Skip to content
体验新版
项目
组织
正在加载...
登录
切换导航
打开侧边栏
Crayon鑫
Paddle
提交
ab5a3560
P
Paddle
项目概览
Crayon鑫
/
Paddle
与 Fork 源项目一致
Fork自
PaddlePaddle / Paddle
通知
1
Star
1
Fork
0
代码
文件
提交
分支
Tags
贡献者
分支图
Diff
Issue
1
列表
看板
标记
里程碑
合并请求
0
Wiki
0
Wiki
分析
仓库
DevOps
项目成员
Pages
P
Paddle
项目概览
项目概览
详情
发布
仓库
仓库
文件
提交
分支
标签
贡献者
分支图
比较
Issue
1
Issue
1
列表
看板
标记
里程碑
合并请求
0
合并请求
0
Pages
分析
分析
仓库分析
DevOps
Wiki
0
Wiki
成员
成员
收起侧边栏
关闭侧边栏
动态
分支图
创建新Issue
提交
Issue看板
未验证
提交
ab5a3560
编写于
3月 26, 2018
作者:
T
Thuan Nguyen
提交者:
GitHub
3月 26, 2018
浏览文件
操作
浏览文件
下载
电子邮件补丁
差异文件
Create go_op design doc (#9389)
* Create go_op design doc
上级
6a97c02e
变更
1
显示空白变更内容
内联
并排
Showing
1 changed file
with
231 addition
and
0 deletion
+231
-0
doc/fluid/design/concurrent/go_op.md
doc/fluid/design/concurrent/go_op.md
+231
-0
未找到文件。
doc/fluid/design/concurrent/go_op.md
0 → 100644
浏览文件 @
ab5a3560
# go_op Design
## Introduction
The
**go_op**
allows user's of PaddlePaddle to run program blocks on a detached
thread. It works in conjuction with CSP operators (channel_send,
channel_receive, channel_open, channel_close, and select) to allow users to
concurrently process data and communicate easily between different threads.
## How to use it
```
channel = fluid.make_channel(dtype=core.VarDesc.VarType.LOD_TENSOR)
with fluid.Go():
# Send a tensor of value 99 to "channel" on a detached thread
tensor = fill_constant(shape=[1], dtype='int', value=99)
tensor.stop_gradient = True
fluid.channel_send(channel, tensor)
# Receive sent tensor from "channel" on the main thread
result = fill_constant(shape=[1], dtype='int', value=-1)
fluid.channel_recv(ch, result)
```
The go operator can be accessed by using the fluid.Go() control flow. This
will create a new sub block, where the user can add additional operators
to be ran on the thread.
**Note:**
Since back propegation is currently not support in the go_op, users
should ensure that operators in the go block does not require gradient
calculations.
## How it Works
Similar to other control blocks, go_op will create a sub block and add it
as a child to the current block. Operators and variables defined in this
block will be added to the go sub_block.
In addition, the go operator will create a new child scope whose parent is
the global scope. Please refer to
[
block captures
](
#block-captures
)
for more
information.
When Paddle executor runs go_op, go_op will take the sub_block and pass it to
the executor.run method (along with a newly created local scope) on a detached
thread.
An example of the generated program description is shown below. Take note of
the
**go_op**
in particular. It is added as an operator in the current
block (in this example, block0). The
**go_op**
contains a
`sub_block`
attribute, which points to the id of the block that will be executed in a
detached thread.
```
blocks {
idx: 0
parent_idx: -1
vars {
name: "return_value"
type {
type: LOD_TENSOR
lod_tensor {
tensor {
data_type: INT64
}
}
}
}
vars {
name: "status_recv"
type {
type: LOD_TENSOR
lod_tensor {
tensor {
data_type: BOOL
}
}
}
}
...
ops {
outputs {
parameter: "Out"
arguments: "channel"
}
type: "channel_create"
attrs {
name: "data_type"
type: INT
i: 7
}
attrs {
name: "capacity"
type: INT
i: 0
}
}
ops {
inputs {
parameter: "X"
arguments: "channel"
}
type: "go"
attrs {
name: "sub_block"
type: BLOCK
block_idx: 1
}
}
ops {
inputs {
parameter: "Channel"
arguments: "channel"
}
outputs {
parameter: "Out"
arguments: "return_value"
}
outputs {
parameter: "Status"
arguments: "status_recv"
}
type: "channel_recv"
}
...
}
blocks {
idx: 1
parent_idx: 0
vars {
name: "status"
type {
type: LOD_TENSOR
lod_tensor {
tensor {
data_type: BOOL
}
}
}
}
...
ops {
outputs {
parameter: "Out"
arguments: "fill_constant_1.tmp_0"
}
type: "fill_constant"
attrs {
name: "force_cpu"
type: BOOLEAN
b: false
}
attrs {
name: "value"
type: FLOAT
f: 99.0
}
attrs {
name: "shape"
type: INTS
ints: 1
}
attrs {
name: "dtype"
type: INT
i: 3
}
}
ops {
inputs {
parameter: "Channel"
arguments: "channel"
}
inputs {
parameter: "X"
arguments: "fill_constant_1.tmp_0"
}
outputs {
parameter: "Status"
arguments: "status"
}
type: "channel_send"
attrs {
name: "copy"
type: BOOLEAN
b: false
}
}
```
## Current Limitations
#### <a name="block-captures"></a>Scopes and block captures:
Paddle utilizes
[
scopes
](
./../concepts/scope.md
)
to store variables used in a
block. When a block is executed, a new local scope is created from the parent
scope (ie: scope derived from the parent block) and associated with the new
child block. After the block finishes executing, then the local scope and
all associated variables in the scope is deleted.
This works well in a single threaded scenario, however with introduction of
go_op, a child block may continue to execute even after the parent block has
exited. If the go_op tries to access variables located in the parent block's
scope, it may receive a segmentation fault because the parent scope may have
been deleted.
We need to implement block closures in order to prevent access to parent
scope variables from causing a segmentation fault. As a temporary workaround,
please ensure that all variables accessed in the go block is not destructed
before it is being accessed. Currently, the go_op will explicitly enforce
this requirement and raise an exception if a variable could not be found in
the scope.
Please refer to
[
Closure issue
](
https://github.com/PaddlePaddle/Paddle/issues/8502
)
for more details.
#### Green Threads
Golang utilizes
`green threads`
, which is a mechnism for the runtime library to
manage multiple threads (instead of natively by the OS). Green threads usually
allows for faster thread creation and switching, as there is less overhead
when spawning these threads. For the first version of CSP, we only support
OS threads.
#### Backward Propegation:
go_op currently does not support backwards propagation. Please use go_op with
non training operators.
编辑
预览
Markdown
is supported
0%
请重试
或
添加新附件
.
添加附件
取消
You are about to add
0
people
to the discussion. Proceed with caution.
先完成此消息的编辑!
取消
想要评论请
注册
或
登录