def equationAnimationBuilder(lTokens, rTokens):
"""Given LHS & RHS tokens for an equation it builds the tokens of complete equation
Arguments:
lTokens {list} -- Tokens of LHS
rTokens {list} -- Tokens of RHS
Returns:
animBulder {list} -- list of tokens of complete equation
"""
animBuilder = []
lToks = copy.deepcopy(lTokens)
rToks = copy.deepcopy(rTokens)
animBuilder = lToks
lenToks = len(lToks)
equalTo = Binary()
equalTo.scope = [lenToks]
equalTo.value = '='
animBuilder.append(equalTo)
if len(rToks) == 0:
zero = Zero()
zero.scope = [lenToks + 1]
animBuilder.append(zero)
else:
animBuilder.extend(rToks)
return animBuilder
def differentiateTokens(funclist, wrtVar):
"""Differentiates given tokens wrt given variable
Arguments:
funclist {list} -- list of function tokens
wrtVar {string} -- with respect to variable
Returns:
diffFunc {list} -- list of differentiated tokens
animNew {list} -- equation tokens for step-by-step
commentsNew {list} -- comments for step-by-step
"""
diffFunc = []
animNew = []
commentsNew = ["Differentiating with respect to " + r"$" + wrtVar + r"$" + "\n"]
for func in funclist:
if isinstance(func, Operator):
diffFunc.append(func)
else:
newfunc = []
while(isinstance(func, Function)):
commentsNew[0] += r"$" + "\\frac{d}{d" + wrtVar + "} ( " + func.__str__() + ")" + r"$"
funcCopy = copy.deepcopy(func)
if wrtVar in funcCopy.functionOf():
if not isinstance(funcCopy, Constant):
for i, var in enumerate(funcCopy.value):
if var == wrtVar:
funcCopy.coefficient *= funcCopy.power[i]
funcCopy.power[i] -= 1
if(funcCopy.power[i] == 0):
del funcCopy.power[i]
del funcCopy.value[i]
if funcCopy.value == []:
funcCopy.__class__ = Constant
funcCopy.value = funcCopy.coefficient
funcCopy.coefficient = 1
funcCopy.power = 1
commentsNew[0] += r"$" + r"= " + funcCopy.__str__() + r"\ ;\ " + r"$"
newfunc.append(funcCopy)
func.differentiate()
if not(isinstance(func, Constant) and func.value == 1):
newfunc.append(func)
else:
funcCopy = (Zero())
newfunc.append(funcCopy)
commentsNew[0] += r"$" + r"= " + funcCopy.__str__() + r"\ ;\ " + r"$"
if func.operand is None:
break
else:
func = func.operand
if isinstance(func, Constant):
diffFunc = Zero()
break
diffFunc.extend(newfunc)
animNew.extend(diffFunc)
return diffFunc, animNew, commentsNew
def differentiateTokens(funclist, wrtVar):
"""Differentiates given tokens wrt given variable
Arguments:
funclist {list} -- list of function tokens
wrtVar {string} -- with respect to variable
Returns:
diffFunc {list} -- list of differentiated tokens
animNew {list} -- equation tokens for step-by-step
commentsNew {list} -- comments for step-by-step
"""
diffFunc = []
animNew = []
commentsNew = ["Differentiating with respect to " + r"$" + wrtVar + r"$" + "\n"]
for func in funclist:
if isinstance(func, Operator):
diffFunc.append(func)
else:
newExpression = Expression()
newfunc = []
while(isinstance(func, Function)):
commentsNew[0] += r"$" + "\\frac{d}{d" + wrtVar + "} ( " + func.__str__() + ")" + r"$"
funcCopy = copy.deepcopy(func)
if wrtVar in funcCopy.functionOf():
if isinstance(funcCopy, Trigonometric) or isinstance(funcCopy, Logarithm) or isinstance(funcCopy, Variable) or isinstance(funcCopy, Exponential):
funcCopy = funcCopy.differentiate(wrtVar)
newfunc.append(funcCopy)
commentsNew[0] += r"$" + r"= " + funcCopy.__str__() + r"\ ;\ " + r"$"
else:
funcCopy = Zero()
newfunc.append(funcCopy)
commentsNew[0] += r"$" + r"= " + funcCopy.__str__() + r"\ ;\ " + r"$"
newfunc.append(Multiply())
if func.operand is None:
break
else:
func = func.operand
if isinstance(func, Constant):
diffFunc = Zero()
break
newfunc.pop()
newExpression.tokens = newfunc
diffFunc.extend([newExpression])
animNew.extend(diffFunc)
return diffFunc, animNew, commentsNew
def determinant(self, mat=None):
"""Calculates square matrices' determinant
Returns:
list of tokens forming the determinant
"""
from visma.simplify.simplify import simplify
if mat is None:
self.dimension()
mat = np.array(self.value)
if (mat.shape[0] > 2):
ans = []
for i in range(mat.shape[0]):
mat1 = SquareMat()
mat1.value = np.concatenate((mat[1:, :i], mat[1:, i + 1:]),
axis=1).tolist()
a, _, _, _, _ = simplify(mat1.determinant())
if (a[0].value != 0 and a != []):
a, _, _, _, _ = simplify(a + [Multiply()] +
mat[0][i].tolist())
if (i % 2 == 0):
if (ans != []):
ans, _, _, _, _ = simplify(ans + [Plus()] + a)
else:
ans = a
else:
ans, _, _, _, _ = simplify(ans + [Minus()] + a)
elif (mat.shape[0] == 2):
a = Multiply()
b = Minus()
mat = mat.tolist()
a1, _, _, _, _ = simplify(mat[0][0] + [a] + mat[1][1])
a2, _, _, _, _ = simplify(mat[0][1] + [a] + mat[1][0])
ans, _, _, _, _ = simplify([a1[0], b, a2[0]])
if (isinstance(ans[0], Minus) or isinstance(
ans[0], Plus)) and ans[0].value not in ['+', '-']:
ans[0] = Constant(ans[0].value)
else:
ans, _, _, _, _ = simplify(mat[0][0])
if not ans:
ans = Zero()
return ans
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 divisionEquation(lToks, rToks, direct=False):
lTokens = copy.deepcopy(lToks)
rTokens = copy.deepcopy(rToks)
animation = []
comments = []
if direct:
comments = [[]]
animBuilder = lToks
lenToks = len(lToks)
equalTo = Binary()
equalTo.scope = [lenToks]
equalTo.value = '='
animBuilder.append(equalTo)
if len(rToks) == 0:
zero = Zero()
zero.scope = [lenToks + 1]
animBuilder.append(zero)
else:
animBuilder.extend(rToks)
animation.append(copy.deepcopy(animBuilder))
lVariables = []
lVariables.extend(getLevelVariables(lTokens))
rVariables = []
rVariables.extend(getLevelVariables(rTokens))
availableOperations = getOperationsExpression(lVariables, lTokens)
while '/' in availableOperations:
_, tok, rem, com = expressionDivision(lVariables, lTokens)
lTokens = removeToken(tok, rem)
comments.append(com)
animBuilder = copy.deepcopy(lTokens)
lenToks = len(lTokens)
equalTo = Binary()
equalTo.scope = [lenToks]
equalTo.value = '='
animBuilder.append(equalTo)
if len(rTokens) == 0:
zero = Zero()
zero.scope = [lenToks + 1]
animBuilder.append(zero)
else:
animBuilder.extend(rTokens)
animation.append(copy.deepcopy(animBuilder))
lVariables = getLevelVariables(lTokens)
availableOperations = getOperationsExpression(lVariables, lTokens)
availableOperations = getOperationsExpression(rVariables, rTokens)
while '/' in availableOperations:
_, tok, rem, com = expressionDivision(rVariables, rTokens)
rTokens = removeToken(tok, rem)
comments.append(com)
animBuilder = copy.deepcopy(lTokens)
lenToks = len(lTokens)
equalTo = Binary()
equalTo.scope = [lenToks]
equalTo.value = '='
animBuilder.append(equalTo)
if len(rTokens) == 0:
zero = Zero()
zero.scope = [lenToks + 1]
animBuilder.append(zero)
else:
animBuilder.extend(rTokens)
animation.append(copy.deepcopy(animBuilder))
rVariables = getLevelVariables(rTokens)
availableOperations = getOperationsExpression(rVariables, rTokens)
tokenToStringBuilder = copy.deepcopy(lTokens)
lenToks = len(lTokens)
equalTo = Binary()
equalTo.scope = [lenToks]
equalTo.value = '='
tokenToStringBuilder.append(equalTo)
if len(rTokens) == 0:
zero = Zero()
zero.scope = [lenToks + 1]
tokenToStringBuilder.append(zero)
else:
tokenToStringBuilder.extend(rTokens)
token_string = tokensToString(tokenToStringBuilder)
lVariables = getLevelVariables(lTokens)
rVariables = getLevelVariables(rTokens)
availableOperations = getOperationsEquation(
lVariables, lTokens, rVariables, rTokens)
return lTokens, rTokens, availableOperations, token_string, animation, comments
def simplifyEquation(lToks, rToks):
"""Simplifies given equation tokens
Arguments:
lToks {list} -- LHS tokens list
rToks {list} -- RHS tokens list
Returns:
lTokens {list} -- LHS tokens list
rTokens {list} -- RHS tokens list
availableOperations {list} -- list of operations
token_string {string} -- simplified result in string
animation {list} -- list of equation simplification progress
comments {list} -- list of solution steps
"""
lTokens = copy.deepcopy(lToks)
rTokens = copy.deepcopy(rToks)
animation = []
comments = [[]]
lVariables = []
lVariables.extend(getLevelVariables(lTokens))
rVariables = []
rVariables.extend(getLevelVariables(rTokens))
animBuilder = lToks
lenToks = len(lToks)
equalTo = Binary()
equalTo.scope = [lenToks]
equalTo.value = '='
animBuilder.append(equalTo)
if len(rToks) == 0:
zero = Zero()
zero.scope = [lenToks + 1]
animBuilder.append(zero)
else:
animBuilder.extend(rToks)
animation.append(copy.deepcopy(animBuilder))
availableOperations = getOperationsEquation(lVariables, lTokens,
rVariables, rTokens)
while len(availableOperations) > 0:
if '/' in availableOperations:
lTokens, rTokens, availableOperations, token_string, anim, com = divisionEquation(
lTokens, rTokens)
animation.pop(len(animation) - 1)
animation.extend(anim)
comments.extend(com)
elif '*' in availableOperations:
lTokens, rTokens, availableOperations, token_string, anim, com = multiplicationEquation(
lTokens, rTokens)
animation.pop(len(animation) - 1)
animation.extend(anim)
comments.extend(com)
elif '+' in availableOperations:
lTokens, rTokens, availableOperations, token_string, anim, com = additionEquation(
lTokens, rTokens)
animation.pop(len(animation) - 1)
animation.extend(anim)
comments.extend(com)
elif '-' in availableOperations:
lTokens, rTokens, availableOperations, token_string, anim, com = subtractionEquation(
lTokens, rTokens)
animation.pop(len(animation) - 1)
animation.extend(anim)
comments.extend(com)
lVariables = getLevelVariables(lTokens)
rVariables = getLevelVariables(rTokens)
availableOperations = getOperationsEquation(lVariables, lTokens,
rVariables, rTokens)
moved = False
if len(rTokens) > 0:
moved = True
lTokens, rTokens = moveRTokensToLTokens(lTokens, rTokens)
tokenToStringBuilder = copy.deepcopy(lTokens)
lenToks = len(lTokens)
equalTo = Binary()
equalTo.scope = [lenToks]
equalTo.value = '='
tokenToStringBuilder.append(equalTo)
if len(rTokens) == 0:
zero = Zero()
zero.scope = [lenToks + 1]
tokenToStringBuilder.append(zero)
else:
tokenToStringBuilder.extend(rTokens)
if moved:
animation.append(copy.deepcopy(tokenToStringBuilder))
comments.append(['Moving the rest of variables/constants to LHS'])
token_string = tokensToString(tokenToStringBuilder)
return lTokens, rTokens, availableOperations, token_string, animation, comments
def integrateTokens(funclist, wrtVar):
"""Integrates given tokens wrt given variable
Arguments:
funclist {list} -- list of funtion tokens
wrtVar {string} -- with respect to variable
Returns:
intFunc {list} -- list of integrated tokens
animNew {list} -- equation tokens for step-by-step
commentsNew {list} -- comments for step-by-step
"""
intFunc = []
animNew = []
commentsNew = [
"Integrating with respect to " + r"$" + wrtVar + r"$" + "\n"
]
for func in funclist:
if isinstance(func, Operator): # add isFuntionOf
intFunc.append(func)
else:
newfunc = []
while (isinstance(func, Function)):
commentsNew[0] += r"$" + "\int \ " + "( " + func.__str__(
) + ")" + " d" + wrtVar + r"$"
funcCopy = copy.deepcopy(func)
if wrtVar in funcCopy.functionOf():
if not isinstance(funcCopy, Constant):
for i, var in enumerate(funcCopy.value):
log = False
if var == wrtVar:
if (funcCopy.power[i] == -1):
log = True
funcLog = Logarithm()
funcLog.operand = Variable()
funcLog.operand.coefficient = 1
funcLog.operand.value.append(
funcCopy.value[i])
funcLog.operand.power.append(1)
del funcCopy.power[i]
del funcCopy.value[i]
if funcCopy.value == []:
funcCopy.__class__ = Constant
funcCopy.value = funcCopy.coefficient
funcCopy.coefficient = 1
funcCopy.power = 1
funcCopy = [funcCopy]
funcJoin = Binary()
funcJoin.value = '*'
funcCopy.append(funcJoin)
funcCopy.append(funcLog)
else:
funcCopy.power[i] += 1
funcCopy.coefficient /= funcCopy.power[i]
if log:
commentsNew[0] += r"$" + "= " + funcCopy[0].__str__(
) + "*" + funcCopy[2].__str__() + "\ ;\ " + r"$"
newfunc.extend(funcCopy)
else:
commentsNew[0] += r"$" + "= " + funcCopy.__str__(
) + "\ ;\ " + r"$"
newfunc.append(funcCopy)
else:
if isinstance(funcCopy, Variable):
funcCopy.value.append(wrtVar)
funcCopy.power.append(1)
if isinstance(funcCopy, Constant):
coeff = funcCopy.value
funcCopy = Variable()
funcCopy.coefficient = coeff
funcCopy.value.append(wrtVar)
funcCopy.power.append(1)
newfunc.append(funcCopy)
commentsNew[0] += r"$" + "= " + funcCopy.__str__(
) + "\ ;\ " + r"$"
if func.operand is None:
break
else:
func = func.operand
if isinstance(func, Constant):
intFunc = Zero()
break
intFunc.extend(newfunc)
animNew.extend(intFunc)
return intFunc, animNew, commentsNew
def divisionEquation(lToks, rToks, direct=False):
"""Function deals with division related operations FOR EQUATIONS (driver function in division module)
Arguments:
rtoks {list} -- list of right tokens
ltoks {list} -- list of left tokens
direct {bool} -- True when we are only concerned about multiplications terms in the input
Returns:
availableOperations {list} -- list of operations which can be performed on a equation token
token_string {string} -- final result stored in a string
animation {list} -- list of equation solving process
comments {list} -- list of comments in equation solving process
"""
lTokens = copy.deepcopy(lToks)
rTokens = copy.deepcopy(rToks)
animation = []
comments = []
if direct:
comments = [[]]
animBuilder = lToks
lenToks = len(lToks)
equalTo = Binary()
equalTo.scope = [lenToks]
equalTo.value = '='
animBuilder.append(equalTo)
if len(rToks) == 0:
zero = Zero()
zero.scope = [lenToks + 1]
animBuilder.append(zero)
else:
animBuilder.extend(rToks)
animation.append(copy.deepcopy(animBuilder))
lVariables = []
lVariables.extend(getLevelVariables(lTokens))
rVariables = []
rVariables.extend(getLevelVariables(rTokens))
availableOperations = getOperationsExpression(lVariables, lTokens)
while '/' in availableOperations:
_, tok, rem, com = expressionDivision(lVariables, lTokens)
lTokens = removeToken(tok, rem)
comments.append(com)
animBuilder = copy.deepcopy(lTokens)
lenToks = len(lTokens)
equalTo = Binary()
equalTo.scope = [lenToks]
equalTo.value = '='
animBuilder.append(equalTo)
if len(rTokens) == 0:
zero = Zero()
zero.scope = [lenToks + 1]
animBuilder.append(zero)
else:
animBuilder.extend(rTokens)
animation.append(copy.deepcopy(animBuilder))
lVariables = getLevelVariables(lTokens)
availableOperations = getOperationsExpression(lVariables, lTokens)
availableOperations = getOperationsExpression(rVariables, rTokens)
while '/' in availableOperations:
_, tok, rem, com = expressionDivision(rVariables, rTokens)
rTokens = removeToken(tok, rem)
comments.append(com)
animBuilder = copy.deepcopy(lTokens)
lenToks = len(lTokens)
equalTo = Binary()
equalTo.scope = [lenToks]
equalTo.value = '='
animBuilder.append(equalTo)
if len(rTokens) == 0:
zero = Zero()
zero.scope = [lenToks + 1]
animBuilder.append(zero)
else:
animBuilder.extend(rTokens)
animation.append(copy.deepcopy(animBuilder))
rVariables = getLevelVariables(rTokens)
availableOperations = getOperationsExpression(rVariables, rTokens)
tokenToStringBuilder = copy.deepcopy(lTokens)
lenToks = len(lTokens)
equalTo = Binary()
equalTo.scope = [lenToks]
equalTo.value = '='
tokenToStringBuilder.append(equalTo)
if len(rTokens) == 0:
zero = Zero()
zero.scope = [lenToks + 1]
tokenToStringBuilder.append(zero)
else:
tokenToStringBuilder.extend(rTokens)
token_string = tokensToString(tokenToStringBuilder)
lVariables = getLevelVariables(lTokens)
rVariables = getLevelVariables(rTokens)
availableOperations = getOperationsEquation(lVariables, lTokens,
rVariables, rTokens)
return lTokens, rTokens, availableOperations, token_string, animation, comments
def cubicRoots(lTokens, rTokens):
'''Used to get roots of a cubic equation
This functions also translates roots {list} into final result of solution
Argument:
lTokens {list} -- list of LHS tokens
rTokens {list} -- list of RHS tokens
Returns:
lTokens {list} -- list of LHS tokens
rTokens {list} -- list of RHS tokens
{empty list}
token_string {string} -- final result stored in a string
animation {list} -- list of equation solving process
comments {list} -- list of comments in equation solving process
'''
from visma.solvers.polynomial.roots import getCoefficients
animations = []
comments = []
lTokens, rTokens, _, token_string, animNew1, commentNew1 = simplifyEquation(
lTokens, rTokens)
animations.extend(animNew1)
comments.extend(commentNew1)
if len(rTokens) > 0:
lTokens, rTokens = moveRTokensToLTokens(lTokens, rTokens)
coeffs = getCoefficients(lTokens, rTokens, 3)
var = getVariables(lTokens)
roots, animNew2, commentNew2 = getRootsCubic(coeffs)
animations.extend(animNew2)
comments.extend(commentNew2)
tokens1 = []
expression1 = Expression(coefficient=1, power=3)
variable = Variable(1, var[0], 1)
tokens1.append(variable)
if roots[0][1] == 0:
binary = Binary()
if roots[0][0] < 0:
roots[0][0] *= -1
binary.value = '+'
else:
binary.value = '-'
tokens1.append(binary)
constant = Constant(round(roots[0][0], ROUNDOFF), 1)
tokens1.append(constant)
expression1.tokens = tokens1
lTokens = [expression1, Binary('*')]
if len(roots) > 1:
expression1.power = 1
for _, root in enumerate(roots[1:]):
tokens2 = []
expression2 = Expression(coefficient=1, power=1)
variable = Variable(1, var[0], 1)
tokens2.append(variable)
binary = Binary()
if root[1] == 0:
if root[0] < 0:
root[0] *= -1
binary.value = '+'
else:
binary.value = '-'
tokens2.append(binary)
constant = Constant(round(root[0], ROUNDOFF), 1)
tokens2.append(constant)
else:
binary.value = '-'
tokens2.append(binary)
expressionResult = Expression(coefficient=1, power=1)
tokensResult = []
real = Constant(round(root[0], ROUNDOFF), 1)
tokensResult.append(real)
imaginary = Constant(round(root[1], ROUNDOFF), 1)
if imaginary.value < 0:
tokensResult.append(Minus())
imaginary.value = abs(imaginary.value)
tokensResult.append(imaginary)
else:
tokensResult.extend([Plus(), imaginary])
sqrt = Sqrt(Constant(2, 1), Constant(-1, 1))
tokensResult.append(Binary('*'))
tokensResult.append(sqrt)
expressionResult.tokens = tokensResult
tokens2.append(expressionResult)
expression2.tokens = tokens2
lTokens.extend([expression2, Binary('*')])
lTokens.pop()
rTokens = [Zero()]
tokenToStringBuilder = copy.deepcopy(lTokens)
tokLen = len(lTokens)
equalTo = Binary()
equalTo.scope = [tokLen]
equalTo.value = '='
tokenToStringBuilder.append(equalTo)
tokenToStringBuilder.extend(rTokens)
token_string = tokensToString(tokenToStringBuilder)
animations.append(copy.deepcopy(tokenToStringBuilder))
comments.append([])
return lTokens, rTokens, [], token_string, animations, comments
def quadraticRoots(lTokens, rTokens):
'''Used to get quadratic roots of an equation
Argument:
lTokens {list} -- list of LHS tokens
rTokens {list} -- list of RHS tokens
Returns:
lTokens {list} -- list of LHS tokens
rTokens {list} -- list of RHS tokens
{empty list}
token_string {string} -- final result stored in a string
animation {list} -- list of equation solving process
comments {list} -- list of comments in equation solving process
'''
from visma.solvers.polynomial.roots import getCoefficients
animations = []
comments = []
lTokens, rTokens, _, token_string, animNew1, commentNew1 = simplifyEquation(lTokens, rTokens)
animations.extend(animNew1)
comments.extend(commentNew1)
if len(rTokens) > 0:
lTokens, rTokens = moveRTokensToLTokens(lTokens, rTokens)
coeffs = getCoefficients(lTokens, rTokens, 2)
var = getVariables(lTokens)
roots, animNew2, commentNew2 = getRootsQuadratic(coeffs)
animations.extend(animNew2)
comments.extend(commentNew2)
if len(roots) == 1:
tokens = []
expression = Expression(coefficient=1, power=2)
variable = Variable(1, var[0], 1)
tokens.append(variable)
binary = Binary()
if roots[0] < 0:
roots[0] *= -1
binary.value = '+'
else:
binary.value = '-'
tokens.append(binary)
constant = Constant(round(roots[0], ROUNDOFF), 1)
tokens.append(constant)
expression.tokens = tokens
lTokens = [expression]
elif len(roots) == 2:
tokens = []
expression = Expression(coefficient=1, power=1)
variable = Variable(1, var[0], 1)
tokens.append(variable)
binary = Binary()
if roots[0] < 0:
roots[0] *= -1
binary.value = '+'
else:
binary.value = '-'
tokens.append(binary)
constant = Constant(round(roots[0], ROUNDOFF), 1)
tokens.append(constant)
expression.tokens = tokens
tokens2 = []
expression2 = Expression(coefficient=1, power=1)
tokens2.append(variable)
binary2 = Binary()
if roots[1] < 0:
roots[1] *= -1
binary2.value = '+'
else:
binary2.value = '-'
tokens2.append(binary2)
constant2 = Constant(round(roots[1], ROUNDOFF), 1)
tokens2.append(constant2)
expression2.tokens = tokens2
binary3 = Binary()
binary3.value = '*'
lTokens = [expression, binary3, expression2]
elif len(roots) == 3:
binary4 = Binary()
if roots[0] < 0:
roots[0] *= -1
binary4.value = '+'
else:
binary4.value = '-'
constant3 = Constant(round(roots[0], ROUNDOFF), 1)
binary5 = Binary()
binary5.value = '*'
constant2 = Constant(round(roots[2], ROUNDOFF), 1)
tokens = []
expression = Expression(coefficient=1, power=1)
variable = Variable(1, var[0], 1)
tokens.extend([variable, binary4, constant3])
binary = Binary()
binary.value = '+'
tokens.extend([binary, constant2, binary5])
constant = Constant(round(roots[1], ROUNDOFF), 1)
sqrt = Sqrt(Constant(2, 1), constant)
tokens.append(sqrt)
expression.tokens = tokens
tokens2 = []
expression2 = Expression(coefficient=1, power=1)
variable2 = Variable(1, var[0], 1)
tokens2.extend([variable2, binary4, constant3])
binary2 = Binary()
binary2.value = '-'
tokens2.extend([binary2, constant2, binary5, sqrt])
expression2.tokens = tokens2
binary3 = Binary()
binary3.value = '*'
lTokens = [expression, binary3, expression2]
zero = Zero()
rTokens = [zero]
comments.append([])
tokenToStringBuilder = copy.deepcopy(lTokens)
tokLen = len(lTokens)
equalTo = Binary()
equalTo.scope = [tokLen]
equalTo.value = '='
tokenToStringBuilder.append(equalTo)
tokenToStringBuilder.extend(rTokens)
animations.append(copy.deepcopy(tokenToStringBuilder))
token_string = tokensToString(tokenToStringBuilder)
return lTokens, rTokens, [], token_string, animations, comments
