gecko-dev/ef/Compiler/FrontEnd/VerificationEnv.cpp

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/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*-
*
* The contents of this file are subject to the Netscape 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/NPL/
*
* 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.org code.
*
* The Initial Developer of the Original Code is Netscape
* Communications Corporation. Portions created by Netscape are
* Copyright (C) 1998 Netscape Communications Corporation. All
* Rights Reserved.
*
* Contributor(s):
*/
#include "VerificationEnv.h"
const VerificationEnv::BindingKind VerificationEnv::valueKindBindingKinds[nValueKinds] =
{
bkVoid, // vkVoid
bkInt, // vkInt
bkLong, // vkLong
bkFloat, // vkFloat
bkDouble, // vkDouble
bkAddr, // vkAddr
bkVoid, // vkCond
bkVoid, // vkMemory
bkVoid // vkTuple
};
const VerificationEnv::BindingKind VerificationEnv::typeKindBindingKinds[nTypeKinds] =
{
bkVoid, // tkVoid
bkInt, // tkBoolean
bkInt, // tkUByte
bkInt, // tkByte
bkInt, // tkChar
bkInt, // tkShort
bkInt, // tkInt
bkLong, // tkLong
bkFloat, // tkFloat
bkDouble, // tkDouble
bkAddr, // tkObject
bkAddr, // tkSpecial
bkAddr, // tkArray
bkAddr // tkInterface
};
// ----------------------------------------------------------------------------
// VerificationEnv::Context
//
// Create a new, empty Context that holds information about which variables a subroutine
// has modified. Clear the modified array (indicating that no variables have been accessed
// yet) and the link to the next context.
//
VerificationEnv::Context::Context(Subroutine subroutine, const Common &common):
next(0),
subroutine(subroutine),
retReachable(false)
#ifdef DEBUG
, common(common)
#endif
{
assert(common.bindingPool);
modified = new(*common.bindingPool) char[common.nEnvSlots];
fill(modified, modified + common.nEnvSlots, 0);
}
//
// Create a copy of the given context. Clear the link to the next context.
//
VerificationEnv::Context::Context(const Context &src, const Common &common):
next(0),
subroutine(src.subroutine),
retReachable(src.retReachable)
#ifdef DEBUG
, common(common)
#endif
{
assert(common.bindingPool);
modified = new(*common.bindingPool) char[common.nEnvSlots];
copy(src.modified, src.modified + common.nEnvSlots, modified);
}
//
// Create a partial copy of the given context. Do not copy the contents of the
// modified array. Translate the Subroutine value using the given translator.
// Clear the link to the next context.
//
inline VerificationEnv::Context::Context(const Context &src, const Common &common, Function1<Subroutine, Subroutine> &translator):
next(0),
subroutine(translator(src.subroutine)),
retReachable(src.retReachable)
#ifdef DEBUG
, common(common)
#endif
{}
//
// Merge this context with the src context. A slot in the merged context is
// set to the modified state if it was modified in either this or the src context.
// Return true if the resulting context differs from the original contents of this
// context.
//
bool VerificationEnv::Context::meet(const Context &src, Uint32 nSlots)
{
assert(subroutine == src.subroutine && common.bindingPool);
bool changed = false;
char *dstModified = modified;
const char *srcModified = src.modified;
for (Uint32 slot = 0; slot != nSlots; slot++)
if (srcModified[slot] && !dstModified[slot]) {
dstModified[slot] = true;
changed = true;
}
return changed;
}
//
// If a context corresponding to the given subroutine is in the linked list of
// contexts, return that context. If not, return nil. list can be nil.
//
VerificationEnv::Context *VerificationEnv::Context::find(Context *list, const Subroutine subroutine)
{
while (list && list->subroutine != subroutine)
list = list->next;
return list;
}
// ----------------------------------------------------------------------------
// VerificationEnv
const VerificationEnv::InitBinding VerificationEnv::secondWordBinding(bkSecondWord);
//
// Assign a partial copy of the given VerificationEnv (which must have been initialized)
// to this VerificationEnv, which is known to be uninitialized. Do not copy the
// bindings nor the modified arrays inside Contexts. Translate all Subroutine values
// using the given translator.
//
VerificationEnv::VerificationEnv(const VerificationEnv &env, Function1<Subroutine, Subroutine> &translator):
common(env.common)
{
assert(env.live());
// Copy the bindings pointer (which is now only relevant to indicate whether this
// environment is live or not).
bindings = env.bindings;
sp = env.sp;
// Copy the context hierarchy.
activeContexts = 0;
Context *srcContext = env.activeContexts;
Context **dstContext = &activeContexts;
while (srcContext) {
*dstContext = new(common.envPool) Context(*srcContext, common, translator);
dstContext = &(*dstContext)->next;
srcContext = srcContext->next;
}
}
//
// Make this VerificationEnv (which must not have been initialized) live,
// assigning bkVoid to every slot.
//
void VerificationEnv::initLive()
{
assert(!live() && common.bindingPool);
// Create and initialize the bindings.
Binding *bdgs = new(*common.bindingPool) Binding[common.nEnvSlots];
bindings = bdgs;
Binding *bdgsEnd = bdgs + common.nEnvSlots;
while (bdgs != bdgsEnd)
bdgs++->setVoid();
sp = common.stackBase;
activeContexts = 0;
}
//
// Assign a copy of the given VerificationEnv (which must have been initialized)
// to this VerificationEnv, which is known to be uninitialized.
//
void VerificationEnv::copyEnv(const VerificationEnv &env)
{
assert(env.live() && common.bindingPool);
// Copy the bindings.
bindings = new(*common.bindingPool) Binding[common.nEnvSlots];
copy(env.bindings, env.bindings + common.nEnvSlots, bindings);
sp = env.sp;
// Copy the context hierarchy.
activeContexts = 0;
Context *srcContext = env.activeContexts;
Context **dstContext = &activeContexts;
while (srcContext) {
*dstContext = new(common.envPool) Context(*srcContext, common);
dstContext = &(*dstContext)->next;
srcContext = srcContext->next;
}
}
//
// Set the value of the given environment slot, adding that slot to
// the list of slots modified by all currently active subroutines.
//
void VerificationEnv::setSlot(Uint32 slot, const Binding &binding)
{
assert(slot < common.nEnvSlots);
bindings[slot] = binding;
for (Context *c = activeContexts; c; c = c->next)
c->modify(slot);
}
//
// Return the value of the one-word local variable in the given slot.
// Throw a verification error if the slot number is out of bounds or the value
// is undefined or a part of a two-word value.
//
const VerificationEnv::Binding &VerificationEnv::getLocal1(Uint32 n) const
{
assert(live() && common.bindingPool);
if (n >= common.nLocals)
verifyError(VerifyError::noSuchLocal);
Binding &b = bindings[n];
if (!b.isOneWord())
verifyError(VerifyError::badType);
return b;
}
//
// Return the value of the two-word local variable in the given slot.
// Throw a verification error if the slot number is out of bounds or the value
// is undefined or not a two-word value.
//
const VerificationEnv::Binding &VerificationEnv::getLocal2(Uint32 n) const
{
assert(live() && common.bindingPool);
if (n+1 >= common.nLocals)
verifyError(VerifyError::noSuchLocal);
Binding &b = bindings[n];
if (!b.isTwoWord())
verifyError(VerifyError::badType);
assert(bindings[n+1].hasKind(bkSecondWord));
return b;
}
//
// Set the value of the one-word local variable in the given slot.
// Throw a verification error if the slot number is out of bounds.
// The given binding must have a one-word kind.
//
void VerificationEnv::setLocal1(Uint32 n, const Binding &binding)
{
assert(live() && binding.isOneWord() && common.bindingPool);
if (n >= common.nLocals)
verifyError(VerifyError::noSuchLocal);
Binding *b = &bindings[n];
// If we're writing into an existing half of a doubleword,
// invalidate the other half of that doubleword.
BindingKind bk = b->getKind();
if (isTwoOrSecondWordKind(bk))
b[bk == bkSecondWord ? -1 : 1].setVoid();
setSlot(n, binding);
}
//
// Set the value of the two-word local variable in the given slot.
// Throw a verification error if the slot number is out of bounds.
// The given binding must have a two-word kind.
//
void VerificationEnv::setLocal2(Uint32 n, const Binding &binding)
{
assert(live() && binding.isTwoWord() && common.bindingPool);
if (n+1 >= common.nLocals)
verifyError(VerifyError::noSuchLocal);
Binding *b = &bindings[n];
// If we're writing into an existing half of a doubleword,
// invalidate the other half of that doubleword.
if (b[0].hasKind(bkSecondWord))
b[-1].setVoid();
if (b[1].isTwoWord())
b[2].setVoid();
setSlot(n, binding);
setSlot(n+1, secondWordBinding);
}
//
// Pop and return a one-word value from the stack.
// Throw a verification error if the stack underflows or the value
// is undefined or a part of a two-word value.
// Note that the returned reference will be invalidated by the next push.
//
const VerificationEnv::Binding &VerificationEnv::pop1()
{
assert(live() && common.bindingPool);
if (sp == common.stackBase)
verifyError(VerifyError::bytecodeStackUnderflow);
Binding &b = bindings[--sp];
if (!b.isOneWord())
verifyError(VerifyError::badType);
return b;
}
//
// Pop and return a one-word value from the stack.
// Throw a verification error if the stack underflows or the value
// is undefined or has a kind other than the given kind.
// Note that the returned reference will be invalidated by the next push.
//
const VerificationEnv::Binding &VerificationEnv::pop1(BindingKind bk)
{
assert(live() && isOneWordKind(bk) && common.bindingPool);
if (sp == common.stackBase)
verifyError(VerifyError::bytecodeStackUnderflow);
Binding &b = bindings[--sp];
if (!b.hasKind(bk))
verifyError(VerifyError::badType);
return b;
}
//
// Pop and return a two-word value or two one-word values from the stack.
// Throw a verification error if the stack underflows or the value
// is undefined or a part of a two-word value that includes one of the two
// stack slots but not the other.
//
void VerificationEnv::pop2(Binding &binding1, Binding &binding2)
{
assert(live() && common.bindingPool);
if (sp <= common.stackBase+1)
verifyError(VerifyError::bytecodeStackUnderflow);
sp -= 2;
Binding *b = &bindings[sp];
BindingKind bk1 = b[0].getKind();
BindingKind bk2 = b[1].getKind();
if (!(isOneWordKind(bk1) && isOneWordKind(bk2) || isTwoWordKind(bk1)))
verifyError(VerifyError::badType);
assert(!isTwoWordKind(bk1) || bk2 == bkSecondWord);
binding1 = b[0];
binding2 = b[1];
}
//
// Pop and return a two-word value from the stack.
// Throw a verification error if the stack underflows or the value
// is undefined or has a kind other than the given kind.
// Note that the returned reference will be invalidated by the next push.
//
const VerificationEnv::Binding &VerificationEnv::pop2(BindingKind bk)
{
assert(live() && isTwoWordKind(bk) && common.bindingPool);
if (sp <= common.stackBase+1)
verifyError(VerifyError::bytecodeStackUnderflow);
sp -= 2;
Binding *b = &bindings[sp];
if (!b[0].hasKind(bk))
verifyError(VerifyError::badType);
assert(b[1].hasKind(bkSecondWord));
return *b;
}
//
// Pop and return a one or two-word value from the stack, depending on bk.
// Throw a verification error if the stack underflows or the value
// is undefined or has a kind other than the given kind.
// Note that the returned reference will be invalidated by the next push.
//
const VerificationEnv::Binding &VerificationEnv::pop1or2(BindingKind bk)
{
return isTwoWordKind(bk) ? pop2(bk) : pop1(bk);
}
//
// Push a one-word value onto the stack.
// Throw a verification error if the stack overflows.
// The given binding must have a one-word kind.
//
void VerificationEnv::push1(const Binding &binding)
{
assert(live() && binding.isOneWord() && common.bindingPool);
if (sp == common.nEnvSlots)
verifyError(VerifyError::bytecodeStackOverflow);
setSlot(sp++, binding);
}
//
// Push a one-word value that contains a new binding of the given kind onto the stack.
// Throw a verification error if the stack overflows.
//
void VerificationEnv::push1(BindingKind bk)
{
// Note: bkAddr will be outlawed here once we start to distinguish among types of
// pointers.
assert(bk == bkVoid || bk == bkInt || bk == bkFloat || bk == bkAddr);
InitBinding b(bk);
push1(b);
}
//
// Push a two-word value onto the stack.
// Throw a verification error if the stack overflows.
// The given binding must have a two-word kind.
//
void VerificationEnv::push2(const Binding &binding)
{
assert(live() && binding.isTwoWord() && common.bindingPool);
if (sp+1 >= common.nEnvSlots)
verifyError(VerifyError::bytecodeStackOverflow);
setSlot(sp++, binding);
setSlot(sp++, secondWordBinding);
}
//
// Push a two-word value that contains a new binding of the given kind onto the stack.
// Throw a verification error if the stack overflows.
//
void VerificationEnv::push2(BindingKind bk)
{
assert(bk == bkLong || bk == bkDouble);
InitBinding b(bk);
push2(b);
}
//
// Push a two-word value or two one-word values onto the stack.
// Throw a verification error if the stack overflows.
// The given bindings must be the two words of a two-word value
// or both be one-word values.
//
void VerificationEnv::push2(const Binding &binding1, const Binding &binding2)
{
assert(live() && (binding1.isTwoWord() && binding2.hasKind(bkSecondWord) ||
binding1.isOneWord() && binding2.isOneWord())
&& common.bindingPool);
if (sp+1 >= common.nEnvSlots)
verifyError(VerifyError::bytecodeStackOverflow);
setSlot(sp++, binding1);
setSlot(sp++, binding2);
}
//
// Push a one or two-word value that contains a new binding of the
// given kind onto the stack.
// Throw a verification error if the stack overflows.
//
void VerificationEnv::push1or2(BindingKind bk)
{
// Note: bkAddr will be outlawed here once we start to distinguish among types of
// pointers.
assert(bk == bkVoid || bk == bkInt || bk == bkFloat || bk == bkAddr || bk == bkLong || bk == bkDouble);
InitBinding b(bk);
if (isTwoWordKind(bk))
push2(b);
else
push1(b);
}
//
// Push the context of the given subroutine onto the list of currently active
// contexts. Initialize that context to record all bindings written to this
// environment after this enterSubroutine call.
//
// Throw a verification error if the given subroutine already is on the list
// of active contexts. This rejects bytecode programs that call subroutines
// recursively. It also rejects some "valid" bytecode programs that do not call
// subroutines recursively (for instance, if subroutine A exits via a jump
// instead of a ret and then calls subroutine A again), but, fortunately, the
// current definition of the Java language does not generate such programs.
// (Specifically, each Java try block has a single entry point and the finally
// handler -- say, subroutine A -- for that try block is outside that block. In
// order for subroutine A to be called again, execution must proceed again
// through the entry point of the try block, and we know that at that point
// subroutine A is not one of the active contexts.)
//
void VerificationEnv::enterSubroutine(Subroutine s)
{
assert(live() && s && common.bindingPool);
if (Context::find(activeContexts, s))
verifyError(VerifyError::jsrNestingError);
Context *c = new(common.envPool) Context(s, common);
c->next = activeContexts;
activeContexts = c;
}
//
// Pop the context of the given subroutine from the list of currently active
// contexts, and replace environment bindings that were not modified by the
// subroutine by their contenst from entryEnv, which represents the environment
// as it was just before entry to the subroutine. Also pop any contexts more
// recent than that of the given subroutine -- these subroutines apparently
// exited using a jump instead of a ret.
//
// Throw a verification error if the subroutine is not on the list of active
// contexts, which indicates that there is some program path along which this
// ret could be reached without this subroutine having been called first.
//
void VerificationEnv::exitSubroutine(Subroutine s, const VerificationEnv &entryEnv)
{
assert(live() && s && entryEnv.live() && common.bindingPool);
Context *c = Context::find(activeContexts, s);
if (!c)
verifyError(VerifyError::jsrNestingError);
activeContexts = c->next;
// Replace unmodified environment bindings.
Uint32 nSlots = sp;
const Binding *srcBindings = entryEnv.bindings;
Binding *dstBindings = bindings;
for (Uint32 slot = 0; slot != nSlots; slot++)
if (!c->isModified(slot))
dstBindings[slot] = srcBindings[slot];
}
//
// Intersect the given VerificationEnv (which must be live) into this
// VerificationEnv, which must also be live. The two environments may have
// different sets of active subroutine contexts, in which case leave the maximal
// common set (for instance, intersecting a->b with b yields b, while
// intersecting a->b->d->e with a->c->d yields a->d). Because each subroutine has
// only one entry point and cannot be recursive, we don't have to worry about
// cases such as intersecting a->b with b->a -- nesting of subroutines follows a
// partial order.
//
// Return true if this VerificationEnv changed.
//
// Throw a verification error if the environments have different stack depths.
//
bool VerificationEnv::meet(const VerificationEnv &env)
{
assert(live() && env.live() && common.bindingPool);
Uint32 nSlots = sp;
if (nSlots != env.sp)
verifyError(VerifyError::bytecodeStackDynamic);
bool changed = false;
// Merge context lists
Context **dstContextPtr = &activeContexts;
Context *srcContext = env.activeContexts;
Context *dstContext;
while ((dstContext = *dstContextPtr) != 0) {
Context *c = Context::find(srcContext, dstContext->subroutine);
if (c) {
srcContext = c;
changed |= dstContext->meet(*c, nSlots);
dstContextPtr = &dstContext->next;
} else {
// Remove this destination context.
*dstContextPtr = dstContext->next;
changed = true;
}
}
// Merge bindings
const Binding *srcBinding = env.bindings;
Binding *dstBinding = bindings;
Binding *dstBindingsEnd = dstBinding + nSlots;
while (dstBinding != dstBindingsEnd) {
if (*dstBinding != *srcBinding && !dstBinding->hasKind(bkVoid)) {
dstBinding->setVoid();
changed = true;
}
srcBinding++;
dstBinding++;
}
return changed;
}
//
// This VerificationEnv (which must be live) is the entry environment to a ret
// bytecode that returns from subroutine s. That subroutine's context is one
// of the active contexts in this VerificationEnv. Set that context's retReachable
// flag because clearly subroutine s's ret is reachable from here.
//
void VerificationEnv::setRetReachable(Subroutine s)
{
assert(live());
Context *c = Context::find(activeContexts, s);
assert(c);
c->retReachable = true;
}
//
// Merge the retReachable flags of env into this VerificationEnv. env is the
// environment of a successor of this VerificationEnv's block. If s is non-nil,
// this VerificationEnv's block is a jsr instruction that calls subroutine s,
// and env belongs to s's first block; in this case don't set this environment's
// retReachable flag for s's context because this environment is outside s.
//
// Return true if this VerificationEnv changed.
//
bool VerificationEnv::mergeRetReachables(const VerificationEnv &env, Subroutine s)
{
assert(live() && env.live());
bool changed = false;
Context *srcContext = env.activeContexts;
Context *dstContext = activeContexts;
while (srcContext) {
if (srcContext->retReachable) {
Subroutine srcSubroutine = srcContext->subroutine;
if (srcSubroutine != s) {
dstContext = Context::find(dstContext, srcSubroutine);
assert(dstContext);
if (!dstContext->retReachable) {
dstContext->retReachable = true;
changed = true;
}
}
}
srcContext = srcContext->next;
}
return changed;
}