# SymPy - Arbitrary number of Symbols

I am coding a function that solves an arbitrary number of simultaneous equations. The number of equations is set by one of the parameters of the function and each equation is built from a number of symbols - as many symbols as there are equations. This means that I can't simply hardcode the equations, or even the symbols needed to put together the equations; the function needs to be able to handle any number of equations. So, my question is, how do I produce a list of symbols?

I have one possible solution, but my gut tells me that it's not going to be very efficient. Please let me know if there is a better way of doing this.

I'm new to SymPy and am still feeling my way about. As far as I can see, Symbols need to be defined with a string. Therefore, I can produce a series strings via appending an incrementing number to a letter (say 't0', 't1', etc), add them to a list and then create the symbols using those strings as parameters. Those symbols would themselves be stored in a list and would be used to produce the equations.

def solveEquations(numEquations):
symbolNameList = []
symbolList = []
equationList = []
for i in range(numEquations):
name = 't' + str(i)
symbolNameList.append(name)
symbolList.append(Symbol(name))

for i in range(numEquations):
equation = 0
for sym in symbolList:
equation += sym ** i # Or whatever structure the equation needs
equationList.append(equation)

#Then go on to solve the equations...

Is this the best way of doing this, or is there a more efficient approach?

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## 4 Answers

The symbols function can be used to easily generate lists of symbols

In [1]: symbols('a0:3')
Out[1]: (a₀, a₁, a₂)

In [2]: numEquations = 15

In [3]: symbols('a0:%d'%numEquations)
Out[3]: (a₀, a₁, a₂, a₃, a₄, a₅, a₆, a₇, a₈, a₉, a₁₀, a₁₁, a₁₂, a₁₃, a₁₄)
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Thanks! That looks really simple. –  thornate Feb 29 '12 at 7:22
It also works for letters: symbols('a:g'). –  asmeurer Dec 28 '12 at 10:06
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numbered_symbols("t") will return a generator that generates t0, t1, t2, etc. You can use the start parameter to choose a different starting value. And if you want to use dummy variables, use numbered_symbols("t", cls=Dummy).

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Your approach is fine, though there's no need to store the symbol names separately (you can access a symbol's name via its name property).

Also, you could express the symbol creation a little more concisely (though no more efficiently), e.g.:

symbolList = map(lambda i: Symbol('t' + str(i)), xrange(numEquations))

However, for your use case (temporary variables), dummy variables are probably the way to go:

symbolList = map(Dummy, xrange(numEquations))

This isn't really any more efficient, since internally the Dummy class is also using a counter to generate unique names, but it's a bit cleaner and clearer.

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You could make a subclass of dict which automatically returns Symbols:

import sympy as sym

class SymDict(dict):
# http://stackoverflow.com/a/3405143/190597
def __missing__(self, key):
self[key]=sym.Symbol(key)
return self[key]

def solveEquations(numEquations):
symbol = SymDict()
symbolList = ['t'+str(i) for i in range(numEquations)]
equationList = [sum(symbol[s]**i for s in symbolList)
for i in range(numEquations)]
print(equationList)

solveEquations(3)
# [3, t0 + t1 + t2, t0**2 + t1**2 + t2**2]
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