In addition to np.sctypeDict, there are these variables:
In [141]: np.typecodes
Out[141]:
{'All': '?bhilqpBHILQPefdgFDGSUVOMm',
'AllFloat': 'efdgFDG',
'AllInteger': 'bBhHiIlLqQpP',
'Character': 'c',
'Complex': 'FDG',
'Datetime': 'Mm',
'Float': 'efdg',
'Integer': 'bhilqp',
'UnsignedInteger': 'BHILQP'}
In [143]: np.sctypes
Out[143]:
{'complex': [numpy.complex64, numpy.complex128, numpy.complex192],
'float': [numpy.float16, numpy.float32, numpy.float64, numpy.float96],
'int': [numpy.int8, numpy.int16, numpy.int32, numpy.int32, numpy.int64],
'others': [bool, object, str, unicode, numpy.void],
'uint': [numpy.uint8, numpy.uint16, numpy.uint32, numpy.uint32, numpy.uint64]}
Videos
In addition to np.sctypeDict, there are these variables:
In [141]: np.typecodes
Out[141]:
{'All': '?bhilqpBHILQPefdgFDGSUVOMm',
'AllFloat': 'efdgFDG',
'AllInteger': 'bBhHiIlLqQpP',
'Character': 'c',
'Complex': 'FDG',
'Datetime': 'Mm',
'Float': 'efdg',
'Integer': 'bhilqp',
'UnsignedInteger': 'BHILQP'}
In [143]: np.sctypes
Out[143]:
{'complex': [numpy.complex64, numpy.complex128, numpy.complex192],
'float': [numpy.float16, numpy.float32, numpy.float64, numpy.float96],
'int': [numpy.int8, numpy.int16, numpy.int32, numpy.int32, numpy.int64],
'others': [bool, object, str, unicode, numpy.void],
'uint': [numpy.uint8, numpy.uint16, numpy.uint32, numpy.uint32, numpy.uint64]}
Generic info about dtypes: http://docs.scipy.org/doc/numpy/reference/arrays.dtypes.html
From http://docs.scipy.org/doc/numpy/reference/arrays.scalars.html#arrays-scalars-built-in
In NumPy, there are 24 new fundamental Python types to describe different types of scalars. These type descriptors are mostly based on the types available in the C language that CPython is written in, with several additional types compatible with Python’s types.
And what I didn't realise, is:
The C-like names are associated with character codes, which are shown in the table. Use of the character codes, however, is discouraged.
I doubt the numpy code/doc base is going anyway anytime soon, so that says it all I guess!
NumPy arrays are stored as contiguous blocks of memory. They usually have a single datatype (e.g. integers, floats or fixed-length strings) and then the bits in memory are interpreted as values with that datatype.
Creating an array with dtype=object is different. The memory taken by the array now is filled with pointers to Python objects which are being stored elsewhere in memory (much like a Python list is really just a list of pointers to objects, not the objects themselves).
Arithmetic operators such as * don't work with arrays such as ar1 which have a string_ datatype (there are special functions instead - see below). NumPy is just treating the bits in memory as characters and the * operator doesn't make sense here. However, the line
np.array(['avinash','jay'], dtype=object) * 2
works because now the array is an array of (pointers to) Python strings. The * operator is well defined for these Python string objects. New Python strings are created in memory and a new object array with references to the new strings is returned.
If you have an array with string_ or unicode_ dtype and want to repeat each string, you can use np.char.multiply:
In [52]: np.char.multiply(ar1, 2)
Out[52]: array(['avinashavinash', 'jayjay'],
dtype='<U14')
NumPy has many other vectorised string methods too.
There are 3 main dtypes to store strings in numpy:
object: Stores pointers to Python objectsstr: Stores fixed-width stringsnumpy.types.StringDType(): New in numpy 2.0 and stores variable-width strings
str consumes more memory than object; StringDType is better
Depending on the length of the fixed-length string and the size of the array, the ratio differs but as long as the longest string in the array is longer than 2 characters, str consumes more memory (they are equal when the longest string in the array is 2 characters long). For example, in the following example, str consumes almost 8 times more memory.
On the other hand, the new (in numpy>=2.0) numpy.dtypes.StringDType stores variable width strings, so consumes much less memory.
from pympler.asizeof import asizeof
ar1 = np.array(['this is a string', 'string']*1000, dtype=object)
ar2 = np.array(['this is a string', 'string']*1000, dtype=str)
ar3 = np.array(['this is a string', 'string']*1000, dtype=np.dtypes.StringDType())
asizeof(ar2) / asizeof(ar1) # 7.944444444444445
asizeof(ar3) / asizeof(ar1) # 1.992063492063492
For numpy 1.x, str is slower than object
For numpy>=2.0.0, str is faster than object
Numpy 2.0 has introduced a new numpy.strings API that has much more performant ufuncs for string operations. A simple test (on numpy 2.2.0) below shows that vectorized string operations on an array of str or StringDType dtype is much faster than the same operations on an object dtype array.
import timeit
t1 = min(timeit.repeat(lambda: ar1*2, number=1000))
t2a = min(timeit.repeat(lambda: np.strings.multiply(ar2, 2), number=1000))
t2b = min(timeit.repeat(lambda: np.strings.multiply(ar3, 2), number=1000))
print(t2a / t1) # 0.8786601958427778
print(t2b / t1) # 0.7311586933668037
t3 = min(timeit.repeat(lambda: np.array([s.count('i') for s in ar1]), number=1000))
t4a = min(timeit.repeat(lambda: np.strings.count(ar2, 'i'), number=1000))
t4b = min(timeit.repeat(lambda: np.strings.count(ar3, 'i'), number=1000))
print(t4a / t3) # 0.13328748153237377
print(t4b / t3) # 0.3365874412749679
For numpy<2.0.0 (tested on numpy 1.26.0)
Numpy 1.x's vectorized string methods are not optimized, so operating on the object array is often faster. For example, in the example in the OP where each character is repeated, a simple * (aka multiply()) is not only more concise but also over 10 times faster than char.multiply().
import timeit
setup = "import numpy as np; from __main__ import ar1, ar2"
t1 = min(timeit.repeat("ar1*2", setup, number=1000))
t2 = min(timeit.repeat("np.char.multiply(ar2, 2)", setup, number=1000))
t2 / t1 # 10.650433758517027
Even for functions that cannot be readily be applied on the array, instead of the vectorized char method of str arrays, it is faster to loop over the object array and work on the Python strings.
For example, iterating over the object array and calling str.count() on each Python string is over 3 times faster than the vectorized char.count() on the str array.
f1 = lambda: np.array([s.count('i') for s in ar1])
f2 = lambda: np.char.count(ar2, 'i')
setup = "import numpy as np; from __main__ import ar1, ar2, f1, f2, f3"
t3 = min(timeit.repeat("f1()", setup, number=1000))
t4 = min(timeit.repeat("f2()", setup, number=1000))
t4 / t3 # 3.251369161574832
On a side note, if it comes to explicit loop, iterating over a list is faster than iterating over a numpy array. So in the previous example, a further performance gain can be made by iterating over the list
f3 = lambda: np.array([s.count('i') for s in ar1.tolist()])
# ^^^^^^^^^ <--- convert to list here
t5 = min(timeit.repeat("f3()", setup, number=1000))
t3 / t5 # 1.2623498005294627