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check parameter split

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pull/5367/head
yangzhenzhang 5 years ago
parent 7336ed94fd
commit fbda03bbcc
5 changed files with 251 additions and 147 deletions
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103
mindspore/ccsrc/frontend/parallel/step_auto_parallel.cc
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@ -649,108 +649,13 @@ void ConstructCostGraphEdges(const std::vector<AnfNodePtr> &all_nodes) {
MS_LOG(INFO) << "Constructing edges for cost graph ends.";
}
std::pair<AnfNodePtr, std::vector<AnfNodePtr>> CNodeWithRefKeys(const AnfNodePtr &cnode) {
MS_EXCEPTION_IF_NULL(cnode);
std::vector<AnfNodePtr> refkeys;
if (cnode->isa<CNode>()) {
auto cnode_ptr = cnode->cast<CNodePtr>();
auto inputs = cnode_ptr->inputs();
for (auto &one_input : inputs) {
if (IsValueNode<RefKey>(one_input)) {
refkeys.push_back(one_input);
}
}
if (refkeys.size() >= 1) {
return std::make_pair(cnode, refkeys);
}
}
return {nullptr, refkeys};
}
void AugmentCostGraph(const std::vector<AnfNodePtr> &all_nodes) {
// Step 3
for (auto &node : all_nodes) {
auto cnode_with_refkeys = CNodeWithRefKeys(node);
if ((!node->isa<Parameter>()) && (cnode_with_refkeys.first == nullptr)) {
continue;
}
std::string parameter_name;
AnfNodePtr target_parameter = nullptr;
AnfNodeIndexSet target_set;
if (cnode_with_refkeys.first != nullptr) {
// Dealing with the RefKey case
auto refkeys = cnode_with_refkeys.second;
auto cnode = cnode_with_refkeys.first;
auto cnode_ptr = cnode->cast<CNodePtr>();
if (cnode_ptr == nullptr || !IsValueNode<Primitive>(cnode_ptr->input(0))) {
continue;
}
if (!IsAutoParallelCareNode(cnode_ptr)) {
continue;
}
if (refkeys.size() > 1) {
MS_LOG(EXCEPTION) << "CNode: " << cnode->fullname_with_scope() << " 's inputs have more than 1 RefKeys.";
}
MS_EXCEPTION_IF_NULL(cnode->func_graph());
auto cnode_func_graph = cnode->func_graph();
MS_EXCEPTION_IF_NULL(cnode->func_graph()->manager());
// Find the RefKey being used
auto candidate_set_by_refkey = cnode_func_graph->manager()->node_users()[refkeys[0]];
for (auto &candidate : candidate_set_by_refkey) {
auto candidate_node = candidate.first;
auto c = candidate_node->cast<CNodePtr>();
if (c == nullptr || !IsValueNode<Primitive>(c->input(0))) {
continue;
}
if (!IsAutoParallelCareNode(c)) {
continue;
}
target_set.add(candidate);
}
// Find the corresponding Parameter being used
std::vector<AnfNodePtr> parameters = FindParameterByRefKeyNode(refkeys[0], cnode_func_graph);
if (parameters.size() != 1) {
MS_LOG(EXCEPTION) << "Find parameter by ref key node failed";
}
parameter_name = parameters[0]->cast<ParameterPtr>()->name();
target_parameter = parameters[0];
auto candidate_set_by_para = cnode_func_graph->manager()->node_users()[parameters[0]];
for (auto &candidate : candidate_set_by_para) {
auto candidate_node = candidate.first;
auto c = candidate_node->cast<CNodePtr>();
if (c == nullptr || !IsValueNode<Primitive>(c->input(0))) {
continue;
}
if (!IsAutoParallelCareNode(c)) {
continue;
}
(void)target_set.insert(candidate);
}
} else if (node->isa<Parameter>()) {
// Dealing with the Parameter case
MS_EXCEPTION_IF_NULL(node->func_graph());
MS_EXCEPTION_IF_NULL(node->func_graph()->manager());
auto candidate_set = node->func_graph()->manager()->node_users()[node];
for (auto &candidate : candidate_set) {
auto candidate_node = candidate.first;
auto c = candidate_node->cast<CNodePtr>();
if (c == nullptr || !IsValueNode<Primitive>(c->input(0))) {
continue;
}
if (!IsAutoParallelCareNode(c)) {
continue;
}
(void)target_set.insert(candidate);
}
// In this case, node is a Parameter
parameter_name = node->cast<ParameterPtr>()->name();
target_parameter = node;
}
ParameterUsersInfo parameter_users_info = FindParameterUsers(node, IsAutoParallelCareNode);
auto parameter_name = parameter_users_info.first;
auto target_parameter = parameter_users_info.second.first;
auto target_set = parameter_users_info.second.second;
if (target_set.size() <= 1) {
continue;
}

146
mindspore/ccsrc/frontend/parallel/step_parallel.cc
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@ -2499,6 +2499,149 @@ void HandleForwardMakeTuple(const std::vector<AnfNodePtr> &all_nodes) {
}
}
RefKeyPair CNodeWithRefKeys(const AnfNodePtr &cnode) {
MS_EXCEPTION_IF_NULL(cnode);
std::vector<AnfNodePtr> refkeys;
if (cnode->isa<CNode>()) {
auto cnode_ptr = cnode->cast<CNodePtr>();
auto inputs = cnode_ptr->inputs();
for (auto &one_input : inputs) {
if (IsValueNode<RefKey>(one_input)) {
refkeys.push_back(one_input);
}
}
if (refkeys.size() >= 1) {
return std::make_pair(cnode, refkeys);
}
}
return {nullptr, refkeys};
}
ParameterUsersInfo FindParameterNodeUsers(const AnfNodePtr &node, bool (*IsCareNode)(const CNodePtr &)) {
// In this case, node is a Parameter
ParameterUsersInfo parameter_user_info;
MS_EXCEPTION_IF_NULL(node->func_graph());
MS_EXCEPTION_IF_NULL(node->func_graph()->manager());
auto candidate_set = node->func_graph()->manager()->node_users()[node];
for (auto &candidate : candidate_set) {
auto candidate_node = candidate.first;
auto c = candidate_node->cast<CNodePtr>();
if (c == nullptr || !IsValueNode<Primitive>(c->input(0)) || !IsCareNode(c)) {
continue;
}
(void)parameter_user_info.second.second.insert(candidate);
}
parameter_user_info.first = node->cast<ParameterPtr>()->name();
parameter_user_info.second.first = node;
return parameter_user_info;
}
ParameterUsersInfo FindRefKeyNodeUsers(const RefKeyPair &ref_key_pair, bool (*IsCareNode)(const CNodePtr &)) {
// Dealing with the RefKey case
ParameterUsersInfo parameter_user_info;
auto refkeys = ref_key_pair.second;
auto cnode = ref_key_pair.first;
auto cnode_ptr = cnode->cast<CNodePtr>();
if ((cnode_ptr == nullptr) || !IsValueNode<Primitive>(cnode_ptr->input(0)) || !IsCareNode(cnode_ptr)) {
return parameter_user_info;
}
if (refkeys.size() > 1) {
MS_LOG(EXCEPTION) << "CNode: " << cnode->fullname_with_scope() << "'s inputs have more than 1 RefKeys";
}
MS_EXCEPTION_IF_NULL(cnode->func_graph());
auto cnode_func_graph = cnode->func_graph();
MS_EXCEPTION_IF_NULL(cnode->func_graph()->manager());
// Find the RefKey being used
auto candidate_set_by_refkey = cnode_func_graph->manager()->node_users()[refkeys[0]];
for (auto &candidate : candidate_set_by_refkey) {
auto candidate_node = candidate.first;
auto c = candidate_node->cast<CNodePtr>();
if ((c == nullptr) || !IsValueNode<Primitive>(c->input(0)) || !IsCareNode(c)) {
continue;
}
parameter_user_info.second.second.add(candidate);
}
// Find the corresponding Parameter being used
std::vector<AnfNodePtr> parameters = FindParameterByRefKeyNode(refkeys[0], cnode_func_graph);
if (parameters.size() != 1) {
MS_LOG(EXCEPTION) << "Find parameter by ref key node failed";
}
parameter_user_info.first = parameters[0]->cast<ParameterPtr>()->name();
parameter_user_info.second.first = parameters[0];
auto candidate_set_by_para = cnode_func_graph->manager()->node_users()[parameters[0]];
for (auto &candidate : candidate_set_by_para) {
auto candidate_node = candidate.first;
auto c = candidate_node->cast<CNodePtr>();
if ((c == nullptr) || !IsValueNode<Primitive>(c->input(0)) || !IsCareNode(c)) {
continue;
}
(void)parameter_user_info.second.second.insert(candidate);
}
return parameter_user_info;
}
ParameterUsersInfo FindParameterUsers(const AnfNodePtr &node, bool (*IsCareNode)(const CNodePtr &)) {
ParameterUsersInfo parameter_users_info;
auto cnode_with_refkeys = CNodeWithRefKeys(node);
if (cnode_with_refkeys.first != nullptr) {
// the node is a ref key node
return FindRefKeyNodeUsers(cnode_with_refkeys, IsCareNode);
} else if (node->isa<Parameter>()) {
// the node is a parameter node
return FindParameterNodeUsers(node, IsCareNode);
}
return parameter_users_info;
}
Shape ParameterSliceShape(const std::pair<AnfNodePtr, int> &param_info) {
auto user_cnode = param_info.first->cast<CNodePtr>();
MS_EXCEPTION_IF_NULL(user_cnode);
auto user_input_index = param_info.second;
OperatorInfoPtr op_info = user_cnode->user_data<OperatorInfo>();
MS_EXCEPTION_IF_NULL(op_info);
size_t input_tensor_info_size = op_info->inputs_tensor_info().size();
if (SizeToInt(input_tensor_info_size) <= user_input_index - 1) {
MS_LOG(EXCEPTION) << op_info->name() << ": the size of inputs tensor info is " << input_tensor_info_size
<< ", but the index is " << user_input_index - 1;
}
TensorInfo tensor_info = op_info->inputs_tensor_info()[user_input_index - 1];
MS_LOG(DEBUG) << "The op name is " << op_info->name() << ", the parameter index is " << user_input_index - 1
<< ", the slice shape is " << ShapeToString(tensor_info.slice_shape()) << ", the origin shape is "
<< ShapeToString(tensor_info.shape());
return tensor_info.slice_shape();
}
void CheckParameterSplit(const std::vector<AnfNodePtr> &all_nodes) {
for (auto &node : all_nodes) {
ParameterUsersInfo parameter_users_info = FindParameterUsers(node, IsParallelCareNode);
auto users_set = parameter_users_info.second.second;
if (users_set.size() <= 1) {
continue;
}
auto parameter_name = parameter_users_info.first;
MS_LOG(INFO) << "The parameter: " << parameter_name << " has " << users_set.size() << " users";
auto first_user = users_set.pop();
Shape first_user_slice_shape = ParameterSliceShape(first_user);
for (auto &user : users_set) {
Shape user_slice_shape = ParameterSliceShape(user);
if (first_user_slice_shape != user_slice_shape) {
MS_LOG(EXCEPTION) << "The parameter: " << parameter_name
<< " has multiple users, but the split strategies are different";
}
}
}
}
bool StepParallel(const FuncGraphPtr &root, const opt::OptimizerPtr &optimizer) {
MS_EXCEPTION_IF_NULL(root);
MS_EXCEPTION_IF_NULL(optimizer);
@ -2556,6 +2699,9 @@ bool StepParallel(const FuncGraphPtr &root, const opt::OptimizerPtr &optimizer)
HandleForwardMakeTuple(all_nodes);
// if the input or parameter has multiple users, check whether its split strategies are consistent.
CheckParameterSplit(all_nodes);
// save strategy as checkpoint for multi-train
if (StrategyCheckpoint::GetInstance().SaveCheckPointOn()) {
CheckpointStrategy(all_nodes);

7
mindspore/ccsrc/frontend/parallel/step_parallel.h
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@ -150,6 +150,13 @@ std::vector<std::string> ExtractInputsTensorName(const CNodePtr &node);
std::set<FuncGraphPtr> ForwardGraph(const FuncGraphPtr &root);
bool AnfNodeIsPrimitive(const AnfNodePtr &anf_node, const std::string &prim_name);
using RefKeyPair = std::pair<AnfNodePtr, std::vector<AnfNodePtr>>;
using ParameterUsersInfo = std::pair<std::string, std::pair<AnfNodePtr, AnfNodeIndexSet>>;
RefKeyPair CNodeWithRefKeys(const AnfNodePtr &cnode);
ParameterUsersInfo FindParameterUsers(const AnfNodePtr &node, bool (*IsCareNode)(const CNodePtr &));
} // namespace parallel
} // namespace mindspore

48
tests/ut/python/parallel/test_auto_parallel_reshape.py
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@ -245,51 +245,3 @@ def test_reshape_auto_5():
context.set_auto_parallel_context(parallel_mode="auto_parallel")
net.set_auto_parallel()
_executor.compile(net, x, y)
def test_reshape_auto_6():
class NetWithLoss6(nn.Cell):
def __init__(self, network):
super(NetWithLoss6, self).__init__()
self.loss = VirtualLoss()
self.network = network
def construct(self, x, y):
predict = self.network(x, y)
return self.loss(predict)
class GradWrap6(nn.Cell):
def __init__(self, network):
super(GradWrap6, self).__init__()
self.network = network
def construct(self, x, y):
return grad_all(self.network)(x, y)
class Net(nn.Cell):
def __init__(self):
super().__init__()
self.relu = P.ReLU()
self.mul = P.Mul()
self.reshape = P.Reshape()
self.reduce_mean = P.ReduceMean()
self.wide_w = Parameter(Tensor(np.ones([4, 1024, 1]), dtype=ms.float32), name="weight")
def construct(self, x, y):
out1 = x + self.wide_w
w = self.reshape(self.wide_w, (4, 1024))
out1 = self.reduce_mean(out1, 1)
out1 = out1 - w
out2 = self.mul(y, w)
out = out1 + out2
return out
size = 8
context.set_auto_parallel_context(device_num=size, global_rank=0)
x = Tensor(np.ones([4, 1024, 1]), dtype=ms.float32)
y = Tensor(np.ones([4, 1024,]), dtype=ms.float32)
net = GradWrap6(NetWithLoss6(Net()))
context.set_auto_parallel_context(parallel_mode="auto_parallel")
net.set_auto_parallel()
_executor.compile(net, x, y)

94
tests/ut/python/parallel/test_parameter_multi_users.py
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@ -0,0 +1,94 @@
# Copyright 2020 Huawei Technologies Co., Ltd
#
# 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.
import numpy as np
import pytest
import mindspore as ms
from mindspore import context, Tensor, Parameter
from mindspore.common.api import _executor
from mindspore.nn import Cell, TrainOneStepCell, Momentum
from mindspore.ops import operations as P
class Net(Cell):
def __init__(self, mul_weight, strategy1=None, strategy2=None):
super().__init__()
self.mul = P.Mul().set_strategy(strategy1)
self.mul2 = P.Mul().set_strategy(strategy2)
self.mul_weight = Parameter(mul_weight, "w1")
def construct(self, x, b):
out = self.mul(x, self.mul_weight)
out = self.mul2(out, self.mul_weight)
return out
class Net2(Cell):
def __init__(self, mul_weight, strategy1=None, strategy2=None):
super().__init__()
self.mul = P.Mul().set_strategy(strategy1)
self.mul2 = P.Mul().set_strategy(strategy2)
self.mul_weight = Parameter(mul_weight, "w1")
def construct(self, x, b):
out = self.mul(x, self.mul_weight)
out = self.mul2(x, out)
return out
_x = Tensor(np.ones([128, 64, 32]), dtype=ms.float32)
_w = Tensor(np.ones([128, 64, 32]), dtype=ms.float32)
_b = Tensor(np.ones([128, 64, 32]), dtype=ms.float32)
def compile_net(net):
optimizer = Momentum(net.trainable_params(), learning_rate=0.1, momentum=0.9)
train_net = TrainOneStepCell(net, optimizer)
train_net.set_auto_parallel()
_executor.compile(train_net, _x, _b)
context.reset_auto_parallel_context()
def test_parameter_same_split():
context.set_auto_parallel_context(parallel_mode="semi_auto_parallel", device_num=16, global_rank=0)
strategy1 = ((16, 1, 1), (16, 1, 1))
strategy2 = ((16, 1, 1), (16, 1, 1))
net = Net(_w, strategy1, strategy2)
compile_net(net)
def test_parameter_different_split():
context.set_auto_parallel_context(parallel_mode="semi_auto_parallel", device_num=16, global_rank=0)
strategy1 = ((16, 1, 1), (16, 1, 1))
strategy2 = ((4, 4, 1), (4, 4, 1))
net = Net(_w, strategy1, strategy2)
with pytest.raises(RuntimeError):
compile_net(net)
def test_input_same_split():
context.set_auto_parallel_context(parallel_mode="semi_auto_parallel", device_num=16, global_rank=0)
strategy1 = ((16, 1, 1), (16, 1, 1))
strategy2 = ((16, 1, 1), (16, 1, 1))
net = Net(_w, strategy1, strategy2)
compile_net(net)
def test_input_different_split():
context.set_auto_parallel_context(parallel_mode="semi_auto_parallel", device_num=16, global_rank=0)
strategy1 = ((16, 1, 1), (16, 1, 1))
strategy2 = ((4, 4, 1), (4, 4, 1))
net = Net2(_w, strategy1, strategy2)
with pytest.raises(RuntimeError):
compile_net(net)
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