//===- JITSymbol.h - JIT symbol abstraction ---------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// Abstraction for target process addresses.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_EXECUTIONENGINE_JITSYMBOL_H
#define LLVM_EXECUTIONENGINE_JITSYMBOL_H
#include <algorithm>
#include <cassert>
#include <cstddef>
#include <cstdint>
#include <functional>
#include <map>
#include <set>
#include <string>
#include "llvm/ADT/BitmaskEnum.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/Support/Error.h"
namespace llvm {
class GlobalValue;
namespace object {
class SymbolRef;
} // end namespace object
/// Represents an address in the target process's address space.
using JITTargetAddress = uint64_t;
/// Convert a JITTargetAddress to a pointer.
template <typename T> T jitTargetAddressToPointer(JITTargetAddress Addr) {
static_assert(std::is_pointer<T>::value, "T must be a pointer type");
uintptr_t IntPtr = static_cast<uintptr_t>(Addr);
assert(IntPtr == Addr && "JITTargetAddress value out of range for uintptr_t");
return reinterpret_cast<T>(IntPtr);
}
template <typename T> JITTargetAddress pointerToJITTargetAddress(T *Ptr) {
return static_cast<JITTargetAddress>(reinterpret_cast<uintptr_t>(Ptr));
}
/// Flags for symbols in the JIT.
class JITSymbolFlags {
public:
using UnderlyingType = uint8_t;
using TargetFlagsType = uint64_t;
enum FlagNames : UnderlyingType {
None = 0,
HasError = 1U << 0,
Weak = 1U << 1,
Common = 1U << 2,
Absolute = 1U << 3,
Exported = 1U << 4,
Callable = 1U << 5,
Lazy = 1U << 6,
Materializing = 1U << 7,
LLVM_MARK_AS_BITMASK_ENUM(/* LargestValue = */ Materializing)
};
static JITSymbolFlags stripTransientFlags(JITSymbolFlags Orig) {
return static_cast<FlagNames>(Orig.Flags & ~Lazy & ~Materializing);
}
/// Default-construct a JITSymbolFlags instance.
JITSymbolFlags() = default;
/// Construct a JITSymbolFlags instance from the given flags.
JITSymbolFlags(FlagNames Flags) : Flags(Flags) {}
/// Construct a JITSymbolFlags instance from the given flags and target
/// flags.
JITSymbolFlags(FlagNames Flags, TargetFlagsType TargetFlags)
: Flags(Flags), TargetFlags(TargetFlags) {}
/// Implicitly convert to bool. Returs true if any flag is set.
explicit operator bool() const { return Flags != None || TargetFlags != 0; }
/// Compare for equality.
bool operator==(const JITSymbolFlags &RHS) const {
return Flags == RHS.Flags && TargetFlags == RHS.TargetFlags;
}
/// Bitwise AND-assignment for FlagNames.
JITSymbolFlags &operator&=(const FlagNames &RHS) {
Flags &= RHS;
return *this;
}
/// Bitwise OR-assignment for FlagNames.
JITSymbolFlags &operator|=(const FlagNames &RHS) {
Flags |= RHS;
return *this;
}
/// Return true if there was an error retrieving this symbol.
bool hasError() const {
return (Flags & HasError) == HasError;
}
/// Returns true if this is a lazy symbol.
/// This flag is used internally by the JIT APIs to track
/// materialization states.
bool isLazy() const { return Flags & Lazy; }
/// Returns true if this symbol is in the process of being
/// materialized.
bool isMaterializing() const { return Flags & Materializing; }
/// Returns true if this symbol is fully materialized.
/// (i.e. neither lazy, nor materializing).
bool isMaterialized() const { return !(Flags & (Lazy | Materializing)); }
/// Returns true if the Weak flag is set.
bool isWeak() const {
return (Flags & Weak) == Weak;
}
/// Returns true if the Common flag is set.
bool isCommon() const {
return (Flags & Common) == Common;
}
/// Returns true if the symbol isn't weak or common.
bool isStrong() const {
return !isWeak() && !isCommon();
}
/// Returns true if the Exported flag is set.
bool isExported() const {
return (Flags & Exported) == Exported;
}
/// Returns true if the given symbol is known to be callable.
bool isCallable() const { return (Flags & Callable) == Callable; }
/// Get the underlying flags value as an integer.
UnderlyingType getRawFlagsValue() const {
return static_cast<UnderlyingType>(Flags);
}
/// Return a reference to the target-specific flags.
TargetFlagsType& getTargetFlags() { return TargetFlags; }
/// Return a reference to the target-specific flags.
const TargetFlagsType& getTargetFlags() const { return TargetFlags; }
/// Construct a JITSymbolFlags value based on the flags of the given global
/// value.
static JITSymbolFlags fromGlobalValue(const GlobalValue &GV);
/// Construct a JITSymbolFlags value based on the flags of the given libobject
/// symbol.
static Expected<JITSymbolFlags>
fromObjectSymbol(const object::SymbolRef &Symbol);
private:
FlagNames Flags = None;
TargetFlagsType TargetFlags = 0;
};
inline JITSymbolFlags operator&(const JITSymbolFlags &LHS,
const JITSymbolFlags::FlagNames &RHS) {
JITSymbolFlags Tmp = LHS;
Tmp &= RHS;
return Tmp;
}
inline JITSymbolFlags operator|(const JITSymbolFlags &LHS,
const JITSymbolFlags::FlagNames &RHS) {
JITSymbolFlags Tmp = LHS;
Tmp |= RHS;
return Tmp;
}
/// ARM-specific JIT symbol flags.
/// FIXME: This should be moved into a target-specific header.
class ARMJITSymbolFlags {
public:
ARMJITSymbolFlags() = default;
enum FlagNames {
None = 0,
Thumb = 1 << 0
};
operator JITSymbolFlags::TargetFlagsType&() { return Flags; }
static ARMJITSymbolFlags fromObjectSymbol(const object::SymbolRef &Symbol);
private:
JITSymbolFlags::TargetFlagsType Flags = 0;
};
/// Represents a symbol that has been evaluated to an address already.
class JITEvaluatedSymbol {
public:
JITEvaluatedSymbol() = default;
/// Create a 'null' symbol.
JITEvaluatedSymbol(std::nullptr_t) {}
/// Create a symbol for the given address and flags.
JITEvaluatedSymbol(JITTargetAddress Address, JITSymbolFlags Flags)
: Address(Address), Flags(Flags) {}
/// An evaluated symbol converts to 'true' if its address is non-zero.
explicit operator bool() const { return Address != 0; }
/// Return the address of this symbol.
JITTargetAddress getAddress() const { return Address; }
/// Return the flags for this symbol.
JITSymbolFlags getFlags() const { return Flags; }
/// Set the flags for this symbol.
void setFlags(JITSymbolFlags Flags) { this->Flags = std::move(Flags); }
private:
JITTargetAddress Address = 0;
JITSymbolFlags Flags;
};
/// Represents a symbol in the JIT.
class JITSymbol {
public:
using GetAddressFtor = std::function<Expected<JITTargetAddress>()>;
/// Create a 'null' symbol, used to represent a "symbol not found"
/// result from a successful (non-erroneous) lookup.
JITSymbol(std::nullptr_t)
: CachedAddr(0) {}
/// Create a JITSymbol representing an error in the symbol lookup
/// process (e.g. a network failure during a remote lookup).
JITSymbol(Error Err)
: Err(std::move(Err)), Flags(JITSymbolFlags::HasError) {}
/// Create a symbol for a definition with a known address.
JITSymbol(JITTargetAddress Addr, JITSymbolFlags Flags)
: CachedAddr(Addr), Flags(Flags) {}
/// Construct a JITSymbol from a JITEvaluatedSymbol.
JITSymbol(JITEvaluatedSymbol Sym)
: CachedAddr(Sym.getAddress()), Flags(Sym.getFlags()) {}
/// Create a symbol for a definition that doesn't have a known address
/// yet.
/// @param GetAddress A functor to materialize a definition (fixing the
/// address) on demand.
///
/// This constructor allows a JIT layer to provide a reference to a symbol
/// definition without actually materializing the definition up front. The
/// user can materialize the definition at any time by calling the getAddress
/// method.
JITSymbol(GetAddressFtor GetAddress, JITSymbolFlags Flags)
: GetAddress(std::move(GetAddress)), CachedAddr(0), Flags(Flags) {}
JITSymbol(const JITSymbol&) = delete;
JITSymbol& operator=(const JITSymbol&) = delete;
JITSymbol(JITSymbol &&Other)
: GetAddress(std::move(Other.GetAddress)), Flags(std::move(Other.Flags)) {
if (Flags.hasError())
Err = std::move(Other.Err);
else
CachedAddr = std::move(Other.CachedAddr);
}
JITSymbol& operator=(JITSymbol &&Other) {
GetAddress = std::move(Other.GetAddress);
Flags = std::move(Other.Flags);
if (Flags.hasError())
Err = std::move(Other.Err);
else
CachedAddr = std::move(Other.CachedAddr);
return *this;
}
~JITSymbol() {
if (Flags.hasError())
Err.~Error();
else
CachedAddr.~JITTargetAddress();
}
/// Returns true if the symbol exists, false otherwise.
explicit operator bool() const {
return !Flags.hasError() && (CachedAddr || GetAddress);
}
/// Move the error field value out of this JITSymbol.
Error takeError() {
if (Flags.hasError())
return std::move(Err);
return Error::success();
}
/// Get the address of the symbol in the target address space. Returns
/// '0' if the symbol does not exist.
Expected<JITTargetAddress> getAddress() {
assert(!Flags.hasError() && "getAddress called on error value");
if (GetAddress) {
if (auto CachedAddrOrErr = GetAddress()) {
GetAddress = nullptr;
CachedAddr = *CachedAddrOrErr;
assert(CachedAddr && "Symbol could not be materialized.");
} else
return CachedAddrOrErr.takeError();
}
return CachedAddr;
}
JITSymbolFlags getFlags() const { return Flags; }
private:
GetAddressFtor GetAddress;
union {
JITTargetAddress CachedAddr;
Error Err;
};
JITSymbolFlags Flags;
};
/// Symbol resolution interface.
///
/// Allows symbol flags and addresses to be looked up by name.
/// Symbol queries are done in bulk (i.e. you request resolution of a set of
/// symbols, rather than a single one) to reduce IPC overhead in the case of
/// remote JITing, and expose opportunities for parallel compilation.
class JITSymbolResolver {
public:
using LookupSet = std::set<StringRef>;
using LookupResult = std::map<StringRef, JITEvaluatedSymbol>;
using OnResolvedFunction = std::function<void(Expected<LookupResult>)>;
virtual ~JITSymbolResolver() = default;
/// Returns the fully resolved address and flags for each of the given
/// symbols.
///
/// This method will return an error if any of the given symbols can not be
/// resolved, or if the resolution process itself triggers an error.
virtual void lookup(const LookupSet &Symbols,
OnResolvedFunction OnResolved) = 0;
/// Returns the subset of the given symbols that should be materialized by
/// the caller. Only weak/common symbols should be looked up, as strong
/// definitions are implicitly always part of the caller's responsibility.
virtual Expected<LookupSet>
getResponsibilitySet(const LookupSet &Symbols) = 0;
private:
virtual void anchor();
};
/// Legacy symbol resolution interface.
class LegacyJITSymbolResolver : public JITSymbolResolver {
public:
/// Performs lookup by, for each symbol, first calling
/// findSymbolInLogicalDylib and if that fails calling
/// findSymbol.
void lookup(const LookupSet &Symbols, OnResolvedFunction OnResolved) final;
/// Performs flags lookup by calling findSymbolInLogicalDylib and
/// returning the flags value for that symbol.
Expected<LookupSet> getResponsibilitySet(const LookupSet &Symbols) final;
/// This method returns the address of the specified symbol if it exists
/// within the logical dynamic library represented by this JITSymbolResolver.
/// Unlike findSymbol, queries through this interface should return addresses
/// for hidden symbols.
///
/// This is of particular importance for the Orc JIT APIs, which support lazy
/// compilation by breaking up modules: Each of those broken out modules
/// must be able to resolve hidden symbols provided by the others. Clients
/// writing memory managers for MCJIT can usually ignore this method.
///
/// This method will be queried by RuntimeDyld when checking for previous
/// definitions of common symbols.
virtual JITSymbol findSymbolInLogicalDylib(const std::string &Name) = 0;
/// This method returns the address of the specified function or variable.
/// It is used to resolve symbols during module linking.
///
/// If the returned symbol's address is equal to ~0ULL then RuntimeDyld will
/// skip all relocations for that symbol, and the client will be responsible
/// for handling them manually.
virtual JITSymbol findSymbol(const std::string &Name) = 0;
private:
virtual void anchor();
};
} // end namespace llvm
#endif // LLVM_EXECUTIONENGINE_JITSYMBOL_H