import copy from visma.functions.structure import Function, Expression from visma.functions.exponential import Logarithm from visma.functions.operator import Plus, Minus, Multiply, Divide, Binary ############ # Variable # ############ class Variable(Function): """Class for variable function type Examples: x 2x^2 3xyz^3 Extends: Function """ def __init__(self, coeff=None, value=None, power=None): super().__init__() # Report self.coefficient = 1 if coeff is not None: self.coefficient = coeff self.value = [] if value is not None: self.value.append(value) self.power = [] if power is not None: self.power.append(power) def inverse(self, rToken, wrtVar): l2rVar = Variable() for i, var in enumerate(self.value): if var != wrtVar: l2rVar.value.append(self.value.pop(i)) l2rVar.power.append(self.power.pop(i)) if l2rVar.value != []: rToken = Expression([rToken, Divide(), l2rVar]) rToken.coefficient /= (self.coefficient)**(1/self.power[0]) rToken.power /= self.power[0] self.coefficient = 1 self.power[0] = 1 comment = "Therefore, " + r"$" + wrtVar + r"$" + " can be written as:" return self, rToken, comment def differentiate(self, wrtVar): from visma.functions.constant import Constant, Zero result = copy.deepcopy(self) if wrtVar in result.functionOf(): for i, var in enumerate(result.value): if var == wrtVar: result.coefficient *= result.power[i] result.power[i] -= 1 if(result.power[i] == 0): del result.power[i] del result.value[i] if result.value == []: result.__class__ = Constant result.value = result.coefficient result.coefficient = 1 result.power = 1 else: result = Zero() return result def integrate(self, wrtVar=None): from visma.functions.constant import Constant result = copy.deepcopy(self) log = False for i, var in enumerate(result.value): if var == wrtVar: if(result.power[i] == -1): log = True funcLog = Logarithm() funcLog.operand = Variable() funcLog.operand.coefficient = 1 funcLog.operand.value.append(result.value[i]) funcLog.operand.power.append(1) del result.power[i] del result.value[i] if result.value == []: result.__class__ = Constant result.value = result.coefficient result.coefficient = 1 result.power = 1 result = [result] funcJoin = Binary() funcJoin.value = '*' result.append(funcJoin) result.append(funcLog) else: result.power[i] += 1 result.coefficient /= result.power[i] print(result) return result, log def calculate(self, val): return self.coefficient * ((val**(self.power))) def __radd__(self, other): return self + other def __add__(self, other): from visma.functions.constant import Constant if isinstance(other, Variable): sortedValuesSelf = sorted(self.value) sortedValuesOther = sorted(other.value) if self.coefficient == 0: return Constant(0, 1, 1) if (self.power == other.power) & (sortedValuesSelf == sortedValuesOther): if self.before == '-': self.coefficient -= other.coefficient else: self.coefficient += other.coefficient return self elif isinstance(other, Constant): expression = Expression() expression.tokens = [self] expression.tokens.extend([Plus(), other]) self = expression return expression elif isinstance(other, Expression): expression = Expression() expression.tokens = [self] for i, token in enumerate(other.tokens): if isinstance(token, Variable): tokenValueSorted = sorted(token.value) selfValueSorted = sorted(self.value) if (token.power == self.power) & (tokenValueSorted == selfValueSorted): if other.tokens[i - 1].value == '+' or (i == 0): self.coefficient += other.tokens[i].coefficient elif other.tokens[i - 1].value == '-': self.coefficient -= other.tokens[i].coefficient else: if other.tokens[i-1].value == '+' or i == 0: expression.tokens.extend([Plus(), Variable(token)]) elif other.tokens[i-1].value == '-': expression.tokens.extend([Minus(), Variable(token)]) elif not isinstance(token, Binary): if other.tokens[i - 1].value == '+' or (i == 0): expression.tokens.extend([Plus(), token]) elif other.tokens[i - 1].value == '-': expression.tokens.extend([Minus(), token]) expression.tokens[0] = self self = expression return expression def __rsub__(self, other): from visma.functions.constant import Constant return Constant(0, 1, 1) - self + other def __sub__(self, other): from visma.functions.constant import Constant if isinstance(other, Variable): otherValueSorted = sorted(other.value) selfValueSorted = sorted(self.value) if (other.power == self.power) & (selfValueSorted == otherValueSorted): self = self + Constant(-1, 1, 1) * other return self else: expression = Expression() expression.tokens = [self] expression.tokens.extend([Minus(), other]) self = expression return expression elif isinstance(other, Constant): if other.isZero(): return self expression = Expression() expression.tokens = [self] expression.tokens.extend([Minus(), other]) self = expression return expression elif isinstance(other, Expression): expression = Expression() expression.tokens = [self] for i, token in enumerate(other.tokens): if isinstance(token, Variable): tokenValueSorted = sorted(token.value) selfValueSorted = sorted(self.value) if (token.power == self.power) & (tokenValueSorted == selfValueSorted): if other.tokens[i - 1].value == '+' or (i == 0): self.coefficient -= other.tokens[i].coefficient elif other.tokens[i - 1].value == '-': self.coefficient += other.tokens[i].coefficient else: if other.tokens[i-1].value == '+' or i == 0: expression.tokens.extend([Plus(), Variable(token)]) elif other.tokens[i-1].value == '-': expression.tokens.extend([Minus(), Variable(token)]) elif not isinstance(token, Binary): if other.tokens[i - 1].value == '+' or (i == 0): expression.tokens.extend([Minus(), token]) elif other.tokens[i - 1].value == '-': expression.tokens.extend([Plus(), token]) expression.tokens[0] = self self = expression return expression def __rmul__(self, other): return self * other def __mul__(self, other): from visma.io.checks import isNumber from visma.functions.constant import Constant if isinstance(other, Variable): for j, var in enumerate(other.value): found = False for k, var2 in enumerate(self.value): self.coefficient *= other.coefficient if var == var2: if isNumber(other.power[j]) and isNumber(self.power[k]): self.power[k] += other.power[j] if self.power[k] == 0: del self.power[k] del self.value[k] found = True break if not found: self.value.append(other.value[j]) self.power.append(other.power[j]) if len(self.value) == 0: result = Constant(self.coefficient) result.scope = self.scope result.power = 1 result.value = self.coefficient self = result return self elif isinstance(other, Constant): self.coefficient *= other.calculate() return self elif isinstance(other, Expression): result = Expression() for _, token in enumerate(other.tokens): if isinstance(token, Variable) or isinstance(token, Constant): c = copy.deepcopy(self) result.tokens.extend([c * token]) else: result.tokens.extend([token]) return result def __pow__(self, other): from visma.functions.constant import Constant if isinstance(other, Constant): if other.value == -1: one = Constant(1, 1, 1) result = Variable() result.value = self.value result.coefficient = one.calculate() / self.coefficient result.power = [] for pows in self.power: result.power.append(-pows) return result def __rtruediv__(self, other): pass # TODO : Add code for expression / variable def __truediv__(self, other): from visma.functions.constant import Constant if isinstance(other, Variable) or isinstance(other, Constant): self = self * (other ** Constant(-1, 1, 1)) return self elif isinstance(other, Expression): expression = Expression() self.coefficient /= other.coefficient other.power *= -1 expression.tokens = [self] expression.tokens.extend([Multiply(), other]) self = expression return expression