It turns out we can reach the `Init.castAs<nonlock::CompoundVal>()`
expression with other kinds of SVals. Such as by `nonloc::ConcreteInt`
in this example: https://godbolt.org/z/s4fdxrcs9
```lang=C++
int buffer[10];
void b();
void top() {
b(&buffer);
}
void b(int *c) {
*c = 42; // would crash
}
```
In this example, we try to store `42` to the `Elem{buffer, 0}`.
This situation can appear if the CallExpr refers to a function
declaration without prototype. In such cases, the engine will pick the
redecl of the referred function decl which has function body, hence has
a function prototype.
This weird situation will have an interesting effect to the AST, such as
the argument at the callsite will miss a cast, which would cast the
`int (*)[10]` expression into `int *`, which means that when we evaluate
the `*c = 42` expression, we want to bind `42` to an array, causing the
crash.
Look at the AST of the callsite with and without the function prototype:
https://godbolt.org/z/Gncebcbdb
The only difference is that without the proper function prototype, we
will not have the `ImplicitCastExpr` `BitCasting` from `int (*)[10]`
to `int *` to match the expected type of the parameter declaration.
In this patch, I'm proposing to emit a cast in the mentioned edge-case,
to bind the argument value of the expected type to the parameter.
I'm only proposing this if the runtime definition has exactly the same
number of parameters as the callsite feeds it by arguments.
If that's not the case, I believe, we are better off by binding `Unknown`
to those parameters.
Reviewed By: martong
Differential Revision: https://reviews.llvm.org/D136162
In case when the prvalue is returned from the function (kind is one
of `SimpleReturnedValueKind`, `CXX17ElidedCopyReturnedValueKind`),
then it construction happens in context of the caller.
We pass `BldrCtx` explicitly, as `currBldrCtx` will always refer to callee
context.
In the following example:
```
struct Result {int value; };
Result create() { return Result{10}; }
int accessValue(Result r) { return r.value; }
void test() {
for (int i = 0; i < 2; ++i)
accessValue(create());
}
```
In case when the returned object was constructed directly into the
argument to a function call `accessValue(create())`, this led to
inappropriate value of `blockCount` being used to locate parameter region,
and as a consequence resulting object (from `create()`) was constructed
into a different region, that was later read by inlined invocation of
outer function (`accessValue`).
This manifests itself only in case when calling block is visited more
than once (loop in above example), as otherwise there is no difference
in `blockCount` value between callee and caller context.
This happens only in case when copy elision is disabled (before C++17).
Reviewed By: NoQ
Differential Revision: https://reviews.llvm.org/D132030
This new CTU implementation is the natural extension of the normal single TU
analysis. The approach consists of two analysis phases. During the first phase,
we do a normal single TU analysis. During this phase, if we find a foreign
function (that could be inlined from another TU) then we don’t inline that
immediately, we rather mark that to be analysed later.
When the first phase is finished then we start the second phase, the CTU phase.
In this phase, we continue the analysis from that point (exploded node)
which had been enqueued during the first phase. We gradually extend the
exploded graph of the single TU analysis with the new node that was
created by the inlining of the foreign function.
We count the number of analysis steps of the first phase and we limit the
second (ctu) phase with this number.
This new implementation makes it convenient for the users to run the
single-TU and the CTU analysis in one go, they don't need to run the two
analysis separately. Thus, we name this new implementation as "onego" CTU.
Discussion:
https://discourse.llvm.org/t/rfc-much-faster-cross-translation-unit-ctu-analysis-implementation/61728
Differential Revision: https://reviews.llvm.org/D123773
This patch restores the symmetry between how operator new and operator delete
are handled by also inlining the content of operator delete when possible.
Patch by Fred Tingaud.
Reviewed By: martong
Differential Revision: https://reviews.llvm.org/D124845
Summary: Refactor return value of `StoreManager::attemptDownCast` function by removing the last parameter `bool &Failed` and replace the return value `SVal` with `Optional<SVal>`. Make the function consistent with the family of `evalDerivedToBase` by renaming it to `evalBaseToDerived`. Aligned the code on the call side with these changes.
Differential Revision: https://reviews.llvm.org/
This patch replaces each use of the previous API with the new one.
In variadic cases, it will use the ADL `matchesAny(Call, CDs...)`
variadic function.
Also simplifies some code involving such operations.
Reviewed By: martong, xazax.hun
Differential Revision: https://reviews.llvm.org/D113591
This patch introduces `CallDescription::matches()` member function,
accepting a `CallEvent`.
Semantically, `Call.isCalled(CD)` is the same as `CD.matches(Call)`.
The patch also introduces the `matchesAny()` variadic free function template.
It accepts a `CallEvent` and at least one `CallDescription` to match
against.
Reviewed By: martong
Differential Revision: https://reviews.llvm.org/D113590
`CallDescriptions` deserve its own translation unit.
This patch simply moves the corresponding parts.
Also includes the `CallDescription.h` where it's necessary.
Reviewed By: martong, xazax.hun, Szelethus
Differential Revision: https://reviews.llvm.org/D113587
Previously, if accidentally multiple checkers `eval::Call`-ed the same
`CallEvent`, in debug builds the analyzer detected this and crashed
with the message stating this. Unfortunately, the message did not state
the offending checkers violating this invariant.
This revision addresses this by printing a more descriptive message
before aborting.
Reviewed By: martong
Differential Revision: https://reviews.llvm.org/D112889
It turns out llvm::isa<> is variadic, and we could have used this at a
lot of places.
The following patterns:
x && isa<T1>(x) || isa<T2>(x) ...
Will be replaced by:
isa_and_non_null<T1, T2, ...>(x)
Sometimes it caused further simplifications, when it would cause even
more code smell.
Aside from this, keep in mind that within `assert()` or any macro
functions, we need to wrap the isa<> expression within a parenthesis,
due to the parsing of the comma.
Reviewed By: martong
Differential Revision: https://reviews.llvm.org/D111982
Fallback to stringification and string comparison if we cannot compare
the `IdentifierInfo`s, which is the case for C++ overloaded operators,
constructors, destructors, etc.
Examples:
{ "std", "basic_string", "basic_string", 2} // match the 2 param std::string constructor
{ "std", "basic_string", "~basic_string" } // match the std::string destructor
{ "aaa", "bbb", "operator int" } // matches the struct bbb conversion operator to int
Reviewed By: martong
Differential Revision: https://reviews.llvm.org/D111535
Refactor the code to make it more readable.
It will set up further changes, and improvements to this code in
subsequent patches.
This is a non-functional change.
Reviewed By: martong
Differential Revision: https://reviews.llvm.org/D111534
'(self.prop)' produces a surprising AST where ParenExpr
resides inside `PseudoObjectExpr.
This breaks ObjCMethodCall::getMessageKind() which in turn causes us
to perform unnecessary dynamic dispatch bifurcation when evaluating
body-farmed property accessors, which in turn causes us
to explore infeasible paths.
This cleanup patch refactors a bunch of functional duplicates of
getDecltypeForParenthesizedExpr into a common implementation.
Signed-off-by: Matheus Izvekov <mizvekov@gmail.com>
Reviewed By: aaronpuchert
Differential Revision: https://reviews.llvm.org/D100713
This renames the expression value categories from rvalue to prvalue,
keeping nomenclature consistent with C++11 onwards.
C++ has the most complicated taxonomy here, and every other language
only uses a subset of it, so it's less confusing to use the C++ names
consistently, and mentally remap to the C names when working on that
context (prvalue -> rvalue, no xvalues, etc).
Renames:
* VK_RValue -> VK_PRValue
* Expr::isRValue -> Expr::isPRValue
* SK_QualificationConversionRValue -> SK_QualificationConversionPRValue
* JSON AST Dumper Expression nodes value category: "rvalue" -> "prvalue"
Signed-off-by: Matheus Izvekov <mizvekov@gmail.com>
Reviewed By: rsmith
Differential Revision: https://reviews.llvm.org/D103720
This change groups
* Rename: `ignoreParenBaseCasts` -> `IgnoreParenBaseCasts` for uniformity
* Rename: `IgnoreConversionOperator` -> `IgnoreConversionOperatorSingleStep` for uniformity
* Inline `IgnoreNoopCastsSingleStep` into a lambda inside `IgnoreNoopCasts`
* Refactor `IgnoreUnlessSpelledInSource` to make adequate use of `IgnoreExprNodes`
Differential Revision: https://reviews.llvm.org/D86880
Pass EvalCallOptions via runCheckersForEvalCall into defaultEvalCall.
Update the AnalysisOrderChecker to support evalCall for testing.
Differential Revision: https://reviews.llvm.org/D82256
Retrieving the parameter location of functions was disabled because it
may causes crashes due to the fact that functions may have multiple
declarations and without definition it is difficult to ensure that
always the same declration is used. Now parameters are stored in
`ParamRegions` which are independent of the declaration of the function,
therefore the same parameters always have the same regions,
independently of the function declaration used actually. This allows us
to remove the limitation described above.
Differential Revision: https://reviews.llvm.org/D80286
Currently, parameters of functions without their definition present cannot
be represented as regions because it would be difficult to ensure that the
same declaration is used in every case. To overcome this, we split
`VarRegion` to two subclasses: `NonParamVarRegion` and `ParamVarRegion`.
The latter does not store the `Decl` of the parameter variable. Instead it
stores the index of the parameter which enables retrieving the actual
`Decl` every time using the function declaration of the stack frame. To
achieve this we also removed storing of `Decl` from `DeclRegion` and made
`getDecl()` pure virtual. The individual `Decl`s are stored in the
appropriate subclasses, such as `FieldRegion`, `ObjCIvarRegion` and the
newly introduced `NonParamVarRegion`.
Differential Revision: https://reviews.llvm.org/D80522
Checkers should be able to get the return value under construction for a
`CallEvenet`. This patch adds a function to achieve this which retrieves
the return value from the construction context of the call.
Differential Revision: https://reviews.llvm.org/D80366
The `SubEngine` interface is an interface with only one implementation
`EpxrEngine`. Adding other implementations are difficult and very
unlikely in the near future. Currently, if anything from `ExprEngine` is
to be exposed to other classes it is moved to `SubEngine` which
restricts the alternative implementations. The virtual methods are have
a slight perofrmance impact. Furthermore, instead of the `LLVM`-style
inheritance a native inheritance is used here, which renders `LLVM`
functions like e.g. `cast<T>()` unusable here. This patch removes this
interface and allows usage of `ExprEngine` directly.
Differential Revision: https://reviews.llvm.org/D80548
Summary:
Objective-C Class objects can be used to do a dynamic dispatch on
class methods. The analyzer had a few places where we tried to overcome
the dynamic nature of it and still guess the actual function that
is being called. That was done mostly using some simple heuristics
covering the most widespread cases (e.g. [[self class] classmethod]).
This solution introduces a way to track types represented by Class
objects and work with that instead of direct AST matching.
rdar://problem/50739539
Differential Revision: https://reviews.llvm.org/D78286
Exactly what it says on the tin! The included testfile demonstrates why this is
important -- for C++ dynamic memory operators, we don't always recognize custom,
or even standard-specified new/delete operators as CXXAllocatorCall or
CXXDeallocatorCall.
Differential Revision: https://reviews.llvm.org/D77391
So far we've been dropping coverage every time we've encountered
a CXXInheritedCtorInitExpr. This patch attempts to add some
initial support for it.
Constructors for arguments of a CXXInheritedCtorInitExpr are still
not fully supported.
Differential Revision: https://reviews.llvm.org/D74735
Fix a canonicalization problem for the newly added property accessor stubs that
was causing a wrong decl to be used for 'self' in the accessor's body farm.
Fix a crash when constructing a body farm for accessors of a property
that is declared and @synthesize'd in different (but related) interfaces.
Differential Revision: https://reviews.llvm.org/D70158
This patch is motivated by (and factored out from)
https://reviews.llvm.org/D66121 which is a debug info bugfix. Starting
with DWARF 5 all Objective-C methods are nested inside their
containing type, and that patch implements this for synthesized
Objective-C properties.
1. SemaObjCProperty populates a list of synthesized accessors that may
need to inserted into an ObjCImplDecl.
2. SemaDeclObjC::ActOnEnd inserts forward-declarations for all
accessors for which no override was provided into their
ObjCImplDecl. This patch does *not* synthesize AST function
*bodies*. Moving that code from the static analyzer into Sema may
be a good idea though.
3. Places that expect all methods to have bodies have been updated.
I did not update the static analyzer's inliner for synthesized
properties to point back to the property declaration (see
test/Analysis/Inputs/expected-plists/nullability-notes.m.plist), which
I believed to be more bug than a feature.
Differential Revision: https://reviews.llvm.org/D68108
rdar://problem/53782400
Member operator declarations and member operator expressions
have different numbering of parameters and arguments respectively:
one of them includes "this", the other does not.
Account for this inconsistency when figuring out whether
the parameter needs to be manually rebound from the Environment
to the Store when entering a stack frame of an operator call,
as opposed to being constructed with a constructor and as such
already having the necessary Store bindings.
Differential Revision: https://reviews.llvm.org/D69155
At this point the PathDiagnostic, PathDiagnosticLocation, PathDiagnosticPiece
structures no longer rely on anything specific to Static Analyzer, so we can
move them out of it for everybody to use.
PathDiagnosticConsumers are still to be handed off.
Differential Revision: https://reviews.llvm.org/D67419
llvm-svn: 371661
Most functions that our checkers react upon are not C-style variadic functions,
and therefore they have as many actual arguments as they have formal parameters.
However, it's not impossible to define a variadic function with the same name.
This will crash any checker that relies on CallDescription to check the number
of arguments but silently assumes that the number of parameters is the same.
Change CallDescription to check both the number of arguments and the number of
parameters by default.
If we're intentionally trying to match variadic functions, allow specifying
arguments and parameters separately (possibly omitting any of them).
For now we only have one CallDescription which would make use of those,
namely __builtin_va_start itself.
Differential Revision: https://reviews.llvm.org/D67019
llvm-svn: 371256
When I'm new to a file/codebase, I personally find C++'s strong static type
system to be a great aid. BugReporter.cpp is still painful to read however:
function calls are made with mile long parameter lists, seemingly all of them
taken with a non-const reference/pointer. This patch fixes nothing but this:
make a few things const, and hammer it until it compiles.
Differential Revision: https://reviews.llvm.org/D65382
llvm-svn: 368735
Summary:
It allows discriminating between stack frames of the same call that is
called multiple times in a loop.
Thanks to Artem Dergachev for the great idea!
Reviewed By: NoQ
Tags: #clang
Differential Revision: https://reviews.llvm.org/D65587
llvm-svn: 367608
When matching C standard library functions in the checker, it's easy to forget
that they are often implemented as macros that are expanded to builtins.
Such builtins would have a different name, so matching the callee identifier
would fail, or may sometimes have more arguments than expected, so matching
the exact number of arguments would fail, but this is fine as long as we have
all the arguments that we need in their respective places.
This patch adds a set of flags to the CallDescription class so that to handle
various special matching rules, and adds the first flag into this set,
which enables a more fuzzy matching for functions that
may be implemented as compiler builtins.
Differential Revision: https://reviews.llvm.org/D62556
llvm-svn: 364867
It encapsulates the procedure of figuring out whether a call event
corresponds to a function that's modeled by a checker.
Checker developers no longer need to worry about performance of
lookups into their own custom maps.
Add unittests - which finally test CallDescription itself as well.
Differential Revision: https://reviews.llvm.org/D62441
llvm-svn: 364866
When a function takes the address of a field the analyzer will no longer
assume that the function will change other fields of the enclosing structs.
Differential Revision: https://reviews.llvm.org/D57230
llvm-svn: 352473
to reflect the new license.
We understand that people may be surprised that we're moving the header
entirely to discuss the new license. We checked this carefully with the
Foundation's lawyer and we believe this is the correct approach.
Essentially, all code in the project is now made available by the LLVM
project under our new license, so you will see that the license headers
include that license only. Some of our contributors have contributed
code under our old license, and accordingly, we have retained a copy of
our old license notice in the top-level files in each project and
repository.
llvm-svn: 351636
Balazs Benics