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How to find a specific value in a numpy array?

I have my np array list with tuples like np.array[(0,1), (2,5),...]
Now I want to search for the index of a certain value. But I just know the left side of the tuple. The approach I have found to get the index of a value (if you have both) is the following:
x = np.array(list(map(lambda x: x== (2, 5), groups)))
print(np.where(x))
But how can I search if I only know x==(2,) but not the right number?

As stated in https://numpy.org/doc/stable/reference/generated/numpy.where.html#numpy.where, it is preferred to use np.nonzero directly. I would also recommend reading up on NumPy's use of boolean masking. The answer to your question, is this:
import numpy as np
i = 0 # index of number we're looking for
j = 2 # number we're looking for
mask = x[:,i] == j # Generate a binary/boolean mask for this array and this comparison
indices = np.nonzero(mask) # Find indices where x==(2,_)
print(indices)
In NumPy it's generally preferred to avoid loops like the one you use above. Instead, you should use vectorized operations. So, try to avoid the list(map()) construction you used here.

It might just be easier that you think.
Example:
# Create a sample array.
a = np.array([(0, 1), (2, 5), (3, 2), (4, 6)])
# Use slicing to return all rows, there column 0 equals 2.
(a[:,0] == 2).argmax()
>>> 1
# Test the returned index against the array to verify.
a[1]
>>> array([2, 5])
Another way to look at the array is shown below, and will help put the concept of rows/columns into perspective for the mentioned array:
>>> a
array([[0, 1],
[2, 5],
[3, 2],
[4, 6]])

What are the operators == and * being used for in this code?

I need to understand the usage of operators in the following python code snippet. I'm not familiar with the usage of * in the np.zeros() statement. It looks like the pointer dereferencing operator in c, but I'm guessing not.
Also, what is the usage of == in the assignment statement? This looks like an equality test, but True and False are not valid indexes into a numpy array.
new_segs = np.zeros((*raw_segs.shape, 3), dtype=np.uint8)
i = 0
for val in [x['handle'] for x in detections]:
colors = [(255,0,255), (55,0,55), (34,33,87)]
new_segs[raw_segs == val] = colors[i % len(colors)]
Sorry for the crappy question. Have tried looking for answers but I get unsatisfactory answers with searches on operator usage.

The star * unpacking was explained. The == in numpy is a boolean mask. You are passing an array that should be the same size of the other numpy array but this tells it which elements of the array to include or not.

The star * is the unpacking operator; it expands raw_segs.shape to a tuple of values.
You're incorrect about indices: True and False are valid, being interpreted as 1 and 0, respectively. Try it and see:
>>> new_segs = np.array((3.3, 4.4))
>>> new_segs[0]
3.2999999999999998
>>> new_segs[True]
4.4000000000000004
>>>

* unpacks the shape tuple, allowing it be joined with the 3 to make a bigger shape tuple:
In [26]: x = np.zeros((2,3))
In [28]: y = np.zeros((*x.shape, 3))
In [29]: y.shape
Out[29]: (2, 3, 3)
another way to do that:
In [30]: y = np.zeros(x.shape+(3,))
In [31]: y.shape
Out[31]: (2, 3, 3)
and
In [32]: i,j = x.shape
In [33]: y = np.zeros((i,j,3))
In [34]: y.shape
Out[34]: (2, 3, 3)

Python equivalent to Matlab [a,b] = sort(y)

I am pretty new to the Python language and want to know how to the following
(1) y = [some vector]
(2) z = [some other vector]
(3) [ynew,indx] = sort(y)
(4) znew = z(indx)
I can do lines 1,2 and 4 but line 3 is giving me fits. Any suggestions. What I am looking for is not a user written function but something intrinsic to the language itself.
Thanks

using NumPy for line 3, assuming y is a row vector, otherwise axis=0 is needed:
ynew=y.sort(axis=1)
indx=y.argsort(axis=1)

I had the same problem with the following form, and the solution provided didn't work for me. I found a solution that work for me and I thought I could share it here in case anyone has the same problem:
My goal was to sort x in ascending number and move the indices of y in the same manner
x = np.array([00, 44, 22, 33, 11]) # create an array to sort
y = np.array([00, 11, 22, 33, 44]) # another array where you want to move index in the same way you did x
x_sorted = x[x.argsort()] # x sorted in ascending number
y_sorted = y[x.argsort()] # y sorted
The difference is that you don't store the original index position but, in my case, it wasn't a problem since I did that to modify multiple array following one. Thus, by using x.argsort(), it already gives where index have to be moved and, I think, will achieve the same results.

You could try to do something like the following:
import numpy as np
y = [1,3,2]
z = [3,2,1]
indx = [i[0] for i in sorted(enumerate(y), key=lambda x:x[1])]
print(indx)
#convert z to numpy array in order to use np.ix_ function
z = np.asarray(z)
znew = z[np.ix_(indx)]
print(znew)
Results:
#the indx is
[0, 2, 1]
#the znew is
array([3, 1, 2])

Converting list of 2-D arrays into a 3-D array, adding elements along "fast" axes

I have a list of 2d numpy arrays. As a test, consider the following list:
lst = [np.arange(10).reshape(5,2)]*10
Now I can get at a particular data element by:
lst[k][j,i]
I would like to convert this to a numpy array so that I can index it:
array[k,j,i]
i.e., the shape should be (10, 5, 2).
This seems to work, but seems completely unnecessary:
z = np.empty((10,5,2))
for i,x in enumerate(z):
x[:,:] = lst[i]
These don't work:
np.hstack(lst)
np.vstack(lst)
np.dstack(lst) #this is closest, but gives wrong shape (5, 2, 10)
I suppose I could pair a np.dstack with a np.rollaxis, but again, that doesn't seem quite right ...
Is there a good way to do this with numpy?
I've looked at this very related post, but I can't quite seem to work it out.

This should work simply by calling the array constructor, i.e. np.array(lst).
>>> l = [np.arange(10).reshape((5,2)) for i in range(10)]
>>> np.array(l).shape
(10, 5, 2)

Do you mean like
>>> lst = [np.arange(10).reshape(5,2)]*10
>>> arr = np.array(lst)
>>> arr.shape
(10, 5, 2)
?

Is there a NumPy function to return the first index of something in an array?

I know there is a method for a Python list to return the first index of something:
>>> xs = [1, 2, 3]
>>> xs.index(2)
1
Is there something like that for NumPy arrays?

Yes, given an array, array, and a value, item to search for, you can use np.where as:
itemindex = numpy.where(array == item)
The result is a tuple with first all the row indices, then all the column indices.
For example, if an array is two dimensions and it contained your item at two locations then
array[itemindex[0][0]][itemindex[1][0]]
would be equal to your item and so would be:
array[itemindex[0][1]][itemindex[1][1]]

If you need the index of the first occurrence of only one value, you can use nonzero (or where, which amounts to the same thing in this case):
>>> t = array([1, 1, 1, 2, 2, 3, 8, 3, 8, 8])
>>> nonzero(t == 8)
(array([6, 8, 9]),)
>>> nonzero(t == 8)[0][0]
6
If you need the first index of each of many values, you could obviously do the same as above repeatedly, but there is a trick that may be faster. The following finds the indices of the first element of each subsequence:
>>> nonzero(r_[1, diff(t)[:-1]])
(array([0, 3, 5, 6, 7, 8]),)
Notice that it finds the beginning of both subsequence of 3s and both subsequences of 8s:
[1, 1, 1, 2, 2, 3, 8, 3, 8, 8]
So it's slightly different than finding the first occurrence of each value. In your program, you may be able to work with a sorted version of t to get what you want:
>>> st = sorted(t)
>>> nonzero(r_[1, diff(st)[:-1]])
(array([0, 3, 5, 7]),)

You can also convert a NumPy array to list in the air and get its index. For example,
l = [1,2,3,4,5] # Python list
a = numpy.array(l) # NumPy array
i = a.tolist().index(2) # i will return index of 2
print i
It will print 1.

Just to add a very performant and handy numba alternative based on np.ndenumerate to find the first index:
from numba import njit
import numpy as np
#njit
def index(array, item):
for idx, val in np.ndenumerate(array):
if val == item:
return idx
# If no item was found return None, other return types might be a problem due to
# numbas type inference.
This is pretty fast and deals naturally with multidimensional arrays:
>>> arr1 = np.ones((100, 100, 100))
>>> arr1[2, 2, 2] = 2
>>> index(arr1, 2)
(2, 2, 2)
>>> arr2 = np.ones(20)
>>> arr2[5] = 2
>>> index(arr2, 2)
(5,)
This can be much faster (because it's short-circuiting the operation) than any approach using np.where or np.nonzero.
However np.argwhere could also deal gracefully with multidimensional arrays (you would need to manually cast it to a tuple and it's not short-circuited) but it would fail if no match is found:
>>> tuple(np.argwhere(arr1 == 2)[0])
(2, 2, 2)
>>> tuple(np.argwhere(arr2 == 2)[0])
(5,)

l.index(x) returns the smallest i such that i is the index of the first occurrence of x in the list.
One can safely assume that the index() function in Python is implemented so that it stops after finding the first match, and this results in an optimal average performance.
For finding an element stopping after the first match in a NumPy array use an iterator (ndenumerate).
In [67]: l=range(100)
In [68]: l.index(2)
Out[68]: 2
NumPy array:
In [69]: a = np.arange(100)
In [70]: next((idx for idx, val in np.ndenumerate(a) if val==2))
Out[70]: (2L,)
Note that both methods index() and next return an error if the element is not found. With next, one can use a second argument to return a special value in case the element is not found, e.g.
In [77]: next((idx for idx, val in np.ndenumerate(a) if val==400),None)
There are other functions in NumPy (argmax, where, and nonzero) that can be used to find an element in an array, but they all have the drawback of going through the whole array looking for all occurrences, thus not being optimized for finding the first element. Note also that where and nonzero return arrays, so you need to select the first element to get the index.
In [71]: np.argmax(a==2)
Out[71]: 2
In [72]: np.where(a==2)
Out[72]: (array([2], dtype=int64),)
In [73]: np.nonzero(a==2)
Out[73]: (array([2], dtype=int64),)
Time comparison
Just checking that for large arrays the solution using an iterator is faster when the searched item is at the beginning of the array (using %timeit in the IPython shell):
In [285]: a = np.arange(100000)
In [286]: %timeit next((idx for idx, val in np.ndenumerate(a) if val==0))
100000 loops, best of 3: 17.6 µs per loop
In [287]: %timeit np.argmax(a==0)
1000 loops, best of 3: 254 µs per loop
In [288]: %timeit np.where(a==0)[0][0]
1000 loops, best of 3: 314 µs per loop
This is an open NumPy GitHub issue.
See also: Numpy: find first index of value fast

If you're going to use this as an index into something else, you can use boolean indices if the arrays are broadcastable; you don't need explicit indices. The absolute simplest way to do this is to simply index based on a truth value.
other_array[first_array == item]
Any boolean operation works:
a = numpy.arange(100)
other_array[first_array > 50]
The nonzero method takes booleans, too:
index = numpy.nonzero(first_array == item)[0][0]
The two zeros are for the tuple of indices (assuming first_array is 1D) and then the first item in the array of indices.

For one-dimensional sorted arrays, it would be much more simpler and efficient O(log(n)) to use numpy.searchsorted which returns a NumPy integer (position). For example,
arr = np.array([1, 1, 1, 2, 3, 3, 4])
i = np.searchsorted(arr, 3)
Just make sure the array is already sorted
Also check if returned index i actually contains the searched element, since searchsorted's main objective is to find indices where elements should be inserted to maintain order.
if arr[i] == 3:
print("present")
else:
print("not present")

For 1D arrays, I'd recommend np.flatnonzero(array == value)[0], which is equivalent to both np.nonzero(array == value)[0][0] and np.where(array == value)[0][0] but avoids the ugliness of unboxing a 1-element tuple.

To index on any criteria, you can so something like the following:
In [1]: from numpy import *
In [2]: x = arange(125).reshape((5,5,5))
In [3]: y = indices(x.shape)
In [4]: locs = y[:,x >= 120] # put whatever you want in place of x >= 120
In [5]: pts = hsplit(locs, len(locs[0]))
In [6]: for pt in pts:
.....: print(', '.join(str(p[0]) for p in pt))
4, 4, 0
4, 4, 1
4, 4, 2
4, 4, 3
4, 4, 4
And here's a quick function to do what list.index() does, except doesn't raise an exception if it's not found. Beware -- this is probably very slow on large arrays. You can probably monkey patch this on to arrays if you'd rather use it as a method.
def ndindex(ndarray, item):
if len(ndarray.shape) == 1:
try:
return [ndarray.tolist().index(item)]
except:
pass
else:
for i, subarray in enumerate(ndarray):
try:
return [i] + ndindex(subarray, item)
except:
pass
In [1]: ndindex(x, 103)
Out[1]: [4, 0, 3]

An alternative to selecting the first element from np.where() is to use a generator expression together with enumerate, such as:
>>> import numpy as np
>>> x = np.arange(100) # x = array([0, 1, 2, 3, ... 99])
>>> next(i for i, x_i in enumerate(x) if x_i == 2)
2
For a two dimensional array one would do:
>>> x = np.arange(100).reshape(10,10) # x = array([[0, 1, 2,... 9], [10,..19],])
>>> next((i,j) for i, x_i in enumerate(x)
... for j, x_ij in enumerate(x_i) if x_ij == 2)
(0, 2)
The advantage of this approach is that it stops checking the elements of the array after the first match is found, whereas np.where checks all elements for a match. A generator expression would be faster if there's match early in the array.

There are lots of operations in NumPy that could perhaps be put together to accomplish this. This will return indices of elements equal to item:
numpy.nonzero(array - item)
You could then take the first elements of the lists to get a single element.

Comparison of 8 methods
TL;DR:
(Note: applicable to 1d arrays under 100M elements.)
For maximum performance use index_of__v5 (numba + numpy.enumerate + for loop; see the code below).
If numba is not available:
Use index_of__v7 (for loop + enumerate) if the target value is expected to be found within the first 100k elements.
Else use index_of__v2/v3/v4 (numpy.argmax or numpy.flatnonzero based).
Powered by perfplot
import numpy as np
from numba import njit
# Based on: numpy.argmax()
# Proposed by: John Haberstroh (https://stackoverflow.com/a/67497472/7204581)
def index_of__v1(arr: np.array, v):
is_v = (arr == v)
return is_v.argmax() if is_v.any() else -1
# Based on: numpy.argmax()
def index_of__v2(arr: np.array, v):
return (arr == v).argmax() if v in arr else -1
# Based on: numpy.flatnonzero()
# Proposed by: 1'' (https://stackoverflow.com/a/42049655/7204581)
def index_of__v3(arr: np.array, v):
idxs = np.flatnonzero(arr == v)
return idxs[0] if len(idxs) > 0 else -1
# Based on: numpy.argmax()
def index_of__v4(arr: np.array, v):
return np.r_[False, (arr == v)].argmax() - 1
# Based on: numba, for loop
# Proposed by: MSeifert (https://stackoverflow.com/a/41578614/7204581)
#njit
def index_of__v5(arr: np.array, v):
for idx, val in np.ndenumerate(arr):
if val == v:
return idx[0]
return -1
# Based on: numpy.ndenumerate(), for loop
def index_of__v6(arr: np.array, v):
return next((idx[0] for idx, val in np.ndenumerate(arr) if val == v), -1)
# Based on: enumerate(), for loop
# Proposed by: Noyer282 (https://stackoverflow.com/a/40426159/7204581)
def index_of__v7(arr: np.array, v):
return next((idx for idx, val in enumerate(arr) if val == v), -1)
# Based on: list.index()
# Proposed by: Hima (https://stackoverflow.com/a/23994923/7204581)
def index_of__v8(arr: np.array, v):
l = list(arr)
try:
return l.index(v)
except ValueError:
return -1
Go to Colab

The numpy_indexed package (disclaimer, I am its author) contains a vectorized equivalent of list.index for numpy.ndarray; that is:
sequence_of_arrays = [[0, 1], [1, 2], [-5, 0]]
arrays_to_query = [[-5, 0], [1, 0]]
import numpy_indexed as npi
idx = npi.indices(sequence_of_arrays, arrays_to_query, missing=-1)
print(idx) # [2, -1]
This solution has vectorized performance, generalizes to ndarrays, and has various ways of dealing with missing values.

There is a fairly idiomatic and vectorized way to do this built into numpy. It uses a quirk of the np.argmax() function to accomplish this -- if many values match, it returns the index of the first match. The trick is that for booleans, there will only ever be two values: True (1) and False (0). Therefore, the returned index will be that of the first True.
For the simple example provided, you can see it work with the following
>>> np.argmax(np.array([1,2,3]) == 2)
1
A great example is computing buckets, e.g. for categorizing. Let's say you have an array of cut points, and you want the "bucket" that corresponds to each element of your array. The algorithm is to compute the first index of cuts where x < cuts (after padding cuts with np.Infitnity). I could use broadcasting to broadcast the comparisons, then apply argmax along the cuts-broadcasted axis.
>>> cuts = np.array([10, 50, 100])
>>> cuts_pad = np.array([*cuts, np.Infinity])
>>> x = np.array([7, 11, 80, 443])
>>> bins = np.argmax( x[:, np.newaxis] < cuts_pad[np.newaxis, :], axis = 1)
>>> print(bins)
[0, 1, 2, 3]
As expected, each value from x falls into one of the sequential bins, with well-defined and easy to specify edge case behavior.

Another option not previously mentioned is the bisect module, which also works on lists, but requires a pre-sorted list/array:
import bisect
import numpy as np
z = np.array([104,113,120,122,126,138])
bisect.bisect_left(z, 122)
yields
3
bisect also returns a result when the number you're looking for doesn't exist in the array, so that the number can be inserted in the correct place.

Note: this is for python 2.7 version
You can use a lambda function to deal with the problem, and it works both on NumPy array and list.
your_list = [11, 22, 23, 44, 55]
result = filter(lambda x:your_list[x]>30, range(len(your_list)))
#result: [3, 4]
import numpy as np
your_numpy_array = np.array([11, 22, 23, 44, 55])
result = filter(lambda x:your_numpy_array [x]>30, range(len(your_list)))
#result: [3, 4]
And you can use
result[0]
to get the first index of the filtered elements.
For python 3.6, use
list(result)
instead of
result

Use ndindex
Sample array
arr = np.array([[1,4],
[2,3]])
print(arr)
...[[1,4],
[2,3]]
create an empty list to store the index and the element tuples
index_elements = []
for i in np.ndindex(arr.shape):
index_elements.append((arr[i],i))
convert the list of tuples into dictionary
index_elements = dict(index_elements)
The keys are the elements and the values are their
indices - use keys to access the index
index_elements[4]
output
... (0,1)

For my use case, I could not sort the array ahead of time because the order of the elements is important. This is my all-NumPy implementation:
import numpy as np
# The array in question
arr = np.array([1,2,1,2,1,5,5,3,5,9])
# Find all of the present values
vals=np.unique(arr)
# Make all indices up-to and including the desired index positive
cum_sum=np.cumsum(arr==vals.reshape(-1,1),axis=1)
# Add zeros to account for the n-1 shape of diff and the all-positive array of the first index
bl_mask=np.concatenate([np.zeros((cum_sum.shape[0],1)),cum_sum],axis=1)>=1
# The desired indices
idx=np.where(np.diff(bl_mask))[1]
# Show results
print(list(zip(vals,idx)))
>>> [(1, 0), (2, 1), (3, 7), (5, 5), (9, 9)]
I believe it accounts for unsorted arrays with duplicate values.

Found another solution with loops:
new_array_of_indicies = []
for i in range(len(some_array)):
if some_array[i] == some_value:
new_array_of_indicies.append(i)

index_lst_form_numpy = pd.DataFrame(df).reset_index()["index"].tolist()