def calluser(): availableOperations = [] tokenString = '' equationTokens = [] if varName == 'back': self.input = str(self.textedit.toPlainText()) self.tokens = tokenizer(self.input) # print(self.tokens) lhs, rhs = getLHSandRHS(self.tokens) operations, self.solutionType = checkTypes(lhs, rhs) self.refreshButtons(operations) else: if operation == 'solve': self.lTokens, self.rTokens, availableOperations, tokenString, equationTokens, comments = solveFor( self.lTokens, self.rTokens, varName) elif operation == 'integrate': self.lTokens, availableOperations, tokenString, equationTokens, comments = integrate( self.lTokens, varName) elif operation == 'differentiate': self.lTokens, availableOperations, tokenString, equationTokens, comments = differentiate( self.lTokens, varName) self.eqToks = equationTokens self.output = resultLatex(operation, equationTokens, comments, varName) if len(availableOperations) == 0: self.clearButtons() else: self.refreshButtons(availableOperations) if self.mode == 'normal': self.textedit.setText(tokenString) elif self.mode == 'interaction': cursor = self.textedit.textCursor() cursor.insertText(tokenString) if self.showStepByStep is True: showSteps(self) if self.showPlotter is True: plot(self)
def calluser(): availableOperations = [] tokenString = '' equationTokens = [] self.resultOut = True if name == 'addition': if self.solutionType == 'expression': self.tokens, availableOperations, tokenString, equationTokens, comments = addition( self.tokens, True) else: self.lTokens, self.rTokens, availableOperations, tokenString, equationTokens, comments = additionEquation( self.lTokens, self.rTokens, True) elif name == 'subtraction': if self.solutionType == 'expression': self.tokens, availableOperations, tokenString, equationTokens, comments = subtraction( self.tokens, True) else: self.lTokens, self.rTokens, availableOperations, tokenString, equationTokens, comments = subtractionEquation( self.lTokens, self.rTokens, True) elif name == 'multiplication': if self.solutionType == 'expression': self.tokens, availableOperations, tokenString, equationTokens, comments = multiplication( self.tokens, True) else: self.lTokens, self.rTokens, availableOperations, tokenString, equationTokens, comments = multiplicationEquation( self.lTokens, self.rTokens, True) elif name == 'division': if self.solutionType == 'expression': self.tokens, availableOperations, tokenString, equationTokens, comments = division( self.tokens, True) else: self.lTokens, self.rTokens, availableOperations, tokenString, equationTokens, comments = divisionEquation( self.lTokens, self.rTokens, True) elif name == 'simplify': if self.solutionType == 'expression': self.tokens, availableOperations, tokenString, equationTokens, comments = simplify( self.tokens) else: self.lTokens, self.rTokens, availableOperations, tokenString, equationTokens, comments = simplifyEquation( self.lTokens, self.rTokens) elif name == 'factorize': self.tokens, availableOperations, tokenString, equationTokens, comments = factorize( self.tokens) elif name == 'find roots': self.lTokens, self.rTokens, availableOperations, tokenString, equationTokens, comments = quadraticRoots( self.lTokens, self.rTokens) elif name == 'solve': lhs, rhs = getLHSandRHS(self.tokens) variables = getVariables(lhs, rhs) self.wrtVariableButtons(variables, name) self.resultOut = False elif name == 'integrate': lhs, rhs = getLHSandRHS(self.tokens) variables = getVariables(lhs, rhs) self.wrtVariableButtons(variables, name) self.resultOut = False elif name == 'differentiate': lhs, rhs = getLHSandRHS(self.tokens) variables = getVariables(lhs, rhs) self.wrtVariableButtons(variables, name) self.resultOut = False if self.resultOut: self.eqToks = equationTokens self.output = resultLatex(name, equationTokens, comments) if len(availableOperations) == 0: self.clearButtons() else: self.refreshButtons(availableOperations) if self.mode == 'normal': self.textedit.setText(tokenString) elif self.mode == 'interaction': cursor = self.textedit.textCursor() cursor.insertText(tokenString) if self.showStepByStep is True: showSteps(self) if self.showPlotter is True: plot(self)
def calluser(): availableOperations = [] tokenString = '' equationTokens = [] self.input = str(self.textedit.toPlainText()) if varName == 'back': if self.input[0:4] == 'mat_': self.input = self.input[4:] self.input = self.input[0:-1] self.input = self.input[1:] if ';' in self.input: self.simul = True if (self.input.count(';') == 2): afterSplit = self.input.split(';') eqStr1 = afterSplit[0] eqStr2 = afterSplit[1] eqStr3 = afterSplit[2] elif (self.input.count(';') == 1): afterSplit = self.input.split(';') eqStr1 = afterSplit[0] eqStr2 = afterSplit[1] eqStr3 = '' if self.simul: self.tokens = [tokenizer(eqStr1), tokenizer(eqStr2), tokenizer(eqStr3)] else: self.tokens = tokenizer(self.input) # DBP: print(self.tokens) self.addEquation() lhs, rhs = getLHSandRHS(self.tokens) self.lTokens = lhs self.rTokens = rhs operations, self.solutionType = checkTypes(lhs, rhs) self.refreshButtons(operations) else: if operation == 'solve': if not self.simul: self.lTokens, self.rTokens, availableOperations, tokenString, equationTokens, comments = solveFor(self.lTokens, self.rTokens, varName) else: tokenString, equationTokens, comments = simulSolver(self.tokens[0], self.tokens[1], self.tokens[2], varName) elif operation == 'integrate': self.lTokens, availableOperations, tokenString, equationTokens, comments = integrate(self.lTokens, varName) elif operation == 'differentiate': self.lTokens, availableOperations, tokenString, equationTokens, comments = differentiate(self.lTokens, varName) self.eqToks = equationTokens renderQuickSol(self, tokenString, self.showQSolver) self.output = resultLatex(equationTokens, operation, comments, self.solutionType, self.simul, varName) if len(availableOperations) == 0: self.clearButtons() else: self.refreshButtons(availableOperations) if self.mode == 'normal': self.textedit.setText(tokenString) elif self.mode == 'interaction': cursor = self.textedit.textCursor() cursor.insertText(tokenString) if self.showStepByStep is True: showSteps(self) if self.showPlotter is True: plot(self)
def calluser(): availableOperations = [] tokenString = '' equationTokens = [] self.resultOut = True if not self.matrix: """ This part handles the cases when VisMa is NOT dealing with matrices. Boolean flags used in code below: simul -- {True} when VisMa is dealing with simultaneous equations & {False} in all other cases """ if name == 'addition': if self.solutionType == 'expression': self.tokens, availableOperations, tokenString, equationTokens, comments = addition( self.tokens, True) else: self.lTokens, self.rTokens, availableOperations, tokenString, equationTokens, comments = additionEquation( self.lTokens, self.rTokens, True) elif name == 'subtraction': if self.solutionType == 'expression': self.tokens, availableOperations, tokenString, equationTokens, comments = subtraction( self.tokens, True) else: self.lTokens, self.rTokens, availableOperations, tokenString, equationTokens, comments = subtractionEquation( self.lTokens, self.rTokens, True) elif name == 'multiplication': if self.solutionType == 'expression': self.tokens, availableOperations, tokenString, equationTokens, comments = multiplication( self.tokens, True) else: self.lTokens, self.rTokens, availableOperations, tokenString, equationTokens, comments = multiplicationEquation( self.lTokens, self.rTokens, True) elif name == 'division': if self.solutionType == 'expression': self.tokens, availableOperations, tokenString, equationTokens, comments = division( self.tokens, True) else: self.lTokens, self.rTokens, availableOperations, tokenString, equationTokens, comments = divisionEquation( self.lTokens, self.rTokens, True) elif name == 'simplify': if self.solutionType == 'expression': self.tokens, availableOperations, tokenString, equationTokens, comments = simplify(self.tokens) else: self.lTokens, self.rTokens, availableOperations, tokenString, equationTokens, comments = simplifyEquation(self.lTokens, self.rTokens) elif name == 'factorize': self.tokens, availableOperations, tokenString, equationTokens, comments = factorize(self.tokens) elif name == 'find roots': self.lTokens, self.rTokens, availableOperations, tokenString, equationTokens, comments = rootFinder(self.lTokens, self.rTokens) elif name == 'solve': if not self.simul: lhs, rhs = getLHSandRHS(self.tokens) variables = getVariables(lhs, rhs) else: variables = getVariableSim(self.tokens) self.wrtVariableButtons(variables, name) self.resultOut = False elif name == 'factorial': self.tokens, availableOperations, tokenString, equationTokens, comments = factorial(self.tokens) elif name == 'combination': nTokens = self.tokens[0] rTokens = self.tokens[1] self.tokens, _, _, equationTokens, comments = combination(nTokens, rTokens) elif name == 'permutation': nTokens = self.tokens[0] rTokens = self.tokens[1] self.tokens, _, _, equationTokens, comments = permutation(nTokens, rTokens) elif name == 'integrate': lhs, rhs = getLHSandRHS(self.tokens) variables = getVariables(lhs, rhs) self.wrtVariableButtons(variables, name) self.resultOut = False elif name == 'differentiate': lhs, rhs = getLHSandRHS(self.tokens) variables = getVariables(lhs, rhs) self.wrtVariableButtons(variables, name) self.resultOut = False else: """ This part handles the cases when VisMa is dealing with matrices. Boolean flags used in code below: dualOperand -- {True} when the matrix operations require two operands (used in operations like addition, subtraction etc) nonMatrixResult -- {True} when the result after performing operations on the Matrix is not a Matrix (in operations like Determinant, Trace etc.) scalarOperations -- {True} when one of the operand in a scalar (used in operations like Scalar Addition, Scalar Subtraction etc.) """ # TODO: use latex tools like /amsmath for displaying matrices if self.dualOperandMatrix: Matrix1_copy = copy.deepcopy(self.Matrix1) Matrix2_copy = copy.deepcopy(self.Matrix2) else: Matrix0_copy = copy.deepcopy(self.Matrix0) if name == 'Addition': MatrixResult = addMatrix(self.Matrix1, self.Matrix2) elif name == 'Subtraction': MatrixResult = subMatrix(self.Matrix1, self.Matrix2) elif name == 'Multiply': MatrixResult = multiplyMatrix(self.Matrix1, self.Matrix2) elif name == 'Simplify': MatrixResult = simplifyMatrix(self.Matrix0) elif name == 'Trace': sqMatrix = SquareMat() sqMatrix.value = self.Matrix0.value result = sqMatrix.traceMat() elif name == 'Determinant': sqMatrix = SquareMat() sqMatrix.value = self.Matrix0.value result = sqMatrix.determinant() elif name == 'Inverse': sqMatrix = SquareMat() sqMatrix.value = self.Matrix0.value MatrixResult = SquareMat() MatrixResult = sqMatrix.inverse() if name in ['Addition', 'Subtraction', 'Multiply']: self.dualOperandMatrix = True else: self.dualOperandMatrix = False if name in ['Determinant', 'Trace']: self.nonMatrixResult = True else: self.nonMatrixResult = False if self.resultOut: if not self.matrix: self.eqToks = equationTokens self.output = resultLatex(equationTokens, name, comments, self.solutionType) if (mathError(self.eqToks[-1])): self.output += 'Math Error: LHS not equal to RHS' + '\n' if len(availableOperations) == 0: self.clearButtons() else: self.refreshButtons(availableOperations) if self.mode == 'normal': self.textedit.setText(tokenString) elif self.mode == 'interaction': cursor = self.textedit.textCursor() cursor.insertText(tokenString) if self.showStepByStep is True: showSteps(self) if self.showPlotter is True: plot(self) else: if self.dualOperandMatrix: if not self.scalarOperationsMatrix: self.output = resultMatrixStringLatex(operation=name, operand1=Matrix1_copy, operand2=Matrix2_copy, result=MatrixResult) else: # TODO: Implement Scalar Matrices operations. pass # finalCLIstring = resultMatrix_Latex(operation=name, operand1=scalarTokens_copy, operand2=Matrix2_copy, result=MatrixResult) else: if self.nonMatrixResult: self.output = resultMatrixStringLatex(operation=name, operand1=Matrix0_copy, nonMatrixResult=True, result=result) else: self.output = resultMatrixStringLatex(operation=name, operand1=Matrix0_copy, result=MatrixResult) if self.mode == 'normal': self.textedit.setText(tokenString) elif self.mode == 'interaction': cursor = self.textedit.textCursor() cursor.insertText(tokenString) if self.showStepByStep is True: showSteps(self)