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llvm-mirror/include/llvm/IR/LLVMContext.h

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//===-- llvm/LLVMContext.h - Class for managing "global" state --*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file declares LLVMContext, a container of "global" state in LLVM, such
// as the global type and constant uniquing tables.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_IR_LLVMCONTEXT_H
#define LLVM_IR_LLVMCONTEXT_H
#include "llvm/Support/CBindingWrapping.h"
#include "llvm/Support/Options.h"
namespace llvm {
class LLVMContextImpl;
class StringRef;
class Twine;
class Instruction;
class Module;
class MDString;
class DICompositeType;
class SMDiagnostic;
class DiagnosticInfo;
enum DiagnosticSeverity : char;
template <typename T> class SmallVectorImpl;
class Function;
class DebugLoc;
class OptBisect;
/// This is an important class for using LLVM in a threaded context. It
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/// (opaquely) owns and manages the core "global" data of LLVM's core
/// infrastructure, including the type and constant uniquing tables.
/// LLVMContext itself provides no locking guarantees, so you should be careful
/// to have one context per thread.
class LLVMContext {
public:
LLVMContextImpl *const pImpl;
LLVMContext();
~LLVMContext();
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// Pinned metadata names, which always have the same value. This is a
// compile-time performance optimization, not a correctness optimization.
enum {
MD_dbg = 0, // "dbg"
MD_tbaa = 1, // "tbaa"
MD_prof = 2, // "prof"
MD_fpmath = 3, // "fpmath"
MD_range = 4, // "range"
MD_tbaa_struct = 5, // "tbaa.struct"
MD_invariant_load = 6, // "invariant.load"
MD_alias_scope = 7, // "alias.scope"
MD_noalias = 8, // "noalias",
MD_nontemporal = 9, // "nontemporal"
MD_mem_parallel_loop_access = 10, // "llvm.mem.parallel_loop_access"
MD_nonnull = 11, // "nonnull"
MD_dereferenceable = 12, // "dereferenceable"
MD_dereferenceable_or_null = 13, // "dereferenceable_or_null"
MD_make_implicit = 14, // "make.implicit"
MD_unpredictable = 15, // "unpredictable"
MD_invariant_group = 16, // "invariant.group"
MD_align = 17, // "align"
MD_loop = 18, // "llvm.loop"
IR: New representation for CFI and virtual call optimization pass metadata. The bitset metadata currently used in LLVM has a few problems: 1. It has the wrong name. The name "bitset" refers to an implementation detail of one use of the metadata (i.e. its original use case, CFI). This makes it harder to understand, as the name makes no sense in the context of virtual call optimization. 2. It is represented using a global named metadata node, rather than being directly associated with a global. This makes it harder to manipulate the metadata when rebuilding global variables, summarise it as part of ThinLTO and drop unused metadata when associated globals are dropped. For this reason, CFI does not currently work correctly when both CFI and vcall opt are enabled, as vcall opt needs to rebuild vtable globals, and fails to associate metadata with the rebuilt globals. As I understand it, the same problem could also affect ASan, which rebuilds globals with a red zone. This patch solves both of those problems in the following way: 1. Rename the metadata to "type metadata". This new name reflects how the metadata is currently being used (i.e. to represent type information for CFI and vtable opt). The new name is reflected in the name for the associated intrinsic (llvm.type.test) and pass (LowerTypeTests). 2. Attach metadata directly to the globals that it pertains to, rather than using the "llvm.bitsets" global metadata node as we are doing now. This is done using the newly introduced capability to attach metadata to global variables (r271348 and r271358). See also: http://lists.llvm.org/pipermail/llvm-dev/2016-June/100462.html Differential Revision: http://reviews.llvm.org/D21053 llvm-svn: 273729
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MD_type = 19, // "type"
};
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/// Known operand bundle tag IDs, which always have the same value. All
/// operand bundle tags that LLVM has special knowledge of are listed here.
/// Additionally, this scheme allows LLVM to efficiently check for specific
/// operand bundle tags without comparing strings.
enum {
OB_deopt = 0, // "deopt"
OB_funclet = 1, // "funclet"
OB_gc_transition = 2, // "gc-transition"
};
/// getMDKindID - Return a unique non-zero ID for the specified metadata kind.
/// This ID is uniqued across modules in the current LLVMContext.
unsigned getMDKindID(StringRef Name) const;
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/// getMDKindNames - Populate client supplied SmallVector with the name for
/// custom metadata IDs registered in this LLVMContext.
void getMDKindNames(SmallVectorImpl<StringRef> &Result) const;
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/// getOperandBundleTags - Populate client supplied SmallVector with the
/// bundle tags registered in this LLVMContext. The bundle tags are ordered
/// by increasing bundle IDs.
/// \see LLVMContext::getOperandBundleTagID
void getOperandBundleTags(SmallVectorImpl<StringRef> &Result) const;
/// getOperandBundleTagID - Maps a bundle tag to an integer ID. Every bundle
/// tag registered with an LLVMContext has an unique ID.
uint32_t getOperandBundleTagID(StringRef Tag) const;
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/// Define the GC for a function
void setGC(const Function &Fn, std::string GCName);
/// Return the GC for a function
const std::string &getGC(const Function &Fn);
/// Remove the GC for a function
void deleteGC(const Function &Fn);
/// Return true if the Context runtime configuration is set to discard all
/// value names. When true, only GlobalValue names will be available in the
/// IR.
bool shouldDiscardValueNames() const;
/// Set the Context runtime configuration to discard all value name (but
/// GlobalValue). Clients can use this flag to save memory and runtime,
/// especially in release mode.
void setDiscardValueNames(bool Discard);
/// Whether there is a string map for uniquing debug info
/// identifiers across the context. Off by default.
bool isODRUniquingDebugTypes() const;
void enableDebugTypeODRUniquing();
void disableDebugTypeODRUniquing();
typedef void (*InlineAsmDiagHandlerTy)(const SMDiagnostic&, void *Context,
unsigned LocCookie);
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/// Defines the type of a diagnostic handler.
/// \see LLVMContext::setDiagnosticHandler.
/// \see LLVMContext::diagnose.
typedef void (*DiagnosticHandlerTy)(const DiagnosticInfo &DI, void *Context);
/// Defines the type of a yield callback.
/// \see LLVMContext::setYieldCallback.
typedef void (*YieldCallbackTy)(LLVMContext *Context, void *OpaqueHandle);
/// setInlineAsmDiagnosticHandler - This method sets a handler that is invoked
/// when problems with inline asm are detected by the backend. The first
/// argument is a function pointer and the second is a context pointer that
/// gets passed into the DiagHandler.
///
/// LLVMContext doesn't take ownership or interpret either of these
/// pointers.
void setInlineAsmDiagnosticHandler(InlineAsmDiagHandlerTy DiagHandler,
void *DiagContext = nullptr);
/// getInlineAsmDiagnosticHandler - Return the diagnostic handler set by
/// setInlineAsmDiagnosticHandler.
InlineAsmDiagHandlerTy getInlineAsmDiagnosticHandler() const;
/// getInlineAsmDiagnosticContext - Return the diagnostic context set by
/// setInlineAsmDiagnosticHandler.
void *getInlineAsmDiagnosticContext() const;
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/// setDiagnosticHandler - This method sets a handler that is invoked
/// when the backend needs to report anything to the user. The first
/// argument is a function pointer and the second is a context pointer that
/// gets passed into the DiagHandler. The third argument should be set to
/// true if the handler only expects enabled diagnostics.
///
/// LLVMContext doesn't take ownership or interpret either of these
/// pointers.
void setDiagnosticHandler(DiagnosticHandlerTy DiagHandler,
void *DiagContext = nullptr,
bool RespectFilters = false);
/// getDiagnosticHandler - Return the diagnostic handler set by
/// setDiagnosticHandler.
DiagnosticHandlerTy getDiagnosticHandler() const;
/// getDiagnosticContext - Return the diagnostic context set by
/// setDiagnosticContext.
void *getDiagnosticContext() const;
[OptRemark,LDist] RFC: Add hotness attribute Summary: This is the first set of changes implementing the RFC from http://thread.gmane.org/gmane.comp.compilers.llvm.devel/98334 This is a cross-sectional patch; rather than implementing the hotness attribute for all optimization remarks and all passes in a patch set, it implements it for the 'missed-optimization' remark for Loop Distribution. My goal is to shake out the design issues before scaling it up to other types and passes. Hotness is computed as an integer as the multiplication of the block frequency with the function entry count. It's only printed in opt currently since clang prints the diagnostic fields directly. E.g.: remark: /tmp/t.c:3:3: loop not distributed: use -Rpass-analysis=loop-distribute for more info (hotness: 300) A new API added is similar to emitOptimizationRemarkMissed. The difference is that it additionally takes a code region that the diagnostic corresponds to. From this, hotness is computed using BFI. The new API is exposed via an analysis pass so that it can be made dependent on LazyBFI. (Thanks to Hal for the analysis pass idea.) This feature can all be enabled by setDiagnosticHotnessRequested in the LLVM context. If this is off, LazyBFI is not calculated (D22141) so there should be no overhead. A new command-line option is added to turn this on in opt. My plan is to switch all user of emitOptimizationRemark* to use this module instead. Reviewers: hfinkel Subscribers: rcox2, mzolotukhin, llvm-commits Differential Revision: http://reviews.llvm.org/D21771 llvm-svn: 275583
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/// \brief Return if a code hotness metric should be included in optimization
/// diagnostics.
bool getDiagnosticHotnessRequested() const;
/// \brief Set if a code hotness metric should be included in optimization
/// diagnostics.
void setDiagnosticHotnessRequested(bool Requested);
/// \brief Get the prefix that should be printed in front of a diagnostic of
/// the given \p Severity
static const char *getDiagnosticMessagePrefix(DiagnosticSeverity Severity);
/// \brief Report a message to the currently installed diagnostic handler.
///
/// This function returns, in particular in the case of error reporting
/// (DI.Severity == \a DS_Error), so the caller should leave the compilation
/// process in a self-consistent state, even though the generated code
/// need not be correct.
///
/// The diagnostic message will be implicitly prefixed with a severity keyword
/// according to \p DI.getSeverity(), i.e., "error: " for \a DS_Error,
/// "warning: " for \a DS_Warning, and "note: " for \a DS_Note.
void diagnose(const DiagnosticInfo &DI);
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/// \brief Registers a yield callback with the given context.
///
/// The yield callback function may be called by LLVM to transfer control back
/// to the client that invoked the LLVM compilation. This can be used to yield
/// control of the thread, or perform periodic work needed by the client.
/// There is no guaranteed frequency at which callbacks must occur; in fact,
/// the client is not guaranteed to ever receive this callback. It is at the
/// sole discretion of LLVM to do so and only if it can guarantee that
/// suspending the thread won't block any forward progress in other LLVM
/// contexts in the same process.
///
/// At a suspend point, the state of the current LLVM context is intentionally
/// undefined. No assumptions about it can or should be made. Only LLVM
/// context API calls that explicitly state that they can be used during a
/// yield callback are allowed to be used. Any other API calls into the
/// context are not supported until the yield callback function returns
/// control to LLVM. Other LLVM contexts are unaffected by this restriction.
void setYieldCallback(YieldCallbackTy Callback, void *OpaqueHandle);
/// \brief Calls the yield callback (if applicable).
///
/// This transfers control of the current thread back to the client, which may
/// suspend the current thread. Only call this method when LLVM doesn't hold
/// any global mutex or cannot block the execution in another LLVM context.
void yield();
/// emitError - Emit an error message to the currently installed error handler
/// with optional location information. This function returns, so code should
/// be prepared to drop the erroneous construct on the floor and "not crash".
/// The generated code need not be correct. The error message will be
/// implicitly prefixed with "error: " and should not end with a ".".
void emitError(unsigned LocCookie, const Twine &ErrorStr);
void emitError(const Instruction *I, const Twine &ErrorStr);
void emitError(const Twine &ErrorStr);
/// \brief Query for a debug option's value.
///
/// This function returns typed data populated from command line parsing.
template <typename ValT, typename Base, ValT(Base::*Mem)>
ValT getOption() const {
return OptionRegistry::instance().template get<ValT, Base, Mem>();
}
/// \brief Access the object which manages optimization bisection for failure
/// analysis.
OptBisect &getOptBisect();
private:
LLVMContext(LLVMContext&) = delete;
void operator=(LLVMContext&) = delete;
/// addModule - Register a module as being instantiated in this context. If
/// the context is deleted, the module will be deleted as well.
void addModule(Module*);
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/// removeModule - Unregister a module from this context.
void removeModule(Module*);
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// Module needs access to the add/removeModule methods.
friend class Module;
};
// Create wrappers for C Binding types (see CBindingWrapping.h).
DEFINE_SIMPLE_CONVERSION_FUNCTIONS(LLVMContext, LLVMContextRef)
/* Specialized opaque context conversions.
*/
inline LLVMContext **unwrap(LLVMContextRef* Tys) {
return reinterpret_cast<LLVMContext**>(Tys);
}
inline LLVMContextRef *wrap(const LLVMContext **Tys) {
return reinterpret_cast<LLVMContextRef*>(const_cast<LLVMContext**>(Tys));
}
}
#endif