llvm-project/clang/lib/CodeGen/CGOpenMPRuntimeNVPTX.cpp

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//===---- CGOpenMPRuntimeNVPTX.cpp - Interface to OpenMP NVPTX Runtimes ---===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This provides a class for OpenMP runtime code generation specialized to NVPTX
// targets.
//
//===----------------------------------------------------------------------===//
#include "CGOpenMPRuntimeNVPTX.h"
#include "CodeGenFunction.h"
#include "clang/AST/DeclOpenMP.h"
#include "clang/AST/StmtOpenMP.h"
#include "clang/AST/StmtVisitor.h"
#include "clang/Basic/Cuda.h"
#include "llvm/ADT/SmallPtrSet.h"
using namespace clang;
using namespace CodeGen;
namespace {
enum OpenMPRTLFunctionNVPTX {
/// Call to void __kmpc_kernel_init(kmp_int32 thread_limit,
/// int16_t RequiresOMPRuntime);
OMPRTL_NVPTX__kmpc_kernel_init,
/// Call to void __kmpc_kernel_deinit(int16_t IsOMPRuntimeInitialized);
OMPRTL_NVPTX__kmpc_kernel_deinit,
/// Call to void __kmpc_spmd_kernel_init(kmp_int32 thread_limit,
/// int16_t RequiresOMPRuntime, int16_t RequiresDataSharing);
OMPRTL_NVPTX__kmpc_spmd_kernel_init,
/// Call to void __kmpc_spmd_kernel_deinit();
OMPRTL_NVPTX__kmpc_spmd_kernel_deinit,
/// Call to void __kmpc_kernel_prepare_parallel(void
/// *outlined_function, int16_t
/// IsOMPRuntimeInitialized);
OMPRTL_NVPTX__kmpc_kernel_prepare_parallel,
/// Call to bool __kmpc_kernel_parallel(void **outlined_function,
/// int16_t IsOMPRuntimeInitialized);
OMPRTL_NVPTX__kmpc_kernel_parallel,
/// Call to void __kmpc_kernel_end_parallel();
OMPRTL_NVPTX__kmpc_kernel_end_parallel,
/// Call to void __kmpc_serialized_parallel(ident_t *loc, kmp_int32
/// global_tid);
OMPRTL_NVPTX__kmpc_serialized_parallel,
/// Call to void __kmpc_end_serialized_parallel(ident_t *loc, kmp_int32
/// global_tid);
OMPRTL_NVPTX__kmpc_end_serialized_parallel,
/// Call to int32_t __kmpc_shuffle_int32(int32_t element,
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
/// int16_t lane_offset, int16_t warp_size);
OMPRTL_NVPTX__kmpc_shuffle_int32,
/// Call to int64_t __kmpc_shuffle_int64(int64_t element,
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
/// int16_t lane_offset, int16_t warp_size);
OMPRTL_NVPTX__kmpc_shuffle_int64,
/// Call to __kmpc_nvptx_parallel_reduce_nowait(kmp_int32
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
/// global_tid, kmp_int32 num_vars, size_t reduce_size, void* reduce_data,
/// void (*kmp_ShuffleReductFctPtr)(void *rhsData, int16_t lane_id, int16_t
/// lane_offset, int16_t shortCircuit),
/// void (*kmp_InterWarpCopyFctPtr)(void* src, int32_t warp_num));
OMPRTL_NVPTX__kmpc_parallel_reduce_nowait,
/// Call to __kmpc_nvptx_teams_reduce_nowait_simple(ident_t *loc, kmp_int32
/// global_tid, kmp_critical_name *lck)
OMPRTL_NVPTX__kmpc_nvptx_teams_reduce_nowait_simple,
/// Call to __kmpc_nvptx_teams_end_reduce_nowait_simple(ident_t *loc,
/// kmp_int32 global_tid, kmp_critical_name *lck)
OMPRTL_NVPTX__kmpc_nvptx_teams_end_reduce_nowait_simple,
/// Call to __kmpc_nvptx_end_reduce_nowait(int32_t global_tid);
OMPRTL_NVPTX__kmpc_end_reduce_nowait,
/// Call to void __kmpc_data_sharing_init_stack();
OMPRTL_NVPTX__kmpc_data_sharing_init_stack,
/// Call to void __kmpc_data_sharing_init_stack_spmd();
OMPRTL_NVPTX__kmpc_data_sharing_init_stack_spmd,
/// Call to void* __kmpc_data_sharing_coalesced_push_stack(size_t size,
/// int16_t UseSharedMemory);
OMPRTL_NVPTX__kmpc_data_sharing_coalesced_push_stack,
/// Call to void __kmpc_data_sharing_pop_stack(void *a);
OMPRTL_NVPTX__kmpc_data_sharing_pop_stack,
/// Call to void __kmpc_begin_sharing_variables(void ***args,
/// size_t n_args);
OMPRTL_NVPTX__kmpc_begin_sharing_variables,
/// Call to void __kmpc_end_sharing_variables();
OMPRTL_NVPTX__kmpc_end_sharing_variables,
/// Call to void __kmpc_get_shared_variables(void ***GlobalArgs)
OMPRTL_NVPTX__kmpc_get_shared_variables,
/// Call to uint16_t __kmpc_parallel_level(ident_t *loc, kmp_int32
/// global_tid);
OMPRTL_NVPTX__kmpc_parallel_level,
/// Call to int8_t __kmpc_is_spmd_exec_mode();
OMPRTL_NVPTX__kmpc_is_spmd_exec_mode,
/// Call to void __kmpc_get_team_static_memory(const void *buf, size_t size,
/// int16_t is_shared, const void **res);
OMPRTL_NVPTX__kmpc_get_team_static_memory,
/// Call to void __kmpc_restore_team_static_memory(int16_t is_shared);
OMPRTL_NVPTX__kmpc_restore_team_static_memory,
};
/// Pre(post)-action for different OpenMP constructs specialized for NVPTX.
class NVPTXActionTy final : public PrePostActionTy {
llvm::Value *EnterCallee = nullptr;
ArrayRef<llvm::Value *> EnterArgs;
llvm::Value *ExitCallee = nullptr;
ArrayRef<llvm::Value *> ExitArgs;
bool Conditional = false;
llvm::BasicBlock *ContBlock = nullptr;
public:
NVPTXActionTy(llvm::Value *EnterCallee, ArrayRef<llvm::Value *> EnterArgs,
llvm::Value *ExitCallee, ArrayRef<llvm::Value *> ExitArgs,
bool Conditional = false)
: EnterCallee(EnterCallee), EnterArgs(EnterArgs), ExitCallee(ExitCallee),
ExitArgs(ExitArgs), Conditional(Conditional) {}
void Enter(CodeGenFunction &CGF) override {
llvm::Value *EnterRes = CGF.EmitRuntimeCall(EnterCallee, EnterArgs);
if (Conditional) {
llvm::Value *CallBool = CGF.Builder.CreateIsNotNull(EnterRes);
auto *ThenBlock = CGF.createBasicBlock("omp_if.then");
ContBlock = CGF.createBasicBlock("omp_if.end");
// Generate the branch (If-stmt)
CGF.Builder.CreateCondBr(CallBool, ThenBlock, ContBlock);
CGF.EmitBlock(ThenBlock);
}
}
void Done(CodeGenFunction &CGF) {
// Emit the rest of blocks/branches
CGF.EmitBranch(ContBlock);
CGF.EmitBlock(ContBlock, true);
}
void Exit(CodeGenFunction &CGF) override {
CGF.EmitRuntimeCall(ExitCallee, ExitArgs);
}
};
/// A class to track the execution mode when codegening directives within
/// a target region. The appropriate mode (SPMD|NON-SPMD) is set on entry
/// to the target region and used by containing directives such as 'parallel'
/// to emit optimized code.
class ExecutionRuntimeModesRAII {
private:
CGOpenMPRuntimeNVPTX::ExecutionMode SavedExecMode =
CGOpenMPRuntimeNVPTX::EM_Unknown;
CGOpenMPRuntimeNVPTX::ExecutionMode &ExecMode;
bool SavedRuntimeMode = false;
bool *RuntimeMode = nullptr;
public:
/// Constructor for Non-SPMD mode.
ExecutionRuntimeModesRAII(CGOpenMPRuntimeNVPTX::ExecutionMode &ExecMode)
: ExecMode(ExecMode) {
SavedExecMode = ExecMode;
ExecMode = CGOpenMPRuntimeNVPTX::EM_NonSPMD;
}
/// Constructor for SPMD mode.
ExecutionRuntimeModesRAII(CGOpenMPRuntimeNVPTX::ExecutionMode &ExecMode,
bool &RuntimeMode, bool FullRuntimeMode)
: ExecMode(ExecMode), RuntimeMode(&RuntimeMode) {
SavedExecMode = ExecMode;
SavedRuntimeMode = RuntimeMode;
ExecMode = CGOpenMPRuntimeNVPTX::EM_SPMD;
RuntimeMode = FullRuntimeMode;
}
~ExecutionRuntimeModesRAII() {
ExecMode = SavedExecMode;
if (RuntimeMode)
*RuntimeMode = SavedRuntimeMode;
}
};
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
/// GPU Configuration: This information can be derived from cuda registers,
/// however, providing compile time constants helps generate more efficient
/// code. For all practical purposes this is fine because the configuration
/// is the same for all known NVPTX architectures.
enum MachineConfiguration : unsigned {
WarpSize = 32,
/// Number of bits required to represent a lane identifier, which is
/// computed as log_2(WarpSize).
LaneIDBits = 5,
LaneIDMask = WarpSize - 1,
/// Global memory alignment for performance.
GlobalMemoryAlignment = 128,
/// Maximal size of the shared memory buffer.
SharedMemorySize = 128,
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
};
enum NamedBarrier : unsigned {
/// Synchronize on this barrier #ID using a named barrier primitive.
/// Only the subset of active threads in a parallel region arrive at the
/// barrier.
NB_Parallel = 1,
};
static const ValueDecl *getPrivateItem(const Expr *RefExpr) {
RefExpr = RefExpr->IgnoreParens();
if (const auto *ASE = dyn_cast<ArraySubscriptExpr>(RefExpr)) {
const Expr *Base = ASE->getBase()->IgnoreParenImpCasts();
while (const auto *TempASE = dyn_cast<ArraySubscriptExpr>(Base))
Base = TempASE->getBase()->IgnoreParenImpCasts();
RefExpr = Base;
} else if (auto *OASE = dyn_cast<OMPArraySectionExpr>(RefExpr)) {
const Expr *Base = OASE->getBase()->IgnoreParenImpCasts();
while (const auto *TempOASE = dyn_cast<OMPArraySectionExpr>(Base))
Base = TempOASE->getBase()->IgnoreParenImpCasts();
while (const auto *TempASE = dyn_cast<ArraySubscriptExpr>(Base))
Base = TempASE->getBase()->IgnoreParenImpCasts();
RefExpr = Base;
}
RefExpr = RefExpr->IgnoreParenImpCasts();
if (const auto *DE = dyn_cast<DeclRefExpr>(RefExpr))
return cast<ValueDecl>(DE->getDecl()->getCanonicalDecl());
const auto *ME = cast<MemberExpr>(RefExpr);
return cast<ValueDecl>(ME->getMemberDecl()->getCanonicalDecl());
}
typedef std::pair<CharUnits /*Align*/, const ValueDecl *> VarsDataTy;
static bool stable_sort_comparator(const VarsDataTy P1, const VarsDataTy P2) {
return P1.first > P2.first;
}
static RecordDecl *buildRecordForGlobalizedVars(
ASTContext &C, ArrayRef<const ValueDecl *> EscapedDecls,
ArrayRef<const ValueDecl *> EscapedDeclsForTeams,
llvm::SmallDenseMap<const ValueDecl *, const FieldDecl *>
&MappedDeclsFields) {
if (EscapedDecls.empty() && EscapedDeclsForTeams.empty())
return nullptr;
SmallVector<VarsDataTy, 4> GlobalizedVars;
for (const ValueDecl *D : EscapedDecls)
GlobalizedVars.emplace_back(
CharUnits::fromQuantity(std::max(
C.getDeclAlign(D).getQuantity(),
static_cast<CharUnits::QuantityType>(GlobalMemoryAlignment))),
D);
for (const ValueDecl *D : EscapedDeclsForTeams)
GlobalizedVars.emplace_back(C.getDeclAlign(D), D);
std::stable_sort(GlobalizedVars.begin(), GlobalizedVars.end(),
stable_sort_comparator);
// Build struct _globalized_locals_ty {
// /* globalized vars */[WarSize] align (max(decl_align,
// GlobalMemoryAlignment))
// /* globalized vars */ for EscapedDeclsForTeams
// };
RecordDecl *GlobalizedRD = C.buildImplicitRecord("_globalized_locals_ty");
GlobalizedRD->startDefinition();
llvm::SmallPtrSet<const ValueDecl *, 16> SingleEscaped(
EscapedDeclsForTeams.begin(), EscapedDeclsForTeams.end());
for (const auto &Pair : GlobalizedVars) {
const ValueDecl *VD = Pair.second;
QualType Type = VD->getType();
if (Type->isLValueReferenceType())
Type = C.getPointerType(Type.getNonReferenceType());
else
Type = Type.getNonReferenceType();
SourceLocation Loc = VD->getLocation();
FieldDecl *Field;
if (SingleEscaped.count(VD)) {
Field = FieldDecl::Create(
C, GlobalizedRD, Loc, Loc, VD->getIdentifier(), Type,
C.getTrivialTypeSourceInfo(Type, SourceLocation()),
/*BW=*/nullptr, /*Mutable=*/false,
/*InitStyle=*/ICIS_NoInit);
Field->setAccess(AS_public);
if (VD->hasAttrs()) {
for (specific_attr_iterator<AlignedAttr> I(VD->getAttrs().begin()),
E(VD->getAttrs().end());
I != E; ++I)
Field->addAttr(*I);
}
} else {
llvm::APInt ArraySize(32, WarpSize);
Type = C.getConstantArrayType(Type, ArraySize, ArrayType::Normal, 0);
Field = FieldDecl::Create(
C, GlobalizedRD, Loc, Loc, VD->getIdentifier(), Type,
C.getTrivialTypeSourceInfo(Type, SourceLocation()),
/*BW=*/nullptr, /*Mutable=*/false,
/*InitStyle=*/ICIS_NoInit);
Field->setAccess(AS_public);
llvm::APInt Align(32, std::max(C.getDeclAlign(VD).getQuantity(),
static_cast<CharUnits::QuantityType>(
GlobalMemoryAlignment)));
Field->addAttr(AlignedAttr::CreateImplicit(
C, AlignedAttr::GNU_aligned, /*IsAlignmentExpr=*/true,
IntegerLiteral::Create(C, Align,
C.getIntTypeForBitwidth(32, /*Signed=*/0),
SourceLocation())));
}
GlobalizedRD->addDecl(Field);
MappedDeclsFields.try_emplace(VD, Field);
}
GlobalizedRD->completeDefinition();
return GlobalizedRD;
}
/// Get the list of variables that can escape their declaration context.
class CheckVarsEscapingDeclContext final
: public ConstStmtVisitor<CheckVarsEscapingDeclContext> {
CodeGenFunction &CGF;
llvm::SetVector<const ValueDecl *> EscapedDecls;
llvm::SetVector<const ValueDecl *> EscapedVariableLengthDecls;
llvm::SmallPtrSet<const Decl *, 4> EscapedParameters;
RecordDecl *GlobalizedRD = nullptr;
llvm::SmallDenseMap<const ValueDecl *, const FieldDecl *> MappedDeclsFields;
bool AllEscaped = false;
bool IsForCombinedParallelRegion = false;
void markAsEscaped(const ValueDecl *VD) {
// Do not globalize declare target variables.
if (!isa<VarDecl>(VD) ||
OMPDeclareTargetDeclAttr::isDeclareTargetDeclaration(VD))
return;
VD = cast<ValueDecl>(VD->getCanonicalDecl());
// Variables captured by value must be globalized.
if (auto *CSI = CGF.CapturedStmtInfo) {
if (const FieldDecl *FD = CSI->lookup(cast<VarDecl>(VD))) {
// Check if need to capture the variable that was already captured by
// value in the outer region.
if (!IsForCombinedParallelRegion) {
if (!FD->hasAttrs())
return;
const auto *Attr = FD->getAttr<OMPCaptureKindAttr>();
if (!Attr)
return;
if (!isOpenMPPrivate(
static_cast<OpenMPClauseKind>(Attr->getCaptureKind())) ||
Attr->getCaptureKind() == OMPC_map)
return;
}
if (!FD->getType()->isReferenceType()) {
assert(!VD->getType()->isVariablyModifiedType() &&
"Parameter captured by value with variably modified type");
EscapedParameters.insert(VD);
} else if (!IsForCombinedParallelRegion) {
return;
}
}
}
if ((!CGF.CapturedStmtInfo ||
(IsForCombinedParallelRegion && CGF.CapturedStmtInfo)) &&
VD->getType()->isReferenceType())
// Do not globalize variables with reference type.
return;
if (VD->getType()->isVariablyModifiedType())
EscapedVariableLengthDecls.insert(VD);
else
EscapedDecls.insert(VD);
}
void VisitValueDecl(const ValueDecl *VD) {
if (VD->getType()->isLValueReferenceType())
markAsEscaped(VD);
if (const auto *VarD = dyn_cast<VarDecl>(VD)) {
if (!isa<ParmVarDecl>(VarD) && VarD->hasInit()) {
const bool SavedAllEscaped = AllEscaped;
AllEscaped = VD->getType()->isLValueReferenceType();
Visit(VarD->getInit());
AllEscaped = SavedAllEscaped;
}
}
}
void VisitOpenMPCapturedStmt(const CapturedStmt *S,
ArrayRef<OMPClause *> Clauses,
bool IsCombinedParallelRegion) {
if (!S)
return;
for (const CapturedStmt::Capture &C : S->captures()) {
if (C.capturesVariable() && !C.capturesVariableByCopy()) {
const ValueDecl *VD = C.getCapturedVar();
bool SavedIsForCombinedParallelRegion = IsForCombinedParallelRegion;
if (IsCombinedParallelRegion) {
// Check if the variable is privatized in the combined construct and
// those private copies must be shared in the inner parallel
// directive.
IsForCombinedParallelRegion = false;
for (const OMPClause *C : Clauses) {
if (!isOpenMPPrivate(C->getClauseKind()) ||
C->getClauseKind() == OMPC_reduction ||
C->getClauseKind() == OMPC_linear ||
C->getClauseKind() == OMPC_private)
continue;
ArrayRef<const Expr *> Vars;
if (const auto *PC = dyn_cast<OMPFirstprivateClause>(C))
Vars = PC->getVarRefs();
else if (const auto *PC = dyn_cast<OMPLastprivateClause>(C))
Vars = PC->getVarRefs();
else
llvm_unreachable("Unexpected clause.");
for (const auto *E : Vars) {
const Decl *D =
cast<DeclRefExpr>(E)->getDecl()->getCanonicalDecl();
if (D == VD->getCanonicalDecl()) {
IsForCombinedParallelRegion = true;
break;
}
}
if (IsForCombinedParallelRegion)
break;
}
}
markAsEscaped(VD);
if (isa<OMPCapturedExprDecl>(VD))
VisitValueDecl(VD);
IsForCombinedParallelRegion = SavedIsForCombinedParallelRegion;
}
}
}
void buildRecordForGlobalizedVars(bool IsInTTDRegion) {
assert(!GlobalizedRD &&
"Record for globalized variables is built already.");
ArrayRef<const ValueDecl *> EscapedDeclsForParallel, EscapedDeclsForTeams;
if (IsInTTDRegion)
EscapedDeclsForTeams = EscapedDecls.getArrayRef();
else
EscapedDeclsForParallel = EscapedDecls.getArrayRef();
GlobalizedRD = ::buildRecordForGlobalizedVars(
CGF.getContext(), EscapedDeclsForParallel, EscapedDeclsForTeams,
MappedDeclsFields);
}
public:
CheckVarsEscapingDeclContext(CodeGenFunction &CGF,
ArrayRef<const ValueDecl *> TeamsReductions)
: CGF(CGF), EscapedDecls(TeamsReductions.begin(), TeamsReductions.end()) {
}
virtual ~CheckVarsEscapingDeclContext() = default;
void VisitDeclStmt(const DeclStmt *S) {
if (!S)
return;
for (const Decl *D : S->decls())
if (const auto *VD = dyn_cast_or_null<ValueDecl>(D))
VisitValueDecl(VD);
}
void VisitOMPExecutableDirective(const OMPExecutableDirective *D) {
if (!D)
return;
if (!D->hasAssociatedStmt())
return;
if (const auto *S =
dyn_cast_or_null<CapturedStmt>(D->getAssociatedStmt())) {
// Do not analyze directives that do not actually require capturing,
// like `omp for` or `omp simd` directives.
llvm::SmallVector<OpenMPDirectiveKind, 4> CaptureRegions;
getOpenMPCaptureRegions(CaptureRegions, D->getDirectiveKind());
if (CaptureRegions.size() == 1 && CaptureRegions.back() == OMPD_unknown) {
VisitStmt(S->getCapturedStmt());
return;
}
VisitOpenMPCapturedStmt(
S, D->clauses(),
CaptureRegions.back() == OMPD_parallel &&
isOpenMPDistributeDirective(D->getDirectiveKind()));
}
}
void VisitCapturedStmt(const CapturedStmt *S) {
if (!S)
return;
for (const CapturedStmt::Capture &C : S->captures()) {
if (C.capturesVariable() && !C.capturesVariableByCopy()) {
const ValueDecl *VD = C.getCapturedVar();
markAsEscaped(VD);
if (isa<OMPCapturedExprDecl>(VD))
VisitValueDecl(VD);
}
}
}
void VisitLambdaExpr(const LambdaExpr *E) {
if (!E)
return;
for (const LambdaCapture &C : E->captures()) {
if (C.capturesVariable()) {
if (C.getCaptureKind() == LCK_ByRef) {
const ValueDecl *VD = C.getCapturedVar();
markAsEscaped(VD);
if (E->isInitCapture(&C) || isa<OMPCapturedExprDecl>(VD))
VisitValueDecl(VD);
}
}
}
}
void VisitBlockExpr(const BlockExpr *E) {
if (!E)
return;
for (const BlockDecl::Capture &C : E->getBlockDecl()->captures()) {
if (C.isByRef()) {
const VarDecl *VD = C.getVariable();
markAsEscaped(VD);
if (isa<OMPCapturedExprDecl>(VD) || VD->isInitCapture())
VisitValueDecl(VD);
}
}
}
void VisitCallExpr(const CallExpr *E) {
if (!E)
return;
for (const Expr *Arg : E->arguments()) {
if (!Arg)
continue;
if (Arg->isLValue()) {
const bool SavedAllEscaped = AllEscaped;
AllEscaped = true;
Visit(Arg);
AllEscaped = SavedAllEscaped;
} else {
Visit(Arg);
}
}
Visit(E->getCallee());
}
void VisitDeclRefExpr(const DeclRefExpr *E) {
if (!E)
return;
const ValueDecl *VD = E->getDecl();
if (AllEscaped)
markAsEscaped(VD);
if (isa<OMPCapturedExprDecl>(VD))
VisitValueDecl(VD);
else if (const auto *VarD = dyn_cast<VarDecl>(VD))
if (VarD->isInitCapture())
VisitValueDecl(VD);
}
void VisitUnaryOperator(const UnaryOperator *E) {
if (!E)
return;
if (E->getOpcode() == UO_AddrOf) {
const bool SavedAllEscaped = AllEscaped;
AllEscaped = true;
Visit(E->getSubExpr());
AllEscaped = SavedAllEscaped;
} else {
Visit(E->getSubExpr());
}
}
void VisitImplicitCastExpr(const ImplicitCastExpr *E) {
if (!E)
return;
if (E->getCastKind() == CK_ArrayToPointerDecay) {
const bool SavedAllEscaped = AllEscaped;
AllEscaped = true;
Visit(E->getSubExpr());
AllEscaped = SavedAllEscaped;
} else {
Visit(E->getSubExpr());
}
}
void VisitExpr(const Expr *E) {
if (!E)
return;
bool SavedAllEscaped = AllEscaped;
if (!E->isLValue())
AllEscaped = false;
for (const Stmt *Child : E->children())
if (Child)
Visit(Child);
AllEscaped = SavedAllEscaped;
}
void VisitStmt(const Stmt *S) {
if (!S)
return;
for (const Stmt *Child : S->children())
if (Child)
Visit(Child);
}
/// Returns the record that handles all the escaped local variables and used
/// instead of their original storage.
const RecordDecl *getGlobalizedRecord(bool IsInTTDRegion) {
if (!GlobalizedRD)
buildRecordForGlobalizedVars(IsInTTDRegion);
return GlobalizedRD;
}
/// Returns the field in the globalized record for the escaped variable.
const FieldDecl *getFieldForGlobalizedVar(const ValueDecl *VD) const {
assert(GlobalizedRD &&
"Record for globalized variables must be generated already.");
auto I = MappedDeclsFields.find(VD);
if (I == MappedDeclsFields.end())
return nullptr;
return I->getSecond();
}
/// Returns the list of the escaped local variables/parameters.
ArrayRef<const ValueDecl *> getEscapedDecls() const {
return EscapedDecls.getArrayRef();
}
/// Checks if the escaped local variable is actually a parameter passed by
/// value.
const llvm::SmallPtrSetImpl<const Decl *> &getEscapedParameters() const {
return EscapedParameters;
}
/// Returns the list of the escaped variables with the variably modified
/// types.
ArrayRef<const ValueDecl *> getEscapedVariableLengthDecls() const {
return EscapedVariableLengthDecls.getArrayRef();
}
};
} // anonymous namespace
/// Get the GPU warp size.
static llvm::Value *getNVPTXWarpSize(CodeGenFunction &CGF) {
return CGF.EmitRuntimeCall(
llvm::Intrinsic::getDeclaration(
&CGF.CGM.getModule(), llvm::Intrinsic::nvvm_read_ptx_sreg_warpsize),
"nvptx_warp_size");
}
/// Get the id of the current thread on the GPU.
static llvm::Value *getNVPTXThreadID(CodeGenFunction &CGF) {
return CGF.EmitRuntimeCall(
llvm::Intrinsic::getDeclaration(
&CGF.CGM.getModule(), llvm::Intrinsic::nvvm_read_ptx_sreg_tid_x),
"nvptx_tid");
}
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
/// Get the id of the warp in the block.
/// We assume that the warp size is 32, which is always the case
/// on the NVPTX device, to generate more efficient code.
static llvm::Value *getNVPTXWarpID(CodeGenFunction &CGF) {
CGBuilderTy &Bld = CGF.Builder;
return Bld.CreateAShr(getNVPTXThreadID(CGF), LaneIDBits, "nvptx_warp_id");
}
/// Get the id of the current lane in the Warp.
/// We assume that the warp size is 32, which is always the case
/// on the NVPTX device, to generate more efficient code.
static llvm::Value *getNVPTXLaneID(CodeGenFunction &CGF) {
CGBuilderTy &Bld = CGF.Builder;
return Bld.CreateAnd(getNVPTXThreadID(CGF), Bld.getInt32(LaneIDMask),
"nvptx_lane_id");
}
/// Get the maximum number of threads in a block of the GPU.
static llvm::Value *getNVPTXNumThreads(CodeGenFunction &CGF) {
return CGF.EmitRuntimeCall(
llvm::Intrinsic::getDeclaration(
&CGF.CGM.getModule(), llvm::Intrinsic::nvvm_read_ptx_sreg_ntid_x),
"nvptx_num_threads");
}
/// Get barrier to synchronize all threads in a block.
static void getNVPTXCTABarrier(CodeGenFunction &CGF) {
llvm::Function *F = llvm::Intrinsic::getDeclaration(
&CGF.CGM.getModule(), llvm::Intrinsic::nvvm_barrier0);
F->addFnAttr(llvm::Attribute::Convergent);
CGF.EmitRuntimeCall(F);
}
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
/// Get barrier #ID to synchronize selected (multiple of warp size) threads in
/// a CTA.
static void getNVPTXBarrier(CodeGenFunction &CGF, int ID,
llvm::Value *NumThreads) {
CGBuilderTy &Bld = CGF.Builder;
llvm::Value *Args[] = {Bld.getInt32(ID), NumThreads};
llvm::Function *F = llvm::Intrinsic::getDeclaration(
&CGF.CGM.getModule(), llvm::Intrinsic::nvvm_barrier);
F->addFnAttr(llvm::Attribute::Convergent);
CGF.EmitRuntimeCall(F, Args);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
}
/// Synchronize all GPU threads in a block.
static void syncCTAThreads(CodeGenFunction &CGF) { getNVPTXCTABarrier(CGF); }
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
/// Synchronize worker threads in a parallel region.
static void syncParallelThreads(CodeGenFunction &CGF, llvm::Value *NumThreads) {
return getNVPTXBarrier(CGF, NB_Parallel, NumThreads);
}
/// Get the value of the thread_limit clause in the teams directive.
/// For the 'generic' execution mode, the runtime encodes thread_limit in
/// the launch parameters, always starting thread_limit+warpSize threads per
/// CTA. The threads in the last warp are reserved for master execution.
/// For the 'spmd' execution mode, all threads in a CTA are part of the team.
static llvm::Value *getThreadLimit(CodeGenFunction &CGF,
bool IsInSPMDExecutionMode = false) {
CGBuilderTy &Bld = CGF.Builder;
return IsInSPMDExecutionMode
? getNVPTXNumThreads(CGF)
: Bld.CreateNUWSub(getNVPTXNumThreads(CGF), getNVPTXWarpSize(CGF),
"thread_limit");
}
/// Get the thread id of the OMP master thread.
/// The master thread id is the first thread (lane) of the last warp in the
/// GPU block. Warp size is assumed to be some power of 2.
/// Thread id is 0 indexed.
/// E.g: If NumThreads is 33, master id is 32.
/// If NumThreads is 64, master id is 32.
/// If NumThreads is 1024, master id is 992.
static llvm::Value *getMasterThreadID(CodeGenFunction &CGF) {
CGBuilderTy &Bld = CGF.Builder;
llvm::Value *NumThreads = getNVPTXNumThreads(CGF);
// We assume that the warp size is a power of 2.
llvm::Value *Mask = Bld.CreateNUWSub(getNVPTXWarpSize(CGF), Bld.getInt32(1));
return Bld.CreateAnd(Bld.CreateNUWSub(NumThreads, Bld.getInt32(1)),
Bld.CreateNot(Mask), "master_tid");
}
CGOpenMPRuntimeNVPTX::WorkerFunctionState::WorkerFunctionState(
CodeGenModule &CGM, SourceLocation Loc)
: WorkerFn(nullptr), CGFI(CGM.getTypes().arrangeNullaryFunction()),
Loc(Loc) {
createWorkerFunction(CGM);
}
void CGOpenMPRuntimeNVPTX::WorkerFunctionState::createWorkerFunction(
CodeGenModule &CGM) {
// Create an worker function with no arguments.
WorkerFn = llvm::Function::Create(
CGM.getTypes().GetFunctionType(CGFI), llvm::GlobalValue::InternalLinkage,
/*placeholder=*/"_worker", &CGM.getModule());
CGM.SetInternalFunctionAttributes(GlobalDecl(), WorkerFn, CGFI);
WorkerFn->setDoesNotRecurse();
}
CGOpenMPRuntimeNVPTX::ExecutionMode
CGOpenMPRuntimeNVPTX::getExecutionMode() const {
return CurrentExecutionMode;
}
static CGOpenMPRuntimeNVPTX::DataSharingMode
getDataSharingMode(CodeGenModule &CGM) {
return CGM.getLangOpts().OpenMPCUDAMode ? CGOpenMPRuntimeNVPTX::CUDA
: CGOpenMPRuntimeNVPTX::Generic;
}
// Checks if the expression is constant or does not have non-trivial function
// calls.
static bool isTrivial(ASTContext &Ctx, const Expr * E) {
// We can skip constant expressions.
// We can skip expressions with trivial calls or simple expressions.
return (E->isEvaluatable(Ctx, Expr::SE_AllowUndefinedBehavior) ||
!E->hasNonTrivialCall(Ctx)) &&
!E->HasSideEffects(Ctx, /*IncludePossibleEffects=*/true);
}
/// Checks if the \p Body is the \a CompoundStmt and returns its child statement
/// iff there is only one that is not evaluatable at the compile time.
static const Stmt *getSingleCompoundChild(ASTContext &Ctx, const Stmt *Body) {
if (const auto *C = dyn_cast<CompoundStmt>(Body)) {
const Stmt *Child = nullptr;
for (const Stmt *S : C->body()) {
if (const auto *E = dyn_cast<Expr>(S)) {
if (isTrivial(Ctx, E))
continue;
}
// Some of the statements can be ignored.
if (isa<AsmStmt>(S) || isa<NullStmt>(S) || isa<OMPFlushDirective>(S) ||
isa<OMPBarrierDirective>(S) || isa<OMPTaskyieldDirective>(S))
continue;
// Analyze declarations.
if (const auto *DS = dyn_cast<DeclStmt>(S)) {
if (llvm::all_of(DS->decls(), [&Ctx](const Decl *D) {
if (isa<EmptyDecl>(D) || isa<DeclContext>(D) ||
isa<TypeDecl>(D) || isa<PragmaCommentDecl>(D) ||
isa<PragmaDetectMismatchDecl>(D) || isa<UsingDecl>(D) ||
isa<UsingDirectiveDecl>(D) ||
isa<OMPDeclareReductionDecl>(D) ||
isa<OMPThreadPrivateDecl>(D))
return true;
const auto *VD = dyn_cast<VarDecl>(D);
if (!VD)
return false;
return VD->isConstexpr() ||
((VD->getType().isTrivialType(Ctx) ||
VD->getType()->isReferenceType()) &&
(!VD->hasInit() || isTrivial(Ctx, VD->getInit())));
}))
continue;
}
// Found multiple children - cannot get the one child only.
if (Child)
return Body;
Child = S;
}
if (Child)
return Child;
}
return Body;
}
/// Check if the parallel directive has an 'if' clause with non-constant or
/// false condition. Also, check if the number of threads is strictly specified
/// and run those directives in non-SPMD mode.
static bool hasParallelIfNumThreadsClause(ASTContext &Ctx,
const OMPExecutableDirective &D) {
if (D.hasClausesOfKind<OMPNumThreadsClause>())
return true;
for (const auto *C : D.getClausesOfKind<OMPIfClause>()) {
OpenMPDirectiveKind NameModifier = C->getNameModifier();
if (NameModifier != OMPD_parallel && NameModifier != OMPD_unknown)
continue;
const Expr *Cond = C->getCondition();
bool Result;
if (!Cond->EvaluateAsBooleanCondition(Result, Ctx) || !Result)
return true;
}
return false;
}
/// Check for inner (nested) SPMD construct, if any
static bool hasNestedSPMDDirective(ASTContext &Ctx,
const OMPExecutableDirective &D) {
const auto *CS = D.getInnermostCapturedStmt();
const auto *Body =
CS->getCapturedStmt()->IgnoreContainers(/*IgnoreCaptured=*/true);
const Stmt *ChildStmt = getSingleCompoundChild(Ctx, Body);
if (const auto *NestedDir = dyn_cast<OMPExecutableDirective>(ChildStmt)) {
OpenMPDirectiveKind DKind = NestedDir->getDirectiveKind();
switch (D.getDirectiveKind()) {
case OMPD_target:
if (isOpenMPParallelDirective(DKind) &&
!hasParallelIfNumThreadsClause(Ctx, *NestedDir))
return true;
if (DKind == OMPD_teams) {
Body = NestedDir->getInnermostCapturedStmt()->IgnoreContainers(
/*IgnoreCaptured=*/true);
if (!Body)
return false;
ChildStmt = getSingleCompoundChild(Ctx, Body);
if (const auto *NND = dyn_cast<OMPExecutableDirective>(ChildStmt)) {
DKind = NND->getDirectiveKind();
if (isOpenMPParallelDirective(DKind) &&
!hasParallelIfNumThreadsClause(Ctx, *NND))
return true;
}
}
return false;
case OMPD_target_teams:
return isOpenMPParallelDirective(DKind) &&
!hasParallelIfNumThreadsClause(Ctx, *NestedDir);
case OMPD_target_simd:
case OMPD_target_parallel:
case OMPD_target_parallel_for:
case OMPD_target_parallel_for_simd:
case OMPD_target_teams_distribute:
case OMPD_target_teams_distribute_simd:
case OMPD_target_teams_distribute_parallel_for:
case OMPD_target_teams_distribute_parallel_for_simd:
case OMPD_parallel:
case OMPD_for:
case OMPD_parallel_for:
case OMPD_parallel_sections:
case OMPD_for_simd:
case OMPD_parallel_for_simd:
case OMPD_cancel:
case OMPD_cancellation_point:
case OMPD_ordered:
case OMPD_threadprivate:
case OMPD_task:
case OMPD_simd:
case OMPD_sections:
case OMPD_section:
case OMPD_single:
case OMPD_master:
case OMPD_critical:
case OMPD_taskyield:
case OMPD_barrier:
case OMPD_taskwait:
case OMPD_taskgroup:
case OMPD_atomic:
case OMPD_flush:
case OMPD_teams:
case OMPD_target_data:
case OMPD_target_exit_data:
case OMPD_target_enter_data:
case OMPD_distribute:
case OMPD_distribute_simd:
case OMPD_distribute_parallel_for:
case OMPD_distribute_parallel_for_simd:
case OMPD_teams_distribute:
case OMPD_teams_distribute_simd:
case OMPD_teams_distribute_parallel_for:
case OMPD_teams_distribute_parallel_for_simd:
case OMPD_target_update:
case OMPD_declare_simd:
case OMPD_declare_target:
case OMPD_end_declare_target:
case OMPD_declare_reduction:
case OMPD_taskloop:
case OMPD_taskloop_simd:
case OMPD_requires:
case OMPD_unknown:
llvm_unreachable("Unexpected directive.");
}
}
return false;
}
static bool supportsSPMDExecutionMode(ASTContext &Ctx,
const OMPExecutableDirective &D) {
OpenMPDirectiveKind DirectiveKind = D.getDirectiveKind();
switch (DirectiveKind) {
case OMPD_target:
case OMPD_target_teams:
return hasNestedSPMDDirective(Ctx, D);
case OMPD_target_parallel:
case OMPD_target_parallel_for:
case OMPD_target_parallel_for_simd:
case OMPD_target_teams_distribute_parallel_for:
case OMPD_target_teams_distribute_parallel_for_simd:
return !hasParallelIfNumThreadsClause(Ctx, D);
case OMPD_target_simd:
case OMPD_target_teams_distribute:
case OMPD_target_teams_distribute_simd:
return false;
case OMPD_parallel:
case OMPD_for:
case OMPD_parallel_for:
case OMPD_parallel_sections:
case OMPD_for_simd:
case OMPD_parallel_for_simd:
case OMPD_cancel:
case OMPD_cancellation_point:
case OMPD_ordered:
case OMPD_threadprivate:
case OMPD_task:
case OMPD_simd:
case OMPD_sections:
case OMPD_section:
case OMPD_single:
case OMPD_master:
case OMPD_critical:
case OMPD_taskyield:
case OMPD_barrier:
case OMPD_taskwait:
case OMPD_taskgroup:
case OMPD_atomic:
case OMPD_flush:
case OMPD_teams:
case OMPD_target_data:
case OMPD_target_exit_data:
case OMPD_target_enter_data:
case OMPD_distribute:
case OMPD_distribute_simd:
case OMPD_distribute_parallel_for:
case OMPD_distribute_parallel_for_simd:
case OMPD_teams_distribute:
case OMPD_teams_distribute_simd:
case OMPD_teams_distribute_parallel_for:
case OMPD_teams_distribute_parallel_for_simd:
case OMPD_target_update:
case OMPD_declare_simd:
case OMPD_declare_target:
case OMPD_end_declare_target:
case OMPD_declare_reduction:
case OMPD_taskloop:
case OMPD_taskloop_simd:
case OMPD_requires:
case OMPD_unknown:
break;
}
llvm_unreachable(
"Unknown programming model for OpenMP directive on NVPTX target.");
}
/// Check if the directive is loops based and has schedule clause at all or has
/// static scheduling.
static bool hasStaticScheduling(const OMPExecutableDirective &D) {
assert(isOpenMPWorksharingDirective(D.getDirectiveKind()) &&
isOpenMPLoopDirective(D.getDirectiveKind()) &&
"Expected loop-based directive.");
return !D.hasClausesOfKind<OMPOrderedClause>() &&
(!D.hasClausesOfKind<OMPScheduleClause>() ||
llvm::any_of(D.getClausesOfKind<OMPScheduleClause>(),
[](const OMPScheduleClause *C) {
return C->getScheduleKind() == OMPC_SCHEDULE_static;
}));
}
/// Check for inner (nested) lightweight runtime construct, if any
static bool hasNestedLightweightDirective(ASTContext &Ctx,
const OMPExecutableDirective &D) {
assert(supportsSPMDExecutionMode(Ctx, D) && "Expected SPMD mode directive.");
const auto *CS = D.getInnermostCapturedStmt();
const auto *Body =
CS->getCapturedStmt()->IgnoreContainers(/*IgnoreCaptured=*/true);
const Stmt *ChildStmt = getSingleCompoundChild(Ctx, Body);
if (const auto *NestedDir = dyn_cast<OMPExecutableDirective>(ChildStmt)) {
OpenMPDirectiveKind DKind = NestedDir->getDirectiveKind();
switch (D.getDirectiveKind()) {
case OMPD_target:
if (isOpenMPParallelDirective(DKind) &&
isOpenMPWorksharingDirective(DKind) && isOpenMPLoopDirective(DKind) &&
hasStaticScheduling(*NestedDir))
return true;
if (DKind == OMPD_parallel) {
Body = NestedDir->getInnermostCapturedStmt()->IgnoreContainers(
/*IgnoreCaptured=*/true);
if (!Body)
return false;
ChildStmt = getSingleCompoundChild(Ctx, Body);
if (const auto *NND = dyn_cast<OMPExecutableDirective>(ChildStmt)) {
DKind = NND->getDirectiveKind();
if (isOpenMPWorksharingDirective(DKind) &&
isOpenMPLoopDirective(DKind) && hasStaticScheduling(*NND))
return true;
}
} else if (DKind == OMPD_teams) {
Body = NestedDir->getInnermostCapturedStmt()->IgnoreContainers(
/*IgnoreCaptured=*/true);
if (!Body)
return false;
ChildStmt = getSingleCompoundChild(Ctx, Body);
if (const auto *NND = dyn_cast<OMPExecutableDirective>(ChildStmt)) {
DKind = NND->getDirectiveKind();
if (isOpenMPParallelDirective(DKind) &&
isOpenMPWorksharingDirective(DKind) &&
isOpenMPLoopDirective(DKind) && hasStaticScheduling(*NND))
return true;
if (DKind == OMPD_parallel) {
Body = NND->getInnermostCapturedStmt()->IgnoreContainers(
/*IgnoreCaptured=*/true);
if (!Body)
return false;
ChildStmt = getSingleCompoundChild(Ctx, Body);
if (const auto *NND = dyn_cast<OMPExecutableDirective>(ChildStmt)) {
DKind = NND->getDirectiveKind();
if (isOpenMPWorksharingDirective(DKind) &&
isOpenMPLoopDirective(DKind) && hasStaticScheduling(*NND))
return true;
}
}
}
}
return false;
case OMPD_target_teams:
if (isOpenMPParallelDirective(DKind) &&
isOpenMPWorksharingDirective(DKind) && isOpenMPLoopDirective(DKind) &&
hasStaticScheduling(*NestedDir))
return true;
if (DKind == OMPD_parallel) {
Body = NestedDir->getInnermostCapturedStmt()->IgnoreContainers(
/*IgnoreCaptured=*/true);
if (!Body)
return false;
ChildStmt = getSingleCompoundChild(Ctx, Body);
if (const auto *NND = dyn_cast<OMPExecutableDirective>(ChildStmt)) {
DKind = NND->getDirectiveKind();
if (isOpenMPWorksharingDirective(DKind) &&
isOpenMPLoopDirective(DKind) && hasStaticScheduling(*NND))
return true;
}
}
return false;
case OMPD_target_parallel:
return isOpenMPWorksharingDirective(DKind) &&
isOpenMPLoopDirective(DKind) && hasStaticScheduling(*NestedDir);
case OMPD_target_teams_distribute:
case OMPD_target_simd:
case OMPD_target_parallel_for:
case OMPD_target_parallel_for_simd:
case OMPD_target_teams_distribute_simd:
case OMPD_target_teams_distribute_parallel_for:
case OMPD_target_teams_distribute_parallel_for_simd:
case OMPD_parallel:
case OMPD_for:
case OMPD_parallel_for:
case OMPD_parallel_sections:
case OMPD_for_simd:
case OMPD_parallel_for_simd:
case OMPD_cancel:
case OMPD_cancellation_point:
case OMPD_ordered:
case OMPD_threadprivate:
case OMPD_task:
case OMPD_simd:
case OMPD_sections:
case OMPD_section:
case OMPD_single:
case OMPD_master:
case OMPD_critical:
case OMPD_taskyield:
case OMPD_barrier:
case OMPD_taskwait:
case OMPD_taskgroup:
case OMPD_atomic:
case OMPD_flush:
case OMPD_teams:
case OMPD_target_data:
case OMPD_target_exit_data:
case OMPD_target_enter_data:
case OMPD_distribute:
case OMPD_distribute_simd:
case OMPD_distribute_parallel_for:
case OMPD_distribute_parallel_for_simd:
case OMPD_teams_distribute:
case OMPD_teams_distribute_simd:
case OMPD_teams_distribute_parallel_for:
case OMPD_teams_distribute_parallel_for_simd:
case OMPD_target_update:
case OMPD_declare_simd:
case OMPD_declare_target:
case OMPD_end_declare_target:
case OMPD_declare_reduction:
case OMPD_taskloop:
case OMPD_taskloop_simd:
case OMPD_requires:
case OMPD_unknown:
llvm_unreachable("Unexpected directive.");
}
}
return false;
}
/// Checks if the construct supports lightweight runtime. It must be SPMD
/// construct + inner loop-based construct with static scheduling.
static bool supportsLightweightRuntime(ASTContext &Ctx,
const OMPExecutableDirective &D) {
if (!supportsSPMDExecutionMode(Ctx, D))
return false;
OpenMPDirectiveKind DirectiveKind = D.getDirectiveKind();
switch (DirectiveKind) {
case OMPD_target:
case OMPD_target_teams:
case OMPD_target_parallel:
return hasNestedLightweightDirective(Ctx, D);
case OMPD_target_parallel_for:
case OMPD_target_parallel_for_simd:
case OMPD_target_teams_distribute_parallel_for:
case OMPD_target_teams_distribute_parallel_for_simd:
// (Last|First)-privates must be shared in parallel region.
return hasStaticScheduling(D);
case OMPD_target_simd:
case OMPD_target_teams_distribute:
case OMPD_target_teams_distribute_simd:
return false;
case OMPD_parallel:
case OMPD_for:
case OMPD_parallel_for:
case OMPD_parallel_sections:
case OMPD_for_simd:
case OMPD_parallel_for_simd:
case OMPD_cancel:
case OMPD_cancellation_point:
case OMPD_ordered:
case OMPD_threadprivate:
case OMPD_task:
case OMPD_simd:
case OMPD_sections:
case OMPD_section:
case OMPD_single:
case OMPD_master:
case OMPD_critical:
case OMPD_taskyield:
case OMPD_barrier:
case OMPD_taskwait:
case OMPD_taskgroup:
case OMPD_atomic:
case OMPD_flush:
case OMPD_teams:
case OMPD_target_data:
case OMPD_target_exit_data:
case OMPD_target_enter_data:
case OMPD_distribute:
case OMPD_distribute_simd:
case OMPD_distribute_parallel_for:
case OMPD_distribute_parallel_for_simd:
case OMPD_teams_distribute:
case OMPD_teams_distribute_simd:
case OMPD_teams_distribute_parallel_for:
case OMPD_teams_distribute_parallel_for_simd:
case OMPD_target_update:
case OMPD_declare_simd:
case OMPD_declare_target:
case OMPD_end_declare_target:
case OMPD_declare_reduction:
case OMPD_taskloop:
case OMPD_taskloop_simd:
case OMPD_requires:
case OMPD_unknown:
break;
}
llvm_unreachable(
"Unknown programming model for OpenMP directive on NVPTX target.");
}
void CGOpenMPRuntimeNVPTX::emitNonSPMDKernel(const OMPExecutableDirective &D,
StringRef ParentName,
llvm::Function *&OutlinedFn,
llvm::Constant *&OutlinedFnID,
bool IsOffloadEntry,
const RegionCodeGenTy &CodeGen) {
ExecutionRuntimeModesRAII ModeRAII(CurrentExecutionMode);
EntryFunctionState EST;
WorkerFunctionState WST(CGM, D.getBeginLoc());
Work.clear();
WrapperFunctionsMap.clear();
// Emit target region as a standalone region.
class NVPTXPrePostActionTy : public PrePostActionTy {
CGOpenMPRuntimeNVPTX::EntryFunctionState &EST;
CGOpenMPRuntimeNVPTX::WorkerFunctionState &WST;
public:
NVPTXPrePostActionTy(CGOpenMPRuntimeNVPTX::EntryFunctionState &EST,
CGOpenMPRuntimeNVPTX::WorkerFunctionState &WST)
: EST(EST), WST(WST) {}
void Enter(CodeGenFunction &CGF) override {
auto &RT =
static_cast<CGOpenMPRuntimeNVPTX &>(CGF.CGM.getOpenMPRuntime());
RT.emitNonSPMDEntryHeader(CGF, EST, WST);
// Skip target region initialization.
RT.setLocThreadIdInsertPt(CGF, /*AtCurrentPoint=*/true);
}
void Exit(CodeGenFunction &CGF) override {
auto &RT =
static_cast<CGOpenMPRuntimeNVPTX &>(CGF.CGM.getOpenMPRuntime());
RT.clearLocThreadIdInsertPt(CGF);
RT.emitNonSPMDEntryFooter(CGF, EST);
}
} Action(EST, WST);
CodeGen.setAction(Action);
IsInTTDRegion = true;
// Reserve place for the globalized memory.
GlobalizedRecords.emplace_back();
if (!KernelStaticGlobalized) {
KernelStaticGlobalized = new llvm::GlobalVariable(
CGM.getModule(), CGM.VoidPtrTy, /*isConstant=*/false,
llvm::GlobalValue::InternalLinkage,
llvm::ConstantPointerNull::get(CGM.VoidPtrTy),
"_openmp_kernel_static_glob_rd$ptr", /*InsertBefore=*/nullptr,
llvm::GlobalValue::NotThreadLocal,
CGM.getContext().getTargetAddressSpace(LangAS::cuda_shared));
}
emitTargetOutlinedFunctionHelper(D, ParentName, OutlinedFn, OutlinedFnID,
IsOffloadEntry, CodeGen);
IsInTTDRegion = false;
// Now change the name of the worker function to correspond to this target
// region's entry function.
WST.WorkerFn->setName(Twine(OutlinedFn->getName(), "_worker"));
// Create the worker function
emitWorkerFunction(WST);
}
// Setup NVPTX threads for master-worker OpenMP scheme.
void CGOpenMPRuntimeNVPTX::emitNonSPMDEntryHeader(CodeGenFunction &CGF,
EntryFunctionState &EST,
WorkerFunctionState &WST) {
CGBuilderTy &Bld = CGF.Builder;
llvm::BasicBlock *WorkerBB = CGF.createBasicBlock(".worker");
llvm::BasicBlock *MasterCheckBB = CGF.createBasicBlock(".mastercheck");
llvm::BasicBlock *MasterBB = CGF.createBasicBlock(".master");
EST.ExitBB = CGF.createBasicBlock(".exit");
llvm::Value *IsWorker =
Bld.CreateICmpULT(getNVPTXThreadID(CGF), getThreadLimit(CGF));
Bld.CreateCondBr(IsWorker, WorkerBB, MasterCheckBB);
CGF.EmitBlock(WorkerBB);
emitCall(CGF, WST.Loc, WST.WorkerFn);
CGF.EmitBranch(EST.ExitBB);
CGF.EmitBlock(MasterCheckBB);
llvm::Value *IsMaster =
Bld.CreateICmpEQ(getNVPTXThreadID(CGF), getMasterThreadID(CGF));
Bld.CreateCondBr(IsMaster, MasterBB, EST.ExitBB);
CGF.EmitBlock(MasterBB);
IsInTargetMasterThreadRegion = true;
// SEQUENTIAL (MASTER) REGION START
// First action in sequential region:
// Initialize the state of the OpenMP runtime library on the GPU.
// TODO: Optimize runtime initialization and pass in correct value.
llvm::Value *Args[] = {getThreadLimit(CGF),
Bld.getInt16(/*RequiresOMPRuntime=*/1)};
CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_kernel_init), Args);
// For data sharing, we need to initialize the stack.
CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(
OMPRTL_NVPTX__kmpc_data_sharing_init_stack));
emitGenericVarsProlog(CGF, WST.Loc);
}
void CGOpenMPRuntimeNVPTX::emitNonSPMDEntryFooter(CodeGenFunction &CGF,
EntryFunctionState &EST) {
IsInTargetMasterThreadRegion = false;
if (!CGF.HaveInsertPoint())
return;
emitGenericVarsEpilog(CGF);
if (!EST.ExitBB)
EST.ExitBB = CGF.createBasicBlock(".exit");
llvm::BasicBlock *TerminateBB = CGF.createBasicBlock(".termination.notifier");
CGF.EmitBranch(TerminateBB);
CGF.EmitBlock(TerminateBB);
// Signal termination condition.
// TODO: Optimize runtime initialization and pass in correct value.
llvm::Value *Args[] = {CGF.Builder.getInt16(/*IsOMPRuntimeInitialized=*/1)};
CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_kernel_deinit), Args);
// Barrier to terminate worker threads.
syncCTAThreads(CGF);
// Master thread jumps to exit point.
CGF.EmitBranch(EST.ExitBB);
CGF.EmitBlock(EST.ExitBB);
EST.ExitBB = nullptr;
}
void CGOpenMPRuntimeNVPTX::emitSPMDKernel(const OMPExecutableDirective &D,
StringRef ParentName,
llvm::Function *&OutlinedFn,
llvm::Constant *&OutlinedFnID,
bool IsOffloadEntry,
const RegionCodeGenTy &CodeGen) {
ExecutionRuntimeModesRAII ModeRAII(
CurrentExecutionMode, RequiresFullRuntime,
CGM.getLangOpts().OpenMPCUDAForceFullRuntime ||
!supportsLightweightRuntime(CGM.getContext(), D));
EntryFunctionState EST;
// Emit target region as a standalone region.
class NVPTXPrePostActionTy : public PrePostActionTy {
CGOpenMPRuntimeNVPTX &RT;
CGOpenMPRuntimeNVPTX::EntryFunctionState &EST;
const OMPExecutableDirective &D;
public:
NVPTXPrePostActionTy(CGOpenMPRuntimeNVPTX &RT,
CGOpenMPRuntimeNVPTX::EntryFunctionState &EST,
const OMPExecutableDirective &D)
: RT(RT), EST(EST), D(D) {}
void Enter(CodeGenFunction &CGF) override {
RT.emitSPMDEntryHeader(CGF, EST, D);
// Skip target region initialization.
RT.setLocThreadIdInsertPt(CGF, /*AtCurrentPoint=*/true);
}
void Exit(CodeGenFunction &CGF) override {
RT.clearLocThreadIdInsertPt(CGF);
RT.emitSPMDEntryFooter(CGF, EST);
}
} Action(*this, EST, D);
CodeGen.setAction(Action);
IsInTTDRegion = true;
// Reserve place for the globalized memory.
GlobalizedRecords.emplace_back();
if (!KernelStaticGlobalized) {
KernelStaticGlobalized = new llvm::GlobalVariable(
CGM.getModule(), CGM.VoidPtrTy, /*isConstant=*/false,
llvm::GlobalValue::InternalLinkage,
llvm::ConstantPointerNull::get(CGM.VoidPtrTy),
"_openmp_kernel_static_glob_rd$ptr", /*InsertBefore=*/nullptr,
llvm::GlobalValue::NotThreadLocal,
CGM.getContext().getTargetAddressSpace(LangAS::cuda_shared));
}
emitTargetOutlinedFunctionHelper(D, ParentName, OutlinedFn, OutlinedFnID,
IsOffloadEntry, CodeGen);
IsInTTDRegion = false;
}
void CGOpenMPRuntimeNVPTX::emitSPMDEntryHeader(
CodeGenFunction &CGF, EntryFunctionState &EST,
const OMPExecutableDirective &D) {
CGBuilderTy &Bld = CGF.Builder;
// Setup BBs in entry function.
llvm::BasicBlock *ExecuteBB = CGF.createBasicBlock(".execute");
EST.ExitBB = CGF.createBasicBlock(".exit");
llvm::Value *Args[] = {getThreadLimit(CGF, /*IsInSPMDExecutionMode=*/true),
/*RequiresOMPRuntime=*/
Bld.getInt16(RequiresFullRuntime ? 1 : 0),
/*RequiresDataSharing=*/Bld.getInt16(0)};
CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_spmd_kernel_init), Args);
if (RequiresFullRuntime) {
// For data sharing, we need to initialize the stack.
CGF.EmitRuntimeCall(createNVPTXRuntimeFunction(
OMPRTL_NVPTX__kmpc_data_sharing_init_stack_spmd));
}
CGF.EmitBranch(ExecuteBB);
CGF.EmitBlock(ExecuteBB);
IsInTargetMasterThreadRegion = true;
}
void CGOpenMPRuntimeNVPTX::emitSPMDEntryFooter(CodeGenFunction &CGF,
EntryFunctionState &EST) {
IsInTargetMasterThreadRegion = false;
if (!CGF.HaveInsertPoint())
return;
if (!EST.ExitBB)
EST.ExitBB = CGF.createBasicBlock(".exit");
llvm::BasicBlock *OMPDeInitBB = CGF.createBasicBlock(".omp.deinit");
CGF.EmitBranch(OMPDeInitBB);
CGF.EmitBlock(OMPDeInitBB);
// DeInitialize the OMP state in the runtime; called by all active threads.
CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_spmd_kernel_deinit), None);
CGF.EmitBranch(EST.ExitBB);
CGF.EmitBlock(EST.ExitBB);
EST.ExitBB = nullptr;
}
// Create a unique global variable to indicate the execution mode of this target
// region. The execution mode is either 'generic', or 'spmd' depending on the
// target directive. This variable is picked up by the offload library to setup
// the device appropriately before kernel launch. If the execution mode is
// 'generic', the runtime reserves one warp for the master, otherwise, all
// warps participate in parallel work.
static void setPropertyExecutionMode(CodeGenModule &CGM, StringRef Name,
bool Mode) {
auto *GVMode =
new llvm::GlobalVariable(CGM.getModule(), CGM.Int8Ty, /*isConstant=*/true,
llvm::GlobalValue::WeakAnyLinkage,
llvm::ConstantInt::get(CGM.Int8Ty, Mode ? 0 : 1),
Twine(Name, "_exec_mode"));
CGM.addCompilerUsedGlobal(GVMode);
}
void CGOpenMPRuntimeNVPTX::emitWorkerFunction(WorkerFunctionState &WST) {
[OpenMP] Add implicit data sharing support when offloading to NVIDIA GPUs using OpenMP device offloading Summary: This patch is part of the development effort to add support in the current OpenMP GPU offloading implementation for implicitly sharing variables between a target region executed by the team master thread and the worker threads within that team. This patch is the first of three required for successfully performing the implicit sharing of master thread variables with the worker threads within a team. The remaining two patches are: - Patch D38978 to the LLVM NVPTX backend which ensures the lowering of shared variables to an device memory which allows the sharing of references; - Patch (coming soon) is a patch to libomptarget runtime library which ensures that a list of references to shared variables is properly maintained. A simple code snippet which illustrates an implicit data sharing situation is as follows: ``` #pragma omp target { // master thread only int v; #pragma omp parallel { // worker threads // use v } } ``` Variable v is implicitly shared from the team master thread which executes the code in between the target and parallel directives. The worker threads must operate on the latest version of v, including any updates performed by the master. The code generated in this patch relies on the LLVM NVPTX patch (mentioned above) which prevents v from being lowered in the thread local memory of the master thread thus making the reference to this variable un-shareable with the workers. This ensures that the code generated by this patch is correct. Since the parallel region is outlined the passing of arguments to the outlined regions must preserve the original order of arguments. The runtime therefore maintains a list of references to shared variables thus ensuring their passing in the correct order. The passing of arguments to the outlined parallel function is performed in a separate function which the data sharing infrastructure constructs in this patch. The function is inlined when optimizations are enabled. Reviewers: hfinkel, carlo.bertolli, arpith-jacob, Hahnfeld, ABataev, caomhin Reviewed By: ABataev Subscribers: cfe-commits, jholewinski Differential Revision: https://reviews.llvm.org/D38976 llvm-svn: 318773
2017-11-21 23:54:54 +08:00
ASTContext &Ctx = CGM.getContext();
CodeGenFunction CGF(CGM, /*suppressNewContext=*/true);
CGF.StartFunction(GlobalDecl(), Ctx.VoidTy, WST.WorkerFn, WST.CGFI, {},
WST.Loc, WST.Loc);
emitWorkerLoop(CGF, WST);
CGF.FinishFunction();
}
void CGOpenMPRuntimeNVPTX::emitWorkerLoop(CodeGenFunction &CGF,
WorkerFunctionState &WST) {
//
// The workers enter this loop and wait for parallel work from the master.
// When the master encounters a parallel region it sets up the work + variable
// arguments, and wakes up the workers. The workers first check to see if
// they are required for the parallel region, i.e., within the # of requested
// parallel threads. The activated workers load the variable arguments and
// execute the parallel work.
//
CGBuilderTy &Bld = CGF.Builder;
llvm::BasicBlock *AwaitBB = CGF.createBasicBlock(".await.work");
llvm::BasicBlock *SelectWorkersBB = CGF.createBasicBlock(".select.workers");
llvm::BasicBlock *ExecuteBB = CGF.createBasicBlock(".execute.parallel");
llvm::BasicBlock *TerminateBB = CGF.createBasicBlock(".terminate.parallel");
llvm::BasicBlock *BarrierBB = CGF.createBasicBlock(".barrier.parallel");
llvm::BasicBlock *ExitBB = CGF.createBasicBlock(".exit");
CGF.EmitBranch(AwaitBB);
// Workers wait for work from master.
CGF.EmitBlock(AwaitBB);
// Wait for parallel work
syncCTAThreads(CGF);
Address WorkFn =
CGF.CreateDefaultAlignTempAlloca(CGF.Int8PtrTy, /*Name=*/"work_fn");
Address ExecStatus =
CGF.CreateDefaultAlignTempAlloca(CGF.Int8Ty, /*Name=*/"exec_status");
CGF.InitTempAlloca(ExecStatus, Bld.getInt8(/*C=*/0));
CGF.InitTempAlloca(WorkFn, llvm::Constant::getNullValue(CGF.Int8PtrTy));
// TODO: Optimize runtime initialization and pass in correct value.
llvm::Value *Args[] = {WorkFn.getPointer(),
/*RequiresOMPRuntime=*/Bld.getInt16(1)};
llvm::Value *Ret = CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_kernel_parallel), Args);
Bld.CreateStore(Bld.CreateZExt(Ret, CGF.Int8Ty), ExecStatus);
// On termination condition (workid == 0), exit loop.
llvm::Value *WorkID = Bld.CreateLoad(WorkFn);
llvm::Value *ShouldTerminate = Bld.CreateIsNull(WorkID, "should_terminate");
Bld.CreateCondBr(ShouldTerminate, ExitBB, SelectWorkersBB);
// Activate requested workers.
CGF.EmitBlock(SelectWorkersBB);
llvm::Value *IsActive =
Bld.CreateIsNotNull(Bld.CreateLoad(ExecStatus), "is_active");
Bld.CreateCondBr(IsActive, ExecuteBB, BarrierBB);
// Signal start of parallel region.
CGF.EmitBlock(ExecuteBB);
// Process work items: outlined parallel functions.
for (llvm::Function *W : Work) {
// Try to match this outlined function.
llvm::Value *ID = Bld.CreatePointerBitCastOrAddrSpaceCast(W, CGM.Int8PtrTy);
llvm::Value *WorkFnMatch =
Bld.CreateICmpEQ(Bld.CreateLoad(WorkFn), ID, "work_match");
llvm::BasicBlock *ExecuteFNBB = CGF.createBasicBlock(".execute.fn");
llvm::BasicBlock *CheckNextBB = CGF.createBasicBlock(".check.next");
Bld.CreateCondBr(WorkFnMatch, ExecuteFNBB, CheckNextBB);
// Execute this outlined function.
CGF.EmitBlock(ExecuteFNBB);
// Insert call to work function via shared wrapper. The shared
// wrapper takes two arguments:
// - the parallelism level;
// - the thread ID;
emitCall(CGF, WST.Loc, W,
{Bld.getInt16(/*ParallelLevel=*/0), getThreadID(CGF, WST.Loc)});
// Go to end of parallel region.
CGF.EmitBranch(TerminateBB);
CGF.EmitBlock(CheckNextBB);
}
// Default case: call to outlined function through pointer if the target
// region makes a declare target call that may contain an orphaned parallel
// directive.
auto *ParallelFnTy =
llvm::FunctionType::get(CGM.VoidTy, {CGM.Int16Ty, CGM.Int32Ty},
/*isVarArg=*/false)
->getPointerTo();
llvm::Value *WorkFnCast = Bld.CreateBitCast(WorkID, ParallelFnTy);
// Insert call to work function via shared wrapper. The shared
// wrapper takes two arguments:
// - the parallelism level;
// - the thread ID;
emitCall(CGF, WST.Loc, WorkFnCast,
{Bld.getInt16(/*ParallelLevel=*/0), getThreadID(CGF, WST.Loc)});
// Go to end of parallel region.
CGF.EmitBranch(TerminateBB);
// Signal end of parallel region.
CGF.EmitBlock(TerminateBB);
CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_kernel_end_parallel),
llvm::None);
CGF.EmitBranch(BarrierBB);
// All active and inactive workers wait at a barrier after parallel region.
CGF.EmitBlock(BarrierBB);
// Barrier after parallel region.
syncCTAThreads(CGF);
CGF.EmitBranch(AwaitBB);
// Exit target region.
CGF.EmitBlock(ExitBB);
}
/// Returns specified OpenMP runtime function for the current OpenMP
/// implementation. Specialized for the NVPTX device.
/// \param Function OpenMP runtime function.
/// \return Specified function.
llvm::Constant *
CGOpenMPRuntimeNVPTX::createNVPTXRuntimeFunction(unsigned Function) {
llvm::Constant *RTLFn = nullptr;
switch (static_cast<OpenMPRTLFunctionNVPTX>(Function)) {
case OMPRTL_NVPTX__kmpc_kernel_init: {
// Build void __kmpc_kernel_init(kmp_int32 thread_limit, int16_t
// RequiresOMPRuntime);
llvm::Type *TypeParams[] = {CGM.Int32Ty, CGM.Int16Ty};
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, TypeParams, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_kernel_init");
break;
}
case OMPRTL_NVPTX__kmpc_kernel_deinit: {
// Build void __kmpc_kernel_deinit(int16_t IsOMPRuntimeInitialized);
llvm::Type *TypeParams[] = {CGM.Int16Ty};
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, TypeParams, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_kernel_deinit");
break;
}
case OMPRTL_NVPTX__kmpc_spmd_kernel_init: {
// Build void __kmpc_spmd_kernel_init(kmp_int32 thread_limit,
// int16_t RequiresOMPRuntime, int16_t RequiresDataSharing);
llvm::Type *TypeParams[] = {CGM.Int32Ty, CGM.Int16Ty, CGM.Int16Ty};
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, TypeParams, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_spmd_kernel_init");
break;
}
case OMPRTL_NVPTX__kmpc_spmd_kernel_deinit: {
// Build void __kmpc_spmd_kernel_deinit();
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, llvm::None, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_spmd_kernel_deinit");
break;
}
case OMPRTL_NVPTX__kmpc_kernel_prepare_parallel: {
/// Build void __kmpc_kernel_prepare_parallel(
/// void *outlined_function, int16_t IsOMPRuntimeInitialized);
llvm::Type *TypeParams[] = {CGM.Int8PtrTy, CGM.Int16Ty};
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, TypeParams, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_kernel_prepare_parallel");
break;
}
case OMPRTL_NVPTX__kmpc_kernel_parallel: {
/// Build bool __kmpc_kernel_parallel(void **outlined_function,
/// int16_t IsOMPRuntimeInitialized);
llvm::Type *TypeParams[] = {CGM.Int8PtrPtrTy, CGM.Int16Ty};
llvm::Type *RetTy = CGM.getTypes().ConvertType(CGM.getContext().BoolTy);
auto *FnTy =
llvm::FunctionType::get(RetTy, TypeParams, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_kernel_parallel");
break;
}
case OMPRTL_NVPTX__kmpc_kernel_end_parallel: {
/// Build void __kmpc_kernel_end_parallel();
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, llvm::None, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_kernel_end_parallel");
break;
}
case OMPRTL_NVPTX__kmpc_serialized_parallel: {
// Build void __kmpc_serialized_parallel(ident_t *loc, kmp_int32
// global_tid);
llvm::Type *TypeParams[] = {getIdentTyPointerTy(), CGM.Int32Ty};
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, TypeParams, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_serialized_parallel");
break;
}
case OMPRTL_NVPTX__kmpc_end_serialized_parallel: {
// Build void __kmpc_end_serialized_parallel(ident_t *loc, kmp_int32
// global_tid);
llvm::Type *TypeParams[] = {getIdentTyPointerTy(), CGM.Int32Ty};
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, TypeParams, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_end_serialized_parallel");
break;
}
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
case OMPRTL_NVPTX__kmpc_shuffle_int32: {
// Build int32_t __kmpc_shuffle_int32(int32_t element,
// int16_t lane_offset, int16_t warp_size);
llvm::Type *TypeParams[] = {CGM.Int32Ty, CGM.Int16Ty, CGM.Int16Ty};
auto *FnTy =
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
llvm::FunctionType::get(CGM.Int32Ty, TypeParams, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_shuffle_int32");
break;
}
case OMPRTL_NVPTX__kmpc_shuffle_int64: {
// Build int64_t __kmpc_shuffle_int64(int64_t element,
// int16_t lane_offset, int16_t warp_size);
llvm::Type *TypeParams[] = {CGM.Int64Ty, CGM.Int16Ty, CGM.Int16Ty};
auto *FnTy =
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
llvm::FunctionType::get(CGM.Int64Ty, TypeParams, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_shuffle_int64");
break;
}
case OMPRTL_NVPTX__kmpc_parallel_reduce_nowait: {
// Build int32_t kmpc_nvptx_parallel_reduce_nowait(kmp_int32 global_tid,
// kmp_int32 num_vars, size_t reduce_size, void* reduce_data,
// void (*kmp_ShuffleReductFctPtr)(void *rhsData, int16_t lane_id, int16_t
// lane_offset, int16_t Algorithm Version),
// void (*kmp_InterWarpCopyFctPtr)(void* src, int warp_num));
llvm::Type *ShuffleReduceTypeParams[] = {CGM.VoidPtrTy, CGM.Int16Ty,
CGM.Int16Ty, CGM.Int16Ty};
auto *ShuffleReduceFnTy =
llvm::FunctionType::get(CGM.VoidTy, ShuffleReduceTypeParams,
/*isVarArg=*/false);
llvm::Type *InterWarpCopyTypeParams[] = {CGM.VoidPtrTy, CGM.Int32Ty};
auto *InterWarpCopyFnTy =
llvm::FunctionType::get(CGM.VoidTy, InterWarpCopyTypeParams,
/*isVarArg=*/false);
llvm::Type *TypeParams[] = {CGM.Int32Ty,
CGM.Int32Ty,
CGM.SizeTy,
CGM.VoidPtrTy,
ShuffleReduceFnTy->getPointerTo(),
InterWarpCopyFnTy->getPointerTo()};
auto *FnTy =
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
llvm::FunctionType::get(CGM.Int32Ty, TypeParams, /*isVarArg=*/false);
RTLFn = CGM.CreateRuntimeFunction(
FnTy, /*Name=*/"__kmpc_nvptx_parallel_reduce_nowait");
break;
}
case OMPRTL_NVPTX__kmpc_end_reduce_nowait: {
// Build __kmpc_end_reduce_nowait(kmp_int32 global_tid);
llvm::Type *TypeParams[] = {CGM.Int32Ty};
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, TypeParams, /*isVarArg=*/false);
RTLFn = CGM.CreateRuntimeFunction(
FnTy, /*Name=*/"__kmpc_nvptx_end_reduce_nowait");
break;
}
case OMPRTL_NVPTX__kmpc_nvptx_teams_reduce_nowait_simple: {
// Build __kmpc_nvptx_teams_reduce_nowait_simple(ident_t *loc, kmp_int32
// global_tid, kmp_critical_name *lck)
llvm::Type *TypeParams[] = {
getIdentTyPointerTy(), CGM.Int32Ty,
llvm::PointerType::getUnqual(getKmpCriticalNameTy())};
auto *FnTy =
llvm::FunctionType::get(CGM.Int32Ty, TypeParams, /*isVarArg=*/false);
RTLFn = CGM.CreateRuntimeFunction(
FnTy, /*Name=*/"__kmpc_nvptx_teams_reduce_nowait_simple");
break;
}
case OMPRTL_NVPTX__kmpc_nvptx_teams_end_reduce_nowait_simple: {
// Build __kmpc_nvptx_teams_end_reduce_nowait_simple(ident_t *loc, kmp_int32
// global_tid, kmp_critical_name *lck)
llvm::Type *TypeParams[] = {
getIdentTyPointerTy(), CGM.Int32Ty,
llvm::PointerType::getUnqual(getKmpCriticalNameTy())};
auto *FnTy =
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
llvm::FunctionType::get(CGM.VoidTy, TypeParams, /*isVarArg=*/false);
RTLFn = CGM.CreateRuntimeFunction(
FnTy, /*Name=*/"__kmpc_nvptx_teams_end_reduce_nowait_simple");
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
break;
}
case OMPRTL_NVPTX__kmpc_data_sharing_init_stack: {
/// Build void __kmpc_data_sharing_init_stack();
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, llvm::None, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_data_sharing_init_stack");
break;
}
case OMPRTL_NVPTX__kmpc_data_sharing_init_stack_spmd: {
/// Build void __kmpc_data_sharing_init_stack_spmd();
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, llvm::None, /*isVarArg*/ false);
RTLFn =
CGM.CreateRuntimeFunction(FnTy, "__kmpc_data_sharing_init_stack_spmd");
break;
}
case OMPRTL_NVPTX__kmpc_data_sharing_coalesced_push_stack: {
// Build void *__kmpc_data_sharing_coalesced_push_stack(size_t size,
// int16_t UseSharedMemory);
llvm::Type *TypeParams[] = {CGM.SizeTy, CGM.Int16Ty};
auto *FnTy =
llvm::FunctionType::get(CGM.VoidPtrTy, TypeParams, /*isVarArg=*/false);
RTLFn = CGM.CreateRuntimeFunction(
FnTy, /*Name=*/"__kmpc_data_sharing_coalesced_push_stack");
break;
}
case OMPRTL_NVPTX__kmpc_data_sharing_pop_stack: {
// Build void __kmpc_data_sharing_pop_stack(void *a);
llvm::Type *TypeParams[] = {CGM.VoidPtrTy};
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, TypeParams, /*isVarArg=*/false);
RTLFn = CGM.CreateRuntimeFunction(FnTy,
/*Name=*/"__kmpc_data_sharing_pop_stack");
break;
}
case OMPRTL_NVPTX__kmpc_begin_sharing_variables: {
/// Build void __kmpc_begin_sharing_variables(void ***args,
/// size_t n_args);
llvm::Type *TypeParams[] = {CGM.Int8PtrPtrTy->getPointerTo(), CGM.SizeTy};
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, TypeParams, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_begin_sharing_variables");
break;
}
case OMPRTL_NVPTX__kmpc_end_sharing_variables: {
/// Build void __kmpc_end_sharing_variables();
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, llvm::None, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_end_sharing_variables");
break;
}
case OMPRTL_NVPTX__kmpc_get_shared_variables: {
/// Build void __kmpc_get_shared_variables(void ***GlobalArgs);
llvm::Type *TypeParams[] = {CGM.Int8PtrPtrTy->getPointerTo()};
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, TypeParams, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_get_shared_variables");
break;
}
case OMPRTL_NVPTX__kmpc_parallel_level: {
// Build uint16_t __kmpc_parallel_level(ident_t *loc, kmp_int32 global_tid);
llvm::Type *TypeParams[] = {getIdentTyPointerTy(), CGM.Int32Ty};
auto *FnTy =
llvm::FunctionType::get(CGM.Int16Ty, TypeParams, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_parallel_level");
break;
}
case OMPRTL_NVPTX__kmpc_is_spmd_exec_mode: {
// Build int8_t __kmpc_is_spmd_exec_mode();
auto *FnTy = llvm::FunctionType::get(CGM.Int8Ty, /*isVarArg=*/false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_is_spmd_exec_mode");
break;
}
case OMPRTL_NVPTX__kmpc_get_team_static_memory: {
// Build void __kmpc_get_team_static_memory(const void *buf, size_t size,
// int16_t is_shared, const void **res);
llvm::Type *TypeParams[] = {CGM.VoidPtrTy, CGM.SizeTy, CGM.Int16Ty,
CGM.VoidPtrPtrTy};
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, TypeParams, /*isVarArg*/ false);
RTLFn = CGM.CreateRuntimeFunction(FnTy, "__kmpc_get_team_static_memory");
break;
}
case OMPRTL_NVPTX__kmpc_restore_team_static_memory: {
// Build void __kmpc_restore_team_static_memory(int16_t is_shared);
auto *FnTy =
llvm::FunctionType::get(CGM.VoidTy, CGM.Int16Ty, /*isVarArg=*/false);
RTLFn =
CGM.CreateRuntimeFunction(FnTy, "__kmpc_restore_team_static_memory");
break;
}
}
return RTLFn;
}
void CGOpenMPRuntimeNVPTX::createOffloadEntry(llvm::Constant *ID,
llvm::Constant *Addr,
uint64_t Size, int32_t,
llvm::GlobalValue::LinkageTypes) {
// TODO: Add support for global variables on the device after declare target
// support.
if (!isa<llvm::Function>(Addr))
return;
llvm::Module &M = CGM.getModule();
llvm::LLVMContext &Ctx = CGM.getLLVMContext();
// Get "nvvm.annotations" metadata node
llvm::NamedMDNode *MD = M.getOrInsertNamedMetadata("nvvm.annotations");
llvm::Metadata *MDVals[] = {
llvm::ConstantAsMetadata::get(Addr), llvm::MDString::get(Ctx, "kernel"),
llvm::ConstantAsMetadata::get(
llvm::ConstantInt::get(llvm::Type::getInt32Ty(Ctx), 1))};
// Append metadata to nvvm.annotations
MD->addOperand(llvm::MDNode::get(Ctx, MDVals));
}
void CGOpenMPRuntimeNVPTX::emitTargetOutlinedFunction(
const OMPExecutableDirective &D, StringRef ParentName,
llvm::Function *&OutlinedFn, llvm::Constant *&OutlinedFnID,
bool IsOffloadEntry, const RegionCodeGenTy &CodeGen) {
if (!IsOffloadEntry) // Nothing to do.
return;
assert(!ParentName.empty() && "Invalid target region parent name!");
bool Mode = supportsSPMDExecutionMode(CGM.getContext(), D);
if (Mode)
emitSPMDKernel(D, ParentName, OutlinedFn, OutlinedFnID, IsOffloadEntry,
CodeGen);
else
emitNonSPMDKernel(D, ParentName, OutlinedFn, OutlinedFnID, IsOffloadEntry,
CodeGen);
setPropertyExecutionMode(CGM, OutlinedFn->getName(), Mode);
}
namespace {
LLVM_ENABLE_BITMASK_ENUMS_IN_NAMESPACE();
/// Enum for accesseing the reserved_2 field of the ident_t struct.
enum ModeFlagsTy : unsigned {
/// Bit set to 1 when in SPMD mode.
KMP_IDENT_SPMD_MODE = 0x01,
/// Bit set to 1 when a simplified runtime is used.
KMP_IDENT_SIMPLE_RT_MODE = 0x02,
LLVM_MARK_AS_BITMASK_ENUM(/*LargestValue=*/KMP_IDENT_SIMPLE_RT_MODE)
};
/// Special mode Undefined. Is the combination of Non-SPMD mode + SimpleRuntime.
static const ModeFlagsTy UndefinedMode =
(~KMP_IDENT_SPMD_MODE) & KMP_IDENT_SIMPLE_RT_MODE;
} // anonymous namespace
unsigned CGOpenMPRuntimeNVPTX::getDefaultLocationReserved2Flags() const {
switch (getExecutionMode()) {
case EM_SPMD:
if (requiresFullRuntime())
return KMP_IDENT_SPMD_MODE & (~KMP_IDENT_SIMPLE_RT_MODE);
return KMP_IDENT_SPMD_MODE | KMP_IDENT_SIMPLE_RT_MODE;
case EM_NonSPMD:
assert(requiresFullRuntime() && "Expected full runtime.");
return (~KMP_IDENT_SPMD_MODE) & (~KMP_IDENT_SIMPLE_RT_MODE);
case EM_Unknown:
return UndefinedMode;
}
llvm_unreachable("Unknown flags are requested.");
}
CGOpenMPRuntimeNVPTX::CGOpenMPRuntimeNVPTX(CodeGenModule &CGM)
: CGOpenMPRuntime(CGM, "_", "$") {
if (!CGM.getLangOpts().OpenMPIsDevice)
llvm_unreachable("OpenMP NVPTX can only handle device code.");
}
void CGOpenMPRuntimeNVPTX::emitProcBindClause(CodeGenFunction &CGF,
OpenMPProcBindClauseKind ProcBind,
SourceLocation Loc) {
// Do nothing in case of SPMD mode and L0 parallel.
if (getExecutionMode() == CGOpenMPRuntimeNVPTX::EM_SPMD)
return;
CGOpenMPRuntime::emitProcBindClause(CGF, ProcBind, Loc);
}
void CGOpenMPRuntimeNVPTX::emitNumThreadsClause(CodeGenFunction &CGF,
llvm::Value *NumThreads,
SourceLocation Loc) {
// Do nothing in case of SPMD mode and L0 parallel.
if (getExecutionMode() == CGOpenMPRuntimeNVPTX::EM_SPMD)
return;
CGOpenMPRuntime::emitNumThreadsClause(CGF, NumThreads, Loc);
}
void CGOpenMPRuntimeNVPTX::emitNumTeamsClause(CodeGenFunction &CGF,
const Expr *NumTeams,
const Expr *ThreadLimit,
SourceLocation Loc) {}
llvm::Value *CGOpenMPRuntimeNVPTX::emitParallelOutlinedFunction(
const OMPExecutableDirective &D, const VarDecl *ThreadIDVar,
OpenMPDirectiveKind InnermostKind, const RegionCodeGenTy &CodeGen) {
// Emit target region as a standalone region.
class NVPTXPrePostActionTy : public PrePostActionTy {
bool &IsInParallelRegion;
bool PrevIsInParallelRegion;
public:
NVPTXPrePostActionTy(bool &IsInParallelRegion)
: IsInParallelRegion(IsInParallelRegion) {}
void Enter(CodeGenFunction &CGF) override {
PrevIsInParallelRegion = IsInParallelRegion;
IsInParallelRegion = true;
}
void Exit(CodeGenFunction &CGF) override {
IsInParallelRegion = PrevIsInParallelRegion;
}
} Action(IsInParallelRegion);
CodeGen.setAction(Action);
bool PrevIsInTTDRegion = IsInTTDRegion;
IsInTTDRegion = false;
bool PrevIsInTargetMasterThreadRegion = IsInTargetMasterThreadRegion;
IsInTargetMasterThreadRegion = false;
auto *OutlinedFun =
cast<llvm::Function>(CGOpenMPRuntime::emitParallelOutlinedFunction(
D, ThreadIDVar, InnermostKind, CodeGen));
IsInTargetMasterThreadRegion = PrevIsInTargetMasterThreadRegion;
IsInTTDRegion = PrevIsInTTDRegion;
if (getExecutionMode() != CGOpenMPRuntimeNVPTX::EM_SPMD &&
!IsInParallelRegion) {
llvm::Function *WrapperFun =
createParallelDataSharingWrapper(OutlinedFun, D);
WrapperFunctionsMap[OutlinedFun] = WrapperFun;
}
return OutlinedFun;
}
/// Get list of lastprivate variables from the teams distribute ... or
/// teams {distribute ...} directives.
static void
getDistributeLastprivateVars(ASTContext &Ctx, const OMPExecutableDirective &D,
llvm::SmallVectorImpl<const ValueDecl *> &Vars) {
assert(isOpenMPTeamsDirective(D.getDirectiveKind()) &&
"expected teams directive.");
const OMPExecutableDirective *Dir = &D;
if (!isOpenMPDistributeDirective(D.getDirectiveKind())) {
if (const Stmt *S = getSingleCompoundChild(
Ctx,
D.getInnermostCapturedStmt()->getCapturedStmt()->IgnoreContainers(
/*IgnoreCaptured=*/true))) {
Dir = dyn_cast<OMPExecutableDirective>(S);
if (Dir && !isOpenMPDistributeDirective(Dir->getDirectiveKind()))
Dir = nullptr;
}
}
if (!Dir)
return;
for (const auto *C : Dir->getClausesOfKind<OMPLastprivateClause>()) {
for (const Expr *E : C->getVarRefs())
Vars.push_back(getPrivateItem(E));
}
}
/// Get list of reduction variables from the teams ... directives.
static void
getTeamsReductionVars(ASTContext &Ctx, const OMPExecutableDirective &D,
llvm::SmallVectorImpl<const ValueDecl *> &Vars) {
assert(isOpenMPTeamsDirective(D.getDirectiveKind()) &&
"expected teams directive.");
for (const auto *C : D.getClausesOfKind<OMPReductionClause>()) {
for (const Expr *E : C->privates())
Vars.push_back(getPrivateItem(E));
}
}
llvm::Value *CGOpenMPRuntimeNVPTX::emitTeamsOutlinedFunction(
const OMPExecutableDirective &D, const VarDecl *ThreadIDVar,
OpenMPDirectiveKind InnermostKind, const RegionCodeGenTy &CodeGen) {
SourceLocation Loc = D.getBeginLoc();
const RecordDecl *GlobalizedRD = nullptr;
llvm::SmallVector<const ValueDecl *, 4> LastPrivatesReductions;
llvm::SmallDenseMap<const ValueDecl *, const FieldDecl *> MappedDeclsFields;
// Globalize team reductions variable unconditionally in all modes.
getTeamsReductionVars(CGM.getContext(), D, LastPrivatesReductions);
if (getExecutionMode() == CGOpenMPRuntimeNVPTX::EM_SPMD) {
getDistributeLastprivateVars(CGM.getContext(), D, LastPrivatesReductions);
if (!LastPrivatesReductions.empty()) {
GlobalizedRD = ::buildRecordForGlobalizedVars(
CGM.getContext(), llvm::None, LastPrivatesReductions,
MappedDeclsFields);
}
} else if (!LastPrivatesReductions.empty()) {
assert(!TeamAndReductions.first &&
"Previous team declaration is not expected.");
TeamAndReductions.first = D.getCapturedStmt(OMPD_teams)->getCapturedDecl();
std::swap(TeamAndReductions.second, LastPrivatesReductions);
}
// Emit target region as a standalone region.
class NVPTXPrePostActionTy : public PrePostActionTy {
SourceLocation &Loc;
const RecordDecl *GlobalizedRD;
llvm::SmallDenseMap<const ValueDecl *, const FieldDecl *>
&MappedDeclsFields;
public:
NVPTXPrePostActionTy(
SourceLocation &Loc, const RecordDecl *GlobalizedRD,
llvm::SmallDenseMap<const ValueDecl *, const FieldDecl *>
&MappedDeclsFields)
: Loc(Loc), GlobalizedRD(GlobalizedRD),
MappedDeclsFields(MappedDeclsFields) {}
void Enter(CodeGenFunction &CGF) override {
auto &Rt =
static_cast<CGOpenMPRuntimeNVPTX &>(CGF.CGM.getOpenMPRuntime());
if (GlobalizedRD) {
auto I = Rt.FunctionGlobalizedDecls.try_emplace(CGF.CurFn).first;
I->getSecond().GlobalRecord = GlobalizedRD;
I->getSecond().MappedParams =
llvm::make_unique<CodeGenFunction::OMPMapVars>();
DeclToAddrMapTy &Data = I->getSecond().LocalVarData;
for (const auto &Pair : MappedDeclsFields) {
assert(Pair.getFirst()->isCanonicalDecl() &&
"Expected canonical declaration");
Data.insert(std::make_pair(Pair.getFirst(),
MappedVarData(Pair.getSecond(),
/*IsOnePerTeam=*/true)));
}
}
Rt.emitGenericVarsProlog(CGF, Loc);
}
void Exit(CodeGenFunction &CGF) override {
static_cast<CGOpenMPRuntimeNVPTX &>(CGF.CGM.getOpenMPRuntime())
.emitGenericVarsEpilog(CGF);
}
} Action(Loc, GlobalizedRD, MappedDeclsFields);
CodeGen.setAction(Action);
llvm::Value *OutlinedFunVal = CGOpenMPRuntime::emitTeamsOutlinedFunction(
D, ThreadIDVar, InnermostKind, CodeGen);
llvm::Function *OutlinedFun = cast<llvm::Function>(OutlinedFunVal);
OutlinedFun->removeFnAttr(llvm::Attribute::NoInline);
OutlinedFun->removeFnAttr(llvm::Attribute::OptimizeNone);
OutlinedFun->addFnAttr(llvm::Attribute::AlwaysInline);
return OutlinedFun;
}
void CGOpenMPRuntimeNVPTX::emitGenericVarsProlog(CodeGenFunction &CGF,
SourceLocation Loc,
bool WithSPMDCheck) {
if (getDataSharingMode(CGM) != CGOpenMPRuntimeNVPTX::Generic &&
getExecutionMode() != CGOpenMPRuntimeNVPTX::EM_SPMD)
return;
CGBuilderTy &Bld = CGF.Builder;
const auto I = FunctionGlobalizedDecls.find(CGF.CurFn);
if (I == FunctionGlobalizedDecls.end())
return;
if (const RecordDecl *GlobalizedVarsRecord = I->getSecond().GlobalRecord) {
QualType GlobalRecTy = CGM.getContext().getRecordType(GlobalizedVarsRecord);
QualType SecGlobalRecTy;
// Recover pointer to this function's global record. The runtime will
// handle the specifics of the allocation of the memory.
// Use actual memory size of the record including the padding
// for alignment purposes.
unsigned Alignment =
CGM.getContext().getTypeAlignInChars(GlobalRecTy).getQuantity();
unsigned GlobalRecordSize =
CGM.getContext().getTypeSizeInChars(GlobalRecTy).getQuantity();
GlobalRecordSize = llvm::alignTo(GlobalRecordSize, Alignment);
llvm::PointerType *GlobalRecPtrTy =
CGF.ConvertTypeForMem(GlobalRecTy)->getPointerTo();
llvm::Value *GlobalRecCastAddr;
llvm::Value *IsTTD = nullptr;
if (!IsInTTDRegion &&
(WithSPMDCheck ||
getExecutionMode() == CGOpenMPRuntimeNVPTX::EM_Unknown)) {
llvm::BasicBlock *ExitBB = CGF.createBasicBlock(".exit");
llvm::BasicBlock *SPMDBB = CGF.createBasicBlock(".spmd");
llvm::BasicBlock *NonSPMDBB = CGF.createBasicBlock(".non-spmd");
if (I->getSecond().SecondaryGlobalRecord.hasValue()) {
llvm::Value *RTLoc = emitUpdateLocation(CGF, Loc);
llvm::Value *ThreadID = getThreadID(CGF, Loc);
llvm::Value *PL = CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_parallel_level),
{RTLoc, ThreadID});
IsTTD = Bld.CreateIsNull(PL);
}
llvm::Value *IsSPMD = Bld.CreateIsNotNull(CGF.EmitNounwindRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_is_spmd_exec_mode)));
Bld.CreateCondBr(IsSPMD, SPMDBB, NonSPMDBB);
// There is no need to emit line number for unconditional branch.
(void)ApplyDebugLocation::CreateEmpty(CGF);
CGF.EmitBlock(SPMDBB);
Address RecPtr = Address(llvm::ConstantPointerNull::get(GlobalRecPtrTy),
CharUnits::fromQuantity(Alignment));
CGF.EmitBranch(ExitBB);
// There is no need to emit line number for unconditional branch.
(void)ApplyDebugLocation::CreateEmpty(CGF);
CGF.EmitBlock(NonSPMDBB);
llvm::Value *Size = llvm::ConstantInt::get(CGM.SizeTy, GlobalRecordSize);
if (const RecordDecl *SecGlobalizedVarsRecord =
I->getSecond().SecondaryGlobalRecord.getValueOr(nullptr)) {
SecGlobalRecTy =
CGM.getContext().getRecordType(SecGlobalizedVarsRecord);
// Recover pointer to this function's global record. The runtime will
// handle the specifics of the allocation of the memory.
// Use actual memory size of the record including the padding
// for alignment purposes.
unsigned Alignment =
CGM.getContext().getTypeAlignInChars(SecGlobalRecTy).getQuantity();
unsigned GlobalRecordSize =
CGM.getContext().getTypeSizeInChars(SecGlobalRecTy).getQuantity();
GlobalRecordSize = llvm::alignTo(GlobalRecordSize, Alignment);
Size = Bld.CreateSelect(
IsTTD, llvm::ConstantInt::get(CGM.SizeTy, GlobalRecordSize), Size);
}
// TODO: allow the usage of shared memory to be controlled by
// the user, for now, default to global.
llvm::Value *GlobalRecordSizeArg[] = {
Size, CGF.Builder.getInt16(/*UseSharedMemory=*/0)};
llvm::Value *GlobalRecValue = CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(
OMPRTL_NVPTX__kmpc_data_sharing_coalesced_push_stack),
GlobalRecordSizeArg);
GlobalRecCastAddr = Bld.CreatePointerBitCastOrAddrSpaceCast(
GlobalRecValue, GlobalRecPtrTy);
CGF.EmitBlock(ExitBB);
auto *Phi = Bld.CreatePHI(GlobalRecPtrTy,
/*NumReservedValues=*/2, "_select_stack");
Phi->addIncoming(RecPtr.getPointer(), SPMDBB);
Phi->addIncoming(GlobalRecCastAddr, NonSPMDBB);
GlobalRecCastAddr = Phi;
I->getSecond().GlobalRecordAddr = Phi;
I->getSecond().IsInSPMDModeFlag = IsSPMD;
} else if (IsInTTDRegion) {
assert(GlobalizedRecords.back().Records.size() < 2 &&
"Expected less than 2 globalized records: one for target and one "
"for teams.");
unsigned Offset = 0;
for (const RecordDecl *RD : GlobalizedRecords.back().Records) {
QualType RDTy = CGM.getContext().getRecordType(RD);
unsigned Alignment =
CGM.getContext().getTypeAlignInChars(RDTy).getQuantity();
unsigned Size = CGM.getContext().getTypeSizeInChars(RDTy).getQuantity();
Offset =
llvm::alignTo(llvm::alignTo(Offset, Alignment) + Size, Alignment);
}
unsigned Alignment =
CGM.getContext().getTypeAlignInChars(GlobalRecTy).getQuantity();
Offset = llvm::alignTo(Offset, Alignment);
GlobalizedRecords.back().Records.push_back(GlobalizedVarsRecord);
++GlobalizedRecords.back().RegionCounter;
if (GlobalizedRecords.back().Records.size() == 1) {
assert(KernelStaticGlobalized &&
"Kernel static pointer must be initialized already.");
auto *UseSharedMemory = new llvm::GlobalVariable(
CGM.getModule(), CGM.Int16Ty, /*isConstant=*/true,
llvm::GlobalValue::InternalLinkage, nullptr,
"_openmp_static_kernel$is_shared");
UseSharedMemory->setUnnamedAddr(llvm::GlobalValue::UnnamedAddr::Global);
QualType Int16Ty = CGM.getContext().getIntTypeForBitwidth(
/*DestWidth=*/16, /*Signed=*/0);
llvm::Value *IsInSharedMemory = CGF.EmitLoadOfScalar(
Address(UseSharedMemory,
CGM.getContext().getTypeAlignInChars(Int16Ty)),
/*Volatile=*/false, Int16Ty, Loc);
auto *StaticGlobalized = new llvm::GlobalVariable(
CGM.getModule(), CGM.Int8Ty, /*isConstant=*/false,
llvm::GlobalValue::CommonLinkage, nullptr);
auto *RecSize = new llvm::GlobalVariable(
CGM.getModule(), CGM.SizeTy, /*isConstant=*/true,
llvm::GlobalValue::InternalLinkage, nullptr,
"_openmp_static_kernel$size");
RecSize->setUnnamedAddr(llvm::GlobalValue::UnnamedAddr::Global);
llvm::Value *Ld = CGF.EmitLoadOfScalar(
Address(RecSize, CGM.getSizeAlign()), /*Volatile=*/false,
CGM.getContext().getSizeType(), Loc);
llvm::Value *ResAddr = Bld.CreatePointerBitCastOrAddrSpaceCast(
KernelStaticGlobalized, CGM.VoidPtrPtrTy);
llvm::Value *GlobalRecordSizeArg[] = {StaticGlobalized, Ld,
IsInSharedMemory, ResAddr};
CGF.EmitRuntimeCall(createNVPTXRuntimeFunction(
OMPRTL_NVPTX__kmpc_get_team_static_memory),
GlobalRecordSizeArg);
GlobalizedRecords.back().Buffer = StaticGlobalized;
GlobalizedRecords.back().RecSize = RecSize;
GlobalizedRecords.back().UseSharedMemory = UseSharedMemory;
GlobalizedRecords.back().Loc = Loc;
}
assert(KernelStaticGlobalized && "Global address must be set already.");
Address FrameAddr = CGF.EmitLoadOfPointer(
Address(KernelStaticGlobalized, CGM.getPointerAlign()),
CGM.getContext()
.getPointerType(CGM.getContext().VoidPtrTy)
.castAs<PointerType>());
llvm::Value *GlobalRecValue =
Bld.CreateConstInBoundsGEP(FrameAddr, Offset, CharUnits::One())
.getPointer();
I->getSecond().GlobalRecordAddr = GlobalRecValue;
I->getSecond().IsInSPMDModeFlag = nullptr;
GlobalRecCastAddr = Bld.CreatePointerBitCastOrAddrSpaceCast(
GlobalRecValue, CGF.ConvertTypeForMem(GlobalRecTy)->getPointerTo());
} else {
// TODO: allow the usage of shared memory to be controlled by
// the user, for now, default to global.
llvm::Value *GlobalRecordSizeArg[] = {
llvm::ConstantInt::get(CGM.SizeTy, GlobalRecordSize),
CGF.Builder.getInt16(/*UseSharedMemory=*/0)};
llvm::Value *GlobalRecValue = CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(
OMPRTL_NVPTX__kmpc_data_sharing_coalesced_push_stack),
GlobalRecordSizeArg);
GlobalRecCastAddr = Bld.CreatePointerBitCastOrAddrSpaceCast(
GlobalRecValue, GlobalRecPtrTy);
I->getSecond().GlobalRecordAddr = GlobalRecValue;
I->getSecond().IsInSPMDModeFlag = nullptr;
}
LValue Base =
CGF.MakeNaturalAlignPointeeAddrLValue(GlobalRecCastAddr, GlobalRecTy);
// Emit the "global alloca" which is a GEP from the global declaration
// record using the pointer returned by the runtime.
LValue SecBase;
decltype(I->getSecond().LocalVarData)::const_iterator SecIt;
if (IsTTD) {
SecIt = I->getSecond().SecondaryLocalVarData->begin();
llvm::PointerType *SecGlobalRecPtrTy =
CGF.ConvertTypeForMem(SecGlobalRecTy)->getPointerTo();
SecBase = CGF.MakeNaturalAlignPointeeAddrLValue(
Bld.CreatePointerBitCastOrAddrSpaceCast(
I->getSecond().GlobalRecordAddr, SecGlobalRecPtrTy),
SecGlobalRecTy);
}
for (auto &Rec : I->getSecond().LocalVarData) {
bool EscapedParam = I->getSecond().EscapedParameters.count(Rec.first);
llvm::Value *ParValue;
if (EscapedParam) {
const auto *VD = cast<VarDecl>(Rec.first);
LValue ParLVal =
CGF.MakeAddrLValue(CGF.GetAddrOfLocalVar(VD), VD->getType());
ParValue = CGF.EmitLoadOfScalar(ParLVal, Loc);
}
LValue VarAddr = CGF.EmitLValueForField(Base, Rec.second.FD);
// Emit VarAddr basing on lane-id if required.
QualType VarTy;
if (Rec.second.IsOnePerTeam) {
VarTy = Rec.second.FD->getType();
} else {
llvm::Value *Ptr = CGF.Builder.CreateInBoundsGEP(
VarAddr.getAddress().getPointer(),
{Bld.getInt32(0), getNVPTXLaneID(CGF)});
VarTy =
Rec.second.FD->getType()->castAsArrayTypeUnsafe()->getElementType();
VarAddr = CGF.MakeAddrLValue(
Address(Ptr, CGM.getContext().getDeclAlign(Rec.first)), VarTy,
AlignmentSource::Decl);
}
Rec.second.PrivateAddr = VarAddr.getAddress();
if (!IsInTTDRegion &&
(WithSPMDCheck ||
getExecutionMode() == CGOpenMPRuntimeNVPTX::EM_Unknown)) {
assert(I->getSecond().IsInSPMDModeFlag &&
"Expected unknown execution mode or required SPMD check.");
if (IsTTD) {
assert(SecIt->second.IsOnePerTeam &&
"Secondary glob data must be one per team.");
LValue SecVarAddr = CGF.EmitLValueForField(SecBase, SecIt->second.FD);
VarAddr.setAddress(
Address(Bld.CreateSelect(IsTTD, SecVarAddr.getPointer(),
VarAddr.getPointer()),
VarAddr.getAlignment()));
Rec.second.PrivateAddr = VarAddr.getAddress();
}
Address GlobalPtr = Rec.second.PrivateAddr;
Address LocalAddr = CGF.CreateMemTemp(VarTy, Rec.second.FD->getName());
Rec.second.PrivateAddr = Address(
Bld.CreateSelect(I->getSecond().IsInSPMDModeFlag,
LocalAddr.getPointer(), GlobalPtr.getPointer()),
LocalAddr.getAlignment());
}
if (EscapedParam) {
const auto *VD = cast<VarDecl>(Rec.first);
CGF.EmitStoreOfScalar(ParValue, VarAddr);
I->getSecond().MappedParams->setVarAddr(CGF, VD, VarAddr.getAddress());
}
if (IsTTD)
++SecIt;
}
}
for (const ValueDecl *VD : I->getSecond().EscapedVariableLengthDecls) {
// Recover pointer to this function's global record. The runtime will
// handle the specifics of the allocation of the memory.
// Use actual memory size of the record including the padding
// for alignment purposes.
CGBuilderTy &Bld = CGF.Builder;
llvm::Value *Size = CGF.getTypeSize(VD->getType());
CharUnits Align = CGM.getContext().getDeclAlign(VD);
Size = Bld.CreateNUWAdd(
Size, llvm::ConstantInt::get(CGF.SizeTy, Align.getQuantity() - 1));
llvm::Value *AlignVal =
llvm::ConstantInt::get(CGF.SizeTy, Align.getQuantity());
Size = Bld.CreateUDiv(Size, AlignVal);
Size = Bld.CreateNUWMul(Size, AlignVal);
// TODO: allow the usage of shared memory to be controlled by
// the user, for now, default to global.
llvm::Value *GlobalRecordSizeArg[] = {
Size, CGF.Builder.getInt16(/*UseSharedMemory=*/0)};
llvm::Value *GlobalRecValue = CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(
OMPRTL_NVPTX__kmpc_data_sharing_coalesced_push_stack),
GlobalRecordSizeArg);
llvm::Value *GlobalRecCastAddr = Bld.CreatePointerBitCastOrAddrSpaceCast(
GlobalRecValue, CGF.ConvertTypeForMem(VD->getType())->getPointerTo());
LValue Base = CGF.MakeAddrLValue(GlobalRecCastAddr, VD->getType(),
CGM.getContext().getDeclAlign(VD),
AlignmentSource::Decl);
I->getSecond().MappedParams->setVarAddr(CGF, cast<VarDecl>(VD),
Base.getAddress());
I->getSecond().EscapedVariableLengthDeclsAddrs.emplace_back(GlobalRecValue);
}
I->getSecond().MappedParams->apply(CGF);
}
void CGOpenMPRuntimeNVPTX::emitGenericVarsEpilog(CodeGenFunction &CGF,
bool WithSPMDCheck) {
if (getDataSharingMode(CGM) != CGOpenMPRuntimeNVPTX::Generic &&
getExecutionMode() != CGOpenMPRuntimeNVPTX::EM_SPMD)
return;
const auto I = FunctionGlobalizedDecls.find(CGF.CurFn);
if (I != FunctionGlobalizedDecls.end()) {
I->getSecond().MappedParams->restore(CGF);
if (!CGF.HaveInsertPoint())
return;
for (llvm::Value *Addr :
llvm::reverse(I->getSecond().EscapedVariableLengthDeclsAddrs)) {
CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_data_sharing_pop_stack),
Addr);
}
if (I->getSecond().GlobalRecordAddr) {
if (!IsInTTDRegion &&
(WithSPMDCheck ||
getExecutionMode() == CGOpenMPRuntimeNVPTX::EM_Unknown)) {
CGBuilderTy &Bld = CGF.Builder;
llvm::BasicBlock *ExitBB = CGF.createBasicBlock(".exit");
llvm::BasicBlock *NonSPMDBB = CGF.createBasicBlock(".non-spmd");
Bld.CreateCondBr(I->getSecond().IsInSPMDModeFlag, ExitBB, NonSPMDBB);
// There is no need to emit line number for unconditional branch.
(void)ApplyDebugLocation::CreateEmpty(CGF);
CGF.EmitBlock(NonSPMDBB);
CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(
OMPRTL_NVPTX__kmpc_data_sharing_pop_stack),
CGF.EmitCastToVoidPtr(I->getSecond().GlobalRecordAddr));
CGF.EmitBlock(ExitBB);
} else if (IsInTTDRegion) {
assert(GlobalizedRecords.back().RegionCounter > 0 &&
"region counter must be > 0.");
--GlobalizedRecords.back().RegionCounter;
// Emit the restore function only in the target region.
if (GlobalizedRecords.back().RegionCounter == 0) {
QualType Int16Ty = CGM.getContext().getIntTypeForBitwidth(
/*DestWidth=*/16, /*Signed=*/0);
llvm::Value *IsInSharedMemory = CGF.EmitLoadOfScalar(
Address(GlobalizedRecords.back().UseSharedMemory,
CGM.getContext().getTypeAlignInChars(Int16Ty)),
/*Volatile=*/false, Int16Ty, GlobalizedRecords.back().Loc);
CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(
OMPRTL_NVPTX__kmpc_restore_team_static_memory),
IsInSharedMemory);
}
} else {
CGF.EmitRuntimeCall(createNVPTXRuntimeFunction(
OMPRTL_NVPTX__kmpc_data_sharing_pop_stack),
I->getSecond().GlobalRecordAddr);
}
}
}
}
void CGOpenMPRuntimeNVPTX::emitTeamsCall(CodeGenFunction &CGF,
const OMPExecutableDirective &D,
SourceLocation Loc,
llvm::Value *OutlinedFn,
ArrayRef<llvm::Value *> CapturedVars) {
if (!CGF.HaveInsertPoint())
return;
Address ZeroAddr = CGF.CreateMemTemp(
CGF.getContext().getIntTypeForBitwidth(/*DestWidth=*/32, /*Signed=*/1),
/*Name*/ ".zero.addr");
CGF.InitTempAlloca(ZeroAddr, CGF.Builder.getInt32(/*C*/ 0));
llvm::SmallVector<llvm::Value *, 16> OutlinedFnArgs;
OutlinedFnArgs.push_back(emitThreadIDAddress(CGF, Loc).getPointer());
OutlinedFnArgs.push_back(ZeroAddr.getPointer());
OutlinedFnArgs.append(CapturedVars.begin(), CapturedVars.end());
emitOutlinedFunctionCall(CGF, Loc, OutlinedFn, OutlinedFnArgs);
}
void CGOpenMPRuntimeNVPTX::emitParallelCall(
CodeGenFunction &CGF, SourceLocation Loc, llvm::Value *OutlinedFn,
ArrayRef<llvm::Value *> CapturedVars, const Expr *IfCond) {
if (!CGF.HaveInsertPoint())
return;
if (getExecutionMode() == CGOpenMPRuntimeNVPTX::EM_SPMD)
emitSPMDParallelCall(CGF, Loc, OutlinedFn, CapturedVars, IfCond);
else
emitNonSPMDParallelCall(CGF, Loc, OutlinedFn, CapturedVars, IfCond);
}
void CGOpenMPRuntimeNVPTX::emitNonSPMDParallelCall(
CodeGenFunction &CGF, SourceLocation Loc, llvm::Value *OutlinedFn,
ArrayRef<llvm::Value *> CapturedVars, const Expr *IfCond) {
llvm::Function *Fn = cast<llvm::Function>(OutlinedFn);
// Force inline this outlined function at its call site.
Fn->setLinkage(llvm::GlobalValue::InternalLinkage);
Address ZeroAddr = CGF.CreateMemTemp(CGF.getContext().getIntTypeForBitwidth(
/*DestWidth=*/32, /*Signed=*/1),
".zero.addr");
CGF.InitTempAlloca(ZeroAddr, CGF.Builder.getInt32(/*C*/ 0));
// ThreadId for serialized parallels is 0.
Address ThreadIDAddr = ZeroAddr;
auto &&CodeGen = [this, Fn, CapturedVars, Loc, ZeroAddr, &ThreadIDAddr](
CodeGenFunction &CGF, PrePostActionTy &Action) {
Action.Enter(CGF);
llvm::SmallVector<llvm::Value *, 16> OutlinedFnArgs;
OutlinedFnArgs.push_back(ThreadIDAddr.getPointer());
OutlinedFnArgs.push_back(ZeroAddr.getPointer());
OutlinedFnArgs.append(CapturedVars.begin(), CapturedVars.end());
emitOutlinedFunctionCall(CGF, Loc, Fn, OutlinedFnArgs);
};
auto &&SeqGen = [this, &CodeGen, Loc](CodeGenFunction &CGF,
PrePostActionTy &) {
RegionCodeGenTy RCG(CodeGen);
llvm::Value *RTLoc = emitUpdateLocation(CGF, Loc);
llvm::Value *ThreadID = getThreadID(CGF, Loc);
llvm::Value *Args[] = {RTLoc, ThreadID};
NVPTXActionTy Action(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_serialized_parallel),
Args,
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_end_serialized_parallel),
Args);
RCG.setAction(Action);
RCG(CGF);
};
auto &&L0ParallelGen = [this, CapturedVars, Fn](CodeGenFunction &CGF,
PrePostActionTy &Action) {
CGBuilderTy &Bld = CGF.Builder;
llvm::Function *WFn = WrapperFunctionsMap[Fn];
assert(WFn && "Wrapper function does not exist!");
llvm::Value *ID = Bld.CreateBitOrPointerCast(WFn, CGM.Int8PtrTy);
// Prepare for parallel region. Indicate the outlined function.
llvm::Value *Args[] = {ID, /*RequiresOMPRuntime=*/Bld.getInt16(1)};
CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_kernel_prepare_parallel),
Args);
// Create a private scope that will globalize the arguments
// passed from the outside of the target region.
CodeGenFunction::OMPPrivateScope PrivateArgScope(CGF);
// There's somehting to share.
if (!CapturedVars.empty()) {
// Prepare for parallel region. Indicate the outlined function.
Address SharedArgs =
CGF.CreateDefaultAlignTempAlloca(CGF.VoidPtrPtrTy, "shared_arg_refs");
llvm::Value *SharedArgsPtr = SharedArgs.getPointer();
llvm::Value *DataSharingArgs[] = {
SharedArgsPtr,
llvm::ConstantInt::get(CGM.SizeTy, CapturedVars.size())};
CGF.EmitRuntimeCall(createNVPTXRuntimeFunction(
OMPRTL_NVPTX__kmpc_begin_sharing_variables),
DataSharingArgs);
// Store variable address in a list of references to pass to workers.
unsigned Idx = 0;
ASTContext &Ctx = CGF.getContext();
Address SharedArgListAddress = CGF.EmitLoadOfPointer(
SharedArgs, Ctx.getPointerType(Ctx.getPointerType(Ctx.VoidPtrTy))
.castAs<PointerType>());
for (llvm::Value *V : CapturedVars) {
Address Dst = Bld.CreateConstInBoundsGEP(SharedArgListAddress, Idx,
CGF.getPointerSize());
llvm::Value *PtrV;
if (V->getType()->isIntegerTy())
PtrV = Bld.CreateIntToPtr(V, CGF.VoidPtrTy);
else
PtrV = Bld.CreatePointerBitCastOrAddrSpaceCast(V, CGF.VoidPtrTy);
CGF.EmitStoreOfScalar(PtrV, Dst, /*Volatile=*/false,
Ctx.getPointerType(Ctx.VoidPtrTy));
++Idx;
}
}
// Activate workers. This barrier is used by the master to signal
// work for the workers.
syncCTAThreads(CGF);
// OpenMP [2.5, Parallel Construct, p.49]
// There is an implied barrier at the end of a parallel region. After the
// end of a parallel region, only the master thread of the team resumes
// execution of the enclosing task region.
//
// The master waits at this barrier until all workers are done.
syncCTAThreads(CGF);
if (!CapturedVars.empty())
CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_end_sharing_variables));
// Remember for post-processing in worker loop.
Work.emplace_back(WFn);
};
auto &&LNParallelGen = [this, Loc, &SeqGen, &L0ParallelGen](
CodeGenFunction &CGF, PrePostActionTy &Action) {
if (IsInParallelRegion) {
SeqGen(CGF, Action);
} else if (IsInTargetMasterThreadRegion) {
L0ParallelGen(CGF, Action);
} else {
// Check for master and then parallelism:
// if (__kmpc_is_spmd_exec_mode() || __kmpc_parallel_level(loc, gtid)) {
// Serialized execution.
// } else {
// Worker call.
// }
CGBuilderTy &Bld = CGF.Builder;
llvm::BasicBlock *ExitBB = CGF.createBasicBlock(".exit");
llvm::BasicBlock *SeqBB = CGF.createBasicBlock(".sequential");
llvm::BasicBlock *ParallelCheckBB = CGF.createBasicBlock(".parcheck");
llvm::BasicBlock *MasterBB = CGF.createBasicBlock(".master");
llvm::Value *IsSPMD = Bld.CreateIsNotNull(CGF.EmitNounwindRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_is_spmd_exec_mode)));
Bld.CreateCondBr(IsSPMD, SeqBB, ParallelCheckBB);
// There is no need to emit line number for unconditional branch.
(void)ApplyDebugLocation::CreateEmpty(CGF);
CGF.EmitBlock(ParallelCheckBB);
llvm::Value *RTLoc = emitUpdateLocation(CGF, Loc);
llvm::Value *ThreadID = getThreadID(CGF, Loc);
llvm::Value *PL = CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_parallel_level),
{RTLoc, ThreadID});
llvm::Value *Res = Bld.CreateIsNotNull(PL);
Bld.CreateCondBr(Res, SeqBB, MasterBB);
CGF.EmitBlock(SeqBB);
SeqGen(CGF, Action);
CGF.EmitBranch(ExitBB);
// There is no need to emit line number for unconditional branch.
(void)ApplyDebugLocation::CreateEmpty(CGF);
CGF.EmitBlock(MasterBB);
L0ParallelGen(CGF, Action);
CGF.EmitBranch(ExitBB);
// There is no need to emit line number for unconditional branch.
(void)ApplyDebugLocation::CreateEmpty(CGF);
// Emit the continuation block for code after the if.
CGF.EmitBlock(ExitBB, /*IsFinished=*/true);
}
};
if (IfCond) {
emitOMPIfClause(CGF, IfCond, LNParallelGen, SeqGen);
} else {
CodeGenFunction::RunCleanupsScope Scope(CGF);
RegionCodeGenTy ThenRCG(LNParallelGen);
ThenRCG(CGF);
}
}
void CGOpenMPRuntimeNVPTX::emitSPMDParallelCall(
CodeGenFunction &CGF, SourceLocation Loc, llvm::Value *OutlinedFn,
ArrayRef<llvm::Value *> CapturedVars, const Expr *IfCond) {
// Just call the outlined function to execute the parallel region.
// OutlinedFn(&GTid, &zero, CapturedStruct);
//
llvm::SmallVector<llvm::Value *, 16> OutlinedFnArgs;
Address ZeroAddr = CGF.CreateMemTemp(CGF.getContext().getIntTypeForBitwidth(
/*DestWidth=*/32, /*Signed=*/1),
".zero.addr");
CGF.InitTempAlloca(ZeroAddr, CGF.Builder.getInt32(/*C*/ 0));
// ThreadId for serialized parallels is 0.
Address ThreadIDAddr = ZeroAddr;
auto &&CodeGen = [this, OutlinedFn, CapturedVars, Loc, ZeroAddr,
&ThreadIDAddr](CodeGenFunction &CGF,
PrePostActionTy &Action) {
Action.Enter(CGF);
llvm::SmallVector<llvm::Value *, 16> OutlinedFnArgs;
OutlinedFnArgs.push_back(ThreadIDAddr.getPointer());
OutlinedFnArgs.push_back(ZeroAddr.getPointer());
OutlinedFnArgs.append(CapturedVars.begin(), CapturedVars.end());
emitOutlinedFunctionCall(CGF, Loc, OutlinedFn, OutlinedFnArgs);
};
auto &&SeqGen = [this, &CodeGen, Loc](CodeGenFunction &CGF,
PrePostActionTy &) {
RegionCodeGenTy RCG(CodeGen);
llvm::Value *RTLoc = emitUpdateLocation(CGF, Loc);
llvm::Value *ThreadID = getThreadID(CGF, Loc);
llvm::Value *Args[] = {RTLoc, ThreadID};
NVPTXActionTy Action(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_serialized_parallel),
Args,
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_end_serialized_parallel),
Args);
RCG.setAction(Action);
RCG(CGF);
};
if (IsInTargetMasterThreadRegion) {
// In the worker need to use the real thread id.
ThreadIDAddr = emitThreadIDAddress(CGF, Loc);
RegionCodeGenTy RCG(CodeGen);
RCG(CGF);
} else {
// If we are not in the target region, it is definitely L2 parallelism or
// more, because for SPMD mode we always has L1 parallel level, sowe don't
// need to check for orphaned directives.
RegionCodeGenTy RCG(SeqGen);
RCG(CGF);
}
}
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
void CGOpenMPRuntimeNVPTX::emitCriticalRegion(
CodeGenFunction &CGF, StringRef CriticalName,
const RegionCodeGenTy &CriticalOpGen, SourceLocation Loc,
const Expr *Hint) {
llvm::BasicBlock *LoopBB = CGF.createBasicBlock("omp.critical.loop");
llvm::BasicBlock *TestBB = CGF.createBasicBlock("omp.critical.test");
llvm::BasicBlock *SyncBB = CGF.createBasicBlock("omp.critical.sync");
llvm::BasicBlock *BodyBB = CGF.createBasicBlock("omp.critical.body");
llvm::BasicBlock *ExitBB = CGF.createBasicBlock("omp.critical.exit");
// Fetch team-local id of the thread.
llvm::Value *ThreadID = getNVPTXThreadID(CGF);
// Get the width of the team.
llvm::Value *TeamWidth = getNVPTXNumThreads(CGF);
// Initialize the counter variable for the loop.
QualType Int32Ty =
CGF.getContext().getIntTypeForBitwidth(/*DestWidth=*/32, /*Signed=*/0);
Address Counter = CGF.CreateMemTemp(Int32Ty, "critical_counter");
LValue CounterLVal = CGF.MakeAddrLValue(Counter, Int32Ty);
CGF.EmitStoreOfScalar(llvm::Constant::getNullValue(CGM.Int32Ty), CounterLVal,
/*isInit=*/true);
// Block checks if loop counter exceeds upper bound.
CGF.EmitBlock(LoopBB);
llvm::Value *CounterVal = CGF.EmitLoadOfScalar(CounterLVal, Loc);
llvm::Value *CmpLoopBound = CGF.Builder.CreateICmpSLT(CounterVal, TeamWidth);
CGF.Builder.CreateCondBr(CmpLoopBound, TestBB, ExitBB);
// Block tests which single thread should execute region, and which threads
// should go straight to synchronisation point.
CGF.EmitBlock(TestBB);
CounterVal = CGF.EmitLoadOfScalar(CounterLVal, Loc);
llvm::Value *CmpThreadToCounter =
CGF.Builder.CreateICmpEQ(ThreadID, CounterVal);
CGF.Builder.CreateCondBr(CmpThreadToCounter, BodyBB, SyncBB);
// Block emits the body of the critical region.
CGF.EmitBlock(BodyBB);
// Output the critical statement.
CriticalOpGen(CGF);
// After the body surrounded by the critical region, the single executing
// thread will jump to the synchronisation point.
// Block waits for all threads in current team to finish then increments the
// counter variable and returns to the loop.
CGF.EmitBlock(SyncBB);
getNVPTXCTABarrier(CGF);
llvm::Value *IncCounterVal =
CGF.Builder.CreateNSWAdd(CounterVal, CGF.Builder.getInt32(1));
CGF.EmitStoreOfScalar(IncCounterVal, CounterLVal);
CGF.EmitBranch(LoopBB);
// Block that is reached when all threads in the team complete the region.
CGF.EmitBlock(ExitBB, /*IsFinished=*/true);
}
/// Cast value to the specified type.
static llvm::Value *castValueToType(CodeGenFunction &CGF, llvm::Value *Val,
QualType ValTy, QualType CastTy,
SourceLocation Loc) {
assert(!CGF.getContext().getTypeSizeInChars(CastTy).isZero() &&
"Cast type must sized.");
assert(!CGF.getContext().getTypeSizeInChars(ValTy).isZero() &&
"Val type must sized.");
llvm::Type *LLVMCastTy = CGF.ConvertTypeForMem(CastTy);
if (ValTy == CastTy)
return Val;
if (CGF.getContext().getTypeSizeInChars(ValTy) ==
CGF.getContext().getTypeSizeInChars(CastTy))
return CGF.Builder.CreateBitCast(Val, LLVMCastTy);
if (CastTy->isIntegerType() && ValTy->isIntegerType())
return CGF.Builder.CreateIntCast(Val, LLVMCastTy,
CastTy->hasSignedIntegerRepresentation());
Address CastItem = CGF.CreateMemTemp(CastTy);
Address ValCastItem = CGF.Builder.CreatePointerBitCastOrAddrSpaceCast(
CastItem, Val->getType()->getPointerTo(CastItem.getAddressSpace()));
CGF.EmitStoreOfScalar(Val, ValCastItem, /*Volatile=*/false, ValTy);
return CGF.EmitLoadOfScalar(CastItem, /*Volatile=*/false, CastTy, Loc);
}
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
/// This function creates calls to one of two shuffle functions to copy
/// variables between lanes in a warp.
static llvm::Value *createRuntimeShuffleFunction(CodeGenFunction &CGF,
llvm::Value *Elem,
QualType ElemType,
llvm::Value *Offset,
SourceLocation Loc) {
CodeGenModule &CGM = CGF.CGM;
CGBuilderTy &Bld = CGF.Builder;
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
CGOpenMPRuntimeNVPTX &RT =
*(static_cast<CGOpenMPRuntimeNVPTX *>(&CGM.getOpenMPRuntime()));
CharUnits Size = CGF.getContext().getTypeSizeInChars(ElemType);
assert(Size.getQuantity() <= 8 &&
"Unsupported bitwidth in shuffle instruction.");
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
OpenMPRTLFunctionNVPTX ShuffleFn = Size.getQuantity() <= 4
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
? OMPRTL_NVPTX__kmpc_shuffle_int32
: OMPRTL_NVPTX__kmpc_shuffle_int64;
// Cast all types to 32- or 64-bit values before calling shuffle routines.
QualType CastTy = CGF.getContext().getIntTypeForBitwidth(
Size.getQuantity() <= 4 ? 32 : 64, /*Signed=*/1);
llvm::Value *ElemCast = castValueToType(CGF, Elem, ElemType, CastTy, Loc);
llvm::Value *WarpSize =
Bld.CreateIntCast(getNVPTXWarpSize(CGF), CGM.Int16Ty, /*isSigned=*/true);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
llvm::Value *ShuffledVal = CGF.EmitRuntimeCall(
RT.createNVPTXRuntimeFunction(ShuffleFn), {ElemCast, Offset, WarpSize});
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
return castValueToType(CGF, ShuffledVal, CastTy, ElemType, Loc);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
}
static void shuffleAndStore(CodeGenFunction &CGF, Address SrcAddr,
Address DestAddr, QualType ElemType,
llvm::Value *Offset, SourceLocation Loc) {
CGBuilderTy &Bld = CGF.Builder;
CharUnits Size = CGF.getContext().getTypeSizeInChars(ElemType);
// Create the loop over the big sized data.
// ptr = (void*)Elem;
// ptrEnd = (void*) Elem + 1;
// Step = 8;
// while (ptr + Step < ptrEnd)
// shuffle((int64_t)*ptr);
// Step = 4;
// while (ptr + Step < ptrEnd)
// shuffle((int32_t)*ptr);
// ...
Address ElemPtr = DestAddr;
Address Ptr = SrcAddr;
Address PtrEnd = Bld.CreatePointerBitCastOrAddrSpaceCast(
Bld.CreateConstGEP(SrcAddr, 1, Size), CGF.VoidPtrTy);
for (int IntSize = 8; IntSize >= 1; IntSize /= 2) {
if (Size < CharUnits::fromQuantity(IntSize))
continue;
QualType IntType = CGF.getContext().getIntTypeForBitwidth(
CGF.getContext().toBits(CharUnits::fromQuantity(IntSize)),
/*Signed=*/1);
llvm::Type *IntTy = CGF.ConvertTypeForMem(IntType);
Ptr = Bld.CreatePointerBitCastOrAddrSpaceCast(Ptr, IntTy->getPointerTo());
ElemPtr =
Bld.CreatePointerBitCastOrAddrSpaceCast(ElemPtr, IntTy->getPointerTo());
if (Size.getQuantity() / IntSize > 1) {
llvm::BasicBlock *PreCondBB = CGF.createBasicBlock(".shuffle.pre_cond");
llvm::BasicBlock *ThenBB = CGF.createBasicBlock(".shuffle.then");
llvm::BasicBlock *ExitBB = CGF.createBasicBlock(".shuffle.exit");
llvm::BasicBlock *CurrentBB = Bld.GetInsertBlock();
CGF.EmitBlock(PreCondBB);
llvm::PHINode *PhiSrc =
Bld.CreatePHI(Ptr.getType(), /*NumReservedValues=*/2);
PhiSrc->addIncoming(Ptr.getPointer(), CurrentBB);
llvm::PHINode *PhiDest =
Bld.CreatePHI(ElemPtr.getType(), /*NumReservedValues=*/2);
PhiDest->addIncoming(ElemPtr.getPointer(), CurrentBB);
Ptr = Address(PhiSrc, Ptr.getAlignment());
ElemPtr = Address(PhiDest, ElemPtr.getAlignment());
llvm::Value *PtrDiff = Bld.CreatePtrDiff(
PtrEnd.getPointer(), Bld.CreatePointerBitCastOrAddrSpaceCast(
Ptr.getPointer(), CGF.VoidPtrTy));
Bld.CreateCondBr(Bld.CreateICmpSGT(PtrDiff, Bld.getInt64(IntSize - 1)),
ThenBB, ExitBB);
CGF.EmitBlock(ThenBB);
llvm::Value *Res = createRuntimeShuffleFunction(
CGF, CGF.EmitLoadOfScalar(Ptr, /*Volatile=*/false, IntType, Loc),
IntType, Offset, Loc);
CGF.EmitStoreOfScalar(Res, ElemPtr, /*Volatile=*/false, IntType);
Address LocalPtr =
Bld.CreateConstGEP(Ptr, 1, CharUnits::fromQuantity(IntSize));
Address LocalElemPtr =
Bld.CreateConstGEP(ElemPtr, 1, CharUnits::fromQuantity(IntSize));
PhiSrc->addIncoming(LocalPtr.getPointer(), ThenBB);
PhiDest->addIncoming(LocalElemPtr.getPointer(), ThenBB);
CGF.EmitBranch(PreCondBB);
CGF.EmitBlock(ExitBB);
} else {
llvm::Value *Res = createRuntimeShuffleFunction(
CGF, CGF.EmitLoadOfScalar(Ptr, /*Volatile=*/false, IntType, Loc),
IntType, Offset, Loc);
CGF.EmitStoreOfScalar(Res, ElemPtr, /*Volatile=*/false, IntType);
Ptr = Bld.CreateConstGEP(Ptr, 1, CharUnits::fromQuantity(IntSize));
ElemPtr =
Bld.CreateConstGEP(ElemPtr, 1, CharUnits::fromQuantity(IntSize));
}
Size = Size % IntSize;
}
}
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
namespace {
enum CopyAction : unsigned {
// RemoteLaneToThread: Copy over a Reduce list from a remote lane in
// the warp using shuffle instructions.
RemoteLaneToThread,
// ThreadCopy: Make a copy of a Reduce list on the thread's stack.
ThreadCopy,
// ThreadToScratchpad: Copy a team-reduced array to the scratchpad.
ThreadToScratchpad,
// ScratchpadToThread: Copy from a scratchpad array in global memory
// containing team-reduced data to a thread's stack.
ScratchpadToThread,
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
};
} // namespace
struct CopyOptionsTy {
llvm::Value *RemoteLaneOffset;
llvm::Value *ScratchpadIndex;
llvm::Value *ScratchpadWidth;
};
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
/// Emit instructions to copy a Reduce list, which contains partially
/// aggregated values, in the specified direction.
static void emitReductionListCopy(
CopyAction Action, CodeGenFunction &CGF, QualType ReductionArrayTy,
ArrayRef<const Expr *> Privates, Address SrcBase, Address DestBase,
CopyOptionsTy CopyOptions = {nullptr, nullptr, nullptr}) {
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
CodeGenModule &CGM = CGF.CGM;
ASTContext &C = CGM.getContext();
CGBuilderTy &Bld = CGF.Builder;
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
llvm::Value *RemoteLaneOffset = CopyOptions.RemoteLaneOffset;
llvm::Value *ScratchpadIndex = CopyOptions.ScratchpadIndex;
llvm::Value *ScratchpadWidth = CopyOptions.ScratchpadWidth;
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// Iterates, element-by-element, through the source Reduce list and
// make a copy.
unsigned Idx = 0;
unsigned Size = Privates.size();
for (const Expr *Private : Privates) {
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
Address SrcElementAddr = Address::invalid();
Address DestElementAddr = Address::invalid();
Address DestElementPtrAddr = Address::invalid();
// Should we shuffle in an element from a remote lane?
bool ShuffleInElement = false;
// Set to true to update the pointer in the dest Reduce list to a
// newly created element.
bool UpdateDestListPtr = false;
// Increment the src or dest pointer to the scratchpad, for each
// new element.
bool IncrScratchpadSrc = false;
bool IncrScratchpadDest = false;
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
switch (Action) {
case RemoteLaneToThread: {
// Step 1.1: Get the address for the src element in the Reduce list.
Address SrcElementPtrAddr =
Bld.CreateConstArrayGEP(SrcBase, Idx, CGF.getPointerSize());
SrcElementAddr = CGF.EmitLoadOfPointer(
SrcElementPtrAddr,
C.getPointerType(Private->getType())->castAs<PointerType>());
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// Step 1.2: Create a temporary to store the element in the destination
// Reduce list.
DestElementPtrAddr =
Bld.CreateConstArrayGEP(DestBase, Idx, CGF.getPointerSize());
DestElementAddr =
CGF.CreateMemTemp(Private->getType(), ".omp.reduction.element");
ShuffleInElement = true;
UpdateDestListPtr = true;
break;
}
case ThreadCopy: {
// Step 1.1: Get the address for the src element in the Reduce list.
Address SrcElementPtrAddr =
Bld.CreateConstArrayGEP(SrcBase, Idx, CGF.getPointerSize());
SrcElementAddr = CGF.EmitLoadOfPointer(
SrcElementPtrAddr,
C.getPointerType(Private->getType())->castAs<PointerType>());
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// Step 1.2: Get the address for dest element. The destination
// element has already been created on the thread's stack.
DestElementPtrAddr =
Bld.CreateConstArrayGEP(DestBase, Idx, CGF.getPointerSize());
DestElementAddr = CGF.EmitLoadOfPointer(
DestElementPtrAddr,
C.getPointerType(Private->getType())->castAs<PointerType>());
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
break;
}
case ThreadToScratchpad: {
// Step 1.1: Get the address for the src element in the Reduce list.
Address SrcElementPtrAddr =
Bld.CreateConstArrayGEP(SrcBase, Idx, CGF.getPointerSize());
SrcElementAddr = CGF.EmitLoadOfPointer(
SrcElementPtrAddr,
C.getPointerType(Private->getType())->castAs<PointerType>());
// Step 1.2: Get the address for dest element:
// address = base + index * ElementSizeInChars.
llvm::Value *ElementSizeInChars = CGF.getTypeSize(Private->getType());
llvm::Value *CurrentOffset =
Bld.CreateNUWMul(ElementSizeInChars, ScratchpadIndex);
llvm::Value *ScratchPadElemAbsolutePtrVal =
Bld.CreateNUWAdd(DestBase.getPointer(), CurrentOffset);
ScratchPadElemAbsolutePtrVal =
Bld.CreateIntToPtr(ScratchPadElemAbsolutePtrVal, CGF.VoidPtrTy);
DestElementAddr = Address(ScratchPadElemAbsolutePtrVal,
C.getTypeAlignInChars(Private->getType()));
IncrScratchpadDest = true;
break;
}
case ScratchpadToThread: {
// Step 1.1: Get the address for the src element in the scratchpad.
// address = base + index * ElementSizeInChars.
llvm::Value *ElementSizeInChars = CGF.getTypeSize(Private->getType());
llvm::Value *CurrentOffset =
Bld.CreateNUWMul(ElementSizeInChars, ScratchpadIndex);
llvm::Value *ScratchPadElemAbsolutePtrVal =
Bld.CreateNUWAdd(SrcBase.getPointer(), CurrentOffset);
ScratchPadElemAbsolutePtrVal =
Bld.CreateIntToPtr(ScratchPadElemAbsolutePtrVal, CGF.VoidPtrTy);
SrcElementAddr = Address(ScratchPadElemAbsolutePtrVal,
C.getTypeAlignInChars(Private->getType()));
IncrScratchpadSrc = true;
// Step 1.2: Create a temporary to store the element in the destination
// Reduce list.
DestElementPtrAddr =
Bld.CreateConstArrayGEP(DestBase, Idx, CGF.getPointerSize());
DestElementAddr =
CGF.CreateMemTemp(Private->getType(), ".omp.reduction.element");
UpdateDestListPtr = true;
break;
}
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
}
// Regardless of src and dest of copy, we emit the load of src
// element as this is required in all directions
SrcElementAddr = Bld.CreateElementBitCast(
SrcElementAddr, CGF.ConvertTypeForMem(Private->getType()));
DestElementAddr = Bld.CreateElementBitCast(DestElementAddr,
SrcElementAddr.getElementType());
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// Now that all active lanes have read the element in the
// Reduce list, shuffle over the value from the remote lane.
if (ShuffleInElement) {
shuffleAndStore(CGF, SrcElementAddr, DestElementAddr, Private->getType(),
RemoteLaneOffset, Private->getExprLoc());
} else {
if (Private->getType()->isScalarType()) {
llvm::Value *Elem =
CGF.EmitLoadOfScalar(SrcElementAddr, /*Volatile=*/false,
Private->getType(), Private->getExprLoc());
// Store the source element value to the dest element address.
CGF.EmitStoreOfScalar(Elem, DestElementAddr, /*Volatile=*/false,
Private->getType());
} else {
CGF.EmitAggregateCopy(
CGF.MakeAddrLValue(DestElementAddr, Private->getType()),
CGF.MakeAddrLValue(SrcElementAddr, Private->getType()),
Private->getType(), AggValueSlot::DoesNotOverlap);
}
}
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// Step 3.1: Modify reference in dest Reduce list as needed.
// Modifying the reference in Reduce list to point to the newly
// created element. The element is live in the current function
// scope and that of functions it invokes (i.e., reduce_function).
// RemoteReduceData[i] = (void*)&RemoteElem
if (UpdateDestListPtr) {
CGF.EmitStoreOfScalar(Bld.CreatePointerBitCastOrAddrSpaceCast(
DestElementAddr.getPointer(), CGF.VoidPtrTy),
DestElementPtrAddr, /*Volatile=*/false,
C.VoidPtrTy);
}
// Step 4.1: Increment SrcBase/DestBase so that it points to the starting
// address of the next element in scratchpad memory, unless we're currently
// processing the last one. Memory alignment is also taken care of here.
if ((IncrScratchpadDest || IncrScratchpadSrc) && (Idx + 1 < Size)) {
llvm::Value *ScratchpadBasePtr =
IncrScratchpadDest ? DestBase.getPointer() : SrcBase.getPointer();
llvm::Value *ElementSizeInChars = CGF.getTypeSize(Private->getType());
ScratchpadBasePtr = Bld.CreateNUWAdd(
ScratchpadBasePtr,
Bld.CreateNUWMul(ScratchpadWidth, ElementSizeInChars));
// Take care of global memory alignment for performance
ScratchpadBasePtr = Bld.CreateNUWSub(
ScratchpadBasePtr, llvm::ConstantInt::get(CGM.SizeTy, 1));
ScratchpadBasePtr = Bld.CreateUDiv(
ScratchpadBasePtr,
llvm::ConstantInt::get(CGM.SizeTy, GlobalMemoryAlignment));
ScratchpadBasePtr = Bld.CreateNUWAdd(
ScratchpadBasePtr, llvm::ConstantInt::get(CGM.SizeTy, 1));
ScratchpadBasePtr = Bld.CreateNUWMul(
ScratchpadBasePtr,
llvm::ConstantInt::get(CGM.SizeTy, GlobalMemoryAlignment));
if (IncrScratchpadDest)
DestBase = Address(ScratchpadBasePtr, CGF.getPointerAlign());
else /* IncrScratchpadSrc = true */
SrcBase = Address(ScratchpadBasePtr, CGF.getPointerAlign());
}
++Idx;
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
}
}
/// This function emits a helper that gathers Reduce lists from the first
/// lane of every active warp to lanes in the first warp.
///
/// void inter_warp_copy_func(void* reduce_data, num_warps)
/// shared smem[warp_size];
/// For all data entries D in reduce_data:
/// If (I am the first lane in each warp)
/// Copy my local D to smem[warp_id]
/// sync
/// if (I am the first warp)
/// Copy smem[thread_id] to my local D
/// sync
static llvm::Value *emitInterWarpCopyFunction(CodeGenModule &CGM,
ArrayRef<const Expr *> Privates,
QualType ReductionArrayTy,
SourceLocation Loc) {
ASTContext &C = CGM.getContext();
llvm::Module &M = CGM.getModule();
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// ReduceList: thread local Reduce list.
// At the stage of the computation when this function is called, partially
// aggregated values reside in the first lane of every active warp.
ImplicitParamDecl ReduceListArg(C, /*DC=*/nullptr, Loc, /*Id=*/nullptr,
C.VoidPtrTy, ImplicitParamDecl::Other);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// NumWarps: number of warps active in the parallel region. This could
// be smaller than 32 (max warps in a CTA) for partial block reduction.
ImplicitParamDecl NumWarpsArg(C, /*DC=*/nullptr, Loc, /*Id=*/nullptr,
C.getIntTypeForBitwidth(32, /* Signed */ true),
ImplicitParamDecl::Other);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
FunctionArgList Args;
Args.push_back(&ReduceListArg);
Args.push_back(&NumWarpsArg);
const CGFunctionInfo &CGFI =
CGM.getTypes().arrangeBuiltinFunctionDeclaration(C.VoidTy, Args);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
auto *Fn = llvm::Function::Create(
CGM.getTypes().GetFunctionType(CGFI), llvm::GlobalValue::InternalLinkage,
"_omp_reduction_inter_warp_copy_func", &CGM.getModule());
CGM.SetInternalFunctionAttributes(GlobalDecl(), Fn, CGFI);
Fn->setDoesNotRecurse();
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
CodeGenFunction CGF(CGM);
CGF.StartFunction(GlobalDecl(), C.VoidTy, Fn, CGFI, Args, Loc, Loc);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
CGBuilderTy &Bld = CGF.Builder;
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// This array is used as a medium to transfer, one reduce element at a time,
// the data from the first lane of every warp to lanes in the first warp
// in order to perform the final step of a reduction in a parallel region
// (reduction across warps). The array is placed in NVPTX __shared__ memory
// for reduced latency, as well as to have a distinct copy for concurrently
// executing target regions. The array is declared with common linkage so
// as to be shared across compilation units.
StringRef TransferMediumName =
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
"__openmp_nvptx_data_transfer_temporary_storage";
llvm::GlobalVariable *TransferMedium =
M.getGlobalVariable(TransferMediumName);
if (!TransferMedium) {
auto *Ty = llvm::ArrayType::get(CGM.Int32Ty, WarpSize);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
unsigned SharedAddressSpace = C.getTargetAddressSpace(LangAS::cuda_shared);
TransferMedium = new llvm::GlobalVariable(
M, Ty, /*isConstant=*/false, llvm::GlobalVariable::CommonLinkage,
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
llvm::Constant::getNullValue(Ty), TransferMediumName,
/*InsertBefore=*/nullptr, llvm::GlobalVariable::NotThreadLocal,
SharedAddressSpace);
CGM.addCompilerUsedGlobal(TransferMedium);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
}
// Get the CUDA thread id of the current OpenMP thread on the GPU.
llvm::Value *ThreadID = getNVPTXThreadID(CGF);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// nvptx_lane_id = nvptx_id % warpsize
llvm::Value *LaneID = getNVPTXLaneID(CGF);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// nvptx_warp_id = nvptx_id / warpsize
llvm::Value *WarpID = getNVPTXWarpID(CGF);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
Address AddrReduceListArg = CGF.GetAddrOfLocalVar(&ReduceListArg);
Address LocalReduceList(
Bld.CreatePointerBitCastOrAddrSpaceCast(
CGF.EmitLoadOfScalar(AddrReduceListArg, /*Volatile=*/false,
C.VoidPtrTy, Loc),
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
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CGF.ConvertTypeForMem(ReductionArrayTy)->getPointerTo()),
CGF.getPointerAlign());
unsigned Idx = 0;
for (const Expr *Private : Privates) {
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
//
// Warp master copies reduce element to transfer medium in __shared__
// memory.
//
unsigned RealTySize =
C.getTypeSizeInChars(Private->getType())
.alignTo(C.getTypeAlignInChars(Private->getType()))
.getQuantity();
for (unsigned TySize = 4; TySize > 0 && RealTySize > 0; TySize /=2) {
unsigned NumIters = RealTySize / TySize;
if (NumIters == 0)
continue;
QualType CType = C.getIntTypeForBitwidth(
C.toBits(CharUnits::fromQuantity(TySize)), /*Signed=*/1);
llvm::Type *CopyType = CGF.ConvertTypeForMem(CType);
CharUnits Align = CharUnits::fromQuantity(TySize);
llvm::Value *Cnt = nullptr;
Address CntAddr = Address::invalid();
llvm::BasicBlock *PrecondBB = nullptr;
llvm::BasicBlock *ExitBB = nullptr;
if (NumIters > 1) {
CntAddr = CGF.CreateMemTemp(C.IntTy, ".cnt.addr");
CGF.EmitStoreOfScalar(llvm::Constant::getNullValue(CGM.IntTy), CntAddr,
/*Volatile=*/false, C.IntTy);
PrecondBB = CGF.createBasicBlock("precond");
ExitBB = CGF.createBasicBlock("exit");
llvm::BasicBlock *BodyBB = CGF.createBasicBlock("body");
// There is no need to emit line number for unconditional branch.
(void)ApplyDebugLocation::CreateEmpty(CGF);
CGF.EmitBlock(PrecondBB);
Cnt = CGF.EmitLoadOfScalar(CntAddr, /*Volatile=*/false, C.IntTy, Loc);
llvm::Value *Cmp =
Bld.CreateICmpULT(Cnt, llvm::ConstantInt::get(CGM.IntTy, NumIters));
Bld.CreateCondBr(Cmp, BodyBB, ExitBB);
CGF.EmitBlock(BodyBB);
}
llvm::BasicBlock *ThenBB = CGF.createBasicBlock("then");
llvm::BasicBlock *ElseBB = CGF.createBasicBlock("else");
llvm::BasicBlock *MergeBB = CGF.createBasicBlock("ifcont");
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// if (lane_id == 0)
llvm::Value *IsWarpMaster = Bld.CreateIsNull(LaneID, "warp_master");
Bld.CreateCondBr(IsWarpMaster, ThenBB, ElseBB);
CGF.EmitBlock(ThenBB);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// Reduce element = LocalReduceList[i]
Address ElemPtrPtrAddr =
Bld.CreateConstArrayGEP(LocalReduceList, Idx, CGF.getPointerSize());
llvm::Value *ElemPtrPtr = CGF.EmitLoadOfScalar(
ElemPtrPtrAddr, /*Volatile=*/false, C.VoidPtrTy, SourceLocation());
// elemptr = ((CopyType*)(elemptrptr)) + I
Address ElemPtr = Address(ElemPtrPtr, Align);
ElemPtr = Bld.CreateElementBitCast(ElemPtr, CopyType);
if (NumIters > 1) {
ElemPtr = Address(Bld.CreateGEP(ElemPtr.getPointer(), Cnt),
ElemPtr.getAlignment());
}
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// Get pointer to location in transfer medium.
// MediumPtr = &medium[warp_id]
llvm::Value *MediumPtrVal = Bld.CreateInBoundsGEP(
TransferMedium, {llvm::Constant::getNullValue(CGM.Int64Ty), WarpID});
Address MediumPtr(MediumPtrVal, Align);
// Casting to actual data type.
// MediumPtr = (CopyType*)MediumPtrAddr;
MediumPtr = Bld.CreateElementBitCast(MediumPtr, CopyType);
// elem = *elemptr
//*MediumPtr = elem
llvm::Value *Elem =
CGF.EmitLoadOfScalar(ElemPtr, /*Volatile=*/false, CType, Loc);
// Store the source element value to the dest element address.
CGF.EmitStoreOfScalar(Elem, MediumPtr, /*Volatile=*/true, CType);
Bld.CreateBr(MergeBB);
CGF.EmitBlock(ElseBB);
Bld.CreateBr(MergeBB);
CGF.EmitBlock(MergeBB);
Address AddrNumWarpsArg = CGF.GetAddrOfLocalVar(&NumWarpsArg);
llvm::Value *NumWarpsVal = CGF.EmitLoadOfScalar(
AddrNumWarpsArg, /*Volatile=*/false, C.IntTy, Loc);
llvm::Value *NumActiveThreads = Bld.CreateNSWMul(
NumWarpsVal, getNVPTXWarpSize(CGF), "num_active_threads");
// named_barrier_sync(ParallelBarrierID, num_active_threads)
syncParallelThreads(CGF, NumActiveThreads);
//
// Warp 0 copies reduce element from transfer medium.
//
llvm::BasicBlock *W0ThenBB = CGF.createBasicBlock("then");
llvm::BasicBlock *W0ElseBB = CGF.createBasicBlock("else");
llvm::BasicBlock *W0MergeBB = CGF.createBasicBlock("ifcont");
// Up to 32 threads in warp 0 are active.
llvm::Value *IsActiveThread =
Bld.CreateICmpULT(ThreadID, NumWarpsVal, "is_active_thread");
Bld.CreateCondBr(IsActiveThread, W0ThenBB, W0ElseBB);
CGF.EmitBlock(W0ThenBB);
// SrcMediumPtr = &medium[tid]
llvm::Value *SrcMediumPtrVal = Bld.CreateInBoundsGEP(
TransferMedium,
{llvm::Constant::getNullValue(CGM.Int64Ty), ThreadID});
Address SrcMediumPtr(SrcMediumPtrVal, Align);
// SrcMediumVal = *SrcMediumPtr;
SrcMediumPtr = Bld.CreateElementBitCast(SrcMediumPtr, CopyType);
// TargetElemPtr = (CopyType*)(SrcDataAddr[i]) + I
Address TargetElemPtrPtr =
Bld.CreateConstArrayGEP(LocalReduceList, Idx, CGF.getPointerSize());
llvm::Value *TargetElemPtrVal = CGF.EmitLoadOfScalar(
TargetElemPtrPtr, /*Volatile=*/false, C.VoidPtrTy, Loc);
Address TargetElemPtr = Address(TargetElemPtrVal, Align);
TargetElemPtr = Bld.CreateElementBitCast(TargetElemPtr, CopyType);
if (NumIters > 1) {
TargetElemPtr = Address(Bld.CreateGEP(TargetElemPtr.getPointer(), Cnt),
TargetElemPtr.getAlignment());
}
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// *TargetElemPtr = SrcMediumVal;
llvm::Value *SrcMediumValue =
CGF.EmitLoadOfScalar(SrcMediumPtr, /*Volatile=*/true, CType, Loc);
CGF.EmitStoreOfScalar(SrcMediumValue, TargetElemPtr, /*Volatile=*/false,
CType);
Bld.CreateBr(W0MergeBB);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
CGF.EmitBlock(W0ElseBB);
Bld.CreateBr(W0MergeBB);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
CGF.EmitBlock(W0MergeBB);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// While warp 0 copies values from transfer medium, all other warps must
// wait.
syncParallelThreads(CGF, NumActiveThreads);
if (NumIters > 1) {
Cnt = Bld.CreateNSWAdd(Cnt, llvm::ConstantInt::get(CGM.IntTy, /*V=*/1));
CGF.EmitStoreOfScalar(Cnt, CntAddr, /*Volatile=*/false, C.IntTy);
CGF.EmitBranch(PrecondBB);
(void)ApplyDebugLocation::CreateEmpty(CGF);
CGF.EmitBlock(ExitBB);
}
RealTySize %= TySize;
}
++Idx;
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
}
CGF.FinishFunction();
return Fn;
}
/// Emit a helper that reduces data across two OpenMP threads (lanes)
/// in the same warp. It uses shuffle instructions to copy over data from
/// a remote lane's stack. The reduction algorithm performed is specified
/// by the fourth parameter.
///
/// Algorithm Versions.
/// Full Warp Reduce (argument value 0):
/// This algorithm assumes that all 32 lanes are active and gathers
/// data from these 32 lanes, producing a single resultant value.
/// Contiguous Partial Warp Reduce (argument value 1):
/// This algorithm assumes that only a *contiguous* subset of lanes
/// are active. This happens for the last warp in a parallel region
/// when the user specified num_threads is not an integer multiple of
/// 32. This contiguous subset always starts with the zeroth lane.
/// Partial Warp Reduce (argument value 2):
/// This algorithm gathers data from any number of lanes at any position.
/// All reduced values are stored in the lowest possible lane. The set
/// of problems every algorithm addresses is a super set of those
/// addressable by algorithms with a lower version number. Overhead
/// increases as algorithm version increases.
///
/// Terminology
/// Reduce element:
/// Reduce element refers to the individual data field with primitive
/// data types to be combined and reduced across threads.
/// Reduce list:
/// Reduce list refers to a collection of local, thread-private
/// reduce elements.
/// Remote Reduce list:
/// Remote Reduce list refers to a collection of remote (relative to
/// the current thread) reduce elements.
///
/// We distinguish between three states of threads that are important to
/// the implementation of this function.
/// Alive threads:
/// Threads in a warp executing the SIMT instruction, as distinguished from
/// threads that are inactive due to divergent control flow.
/// Active threads:
/// The minimal set of threads that has to be alive upon entry to this
/// function. The computation is correct iff active threads are alive.
/// Some threads are alive but they are not active because they do not
/// contribute to the computation in any useful manner. Turning them off
/// may introduce control flow overheads without any tangible benefits.
/// Effective threads:
/// In order to comply with the argument requirements of the shuffle
/// function, we must keep all lanes holding data alive. But at most
/// half of them perform value aggregation; we refer to this half of
/// threads as effective. The other half is simply handing off their
/// data.
///
/// Procedure
/// Value shuffle:
/// In this step active threads transfer data from higher lane positions
/// in the warp to lower lane positions, creating Remote Reduce list.
/// Value aggregation:
/// In this step, effective threads combine their thread local Reduce list
/// with Remote Reduce list and store the result in the thread local
/// Reduce list.
/// Value copy:
/// In this step, we deal with the assumption made by algorithm 2
/// (i.e. contiguity assumption). When we have an odd number of lanes
/// active, say 2k+1, only k threads will be effective and therefore k
/// new values will be produced. However, the Reduce list owned by the
/// (2k+1)th thread is ignored in the value aggregation. Therefore
/// we copy the Reduce list from the (2k+1)th lane to (k+1)th lane so
/// that the contiguity assumption still holds.
static llvm::Value *emitShuffleAndReduceFunction(
CodeGenModule &CGM, ArrayRef<const Expr *> Privates,
QualType ReductionArrayTy, llvm::Value *ReduceFn, SourceLocation Loc) {
ASTContext &C = CGM.getContext();
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// Thread local Reduce list used to host the values of data to be reduced.
ImplicitParamDecl ReduceListArg(C, /*DC=*/nullptr, Loc, /*Id=*/nullptr,
C.VoidPtrTy, ImplicitParamDecl::Other);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// Current lane id; could be logical.
ImplicitParamDecl LaneIDArg(C, /*DC=*/nullptr, Loc, /*Id=*/nullptr, C.ShortTy,
ImplicitParamDecl::Other);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// Offset of the remote source lane relative to the current lane.
ImplicitParamDecl RemoteLaneOffsetArg(C, /*DC=*/nullptr, Loc, /*Id=*/nullptr,
C.ShortTy, ImplicitParamDecl::Other);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// Algorithm version. This is expected to be known at compile time.
ImplicitParamDecl AlgoVerArg(C, /*DC=*/nullptr, Loc, /*Id=*/nullptr,
C.ShortTy, ImplicitParamDecl::Other);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
FunctionArgList Args;
Args.push_back(&ReduceListArg);
Args.push_back(&LaneIDArg);
Args.push_back(&RemoteLaneOffsetArg);
Args.push_back(&AlgoVerArg);
const CGFunctionInfo &CGFI =
CGM.getTypes().arrangeBuiltinFunctionDeclaration(C.VoidTy, Args);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
auto *Fn = llvm::Function::Create(
CGM.getTypes().GetFunctionType(CGFI), llvm::GlobalValue::InternalLinkage,
"_omp_reduction_shuffle_and_reduce_func", &CGM.getModule());
CGM.SetInternalFunctionAttributes(GlobalDecl(), Fn, CGFI);
Fn->setDoesNotRecurse();
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
CodeGenFunction CGF(CGM);
CGF.StartFunction(GlobalDecl(), C.VoidTy, Fn, CGFI, Args, Loc, Loc);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
CGBuilderTy &Bld = CGF.Builder;
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
Address AddrReduceListArg = CGF.GetAddrOfLocalVar(&ReduceListArg);
Address LocalReduceList(
Bld.CreatePointerBitCastOrAddrSpaceCast(
CGF.EmitLoadOfScalar(AddrReduceListArg, /*Volatile=*/false,
C.VoidPtrTy, SourceLocation()),
CGF.ConvertTypeForMem(ReductionArrayTy)->getPointerTo()),
CGF.getPointerAlign());
Address AddrLaneIDArg = CGF.GetAddrOfLocalVar(&LaneIDArg);
llvm::Value *LaneIDArgVal = CGF.EmitLoadOfScalar(
AddrLaneIDArg, /*Volatile=*/false, C.ShortTy, SourceLocation());
Address AddrRemoteLaneOffsetArg = CGF.GetAddrOfLocalVar(&RemoteLaneOffsetArg);
llvm::Value *RemoteLaneOffsetArgVal = CGF.EmitLoadOfScalar(
AddrRemoteLaneOffsetArg, /*Volatile=*/false, C.ShortTy, SourceLocation());
Address AddrAlgoVerArg = CGF.GetAddrOfLocalVar(&AlgoVerArg);
llvm::Value *AlgoVerArgVal = CGF.EmitLoadOfScalar(
AddrAlgoVerArg, /*Volatile=*/false, C.ShortTy, SourceLocation());
// Create a local thread-private variable to host the Reduce list
// from a remote lane.
Address RemoteReduceList =
CGF.CreateMemTemp(ReductionArrayTy, ".omp.reduction.remote_reduce_list");
// This loop iterates through the list of reduce elements and copies,
// element by element, from a remote lane in the warp to RemoteReduceList,
// hosted on the thread's stack.
emitReductionListCopy(RemoteLaneToThread, CGF, ReductionArrayTy, Privates,
LocalReduceList, RemoteReduceList,
{/*RemoteLaneOffset=*/RemoteLaneOffsetArgVal,
/*ScratchpadIndex=*/nullptr,
/*ScratchpadWidth=*/nullptr});
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// The actions to be performed on the Remote Reduce list is dependent
// on the algorithm version.
//
// if (AlgoVer==0) || (AlgoVer==1 && (LaneId < Offset)) || (AlgoVer==2 &&
// LaneId % 2 == 0 && Offset > 0):
// do the reduction value aggregation
//
// The thread local variable Reduce list is mutated in place to host the
// reduced data, which is the aggregated value produced from local and
// remote lanes.
//
// Note that AlgoVer is expected to be a constant integer known at compile
// time.
// When AlgoVer==0, the first conjunction evaluates to true, making
// the entire predicate true during compile time.
// When AlgoVer==1, the second conjunction has only the second part to be
// evaluated during runtime. Other conjunctions evaluates to false
// during compile time.
// When AlgoVer==2, the third conjunction has only the second part to be
// evaluated during runtime. Other conjunctions evaluates to false
// during compile time.
llvm::Value *CondAlgo0 = Bld.CreateIsNull(AlgoVerArgVal);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
llvm::Value *Algo1 = Bld.CreateICmpEQ(AlgoVerArgVal, Bld.getInt16(1));
llvm::Value *CondAlgo1 = Bld.CreateAnd(
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
Algo1, Bld.CreateICmpULT(LaneIDArgVal, RemoteLaneOffsetArgVal));
llvm::Value *Algo2 = Bld.CreateICmpEQ(AlgoVerArgVal, Bld.getInt16(2));
llvm::Value *CondAlgo2 = Bld.CreateAnd(
Algo2, Bld.CreateIsNull(Bld.CreateAnd(LaneIDArgVal, Bld.getInt16(1))));
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
CondAlgo2 = Bld.CreateAnd(
CondAlgo2, Bld.CreateICmpSGT(RemoteLaneOffsetArgVal, Bld.getInt16(0)));
llvm::Value *CondReduce = Bld.CreateOr(CondAlgo0, CondAlgo1);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
CondReduce = Bld.CreateOr(CondReduce, CondAlgo2);
llvm::BasicBlock *ThenBB = CGF.createBasicBlock("then");
llvm::BasicBlock *ElseBB = CGF.createBasicBlock("else");
llvm::BasicBlock *MergeBB = CGF.createBasicBlock("ifcont");
Bld.CreateCondBr(CondReduce, ThenBB, ElseBB);
CGF.EmitBlock(ThenBB);
// reduce_function(LocalReduceList, RemoteReduceList)
llvm::Value *LocalReduceListPtr = Bld.CreatePointerBitCastOrAddrSpaceCast(
LocalReduceList.getPointer(), CGF.VoidPtrTy);
llvm::Value *RemoteReduceListPtr = Bld.CreatePointerBitCastOrAddrSpaceCast(
RemoteReduceList.getPointer(), CGF.VoidPtrTy);
CGM.getOpenMPRuntime().emitOutlinedFunctionCall(
CGF, Loc, ReduceFn, {LocalReduceListPtr, RemoteReduceListPtr});
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
Bld.CreateBr(MergeBB);
CGF.EmitBlock(ElseBB);
Bld.CreateBr(MergeBB);
CGF.EmitBlock(MergeBB);
// if (AlgoVer==1 && (LaneId >= Offset)) copy Remote Reduce list to local
// Reduce list.
Algo1 = Bld.CreateICmpEQ(AlgoVerArgVal, Bld.getInt16(1));
llvm::Value *CondCopy = Bld.CreateAnd(
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
Algo1, Bld.CreateICmpUGE(LaneIDArgVal, RemoteLaneOffsetArgVal));
llvm::BasicBlock *CpyThenBB = CGF.createBasicBlock("then");
llvm::BasicBlock *CpyElseBB = CGF.createBasicBlock("else");
llvm::BasicBlock *CpyMergeBB = CGF.createBasicBlock("ifcont");
Bld.CreateCondBr(CondCopy, CpyThenBB, CpyElseBB);
CGF.EmitBlock(CpyThenBB);
emitReductionListCopy(ThreadCopy, CGF, ReductionArrayTy, Privates,
RemoteReduceList, LocalReduceList);
Bld.CreateBr(CpyMergeBB);
CGF.EmitBlock(CpyElseBB);
Bld.CreateBr(CpyMergeBB);
CGF.EmitBlock(CpyMergeBB);
CGF.FinishFunction();
return Fn;
}
///
/// Design of OpenMP reductions on the GPU
///
/// Consider a typical OpenMP program with one or more reduction
/// clauses:
///
/// float foo;
/// double bar;
/// #pragma omp target teams distribute parallel for \
/// reduction(+:foo) reduction(*:bar)
/// for (int i = 0; i < N; i++) {
/// foo += A[i]; bar *= B[i];
/// }
///
/// where 'foo' and 'bar' are reduced across all OpenMP threads in
/// all teams. In our OpenMP implementation on the NVPTX device an
/// OpenMP team is mapped to a CUDA threadblock and OpenMP threads
/// within a team are mapped to CUDA threads within a threadblock.
/// Our goal is to efficiently aggregate values across all OpenMP
/// threads such that:
///
/// - the compiler and runtime are logically concise, and
/// - the reduction is performed efficiently in a hierarchical
/// manner as follows: within OpenMP threads in the same warp,
/// across warps in a threadblock, and finally across teams on
/// the NVPTX device.
///
/// Introduction to Decoupling
///
/// We would like to decouple the compiler and the runtime so that the
/// latter is ignorant of the reduction variables (number, data types)
/// and the reduction operators. This allows a simpler interface
/// and implementation while still attaining good performance.
///
/// Pseudocode for the aforementioned OpenMP program generated by the
/// compiler is as follows:
///
/// 1. Create private copies of reduction variables on each OpenMP
/// thread: 'foo_private', 'bar_private'
/// 2. Each OpenMP thread reduces the chunk of 'A' and 'B' assigned
/// to it and writes the result in 'foo_private' and 'bar_private'
/// respectively.
/// 3. Call the OpenMP runtime on the GPU to reduce within a team
/// and store the result on the team master:
///
/// __kmpc_nvptx_parallel_reduce_nowait(...,
/// reduceData, shuffleReduceFn, interWarpCpyFn)
///
/// where:
/// struct ReduceData {
/// double *foo;
/// double *bar;
/// } reduceData
/// reduceData.foo = &foo_private
/// reduceData.bar = &bar_private
///
/// 'shuffleReduceFn' and 'interWarpCpyFn' are pointers to two
/// auxiliary functions generated by the compiler that operate on
/// variables of type 'ReduceData'. They aid the runtime perform
/// algorithmic steps in a data agnostic manner.
///
/// 'shuffleReduceFn' is a pointer to a function that reduces data
/// of type 'ReduceData' across two OpenMP threads (lanes) in the
/// same warp. It takes the following arguments as input:
///
/// a. variable of type 'ReduceData' on the calling lane,
/// b. its lane_id,
/// c. an offset relative to the current lane_id to generate a
/// remote_lane_id. The remote lane contains the second
/// variable of type 'ReduceData' that is to be reduced.
/// d. an algorithm version parameter determining which reduction
/// algorithm to use.
///
/// 'shuffleReduceFn' retrieves data from the remote lane using
/// efficient GPU shuffle intrinsics and reduces, using the
/// algorithm specified by the 4th parameter, the two operands
/// element-wise. The result is written to the first operand.
///
/// Different reduction algorithms are implemented in different
/// runtime functions, all calling 'shuffleReduceFn' to perform
/// the essential reduction step. Therefore, based on the 4th
/// parameter, this function behaves slightly differently to
/// cooperate with the runtime to ensure correctness under
/// different circumstances.
///
/// 'InterWarpCpyFn' is a pointer to a function that transfers
/// reduced variables across warps. It tunnels, through CUDA
/// shared memory, the thread-private data of type 'ReduceData'
/// from lane 0 of each warp to a lane in the first warp.
/// 4. Call the OpenMP runtime on the GPU to reduce across teams.
/// The last team writes the global reduced value to memory.
///
/// ret = __kmpc_nvptx_teams_reduce_nowait(...,
/// reduceData, shuffleReduceFn, interWarpCpyFn,
/// scratchpadCopyFn, loadAndReduceFn)
///
/// 'scratchpadCopyFn' is a helper that stores reduced
/// data from the team master to a scratchpad array in
/// global memory.
///
/// 'loadAndReduceFn' is a helper that loads data from
/// the scratchpad array and reduces it with the input
/// operand.
///
/// These compiler generated functions hide address
/// calculation and alignment information from the runtime.
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
/// 5. if ret == 1:
/// The team master of the last team stores the reduced
/// result to the globals in memory.
/// foo += reduceData.foo; bar *= reduceData.bar
///
///
/// Warp Reduction Algorithms
///
/// On the warp level, we have three algorithms implemented in the
/// OpenMP runtime depending on the number of active lanes:
///
/// Full Warp Reduction
///
/// The reduce algorithm within a warp where all lanes are active
/// is implemented in the runtime as follows:
///
/// full_warp_reduce(void *reduce_data,
/// kmp_ShuffleReductFctPtr ShuffleReduceFn) {
/// for (int offset = WARPSIZE/2; offset > 0; offset /= 2)
/// ShuffleReduceFn(reduce_data, 0, offset, 0);
/// }
///
/// The algorithm completes in log(2, WARPSIZE) steps.
///
/// 'ShuffleReduceFn' is used here with lane_id set to 0 because it is
/// not used therefore we save instructions by not retrieving lane_id
/// from the corresponding special registers. The 4th parameter, which
/// represents the version of the algorithm being used, is set to 0 to
/// signify full warp reduction.
///
/// In this version, 'ShuffleReduceFn' behaves, per element, as follows:
///
/// #reduce_elem refers to an element in the local lane's data structure
/// #remote_elem is retrieved from a remote lane
/// remote_elem = shuffle_down(reduce_elem, offset, WARPSIZE);
/// reduce_elem = reduce_elem REDUCE_OP remote_elem;
///
/// Contiguous Partial Warp Reduction
///
/// This reduce algorithm is used within a warp where only the first
/// 'n' (n <= WARPSIZE) lanes are active. It is typically used when the
/// number of OpenMP threads in a parallel region is not a multiple of
/// WARPSIZE. The algorithm is implemented in the runtime as follows:
///
/// void
/// contiguous_partial_reduce(void *reduce_data,
/// kmp_ShuffleReductFctPtr ShuffleReduceFn,
/// int size, int lane_id) {
/// int curr_size;
/// int offset;
/// curr_size = size;
/// mask = curr_size/2;
/// while (offset>0) {
/// ShuffleReduceFn(reduce_data, lane_id, offset, 1);
/// curr_size = (curr_size+1)/2;
/// offset = curr_size/2;
/// }
/// }
///
/// In this version, 'ShuffleReduceFn' behaves, per element, as follows:
///
/// remote_elem = shuffle_down(reduce_elem, offset, WARPSIZE);
/// if (lane_id < offset)
/// reduce_elem = reduce_elem REDUCE_OP remote_elem
/// else
/// reduce_elem = remote_elem
///
/// This algorithm assumes that the data to be reduced are located in a
/// contiguous subset of lanes starting from the first. When there is
/// an odd number of active lanes, the data in the last lane is not
/// aggregated with any other lane's dat but is instead copied over.
///
/// Dispersed Partial Warp Reduction
///
/// This algorithm is used within a warp when any discontiguous subset of
/// lanes are active. It is used to implement the reduction operation
/// across lanes in an OpenMP simd region or in a nested parallel region.
///
/// void
/// dispersed_partial_reduce(void *reduce_data,
/// kmp_ShuffleReductFctPtr ShuffleReduceFn) {
/// int size, remote_id;
/// int logical_lane_id = number_of_active_lanes_before_me() * 2;
/// do {
/// remote_id = next_active_lane_id_right_after_me();
/// # the above function returns 0 of no active lane
/// # is present right after the current lane.
/// size = number_of_active_lanes_in_this_warp();
/// logical_lane_id /= 2;
/// ShuffleReduceFn(reduce_data, logical_lane_id,
/// remote_id-1-threadIdx.x, 2);
/// } while (logical_lane_id % 2 == 0 && size > 1);
/// }
///
/// There is no assumption made about the initial state of the reduction.
/// Any number of lanes (>=1) could be active at any position. The reduction
/// result is returned in the first active lane.
///
/// In this version, 'ShuffleReduceFn' behaves, per element, as follows:
///
/// remote_elem = shuffle_down(reduce_elem, offset, WARPSIZE);
/// if (lane_id % 2 == 0 && offset > 0)
/// reduce_elem = reduce_elem REDUCE_OP remote_elem
/// else
/// reduce_elem = remote_elem
///
///
/// Intra-Team Reduction
///
/// This function, as implemented in the runtime call
/// '__kmpc_nvptx_parallel_reduce_nowait', aggregates data across OpenMP
/// threads in a team. It first reduces within a warp using the
/// aforementioned algorithms. We then proceed to gather all such
/// reduced values at the first warp.
///
/// The runtime makes use of the function 'InterWarpCpyFn', which copies
/// data from each of the "warp master" (zeroth lane of each warp, where
/// warp-reduced data is held) to the zeroth warp. This step reduces (in
/// a mathematical sense) the problem of reduction across warp masters in
/// a block to the problem of warp reduction.
///
///
/// Inter-Team Reduction
///
/// Once a team has reduced its data to a single value, it is stored in
/// a global scratchpad array. Since each team has a distinct slot, this
/// can be done without locking.
///
/// The last team to write to the scratchpad array proceeds to reduce the
/// scratchpad array. One or more workers in the last team use the helper
/// 'loadAndReduceDataFn' to load and reduce values from the array, i.e.,
/// the k'th worker reduces every k'th element.
///
/// Finally, a call is made to '__kmpc_nvptx_parallel_reduce_nowait' to
/// reduce across workers and compute a globally reduced value.
///
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
void CGOpenMPRuntimeNVPTX::emitReduction(
CodeGenFunction &CGF, SourceLocation Loc, ArrayRef<const Expr *> Privates,
ArrayRef<const Expr *> LHSExprs, ArrayRef<const Expr *> RHSExprs,
ArrayRef<const Expr *> ReductionOps, ReductionOptionsTy Options) {
if (!CGF.HaveInsertPoint())
return;
bool ParallelReduction = isOpenMPParallelDirective(Options.ReductionKind);
#ifndef NDEBUG
bool TeamsReduction = isOpenMPTeamsDirective(Options.ReductionKind);
#endif
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
if (Options.SimpleReduction) {
assert(!TeamsReduction && !ParallelReduction &&
"Invalid reduction selection in emitReduction.");
CGOpenMPRuntime::emitReduction(CGF, Loc, Privates, LHSExprs, RHSExprs,
ReductionOps, Options);
return;
}
assert((TeamsReduction || ParallelReduction) &&
"Invalid reduction selection in emitReduction.");
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// Build res = __kmpc_reduce{_nowait}(<gtid>, <n>, sizeof(RedList),
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// RedList, shuffle_reduce_func, interwarp_copy_func);
// or
// Build res = __kmpc_reduce_teams_nowait_simple(<loc>, <gtid>, <lck>);
llvm::Value *ThreadId = getThreadID(CGF, Loc);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
llvm::Value *Res;
if (ParallelReduction) {
ASTContext &C = CGM.getContext();
// 1. Build a list of reduction variables.
// void *RedList[<n>] = {<ReductionVars>[0], ..., <ReductionVars>[<n>-1]};
auto Size = RHSExprs.size();
for (const Expr *E : Privates) {
if (E->getType()->isVariablyModifiedType())
// Reserve place for array size.
++Size;
}
llvm::APInt ArraySize(/*unsigned int numBits=*/32, Size);
QualType ReductionArrayTy =
C.getConstantArrayType(C.VoidPtrTy, ArraySize, ArrayType::Normal,
/*IndexTypeQuals=*/0);
Address ReductionList =
CGF.CreateMemTemp(ReductionArrayTy, ".omp.reduction.red_list");
auto IPriv = Privates.begin();
unsigned Idx = 0;
for (unsigned I = 0, E = RHSExprs.size(); I < E; ++I, ++IPriv, ++Idx) {
Address Elem = CGF.Builder.CreateConstArrayGEP(ReductionList, Idx,
CGF.getPointerSize());
CGF.Builder.CreateStore(
CGF.Builder.CreatePointerBitCastOrAddrSpaceCast(
CGF.EmitLValue(RHSExprs[I]).getPointer(), CGF.VoidPtrTy),
Elem);
if ((*IPriv)->getType()->isVariablyModifiedType()) {
// Store array size.
++Idx;
Elem = CGF.Builder.CreateConstArrayGEP(ReductionList, Idx,
CGF.getPointerSize());
llvm::Value *Size = CGF.Builder.CreateIntCast(
CGF.getVLASize(
CGF.getContext().getAsVariableArrayType((*IPriv)->getType()))
.NumElts,
CGF.SizeTy, /*isSigned=*/false);
CGF.Builder.CreateStore(CGF.Builder.CreateIntToPtr(Size, CGF.VoidPtrTy),
Elem);
}
}
llvm::Value *ReductionArrayTySize = CGF.getTypeSize(ReductionArrayTy);
llvm::Value *RL = CGF.Builder.CreatePointerBitCastOrAddrSpaceCast(
ReductionList.getPointer(), CGF.VoidPtrTy);
llvm::Value *ReductionFn = emitReductionFunction(
CGM, Loc, CGF.ConvertTypeForMem(ReductionArrayTy)->getPointerTo(),
Privates, LHSExprs, RHSExprs, ReductionOps);
llvm::Value *ShuffleAndReduceFn = emitShuffleAndReduceFunction(
CGM, Privates, ReductionArrayTy, ReductionFn, Loc);
llvm::Value *InterWarpCopyFn =
emitInterWarpCopyFunction(CGM, Privates, ReductionArrayTy, Loc);
llvm::Value *Args[] = {ThreadId,
CGF.Builder.getInt32(RHSExprs.size()),
ReductionArrayTySize,
RL,
ShuffleAndReduceFn,
InterWarpCopyFn};
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
Res = CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_parallel_reduce_nowait),
Args);
} else {
assert(TeamsReduction && "expected teams reduction.");
llvm::Value *RTLoc = emitUpdateLocation(CGF, Loc);
std::string Name = getName({"reduction"});
llvm::Value *Lock = getCriticalRegionLock(Name);
llvm::Value *Args[] = {RTLoc, ThreadId, Lock};
Res = CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(
OMPRTL_NVPTX__kmpc_nvptx_teams_reduce_nowait_simple),
Args);
}
// 5. Build if (res == 1)
llvm::BasicBlock *ExitBB = CGF.createBasicBlock(".omp.reduction.done");
llvm::BasicBlock *ThenBB = CGF.createBasicBlock(".omp.reduction.then");
llvm::Value *Cond = CGF.Builder.CreateICmpEQ(
Res, llvm::ConstantInt::get(CGM.Int32Ty, /*V=*/1));
CGF.Builder.CreateCondBr(Cond, ThenBB, ExitBB);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// 6. Build then branch: where we have reduced values in the master
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// thread in each team.
// __kmpc_end_reduce{_nowait}(<gtid>);
// break;
CGF.EmitBlock(ThenBB);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
// Add emission of __kmpc_end_reduce{_nowait}(<gtid>);
auto &&CodeGen = [Privates, LHSExprs, RHSExprs, ReductionOps,
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
this](CodeGenFunction &CGF, PrePostActionTy &Action) {
auto IPriv = Privates.begin();
auto ILHS = LHSExprs.begin();
auto IRHS = RHSExprs.begin();
for (const Expr *E : ReductionOps) {
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
emitSingleReductionCombiner(CGF, E, *IPriv, cast<DeclRefExpr>(*ILHS),
cast<DeclRefExpr>(*IRHS));
++IPriv;
++ILHS;
++IRHS;
}
};
if (ParallelReduction) {
llvm::Value *EndArgs[] = {ThreadId};
RegionCodeGenTy RCG(CodeGen);
NVPTXActionTy Action(
nullptr, llvm::None,
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_end_reduce_nowait),
EndArgs);
RCG.setAction(Action);
RCG(CGF);
} else {
assert(TeamsReduction && "expected teams reduction.");
llvm::Value *RTLoc = emitUpdateLocation(CGF, Loc);
std::string Name = getName({"reduction"});
llvm::Value *Lock = getCriticalRegionLock(Name);
llvm::Value *EndArgs[] = {RTLoc, ThreadId, Lock};
RegionCodeGenTy RCG(CodeGen);
NVPTXActionTy Action(
nullptr, llvm::None,
createNVPTXRuntimeFunction(
OMPRTL_NVPTX__kmpc_nvptx_teams_end_reduce_nowait_simple),
EndArgs);
RCG.setAction(Action);
RCG(CGF);
}
// There is no need to emit line number for unconditional branch.
(void)ApplyDebugLocation::CreateEmpty(CGF);
CGF.EmitBlock(ExitBB, /*IsFinished=*/true);
[OpenMP] Parallel reduction on the NVPTX device. This patch implements codegen for the reduction clause on any parallel construct for elementary data types. An efficient implementation requires hierarchical reduction within a warp and a threadblock. It is complicated by the fact that variables declared in the stack of a CUDA thread cannot be shared with other threads. The patch creates a struct to hold reduction variables and a number of helper functions. The OpenMP runtime on the GPU implements reduction algorithms that uses these helper functions to perform reductions within a team. Variables are shared between CUDA threads using shuffle intrinsics. An implementation of reductions on the NVPTX device is substantially different to that of CPUs. However, this patch is written so that there are minimal changes to the rest of OpenMP codegen. The implemented design allows the compiler and runtime to be decoupled, i.e., the runtime does not need to know of the reduction operation(s), the type of the reduction variable(s), or the number of reductions. The design also allows reuse of host codegen, with appropriate specialization for the NVPTX device. While the patch does introduce a number of abstractions, the expected use case calls for inlining of the GPU OpenMP runtime. After inlining and optimizations in LLVM, these abstractions are unwound and performance of OpenMP reductions is comparable to CUDA-canonical code. Patch by Tian Jin in collaboration with Arpith Jacob Reviewers: ABataev Differential Revision: https://reviews.llvm.org/D29758 llvm-svn: 295333
2017-02-17 00:20:16 +08:00
}
const VarDecl *
CGOpenMPRuntimeNVPTX::translateParameter(const FieldDecl *FD,
const VarDecl *NativeParam) const {
if (!NativeParam->getType()->isReferenceType())
return NativeParam;
QualType ArgType = NativeParam->getType();
QualifierCollector QC;
const Type *NonQualTy = QC.strip(ArgType);
QualType PointeeTy = cast<ReferenceType>(NonQualTy)->getPointeeType();
if (const auto *Attr = FD->getAttr<OMPCaptureKindAttr>()) {
if (Attr->getCaptureKind() == OMPC_map) {
PointeeTy = CGM.getContext().getAddrSpaceQualType(PointeeTy,
LangAS::opencl_global);
}
}
ArgType = CGM.getContext().getPointerType(PointeeTy);
QC.addRestrict();
enum { NVPTX_local_addr = 5 };
Convert clang::LangAS to a strongly typed enum Summary: Convert clang::LangAS to a strongly typed enum Currently both clang AST address spaces and target specific address spaces are represented as unsigned which can lead to subtle errors if the wrong type is passed. It is especially confusing in the CodeGen files as it is not possible to see what kind of address space should be passed to a function without looking at the implementation. I originally made this change for our LLVM fork for the CHERI architecture where we make extensive use of address spaces to differentiate between capabilities and pointers. When merging the upstream changes I usually run into some test failures or runtime crashes because the wrong kind of address space is passed to a function. By converting the LangAS enum to a C++11 we can catch these errors at compile time. Additionally, it is now obvious from the function signature which kind of address space it expects. I found the following errors while writing this patch: - ItaniumRecordLayoutBuilder::LayoutField was passing a clang AST address space to TargetInfo::getPointer{Width,Align}() - TypePrinter::printAttributedAfter() prints the numeric value of the clang AST address space instead of the target address space. However, this code is not used so I kept the current behaviour - initializeForBlockHeader() in CGBlocks.cpp was passing LangAS::opencl_generic to TargetInfo::getPointer{Width,Align}() - CodeGenFunction::EmitBlockLiteral() was passing a AST address space to TargetInfo::getPointerWidth() - CGOpenMPRuntimeNVPTX::translateParameter() passed a target address space to Qualifiers::addAddressSpace() - CGOpenMPRuntimeNVPTX::getParameterAddress() was using llvm::Type::getPointerTo() with a AST address space - clang_getAddressSpace() returns either a LangAS or a target address space. As this is exposed to C I have kept the current behaviour and added a comment stating that it is probably not correct. Other than this the patch should not cause any functional changes. Reviewers: yaxunl, pcc, bader Reviewed By: yaxunl, bader Subscribers: jlebar, jholewinski, nhaehnle, Anastasia, cfe-commits Differential Revision: https://reviews.llvm.org/D38816 llvm-svn: 315871
2017-10-16 02:48:14 +08:00
QC.addAddressSpace(getLangASFromTargetAS(NVPTX_local_addr));
ArgType = QC.apply(CGM.getContext(), ArgType);
if (isa<ImplicitParamDecl>(NativeParam))
return ImplicitParamDecl::Create(
CGM.getContext(), /*DC=*/nullptr, NativeParam->getLocation(),
NativeParam->getIdentifier(), ArgType, ImplicitParamDecl::Other);
return ParmVarDecl::Create(
CGM.getContext(),
const_cast<DeclContext *>(NativeParam->getDeclContext()),
NativeParam->getBeginLoc(), NativeParam->getLocation(),
NativeParam->getIdentifier(), ArgType,
/*TInfo=*/nullptr, SC_None, /*DefArg=*/nullptr);
}
Address
CGOpenMPRuntimeNVPTX::getParameterAddress(CodeGenFunction &CGF,
const VarDecl *NativeParam,
const VarDecl *TargetParam) const {
assert(NativeParam != TargetParam &&
NativeParam->getType()->isReferenceType() &&
"Native arg must not be the same as target arg.");
Address LocalAddr = CGF.GetAddrOfLocalVar(TargetParam);
QualType NativeParamType = NativeParam->getType();
QualifierCollector QC;
const Type *NonQualTy = QC.strip(NativeParamType);
QualType NativePointeeTy = cast<ReferenceType>(NonQualTy)->getPointeeType();
unsigned NativePointeeAddrSpace =
Convert clang::LangAS to a strongly typed enum Summary: Convert clang::LangAS to a strongly typed enum Currently both clang AST address spaces and target specific address spaces are represented as unsigned which can lead to subtle errors if the wrong type is passed. It is especially confusing in the CodeGen files as it is not possible to see what kind of address space should be passed to a function without looking at the implementation. I originally made this change for our LLVM fork for the CHERI architecture where we make extensive use of address spaces to differentiate between capabilities and pointers. When merging the upstream changes I usually run into some test failures or runtime crashes because the wrong kind of address space is passed to a function. By converting the LangAS enum to a C++11 we can catch these errors at compile time. Additionally, it is now obvious from the function signature which kind of address space it expects. I found the following errors while writing this patch: - ItaniumRecordLayoutBuilder::LayoutField was passing a clang AST address space to TargetInfo::getPointer{Width,Align}() - TypePrinter::printAttributedAfter() prints the numeric value of the clang AST address space instead of the target address space. However, this code is not used so I kept the current behaviour - initializeForBlockHeader() in CGBlocks.cpp was passing LangAS::opencl_generic to TargetInfo::getPointer{Width,Align}() - CodeGenFunction::EmitBlockLiteral() was passing a AST address space to TargetInfo::getPointerWidth() - CGOpenMPRuntimeNVPTX::translateParameter() passed a target address space to Qualifiers::addAddressSpace() - CGOpenMPRuntimeNVPTX::getParameterAddress() was using llvm::Type::getPointerTo() with a AST address space - clang_getAddressSpace() returns either a LangAS or a target address space. As this is exposed to C I have kept the current behaviour and added a comment stating that it is probably not correct. Other than this the patch should not cause any functional changes. Reviewers: yaxunl, pcc, bader Reviewed By: yaxunl, bader Subscribers: jlebar, jholewinski, nhaehnle, Anastasia, cfe-commits Differential Revision: https://reviews.llvm.org/D38816 llvm-svn: 315871
2017-10-16 02:48:14 +08:00
CGF.getContext().getTargetAddressSpace(NativePointeeTy);
QualType TargetTy = TargetParam->getType();
llvm::Value *TargetAddr = CGF.EmitLoadOfScalar(
LocalAddr, /*Volatile=*/false, TargetTy, SourceLocation());
// First cast to generic.
TargetAddr = CGF.Builder.CreatePointerBitCastOrAddrSpaceCast(
TargetAddr, TargetAddr->getType()->getPointerElementType()->getPointerTo(
/*AddrSpace=*/0));
// Cast from generic to native address space.
TargetAddr = CGF.Builder.CreatePointerBitCastOrAddrSpaceCast(
TargetAddr, TargetAddr->getType()->getPointerElementType()->getPointerTo(
NativePointeeAddrSpace));
Address NativeParamAddr = CGF.CreateMemTemp(NativeParamType);
CGF.EmitStoreOfScalar(TargetAddr, NativeParamAddr, /*Volatile=*/false,
NativeParamType);
return NativeParamAddr;
}
void CGOpenMPRuntimeNVPTX::emitOutlinedFunctionCall(
CodeGenFunction &CGF, SourceLocation Loc, llvm::Value *OutlinedFn,
ArrayRef<llvm::Value *> Args) const {
SmallVector<llvm::Value *, 4> TargetArgs;
TargetArgs.reserve(Args.size());
auto *FnType =
cast<llvm::FunctionType>(OutlinedFn->getType()->getPointerElementType());
for (unsigned I = 0, E = Args.size(); I < E; ++I) {
if (FnType->isVarArg() && FnType->getNumParams() <= I) {
TargetArgs.append(std::next(Args.begin(), I), Args.end());
break;
}
llvm::Type *TargetType = FnType->getParamType(I);
llvm::Value *NativeArg = Args[I];
if (!TargetType->isPointerTy()) {
TargetArgs.emplace_back(NativeArg);
continue;
}
llvm::Value *TargetArg = CGF.Builder.CreatePointerBitCastOrAddrSpaceCast(
NativeArg,
NativeArg->getType()->getPointerElementType()->getPointerTo());
TargetArgs.emplace_back(
CGF.Builder.CreatePointerBitCastOrAddrSpaceCast(TargetArg, TargetType));
}
CGOpenMPRuntime::emitOutlinedFunctionCall(CGF, Loc, OutlinedFn, TargetArgs);
}
/// Emit function which wraps the outline parallel region
/// and controls the arguments which are passed to this function.
/// The wrapper ensures that the outlined function is called
/// with the correct arguments when data is shared.
llvm::Function *CGOpenMPRuntimeNVPTX::createParallelDataSharingWrapper(
llvm::Function *OutlinedParallelFn, const OMPExecutableDirective &D) {
ASTContext &Ctx = CGM.getContext();
const auto &CS = *D.getCapturedStmt(OMPD_parallel);
// Create a function that takes as argument the source thread.
FunctionArgList WrapperArgs;
QualType Int16QTy =
Ctx.getIntTypeForBitwidth(/*DestWidth=*/16, /*Signed=*/false);
QualType Int32QTy =
Ctx.getIntTypeForBitwidth(/*DestWidth=*/32, /*Signed=*/false);
ImplicitParamDecl ParallelLevelArg(Ctx, /*DC=*/nullptr, D.getBeginLoc(),
/*Id=*/nullptr, Int16QTy,
ImplicitParamDecl::Other);
ImplicitParamDecl WrapperArg(Ctx, /*DC=*/nullptr, D.getBeginLoc(),
/*Id=*/nullptr, Int32QTy,
ImplicitParamDecl::Other);
WrapperArgs.emplace_back(&ParallelLevelArg);
WrapperArgs.emplace_back(&WrapperArg);
const CGFunctionInfo &CGFI =
CGM.getTypes().arrangeBuiltinFunctionDeclaration(Ctx.VoidTy, WrapperArgs);
auto *Fn = llvm::Function::Create(
CGM.getTypes().GetFunctionType(CGFI), llvm::GlobalValue::InternalLinkage,
Twine(OutlinedParallelFn->getName(), "_wrapper"), &CGM.getModule());
CGM.SetInternalFunctionAttributes(GlobalDecl(), Fn, CGFI);
Fn->setLinkage(llvm::GlobalValue::InternalLinkage);
Fn->setDoesNotRecurse();
CodeGenFunction CGF(CGM, /*suppressNewContext=*/true);
CGF.StartFunction(GlobalDecl(), Ctx.VoidTy, Fn, CGFI, WrapperArgs,
D.getBeginLoc(), D.getBeginLoc());
const auto *RD = CS.getCapturedRecordDecl();
auto CurField = RD->field_begin();
Address ZeroAddr = CGF.CreateMemTemp(
CGF.getContext().getIntTypeForBitwidth(/*DestWidth=*/32, /*Signed=*/1),
/*Name*/ ".zero.addr");
CGF.InitTempAlloca(ZeroAddr, CGF.Builder.getInt32(/*C*/ 0));
// Get the array of arguments.
SmallVector<llvm::Value *, 8> Args;
Args.emplace_back(CGF.GetAddrOfLocalVar(&WrapperArg).getPointer());
Args.emplace_back(ZeroAddr.getPointer());
CGBuilderTy &Bld = CGF.Builder;
auto CI = CS.capture_begin();
// Use global memory for data sharing.
// Handle passing of global args to workers.
Address GlobalArgs =
CGF.CreateDefaultAlignTempAlloca(CGF.VoidPtrPtrTy, "global_args");
llvm::Value *GlobalArgsPtr = GlobalArgs.getPointer();
llvm::Value *DataSharingArgs[] = {GlobalArgsPtr};
CGF.EmitRuntimeCall(
createNVPTXRuntimeFunction(OMPRTL_NVPTX__kmpc_get_shared_variables),
DataSharingArgs);
// Retrieve the shared variables from the list of references returned
// by the runtime. Pass the variables to the outlined function.
Address SharedArgListAddress = Address::invalid();
if (CS.capture_size() > 0 ||
isOpenMPLoopBoundSharingDirective(D.getDirectiveKind())) {
SharedArgListAddress = CGF.EmitLoadOfPointer(
GlobalArgs, CGF.getContext()
.getPointerType(CGF.getContext().getPointerType(
CGF.getContext().VoidPtrTy))
.castAs<PointerType>());
}
unsigned Idx = 0;
if (isOpenMPLoopBoundSharingDirective(D.getDirectiveKind())) {
Address Src = Bld.CreateConstInBoundsGEP(SharedArgListAddress, Idx,
CGF.getPointerSize());
Address TypedAddress = Bld.CreatePointerBitCastOrAddrSpaceCast(
Src, CGF.SizeTy->getPointerTo());
llvm::Value *LB = CGF.EmitLoadOfScalar(
TypedAddress,
/*Volatile=*/false,
CGF.getContext().getPointerType(CGF.getContext().getSizeType()),
cast<OMPLoopDirective>(D).getLowerBoundVariable()->getExprLoc());
Args.emplace_back(LB);
++Idx;
Src = Bld.CreateConstInBoundsGEP(SharedArgListAddress, Idx,
CGF.getPointerSize());
TypedAddress = Bld.CreatePointerBitCastOrAddrSpaceCast(
Src, CGF.SizeTy->getPointerTo());
llvm::Value *UB = CGF.EmitLoadOfScalar(
TypedAddress,
/*Volatile=*/false,
CGF.getContext().getPointerType(CGF.getContext().getSizeType()),
cast<OMPLoopDirective>(D).getUpperBoundVariable()->getExprLoc());
Args.emplace_back(UB);
++Idx;
}
if (CS.capture_size() > 0) {
ASTContext &CGFContext = CGF.getContext();
for (unsigned I = 0, E = CS.capture_size(); I < E; ++I, ++CI, ++CurField) {
QualType ElemTy = CurField->getType();
Address Src = Bld.CreateConstInBoundsGEP(SharedArgListAddress, I + Idx,
CGF.getPointerSize());
Address TypedAddress = Bld.CreatePointerBitCastOrAddrSpaceCast(
Src, CGF.ConvertTypeForMem(CGFContext.getPointerType(ElemTy)));
llvm::Value *Arg = CGF.EmitLoadOfScalar(TypedAddress,
/*Volatile=*/false,
CGFContext.getPointerType(ElemTy),
CI->getLocation());
if (CI->capturesVariableByCopy() &&
!CI->getCapturedVar()->getType()->isAnyPointerType()) {
Arg = castValueToType(CGF, Arg, ElemTy, CGFContext.getUIntPtrType(),
CI->getLocation());
}
Args.emplace_back(Arg);
}
}
emitOutlinedFunctionCall(CGF, D.getBeginLoc(), OutlinedParallelFn, Args);
CGF.FinishFunction();
return Fn;
}
void CGOpenMPRuntimeNVPTX::emitFunctionProlog(CodeGenFunction &CGF,
const Decl *D) {
if (getDataSharingMode(CGM) != CGOpenMPRuntimeNVPTX::Generic)
return;
assert(D && "Expected function or captured|block decl.");
assert(FunctionGlobalizedDecls.count(CGF.CurFn) == 0 &&
"Function is registered already.");
assert((!TeamAndReductions.first || TeamAndReductions.first == D) &&
"Team is set but not processed.");
const Stmt *Body = nullptr;
bool NeedToDelayGlobalization = false;
if (const auto *FD = dyn_cast<FunctionDecl>(D)) {
Body = FD->getBody();
} else if (const auto *BD = dyn_cast<BlockDecl>(D)) {
Body = BD->getBody();
} else if (const auto *CD = dyn_cast<CapturedDecl>(D)) {
Body = CD->getBody();
NeedToDelayGlobalization = CGF.CapturedStmtInfo->getKind() == CR_OpenMP;
if (NeedToDelayGlobalization &&
getExecutionMode() == CGOpenMPRuntimeNVPTX::EM_SPMD)
return;
}
if (!Body)
return;
CheckVarsEscapingDeclContext VarChecker(CGF, TeamAndReductions.second);
VarChecker.Visit(Body);
const RecordDecl *GlobalizedVarsRecord =
VarChecker.getGlobalizedRecord(IsInTTDRegion);
TeamAndReductions.first = nullptr;
TeamAndReductions.second.clear();
ArrayRef<const ValueDecl *> EscapedVariableLengthDecls =
VarChecker.getEscapedVariableLengthDecls();
if (!GlobalizedVarsRecord && EscapedVariableLengthDecls.empty())
return;
auto I = FunctionGlobalizedDecls.try_emplace(CGF.CurFn).first;
I->getSecond().MappedParams =
llvm::make_unique<CodeGenFunction::OMPMapVars>();
I->getSecond().GlobalRecord = GlobalizedVarsRecord;
I->getSecond().EscapedParameters.insert(
VarChecker.getEscapedParameters().begin(),
VarChecker.getEscapedParameters().end());
I->getSecond().EscapedVariableLengthDecls.append(
EscapedVariableLengthDecls.begin(), EscapedVariableLengthDecls.end());
DeclToAddrMapTy &Data = I->getSecond().LocalVarData;
for (const ValueDecl *VD : VarChecker.getEscapedDecls()) {
assert(VD->isCanonicalDecl() && "Expected canonical declaration");
const FieldDecl *FD = VarChecker.getFieldForGlobalizedVar(VD);
Data.insert(std::make_pair(VD, MappedVarData(FD, IsInTTDRegion)));
}
if (!IsInTTDRegion && !NeedToDelayGlobalization && !IsInParallelRegion) {
CheckVarsEscapingDeclContext VarChecker(CGF, llvm::None);
VarChecker.Visit(Body);
I->getSecond().SecondaryGlobalRecord =
VarChecker.getGlobalizedRecord(/*IsInTTDRegion=*/true);
I->getSecond().SecondaryLocalVarData.emplace();
DeclToAddrMapTy &Data = I->getSecond().SecondaryLocalVarData.getValue();
for (const ValueDecl *VD : VarChecker.getEscapedDecls()) {
assert(VD->isCanonicalDecl() && "Expected canonical declaration");
const FieldDecl *FD = VarChecker.getFieldForGlobalizedVar(VD);
Data.insert(
std::make_pair(VD, MappedVarData(FD, /*IsInTTDRegion=*/true)));
}
}
if (!NeedToDelayGlobalization) {
emitGenericVarsProlog(CGF, D->getBeginLoc(), /*WithSPMDCheck=*/true);
struct GlobalizationScope final : EHScopeStack::Cleanup {
GlobalizationScope() = default;
void Emit(CodeGenFunction &CGF, Flags flags) override {
static_cast<CGOpenMPRuntimeNVPTX &>(CGF.CGM.getOpenMPRuntime())
.emitGenericVarsEpilog(CGF, /*WithSPMDCheck=*/true);
}
};
CGF.EHStack.pushCleanup<GlobalizationScope>(NormalAndEHCleanup);
}
}
Address CGOpenMPRuntimeNVPTX::getAddressOfLocalVariable(CodeGenFunction &CGF,
const VarDecl *VD) {
if (getDataSharingMode(CGM) != CGOpenMPRuntimeNVPTX::Generic)
return Address::invalid();
VD = VD->getCanonicalDecl();
auto I = FunctionGlobalizedDecls.find(CGF.CurFn);
if (I == FunctionGlobalizedDecls.end())
return Address::invalid();
auto VDI = I->getSecond().LocalVarData.find(VD);
if (VDI != I->getSecond().LocalVarData.end())
return VDI->second.PrivateAddr;
if (VD->hasAttrs()) {
for (specific_attr_iterator<OMPReferencedVarAttr> IT(VD->attr_begin()),
E(VD->attr_end());
IT != E; ++IT) {
auto VDI = I->getSecond().LocalVarData.find(
cast<VarDecl>(cast<DeclRefExpr>(IT->getRef())->getDecl())
->getCanonicalDecl());
if (VDI != I->getSecond().LocalVarData.end())
return VDI->second.PrivateAddr;
}
}
return Address::invalid();
}
void CGOpenMPRuntimeNVPTX::functionFinished(CodeGenFunction &CGF) {
FunctionGlobalizedDecls.erase(CGF.CurFn);
CGOpenMPRuntime::functionFinished(CGF);
}
void CGOpenMPRuntimeNVPTX::getDefaultDistScheduleAndChunk(
CodeGenFunction &CGF, const OMPLoopDirective &S,
OpenMPDistScheduleClauseKind &ScheduleKind,
llvm::Value *&Chunk) const {
if (getExecutionMode() == CGOpenMPRuntimeNVPTX::EM_SPMD) {
ScheduleKind = OMPC_DIST_SCHEDULE_static;
Chunk = CGF.EmitScalarConversion(getNVPTXNumThreads(CGF),
CGF.getContext().getIntTypeForBitwidth(32, /*Signed=*/0),
S.getIterationVariable()->getType(), S.getBeginLoc());
return;
}
CGOpenMPRuntime::getDefaultDistScheduleAndChunk(
CGF, S, ScheduleKind, Chunk);
}
void CGOpenMPRuntimeNVPTX::getDefaultScheduleAndChunk(
CodeGenFunction &CGF, const OMPLoopDirective &S,
OpenMPScheduleClauseKind &ScheduleKind,
const Expr *&ChunkExpr) const {
ScheduleKind = OMPC_SCHEDULE_static;
// Chunk size is 1 in this case.
llvm::APInt ChunkSize(32, 1);
ChunkExpr = IntegerLiteral::Create(CGF.getContext(), ChunkSize,
CGF.getContext().getIntTypeForBitwidth(32, /*Signed=*/0),
SourceLocation());
}
void CGOpenMPRuntimeNVPTX::adjustTargetSpecificDataForLambdas(
CodeGenFunction &CGF, const OMPExecutableDirective &D) const {
assert(isOpenMPTargetExecutionDirective(D.getDirectiveKind()) &&
" Expected target-based directive.");
const CapturedStmt *CS = D.getCapturedStmt(OMPD_target);
for (const CapturedStmt::Capture &C : CS->captures()) {
// Capture variables captured by reference in lambdas for target-based
// directives.
if (!C.capturesVariable())
continue;
const VarDecl *VD = C.getCapturedVar();
const auto *RD = VD->getType()
.getCanonicalType()
.getNonReferenceType()
->getAsCXXRecordDecl();
if (!RD || !RD->isLambda())
continue;
Address VDAddr = CGF.GetAddrOfLocalVar(VD);
LValue VDLVal;
if (VD->getType().getCanonicalType()->isReferenceType())
VDLVal = CGF.EmitLoadOfReferenceLValue(VDAddr, VD->getType());
else
VDLVal = CGF.MakeAddrLValue(
VDAddr, VD->getType().getCanonicalType().getNonReferenceType());
llvm::DenseMap<const VarDecl *, FieldDecl *> Captures;
FieldDecl *ThisCapture = nullptr;
RD->getCaptureFields(Captures, ThisCapture);
if (ThisCapture && CGF.CapturedStmtInfo->isCXXThisExprCaptured()) {
LValue ThisLVal =
CGF.EmitLValueForFieldInitialization(VDLVal, ThisCapture);
llvm::Value *CXXThis = CGF.LoadCXXThis();
CGF.EmitStoreOfScalar(CXXThis, ThisLVal);
}
for (const LambdaCapture &LC : RD->captures()) {
if (LC.getCaptureKind() != LCK_ByRef)
continue;
const VarDecl *VD = LC.getCapturedVar();
if (!CS->capturesVariable(VD))
continue;
auto It = Captures.find(VD);
assert(It != Captures.end() && "Found lambda capture without field.");
LValue VarLVal = CGF.EmitLValueForFieldInitialization(VDLVal, It->second);
Address VDAddr = CGF.GetAddrOfLocalVar(VD);
if (VD->getType().getCanonicalType()->isReferenceType())
VDAddr = CGF.EmitLoadOfReferenceLValue(VDAddr,
VD->getType().getCanonicalType())
.getAddress();
CGF.EmitStoreOfScalar(VDAddr.getPointer(), VarLVal);
}
}
}
// Get current CudaArch and ignore any unknown values
static CudaArch getCudaArch(CodeGenModule &CGM) {
if (!CGM.getTarget().hasFeature("ptx"))
return CudaArch::UNKNOWN;
llvm::StringMap<bool> Features;
CGM.getTarget().initFeatureMap(Features, CGM.getDiags(),
CGM.getTarget().getTargetOpts().CPU,
CGM.getTarget().getTargetOpts().Features);
for (const auto &Feature : Features) {
if (Feature.getValue()) {
CudaArch Arch = StringToCudaArch(Feature.getKey());
if (Arch != CudaArch::UNKNOWN)
return Arch;
}
}
return CudaArch::UNKNOWN;
}
/// Check to see if target architecture supports unified addressing which is
/// a restriction for OpenMP requires clause "unified_shared_memory".
void CGOpenMPRuntimeNVPTX::checkArchForUnifiedAddressing(
CodeGenModule &CGM, const OMPRequiresDecl *D) const {
for (const OMPClause *Clause : D->clauselists()) {
if (Clause->getClauseKind() == OMPC_unified_shared_memory) {
switch (getCudaArch(CGM)) {
case CudaArch::SM_20:
case CudaArch::SM_21:
case CudaArch::SM_30:
case CudaArch::SM_32:
case CudaArch::SM_35:
case CudaArch::SM_37:
case CudaArch::SM_50:
case CudaArch::SM_52:
case CudaArch::SM_53:
case CudaArch::SM_60:
case CudaArch::SM_61:
case CudaArch::SM_62:
CGM.Error(Clause->getBeginLoc(),
"Target architecture does not support unified addressing");
return;
case CudaArch::SM_70:
case CudaArch::SM_72:
case CudaArch::SM_75:
case CudaArch::GFX600:
case CudaArch::GFX601:
case CudaArch::GFX700:
case CudaArch::GFX701:
case CudaArch::GFX702:
case CudaArch::GFX703:
case CudaArch::GFX704:
case CudaArch::GFX801:
case CudaArch::GFX802:
case CudaArch::GFX803:
case CudaArch::GFX810:
case CudaArch::GFX900:
case CudaArch::GFX902:
case CudaArch::GFX904:
case CudaArch::GFX906:
case CudaArch::GFX909:
case CudaArch::UNKNOWN:
break;
case CudaArch::LAST:
llvm_unreachable("Unexpected Cuda arch.");
}
}
}
}
/// Get number of SMs and number of blocks per SM.
static std::pair<unsigned, unsigned> getSMsBlocksPerSM(CodeGenModule &CGM) {
std::pair<unsigned, unsigned> Data;
if (CGM.getLangOpts().OpenMPCUDANumSMs)
Data.first = CGM.getLangOpts().OpenMPCUDANumSMs;
if (CGM.getLangOpts().OpenMPCUDABlocksPerSM)
Data.second = CGM.getLangOpts().OpenMPCUDABlocksPerSM;
if (Data.first && Data.second)
return Data;
switch (getCudaArch(CGM)) {
case CudaArch::SM_20:
case CudaArch::SM_21:
case CudaArch::SM_30:
case CudaArch::SM_32:
case CudaArch::SM_35:
case CudaArch::SM_37:
case CudaArch::SM_50:
case CudaArch::SM_52:
case CudaArch::SM_53:
return {16, 16};
case CudaArch::SM_60:
case CudaArch::SM_61:
case CudaArch::SM_62:
return {56, 32};
case CudaArch::SM_70:
case CudaArch::SM_72:
case CudaArch::SM_75:
return {84, 32};
case CudaArch::GFX600:
case CudaArch::GFX601:
case CudaArch::GFX700:
case CudaArch::GFX701:
case CudaArch::GFX702:
case CudaArch::GFX703:
case CudaArch::GFX704:
case CudaArch::GFX801:
case CudaArch::GFX802:
case CudaArch::GFX803:
case CudaArch::GFX810:
case CudaArch::GFX900:
case CudaArch::GFX902:
case CudaArch::GFX904:
case CudaArch::GFX906:
case CudaArch::GFX909:
case CudaArch::UNKNOWN:
break;
case CudaArch::LAST:
llvm_unreachable("Unexpected Cuda arch.");
}
llvm_unreachable("Unexpected NVPTX target without ptx feature.");
}
void CGOpenMPRuntimeNVPTX::clear() {
if (!GlobalizedRecords.empty()) {
ASTContext &C = CGM.getContext();
llvm::SmallVector<const GlobalPtrSizeRecsTy *, 4> GlobalRecs;
llvm::SmallVector<const GlobalPtrSizeRecsTy *, 4> SharedRecs;
RecordDecl *StaticRD = C.buildImplicitRecord(
"_openmp_static_memory_type_$_", RecordDecl::TagKind::TTK_Union);
StaticRD->startDefinition();
RecordDecl *SharedStaticRD = C.buildImplicitRecord(
"_shared_openmp_static_memory_type_$_", RecordDecl::TagKind::TTK_Union);
SharedStaticRD->startDefinition();
for (const GlobalPtrSizeRecsTy &Records : GlobalizedRecords) {
if (Records.Records.empty())
continue;
unsigned Size = 0;
unsigned RecAlignment = 0;
for (const RecordDecl *RD : Records.Records) {
QualType RDTy = C.getRecordType(RD);
unsigned Alignment = C.getTypeAlignInChars(RDTy).getQuantity();
RecAlignment = std::max(RecAlignment, Alignment);
unsigned RecSize = C.getTypeSizeInChars(RDTy).getQuantity();
Size =
llvm::alignTo(llvm::alignTo(Size, Alignment) + RecSize, Alignment);
}
Size = llvm::alignTo(Size, RecAlignment);
llvm::APInt ArySize(/*numBits=*/64, Size);
QualType SubTy = C.getConstantArrayType(
C.CharTy, ArySize, ArrayType::Normal, /*IndexTypeQuals=*/0);
const bool UseSharedMemory = Size <= SharedMemorySize;
auto *Field =
FieldDecl::Create(C, UseSharedMemory ? SharedStaticRD : StaticRD,
SourceLocation(), SourceLocation(), nullptr, SubTy,
C.getTrivialTypeSourceInfo(SubTy, SourceLocation()),
/*BW=*/nullptr, /*Mutable=*/false,
/*InitStyle=*/ICIS_NoInit);
Field->setAccess(AS_public);
if (UseSharedMemory) {
SharedStaticRD->addDecl(Field);
SharedRecs.push_back(&Records);
} else {
StaticRD->addDecl(Field);
GlobalRecs.push_back(&Records);
}
Records.RecSize->setInitializer(llvm::ConstantInt::get(CGM.SizeTy, Size));
Records.UseSharedMemory->setInitializer(
llvm::ConstantInt::get(CGM.Int16Ty, UseSharedMemory ? 1 : 0));
}
SharedStaticRD->completeDefinition();
if (!SharedStaticRD->field_empty()) {
QualType StaticTy = C.getRecordType(SharedStaticRD);
llvm::Type *LLVMStaticTy = CGM.getTypes().ConvertTypeForMem(StaticTy);
auto *GV = new llvm::GlobalVariable(
CGM.getModule(), LLVMStaticTy,
/*isConstant=*/false, llvm::GlobalValue::CommonLinkage,
llvm::Constant::getNullValue(LLVMStaticTy),
"_openmp_shared_static_glob_rd_$_", /*InsertBefore=*/nullptr,
llvm::GlobalValue::NotThreadLocal,
C.getTargetAddressSpace(LangAS::cuda_shared));
auto *Replacement = llvm::ConstantExpr::getPointerBitCastOrAddrSpaceCast(
GV, CGM.VoidPtrTy);
for (const GlobalPtrSizeRecsTy *Rec : SharedRecs) {
Rec->Buffer->replaceAllUsesWith(Replacement);
Rec->Buffer->eraseFromParent();
}
}
StaticRD->completeDefinition();
if (!StaticRD->field_empty()) {
QualType StaticTy = C.getRecordType(StaticRD);
std::pair<unsigned, unsigned> SMsBlockPerSM = getSMsBlocksPerSM(CGM);
llvm::APInt Size1(32, SMsBlockPerSM.second);
QualType Arr1Ty =
C.getConstantArrayType(StaticTy, Size1, ArrayType::Normal,
/*IndexTypeQuals=*/0);
llvm::APInt Size2(32, SMsBlockPerSM.first);
QualType Arr2Ty = C.getConstantArrayType(Arr1Ty, Size2, ArrayType::Normal,
/*IndexTypeQuals=*/0);
llvm::Type *LLVMArr2Ty = CGM.getTypes().ConvertTypeForMem(Arr2Ty);
auto *GV = new llvm::GlobalVariable(
CGM.getModule(), LLVMArr2Ty,
/*isConstant=*/false, llvm::GlobalValue::CommonLinkage,
llvm::Constant::getNullValue(LLVMArr2Ty),
"_openmp_static_glob_rd_$_");
auto *Replacement = llvm::ConstantExpr::getPointerBitCastOrAddrSpaceCast(
GV, CGM.VoidPtrTy);
for (const GlobalPtrSizeRecsTy *Rec : GlobalRecs) {
Rec->Buffer->replaceAllUsesWith(Replacement);
Rec->Buffer->eraseFromParent();
}
}
}
CGOpenMPRuntime::clear();
}