mirror of https://github.com/llvm/torch-mlir
184 lines
5.5 KiB
C++
184 lines
5.5 KiB
C++
//===----------------------------------------------------------------------===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// This is the public-facing interface for interacting with the npcomp
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// runtime.
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//
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// This functionality is totally firewalled from the compiler codebase, so
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// even if things superficially look similar, remember that there are no
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// LLVM utilities here, memory allocation should be kept to a minimum, etc.
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//
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// npcomp/RefBackend/Runtime/Support.h provides some minimal LLVM-like support
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// code to keep the API familiar.
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//
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//===----------------------------------------------------------------------===//
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#ifndef NPCOMP_RUNTIME_USERAPI_H
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#define NPCOMP_RUNTIME_USERAPI_H
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#include "npcomp/RefBackend/Runtime/Support.h"
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#include <atomic>
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#include <cstdlib>
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namespace refbackrt {
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// Reference-counted handle to a type with a `refCount` member.
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template <typename T> class Ref {
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public:
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Ref() { ptr = nullptr; }
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// Creates a Ref and increments the refcount by 1.
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// rawPtr must be allocated with std::malloc.
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Ref(T *rawPtr) {
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ptr = rawPtr;
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ptr->refCount += 1;
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}
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Ref(const Ref &other) {
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ptr = other.ptr;
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incref(ptr);
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}
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Ref(Ref &&other) { ptr = other.takePtr(); }
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Ref &operator=(const Ref &other) {
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if (&other == this)
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return *this;
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decref(ptr);
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ptr = other.ptr;
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incref(ptr);
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return *this;
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}
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Ref &operator=(Ref &&other) {
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if (&other == this)
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return *this;
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decref(ptr);
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ptr = other.takePtr();
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return *this;
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}
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~Ref() { decref(ptr); }
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T &operator*() const { return *ptr; }
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T *operator->() const { return ptr; }
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T *get() const { return ptr; }
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T *takePtr() {
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auto *ret = ptr;
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ptr = nullptr;
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return ret;
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}
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private:
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static void incref(T *ptr) {
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if (!ptr)
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return;
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ptr->refCount += 1;
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}
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static void decref(T *ptr) {
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if (!ptr)
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return;
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if (ptr->refCount.fetch_sub(1) == 1) {
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ptr->~T();
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std::free(static_cast<void *>(ptr));
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}
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}
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T *ptr;
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};
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// The available data types.
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enum class ElementType : std::int32_t {
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F32,
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};
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std::int32_t getElementTypeByteSize(ElementType type);
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// Representation of a tensor.
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class Tensor {
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public:
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// Due to tail-allocated objects, this struct should never be directly
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// constructed.
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Tensor() = delete;
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// Create a Tensor with the given extents and element type, with a buffer
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// holding a copy of `data`.
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static Ref<Tensor> create(ArrayRef<std::int32_t> extents,
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ElementType elementType, void *data);
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// Same as `create`, but returns a raw pointer.
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static Tensor *createRaw(ArrayRef<std::int32_t> extents,
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ElementType elementType, void *data);
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ElementType getElementType() const { return elementType; }
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std::int32_t getRank() const { return rank; }
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void *getData() const { return data; }
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template <typename T> T *getData() const { return static_cast<T *>(data); }
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std::int32_t getExtent(int dimension) const {
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return getExtents()[dimension];
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}
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ArrayRef<std::int32_t> getExtents() const {
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auto extents = const_cast<Tensor *>(this)->getMutableExtents();
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return ArrayRef<std::int32_t>(extents.data(), extents.size());
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}
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// Returns the number of bytes occupied by the data representing this tensor.
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// The total allocated amount might be higher to allow e.g. for alignment
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// nudging.
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std::int32_t getDataByteSize() const;
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~Tensor() { std::free(allocatedPtr); }
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private:
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MutableArrayRef<std::int32_t> getMutableExtents() {
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auto *tail = reinterpret_cast<std::int32_t *>(this + 1);
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return MutableArrayRef<std::int32_t>(tail, rank);
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}
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// Reference count management.
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template <typename T> friend class Ref;
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std::atomic<int> refCount{0};
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ElementType elementType;
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// The number of dimensions of this Tensor.
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// There are `rank` tail-allocated std::int32_t values representing the
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// tensor extents.
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std::int32_t rank;
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// The buffer base.
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void *data;
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// The raw pointer returned by the allocator (currently assumed to be
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// malloc), suitable for freeing the buffer.
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void *allocatedPtr;
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// Sizes are tail-allocated.
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};
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//===----------------------------------------------------------------------===//
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// Module loading.
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// This is the main entry point that users interact with.
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//===----------------------------------------------------------------------===//
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// Metadata for a particular function.
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// TODO: Add arg types.
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struct FunctionMetadata {
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std::int32_t numInputs;
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std::int32_t numOutputs;
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};
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// Opaque forward declaration of module descriptor type. This is the type
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// created by the compiler in the module binary.
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struct ModuleDescriptor;
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// Maximum input or output arity.
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constexpr static int kMaxArity = 20;
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// Low-level invocation API. The number of inputs and outputs should be correct
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// and match the results of getMetadata.
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void invoke(ModuleDescriptor *moduleDescriptor, StringRef functionName,
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ArrayRef<Ref<Tensor>> inputs, MutableArrayRef<Ref<Tensor>> outputs);
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// Metadata for function `functionName`.
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//
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// Returns failure if functionName wasn't found.
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LogicalResult getMetadata(ModuleDescriptor *moduleDescriptor,
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StringRef functionName,
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FunctionMetadata &outMetadata);
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} // namespace refbackrt
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#endif // NPCOMP_RUNTIME_USERAPI_H
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