3

I've been playing around with sympy and decided to make an arbitrary equations solver since my finance class was getting a little dreary. I wrote a basic framework and started playing with some examples, but some work and some don't for some reason.

from sympy import *
import sympy.mpmath as const

OUT_OF_BOUNDS = "Integer out of bounds."
INVALID_INTEGER = "Invalid Integer."
INVALID_FLOAT = "Invalid Float."
CANT_SOLVE_VARIABLES = "Unable to Solve for More than One Variable."
CANT_SOLVE_DONE = "Already Solved. Nothing to do."

# time value of money equation: FV = PV(1 + i)**n
# FV = future value
# PV = present value
# i = growth rate per perioid
# n = number of periods
FV, PV, i, n = symbols('FV PV i n')
time_value_money_discrete = Eq(FV, PV*(1+i)**n)
time_value_money_continuous = Eq(FV, PV*const.e**(i*n))

def get_sym_num(prompt, fail_prompt):
    while(True):
        try:
            s = input(prompt)
            if s == "":
                return None
            f = sympify(s)
            return f
        except:
            print(fail_prompt)
            continue

equations_supported = [['Time Value of Money (discrete)', [FV, PV, i, n], time_value_money_discrete], 
                       ['Time Value of Money (continuous)',[FV, PV, i, n], time_value_money_continuous]]
EQUATION_NAME = 0
EQUATION_PARAMS = 1
EQUATION_EXPR = 2

if __name__ == "__main__":
    while(True):
        print()
        for i, v in enumerate(equations_supported):
            print("{}: {}".format(i, v[EQUATION_NAME]))
        try:
            process = input("What equation do you want to solve?  ")
            if process == "" or process == "exit":
                break
            process = int(process)
        except:
            print(INVALID_INTEGER)
            continue
        if process < 0 or process >= len(equations_supported):
            print(OUT_OF_BOUNDS)
            continue
        params = [None]*len(equations_supported[process][EQUATION_PARAMS])
        for i, p in enumerate(equations_supported[process][EQUATION_PARAMS]):
            params[i] = get_sym_num("What is {}? ".format(p), INVALID_FLOAT)
        if params.count(None) > 1:
            print(CANT_SOLVE_VARIABLES)
            continue
        if params.count(None) == 0:
            print(CANT_SOLVE_DONE)
            continue
        curr_expr = equations_supported[process][EQUATION_EXPR]
        for i, p in enumerate(params):
            if p != None:
                curr_expr = curr_expr.subs(equations_supported[process][EQUATION_PARAMS][i], params[i])
        print(solve(curr_expr,  equations_supported[process][EQUATION_PARAMS][params.index(None)]))

This is the code I have so far. I guess I can strip it down to a basic example if need be, but I was also wondering if there was a better way to implement this sort of system. After I have this down, I want to be able to add arbitrary equations and solve them after inputting all but one parameter.

For example, if I put in (for equation 0), FV = 1000, PV = 500, i = .02, n is empty I get 35.0027887811465 which is the correct answer. If I redo it and change FV to 4000, it returns an empty list as the answer.

Another example, when I input an FV, PV, and an n, the program seems to hang. When I input small numbers, I got RootOf() answers instead of a simple decimal.

Can anyone help me?

Side note: I'm using SymPy 0.7.6 and Python 3.5.1 which I'm pretty sure are the latest

1
  • For numerical solutions you might try nsolve.
    – asmeurer
    Jan 22, 2016 at 19:41

2 Answers 2

2

This is a floating point accuracy issue. solve by default plugs solutions into the original equation and evaluates them (using floating point arithmetic) in order to sort out false solutions. You can disable this by setting check=False. For example, for Hugh Bothwell's code

for fv in range(1870, 1875, 1):
    sols = sp.solve(eq.subs({FV:fv}), check=False)
    print("{}: {}".format(fv, sols))

which gives

1870: [66.6116466112007]
1871: [66.6386438584579]
1872: [66.6656266802551]
1873: [66.6925950919998]
1874: [66.7195491090752]
1
  • Awesome! As a little addon in case anyone was wondering about the second example, sympy tries to find the exact solution, so if n is really high, it gives n RootOf solutions. If you experiment with n = 1 and n = 2, you can see sympy gives answers with sqrt in it. Using nsolve works better
    – Billy Won
    Jan 25, 2016 at 16:30
1

I don't have an answer, but I do have a much simpler demonstration case ;-)

import sympy as sp

FV, n = sp.symbols("FV n")
eq = sp.Eq(FV, sp.S("500 * 1.02 ** n"))

# see where it breaks
for fv in range(1870, 1875, 1):
    sols = sp.solve(eq.subs({FV:fv}))
    print("{}: {}".format(fv, sols))

which produces

1870: [66.6116466112007]
1871: [66.6386438584579]
1872: []
1873: []
1874: []

At a guess this is where the accuracy breaks down enough that it can't find a verifiable solution for n?


Also, while poking at this I did a fairly extensive rewrite which you may find useful. It does pretty much the same as your code but in a much more loosely-coupled fashion.

import sympy as sp

class Equation:
    def __init__(self, label, equality_str, eq="=="):
        self.label = label
        # parse the equality
        lhs, rhs = equality_str.split(eq)
        self.equality = sp.Eq(sp.sympify(lhs), sp.sympify(rhs))
        # index free variables by name
        self.vars = {var.name: var for var in self.equality.free_symbols}

    def prompt_for_values(self):
        # show variables to be entered
        var_names = sorted(self.vars, key=str.lower)
        print("\nFree variables are: " + ", ".join(var_names))
        print("Enter a value for all but one (press Enter to skip):")
        # prompt for values by name
        var_values = {}
        for name in var_names:
            value = input("Value of {}: ".format(name)).strip()
            if value:
                var_values[name] = sp.sympify(value)
        # convert names to Sympy variable references
        return {self.vars[name]:value for name,value in var_values.items()}

    def solve(self):
        values = self.prompt_for_values()
        solutions = sp.solve(self.equality.subs(values))
        # remove complex answers
        solutions = [sol.evalf() for sol in solutions if sol.is_real]
        return solutions

    def __str__(self):
        return str(self.equality)

# Define some equations!
equations = [
    Equation("Time value of money (discrete)",   "FV == PV * (1 + i) ** n"),
    Equation("Time value of money (continuous)", "FV == PV * exp(i * n)"  )
]

# Create menu
menu_lo = 1
menu_hi = len(equations) + 1
menu_prompt = "\n".join(
    [""]
    + ["{}: {}".format(i, eq.label) for i, eq in enumerate(equations, 1)]
    + ["{}: Exit".format(menu_hi)]
    + ["? "]
)

def get_int(prompt, lo=None, hi=None):
    while True:
        try:
            value = int(input(prompt))
            if (lo is None or lo <= value) and (hi is None or value <= hi):
                return value
        except ValueError:
            pass

def main():
    while True:
        choice = get_int(menu_prompt, menu_lo, menu_hi)
        if choice == menu_hi:
            print("Goodbye!")
            break
        else:
            solutions = equations[choice - 1].solve()
            num = len(solutions)
            if num == 0:
                print("No solutions found")
            elif num == 1:
                print("1 solution found: " + str(solutions[0]))
            else:
                print("{} solutions found:".format(num))
                for sol in solutions:
                    print(sol)

if __name__ == "__main__":
    main()
2
  • No, this also happens if you substitute "1.02" with "(102/100)", which stops sympy from using floating point values (verify by looking at the string repr of eq). At that point, it truly is trying to solve the equation symbolically, so it can’t be accuracy I think. Jan 22, 2016 at 17:48
  • Wow very nice code. I've learned a lot of interesting idioms :) I've shyed away from classes in python but it proves useful. I'm playing around with nsolve and hopefully it'll turn out better
    – Billy Won
    Jan 23, 2016 at 5:49

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.