BODY(DUK__REGP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_NEQ_CC:
DUK__NEQ_BODY(DUK__CONSTP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_SEQ_RR:
DUK__SEQ_BODY(DUK__REGP_B(ins), DUK__REGP_C(ins));
case DUK_OP_SEQ_CR:
DUK__SEQ_BODY(DUK__CONSTP_B(ins), DUK__REGP_C(ins));
case DUK_OP_SEQ_RC:
DUK__SEQ_BODY(DUK__REGP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_SEQ_CC:
DUK__SEQ_BODY(DUK__CONSTP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_SNEQ_RR:
DUK__SNEQ_BODY(DUK__REGP_B(ins), DUK__REGP_C(ins));
case DUK_OP_SNEQ_CR:
DUK__SNEQ_BODY(DUK__CONSTP_B(ins), DUK__REGP_C(ins));
case DUK_OP_SNEQ_RC:
DUK__SNEQ_BODY(DUK__REGP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_SNEQ_CC:
DUK__SNEQ_BODY(DUK__CONSTP_B(ins), DUK__CONSTP_C(ins));
#endif /* DUK_USE_EXEC_PREFER_SIZE */
#define DUK__COMPARE_BODY(arg1,arg2,flags) { \
duk_bool_t tmp; \
tmp = duk_js_compare_helper(thr, (arg1), (arg2), (flags)); \
DUK_ASSERT(tmp == 0 || tmp == 1); \
DUK__REPLACE_BOOL_A_BREAK(tmp); \
}
#define DUK__GT_BODY(barg,carg) DUK__COMPARE_BODY((carg), (barg), 0)
#define DUK__GE_BODY(barg,carg) DUK__COMPARE_BODY((barg), (carg), DUK_COMPARE_FLAG_EVAL_LEFT_FIRST | DUK_COMPARE_FLAG_NEGATE)
#define DUK__LT_BODY(barg,carg) DUK__COMPARE_BODY((barg), (carg), DUK_COMPARE_FLAG_EVAL_LEFT_FIRST)
#define DUK__LE_BODY(barg,carg) DUK__COMPARE_BODY((carg), (barg), DUK_COMPARE_FLAG_NEGATE)
#if defined(DUK_USE_EXEC_PREFER_SIZE)
case DUK_OP_GT_RR:
case DUK_OP_GT_CR:
case DUK_OP_GT_RC:
case DUK_OP_GT_CC:
DUK__GT_BODY(DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins));
case DUK_OP_GE_RR:
case DUK_OP_GE_CR:
case DUK_OP_GE_RC:
case DUK_OP_GE_CC:
DUK__GE_BODY(DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins));
case DUK_OP_LT_RR:
case DUK_OP_LT_CR:
case DUK_OP_LT_RC:
case DUK_OP_LT_CC:
DUK__LT_BODY(DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins));
case DUK_OP_LE_RR:
case DUK_OP_LE_CR:
case DUK_OP_LE_RC:
case DUK_OP_LE_CC:
DUK__LE_BODY(DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins));
#else /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_GT_RR:
DUK__GT_BODY(DUK__REGP_B(ins), DUK__REGP_C(ins));
case DUK_OP_GT_CR:
DUK__GT_BODY(DUK__CONSTP_B(ins), DUK__REGP_C(ins));
case DUK_OP_GT_RC:
DUK__GT_BODY(DUK__REGP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_GT_CC:
DUK__GT_BODY(DUK__CONSTP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_GE_RR:
DUK__GE_BODY(DUK__REGP_B(ins), DUK__REGP_C(ins));
case DUK_OP_GE_CR:
DUK__GE_BODY(DUK__CONSTP_B(ins), DUK__REGP_C(ins));
case DUK_OP_GE_RC:
DUK__GE_BODY(DUK__REGP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_GE_CC:
DUK__GE_BODY(DUK__CONSTP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_LT_RR:
DUK__LT_BODY(DUK__REGP_B(ins), DUK__REGP_C(ins));
case DUK_OP_LT_CR:
DUK__LT_BODY(DUK__CONSTP_B(ins), DUK__REGP_C(ins));
case DUK_OP_LT_RC:
DUK__LT_BODY(DUK__REGP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_LT_CC:
DUK__LT_BODY(DUK__CONSTP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_LE_RR:
DUK__LE_BODY(DUK__REGP_B(ins), DUK__REGP_C(ins));
case DUK_OP_LE_CR:
DUK__LE_BODY(DUK__CONSTP_B(ins), DUK__REGP_C(ins));
case DUK_OP_LE_RC:
DUK__LE_BODY(DUK__REGP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_LE_CC:
DUK__LE_BODY(DUK__CONSTP_B(ins), DUK__CONSTP_C(ins));
#endif /* DUK_USE_EXEC_PREFER_SIZE */
/* No size optimized variant at present for IF. */
case DUK_OP_IFTRUE_R: {
if (duk_js_toboolean(DUK__REGP_BC(ins)) != 0) {
curr_pc++;
}
break;
}
case DUK_OP_IFTRUE_C: {
if (duk_js_toboolean(DUK__CONSTP_BC(ins)) != 0) {
curr_pc++;
}
break;
}
case DUK_OP_IFFALSE_R: {
if (duk_js_toboolean(DUK__REGP_BC(ins)) == 0) {
curr_pc++;
}
break;
}
case DUK_OP_IFFALSE_C: {
if (duk_js_toboolean(DUK__CONSTP_BC(ins)) == 0) {
curr_pc++;
}
break;
}
#if defined(DUK_USE_EXEC_PREFER_SIZE)
case DUK_OP_ADD_RR:
case DUK_OP_ADD_CR:
case DUK_OP_ADD_RC:
case DUK_OP_ADD_CC: {
/* XXX: could leave value on stack top and goto replace_top_a; */
duk__vm_arith_add(thr, DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins), DUK_DEC_A(ins));
break;
}
#else /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_ADD_RR: {
duk__vm_arith_add(thr, DUK__REGP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins));
break;
}
case DUK_OP_ADD_CR: {
duk__vm_arith_add(thr, DUK__CONSTP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins));
break;
}
case DUK_OP_ADD_RC: {
duk__vm_arith_add(thr, DUK__REGP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins));
break;
}
case DUK_OP_ADD_CC: {
duk__vm_arith_add(thr, DUK__CONSTP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins));
break;
}
#endif /* DUK_USE_EXEC_PREFER_SIZE */
#if defined(DUK_USE_EXEC_PREFER_SIZE)
case DUK_OP_SUB_RR:
case DUK_OP_SUB_CR:
case DUK_OP_SUB_RC:
case DUK_OP_SUB_CC:
case DUK_OP_MUL_RR:
case DUK_OP_MUL_CR:
case DUK_OP_MUL_RC:
case DUK_OP_MUL_CC:
case DUK_OP_DIV_RR:
case DUK_OP_DIV_CR:
case DUK_OP_DIV_RC:
case DUK_OP_DIV_CC:
case DUK_OP_MOD_RR:
case DUK_OP_MOD_CR:
case DUK_OP_MOD_RC:
case DUK_OP_MOD_CC:
#if defined(DUK_USE_ES7_EXP_OPERATOR)
case DUK_OP_EXP_RR:
case DUK_OP_EXP_CR:
case DUK_OP_EXP_RC:
case DUK_OP_EXP_CC:
#endif /* DUK_USE_ES7_EXP_OPERATOR */
{
/* XXX: could leave value on stack top and goto replace_top_a; */
duk__vm_arith_binary_op(thr, DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins), DUK_DEC_A(ins), op);
break;
}
#else /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_SUB_RR: {
duk__vm_arith_binary_op(thr, DUK__REGP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_SUB);
break;
}
case DUK_OP_SUB_CR: {
duk__vm_arith_binary_op(thr, DUK__CONSTP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_SUB);
break;
}
case DUK_OP_SUB_RC: {
duk__vm_arith_binary_op(thr, DUK__REGP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_SUB);
break;
}
case DUK_OP_SUB_CC: {
duk__vm_arith_binary_op(thr, DUK__CONSTP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_SUB);
break;
}
case DUK_OP_MUL_RR: {
duk__vm_arith_binary_op(thr, DUK__REGP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_MUL);
break;
}
case DUK_OP_MUL_CR: {
duk__vm_arith_binary_op(thr, DUK__CONSTP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_MUL);
break;
}
case DUK_OP_MUL_RC: {
duk__vm_arith_binary_op(thr, DUK__REGP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_MUL);
break;
}
case DUK_OP_MUL_CC: {
duk__vm_arith_binary_op(thr, DUK__CONSTP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_MUL);
break;
}
case DUK_OP_DIV_RR: {
duk__vm_arith_binary_op(thr, DUK__REGP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_DIV);
break;
}
case DUK_OP_DIV_CR: {
duk__vm_arith_binary_op(thr, DUK__CONSTP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_DIV);
break;
}
case DUK_OP_DIV_RC: {
duk__vm_arith_binary_op(thr, DUK__REGP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_DIV);
break;
}
case DUK_OP_DIV_CC: {
duk__vm_arith_binary_op(thr, DUK__CONSTP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_DIV);
break;
}
case DUK_OP_MOD_RR: {
duk__vm_arith_binary_op(thr, DUK__REGP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_MOD);
break;
}
case DUK_OP_MOD_CR: {
duk__vm_arith_binary_op(thr, DUK__CONSTP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_MOD);
break;
}
case DUK_OP_MOD_RC: {
duk__vm_arith_binary_op(thr, DUK__REGP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_MOD);
break;
}
case DUK_OP_MOD_CC: {
duk__vm_arith_binary_op(thr, DUK__CONSTP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_MOD);
break;
}
#if defined(DUK_USE_ES7_EXP_OPERATOR)
case DUK_OP_EXP_RR: {
duk__vm_arith_binary_op(thr, DUK__REGP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_EXP);
break;
}
case DUK_OP_EXP_CR: {
duk__vm_arith_binary_op(thr, DUK__CONSTP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_EXP);
break;
}
case DUK_OP_EXP_RC: {
duk__vm_arith_binary_op(thr, DUK__REGP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_EXP);
break;
}
case DUK_OP_EXP_CC: {
duk__vm_arith_binary_op(thr, DUK__CONSTP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_EXP);
break;
}
#endif /* DUK_USE_ES7_EXP_OPERATOR */
#endif /* DUK_USE_EXEC_PREFER_SIZE */
#if defined(DUK_USE_EXEC_PREFER_SIZE)
case DUK_OP_BAND_RR:
case DUK_OP_BAND_CR:
case DUK_OP_BAND_RC:
case DUK_OP_BAND_CC:
case DUK_OP_BOR_RR:
case DUK_OP_BOR_CR:
case DUK_OP_BOR_RC:
case DUK_OP_BOR_CC:
case DUK_OP_BXOR_RR:
case DUK_OP_BXOR_CR:
case DUK_OP_BXOR_RC:
case DUK_OP_BXOR_CC:
case DUK_OP_BASL_RR:
case DUK_OP_BASL_CR:
case DUK_OP_BASL_RC:
case DUK_OP_BASL_CC:
case DUK_OP_BLSR_RR:
case DUK_OP_BLSR_CR:
case DUK_OP_BLSR_RC:
case DUK_OP_BLSR_CC:
case DUK_OP_BASR_RR:
case DUK_OP_BASR_CR:
case DUK_OP_BASR_RC:
case DUK_OP_BASR_CC: {
/* XXX: could leave value on stack top and goto replace_top_a; */
duk__vm_bitwise_binary_op(thr, DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins), DUK_DEC_A(ins), op);
break;
}
#else /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_BAND_RR: {
duk__vm_bitwise_binary_op(thr, DUK__REGP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_BAND);
break;
}
case DUK_OP_BAND_CR: {
duk__vm_bitwise_binary_op(thr, DUK__CONSTP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_BAND);
break;
}
case DUK_OP_BAND_RC: {
duk__vm_bitwise_binary_op(thr, DUK__REGP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_BAND);
break;
}
case DUK_OP_BAND_CC: {
duk__vm_bitwise_binary_op(thr, DUK__CONSTP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_BAND);
break;
}
case DUK_OP_BOR_RR: {
duk__vm_bitwise_binary_op(thr, DUK__REGP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_BOR);
break;
}
case DUK_OP_BOR_CR: {
duk__vm_bitwise_binary_op(thr, DUK__CONSTP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_BOR);
break;
}
case DUK_OP_BOR_RC: {
duk__vm_bitwise_binary_op(thr, DUK__REGP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_BOR);
break;
}
case DUK_OP_BOR_CC: {
duk__vm_bitwise_binary_op(thr, DUK__CONSTP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_BOR);
break;
}
case DUK_OP_BXOR_RR: {
duk__vm_bitwise_binary_op(thr, DUK__REGP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_BXOR);
break;
}
case DUK_OP_BXOR_CR: {
duk__vm_bitwise_binary_op(thr, DUK__CONSTP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_BXOR);
break;
}
case DUK_OP_BXOR_RC: {
duk__vm_bitwise_binary_op(thr, DUK__REGP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_BXOR);
break;
}
case DUK_OP_BXOR_CC: {
duk__vm_bitwise_binary_op(thr, DUK__CONSTP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_BXOR);
break;
}
case DUK_OP_BASL_RR: {
duk__vm_bitwise_binary_op(thr, DUK__REGP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_BASL);
break;
}
case DUK_OP_BASL_CR: {
duk__vm_bitwise_binary_op(thr, DUK__CONSTP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_BASL);
break;
}
case DUK_OP_BASL_RC: {
duk__vm_bitwise_binary_op(thr, DUK__REGP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_BASL);
break;
}
case DUK_OP_BASL_CC: {
duk__vm_bitwise_binary_op(thr, DUK__CONSTP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_BASL);
break;
}
case DUK_OP_BLSR_RR: {
duk__vm_bitwise_binary_op(thr, DUK__REGP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_BLSR);
break;
}
case DUK_OP_BLSR_CR: {
duk__vm_bitwise_binary_op(thr, DUK__CONSTP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_BLSR);
break;
}
case DUK_OP_BLSR_RC: {
duk__vm_bitwise_binary_op(thr, DUK__REGP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_BLSR);
break;
}
case DUK_OP_BLSR_CC: {
duk__vm_bitwise_binary_op(thr, DUK__CONSTP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_BLSR);
break;
}
case DUK_OP_BASR_RR: {
duk__vm_bitwise_binary_op(thr, DUK__REGP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_BASR);
break;
}
case DUK_OP_BASR_CR: {
duk__vm_bitwise_binary_op(thr, DUK__CONSTP_B(ins), DUK__REGP_C(ins), DUK_DEC_A(ins), DUK_OP_BASR);
break;
}
case DUK_OP_BASR_RC: {
duk__vm_bitwise_binary_op(thr, DUK__REGP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_BASR);
break;
}
case DUK_OP_BASR_CC: {
duk__vm_bitwise_binary_op(thr, DUK__CONSTP_B(ins), DUK__CONSTP_C(ins), DUK_DEC_A(ins), DUK_OP_BASR);
break;
}
#endif /* DUK_USE_EXEC_PREFER_SIZE */
/* For INSTOF and IN, B is always a register. */
#define DUK__INSTOF_BODY(barg,carg) { \
duk_bool_t tmp; \
tmp = duk_js_instanceof(thr, (barg), (carg)); \
DUK_ASSERT(tmp == 0 || tmp == 1); \
DUK__REPLACE_BOOL_A_BREAK(tmp); \
}
#define DUK__IN_BODY(barg,carg) { \
duk_bool_t tmp; \
tmp = duk_js_in(thr, (barg), (carg)); \
DUK_ASSERT(tmp == 0 || tmp == 1); \
DUK__REPLACE_BOOL_A_BREAK(tmp); \
}
#if defined(DUK_USE_EXEC_PREFER_SIZE)
case DUK_OP_INSTOF_RR:
case DUK_OP_INSTOF_CR:
case DUK_OP_INSTOF_RC:
case DUK_OP_INSTOF_CC:
DUK__INSTOF_BODY(DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins));
case DUK_OP_IN_RR:
case DUK_OP_IN_CR:
case DUK_OP_IN_RC:
case DUK_OP_IN_CC:
DUK__IN_BODY(DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins));
#else /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_INSTOF_RR:
DUK__INSTOF_BODY(DUK__REGP_B(ins), DUK__REGP_C(ins));
case DUK_OP_INSTOF_CR:
DUK__INSTOF_BODY(DUK__CONSTP_B(ins), DUK__REGP_C(ins));
case DUK_OP_INSTOF_RC:
DUK__INSTOF_BODY(DUK__REGP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_INSTOF_CC:
DUK__INSTOF_BODY(DUK__CONSTP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_IN_RR:
DUK__IN_BODY(DUK__REGP_B(ins), DUK__REGP_C(ins));
case DUK_OP_IN_CR:
DUK__IN_BODY(DUK__CONSTP_B(ins), DUK__REGP_C(ins));
case DUK_OP_IN_RC:
DUK__IN_BODY(DUK__REGP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_IN_CC:
DUK__IN_BODY(DUK__CONSTP_B(ins), DUK__CONSTP_C(ins));
#endif /* DUK_USE_EXEC_PREFER_SIZE */
/* Pre/post inc/dec for register variables, important for loops. */
#if defined(DUK_USE_EXEC_PREFER_SIZE)
case DUK_OP_PREINCR:
case DUK_OP_PREDECR:
case DUK_OP_POSTINCR:
case DUK_OP_POSTDECR: {
duk__prepost_incdec_reg_helper(thr, DUK__REGP_A(ins), DUK__REGP_BC(ins), op);
break;
}
case DUK_OP_PREINCV:
case DUK_OP_PREDECV:
case DUK_OP_POSTINCV:
case DUK_OP_POSTDECV: {
duk__prepost_incdec_var_helper(thr, DUK_DEC_A(ins), DUK__CONSTP_BC(ins), op, DUK__STRICT());
break;
}
#else /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_PREINCR: {
duk__prepost_incdec_reg_helper(thr, DUK__REGP_A(ins), DUK__REGP_BC(ins), DUK_OP_PREINCR);
break;
}
case DUK_OP_PREDECR: {
duk__prepost_incdec_reg_helper(thr, DUK__REGP_A(ins), DUK__REGP_BC(ins), DUK_OP_PREDECR);
break;
}
case DUK_OP_POSTINCR: {
duk__prepost_incdec_reg_helper(thr, DUK__REGP_A(ins), DUK__REGP_BC(ins), DUK_OP_POSTINCR);
break;
}
case DUK_OP_POSTDECR: {
duk__prepost_incdec_reg_helper(thr, DUK__REGP_A(ins), DUK__REGP_BC(ins), DUK_OP_POSTDECR);
break;
}
case DUK_OP_PREINCV: {
duk__prepost_incdec_var_helper(thr, DUK_DEC_A(ins), DUK__CONSTP_BC(ins), DUK_OP_PREINCV, DUK__STRICT());
break;
}
case DUK_OP_PREDECV: {
duk__prepost_incdec_var_helper(thr, DUK_DEC_A(ins), DUK__CONSTP_BC(ins), DUK_OP_PREDECV, DUK__STRICT());
break;
}
case DUK_OP_POSTINCV: {
duk__prepost_incdec_var_helper(thr, DUK_DEC_A(ins), DUK__CONSTP_BC(ins), DUK_OP_POSTINCV, DUK__STRICT());
break;
}
case DUK_OP_POSTDECV: {
duk__prepost_incdec_var_helper(thr, DUK_DEC_A(ins), DUK__CONSTP_BC(ins), DUK_OP_POSTDECV, DUK__STRICT());
break;
}
#endif /* DUK_USE_EXEC_PREFER_SIZE */
/* XXX: Move to separate helper, optimize for perf/size separately. */
/* Preinc/predec for object properties. */
case DUK_OP_PREINCP_RR:
case DUK_OP_PREINCP_CR:
case DUK_OP_PREINCP_RC:
case DUK_OP_PREINCP_CC:
case DUK_OP_PREDECP_RR:
case DUK_OP_PREDECP_CR:
case DUK_OP_PREDECP_RC:
case DUK_OP_PREDECP_CC:
case DUK_OP_POSTINCP_RR:
case DUK_OP_POSTINCP_CR:
case DUK_OP_POSTINCP_RC:
case DUK_OP_POSTINCP_CC:
case DUK_OP_POSTDECP_RR:
case DUK_OP_POSTDECP_CR:
case DUK_OP_POSTDECP_RC:
case DUK_OP_POSTDECP_CC: {
duk_tval *tv_obj;
duk_tval *tv_key;
duk_tval *tv_val;
duk_bool_t rc;
duk_double_t x, y, z;
#if !defined(DUK_USE_EXEC_PREFER_SIZE)
duk_tval *tv_dst;
#endif /* DUK_USE_EXEC_PREFER_SIZE */
/* A -> target reg
* B -> object reg/const (may be const e.g. in "'foo'[1]")
* C -> key reg/const
*/
/* Opcode bits 0-1 are used to distinguish reg/const variants.
* Opcode bits 2-3 are used to distinguish inc/dec variants:
* Bit 2 = inc(0)/dec(1), bit 3 = pre(0)/post(1).
*/
DUK_ASSERT((DUK_OP_PREINCP_RR & 0x0c) == 0x00);
DUK_ASSERT((DUK_OP_PREDECP_RR & 0x0c) == 0x04);
DUK_ASSERT((DUK_OP_POSTINCP_RR & 0x0c) == 0x08);
DUK_ASSERT((DUK_OP_POSTDECP_RR & 0x0c) == 0x0c);
tv_obj = DUK__REGCONSTP_B(ins);
tv_key = DUK__REGCONSTP_C(ins);
rc = duk_hobject_getprop(thr, tv_obj, tv_key); /* -> [val] */
DUK_UNREF(rc); /* ignore */
tv_obj = NULL; /* invalidated */
tv_key = NULL; /* invalidated */
/* XXX: Fastint fast path would be useful here. Also fastints
* now lose their fastint status in current handling which is
* not intuitive.
*/
x = duk_to_number_m1(thr);
duk_pop_unsafe(thr);
if (ins & DUK_BC_INCDECP_FLAG_DEC) {
y = x - 1.0;
} else {
y = x + 1.0;
}
duk_push_number(thr, y);
tv_val = DUK_GET_TVAL_NEGIDX(thr, -1);
DUK_ASSERT(tv_val != NULL);
tv_obj = DUK__REGCONSTP_B(ins);
tv_key = DUK__REGCONSTP_C(ins);
rc = duk_hobject_putprop(thr, tv_obj, tv_key, tv_val, DUK__STRICT());
DUK_UNREF(rc); /* ignore */
tv_obj = NULL; /* invalidated */
tv_key = NULL; /* invalidated */
duk_pop_unsafe(thr);
z = (ins & DUK_BC_INCDECP_FLAG_POST) ? x : y;
#if defined(DUK_USE_EXEC_PREFER_SIZE)
duk_push_number(thr, z);
DUK__REPLACE_TOP_A_BREAK();
#else
tv_dst = DUK__REGP_A(ins);
DUK_TVAL_SET_NUMBER_UPDREF(thr, tv_dst, z);
break;
#endif
}
/* XXX: GETPROP where object is 'this', GETPROPT?
* Occurs relatively often in object oriented code.
*/
#define DUK__GETPROP_BODY(barg,carg) { \
/* A -> target reg \
* B -> object reg/const (may be const e.g. in "'foo'[1]") \
* C -> key reg/const \
*/ \
(void) duk_hobject_getprop(thr, (barg), (carg)); \
DUK__REPLACE_TOP_A_BREAK(); \
}
#define DUK__GETPROPC_BODY(barg,carg) { \
/* Same as GETPROP but callability check for property-based calls. */ \
duk_tval *tv__targ; \
(void) duk_hobject_getprop(thr, (barg), (carg)); \
DUK_GC_TORTURE(thr->heap); \
tv__targ = DUK_GET_TVAL_NEGIDX(thr, -1); \
if (DUK_UNLIKELY(!duk_is_callable_tval(thr, tv__targ))) { \
/* Here we intentionally re-evaluate the macro \
* arguments to deal with potentially changed \
* valstack base pointer! \
*/ \
duk_call_setup_propcall_error(thr, (barg), (carg)); \
} \
DUK__REPLACE_TOP_A_BREAK(); \
}
#define DUK__PUTPROP_BODY(aarg,barg,carg) { \
/* A -> object reg \
* B -> key reg/const \
* C -> value reg/const \
* \
* Note: intentional difference to register arrangement \
* of e.g. GETPROP; 'A' must contain a register-only value. \
*/ \
(void) duk_hobject_putprop(thr, (aarg), (barg), (carg), DUK__STRICT()); \
break; \
}
#define DUK__DELPROP_BODY(barg,carg) { \
/* A -> result reg \
* B -> object reg \
* C -> key reg/const \
*/ \
duk_bool_t rc; \
rc = duk_hobject_delprop(thr, (barg), (carg), DUK__STRICT()); \
DUK_ASSERT(rc == 0 || rc == 1); \
DUK__REPLACE_BOOL_A_BREAK(rc); \
}
#if defined(DUK_USE_EXEC_PREFER_SIZE)
case DUK_OP_GETPROP_RR:
case DUK_OP_GETPROP_CR:
case DUK_OP_GETPROP_RC:
case DUK_OP_GETPROP_CC:
DUK__GETPROP_BODY(DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins));
#if defined(DUK_USE_VERBOSE_ERRORS)
case DUK_OP_GETPROPC_RR:
case DUK_OP_GETPROPC_CR:
case DUK_OP_GETPROPC_RC:
case DUK_OP_GETPROPC_CC:
DUK__GETPROPC_BODY(DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins));
#endif
case DUK_OP_PUTPROP_RR:
case DUK_OP_PUTPROP_CR:
case DUK_OP_PUTPROP_RC:
case DUK_OP_PUTPROP_CC:
DUK__PUTPROP_BODY(DUK__REGP_A(ins), DUK__REGCONSTP_B(ins), DUK__REGCONSTP_C(ins));
case DUK_OP_DELPROP_RR:
case DUK_OP_DELPROP_RC: /* B is always reg */
DUK__DELPROP_BODY(DUK__REGP_B(ins), DUK__REGCONSTP_C(ins));
#else /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_GETPROP_RR:
DUK__GETPROP_BODY(DUK__REGP_B(ins), DUK__REGP_C(ins));
case DUK_OP_GETPROP_CR:
DUK__GETPROP_BODY(DUK__CONSTP_B(ins), DUK__REGP_C(ins));
case DUK_OP_GETPROP_RC:
DUK__GETPROP_BODY(DUK__REGP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_GETPROP_CC:
DUK__GETPROP_BODY(DUK__CONSTP_B(ins), DUK__CONSTP_C(ins));
#if defined(DUK_USE_VERBOSE_ERRORS)
case DUK_OP_GETPROPC_RR:
DUK__GETPROPC_BODY(DUK__REGP_B(ins), DUK__REGP_C(ins));
case DUK_OP_GETPROPC_CR:
DUK__GETPROPC_BODY(DUK__CONSTP_B(ins), DUK__REGP_C(ins));
case DUK_OP_GETPROPC_RC:
DUK__GETPROPC_BODY(DUK__REGP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_GETPROPC_CC:
DUK__GETPROPC_BODY(DUK__CONSTP_B(ins), DUK__CONSTP_C(ins));
#endif
case DUK_OP_PUTPROP_RR:
DUK__PUTPROP_BODY(DUK__REGP_A(ins), DUK__REGP_B(ins), DUK__REGP_C(ins));
case DUK_OP_PUTPROP_CR:
DUK__PUTPROP_BODY(DUK__REGP_A(ins), DUK__CONSTP_B(ins), DUK__REGP_C(ins));
case DUK_OP_PUTPROP_RC:
DUK__PUTPROP_BODY(DUK__REGP_A(ins), DUK__REGP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_PUTPROP_CC:
DUK__PUTPROP_BODY(DUK__REGP_A(ins), DUK__CONSTP_B(ins), DUK__CONSTP_C(ins));
case DUK_OP_DELPROP_RR: /* B is always reg */
DUK__DELPROP_BODY(DUK__REGP_B(ins), DUK__REGP_C(ins));
case DUK_OP_DELPROP_RC:
DUK__DELPROP_BODY(DUK__REGP_B(ins), DUK__CONSTP_C(ins));
#endif /* DUK_USE_EXEC_PREFER_SIZE */
/* No fast path for DECLVAR now, it's quite a rare instruction. */
case DUK_OP_DECLVAR_RR:
case DUK_OP_DECLVAR_CR:
case DUK_OP_DECLVAR_RC:
case DUK_OP_DECLVAR_CC: {
duk_activation *act;
duk_small_uint_fast_t a = DUK_DEC_A(ins);
duk_tval *tv1;
duk_hstring *name;
duk_small_uint_t prop_flags;
duk_bool_t is_func_decl;
tv1 = DUK__REGCONSTP_B(ins);
DUK_ASSERT(DUK_TVAL_IS_STRING(tv1));
name = DUK_TVAL_GET_STRING(tv1);
DUK_ASSERT(name != NULL);
is_func_decl = ((a & DUK_BC_DECLVAR_FLAG_FUNC_DECL) != 0);
/* XXX: declvar takes an duk_tval pointer, which is awkward and
* should be reworked.
*/
/* Compiler is responsible for selecting property flags (configurability,
* writability, etc).
*/
prop_flags = a & DUK_PROPDESC_FLAGS_MASK;
if (is_func_decl) {
duk_push_tval(thr, DUK__REGCONSTP_C(ins));
} else {
DUK_ASSERT(DUK_TVAL_IS_UNDEFINED(thr->valstack_top)); /* valstack policy */
thr->valstack_top++;
}
tv1 = DUK_GET_TVAL_NEGIDX(thr, -1);
act = thr->callstack_curr;
if (duk_js_declvar_activation(thr, act, name, tv1, prop_flags, is_func_decl)) {
if (is_func_decl) {
/* Already declared, update value. */
tv1 = DUK_GET_TVAL_NEGIDX(thr, -1);
duk_js_putvar_activation(thr, act, name, tv1, DUK__STRICT());
} else {
/* Already declared but no initializer value
* (e.g. 'var xyz;'), no-op.
*/
}
}
duk_pop_unsafe(thr);
break;
}
#if defined(DUK_USE_REGEXP_SUPPORT)
/* The compiler should never emit DUK_OP_REGEXP if there is no
* regexp support.
*/
case DUK_OP_REGEXP_RR:
case DUK_OP_REGEXP_CR:
case DUK_OP_REGEXP_RC:
case DUK_OP_REGEXP_CC: {
/* A -> target register
* B -> bytecode (also contains flags)
* C -> escaped source
*/
duk_push_tval(thr, DUK__REGCONSTP_C(ins));
duk_push_tval(thr, DUK__REGCONSTP_B(ins)); /* -> [ ... escaped_source bytecode ] */
duk_regexp_create_instance(thr); /* -> [ ... regexp_instance ] */
DUK__REPLACE_TOP_A_BREAK();
}
#endif /* DUK_USE_REGEXP_SUPPORT */
/* XXX: 'c' is unused, use whole BC, etc. */
case DUK_OP_CSVAR_RR:
case DUK_OP_CSVAR_CR:
case DUK_OP_CSVAR_RC:
case DUK_OP_CSVAR_CC: {
/* The speciality of calling through a variable binding is that the
* 'this' value may be provided by the variable lookup: E5 Section 6.b.i.
*
* The only (standard) case where the 'this' binding is non-null is when
* (1) the variable is found in an object environment record, and
* (2) that object environment record is a 'with' block.
*/
duk_activation *act;
duk_uint_fast_t idx;
duk_tval *tv1;
duk_hstring *name;
/* A -> target registers (A, A + 1) for call setup
* B -> identifier name, usually constant but can be a register due to shuffling
*/
tv1 = DUK__REGCONSTP_B(ins);
DUK_ASSERT(DUK_TVAL_IS_STRING(tv1));
name = DUK_TVAL_GET_STRING(tv1);
DUK_ASSERT(name != NULL);
act = thr->callstack_curr;
(void) duk_js_getvar_activation(thr, act, name, 1 /*throw*/); /* -> [... val this] */
idx = (duk_uint_fast_t) DUK_DEC_A(ins);
/* Could add direct value stack handling. */
duk_replace(thr, (duk_idx_t) (idx + 1)); /* 'this' binding */
duk_replace(thr, (duk_idx_t) idx); /* variable value (function, we hope, not checked here) */
break;
}
case DUK_OP_CLOSURE: {
duk_activation *act;
duk_hcompfunc *fun_act;
duk_small_uint_fast_t bc = DUK_DEC_BC(ins);
duk_hobject *fun_temp;
/* A -> target reg
* BC -> inner function index
*/
DUK_DDD(DUK_DDDPRINT("CLOSURE to target register %ld, fnum %ld (count %ld)",
(long) DUK_DEC_A(ins), (long) DUK_DEC_BC(ins), (long) DUK_HCOMPFUNC_GET_FUNCS_COUNT(thr->heap, DUK__FUN())));
DUK_ASSERT_DISABLE(bc >= 0); /* unsigned */
DUK_ASSERT((duk_uint_t) bc < (duk_uint_t) DUK_HCOMPFUNC_GET_FUNCS_COUNT(thr->heap, DUK__FUN()));
act = thr->callstack_curr;
fun_act = (duk_hcompfunc *) DUK_ACT_GET_FUNC(act);
fun_temp = DUK_HCOMPFUNC_GET_FUNCS_BASE(thr->heap, fun_act)[bc];
DUK_ASSERT(fun_temp != NULL);
DUK_ASSERT(DUK_HOBJECT_IS_COMPFUNC(fun_temp));
DUK_DDD(DUK_DDDPRINT("CLOSURE: function template is: %p -> %!O",
(void *) fun_temp, (duk_heaphdr *) fun_temp));
if (act->lex_env == NULL) {
DUK_ASSERT(act->var_env == NULL);
duk_js_init_activation_environment_records_delayed(thr, act);
act = thr->callstack_curr;
}
DUK_ASSERT(act->lex_env != NULL);
DUK_ASSERT(act->var_env != NULL);
/* functions always have a NEWENV flag, i.e. they get a
* new variable declaration environment, so only lex_env
* matters here.
*/
duk_js_push_closure(thr,
(duk_hcompfunc *) fun_temp,
act->var_env,
act->lex_env,
1 /*add_auto_proto*/);
DUK__REPLACE_TOP_A_BREAK();
}
case DUK_OP_GETVAR: {
duk_activation *act;
duk_tval *tv1;
duk_hstring *name;
tv1 = DUK__CONSTP_BC(ins);
DUK_ASSERT(DUK_TVAL_IS_STRING(tv1));
name = DUK_TVAL_GET_STRING(tv1);
DUK_ASSERT(name != NULL);
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
(void) duk_js_getvar_activation(thr, act, name, 1 /*throw*/); /* -> [... val this] */
duk_pop_unsafe(thr); /* 'this' binding is not needed here */
DUK__REPLACE_TOP_A_BREAK();
}
case DUK_OP_PUTVAR: {
duk_activation *act;
duk_tval *tv1;
duk_hstring *name;
tv1 = DUK__CONSTP_BC(ins);
DUK_ASSERT(DUK_TVAL_IS_STRING(tv1));
name = DUK_TVAL_GET_STRING(tv1);
DUK_ASSERT(name != NULL);
/* XXX: putvar takes a duk_tval pointer, which is awkward and
* should be reworked.
*/
tv1 = DUK__REGP_A(ins); /* val */
act = thr->callstack_curr;
duk_js_putvar_activation(thr, act, name, tv1, DUK__STRICT());
break;
}
case DUK_OP_DELVAR: {
duk_activation *act;
duk_tval *tv1;
duk_hstring *name;
duk_bool_t rc;
tv1 = DUK__CONSTP_BC(ins);
DUK_ASSERT(DUK_TVAL_IS_STRING(tv1));
name = DUK_TVAL_GET_STRING(tv1);
DUK_ASSERT(name != NULL);
act = thr->callstack_curr;
rc = duk_js_delvar_activation(thr, act, name);
DUK__REPLACE_BOOL_A_BREAK(rc);
}
case DUK_OP_JUMP: {
/* Note: without explicit cast to signed, MSVC will
* apparently generate a large positive jump when the
* bias-corrected value would normally be negative.
*/
curr_pc += (duk_int_fast_t) DUK_DEC_ABC(ins) - (duk_int_fast_t) DUK_BC_JUMP_BIAS;
break;
}
#define DUK__RETURN_SHARED() do { \
duk_small_uint_t ret_result; \
/* duk__handle_return() is guaranteed never to throw, except \
* for potential out-of-memory situations which will then \
* propagate out of the executor longjmp handler. \
*/ \
DUK_ASSERT(thr->ptr_curr_pc == NULL); \
ret_result = duk__handle_return(thr, entry_act); \
if (ret_result == DUK__RETHAND_RESTART) { \
goto restart_execution; \
} \
DUK_ASSERT(ret_result == DUK__RETHAND_FINISHED); \
return; \
} while (0)
#if defined(DUK_USE_EXEC_PREFER_SIZE)
case DUK_OP_RETREG:
case DUK_OP_RETCONST:
case DUK_OP_RETCONSTN:
case DUK_OP_RETUNDEF: {
/* BC -> return value reg/const */
DUK__SYNC_AND_NULL_CURR_PC();
if (op == DUK_OP_RETREG) {
duk_push_tval(thr, DUK__REGP_BC(ins));
} else if (op == DUK_OP_RETUNDEF) {
DUK_ASSERT(DUK_TVAL_IS_UNDEFINED(thr->valstack_top)); /* valstack policy */
thr->valstack_top++;
} else {
DUK_ASSERT(op == DUK_OP_RETCONST || op == DUK_OP_RETCONSTN);
duk_push_tval(thr, DUK__CONSTP_BC(ins));
}
DUK__RETURN_SHARED();
}
#else /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_RETREG: {
duk_tval *tv;
DUK__SYNC_AND_NULL_CURR_PC();
tv = DUK__REGP_BC(ins);
DUK_TVAL_SET_TVAL(thr->valstack_top, tv);
DUK_TVAL_INCREF(thr, tv);
thr->valstack_top++;
DUK__RETURN_SHARED();
}
/* This will be unused without refcounting. */
case DUK_OP_RETCONST: {
duk_tval *tv;
DUK__SYNC_AND_NULL_CURR_PC();
tv = DUK__CONSTP_BC(ins);
DUK_TVAL_SET_TVAL(thr->valstack_top, tv);
DUK_TVAL_INCREF(thr, tv);
thr->valstack_top++;
DUK__RETURN_SHARED();
}
case DUK_OP_RETCONSTN: {
duk_tval *tv;
DUK__SYNC_AND_NULL_CURR_PC();
tv = DUK__CONSTP_BC(ins);
DUK_TVAL_SET_TVAL(thr->valstack_top, tv);
#if defined(DUK_USE_REFERENCE_COUNTING)
/* Without refcounting only RETCONSTN is used. */
DUK_ASSERT(!DUK_TVAL_IS_HEAP_ALLOCATED(tv)); /* no INCREF for this constant */
#endif
thr->valstack_top++;
DUK__RETURN_SHARED();
}
case DUK_OP_RETUNDEF: {
DUK__SYNC_AND_NULL_CURR_PC();
thr->valstack_top++; /* value at valstack top is already undefined by valstack policy */
DUK_ASSERT(DUK_TVAL_IS_UNDEFINED(thr->valstack_top));
DUK__RETURN_SHARED();
}
#endif /* DUK_USE_EXEC_PREFER_SIZE */
case DUK_OP_LABEL: {
duk_activation *act;
duk_catcher *cat;
duk_small_uint_fast_t bc = DUK_DEC_BC(ins);
/* Allocate catcher and populate it (must be atomic). */
cat = duk_hthread_catcher_alloc(thr);
DUK_ASSERT(cat != NULL);
cat->flags = (duk_uint32_t) (DUK_CAT_TYPE_LABEL | (bc << DUK_CAT_LABEL_SHIFT));
cat->pc_base = (duk_instr_t *) curr_pc; /* pre-incremented, points to first jump slot */
cat->idx_base = 0; /* unused for label */
cat->h_varname = NULL;
act = thr->callstack_curr;
DUK_ASSERT(act != NULL);
cat->parent = act->cat;
act->cat = cat;
DUK_DDD(DUK_DDDPRINT("LABEL catcher: flags=0x%08lx, pc_base=%ld, "
"idx_base=%ld, h_varname=%!O, label_id=%ld",
(long) cat->flags, (long) cat->pc_base,
(long) cat->idx_base, (duk_heaphdr *) cat->h_varname, (long) DUK_CAT_GET_LABEL(cat)));
curr_pc += 2; /* skip jump slots */
break;
}
case DUK_OP_ENDLABEL: {
duk_activation *act;
#if (defined(DUK_USE_DEBUG_LEVEL) && (DUK_USE_DEBUG_LEVEL >= 2)) || defined(DUK_USE_ASSERTIONS)
duk_small_uint_fast_t bc = DUK_DEC_BC(ins);
#endif
#if defined(DUK_USE_DEBUG_LEVEL) && (DUK_USE_DEBUG_LEVEL >= 2)
DUK_DDD(DUK_DDDPRINT("ENDLABEL %ld", (long) bc));
#endif
act = thr->callstack_curr;
DUK_ASSERT(act->cat != NULL);
DUK_ASSERT(DUK_CAT_GET_TYPE(act->cat) == DUK_CAT_TYPE_LABEL);
DUK_ASSERT((duk_uint_fast_t) DUK_CAT_GET_LABEL(act->cat) == bc);
duk_hthread_catcher_unwind_nolexenv_norz(thr, act);
/* no need to unwind callstack */
break;
}
case DUK_OP_BREAK: {
duk_small_uint_fast_t bc = DUK_DEC_BC(ins);
DUK__SYNC_AND_NULL_CURR_PC();
duk__handle_break_or_continue(thr, (duk_uint_t) bc, DUK_LJ_TYPE_BREAK);
goto restart_execution;
}
case DUK_OP_CONTINUE: {
duk_small_uint_fast_t bc = DUK_DEC_BC(ins);
DUK__SYNC_AND_NULL_CURR_PC();
duk__handle_break_or_continue(thr, (duk_uint_t) bc, DUK_LJ_TYPE_CONTINUE);
goto restart_execution;
}
/* XXX: move to helper, too large to be inline here */
case DUK_OP_TRYCATCH: {
duk__handle_op_trycatch(thr, ins, curr_pc);
curr_pc += 2; /* skip jump slots */
break;
}
case DUK_OP_ENDTRY: {
curr_pc = duk__handle_op_endtry(thr, ins);
break;
}
case DUK_OP_ENDCATCH: {
duk__handle_op_endcatch(thr, ins);
break;
}
case DUK_OP_ENDFIN: {
/* Sync and NULL early. */
DUK__SYNC_AND_NULL_CURR_PC();
if (duk__handle_op_endfin(thr, ins, entry_act) != 0) {
return;
}
/* Must restart because we NULLed out curr_pc. */
goto restart_execution;
}
case DUK_OP_THROW: {
duk_small_uint_fast_t bc = DUK_DEC_BC(ins);
/* Note: errors are augmented when they are created, not
* when they are thrown. So, don't augment here, it would
* break re-throwing for instance.
*/
/* Sync so that augmentation sees up-to-date activations, NULL
* thr->ptr_curr_pc so that it's not used if side effects occur
* in augmentation or longjmp handling.
*/
DUK__SYNC_AND_NULL_CURR_PC();
duk_dup(thr, (duk_idx_t) bc);
DUK_DDD(DUK_DDDPRINT("THROW ERROR (BYTECODE): %!dT (before throw augment)",
(duk_tval *) duk_get_tval(thr, -1)));
#if defined(DUK_USE_AUGMENT_ERROR_THROW)
duk_err_augment_error_throw(thr);
DUK_DDD(DUK_DDDPRINT("THROW ERROR (BYTECODE): %!dT (after throw augment)",
(duk_tval *) duk_get_tval(thr, -1)));
#endif
duk_err_setup_ljstate1(thr, DUK_LJ_TYPE_THROW, DUK_GET_TVAL_NEGIDX(thr, -1));
#if defined(DUK_USE_DEBUGGER_SUPPORT)
duk_err_check_debugger_integration(thr);
#endif
DUK_ASSERT(thr->heap->lj.jmpbuf_ptr != NULL); /* always in executor */
duk_err_longjmp(thr);
DUK_UNREACHABLE();
break;
}
case DUK_OP_CSREG: {
/*
* Assuming a register binds to a variable declared within this
* function (a declarative binding), the 'this' for the call
* setup is always 'undefined'. E5 Section 10.2.1.1.6.
*/
duk_small_uint_fast_t a = DUK_DEC_A(ins);
duk_small_uint_fast_t bc = DUK_DEC_BC(ins);
/* A -> register containing target function (not type checked here)
* BC -> target registers (BC, BC + 1) for call setup
*/
#if defined(DUK_USE_PREFER_SIZE)
duk_dup(thr, (duk_idx_t) a);
duk_replace(thr, (duk_idx_t) bc);
duk_to_undefined(thr, (duk_idx_t) (bc + 1));
#else
duk_tval *tv1;
duk_tval *tv2;
duk_tval *tv3;
duk_tval tv_tmp1;
duk_tval tv_tmp2;
tv1 = DUK__REGP(bc);
tv2 = tv1 + 1;
DUK_TVAL_SET_TVAL(&tv_tmp1, tv1);
DUK_TVAL_SET_TVAL(&tv_tmp2, tv2);
tv3 = DUK__REGP(a);
DUK_TVAL_SET_TVAL(tv1, tv3);
DUK_TVAL_INCREF(thr, tv1); /* no side effects */
DUK_TVAL_SET_UNDEFINED(tv2); /* no need for incref */
DUK_TVAL_DECREF(thr, &tv_tmp1);
DUK_TVAL_DECREF(thr, &tv_tmp2);
#endif
break;
}
/* XXX: in some cases it's faster NOT to reuse the value
* stack but rather copy the arguments on top of the stack
* (mainly when the calling value stack is large and the value
* stack resize would be large).
*/
case DUK_OP_CALL0:
case DUK_OP_CALL1:
case DUK_OP_CALL2:
case DUK_OP_CALL3:
case DUK_OP_CALL4:
case DUK_OP_CALL5:
case DUK_OP_CALL6:
case DUK_OP_CALL7: {
/* Opcode packs 4 flag bits: 1 for indirect, 3 map
* 1:1 to three lowest call handling flags.
*
* A -> nargs or register with nargs (indirect)
* BC -> base register for call (base -> func, base+1 -> this, base+2 -> arg1 ... base+2+N-1 -> argN)
*/
duk_idx_t nargs;
duk_idx_t idx;
duk_small_uint_t call_flags;
#if !defined(DUK_USE_EXEC_FUN_LOCAL)
duk_hcompfunc *fun;
#endif
DUK_ASSERT((DUK_OP_CALL0 & 0x0fU) == 0);
DUK_ASSERT((ins & DUK_BC_CALL_FLAG_INDIRECT) == 0);
nargs = (duk_idx_t) DUK_DEC_A(ins);
call_flags = (ins & 0x07U) | DUK_CALL_FLAG_ALLOW_ECMATOECMA;
idx = (duk_idx_t) DUK_DEC_BC(ins);
if (duk__executor_handle_call(thr, idx, nargs, call_flags)) {
/* curr_pc synced by duk_handle_call_unprotected() */
DUK_ASSERT(thr->ptr_curr_pc == NULL);
goto restart_execution;
}
DUK_ASSERT(thr->ptr_curr_pc != NULL);
/* duk_js_call.c is required to restore the stack reserve
* so we only need to reset the top.
*/
#if !defined(DUK_USE_EXEC_FUN_LOCAL)
fun = DUK__FUN();
#endif
duk_set_top_unsafe(thr, (duk_idx_t) fun->nregs);
/* No need to reinit setjmp() catchpoint, as call handling
* will store and restore our state.
*
* When debugger is enabled, we need to recheck the activation
* status after returning. This is now handled by call handling
* and heap->dbg_force_restart.
*/
break;
}
case DUK_OP_CALL8:
case DUK_OP_CALL9:
case DUK_OP_CALL10:
case DUK_OP_CALL11:
case DUK_OP_CALL12:
case DUK_OP_CALL13:
case DUK_OP_CALL14:
case DUK_OP_CALL15: {
/* Indirect variant. */
duk_uint_fast_t nargs;
duk_idx_t idx;
duk_small_uint_t call_flags;
#if !defined(DUK_USE_EXEC_FUN_LOCAL)
duk_hcompfunc *fun;
#endif
DUK_ASSERT((DUK_OP_CALL0 & 0x0fU) == 0);
DUK_ASSERT((ins & DUK_BC_CALL_FLAG_INDIRECT) != 0);
nargs = (duk_uint_fast_t) DUK_DEC_A(ins);
DUK__LOOKUP_INDIRECT(nargs);
call_flags = (ins & 0x07U) | DUK_CALL_FLAG_ALLOW_ECMATOECMA;
idx = (duk_idx_t) DUK_DEC_BC(ins);
if (duk__executor_handle_call(thr, idx, (duk_idx_t) nargs, call_flags)) {
DUK_ASSERT(thr->ptr_curr_pc == NULL);
goto restart_execution;
}
DUK_ASSERT(thr->ptr_curr_pc != NULL);
#if !defined(DUK_USE_EXEC_FUN_LOCAL)
fun = DUK__FUN();
#endif
duk_set_top_unsafe(thr, (duk_idx_t) fun->nregs);
break;
}
case DUK_OP_NEWOBJ: {
duk_push_object(thr);
#if defined(DUK_USE_ASSERTIONS)
{
duk_hobject *h;
h = duk_require_hobject(thr, -1);
DUK_ASSERT(DUK_HOBJECT_GET_ESIZE(h) == 0);
DUK_ASSERT(DUK_HOBJECT_GET_ENEXT(h) == 0);
DUK_ASSERT(DUK_HOBJECT_GET_ASIZE(h) == 0);
DUK_ASSERT(DUK_HOBJECT_GET_HSIZE(h) == 0);
}
#endif
#if !defined(DUK_USE_PREFER_SIZE)
/* XXX: could do a direct props realloc, but need hash size */
duk_hobject_resize_entrypart(thr, duk_known_hobject(thr, -1), DUK_DEC_A(ins));
#endif
DUK__REPLACE_TOP_BC_BREAK();
}
case DUK_OP_NEWARR: {
duk_push_array(thr);
#if defined(DUK_USE_ASSERTIONS)
{
duk_hobject *h;
h = duk_require_hobject(thr, -1);
DUK_ASSERT(DUK_HOBJECT_GET_ESIZE(h) == 0);
DUK_ASSERT(DUK_HOBJECT_GET_ENEXT(h) == 0);
DUK_ASSERT(DUK_HOBJECT_GET_ASIZE(h) == 0);
DUK_ASSERT(DUK_HOBJECT_GET_HSIZE(h) == 0);
DUK_ASSERT(DUK_HOBJECT_HAS_ARRAY_PART(h));
}
#endif
#if !defined(DUK_USE_PREFER_SIZE)
duk_hobject_realloc_props(thr,
duk_known_hobject(thr, -1),
0 /*new_e_size*/,
DUK_DEC_A(ins) /*new_a_size*/,
0 /*new_h_size*/,
0 /*abandon_array*/);
#if 0
duk_hobject_resize_arraypart(thr, duk_known_hobject(thr, -1), DUK_DEC_A(ins));
#endif
#endif
DUK__REPLACE_TOP_BC_BREAK();
}
case DUK_OP_MPUTOBJ:
case DUK_OP_MPUTOBJI: {
duk_idx_t obj_idx;
duk_uint_fast_t idx, idx_end;
duk_small_uint_fast_t count;
/* A -> register of target object
* B -> first register of key/value pair list
* or register containing first register number if indirect
* C -> number of key/value pairs * 2
* (= number of value stack indices used starting from 'B')
*/
obj_idx = DUK_DEC_A(ins);
DUK_ASSERT(duk_is_object(thr, obj_idx));
idx = (duk_uint_fast_t) DUK_DEC_B(ins);
if (DUK_DEC_OP(ins) == DUK_OP_MPUTOBJI) {
DUK__LOOKUP_INDIRECT(idx);
}
count = (duk_small_uint_fast_t) DUK_DEC_C(ins);
DUK_ASSERT(count > 0); /* compiler guarantees */
idx_end = idx + count;
#if defined(DUK_USE_EXEC_INDIRECT_BOUND_CHECK)
if (DUK_UNLIKELY(idx_end > (duk_uint_fast_t) duk_get_top(thr))) {
/* XXX: use duk_is_valid_index() instead? */
/* XXX: improve check; check against nregs, not against top */
DUK__INTERNAL_ERROR("MPUTOBJ out of bounds");
}
#endif
/* Use 'force' flag to duk_def_prop() to ensure that any
* inherited properties don't prevent the operation.
* With ES2015 duplicate properties are allowed, so that we
* must overwrite any previous data or accessor property.
*
* With ES2015 computed property names the literal keys
* may be arbitrary values and need to be ToPropertyKey()
* coerced at runtime.
*/
do {
/* XXX: faster initialization (direct access or better primitives) */
duk_dup(thr, (duk_idx_t) idx);
duk_dup(thr, (duk_idx_t) (idx + 1));
duk_def_prop(thr, obj_idx, DUK_DEFPROP_HAVE_VALUE |
DUK_DEFPROP_FORCE |
DUK_DEFPROP_SET_WRITABLE |
DUK_DEFPROP_SET_ENUMERABLE |
DUK_DEFPROP_SET_CONFIGURABLE);
idx += 2;
} while (idx < idx_end);
break;
}
case DUK_OP_INITSET:
case DUK_OP_INITGET: {
duk__handle_op_initset_initget(thr, ins);
break;
}
case DUK_OP_MPUTARR:
case DUK_OP_MPUTARRI: {
duk_idx_t obj_idx;
duk_uint_fast_t idx, idx_end;
duk_small_uint_fast_t count;
duk_tval *tv1;
duk_uint32_t arr_idx;
/* A -> register of target object
* B -> first register of value data (start_index, value1, value2, ..., valueN)
* or register containing first register number if indirect
* C -> number of key/value pairs (N)
*/
obj_idx = DUK_DEC_A(ins);
DUK_ASSERT(duk_is_object(thr, obj_idx));
idx = (duk_uint_fast_t) DUK_DEC_B(ins);
if (DUK_DEC_OP(ins) == DUK_OP_MPUTARRI) {
DUK__LOOKUP_INDIRECT(idx);
}
count = (duk_small_uint_fast_t) DUK_DEC_C(ins);
DUK_ASSERT(count > 0 + 1); /* compiler guarantees */
idx_end = idx + count;
#if defined(DUK_USE_EXEC_INDIRECT_BOUND_CHECK)
if (idx_end > (duk_uint_fast_t) duk_get_top(thr)) {
/* XXX: use duk_is_valid_index() instead? */
/* XXX: improve check; check against nregs, not against top */
DUK__INTERNAL_ERROR("MPUTARR out of bounds");
}
#endif
tv1 = DUK__REGP(idx);
DUK_ASSERT(DUK_TVAL_IS_NUMBER(tv1));
#if defined(DUK_USE_FASTINT)
DUK_ASSERT(DUK_TVAL_IS_FASTINT(tv1));
arr_idx = (duk_uint32_t) DUK_TVAL_GET_FASTINT_U32(tv1);
#else
arr_idx = (duk_uint32_t) DUK_TVAL_GET_NUMBER(tv1);
#endif
idx++;
do {
/* duk_xdef_prop() will define an own property without any array
* special behaviors. We'll need to set the array length explicitly
* in the end. For arrays with elisions, the compiler will emit an
* explicit SETALEN which will update the length.
*/
/* XXX: because we're dealing with 'own' properties of a fresh array,
* the array initializer should just ensure that the array has a large
* enough array part and write the values directly into array part,
* and finally set 'length' manually in the end (as already happens now).
*/
duk_dup(thr, (duk_idx_t) idx);
duk_xdef_prop_index_wec(thr, obj_idx, arr_idx);
idx++;
arr_idx++;
} while (idx < idx_end);
/* XXX: E5.1 Section 11.1.4 coerces the final length through
* ToUint32() which is odd but happens now as a side effect of
* 'arr_idx' type.
*/
duk_set_length(thr, obj_idx, (duk_size_t) (duk_uarridx_t) arr_idx);
break;
}
case DUK_OP_SETALEN: {
duk_tval *tv1;
duk_hobject *h;
duk_uint32_t len;
tv1 = DUK__REGP_A(ins);
DUK_ASSERT(DUK_TVAL_IS_OBJECT(tv1));
h = DUK_TVAL_GET_OBJECT(tv1);
DUK_ASSERT(DUK_HOBJECT_IS_ARRAY(h));
tv1 = DUK__REGP_BC(ins);
DUK_ASSERT(DUK_TVAL_IS_NUMBER(tv1));
#if defined(DUK_USE_FASTINT)
DUK_ASSERT(DUK_TVAL_IS_FASTINT(tv1));
len = (duk_uint32_t) DUK_TVAL_GET_FASTINT_U32(tv1);
#else
len = (duk_uint32_t) DUK_TVAL_GET_NUMBER(tv1);
#endif
((duk_harray *) h)->length = len;
break;
}
case DUK_OP_INITENUM: {
duk__handle_op_initenum(thr, ins);
break;
}
case DUK_OP_NEXTENUM: {
curr_pc += duk__handle_op_nextenum(thr, ins);
break;
}
case DUK_OP_INVLHS: {
DUK_ERROR_REFERENCE(thr, DUK_STR_INVALID_LVALUE);
DUK_WO_NORETURN(return;);
break;
}
case DUK_OP_DEBUGGER: {
/* Opcode only emitted by compiler when debugger
* support is enabled. Ignore it silently without
* debugger support, in case it has been loaded
* from precompiled bytecode.
*/
#if defined(DUK_USE_DEBUGGER_SUPPORT)
if (duk_debug_is_attached(thr->heap)) {
DUK_D(DUK_DPRINT("DEBUGGER statement encountered, halt execution"));
DUK__SYNC_AND_NULL_CURR_PC();
duk_debug_halt_execution(thr, 1 /*use_prev_pc*/);
DUK_D(DUK_DPRINT("DEBUGGER statement finished, resume execution"));
goto restart_execution;
} else {
DUK_D(DUK_DPRINT("DEBUGGER statement ignored, debugger not attached"));
}
#else
DUK_D(DUK_DPRINT("DEBUGGER statement ignored, no debugger support"));
#endif
break;
}
case DUK_OP_NOP: {
/* Nop, ignored, but ABC fields may carry a value e.g.
* for indirect opcode handling.
*/
break;
}
case DUK_OP_INVALID: {
DUK_ERROR_FMT1(thr, DUK_ERR_ERROR, "INVALID opcode (%ld)", (long) DUK_DEC_ABC(ins));
DUK_WO_NORETURN(return;);
break;
}
#if defined(DUK_USE_ES6)
case DUK_OP_NEWTARGET: {
duk_push_new_target(thr);
DUK__REPLACE_TOP_BC_BREAK();
}
#endif /* DUK_USE_ES6 */
#if !defined(DUK_USE_EXEC_PREFER_SIZE)
#if !defined(DUK_USE_ES7_EXP_OPERATOR)
case DUK_OP_EXP_RR:
case DUK_OP_EXP_CR:
case DUK_OP_EXP_RC:
case DUK_OP_EXP_CC:
#endif
#if !defined(DUK_USE_ES6)
case DUK_OP_NEWTARGET:
#endif
#if !defined(DUK_USE_VERBOSE_ERRORS)
case DUK_OP_GETPROPC_RR:
case DUK_OP_GETPROPC_CR:
case DUK_OP_GETPROPC_RC:
case DUK_OP_GETPROPC_CC:
#endif
case DUK_OP_UNUSED207:
case DUK_OP_UNUSED212:
case DUK_OP_UNUSED213:
case DUK_OP_UNUSED214:
case DUK_OP_UNUSED215:
case DUK_OP_UNUSED216:
case DUK_OP_UNUSED217:
case DUK_OP_UNUSED218:
case DUK_OP_UNUSED219:
case DUK_OP_UNUSED220:
case DUK_OP_UNUSED221:
case DUK_OP_UNUSED222:
case DUK_OP_UNUSED223:
case DUK_OP_UNUSED224:
case DUK_OP_UNUSED225:
case DUK_OP_UNUSED226:
case DUK_OP_UNUSED227:
case DUK_OP_UNUSED228:
case DUK_OP_UNUSED229:
case DUK_OP_UNUSED230:
case DUK_OP_UNUSED231:
case DUK_OP_UNUSED232:
case DUK_OP_UNUSED233:
case DUK_OP_UNUSED234:
case DUK_OP_UNUSED235:
case DUK_OP_UNUSED236:
case DUK_OP_UNUSED237:
case DUK_OP_UNUSED238:
case DUK_OP_UNUSED239:
case DUK_OP_UNUSED240:
case DUK_OP_UNUSED241:
case DUK_OP_UNUSED242:
case DUK_OP_UNUSED243:
case DUK_OP_UNUSED244:
case DUK_OP_UNUSED245:
case DUK_OP_UNUSED246:
case DUK_OP_UNUSED247:
case DUK_OP_UNUSED248:
case DUK_OP_UNUSED249:
case DUK_OP_UNUSED250:
case DUK_OP_UNUSED251:
case DUK_OP_UNUSED252:
case DUK_OP_UNUSED253:
case DUK_OP_UNUSED254:
case DUK_OP_UNUSED255:
/* Force all case clauses to map to an actual handler
* so that the compiler can emit a jump without a bounds
* check: the switch argument is a duk_uint8_t so that
* the compiler may be able to figure it out. This is
* a small detail and obviously compiler dependent.
*/
/* default: clause omitted on purpose */
#else /* DUK_USE_EXEC_PREFER_SIZE */
default:
#endif /* DUK_USE_EXEC_PREFER_SIZE */
{
/* Default case catches invalid/unsupported opcodes. */
DUK_D(DUK_DPRINT("invalid opcode: %ld - %!I", (long) op, ins));
DUK__INTERNAL_ERROR("invalid opcode");
break;
}
} /* end switch */
continue;
/* Some shared exit paths for opcode handling below. These
* are mostly useful to reduce code footprint when multiple
* opcodes have a similar epilogue (like replacing stack top
* with index 'a').
*/
#if defined(DUK_USE_EXEC_PREFER_SIZE)
replace_top_a:
DUK__REPLACE_TO_TVPTR(thr, DUK__REGP_A(ins));
continue;
replace_top_bc:
DUK__REPLACE_TO_TVPTR(thr, DUK__REGP_BC(ins));
continue;
#endif
}
DUK_WO_NORETURN(return;);
#if !defined(DUK_USE_VERBOSE_EXECUTOR_ERRORS)
internal_error:
DUK_ERROR_INTERNAL(thr);
DUK_WO_NORETURN(return;);
#endif
}
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