numutils.py
305 lines
| 10.0 KiB
| text/x-python
|
PythonLexer
/ IPython / numutils.py
fperez
|
r0 | # -*- coding: utf-8 -*- | ||
""" | ||||
A set of convenient utilities for numerical work. | ||||
Most of this module requires Numerical Python or is meant to be used with it. | ||||
See http://www.pfdubois.com/numpy for details. | ||||
$Id: numutils.py 486 2005-01-27 19:34:21Z fperez $""" | ||||
#***************************************************************************** | ||||
# Copyright (C) 2001-2005 Fernando Perez <fperez@colorado.edu> | ||||
# | ||||
# Distributed under the terms of the BSD License. The full license is in | ||||
# the file COPYING, distributed as part of this software. | ||||
#***************************************************************************** | ||||
from IPython import Release | ||||
__author__ = '%s <%s>' % Release.authors['Fernando'] | ||||
__license__ = Release.license | ||||
__all__ = ['sum_flat','mean_flat','rms_flat','base_repr','binary_repr', | ||||
'amin','amax','amap','zeros_like','empty_like', | ||||
'frange','diagonal_matrix','identity', | ||||
'fromfunction_kw','log2','ispower2', | ||||
'norm','l1norm','l2norm','exp_safe', | ||||
'inf','infty','Infinity', | ||||
'Numeric'] | ||||
#**************************************************************************** | ||||
# required modules | ||||
import __main__ | ||||
import sys,operator | ||||
import math | ||||
import Numeric | ||||
from Numeric import * | ||||
#***************************************************************************** | ||||
# Globals | ||||
# useful for testing infinities in results of array divisions (which don't | ||||
# raise an exception) | ||||
# Python, LaTeX and Mathematica names. | ||||
inf = infty = Infinity = (array([1])/0.0)[0] | ||||
#**************************************************************************** | ||||
# function definitions | ||||
exp_safe_MIN = math.log(2.2250738585072014e-308) | ||||
exp_safe_MAX = 1.7976931348623157e+308 | ||||
def exp_safe(x): | ||||
"""Compute exponentials which safely underflow to zero. | ||||
Slow but convenient to use. Note that NumArray will introduce proper | ||||
floating point exception handling with access to the underlying | ||||
hardware.""" | ||||
if type(x) is ArrayType: | ||||
return exp(clip(x,exp_safe_MIN,exp_safe_MAX)) | ||||
else: | ||||
return math.exp(x) | ||||
def amap(fn,*args): | ||||
"""amap(function, sequence[, sequence, ...]) -> array. | ||||
Works like map(), but it returns an array. This is just a convenient | ||||
shorthand for Numeric.array(map(...))""" | ||||
return array(map(fn,*args)) | ||||
def amin(m,axis=0): | ||||
"""amin(m,axis=0) returns the minimum of m along dimension axis. | ||||
""" | ||||
return minimum.reduce(asarray(m),axis) | ||||
def amax(m,axis=0): | ||||
"""amax(m,axis=0) returns the maximum of m along dimension axis. | ||||
""" | ||||
return maximum.reduce(asarray(m),axis) | ||||
def zeros_like(a): | ||||
"""Return an array of zeros of the shape and typecode of a. | ||||
If you don't explicitly need the array to be zeroed, you should instead | ||||
use empty_like(), which is faster as it only allocates memory.""" | ||||
return zeros(a.shape,a.typecode()) | ||||
def empty_like(a): | ||||
"""Return an empty (uninitialized) array of the shape and typecode of a. | ||||
Note that this does NOT initialize the returned array. If you require | ||||
your array to be initialized, you should use zeros_like(). | ||||
This requires Numeric.empty(), which appeared in Numeric 23.7.""" | ||||
return empty(a.shape,a.typecode()) | ||||
def sum_flat(a): | ||||
"""Return the sum of all the elements of a, flattened out. | ||||
It uses a.flat, and if a is not contiguous, a call to ravel(a) is made.""" | ||||
if a.iscontiguous(): | ||||
return Numeric.sum(a.flat) | ||||
else: | ||||
return Numeric.sum(ravel(a)) | ||||
def mean_flat(a): | ||||
"""Return the mean of all the elements of a, flattened out.""" | ||||
return sum_flat(a)/float(size(a)) | ||||
def rms_flat(a): | ||||
"""Return the root mean square of all the elements of a, flattened out.""" | ||||
return math.sqrt(sum_flat(absolute(a)**2)/float(size(a))) | ||||
def l1norm(a): | ||||
"""Return the l1 norm of a, flattened out. | ||||
Implemented as a separate function (not a call to norm() for speed). | ||||
Ref: http://mathworld.wolfram.com/L1-Norm.html""" | ||||
return sum_flat(absolute(a)) | ||||
def l2norm(a): | ||||
"""Return the l2 norm of a, flattened out. | ||||
Implemented as a separate function (not a call to norm() for speed). | ||||
Ref: http://mathworld.wolfram.com/L2-Norm.html""" | ||||
return math.sqrt(sum_flat(absolute(a)**2)) | ||||
def norm(a,p=2): | ||||
"""norm(a,p=2) -> l-p norm of a.flat | ||||
Return the l-p norm of a, considered as a flat array. This is NOT a true | ||||
matrix norm, since arrays of arbitrary rank are always flattened. | ||||
p can be a number or one of the strings ('inf','Infinity') to get the | ||||
L-infinity norm. | ||||
Ref: http://mathworld.wolfram.com/VectorNorm.html | ||||
http://mathworld.wolfram.com/L-Infinity-Norm.html""" | ||||
if p in ('inf','Infinity'): | ||||
return max(absolute(a).flat) | ||||
else: | ||||
return (sum_flat(absolute(a)**p))**(1.0/p) | ||||
def frange(xini,xfin=None,delta=None,**kw): | ||||
"""frange([start,] stop[, step, keywords]) -> array of floats | ||||
Return a Numeric array() containing a progression of floats. Similar to | ||||
arange(), but defaults to a closed interval. | ||||
frange(x0, x1) returns [x0, x0+1, x0+2, ..., x1]; start defaults to 0, and | ||||
the endpoint *is included*. This behavior is different from that of | ||||
range() and arange(). This is deliberate, since frange will probably be | ||||
more useful for generating lists of points for function evaluation, and | ||||
endpoints are often desired in this use. The usual behavior of range() can | ||||
be obtained by setting the keyword 'closed=0', in this case frange() | ||||
basically becomes arange(). | ||||
When step is given, it specifies the increment (or decrement). All | ||||
arguments can be floating point numbers. | ||||
frange(x0,x1,d) returns [x0,x0+d,x0+2d,...,xfin] where xfin<=x1. | ||||
frange can also be called with the keyword 'npts'. This sets the number of | ||||
points the list should contain (and overrides the value 'step' might have | ||||
been given). arange() doesn't offer this option. | ||||
Examples: | ||||
>>> frange(3) | ||||
array([ 0., 1., 2., 3.]) | ||||
>>> frange(3,closed=0) | ||||
array([ 0., 1., 2.]) | ||||
>>> frange(1,6,2) | ||||
array([1, 3, 5]) | ||||
>>> frange(1,6.5,npts=5) | ||||
array([ 1. , 2.375, 3.75 , 5.125, 6.5 ]) | ||||
""" | ||||
#defaults | ||||
kw.setdefault('closed',1) | ||||
endpoint = kw['closed'] != 0 | ||||
# funny logic to allow the *first* argument to be optional (like range()) | ||||
# This was modified with a simpler version from a similar frange() found | ||||
# at http://aspn.activestate.com/ASPN/Cookbook/Python/Recipe/66472 | ||||
if xfin == None: | ||||
xfin = xini + 0.0 | ||||
xini = 0.0 | ||||
if delta == None: | ||||
delta = 1.0 | ||||
# compute # of points, spacing and return final list | ||||
try: | ||||
npts=kw['npts'] | ||||
delta=(xfin-xini)/float(npts-endpoint) | ||||
except KeyError: | ||||
# round() gets npts right even with the vagaries of floating point. | ||||
npts=int(round((xfin-xini)/delta+endpoint)) | ||||
return arange(npts)*delta+xini | ||||
def diagonal_matrix(diag): | ||||
"""Return square diagonal matrix whose non-zero elements are given by the | ||||
input array.""" | ||||
return diag*identity(len(diag)) | ||||
def identity(n,rank=2,typecode='l'): | ||||
"""identity(n,r) returns the identity matrix of shape (n,n,...,n) (rank r). | ||||
For ranks higher than 2, this object is simply a multi-index Kronecker | ||||
delta: | ||||
/ 1 if i0=i1=...=iR, | ||||
id[i0,i1,...,iR] = -| | ||||
\ 0 otherwise. | ||||
Optionally a typecode may be given (it defaults to 'l'). | ||||
Since rank defaults to 2, this function behaves in the default case (when | ||||
only n is given) like the Numeric identity function.""" | ||||
iden = zeros((n,)*rank,typecode=typecode) | ||||
for i in range(n): | ||||
idx = (i,)*rank | ||||
iden[idx] = 1 | ||||
return iden | ||||
def base_repr (number, base = 2, padding = 0): | ||||
"""Return the representation of a number in any given base.""" | ||||
chars = '0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ' | ||||
if number < base: \ | ||||
return (padding - 1) * chars [0] + chars [int (number)] | ||||
max_exponent = int (math.log (number)/math.log (base)) | ||||
max_power = long (base) ** max_exponent | ||||
lead_digit = int (number/max_power) | ||||
return chars [lead_digit] + \ | ||||
base_repr (number - max_power * lead_digit, base, \ | ||||
max (padding - 1, max_exponent)) | ||||
def binary_repr(number, max_length = 1025): | ||||
"""Return the binary representation of the input number as a string. | ||||
This is more efficient than using base_repr with base 2. | ||||
Increase the value of max_length for very large numbers. Note that on | ||||
32-bit machines, 2**1023 is the largest integer power of 2 which can be | ||||
converted to a Python float.""" | ||||
assert number < 2L << max_length | ||||
shifts = map (operator.rshift, max_length * [number], \ | ||||
range (max_length - 1, -1, -1)) | ||||
digits = map (operator.mod, shifts, max_length * [2]) | ||||
if not digits.count (1): return 0 | ||||
digits = digits [digits.index (1):] | ||||
return ''.join (map (repr, digits)).replace('L','') | ||||
def log2(x,ln2 = math.log(2.0)): | ||||
"""Return the log(x) in base 2. | ||||
This is a _slow_ function but which is guaranteed to return the correct | ||||
integer value if the input is an ineger exact power of 2.""" | ||||
try: | ||||
bin_n = binary_repr(x)[1:] | ||||
except (AssertionError,TypeError): | ||||
return math.log(x)/ln2 | ||||
else: | ||||
if '1' in bin_n: | ||||
return math.log(x)/ln2 | ||||
else: | ||||
return len(bin_n) | ||||
def ispower2(n): | ||||
"""Returns the log base 2 of n if n is a power of 2, zero otherwise. | ||||
Note the potential ambiguity if n==1: 2**0==1, interpret accordingly.""" | ||||
bin_n = binary_repr(n)[1:] | ||||
if '1' in bin_n: | ||||
return 0 | ||||
else: | ||||
return len(bin_n) | ||||
def fromfunction_kw(function, dimensions, **kwargs): | ||||
"""Drop-in replacement for fromfunction() from Numerical Python. | ||||
Allows passing keyword arguments to the desired function. | ||||
Call it as (keywords are optional): | ||||
fromfunction_kw(MyFunction, dimensions, keywords) | ||||
The function MyFunction() is responsible for handling the dictionary of | ||||
keywords it will recieve.""" | ||||
return function(tuple(indices(dimensions)),**kwargs) | ||||
#**************************** end file <numutils.py> ************************ | ||||