llvm/lib/Target/X86/X86InstrFMA3Info.h

319 lines
12 KiB
C++

//===- X86InstrFMA3Info.h - X86 FMA3 Instruction Information ----*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file contains the implementation of the classes providing information
// about existing X86 FMA3 opcodes, classifying and grouping them.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_LIB_TARGET_X86_UTILS_X86INSTRFMA3INFO_H
#define LLVM_LIB_TARGET_X86_UTILS_X86INSTRFMA3INFO_H
#include "X86.h"
#include "llvm/ADT/DenseMap.h"
#include <cassert>
#include <cstdint>
#include <set>
namespace llvm {
/// This class is used to group {132, 213, 231} forms of FMA opcodes together.
/// Each of the groups has either 3 register opcodes, 3 memory opcodes,
/// or 6 register and memory opcodes. Also, each group has an attrubutes field
/// describing it.
class X86InstrFMA3Group {
private:
/// Reference to an array holding 3 forms of register FMA opcodes.
/// It may be set to nullptr if the group of FMA opcodes does not have
/// any register form opcodes.
const uint16_t *RegOpcodes;
/// Reference to an array holding 3 forms of memory FMA opcodes.
/// It may be set to nullptr if the group of FMA opcodes does not have
/// any register form opcodes.
const uint16_t *MemOpcodes;
/// This bitfield specifies the attributes associated with the created
/// FMA groups of opcodes.
unsigned Attributes;
static const unsigned Form132 = 0;
static const unsigned Form213 = 1;
static const unsigned Form231 = 2;
public:
/// This bit must be set in the 'Attributes' field of FMA group if such
/// group of FMA opcodes consists of FMA intrinsic opcodes.
static const unsigned X86FMA3Intrinsic = 0x1;
/// This bit must be set in the 'Attributes' field of FMA group if such
/// group of FMA opcodes consists of AVX512 opcodes accepting a k-mask and
/// passing the elements from the 1st operand to the result of the operation
/// when the correpondings bits in the k-mask are unset.
static const unsigned X86FMA3KMergeMasked = 0x2;
/// This bit must be set in the 'Attributes' field of FMA group if such
/// group of FMA opcodes consists of AVX512 opcodes accepting a k-zeromask.
static const unsigned X86FMA3KZeroMasked = 0x4;
/// Constructor. Creates a new group of FMA opcodes with three register form
/// FMA opcodes \p RegOpcodes and three memory form FMA opcodes \p MemOpcodes.
/// The parameters \p RegOpcodes and \p MemOpcodes may be set to nullptr,
/// which means that the created group of FMA opcodes does not have the
/// corresponding (register or memory) opcodes.
/// The parameter \p Attr specifies the attributes describing the created
/// group.
X86InstrFMA3Group(const uint16_t *RegOpcodes, const uint16_t *MemOpcodes,
unsigned Attr)
: RegOpcodes(RegOpcodes), MemOpcodes(MemOpcodes), Attributes(Attr) {
assert((RegOpcodes || MemOpcodes) &&
"Cannot create a group not having any opcodes.");
}
/// Returns a memory form opcode that is the equivalent of the given register
/// form opcode \p RegOpcode. 0 is returned if the group does not have
/// either register of memory opcodes.
unsigned getMemOpcode(unsigned RegOpcode) const {
if (!RegOpcodes || !MemOpcodes)
return 0;
for (unsigned Form = 0; Form < 3; Form++)
if (RegOpcodes[Form] == RegOpcode)
return MemOpcodes[Form];
return 0;
}
/// Returns the 132 form of FMA register opcode.
unsigned getReg132Opcode() const {
assert(RegOpcodes && "The group does not have register opcodes.");
return RegOpcodes[Form132];
}
/// Returns the 213 form of FMA register opcode.
unsigned getReg213Opcode() const {
assert(RegOpcodes && "The group does not have register opcodes.");
return RegOpcodes[Form213];
}
/// Returns the 231 form of FMA register opcode.
unsigned getReg231Opcode() const {
assert(RegOpcodes && "The group does not have register opcodes.");
return RegOpcodes[Form231];
}
/// Returns the 132 form of FMA memory opcode.
unsigned getMem132Opcode() const {
assert(MemOpcodes && "The group does not have memory opcodes.");
return MemOpcodes[Form132];
}
/// Returns the 213 form of FMA memory opcode.
unsigned getMem213Opcode() const {
assert(MemOpcodes && "The group does not have memory opcodes.");
return MemOpcodes[Form213];
}
/// Returns the 231 form of FMA memory opcode.
unsigned getMem231Opcode() const {
assert(MemOpcodes && "The group does not have memory opcodes.");
return MemOpcodes[Form231];
}
/// Returns true iff the group of FMA opcodes holds intrinsic opcodes.
bool isIntrinsic() const { return (Attributes & X86FMA3Intrinsic) != 0; }
/// Returns true iff the group of FMA opcodes holds k-merge-masked opcodes.
bool isKMergeMasked() const {
return (Attributes & X86FMA3KMergeMasked) != 0;
}
/// Returns true iff the group of FMA opcodes holds k-zero-masked opcodes.
bool isKZeroMasked() const { return (Attributes & X86FMA3KZeroMasked) != 0; }
/// Returns true iff the group of FMA opcodes holds any of k-masked opcodes.
bool isKMasked() const {
return (Attributes & (X86FMA3KMergeMasked | X86FMA3KZeroMasked)) != 0;
}
/// Returns true iff the given \p Opcode is a register opcode from the
/// groups of FMA opcodes.
bool isRegOpcodeFromGroup(unsigned Opcode) const {
if (!RegOpcodes)
return false;
for (unsigned Form = 0; Form < 3; Form++)
if (Opcode == RegOpcodes[Form])
return true;
return false;
}
/// Returns true iff the given \p Opcode is a memory opcode from the
/// groups of FMA opcodes.
bool isMemOpcodeFromGroup(unsigned Opcode) const {
if (!MemOpcodes)
return false;
for (unsigned Form = 0; Form < 3; Form++)
if (Opcode == MemOpcodes[Form])
return true;
return false;
}
};
/// This class provides information about all existing FMA3 opcodes
///
class X86InstrFMA3Info {
private:
/// A map that is used to find the group of FMA opcodes using any FMA opcode
/// from the group.
DenseMap<unsigned, const X86InstrFMA3Group *> OpcodeToGroup;
/// Creates groups of FMA opcodes and initializes Opcode-to-Group map.
/// This method can be called many times, but the actual initialization is
/// called only once.
static void initGroupsOnce();
/// Creates groups of FMA opcodes and initializes Opcode-to-Group map.
/// This method must be called ONLY from initGroupsOnce(). Otherwise, such
/// call is not thread safe.
void initGroupsOnceImpl();
/// Creates one group of FMA opcodes having the register opcodes
/// \p RegOpcodes and memory opcodes \p MemOpcodes. The parameter \p Attr
/// specifies the attributes describing the created group.
void initRMGroup(const uint16_t *RegOpcodes,
const uint16_t *MemOpcodes, unsigned Attr = 0);
/// Creates one group of FMA opcodes having only the register opcodes
/// \p RegOpcodes. The parameter \p Attr specifies the attributes describing
/// the created group.
void initRGroup(const uint16_t *RegOpcodes, unsigned Attr = 0);
/// Creates one group of FMA opcodes having only the memory opcodes
/// \p MemOpcodes. The parameter \p Attr specifies the attributes describing
/// the created group.
void initMGroup(const uint16_t *MemOpcodes, unsigned Attr = 0);
public:
/// Returns the reference to an object of this class. It is assumed that
/// only one object may exist.
static X86InstrFMA3Info *getX86InstrFMA3Info();
/// Constructor. Just creates an object of the class.
X86InstrFMA3Info() = default;
/// Destructor. Deallocates the memory used for FMA3 Groups.
~X86InstrFMA3Info() {
std::set<const X86InstrFMA3Group *> DeletedGroups;
auto E = OpcodeToGroup.end();
for (auto I = OpcodeToGroup.begin(); I != E; I++) {
const X86InstrFMA3Group *G = I->second;
if (DeletedGroups.find(G) == DeletedGroups.end()) {
DeletedGroups.insert(G);
delete G;
}
}
}
/// Returns a reference to a group of FMA3 opcodes to where the given
/// \p Opcode is included. If the given \p Opcode is not recognized as FMA3
/// and not included into any FMA3 group, then nullptr is returned.
static const X86InstrFMA3Group *getFMA3Group(unsigned Opcode) {
// Ensure that the groups of opcodes are initialized.
initGroupsOnce();
// Find the group including the given opcode.
const X86InstrFMA3Info *FMA3Info = getX86InstrFMA3Info();
auto I = FMA3Info->OpcodeToGroup.find(Opcode);
if (I == FMA3Info->OpcodeToGroup.end())
return nullptr;
return I->second;
}
/// Returns true iff the given \p Opcode is recognized as FMA3 by this class.
static bool isFMA3(unsigned Opcode) {
return getFMA3Group(Opcode) != nullptr;
}
/// Iterator that is used to walk on FMA register opcodes having memory
/// form equivalents.
class rm_iterator {
private:
/// Iterator associated with the OpcodeToGroup map. It must always be
/// initialized with an entry from OpcodeToGroup for which I->first
/// points to a register FMA opcode and I->second points to a group of
/// FMA opcodes having memory form equivalent of I->first.
DenseMap<unsigned, const X86InstrFMA3Group *>::const_iterator I;
public:
/// Constructor. Creates rm_iterator. The parameter \p I must be an
/// iterator to OpcodeToGroup map entry having I->first pointing to
/// register form FMA opcode and I->second pointing to a group of FMA
/// opcodes holding memory form equivalent for I->fist.
rm_iterator(DenseMap<unsigned, const X86InstrFMA3Group *>::const_iterator I)
: I(I) {}
/// Returns the register form FMA opcode.
unsigned getRegOpcode() const { return I->first; };
/// Returns the memory form equivalent opcode for FMA register opcode
/// referenced by I->first.
unsigned getMemOpcode() const {
unsigned Opcode = I->first;
const X86InstrFMA3Group *Group = I->second;
return Group->getMemOpcode(Opcode);
}
/// Returns a reference to a group of FMA opcodes.
const X86InstrFMA3Group *getGroup() const { return I->second; }
bool operator==(const rm_iterator &OtherIt) const { return I == OtherIt.I; }
bool operator!=(const rm_iterator &OtherIt) const { return I != OtherIt.I; }
/// Increment. Advances the 'I' iterator to the next OpcodeToGroup entry
/// having I->first pointing to register form FMA and I->second pointing
/// to a group of FMA opcodes holding memory form equivalen for I->first.
rm_iterator &operator++() {
auto E = getX86InstrFMA3Info()->OpcodeToGroup.end();
for (++I; I != E; ++I) {
unsigned RegOpcode = I->first;
const X86InstrFMA3Group *Group = I->second;
if (Group->getMemOpcode(RegOpcode) != 0)
break;
}
return *this;
}
};
/// Returns rm_iterator pointing to the first entry of OpcodeToGroup map
/// with a register FMA opcode having memory form opcode equivalent.
static rm_iterator rm_begin() {
initGroupsOnce();
const X86InstrFMA3Info *FMA3Info = getX86InstrFMA3Info();
auto I = FMA3Info->OpcodeToGroup.begin();
auto E = FMA3Info->OpcodeToGroup.end();
while (I != E) {
unsigned Opcode = I->first;
const X86InstrFMA3Group *G = I->second;
if (G->getMemOpcode(Opcode) != 0)
break;
I++;
}
return rm_iterator(I);
}
/// Returns the last rm_iterator.
static rm_iterator rm_end() {
initGroupsOnce();
return rm_iterator(getX86InstrFMA3Info()->OpcodeToGroup.end());
}
};
} // end namespace llvm
#endif // LLVM_LIB_TARGET_X86_UTILS_X86INSTRFMA3INFO_H