Programming¶
Loading and Attaching Sage files¶
Next we illustrate how to load programs written in a separate file
into Sage. Create a file called example.sage
with the following
content:
print("Hello World")
print(2^3)
You can read in and execute example.sage
file using the load
command.
sage: load("example.sage")
Hello World
8
>>> from sage.all import *
>>> load("example.sage")
Hello World
8
load("example.sage")
You can also attach a Sage file to a running session using the
attach
command:
sage: attach("example.sage")
Hello World
8
>>> from sage.all import *
>>> attach("example.sage")
Hello World
8
attach("example.sage")
Now if you change example.sage
and enter one blank line into Sage
(i.e., hit return
), then the contents of example.sage
will be
automatically reloaded into Sage.
In particular, attach
automatically reloads a file whenever it
changes, which is handy when debugging code, whereas load
only
loads a file once.
When Sage loads example.sage
it converts it to Python, which is
then executed by the Python interpreter. This conversion is
minimal; it mainly involves wrapping integer literals in Integer()
floating point literals in RealNumber()
, replacing ^
’s by **
’s,
and replacing e.g., R.2
by R.gen(2)
. The converted version of
example.sage
is contained in the same directory as example.sage
and is called example.sage.py
. This file contains the following
code:
print("Hello World")
print(Integer(2)**Integer(3))
Integer literals are wrapped and the ^
is replaced by a **
.
(In Python ^
means “exclusive or” and **
means
“exponentiation”.)
(This preparsing is implemented in sage/misc/interpreter.py
.)
You can paste multi-line indented code into Sage as long as there
are newlines to make new blocks (this is not necessary in files).
However, the best way to enter such code into Sage is to save it to
a file and use attach
, as described above.
Creating Compiled Code¶
Speed is crucial in mathematical computations. Though Python is a
convenient very high-level language, certain calculations can be
several orders of magnitude faster than in Python if they are
implemented using static types in a compiled language. Some aspects
of Sage would have been too slow if it had been written entirely in
Python. To deal with this, Sage supports a compiled “version” of Python
called Cython ([Cyt] and [Pyr]). Cython is simultaneously
similar to both Python and C. Most Python constructions, including
list comprehensions, conditional expressions, code like +=
are
allowed; you can also import code that you have written in other
Python modules. Moreover, you can declare arbitrary C variables,
and arbitrary C library calls can be made directly. The resulting
code is converted to C and compiled using a C compiler.
In order to make your own compiled Sage code, give the file an
.spyx
extension (instead of .sage
). If you are working with the
command-line interface, you can attach and load compiled code
exactly like with interpreted code (at the moment, attaching and
loading Cython code is not supported with the notebook interface).
The actual compilation is done “behind the scenes” without your
having to do anything explicit. The compiled shared object library is stored under
$HOME/.sage/temp/hostname/pid/spyx
. These files are deleted
when you exit Sage.
NO Sage preparsing is applied to spyx files, e.g., 1/3
will result in
0 in a spyx file instead of the rational number \(1/3\). If
foo
is a function in the Sage library, to use it from a spyx file
import sage.all
and use sage.all.foo
.
import sage.all
def foo(n):
return sage.all.factorial(n)
Accessing C Functions in Separate Files¶
It is also easy to access C functions defined in separate *.c
files. Here’s an example. Create files test.c
and test.spyx
in the same directory with contents:
The pure C code: test.c
int add_one(int n) {
return n + 1;
}
The Cython code: test.spyx
:
cdef extern from "test.c":
int add_one(int n)
def test(n):
return add_one(n)
Then the following works:
sage: attach("test.spyx")
Compiling (...)/test.spyx...
sage: test(10)
11
>>> from sage.all import *
>>> attach("test.spyx")
Compiling (...)/test.spyx...
>>> test(Integer(10))
11
attach("test.spyx") test(10)
If an additional library foo
is needed to compile the C code
generated from a Cython file, add the line clib foo
to the
Cython source. Similarly, an additional C file bar
can be
included in the compilation with the declaration cfile bar
.
Standalone Python/Sage Scripts¶
The following standalone Sage script factors integers, polynomials, etc:
#!/usr/bin/env sage
import sys
if len(sys.argv) != 2:
print("Usage: %s <n>" % sys.argv[0])
print("Outputs the prime factorization of n.")
sys.exit(1)
print(factor(sage_eval(sys.argv[1])))
In order to use this script, your SAGE_ROOT
must be in your PATH.
If the above script is called factor
, here is an example usage:
$ ./factor 2006
2 * 17 * 59
Data Types¶
Every object in Sage has a well-defined type. Python has a wide range of basic built-in types, and the Sage library adds many more. Some built-in Python types include strings, lists, tuples, ints and floats, as illustrated:
sage: s = "sage"; type(s)
<... 'str'>
sage: s = 'sage'; type(s) # you can use either single or double quotes
<... 'str'>
sage: s = [1,2,3,4]; type(s)
<... 'list'>
sage: s = (1,2,3,4); type(s)
<... 'tuple'>
sage: s = int(2006); type(s)
<... 'int'>
sage: s = float(2006); type(s)
<... 'float'>
>>> from sage.all import *
>>> s = "sage"; type(s)
<... 'str'>
>>> s = 'sage'; type(s) # you can use either single or double quotes
<... 'str'>
>>> s = [Integer(1),Integer(2),Integer(3),Integer(4)]; type(s)
<... 'list'>
>>> s = (Integer(1),Integer(2),Integer(3),Integer(4)); type(s)
<... 'tuple'>
>>> s = int(Integer(2006)); type(s)
<... 'int'>
>>> s = float(Integer(2006)); type(s)
<... 'float'>
s = "sage"; type(s) s = 'sage'; type(s) # you can use either single or double quotes s = [1,2,3,4]; type(s) s = (1,2,3,4); type(s) s = int(2006); type(s) s = float(2006); type(s)
To this, Sage adds many other types. E.g., vector spaces:
sage: V = VectorSpace(QQ, 1000000); V
Vector space of dimension 1000000 over Rational Field
sage: type(V)
<class 'sage.modules.free_module.FreeModule_ambient_field_with_category'>
>>> from sage.all import *
>>> V = VectorSpace(QQ, Integer(1000000)); V
Vector space of dimension 1000000 over Rational Field
>>> type(V)
<class 'sage.modules.free_module.FreeModule_ambient_field_with_category'>
V = VectorSpace(QQ, 1000000); V type(V)
Only certain
functions can be called on V
. In other math software
systems, these would be called using the “functional” notation
foo(V,...)
. In Sage, certain functions are attached to the type (or
class) of V
, and are called using an object-oriented
syntax like in Java or C++, e.g., V.foo(...)
. This helps keep the
global namespace from being polluted with tens of thousands of
functions, and means that many different functions with different
behavior can be named foo, without having to use type-checking of
arguments (or case statements) to decide which to call. Also, if
you reuse the name of a function, that function is still available
(e.g., if you call something zeta
, then want to compute the value
of the Riemann-Zeta function at 0.5, you can still type
s=.5; s.zeta()
).
sage: zeta = -1
sage: s=.5; s.zeta()
-1.46035450880959
>>> from sage.all import *
>>> zeta = -Integer(1)
>>> s=RealNumber('.5'); s.zeta()
-1.46035450880959
zeta = -1 s=.5; s.zeta()
In some very common cases, the usual functional notation is also supported for convenience and because mathematical expressions might look confusing using object-oriented notation. Here are some examples.
sage: n = 2; n.sqrt()
sqrt(2)
sage: sqrt(2)
sqrt(2)
sage: V = VectorSpace(QQ,2)
sage: V.basis()
[
(1, 0),
(0, 1)
]
sage: basis(V)
[
(1, 0),
(0, 1)
]
sage: M = MatrixSpace(GF(7), 2); M
Full MatrixSpace of 2 by 2 dense matrices over Finite Field of size 7
sage: A = M([1,2,3,4]); A
[1 2]
[3 4]
sage: A.charpoly('x')
x^2 + 2*x + 5
sage: charpoly(A, 'x')
x^2 + 2*x + 5
>>> from sage.all import *
>>> n = Integer(2); n.sqrt()
sqrt(2)
>>> sqrt(Integer(2))
sqrt(2)
>>> V = VectorSpace(QQ,Integer(2))
>>> V.basis()
[
(1, 0),
(0, 1)
]
>>> basis(V)
[
(1, 0),
(0, 1)
]
>>> M = MatrixSpace(GF(Integer(7)), Integer(2)); M
Full MatrixSpace of 2 by 2 dense matrices over Finite Field of size 7
>>> A = M([Integer(1),Integer(2),Integer(3),Integer(4)]); A
[1 2]
[3 4]
>>> A.charpoly('x')
x^2 + 2*x + 5
>>> charpoly(A, 'x')
x^2 + 2*x + 5
n = 2; n.sqrt() sqrt(2) V = VectorSpace(QQ,2) V.basis() basis(V) M = MatrixSpace(GF(7), 2); M A = M([1,2,3,4]); A A.charpoly('x') charpoly(A, 'x')
To list all member functions for \(A\), use tab completion.
Just type A.
, then type the [tab]
key on your keyboard, as
explained in Reverse Search and Tab Completion.
Lists, Tuples, and Sequences¶
The list data type stores elements of arbitrary type. Like in C, C++, etc. (but unlike most standard computer algebra systems), the elements of the list are indexed starting from \(0\):
sage: v = [2, 3, 5, 'x', SymmetricGroup(3)]; v
[2, 3, 5, 'x', Symmetric group of order 3! as a permutation group]
sage: type(v)
<... 'list'>
sage: v[0]
2
sage: v[2]
5
>>> from sage.all import *
>>> v = [Integer(2), Integer(3), Integer(5), 'x', SymmetricGroup(Integer(3))]; v
[2, 3, 5, 'x', Symmetric group of order 3! as a permutation group]
>>> type(v)
<... 'list'>
>>> v[Integer(0)]
2
>>> v[Integer(2)]
5
v = [2, 3, 5, 'x', SymmetricGroup(3)]; v type(v) v[0] v[2]
(When indexing into a list, it is OK if the index is
not a Python int!)
A Sage Integer (or Rational, or anything with an __index__
method)
will work just fine.
sage: v = [1,2,3]
sage: v[2]
3
sage: n = 2 # Sage Integer
sage: v[n] # Perfectly OK!
3
sage: v[int(n)] # Also OK.
3
>>> from sage.all import *
>>> v = [Integer(1),Integer(2),Integer(3)]
>>> v[Integer(2)]
3
>>> n = Integer(2) # Sage Integer
>>> v[n] # Perfectly OK!
3
>>> v[int(n)] # Also OK.
3
v = [1,2,3] v[2] n = 2 # Sage Integer v[n] # Perfectly OK! v[int(n)] # Also OK.
The range
function creates a list of Python int’s (not Sage
Integers):
sage: list(range(1, 15))
[1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14]
>>> from sage.all import *
>>> list(range(Integer(1), Integer(15)))
[1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14]
list(range(1, 15))
This is useful when using list comprehensions to construct lists:
sage: L = [factor(n) for n in range(1, 15)]
sage: L
[1, 2, 3, 2^2, 5, 2 * 3, 7, 2^3, 3^2, 2 * 5, 11, 2^2 * 3, 13, 2 * 7]
sage: L[12]
13
sage: type(L[12])
<class 'sage.structure.factorization_integer.IntegerFactorization'>
sage: [factor(n) for n in range(1, 15) if is_odd(n)]
[1, 3, 5, 7, 3^2, 11, 13]
>>> from sage.all import *
>>> L = [factor(n) for n in range(Integer(1), Integer(15))]
>>> L
[1, 2, 3, 2^2, 5, 2 * 3, 7, 2^3, 3^2, 2 * 5, 11, 2^2 * 3, 13, 2 * 7]
>>> L[Integer(12)]
13
>>> type(L[Integer(12)])
<class 'sage.structure.factorization_integer.IntegerFactorization'>
>>> [factor(n) for n in range(Integer(1), Integer(15)) if is_odd(n)]
[1, 3, 5, 7, 3^2, 11, 13]
L = [factor(n) for n in range(1, 15)] L L[12] type(L[12]) [factor(n) for n in range(1, 15) if is_odd(n)]
For more about how to create lists using list comprehensions, see [PyT].
List slicing is a wonderful feature. If L
is a list, then L[m:n]
returns the sublist of L
obtained by
starting at the \(m^{th}\) element and stopping at the
\((n-1)^{st}\) element, as illustrated below.
sage: L = [factor(n) for n in range(1, 20)]
sage: L[4:9]
[5, 2 * 3, 7, 2^3, 3^2]
sage: L[:4]
[1, 2, 3, 2^2]
sage: L[14:4]
[]
sage: L[14:]
[3 * 5, 2^4, 17, 2 * 3^2, 19]
>>> from sage.all import *
>>> L = [factor(n) for n in range(Integer(1), Integer(20))]
>>> L[Integer(4):Integer(9)]
[5, 2 * 3, 7, 2^3, 3^2]
>>> L[:Integer(4)]
[1, 2, 3, 2^2]
>>> L[Integer(14):Integer(4)]
[]
>>> L[Integer(14):]
[3 * 5, 2^4, 17, 2 * 3^2, 19]
L = [factor(n) for n in range(1, 20)] L[4:9] L[:4] L[14:4] L[14:]
Tuples are similar to lists, except they are immutable, meaning once they are created they can’t be changed.
sage: v = (1,2,3,4); v
(1, 2, 3, 4)
sage: type(v)
<... 'tuple'>
sage: v[1] = 5
Traceback (most recent call last):
...
TypeError: 'tuple' object does not support item assignment
>>> from sage.all import *
>>> v = (Integer(1),Integer(2),Integer(3),Integer(4)); v
(1, 2, 3, 4)
>>> type(v)
<... 'tuple'>
>>> v[Integer(1)] = Integer(5)
Traceback (most recent call last):
...
TypeError: 'tuple' object does not support item assignment
v = (1,2,3,4); v type(v) v[1] = 5
Sequences are a third list-oriented Sage
type. Unlike lists and tuples, Sequence is not a built-in Python
type. By default, a sequence is mutable, but using the Sequence
class method set_immutable
, it can be set to be immutable, as
the following example illustrates. All elements of a sequence have
a common parent, called the sequences universe.
sage: v = Sequence([1,2,3,4/5])
sage: v
[1, 2, 3, 4/5]
sage: type(v)
<class 'sage.structure.sequence.Sequence_generic'>
sage: type(v[1])
<class 'sage.rings.rational.Rational'>
sage: v.universe()
Rational Field
sage: v.is_immutable()
False
sage: v.set_immutable()
sage: v[0] = 3
Traceback (most recent call last):
...
ValueError: object is immutable; please change a copy instead.
>>> from sage.all import *
>>> v = Sequence([Integer(1),Integer(2),Integer(3),Integer(4)/Integer(5)])
>>> v
[1, 2, 3, 4/5]
>>> type(v)
<class 'sage.structure.sequence.Sequence_generic'>
>>> type(v[Integer(1)])
<class 'sage.rings.rational.Rational'>
>>> v.universe()
Rational Field
>>> v.is_immutable()
False
>>> v.set_immutable()
>>> v[Integer(0)] = Integer(3)
Traceback (most recent call last):
...
ValueError: object is immutable; please change a copy instead.
v = Sequence([1,2,3,4/5]) v type(v) type(v[1]) v.universe() v.is_immutable() v.set_immutable() v[0] = 3
Sequences derive from lists and can be used anywhere a list can be used:
sage: v = Sequence([1,2,3,4/5])
sage: isinstance(v, list)
True
sage: list(v)
[1, 2, 3, 4/5]
sage: type(list(v))
<... 'list'>
>>> from sage.all import *
>>> v = Sequence([Integer(1),Integer(2),Integer(3),Integer(4)/Integer(5)])
>>> isinstance(v, list)
True
>>> list(v)
[1, 2, 3, 4/5]
>>> type(list(v))
<... 'list'>
v = Sequence([1,2,3,4/5]) isinstance(v, list) list(v) type(list(v))
As another example, basis for vector spaces are immutable sequences, since it’s important that you don’t change them.
sage: V = QQ^3; B = V.basis(); B
[
(1, 0, 0),
(0, 1, 0),
(0, 0, 1)
]
sage: type(B)
<class 'sage.structure.sequence.Sequence_generic'>
sage: B[0] = B[1]
Traceback (most recent call last):
...
ValueError: object is immutable; please change a copy instead.
sage: B.universe()
Vector space of dimension 3 over Rational Field
>>> from sage.all import *
>>> V = QQ**Integer(3); B = V.basis(); B
[
(1, 0, 0),
(0, 1, 0),
(0, 0, 1)
]
>>> type(B)
<class 'sage.structure.sequence.Sequence_generic'>
>>> B[Integer(0)] = B[Integer(1)]
Traceback (most recent call last):
...
ValueError: object is immutable; please change a copy instead.
>>> B.universe()
Vector space of dimension 3 over Rational Field
V = QQ^3; B = V.basis(); B type(B) B[0] = B[1] B.universe()
Dictionaries¶
A dictionary (also sometimes called an associative array) is a mapping from ‘hashable’ objects (e.g., strings, numbers, and tuples of such; see the Python documentation http://docs.python.org/tut/node7.html and http://docs.python.org/lib/typesmapping.html for details) to arbitrary objects.
sage: d = {1:5, 'sage':17, ZZ:GF(7)}
sage: type(d)
<... 'dict'>
sage: list(d.keys())
[1, 'sage', Integer Ring]
sage: d['sage']
17
sage: d[ZZ]
Finite Field of size 7
sage: d[1]
5
>>> from sage.all import *
>>> d = {Integer(1):Integer(5), 'sage':Integer(17), ZZ:GF(Integer(7))}
>>> type(d)
<... 'dict'>
>>> list(d.keys())
[1, 'sage', Integer Ring]
>>> d['sage']
17
>>> d[ZZ]
Finite Field of size 7
>>> d[Integer(1)]
5
d = {1:5, 'sage':17, ZZ:GF(7)} type(d) list(d.keys()) d['sage'] d[ZZ] d[1]
The third key illustrates that the indexes of a dictionary can be complicated, e.g., the ring of integers.
You can turn the above dictionary into a list with the same data:
sage: list(d.items())
[(1, 5), ('sage', 17), (Integer Ring, Finite Field of size 7)]
>>> from sage.all import *
>>> list(d.items())
[(1, 5), ('sage', 17), (Integer Ring, Finite Field of size 7)]
list(d.items())
A common idiom is to iterate through the pairs in a dictionary:
sage: d = {2:4, 3:9, 4:16}
sage: [a*b for a, b in d.items()]
[8, 27, 64]
>>> from sage.all import *
>>> d = {Integer(2):Integer(4), Integer(3):Integer(9), Integer(4):Integer(16)}
>>> [a*b for a, b in d.items()]
[8, 27, 64]
d = {2:4, 3:9, 4:16} [a*b for a, b in d.items()]
A dictionary is unordered, as the last output illustrates.
Sets¶
Python has a built-in set type. The main feature it offers is very fast lookup of whether an element is in the set or not, along with standard set-theoretic operations.
sage: X = set([1,19,'a']); Y = set([1,1,1, 2/3])
sage: X # random sort order
{1, 19, 'a'}
sage: X == set(['a', 1, 1, 19])
True
sage: Y
{2/3, 1}
sage: 'a' in X
True
sage: 'a' in Y
False
sage: X.intersection(Y)
{1}
>>> from sage.all import *
>>> X = set([Integer(1),Integer(19),'a']); Y = set([Integer(1),Integer(1),Integer(1), Integer(2)/Integer(3)])
>>> X # random sort order
{1, 19, 'a'}
>>> X == set(['a', Integer(1), Integer(1), Integer(19)])
True
>>> Y
{2/3, 1}
>>> 'a' in X
True
>>> 'a' in Y
False
>>> X.intersection(Y)
{1}
X = set([1,19,'a']); Y = set([1,1,1, 2/3]) X # random sort order X == set(['a', 1, 1, 19]) Y 'a' in X 'a' in Y X.intersection(Y)
Sage also has its own set type that is (in some cases) implemented using
the built-in Python set type, but has a little bit of extra Sage-related
functionality. Create a Sage set using Set(...)
. For
example,
sage: X = Set([1,19,'a']); Y = Set([1,1,1, 2/3])
sage: X # random sort order
{'a', 1, 19}
sage: X == Set(['a', 1, 1, 19])
True
sage: Y
{1, 2/3}
sage: X.intersection(Y)
{1}
sage: print(latex(Y))
\left\{1, \frac{2}{3}\right\}
sage: Set(ZZ)
Set of elements of Integer Ring
>>> from sage.all import *
>>> X = Set([Integer(1),Integer(19),'a']); Y = Set([Integer(1),Integer(1),Integer(1), Integer(2)/Integer(3)])
>>> X # random sort order
{'a', 1, 19}
>>> X == Set(['a', Integer(1), Integer(1), Integer(19)])
True
>>> Y
{1, 2/3}
>>> X.intersection(Y)
{1}
>>> print(latex(Y))
\left\{1, \frac{2}{3}\right\}
>>> Set(ZZ)
Set of elements of Integer Ring
X = Set([1,19,'a']); Y = Set([1,1,1, 2/3]) X # random sort order X == Set(['a', 1, 1, 19]) Y X.intersection(Y) print(latex(Y)) Set(ZZ)
Iterators¶
Iterators are a recent addition to Python that are particularly useful in mathematics applications. Here are several examples; see [PyT] for more details. We make an iterator over the squares of the nonnegative integers up to \(10000000\).
sage: v = (n^2 for n in range(10000000))
sage: next(v)
0
sage: next(v)
1
sage: next(v)
4
>>> from sage.all import *
>>> v = (n**Integer(2) for n in range(Integer(10000000)))
>>> next(v)
0
>>> next(v)
1
>>> next(v)
4
v = (n^2 for n in range(10000000)) next(v) next(v) next(v)
We create an iterate over the primes of the form \(4p+1\) with \(p\) also prime, and look at the first few values.
sage: w = (4*p + 1 for p in Primes() if is_prime(4*p+1))
sage: w # in the next line, 0xb0853d6c is a random 0x number
<generator object at 0xb0853d6c>
sage: next(w)
13
sage: next(w)
29
sage: next(w)
53
>>> from sage.all import *
>>> w = (Integer(4)*p + Integer(1) for p in Primes() if is_prime(Integer(4)*p+Integer(1)))
>>> w # in the next line, 0xb0853d6c is a random 0x number
<generator object at 0xb0853d6c>
>>> next(w)
13
>>> next(w)
29
>>> next(w)
53
w = (4*p + 1 for p in Primes() if is_prime(4*p+1)) w # in the next line, 0xb0853d6c is a random 0x number next(w) next(w) next(w)
Certain rings, e.g., finite fields and the integers have iterators associated to them:
sage: [x for x in GF(7)]
[0, 1, 2, 3, 4, 5, 6]
sage: W = ((x,y) for x in ZZ for y in ZZ)
sage: next(W)
(0, 0)
sage: next(W)
(0, 1)
sage: next(W)
(0, -1)
>>> from sage.all import *
>>> [x for x in GF(Integer(7))]
[0, 1, 2, 3, 4, 5, 6]
>>> W = ((x,y) for x in ZZ for y in ZZ)
>>> next(W)
(0, 0)
>>> next(W)
(0, 1)
>>> next(W)
(0, -1)
[x for x in GF(7)] W = ((x,y) for x in ZZ for y in ZZ) next(W) next(W) next(W)
Loops, Functions, Control Statements, and Comparisons¶
We have seen a few examples already of some common uses of for
loops. In Python, a for
loop has an indented structure, such as
>>> for i in range(5):
... print(i)
...
0
1
2
3
4
Note the colon at the end of the for statement (there is no “do” or
“od” as in GAP or Maple), and the indentation before the “body” of
the loop, namely print(i)
. This indentation is important. In
Sage, the indentation is automatically put in for you when you hit
enter
after a “:”, as illustrated below.
sage: for i in range(5):
....: print(i) # now hit enter twice
....:
0
1
2
3
4
>>> from sage.all import *
>>> for i in range(Integer(5)):
... print(i) # now hit enter twice
....:
0
1
2
3
4
for i in range(5): print(i) # now hit enter twice
The symbol =
is used for assignment.
The symbol ==
is used to check for equality:
sage: for i in range(15):
....: if gcd(i,15) == 1:
....: print(i)
....:
1
2
4
7
8
11
13
14
>>> from sage.all import *
>>> for i in range(Integer(15)):
... if gcd(i,Integer(15)) == Integer(1):
... print(i)
....:
1
2
4
7
8
11
13
14
for i in range(15): if gcd(i,15) == 1: print(i)
Keep in mind how indentation determines the block structure for
if
, for
, and while
statements:
sage: def legendre(a,p):
....: is_sqr_modp=-1
....: for i in range(p):
....: if a % p == i^2 % p:
....: is_sqr_modp=1
....: return is_sqr_modp
sage: legendre(2,7)
1
sage: legendre(3,7)
-1
>>> from sage.all import *
>>> def legendre(a,p):
... is_sqr_modp=-Integer(1)
... for i in range(p):
... if a % p == i**Integer(2) % p:
... is_sqr_modp=Integer(1)
... return is_sqr_modp
>>> legendre(Integer(2),Integer(7))
1
>>> legendre(Integer(3),Integer(7))
-1
def legendre(a,p): is_sqr_modp=-1 for i in range(p): if a % p == i^2 % p: is_sqr_modp=1 return is_sqr_modp legendre(2,7) legendre(3,7)
Of course this is not an efficient implementation of the Legendre symbol! It is meant to illustrate various aspects of Python/Sage programming. The function {kronecker}, which comes with Sage, computes the Legendre symbol efficiently via a C-library call to PARI.
Finally, we note that comparisons, such as ==
,
!=
, <=
, >=
, >
, <
, between numbers will automatically
convert both numbers into the same type if possible:
sage: 2 < 3.1; 3.1 <= 1
True
False
sage: 2/3 < 3/2; 3/2 < 3/1
True
True
>>> from sage.all import *
>>> Integer(2) < RealNumber('3.1'); RealNumber('3.1') <= Integer(1)
True
False
>>> Integer(2)/Integer(3) < Integer(3)/Integer(2); Integer(3)/Integer(2) < Integer(3)/Integer(1)
True
True
2 < 3.1; 3.1 <= 1 2/3 < 3/2; 3/2 < 3/1
Use bool for symbolic inequalities:
sage: x < x + 1
x < x + 1
sage: bool(x < x + 1)
True
>>> from sage.all import *
>>> x < x + Integer(1)
x < x + 1
>>> bool(x < x + Integer(1))
True
x < x + 1 bool(x < x + 1)
When comparing objects of different types in Sage, in most cases
Sage tries to find a canonical coercion of both objects to a common
parent (see Parents, Conversion and Coercion for more details). If successful,
the comparison is performed between the coerced objects; if not successful,
the objects are considered not equal. For testing whether two variables
reference the same object use is
. As we see in this example,
the Python int 1
is unique, but the Sage Integer 1
is not:
sage: 1 is 2/2
False
sage: 1 is 1
False
sage: 1 == 2/2
True
>>> from sage.all import *
>>> Integer(1) is Integer(2)/Integer(2)
False
>>> Integer(1) is Integer(1)
False
>>> Integer(1) == Integer(2)/Integer(2)
True
1 is 2/2 1 is 1 1 == 2/2
In the following two lines, the first equality is False
because
there is no canonical morphism \(\QQ\to \GF{5}\), hence no
canonical way to compare the \(1\) in \(\GF{5}\) to the
\(1 \in \QQ\). In contrast, there is a canonical map
\(\ZZ \to \GF{5}\), hence the second comparison is True
. Note
also that the order doesn’t matter.
sage: GF(5)(1) == QQ(1); QQ(1) == GF(5)(1)
False
False
sage: GF(5)(1) == ZZ(1); ZZ(1) == GF(5)(1)
True
True
sage: ZZ(1) == QQ(1)
True
>>> from sage.all import *
>>> GF(Integer(5))(Integer(1)) == QQ(Integer(1)); QQ(Integer(1)) == GF(Integer(5))(Integer(1))
False
False
>>> GF(Integer(5))(Integer(1)) == ZZ(Integer(1)); ZZ(Integer(1)) == GF(Integer(5))(Integer(1))
True
True
>>> ZZ(Integer(1)) == QQ(Integer(1))
True
GF(5)(1) == QQ(1); QQ(1) == GF(5)(1) GF(5)(1) == ZZ(1); ZZ(1) == GF(5)(1) ZZ(1) == QQ(1)
WARNING: Comparison in Sage is more restrictive than in Magma, which declares the \(1 \in \GF{5}\) equal to \(1 \in \QQ\).
sage: magma('GF(5)!1 eq Rationals()!1') # optional - magma
true
>>> from sage.all import *
>>> magma('GF(5)!1 eq Rationals()!1') # optional - magma
true
magma('GF(5)!1 eq Rationals()!1') # optional - magma
Profiling¶
“Premature optimization is the root of all evil.” - Donald Knuth
Section author: Martin Albrecht <malb@informatik.uni-bremen.de>
Sometimes it is useful to check for bottlenecks in code to understand which parts take the most computational time; this can give a good idea of which parts to optimize. Python and therefore Sage offers several profiling–as this process is called–options.
The simplest to use is the prun
command in the interactive
shell. It returns a summary describing which functions took how
much computational time. To profile (the currently slow! - as of
version 1.0) matrix multiplication over finite fields, for example,
do:
sage: k,a = GF(2**8, 'a').objgen()
sage: A = Matrix(k,10,10,[k.random_element() for _ in range(10*10)])
>>> from sage.all import *
>>> k,a = GF(Integer(2)**Integer(8), 'a').objgen()
>>> A = Matrix(k,Integer(10),Integer(10),[k.random_element() for _ in range(Integer(10)*Integer(10))])
k,a = GF(2**8, 'a').objgen() A = Matrix(k,10,10,[k.random_element() for _ in range(10*10)])
sage: %prun B = A*A
32893 function calls in 1.100 CPU seconds
Ordered by: internal time
ncalls tottime percall cumtime percall filename:lineno(function)
12127 0.160 0.000 0.160 0.000 :0(isinstance)
2000 0.150 0.000 0.280 0.000 matrix.py:2235(__getitem__)
1000 0.120 0.000 0.370 0.000 finite_field_element.py:392(__mul__)
1903 0.120 0.000 0.200 0.000 finite_field_element.py:47(__init__)
1900 0.090 0.000 0.220 0.000 finite_field_element.py:376(__compat)
900 0.080 0.000 0.260 0.000 finite_field_element.py:380(__add__)
1 0.070 0.070 1.100 1.100 matrix.py:864(__mul__)
2105 0.070 0.000 0.070 0.000 matrix.py:282(ncols)
...
>>> from sage.all import *
>>> %prun B = A*A
32893 function calls in 1.100 CPU seconds
Ordered by: internal time
ncalls tottime percall cumtime percall filename:lineno(function)
12127 0.160 0.000 0.160 0.000 :0(isinstance)
2000 0.150 0.000 0.280 0.000 matrix.py:2235(__getitem__)
1000 0.120 0.000 0.370 0.000 finite_field_element.py:392(__mul__)
1903 0.120 0.000 0.200 0.000 finite_field_element.py:47(__init__)
1900 0.090 0.000 0.220 0.000 finite_field_element.py:376(__compat)
900 0.080 0.000 0.260 0.000 finite_field_element.py:380(__add__)
1 0.070 0.070 1.100 1.100 matrix.py:864(__mul__)
2105 0.070 0.000 0.070 0.000 matrix.py:282(ncols)
...
%prun B = A*A
Here ncalls
is the number of calls, tottime
is the total time
spent in the given function (and excluding time made in calls to
sub-functions), percall
is the quotient of tottime
divided by
ncalls
. cumtime
is the total time spent in this and all
sub-functions (i.e., from invocation until exit), percall
is the
quotient of cumtime
divided by primitive calls, and
filename:lineno(function)
provides the respective data of each
function. The rule of thumb here is: The higher the function in
that listing, the more expensive it is. Thus it is more interesting
for optimization.
As usual, prun?
provides details on how to use the profiler and
understand the output.
The profiling data may be written to an object as well to allow closer examination:
sage: %prun -r A*A
sage: stats = _
sage: stats?
>>> from sage.all import *
>>> %prun -r A*A
>>> stats = _
>>> stats?
%prun -r A*A stats = _ stats?
Note: entering stats = prun -r A\*A
displays a syntax error
message because prun is an IPython shell command, not a regular
function.
For a nice graphical representation of profiling data, you can use
the hotshot profiler, a small script called hotshot2cachetree
and
the program kcachegrind
(Unix only). The same example with the
hotshot profiler:
sage: k,a = GF(2**8, 'a').objgen()
sage: A = Matrix(k,10,10,[k.random_element() for _ in range(10*10)])
sage: import hotshot
sage: filename = "pythongrind.prof"
sage: prof = hotshot.Profile(filename, lineevents=1)
>>> from sage.all import *
>>> k,a = GF(Integer(2)**Integer(8), 'a').objgen()
>>> A = Matrix(k,Integer(10),Integer(10),[k.random_element() for _ in range(Integer(10)*Integer(10))])
>>> import hotshot
>>> filename = "pythongrind.prof"
>>> prof = hotshot.Profile(filename, lineevents=Integer(1))
k,a = GF(2**8, 'a').objgen() A = Matrix(k,10,10,[k.random_element() for _ in range(10*10)]) import hotshot filename = "pythongrind.prof" prof = hotshot.Profile(filename, lineevents=1)
sage: prof.run("A*A")
<hotshot.Profile instance at 0x414c11ec>
sage: prof.close()
>>> from sage.all import *
>>> prof.run("A*A")
<hotshot.Profile instance at 0x414c11ec>
>>> prof.close()
prof.run("A*A") prof.close()
This results in a file pythongrind.prof
in the current working
directory. It can now be converted to the cachegrind format for
visualization.
On a system shell, type
$ hotshot2calltree -o cachegrind.out.42 pythongrind.prof
The output file cachegrind.out.42
can now be examined with
kcachegrind
. Please note that the naming convention
cachegrind.out.XX
needs to be obeyed.