Gotchas and Pitfalls¶
Introduction¶
SymPy runs under the Python Programming Language, so there are some things that may behave differently than they do in other, independent computer algebra systems like Maple or Mathematica. These are some of the gotchas and pitfalls that you may encounter when using SymPy. See also the FAQ, the Tutorial, the remainder of the SymPy Docs, and the official Python Tutorial.
If you are already familiar with C or Java, you might also want to look at this 4 minute Python tutorial.
Ignore #doctest: +SKIP
in the examples. That has to do with
internal testing of the examples.
Equals Signs (=)¶
Single Equals Sign¶
The equals sign (=
) is the assignment operator, not equality. If
you want to do \(x = y\), use Eq(x, y)
for equality.
Alternatively, all expressions are assumed to equal zero, so you can
just subtract one side and use x  y
.
The proper use of the equals sign is to assign expressions to variables.
For example:
>>> from sympy.abc import x, y
>>> a = x  y
>>> print(a)
x  y
Double Equals Signs¶
Double equals signs (==
) are used to test equality. However, this
tests expressions exactly, not symbolically. For example:
>>> (x + 1)**2 == x**2 + 2*x + 1
False
>>> (x + 1)**2 == (x + 1)**2
True
If you want to test for symbolic equality, one way is to subtract one
expression from the other and run it through functions like
expand()
, simplify()
, and trigsimp()
and see if the
equation reduces to 0.
>>> from sympy import simplify, cos, sin, expand
>>> simplify((x + 1)**2  (x**2 + 2*x + 1))
0
>>> eq = sin(2*x)  2*sin(x)*cos(x)
>>> simplify(eq)
0
>>> expand(eq, trig=True)
0
Note
See also Why does SymPy say that two equal expressions are unequal? in the FAQ.
Variables¶
Variables Assignment does not Create a Relation Between Expressions¶
When you use =
to do assignment, remember that in Python, as in most
programming languages, the variable does not change if you change the
value you assigned to it. The equations you are typing use the values
present at the time of creation to “fill in” values, just like regular
Python definitions. They are not altered by changes made afterwards.
Consider the following:
>>> from sympy import Symbol
>>> a = Symbol('a') # Symbol, `a`, stored as variable "a"
>>> b = a + 1 # an expression involving `a` stored as variable "b"
>>> print(b)
a + 1
>>> a = 4 # "a" now points to literal integer 4, not Symbol('a')
>>> print(a)
4
>>> print(b) # "b" is still pointing at the expression involving `a`
a + 1
Changing quantity a
does not change b
; you are not working
with a set of simultaneous equations. It might be helpful to remember
that the string that gets printed when you print a variable referring to
a SymPy object is the string that was given to it when it was created;
that string does not have to be the same as the variable that you assign
it to.
>>> from sympy import var
>>> r, t, d = var('rate time short_life')
>>> d = r*t
>>> print(d)
rate*time
>>> r = 80
>>> t = 2
>>> print(d) # We haven't changed d, only r and t
rate*time
>>> d = r*t
>>> print(d) # Now d is using the current values of r and t
160
If you need variables that have dependence on each other, you can define
functions. Use the def
operator. Indent the body of the function.
See the Python docs for more information on defining functions.
>>> c, d = var('c d')
>>> print(c)
c
>>> print(d)
d
>>> def ctimesd():
... """
... This function returns whatever c is times whatever d is.
... """
... return c*d
...
>>> ctimesd()
c*d
>>> c = 2
>>> print(c)
2
>>> ctimesd()
2*d
If you define a circular relationship, you will get a
RuntimeError
.
>>> def a():
... return b()
...
>>> def b():
... return a()
...
>>> a()
Traceback (most recent call last):
File "...", line ..., in ...
compileflags, 1) in test.globs
File "<...>", line 1, in <module>
a()
File "<...>", line 2, in a
return b()
File "<...>", line 2, in b
return a()
File "<...>", line 2, in a
return b()
...
RuntimeError: maximum recursion depth exceeded
Note
See also Why doesn’t changing one variable change another that depends on it? in the FAQ.
Symbols¶
Symbols are variables, and like all other variables, they need to be assigned before you can use them. For example:
>>> import sympy
>>> z**2 # z is not defined yet
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
NameError: name 'z' is not defined
>>> sympy.var('z') # This is the easiest way to define z as a standard symbol
z
>>> z**2
z**2
If you use isympy, it runs the following commands for you, giving you some default Symbols and Functions.
>>> from __future__ import division
>>> from sympy import *
>>> x, y, z, t = symbols('x y z t')
>>> k, m, n = symbols('k m n', integer=True)
>>> f, g, h = symbols('f g h', cls=Function)
You can also import common symbol names from sympy.abc
.
>>> from sympy.abc import w
>>> w
w
>>> import sympy
>>> dir(sympy.abc)
['A', 'B', 'C', 'D', 'E', 'F', 'G', 'H', 'I', 'J', 'K', 'L', 'M', 'N', 'O',
'P', 'Q', 'R', 'S', 'Symbol', 'T', 'U', 'V', 'W', 'X', 'Y', 'Z',
'__builtins__', '__doc__', '__file__', '__name__', '__package__', '_greek',
'_latin', 'a', 'alpha', 'b', 'beta', 'c', 'chi', 'd', 'delta', 'e',
'epsilon', 'eta', 'f', 'g', 'gamma', 'h', 'i', 'iota', 'j', 'k', 'kappa',
'l', 'm', 'mu', 'n', 'nu', 'o', 'omega', 'omicron', 'p', 'phi', 'pi',
'psi', 'q', 'r', 'rho', 's', 'sigma', 't', 'tau', 'theta', 'u', 'upsilon',
'v', 'w', 'x', 'xi', 'y', 'z', 'zeta']
If you want control over the assumptions of the variables, use
Symbol
and symbols()
. See Keyword
Arguments below.
Lastly, it is recommended that you not use I
, E
, S
, N
, C
, O
, or Q
for variable or symbol names, as those
are used for the imaginary unit (\(i\)), the base of the natural logarithm
(\(e\)), the sympify()
function (see Symbolic
Expressions below), numeric evaluation (N()
is
equivalent to evalf() ), the big O order symbol (as in
\(O(n\log{n})\)), and the assumptions object that holds a list of
supported ask keys (such as Q.real
), respectively. You can use the
mnemonic OSINEQ
to remember what Symbols are defined by default in SymPy.
Or better yet, always use lowercase letters for Symbol names. Python will not
prevent you from overriding default SymPy names or functions, so be careful.
>>> cos(pi) # cos and pi are a builtin sympy names.
1
>>> pi = 3 # Notice that there is no warning for overriding pi.
>>> cos(pi)
cos(3)
>>> def cos(x): # No warning for overriding builtin functions either.
... return 5*x
...
>>> cos(pi)
15
>>> from sympy import cos # reimport to restore normal behavior
To get a full list of all default names in SymPy do:
>>> import sympy
>>> dir(sympy)
# A big list of all default sympy names and functions follows.
# Ignore everything that starts and ends with __.
If you have IPython installed and use isympy, you can also press the TAB key to get a list of all builtin names and to autocomplete. Also, see this page for a trick for getting tab completion in the regular Python console.
Note
See also What is the best way to create symbols? in the FAQ.
Symbolic Expressions¶
Python numbers vs. SymPy Numbers¶
SymPy uses its own classes for integers, rational numbers, and floating
point numbers instead of the default Python int
and float
types because it allows for more control. But you have to be careful.
If you type an expression that just has numbers in it, it will default
to a Python expression. Use the sympify()
function, or just
S
, to ensure that something is a SymPy expression.
>>> 6.2 # Python float. Notice the floating point accuracy problems.
6.2000000000000002
>>> type(6.2) # <type 'float'> in Python 2.x, <class 'float'> in Py3k
<... 'float'>
>>> S(6.2) # SymPy Float has no such problems because of arbitrary precision.
6.20000000000000
>>> type(S(6.2))
<class 'sympy.core.numbers.Float'>
If you include numbers in a SymPy expression, they will be sympified
automatically, but there is one gotcha you should be aware of. If you
do <number>/<number>
inside of a SymPy expression, Python will
evaluate the two numbers before SymPy has a chance to get
to them. The solution is to sympify()
one of the numbers, or use
Rational
.
>>> x**(1/2) # evaluates to x**0 or x**0.5
x**0.5
>>> x**(S(1)/2) # sympyify one of the ints
sqrt(x)
>>> x**Rational(1, 2) # use the Rational class
sqrt(x)
With a power of 1/2
you can also use sqrt
shorthand:
>>> sqrt(x) == x**Rational(1, 2)
True
If the two integers are not directly separated by a division sign then you don’t have to worry about this problem:
>>> x**(2*x/3)
x**(2*x/3)
Note
A common mistake is copying an expression that is printed and
reusing it. If the expression has a Rational
(i.e.,
<number>/<number>
) in it, you will not get the same result,
obtaining the Python result for the division rather than a SymPy
Rational.
>>> x = Symbol('x')
>>> print(solve(7*x 22, x))
[22/7]
>>> 22/7 # If we just copy and paste we get int 3 or a float
3.142857142857143
>>> # One solution is to just assign the expression to a variable
>>> # if we need to use it again.
>>> a = solve(7*x  22, x)[0]
>>> a
22/7
The other solution is to put quotes around the expression and run it through S() (i.e., sympify it):
>>> S("22/7")
22/7
Also, if you do not use isympy, you could use from
__future__ import division
to prevent the /
sign from performing
integer division.
>>> from __future__ import division >>> 1/2 # With division imported it evaluates to a python float 0.5 >>> 1//2 # You can still achieve integer division with // 0But be careful: you will now receive floats where you might have desired a Rational:
>>> x**(1/2) x**0.5
Rational
only works for number/number and is only meant for
rational numbers. If you want a fraction with symbols or expressions in
it, just use /
. If you do number/expression or expression/number,
then the number will automatically be converted into a SymPy Number.
You only need to be careful with number/number.
>>> Rational(2, x)
Traceback (most recent call last):
...
TypeError: invalid input: x
>>> 2/x
2/x
Evaluating Expressions with Floats and Rationals¶
SymPy keeps track of the precision of Float
objects. The default precision is
15 digits. When an expression involving a Float
is evaluated, the result
will be expressed to 15 digits of precision but those digits (depending
on the numbers involved with the calculation) may not all be significant.
The first issue to keep in mind is how the Float
is created: it is created
with a value and a precision. The precision indicates how precise of a value
to use when that Float
(or an expression it appears in) is evaluated.
The values can be given as strings, integers, floats, or rationals.
strings and integers are interpreted as exact
>>> Float(100) 100.000000000000 >>> Float('100', 5) 100.00
to have the precision match the number of digits, the null string can be used for the precision
>>> Float(100, '') 100. >>> Float('12.34') 12.3400000000000 >>> Float('12.34', '') 12.34>>> s, r = [Float(j, 3) for j in ('0.25', Rational(1, 7))] >>> for f in [s, r]: ... print(f) 0.250 0.143
Next, notice that each of those values looks correct to 3 digits. But if we try to evaluate them to 20 digits, a difference will become apparent:
The 0.25 (with precision of 3) represents a number that has a nonrepeating binary decimal; 1/7 is repeating in binary and decimal – it cannot be represented accurately too far past those first 3 digits (the correct decimal is a repeating 142857):
>>> s.n(20) 0.25000000000000000000 >>> r.n(20) 0.14285278320312500000It is important to realize that although a Float is being displayed in decimal at arbitrary precision, it is actually stored in binary. Once the Float is created, its binary information is set at the given precision. The accuracy of that value cannot be subsequently changed; so 1/7, at a precision of 3 digits, can be padded with binary zeros, but these will not make it a more accurate value of 1/7.
If inexact, lowprecision numbers are involved in a calculation with higher precision values, the evalf engine will increase the precision of the low precision values and inexact results will be obtained. This is feature of calculations with limited precision:
>>> Float('0.1', 10) + Float('0.1', 3)
0.2000061035
Although the evalf
engine tried to maintain 10 digits of precision (since
that was the highest precision represented) the 3digit precision used
limits the accuracy to about 4 digits – not all the digits you see
are significant. evalf doesn’t try to keep track of the number of
significant digits.
That very simple expression involving the addition of two numbers with different precisions will hopefully be instructive in helping you understand why more complicated expressions (like trig expressions that may not be simplified) will not evaluate to an exact zero even though, with the right simplification, they should be zero. Consider this unsimplified trig identity, multiplied by a big number:
>>> big = 12345678901234567890
>>> big_trig_identity = big*cos(x)**2 + big*sin(x)**2  big*1
>>> abs(big_trig_identity.subs(x, .1).n(2)) > 1000
True
When the \(\cos\) and \(\sin\) terms were evaluated to 15 digits of precision and multiplied by the big number, they gave a large number that was only precise to 15 digits (approximately) and when the 20 digit big number was subtracted the result was not zero.
There are three things that will help you obtain more precise numerical values for expressions:
1) Pass the desired substitutions with the call to evaluate. By doing the subs first, the
Float
values cannot be updated as necessary. By passing the desired substitutions with the call to evalf the ability to reevaluate as necessary is gained and the results are impressively better:>>> big_trig_identity.n(2, {x: 0.1}) 0.e912) Use Rationals, not Floats. During the evaluation process, the Rational can be computed to an arbitrary precision while the Float, once created – at a default of 15 digits – cannot. Compare the value of
1.4e+3
above with the nearly zero value obtained when replacing x with a Rational representing 1/10 – before the call to evaluate:>>> big_trig_identity.subs(x, S('1/10')).n(2) 0.e913) Try to simplify the expression. In this case, SymPy will recognize the trig identity and simplify it to zero so you don’t even have to evaluate it numerically:
>>> big_trig_identity.simplify() 0
Immutability of Expressions¶
Expressions in SymPy are immutable, and cannot be modified by an inplace operation. This means that a function will always return an object, and the original expression will not be modified. The following example snippet demonstrates how this works:
def main():
var('x y a b')
expr = 3*x + 4*y
print('original =', expr)
expr_modified = expr.subs({x: a, y: b})
print('modified =', expr_modified)
if __name__ == "__main__":
main()
The output shows that the subs()
function has replaced variable
x
with variable a
, and variable y
with variable b
:
original = 3*x + 4*y
modified = 3*a + 4*b
The subs()
function does not modify the original expression expr
.
Rather, a modified copy of the expression is returned. This returned object
is stored in the variable expr_modified
. Note that unlike C/C++ and
other highlevel languages, Python does not require you to declare a variable
before it is used.
Mathematical Operators¶
SymPy uses the same default operators as Python. Most of these, like
*/+
, are standard. Aside from integer division discussed in
Python numbers vs. SymPy Numbers above,
you should also be aware that implied multiplication is not allowed. You
need to use *
whenever you wish to multiply something. Also, to
raise something to a power, use **
, not ^
as many computer
algebra systems use. Parentheses ()
change operator precedence as
you would normally expect.
In isympy, with the ipython shell:
>>> 2x
Traceback (most recent call last):
...
SyntaxError: invalid syntax
>>> 2*x
2*x
>>> (x + 1)^2 # This is not power. Use ** instead.
Traceback (most recent call last):
...
TypeError: unsupported operand type(s) for ^: 'Add' and 'int'
>>> (x + 1)**2
(x + 1)**2
>>> pprint(3  x**(2*x)/(x + 1))
2*x
x
  + 3
x + 1
Inverse Trig Functions¶
SymPy uses different names for some functions than most computer algebra
systems. In particular, the inverse trig functions use the python names
of asin
, acos
and so on instead of the usual arcsin
and arccos
. Use the methods described in Symbols
above to see the names of all SymPy functions.
Special Symbols¶
The symbols []
, {}
, =
, and ()
have special meanings in
Python, and thus in SymPy. See the Python docs linked to above for
additional information.
Lists¶
Square brackets []
denote a list. A list is a container that holds
any number of different objects. A list can contain anything, including
items of different types. Lists are mutable, which means that you can
change the elements of a list after it has been created. You access the
items of a list also using square brackets, placing them after the list
or list variable. Items are numbered using the space before the item.
Note
List indexes begin at 0.
Example:
>>> a = [x, 1] # A simple list of two items
>>> a
[x, 1]
>>> a[0] # This is the first item
x
>>> a[0] = 2 # You can change values of lists after they have been created
>>> print(a)
[2, 1]
>>> print(solve(x**2 + 2*x  1, x)) # Some functions return lists
[1 + sqrt(2), sqrt(2)  1]
Note
See the Python docs for more information on lists and the square bracket notation for accessing elements of a list.
Dictionaries¶
Curly brackets {}
denote a dictionary, or a dict for short. A
dictionary is an unordered list of nonduplicate keys and values. The
syntax is {key: value}
. You can access values of keys using square
bracket notation.
>>> d = {'a': 1, 'b': 2} # A dictionary.
>>> d
{'a': 1, 'b': 2}
>>> d['a'] # How to access items in a dict
1
>>> roots((x  1)**2*(x  2), x) # Some functions return dicts
{1: 2, 2: 1}
>>> # Some SymPy functions return dictionaries. For example,
>>> # roots returns a dictionary of root:multiplicity items.
>>> roots((x  5)**2*(x + 3), x)
{3: 1, 5: 2}
>>> # This means that the root 3 occurs once and the root 5 occurs twice.
Note
See the Python docs for more information on dictionaries.
Tuples¶
Parentheses ()
, aside from changing operator precedence and their
use in function calls, (like cos(x)
), are also used for tuples. A
tuple
is identical to a list, except that it is not
mutable. That means that you cannot change their values after they
have been created. In general, you will not need tuples in SymPy, but
sometimes it can be more convenient to type parentheses instead of
square brackets.
>>> t = (1, 2, x) # Tuples are like lists >>> t (1, 2, x) >>> t[0] 1 >>> t[0] = 4 # Except you cannot change them after they have been created Traceback (most recent call last): File "<console>", line 1, in <module> TypeError: 'tuple' object does not support item assignmentSingle element tuples, unlike lists, must have a comma in them:
>>> (x,) (x,)Without the comma, a single expression without a comma is not a tuple:
>>> (x) xintegrate takes a sequence as the second argument if you want to integrate with limits (and a tuple or list will work):
>>> integrate(x**2, (x, 0, 1)) 1/3 >>> integrate(x**2, [x, 0, 1]) 1/3
Note
See the Python docs for more information on tuples.
Keyword Arguments¶
Aside from the usage described above, equals signs
(=
) are also used to give named arguments to functions. Any
function that has key=value
in its parameters list (see below on how
to find this out), then key
is set to value
by default. You can
change the value of the key by supplying your own value using the equals
sign in the function call. Also, functions that have **
followed by
a name in the parameters list (usually **kwargs
or
**assumptions
) allow you to add any number of key=value
pairs
that you want, and they will all be evaluated according to the function.
sqrt(x**2)
doesn’t auto simplify to x because x is assumed to be complex by default, and, for example,sqrt((1)**2) == sqrt(1) == 1 != 1
:>>> sqrt(x**2) sqrt(x**2)Giving assumptions to Symbols is an example of using the keyword argument:
>>> x = Symbol('x', positive=True)The square root will now simplify since it knows that
x >= 0
:>>> sqrt(x**2) xpowsimp has a default argument of
combine='all'
:>>> pprint(powsimp(x**n*x**m*y**n*y**m)) m + n (x*y)Setting combine to the default value is the same as not setting it.
>>> pprint(powsimp(x**n*x**m*y**n*y**m, combine='all')) m + n (x*y)The nondefault options are
'exp'
, which combines exponents…>>> pprint(powsimp(x**n*x**m*y**n*y**m, combine='exp')) m + n m + n x *y…and ‘base’, which combines bases.
>>> pprint(powsimp(x**n*x**m*y**n*y**m, combine='base')) m n (x*y) *(x*y)
Note
See the Python docs for more information on function parameters.
Getting help from within SymPy¶
help()¶
Although all docs are available at docs.sympy.org or on the
SymPy Wiki, you can also get info on functions from within the
Python interpreter that runs SymPy. The easiest way to do this is to do
help(function)
, or function?
if you are using ipython:
In [1]: help(powsimp) # help() works everywhere
In [2]: # But in ipython, you can also use ?, which is better because it
In [3]: # it gives you more information
In [4]: powsimp?
These will give you the function parameters and docstring for
powsimp()
. The output will look something like this:

sympy.simplify.simplify.
powsimp
(expr, deep=False, combine='all', force=False, measure=<function count_ops>)[source] reduces expression by combining powers with similar bases and exponents.
Notes
If deep is True then powsimp() will also simplify arguments of functions. By default deep is set to False.
If force is True then bases will be combined without checking for assumptions, e.g. sqrt(x)*sqrt(y) > sqrt(x*y) which is not true if x and y are both negative.
You can make powsimp() only combine bases or only combine exponents by changing combine=’base’ or combine=’exp’. By default, combine=’all’, which does both. combine=’base’ will only combine:
a a a 2x x x * y => (x*y) as well as things like 2 => 4
and combine=’exp’ will only combine
a b (a + b) x * x => x
combine=’exp’ will strictly only combine exponents in the way that used to be automatic. Also use deep=True if you need the old behavior.
When combine=’all’, ‘exp’ is evaluated first. Consider the first example below for when there could be an ambiguity relating to this. This is done so things like the second example can be completely combined. If you want ‘base’ combined first, do something like powsimp(powsimp(expr, combine=’base’), combine=’exp’).
Examples
>>> from sympy import powsimp, exp, log, symbols >>> from sympy.abc import x, y, z, n >>> powsimp(x**y*x**z*y**z, combine='all') x**(y + z)*y**z >>> powsimp(x**y*x**z*y**z, combine='exp') x**(y + z)*y**z >>> powsimp(x**y*x**z*y**z, combine='base', force=True) x**y*(x*y)**z
>>> powsimp(x**z*x**y*n**z*n**y, combine='all', force=True) (n*x)**(y + z) >>> powsimp(x**z*x**y*n**z*n**y, combine='exp') n**(y + z)*x**(y + z) >>> powsimp(x**z*x**y*n**z*n**y, combine='base', force=True) (n*x)**y*(n*x)**z
>>> x, y = symbols('x y', positive=True) >>> powsimp(log(exp(x)*exp(y))) log(exp(x)*exp(y)) >>> powsimp(log(exp(x)*exp(y)), deep=True) x + y
Radicals with Mul bases will be combined if combine=’exp’
>>> from sympy import sqrt, Mul >>> x, y = symbols('x y')
Two radicals are automatically joined through Mul:
>>> a=sqrt(x*sqrt(y)) >>> a*a**3 == a**4 True
But if an integer power of that radical has been autoexpanded then Mul does not join the resulting factors:
>>> a**4 # auto expands to a Mul, no longer a Pow x**2*y >>> _*a # so Mul doesn't combine them x**2*y*sqrt(x*sqrt(y)) >>> powsimp(_) # but powsimp will (x*sqrt(y))**(5/2) >>> powsimp(x*y*a) # but won't when doing so would violate assumptions x*y*sqrt(x*sqrt(y))
source()¶
Another useful option is the source()
function. This will print
the source code of a function, including any docstring that it may have.
You can also do function??
in ipython. For example,
from SymPy 0.6.5:
>>> source(simplify) # simplify() is actually only 2 lines of code.
In file: ./sympy/simplify/simplify.py
def simplify(expr):
"""Naively simplifies the given expression.
...
Simplification is not a well defined term and the exact strategies
this function tries can change in the future versions of SymPy. If
your algorithm relies on "simplification" (whatever it is), try to
determine what you need exactly  is it powsimp()? radsimp()?
together()?, logcombine()?, or something else? And use this particular
function directly, because those are well defined and thus your algorithm
will be robust.
...
"""
expr = Poly.cancel(powsimp(expr))
return powsimp(together(expr.expand()), combine='exp', deep=True)