提交 c7305fbe 编写于 作者: S sneaxiy

buffered_allocator: add unittest and fix bug

test=develop
上级 e3fc544c
...@@ -3,6 +3,7 @@ cc_library(cpu_allocator SRCS cpu_allocator.cc DEPS allocator) ...@@ -3,6 +3,7 @@ cc_library(cpu_allocator SRCS cpu_allocator.cc DEPS allocator)
cc_library(best_fit_allocator SRCS best_fit_allocator.cc DEPS allocator) cc_library(best_fit_allocator SRCS best_fit_allocator.cc DEPS allocator)
cc_library(locked_allocator SRCS locked_allocator.cc DEPS allocator) cc_library(locked_allocator SRCS locked_allocator.cc DEPS allocator)
cc_library(buffered_allocator SRCS buffered_allocator.cc DEPS allocator) cc_library(buffered_allocator SRCS buffered_allocator.cc DEPS allocator)
cc_test(buffered_allocator_test SRCS buffered_allocator_test.cc DEPS best_fit_allocator locked_allocator buffered_allocator cpu_allocator)
if (WITH_GPU) if (WITH_GPU)
nv_library(cuda_allocator SRCS cuda_allocator.cc DEPS allocator cuda_device_guard) nv_library(cuda_allocator SRCS cuda_allocator.cc DEPS allocator cuda_device_guard)
......
...@@ -34,11 +34,23 @@ BufferedAllocator::BufferedAllocator(std::unique_ptr<Allocator>&& allocator, ...@@ -34,11 +34,23 @@ BufferedAllocator::BufferedAllocator(std::unique_ptr<Allocator>&& allocator,
InitAndEnforceCheck(std::move(allocator), division_plan); InitAndEnforceCheck(std::move(allocator), division_plan);
} }
BufferedAllocator::~BufferedAllocator() { BufferedAllocator::~BufferedAllocator() { FlushImpl(); }
void BufferedAllocator::FlushImpl() {
for (auto& v : allocations_) { for (auto& v : allocations_) {
for (auto& pair : v) { for (auto& pair : v) {
underlying_allocator_->FreeUniquePtr(std::move(pair.second)); underlying_allocator_->FreeUniquePtr(std::move(pair.second));
} }
v.clear();
}
}
void BufferedAllocator::Flush() {
if (mtx_) {
std::lock_guard<std::mutex> lock(*mtx_);
FlushImpl();
} else {
FlushImpl();
} }
} }
...@@ -77,8 +89,7 @@ void BufferedAllocator::InsertAllocationImpl( ...@@ -77,8 +89,7 @@ void BufferedAllocator::InsertAllocationImpl(
std::unique_ptr<Allocation>&& allocation) { std::unique_ptr<Allocation>&& allocation) {
auto size = allocation->size(); auto size = allocation->size();
auto idx = GetListIndex(size); auto idx = GetListIndex(size);
allocations_[idx].insert(std::pair<size_t, std::unique_ptr<Allocation>>( allocations_[idx].emplace(size, std::move(allocation));
size, std::move(allocation)));
} }
void BufferedAllocator::InsertAllocation( void BufferedAllocator::InsertAllocation(
...@@ -91,9 +102,8 @@ void BufferedAllocator::InsertAllocation( ...@@ -91,9 +102,8 @@ void BufferedAllocator::InsertAllocation(
} }
} }
bool BufferedAllocator::Match(const std::unique_ptr<Allocation>& allocation, bool BufferedAllocator::Match(size_t actual_size, size_t requested_size) {
size_t size) { return (actual_size >> 1) < requested_size;
return (allocation->size() >> 1) <= size;
} }
size_t BufferedAllocator::GetListIndex(size_t size) { size_t BufferedAllocator::GetListIndex(size_t size) {
...@@ -108,13 +118,30 @@ std::unique_ptr<Allocation> BufferedAllocator::RemoveAllocationImpl( ...@@ -108,13 +118,30 @@ std::unique_ptr<Allocation> BufferedAllocator::RemoveAllocationImpl(
auto& allocation_map = allocations_[idx]; auto& allocation_map = allocations_[idx];
auto it = allocation_map.lower_bound(size); auto it = allocation_map.lower_bound(size);
// Only remove allocation whose size is not more than twice of requested size // Only remove allocation whose size is not more than twice of requested size
if (it != allocation_map.end() && Match(it->second, size)) { if (it != allocation_map.end()) {
if (Match(it->second->size(), size)) {
auto ret = std::move(it->second);
allocation_map.erase(it);
return ret;
} else {
return nullptr;
}
} else {
while (++idx < allocations_.size() && Match(division_plan_[idx], size)) {
auto& allocation_map = allocations_[idx];
if (!allocation_map.empty()) {
auto it = allocation_map.begin();
if (Match(it->second->size(), size)) {
auto ret = std::move(it->second); auto ret = std::move(it->second);
allocation_map.erase(it); allocation_map.erase(it);
return ret; return ret;
} else { } else {
return nullptr; return nullptr;
} }
}
}
return nullptr;
}
} }
std::unique_ptr<Allocation> BufferedAllocator::RemoveAllocation(size_t size) { std::unique_ptr<Allocation> BufferedAllocator::RemoveAllocation(size_t size) {
...@@ -171,6 +198,10 @@ void BufferedAllocator::FreeUniquePtr(std::unique_ptr<Allocation> allocation) { ...@@ -171,6 +198,10 @@ void BufferedAllocator::FreeUniquePtr(std::unique_ptr<Allocation> allocation) {
bool BufferedAllocator::IsAllocThreadSafe() const { return mtx_ != nullptr; } bool BufferedAllocator::IsAllocThreadSafe() const { return mtx_ != nullptr; }
const std::vector<size_t>& BufferedAllocator::GetDivisionPlan() const {
return division_plan_;
}
} // namespace allocation } // namespace allocation
} // namespace memory } // namespace memory
} // namespace paddle } // namespace paddle
...@@ -37,12 +37,17 @@ class BufferedAllocator : public UnmanagedAllocator { ...@@ -37,12 +37,17 @@ class BufferedAllocator : public UnmanagedAllocator {
~BufferedAllocator(); ~BufferedAllocator();
std::unique_ptr<Allocation> Allocate(size_t size, Allocator::Attr) override; std::unique_ptr<Allocation> Allocate(
size_t size, Allocator::Attr attr = Allocator::Attr::kDefault) override;
void FreeUniquePtr(std::unique_ptr<Allocation> allocation) override; void FreeUniquePtr(std::unique_ptr<Allocation> allocation) override;
bool IsAllocThreadSafe() const override; bool IsAllocThreadSafe() const override;
const std::vector<size_t>& GetDivisionPlan() const;
void Flush();
private: private:
void InitAndEnforceCheck(std::unique_ptr<Allocator>&& allocator, void InitAndEnforceCheck(std::unique_ptr<Allocator>&& allocator,
const std::vector<size_t>& division_plan); const std::vector<size_t>& division_plan);
...@@ -50,13 +55,15 @@ class BufferedAllocator : public UnmanagedAllocator { ...@@ -50,13 +55,15 @@ class BufferedAllocator : public UnmanagedAllocator {
void InsertAllocation(std::unique_ptr<Allocation>&& allocation); void InsertAllocation(std::unique_ptr<Allocation>&& allocation);
void InsertAllocationImpl(std::unique_ptr<Allocation>&& allocation); void InsertAllocationImpl(std::unique_ptr<Allocation>&& allocation);
static bool Match(const std::unique_ptr<Allocation>& allocation, size_t size); static bool Match(size_t actual_size, size_t requested_size);
std::unique_ptr<Allocation> RemoveAllocation(size_t size); std::unique_ptr<Allocation> RemoveAllocation(size_t size);
std::unique_ptr<Allocation> RemoveAllocationImpl(size_t size); std::unique_ptr<Allocation> RemoveAllocationImpl(size_t size);
void FreeAllocations(size_t size); void FreeAllocations(size_t size);
void FreeAllocationsImpl(size_t size); void FreeAllocationsImpl(size_t size);
void FlushImpl();
size_t GetListIndex(size_t size); size_t GetListIndex(size_t size);
std::unique_ptr<UnmanagedAllocator> underlying_allocator_; std::unique_ptr<UnmanagedAllocator> underlying_allocator_;
......
// Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "paddle/fluid/memory/allocation/buffered_allocator.h"
#include <gtest/gtest.h>
#include "paddle/fluid/memory/allocation/best_fit_allocator.h"
#include "paddle/fluid/memory/allocation/cpu_allocator.h"
#include "paddle/fluid/memory/allocation/locked_allocator.h"
namespace paddle {
namespace memory {
namespace allocation {
inline std::unique_ptr<BufferedAllocator> GetBufferedAllocator(
Allocation *allocation, bool thread_safe) {
std::unique_ptr<Allocator> allocator(new BestFitAllocator(allocation));
if (thread_safe) {
allocator.reset(new LockedAllocator(std::move(allocator)));
}
return std::unique_ptr<BufferedAllocator>(
new BufferedAllocator(std::move(allocator)));
}
TEST(buffered_allocator, thread_safety) {
std::unique_ptr<CPUAllocator> allocator(new CPUAllocator());
auto chunk = allocator->Allocate(1 << 20);
{
auto buf_allocator = GetBufferedAllocator(chunk.get(), true);
ASSERT_EQ(buf_allocator->IsAllocThreadSafe(), true);
}
{
auto buf_allocator = GetBufferedAllocator(chunk.get(), false);
ASSERT_EQ(buf_allocator->IsAllocThreadSafe(), false);
}
allocator->FreeUniquePtr(std::move(chunk));
}
class StubAllocation : public Allocation {
public:
using Allocation::Allocation;
};
class StubAllocator : public UnmanagedAllocator {
public:
std::unique_ptr<Allocation> Allocate(size_t size,
Allocator::Attr attr) override {
++construct_count_;
if (size == 0) {
return std::unique_ptr<Allocation>(
new StubAllocation(nullptr, 0, platform::CPUPlace()));
} else {
return std::unique_ptr<Allocation>(
new StubAllocation(new uint8_t[size], size, platform::CPUPlace()));
}
}
void FreeUniquePtr(std::unique_ptr<Allocation> allocation) {
StubAllocation *alloc = dynamic_cast<StubAllocation *>(allocation.get());
PADDLE_ENFORCE_NOT_NULL(alloc);
if (alloc->ptr()) delete[] static_cast<uint8_t *>(alloc->ptr());
++destruct_count_;
}
void ResetCounter() {
construct_count_ = 0;
destruct_count_ = 0;
}
size_t GetAllocCount() const { return construct_count_; }
size_t GetFreeCount() const { return destruct_count_; }
private:
size_t construct_count_ = 0;
size_t destruct_count_ = 0;
};
constexpr size_t kZero = 0;
constexpr size_t kOne = 1;
constexpr size_t kTwo = 2;
TEST(buffered_allocator, lazy_free) {
std::unique_ptr<StubAllocator> stub_allocator(new StubAllocator());
auto *underlying_allocator = stub_allocator.get();
std::unique_ptr<BufferedAllocator> allocator(
new BufferedAllocator(std::move(stub_allocator)));
{
underlying_allocator->ResetCounter();
auto x = allocator->Allocate(1025);
ASSERT_EQ(underlying_allocator->GetAllocCount(), kOne);
ASSERT_EQ(underlying_allocator->GetFreeCount(), kZero);
allocator->FreeUniquePtr(std::move(x));
ASSERT_EQ(underlying_allocator->GetFreeCount(), kZero);
}
{
underlying_allocator->ResetCounter();
auto x = allocator->Allocate(900);
ASSERT_EQ(underlying_allocator->GetAllocCount(), kZero);
ASSERT_EQ(underlying_allocator->GetFreeCount(), kZero);
auto y = allocator->Allocate(2048);
ASSERT_EQ(underlying_allocator->GetAllocCount(), kOne);
ASSERT_EQ(underlying_allocator->GetFreeCount(), kZero);
allocator->FreeUniquePtr(std::move(x));
ASSERT_EQ(underlying_allocator->GetFreeCount(), kZero);
allocator->FreeUniquePtr(std::move(y));
ASSERT_EQ(underlying_allocator->GetFreeCount(), kZero);
}
{
underlying_allocator->ResetCounter();
allocator->Flush();
ASSERT_EQ(underlying_allocator->GetAllocCount(), kZero);
ASSERT_EQ(underlying_allocator->GetFreeCount(), kTwo);
}
}
TEST(buffered_allocator, garbage_collection) {
std::unique_ptr<CPUAllocator> cpu_allocator(new CPUAllocator());
auto chunk = cpu_allocator->Allocate(2048);
auto allocator = GetBufferedAllocator(chunk.get(), false);
auto x1 = allocator->Allocate(1600);
auto x2 = allocator->Allocate(400);
allocator->FreeUniquePtr(std::move(x1));
allocator->FreeUniquePtr(std::move(x2));
auto x3 = allocator->Allocate(1600);
ASSERT_NE(x3, nullptr);
ASSERT_NE(x3->ptr(), nullptr);
}
} // namespace allocation
} // namespace memory
} // namespace paddle
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