def add_expandable_expression(self, order=2, max_lowest_term=10, factor_order=1, symbols='x', leading_coeff=False, mixed_var=False, len_factor=2): ''' Adds a problem to the given order requiring the expansion of a polynominal. Arguments: order - The order of the resulting polynomial. factor_order - The order of the binominal terms. symbols - a string containing the variables that should be used. leading_coeff - Set to true to have a leading coeff for the binomial terms that is greater than 0. Returns a tuple of expressions. The first expression is still factored, the second expression is expanded. ''' try: for i in range(self.NUM_ATTEMPTS): # Generating expression expr = self.gen.gen_factorable_expression( len_factor=len_factor, factor_order=factor_order, order=order, leading_coeff=leading_coeff, max_lowest_term=max_lowest_term, symbols=symbols, mixed_var=mixed_var) # swap the reduced and unreduced terms temp = expr.unreduced_terms expr.unreduced_terms = expr.reduced_terms expr.reduced_terms = temp # Setting up problem prob = backend.Problem(expr) # Attempting to add it if self.add_problem(prob): return # Problem was a dupe, looping back # All of the problems generated were dupes, there likely aren't many unique # problems for the parameters given raise backend.GeneratorError( 'expandable', 'Unable to generate additional ' + 'unique problems after trying ' + str(self.NUM_ATTEMPTS) + ' times.' + 'Your input parameters may be too restrictive.') except backend.GeneratorError as e: print('GeneratorError: %s' % e.message) except: backend.PrintException()
def add_quadratic(self, max_lowest_term=4, factorable=True, solvable=True, leading_coeff=False, middle_sign='='): ''' Adds a quadratic equation that can be factorable, unfactorable, or unsolvable. Arguments: max_lowest_term - The lowest coefficient that can appear in the problem. factorable - bool determining if the equation should be factorable. solvable - bool determining if the equation should be solvable. leading_coeff - bool determining if a in ax^2 + bx + c should be 1 or not. False means a = 1. middle_sign - Determines if this is an equation or an inequality. Appropriate arguments are '=', '>=', '<=', '<', '>', '!='. Returns an Equation. ''' try: for i in range(self.NUM_ATTEMPTS): # Generating expression eq = self.gen.gen_quadratic(max_lowest_term=max_lowest_term, factorable=factorable, solvable=solvable, leading_coeff=leading_coeff, middle_sign=middle_sign) # Attempting to add it if self.add_problem(backend.Problem(eq)): return # Problem was a dupe, looping back # All of the problems generated were dupes, there likely aren't many unique # problems for the parameters given raise backend.GeneratorError( 'quadratic', 'Unable to generate additional ' + 'unique problems after trying ' + str(self.NUM_ATTEMPTS) + ' times.' + 'Your input parameters may be too restrictive.') except backend.GeneratorError as e: print('GeneratorError: %s' % e.message) except: backend.PrintException()
def add_system(self, num_equations=2, num_lhs_terms=2, num_rhs_terms=1, types='i', symbols='xy', order_lhs=1, order_rhs=0, lhs_coeff=[], rhs_coeff=[], mixed_var=False, max_lowest_term=10, middle_sign='=', max_multiple=1, same_base_root=True): ''' Generates a System of Equations involving denoted variables to the order specified. Arguments: num_equations - Number of Equations in the System. Default 2. num_lhs_terms - Number of terms on the left hand side of the equation. Default 2. num_rhs_terms - Number of terms on the right hand side of the equation. Default 1. types - Types of coefficients. 'i' -> Integers, 'f' -> fractions, 'r' -> square roots. order_lhs - Order of the left hand side expression. Default 1 order_rhs - Order of the right hand side expression. Default 0. lhs_coeff - A list of the coefficients for the lhs. Should be of the same length as the number of terms on the left hand side, and will override any automatic number generation. Default [], allowing automatic number generation. rhs_coeff - A list of the coefficients for the rhs. Should be of the same length as the number of terms on the left hand side, and will override any automatic number generation. Default [], allowing automatic number generation. mixed_var - boolean determining if variables should be mixed or not (xy vs. x^2 + y^2). Default False. max_lowest_term - the maximum coefficient obtained through automatic coefficient generation. Default 10. max_multiple - Maximum multiple to mulitply coefficients by. This will increase the threshold for automatic numbers beyond max_lowest_term. Default 1. same_base_root - Boolean determining if radical expressions should have the same base root so they can reduce to a single term. Default True. symbols - Variables in the equation. E.g. 'xy' will include x and y terms. Default 'x'. ''' try: for i in range(self.NUM_ATTEMPTS): # Generating expression syst = self.gen.gen_system(num_equations=num_equations, num_lhs_terms=num_lhs_terms, num_rhs_terms=num_rhs_terms, types=types, symbols=symbols, order_lhs=order_lhs, order_rhs=order_rhs, lhs_coeff=lhs_coeff, rhs_coeff=rhs_coeff, mixed_var=mixed_var, max_lowest_term=max_lowest_term, middle_sign=middle_sign, max_multiple=max_multiple, same_base_root=same_base_root) # Attempting to add it if self.add_problem(backend.Problem(syst)): return # Problem was a dupe, looping back # All of the problems generated were dupes, likely aren't many unique # problems for the parameters given raise backend.GeneratorError( 'system', 'Unable to generate additional ' + 'unique problems after trying ' + str(self.NUM_ATTEMPTS) + ' times.' + 'Input parameters may be too restrictive.') except backend.GeneratorError as e: print('GeneratorError: %s' % e.message) except: backend.PrintException()
def add_algebraic_expression(self, num_terms=2, types='i', symbols='x', order=1, mixed_var=False, coeff=[], max_lowest_term=10, max_multiple=1, same_base_root=True): ''' Adds a generic algebraic expression (involving denoted variables to the order specified) as a problem (where the goal is to simplify). Arguments: num_terms - the number of terms in the Expression. Default 2. types - The types of coefficients allowed to appear. This is expresssed as a string, containing only the characters 'i' (positive integers), 'r' (square roots), and/or 'f' (fractions). Default 'i'. symbols - A string listing the variables to be used in the expression. Must be single character variables. Default 'x'. order - The order of the expression to be generated. Default 1. mixed_var - Denotes if the expression should mix different variables together (within the bounds of the order) or not. coeff - A list containing coefficients to be used in creating the expression. They should be in order from highest order to lowest order max_lowest_term - the largest number that can appear in the reduced expression. (Of course, larger numbers may appear due to the operations being done.) max_multiple - the maximum multiplier used in the creation of fractions and radicals. same_base_root - bool determining if all radicals in the expression should reduce to the same base root. ''' try: for i in range(self.NUM_ATTEMPTS): # Generating expression expr = self.gen.gen_algebraic_expression( num_terms=num_terms, types=types, symbols=symbols, order=order, mixed_var=mixed_var, coeff=coeff, max_lowest_term=max_lowest_term, max_multiple=max_multiple, same_base_root=same_base_root) # Attempting to add it if self.add_problem(backend.Problem(expr)): return # Problem was a dupe, looping back # All of the problems generated were dupes, there likely aren't many unique # problems for the parameters given raise backend.GeneratorError( 'algebraic', 'Unable to generate additional ' + 'unique problems after trying ' + str(self.NUM_ATTEMPTS) + ' times.' + 'Your input parameters may be too restrictive.') except backend.GeneratorError as e: print('GeneratorError: %s' % e.message) except: backend.PrintException()
def add_numerical_expression(self, num_terms=2, op='+-', types='i', max_lowest_term=10, max_multiple=1, same_base_root=True): ''' Adds an expression involving a chosen quantity of numbers and their solution. * Note : all radicals involved in the expression Arguments: num_terms - the number of terms in the Expression. Default 2. op - a string expressing which operations should be used. String should only contain the characters +, -, *, ^, or /. For example, the string '+/' would indicate the problem should include addition and/or division. Default '+-'. types - The types of numbers that should be allowed to appear. This is expressed as a string, containing only the characters 'i' (positive integers), 'r' (square roots), 'f' (fractions). Default 'i'. max_lowest_term - the largest number that can appear in the reduced expression. (Of course, larger numbers may appear due to the operations being done.) max_multiple - the maximum multiplier used in the creation of fractions and radicals. same_base_root - bool determining if all radicals in the expression should reduce to the same base root. Returns an Expression. ''' try: for i in range(self.NUM_ATTEMPTS): # Generating expression expr = self.gen.gen_numerical_expression( num_terms=num_terms, op=op, types=types, max_lowest_term=max_lowest_term, max_multiple=max_multiple, same_base_root=same_base_root) # Attempting to add it if self.add_problem(backend.Problem(expr)): return # Problem was a dupe, looping back # All of the problems generated were dupes, there likely aren't many unique # problems for the parameters given raise backend.GeneratorError( 'numerical', 'Unable to generate additional ' + 'unique problems after trying ' + str(self.NUM_ATTEMPTS) + ' times.' + 'Your input parameters may be too restrictive.') except backend.GeneratorError as e: print('GeneratorError: %s' % e.message) except: backend.PrintException()