提交 09103084 编写于 作者: M minqiyang

Polish compat.py and add unittest for it

上级 c3fdf3ae
...@@ -202,7 +202,6 @@ std::vector<std::string> OpDesc::AttrNames() const { ...@@ -202,7 +202,6 @@ std::vector<std::string> OpDesc::AttrNames() const {
} }
void OpDesc::SetAttr(const std::string &name, const Attribute &v) { void OpDesc::SetAttr(const std::string &name, const Attribute &v) {
VLOG(11) << "SetAttr: " << Type() << ", " << name << ", " << v.which();
// NOTICE(minqiyang): pybind11 will take the empty list in python as // NOTICE(minqiyang): pybind11 will take the empty list in python as
// the std::vector<int> type in C++; so we have to change the attr's type // the std::vector<int> type in C++; so we have to change the attr's type
// here if we meet this issue // here if we meet this issue
......
...@@ -15,18 +15,77 @@ ...@@ -15,18 +15,77 @@
import six import six
import math import math
__all__ = [
'to_literal_str',
'to_bytes',
'round',
'floor_division',
'get_exception_message',
]
# str and bytes related functions # str and bytes related functions
def to_literal_str(obj, encoding='utf-8'): def to_literal_str(obj, encoding='utf-8', inplace=False):
"""
All string in PaddlePaddle should be represented as a literal string.
This function will convert object to a literal string without any encoding.
Especially, if the object type is a list or set container, we will iterate
all items in the object and convert them to literal string.
In Python3:
Decode the bytes type object to str type with specific encoding
In Python2:
Decode the str type object to unicode type with specific encoding
Args:
obj(unicode|str|bytes|list|set) : The object to be decoded.
encoding(str) : The encoding format to decode a string
inplace(bool) : If we change the original object or we create a new one
Returns:
Decoded result of obj
"""
if obj is None:
return obj
if isinstance(obj, list): if isinstance(obj, list):
if inplace:
for i in six.moves.xrange(len(obj)):
obj[i] = _to_literal_str(obj[i], encoding)
return obj
else:
return [_to_literal_str(item, encoding) for item in obj] return [_to_literal_str(item, encoding) for item in obj]
elif isinstance(obj, set): elif isinstance(obj, set):
if inplace:
for item in obj:
obj.remove(item)
obj.add(_to_literal_str(item, encoding))
return obj
else:
return set([_to_literal_str(item, encoding) for item in obj]) return set([_to_literal_str(item, encoding) for item in obj])
else: else:
return _to_literal_str(obj, encoding) return _to_literal_str(obj, encoding)
def _to_literal_str(obj, encoding): def _to_literal_str(obj, encoding):
"""
In Python3:
Decode the bytes type object to str type with specific encoding
In Python2:
Decode the str type object to unicode type with specific encoding,
or we just return the unicode string of object
Args:
obj(unicode|str|bytes) : The object to be decoded.
encoding(str) : The encoding format
Returns:
decoded result of obj
"""
if obj is None:
return obj
if isinstance(obj, six.binary_type): if isinstance(obj, six.binary_type):
return obj.decode(encoding) return obj.decode(encoding)
elif isinstance(obj, six.text_type): elif isinstance(obj, six.text_type):
...@@ -35,16 +94,70 @@ def _to_literal_str(obj, encoding): ...@@ -35,16 +94,70 @@ def _to_literal_str(obj, encoding):
return six.u(obj) return six.u(obj)
def to_bytes(obj, encoding='utf-8'): def to_bytes(obj, encoding='utf-8', inplace=False):
"""
All string in PaddlePaddle should be represented as a literal string.
This function will convert object to a bytes with specific encoding.
Especially, if the object type is a list or set container, we will iterate
all items in the object and convert them to bytes.
In Python3:
Encode the str type object to bytes type with specific encoding
In Python2:
Encode the unicode type object to str type with specific encoding,
or we just return the 8-bit string of object
Args:
obj(unicode|str|bytes|list|set) : The object to be encoded.
encoding(str) : The encoding format to encode a string
inplace(bool) : If we change the original object or we create a new one
Returns:
Decoded result of obj
"""
if obj is None:
return obj
if isinstance(obj, list): if isinstance(obj, list):
if inplace:
for i in six.moves.xrange(len(obj)):
obj[i] = _to_bytes(obj[i], encoding)
return obj
else:
return [_to_bytes(item, encoding) for item in obj] return [_to_bytes(item, encoding) for item in obj]
elif isinstance(obj, set): elif isinstance(obj, set):
if inplace:
for item in obj:
obj.remove(item)
obj.add(_to_bytes(item, encoding))
return obj
else:
return set([_to_bytes(item, encoding) for item in obj]) return set([_to_bytes(item, encoding) for item in obj])
else: else:
return _to_bytes(obj, encoding) return _to_bytes(obj, encoding)
def _to_bytes(obj, encoding): def _to_bytes(obj, encoding):
"""
In Python3:
Encode the str type object to bytes type with specific encoding
In Python2:
Encode the unicode type object to str type with specific encoding,
or we just return the 8-bit string of object
Args:
obj(unicode|str|bytes) : The object to be encoded.
encoding(str) : The encoding format
Returns:
encoded result of obj
"""
if obj is None:
return obj
assert encoding is not None
if isinstance(obj, six.text_type): if isinstance(obj, six.text_type):
return obj.encode(encoding) return obj.encode(encoding)
elif isinstance(obj, six.binary_type): elif isinstance(obj, six.binary_type):
...@@ -64,15 +177,48 @@ def round(x, d=0): ...@@ -64,15 +177,48 @@ def round(x, d=0):
Returns: Returns:
round result of x round result of x
""" """
p = 10**d if six.PY3:
# The official walkaround of round in Python3 is incorrect
# we implement accroding this answer: https://www.techforgeek.info/round_python.html
if x > 0.0:
p = 10 ** d
return float(math.floor((x * p) + math.copysign(0.5, x))) / p return float(math.floor((x * p) + math.copysign(0.5, x))) / p
else:
p = 10 ** d
return float(math.ceil((x * p) + math.copysign(0.5, x))) / p
else:
import __builtin__
return __builtin__.round(x, d)
def floor_division(x, y): def floor_division(x, y):
"""
Compatible division which act the same behaviour in Python3 and Python2,
whose result will be a int value of floor(x / y) in Python3 and value of
(x / y) in Python2.
Args:
x(int|float) : The number to divide.
y(int|float) : The number to be divided
Returns:
division result of x // y
"""
return x // y return x // y
# exception related functions # exception related functions
def get_exception_message(exc): def get_exception_message(exc):
"""
Get the error message of a specific exception
Args:
exec(Exception) : The exception to get error message.
Returns:
the error message of exec
"""
assert exc is not None
if six.PY2: if six.PY2:
return exc.message return exc.message
else: else:
......
...@@ -20,6 +20,7 @@ from .layer_function_generator import autodoc, templatedoc ...@@ -20,6 +20,7 @@ from .layer_function_generator import autodoc, templatedoc
from ..layer_helper import LayerHelper from ..layer_helper import LayerHelper
from . import tensor from . import tensor
from . import nn from . import nn
from .. import compat as cpt
import math import math
import six import six
from functools import reduce from functools import reduce
...@@ -1104,7 +1105,8 @@ def multi_box_head(inputs, ...@@ -1104,7 +1105,8 @@ def multi_box_head(inputs,
mbox_loc = nn.transpose(mbox_loc, perm=[0, 2, 3, 1]) mbox_loc = nn.transpose(mbox_loc, perm=[0, 2, 3, 1])
new_shape = [ new_shape = [
mbox_loc.shape[0], mbox_loc.shape[0],
mbox_loc.shape[1] * mbox_loc.shape[2] * mbox_loc.shape[3] / 4, 4 mbox_loc.shape[1] * mbox_loc.shape[2] * cpt.floor_division(mbox_loc.shape[3], 4),
4
] ]
mbox_loc_flatten = nn.reshape(mbox_loc, shape=new_shape) mbox_loc_flatten = nn.reshape(mbox_loc, shape=new_shape)
mbox_locs.append(mbox_loc_flatten) mbox_locs.append(mbox_loc_flatten)
...@@ -1119,8 +1121,9 @@ def multi_box_head(inputs, ...@@ -1119,8 +1121,9 @@ def multi_box_head(inputs,
stride=stride) stride=stride)
conf_loc = nn.transpose(conf_loc, perm=[0, 2, 3, 1]) conf_loc = nn.transpose(conf_loc, perm=[0, 2, 3, 1])
new_shape = [ new_shape = [
conf_loc.shape[0], conf_loc.shape[1] * conf_loc.shape[2] * conf_loc.shape[0],
conf_loc.shape[3] / num_classes, num_classes conf_loc.shape[1] * conf_loc.shape[2] * cpt.floor_division(conf_loc.shape[3], num_classes),
num_classes
] ]
conf_loc_flatten = nn.reshape(conf_loc, shape=new_shape) conf_loc_flatten = nn.reshape(conf_loc, shape=new_shape)
mbox_confs.append(conf_loc_flatten) mbox_confs.append(conf_loc_flatten)
......
此差异已折叠。
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