Python/linear_programming/simplex.py

"""
Python implementation of the simplex algorithm for solving linear programs in
tabular form with
- `>=`, `<=`, and `=` constraints and
- each variable `x1, x2, ...>= 0`.

See https://gist.github.com/imengus/f9619a568f7da5bc74eaf20169a24d98 for how to
convert linear programs to simplex tableaus, and the steps taken in the simplex
algorithm.

Resources:
https://en.wikipedia.org/wiki/Simplex_algorithm
https://tinyurl.com/simplex4beginners
"""
from typing import Any

import numpy as np


class Tableau:
    """Operate on simplex tableaus

    >>> t = Tableau(np.array([[-1,-1,0,0,-1],[1,3,1,0,4],[3,1,0,1,4.]]), 2)
    Traceback (most recent call last):
    ...
    ValueError: RHS must be > 0
    """

    def __init__(self, tableau: np.ndarray, n_vars: int) -> None:
        # Check if RHS is negative
        if np.any(tableau[:, -1], where=tableau[:, -1] < 0):
            raise ValueError("RHS must be > 0")

        self.tableau = tableau
        self.n_rows, _ = tableau.shape

        # Number of decision variables x1, x2, x3...
        self.n_vars = n_vars

        # Number of artificial variables to be minimised
        self.n_art_vars = len(np.where(tableau[self.n_vars : -1] == -1)[0])

        # 2 if there are >= or == constraints (nonstandard), 1 otherwise (std)
        self.n_stages = (self.n_art_vars > 0) + 1

        # Number of slack variables added to make inequalities into equalities
        self.n_slack = self.n_rows - self.n_stages

        # Objectives for each stage
        self.objectives = ["max"]

        # In two stage simplex, first minimise then maximise
        if self.n_art_vars:
            self.objectives.append("min")

        self.col_titles = [""]

        # Index of current pivot row and column
        self.row_idx = None
        self.col_idx = None

        # Does objective row only contain (non)-negative values?
        self.stop_iter = False

    @staticmethod
    def generate_col_titles(*args: int) -> list[str]:
        """Generate column titles for tableau of specific dimensions

        >>> Tableau.generate_col_titles(2, 3, 1)
        ['x1', 'x2', 's1', 's2', 's3', 'a1', 'RHS']

        >>> Tableau.generate_col_titles()
        Traceback (most recent call last):
        ...
        ValueError: Must provide n_vars, n_slack, and n_art_vars
        >>> Tableau.generate_col_titles(-2, 3, 1)
        Traceback (most recent call last):
        ...
        ValueError: All arguments must be non-negative integers
        """
        if len(args) != 3:
            raise ValueError("Must provide n_vars, n_slack, and n_art_vars")

        if not all(x >= 0 and isinstance(x, int) for x in args):
            raise ValueError("All arguments must be non-negative integers")

        # decision | slack | artificial
        string_starts = ["x", "s", "a"]
        titles = []
        for i in range(3):
            for j in range(args[i]):
                titles.append(string_starts[i] + str(j + 1))
        titles.append("RHS")
        return titles

    def find_pivot(self, tableau: np.ndarray) -> tuple[Any, Any]:
        """Finds the pivot row and column.
        >>> t = Tableau(np.array([[-2,1,0,0,0], [3,1,1,0,6], [1,2,0,1,7.]]), 2)
        >>> t.find_pivot(t.tableau)
        (1, 0)
        """
        objective = self.objectives[-1]

        # Find entries of highest magnitude in objective rows
        sign = (objective == "min") - (objective == "max")
        col_idx = np.argmax(sign * tableau[0, : self.n_vars])

        # Choice is only valid if below 0 for maximise, and above for minimise
        if sign * self.tableau[0, col_idx] <= 0:
            self.stop_iter = True
            return 0, 0

        # Pivot row is chosen as having the lowest quotient when elements of
        # the pivot column divide the right-hand side

        # Slice excluding the objective rows
        s = slice(self.n_stages, self.n_rows)

        # RHS
        dividend = tableau[s, -1]

        # Elements of pivot column within slice
        divisor = tableau[s, col_idx]

        # Array filled with nans
        nans = np.full(self.n_rows - self.n_stages, np.nan)

        # If element in pivot column is greater than zeron_stages, return
        # quotient or nan otherwise
        quotients = np.divide(dividend, divisor, out=nans, where=divisor > 0)

        # Arg of minimum quotient excluding the nan values. n_stages is added
        # to compensate for earlier exclusion of objective columns
        row_idx = np.nanargmin(quotients) + self.n_stages
        return row_idx, col_idx

    def pivot(self, tableau: np.ndarray, row_idx: int, col_idx: int) -> np.ndarray:
        """Pivots on value on the intersection of pivot row and column.

        >>> t = Tableau(np.array([[-2,-3,0,0,0],[1,3,1,0,4],[3,1,0,1,4.]]), 2)
        >>> t.pivot(t.tableau, 1, 0).tolist()
        ... # doctest: +NORMALIZE_WHITESPACE
        [[0.0, 3.0, 2.0, 0.0, 8.0],
        [1.0, 3.0, 1.0, 0.0, 4.0],
        [0.0, -8.0, -3.0, 1.0, -8.0]]
        """
        # Avoid changes to original tableau
        piv_row = tableau[row_idx].copy()

        piv_val = piv_row[col_idx]

        # Entry becomes 1
        piv_row *= 1 / piv_val

        # Variable in pivot column becomes basic, ie the only non-zero entry
        for idx, coeff in enumerate(tableau[:, col_idx]):
            tableau[idx] += -coeff * piv_row
        tableau[row_idx] = piv_row
        return tableau

    def change_stage(self, tableau: np.ndarray) -> np.ndarray:
        """Exits first phase of the two-stage method by deleting artificial
        rows and columns, or completes the algorithm if exiting the standard
        case.

        >>> t = Tableau(np.array([
        ... [3, 3, -1, -1, 0, 0, 4],
        ... [2, 1, 0, 0, 0, 0, 0.],
        ... [1, 2, -1, 0, 1, 0, 2],
        ... [2, 1, 0, -1, 0, 1, 2]
        ... ]), 2)
        >>> t.change_stage(t.tableau).tolist()
        ... # doctest: +NORMALIZE_WHITESPACE
        [[2.0, 1.0, 0.0, 0.0, 0.0, 0.0],
        [1.0, 2.0, -1.0, 0.0, 1.0, 2.0],
        [2.0, 1.0, 0.0, -1.0, 0.0, 2.0]]
        """
        # Objective of original objective row remains
        self.objectives.pop()

        if not self.objectives:
            return tableau

        # Slice containing ids for artificial columns
        s = slice(-self.n_art_vars - 1, -1)

        # Delete the artificial variable columns
        tableau = np.delete(tableau, s, axis=1)

        # Delete the objective row of the first stage
        tableau = np.delete(tableau, 0, axis=0)

        self.n_stages = 1
        self.n_rows -= 1
        self.n_art_vars = 0
        self.stop_iter = False
        return tableau

    def run_simplex(self) -> dict[Any, Any]:
        """Operate on tableau until objective function cannot be
        improved further.

        # Standard linear program:
        Max:  x1 +  x2
        ST:   x1 + 3x2 <= 4
             3x1 +  x2 <= 4
        >>> Tableau(np.array([[-1,-1,0,0,0],[1,3,1,0,4],[3,1,0,1,4.]]),
        ... 2).run_simplex()
        {'P': 2.0, 'x1': 1.0, 'x2': 1.0}

        # Optimal tableau input:
        >>> Tableau(np.array([
        ... [0, 0, 0.25, 0.25, 2],
        ... [0, 1, 0.375, -0.125, 1],
        ... [1, 0, -0.125, 0.375, 1]
        ... ]), 2).run_simplex()
        {'P': 2.0, 'x1': 1.0, 'x2': 1.0}

        # Non-standard: >= constraints
        Max: 2x1 + 3x2 +  x3
        ST:   x1 +  x2 +  x3 <= 40
             2x1 +  x2 -  x3 >= 10
                 -  x2 +  x3 >= 10
        >>> Tableau(np.array([
        ... [2, 0, 0, 0, -1, -1, 0, 0, 20],
        ... [-2, -3, -1, 0, 0, 0, 0, 0, 0],
        ... [1, 1, 1, 1, 0, 0, 0, 0, 40],
        ... [2, 1, -1, 0, -1, 0, 1, 0, 10],
        ... [0, -1, 1, 0, 0, -1, 0, 1, 10.]
        ... ]), 3).run_simplex()
        {'P': 70.0, 'x1': 10.0, 'x2': 10.0, 'x3': 20.0}

        # Non standard: minimisation and equalities
        Min: x1 +  x2
        ST: 2x1 +  x2 = 12
            6x1 + 5x2 = 40
        >>> Tableau(np.array([
        ... [8, 6, 0, -1, 0, -1, 0, 0, 52],
        ... [1, 1, 0, 0, 0, 0, 0, 0, 0],
        ... [2, 1, 1, 0, 0, 0, 0, 0, 12],
        ... [2, 1, 0, -1, 0, 0, 1, 0, 12],
        ... [6, 5, 0, 0, 1, 0, 0, 0, 40],
        ... [6, 5, 0, 0, 0, -1, 0, 1, 40.]
        ... ]), 2).run_simplex()
        {'P': 7.0, 'x1': 5.0, 'x2': 2.0}
        """
        # Stop simplex algorithm from cycling.
        for _ in range(100):
            # Completion of each stage removes an objective. If both stages
            # are complete, then no objectives are left
            if not self.objectives:
                self.col_titles = self.generate_col_titles(
                    self.n_vars, self.n_slack, self.n_art_vars
                )

                # Find the values of each variable at optimal solution
                return self.interpret_tableau(self.tableau, self.col_titles)

            row_idx, col_idx = self.find_pivot(self.tableau)

            # If there are no more negative values in objective row
            if self.stop_iter:
                # Delete artificial variable columns and rows. Update attributes
                self.tableau = self.change_stage(self.tableau)
            else:
                self.tableau = self.pivot(self.tableau, row_idx, col_idx)
        return {}

    def interpret_tableau(
        self, tableau: np.ndarray, col_titles: list[str]
    ) -> dict[str, float]:
        """Given the final tableau, add the corresponding values of the basic
        decision variables to the `output_dict`
        >>> tableau = np.array([
        ... [0,0,0.875,0.375,5],
        ... [0,1,0.375,-0.125,1],
        ... [1,0,-0.125,0.375,1]
        ... ])
        >>> t = Tableau(tableau, 2)
        >>> t.interpret_tableau(tableau, ["x1", "x2", "s1", "s2", "RHS"])
        {'P': 5.0, 'x1': 1.0, 'x2': 1.0}
        """
        # P = RHS of final tableau
        output_dict = {"P": abs(tableau[0, -1])}

        for i in range(self.n_vars):
            # Gives ids of nonzero entries in the ith column
            nonzero = np.nonzero(tableau[:, i])
            n_nonzero = len(nonzero[0])

            # First entry in the nonzero ids
            nonzero_rowidx = nonzero[0][0]
            nonzero_val = tableau[nonzero_rowidx, i]

            # If there is only one nonzero value in column, which is one
            if n_nonzero == nonzero_val == 1:
                rhs_val = tableau[nonzero_rowidx, -1]
                output_dict[col_titles[i]] = rhs_val

        # Check for basic variables
        for title in col_titles:
            # Don't add RHS or slack variables to output dict
            if title[0] not in "R-s-a":
                output_dict.setdefault(title, 0)
        return output_dict


if __name__ == "__main__":
    import doctest

    doctest.testmod()
Simplex algorithm (#8825) * feat: added simplex.py * added docstrings * Update linear_programming/simplex.py Co-authored-by: Caeden Perelli-Harris <caedenperelliharris@gmail.com> * Update linear_programming/simplex.py Co-authored-by: Caeden Perelli-Harris <caedenperelliharris@gmail.com> * [pre-commit.ci] auto fixes from pre-commit.com hooks for more information, see https://pre-commit.ci * Update linear_programming/simplex.py Co-authored-by: Caeden Perelli-Harris <caedenperelliharris@gmail.com> * [pre-commit.ci] auto fixes from pre-commit.com hooks for more information, see https://pre-commit.ci * ruff fix Co-authored by: CaedenPH <caedenperelliharris@gmail.com> * removed README to add in separate PR * Update linear_programming/simplex.py Co-authored-by: Tianyi Zheng <tianyizheng02@gmail.com> * Update linear_programming/simplex.py Co-authored-by: Tianyi Zheng <tianyizheng02@gmail.com> * fix class docstring * add comments --------- Co-authored-by: Caeden Perelli-Harris <caedenperelliharris@gmail.com> Co-authored-by: pre-commit-ci[bot] <66853113+pre-commit-ci[bot]@users.noreply.github.com> Co-authored-by: Tianyi Zheng <tianyizheng02@gmail.com> 2023-06-18 16:00:02 +00:00			`"""`
			`Python implementation of the simplex algorithm for solving linear programs in`
			`tabular form with`
			- `>=`, `<=`, and `=` constraints and
			- each variable `x1, x2, ...>= 0`.

			`See https://gist.github.com/imengus/f9619a568f7da5bc74eaf20169a24d98 for how to`
			`convert linear programs to simplex tableaus, and the steps taken in the simplex`
			`algorithm.`

			`Resources:`
			`https://en.wikipedia.org/wiki/Simplex_algorithm`
			`https://tinyurl.com/simplex4beginners`
			`"""`
			`from typing import Any`

			`import numpy as np`


			`class Tableau:`
			`"""Operate on simplex tableaus`

			`>>> t = Tableau(np.array([[-1,-1,0,0,-1],[1,3,1,0,4],[3,1,0,1,4.]]), 2)`
			`Traceback (most recent call last):`
			`...`
			`ValueError: RHS must be > 0`
			`"""`

			`def __init__(self, tableau: np.ndarray, n_vars: int) -> None:`
			`# Check if RHS is negative`
			`if np.any(tableau[:, -1], where=tableau[:, -1] < 0):`
			`raise ValueError("RHS must be > 0")`

			`self.tableau = tableau`
			`self.n_rows, _ = tableau.shape`

			`# Number of decision variables x1, x2, x3...`
			`self.n_vars = n_vars`

			`# Number of artificial variables to be minimised`
			`self.n_art_vars = len(np.where(tableau[self.n_vars : -1] == -1)[0])`

			`# 2 if there are >= or == constraints (nonstandard), 1 otherwise (std)`
			`self.n_stages = (self.n_art_vars > 0) + 1`

			`# Number of slack variables added to make inequalities into equalities`
			`self.n_slack = self.n_rows - self.n_stages`

			`# Objectives for each stage`
			`self.objectives = ["max"]`

			`# In two stage simplex, first minimise then maximise`
			`if self.n_art_vars:`
			`self.objectives.append("min")`

			`self.col_titles = [""]`

			`# Index of current pivot row and column`
			`self.row_idx = None`
			`self.col_idx = None`

			`# Does objective row only contain (non)-negative values?`
			`self.stop_iter = False`

			`@staticmethod`
			`def generate_col_titles(*args: int) -> list[str]:`
			`"""Generate column titles for tableau of specific dimensions`

			`>>> Tableau.generate_col_titles(2, 3, 1)`
			`['x1', 'x2', 's1', 's2', 's3', 'a1', 'RHS']`

			`>>> Tableau.generate_col_titles()`
			`Traceback (most recent call last):`
			`...`
			`ValueError: Must provide n_vars, n_slack, and n_art_vars`
			`>>> Tableau.generate_col_titles(-2, 3, 1)`
			`Traceback (most recent call last):`
			`...`
			`ValueError: All arguments must be non-negative integers`
			`"""`
			`if len(args) != 3:`
			`raise ValueError("Must provide n_vars, n_slack, and n_art_vars")`

			`if not all(x >= 0 and isinstance(x, int) for x in args):`
			`raise ValueError("All arguments must be non-negative integers")`

			`# decision \| slack \| artificial`
			`string_starts = ["x", "s", "a"]`
			`titles = []`
			`for i in range(3):`
			`for j in range(args[i]):`
			`titles.append(string_starts[i] + str(j + 1))`
			`titles.append("RHS")`
			`return titles`

			`def find_pivot(self, tableau: np.ndarray) -> tuple[Any, Any]:`
			`"""Finds the pivot row and column.`
			`>>> t = Tableau(np.array([[-2,1,0,0,0], [3,1,1,0,6], [1,2,0,1,7.]]), 2)`
			`>>> t.find_pivot(t.tableau)`
			`(1, 0)`
			`"""`
			`objective = self.objectives[-1]`

			`# Find entries of highest magnitude in objective rows`
			`sign = (objective == "min") - (objective == "max")`
			`col_idx = np.argmax(sign * tableau[0, : self.n_vars])`

			`# Choice is only valid if below 0 for maximise, and above for minimise`
			`if sign * self.tableau[0, col_idx] <= 0:`
			`self.stop_iter = True`
			`return 0, 0`

			`# Pivot row is chosen as having the lowest quotient when elements of`
			`# the pivot column divide the right-hand side`

			`# Slice excluding the objective rows`
			`s = slice(self.n_stages, self.n_rows)`

			`# RHS`
			`dividend = tableau[s, -1]`

			`# Elements of pivot column within slice`
			`divisor = tableau[s, col_idx]`

			`# Array filled with nans`
			`nans = np.full(self.n_rows - self.n_stages, np.nan)`

			`# If element in pivot column is greater than zeron_stages, return`
			`# quotient or nan otherwise`
			`quotients = np.divide(dividend, divisor, out=nans, where=divisor > 0)`

			`# Arg of minimum quotient excluding the nan values. n_stages is added`
			`# to compensate for earlier exclusion of objective columns`
			`row_idx = np.nanargmin(quotients) + self.n_stages`
			`return row_idx, col_idx`

			`def pivot(self, tableau: np.ndarray, row_idx: int, col_idx: int) -> np.ndarray:`
			`"""Pivots on value on the intersection of pivot row and column.`

			`>>> t = Tableau(np.array([[-2,-3,0,0,0],[1,3,1,0,4],[3,1,0,1,4.]]), 2)`
			`>>> t.pivot(t.tableau, 1, 0).tolist()`
			`... # doctest: +NORMALIZE_WHITESPACE`
			`[[0.0, 3.0, 2.0, 0.0, 8.0],`
			`[1.0, 3.0, 1.0, 0.0, 4.0],`
			`[0.0, -8.0, -3.0, 1.0, -8.0]]`
			`"""`
			`# Avoid changes to original tableau`
			`piv_row = tableau[row_idx].copy()`

			`piv_val = piv_row[col_idx]`

			`# Entry becomes 1`
			`piv_row *= 1 / piv_val`

			`# Variable in pivot column becomes basic, ie the only non-zero entry`
			`for idx, coeff in enumerate(tableau[:, col_idx]):`
			`tableau[idx] += -coeff * piv_row`
			`tableau[row_idx] = piv_row`
			`return tableau`

			`def change_stage(self, tableau: np.ndarray) -> np.ndarray:`
			`"""Exits first phase of the two-stage method by deleting artificial`
			`rows and columns, or completes the algorithm if exiting the standard`
			`case.`

			`>>> t = Tableau(np.array([`
			`... [3, 3, -1, -1, 0, 0, 4],`
			`... [2, 1, 0, 0, 0, 0, 0.],`
			`... [1, 2, -1, 0, 1, 0, 2],`
			`... [2, 1, 0, -1, 0, 1, 2]`
			`... ]), 2)`
			`>>> t.change_stage(t.tableau).tolist()`
			`... # doctest: +NORMALIZE_WHITESPACE`
			`[[2.0, 1.0, 0.0, 0.0, 0.0, 0.0],`
			`[1.0, 2.0, -1.0, 0.0, 1.0, 2.0],`
			`[2.0, 1.0, 0.0, -1.0, 0.0, 2.0]]`
			`"""`
			`# Objective of original objective row remains`
			`self.objectives.pop()`

			`if not self.objectives:`
			`return tableau`

			`# Slice containing ids for artificial columns`
			`s = slice(-self.n_art_vars - 1, -1)`

			`# Delete the artificial variable columns`
			`tableau = np.delete(tableau, s, axis=1)`

			`# Delete the objective row of the first stage`
			`tableau = np.delete(tableau, 0, axis=0)`

			`self.n_stages = 1`
			`self.n_rows -= 1`
			`self.n_art_vars = 0`
			`self.stop_iter = False`
			`return tableau`

			`def run_simplex(self) -> dict[Any, Any]:`
			`"""Operate on tableau until objective function cannot be`
			`improved further.`

			`# Standard linear program:`
			`Max: x1 + x2`
			`ST: x1 + 3x2 <= 4`
			`3x1 + x2 <= 4`
			`>>> Tableau(np.array([[-1,-1,0,0,0],[1,3,1,0,4],[3,1,0,1,4.]]),`
			`... 2).run_simplex()`
			`{'P': 2.0, 'x1': 1.0, 'x2': 1.0}`

			`# Optimal tableau input:`
			`>>> Tableau(np.array([`
			`... [0, 0, 0.25, 0.25, 2],`
			`... [0, 1, 0.375, -0.125, 1],`
			`... [1, 0, -0.125, 0.375, 1]`
			`... ]), 2).run_simplex()`
			`{'P': 2.0, 'x1': 1.0, 'x2': 1.0}`

			`# Non-standard: >= constraints`
			`Max: 2x1 + 3x2 + x3`
			`ST: x1 + x2 + x3 <= 40`
			`2x1 + x2 - x3 >= 10`
			`- x2 + x3 >= 10`
			`>>> Tableau(np.array([`
			`... [2, 0, 0, 0, -1, -1, 0, 0, 20],`
			`... [-2, -3, -1, 0, 0, 0, 0, 0, 0],`
			`... [1, 1, 1, 1, 0, 0, 0, 0, 40],`
			`... [2, 1, -1, 0, -1, 0, 1, 0, 10],`
			`... [0, -1, 1, 0, 0, -1, 0, 1, 10.]`
			`... ]), 3).run_simplex()`
			`{'P': 70.0, 'x1': 10.0, 'x2': 10.0, 'x3': 20.0}`

			`# Non standard: minimisation and equalities`
			`Min: x1 + x2`
			`ST: 2x1 + x2 = 12`
			`6x1 + 5x2 = 40`
			`>>> Tableau(np.array([`
			`... [8, 6, 0, -1, 0, -1, 0, 0, 52],`
			`... [1, 1, 0, 0, 0, 0, 0, 0, 0],`
			`... [2, 1, 1, 0, 0, 0, 0, 0, 12],`
			`... [2, 1, 0, -1, 0, 0, 1, 0, 12],`
			`... [6, 5, 0, 0, 1, 0, 0, 0, 40],`
			`... [6, 5, 0, 0, 0, -1, 0, 1, 40.]`
			`... ]), 2).run_simplex()`
			`{'P': 7.0, 'x1': 5.0, 'x2': 2.0}`
			`"""`
			`# Stop simplex algorithm from cycling.`
			`for _ in range(100):`
			`# Completion of each stage removes an objective. If both stages`
			`# are complete, then no objectives are left`
			`if not self.objectives:`
			`self.col_titles = self.generate_col_titles(`
			`self.n_vars, self.n_slack, self.n_art_vars`
			`)`

			`# Find the values of each variable at optimal solution`
			`return self.interpret_tableau(self.tableau, self.col_titles)`

			`row_idx, col_idx = self.find_pivot(self.tableau)`

			`# If there are no more negative values in objective row`
			`if self.stop_iter:`
			`# Delete artificial variable columns and rows. Update attributes`
			`self.tableau = self.change_stage(self.tableau)`
			`else:`
			`self.tableau = self.pivot(self.tableau, row_idx, col_idx)`
			`return {}`

			`def interpret_tableau(`
			`self, tableau: np.ndarray, col_titles: list[str]`
			`) -> dict[str, float]:`
			`"""Given the final tableau, add the corresponding values of the basic`
			decision variables to the `output_dict`
			`>>> tableau = np.array([`
			`... [0,0,0.875,0.375,5],`
			`... [0,1,0.375,-0.125,1],`
			`... [1,0,-0.125,0.375,1]`
			`... ])`
			`>>> t = Tableau(tableau, 2)`
			`>>> t.interpret_tableau(tableau, ["x1", "x2", "s1", "s2", "RHS"])`
			`{'P': 5.0, 'x1': 1.0, 'x2': 1.0}`
			`"""`
			`# P = RHS of final tableau`
			`output_dict = {"P": abs(tableau[0, -1])}`

			`for i in range(self.n_vars):`
			`# Gives ids of nonzero entries in the ith column`
			`nonzero = np.nonzero(tableau[:, i])`
			`n_nonzero = len(nonzero[0])`

			`# First entry in the nonzero ids`
			`nonzero_rowidx = nonzero[0][0]`
			`nonzero_val = tableau[nonzero_rowidx, i]`

			`# If there is only one nonzero value in column, which is one`
			`if n_nonzero == nonzero_val == 1:`
			`rhs_val = tableau[nonzero_rowidx, -1]`
			`output_dict[col_titles[i]] = rhs_val`

			`# Check for basic variables`
			`for title in col_titles:`
			`# Don't add RHS or slack variables to output dict`
			`if title[0] not in "R-s-a":`
			`output_dict.setdefault(title, 0)`
			`return output_dict`


			`if __name__ == "__main__":`
			`import doctest`

			`doctest.testmod()`