I am working on a competition on Kaggle, where the evaluation metric is defined as

This competition is evaluated on the mean average precision at different intersection over union (IoU) thresholds. The IoU of a proposed set of object pixels and a set of true object pixels is calculated as:

```
IoU(A,B)=(A∩B)/(A∪B)
```

The metric sweeps over a range of IoU thresholds, at each point calculating an average precision value. The threshold values range from 0.5 to 0.95 with a step size of 0.05: `(0.5, 0.55, 0.6, 0.65, 0.7, 0.75, 0.8, 0.85, 0.9, 0.95)`

. In other words, at a threshold of 0.5, a predicted object is considered a "hit" if its intersection over union with a ground truth object is greater than 0.5. At each threshold value t, a precision value is calculated based on the number of true positives `(TP)`

, false negatives `(FN)`

, and false positives `(FP)`

resulting from comparing the predicted object to all ground truth objects:

```
TP(t)/TP(t)+FP(t)+FN(t).
```

A true positive is counted when a single predicted object matches a ground truth object with an IoU above the threshold. A false positive indicates a predicted object had no associated ground truth object. A false negative indicates a ground truth object had no associated predicted object. The average precision of a single image is then calculated as the mean of the above precision values at each IoU threshold:

```
(1/|thresholds|)*∑tTP(t)/TP(t)+FP(t)+FN(t)
```

Now, I have written this function in pure numpy as it was much easier to code in that and I have decorated it with `tf.py_fucn()`

in order to use with it with Keras. Here is the sample code:

```
def iou_metric(y_true_in, y_pred_in, fix_zero=False):
labels = y_true_in
y_pred = y_pred_in
true_objects = 2
pred_objects = 2
if fix_zero:
if np.sum(y_true_in) == 0:
return 1 if np.sum(y_pred_in) == 0 else 0
intersection = np.histogram2d(labels.flatten(), y_pred.flatten(), bins=(true_objects, pred_objects))[0]
# Compute areas (needed for finding the union between all objects)
area_true = np.histogram(labels, bins = true_objects)[0]
area_pred = np.histogram(y_pred, bins = pred_objects)[0]
area_true = np.expand_dims(area_true, -1)
area_pred = np.expand_dims(area_pred, 0)
# Compute union
union = area_true + area_pred - intersection
# Exclude background from the analysis
intersection = intersection[1:,1:]
union = union[1:,1:]
union[union == 0] = 1e-9
# Compute the intersection over union
iou = intersection / union
# Precision helper function
def precision_at(threshold, iou):
matches = iou > threshold
true_positives = np.sum(matches, axis=1) == 1 # Correct objects
false_positives = np.sum(matches, axis=0) == 0 # Missed objects
false_negatives = np.sum(matches, axis=1) == 0 # Extra objects
tp, fp, fn = np.sum(true_positives), np.sum(false_positives), np.sum(false_negatives)
return tp, fp, fn
# Loop over IoU thresholds
prec = []
for t in np.arange(0.5, 1.0, 0.05):
tp, fp, fn = precision_at(t, iou)
if (tp + fp + fn) > 0:
p = tp / (tp + fp + fn)
else:
p = 0
prec.append(p)
return np.mean(prec)
```

I tried to convert it into pure `tf`

function but was unable to do it as I am not able to figure out how the `control dependencies`

would work out. Can anyone help me with it?

`pyfunc`

? – Jonas Adler Jan 5 '19 at 18:25`tf.py_func()`

only as of now – mlRocks Jan 5 '19 at 18:30`tf.metrics.mean_iou`

. – Zaccharie Ramzi May 8 '19 at 15:04