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RetroZilla/js/src/jsemit.c
Ryan Nematz 2f2ae146c0 first commit
2015-10-20 23:03:22 -04:00

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/* -*- Mode: C; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
* vim: set ts=8 sw=4 et tw=78:
*
* ***** BEGIN LICENSE BLOCK *****
* Version: MPL 1.1/GPL 2.0/LGPL 2.1
*
* The contents of this file are subject to the Mozilla Public License Version
* 1.1 (the "License"); you may not use this file except in compliance with
* the License. You may obtain a copy of the License at
* http://www.mozilla.org/MPL/
*
* Software distributed under the License is distributed on an "AS IS" basis,
* WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
* for the specific language governing rights and limitations under the
* License.
*
* The Original Code is Mozilla Communicator client code, released
* March 31, 1998.
*
* The Initial Developer of the Original Code is
* Netscape Communications Corporation.
* Portions created by the Initial Developer are Copyright (C) 1998
* the Initial Developer. All Rights Reserved.
*
* Contributor(s):
*
* Alternatively, the contents of this file may be used under the terms of
* either of the GNU General Public License Version 2 or later (the "GPL"),
* or the GNU Lesser General Public License Version 2.1 or later (the "LGPL"),
* in which case the provisions of the GPL or the LGPL are applicable instead
* of those above. If you wish to allow use of your version of this file only
* under the terms of either the GPL or the LGPL, and not to allow others to
* use your version of this file under the terms of the MPL, indicate your
* decision by deleting the provisions above and replace them with the notice
* and other provisions required by the GPL or the LGPL. If you do not delete
* the provisions above, a recipient may use your version of this file under
* the terms of any one of the MPL, the GPL or the LGPL.
*
* ***** END LICENSE BLOCK ***** */
/*
* JS bytecode generation.
*/
#include "jsstddef.h"
#ifdef HAVE_MEMORY_H
#include <memory.h>
#endif
#include <string.h>
#include "jstypes.h"
#include "jsarena.h" /* Added by JSIFY */
#include "jsutil.h" /* Added by JSIFY */
#include "jsbit.h"
#include "jsprf.h"
#include "jsapi.h"
#include "jsatom.h"
#include "jscntxt.h"
#include "jsconfig.h"
#include "jsemit.h"
#include "jsfun.h"
#include "jsnum.h"
#include "jsopcode.h"
#include "jsparse.h"
#include "jsregexp.h"
#include "jsscan.h"
#include "jsscope.h"
#include "jsscript.h"
/* Allocation chunk counts, must be powers of two in general. */
#define BYTECODE_CHUNK 256 /* code allocation increment */
#define SRCNOTE_CHUNK 64 /* initial srcnote allocation increment */
#define TRYNOTE_CHUNK 64 /* trynote allocation increment */
/* Macros to compute byte sizes from typed element counts. */
#define BYTECODE_SIZE(n) ((n) * sizeof(jsbytecode))
#define SRCNOTE_SIZE(n) ((n) * sizeof(jssrcnote))
#define TRYNOTE_SIZE(n) ((n) * sizeof(JSTryNote))
JS_FRIEND_API(JSBool)
js_InitCodeGenerator(JSContext *cx, JSCodeGenerator *cg,
JSArenaPool *codePool, JSArenaPool *notePool,
const char *filename, uintN lineno,
JSPrincipals *principals)
{
memset(cg, 0, sizeof *cg);
TREE_CONTEXT_INIT(&cg->treeContext);
cg->treeContext.flags |= TCF_COMPILING;
cg->codePool = codePool;
cg->notePool = notePool;
cg->codeMark = JS_ARENA_MARK(codePool);
cg->noteMark = JS_ARENA_MARK(notePool);
cg->tempMark = JS_ARENA_MARK(&cx->tempPool);
cg->current = &cg->main;
cg->filename = filename;
cg->firstLine = cg->prolog.currentLine = cg->main.currentLine = lineno;
cg->principals = principals;
ATOM_LIST_INIT(&cg->atomList);
cg->prolog.noteMask = cg->main.noteMask = SRCNOTE_CHUNK - 1;
ATOM_LIST_INIT(&cg->constList);
return JS_TRUE;
}
JS_FRIEND_API(void)
js_FinishCodeGenerator(JSContext *cx, JSCodeGenerator *cg)
{
TREE_CONTEXT_FINISH(&cg->treeContext);
JS_ARENA_RELEASE(cg->codePool, cg->codeMark);
JS_ARENA_RELEASE(cg->notePool, cg->noteMark);
JS_ARENA_RELEASE(&cx->tempPool, cg->tempMark);
}
static ptrdiff_t
EmitCheck(JSContext *cx, JSCodeGenerator *cg, JSOp op, ptrdiff_t delta)
{
jsbytecode *base, *limit, *next;
ptrdiff_t offset, length;
size_t incr, size;
base = CG_BASE(cg);
next = CG_NEXT(cg);
limit = CG_LIMIT(cg);
offset = PTRDIFF(next, base, jsbytecode);
if (next + delta > limit) {
length = offset + delta;
length = (length <= BYTECODE_CHUNK)
? BYTECODE_CHUNK
: JS_BIT(JS_CeilingLog2(length));
incr = BYTECODE_SIZE(length);
if (!base) {
JS_ARENA_ALLOCATE_CAST(base, jsbytecode *, cg->codePool, incr);
} else {
size = BYTECODE_SIZE(PTRDIFF(limit, base, jsbytecode));
incr -= size;
JS_ARENA_GROW_CAST(base, jsbytecode *, cg->codePool, size, incr);
}
if (!base) {
JS_ReportOutOfMemory(cx);
return -1;
}
CG_BASE(cg) = base;
CG_LIMIT(cg) = base + length;
CG_NEXT(cg) = base + offset;
}
return offset;
}
static void
UpdateDepth(JSContext *cx, JSCodeGenerator *cg, ptrdiff_t target)
{
jsbytecode *pc;
const JSCodeSpec *cs;
intN nuses;
pc = CG_CODE(cg, target);
cs = &js_CodeSpec[pc[0]];
nuses = cs->nuses;
if (nuses < 0)
nuses = 2 + GET_ARGC(pc); /* stack: fun, this, [argc arguments] */
cg->stackDepth -= nuses;
JS_ASSERT(cg->stackDepth >= 0);
if (cg->stackDepth < 0) {
char numBuf[12];
JS_snprintf(numBuf, sizeof numBuf, "%d", target);
JS_ReportErrorFlagsAndNumber(cx, JSREPORT_WARNING,
js_GetErrorMessage, NULL,
JSMSG_STACK_UNDERFLOW,
cg->filename ? cg->filename : "stdin",
numBuf);
}
cg->stackDepth += cs->ndefs;
if ((uintN)cg->stackDepth > cg->maxStackDepth)
cg->maxStackDepth = cg->stackDepth;
}
ptrdiff_t
js_Emit1(JSContext *cx, JSCodeGenerator *cg, JSOp op)
{
ptrdiff_t offset = EmitCheck(cx, cg, op, 1);
if (offset >= 0) {
*CG_NEXT(cg)++ = (jsbytecode)op;
UpdateDepth(cx, cg, offset);
}
return offset;
}
ptrdiff_t
js_Emit2(JSContext *cx, JSCodeGenerator *cg, JSOp op, jsbytecode op1)
{
ptrdiff_t offset = EmitCheck(cx, cg, op, 2);
if (offset >= 0) {
jsbytecode *next = CG_NEXT(cg);
next[0] = (jsbytecode)op;
next[1] = op1;
CG_NEXT(cg) = next + 2;
UpdateDepth(cx, cg, offset);
}
return offset;
}
ptrdiff_t
js_Emit3(JSContext *cx, JSCodeGenerator *cg, JSOp op, jsbytecode op1,
jsbytecode op2)
{
ptrdiff_t offset = EmitCheck(cx, cg, op, 3);
if (offset >= 0) {
jsbytecode *next = CG_NEXT(cg);
next[0] = (jsbytecode)op;
next[1] = op1;
next[2] = op2;
CG_NEXT(cg) = next + 3;
UpdateDepth(cx, cg, offset);
}
return offset;
}
ptrdiff_t
js_EmitN(JSContext *cx, JSCodeGenerator *cg, JSOp op, size_t extra)
{
ptrdiff_t length = 1 + (ptrdiff_t)extra;
ptrdiff_t offset = EmitCheck(cx, cg, op, length);
if (offset >= 0) {
jsbytecode *next = CG_NEXT(cg);
*next = (jsbytecode)op;
memset(next + 1, 0, BYTECODE_SIZE(extra));
CG_NEXT(cg) = next + length;
UpdateDepth(cx, cg, offset);
}
return offset;
}
/* XXX too many "... statement" L10N gaffes below -- fix via js.msg! */
const char js_with_statement_str[] = "with statement";
const char js_finally_block_str[] = "finally block";
const char js_script_str[] = "script";
static const char *statementName[] = {
"label statement", /* LABEL */
"if statement", /* IF */
"else statement", /* ELSE */
"switch statement", /* SWITCH */
"block", /* BLOCK */
js_with_statement_str, /* WITH */
"catch block", /* CATCH */
"try block", /* TRY */
js_finally_block_str, /* FINALLY */
js_finally_block_str, /* SUBROUTINE */
"do loop", /* DO_LOOP */
"for loop", /* FOR_LOOP */
"for/in loop", /* FOR_IN_LOOP */
"while loop", /* WHILE_LOOP */
};
static const char *
StatementName(JSCodeGenerator *cg)
{
if (!cg->treeContext.topStmt)
return js_script_str;
return statementName[cg->treeContext.topStmt->type];
}
static void
ReportStatementTooLarge(JSContext *cx, JSCodeGenerator *cg)
{
JS_ReportErrorNumber(cx, js_GetErrorMessage, NULL, JSMSG_NEED_DIET,
StatementName(cg));
}
/**
Span-dependent instructions in JS bytecode consist of the jump (JOF_JUMP)
and switch (JOF_LOOKUPSWITCH, JOF_TABLESWITCH) format opcodes, subdivided
into unconditional (gotos and gosubs), and conditional jumps or branches
(which pop a value, test it, and jump depending on its value). Most jumps
have just one immediate operand, a signed offset from the jump opcode's pc
to the target bytecode. The lookup and table switch opcodes may contain
many jump offsets.
Mozilla bug #80981 (http://bugzilla.mozilla.org/show_bug.cgi?id=80981) was
fixed by adding extended "X" counterparts to the opcodes/formats (NB: X is
suffixed to prefer JSOP_ORX thereby avoiding a JSOP_XOR name collision for
the extended form of the JSOP_OR branch opcode). The unextended or short
formats have 16-bit signed immediate offset operands, the extended or long
formats have 32-bit signed immediates. The span-dependency problem consists
of selecting as few long instructions as possible, or about as few -- since
jumps can span other jumps, extending one jump may cause another to need to
be extended.
Most JS scripts are short, so need no extended jumps. We optimize for this
case by generating short jumps until we know a long jump is needed. After
that point, we keep generating short jumps, but each jump's 16-bit immediate
offset operand is actually an unsigned index into cg->spanDeps, an array of
JSSpanDep structs. Each struct tells the top offset in the script of the
opcode, the "before" offset of the jump (which will be the same as top for
simplex jumps, but which will index further into the bytecode array for a
non-initial jump offset in a lookup or table switch), the after "offset"
adjusted during span-dependent instruction selection (initially the same
value as the "before" offset), and the jump target (more below).
Since we generate cg->spanDeps lazily, from within js_SetJumpOffset, we must
ensure that all bytecode generated so far can be inspected to discover where
the jump offset immediate operands lie within CG_CODE(cg). But the bonus is
that we generate span-dependency records sorted by their offsets, so we can
binary-search when trying to find a JSSpanDep for a given bytecode offset,
or the nearest JSSpanDep at or above a given pc.
To avoid limiting scripts to 64K jumps, if the cg->spanDeps index overflows
65534, we store SPANDEP_INDEX_HUGE in the jump's immediate operand. This
tells us that we need to binary-search for the cg->spanDeps entry by the
jump opcode's bytecode offset (sd->before).
Jump targets need to be maintained in a data structure that lets us look
up an already-known target by its address (jumps may have a common target),
and that also lets us update the addresses (script-relative, a.k.a. absolute
offsets) of targets that come after a jump target (for when a jump below
that target needs to be extended). We use an AVL tree, implemented using
recursion, but with some tricky optimizations to its height-balancing code
(see http://www.cmcrossroads.com/bradapp/ftp/src/libs/C++/AvlTrees.html).
A final wrinkle: backpatch chains are linked by jump-to-jump offsets with
positive sign, even though they link "backward" (i.e., toward lower bytecode
address). We don't want to waste space and search time in the AVL tree for
such temporary backpatch deltas, so we use a single-bit wildcard scheme to
tag true JSJumpTarget pointers and encode untagged, signed (positive) deltas
in JSSpanDep.target pointers, depending on whether the JSSpanDep has a known
target, or is still awaiting backpatching.
Note that backpatch chains would present a problem for BuildSpanDepTable,
which inspects bytecode to build cg->spanDeps on demand, when the first
short jump offset overflows. To solve this temporary problem, we emit a
proxy bytecode (JSOP_BACKPATCH; JSOP_BACKPATCH_POP for branch ops) whose
nuses/ndefs counts help keep the stack balanced, but whose opcode format
distinguishes its backpatch delta immediate operand from a normal jump
offset.
*/
static int
BalanceJumpTargets(JSJumpTarget **jtp)
{
JSJumpTarget *jt, *jt2, *root;
int dir, otherDir, heightChanged;
JSBool doubleRotate;
jt = *jtp;
JS_ASSERT(jt->balance != 0);
if (jt->balance < -1) {
dir = JT_RIGHT;
doubleRotate = (jt->kids[JT_LEFT]->balance > 0);
} else if (jt->balance > 1) {
dir = JT_LEFT;
doubleRotate = (jt->kids[JT_RIGHT]->balance < 0);
} else {
return 0;
}
otherDir = JT_OTHER_DIR(dir);
if (doubleRotate) {
jt2 = jt->kids[otherDir];
*jtp = root = jt2->kids[dir];
jt->kids[otherDir] = root->kids[dir];
root->kids[dir] = jt;
jt2->kids[dir] = root->kids[otherDir];
root->kids[otherDir] = jt2;
heightChanged = 1;
root->kids[JT_LEFT]->balance = -JS_MAX(root->balance, 0);
root->kids[JT_RIGHT]->balance = -JS_MIN(root->balance, 0);
root->balance = 0;
} else {
*jtp = root = jt->kids[otherDir];
jt->kids[otherDir] = root->kids[dir];
root->kids[dir] = jt;
heightChanged = (root->balance != 0);
jt->balance = -((dir == JT_LEFT) ? --root->balance : ++root->balance);
}
return heightChanged;
}
typedef struct AddJumpTargetArgs {
JSContext *cx;
JSCodeGenerator *cg;
ptrdiff_t offset;
JSJumpTarget *node;
} AddJumpTargetArgs;
static int
AddJumpTarget(AddJumpTargetArgs *args, JSJumpTarget **jtp)
{
JSJumpTarget *jt;
int balanceDelta;
jt = *jtp;
if (!jt) {
JSCodeGenerator *cg = args->cg;
jt = cg->jtFreeList;
if (jt) {
cg->jtFreeList = jt->kids[JT_LEFT];
} else {
JS_ARENA_ALLOCATE_CAST(jt, JSJumpTarget *, &args->cx->tempPool,
sizeof *jt);
if (!jt) {
JS_ReportOutOfMemory(args->cx);
return 0;
}
}
jt->offset = args->offset;
jt->balance = 0;
jt->kids[JT_LEFT] = jt->kids[JT_RIGHT] = NULL;
cg->numJumpTargets++;
args->node = jt;
*jtp = jt;
return 1;
}
if (jt->offset == args->offset) {
args->node = jt;
return 0;
}
if (args->offset < jt->offset)
balanceDelta = -AddJumpTarget(args, &jt->kids[JT_LEFT]);
else
balanceDelta = AddJumpTarget(args, &jt->kids[JT_RIGHT]);
if (!args->node)
return 0;
jt->balance += balanceDelta;
return (balanceDelta && jt->balance)
? 1 - BalanceJumpTargets(jtp)
: 0;
}
#ifdef DEBUG_brendan
static int AVLCheck(JSJumpTarget *jt)
{
int lh, rh;
if (!jt) return 0;
JS_ASSERT(-1 <= jt->balance && jt->balance <= 1);
lh = AVLCheck(jt->kids[JT_LEFT]);
rh = AVLCheck(jt->kids[JT_RIGHT]);
JS_ASSERT(jt->balance == rh - lh);
return 1 + JS_MAX(lh, rh);
}
#endif
static JSBool
SetSpanDepTarget(JSContext *cx, JSCodeGenerator *cg, JSSpanDep *sd,
ptrdiff_t off)
{
AddJumpTargetArgs args;
if (off < JUMPX_OFFSET_MIN || JUMPX_OFFSET_MAX < off) {
ReportStatementTooLarge(cx, cg);
return JS_FALSE;
}
args.cx = cx;
args.cg = cg;
args.offset = sd->top + off;
args.node = NULL;
AddJumpTarget(&args, &cg->jumpTargets);
if (!args.node)
return JS_FALSE;
#ifdef DEBUG_brendan
AVLCheck(cg->jumpTargets);
#endif
SD_SET_TARGET(sd, args.node);
return JS_TRUE;
}
#define SPANDEPS_MIN 256
#define SPANDEPS_SIZE(n) ((n) * sizeof(JSSpanDep))
#define SPANDEPS_SIZE_MIN SPANDEPS_SIZE(SPANDEPS_MIN)
static JSBool
AddSpanDep(JSContext *cx, JSCodeGenerator *cg, jsbytecode *pc, jsbytecode *pc2,
ptrdiff_t off)
{
uintN index;
JSSpanDep *sdbase, *sd;
size_t size;
index = cg->numSpanDeps;
if (index + 1 == 0) {
ReportStatementTooLarge(cx, cg);
return JS_FALSE;
}
if ((index & (index - 1)) == 0 &&
(!(sdbase = cg->spanDeps) || index >= SPANDEPS_MIN)) {
if (!sdbase) {
size = SPANDEPS_SIZE_MIN;
JS_ARENA_ALLOCATE_CAST(sdbase, JSSpanDep *, &cx->tempPool, size);
} else {
size = SPANDEPS_SIZE(index);
JS_ARENA_GROW_CAST(sdbase, JSSpanDep *, &cx->tempPool, size, size);
}
if (!sdbase)
return JS_FALSE;
cg->spanDeps = sdbase;
}
cg->numSpanDeps = index + 1;
sd = cg->spanDeps + index;
sd->top = PTRDIFF(pc, CG_BASE(cg), jsbytecode);
sd->offset = sd->before = PTRDIFF(pc2, CG_BASE(cg), jsbytecode);
if (js_CodeSpec[*pc].format & JOF_BACKPATCH) {
/* Jump offset will be backpatched if off is a non-zero "bpdelta". */
if (off != 0) {
JS_ASSERT(off >= 1 + JUMP_OFFSET_LEN);
if (off > BPDELTA_MAX) {
ReportStatementTooLarge(cx, cg);
return JS_FALSE;
}
}
SD_SET_BPDELTA(sd, off);
} else if (off == 0) {
/* Jump offset will be patched directly, without backpatch chaining. */
SD_SET_TARGET(sd, NULL);
} else {
/* The jump offset in off is non-zero, therefore it's already known. */
if (!SetSpanDepTarget(cx, cg, sd, off))
return JS_FALSE;
}
if (index > SPANDEP_INDEX_MAX)
index = SPANDEP_INDEX_HUGE;
SET_SPANDEP_INDEX(pc2, index);
return JS_TRUE;
}
static jsbytecode *
AddSwitchSpanDeps(JSContext *cx, JSCodeGenerator *cg, jsbytecode *pc)
{
JSOp op;
jsbytecode *pc2;
ptrdiff_t off;
jsint low, high;
uintN njumps, indexlen;
op = (JSOp) *pc;
JS_ASSERT(op == JSOP_TABLESWITCH || op == JSOP_LOOKUPSWITCH);
pc2 = pc;
off = GET_JUMP_OFFSET(pc2);
if (!AddSpanDep(cx, cg, pc, pc2, off))
return NULL;
pc2 += JUMP_OFFSET_LEN;
if (op == JSOP_TABLESWITCH) {
low = GET_JUMP_OFFSET(pc2);
pc2 += JUMP_OFFSET_LEN;
high = GET_JUMP_OFFSET(pc2);
pc2 += JUMP_OFFSET_LEN;
njumps = (uintN) (high - low + 1);
indexlen = 0;
} else {
njumps = GET_UINT16(pc2);
pc2 += JUMP_OFFSET_LEN;
indexlen = ATOM_INDEX_LEN;
}
while (njumps) {
--njumps;
pc2 += indexlen;
off = GET_JUMP_OFFSET(pc2);
if (!AddSpanDep(cx, cg, pc, pc2, off))
return NULL;
pc2 += JUMP_OFFSET_LEN;
}
return 1 + pc2;
}
static JSBool
BuildSpanDepTable(JSContext *cx, JSCodeGenerator *cg)
{
jsbytecode *pc, *end;
JSOp op;
const JSCodeSpec *cs;
ptrdiff_t off;
pc = CG_BASE(cg) + cg->spanDepTodo;
end = CG_NEXT(cg);
while (pc != end) {
JS_ASSERT(pc < end);
op = (JSOp)*pc;
cs = &js_CodeSpec[op];
switch (cs->format & JOF_TYPEMASK) {
case JOF_TABLESWITCH:
case JOF_LOOKUPSWITCH:
pc = AddSwitchSpanDeps(cx, cg, pc);
if (!pc)
return JS_FALSE;
break;
case JOF_JUMP:
off = GET_JUMP_OFFSET(pc);
if (!AddSpanDep(cx, cg, pc, pc, off))
return JS_FALSE;
/* FALL THROUGH */
default:
pc += cs->length;
break;
}
}
return JS_TRUE;
}
static JSSpanDep *
GetSpanDep(JSCodeGenerator *cg, jsbytecode *pc)
{
uintN index;
ptrdiff_t offset;
int lo, hi, mid;
JSSpanDep *sd;
index = GET_SPANDEP_INDEX(pc);
if (index != SPANDEP_INDEX_HUGE)
return cg->spanDeps + index;
offset = PTRDIFF(pc, CG_BASE(cg), jsbytecode);
lo = 0;
hi = cg->numSpanDeps - 1;
while (lo <= hi) {
mid = (lo + hi) / 2;
sd = cg->spanDeps + mid;
if (sd->before == offset)
return sd;
if (sd->before < offset)
lo = mid + 1;
else
hi = mid - 1;
}
JS_ASSERT(0);
return NULL;
}
static JSBool
SetBackPatchDelta(JSContext *cx, JSCodeGenerator *cg, jsbytecode *pc,
ptrdiff_t delta)
{
JSSpanDep *sd;
JS_ASSERT(delta >= 1 + JUMP_OFFSET_LEN);
if (!cg->spanDeps && delta < JUMP_OFFSET_MAX) {
SET_JUMP_OFFSET(pc, delta);
return JS_TRUE;
}
if (delta > BPDELTA_MAX) {
ReportStatementTooLarge(cx, cg);
return JS_FALSE;
}
if (!cg->spanDeps && !BuildSpanDepTable(cx, cg))
return JS_FALSE;
sd = GetSpanDep(cg, pc);
JS_ASSERT(SD_GET_BPDELTA(sd) == 0);
SD_SET_BPDELTA(sd, delta);
return JS_TRUE;
}
static void
UpdateJumpTargets(JSJumpTarget *jt, ptrdiff_t pivot, ptrdiff_t delta)
{
if (jt->offset > pivot) {
jt->offset += delta;
if (jt->kids[JT_LEFT])
UpdateJumpTargets(jt->kids[JT_LEFT], pivot, delta);
}
if (jt->kids[JT_RIGHT])
UpdateJumpTargets(jt->kids[JT_RIGHT], pivot, delta);
}
static JSSpanDep *
FindNearestSpanDep(JSCodeGenerator *cg, ptrdiff_t offset, int lo,
JSSpanDep *guard)
{
int num, hi, mid;
JSSpanDep *sdbase, *sd;
num = cg->numSpanDeps;
JS_ASSERT(num > 0);
hi = num - 1;
sdbase = cg->spanDeps;
while (lo <= hi) {
mid = (lo + hi) / 2;
sd = sdbase + mid;
if (sd->before == offset)
return sd;
if (sd->before < offset)
lo = mid + 1;
else
hi = mid - 1;
}
if (lo == num)
return guard;
sd = sdbase + lo;
JS_ASSERT(sd->before >= offset && (lo == 0 || sd[-1].before < offset));
return sd;
}
static void
FreeJumpTargets(JSCodeGenerator *cg, JSJumpTarget *jt)
{
if (jt->kids[JT_LEFT])
FreeJumpTargets(cg, jt->kids[JT_LEFT]);
if (jt->kids[JT_RIGHT])
FreeJumpTargets(cg, jt->kids[JT_RIGHT]);
jt->kids[JT_LEFT] = cg->jtFreeList;
cg->jtFreeList = jt;
}
static JSBool
OptimizeSpanDeps(JSContext *cx, JSCodeGenerator *cg)
{
jsbytecode *pc, *oldpc, *base, *limit, *next;
JSSpanDep *sd, *sd2, *sdbase, *sdlimit, *sdtop, guard;
ptrdiff_t offset, growth, delta, top, pivot, span, length, target;
JSBool done;
JSOp op;
uint32 type;
size_t size, incr;
jssrcnote *sn, *snlimit;
JSSrcNoteSpec *spec;
uintN i, n, noteIndex;
JSTryNote *tn, *tnlimit;
#ifdef DEBUG_brendan
int passes = 0;
#endif
base = CG_BASE(cg);
sdbase = cg->spanDeps;
sdlimit = sdbase + cg->numSpanDeps;
offset = CG_OFFSET(cg);
growth = 0;
do {
done = JS_TRUE;
delta = 0;
top = pivot = -1;
sdtop = NULL;
pc = NULL;
op = JSOP_NOP;
type = 0;
#ifdef DEBUG_brendan
passes++;
#endif
for (sd = sdbase; sd < sdlimit; sd++) {
JS_ASSERT(JT_HAS_TAG(sd->target));
sd->offset += delta;
if (sd->top != top) {
sdtop = sd;
top = sd->top;
JS_ASSERT(top == sd->before);
pivot = sd->offset;
pc = base + top;
op = (JSOp) *pc;
type = (js_CodeSpec[op].format & JOF_TYPEMASK);
if (JOF_TYPE_IS_EXTENDED_JUMP(type)) {
/*
* We already extended all the jump offset operands for
* the opcode at sd->top. Jumps and branches have only
* one jump offset operand, but switches have many, all
* of which are adjacent in cg->spanDeps.
*/
continue;
}
JS_ASSERT(type == JOF_JUMP ||
type == JOF_TABLESWITCH ||
type == JOF_LOOKUPSWITCH);
}
if (!JOF_TYPE_IS_EXTENDED_JUMP(type)) {
span = SD_SPAN(sd, pivot);
if (span < JUMP_OFFSET_MIN || JUMP_OFFSET_MAX < span) {
ptrdiff_t deltaFromTop = 0;
done = JS_FALSE;
switch (op) {
case JSOP_GOTO: op = JSOP_GOTOX; break;
case JSOP_IFEQ: op = JSOP_IFEQX; break;
case JSOP_IFNE: op = JSOP_IFNEX; break;
case JSOP_OR: op = JSOP_ORX; break;
case JSOP_AND: op = JSOP_ANDX; break;
case JSOP_GOSUB: op = JSOP_GOSUBX; break;
case JSOP_CASE: op = JSOP_CASEX; break;
case JSOP_DEFAULT: op = JSOP_DEFAULTX; break;
case JSOP_TABLESWITCH: op = JSOP_TABLESWITCHX; break;
case JSOP_LOOKUPSWITCH: op = JSOP_LOOKUPSWITCHX; break;
default:
ReportStatementTooLarge(cx, cg);
return JS_FALSE;
}
*pc = (jsbytecode) op;
for (sd2 = sdtop; sd2 < sdlimit && sd2->top == top; sd2++) {
if (sd2 <= sd) {
/*
* sd2->offset already includes delta as it stood
* before we entered this loop, but it must also
* include the delta relative to top due to all the
* extended jump offset immediates for the opcode
* starting at top, which we extend in this loop.
*
* If there is only one extended jump offset, then
* sd2->offset won't change and this for loop will
* iterate once only.
*/
sd2->offset += deltaFromTop;
deltaFromTop += JUMPX_OFFSET_LEN - JUMP_OFFSET_LEN;
} else {
/*
* sd2 comes after sd, and won't be revisited by
* the outer for loop, so we have to increase its
* offset by delta, not merely by deltaFromTop.
*/
sd2->offset += delta;
}
delta += JUMPX_OFFSET_LEN - JUMP_OFFSET_LEN;
UpdateJumpTargets(cg->jumpTargets, sd2->offset,
JUMPX_OFFSET_LEN - JUMP_OFFSET_LEN);
}
sd = sd2 - 1;
}
}
}
growth += delta;
} while (!done);
if (growth) {
#ifdef DEBUG_brendan
printf("%s:%u: %u/%u jumps extended in %d passes (%d=%d+%d)\n",
cg->filename ? cg->filename : "stdin", cg->firstLine,
growth / (JUMPX_OFFSET_LEN - JUMP_OFFSET_LEN), cg->numSpanDeps,
passes, offset + growth, offset, growth);
#endif
/*
* Ensure that we have room for the extended jumps, but don't round up
* to a power of two -- we're done generating code, so we cut to fit.
*/
limit = CG_LIMIT(cg);
length = offset + growth;
next = base + length;
if (next > limit) {
JS_ASSERT(length > BYTECODE_CHUNK);
size = BYTECODE_SIZE(PTRDIFF(limit, base, jsbytecode));
incr = BYTECODE_SIZE(length) - size;
JS_ARENA_GROW_CAST(base, jsbytecode *, cg->codePool, size, incr);
if (!base) {
JS_ReportOutOfMemory(cx);
return JS_FALSE;
}
CG_BASE(cg) = base;
CG_LIMIT(cg) = next = base + length;
}
CG_NEXT(cg) = next;
/*
* Set up a fake span dependency record to guard the end of the code
* being generated. This guard record is returned as a fencepost by
* FindNearestSpanDep if there is no real spandep at or above a given
* unextended code offset.
*/
guard.top = -1;
guard.offset = offset + growth;
guard.before = offset;
guard.target = NULL;
}
/*
* Now work backwards through the span dependencies, copying chunks of
* bytecode between each extended jump toward the end of the grown code
* space, and restoring immediate offset operands for all jump bytecodes.
* The first chunk of bytecodes, starting at base and ending at the first
* extended jump offset (NB: this chunk includes the operation bytecode
* just before that immediate jump offset), doesn't need to be copied.
*/
JS_ASSERT(sd == sdlimit);
top = -1;
while (--sd >= sdbase) {
if (sd->top != top) {
top = sd->top;
op = (JSOp) base[top];
type = (js_CodeSpec[op].format & JOF_TYPEMASK);
for (sd2 = sd - 1; sd2 >= sdbase && sd2->top == top; sd2--)
continue;
sd2++;
pivot = sd2->offset;
JS_ASSERT(top == sd2->before);
}
oldpc = base + sd->before;
span = SD_SPAN(sd, pivot);
/*
* If this jump didn't need to be extended, restore its span immediate
* offset operand now, overwriting the index of sd within cg->spanDeps
* that was stored temporarily after *pc when BuildSpanDepTable ran.
*
* Note that span might fit in 16 bits even for an extended jump op,
* if the op has multiple span operands, not all of which overflowed
* (e.g. JSOP_LOOKUPSWITCH or JSOP_TABLESWITCH where some cases are in
* range for a short jump, but others are not).
*/
if (!JOF_TYPE_IS_EXTENDED_JUMP(type)) {
JS_ASSERT(JUMP_OFFSET_MIN <= span && span <= JUMP_OFFSET_MAX);
SET_JUMP_OFFSET(oldpc, span);
continue;
}
/*
* Set up parameters needed to copy the next run of bytecode starting
* at offset (which is a cursor into the unextended, original bytecode
* vector), down to sd->before (a cursor of the same scale as offset,
* it's the index of the original jump pc). Reuse delta to count the
* nominal number of bytes to copy.
*/
pc = base + sd->offset;
delta = offset - sd->before;
JS_ASSERT(delta >= 1 + JUMP_OFFSET_LEN);
/*
* Don't bother copying the jump offset we're about to reset, but do
* copy the bytecode at oldpc (which comes just before its immediate
* jump offset operand), on the next iteration through the loop, by
* including it in offset's new value.
*/
offset = sd->before + 1;
size = BYTECODE_SIZE(delta - (1 + JUMP_OFFSET_LEN));
if (size) {
memmove(pc + 1 + JUMPX_OFFSET_LEN,
oldpc + 1 + JUMP_OFFSET_LEN,
size);
}
SET_JUMPX_OFFSET(pc, span);
}
if (growth) {
/*
* Fix source note deltas. Don't hardwire the delta fixup adjustment,
* even though currently it must be JUMPX_OFFSET_LEN - JUMP_OFFSET_LEN
* at each sd that moved. The future may bring different offset sizes
* for span-dependent instruction operands. However, we fix only main
* notes here, not prolog notes -- we know that prolog opcodes are not
* span-dependent, and aren't likely ever to be.
*/
offset = growth = 0;
sd = sdbase;
for (sn = cg->main.notes, snlimit = sn + cg->main.noteCount;
sn < snlimit;
sn = SN_NEXT(sn)) {
/*
* Recall that the offset of a given note includes its delta, and
* tells the offset of the annotated bytecode from the main entry
* point of the script.
*/
offset += SN_DELTA(sn);
while (sd < sdlimit && sd->before < offset) {
/*
* To compute the delta to add to sn, we need to look at the
* spandep after sd, whose offset - (before + growth) tells by
* how many bytes sd's instruction grew.
*/
sd2 = sd + 1;
if (sd2 == sdlimit)
sd2 = &guard;
delta = sd2->offset - (sd2->before + growth);
if (delta > 0) {
JS_ASSERT(delta == JUMPX_OFFSET_LEN - JUMP_OFFSET_LEN);
sn = js_AddToSrcNoteDelta(cx, cg, sn, delta);
if (!sn)
return JS_FALSE;
snlimit = cg->main.notes + cg->main.noteCount;
growth += delta;
}
sd++;
}
/*
* If sn has span-dependent offset operands, check whether each
* covers further span-dependencies, and increase those operands
* accordingly. Some source notes measure offset not from the
* annotated pc, but from that pc plus some small bias. NB: we
* assume that spec->offsetBias can't itself span span-dependent
* instructions!
*/
spec = &js_SrcNoteSpec[SN_TYPE(sn)];
if (spec->isSpanDep) {
pivot = offset + spec->offsetBias;
n = spec->arity;
for (i = 0; i < n; i++) {
span = js_GetSrcNoteOffset(sn, i);
if (span == 0)
continue;
target = pivot + span * spec->isSpanDep;
sd2 = FindNearestSpanDep(cg, target,
(target >= pivot)
? sd - sdbase
: 0,
&guard);
/*
* Increase target by sd2's before-vs-after offset delta,
* which is absolute (i.e., relative to start of script,
* as is target). Recompute the span by subtracting its
* adjusted pivot from target.
*/
target += sd2->offset - sd2->before;
span = target - (pivot + growth);
span *= spec->isSpanDep;
noteIndex = sn - cg->main.notes;
if (!js_SetSrcNoteOffset(cx, cg, noteIndex, i, span))
return JS_FALSE;
sn = cg->main.notes + noteIndex;
snlimit = cg->main.notes + cg->main.noteCount;
}
}
}
cg->main.lastNoteOffset += growth;
/*
* Fix try/catch notes (O(numTryNotes * log2(numSpanDeps)), but it's
* not clear how we can beat that).
*/
for (tn = cg->tryBase, tnlimit = cg->tryNext; tn < tnlimit; tn++) {
/*
* First, look for the nearest span dependency at/above tn->start.
* There may not be any such spandep, in which case the guard will
* be returned.
*/
offset = tn->start;
sd = FindNearestSpanDep(cg, offset, 0, &guard);
delta = sd->offset - sd->before;
tn->start = offset + delta;
/*
* Next, find the nearest spandep at/above tn->start + tn->length.
* Use its delta minus tn->start's delta to increase tn->length.
*/
length = tn->length;
sd2 = FindNearestSpanDep(cg, offset + length, sd - sdbase, &guard);
if (sd2 != sd)
tn->length = length + sd2->offset - sd2->before - delta;
/*
* Finally, adjust tn->catchStart upward only if it is non-zero,
* and provided there are spandeps below it that grew.
*/
offset = tn->catchStart;
if (offset != 0) {
sd = FindNearestSpanDep(cg, offset, sd2 - sdbase, &guard);
tn->catchStart = offset + sd->offset - sd->before;
}
}
}
#ifdef DEBUG_brendan
{
uintN bigspans = 0;
top = -1;
for (sd = sdbase; sd < sdlimit; sd++) {
offset = sd->offset;
/* NB: sd->top cursors into the original, unextended bytecode vector. */
if (sd->top != top) {
JS_ASSERT(top == -1 ||
!JOF_TYPE_IS_EXTENDED_JUMP(type) ||
bigspans != 0);
bigspans = 0;
top = sd->top;
JS_ASSERT(top == sd->before);
op = (JSOp) base[offset];
type = (js_CodeSpec[op].format & JOF_TYPEMASK);
JS_ASSERT(type == JOF_JUMP ||
type == JOF_JUMPX ||
type == JOF_TABLESWITCH ||
type == JOF_TABLESWITCHX ||
type == JOF_LOOKUPSWITCH ||
type == JOF_LOOKUPSWITCHX);
pivot = offset;
}
pc = base + offset;
if (JOF_TYPE_IS_EXTENDED_JUMP(type)) {
span = GET_JUMPX_OFFSET(pc);
if (span < JUMP_OFFSET_MIN || JUMP_OFFSET_MAX < span) {
bigspans++;
} else {
JS_ASSERT(type == JOF_TABLESWITCHX ||
type == JOF_LOOKUPSWITCHX);
}
} else {
span = GET_JUMP_OFFSET(pc);
}
JS_ASSERT(SD_SPAN(sd, pivot) == span);
}
JS_ASSERT(!JOF_TYPE_IS_EXTENDED_JUMP(type) || bigspans != 0);
}
#endif
/*
* Reset so we optimize at most once -- cg may be used for further code
* generation of successive, independent, top-level statements. No jump
* can span top-level statements, because JS lacks goto.
*/
size = SPANDEPS_SIZE(JS_BIT(JS_CeilingLog2(cg->numSpanDeps)));
JS_ArenaFreeAllocation(&cx->tempPool, cg->spanDeps,
JS_MAX(size, SPANDEPS_SIZE_MIN));
cg->spanDeps = NULL;
FreeJumpTargets(cg, cg->jumpTargets);
cg->jumpTargets = NULL;
cg->numSpanDeps = cg->numJumpTargets = 0;
cg->spanDepTodo = CG_OFFSET(cg);
return JS_TRUE;
}
static JSBool
EmitJump(JSContext *cx, JSCodeGenerator *cg, JSOp op, ptrdiff_t off)
{
JSBool extend;
ptrdiff_t jmp;
jsbytecode *pc;
extend = off < JUMP_OFFSET_MIN || JUMP_OFFSET_MAX < off;
if (extend && !cg->spanDeps && !BuildSpanDepTable(cx, cg))
return JS_FALSE;
jmp = js_Emit3(cx, cg, op, JUMP_OFFSET_HI(off), JUMP_OFFSET_LO(off));
if (jmp >= 0 && (extend || cg->spanDeps)) {
pc = CG_CODE(cg, jmp);
if (!AddSpanDep(cx, cg, pc, pc, off))
return JS_FALSE;
}
return jmp;
}
static ptrdiff_t
GetJumpOffset(JSCodeGenerator *cg, jsbytecode *pc)
{
JSSpanDep *sd;
JSJumpTarget *jt;
ptrdiff_t top;
if (!cg->spanDeps)
return GET_JUMP_OFFSET(pc);
sd = GetSpanDep(cg, pc);
jt = sd->target;
if (!JT_HAS_TAG(jt))
return JT_TO_BPDELTA(jt);
top = sd->top;
while (--sd >= cg->spanDeps && sd->top == top)
continue;
sd++;
return JT_CLR_TAG(jt)->offset - sd->offset;
}
JSBool
js_SetJumpOffset(JSContext *cx, JSCodeGenerator *cg, jsbytecode *pc,
ptrdiff_t off)
{
if (!cg->spanDeps) {
if (JUMP_OFFSET_MIN <= off && off <= JUMP_OFFSET_MAX) {
SET_JUMP_OFFSET(pc, off);
return JS_TRUE;
}
if (!BuildSpanDepTable(cx, cg))
return JS_FALSE;
}
return SetSpanDepTarget(cx, cg, GetSpanDep(cg, pc), off);
}
JSBool
js_InStatement(JSTreeContext *tc, JSStmtType type)
{
JSStmtInfo *stmt;
for (stmt = tc->topStmt; stmt; stmt = stmt->down) {
if (stmt->type == type)
return JS_TRUE;
}
return JS_FALSE;
}
JSBool
js_IsGlobalReference(JSTreeContext *tc, JSAtom *atom, JSBool *loopyp)
{
JSStmtInfo *stmt;
JSObject *obj;
JSScope *scope;
*loopyp = JS_FALSE;
for (stmt = tc->topStmt; stmt; stmt = stmt->down) {
if (stmt->type == STMT_WITH)
return JS_FALSE;
if (STMT_IS_LOOP(stmt)) {
*loopyp = JS_TRUE;
continue;
}
if (stmt->flags & SIF_SCOPE) {
obj = ATOM_TO_OBJECT(stmt->atom);
JS_ASSERT(LOCKED_OBJ_GET_CLASS(obj) == &js_BlockClass);
scope = OBJ_SCOPE(obj);
if (SCOPE_GET_PROPERTY(scope, ATOM_TO_JSID(atom)))
return JS_FALSE;
}
}
return JS_TRUE;
}
void
js_PushStatement(JSTreeContext *tc, JSStmtInfo *stmt, JSStmtType type,
ptrdiff_t top)
{
stmt->type = type;
stmt->flags = 0;
SET_STATEMENT_TOP(stmt, top);
stmt->atom = NULL;
stmt->down = tc->topStmt;
tc->topStmt = stmt;
if (STMT_LINKS_SCOPE(stmt)) {
stmt->downScope = tc->topScopeStmt;
tc->topScopeStmt = stmt;
} else {
stmt->downScope = NULL;
}
}
void
js_PushBlockScope(JSTreeContext *tc, JSStmtInfo *stmt, JSAtom *blockAtom,
ptrdiff_t top)
{
JSObject *blockObj;
js_PushStatement(tc, stmt, STMT_BLOCK, top);
stmt->flags |= SIF_SCOPE;
blockObj = ATOM_TO_OBJECT(blockAtom);
blockObj->slots[JSSLOT_PARENT] = OBJECT_TO_JSVAL(tc->blockChain);
stmt->downScope = tc->topScopeStmt;
tc->topScopeStmt = stmt;
tc->blockChain = blockObj;
stmt->atom = blockAtom;
}
/*
* Emit a backpatch op with offset pointing to the previous jump of this type,
* so that we can walk back up the chain fixing up the op and jump offset.
*/
static ptrdiff_t
EmitBackPatchOp(JSContext *cx, JSCodeGenerator *cg, JSOp op, ptrdiff_t *lastp)
{
ptrdiff_t offset, delta;
offset = CG_OFFSET(cg);
delta = offset - *lastp;
*lastp = offset;
JS_ASSERT(delta > 0);
return EmitJump(cx, cg, op, delta);
}
/*
* Macro to emit a bytecode followed by a uint16 immediate operand stored in
* big-endian order, used for arg and var numbers as well as for atomIndexes.
* NB: We use cx and cg from our caller's lexical environment, and return
* false on error.
*/
#define EMIT_UINT16_IMM_OP(op, i) \
JS_BEGIN_MACRO \
if (js_Emit3(cx, cg, op, UINT16_HI(i), UINT16_LO(i)) < 0) \
return JS_FALSE; \
JS_END_MACRO
/* Emit additional bytecode(s) for non-local jumps. */
static JSBool
EmitNonLocalJumpFixup(JSContext *cx, JSCodeGenerator *cg, JSStmtInfo *toStmt,
JSOp *returnop)
{
intN depth;
JSStmtInfo *stmt;
ptrdiff_t jmp;
/*
* Return from within a try block that has a finally clause must be split
* into two ops: JSOP_SETRVAL, to pop the r.v. and store it in fp->rval;
* and JSOP_RETRVAL, which makes control flow go back to the caller, who
* picks up fp->rval as usual. Otherwise, the stack will be unbalanced
* when executing the finally clause.
*
* We mutate *returnop once only if we find an enclosing try-block (viz,
* STMT_FINALLY) to ensure that we emit just one JSOP_SETRVAL before one
* or more JSOP_GOSUBs and other fixup opcodes emitted by this function.
* Our caller (the TOK_RETURN case of js_EmitTree) then emits *returnop.
* The fixup opcodes and gosubs must interleave in the proper order, from
* inner statement to outer, so that finally clauses run at the correct
* stack depth.
*/
if (returnop) {
JS_ASSERT(*returnop == JSOP_RETURN);
for (stmt = cg->treeContext.topStmt; stmt != toStmt;
stmt = stmt->down) {
if (stmt->type == STMT_FINALLY ||
((cg->treeContext.flags & TCF_FUN_HEAVYWEIGHT) &&
STMT_MAYBE_SCOPE(stmt))) {
if (js_Emit1(cx, cg, JSOP_SETRVAL) < 0)
return JS_FALSE;
*returnop = JSOP_RETRVAL;
break;
}
}
/*
* If there are no try-with-finally blocks open around this return
* statement, we can generate a return forthwith and skip generating
* any fixup code.
*/
if (*returnop == JSOP_RETURN)
return JS_TRUE;
}
/*
* The non-local jump fixup we emit will unbalance cg->stackDepth, because
* the fixup replicates balanced code such as JSOP_LEAVEWITH emitted at the
* end of a with statement, so we save cg->stackDepth here and restore it
* just before a successful return.
*/
depth = cg->stackDepth;
for (stmt = cg->treeContext.topStmt; stmt != toStmt; stmt = stmt->down) {
switch (stmt->type) {
case STMT_FINALLY:
if (js_NewSrcNote(cx, cg, SRC_HIDDEN) < 0)
return JS_FALSE;
jmp = EmitBackPatchOp(cx, cg, JSOP_BACKPATCH, &GOSUBS(*stmt));
if (jmp < 0)
return JS_FALSE;
break;
case STMT_WITH:
/* There's a With object on the stack that we need to pop. */
if (js_NewSrcNote(cx, cg, SRC_HIDDEN) < 0)
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_LEAVEWITH) < 0)
return JS_FALSE;
break;
case STMT_FOR_IN_LOOP:
/*
* The iterator and the object being iterated need to be popped.
*/
if (js_NewSrcNote(cx, cg, SRC_HIDDEN) < 0)
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_ENDITER) < 0)
return JS_FALSE;
break;
case STMT_SUBROUTINE:
/*
* There's a [exception or hole, retsub pc-index] pair on the
* stack that we need to pop.
*/
if (js_NewSrcNote(cx, cg, SRC_HIDDEN) < 0)
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_POP2) < 0)
return JS_FALSE;
break;
default:;
}
if (stmt->flags & SIF_SCOPE) {
uintN i;
/* There is a Block object with locals on the stack to pop. */
if (js_NewSrcNote(cx, cg, SRC_HIDDEN) < 0)
return JS_FALSE;
i = OBJ_BLOCK_COUNT(cx, ATOM_TO_OBJECT(stmt->atom));
EMIT_UINT16_IMM_OP(JSOP_LEAVEBLOCK, i);
}
}
cg->stackDepth = depth;
return JS_TRUE;
}
static ptrdiff_t
EmitGoto(JSContext *cx, JSCodeGenerator *cg, JSStmtInfo *toStmt,
ptrdiff_t *lastp, JSAtomListElement *label, JSSrcNoteType noteType)
{
intN index;
if (!EmitNonLocalJumpFixup(cx, cg, toStmt, NULL))
return -1;
if (label)
index = js_NewSrcNote2(cx, cg, noteType, (ptrdiff_t) ALE_INDEX(label));
else if (noteType != SRC_NULL)
index = js_NewSrcNote(cx, cg, noteType);
else
index = 0;
if (index < 0)
return -1;
return EmitBackPatchOp(cx, cg, JSOP_BACKPATCH, lastp);
}
static JSBool
BackPatch(JSContext *cx, JSCodeGenerator *cg, ptrdiff_t last,
jsbytecode *target, jsbytecode op)
{
jsbytecode *pc, *stop;
ptrdiff_t delta, span;
pc = CG_CODE(cg, last);
stop = CG_CODE(cg, -1);
while (pc != stop) {
delta = GetJumpOffset(cg, pc);
span = PTRDIFF(target, pc, jsbytecode);
CHECK_AND_SET_JUMP_OFFSET(cx, cg, pc, span);
/*
* Set *pc after jump offset in case bpdelta didn't overflow, but span
* does (if so, CHECK_AND_SET_JUMP_OFFSET might call BuildSpanDepTable
* and need to see the JSOP_BACKPATCH* op at *pc).
*/
*pc = op;
pc -= delta;
}
return JS_TRUE;
}
void
js_PopStatement(JSTreeContext *tc)
{
JSStmtInfo *stmt;
JSObject *blockObj;
stmt = tc->topStmt;
tc->topStmt = stmt->down;
if (STMT_LINKS_SCOPE(stmt)) {
tc->topScopeStmt = stmt->downScope;
if (stmt->flags & SIF_SCOPE) {
blockObj = ATOM_TO_OBJECT(stmt->atom);
tc->blockChain = JSVAL_TO_OBJECT(blockObj->slots[JSSLOT_PARENT]);
}
}
}
JSBool
js_PopStatementCG(JSContext *cx, JSCodeGenerator *cg)
{
JSStmtInfo *stmt;
stmt = cg->treeContext.topStmt;
if (!STMT_IS_TRYING(stmt) &&
(!BackPatch(cx, cg, stmt->breaks, CG_NEXT(cg), JSOP_GOTO) ||
!BackPatch(cx, cg, stmt->continues, CG_CODE(cg, stmt->update),
JSOP_GOTO))) {
return JS_FALSE;
}
js_PopStatement(&cg->treeContext);
return JS_TRUE;
}
JSBool
js_DefineCompileTimeConstant(JSContext *cx, JSCodeGenerator *cg, JSAtom *atom,
JSParseNode *pn)
{
jsdouble dval;
jsint ival;
JSAtom *valueAtom;
JSAtomListElement *ale;
/* XXX just do numbers for now */
if (pn->pn_type == TOK_NUMBER) {
dval = pn->pn_dval;
valueAtom = (JSDOUBLE_IS_INT(dval, ival) && INT_FITS_IN_JSVAL(ival))
? js_AtomizeInt(cx, ival, 0)
: js_AtomizeDouble(cx, dval, 0);
if (!valueAtom)
return JS_FALSE;
ale = js_IndexAtom(cx, atom, &cg->constList);
if (!ale)
return JS_FALSE;
ALE_SET_VALUE(ale, ATOM_KEY(valueAtom));
}
return JS_TRUE;
}
JSStmtInfo *
js_LexicalLookup(JSTreeContext *tc, JSAtom *atom, jsint *slotp, JSBool letdecl)
{
JSStmtInfo *stmt;
JSObject *obj;
JSScope *scope;
JSScopeProperty *sprop;
jsval v;
for (stmt = tc->topScopeStmt; stmt; stmt = stmt->downScope) {
if (stmt->type == STMT_WITH) {
/* Ignore with statements enclosing a single let declaration. */
if (letdecl)
continue;
break;
}
/* Skip "maybe scope" statements that don't contain let bindings. */
if (!(stmt->flags & SIF_SCOPE))
continue;
obj = ATOM_TO_OBJECT(stmt->atom);
JS_ASSERT(LOCKED_OBJ_GET_CLASS(obj) == &js_BlockClass);
scope = OBJ_SCOPE(obj);
sprop = SCOPE_GET_PROPERTY(scope, ATOM_TO_JSID(atom));
if (sprop) {
JS_ASSERT(sprop->flags & SPROP_HAS_SHORTID);
if (slotp) {
/*
* Use LOCKED_OBJ_GET_SLOT since we know obj is single-
* threaded and owned by this compiler activation.
*/
v = LOCKED_OBJ_GET_SLOT(obj, JSSLOT_BLOCK_DEPTH);
JS_ASSERT(JSVAL_IS_INT(v) && JSVAL_TO_INT(v) >= 0);
*slotp = JSVAL_TO_INT(v) + sprop->shortid;
}
return stmt;
}
}
if (slotp)
*slotp = -1;
return stmt;
}
JSBool
js_LookupCompileTimeConstant(JSContext *cx, JSCodeGenerator *cg, JSAtom *atom,
jsval *vp)
{
JSBool ok;
JSStackFrame *fp;
JSStmtInfo *stmt;
jsint slot;
JSAtomListElement *ale;
JSObject *obj, *pobj;
JSProperty *prop;
uintN attrs;
/*
* fp chases cg down the stack, but only until we reach the outermost cg.
* This enables propagating consts from top-level into switch cases in a
* function compiled along with the top-level script. All stack frames
* with matching code generators should be flagged with JSFRAME_COMPILING;
* we check sanity here.
*/
*vp = JSVAL_VOID;
ok = JS_TRUE;
fp = cx->fp;
do {
JS_ASSERT(fp->flags & JSFRAME_COMPILING);
obj = fp->varobj;
if (obj == fp->scopeChain) {
/* XXX this will need revising when 'let const' is added. */
stmt = js_LexicalLookup(&cg->treeContext, atom, &slot, JS_FALSE);
if (stmt)
return JS_TRUE;
ATOM_LIST_SEARCH(ale, &cg->constList, atom);
if (ale) {
*vp = ALE_VALUE(ale);
return JS_TRUE;
}
/*
* Try looking in the variable object for a direct property that
* is readonly and permanent. We know such a property can't be
* shadowed by another property on obj's prototype chain, or a
* with object or catch variable; nor can prop's value be changed,
* nor can prop be deleted.
*/
prop = NULL;
if (OBJ_GET_CLASS(cx, obj) == &js_FunctionClass) {
ok = js_LookupHiddenProperty(cx, obj, ATOM_TO_JSID(atom),
&pobj, &prop);
if (!ok)
break;
if (prop) {
#ifdef DEBUG
JSScopeProperty *sprop = (JSScopeProperty *)prop;
/*
* Any hidden property must be a formal arg or local var,
* which will shadow a global const of the same name.
*/
JS_ASSERT(sprop->getter == js_GetArgument ||
sprop->getter == js_GetLocalVariable);
#endif
OBJ_DROP_PROPERTY(cx, pobj, prop);
break;
}
}
ok = OBJ_LOOKUP_PROPERTY(cx, obj, ATOM_TO_JSID(atom), &pobj, &prop);
if (ok) {
if (pobj == obj &&
(fp->flags & (JSFRAME_EVAL | JSFRAME_COMPILE_N_GO))) {
/*
* We're compiling code that will be executed immediately,
* not re-executed against a different scope chain and/or
* variable object. Therefore we can get constant values
* from our variable object here.
*/
ok = OBJ_GET_ATTRIBUTES(cx, obj, ATOM_TO_JSID(atom), prop,
&attrs);
if (ok && !(~attrs & (JSPROP_READONLY | JSPROP_PERMANENT)))
ok = OBJ_GET_PROPERTY(cx, obj, ATOM_TO_JSID(atom), vp);
}
if (prop)
OBJ_DROP_PROPERTY(cx, pobj, prop);
}
if (!ok || prop)
break;
}
fp = fp->down;
} while ((cg = cg->parent) != NULL);
return ok;
}
/*
* Allocate an index invariant for all activations of the code being compiled
* in cg, that can be used to store and fetch a reference to a cloned RegExp
* object that shares the same JSRegExp private data created for the object
* literal in pn->pn_atom. We need clones to hold lastIndex and other direct
* properties that should not be shared among threads sharing a precompiled
* function or script.
*
* If the code being compiled is function code, allocate a reserved slot in
* the cloned function object that shares its precompiled script with other
* cloned function objects and with the compiler-created clone-parent. There
* are fun->nregexps such reserved slots in each function object cloned from
* fun->object. NB: during compilation, funobj slots must never be allocated,
* because js_AllocSlot could hand out one of the slots that should be given
* to a regexp clone.
*
* If the code being compiled is global code, reserve the fp->vars slot at
* ALE_INDEX(ale), by ensuring that cg->treeContext.numGlobalVars is at least
* one more than this index. For global code, fp->vars is parallel to the
* global script->atomMap.vector array, but possibly shorter for the common
* case (where var declarations and regexp literals cluster toward the front
* of the script or function body).
*
* Global variable name literals in script->atomMap have fast-global slot
* numbers (stored as int-tagged jsvals) in the corresponding fp->vars array
* element. The atomIndex for a regexp object literal thus also addresses an
* fp->vars element that is not used by any optimized global variable, so we
* use that GC-scanned element to keep the regexp object clone alive, as well
* as to lazily create and find it at run-time for the JSOP_REGEXP bytecode.
*
* In no case can cx->fp->varobj be a Call object here, because that implies
* we are compiling eval code, in which case (cx->fp->flags & JSFRAME_EVAL)
* is true, and js_GetToken will have already selected JSOP_OBJECT instead of
* JSOP_REGEXP, to avoid all this RegExp object cloning business.
*
* Why clone regexp objects? ECMA specifies that when a regular expression
* literal is scanned, a RegExp object is created. In the spec, compilation
* and execution happen indivisibly, but in this implementation and many of
* its embeddings, code is precompiled early and re-executed in multiple
* threads, or using multiple global objects, or both, for efficiency.
*
* In such cases, naively following ECMA leads to wrongful sharing of RegExp
* objects, which makes for collisions on the lastIndex property (especially
* for global regexps) and on any ad-hoc properties. Also, __proto__ and
* __parent__ refer to the pre-compilation prototype and global objects, a
* pigeon-hole problem for instanceof tests.
*/
static JSBool
IndexRegExpClone(JSContext *cx, JSParseNode *pn, JSAtomListElement *ale,
JSCodeGenerator *cg)
{
JSObject *varobj, *reobj;
JSClass *clasp;
JSFunction *fun;
JSRegExp *re;
uint16 *countPtr;
uintN cloneIndex;
JS_ASSERT(!(cx->fp->flags & (JSFRAME_EVAL | JSFRAME_COMPILE_N_GO)));
varobj = cx->fp->varobj;
clasp = OBJ_GET_CLASS(cx, varobj);
if (clasp == &js_FunctionClass) {
fun = (JSFunction *) JS_GetPrivate(cx, varobj);
countPtr = &fun->u.i.nregexps;
cloneIndex = *countPtr;
} else {
JS_ASSERT(clasp != &js_CallClass);
countPtr = &cg->treeContext.numGlobalVars;
cloneIndex = ALE_INDEX(ale);
}
if ((cloneIndex + 1) >> 16) {
JS_ReportErrorNumber(cx, js_GetErrorMessage, NULL,
JSMSG_NEED_DIET, js_script_str);
return JS_FALSE;
}
if (cloneIndex >= *countPtr)
*countPtr = cloneIndex + 1;
reobj = ATOM_TO_OBJECT(pn->pn_atom);
JS_ASSERT(OBJ_GET_CLASS(cx, reobj) == &js_RegExpClass);
re = (JSRegExp *) JS_GetPrivate(cx, reobj);
re->cloneIndex = cloneIndex;
return JS_TRUE;
}
/*
* Emit a bytecode and its 2-byte constant (atom) index immediate operand.
* If the atomIndex requires more than 2 bytes, emit a prefix op whose 24-bit
* immediate operand indexes the atom in script->atomMap.
*
* If op has JOF_NAME mode, emit JSOP_FINDNAME to find and push the object in
* the scope chain in which the literal name was found, followed by the name
* as a string. This enables us to use the JOF_ELEM counterpart to op.
*
* Otherwise, if op has JOF_PROP mode, emit JSOP_LITERAL before op, to push
* the atom's value key. For JOF_PROP ops, the object being operated on has
* already been pushed, and JSOP_LITERAL will push the id, leaving the stack
* in the proper state for a JOF_ELEM counterpart.
*
* Otherwise, emit JSOP_LITOPX to push the atom index, then perform a special
* dispatch on op, but getting op's atom index from the stack instead of from
* an unsigned 16-bit immediate operand.
*/
static JSBool
EmitAtomIndexOp(JSContext *cx, JSOp op, jsatomid atomIndex, JSCodeGenerator *cg)
{
uint32 mode;
JSOp prefixOp;
ptrdiff_t off;
jsbytecode *pc;
if (atomIndex >= JS_BIT(16)) {
mode = (js_CodeSpec[op].format & JOF_MODEMASK);
if (op != JSOP_SETNAME) {
prefixOp = ((mode != JOF_NAME && mode != JOF_PROP) ||
#if JS_HAS_XML_SUPPORT
op == JSOP_GETMETHOD ||
op == JSOP_SETMETHOD ||
#endif
op == JSOP_SETCONST)
? JSOP_LITOPX
: (mode == JOF_NAME)
? JSOP_FINDNAME
: JSOP_LITERAL;
off = js_EmitN(cx, cg, prefixOp, 3);
if (off < 0)
return JS_FALSE;
pc = CG_CODE(cg, off);
SET_LITERAL_INDEX(pc, atomIndex);
}
switch (op) {
case JSOP_DECNAME: op = JSOP_DECELEM; break;
case JSOP_DECPROP: op = JSOP_DECELEM; break;
case JSOP_DELNAME: op = JSOP_DELELEM; break;
case JSOP_DELPROP: op = JSOP_DELELEM; break;
case JSOP_FORNAME: op = JSOP_FORELEM; break;
case JSOP_FORPROP: op = JSOP_FORELEM; break;
case JSOP_GETPROP: op = JSOP_GETELEM; break;
case JSOP_GETXPROP: op = JSOP_GETXELEM; break;
case JSOP_IMPORTPROP: op = JSOP_IMPORTELEM; break;
case JSOP_INCNAME: op = JSOP_INCELEM; break;
case JSOP_INCPROP: op = JSOP_INCELEM; break;
case JSOP_INITPROP: op = JSOP_INITELEM; break;
case JSOP_NAME: op = JSOP_GETELEM; break;
case JSOP_NAMEDEC: op = JSOP_ELEMDEC; break;
case JSOP_NAMEINC: op = JSOP_ELEMINC; break;
case JSOP_PROPDEC: op = JSOP_ELEMDEC; break;
case JSOP_PROPINC: op = JSOP_ELEMINC; break;
case JSOP_BINDNAME: return JS_TRUE;
case JSOP_SETNAME: op = JSOP_SETELEM; break;
case JSOP_SETPROP: op = JSOP_SETELEM; break;
#if JS_HAS_EXPORT_IMPORT
case JSOP_EXPORTNAME:
ReportStatementTooLarge(cx, cg);
return JS_FALSE;
#endif
default:
#if JS_HAS_XML_SUPPORT
JS_ASSERT(mode == 0 || op == JSOP_SETCONST ||
op == JSOP_GETMETHOD || op == JSOP_SETMETHOD);
#else
JS_ASSERT(mode == 0 || op == JSOP_SETCONST);
#endif
break;
}
return js_Emit1(cx, cg, op) >= 0;
}
EMIT_UINT16_IMM_OP(op, atomIndex);
return JS_TRUE;
}
/*
* Slight sugar for EmitAtomIndexOp, again accessing cx and cg from the macro
* caller's lexical environment, and embedding a false return on error.
* XXXbe hey, who checks for fun->nvars and fun->nargs overflow?!
*/
#define EMIT_ATOM_INDEX_OP(op, atomIndex) \
JS_BEGIN_MACRO \
if (!EmitAtomIndexOp(cx, op, atomIndex, cg)) \
return JS_FALSE; \
JS_END_MACRO
static JSBool
EmitAtomOp(JSContext *cx, JSParseNode *pn, JSOp op, JSCodeGenerator *cg)
{
JSAtomListElement *ale;
ale = js_IndexAtom(cx, pn->pn_atom, &cg->atomList);
if (!ale)
return JS_FALSE;
if (op == JSOP_REGEXP && !IndexRegExpClone(cx, pn, ale, cg))
return JS_FALSE;
return EmitAtomIndexOp(cx, op, ALE_INDEX(ale), cg);
}
/*
* This routine tries to optimize name gets and sets to stack slot loads and
* stores, given the variables object and scope chain in cx's top frame, the
* compile-time context in tc, and a TOK_NAME node pn. It returns false on
* error, true on success.
*
* The caller can inspect pn->pn_slot for a non-negative slot number to tell
* whether optimization occurred, in which case BindNameToSlot also updated
* pn->pn_op. If pn->pn_slot is still -1 on return, pn->pn_op nevertheless
* may have been optimized, e.g., from JSOP_NAME to JSOP_ARGUMENTS. Whether
* or not pn->pn_op was modified, if this function finds an argument or local
* variable name, pn->pn_attrs will contain the property's attributes after a
* successful return.
*
* NB: if you add more opcodes specialized from JSOP_NAME, etc., don't forget
* to update the TOK_FOR (for-in) and TOK_ASSIGN (op=, e.g. +=) special cases
* in js_EmitTree.
*/
static JSBool
BindNameToSlot(JSContext *cx, JSTreeContext *tc, JSParseNode *pn,
JSBool letdecl)
{
JSAtom *atom;
JSStmtInfo *stmt;
jsint slot;
JSOp op;
JSStackFrame *fp;
JSObject *obj, *pobj;
JSClass *clasp;
JSBool optimizeGlobals;
JSPropertyOp getter;
uintN attrs;
JSAtomListElement *ale;
JSProperty *prop;
JSScopeProperty *sprop;
JS_ASSERT(pn->pn_type == TOK_NAME);
if (pn->pn_slot >= 0 || pn->pn_op == JSOP_ARGUMENTS)
return JS_TRUE;
/* QNAME references can never be optimized to use arg/var storage. */
if (pn->pn_op == JSOP_QNAMEPART)
return JS_TRUE;
/*
* We can't optimize if we are compiling a with statement and its body,
* or we're in a catch block whose exception variable has the same name
* as this node. FIXME: we should be able to optimize catch vars to be
* block-locals.
*/
atom = pn->pn_atom;
stmt = js_LexicalLookup(tc, atom, &slot, letdecl);
if (stmt) {
if (stmt->type == STMT_WITH)
return JS_TRUE;
JS_ASSERT(stmt->flags & SIF_SCOPE);
JS_ASSERT(slot >= 0);
op = pn->pn_op;
switch (op) {
case JSOP_NAME: op = JSOP_GETLOCAL; break;
case JSOP_SETNAME: op = JSOP_SETLOCAL; break;
case JSOP_INCNAME: op = JSOP_INCLOCAL; break;
case JSOP_NAMEINC: op = JSOP_LOCALINC; break;
case JSOP_DECNAME: op = JSOP_DECLOCAL; break;
case JSOP_NAMEDEC: op = JSOP_LOCALDEC; break;
case JSOP_FORNAME: op = JSOP_FORLOCAL; break;
case JSOP_DELNAME: op = JSOP_FALSE; break;
default: JS_ASSERT(0);
}
if (op != pn->pn_op) {
pn->pn_op = op;
pn->pn_slot = slot;
}
return JS_TRUE;
}
/*
* A Script object can be used to split an eval into a compile step done
* at construction time, and an execute step done separately, possibly in
* a different scope altogether. We therefore cannot do any name-to-slot
* optimizations, but must lookup names at runtime. Note that script_exec
* ensures that its caller's frame has a Call object, so arg and var name
* lookups will succeed.
*/
fp = cx->fp;
if (fp->flags & JSFRAME_SCRIPT_OBJECT)
return JS_TRUE;
/*
* We can't optimize if var and closure (a local function not in a larger
* expression and not at top-level within another's body) collide.
* XXX suboptimal: keep track of colliding names and deoptimize only those
*/
if (tc->flags & TCF_FUN_CLOSURE_VS_VAR)
return JS_TRUE;
/*
* We can't optimize if we're not compiling a function body, whether via
* eval, or directly when compiling a function statement or expression.
*/
obj = fp->varobj;
clasp = OBJ_GET_CLASS(cx, obj);
if (clasp != &js_FunctionClass && clasp != &js_CallClass) {
/* Check for an eval or debugger frame. */
if (fp->flags & JSFRAME_SPECIAL)
return JS_TRUE;
/*
* Optimize global variable accesses if there are at least 100 uses
* in unambiguous contexts, or failing that, if least half of all the
* uses of global vars/consts/functions are in loops.
*/
optimizeGlobals = (tc->globalUses >= 100 ||
(tc->loopyGlobalUses &&
tc->loopyGlobalUses >= tc->globalUses / 2));
if (!optimizeGlobals)
return JS_TRUE;
} else {
optimizeGlobals = JS_FALSE;
}
/*
* We can't optimize if we are in an eval called inside a with statement.
*/
if (fp->scopeChain != obj)
return JS_TRUE;
op = pn->pn_op;
getter = NULL;
#ifdef __GNUC__
attrs = slot = 0; /* quell GCC overwarning */
#endif
if (optimizeGlobals) {
/*
* We are optimizing global variables, and there is no pre-existing
* global property named atom. If atom was declared via const or var,
* optimize pn to access fp->vars using the appropriate JOF_QVAR op.
*/
ATOM_LIST_SEARCH(ale, &tc->decls, atom);
if (!ale) {
/* Use precedes declaration, or name is never declared. */
return JS_TRUE;
}
attrs = (ALE_JSOP(ale) == JSOP_DEFCONST)
? JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT
: JSPROP_ENUMERATE | JSPROP_PERMANENT;
/* Index atom so we can map fast global number to name. */
JS_ASSERT(tc->flags & TCF_COMPILING);
ale = js_IndexAtom(cx, atom, &((JSCodeGenerator *) tc)->atomList);
if (!ale)
return JS_FALSE;
/* Defend against tc->numGlobalVars 16-bit overflow. */
slot = ALE_INDEX(ale);
if ((slot + 1) >> 16)
return JS_TRUE;
if ((uint16)(slot + 1) > tc->numGlobalVars)
tc->numGlobalVars = (uint16)(slot + 1);
} else {
/*
* We may be able to optimize name to stack slot. Look for an argument
* or variable property in the function, or its call object, not found
* in any prototype object. Rewrite pn_op and update pn accordingly.
* NB: We know that JSOP_DELNAME on an argument or variable evaluates
* to false, due to JSPROP_PERMANENT.
*/
if (!js_LookupHiddenProperty(cx, obj, ATOM_TO_JSID(atom), &pobj, &prop))
return JS_FALSE;
sprop = (JSScopeProperty *) prop;
if (sprop) {
if (pobj == obj) {
getter = sprop->getter;
attrs = sprop->attrs;
slot = (sprop->flags & SPROP_HAS_SHORTID) ? sprop->shortid : -1;
}
OBJ_DROP_PROPERTY(cx, pobj, prop);
}
}
if (optimizeGlobals || getter) {
if (optimizeGlobals) {
switch (op) {
case JSOP_NAME: op = JSOP_GETGVAR; break;
case JSOP_SETNAME: op = JSOP_SETGVAR; break;
case JSOP_SETCONST: /* NB: no change */ break;
case JSOP_INCNAME: op = JSOP_INCGVAR; break;
case JSOP_NAMEINC: op = JSOP_GVARINC; break;
case JSOP_DECNAME: op = JSOP_DECGVAR; break;
case JSOP_NAMEDEC: op = JSOP_GVARDEC; break;
case JSOP_FORNAME: /* NB: no change */ break;
case JSOP_DELNAME: /* NB: no change */ break;
default: JS_ASSERT(0);
}
} else if (getter == js_GetLocalVariable ||
getter == js_GetCallVariable) {
switch (op) {
case JSOP_NAME: op = JSOP_GETVAR; break;
case JSOP_SETNAME: op = JSOP_SETVAR; break;
case JSOP_SETCONST: op = JSOP_SETVAR; break;
case JSOP_INCNAME: op = JSOP_INCVAR; break;
case JSOP_NAMEINC: op = JSOP_VARINC; break;
case JSOP_DECNAME: op = JSOP_DECVAR; break;
case JSOP_NAMEDEC: op = JSOP_VARDEC; break;
case JSOP_FORNAME: op = JSOP_FORVAR; break;
case JSOP_DELNAME: op = JSOP_FALSE; break;
default: JS_ASSERT(0);
}
} else if (getter == js_GetArgument ||
(getter == js_CallClass.getProperty &&
fp->fun && (uintN) slot < fp->fun->nargs)) {
switch (op) {
case JSOP_NAME: op = JSOP_GETARG; break;
case JSOP_SETNAME: op = JSOP_SETARG; break;
case JSOP_INCNAME: op = JSOP_INCARG; break;
case JSOP_NAMEINC: op = JSOP_ARGINC; break;
case JSOP_DECNAME: op = JSOP_DECARG; break;
case JSOP_NAMEDEC: op = JSOP_ARGDEC; break;
case JSOP_FORNAME: op = JSOP_FORARG; break;
case JSOP_DELNAME: op = JSOP_FALSE; break;
default: JS_ASSERT(0);
}
}
if (op != pn->pn_op) {
pn->pn_op = op;
pn->pn_slot = slot;
}
pn->pn_attrs = attrs;
}
if (pn->pn_slot < 0) {
/*
* We couldn't optimize pn, so it's not a global or local slot name.
* Now we must check for the predefined arguments variable. It may be
* overridden by assignment, in which case the function is heavyweight
* and the interpreter will look up 'arguments' in the function's call
* object.
*/
if (pn->pn_op == JSOP_NAME &&
atom == cx->runtime->atomState.argumentsAtom) {
pn->pn_op = JSOP_ARGUMENTS;
return JS_TRUE;
}
tc->flags |= TCF_FUN_USES_NONLOCALS;
}
return JS_TRUE;
}
/*
* If pn contains a useful expression, return true with *answer set to true.
* If pn contains a useless expression, return true with *answer set to false.
* Return false on error.
*
* The caller should initialize *answer to false and invoke this function on
* an expression statement or similar subtree to decide whether the tree could
* produce code that has any side effects. For an expression statement, we
* define useless code as code with no side effects, because the main effect,
* the value left on the stack after the code executes, will be discarded by a
* pop bytecode.
*/
static JSBool
CheckSideEffects(JSContext *cx, JSTreeContext *tc, JSParseNode *pn,
JSBool *answer)
{
JSBool ok;
JSFunction *fun;
JSParseNode *pn2;
ok = JS_TRUE;
if (!pn || *answer)
return ok;
switch (pn->pn_arity) {
case PN_FUNC:
/*
* A named function is presumed useful: we can't yet know that it is
* not called. The side effects are the creation of a scope object
* to parent this function object, and the binding of the function's
* name in that scope object. See comments at case JSOP_NAMEDFUNOBJ:
* in jsinterp.c.
*/
fun = (JSFunction *) JS_GetPrivate(cx, ATOM_TO_OBJECT(pn->pn_funAtom));
if (fun->atom)
*answer = JS_TRUE;
break;
case PN_LIST:
if (pn->pn_type == TOK_NEW ||
pn->pn_type == TOK_LP ||
pn->pn_type == TOK_LB ||
pn->pn_type == TOK_RB ||
pn->pn_type == TOK_RC) {
/*
* All invocation operations (construct: TOK_NEW, call: TOK_LP)
* are presumed to be useful, because they may have side effects
* even if their main effect (their return value) is discarded.
*
* TOK_LB binary trees of 3 or more nodes are flattened into lists
* to avoid too much recursion. All such lists must be presumed
* to be useful because each index operation could invoke a getter
* (the JSOP_ARGUMENTS special case below, in the PN_BINARY case,
* does not apply here: arguments[i][j] might invoke a getter).
*
* Array and object initializers (TOK_RB and TOK_RC lists) must be
* considered useful, because they are sugar for constructor calls
* (to Array and Object, respectively).
*/
*answer = JS_TRUE;
} else {
for (pn2 = pn->pn_head; pn2; pn2 = pn2->pn_next)
ok &= CheckSideEffects(cx, tc, pn2, answer);
}
break;
case PN_TERNARY:
ok = CheckSideEffects(cx, tc, pn->pn_kid1, answer) &&
CheckSideEffects(cx, tc, pn->pn_kid2, answer) &&
CheckSideEffects(cx, tc, pn->pn_kid3, answer);
break;
case PN_BINARY:
if (pn->pn_type == TOK_ASSIGN) {
/*
* Assignment is presumed to be useful, even if the next operation
* is another assignment overwriting this one's ostensible effect,
* because the left operand may be a property with a setter that
* has side effects.
*
* The only exception is assignment of a useless value to a const
* declared in the function currently being compiled.
*/
pn2 = pn->pn_left;
if (pn2->pn_type != TOK_NAME) {
*answer = JS_TRUE;
} else {
if (!BindNameToSlot(cx, tc, pn2, JS_FALSE))
return JS_FALSE;
if (!CheckSideEffects(cx, tc, pn->pn_right, answer))
return JS_FALSE;
if (!*answer &&
(pn2->pn_slot < 0 || !(pn2->pn_attrs & JSPROP_READONLY))) {
*answer = JS_TRUE;
}
}
} else {
if (pn->pn_type == TOK_LB) {
pn2 = pn->pn_left;
if (pn2->pn_type == TOK_NAME &&
!BindNameToSlot(cx, tc, pn2, JS_FALSE)) {
return JS_FALSE;
}
if (pn2->pn_op != JSOP_ARGUMENTS) {
/*
* Any indexed property reference could call a getter with
* side effects, except for arguments[i] where arguments is
* unambiguous.
*/
*answer = JS_TRUE;
}
}
ok = CheckSideEffects(cx, tc, pn->pn_left, answer) &&
CheckSideEffects(cx, tc, pn->pn_right, answer);
}
break;
case PN_UNARY:
if (pn->pn_type == TOK_INC || pn->pn_type == TOK_DEC ||
pn->pn_type == TOK_THROW ||
#if JS_HAS_GENERATORS
pn->pn_type == TOK_YIELD ||
#endif
pn->pn_type == TOK_DEFSHARP) {
/* All these operations have effects that we must commit. */
*answer = JS_TRUE;
} else if (pn->pn_type == TOK_DELETE) {
pn2 = pn->pn_kid;
switch (pn2->pn_type) {
case TOK_NAME:
case TOK_DOT:
#if JS_HAS_XML_SUPPORT
case TOK_DBLDOT:
#endif
#if JS_HAS_LVALUE_RETURN
case TOK_LP:
#endif
case TOK_LB:
/* All these delete addressing modes have effects too. */
*answer = JS_TRUE;
break;
default:
ok = CheckSideEffects(cx, tc, pn2, answer);
break;
}
} else {
ok = CheckSideEffects(cx, tc, pn->pn_kid, answer);
}
break;
case PN_NAME:
/*
* Take care to avoid trying to bind a label name (labels, both for
* statements and property values in object initialisers, have pn_op
* defaulted to JSOP_NOP).
*/
if (pn->pn_type == TOK_NAME && pn->pn_op != JSOP_NOP) {
if (!BindNameToSlot(cx, tc, pn, JS_FALSE))
return JS_FALSE;
if (pn->pn_slot < 0 && pn->pn_op != JSOP_ARGUMENTS) {
/*
* Not an argument or local variable use, so this expression
* could invoke a getter that has side effects.
*/
*answer = JS_TRUE;
}
}
pn2 = pn->pn_expr;
if (pn->pn_type == TOK_DOT) {
if (pn2->pn_type == TOK_NAME &&
!BindNameToSlot(cx, tc, pn2, JS_FALSE)) {
return JS_FALSE;
}
if (!(pn2->pn_op == JSOP_ARGUMENTS &&
pn->pn_atom == cx->runtime->atomState.lengthAtom)) {
/*
* Any dotted property reference could call a getter, except
* for arguments.length where arguments is unambiguous.
*/
*answer = JS_TRUE;
}
}
ok = CheckSideEffects(cx, tc, pn2, answer);
break;
case PN_NULLARY:
if (pn->pn_type == TOK_DEBUGGER)
*answer = JS_TRUE;
break;
}
return ok;
}
/*
* Secret handshake with js_EmitTree's TOK_LP/TOK_NEW case logic, to flag all
* uses of JSOP_GETMETHOD that implicitly qualify the method property's name
* with a function:: prefix. All other JSOP_GETMETHOD and JSOP_SETMETHOD uses
* must be explicit, so we need a distinct source note (SRC_METHODBASE rather
* than SRC_PCBASE) for round-tripping through the beloved decompiler.
*/
#define JSPROP_IMPLICIT_FUNCTION_NAMESPACE 0x100
static jssrcnote
SrcNoteForPropOp(JSParseNode *pn, JSOp op)
{
return ((op == JSOP_GETMETHOD &&
!(pn->pn_attrs & JSPROP_IMPLICIT_FUNCTION_NAMESPACE)) ||
op == JSOP_SETMETHOD)
? SRC_METHODBASE
: SRC_PCBASE;
}
static JSBool
EmitPropOp(JSContext *cx, JSParseNode *pn, JSOp op, JSCodeGenerator *cg)
{
JSParseNode *pn2, *pndot, *pnup, *pndown;
ptrdiff_t top;
pn2 = pn->pn_expr;
if (op == JSOP_GETPROP &&
pn->pn_type == TOK_DOT &&
pn2->pn_type == TOK_NAME) {
/* Try to optimize arguments.length into JSOP_ARGCNT. */
if (!BindNameToSlot(cx, &cg->treeContext, pn2, JS_FALSE))
return JS_FALSE;
if (pn2->pn_op == JSOP_ARGUMENTS &&
pn->pn_atom == cx->runtime->atomState.lengthAtom) {
return js_Emit1(cx, cg, JSOP_ARGCNT) >= 0;
}
}
/*
* If the object operand is also a dotted property reference, reverse the
* list linked via pn_expr temporarily so we can iterate over it from the
* bottom up (reversing again as we go), to avoid excessive recursion.
*/
if (pn2->pn_type == TOK_DOT) {
pndot = pn2;
pnup = NULL;
top = CG_OFFSET(cg);
for (;;) {
/* Reverse pndot->pn_expr to point up, not down. */
pndot->pn_offset = top;
pndown = pndot->pn_expr;
pndot->pn_expr = pnup;
if (pndown->pn_type != TOK_DOT)
break;
pnup = pndot;
pndot = pndown;
}
/* pndown is a primary expression, not a dotted property reference. */
if (!js_EmitTree(cx, cg, pndown))
return JS_FALSE;
do {
/* Walk back up the list, emitting annotated name ops. */
if (js_NewSrcNote2(cx, cg, SrcNoteForPropOp(pndot, pndot->pn_op),
CG_OFFSET(cg) - pndown->pn_offset) < 0) {
return JS_FALSE;
}
if (!EmitAtomOp(cx, pndot, pndot->pn_op, cg))
return JS_FALSE;
/* Reverse the pn_expr link again. */
pnup = pndot->pn_expr;
pndot->pn_expr = pndown;
pndown = pndot;
} while ((pndot = pnup) != NULL);
} else {
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
}
if (js_NewSrcNote2(cx, cg, SrcNoteForPropOp(pn, op),
CG_OFFSET(cg) - pn2->pn_offset) < 0) {
return JS_FALSE;
}
if (!pn->pn_atom) {
JS_ASSERT(op == JSOP_IMPORTALL);
if (js_Emit1(cx, cg, op) < 0)
return JS_FALSE;
} else {
if (!EmitAtomOp(cx, pn, op, cg))
return JS_FALSE;
}
return JS_TRUE;
}
static JSBool
EmitElemOp(JSContext *cx, JSParseNode *pn, JSOp op, JSCodeGenerator *cg)
{
ptrdiff_t top;
JSParseNode *left, *right, *next, ltmp, rtmp;
jsint slot;
top = CG_OFFSET(cg);
if (pn->pn_arity == PN_LIST) {
/* Left-associative operator chain to avoid too much recursion. */
JS_ASSERT(pn->pn_op == JSOP_GETELEM || pn->pn_op == JSOP_IMPORTELEM);
JS_ASSERT(pn->pn_count >= 3);
left = pn->pn_head;
right = PN_LAST(pn);
next = left->pn_next;
JS_ASSERT(next != right);
/*
* Try to optimize arguments[0][j]... into JSOP_ARGSUB<0> followed by
* one or more index expression and JSOP_GETELEM op pairs.
*/
if (left->pn_type == TOK_NAME && next->pn_type == TOK_NUMBER) {
if (!BindNameToSlot(cx, &cg->treeContext, left, JS_FALSE))
return JS_FALSE;
if (left->pn_op == JSOP_ARGUMENTS &&
JSDOUBLE_IS_INT(next->pn_dval, slot) &&
(jsuint)slot < JS_BIT(16)) {
left->pn_offset = next->pn_offset = top;
EMIT_UINT16_IMM_OP(JSOP_ARGSUB, (jsatomid)slot);
left = next;
next = left->pn_next;
}
}
/*
* Check whether we generated JSOP_ARGSUB, just above, and have only
* one more index expression to emit. Given arguments[0][j], we must
* skip the while loop altogether, falling through to emit code for j
* (in the subtree referenced by right), followed by the annotated op,
* at the bottom of this function.
*/
JS_ASSERT(next != right || pn->pn_count == 3);
if (left == pn->pn_head) {
if (!js_EmitTree(cx, cg, left))
return JS_FALSE;
}
while (next != right) {
if (!js_EmitTree(cx, cg, next))
return JS_FALSE;
if (js_NewSrcNote2(cx, cg, SRC_PCBASE, CG_OFFSET(cg) - top) < 0)
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_GETELEM) < 0)
return JS_FALSE;
next = next->pn_next;
}
} else {
if (pn->pn_arity == PN_NAME) {
/*
* Set left and right so pn appears to be a TOK_LB node, instead
* of a TOK_DOT node. See the TOK_FOR/IN case in js_EmitTree, and
* EmitDestructuringOps nearer below. In the destructuring case,
* the base expression (pn_expr) of the name may be null, which
* means we have to emit a JSOP_BINDNAME.
*/
left = pn->pn_expr;
if (!left) {
left = &ltmp;
left->pn_type = TOK_OBJECT;
left->pn_op = JSOP_BINDNAME;
left->pn_arity = PN_NULLARY;
left->pn_pos = pn->pn_pos;
left->pn_atom = pn->pn_atom;
}
right = &rtmp;
right->pn_type = TOK_STRING;
JS_ASSERT(ATOM_IS_STRING(pn->pn_atom));
right->pn_op = js_IsIdentifier(ATOM_TO_STRING(pn->pn_atom))
? JSOP_QNAMEPART
: JSOP_STRING;
right->pn_arity = PN_NULLARY;
right->pn_pos = pn->pn_pos;
right->pn_atom = pn->pn_atom;
} else {
JS_ASSERT(pn->pn_arity == PN_BINARY);
left = pn->pn_left;
right = pn->pn_right;
}
/* Try to optimize arguments[0] (e.g.) into JSOP_ARGSUB<0>. */
if (op == JSOP_GETELEM &&
left->pn_type == TOK_NAME &&
right->pn_type == TOK_NUMBER) {
if (!BindNameToSlot(cx, &cg->treeContext, left, JS_FALSE))
return JS_FALSE;
if (left->pn_op == JSOP_ARGUMENTS &&
JSDOUBLE_IS_INT(right->pn_dval, slot) &&
(jsuint)slot < JS_BIT(16)) {
left->pn_offset = right->pn_offset = top;
EMIT_UINT16_IMM_OP(JSOP_ARGSUB, (jsatomid)slot);
return JS_TRUE;
}
}
if (!js_EmitTree(cx, cg, left))
return JS_FALSE;
}
/* The right side of the descendant operator is implicitly quoted. */
JS_ASSERT(op != JSOP_DESCENDANTS || right->pn_type != TOK_STRING ||
right->pn_op == JSOP_QNAMEPART);
if (!js_EmitTree(cx, cg, right))
return JS_FALSE;
if (js_NewSrcNote2(cx, cg, SRC_PCBASE, CG_OFFSET(cg) - top) < 0)
return JS_FALSE;
return js_Emit1(cx, cg, op) >= 0;
}
static JSBool
EmitNumberOp(JSContext *cx, jsdouble dval, JSCodeGenerator *cg)
{
jsint ival;
jsatomid atomIndex;
ptrdiff_t off;
jsbytecode *pc;
JSAtom *atom;
JSAtomListElement *ale;
if (JSDOUBLE_IS_INT(dval, ival) && INT_FITS_IN_JSVAL(ival)) {
if (ival == 0)
return js_Emit1(cx, cg, JSOP_ZERO) >= 0;
if (ival == 1)
return js_Emit1(cx, cg, JSOP_ONE) >= 0;
atomIndex = (jsatomid)ival;
if (atomIndex < JS_BIT(16)) {
EMIT_UINT16_IMM_OP(JSOP_UINT16, atomIndex);
return JS_TRUE;
}
if (atomIndex < JS_BIT(24)) {
off = js_EmitN(cx, cg, JSOP_UINT24, 3);
if (off < 0)
return JS_FALSE;
pc = CG_CODE(cg, off);
SET_LITERAL_INDEX(pc, atomIndex);
return JS_TRUE;
}
atom = js_AtomizeInt(cx, ival, 0);
} else {
atom = js_AtomizeDouble(cx, dval, 0);
}
if (!atom)
return JS_FALSE;
ale = js_IndexAtom(cx, atom, &cg->atomList);
if (!ale)
return JS_FALSE;
return EmitAtomIndexOp(cx, JSOP_NUMBER, ALE_INDEX(ale), cg);
}
static JSBool
EmitSwitch(JSContext *cx, JSCodeGenerator *cg, JSParseNode *pn,
JSStmtInfo *stmtInfo)
{
JSOp switchOp;
JSBool ok, hasDefault, constPropagated;
ptrdiff_t top, off, defaultOffset;
JSParseNode *pn2, *pn3, *pn4;
uint32 caseCount, tableLength;
JSParseNode **table;
jsdouble d;
jsint i, low, high;
jsval v;
JSAtom *atom;
JSAtomListElement *ale;
intN noteIndex;
size_t switchSize, tableSize;
jsbytecode *pc, *savepc;
#if JS_HAS_BLOCK_SCOPE
JSObject *obj;
jsint count;
#endif
/* Try for most optimal, fall back if not dense ints, and per ECMAv2. */
switchOp = JSOP_TABLESWITCH;
ok = JS_TRUE;
hasDefault = constPropagated = JS_FALSE;
defaultOffset = -1;
/*
* If the switch contains let variables scoped by its body, model the
* resulting block on the stack first, before emitting the discriminant's
* bytecode (in case the discriminant contains a stack-model dependency
* such as a let expression).
*/
pn2 = pn->pn_right;
#if JS_HAS_BLOCK_SCOPE
if (pn2->pn_type == TOK_LEXICALSCOPE) {
atom = pn2->pn_atom;
obj = ATOM_TO_OBJECT(atom);
OBJ_SET_BLOCK_DEPTH(cx, obj, cg->stackDepth);
/*
* Push the body's block scope before discriminant code-gen for proper
* static block scope linkage in case the discriminant contains a let
* expression. The block's locals must lie under the discriminant on
* the stack so that case-dispatch bytecodes can find the discriminant
* on top of stack.
*/
js_PushBlockScope(&cg->treeContext, stmtInfo, atom, -1);
stmtInfo->type = STMT_SWITCH;
count = OBJ_BLOCK_COUNT(cx, obj);
cg->stackDepth += count;
if ((uintN)cg->stackDepth > cg->maxStackDepth)
cg->maxStackDepth = cg->stackDepth;
/* Emit JSOP_ENTERBLOCK before code to evaluate the discriminant. */
ale = js_IndexAtom(cx, atom, &cg->atomList);
if (!ale)
return JS_FALSE;
EMIT_ATOM_INDEX_OP(JSOP_ENTERBLOCK, ALE_INDEX(ale));
/*
* Pop the switch's statement info around discriminant code-gen. Note
* how this leaves cg->treeContext.blockChain referencing the switch's
* block scope object, which is necessary for correct block parenting
* in the case where the discriminant contains a let expression.
*/
cg->treeContext.topStmt = stmtInfo->down;
cg->treeContext.topScopeStmt = stmtInfo->downScope;
}
#ifdef __GNUC__
else {
atom = NULL;
count = -1;
}
#endif
#endif
/*
* Emit code for the discriminant first (or nearly first, in the case of a
* switch whose body is a block scope).
*/
if (!js_EmitTree(cx, cg, pn->pn_left))
return JS_FALSE;
/* Switch bytecodes run from here till end of final case. */
top = CG_OFFSET(cg);
#if !JS_HAS_BLOCK_SCOPE
js_PushStatement(&cg->treeContext, stmtInfo, STMT_SWITCH, top);
#else
if (pn2->pn_type == TOK_LC) {
js_PushStatement(&cg->treeContext, stmtInfo, STMT_SWITCH, top);
} else {
/* Re-push the switch's statement info record. */
cg->treeContext.topStmt = cg->treeContext.topScopeStmt = stmtInfo;
/* Set the statement info record's idea of top. */
stmtInfo->update = top;
/* Advance pn2 to refer to the switch case list. */
pn2 = pn2->pn_expr;
}
#endif
caseCount = pn2->pn_count;
tableLength = 0;
table = NULL;
if (caseCount == 0 ||
(caseCount == 1 &&
(hasDefault = (pn2->pn_head->pn_type == TOK_DEFAULT)))) {
caseCount = 0;
low = 0;
high = -1;
} else {
#define INTMAP_LENGTH 256
jsbitmap intmap_space[INTMAP_LENGTH];
jsbitmap *intmap = NULL;
int32 intmap_bitlen = 0;
low = JSVAL_INT_MAX;
high = JSVAL_INT_MIN;
for (pn3 = pn2->pn_head; pn3; pn3 = pn3->pn_next) {
if (pn3->pn_type == TOK_DEFAULT) {
hasDefault = JS_TRUE;
caseCount--; /* one of the "cases" was the default */
continue;
}
JS_ASSERT(pn3->pn_type == TOK_CASE);
if (switchOp == JSOP_CONDSWITCH)
continue;
pn4 = pn3->pn_left;
switch (pn4->pn_type) {
case TOK_NUMBER:
d = pn4->pn_dval;
if (JSDOUBLE_IS_INT(d, i) && INT_FITS_IN_JSVAL(i)) {
pn3->pn_val = INT_TO_JSVAL(i);
} else {
atom = js_AtomizeDouble(cx, d, 0);
if (!atom) {
ok = JS_FALSE;
goto release;
}
pn3->pn_val = ATOM_KEY(atom);
}
break;
case TOK_STRING:
pn3->pn_val = ATOM_KEY(pn4->pn_atom);
break;
case TOK_NAME:
if (!pn4->pn_expr) {
ok = js_LookupCompileTimeConstant(cx, cg, pn4->pn_atom, &v);
if (!ok)
goto release;
if (!JSVAL_IS_VOID(v)) {
pn3->pn_val = v;
constPropagated = JS_TRUE;
break;
}
}
/* FALL THROUGH */
case TOK_PRIMARY:
if (pn4->pn_op == JSOP_TRUE) {
pn3->pn_val = JSVAL_TRUE;
break;
}
if (pn4->pn_op == JSOP_FALSE) {
pn3->pn_val = JSVAL_FALSE;
break;
}
/* FALL THROUGH */
default:
switchOp = JSOP_CONDSWITCH;
continue;
}
JS_ASSERT(JSVAL_IS_NUMBER(pn3->pn_val) ||
JSVAL_IS_STRING(pn3->pn_val) ||
JSVAL_IS_BOOLEAN(pn3->pn_val));
if (switchOp != JSOP_TABLESWITCH)
continue;
if (!JSVAL_IS_INT(pn3->pn_val)) {
switchOp = JSOP_LOOKUPSWITCH;
continue;
}
i = JSVAL_TO_INT(pn3->pn_val);
if ((jsuint)(i + (jsint)JS_BIT(15)) >= (jsuint)JS_BIT(16)) {
switchOp = JSOP_LOOKUPSWITCH;
continue;
}
if (i < low)
low = i;
if (high < i)
high = i;
/*
* Check for duplicates, which require a JSOP_LOOKUPSWITCH.
* We bias i by 65536 if it's negative, and hope that's a rare
* case (because it requires a malloc'd bitmap).
*/
if (i < 0)
i += JS_BIT(16);
if (i >= intmap_bitlen) {
if (!intmap &&
i < (INTMAP_LENGTH << JS_BITS_PER_WORD_LOG2)) {
intmap = intmap_space;
intmap_bitlen = INTMAP_LENGTH << JS_BITS_PER_WORD_LOG2;
} else {
/* Just grab 8K for the worst-case bitmap. */
intmap_bitlen = JS_BIT(16);
intmap = (jsbitmap *)
JS_malloc(cx,
(JS_BIT(16) >> JS_BITS_PER_WORD_LOG2)
* sizeof(jsbitmap));
if (!intmap) {
JS_ReportOutOfMemory(cx);
return JS_FALSE;
}
}
memset(intmap, 0, intmap_bitlen >> JS_BITS_PER_BYTE_LOG2);
}
if (JS_TEST_BIT(intmap, i)) {
switchOp = JSOP_LOOKUPSWITCH;
continue;
}
JS_SET_BIT(intmap, i);
}
release:
if (intmap && intmap != intmap_space)
JS_free(cx, intmap);
if (!ok)
return JS_FALSE;
/*
* Compute table length and select lookup instead if overlarge or
* more than half-sparse.
*/
if (switchOp == JSOP_TABLESWITCH) {
tableLength = (uint32)(high - low + 1);
if (tableLength >= JS_BIT(16) || tableLength > 2 * caseCount)
switchOp = JSOP_LOOKUPSWITCH;
} else if (switchOp == JSOP_LOOKUPSWITCH) {
/*
* Lookup switch supports only atom indexes below 64K limit.
* Conservatively estimate the maximum possible index during
* switch generation and use conditional switch if it exceeds
* the limit.
*/
if (caseCount + cg->atomList.count > JS_BIT(16))
switchOp = JSOP_CONDSWITCH;
}
}
/*
* Emit a note with two offsets: first tells total switch code length,
* second tells offset to first JSOP_CASE if condswitch.
*/
noteIndex = js_NewSrcNote3(cx, cg, SRC_SWITCH, 0, 0);
if (noteIndex < 0)
return JS_FALSE;
if (switchOp == JSOP_CONDSWITCH) {
/*
* 0 bytes of immediate for unoptimized ECMAv2 switch.
*/
switchSize = 0;
} else if (switchOp == JSOP_TABLESWITCH) {
/*
* 3 offsets (len, low, high) before the table, 1 per entry.
*/
switchSize = (size_t)(JUMP_OFFSET_LEN * (3 + tableLength));
} else {
/*
* JSOP_LOOKUPSWITCH:
* 1 offset (len) and 1 atom index (npairs) before the table,
* 1 atom index and 1 jump offset per entry.
*/
switchSize = (size_t)(JUMP_OFFSET_LEN + ATOM_INDEX_LEN +
(ATOM_INDEX_LEN + JUMP_OFFSET_LEN) * caseCount);
}
/*
* Emit switchOp followed by switchSize bytes of jump or lookup table.
*
* If switchOp is JSOP_LOOKUPSWITCH or JSOP_TABLESWITCH, it is crucial
* to emit the immediate operand(s) by which bytecode readers such as
* BuildSpanDepTable discover the length of the switch opcode *before*
* calling js_SetJumpOffset (which may call BuildSpanDepTable). It's
* also important to zero all unknown jump offset immediate operands,
* so they can be converted to span dependencies with null targets to
* be computed later (js_EmitN zeros switchSize bytes after switchOp).
*/
if (js_EmitN(cx, cg, switchOp, switchSize) < 0)
return JS_FALSE;
off = -1;
if (switchOp == JSOP_CONDSWITCH) {
intN caseNoteIndex = -1;
JSBool beforeCases = JS_TRUE;
/* Emit code for evaluating cases and jumping to case statements. */
for (pn3 = pn2->pn_head; pn3; pn3 = pn3->pn_next) {
pn4 = pn3->pn_left;
if (pn4 && !js_EmitTree(cx, cg, pn4))
return JS_FALSE;
if (caseNoteIndex >= 0) {
/* off is the previous JSOP_CASE's bytecode offset. */
if (!js_SetSrcNoteOffset(cx, cg, (uintN)caseNoteIndex, 0,
CG_OFFSET(cg) - off)) {
return JS_FALSE;
}
}
if (!pn4) {
JS_ASSERT(pn3->pn_type == TOK_DEFAULT);
continue;
}
caseNoteIndex = js_NewSrcNote2(cx, cg, SRC_PCDELTA, 0);
if (caseNoteIndex < 0)
return JS_FALSE;
off = EmitJump(cx, cg, JSOP_CASE, 0);
if (off < 0)
return JS_FALSE;
pn3->pn_offset = off;
if (beforeCases) {
uintN noteCount, noteCountDelta;
/* Switch note's second offset is to first JSOP_CASE. */
noteCount = CG_NOTE_COUNT(cg);
if (!js_SetSrcNoteOffset(cx, cg, (uintN)noteIndex, 1,
off - top)) {
return JS_FALSE;
}
noteCountDelta = CG_NOTE_COUNT(cg) - noteCount;
if (noteCountDelta != 0)
caseNoteIndex += noteCountDelta;
beforeCases = JS_FALSE;
}
}
/*
* If we didn't have an explicit default (which could fall in between
* cases, preventing us from fusing this js_SetSrcNoteOffset with the
* call in the loop above), link the last case to the implicit default
* for the decompiler.
*/
if (!hasDefault &&
caseNoteIndex >= 0 &&
!js_SetSrcNoteOffset(cx, cg, (uintN)caseNoteIndex, 0,
CG_OFFSET(cg) - off)) {
return JS_FALSE;
}
/* Emit default even if no explicit default statement. */
defaultOffset = EmitJump(cx, cg, JSOP_DEFAULT, 0);
if (defaultOffset < 0)
return JS_FALSE;
} else {
pc = CG_CODE(cg, top + JUMP_OFFSET_LEN);
if (switchOp == JSOP_TABLESWITCH) {
/* Fill in switch bounds, which we know fit in 16-bit offsets. */
SET_JUMP_OFFSET(pc, low);
pc += JUMP_OFFSET_LEN;
SET_JUMP_OFFSET(pc, high);
pc += JUMP_OFFSET_LEN;
/*
* Use malloc to avoid arena bloat for programs with many switches.
* We free table if non-null at label out, so all control flow must
* exit this function through goto out or goto bad.
*/
if (tableLength != 0) {
tableSize = (size_t)tableLength * sizeof *table;
table = (JSParseNode **) JS_malloc(cx, tableSize);
if (!table)
return JS_FALSE;
memset(table, 0, tableSize);
for (pn3 = pn2->pn_head; pn3; pn3 = pn3->pn_next) {
if (pn3->pn_type == TOK_DEFAULT)
continue;
i = JSVAL_TO_INT(pn3->pn_val);
i -= low;
JS_ASSERT((uint32)i < tableLength);
table[i] = pn3;
}
}
} else {
JS_ASSERT(switchOp == JSOP_LOOKUPSWITCH);
/* Fill in the number of cases. */
SET_ATOM_INDEX(pc, caseCount);
pc += ATOM_INDEX_LEN;
}
/*
* After this point, all control flow involving JSOP_TABLESWITCH
* must set ok and goto out to exit this function. To keep things
* simple, all switchOp cases exit that way.
*/
if (cg->spanDeps) {
/*
* We have already generated at least one big jump so we must
* explicitly add span dependencies for the switch jumps. When
* called below, js_SetJumpOffset can only do it when patching
* the first big jump or when cg->spanDeps is null.
*/
if (!AddSwitchSpanDeps(cx, cg, CG_CODE(cg, top)))
goto bad;
}
if (constPropagated) {
/*
* Skip switchOp, as we are not setting jump offsets in the two
* for loops below. We'll restore CG_NEXT(cg) from savepc after,
* unless there was an error.
*/
savepc = CG_NEXT(cg);
CG_NEXT(cg) = pc + 1;
if (switchOp == JSOP_TABLESWITCH) {
for (i = 0; i < (jsint)tableLength; i++) {
pn3 = table[i];
if (pn3 &&
(pn4 = pn3->pn_left) != NULL &&
pn4->pn_type == TOK_NAME) {
/* Note a propagated constant with the const's name. */
JS_ASSERT(!pn4->pn_expr);
ale = js_IndexAtom(cx, pn4->pn_atom, &cg->atomList);
if (!ale)
goto bad;
CG_NEXT(cg) = pc;
if (js_NewSrcNote2(cx, cg, SRC_LABEL, (ptrdiff_t)
ALE_INDEX(ale)) < 0) {
goto bad;
}
}
pc += JUMP_OFFSET_LEN;
}
} else {
for (pn3 = pn2->pn_head; pn3; pn3 = pn3->pn_next) {
pn4 = pn3->pn_left;
if (pn4 && pn4->pn_type == TOK_NAME) {
/* Note a propagated constant with the const's name. */
JS_ASSERT(!pn4->pn_expr);
ale = js_IndexAtom(cx, pn4->pn_atom, &cg->atomList);
if (!ale)
goto bad;
CG_NEXT(cg) = pc;
if (js_NewSrcNote2(cx, cg, SRC_LABEL, (ptrdiff_t)
ALE_INDEX(ale)) < 0) {
goto bad;
}
}
pc += ATOM_INDEX_LEN + JUMP_OFFSET_LEN;
}
}
CG_NEXT(cg) = savepc;
}
}
/* Emit code for each case's statements, copying pn_offset up to pn3. */
for (pn3 = pn2->pn_head; pn3; pn3 = pn3->pn_next) {
if (switchOp == JSOP_CONDSWITCH && pn3->pn_type != TOK_DEFAULT)
CHECK_AND_SET_JUMP_OFFSET_AT(cx, cg, pn3->pn_offset);
pn4 = pn3->pn_right;
ok = js_EmitTree(cx, cg, pn4);
if (!ok)
goto out;
pn3->pn_offset = pn4->pn_offset;
if (pn3->pn_type == TOK_DEFAULT)
off = pn3->pn_offset - top;
}
if (!hasDefault) {
/* If no default case, offset for default is to end of switch. */
off = CG_OFFSET(cg) - top;
}
/* We better have set "off" by now. */
JS_ASSERT(off != -1);
/* Set the default offset (to end of switch if no default). */
if (switchOp == JSOP_CONDSWITCH) {
pc = NULL;
JS_ASSERT(defaultOffset != -1);
ok = js_SetJumpOffset(cx, cg, CG_CODE(cg, defaultOffset),
off - (defaultOffset - top));
if (!ok)
goto out;
} else {
pc = CG_CODE(cg, top);
ok = js_SetJumpOffset(cx, cg, pc, off);
if (!ok)
goto out;
pc += JUMP_OFFSET_LEN;
}
/* Set the SRC_SWITCH note's offset operand to tell end of switch. */
off = CG_OFFSET(cg) - top;
ok = js_SetSrcNoteOffset(cx, cg, (uintN)noteIndex, 0, off);
if (!ok)
goto out;
if (switchOp == JSOP_TABLESWITCH) {
/* Skip over the already-initialized switch bounds. */
pc += 2 * JUMP_OFFSET_LEN;
/* Fill in the jump table, if there is one. */
for (i = 0; i < (jsint)tableLength; i++) {
pn3 = table[i];
off = pn3 ? pn3->pn_offset - top : 0;
ok = js_SetJumpOffset(cx, cg, pc, off);
if (!ok)
goto out;
pc += JUMP_OFFSET_LEN;
}
} else if (switchOp == JSOP_LOOKUPSWITCH) {
/* Skip over the already-initialized number of cases. */
pc += ATOM_INDEX_LEN;
for (pn3 = pn2->pn_head; pn3; pn3 = pn3->pn_next) {
if (pn3->pn_type == TOK_DEFAULT)
continue;
atom = js_AtomizeValue(cx, pn3->pn_val, 0);
if (!atom)
goto bad;
ale = js_IndexAtom(cx, atom, &cg->atomList);
if (!ale)
goto bad;
SET_ATOM_INDEX(pc, ALE_INDEX(ale));
pc += ATOM_INDEX_LEN;
off = pn3->pn_offset - top;
ok = js_SetJumpOffset(cx, cg, pc, off);
if (!ok)
goto out;
pc += JUMP_OFFSET_LEN;
}
}
out:
if (table)
JS_free(cx, table);
if (ok) {
ok = js_PopStatementCG(cx, cg);
#if JS_HAS_BLOCK_SCOPE
if (ok && pn->pn_right->pn_type == TOK_LEXICALSCOPE) {
EMIT_UINT16_IMM_OP(JSOP_LEAVEBLOCK, count);
cg->stackDepth -= count;
}
#endif
}
return ok;
bad:
ok = JS_FALSE;
goto out;
}
JSBool
js_EmitFunctionBytecode(JSContext *cx, JSCodeGenerator *cg, JSParseNode *body)
{
if (!js_AllocTryNotes(cx, cg))
return JS_FALSE;
if (cg->treeContext.flags & TCF_FUN_IS_GENERATOR) {
/* JSOP_GENERATOR must be the first instruction. */
CG_SWITCH_TO_PROLOG(cg);
JS_ASSERT(CG_NEXT(cg) == CG_BASE(cg));
if (js_Emit1(cx, cg, JSOP_GENERATOR) < 0)
return JS_FALSE;
CG_SWITCH_TO_MAIN(cg);
}
return js_EmitTree(cx, cg, body) &&
js_Emit1(cx, cg, JSOP_STOP) >= 0;
}
JSBool
js_EmitFunctionBody(JSContext *cx, JSCodeGenerator *cg, JSParseNode *body,
JSFunction *fun)
{
JSStackFrame *fp, frame;
JSObject *funobj;
JSBool ok;
fp = cx->fp;
funobj = fun->object;
JS_ASSERT(!fp || (fp->fun != fun && fp->varobj != funobj &&
fp->scopeChain != funobj));
memset(&frame, 0, sizeof frame);
frame.fun = fun;
frame.varobj = frame.scopeChain = funobj;
frame.down = fp;
frame.flags = JS_HAS_COMPILE_N_GO_OPTION(cx)
? JSFRAME_COMPILING | JSFRAME_COMPILE_N_GO
: JSFRAME_COMPILING;
cx->fp = &frame;
ok = js_EmitFunctionBytecode(cx, cg, body);
cx->fp = fp;
if (!ok)
return JS_FALSE;
if (!js_NewScriptFromCG(cx, cg, fun))
return JS_FALSE;
JS_ASSERT(FUN_INTERPRETED(fun));
return JS_TRUE;
}
/* A macro for inlining at the top of js_EmitTree (whence it came). */
#define UPDATE_LINE_NUMBER_NOTES(cx, cg, pn) \
JS_BEGIN_MACRO \
uintN line_ = (pn)->pn_pos.begin.lineno; \
uintN delta_ = line_ - CG_CURRENT_LINE(cg); \
if (delta_ != 0) { \
/* \
* Encode any change in the current source line number by using \
* either several SRC_NEWLINE notes or just one SRC_SETLINE note, \
* whichever consumes less space. \
* \
* NB: We handle backward line number deltas (possible with for \
* loops where the update part is emitted after the body, but its \
* line number is <= any line number in the body) here by letting \
* unsigned delta_ wrap to a very large number, which triggers a \
* SRC_SETLINE. \
*/ \
CG_CURRENT_LINE(cg) = line_; \
if (delta_ >= (uintN)(2 + ((line_ > SN_3BYTE_OFFSET_MASK)<<1))) { \
if (js_NewSrcNote2(cx, cg, SRC_SETLINE, (ptrdiff_t)line_) < 0)\
return JS_FALSE; \
} else { \
do { \
if (js_NewSrcNote(cx, cg, SRC_NEWLINE) < 0) \
return JS_FALSE; \
} while (--delta_ != 0); \
} \
} \
JS_END_MACRO
/* A function, so that we avoid macro-bloating all the other callsites. */
static JSBool
UpdateLineNumberNotes(JSContext *cx, JSCodeGenerator *cg, JSParseNode *pn)
{
UPDATE_LINE_NUMBER_NOTES(cx, cg, pn);
return JS_TRUE;
}
static JSBool
MaybeEmitVarDecl(JSContext *cx, JSCodeGenerator *cg, JSOp prologOp,
JSParseNode *pn, jsatomid *result)
{
jsatomid atomIndex;
JSAtomListElement *ale;
if (pn->pn_slot >= 0) {
atomIndex = (jsatomid) pn->pn_slot;
} else {
ale = js_IndexAtom(cx, pn->pn_atom, &cg->atomList);
if (!ale)
return JS_FALSE;
atomIndex = ALE_INDEX(ale);
}
if ((js_CodeSpec[pn->pn_op].format & JOF_TYPEMASK) == JOF_CONST &&
(!(cg->treeContext.flags & TCF_IN_FUNCTION) ||
(cg->treeContext.flags & TCF_FUN_HEAVYWEIGHT))) {
/* Emit a prolog bytecode to predefine the variable. */
CG_SWITCH_TO_PROLOG(cg);
if (!UpdateLineNumberNotes(cx, cg, pn))
return JS_FALSE;
EMIT_ATOM_INDEX_OP(prologOp, atomIndex);
CG_SWITCH_TO_MAIN(cg);
}
if (result)
*result = atomIndex;
return JS_TRUE;
}
#if JS_HAS_DESTRUCTURING
typedef JSBool
(*DestructuringDeclEmitter)(JSContext *cx, JSCodeGenerator *cg, JSOp prologOp,
JSParseNode *pn);
static JSBool
EmitDestructuringDecl(JSContext *cx, JSCodeGenerator *cg, JSOp prologOp,
JSParseNode *pn)
{
JS_ASSERT(pn->pn_type == TOK_NAME);
if (!BindNameToSlot(cx, &cg->treeContext, pn, prologOp == JSOP_NOP))
return JS_FALSE;
JS_ASSERT(pn->pn_op != JSOP_ARGUMENTS);
return MaybeEmitVarDecl(cx, cg, prologOp, pn, NULL);
}
static JSBool
EmitDestructuringDecls(JSContext *cx, JSCodeGenerator *cg, JSOp prologOp,
JSParseNode *pn)
{
JSParseNode *pn2, *pn3;
DestructuringDeclEmitter emitter;
if (pn->pn_type == TOK_RB) {
for (pn2 = pn->pn_head; pn2; pn2 = pn2->pn_next) {
if (pn2->pn_type == TOK_COMMA)
continue;
emitter = (pn2->pn_type == TOK_NAME)
? EmitDestructuringDecl
: EmitDestructuringDecls;
if (!emitter(cx, cg, prologOp, pn2))
return JS_FALSE;
}
} else {
JS_ASSERT(pn->pn_type == TOK_RC);
for (pn2 = pn->pn_head; pn2; pn2 = pn2->pn_next) {
pn3 = pn2->pn_right;
emitter = (pn3->pn_type == TOK_NAME)
? EmitDestructuringDecl
: EmitDestructuringDecls;
if (!emitter(cx, cg, prologOp, pn3))
return JS_FALSE;
}
}
return JS_TRUE;
}
static JSBool
EmitDestructuringOpsHelper(JSContext *cx, JSCodeGenerator *cg, JSParseNode *pn);
static JSBool
EmitDestructuringLHS(JSContext *cx, JSCodeGenerator *cg, JSParseNode *pn,
JSBool wantpop)
{
jsuint slot;
/* Skip any parenthesization. */
while (pn->pn_type == TOK_RP)
pn = pn->pn_kid;
/*
* Now emit the lvalue opcode sequence. If the lvalue is a nested
* destructuring initialiser-form, call ourselves to handle it, then
* pop the matched value. Otherwise emit an lvalue bytecode sequence
* ending with a JSOP_ENUMELEM or equivalent op.
*/
if (pn->pn_type == TOK_RB || pn->pn_type == TOK_RC) {
if (!EmitDestructuringOpsHelper(cx, cg, pn))
return JS_FALSE;
if (wantpop && js_Emit1(cx, cg, JSOP_POP) < 0)
return JS_FALSE;
} else {
if (pn->pn_type == TOK_NAME &&
!BindNameToSlot(cx, &cg->treeContext, pn, JS_FALSE)) {
return JS_FALSE;
}
switch (pn->pn_op) {
case JSOP_SETNAME:
/*
* NB: pn is a PN_NAME node, not a PN_BINARY. Nevertheless,
* we want to emit JSOP_ENUMELEM, which has format JOF_ELEM.
* So here and for JSOP_ENUMCONSTELEM, we use EmitElemOp.
*/
if (!EmitElemOp(cx, pn, JSOP_ENUMELEM, cg))
return JS_FALSE;
break;
case JSOP_SETCONST:
if (!EmitElemOp(cx, pn, JSOP_ENUMCONSTELEM, cg))
return JS_FALSE;
break;
case JSOP_SETLOCAL:
if (wantpop) {
slot = (jsuint) pn->pn_slot;
EMIT_UINT16_IMM_OP(JSOP_SETLOCALPOP, slot);
break;
}
/* FALL THROUGH */
case JSOP_SETARG:
case JSOP_SETVAR:
case JSOP_SETGVAR:
slot = (jsuint) pn->pn_slot;
EMIT_UINT16_IMM_OP(pn->pn_op, slot);
if (wantpop && js_Emit1(cx, cg, JSOP_POP) < 0)
return JS_FALSE;
break;
default:
#if JS_HAS_LVALUE_RETURN || JS_HAS_XML_SUPPORT
{
ptrdiff_t top;
top = CG_OFFSET(cg);
if (!js_EmitTree(cx, cg, pn))
return JS_FALSE;
if (js_NewSrcNote2(cx, cg, SRC_PCBASE, CG_OFFSET(cg) - top) < 0)
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_ENUMELEM) < 0)
return JS_FALSE;
break;
}
#endif
case JSOP_ENUMELEM:
JS_ASSERT(0);
}
}
return JS_TRUE;
}
/*
* Recursive helper for EmitDestructuringOps.
*
* Given a value to destructure on the stack, walk over an object or array
* initialiser at pn, emitting bytecodes to match property values and store
* them in the lvalues identified by the matched property names.
*/
static JSBool
EmitDestructuringOpsHelper(JSContext *cx, JSCodeGenerator *cg, JSParseNode *pn)
{
jsuint index;
JSParseNode *pn2, *pn3;
JSBool doElemOp;
#ifdef DEBUG
intN stackDepth = cg->stackDepth;
JS_ASSERT(stackDepth != 0);
JS_ASSERT(pn->pn_arity == PN_LIST);
JS_ASSERT(pn->pn_type == TOK_RB || pn->pn_type == TOK_RC);
#endif
if (pn->pn_count == 0) {
/* Emit a DUP;POP sequence for the decompiler. */
return js_Emit1(cx, cg, JSOP_DUP) >= 0 &&
js_Emit1(cx, cg, JSOP_POP) >= 0;
}
index = 0;
for (pn2 = pn->pn_head; pn2; pn2 = pn2->pn_next) {
/*
* Duplicate the value being destructured to use as a reference base.
*/
if (js_Emit1(cx, cg, JSOP_DUP) < 0)
return JS_FALSE;
/*
* Now push the property name currently being matched, which is either
* the array initialiser's current index, or the current property name
* "label" on the left of a colon in the object initialiser. Set pn3
* to the lvalue node, which is in the value-initializing position.
*/
doElemOp = JS_TRUE;
if (pn->pn_type == TOK_RB) {
if (!EmitNumberOp(cx, index, cg))
return JS_FALSE;
pn3 = pn2;
} else {
JS_ASSERT(pn->pn_type == TOK_RC);
JS_ASSERT(pn2->pn_type == TOK_COLON);
pn3 = pn2->pn_left;
if (pn3->pn_type == TOK_NUMBER) {
/*
* If we are emitting an object destructuring initialiser,
* annotate the index op with SRC_INITPROP so we know we are
* not decompiling an array initialiser.
*/
if (js_NewSrcNote(cx, cg, SRC_INITPROP) < 0)
return JS_FALSE;
if (!EmitNumberOp(cx, pn3->pn_dval, cg))
return JS_FALSE;
} else {
JS_ASSERT(pn3->pn_type == TOK_STRING ||
pn3->pn_type == TOK_NAME);
if (!EmitAtomOp(cx, pn3, JSOP_GETPROP, cg))
return JS_FALSE;
doElemOp = JS_FALSE;
}
pn3 = pn2->pn_right;
}
if (doElemOp) {
/*
* Ok, get the value of the matching property name. This leaves
* that value on top of the value being destructured, so the stack
* is one deeper than when we started.
*/
if (js_Emit1(cx, cg, JSOP_GETELEM) < 0)
return JS_FALSE;
JS_ASSERT(cg->stackDepth == stackDepth + 1);
}
/* Nullary comma node makes a hole in the array destructurer. */
if (pn3->pn_type == TOK_COMMA && pn3->pn_arity == PN_NULLARY) {
JS_ASSERT(pn->pn_type == TOK_RB);
JS_ASSERT(pn2 == pn3);
if (js_Emit1(cx, cg, JSOP_POP) < 0)
return JS_FALSE;
} else {
if (!EmitDestructuringLHS(cx, cg, pn3, JS_TRUE))
return JS_FALSE;
}
JS_ASSERT(cg->stackDepth == stackDepth);
++index;
}
return JS_TRUE;
}
static ptrdiff_t
OpToDeclType(JSOp op)
{
switch (op) {
case JSOP_NOP:
return SRC_DECL_LET;
case JSOP_DEFCONST:
return SRC_DECL_CONST;
case JSOP_DEFVAR:
return SRC_DECL_VAR;
default:
return SRC_DECL_NONE;
}
}
static JSBool
EmitDestructuringOps(JSContext *cx, JSCodeGenerator *cg, JSOp declOp,
JSParseNode *pn)
{
/*
* If we're called from a variable declaration, help the decompiler by
* annotating the first JSOP_DUP that EmitDestructuringOpsHelper emits.
* If the destructuring initialiser is empty, our helper will emit a
* JSOP_DUP followed by a JSOP_POP for the decompiler.
*/
if (js_NewSrcNote2(cx, cg, SRC_DESTRUCT, OpToDeclType(declOp)) < 0)
return JS_FALSE;
/*
* Call our recursive helper to emit the destructuring assignments and
* related stack manipulations.
*/
return EmitDestructuringOpsHelper(cx, cg, pn);
}
static JSBool
EmitGroupAssignment(JSContext *cx, JSCodeGenerator *cg, JSOp declOp,
JSParseNode *lhs, JSParseNode *rhs)
{
jsuint depth, limit, slot;
JSParseNode *pn;
depth = limit = (uintN) cg->stackDepth;
for (pn = rhs->pn_head; pn; pn = pn->pn_next) {
if (limit == JS_BIT(16)) {
js_ReportCompileErrorNumber(cx, rhs,
JSREPORT_PN | JSREPORT_ERROR,
JSMSG_ARRAY_INIT_TOO_BIG);
return JS_FALSE;
}
if (pn->pn_type == TOK_COMMA) {
if (js_Emit1(cx, cg, JSOP_PUSH) < 0)
return JS_FALSE;
} else {
JS_ASSERT(pn->pn_type != TOK_DEFSHARP);
if (!js_EmitTree(cx, cg, pn))
return JS_FALSE;
}
++limit;
}
if (js_NewSrcNote2(cx, cg, SRC_GROUPASSIGN, OpToDeclType(declOp)) < 0)
return JS_FALSE;
slot = depth;
for (pn = lhs->pn_head; pn; pn = pn->pn_next) {
if (slot < limit) {
EMIT_UINT16_IMM_OP(JSOP_GETLOCAL, slot);
} else {
if (js_Emit1(cx, cg, JSOP_PUSH) < 0)
return JS_FALSE;
}
if (pn->pn_type == TOK_COMMA && pn->pn_arity == PN_NULLARY) {
if (js_Emit1(cx, cg, JSOP_POP) < 0)
return JS_FALSE;
} else {
if (!EmitDestructuringLHS(cx, cg, pn, pn->pn_next != NULL))
return JS_FALSE;
}
++slot;
}
EMIT_UINT16_IMM_OP(JSOP_SETSP, (jsatomid)depth);
cg->stackDepth = (uintN) depth;
return JS_TRUE;
}
/*
* Helper called with pop out param initialized to a JSOP_POP* opcode. If we
* can emit a group assignment sequence, which results in 0 stack depth delta,
* we set *pop to JSOP_NOP so callers can veto emitting pn followed by a pop.
*/
static JSBool
MaybeEmitGroupAssignment(JSContext *cx, JSCodeGenerator *cg, JSOp declOp,
JSParseNode *pn, JSOp *pop)
{
JSParseNode *lhs, *rhs;
JS_ASSERT(pn->pn_type == TOK_ASSIGN);
JS_ASSERT(*pop == JSOP_POP || *pop == JSOP_POPV);
lhs = pn->pn_left;
rhs = pn->pn_right;
if (lhs->pn_type == TOK_RB && rhs->pn_type == TOK_RB &&
lhs->pn_count <= rhs->pn_count &&
(rhs->pn_count == 0 ||
rhs->pn_head->pn_type != TOK_DEFSHARP)) {
if (!EmitGroupAssignment(cx, cg, declOp, lhs, rhs))
return JS_FALSE;
*pop = JSOP_NOP;
}
return JS_TRUE;
}
#endif /* JS_HAS_DESTRUCTURING */
static JSBool
EmitVariables(JSContext *cx, JSCodeGenerator *cg, JSParseNode *pn,
JSBool inLetHead, ptrdiff_t *headNoteIndex)
{
JSTreeContext *tc;
JSBool let, forInVar;
#if JS_HAS_BLOCK_SCOPE
JSBool forInLet, popScope;
JSStmtInfo *stmt, *scopeStmt;
#endif
ptrdiff_t off, noteIndex, tmp;
JSParseNode *pn2, *pn3;
JSOp op;
jsatomid atomIndex;
uintN oldflags;
/* Default in case of JS_HAS_BLOCK_SCOPE early return, below. */
*headNoteIndex = -1;
/*
* Let blocks and expressions have a parenthesized head in which the new
* scope is not yet open. Initializer evaluation uses the parent node's
* lexical scope. If popScope is true below, then we hide the top lexical
* block from any calls to BindNameToSlot hiding in pn2->pn_expr so that
* it won't find any names in the new let block.
*
* The same goes for let declarations in the head of any kind of for loop.
* Unlike a let declaration 'let x = i' within a block, where x is hoisted
* to the start of the block, a 'for (let x = i...) ...' loop evaluates i
* in the containing scope, and puts x in the loop body's scope.
*/
tc = &cg->treeContext;
let = (pn->pn_op == JSOP_NOP);
forInVar = (pn->pn_extra & PNX_FORINVAR) != 0;
#if JS_HAS_BLOCK_SCOPE
forInLet = let && forInVar;
popScope = (inLetHead || (let && (tc->flags & TCF_IN_FOR_INIT)));
JS_ASSERT(!popScope || let);
#endif
off = noteIndex = -1;
for (pn2 = pn->pn_head; ; pn2 = pn2->pn_next) {
#if JS_HAS_DESTRUCTURING
if (pn2->pn_type != TOK_NAME) {
if (pn2->pn_type == TOK_RB || pn2->pn_type == TOK_RC) {
/*
* Emit variable binding ops, but not destructuring ops.
* The parser (see Variables, jsparse.c) has ensured that
* our caller will be the TOK_FOR/TOK_IN case in js_EmitTree,
* and that case will emit the destructuring code only after
* emitting an enumerating opcode and a branch that tests
* whether the enumeration ended.
*/
JS_ASSERT(forInVar);
JS_ASSERT(pn->pn_count == 1);
if (!EmitDestructuringDecls(cx, cg, pn->pn_op, pn2))
return JS_FALSE;
break;
}
/*
* A destructuring initialiser assignment preceded by var is
* always evaluated promptly, even if it is to the left of 'in'
* in a for-in loop. As with 'for (var x = i in o)...', this
* will cause the entire 'var [a, b] = i' to be hoisted out of
* the head of the loop.
*/
JS_ASSERT(pn2->pn_type == TOK_ASSIGN);
if (pn->pn_count == 1 && !forInLet) {
/*
* If this is the only destructuring assignment in the list,
* try to optimize to a group assignment. If we're in a let
* head, pass JSOP_POP rather than the pseudo-prolog JSOP_NOP
* in pn->pn_op, to suppress a second (and misplaced) 'let'.
*/
JS_ASSERT(noteIndex < 0 && !pn2->pn_next);
op = JSOP_POP;
if (!MaybeEmitGroupAssignment(cx, cg,
inLetHead ? JSOP_POP : pn->pn_op,
pn2, &op)) {
return JS_FALSE;
}
if (op == JSOP_NOP) {
pn->pn_extra = (pn->pn_extra & ~PNX_POPVAR) | PNX_GROUPINIT;
break;
}
}
pn3 = pn2->pn_left;
if (!EmitDestructuringDecls(cx, cg, pn->pn_op, pn3))
return JS_FALSE;
#if JS_HAS_BLOCK_SCOPE
/*
* If this is a 'for (let [x, y] = i in o) ...' let declaration,
* throw away i if it is a useless expression.
*/
if (forInLet) {
JSBool useful = JS_FALSE;
JS_ASSERT(pn->pn_count == 1);
if (!CheckSideEffects(cx, tc, pn2->pn_right, &useful))
return JS_FALSE;
if (!useful)
return JS_TRUE;
}
#endif
if (!js_EmitTree(cx, cg, pn2->pn_right))
return JS_FALSE;
#if JS_HAS_BLOCK_SCOPE
/*
* The expression i in 'for (let [x, y] = i in o) ...', which is
* pn2->pn_right above, appears to have side effects. We've just
* emitted code to evaluate i, but we must not destructure i yet.
* Let the TOK_FOR: code in js_EmitTree do the destructuring to
* emit the right combination of source notes and bytecode for the
* decompiler.
*
* This has the effect of hoisting the evaluation of i out of the
* for-in loop, without hoisting the let variables, which must of
* course be scoped by the loop. Set PNX_POPVAR to cause JSOP_POP
* to be emitted, just before returning from this function.
*/
if (forInVar) {
pn->pn_extra |= PNX_POPVAR;
if (forInLet)
break;
}
#endif
/*
* Veto pn->pn_op if inLetHead to avoid emitting a SRC_DESTRUCT
* that's redundant with respect to the SRC_DECL/SRC_DECL_LET that
* we will emit at the bottom of this function.
*/
if (!EmitDestructuringOps(cx, cg,
inLetHead ? JSOP_POP : pn->pn_op,
pn3)) {
return JS_FALSE;
}
goto emit_note_pop;
}
#else
JS_ASSERT(pn2->pn_type == TOK_NAME);
#endif
if (!BindNameToSlot(cx, &cg->treeContext, pn2, let))
return JS_FALSE;
JS_ASSERT(pn2->pn_slot >= 0 || !let);
op = pn2->pn_op;
if (op == JSOP_ARGUMENTS) {
/* JSOP_ARGUMENTS => no initializer */
JS_ASSERT(!pn2->pn_expr && !let);
pn3 = NULL;
#ifdef __GNUC__
atomIndex = 0; /* quell GCC overwarning */
#endif
} else {
if (!MaybeEmitVarDecl(cx, cg, pn->pn_op, pn2, &atomIndex))
return JS_FALSE;
pn3 = pn2->pn_expr;
if (pn3) {
#if JS_HAS_BLOCK_SCOPE
/*
* If this is a 'for (let x = i in o) ...' let declaration,
* throw away i if it is a useless expression.
*/
if (forInLet) {
JSBool useful = JS_FALSE;
JS_ASSERT(pn->pn_count == 1);
if (!CheckSideEffects(cx, tc, pn3, &useful))
return JS_FALSE;
if (!useful)
return JS_TRUE;
}
#endif
if (op == JSOP_SETNAME) {
JS_ASSERT(!let);
EMIT_ATOM_INDEX_OP(JSOP_BINDNAME, atomIndex);
}
if (pn->pn_op == JSOP_DEFCONST &&
!js_DefineCompileTimeConstant(cx, cg, pn2->pn_atom,
pn3)) {
return JS_FALSE;
}
#if JS_HAS_BLOCK_SCOPE
/* Evaluate expr in the outer lexical scope if requested. */
if (popScope) {
stmt = tc->topStmt;
scopeStmt = tc->topScopeStmt;
tc->topStmt = stmt->down;
tc->topScopeStmt = scopeStmt->downScope;
}
#ifdef __GNUC__
else {
stmt = scopeStmt = NULL; /* quell GCC overwarning */
}
#endif
#endif
oldflags = cg->treeContext.flags;
cg->treeContext.flags &= ~TCF_IN_FOR_INIT;
if (!js_EmitTree(cx, cg, pn3))
return JS_FALSE;
cg->treeContext.flags |= oldflags & TCF_IN_FOR_INIT;
#if JS_HAS_BLOCK_SCOPE
if (popScope) {
tc->topStmt = stmt;
tc->topScopeStmt = scopeStmt;
}
#endif
}
}
/*
* 'for (var x in o) ...' and 'for (var x = i in o) ...' call the
* TOK_VAR case, but only the initialized case (a strange one that
* falls out of ECMA-262's grammar) wants to run past this point.
* Both cases must conditionally emit a JSOP_DEFVAR, above. Note
* that the parser error-checks to ensure that pn->pn_count is 1.
*
* 'for (let x = i in o) ...' must evaluate i before the loop, and
* subject it to useless expression elimination. The variable list
* in pn is a single let declaration if pn_op == JSOP_NOP. We test
* the let local in order to break early in this case, as well as in
* the 'for (var x in o)' case.
*
* XXX Narcissus keeps track of variable declarations in the node
* for the script being compiled, so there's no need to share any
* conditional prolog code generation there. We could do likewise,
* but it's a big change, requiring extra allocation, so probably
* not worth the trouble for SpiderMonkey.
*/
JS_ASSERT(pn3 == pn2->pn_expr);
if (forInVar && (!pn3 || let)) {
JS_ASSERT(pn->pn_count == 1);
break;
}
if (pn2 == pn->pn_head &&
!inLetHead &&
js_NewSrcNote2(cx, cg, SRC_DECL,
(pn->pn_op == JSOP_DEFCONST)
? SRC_DECL_CONST
: (pn->pn_op == JSOP_DEFVAR)
? SRC_DECL_VAR
: SRC_DECL_LET) < 0) {
return JS_FALSE;
}
if (op == JSOP_ARGUMENTS) {
if (js_Emit1(cx, cg, op) < 0)
return JS_FALSE;
} else if (pn2->pn_slot >= 0) {
EMIT_UINT16_IMM_OP(op, atomIndex);
} else {
EMIT_ATOM_INDEX_OP(op, atomIndex);
}
#if JS_HAS_DESTRUCTURING
emit_note_pop:
#endif
tmp = CG_OFFSET(cg);
if (noteIndex >= 0) {
if (!js_SetSrcNoteOffset(cx, cg, (uintN)noteIndex, 0, tmp-off))
return JS_FALSE;
}
if (!pn2->pn_next)
break;
off = tmp;
noteIndex = js_NewSrcNote2(cx, cg, SRC_PCDELTA, 0);
if (noteIndex < 0 || js_Emit1(cx, cg, JSOP_POP) < 0)
return JS_FALSE;
}
/* If this is a let head, emit and return a srcnote on the pop. */
if (inLetHead) {
*headNoteIndex = js_NewSrcNote(cx, cg, SRC_DECL);
if (*headNoteIndex < 0)
return JS_FALSE;
if (!(pn->pn_extra & PNX_POPVAR))
return js_Emit1(cx, cg, JSOP_NOP) >= 0;
}
return !(pn->pn_extra & PNX_POPVAR) || js_Emit1(cx, cg, JSOP_POP) >= 0;
}
#if defined DEBUG_brendan || defined DEBUG_mrbkap
static JSBool
GettableNoteForNextOp(JSCodeGenerator *cg)
{
ptrdiff_t offset, target;
jssrcnote *sn, *end;
offset = 0;
target = CG_OFFSET(cg);
for (sn = CG_NOTES(cg), end = sn + CG_NOTE_COUNT(cg); sn < end;
sn = SN_NEXT(sn)) {
if (offset == target && SN_IS_GETTABLE(sn))
return JS_TRUE;
offset += SN_DELTA(sn);
}
return JS_FALSE;
}
#endif
JSBool
js_EmitTree(JSContext *cx, JSCodeGenerator *cg, JSParseNode *pn)
{
JSBool ok, useful, wantval;
JSStmtInfo *stmt, stmtInfo;
ptrdiff_t top, off, tmp, beq, jmp;
JSParseNode *pn2, *pn3;
JSAtom *atom;
JSAtomListElement *ale;
jsatomid atomIndex;
ptrdiff_t noteIndex;
JSSrcNoteType noteType;
jsbytecode *pc;
JSOp op;
JSTokenType type;
uint32 argc;
int stackDummy;
if (!JS_CHECK_STACK_SIZE(cx, stackDummy)) {
JS_ReportErrorNumber(cx, js_GetErrorMessage, NULL, JSMSG_OVER_RECURSED);
return JS_FALSE;
}
ok = JS_TRUE;
cg->emitLevel++;
pn->pn_offset = top = CG_OFFSET(cg);
/* Emit notes to tell the current bytecode's source line number. */
UPDATE_LINE_NUMBER_NOTES(cx, cg, pn);
switch (pn->pn_type) {
case TOK_FUNCTION:
{
void *cg2mark;
JSCodeGenerator *cg2;
JSFunction *fun;
#if JS_HAS_XML_SUPPORT
if (pn->pn_arity == PN_NULLARY) {
if (js_Emit1(cx, cg, JSOP_GETFUNNS) < 0)
return JS_FALSE;
break;
}
#endif
/* Generate code for the function's body. */
cg2mark = JS_ARENA_MARK(cg->codePool);
JS_ARENA_ALLOCATE_TYPE(cg2, JSCodeGenerator, cg->codePool);
if (!cg2) {
JS_ReportOutOfMemory(cx);
return JS_FALSE;
}
if (!js_InitCodeGenerator(cx, cg2, cg->codePool, cg->notePool,
cg->filename, pn->pn_pos.begin.lineno,
cg->principals)) {
return JS_FALSE;
}
cg2->treeContext.flags = (uint16) (pn->pn_flags | TCF_IN_FUNCTION);
cg2->treeContext.tryCount = pn->pn_tryCount;
cg2->parent = cg;
fun = (JSFunction *) JS_GetPrivate(cx, ATOM_TO_OBJECT(pn->pn_funAtom));
if (!js_EmitFunctionBody(cx, cg2, pn->pn_body, fun))
return JS_FALSE;
/*
* We need an activation object if an inner peeks out, or if such
* inner-peeking caused one of our inners to become heavyweight.
*/
if (cg2->treeContext.flags &
(TCF_FUN_USES_NONLOCALS | TCF_FUN_HEAVYWEIGHT)) {
cg->treeContext.flags |= TCF_FUN_HEAVYWEIGHT;
}
js_FinishCodeGenerator(cx, cg2);
JS_ARENA_RELEASE(cg->codePool, cg2mark);
/* Make the function object a literal in the outer script's pool. */
ale = js_IndexAtom(cx, pn->pn_funAtom, &cg->atomList);
if (!ale)
return JS_FALSE;
atomIndex = ALE_INDEX(ale);
/* Emit a bytecode pointing to the closure object in its immediate. */
if (pn->pn_op != JSOP_NOP) {
EMIT_ATOM_INDEX_OP(pn->pn_op, atomIndex);
break;
}
/* Top-level named functions need a nop for decompilation. */
noteIndex = js_NewSrcNote2(cx, cg, SRC_FUNCDEF, (ptrdiff_t)atomIndex);
if (noteIndex < 0 ||
js_Emit1(cx, cg, JSOP_NOP) < 0) {
return JS_FALSE;
}
/*
* Top-levels also need a prolog op to predefine their names in the
* variable object, or if local, to fill their stack slots.
*/
CG_SWITCH_TO_PROLOG(cg);
if (cg->treeContext.flags & TCF_IN_FUNCTION) {
JSObject *obj, *pobj;
JSProperty *prop;
JSScopeProperty *sprop;
uintN slot;
obj = OBJ_GET_PARENT(cx, fun->object);
if (!js_LookupHiddenProperty(cx, obj, ATOM_TO_JSID(fun->atom),
&pobj, &prop)) {
return JS_FALSE;
}
JS_ASSERT(prop && pobj == obj);
sprop = (JSScopeProperty *) prop;
JS_ASSERT(sprop->getter == js_GetLocalVariable);
slot = sprop->shortid;
OBJ_DROP_PROPERTY(cx, pobj, prop);
/*
* If this local function is declared in a body block induced by
* let declarations, reparent fun->object to the compiler-created
* body block object so that JSOP_DEFLOCALFUN can clone that block
* into the runtime scope chain.
*/
stmt = cg->treeContext.topStmt;
if (stmt && stmt->type == STMT_BLOCK &&
stmt->down && stmt->down->type == STMT_BLOCK &&
(stmt->down->flags & SIF_SCOPE)) {
obj = ATOM_TO_OBJECT(stmt->down->atom);
JS_ASSERT(LOCKED_OBJ_GET_CLASS(obj) == &js_BlockClass);
OBJ_SET_PARENT(cx, fun->object, obj);
}
if (atomIndex >= JS_BIT(16)) {
/*
* Lots of literals in the outer function, so we have to emit
* [JSOP_LITOPX, atomIndex, JSOP_DEFLOCALFUN, var slot].
*/
off = js_EmitN(cx, cg, JSOP_LITOPX, 3);
if (off < 0)
return JS_FALSE;
pc = CG_CODE(cg, off);
SET_LITERAL_INDEX(pc, atomIndex);
EMIT_UINT16_IMM_OP(JSOP_DEFLOCALFUN, slot);
} else {
/* Emit [JSOP_DEFLOCALFUN, var slot, atomIndex]. */
off = js_EmitN(cx, cg, JSOP_DEFLOCALFUN,
VARNO_LEN + ATOM_INDEX_LEN);
if (off < 0)
return JS_FALSE;
pc = CG_CODE(cg, off);
SET_VARNO(pc, slot);
pc += VARNO_LEN;
SET_ATOM_INDEX(pc, atomIndex);
}
} else {
JS_ASSERT(!cg->treeContext.topStmt);
EMIT_ATOM_INDEX_OP(JSOP_DEFFUN, atomIndex);
}
CG_SWITCH_TO_MAIN(cg);
break;
}
#if JS_HAS_EXPORT_IMPORT
case TOK_EXPORT:
pn2 = pn->pn_head;
if (pn2->pn_type == TOK_STAR) {
/*
* 'export *' must have no other elements in the list (what would
* be the point?).
*/
if (js_Emit1(cx, cg, JSOP_EXPORTALL) < 0)
return JS_FALSE;
} else {
/*
* If not 'export *', the list consists of NAME nodes identifying
* properties of the variables object to flag as exported.
*/
do {
ale = js_IndexAtom(cx, pn2->pn_atom, &cg->atomList);
if (!ale)
return JS_FALSE;
EMIT_ATOM_INDEX_OP(JSOP_EXPORTNAME, ALE_INDEX(ale));
} while ((pn2 = pn2->pn_next) != NULL);
}
break;
case TOK_IMPORT:
for (pn2 = pn->pn_head; pn2; pn2 = pn2->pn_next) {
/*
* Each subtree on an import list is rooted by a DOT or LB node.
* A DOT may have a null pn_atom member, in which case pn_op must
* be JSOP_IMPORTALL -- see EmitPropOp above.
*/
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
}
break;
#endif /* JS_HAS_EXPORT_IMPORT */
case TOK_IF:
/* Initialize so we can detect else-if chains and avoid recursion. */
stmtInfo.type = STMT_IF;
beq = jmp = -1;
noteIndex = -1;
if_again:
/* Emit code for the condition before pushing stmtInfo. */
if (!js_EmitTree(cx, cg, pn->pn_kid1))
return JS_FALSE;
top = CG_OFFSET(cg);
if (stmtInfo.type == STMT_IF) {
js_PushStatement(&cg->treeContext, &stmtInfo, STMT_IF, top);
} else {
/*
* We came here from the goto further below that detects else-if
* chains, so we must mutate stmtInfo back into a STMT_IF record.
* Also (see below for why) we need a note offset for SRC_IF_ELSE
* to help the decompiler. Actually, we need two offsets, one for
* decompiling any else clause and the second for decompiling an
* else-if chain without bracing, overindenting, or incorrectly
* scoping let declarations.
*/
JS_ASSERT(stmtInfo.type == STMT_ELSE);
stmtInfo.type = STMT_IF;
stmtInfo.update = top;
if (!js_SetSrcNoteOffset(cx, cg, noteIndex, 0, jmp - beq))
return JS_FALSE;
if (!js_SetSrcNoteOffset(cx, cg, noteIndex, 1, top - jmp))
return JS_FALSE;
}
/* Emit an annotated branch-if-false around the then part. */
pn3 = pn->pn_kid3;
noteIndex = js_NewSrcNote(cx, cg, pn3 ? SRC_IF_ELSE : SRC_IF);
if (noteIndex < 0)
return JS_FALSE;
beq = EmitJump(cx, cg, JSOP_IFEQ, 0);
if (beq < 0)
return JS_FALSE;
/* Emit code for the then and optional else parts. */
if (!js_EmitTree(cx, cg, pn->pn_kid2))
return JS_FALSE;
if (pn3) {
/* Modify stmtInfo so we know we're in the else part. */
stmtInfo.type = STMT_ELSE;
/*
* Emit a JSOP_BACKPATCH op to jump from the end of our then part
* around the else part. The js_PopStatementCG call at the bottom
* of this switch case will fix up the backpatch chain linked from
* stmtInfo.breaks.
*/
jmp = EmitGoto(cx, cg, &stmtInfo, &stmtInfo.breaks, NULL, SRC_NULL);
if (jmp < 0)
return JS_FALSE;
/* Ensure the branch-if-false comes here, then emit the else. */
CHECK_AND_SET_JUMP_OFFSET_AT(cx, cg, beq);
if (pn3->pn_type == TOK_IF) {
pn = pn3;
goto if_again;
}
if (!js_EmitTree(cx, cg, pn3))
return JS_FALSE;
/*
* Annotate SRC_IF_ELSE with the offset from branch to jump, for
* the decompiler's benefit. We can't just "back up" from the pc
* of the else clause, because we don't know whether an extended
* jump was required to leap from the end of the then clause over
* the else clause.
*/
if (!js_SetSrcNoteOffset(cx, cg, noteIndex, 0, jmp - beq))
return JS_FALSE;
} else {
/* No else part, fixup the branch-if-false to come here. */
CHECK_AND_SET_JUMP_OFFSET_AT(cx, cg, beq);
}
ok = js_PopStatementCG(cx, cg);
break;
case TOK_SWITCH:
/* Out of line to avoid bloating js_EmitTree's stack frame size. */
ok = EmitSwitch(cx, cg, pn, &stmtInfo);
break;
case TOK_WHILE:
js_PushStatement(&cg->treeContext, &stmtInfo, STMT_WHILE_LOOP, top);
if (!js_EmitTree(cx, cg, pn->pn_left))
return JS_FALSE;
noteIndex = js_NewSrcNote(cx, cg, SRC_WHILE);
if (noteIndex < 0)
return JS_FALSE;
beq = EmitJump(cx, cg, JSOP_IFEQ, 0);
if (beq < 0)
return JS_FALSE;
if (!js_EmitTree(cx, cg, pn->pn_right))
return JS_FALSE;
jmp = EmitJump(cx, cg, JSOP_GOTO, top - CG_OFFSET(cg));
if (jmp < 0)
return JS_FALSE;
CHECK_AND_SET_JUMP_OFFSET_AT(cx, cg, beq);
if (!js_SetSrcNoteOffset(cx, cg, noteIndex, 0, jmp - beq))
return JS_FALSE;
ok = js_PopStatementCG(cx, cg);
break;
case TOK_DO:
/* Emit an annotated nop so we know to decompile a 'do' keyword. */
if (js_NewSrcNote(cx, cg, SRC_WHILE) < 0 ||
js_Emit1(cx, cg, JSOP_NOP) < 0) {
return JS_FALSE;
}
/* Compile the loop body. */
top = CG_OFFSET(cg);
js_PushStatement(&cg->treeContext, &stmtInfo, STMT_DO_LOOP, top);
if (!js_EmitTree(cx, cg, pn->pn_left))
return JS_FALSE;
/* Set loop and enclosing label update offsets, for continue. */
stmt = &stmtInfo;
do {
stmt->update = CG_OFFSET(cg);
} while ((stmt = stmt->down) != NULL && stmt->type == STMT_LABEL);
/* Compile the loop condition, now that continues know where to go. */
if (!js_EmitTree(cx, cg, pn->pn_right))
return JS_FALSE;
/*
* No source note needed, because JSOP_IFNE is used only for do-while.
* If we ever use JSOP_IFNE for other purposes, we can still avoid yet
* another note here, by storing (jmp - top) in the SRC_WHILE note's
* offset, and fetching that delta in order to decompile recursively.
*/
if (EmitJump(cx, cg, JSOP_IFNE, top - CG_OFFSET(cg)) < 0)
return JS_FALSE;
ok = js_PopStatementCG(cx, cg);
break;
case TOK_FOR:
beq = 0; /* suppress gcc warnings */
pn2 = pn->pn_left;
js_PushStatement(&cg->treeContext, &stmtInfo, STMT_FOR_LOOP, top);
if (pn2->pn_type == TOK_IN) {
JSBool emitIFEQ;
/* Set stmtInfo type for later testing. */
stmtInfo.type = STMT_FOR_IN_LOOP;
noteIndex = -1;
/*
* If the left part is 'var x', emit code to define x if necessary
* using a prolog opcode, but do not emit a pop. If the left part
* is 'var x = i', emit prolog code to define x if necessary; then
* emit code to evaluate i, assign the result to x, and pop the
* result off the stack.
*
* All the logic to do this is implemented in the outer switch's
* TOK_VAR case, conditioned on pn_extra flags set by the parser.
*
* In the 'for (var x = i in o) ...' case, the js_EmitTree(...pn3)
* called here will generate the proper note for the assignment
* op that sets x = i, hoisting the initialized var declaration
* out of the loop: 'var x = i; for (x in o) ...'.
*
* In the 'for (var x in o) ...' case, nothing but the prolog op
* (if needed) should be generated here, we must emit the note
* just before the JSOP_FOR* opcode in the switch on pn3->pn_type
* a bit below, so nothing is hoisted: 'for (var x in o) ...'.
*
* A 'for (let x = i in o)' loop must not be hoisted, since in
* this form the let variable is scoped by the loop body (but not
* the head). The initializer expression i must be evaluated for
* any side effects. So we hoist only i in the let case.
*/
pn3 = pn2->pn_left;
type = pn3->pn_type;
cg->treeContext.flags |= TCF_IN_FOR_INIT;
if (TOKEN_TYPE_IS_DECL(type) && !js_EmitTree(cx, cg, pn3))
return JS_FALSE;
cg->treeContext.flags &= ~TCF_IN_FOR_INIT;
/* Compile the object expression to the right of 'in'. */
if (!js_EmitTree(cx, cg, pn2->pn_right))
return JS_FALSE;
/*
* Emit a bytecode to convert top of stack value to the iterator
* object depending on the loop variant (for-in, for-each-in, or
* destructuring for-in).
*/
#if JS_HAS_DESTRUCTURING
JS_ASSERT(pn->pn_op == JSOP_FORIN ||
pn->pn_op == JSOP_FOREACHKEYVAL ||
pn->pn_op == JSOP_FOREACH);
#else
JS_ASSERT(pn->pn_op == JSOP_FORIN || pn->pn_op == JSOP_FOREACH);
#endif
if (js_Emit1(cx, cg, pn->pn_op) < 0)
return JS_FALSE;
top = CG_OFFSET(cg);
SET_STATEMENT_TOP(&stmtInfo, top);
/*
* Compile a JSOP_FOR* bytecode based on the left hand side.
*
* Initialize op to JSOP_SETNAME in case of |for ([a, b] in o)...|
* or similar, to signify assignment, rather than declaration, to
* the decompiler. EmitDestructuringOps takes a prolog bytecode
* parameter and emits the appropriate source note, defaulting to
* assignment, so JSOP_SETNAME is not critical here; many similar
* ops could be used -- just not JSOP_NOP (which means 'let').
*/
emitIFEQ = JS_TRUE;
op = JSOP_SETNAME;
switch (type) {
#if JS_HAS_BLOCK_SCOPE
case TOK_LET:
#endif
case TOK_VAR:
JS_ASSERT(pn3->pn_arity == PN_LIST && pn3->pn_count == 1);
pn3 = pn3->pn_head;
#if JS_HAS_DESTRUCTURING
if (pn3->pn_type == TOK_ASSIGN) {
pn3 = pn3->pn_left;
JS_ASSERT(pn3->pn_type == TOK_RB || pn3->pn_type == TOK_RC);
}
if (pn3->pn_type == TOK_RB || pn3->pn_type == TOK_RC) {
op = pn2->pn_left->pn_op;
goto destructuring_for;
}
#else
JS_ASSERT(pn3->pn_type == TOK_NAME);
#endif
/*
* Always annotate JSOP_FORLOCAL if given input of the form
* 'for (let x in * o)' -- the decompiler must not hoist the
* 'let x' out of the loop head, or x will be bound in the
* wrong scope. Likewise, but in this case only for the sake
* of higher decompilation fidelity only, do not hoist 'var x'
* when given 'for (var x in o)'. But 'for (var x = i in o)'
* requires hoisting in order to preserve the initializer i.
* The decompiler can only handle so much!
*/
if ((
#if JS_HAS_BLOCK_SCOPE
type == TOK_LET ||
#endif
!pn3->pn_expr) &&
js_NewSrcNote2(cx, cg, SRC_DECL,
type == TOK_VAR
? SRC_DECL_VAR
: SRC_DECL_LET) < 0) {
return JS_FALSE;
}
/* FALL THROUGH */
case TOK_NAME:
if (pn3->pn_slot >= 0) {
op = pn3->pn_op;
switch (op) {
case JSOP_GETARG: /* FALL THROUGH */
case JSOP_SETARG: op = JSOP_FORARG; break;
case JSOP_GETVAR: /* FALL THROUGH */
case JSOP_SETVAR: op = JSOP_FORVAR; break;
case JSOP_GETGVAR: /* FALL THROUGH */
case JSOP_SETGVAR: op = JSOP_FORNAME; break;
case JSOP_GETLOCAL: /* FALL THROUGH */
case JSOP_SETLOCAL: op = JSOP_FORLOCAL; break;
default: JS_ASSERT(0);
}
} else {
pn3->pn_op = JSOP_FORNAME;
if (!BindNameToSlot(cx, &cg->treeContext, pn3, JS_FALSE))
return JS_FALSE;
op = pn3->pn_op;
}
if (pn3->pn_slot >= 0) {
if (pn3->pn_attrs & JSPROP_READONLY) {
JS_ASSERT(op == JSOP_FORVAR);
op = JSOP_FORCONST;
}
atomIndex = (jsatomid) pn3->pn_slot;
EMIT_UINT16_IMM_OP(op, atomIndex);
} else {
if (!EmitAtomOp(cx, pn3, op, cg))
return JS_FALSE;
}
break;
case TOK_DOT:
useful = JS_FALSE;
if (!CheckSideEffects(cx, &cg->treeContext, pn3->pn_expr,
&useful)) {
return JS_FALSE;
}
if (!useful) {
if (!EmitPropOp(cx, pn3, JSOP_FORPROP, cg))
return JS_FALSE;
break;
}
/* FALL THROUGH */
#if JS_HAS_DESTRUCTURING
case TOK_RB:
case TOK_RC:
destructuring_for:
#endif
#if JS_HAS_XML_SUPPORT
case TOK_UNARYOP:
#endif
#if JS_HAS_LVALUE_RETURN
case TOK_LP:
#endif
case TOK_LB:
/*
* We separate the first/next bytecode from the enumerator
* variable binding to avoid any side-effects in the index
* expression (e.g., for (x[i++] in {}) should not bind x[i]
* or increment i at all).
*/
emitIFEQ = JS_FALSE;
if (!js_Emit1(cx, cg, JSOP_FORELEM))
return JS_FALSE;
/*
* Emit a SRC_WHILE note with offset telling the distance to
* the loop-closing jump (we can't reckon from the branch at
* the top of the loop, because the loop-closing jump might
* need to be an extended jump, independent of whether the
* branch is short or long).
*/
noteIndex = js_NewSrcNote(cx, cg, SRC_WHILE);
if (noteIndex < 0)
return JS_FALSE;
beq = EmitJump(cx, cg, JSOP_IFEQ, 0);
if (beq < 0)
return JS_FALSE;
#if JS_HAS_DESTRUCTURING
if (pn3->pn_type == TOK_RB || pn3->pn_type == TOK_RC) {
if (!EmitDestructuringOps(cx, cg, op, pn3))
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_POP) < 0)
return JS_FALSE;
break;
}
#endif
#if JS_HAS_LVALUE_RETURN
if (pn3->pn_type == TOK_LP) {
JS_ASSERT(pn3->pn_op == JSOP_SETCALL);
if (!js_EmitTree(cx, cg, pn3))
return JS_FALSE;
if (!js_Emit1(cx, cg, JSOP_ENUMELEM))
return JS_FALSE;
break;
}
#endif
#if JS_HAS_XML_SUPPORT
if (pn3->pn_type == TOK_UNARYOP) {
JS_ASSERT(pn3->pn_op == JSOP_BINDXMLNAME);
if (!js_EmitTree(cx, cg, pn3))
return JS_FALSE;
if (!js_Emit1(cx, cg, JSOP_ENUMELEM))
return JS_FALSE;
break;
}
#endif
/* Now that we're safely past the IFEQ, commit side effects. */
if (!EmitElemOp(cx, pn3, JSOP_ENUMELEM, cg))
return JS_FALSE;
break;
default:
JS_ASSERT(0);
}
if (emitIFEQ) {
/* Annotate so the decompiler can find the loop-closing jump. */
noteIndex = js_NewSrcNote(cx, cg, SRC_WHILE);
if (noteIndex < 0)
return JS_FALSE;
/* Pop and test the loop condition generated by JSOP_FOR*. */
beq = EmitJump(cx, cg, JSOP_IFEQ, 0);
if (beq < 0)
return JS_FALSE;
}
} else {
op = JSOP_POP;
if (!pn2->pn_kid1) {
/* No initializer: emit an annotated nop for the decompiler. */
op = JSOP_NOP;
} else {
cg->treeContext.flags |= TCF_IN_FOR_INIT;
#if JS_HAS_DESTRUCTURING
pn3 = pn2->pn_kid1;
if (pn3->pn_type == TOK_ASSIGN &&
!MaybeEmitGroupAssignment(cx, cg, op, pn3, &op)) {
return JS_FALSE;
}
#endif
if (op == JSOP_POP) {
if (!js_EmitTree(cx, cg, pn3))
return JS_FALSE;
if (TOKEN_TYPE_IS_DECL(pn3->pn_type)) {
/*
* Check whether a destructuring-initialized var decl
* was optimized to a group assignment. If so, we do
* not need to emit a pop below, so switch to a nop,
* just for the decompiler.
*/
JS_ASSERT(pn3->pn_arity == PN_LIST);
if (pn3->pn_extra & PNX_GROUPINIT)
op = JSOP_NOP;
}
}
cg->treeContext.flags &= ~TCF_IN_FOR_INIT;
}
noteIndex = js_NewSrcNote(cx, cg, SRC_FOR);
if (noteIndex < 0 ||
js_Emit1(cx, cg, op) < 0) {
return JS_FALSE;
}
top = CG_OFFSET(cg);
SET_STATEMENT_TOP(&stmtInfo, top);
if (!pn2->pn_kid2) {
/* No loop condition: flag this fact in the source notes. */
if (!js_SetSrcNoteOffset(cx, cg, (uintN)noteIndex, 0, 0))
return JS_FALSE;
} else {
if (!js_EmitTree(cx, cg, pn2->pn_kid2))
return JS_FALSE;
if (!js_SetSrcNoteOffset(cx, cg, (uintN)noteIndex, 0,
CG_OFFSET(cg) - top)) {
return JS_FALSE;
}
beq = EmitJump(cx, cg, JSOP_IFEQ, 0);
if (beq < 0)
return JS_FALSE;
}
/* Set pn3 (used below) here to avoid spurious gcc warnings. */
pn3 = pn2->pn_kid3;
}
/* Emit code for the loop body. */
if (!js_EmitTree(cx, cg, pn->pn_right))
return JS_FALSE;
if (pn2->pn_type != TOK_IN) {
/* Set the second note offset so we can find the update part. */
JS_ASSERT(noteIndex != -1);
if (!js_SetSrcNoteOffset(cx, cg, (uintN)noteIndex, 1,
CG_OFFSET(cg) - top)) {
return JS_FALSE;
}
if (pn3) {
/* Set loop and enclosing "update" offsets, for continue. */
stmt = &stmtInfo;
do {
stmt->update = CG_OFFSET(cg);
} while ((stmt = stmt->down) != NULL &&
stmt->type == STMT_LABEL);
op = JSOP_POP;
#if JS_HAS_DESTRUCTURING
if (pn3->pn_type == TOK_ASSIGN &&
!MaybeEmitGroupAssignment(cx, cg, op, pn3, &op)) {
return JS_FALSE;
}
#endif
if (op == JSOP_POP) {
if (!js_EmitTree(cx, cg, pn3))
return JS_FALSE;
if (js_Emit1(cx, cg, op) < 0)
return JS_FALSE;
}
/* Restore the absolute line number for source note readers. */
off = (ptrdiff_t) pn->pn_pos.end.lineno;
if (CG_CURRENT_LINE(cg) != (uintN) off) {
if (js_NewSrcNote2(cx, cg, SRC_SETLINE, off) < 0)
return JS_FALSE;
CG_CURRENT_LINE(cg) = (uintN) off;
}
}
/* The third note offset helps us find the loop-closing jump. */
if (!js_SetSrcNoteOffset(cx, cg, (uintN)noteIndex, 2,
CG_OFFSET(cg) - top)) {
return JS_FALSE;
}
}
/* Emit the loop-closing jump and fixup all jump offsets. */
jmp = EmitJump(cx, cg, JSOP_GOTO, top - CG_OFFSET(cg));
if (jmp < 0)
return JS_FALSE;
if (beq > 0)
CHECK_AND_SET_JUMP_OFFSET_AT(cx, cg, beq);
if (pn2->pn_type == TOK_IN) {
/* Set the SRC_WHILE note offset so we can find the closing jump. */
JS_ASSERT(noteIndex != -1);
if (!js_SetSrcNoteOffset(cx, cg, (uintN)noteIndex, 0, jmp - beq))
return JS_FALSE;
}
/* Now fixup all breaks and continues (before for/in's JSOP_ENDITER). */
if (!js_PopStatementCG(cx, cg))
return JS_FALSE;
if (pn2->pn_type == TOK_IN) {
if (js_Emit1(cx, cg, JSOP_ENDITER) < 0)
return JS_FALSE;
}
break;
case TOK_BREAK:
stmt = cg->treeContext.topStmt;
atom = pn->pn_atom;
if (atom) {
ale = js_IndexAtom(cx, atom, &cg->atomList);
if (!ale)
return JS_FALSE;
while (stmt->type != STMT_LABEL || stmt->atom != atom)
stmt = stmt->down;
noteType = SRC_BREAK2LABEL;
} else {
ale = NULL;
while (!STMT_IS_LOOP(stmt) && stmt->type != STMT_SWITCH)
stmt = stmt->down;
noteType = SRC_NULL;
}
if (EmitGoto(cx, cg, stmt, &stmt->breaks, ale, noteType) < 0)
return JS_FALSE;
break;
case TOK_CONTINUE:
stmt = cg->treeContext.topStmt;
atom = pn->pn_atom;
if (atom) {
/* Find the loop statement enclosed by the matching label. */
JSStmtInfo *loop = NULL;
ale = js_IndexAtom(cx, atom, &cg->atomList);
if (!ale)
return JS_FALSE;
while (stmt->type != STMT_LABEL || stmt->atom != atom) {
if (STMT_IS_LOOP(stmt))
loop = stmt;
stmt = stmt->down;
}
stmt = loop;
noteType = SRC_CONT2LABEL;
} else {
ale = NULL;
while (!STMT_IS_LOOP(stmt))
stmt = stmt->down;
noteType = SRC_CONTINUE;
}
if (EmitGoto(cx, cg, stmt, &stmt->continues, ale, noteType) < 0)
return JS_FALSE;
break;
case TOK_WITH:
if (!js_EmitTree(cx, cg, pn->pn_left))
return JS_FALSE;
js_PushStatement(&cg->treeContext, &stmtInfo, STMT_WITH, CG_OFFSET(cg));
if (js_Emit1(cx, cg, JSOP_ENTERWITH) < 0)
return JS_FALSE;
if (!js_EmitTree(cx, cg, pn->pn_right))
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_LEAVEWITH) < 0)
return JS_FALSE;
ok = js_PopStatementCG(cx, cg);
break;
case TOK_TRY:
{
ptrdiff_t start, end, catchJump, catchStart, finallyCatch;
intN depth;
JSParseNode *lastCatch;
catchJump = catchStart = finallyCatch = -1;
/*
* Push stmtInfo to track jumps-over-catches and gosubs-to-finally
* for later fixup.
*
* When a finally block is 'active' (STMT_FINALLY on the treeContext),
* non-local jumps (including jumps-over-catches) result in a GOSUB
* being written into the bytecode stream and fixed-up later (c.f.
* EmitBackPatchOp and BackPatch).
*/
js_PushStatement(&cg->treeContext, &stmtInfo,
pn->pn_kid3 ? STMT_FINALLY : STMT_TRY,
CG_OFFSET(cg));
/*
* About JSOP_SETSP: an exception can be thrown while the stack is in
* an unbalanced state, and this imbalance causes problems with things
* like function invocation later on.
*
* To fix this, we compute the 'balanced' stack depth upon try entry,
* and then restore the stack to this depth when we hit the first catch
* or finally block. We can't just zero the stack, because things like
* for/in and with that are active upon entry to the block keep state
* variables on the stack.
*/
depth = cg->stackDepth;
/* Mark try location for decompilation, then emit try block. */
if (js_Emit1(cx, cg, JSOP_TRY) < 0)
return JS_FALSE;
start = CG_OFFSET(cg);
if (!js_EmitTree(cx, cg, pn->pn_kid1))
return JS_FALSE;
/* GOSUB to finally, if present. */
if (pn->pn_kid3) {
if (js_NewSrcNote(cx, cg, SRC_HIDDEN) < 0)
return JS_FALSE;
jmp = EmitBackPatchOp(cx, cg, JSOP_BACKPATCH, &GOSUBS(stmtInfo));
if (jmp < 0)
return JS_FALSE;
/* JSOP_RETSUB pops the return pc-index, balancing the stack. */
cg->stackDepth = depth;
}
/* Emit (hidden) jump over catch and/or finally. */
if (js_NewSrcNote(cx, cg, SRC_HIDDEN) < 0)
return JS_FALSE;
jmp = EmitBackPatchOp(cx, cg, JSOP_BACKPATCH, &catchJump);
if (jmp < 0)
return JS_FALSE;
end = CG_OFFSET(cg);
/* If this try has a catch block, emit it. */
pn2 = pn->pn_kid2;
lastCatch = NULL;
if (pn2) {
jsint count = 0; /* previous catch block's population */
catchStart = end;
/*
* The emitted code for a catch block looks like:
*
* [throwing] only if 2nd+ catch block
* [leaveblock] only if 2nd+ catch block
* enterblock with SRC_CATCH
* exception
* [dup] only if catchguard
* setlocalpop <slot> or destructuring code
* [< catchguard code >] if there's a catchguard
* [ifeq <offset to next catch block>] " "
* [pop] only if catchguard
* < catch block contents >
* leaveblock
* goto <end of catch blocks> non-local; finally applies
*
* If there's no catch block without a catchguard, the last
* <offset to next catch block> points to rethrow code. This
* code will [gosub] to the finally code if appropriate, and is
* also used for the catch-all trynote for capturing exceptions
* thrown from catch{} blocks.
*/
for (pn3 = pn2->pn_head; pn3; pn3 = pn3->pn_next) {
ptrdiff_t guardJump, catchNote;
guardJump = GUARDJUMP(stmtInfo);
if (guardJump == -1) {
/* Set stack to original depth (see SETSP comment above). */
EMIT_UINT16_IMM_OP(JSOP_SETSP, (jsatomid)depth);
cg->stackDepth = depth;
} else {
/* Fix up and clean up previous catch block. */
CHECK_AND_SET_JUMP_OFFSET_AT(cx, cg, guardJump);
/*
* Account for the pushed exception object that we still
* have after the jumping from the previous guard.
*/
JS_ASSERT(cg->stackDepth == depth);
cg->stackDepth = depth + 1;
/*
* Move exception back to cx->exception to prepare for
* the next catch. We hide [throwing] from the decompiler
* since it compensates for the hidden JSOP_DUP at the
* start of the previous guarded catch.
*/
if (js_NewSrcNote(cx, cg, SRC_HIDDEN) < 0 ||
js_Emit1(cx, cg, JSOP_THROWING) < 0) {
return JS_FALSE;
}
/*
* Emit an unbalanced [leaveblock] for the previous catch,
* whose block object count is saved below.
*/
if (js_NewSrcNote(cx, cg, SRC_HIDDEN) < 0)
return JS_FALSE;
JS_ASSERT(count >= 0);
EMIT_UINT16_IMM_OP(JSOP_LEAVEBLOCK, count);
}
/*
* Annotate the JSOP_ENTERBLOCK that's about to be generated
* by the call to js_EmitTree immediately below. Save this
* source note's index in stmtInfo for use by the TOK_CATCH:
* case, where the length of the catch guard is set as the
* note's offset.
*/
catchNote = js_NewSrcNote2(cx, cg, SRC_CATCH, 0);
if (catchNote < 0)
return JS_FALSE;
CATCHNOTE(stmtInfo) = catchNote;
/*
* Emit the lexical scope and catch body. Save the catch's
* block object population via count, for use when targeting
* guardJump at the next catch (the guard mismatch case).
*/
JS_ASSERT(pn3->pn_type == TOK_LEXICALSCOPE);
count = OBJ_BLOCK_COUNT(cx, ATOM_TO_OBJECT(pn3->pn_atom));
if (!js_EmitTree(cx, cg, pn3))
return JS_FALSE;
/* gosub <finally>, if required */
if (pn->pn_kid3) {
jmp = EmitBackPatchOp(cx, cg, JSOP_BACKPATCH,
&GOSUBS(stmtInfo));
if (jmp < 0)
return JS_FALSE;
JS_ASSERT(cg->stackDepth == depth);
}
/*
* Jump over the remaining catch blocks. This will get fixed
* up to jump to after catch/finally.
*/
if (js_NewSrcNote(cx, cg, SRC_HIDDEN) < 0)
return JS_FALSE;
jmp = EmitBackPatchOp(cx, cg, JSOP_BACKPATCH, &catchJump);
if (jmp < 0)
return JS_FALSE;
/*
* Save a pointer to the last catch node to handle try-finally
* and try-catch(guard)-finally special cases.
*/
lastCatch = pn3->pn_expr;
}
}
/*
* Last catch guard jumps to the rethrow code sequence if none of the
* guards match. Target guardJump at the beginning of the rethrow
* sequence, just in case a guard expression throws and leaves the
* stack unbalanced.
*/
if (lastCatch && lastCatch->pn_kid2) {
CHECK_AND_SET_JUMP_OFFSET_AT(cx, cg, GUARDJUMP(stmtInfo));
/* Sync the stack to take into account pushed exception. */
JS_ASSERT(cg->stackDepth == depth);
cg->stackDepth = depth + 1;
/*
* Rethrow the exception, delegating executing of finally if any
* to the exception handler.
*/
if (js_NewSrcNote(cx, cg, SRC_HIDDEN) < 0 ||
js_Emit1(cx, cg, JSOP_THROW) < 0) {
return JS_FALSE;
}
}
JS_ASSERT(cg->stackDepth == depth);
/* Emit finally handler if any. */
if (pn->pn_kid3) {
/*
* We emit [setsp][gosub] to call try-finally when an exception is
* thrown from try or try-catch blocks. The [gosub] and [retsub]
* opcodes will take care of stacking and rethrowing any exception
* pending across the finally.
*/
finallyCatch = CG_OFFSET(cg);
EMIT_UINT16_IMM_OP(JSOP_SETSP, (jsatomid)depth);
jmp = EmitBackPatchOp(cx, cg, JSOP_BACKPATCH,
&GOSUBS(stmtInfo));
if (jmp < 0)
return JS_FALSE;
JS_ASSERT(cg->stackDepth == depth);
JS_ASSERT((uintN)depth <= cg->maxStackDepth);
/*
* Fix up the gosubs that might have been emitted before non-local
* jumps to the finally code.
*/
if (!BackPatch(cx, cg, GOSUBS(stmtInfo), CG_NEXT(cg), JSOP_GOSUB))
return JS_FALSE;
/*
* The stack budget must be balanced at this point. All [gosub]
* calls emitted before this point will push two stack slots, one
* for the pending exception (or JSVAL_HOLE if there is no pending
* exception) and one for the [retsub] pc-index.
*/
JS_ASSERT(cg->stackDepth == depth);
cg->stackDepth += 2;
if ((uintN)cg->stackDepth > cg->maxStackDepth)
cg->maxStackDepth = cg->stackDepth;
/* Now indicate that we're emitting a subroutine body. */
stmtInfo.type = STMT_SUBROUTINE;
if (!UpdateLineNumberNotes(cx, cg, pn->pn_kid3))
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_FINALLY) < 0 ||
!js_EmitTree(cx, cg, pn->pn_kid3) ||
js_Emit1(cx, cg, JSOP_RETSUB) < 0) {
return JS_FALSE;
}
/* Restore stack depth budget to its balanced state. */
JS_ASSERT(cg->stackDepth == depth + 2);
cg->stackDepth = depth;
}
if (!js_PopStatementCG(cx, cg))
return JS_FALSE;
if (js_NewSrcNote(cx, cg, SRC_ENDBRACE) < 0 ||
js_Emit1(cx, cg, JSOP_NOP) < 0) {
return JS_FALSE;
}
/* Fix up the end-of-try/catch jumps to come here. */
if (!BackPatch(cx, cg, catchJump, CG_NEXT(cg), JSOP_GOTO))
return JS_FALSE;
/*
* Add the try note last, to let post-order give us the right ordering
* (first to last for a given nesting level, inner to outer by level).
*/
if (pn->pn_kid2) {
JS_ASSERT(end != -1 && catchStart != -1);
if (!js_NewTryNote(cx, cg, start, end, catchStart))
return JS_FALSE;
}
/*
* If we've got a finally, mark try+catch region with additional
* trynote to catch exceptions (re)thrown from a catch block or
* for the try{}finally{} case.
*/
if (pn->pn_kid3) {
JS_ASSERT(finallyCatch != -1);
if (!js_NewTryNote(cx, cg, start, finallyCatch, finallyCatch))
return JS_FALSE;
}
break;
}
case TOK_CATCH:
{
ptrdiff_t catchStart, guardJump;
/*
* Morph STMT_BLOCK to STMT_CATCH, note the block entry code offset,
* and save the block object atom.
*/
stmt = cg->treeContext.topStmt;
JS_ASSERT(stmt->type == STMT_BLOCK && (stmt->flags & SIF_SCOPE));
stmt->type = STMT_CATCH;
catchStart = stmt->update;
atom = stmt->atom;
/* Go up one statement info record to the TRY or FINALLY record. */
stmt = stmt->down;
JS_ASSERT(stmt->type == STMT_TRY || stmt->type == STMT_FINALLY);
/* Pick up the pending exception and bind it to the catch variable. */
if (js_Emit1(cx, cg, JSOP_EXCEPTION) < 0)
return JS_FALSE;
/*
* Dup the exception object if there is a guard for rethrowing to use
* it later when rethrowing or in other catches.
*/
if (pn->pn_kid2) {
if (js_NewSrcNote(cx, cg, SRC_HIDDEN) < 0 ||
js_Emit1(cx, cg, JSOP_DUP) < 0) {
return JS_FALSE;
}
}
pn2 = pn->pn_kid1;
switch (pn2->pn_type) {
#if JS_HAS_DESTRUCTURING
case TOK_RB:
case TOK_RC:
if (!EmitDestructuringOps(cx, cg, JSOP_NOP, pn2))
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_POP) < 0)
return JS_FALSE;
break;
#endif
case TOK_NAME:
/* Inline BindNameToSlot, adding block depth to pn2->pn_slot. */
pn2->pn_slot += OBJ_BLOCK_DEPTH(cx, ATOM_TO_OBJECT(atom));
EMIT_UINT16_IMM_OP(JSOP_SETLOCALPOP, pn2->pn_slot);
break;
default:
JS_ASSERT(0);
}
/* Emit the guard expression, if there is one. */
if (pn->pn_kid2) {
if (!js_EmitTree(cx, cg, pn->pn_kid2))
return JS_FALSE;
if (!js_SetSrcNoteOffset(cx, cg, CATCHNOTE(*stmt), 0,
CG_OFFSET(cg) - catchStart)) {
return JS_FALSE;
}
/* ifeq <next block> */
guardJump = EmitJump(cx, cg, JSOP_IFEQ, 0);
if (guardJump < 0)
return JS_FALSE;
GUARDJUMP(*stmt) = guardJump;
/* Pop duplicated exception object as we no longer need it. */
if (js_NewSrcNote(cx, cg, SRC_HIDDEN) < 0 ||
js_Emit1(cx, cg, JSOP_POP) < 0) {
return JS_FALSE;
}
}
/* Emit the catch body. */
if (!js_EmitTree(cx, cg, pn->pn_kid3))
return JS_FALSE;
/*
* Annotate the JSOP_LEAVEBLOCK that will be emitted as we unwind via
* our TOK_LEXICALSCOPE parent, so the decompiler knows to pop.
*/
off = cg->stackDepth;
if (js_NewSrcNote2(cx, cg, SRC_CATCH, off) < 0)
return JS_FALSE;
break;
}
case TOK_VAR:
if (!EmitVariables(cx, cg, pn, JS_FALSE, &noteIndex))
return JS_FALSE;
break;
case TOK_RETURN:
/* Push a return value */
pn2 = pn->pn_kid;
if (pn2) {
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
} else {
if (js_Emit1(cx, cg, JSOP_PUSH) < 0)
return JS_FALSE;
}
/*
* EmitNonLocalJumpFixup mutates op to JSOP_RETRVAL after emitting a
* JSOP_SETRVAL if there are open try blocks having finally clauses.
* We can't simply transfer control flow to our caller in that case,
* because we must gosub to those clauses from inner to outer, with
* the correct stack pointer (i.e., after popping any with, for/in,
* etc., slots nested inside the finally's try).
*/
op = JSOP_RETURN;
if (!EmitNonLocalJumpFixup(cx, cg, NULL, &op))
return JS_FALSE;
if (js_Emit1(cx, cg, op) < 0)
return JS_FALSE;
break;
#if JS_HAS_GENERATORS
case TOK_YIELD:
if (pn->pn_kid) {
if (!js_EmitTree(cx, cg, pn->pn_kid))
return JS_FALSE;
} else {
if (js_Emit1(cx, cg, JSOP_PUSH) < 0)
return JS_FALSE;
}
if (js_Emit1(cx, cg, JSOP_YIELD) < 0)
return JS_FALSE;
break;
#endif
case TOK_LC:
#if JS_HAS_XML_SUPPORT
if (pn->pn_arity == PN_UNARY) {
if (!js_EmitTree(cx, cg, pn->pn_kid))
return JS_FALSE;
if (js_Emit1(cx, cg, pn->pn_op) < 0)
return JS_FALSE;
break;
}
#endif
JS_ASSERT(pn->pn_arity == PN_LIST);
noteIndex = -1;
tmp = CG_OFFSET(cg);
if (pn->pn_extra & PNX_NEEDBRACES) {
noteIndex = js_NewSrcNote2(cx, cg, SRC_BRACE, 0);
if (noteIndex < 0 || js_Emit1(cx, cg, JSOP_NOP) < 0)
return JS_FALSE;
}
js_PushStatement(&cg->treeContext, &stmtInfo, STMT_BLOCK, top);
for (pn2 = pn->pn_head; pn2; pn2 = pn2->pn_next) {
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
}
if (noteIndex >= 0 &&
!js_SetSrcNoteOffset(cx, cg, (uintN)noteIndex, 0,
CG_OFFSET(cg) - tmp)) {
return JS_FALSE;
}
ok = js_PopStatementCG(cx, cg);
break;
case TOK_BODY:
JS_ASSERT(pn->pn_arity == PN_LIST);
js_PushStatement(&cg->treeContext, &stmtInfo, STMT_BODY, top);
for (pn2 = pn->pn_head; pn2; pn2 = pn2->pn_next) {
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
}
ok = js_PopStatementCG(cx, cg);
break;
case TOK_SEMI:
pn2 = pn->pn_kid;
if (pn2) {
/*
* Top-level or called-from-a-native JS_Execute/EvaluateScript,
* debugger, and eval frames may need the value of the ultimate
* expression statement as the script's result, despite the fact
* that it appears useless to the compiler.
*/
useful = wantval = !cx->fp->fun ||
!FUN_INTERPRETED(cx->fp->fun) ||
(cx->fp->flags & JSFRAME_SPECIAL);
if (!useful) {
if (!CheckSideEffects(cx, &cg->treeContext, pn2, &useful))
return JS_FALSE;
}
/*
* Don't eliminate apparently useless expressions if they are
* labeled expression statements. The tc->topStmt->update test
* catches the case where we are nesting in js_EmitTree for a
* labeled compound statement.
*/
if (!useful &&
(!cg->treeContext.topStmt ||
cg->treeContext.topStmt->type != STMT_LABEL ||
cg->treeContext.topStmt->update < CG_OFFSET(cg))) {
CG_CURRENT_LINE(cg) = pn2->pn_pos.begin.lineno;
if (!js_ReportCompileErrorNumber(cx, cg,
JSREPORT_CG |
JSREPORT_WARNING |
JSREPORT_STRICT,
JSMSG_USELESS_EXPR)) {
return JS_FALSE;
}
} else {
op = wantval ? JSOP_POPV : JSOP_POP;
#if JS_HAS_DESTRUCTURING
if (!wantval &&
pn2->pn_type == TOK_ASSIGN &&
!MaybeEmitGroupAssignment(cx, cg, op, pn2, &op)) {
return JS_FALSE;
}
#endif
if (op != JSOP_NOP) {
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
if (js_Emit1(cx, cg, op) < 0)
return JS_FALSE;
}
}
}
break;
case TOK_COLON:
/* Emit an annotated nop so we know to decompile a label. */
atom = pn->pn_atom;
ale = js_IndexAtom(cx, atom, &cg->atomList);
if (!ale)
return JS_FALSE;
pn2 = pn->pn_expr;
noteType = (pn2->pn_type == TOK_LC ||
(pn2->pn_type == TOK_LEXICALSCOPE &&
pn2->pn_expr->pn_type == TOK_LC))
? SRC_LABELBRACE
: SRC_LABEL;
noteIndex = js_NewSrcNote2(cx, cg, noteType,
(ptrdiff_t) ALE_INDEX(ale));
if (noteIndex < 0 ||
js_Emit1(cx, cg, JSOP_NOP) < 0) {
return JS_FALSE;
}
/* Emit code for the labeled statement. */
js_PushStatement(&cg->treeContext, &stmtInfo, STMT_LABEL,
CG_OFFSET(cg));
stmtInfo.atom = atom;
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
if (!js_PopStatementCG(cx, cg))
return JS_FALSE;
/* If the statement was compound, emit a note for the end brace. */
if (noteType == SRC_LABELBRACE) {
if (js_NewSrcNote(cx, cg, SRC_ENDBRACE) < 0 ||
js_Emit1(cx, cg, JSOP_NOP) < 0) {
return JS_FALSE;
}
}
break;
case TOK_COMMA:
/*
* Emit SRC_PCDELTA notes on each JSOP_POP between comma operands.
* These notes help the decompiler bracket the bytecodes generated
* from each sub-expression that follows a comma.
*/
off = noteIndex = -1;
for (pn2 = pn->pn_head; ; pn2 = pn2->pn_next) {
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
tmp = CG_OFFSET(cg);
if (noteIndex >= 0) {
if (!js_SetSrcNoteOffset(cx, cg, (uintN)noteIndex, 0, tmp-off))
return JS_FALSE;
}
if (!pn2->pn_next)
break;
off = tmp;
noteIndex = js_NewSrcNote2(cx, cg, SRC_PCDELTA, 0);
if (noteIndex < 0 ||
js_Emit1(cx, cg, JSOP_POP) < 0) {
return JS_FALSE;
}
}
break;
case TOK_ASSIGN:
/*
* Check left operand type and generate specialized code for it.
* Specialize to avoid ECMA "reference type" values on the operand
* stack, which impose pervasive runtime "GetValue" costs.
*/
pn2 = pn->pn_left;
JS_ASSERT(pn2->pn_type != TOK_RP);
atomIndex = (jsatomid) -1;
switch (pn2->pn_type) {
case TOK_NAME:
if (!BindNameToSlot(cx, &cg->treeContext, pn2, JS_FALSE))
return JS_FALSE;
if (pn2->pn_slot >= 0) {
atomIndex = (jsatomid) pn2->pn_slot;
} else {
ale = js_IndexAtom(cx, pn2->pn_atom, &cg->atomList);
if (!ale)
return JS_FALSE;
atomIndex = ALE_INDEX(ale);
EMIT_ATOM_INDEX_OP(JSOP_BINDNAME, atomIndex);
}
break;
case TOK_DOT:
if (!js_EmitTree(cx, cg, pn2->pn_expr))
return JS_FALSE;
ale = js_IndexAtom(cx, pn2->pn_atom, &cg->atomList);
if (!ale)
return JS_FALSE;
atomIndex = ALE_INDEX(ale);
break;
case TOK_LB:
JS_ASSERT(pn2->pn_arity == PN_BINARY);
if (!js_EmitTree(cx, cg, pn2->pn_left))
return JS_FALSE;
if (!js_EmitTree(cx, cg, pn2->pn_right))
return JS_FALSE;
break;
#if JS_HAS_DESTRUCTURING
case TOK_RB:
case TOK_RC:
break;
#endif
#if JS_HAS_LVALUE_RETURN
case TOK_LP:
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
break;
#endif
#if JS_HAS_XML_SUPPORT
case TOK_UNARYOP:
JS_ASSERT(pn2->pn_op == JSOP_SETXMLNAME);
if (!js_EmitTree(cx, cg, pn2->pn_kid))
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_BINDXMLNAME) < 0)
return JS_FALSE;
break;
#endif
default:
JS_ASSERT(0);
}
op = pn->pn_op;
#if JS_HAS_GETTER_SETTER
if (op == JSOP_GETTER || op == JSOP_SETTER) {
/* We'll emit these prefix bytecodes after emitting the r.h.s. */
if (atomIndex != (jsatomid) -1 && atomIndex >= JS_BIT(16)) {
ReportStatementTooLarge(cx, cg);
return JS_FALSE;
}
if (pn2->pn_type == TOK_NAME && pn2->pn_op != JSOP_SETNAME) {
/*
* x getter = y where x is a local or let variable is not
* supported.
*/
js_ReportCompileErrorNumber(cx,
pn2, JSREPORT_PN | JSREPORT_ERROR,
JSMSG_BAD_GETTER_OR_SETTER,
(op == JSOP_GETTER)
? js_getter_str
: js_setter_str);
return JS_FALSE;
}
} else
#endif
/* If += or similar, dup the left operand and get its value. */
if (op != JSOP_NOP) {
switch (pn2->pn_type) {
case TOK_NAME:
if (pn2->pn_op != JSOP_SETNAME) {
EMIT_UINT16_IMM_OP((pn2->pn_op == JSOP_SETGVAR)
? JSOP_GETGVAR
: (pn2->pn_op == JSOP_SETARG)
? JSOP_GETARG
: (pn2->pn_op == JSOP_SETLOCAL)
? JSOP_GETLOCAL
: JSOP_GETVAR,
atomIndex);
break;
}
/* FALL THROUGH */
case TOK_DOT:
if (js_Emit1(cx, cg, JSOP_DUP) < 0)
return JS_FALSE;
EMIT_ATOM_INDEX_OP((pn2->pn_type == TOK_NAME)
? JSOP_GETXPROP
: JSOP_GETPROP,
atomIndex);
break;
case TOK_LB:
#if JS_HAS_LVALUE_RETURN
case TOK_LP:
#endif
#if JS_HAS_XML_SUPPORT
case TOK_UNARYOP:
#endif
if (js_Emit1(cx, cg, JSOP_DUP2) < 0)
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_GETELEM) < 0)
return JS_FALSE;
break;
default:;
}
}
/* Now emit the right operand (it may affect the namespace). */
if (!js_EmitTree(cx, cg, pn->pn_right))
return JS_FALSE;
/* If += etc., emit the binary operator with a decompiler note. */
if (op != JSOP_NOP) {
/*
* Take care to avoid SRC_ASSIGNOP if the left-hand side is a
* const declared in a function (i.e., with non-negative pn_slot
* and JSPROP_READONLY in pn_attrs), as in this case (just a bit
* further below) we will avoid emitting the assignment op.
*/
if (pn2->pn_type != TOK_NAME ||
pn2->pn_slot < 0 ||
!(pn2->pn_attrs & JSPROP_READONLY)) {
if (js_NewSrcNote(cx, cg, SRC_ASSIGNOP) < 0)
return JS_FALSE;
}
if (js_Emit1(cx, cg, op) < 0)
return JS_FALSE;
}
/* Left parts such as a.b.c and a[b].c need a decompiler note. */
if (pn2->pn_type != TOK_NAME &&
#if JS_HAS_DESTRUCTURING
pn2->pn_type != TOK_RB &&
pn2->pn_type != TOK_RC &&
#endif
js_NewSrcNote2(cx, cg, SrcNoteForPropOp(pn2, pn2->pn_op),
CG_OFFSET(cg) - top) < 0) {
return JS_FALSE;
}
/* Finally, emit the specialized assignment bytecode. */
switch (pn2->pn_type) {
case TOK_NAME:
if (pn2->pn_slot >= 0) {
if (!(pn2->pn_attrs & JSPROP_READONLY))
EMIT_UINT16_IMM_OP(pn2->pn_op, atomIndex);
break;
}
/* FALL THROUGH */
case TOK_DOT:
EMIT_ATOM_INDEX_OP(pn2->pn_op, atomIndex);
break;
case TOK_LB:
#if JS_HAS_LVALUE_RETURN
case TOK_LP:
#endif
if (js_Emit1(cx, cg, JSOP_SETELEM) < 0)
return JS_FALSE;
break;
#if JS_HAS_DESTRUCTURING
case TOK_RB:
case TOK_RC:
if (!EmitDestructuringOps(cx, cg, JSOP_SETNAME, pn2))
return JS_FALSE;
break;
#endif
#if JS_HAS_XML_SUPPORT
case TOK_UNARYOP:
if (js_Emit1(cx, cg, JSOP_SETXMLNAME) < 0)
return JS_FALSE;
break;
#endif
default:
JS_ASSERT(0);
}
break;
case TOK_HOOK:
/* Emit the condition, then branch if false to the else part. */
if (!js_EmitTree(cx, cg, pn->pn_kid1))
return JS_FALSE;
noteIndex = js_NewSrcNote(cx, cg, SRC_COND);
if (noteIndex < 0)
return JS_FALSE;
beq = EmitJump(cx, cg, JSOP_IFEQ, 0);
if (beq < 0 || !js_EmitTree(cx, cg, pn->pn_kid2))
return JS_FALSE;
/* Jump around else, fixup the branch, emit else, fixup jump. */
jmp = EmitJump(cx, cg, JSOP_GOTO, 0);
if (jmp < 0)
return JS_FALSE;
CHECK_AND_SET_JUMP_OFFSET_AT(cx, cg, beq);
/*
* Because each branch pushes a single value, but our stack budgeting
* analysis ignores branches, we now have to adjust cg->stackDepth to
* ignore the value pushed by the first branch. Execution will follow
* only one path, so we must decrement cg->stackDepth.
*
* Failing to do this will foil code, such as the try/catch/finally
* exception handling code generator, that samples cg->stackDepth for
* use at runtime (JSOP_SETSP), or in let expression and block code
* generation, which must use the stack depth to compute local stack
* indexes correctly.
*/
JS_ASSERT(cg->stackDepth > 0);
cg->stackDepth--;
if (!js_EmitTree(cx, cg, pn->pn_kid3))
return JS_FALSE;
CHECK_AND_SET_JUMP_OFFSET_AT(cx, cg, jmp);
if (!js_SetSrcNoteOffset(cx, cg, noteIndex, 0, jmp - beq))
return JS_FALSE;
break;
case TOK_OR:
case TOK_AND:
/*
* JSOP_OR converts the operand on the stack to boolean, and if true,
* leaves the original operand value on the stack and jumps; otherwise
* it pops and falls into the next bytecode, which evaluates the right
* operand. The jump goes around the right operand evaluation.
*
* JSOP_AND converts the operand on the stack to boolean, and if false,
* leaves the original operand value on the stack and jumps; otherwise
* it pops and falls into the right operand's bytecode.
*
* Avoid tail recursion for long ||...|| expressions and long &&...&&
* expressions or long mixtures of ||'s and &&'s that can easily blow
* the stack, by forward-linking and then backpatching all the JSOP_OR
* and JSOP_AND bytecodes' immediate jump-offset operands.
*/
pn3 = pn;
if (!js_EmitTree(cx, cg, pn->pn_left))
return JS_FALSE;
top = EmitJump(cx, cg, JSOP_BACKPATCH_POP, 0);
if (top < 0)
return JS_FALSE;
jmp = top;
pn2 = pn->pn_right;
while (pn2->pn_type == TOK_OR || pn2->pn_type == TOK_AND) {
pn = pn2;
if (!js_EmitTree(cx, cg, pn->pn_left))
return JS_FALSE;
off = EmitJump(cx, cg, JSOP_BACKPATCH_POP, 0);
if (off < 0)
return JS_FALSE;
if (!SetBackPatchDelta(cx, cg, CG_CODE(cg, jmp), off - jmp))
return JS_FALSE;
jmp = off;
pn2 = pn->pn_right;
}
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
off = CG_OFFSET(cg);
do {
pc = CG_CODE(cg, top);
tmp = GetJumpOffset(cg, pc);
CHECK_AND_SET_JUMP_OFFSET(cx, cg, pc, off - top);
*pc = pn3->pn_op;
top += tmp;
} while ((pn3 = pn3->pn_right) != pn2);
break;
case TOK_BITOR:
case TOK_BITXOR:
case TOK_BITAND:
case TOK_EQOP:
case TOK_RELOP:
case TOK_IN:
case TOK_INSTANCEOF:
case TOK_SHOP:
case TOK_PLUS:
case TOK_MINUS:
case TOK_STAR:
case TOK_DIVOP:
if (pn->pn_arity == PN_LIST) {
/* Left-associative operator chain: avoid too much recursion. */
pn2 = pn->pn_head;
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
op = pn->pn_op;
while ((pn2 = pn2->pn_next) != NULL) {
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
if (js_Emit1(cx, cg, op) < 0)
return JS_FALSE;
}
} else {
#if JS_HAS_XML_SUPPORT
uintN oldflags;
case TOK_DBLCOLON:
if (pn->pn_arity == PN_NAME) {
if (!js_EmitTree(cx, cg, pn->pn_expr))
return JS_FALSE;
if (!EmitAtomOp(cx, pn, pn->pn_op, cg))
return JS_FALSE;
break;
}
/*
* Binary :: has a right operand that brackets arbitrary code,
* possibly including a let (a = b) ... expression. We must clear
* TCF_IN_FOR_INIT to avoid mis-compiling such beasts.
*/
oldflags = cg->treeContext.flags;
cg->treeContext.flags &= ~TCF_IN_FOR_INIT;
#endif
/* Binary operators that evaluate both operands unconditionally. */
if (!js_EmitTree(cx, cg, pn->pn_left))
return JS_FALSE;
if (!js_EmitTree(cx, cg, pn->pn_right))
return JS_FALSE;
#if JS_HAS_XML_SUPPORT
cg->treeContext.flags |= oldflags & TCF_IN_FOR_INIT;
#endif
if (js_Emit1(cx, cg, pn->pn_op) < 0)
return JS_FALSE;
}
break;
case TOK_THROW:
#if JS_HAS_XML_SUPPORT
case TOK_AT:
case TOK_DEFAULT:
JS_ASSERT(pn->pn_arity == PN_UNARY);
/* FALL THROUGH */
#endif
case TOK_UNARYOP:
{
uintN oldflags;
/* Unary op, including unary +/-. */
pn2 = pn->pn_kid;
op = pn->pn_op;
if (op == JSOP_TYPEOF) {
for (pn3 = pn2; pn3->pn_type == TOK_RP; pn3 = pn3->pn_kid)
continue;
if (pn3->pn_type != TOK_NAME)
op = JSOP_TYPEOFEXPR;
}
oldflags = cg->treeContext.flags;
cg->treeContext.flags &= ~TCF_IN_FOR_INIT;
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
cg->treeContext.flags |= oldflags & TCF_IN_FOR_INIT;
#if JS_HAS_XML_SUPPORT
if (op == JSOP_XMLNAME &&
js_NewSrcNote2(cx, cg, SRC_PCBASE,
CG_OFFSET(cg) - pn2->pn_offset) < 0) {
return JS_FALSE;
}
#endif
if (js_Emit1(cx, cg, op) < 0)
return JS_FALSE;
break;
}
case TOK_INC:
case TOK_DEC:
{
intN depth;
/* Emit lvalue-specialized code for ++/-- operators. */
pn2 = pn->pn_kid;
JS_ASSERT(pn2->pn_type != TOK_RP);
op = pn->pn_op;
depth = cg->stackDepth;
switch (pn2->pn_type) {
case TOK_NAME:
pn2->pn_op = op;
if (!BindNameToSlot(cx, &cg->treeContext, pn2, JS_FALSE))
return JS_FALSE;
op = pn2->pn_op;
if (pn2->pn_slot >= 0) {
if (pn2->pn_attrs & JSPROP_READONLY) {
/* Incrementing a declared const: just get its value. */
op = ((js_CodeSpec[op].format & JOF_TYPEMASK) == JOF_CONST)
? JSOP_GETGVAR
: JSOP_GETVAR;
}
atomIndex = (jsatomid) pn2->pn_slot;
EMIT_UINT16_IMM_OP(op, atomIndex);
} else {
if (!EmitAtomOp(cx, pn2, op, cg))
return JS_FALSE;
}
break;
case TOK_DOT:
if (!EmitPropOp(cx, pn2, op, cg))
return JS_FALSE;
++depth;
break;
case TOK_LB:
if (!EmitElemOp(cx, pn2, op, cg))
return JS_FALSE;
depth += 2;
break;
#if JS_HAS_LVALUE_RETURN
case TOK_LP:
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
depth = cg->stackDepth;
if (js_NewSrcNote2(cx, cg, SRC_PCBASE,
CG_OFFSET(cg) - pn2->pn_offset) < 0) {
return JS_FALSE;
}
if (js_Emit1(cx, cg, op) < 0)
return JS_FALSE;
break;
#endif
#if JS_HAS_XML_SUPPORT
case TOK_UNARYOP:
JS_ASSERT(pn2->pn_op == JSOP_SETXMLNAME);
if (!js_EmitTree(cx, cg, pn2->pn_kid))
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_BINDXMLNAME) < 0)
return JS_FALSE;
depth = cg->stackDepth;
if (js_Emit1(cx, cg, op) < 0)
return JS_FALSE;
break;
#endif
default:
JS_ASSERT(0);
}
/*
* Allocate another stack slot for GC protection in case the initial
* value being incremented or decremented is not a number, but
* converts to a jsdouble. In the TOK_NAME cases, op has 0 operand
* uses and 1 definition, so we don't need an extra stack slot -- we
* can use the one allocated for the def.
*/
if (pn2->pn_type != TOK_NAME &&
(js_CodeSpec[op].format & (JOF_INC | JOF_DEC)) &&
(uintN)depth == cg->maxStackDepth) {
++cg->maxStackDepth;
}
break;
}
case TOK_DELETE:
/*
* Under ECMA 3, deleting a non-reference returns true -- but alas we
* must evaluate the operand if it appears it might have side effects.
*/
pn2 = pn->pn_kid;
switch (pn2->pn_type) {
case TOK_NAME:
pn2->pn_op = JSOP_DELNAME;
if (!BindNameToSlot(cx, &cg->treeContext, pn2, JS_FALSE))
return JS_FALSE;
op = pn2->pn_op;
if (op == JSOP_FALSE) {
if (js_Emit1(cx, cg, op) < 0)
return JS_FALSE;
} else {
if (!EmitAtomOp(cx, pn2, op, cg))
return JS_FALSE;
}
break;
case TOK_DOT:
if (!EmitPropOp(cx, pn2, JSOP_DELPROP, cg))
return JS_FALSE;
break;
#if JS_HAS_XML_SUPPORT
case TOK_DBLDOT:
if (!EmitElemOp(cx, pn2, JSOP_DELDESC, cg))
return JS_FALSE;
break;
#endif
#if JS_HAS_LVALUE_RETURN
case TOK_LP:
if (pn2->pn_op != JSOP_SETCALL) {
JS_ASSERT(pn2->pn_op == JSOP_CALL || pn2->pn_op == JSOP_EVAL);
pn2->pn_op = JSOP_SETCALL;
}
top = CG_OFFSET(cg);
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
if (js_NewSrcNote2(cx, cg, SRC_PCBASE, CG_OFFSET(cg) - top) < 0)
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_DELELEM) < 0)
return JS_FALSE;
break;
#endif
case TOK_LB:
if (!EmitElemOp(cx, pn2, JSOP_DELELEM, cg))
return JS_FALSE;
break;
default:
/*
* If useless, just emit JSOP_TRUE; otherwise convert delete foo()
* to foo(), true (a comma expression, requiring SRC_PCDELTA).
*/
useful = JS_FALSE;
if (!CheckSideEffects(cx, &cg->treeContext, pn2, &useful))
return JS_FALSE;
if (!useful) {
off = noteIndex = -1;
} else {
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
off = CG_OFFSET(cg);
noteIndex = js_NewSrcNote2(cx, cg, SRC_PCDELTA, 0);
if (noteIndex < 0 || js_Emit1(cx, cg, JSOP_POP) < 0)
return JS_FALSE;
}
if (js_Emit1(cx, cg, JSOP_TRUE) < 0)
return JS_FALSE;
if (noteIndex >= 0) {
tmp = CG_OFFSET(cg);
if (!js_SetSrcNoteOffset(cx, cg, (uintN)noteIndex, 0, tmp-off))
return JS_FALSE;
}
}
break;
#if JS_HAS_XML_SUPPORT
case TOK_FILTER:
if (!js_EmitTree(cx, cg, pn->pn_left))
return JS_FALSE;
jmp = js_Emit3(cx, cg, JSOP_FILTER, 0, 0);
if (jmp < 0)
return JS_FALSE;
if (!js_EmitTree(cx, cg, pn->pn_right))
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_ENDFILTER) < 0)
return JS_FALSE;
CHECK_AND_SET_JUMP_OFFSET_AT(cx, cg, jmp);
break;
#endif
case TOK_DOT:
/*
* Pop a stack operand, convert it to object, get a property named by
* this bytecode's immediate-indexed atom operand, and push its value
* (not a reference to it). This bytecode sets the virtual machine's
* "obj" register to the left operand's ToObject conversion result,
* for use by JSOP_PUSHOBJ.
*/
ok = EmitPropOp(cx, pn, pn->pn_op, cg);
break;
case TOK_LB:
#if JS_HAS_XML_SUPPORT
case TOK_DBLDOT:
#endif
/*
* Pop two operands, convert the left one to object and the right one
* to property name (atom or tagged int), get the named property, and
* push its value. Set the "obj" register to the result of ToObject
* on the left operand.
*/
ok = EmitElemOp(cx, pn, pn->pn_op, cg);
break;
case TOK_NEW:
case TOK_LP:
{
uintN oldflags;
/*
* Emit function call or operator new (constructor call) code.
* First, emit code for the left operand to evaluate the callable or
* constructable object expression.
*
* For E4X, if this expression is a dotted member reference, select
* JSOP_GETMETHOD instead of JSOP_GETPROP. ECMA-357 separates XML
* method lookup from the normal property id lookup done for native
* objects.
*/
pn2 = pn->pn_head;
#if JS_HAS_XML_SUPPORT
if (pn2->pn_type == TOK_DOT && pn2->pn_op != JSOP_GETMETHOD) {
JS_ASSERT(pn2->pn_op == JSOP_GETPROP);
pn2->pn_op = JSOP_GETMETHOD;
pn2->pn_attrs |= JSPROP_IMPLICIT_FUNCTION_NAMESPACE;
}
#endif
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
/*
* Push the virtual machine's "obj" register, which was set by a
* name, property, or element get (or set) bytecode.
*/
if (js_Emit1(cx, cg, JSOP_PUSHOBJ) < 0)
return JS_FALSE;
/* Remember start of callable-object bytecode for decompilation hint. */
off = top;
/*
* Emit code for each argument in order, then emit the JSOP_*CALL or
* JSOP_NEW bytecode with a two-byte immediate telling how many args
* were pushed on the operand stack.
*/
oldflags = cg->treeContext.flags;
cg->treeContext.flags &= ~TCF_IN_FOR_INIT;
for (pn2 = pn2->pn_next; pn2; pn2 = pn2->pn_next) {
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
}
cg->treeContext.flags |= oldflags & TCF_IN_FOR_INIT;
if (js_NewSrcNote2(cx, cg, SRC_PCBASE, CG_OFFSET(cg) - off) < 0)
return JS_FALSE;
argc = pn->pn_count - 1;
if (js_Emit3(cx, cg, pn->pn_op, ARGC_HI(argc), ARGC_LO(argc)) < 0)
return JS_FALSE;
break;
}
case TOK_LEXICALSCOPE:
{
JSObject *obj;
jsint count;
atom = pn->pn_atom;
obj = ATOM_TO_OBJECT(atom);
js_PushBlockScope(&cg->treeContext, &stmtInfo, atom, CG_OFFSET(cg));
OBJ_SET_BLOCK_DEPTH(cx, obj, cg->stackDepth);
count = OBJ_BLOCK_COUNT(cx, obj);
cg->stackDepth += count;
if ((uintN)cg->stackDepth > cg->maxStackDepth)
cg->maxStackDepth = cg->stackDepth;
/*
* If this lexical scope is not for a catch block, let block or let
* expression, or any kind of for loop (where the scope starts in the
* head after the first part if for (;;), else in the body if for-in);
* and if our container is top-level but not a function body, or else
* a block statement; then emit a SRC_BRACE note. All other container
* statements get braces by default from the decompiler.
*/
noteIndex = -1;
type = pn->pn_expr->pn_type;
if (type != TOK_CATCH && type != TOK_LET && type != TOK_FOR &&
(!(stmt = stmtInfo.down)
? !(cg->treeContext.flags & TCF_IN_FUNCTION)
: stmt->type == STMT_BLOCK)) {
#if defined DEBUG_brendan || defined DEBUG_mrbkap
/* There must be no source note already output for the next op. */
JS_ASSERT(CG_NOTE_COUNT(cg) == 0 ||
CG_LAST_NOTE_OFFSET(cg) != CG_OFFSET(cg) ||
!GettableNoteForNextOp(cg));
#endif
noteIndex = js_NewSrcNote2(cx, cg, SRC_BRACE, 0);
if (noteIndex < 0)
return JS_FALSE;
}
ale = js_IndexAtom(cx, atom, &cg->atomList);
if (!ale)
return JS_FALSE;
JS_ASSERT(CG_OFFSET(cg) == top);
EMIT_ATOM_INDEX_OP(JSOP_ENTERBLOCK, ALE_INDEX(ale));
if (!js_EmitTree(cx, cg, pn->pn_expr))
return JS_FALSE;
op = pn->pn_op;
if (op == JSOP_LEAVEBLOCKEXPR) {
if (js_NewSrcNote2(cx, cg, SRC_PCBASE, CG_OFFSET(cg) - top) < 0)
return JS_FALSE;
} else {
if (noteIndex >= 0 &&
!js_SetSrcNoteOffset(cx, cg, (uintN)noteIndex, 0,
CG_OFFSET(cg) - top)) {
return JS_FALSE;
}
}
/* Emit the JSOP_LEAVEBLOCK or JSOP_LEAVEBLOCKEXPR opcode. */
EMIT_UINT16_IMM_OP(op, count);
cg->stackDepth -= count;
ok = js_PopStatementCG(cx, cg);
break;
}
#if JS_HAS_BLOCK_SCOPE
case TOK_LET:
/* Let statements have their variable declarations on the left. */
if (pn->pn_arity == PN_BINARY) {
pn2 = pn->pn_right;
pn = pn->pn_left;
} else {
pn2 = NULL;
}
/* Non-null pn2 means that pn is the variable list from a let head. */
JS_ASSERT(pn->pn_arity == PN_LIST);
if (!EmitVariables(cx, cg, pn, pn2 != NULL, &noteIndex))
return JS_FALSE;
/* Thus non-null pn2 is the body of the let block or expression. */
tmp = CG_OFFSET(cg);
if (pn2 && !js_EmitTree(cx, cg, pn2))
return JS_FALSE;
if (noteIndex >= 0 &&
!js_SetSrcNoteOffset(cx, cg, (uintN)noteIndex, 0,
CG_OFFSET(cg) - tmp)) {
return JS_FALSE;
}
break;
#endif /* JS_HAS_BLOCK_SCOPE */
#if JS_HAS_GENERATORS
case TOK_ARRAYPUSH:
/*
* The array object's stack index is in cg->arrayCompSlot. See below
* under the array initialiser code generator for array comprehension
* special casing.
*/
if (!js_EmitTree(cx, cg, pn->pn_kid))
return JS_FALSE;
EMIT_UINT16_IMM_OP(pn->pn_op, cg->arrayCompSlot);
break;
#endif
case TOK_RB:
#if JS_HAS_GENERATORS
case TOK_ARRAYCOMP:
#endif
/*
* Emit code for [a, b, c] of the form:
* t = new Array; t[0] = a; t[1] = b; t[2] = c; t;
* but use a stack slot for t and avoid dup'ing and popping it via
* the JSOP_NEWINIT and JSOP_INITELEM bytecodes.
*/
ale = js_IndexAtom(cx, CLASS_ATOM(cx, Array), &cg->atomList);
if (!ale)
return JS_FALSE;
EMIT_ATOM_INDEX_OP(JSOP_NAME, ALE_INDEX(ale));
if (js_Emit1(cx, cg, JSOP_PUSHOBJ) < 0)
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_NEWINIT) < 0)
return JS_FALSE;
pn2 = pn->pn_head;
#if JS_HAS_SHARP_VARS
if (pn2 && pn2->pn_type == TOK_DEFSHARP) {
EMIT_UINT16_IMM_OP(JSOP_DEFSHARP, (jsatomid)pn2->pn_num);
pn2 = pn2->pn_next;
}
#endif
#if JS_HAS_GENERATORS
if (pn->pn_type == TOK_ARRAYCOMP) {
uintN saveSlot;
/*
* Pass the new array's stack index to the TOK_ARRAYPUSH case by
* storing it in pn->pn_extra, then simply traverse the TOK_FOR
* node and its kids under pn2 to generate this comprehension.
*/
JS_ASSERT(cg->stackDepth > 0);
saveSlot = cg->arrayCompSlot;
cg->arrayCompSlot = (uint32) (cg->stackDepth - 1);
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
cg->arrayCompSlot = saveSlot;
/* Emit the usual op needed for decompilation. */
if (js_Emit1(cx, cg, JSOP_ENDINIT) < 0)
return JS_FALSE;
break;
}
#endif /* JS_HAS_GENERATORS */
for (atomIndex = 0; pn2; atomIndex++, pn2 = pn2->pn_next) {
if (!EmitNumberOp(cx, atomIndex, cg))
return JS_FALSE;
/* FIXME 260106: holes in a sparse initializer are void-filled. */
if (pn2->pn_type == TOK_COMMA) {
if (js_Emit1(cx, cg, JSOP_PUSH) < 0)
return JS_FALSE;
} else {
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
}
if (js_Emit1(cx, cg, JSOP_INITELEM) < 0)
return JS_FALSE;
}
if (pn->pn_extra & PNX_ENDCOMMA) {
/* Emit a source note so we know to decompile an extra comma. */
if (js_NewSrcNote(cx, cg, SRC_CONTINUE) < 0)
return JS_FALSE;
}
/* Emit an op for sharp array cleanup and decompilation. */
if (js_Emit1(cx, cg, JSOP_ENDINIT) < 0)
return JS_FALSE;
break;
case TOK_RC:
/*
* Emit code for {p:a, '%q':b, 2:c} of the form:
* t = new Object; t.p = a; t['%q'] = b; t[2] = c; t;
* but use a stack slot for t and avoid dup'ing and popping it via
* the JSOP_NEWINIT and JSOP_INITELEM bytecodes.
*/
ale = js_IndexAtom(cx, CLASS_ATOM(cx, Object), &cg->atomList);
if (!ale)
return JS_FALSE;
EMIT_ATOM_INDEX_OP(JSOP_NAME, ALE_INDEX(ale));
if (js_Emit1(cx, cg, JSOP_PUSHOBJ) < 0)
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_NEWINIT) < 0)
return JS_FALSE;
pn2 = pn->pn_head;
#if JS_HAS_SHARP_VARS
if (pn2 && pn2->pn_type == TOK_DEFSHARP) {
EMIT_UINT16_IMM_OP(JSOP_DEFSHARP, (jsatomid)pn2->pn_num);
pn2 = pn2->pn_next;
}
#endif
for (; pn2; pn2 = pn2->pn_next) {
/* Emit an index for t[2], else map an atom for t.p or t['%q']. */
pn3 = pn2->pn_left;
switch (pn3->pn_type) {
case TOK_NUMBER:
if (!EmitNumberOp(cx, pn3->pn_dval, cg))
return JS_FALSE;
break;
case TOK_NAME:
case TOK_STRING:
ale = js_IndexAtom(cx, pn3->pn_atom, &cg->atomList);
if (!ale)
return JS_FALSE;
break;
default:
JS_ASSERT(0);
}
/* Emit code for the property initializer. */
if (!js_EmitTree(cx, cg, pn2->pn_right))
return JS_FALSE;
#if JS_HAS_GETTER_SETTER
op = pn2->pn_op;
if (op == JSOP_GETTER || op == JSOP_SETTER) {
if (pn3->pn_type != TOK_NUMBER &&
ALE_INDEX(ale) >= JS_BIT(16)) {
ReportStatementTooLarge(cx, cg);
return JS_FALSE;
}
if (js_Emit1(cx, cg, op) < 0)
return JS_FALSE;
}
#endif
/* Annotate JSOP_INITELEM so we decompile 2:c and not just c. */
if (pn3->pn_type == TOK_NUMBER) {
if (js_NewSrcNote(cx, cg, SRC_INITPROP) < 0)
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_INITELEM) < 0)
return JS_FALSE;
} else {
EMIT_ATOM_INDEX_OP(JSOP_INITPROP, ALE_INDEX(ale));
}
}
/* Emit an op for sharpArray cleanup and decompilation. */
if (js_Emit1(cx, cg, JSOP_ENDINIT) < 0)
return JS_FALSE;
break;
#if JS_HAS_SHARP_VARS
case TOK_DEFSHARP:
if (!js_EmitTree(cx, cg, pn->pn_kid))
return JS_FALSE;
EMIT_UINT16_IMM_OP(JSOP_DEFSHARP, (jsatomid) pn->pn_num);
break;
case TOK_USESHARP:
EMIT_UINT16_IMM_OP(JSOP_USESHARP, (jsatomid) pn->pn_num);
break;
#endif /* JS_HAS_SHARP_VARS */
case TOK_RP:
{
uintN oldflags;
/*
* The node for (e) has e as its kid, enabling users who want to nest
* assignment expressions in conditions to avoid the error correction
* done by Condition (from x = y to x == y) by double-parenthesizing.
*/
oldflags = cg->treeContext.flags;
cg->treeContext.flags &= ~TCF_IN_FOR_INIT;
if (!js_EmitTree(cx, cg, pn->pn_kid))
return JS_FALSE;
cg->treeContext.flags |= oldflags & TCF_IN_FOR_INIT;
if (js_Emit1(cx, cg, JSOP_GROUP) < 0)
return JS_FALSE;
break;
}
case TOK_NAME:
if (!BindNameToSlot(cx, &cg->treeContext, pn, JS_FALSE))
return JS_FALSE;
op = pn->pn_op;
if (op == JSOP_ARGUMENTS) {
if (js_Emit1(cx, cg, op) < 0)
return JS_FALSE;
break;
}
if (pn->pn_slot >= 0) {
atomIndex = (jsatomid) pn->pn_slot;
EMIT_UINT16_IMM_OP(op, atomIndex);
break;
}
/* FALL THROUGH */
#if JS_HAS_XML_SUPPORT
case TOK_XMLATTR:
case TOK_XMLSPACE:
case TOK_XMLTEXT:
case TOK_XMLCDATA:
case TOK_XMLCOMMENT:
#endif
case TOK_STRING:
case TOK_OBJECT:
/*
* The scanner and parser associate JSOP_NAME with TOK_NAME, although
* other bytecodes may result instead (JSOP_BINDNAME/JSOP_SETNAME,
* JSOP_FORNAME, etc.). Among JSOP_*NAME* variants, only JSOP_NAME
* may generate the first operand of a call or new expression, so only
* it sets the "obj" virtual machine register to the object along the
* scope chain in which the name was found.
*
* Token types for STRING and OBJECT have corresponding bytecode ops
* in pn_op and emit the same format as NAME, so they share this code.
*/
ok = EmitAtomOp(cx, pn, pn->pn_op, cg);
break;
case TOK_NUMBER:
ok = EmitNumberOp(cx, pn->pn_dval, cg);
break;
#if JS_HAS_XML_SUPPORT
case TOK_ANYNAME:
#endif
case TOK_PRIMARY:
if (js_Emit1(cx, cg, pn->pn_op) < 0)
return JS_FALSE;
break;
#if JS_HAS_DEBUGGER_KEYWORD
case TOK_DEBUGGER:
if (js_Emit1(cx, cg, JSOP_DEBUGGER) < 0)
return JS_FALSE;
break;
#endif /* JS_HAS_DEBUGGER_KEYWORD */
#if JS_HAS_XML_SUPPORT
case TOK_XMLELEM:
case TOK_XMLLIST:
if (pn->pn_op == JSOP_XMLOBJECT) {
ok = EmitAtomOp(cx, pn, pn->pn_op, cg);
break;
}
JS_ASSERT(pn->pn_type == TOK_XMLLIST || pn->pn_count != 0);
switch (pn->pn_head ? pn->pn_head->pn_type : TOK_XMLLIST) {
case TOK_XMLETAGO:
JS_ASSERT(0);
/* FALL THROUGH */
case TOK_XMLPTAGC:
case TOK_XMLSTAGO:
break;
default:
if (js_Emit1(cx, cg, JSOP_STARTXML) < 0)
return JS_FALSE;
}
for (pn2 = pn->pn_head; pn2; pn2 = pn2->pn_next) {
if (pn2->pn_type == TOK_LC &&
js_Emit1(cx, cg, JSOP_STARTXMLEXPR) < 0) {
return JS_FALSE;
}
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
if (pn2 != pn->pn_head && js_Emit1(cx, cg, JSOP_ADD) < 0)
return JS_FALSE;
}
if (pn->pn_extra & PNX_XMLROOT) {
if (pn->pn_count == 0) {
JS_ASSERT(pn->pn_type == TOK_XMLLIST);
atom = cx->runtime->atomState.emptyAtom;
ale = js_IndexAtom(cx, atom, &cg->atomList);
if (!ale)
return JS_FALSE;
EMIT_ATOM_INDEX_OP(JSOP_STRING, ALE_INDEX(ale));
}
if (js_Emit1(cx, cg, pn->pn_op) < 0)
return JS_FALSE;
}
#ifdef DEBUG
else
JS_ASSERT(pn->pn_count != 0);
#endif
break;
case TOK_XMLPTAGC:
if (pn->pn_op == JSOP_XMLOBJECT) {
ok = EmitAtomOp(cx, pn, pn->pn_op, cg);
break;
}
/* FALL THROUGH */
case TOK_XMLSTAGO:
case TOK_XMLETAGO:
{
uint32 i;
if (js_Emit1(cx, cg, JSOP_STARTXML) < 0)
return JS_FALSE;
ale = js_IndexAtom(cx,
(pn->pn_type == TOK_XMLETAGO)
? cx->runtime->atomState.etagoAtom
: cx->runtime->atomState.stagoAtom,
&cg->atomList);
if (!ale)
return JS_FALSE;
EMIT_ATOM_INDEX_OP(JSOP_STRING, ALE_INDEX(ale));
JS_ASSERT(pn->pn_count != 0);
pn2 = pn->pn_head;
if (pn2->pn_type == TOK_LC && js_Emit1(cx, cg, JSOP_STARTXMLEXPR) < 0)
return JS_FALSE;
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
if (js_Emit1(cx, cg, JSOP_ADD) < 0)
return JS_FALSE;
for (pn2 = pn2->pn_next, i = 0; pn2; pn2 = pn2->pn_next, i++) {
if (pn2->pn_type == TOK_LC &&
js_Emit1(cx, cg, JSOP_STARTXMLEXPR) < 0) {
return JS_FALSE;
}
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
if ((i & 1) && pn2->pn_type == TOK_LC) {
if (js_Emit1(cx, cg, JSOP_TOATTRVAL) < 0)
return JS_FALSE;
}
if (js_Emit1(cx, cg,
(i & 1) ? JSOP_ADDATTRVAL : JSOP_ADDATTRNAME) < 0) {
return JS_FALSE;
}
}
ale = js_IndexAtom(cx,
(pn->pn_type == TOK_XMLPTAGC)
? cx->runtime->atomState.ptagcAtom
: cx->runtime->atomState.tagcAtom,
&cg->atomList);
if (!ale)
return JS_FALSE;
EMIT_ATOM_INDEX_OP(JSOP_STRING, ALE_INDEX(ale));
if (js_Emit1(cx, cg, JSOP_ADD) < 0)
return JS_FALSE;
if ((pn->pn_extra & PNX_XMLROOT) && js_Emit1(cx, cg, pn->pn_op) < 0)
return JS_FALSE;
break;
}
case TOK_XMLNAME:
if (pn->pn_arity == PN_LIST) {
JS_ASSERT(pn->pn_count != 0);
for (pn2 = pn->pn_head; pn2; pn2 = pn2->pn_next) {
if (!js_EmitTree(cx, cg, pn2))
return JS_FALSE;
if (pn2 != pn->pn_head && js_Emit1(cx, cg, JSOP_ADD) < 0)
return JS_FALSE;
}
} else {
JS_ASSERT(pn->pn_arity == PN_NULLARY);
ok = EmitAtomOp(cx, pn, pn->pn_op, cg);
}
break;
case TOK_XMLPI:
ale = js_IndexAtom(cx, pn->pn_atom2, &cg->atomList);
if (!ale)
return JS_FALSE;
if (!EmitAtomIndexOp(cx, JSOP_QNAMEPART, ALE_INDEX(ale), cg))
return JS_FALSE;
if (!EmitAtomOp(cx, pn, JSOP_XMLPI, cg))
return JS_FALSE;
break;
#endif /* JS_HAS_XML_SUPPORT */
default:
JS_ASSERT(0);
}
if (ok && --cg->emitLevel == 0 && cg->spanDeps)
ok = OptimizeSpanDeps(cx, cg);
return ok;
}
/* XXX get rid of offsetBias, it's used only by SRC_FOR and SRC_DECL */
JS_FRIEND_DATA(JSSrcNoteSpec) js_SrcNoteSpec[] = {
{"null", 0, 0, 0},
{"if", 0, 0, 0},
{"if-else", 2, 0, 1},
{"while", 1, 0, 1},
{"for", 3, 1, 1},
{"continue", 0, 0, 0},
{"decl", 1, 1, 1},
{"pcdelta", 1, 0, 1},
{"assignop", 0, 0, 0},
{"cond", 1, 0, 1},
{"brace", 1, 0, 1},
{"hidden", 0, 0, 0},
{"pcbase", 1, 0, -1},
{"label", 1, 0, 0},
{"labelbrace", 1, 0, 0},
{"endbrace", 0, 0, 0},
{"break2label", 1, 0, 0},
{"cont2label", 1, 0, 0},
{"switch", 2, 0, 1},
{"funcdef", 1, 0, 0},
{"catch", 1, 0, 1},
{"extended", -1, 0, 0},
{"newline", 0, 0, 0},
{"setline", 1, 0, 0},
{"xdelta", 0, 0, 0},
};
static intN
AllocSrcNote(JSContext *cx, JSCodeGenerator *cg)
{
intN index;
JSArenaPool *pool;
size_t size;
index = CG_NOTE_COUNT(cg);
if (((uintN)index & CG_NOTE_MASK(cg)) == 0) {
pool = cg->notePool;
size = SRCNOTE_SIZE(CG_NOTE_MASK(cg) + 1);
if (!CG_NOTES(cg)) {
/* Allocate the first note array lazily; leave noteMask alone. */
JS_ARENA_ALLOCATE_CAST(CG_NOTES(cg), jssrcnote *, pool, size);
} else {
/* Grow by doubling note array size; update noteMask on success. */
JS_ARENA_GROW_CAST(CG_NOTES(cg), jssrcnote *, pool, size, size);
if (CG_NOTES(cg))
CG_NOTE_MASK(cg) = (CG_NOTE_MASK(cg) << 1) | 1;
}
if (!CG_NOTES(cg)) {
JS_ReportOutOfMemory(cx);
return -1;
}
}
CG_NOTE_COUNT(cg) = index + 1;
return index;
}
intN
js_NewSrcNote(JSContext *cx, JSCodeGenerator *cg, JSSrcNoteType type)
{
intN index, n;
jssrcnote *sn;
ptrdiff_t offset, delta, xdelta;
/*
* Claim a note slot in CG_NOTES(cg) by growing it if necessary and then
* incrementing CG_NOTE_COUNT(cg).
*/
index = AllocSrcNote(cx, cg);
if (index < 0)
return -1;
sn = &CG_NOTES(cg)[index];
/*
* Compute delta from the last annotated bytecode's offset. If it's too
* big to fit in sn, allocate one or more xdelta notes and reset sn.
*/
offset = CG_OFFSET(cg);
delta = offset - CG_LAST_NOTE_OFFSET(cg);
CG_LAST_NOTE_OFFSET(cg) = offset;
if (delta >= SN_DELTA_LIMIT) {
do {
xdelta = JS_MIN(delta, SN_XDELTA_MASK);
SN_MAKE_XDELTA(sn, xdelta);
delta -= xdelta;
index = AllocSrcNote(cx, cg);
if (index < 0)
return -1;
sn = &CG_NOTES(cg)[index];
} while (delta >= SN_DELTA_LIMIT);
}
/*
* Initialize type and delta, then allocate the minimum number of notes
* needed for type's arity. Usually, we won't need more, but if an offset
* does take two bytes, js_SetSrcNoteOffset will grow CG_NOTES(cg).
*/
SN_MAKE_NOTE(sn, type, delta);
for (n = (intN)js_SrcNoteSpec[type].arity; n > 0; n--) {
if (js_NewSrcNote(cx, cg, SRC_NULL) < 0)
return -1;
}
return index;
}
intN
js_NewSrcNote2(JSContext *cx, JSCodeGenerator *cg, JSSrcNoteType type,
ptrdiff_t offset)
{
intN index;
index = js_NewSrcNote(cx, cg, type);
if (index >= 0) {
if (!js_SetSrcNoteOffset(cx, cg, index, 0, offset))
return -1;
}
return index;
}
intN
js_NewSrcNote3(JSContext *cx, JSCodeGenerator *cg, JSSrcNoteType type,
ptrdiff_t offset1, ptrdiff_t offset2)
{
intN index;
index = js_NewSrcNote(cx, cg, type);
if (index >= 0) {
if (!js_SetSrcNoteOffset(cx, cg, index, 0, offset1))
return -1;
if (!js_SetSrcNoteOffset(cx, cg, index, 1, offset2))
return -1;
}
return index;
}
static JSBool
GrowSrcNotes(JSContext *cx, JSCodeGenerator *cg)
{
JSArenaPool *pool;
size_t size;
/* Grow by doubling note array size; update noteMask on success. */
pool = cg->notePool;
size = SRCNOTE_SIZE(CG_NOTE_MASK(cg) + 1);
JS_ARENA_GROW_CAST(CG_NOTES(cg), jssrcnote *, pool, size, size);
if (!CG_NOTES(cg)) {
JS_ReportOutOfMemory(cx);
return JS_FALSE;
}
CG_NOTE_MASK(cg) = (CG_NOTE_MASK(cg) << 1) | 1;
return JS_TRUE;
}
jssrcnote *
js_AddToSrcNoteDelta(JSContext *cx, JSCodeGenerator *cg, jssrcnote *sn,
ptrdiff_t delta)
{
ptrdiff_t base, limit, newdelta, diff;
intN index;
/*
* Called only from OptimizeSpanDeps and js_FinishTakingSrcNotes to add to
* main script note deltas, and only by a small positive amount.
*/
JS_ASSERT(cg->current == &cg->main);
JS_ASSERT((unsigned) delta < (unsigned) SN_XDELTA_LIMIT);
base = SN_DELTA(sn);
limit = SN_IS_XDELTA(sn) ? SN_XDELTA_LIMIT : SN_DELTA_LIMIT;
newdelta = base + delta;
if (newdelta < limit) {
SN_SET_DELTA(sn, newdelta);
} else {
index = sn - cg->main.notes;
if ((cg->main.noteCount & cg->main.noteMask) == 0) {
if (!GrowSrcNotes(cx, cg))
return NULL;
sn = cg->main.notes + index;
}
diff = cg->main.noteCount - index;
cg->main.noteCount++;
memmove(sn + 1, sn, SRCNOTE_SIZE(diff));
SN_MAKE_XDELTA(sn, delta);
sn++;
}
return sn;
}
JS_FRIEND_API(uintN)
js_SrcNoteLength(jssrcnote *sn)
{
uintN arity;
jssrcnote *base;
arity = (intN)js_SrcNoteSpec[SN_TYPE(sn)].arity;
for (base = sn++; arity; sn++, arity--) {
if (*sn & SN_3BYTE_OFFSET_FLAG)
sn += 2;
}
return sn - base;
}
JS_FRIEND_API(ptrdiff_t)
js_GetSrcNoteOffset(jssrcnote *sn, uintN which)
{
/* Find the offset numbered which (i.e., skip exactly which offsets). */
JS_ASSERT(SN_TYPE(sn) != SRC_XDELTA);
JS_ASSERT(which < js_SrcNoteSpec[SN_TYPE(sn)].arity);
for (sn++; which; sn++, which--) {
if (*sn & SN_3BYTE_OFFSET_FLAG)
sn += 2;
}
if (*sn & SN_3BYTE_OFFSET_FLAG) {
return (ptrdiff_t)(((uint32)(sn[0] & SN_3BYTE_OFFSET_MASK) << 16)
| (sn[1] << 8)
| sn[2]);
}
return (ptrdiff_t)*sn;
}
JSBool
js_SetSrcNoteOffset(JSContext *cx, JSCodeGenerator *cg, uintN index,
uintN which, ptrdiff_t offset)
{
jssrcnote *sn;
ptrdiff_t diff;
if ((jsuword)offset >= (jsuword)((ptrdiff_t)SN_3BYTE_OFFSET_FLAG << 16)) {
ReportStatementTooLarge(cx, cg);
return JS_FALSE;
}
/* Find the offset numbered which (i.e., skip exactly which offsets). */
sn = &CG_NOTES(cg)[index];
JS_ASSERT(SN_TYPE(sn) != SRC_XDELTA);
JS_ASSERT(which < js_SrcNoteSpec[SN_TYPE(sn)].arity);
for (sn++; which; sn++, which--) {
if (*sn & SN_3BYTE_OFFSET_FLAG)
sn += 2;
}
/* See if the new offset requires three bytes. */
if (offset > (ptrdiff_t)SN_3BYTE_OFFSET_MASK) {
/* Maybe this offset was already set to a three-byte value. */
if (!(*sn & SN_3BYTE_OFFSET_FLAG)) {
/* Losing, need to insert another two bytes for this offset. */
index = PTRDIFF(sn, CG_NOTES(cg), jssrcnote);
/*
* Simultaneously test to see if the source note array must grow to
* accomodate either the first or second byte of additional storage
* required by this 3-byte offset.
*/
if (((CG_NOTE_COUNT(cg) + 1) & CG_NOTE_MASK(cg)) <= 1) {
if (!GrowSrcNotes(cx, cg))
return JS_FALSE;
sn = CG_NOTES(cg) + index;
}
CG_NOTE_COUNT(cg) += 2;
diff = CG_NOTE_COUNT(cg) - (index + 3);
JS_ASSERT(diff >= 0);
if (diff > 0)
memmove(sn + 3, sn + 1, SRCNOTE_SIZE(diff));
}
*sn++ = (jssrcnote)(SN_3BYTE_OFFSET_FLAG | (offset >> 16));
*sn++ = (jssrcnote)(offset >> 8);
}
*sn = (jssrcnote)offset;
return JS_TRUE;
}
#ifdef DEBUG_notme
#define DEBUG_srcnotesize
#endif
#ifdef DEBUG_srcnotesize
#define NBINS 10
static uint32 hist[NBINS];
void DumpSrcNoteSizeHist()
{
static FILE *fp;
int i, n;
if (!fp) {
fp = fopen("/tmp/srcnotes.hist", "w");
if (!fp)
return;
setvbuf(fp, NULL, _IONBF, 0);
}
fprintf(fp, "SrcNote size histogram:\n");
for (i = 0; i < NBINS; i++) {
fprintf(fp, "%4u %4u ", JS_BIT(i), hist[i]);
for (n = (int) JS_HOWMANY(hist[i], 10); n > 0; --n)
fputc('*', fp);
fputc('\n', fp);
}
fputc('\n', fp);
}
#endif
/*
* Fill in the storage at notes with prolog and main srcnotes; the space at
* notes was allocated using the CG_COUNT_FINAL_SRCNOTES macro from jsemit.h.
* SO DON'T CHANGE THIS FUNCTION WITHOUT AT LEAST CHECKING WHETHER jsemit.h's
* CG_COUNT_FINAL_SRCNOTES MACRO NEEDS CORRESPONDING CHANGES!
*/
JSBool
js_FinishTakingSrcNotes(JSContext *cx, JSCodeGenerator *cg, jssrcnote *notes)
{
uintN prologCount, mainCount, totalCount;
ptrdiff_t offset, delta;
jssrcnote *sn;
JS_ASSERT(cg->current == &cg->main);
prologCount = cg->prolog.noteCount;
if (prologCount && cg->prolog.currentLine != cg->firstLine) {
CG_SWITCH_TO_PROLOG(cg);
if (js_NewSrcNote2(cx, cg, SRC_SETLINE, (ptrdiff_t)cg->firstLine) < 0)
return JS_FALSE;
prologCount = cg->prolog.noteCount;
CG_SWITCH_TO_MAIN(cg);
} else {
/*
* Either no prolog srcnotes, or no line number change over prolog.
* We don't need a SRC_SETLINE, but we may need to adjust the offset
* of the first main note, by adding to its delta and possibly even
* prepending SRC_XDELTA notes to it to account for prolog bytecodes
* that came at and after the last annotated bytecode.
*/
offset = CG_PROLOG_OFFSET(cg) - cg->prolog.lastNoteOffset;
JS_ASSERT(offset >= 0);
if (offset > 0 && cg->main.noteCount != 0) {
/* NB: Use as much of the first main note's delta as we can. */
sn = cg->main.notes;
delta = SN_IS_XDELTA(sn)
? SN_XDELTA_MASK - (*sn & SN_XDELTA_MASK)
: SN_DELTA_MASK - (*sn & SN_DELTA_MASK);
if (offset < delta)
delta = offset;
for (;;) {
if (!js_AddToSrcNoteDelta(cx, cg, sn, delta))
return JS_FALSE;
offset -= delta;
if (offset == 0)
break;
delta = JS_MIN(offset, SN_XDELTA_MASK);
sn = cg->main.notes;
}
}
}
mainCount = cg->main.noteCount;
totalCount = prologCount + mainCount;
if (prologCount)
memcpy(notes, cg->prolog.notes, SRCNOTE_SIZE(prologCount));
memcpy(notes + prologCount, cg->main.notes, SRCNOTE_SIZE(mainCount));
SN_MAKE_TERMINATOR(&notes[totalCount]);
#ifdef DEBUG_notme
{ int bin = JS_CeilingLog2(totalCount);
if (bin >= NBINS)
bin = NBINS - 1;
++hist[bin];
}
#endif
return JS_TRUE;
}
JSBool
js_AllocTryNotes(JSContext *cx, JSCodeGenerator *cg)
{
size_t size, incr;
ptrdiff_t delta;
size = TRYNOTE_SIZE(cg->treeContext.tryCount);
if (size <= cg->tryNoteSpace)
return JS_TRUE;
/*
* Allocate trynotes from cx->tempPool.
* XXX Too much growing and we bloat, as other tempPool allocators block
* in-place growth, and we never recycle old free space in an arena.
* YYY But once we consume an entire arena, we'll realloc it, letting the
* malloc heap recycle old space, while still freeing _en masse_ via the
* arena pool.
*/
if (!cg->tryBase) {
size = JS_ROUNDUP(size, TRYNOTE_SIZE(TRYNOTE_CHUNK));
JS_ARENA_ALLOCATE_CAST(cg->tryBase, JSTryNote *, &cx->tempPool, size);
if (!cg->tryBase)
return JS_FALSE;
cg->tryNoteSpace = size;
cg->tryNext = cg->tryBase;
} else {
delta = PTRDIFF((char *)cg->tryNext, (char *)cg->tryBase, char);
incr = size - cg->tryNoteSpace;
incr = JS_ROUNDUP(incr, TRYNOTE_SIZE(TRYNOTE_CHUNK));
size = cg->tryNoteSpace;
JS_ARENA_GROW_CAST(cg->tryBase, JSTryNote *, &cx->tempPool, size, incr);
if (!cg->tryBase)
return JS_FALSE;
cg->tryNoteSpace = size + incr;
cg->tryNext = (JSTryNote *)((char *)cg->tryBase + delta);
}
return JS_TRUE;
}
JSTryNote *
js_NewTryNote(JSContext *cx, JSCodeGenerator *cg, ptrdiff_t start,
ptrdiff_t end, ptrdiff_t catchStart)
{
JSTryNote *tn;
JS_ASSERT(cg->tryBase <= cg->tryNext);
JS_ASSERT(catchStart >= 0);
tn = cg->tryNext++;
tn->start = start;
tn->length = end - start;
tn->catchStart = catchStart;
return tn;
}
void
js_FinishTakingTryNotes(JSContext *cx, JSCodeGenerator *cg, JSTryNote *notes)
{
uintN count;
count = PTRDIFF(cg->tryNext, cg->tryBase, JSTryNote);
if (!count)
return;
memcpy(notes, cg->tryBase, TRYNOTE_SIZE(count));
notes[count].start = 0;
notes[count].length = CG_OFFSET(cg);
notes[count].catchStart = 0;
}
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