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未验证 提交 8c166b64 编写于 作者: Q qingqing01 提交者: GitHub
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Merge pull request #14012 from qingqing01/map_api 

Refine detection mAP in metrics.py.
上级 5ed3e6f3 af0fab94
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Showing with 232 addition and 64 deletion
python/paddle/fluid/evaluator.py
浏览文件 @ 8c166b64
......@@ -316,7 +316,7 @@ class DetectionMAP(Evaluator):
gt_label (Variable): The ground truth label index, which is a LoDTensor
with shape [N, 1].
gt_box (Variable): The ground truth bounding box (bbox), which is a
LoDTensor with shape [N, 6]. The layout is [xmin, ymin, xmax, ymax].
LoDTensor with shape [N, 4]. The layout is [xmin, ymin, xmax, ymax].
gt_difficult (Variable|None): Whether this ground truth is a difficult
bounding bbox, which can be a LoDTensor [N, 1] or not set. If None,
it means all the ground truth labels are not difficult bbox.
......
python/paddle/fluid/metrics.py
浏览文件 @ 8c166b64
......@@ -13,8 +13,6 @@
# limitations under the License.
"""
Fluid Metrics
The metrics are accomplished via Python natively.
"""
from __future__ import print_function
......@@ -24,6 +22,12 @@ import copy
import warnings
import six
from .layer_helper import LayerHelper
from .initializer import Constant
from . import unique_name
from .framework import Program, Variable, program_guard
from . import layers
__all__ = [
'MetricBase',
'CompositeMetric',
......@@ -478,67 +482,6 @@ class EditDistance(MetricBase):
return avg_distance, avg_instance_error
class DetectionMAP(MetricBase):
"""
Calculate the detection mean average precision (mAP).
mAP is the metric to measure the accuracy of object detectors
like Faster R-CNN, SSD, etc.
It is the average of the maximum precisions at different recall values.
Please get more information from the following articles:
https://sanchom.wordpress.com/tag/average-precision/
https://arxiv.org/abs/1512.02325
The general steps are as follows:
1. calculate the true positive and false positive according to the input
of detection and labels.
2. calculate mAP value, support two versions: '11 point' and 'integral'.
Examples:
.. code-block:: python
pred = fluid.layers.fc(input=data, size=1000, act="tanh")
batch_map = layers.detection_map(
input,
label,
class_num,
background_label,
overlap_threshold=overlap_threshold,
evaluate_difficult=evaluate_difficult,
ap_version=ap_version)
metric = fluid.metrics.DetectionMAP()
for data in train_reader():
loss, preds, labels = exe.run(fetch_list=[cost, batch_map])
batch_size = data[0]
metric.update(value=batch_map, weight=batch_size)
numpy_map = metric.eval()
"""
def __init__(self, name=None):
super(DetectionMAP, self).__init__(name)
# the current map value
self.value = .0
self.weight = .0
def update(self, value, weight):
if not _is_number_or_matrix_(value):
raise ValueError(
"The 'value' must be a number(int, float) or a numpy ndarray.")
if not _is_number_(weight):
raise ValueError("The 'weight' must be a number(int, float).")
self.value += value
self.weight += weight
def eval(self):
if self.weight == 0:
raise ValueError(
"There is no data in DetectionMAP Metrics. "
"Please check layers.detection_map output has added to DetectionMAP."
)
return self.value / self.weight
class Auc(MetricBase):
"""
Auc metric adapts to the binary classification.
......@@ -616,3 +559,179 @@ class Auc(MetricBase):
idx -= 1
return auc / tot_pos / tot_neg if tot_pos > 0.0 and tot_neg > 0.0 else 0.0
class DetectionMAP(object):
"""
Calculate the detection mean average precision (mAP).
The general steps are as follows:
1. calculate the true positive and false positive according to the input
of detection and labels.
2. calculate mAP value, support two versions: '11 point' and 'integral'.
Please get more information from the following articles:
https://sanchom.wordpress.com/tag/average-precision/
https://arxiv.org/abs/1512.02325
Args:
input (Variable): The detection results, which is a LoDTensor with shape
[M, 6]. The layout is [label, confidence, xmin, ymin, xmax, ymax].
gt_label (Variable): The ground truth label index, which is a LoDTensor
with shape [N, 1].
gt_box (Variable): The ground truth bounding box (bbox), which is a
LoDTensor with shape [N, 4]. The layout is [xmin, ymin, xmax, ymax].
gt_difficult (Variable|None): Whether this ground truth is a difficult
bounding bbox, which can be a LoDTensor [N, 1] or not set. If None,
it means all the ground truth labels are not difficult bbox.
class_num (int): The class number.
background_label (int): The index of background label, the background
label will be ignored. If set to -1, then all categories will be
considered, 0 by defalut.
overlap_threshold (float): The threshold for deciding true/false
positive, 0.5 by defalut.
evaluate_difficult (bool): Whether to consider difficult ground truth
for evaluation, True by defalut. This argument does not work when
gt_difficult is None.
ap_version (string): The average precision calculation ways, it must be
'integral' or '11point'. Please check
https://sanchom.wordpress.com/tag/average-precision/ for details.
- 11point: the 11-point interpolated average precision.
- integral: the natural integral of the precision-recall curve.
Examples:
.. code-block:: python
exe = fluid.Executor(place)
map_evaluator = fluid.Evaluator.DetectionMAP(input,
gt_label, gt_box, gt_difficult)
cur_map, accum_map = map_evaluator.get_map_var()
fetch = [cost, cur_map, accum_map]
for epoch in PASS_NUM:
map_evaluator.reset(exe)
for data in batches:
loss, cur_map_v, accum_map_v = exe.run(fetch_list=fetch)
In the above example:
'cur_map_v' is the mAP of current mini-batch.
'accum_map_v' is the accumulative mAP of one pass.
"""
def __init__(self,
input,
gt_label,
gt_box,
gt_difficult=None,
class_num=None,
background_label=0,
overlap_threshold=0.5,
evaluate_difficult=True,
ap_version='integral'):
self.helper = LayerHelper('map_eval')
gt_label = layers.cast(x=gt_label, dtype=gt_box.dtype)
if gt_difficult:
gt_difficult = layers.cast(x=gt_difficult, dtype=gt_box.dtype)
label = layers.concat([gt_label, gt_difficult, gt_box], axis=1)
else:
label = layers.concat([gt_label, gt_box], axis=1)
# calculate mean average precision (mAP) of current mini-batch
map = layers.detection_map(
input,
label,
class_num,
background_label,
overlap_threshold=overlap_threshold,
evaluate_difficult=evaluate_difficult,
ap_version=ap_version)
states = []
states.append(
self._create_state(
dtype='int32', shape=None, suffix='accum_pos_count'))
states.append(
self._create_state(
dtype='float32', shape=None, suffix='accum_true_pos'))
states.append(
self._create_state(
dtype='float32', shape=None, suffix='accum_false_pos'))
var = self._create_state(dtype='int32', shape=[1], suffix='has_state')
self.helper.set_variable_initializer(
var, initializer=Constant(value=int(0)))
self.has_state = var
# calculate accumulative mAP
accum_map = layers.detection_map(
input,
label,
class_num,
background_label,
overlap_threshold=overlap_threshold,
evaluate_difficult=evaluate_difficult,
has_state=self.has_state,
input_states=states,
out_states=states,
ap_version=ap_version)
layers.fill_constant(
shape=self.has_state.shape,
value=1,
dtype=self.has_state.dtype,
out=self.has_state)
self.cur_map = map
self.accum_map = accum_map
def _create_state(self, suffix, dtype, shape):
"""
Create state variable.
Args:
suffix(str): the state suffix.
dtype(str|core.VarDesc.VarType): the state data type
shape(tuple|list): the shape of state
Returns: State variable
"""
state = self.helper.create_variable(
name="_".join([unique_name.generate(self.helper.name), suffix]),
persistable=True,
dtype=dtype,
shape=shape)
return state
def get_map_var(self):
"""
Returns: mAP variable of current mini-batch and
accumulative mAP variable cross mini-batches.
"""
return self.cur_map, self.accum_map
def reset(self, executor, reset_program=None):
"""
Reset metric states at the begin of each pass/user specified batch.
Args:
executor(Executor): a executor for executing
the reset_program.
reset_program(Program|None): a single Program for reset process.
If None, will create a Program.
"""
def _clone_var_(block, var):
assert isinstance(var, Variable)
return block.create_var(
name=var.name,
shape=var.shape,
dtype=var.dtype,
type=var.type,
lod_level=var.lod_level,
persistable=var.persistable)
if reset_program is None:
reset_program = Program()
with program_guard(main_program=reset_program):
var = _clone_var_(reset_program.current_block(), self.has_state)
layers.fill_constant(
shape=var.shape, value=0, dtype=var.dtype, out=var)
executor.run(reset_program)
python/paddle/fluid/tests/unittests/test_metrics.py 0 → 100644
浏览文件 @ 8c166b64
# Copyright (c) 2018 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.
import unittest
import paddle.fluid as fluid
from paddle.fluid.framework import Program, program_guard
class TestMetricsDetectionMap(unittest.TestCase):
def test_detection_map(self):
program = fluid.Program()
with program_guard(program):
detect_res = fluid.layers.data(
name='detect_res',
shape=[10, 6],
append_batch_size=False,
dtype='float32')
label = fluid.layers.data(
name='label',
shape=[10, 1],
append_batch_size=False,
dtype='float32')
box = fluid.layers.data(
name='bbox',
shape=[10, 4],
append_batch_size=False,
dtype='float32')
map_eval = fluid.metrics.DetectionMAP(
detect_res, label, box, class_num=21)
cur_map, accm_map = map_eval.get_map_var()
self.assertIsNotNone(cur_map)
self.assertIsNotNone(accm_map)
print(str(program))
if __name__ == '__main__':
unittest.main()
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