The basic structure of a PaddlePaddle program is some nested blocks, as a C++ or Java program.
## Compile and Execution
A PaddlePaddle program consists of two parts -- the first generates a `ProgramDesc` protobuf message that describes the program, and the second runs this message using a C++ class `Executor`.
As described in [graph.md](./graph.md), the first five lines of the following PaddlePaddle program
A simple example PaddlePaddle program can be found in [graph.md](./graph.md):
```python
x=layer.data("images")
...
...
@@ -13,36 +15,112 @@ optimize(cost)
train(cost,reader=mnist.train())
```
generates, or compiles, a PaddelPaddle program, which is represented by the following protobuf message:
The first five lines of the following PaddlePaddle program generates, or, compiles, the `ProgramDesc` message. The last line runs it.
```protobuf
messageProgramDesc{
repeatedBlockDescblocks=1;
## Programs and Blocks
The basic structure of a PaddlePaddle program is some nested blocks, as a C++ or Java program.
- program: some nested blocks
-[block](./block.md):
- some local variable definitions, and
- a sequence of operators
The concept of block comes from usual programs. For example, the following C++ program has three blocks:
```c++
intmain(){// block 0
inti=0;
if(i<10){// block 1
for(intj=0;j<10;j++){// block 2
}
}
return0;
}
```
The following PaddlePaddle program has three blocks:
```python
importpaddleaspd//block0
x=minibatch([10,20,30])# shape=[None, 1]
y=var(1)# shape=[1], value=1
z=minibatch([10,20,30])# shape=[None, 1]
cond=larger_than(x,15)# [false, true, true]
ie=pd.ifelse()
withie.true_block()://block1
d=pd.layer.add_scalar(x,y)
ie.output(d,pd.layer.softmax(d))
withie.false_block()://block2
d=pd.layer.fc(z)
ie.output(d,d+1)
o1,o2=ie(cond)
```
## `BlockDesc` and `ProgramDesc`
All protobuf messages are defined in `framework.proto`.
`BlockDesc` is straight-forward -- it includes local variable definitions, `vars`, and a sequence of operators, `ops`.
```protobuf
messageBlockDesc{
requiredint32parent=1;
repeatedVarDescvars=2;
repeatedOpDescops=3;
}
```
The parent ID indicates the parent block so that operators in a block can refer to variables defined locally and also those defined in their ancestor blocks.
All hierarchical blocks in a program are flattened and stored in an array. The block ID is the index of the block in this array.
```protobuf
messageProgramDesc{
repeatedBlockDescblocks=1;
}
```
### Global Block
The global block is the first one in the above array.
## Operators that Use Blocks
In the above example, the operator `IfElseOp` has two blocks -- the true branch and the false branch.
The definition of `OpDesc` shows that an operator could have some attributes:
```protobuf
messageOpDesc{
AttrDescattrs=1;
...
}
```
and an attribute could be of type block, which is, in fact, a block ID as described above:
```
message AttrDesc {
requiredAttrTypetype=1;
required string name = 1;
// index into ProgramDesc::blocks when type==BLOCK
optionalint32block=2;
enum AttrType {
INT = 1,
STRING = 2,
...
BLOCK = ...
}
required AttrType type = 2;
optional int32 block = 10; // when type == BLOCK
...
}
```
When each of the first five lines runs, related Python function, e.g., `layer.fc`, calls C++ InferShape functions. This InferShape function needs to access the properties of VarDesc's accessed by the current OpDesc. These VarDesc's might not be defined in the current block, but in some ancestor blocks. This requires that we can trace the parent of a block.
A nested block is often an attribute of an operator, most likely, an IfElseOp or a WhileOp. In above solution, all blocks are in `ProgramDesc::blocks`, this implicitly assigns a zero-based ID to each block -- the index of the block in `ProgramDesc::blocks`. So that `AttrDesc::block` could be an integer block ID.
## InferShape
With this design, the InferShape function should take the following parameters:
