values of variables in the Materializer.
The Materializer should not write the variable
back if its new value is the *same* as the old
value, not if the new value is *different*.
<rdar://problem/16712205>
llvm-svn: 207148
This is a purely mechanical change explicitly casting any parameters for printf
style conversion. This cleans up the warnings emitted by gcc 4.8 on Linux.
llvm-svn: 205607
if they didn't change, just like it does for
registers. This makes life easier for kernel
debugging and any other situation where values
are read-only.
<rdar://problem/16367795>
llvm-svn: 204764
read during materialization. First of all, report
if we can't read the data for some reason. Second,
consult the ValueObject's error and report that if
there's some problem.
<rdar://problem/16074201>
llvm-svn: 202552
materialize a variable in a register correctly
if the variable is a pointer. This fixes a
regression introduced by my commit of Oct. 22nd
(r193191).
llvm-svn: 198718
pure virtual base class and made StackFrame a subclass of that. As
I started to build on top of that arrangement today, I found that it
wasn't working out like I intended. Instead I'll try sticking with
the single StackFrame class -- there's too much code duplication to
make a more complicated class hierarchy sensible I think.
llvm-svn: 193983
defines a protocol that all subclasses will implement. StackFrame
is currently the only subclass and the methods that Frame vends are
nearly identical to StackFrame's old methods.
Update all callers to use Frame*/Frame& instead of pointers to
StackFrames.
This is almost entirely a mechanical change that touches a lot of
the code base so I'm committing it alone. No new functionality is
added with this patch, no new subclasses of Frame exist yet.
I'll probably need to tweak some of the separation, possibly moving
some of StackFrame's methods up in to Frame, but this is a good
starting point.
<rdar://problem/15314068>
llvm-svn: 193907
write to registers if they were modified in the
expression. This eliminates spurious errors if
the register can't be written to but the
expression didn't write to it anyway.
Also improved error handling for the materializer
to make "couldn't materialize struct" errors more
informative.
<rdar://problem/14322579>
llvm-svn: 186228
A long time ago we start with clang types that were created by the symbol files and there were many functions in lldb_private::ClangASTContext that helped. Later we create ClangASTType which contains a clang::ASTContext and an opauque QualType, but we didn't switch over to fully using it. There were a lot of places where we would pass around a raw clang_type_t and also pass along a clang::ASTContext separately. This left room for error.
This checkin change all type code over to use ClangASTType everywhere and I cleaned up the interfaces quite a bit. Any code that was in ClangASTContext that was type related, was moved over into ClangASTType. All code that used these types was switched over to use all of the new goodness.
llvm-svn: 186130
dematerialization of registers that caused
conditional breakpoint expressions not to
work properly. Also added a testcase.
<rdar://problem/14129252>
llvm-svn: 184451
live as long as they needed to. This led to
equality tests involving persistent variables
often failing or succeeding when they had no
business doing so.
To do this, I introduced the ability for a
memory allocation to "leak" - that is, to
persist in the process beyond the lifetime of
the expression. Hand-declared persistent
variables do this now.
<rdar://problem/13956311>
llvm-svn: 182528
Show variables that were in the debug info but optimized out. Also display a good error message when one of these variables get used in an expression.
llvm-svn: 182066
mostly related to management of the stack frame
for the interpreter.
- First, if the expression can be interpreted,
allocate the stack frame in the target process
(to make sure pointers are valid) but only
read/write to the copy in the host's memory.
- Second, keep the memory allocations for the
stack frame and the materialized struct as
member variables of ClangUserExpression. This
avoids memory allocations and deallocations
each time the expression runs.
<rdar://problem/13043685>
llvm-svn: 180664
and persistent variables so that they are not
treated as remaining in the target process (i.e.,
having live data) when the process does not allow
persistent allocations (e.g., when there is no
process or in the case of kernel core files).
llvm-svn: 179919
variables in the ValueObject code:
- Report an error if the variable does not have
a valid address.
- Return the contents of the data to GetData(),
even if the value is constant.
<rdar://problem/13690855>
llvm-svn: 179876
expressions.
Previously, ClangUserExpression assumed that if
there was a constant result for an expression
then it could be determined during parsing. In
particular, the IRInterpreter ran while parser
state (in particular, ClangExpressionDeclMap)
was present. This approach is flawed, because
the IRInterpreter actually is capable of using
external variables, and hence the result might
be different each run. Until now, we papered
over this flaw by re-parsing the expression each
time we ran it.
I have rewritten the IRInterpreter to be
completely independent of the ClangExpressionDeclMap.
Instead of special-casing external variable lookup,
which ties the IRInterpreter closely to LLDB,
we now interpret the exact same IR that the JIT
would see. This IR assumes that materialization
has occurred; hence the recent implementation of the
Materializer, which does not require parser state
(in the form of ClangExpressionDeclMap) to be
present.
Materialization, interpretation, and dematerialization
are now all independent of parsing. This means that
in theory we can parse expressions once and run them
many times. I have three outstanding tasks before
shutting this down:
- First, I will ensure that all of this works with
core files. Core files have a Process but do not
allow allocating memory, which currently confuses
materialization.
- Second, I will make expression breakpoint
conditions remember their ClangUserExpression and
re-use it.
- Third, I will tear out all the redundant code
(for example, materialization logic in
ClangExpressionDeclMap) that is no longer used.
While implementing this fix, I also found a bug in
IRForTarget's handling of floating-point constants.
This should be fixed.
llvm-svn: 179801
Materializer for all expressions that need to
run in the target. This includes the following
changes:
- Removed a bunch of (de-)materialization code
from ClangExpressionDeclMap and assumed the
presence of a Materializer where we previously
had a fallback.
- Ensured that an IRMemoryMap is passed into
ClangExpressionDeclMap::Materialize().
- Fixed object ownership on LLVMContext; it is
now owned by the IRExecutionUnit, since the
Module and the ExecutionEngine both depend on
its existence.
- Fixed a few bugs in IRMemoryMap and the
Materializer that showed up during testing.
llvm-svn: 179649
for variables in the new Materializer. This is
much easier now that the ValueObject API is solid.
I still have to implement reading bytes into a
ValueObject, but committing what I have so far.
This code is not yet used, so there will be fixes
when I switch the expression parser over to use the
new Materializer.
llvm-svn: 179416
to the Materializer. Materialization is still done by
the ClangExpressionDeclMap; this will be the next thing
to move.
Also fixed a layout bug that this uncovered.
llvm-svn: 179318
information about each variable that needs to
be materialized for an expression to work. The
next step is to migrate all materialization code
from ClangExpressionDeclMap to Materializer, and
to use it for variable materialization.
llvm-svn: 179245
Sylvestre Ledru