Skip to content

P
Paddle

csdn_franckjun / Paddle
与 Fork 源项目一致

Fork自 PaddlePaddle / Paddle

通知 1
Star 1
Fork 0
P
Paddle

体验新版 GitCode,发现更多精彩内容 >>

未验证 提交 1a0ef45e 编写于 作者: T taixiurong 提交者: GitHub
浏览文件
操作

xpu-paddlepaddle-37 [任务] 迁移lamb到phi (#45520) 

test=kunlun
上级 5696f967
隐藏空白更改
内联 并排
Showing with 357 addition and 168 deletion
paddle/fluid/operators/optimizers/lamb_op_xpu.cc 已删除 100644 → 0
浏览文件 @ 5696f967
/* Copyright (c) 2022 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 "gflags/gflags.h"
#include "paddle/fluid/framework/op_registry.h"
#include "paddle/fluid/platform/device/device_wrapper.h"
namespace paddle {
namespace operators {
using Tensor = framework::Tensor;
#ifdef PADDLE_WITH_XPU
template <typename DeviceContext, typename T>
class LambOpXPUKernel : public framework::OpKernel<T> {
public:
void Compute(const framework::ExecutionContext& ctx) const override {
using paddle::framework::LoDTensor;
const auto* param_var = ctx.InputVar("Param");
PADDLE_ENFORCE_EQ(param_var->IsType<framework::LoDTensor>(),
true,
platform::errors::InvalidArgument(
"The Var(%s)'s type should be LoDTensor, "
"but the received is %s",
ctx.InputNames("Param").front(),
framework::ToTypeName(param_var->Type())));
using paddle::framework::LoDTensor;
// inputs
T epsilon = static_cast<T>(ctx.Attr<float>("epsilon"));
T weight_decay = static_cast<T>(ctx.Attr<float>("weight_decay"));
T beta1 = static_cast<T>(ctx.Attr<float>("beta1"));
T beta2 = static_cast<T>(ctx.Attr<float>("beta2"));
auto& param = GET_DATA_SAFELY(
ctx.Input<LoDTensor>("Param"), "Input", "Param", "Lamb");
auto* grad_var = ctx.InputVar("Grad");
auto& mom1 = GET_DATA_SAFELY(
ctx.Input<LoDTensor>("Moment1"), "Input", "Moment1", "Lamb");
auto& mom2 = GET_DATA_SAFELY(
ctx.Input<LoDTensor>("Moment2"), "Input", "Moment2", "Lamb");
auto& lr = GET_DATA_SAFELY(
ctx.Input<LoDTensor>("LearningRate"), "Input", "LearningRate", "Lamb");
auto& beta1_pow = GET_DATA_SAFELY(
ctx.Input<LoDTensor>("Beta1Pow"), "Input", "Beta1Pow", "Lamb");
auto& beta2_pow = GET_DATA_SAFELY(
ctx.Input<LoDTensor>("Beta2Pow"), "Input", "Beta2Pow", "Lamb");
auto& param_out = GET_DATA_SAFELY(
ctx.Output<LoDTensor>("ParamOut"), "Output", "ParamOut", "Lamb");
auto& mom1_out = GET_DATA_SAFELY(
ctx.Output<LoDTensor>("Moment1Out"), "Output", "Moment1Out", "Lamb");
auto& mom2_out = GET_DATA_SAFELY(
ctx.Output<LoDTensor>("Moment2Out"), "Output", "Moment2Out", "Lamb");
auto& beta1_pow_out = GET_DATA_SAFELY(
ctx.Output<LoDTensor>("Beta1PowOut"), "Output", "Beta1PowOut", "Lamb");
auto& beta2_pow_out = GET_DATA_SAFELY(
ctx.Output<LoDTensor>("Beta2PowOut"), "Output", "Beta2PowOut", "Lamb");
auto& dev_ctx = ctx.template device_context<DeviceContext>();
if (grad_var->IsType<framework::LoDTensor>()) {
auto& grad = *ctx.Input<LoDTensor>("Grad");
int r = xpu::lamb(dev_ctx.x_context(),
grad.template data<T>(),
mom1.template data<T>(),
mom2.template data<T>(),
param.template data<T>(),
beta1_pow.template data<T>(),
beta2_pow.template data<T>(),
mom1_out.template mutable_data<T>(ctx.GetPlace()),
mom2_out.template mutable_data<T>(ctx.GetPlace()),
param_out.template mutable_data<T>(ctx.GetPlace()),
beta1_pow_out.template mutable_data<T>(ctx.GetPlace()),
beta2_pow_out.template mutable_data<T>(ctx.GetPlace()),
beta1,
beta2,
epsilon,
weight_decay,
lr.template data<T>(),
param.numel());
PADDLE_ENFORCE_XDNN_SUCCESS(r, "lamb");
} else {
PADDLE_THROW(platform::errors::InvalidArgument(
"Variable type not supported by lamb_op. Expect LoDTensor, "
"but got %s",
framework::ToTypeName(param_var->Type())));
}
}
};
} // namespace operators
} // namespace paddle
namespace ops = paddle::operators;
REGISTER_OP_XPU_KERNEL(
lamb, ops::LambOpXPUKernel<paddle::platform::XPUDeviceContext, float>);
#endif
paddle/fluid/platform/device/xpu/xpu2_op_list.h
浏览文件 @ 1a0ef45e
......@@ -306,6 +306,9 @@ XPUOpMap& get_kl2_ops() {
XPUKernelSet({pOpKernelType(vartype::FP32, XPUPlace())})},
{"label_smooth",
XPUKernelSet({pOpKernelType(vartype::FP32, XPUPlace())})},
{"lamb",
XPUKernelSet({pOpKernelType(vartype::FP32, XPUPlace()),
pOpKernelType(vartype::FP16, XPUPlace())})},
{"lars_momentum",
XPUKernelSet({pOpKernelType(vartype::FP32, XPUPlace()),
pOpKernelType(vartype::FP16, XPUPlace())})},
......@@ -650,8 +653,7 @@ XPUOpMap& get_kl2_ops() {
{"resnet_basic_block_grad",
XPUKernelSet({pOpKernelType(vartype::FP32, XPUPlace())})},
{"resnet_basic_block",
XPUKernelSet({pOpKernelType(vartype::FP32, XPUPlace())})},
};
XPUKernelSet({pOpKernelType(vartype::FP32, XPUPlace())})}};
return s_xpu2_kernels;
}
......
paddle/phi/kernels/xpu/lamb_kernel.cc 0 → 100644
浏览文件 @ 1a0ef45e
// Copyright (c) 2022 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/phi/kernels/lamb_kernel.h"
#include "paddle/fluid/memory/memcpy.h"
#include "paddle/phi/backends/xpu/enforce_xpu.h"
#include "paddle/phi/backends/xpu/xpu_context.h"
#include "paddle/phi/common/amp_type_traits.h"
#include "paddle/phi/common/place.h"
#include "paddle/phi/core/kernel_registry.h"
namespace phi {
template <typename T, typename Context>
void LambKernel(const Context& dev_ctx,
const DenseTensor& param,
const DenseTensor& grad,
const DenseTensor& learning_rate,
const DenseTensor& moment1,
const DenseTensor& moment2,
const DenseTensor& beta1_pow,
const DenseTensor& beta2_pow,
const paddle::optional<DenseTensor>& master_param,
const paddle::optional<DenseTensor>& skip_update,
float weight_decay,
float beta1,
float beta2,
float epsilon,
bool multi_precision,
DenseTensor* param_outs,
DenseTensor* moment1_out,
DenseTensor* moment2_out,
DenseTensor* beta1_pow_out,
DenseTensor* beta2_pow_out,
DenseTensor* master_param_outs) {
using XPUType = typename XPUTypeTrait<T>::Type;
using MT = typename phi::dtype::MPTypeTrait<T>::Type;
if (!multi_precision) {
constexpr auto kIsSameType = std::is_same<T, MT>::value;
PADDLE_ENFORCE_EQ(
kIsSameType,
true,
phi::errors::InvalidArgument(
"When multi_precision=False, T and MT must be the same type."));
}
bool cpu_skip_update = false;
if (skip_update && skip_update->IsInitialized()) {
if (paddle::platform::is_cpu_place(skip_update->place())) {
cpu_skip_update = *(skip_update->data<bool>());
} else {
const bool* skip_update_flag = skip_update->data<bool>();
paddle::memory::Copy(phi::CPUPlace(),
static_cast<void*>(&cpu_skip_update),
dev_ctx.GetPlace(),
static_cast<const void*>(skip_update_flag),
sizeof(bool));
}
}
if (cpu_skip_update) {
return;
}
// tensor --> data_ptr
// inputs
const XPUType* param_ptr = reinterpret_cast<const XPUType*>(param.data<T>());
const XPUType* grad_ptr = reinterpret_cast<const XPUType*>(grad.data<T>());
const MT* learning_rate_ptr = learning_rate.data<MT>();
const MT* moment1_ptr = moment1.data<MT>();
const MT* moment2_ptr = moment2.data<MT>();
const MT* beta1_pow_ptr = beta1_pow.data<MT>();
const MT* beta2_pow_ptr = beta2_pow.data<MT>();
const MT* master_param_ptr = nullptr;
if (multi_precision) {
master_param_ptr = master_param.get_ptr()->data<MT>();
}
// outputs
XPUType* param_outs_ptr =
reinterpret_cast<XPUType*>(dev_ctx.template Alloc<T>(param_outs));
MT* moment1_out_ptr = dev_ctx.template Alloc<MT>(moment1_out);
MT* moment2_out_ptr = dev_ctx.template Alloc<MT>(moment2_out);
MT* master_param_outs_ptr = nullptr;
if (multi_precision) {
if (master_param_outs->numel() != master_param.get_ptr()->numel()) {
master_param_outs->Resize(master_param.get_ptr()->dims());
}
master_param_outs_ptr = dev_ctx.template Alloc<MT>(master_param_outs);
}
MT* beta1_pow_out_ptr = nullptr;
MT* beta2_pow_out_ptr = nullptr;
MT* beta1_pow_xpu_ptr = nullptr;
MT* beta2_pow_xpu_ptr = nullptr;
xpu::Context* xpu_ctx = dev_ctx.x_context();
xpu::ctx_guard RAII_GUARD(xpu_ctx);
if (beta1_pow.place().GetType() == phi::AllocationType::CPU) {
int r = xpu_malloc(reinterpret_cast<void**>(&beta1_pow_xpu_ptr),
(beta1_pow.numel()) * sizeof(MT));
PADDLE_ENFORCE_XPU_SUCCESS(r);
paddle::memory::Copy(dev_ctx.GetPlace(),
beta1_pow_xpu_ptr,
beta1_pow.place(),
beta1_pow.data<MT>(),
sizeof(MT) * beta1_pow.numel());
beta1_pow_ptr = beta1_pow_xpu_ptr;
beta1_pow_out_ptr = RAII_GUARD.alloc_l3_or_gm<MT>(beta1_pow_out->numel());
PADDLE_ENFORCE_XDNN_NOT_NULL(beta1_pow_out_ptr);
} else {
beta1_pow_out_ptr = dev_ctx.template Alloc<MT>(beta1_pow_out);
}
if (beta2_pow.place().GetType() == phi::AllocationType::CPU) {
int r = xpu_malloc(reinterpret_cast<void**>(&beta2_pow_xpu_ptr),
(beta2_pow.numel()) * sizeof(MT));
PADDLE_ENFORCE_XPU_SUCCESS(r);
paddle::memory::Copy(dev_ctx.GetPlace(),
beta2_pow_xpu_ptr,
beta2_pow.place(),
beta2_pow.data<MT>(),
sizeof(MT) * beta2_pow.numel());
beta2_pow_ptr = beta2_pow_xpu_ptr;
beta2_pow_out_ptr = RAII_GUARD.alloc_l3_or_gm<MT>(beta2_pow_out->numel());
PADDLE_ENFORCE_XDNN_NOT_NULL(beta2_pow_out_ptr);
} else {
beta2_pow_out_ptr = dev_ctx.template Alloc<MT>(beta2_pow_out);
}
const MT* param_calc_ptr = nullptr;
const MT* grad_calc_ptr = nullptr;
MT* param_outs_calc_ptr = nullptr;
if (std::is_same<T, phi::dtype::float16>::value) {
MT* param_float = RAII_GUARD.alloc_l3_or_gm<MT>(param.numel());
PADDLE_ENFORCE_XDNN_NOT_NULL(param_float);
MT* grad_float = RAII_GUARD.alloc_l3_or_gm<MT>(grad.numel());
PADDLE_ENFORCE_XDNN_NOT_NULL(grad_float);
MT* param_outs_float = RAII_GUARD.alloc_l3_or_gm<MT>(param_outs->numel());
PADDLE_ENFORCE_XDNN_NOT_NULL(param_outs_float);
int r =
xpu::cast<XPUType, MT>(xpu_ctx, param_ptr, param_float, param.numel());
PADDLE_ENFORCE_XDNN_SUCCESS(r, "cast");
r = xpu::cast<XPUType, MT>(xpu_ctx, grad_ptr, grad_float, grad.numel());
PADDLE_ENFORCE_XDNN_SUCCESS(r, "cast");
param_calc_ptr = param_float;
grad_calc_ptr = grad_float;
param_outs_calc_ptr = param_outs_float;
} else {
param_calc_ptr = reinterpret_cast<const MT*>(param_ptr);
grad_calc_ptr = reinterpret_cast<const MT*>(grad_ptr);
param_outs_calc_ptr = reinterpret_cast<MT*>(param_outs_ptr);
}
int r = xpu::lamb<MT>(
xpu_ctx,
grad_calc_ptr,
moment1_ptr,
moment2_ptr,
(multi_precision ? master_param_ptr : param_calc_ptr),
beta1_pow_ptr,
beta2_pow_ptr,
moment1_out_ptr,
moment2_out_ptr,
(multi_precision ? master_param_outs_ptr : param_outs_calc_ptr),
beta1_pow_out_ptr,
beta2_pow_out_ptr,
beta1,
beta2,
epsilon,
weight_decay,
learning_rate_ptr,
param.numel());
PADDLE_ENFORCE_XDNN_SUCCESS(r, "lamb");
if (std::is_same<T, phi::dtype::float16>::value && multi_precision == false) {
int r = xpu::cast<MT, XPUType>(
xpu_ctx, param_outs_calc_ptr, param_outs_ptr, param_outs->numel());
PADDLE_ENFORCE_XDNN_SUCCESS(r, "cast");
}
if (beta1_pow.place().GetType() == phi::AllocationType::CPU) {
// copy beta1_pow_out from xpu to cpu
paddle::memory::Copy(beta1_pow.place(),
dev_ctx.template HostAlloc<MT>(beta1_pow_out),
dev_ctx.GetPlace(),
beta1_pow_out_ptr,
sizeof(MT) * beta1_pow_out->numel());
if (beta1_pow_xpu_ptr) {
xpu_free(beta1_pow_xpu_ptr);
}
}
if (beta2_pow.place().GetType() == phi::AllocationType::CPU) {
// copy beta2_pow_out from xpu to cpu
paddle::memory::Copy(beta2_pow.place(),
dev_ctx.template HostAlloc<MT>(beta2_pow_out),
dev_ctx.GetPlace(),
beta2_pow_out_ptr,
sizeof(MT) * beta2_pow_out->numel());
if (beta2_pow_xpu_ptr) {
xpu_free(beta2_pow_xpu_ptr);
}
}
}
} // namespace phi
PD_REGISTER_KERNEL(
lamb, XPU, ALL_LAYOUT, phi::LambKernel, float, phi::dtype::float16) {
kernel->InputAt(5).SetBackend(phi::Backend::ALL_BACKEND);
kernel->InputAt(6).SetBackend(phi::Backend::ALL_BACKEND);
}
python/paddle/fluid/tests/unittests/xpu/get_test_cover_info.py
浏览文件 @ 1a0ef45e
......@@ -88,6 +88,7 @@ xpu_test_op_type_white_list = [
'dropout_float16',
'dropout_grad_float16',
"grad_add_float32", # no api for grad_add, skip
"lamb_float16",
"lars_momentum_float32",
"resnet_unit",
"resnet_unit_grad"
......
python/paddle/fluid/tests/unittests/xpu/test_lamb_op_xpu.py
浏览文件 @ 1a0ef45e
......@@ -23,53 +23,8 @@ from paddle.fluid import core
from paddle.fluid.op import Operator
import paddle.fluid as fluid
import paddle
"""
class TestLambOp1(XPUOpTest):
def set_attrs(self):
self.attrs = {
'epsilon': 1e-6,
'beta1': 0.9,
'beta2': 0.999,
'weight_decay': 0.01
}
def setUp(self):
'''Test Lamb Op with supplied attributes
'''
self.op_type = 'lamb'
param = np.random.uniform(-1, 1, 5000).astype('float32')
grad = np.random.uniform(-1, 1, 5000).astype('float32')
moment1 = np.random.uniform(-1, 1, 5000).astype('float32')
moment2 = np.random.random(5000).astype('float32')
self.set_attrs()
learning_rate = 0.001
beta1_pow = self.attrs['beta1']
beta2_pow = self.attrs['beta2']
self.inputs = {
'Param': param,
'Grad': grad,
'Moment1': moment1,
'Moment2': moment2,
'LearningRate': np.array([learning_rate]).astype('float32'),
'Beta1Pow': np.array([beta1_pow]).astype('float32'),
'Beta2Pow': np.array([beta2_pow]).astype('float32')
}
param_out, moment1_out, moment2_out, \
beta1_pow_out, beta2_pow_out = lamb_step(self.inputs, self.attrs)
self.outputs = {
'Moment1Out': moment1_out,
'Moment2Out': moment2_out,
'ParamOut': param_out,
'Beta1PowOut': beta1_pow_out,
'Beta2PowOut': beta2_pow_out
}
def test_check_output(self):
self.check_output_with_place(paddle.XPUPlace(0))
from xpu.get_test_cover_info import create_test_class, get_xpu_op_support_types, XPUOpTestWrapper
def lamb_step(inputs, attributes):
......@@ -100,21 +55,132 @@ def lamb_step(inputs, attributes):
moment2_unbiased = moment2_out / (1 - beta2_pow)
r_1 = np.linalg.norm(param)
r_2 = np.linalg.norm(moment1_unbiased / (np.sqrt(moment2_unbiased) + epsilon
) + weight_decay * param)
if r_1 > 0.0 and r_2 > 0.0:
lr_t = lr * r_1 / r_2
else:
lr_t = 1.0
r_2 = np.linalg.norm(moment1_unbiased /
(np.sqrt(moment2_unbiased) + epsilon) +
weight_decay * param)
lr_t = lr * r_1 / r_2
param_out = param - lr_t * (moment1_unbiased / (
np.sqrt(moment2_unbiased) + epsilon) + weight_decay * param)
param_out = param - lr_t * (moment1_unbiased /
(np.sqrt(moment2_unbiased) + epsilon) +
weight_decay * param)
beta1_pow_out = beta1_pow * beta1
beta2_pow_out = beta2_pow * beta2
return param_out, moment1_out, moment2_out, beta1_pow_out, beta2_pow_out
"""
class XPUTestLambOp(XPUOpTestWrapper):
def __init__(self):
self.op_name = 'lamb'
self.use_dynamic_create_class = False
class TestLambOp1(XPUOpTest):
def set_attrs(self):
self.attrs = {
'epsilon': 1e-4,
'beta1': 0.78,
'beta2': 0.836,
'weight_decay': 0.01
}
def setUp(self):
'''Test Lamb Op with supplied attributes
'''
# self.op_type = self.op_name
self.__class__.op_type = 'lamb'
self.dtype = self.in_type
param = np.random.uniform(-1, 1, (102, 105)).astype(self.dtype)
grad = np.random.uniform(-1, 1, (102, 105)).astype(self.dtype)
moment1 = np.random.uniform(-1, 1, (102, 105)).astype("float32")
moment2 = np.random.random((102, 105)).astype("float32")
learning_rate = 0.001
self.set_attrs()
beta1_pow = self.attrs['beta1']
beta2_pow = self.attrs['beta2']
self.inputs = {
'Param': param,
'Grad': grad,
'Moment1': moment1,
'Moment2': moment2,
'LearningRate': np.array([learning_rate]).astype("float32"),
'Beta1Pow': np.array([beta1_pow]).astype("float32"),
'Beta2Pow': np.array([beta2_pow]).astype("float32")
}
param_out, moment1_out, moment2_out, \
beta1_pow_out, beta2_pow_out = lamb_step(self.inputs, self.attrs)
self.outputs = {
'Moment1Out': moment1_out,
'Moment2Out': moment2_out,
'ParamOut': param_out,
'Beta1PowOut': beta1_pow_out,
'Beta2PowOut': beta2_pow_out
}
def test_check_output(self):
self.check_output_with_place(paddle.XPUPlace(0))
class TestLambOp2(TestLambOp1):
def set_attrs(self):
self.attrs = {
'epsilon': 1e-8,
'beta1': 0.9,
'beta2': 0.999,
'weight_decay': 0.01
}
class TestLambOpMultipleSteps(TestLambOp1):
def set_attrs(self):
self.attrs = {
'epsilon': 1e-8,
'beta1': 0.9,
'beta2': 0.999,
'weight_decay': 0.01
}
self.num_steps = 10
def test_check_output(self):
for i in range(self.num_steps):
param_out, moment1_out, moment2_out, \
beta1_pow_out, beta2_pow_out = lamb_step(self.inputs, self.attrs)
self.outputs = {
'Moment1Out': moment1_out,
'Moment2Out': moment2_out,
'ParamOut': param_out,
'Beta1PowOut': beta1_pow_out,
'Beta2PowOut': beta2_pow_out
}
# Verify output for this step
self.check_output()
# Output of this step becomes input for next step
self.inputs['Param'] = param_out
self.inputs['Moment1'] = moment1_out
self.inputs['Moment2'] = moment2_out
# Update powers of Beta1 and Beta2 for next time step
self.inputs['Beta1Pow'] = beta1_pow_out
self.inputs['Beta2Pow'] = beta2_pow_out
# Randomize gradient for next step
self.inputs['Grad'] = np.random.uniform(
-1, 1, (102, 105)).astype("float32")
support_types = get_xpu_op_support_types('lamb')
for stype in support_types:
create_test_class(globals(), XPUTestLambOp, stype)
if __name__ == "__main__":
paddle.enable_static()
......
python/paddle/optimizer/lamb.py
浏览文件 @ 1a0ef45e
......@@ -108,6 +108,7 @@ class Lamb(Optimizer):
parameters=None,
grad_clip=None,
exclude_from_weight_decay_fn=None,
multi_precision=False,
name=None):
assert learning_rate is not None
assert beta1 is not None
......@@ -134,7 +135,7 @@ class Lamb(Optimizer):
self._master_weights = {}
self._used_master_weights = {}
# TODO(zengjinle): expose API as soon as possible
self._multi_precision = False
self._multi_precision = multi_precision
def _get_parameter(self, name, scope=None):
if scope is None:
......
Markdown is supported
0% .
You are about to add 0 people to the discussion. Proceed with caution.
先完成此消息的编辑!
想要评论请 注册