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llvm-mirror/lib/Frontend/OpenMP/OMPContext.cpp
Johannes Doerfert dd2810924a [OpenMP] Allow traits for the OpenMP context selector isa
It was unclear what `isa` was supposed to mean so we did not provide any
traits for this context selector. With this patch we will allow *any*
string or identifier. We use the target attribute and target info to
determine if the trait matches. In other words, we will check if the
provided value is a target feature that is available (at the call site).

Fixes PR46338

Reviewed By: ABataev

Differential Revision: https://reviews.llvm.org/D83281
2020-07-29 10:22:27 -05:00

543 lines
20 KiB
C++

//===- OMPContext.cpp ------ Collection of helpers for OpenMP contexts ----===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
/// \file
///
/// This file implements helper functions and classes to deal with OpenMP
/// contexts as used by `[begin/end] declare variant` and `metadirective`.
///
//===----------------------------------------------------------------------===//
#include "llvm/Frontend/OpenMP/OMPContext.h"
#include "llvm/ADT/SetOperations.h"
#include "llvm/ADT/StringSwitch.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/raw_ostream.h"
#define DEBUG_TYPE "openmp-ir-builder"
using namespace llvm;
using namespace omp;
OMPContext::OMPContext(bool IsDeviceCompilation, Triple TargetTriple) {
// Add the appropriate device kind trait based on the triple and the
// IsDeviceCompilation flag.
ActiveTraits.set(unsigned(IsDeviceCompilation
? TraitProperty::device_kind_nohost
: TraitProperty::device_kind_host));
switch (TargetTriple.getArch()) {
case Triple::arm:
case Triple::armeb:
case Triple::aarch64:
case Triple::aarch64_be:
case Triple::aarch64_32:
case Triple::mips:
case Triple::mipsel:
case Triple::mips64:
case Triple::mips64el:
case Triple::ppc:
case Triple::ppc64:
case Triple::ppc64le:
case Triple::x86:
case Triple::x86_64:
ActiveTraits.set(unsigned(TraitProperty::device_kind_cpu));
break;
case Triple::amdgcn:
case Triple::nvptx:
case Triple::nvptx64:
ActiveTraits.set(unsigned(TraitProperty::device_kind_gpu));
break;
default:
break;
}
// Add the appropriate device architecture trait based on the triple.
#define OMP_TRAIT_PROPERTY(Enum, TraitSetEnum, TraitSelectorEnum, Str) \
if (TraitSelector::TraitSelectorEnum == TraitSelector::device_arch) \
if (TargetTriple.getArch() == TargetTriple.getArchTypeForLLVMName(Str)) \
ActiveTraits.set(unsigned(TraitProperty::Enum));
#include "llvm/Frontend/OpenMP/OMPKinds.def"
// TODO: What exactly do we want to see as device ISA trait?
// The discussion on the list did not seem to have come to an agreed
// upon solution.
// LLVM is the "OpenMP vendor" but we could also interpret vendor as the
// target vendor.
ActiveTraits.set(unsigned(TraitProperty::implementation_vendor_llvm));
// The user condition true is accepted but not false.
ActiveTraits.set(unsigned(TraitProperty::user_condition_true));
// This is for sure some device.
ActiveTraits.set(unsigned(TraitProperty::device_kind_any));
LLVM_DEBUG({
dbgs() << "[" << DEBUG_TYPE
<< "] New OpenMP context with the following properties:\n";
for (unsigned Bit : ActiveTraits.set_bits()) {
TraitProperty Property = TraitProperty(Bit);
dbgs() << "\t " << getOpenMPContextTraitPropertyFullName(Property)
<< "\n";
}
});
}
/// Return true if \p C0 is a subset of \p C1. Note that both arrays are
/// expected to be sorted.
template <typename T> static bool isSubset(ArrayRef<T> C0, ArrayRef<T> C1) {
#ifdef EXPENSIVE_CHECKS
assert(llvm::is_sorted(C0) && llvm::is_sorted(C1) &&
"Expected sorted arrays!");
#endif
if (C0.size() > C1.size())
return false;
auto It0 = C0.begin(), End0 = C0.end();
auto It1 = C1.begin(), End1 = C1.end();
while (It0 != End0) {
if (It1 == End1)
return false;
if (*It0 == *It1) {
++It0;
++It1;
continue;
}
++It0;
}
return true;
}
/// Return true if \p C0 is a strict subset of \p C1. Note that both arrays are
/// expected to be sorted.
template <typename T>
static bool isStrictSubset(ArrayRef<T> C0, ArrayRef<T> C1) {
if (C0.size() >= C1.size())
return false;
return isSubset<T>(C0, C1);
}
static bool isStrictSubset(const VariantMatchInfo &VMI0,
const VariantMatchInfo &VMI1) {
// If all required traits are a strict subset and the ordered vectors storing
// the construct traits, we say it is a strict subset. Note that the latter
// relation is not required to be strict.
if (VMI0.RequiredTraits.count() >= VMI1.RequiredTraits.count())
return false;
for (unsigned Bit : VMI0.RequiredTraits.set_bits())
if (!VMI1.RequiredTraits.test(Bit))
return false;
if (!isSubset<TraitProperty>(VMI0.ConstructTraits, VMI1.ConstructTraits))
return false;
return true;
}
static int isVariantApplicableInContextHelper(
const VariantMatchInfo &VMI, const OMPContext &Ctx,
SmallVectorImpl<unsigned> *ConstructMatches, bool DeviceSetOnly) {
// The match kind determines if we need to match all traits, any of the
// traits, or none of the traits for it to be an applicable context.
enum MatchKind { MK_ALL, MK_ANY, MK_NONE };
MatchKind MK = MK_ALL;
// Determine the match kind the user wants, "all" is the default and provided
// to the user only for completeness.
if (VMI.RequiredTraits.test(
unsigned(TraitProperty::implementation_extension_match_any)))
MK = MK_ANY;
if (VMI.RequiredTraits.test(
unsigned(TraitProperty::implementation_extension_match_none)))
MK = MK_NONE;
// Helper to deal with a single property that was (not) found in the OpenMP
// context based on the match kind selected by the user via
// `implementation={extensions(match_[all,any,none])}'
auto HandleTrait = [MK](TraitProperty Property,
bool WasFound) -> Optional<bool> /* Result */ {
// For kind "any" a single match is enough but we ignore non-matched
// properties.
if (MK == MK_ANY) {
if (WasFound)
return true;
return None;
}
// In "all" or "none" mode we accept a matching or non-matching property
// respectively and move on. We are not done yet!
if ((WasFound && MK == MK_ALL) || (!WasFound && MK == MK_NONE))
return None;
// We missed a property, provide some debug output and indicate failure.
LLVM_DEBUG({
if (MK == MK_ALL)
dbgs() << "[" << DEBUG_TYPE << "] Property "
<< getOpenMPContextTraitPropertyName(Property, "")
<< " was not in the OpenMP context but match kind is all.\n";
if (MK == MK_NONE)
dbgs() << "[" << DEBUG_TYPE << "] Property "
<< getOpenMPContextTraitPropertyName(Property, "")
<< " was in the OpenMP context but match kind is none.\n";
});
return false;
};
for (unsigned Bit : VMI.RequiredTraits.set_bits()) {
TraitProperty Property = TraitProperty(Bit);
if (DeviceSetOnly &&
getOpenMPContextTraitSetForProperty(Property) != TraitSet::device)
continue;
// So far all extensions are handled elsewhere, we skip them here as they
// are not part of the OpenMP context.
if (getOpenMPContextTraitSelectorForProperty(Property) ==
TraitSelector::implementation_extension)
continue;
bool IsActiveTrait = Ctx.ActiveTraits.test(unsigned(Property));
// We overwrite the isa trait as it is actually up to the OMPContext hook to
// check the raw string(s).
if (Property == TraitProperty::device_isa___ANY)
IsActiveTrait = llvm::all_of(VMI.ISATraits, [&](StringRef RawString) {
return Ctx.matchesISATrait(RawString);
});
Optional<bool> Result = HandleTrait(Property, IsActiveTrait);
if (Result.hasValue())
return Result.getValue();
}
if (!DeviceSetOnly) {
// We could use isSubset here but we also want to record the match
// locations.
unsigned ConstructIdx = 0, NoConstructTraits = Ctx.ConstructTraits.size();
for (TraitProperty Property : VMI.ConstructTraits) {
assert(getOpenMPContextTraitSetForProperty(Property) ==
TraitSet::construct &&
"Variant context is ill-formed!");
// Verify the nesting.
bool FoundInOrder = false;
while (!FoundInOrder && ConstructIdx != NoConstructTraits)
FoundInOrder = (Ctx.ConstructTraits[ConstructIdx++] == Property);
if (ConstructMatches)
ConstructMatches->push_back(ConstructIdx - 1);
Optional<bool> Result = HandleTrait(Property, FoundInOrder);
if (Result.hasValue())
return Result.getValue();
if (!FoundInOrder) {
LLVM_DEBUG(dbgs() << "[" << DEBUG_TYPE << "] Construct property "
<< getOpenMPContextTraitPropertyName(Property, "")
<< " was not nested properly.\n");
return false;
}
// TODO: Verify SIMD
}
assert(isSubset<TraitProperty>(VMI.ConstructTraits, Ctx.ConstructTraits) &&
"Broken invariant!");
}
if (MK == MK_ANY) {
LLVM_DEBUG(dbgs() << "[" << DEBUG_TYPE
<< "] None of the properties was in the OpenMP context "
"but match kind is any.\n");
return false;
}
return true;
}
bool llvm::omp::isVariantApplicableInContext(const VariantMatchInfo &VMI,
const OMPContext &Ctx,
bool DeviceSetOnly) {
return isVariantApplicableInContextHelper(
VMI, Ctx, /* ConstructMatches */ nullptr, DeviceSetOnly);
}
static APInt getVariantMatchScore(const VariantMatchInfo &VMI,
const OMPContext &Ctx,
SmallVectorImpl<unsigned> &ConstructMatches) {
APInt Score(64, 1);
unsigned NoConstructTraits = VMI.ConstructTraits.size();
for (unsigned Bit : VMI.RequiredTraits.set_bits()) {
TraitProperty Property = TraitProperty(Bit);
// If there is a user score attached, use it.
if (VMI.ScoreMap.count(Property)) {
const APInt &UserScore = VMI.ScoreMap.lookup(Property);
assert(UserScore.uge(0) && "Expect non-negative user scores!");
Score += UserScore.getZExtValue();
continue;
}
switch (getOpenMPContextTraitSetForProperty(Property)) {
case TraitSet::construct:
// We handle the construct traits later via the VMI.ConstructTraits
// container.
continue;
case TraitSet::implementation:
// No effect on the score (implementation defined).
continue;
case TraitSet::user:
// No effect on the score.
continue;
case TraitSet::device:
// Handled separately below.
break;
case TraitSet::invalid:
llvm_unreachable("Unknown trait set is not to be used!");
}
// device={kind(any)} is "as if" no kind selector was specified.
if (Property == TraitProperty::device_kind_any)
continue;
switch (getOpenMPContextTraitSelectorForProperty(Property)) {
case TraitSelector::device_kind:
Score += (1ULL << (NoConstructTraits + 0));
continue;
case TraitSelector::device_arch:
Score += (1ULL << (NoConstructTraits + 1));
continue;
case TraitSelector::device_isa:
Score += (1ULL << (NoConstructTraits + 2));
continue;
default:
continue;
}
}
unsigned ConstructIdx = 0;
assert(NoConstructTraits == ConstructMatches.size() &&
"Mismatch in the construct traits!");
for (TraitProperty Property : VMI.ConstructTraits) {
assert(getOpenMPContextTraitSetForProperty(Property) ==
TraitSet::construct &&
"Ill-formed variant match info!");
(void)Property;
// ConstructMatches is the position p - 1 and we need 2^(p-1).
Score += (1ULL << ConstructMatches[ConstructIdx++]);
}
LLVM_DEBUG(dbgs() << "[" << DEBUG_TYPE << "] Variant has a score of " << Score
<< "\n");
return Score;
}
int llvm::omp::getBestVariantMatchForContext(
const SmallVectorImpl<VariantMatchInfo> &VMIs, const OMPContext &Ctx) {
APInt BestScore(64, 0);
int BestVMIIdx = -1;
const VariantMatchInfo *BestVMI = nullptr;
for (unsigned u = 0, e = VMIs.size(); u < e; ++u) {
const VariantMatchInfo &VMI = VMIs[u];
SmallVector<unsigned, 8> ConstructMatches;
// If the variant is not applicable its not the best.
if (!isVariantApplicableInContextHelper(VMI, Ctx, &ConstructMatches,
/* DeviceSetOnly */ false))
continue;
// Check if its clearly not the best.
APInt Score = getVariantMatchScore(VMI, Ctx, ConstructMatches);
if (Score.ult(BestScore))
continue;
// Equal score need subset checks.
if (Score.eq(BestScore)) {
// Strict subset are never best.
if (isStrictSubset(VMI, *BestVMI))
continue;
// Same score and the current best is no strict subset so we keep it.
if (!isStrictSubset(*BestVMI, VMI))
continue;
}
// New best found.
BestVMI = &VMI;
BestVMIIdx = u;
BestScore = Score;
}
return BestVMIIdx;
}
TraitSet llvm::omp::getOpenMPContextTraitSetKind(StringRef S) {
return StringSwitch<TraitSet>(S)
#define OMP_TRAIT_SET(Enum, Str) .Case(Str, TraitSet::Enum)
#include "llvm/Frontend/OpenMP/OMPKinds.def"
.Default(TraitSet::invalid);
}
TraitSet
llvm::omp::getOpenMPContextTraitSetForSelector(TraitSelector Selector) {
switch (Selector) {
#define OMP_TRAIT_SELECTOR(Enum, TraitSetEnum, Str, ReqProp) \
case TraitSelector::Enum: \
return TraitSet::TraitSetEnum;
#include "llvm/Frontend/OpenMP/OMPKinds.def"
}
llvm_unreachable("Unknown trait selector!");
}
TraitSet
llvm::omp::getOpenMPContextTraitSetForProperty(TraitProperty Property) {
switch (Property) {
#define OMP_TRAIT_PROPERTY(Enum, TraitSetEnum, TraitSelectorEnum, Str) \
case TraitProperty::Enum: \
return TraitSet::TraitSetEnum;
#include "llvm/Frontend/OpenMP/OMPKinds.def"
}
llvm_unreachable("Unknown trait set!");
}
StringRef llvm::omp::getOpenMPContextTraitSetName(TraitSet Kind) {
switch (Kind) {
#define OMP_TRAIT_SET(Enum, Str) \
case TraitSet::Enum: \
return Str;
#include "llvm/Frontend/OpenMP/OMPKinds.def"
}
llvm_unreachable("Unknown trait set!");
}
TraitSelector llvm::omp::getOpenMPContextTraitSelectorKind(StringRef S) {
return StringSwitch<TraitSelector>(S)
#define OMP_TRAIT_SELECTOR(Enum, TraitSetEnum, Str, ReqProp) \
.Case(Str, TraitSelector::Enum)
#include "llvm/Frontend/OpenMP/OMPKinds.def"
.Default(TraitSelector::invalid);
}
TraitSelector
llvm::omp::getOpenMPContextTraitSelectorForProperty(TraitProperty Property) {
switch (Property) {
#define OMP_TRAIT_PROPERTY(Enum, TraitSetEnum, TraitSelectorEnum, Str) \
case TraitProperty::Enum: \
return TraitSelector::TraitSelectorEnum;
#include "llvm/Frontend/OpenMP/OMPKinds.def"
}
llvm_unreachable("Unknown trait set!");
}
StringRef llvm::omp::getOpenMPContextTraitSelectorName(TraitSelector Kind) {
switch (Kind) {
#define OMP_TRAIT_SELECTOR(Enum, TraitSetEnum, Str, ReqProp) \
case TraitSelector::Enum: \
return Str;
#include "llvm/Frontend/OpenMP/OMPKinds.def"
}
llvm_unreachable("Unknown trait selector!");
}
TraitProperty llvm::omp::getOpenMPContextTraitPropertyKind(
TraitSet Set, TraitSelector Selector, StringRef S) {
// Special handling for `device={isa(...)}` as we accept anything here. It is
// up to the target to decide if the feature is available.
if (Set == TraitSet::device && Selector == TraitSelector::device_isa)
return TraitProperty::device_isa___ANY;
#define OMP_TRAIT_PROPERTY(Enum, TraitSetEnum, TraitSelectorEnum, Str) \
if (Set == TraitSet::TraitSetEnum && Str == S) \
return TraitProperty::Enum;
#include "llvm/Frontend/OpenMP/OMPKinds.def"
return TraitProperty::invalid;
}
TraitProperty
llvm::omp::getOpenMPContextTraitPropertyForSelector(TraitSelector Selector) {
return StringSwitch<TraitProperty>(
getOpenMPContextTraitSelectorName(Selector))
#define OMP_TRAIT_PROPERTY(Enum, TraitSetEnum, TraitSelectorEnum, Str) \
.Case(Str, Selector == TraitSelector::TraitSelectorEnum \
? TraitProperty::Enum \
: TraitProperty::invalid)
#include "llvm/Frontend/OpenMP/OMPKinds.def"
.Default(TraitProperty::invalid);
}
StringRef llvm::omp::getOpenMPContextTraitPropertyName(TraitProperty Kind,
StringRef RawString) {
if (Kind == TraitProperty::device_isa___ANY)
return RawString;
switch (Kind) {
#define OMP_TRAIT_PROPERTY(Enum, TraitSetEnum, TraitSelectorEnum, Str) \
case TraitProperty::Enum: \
return Str;
#include "llvm/Frontend/OpenMP/OMPKinds.def"
}
llvm_unreachable("Unknown trait property!");
}
StringRef llvm::omp::getOpenMPContextTraitPropertyFullName(TraitProperty Kind) {
switch (Kind) {
#define OMP_TRAIT_PROPERTY(Enum, TraitSetEnum, TraitSelectorEnum, Str) \
case TraitProperty::Enum: \
return "(" #TraitSetEnum "," #TraitSelectorEnum "," Str ")";
#include "llvm/Frontend/OpenMP/OMPKinds.def"
}
llvm_unreachable("Unknown trait property!");
}
bool llvm::omp::isValidTraitSelectorForTraitSet(TraitSelector Selector,
TraitSet Set,
bool &AllowsTraitScore,
bool &RequiresProperty) {
AllowsTraitScore = Set != TraitSet::construct && Set != TraitSet::device;
switch (Selector) {
#define OMP_TRAIT_SELECTOR(Enum, TraitSetEnum, Str, ReqProp) \
case TraitSelector::Enum: \
RequiresProperty = ReqProp; \
return Set == TraitSet::TraitSetEnum;
#include "llvm/Frontend/OpenMP/OMPKinds.def"
}
llvm_unreachable("Unknown trait selector!");
}
bool llvm::omp::isValidTraitPropertyForTraitSetAndSelector(
TraitProperty Property, TraitSelector Selector, TraitSet Set) {
switch (Property) {
#define OMP_TRAIT_PROPERTY(Enum, TraitSetEnum, TraitSelectorEnum, Str) \
case TraitProperty::Enum: \
return Set == TraitSet::TraitSetEnum && \
Selector == TraitSelector::TraitSelectorEnum;
#include "llvm/Frontend/OpenMP/OMPKinds.def"
}
llvm_unreachable("Unknown trait property!");
}
std::string llvm::omp::listOpenMPContextTraitSets() {
std::string S;
#define OMP_TRAIT_SET(Enum, Str) \
if (StringRef(Str) != "invalid") \
S.append("'").append(Str).append("'").append(" ");
#include "llvm/Frontend/OpenMP/OMPKinds.def"
S.pop_back();
return S;
}
std::string llvm::omp::listOpenMPContextTraitSelectors(TraitSet Set) {
std::string S;
#define OMP_TRAIT_SELECTOR(Enum, TraitSetEnum, Str, ReqProp) \
if (TraitSet::TraitSetEnum == Set && StringRef(Str) != "Invalid") \
S.append("'").append(Str).append("'").append(" ");
#include "llvm/Frontend/OpenMP/OMPKinds.def"
S.pop_back();
return S;
}
std::string
llvm::omp::listOpenMPContextTraitProperties(TraitSet Set,
TraitSelector Selector) {
std::string S;
#define OMP_TRAIT_PROPERTY(Enum, TraitSetEnum, TraitSelectorEnum, Str) \
if (TraitSet::TraitSetEnum == Set && \
TraitSelector::TraitSelectorEnum == Selector && \
StringRef(Str) != "invalid") \
S.append("'").append(Str).append("'").append(" ");
#include "llvm/Frontend/OpenMP/OMPKinds.def"
if (S.empty())
return "<none>";
S.pop_back();
return S;
}