def entity(self): return dict( x=self.x, y=self.y, color=self.color, formula='[%s,%s]' % (jscode(self.fx), jscode(self.fy)), )
def test_jscode_Pow(): g = implemented_function('g', Lambda(x, 2 * x)) assert jscode(x**3) == "Math.pow(x, 3)" assert jscode(x**(y**3)) == "Math.pow(x, Math.pow(y, 3))" assert jscode(1/(g(x)*3.5)**(x - y**x)/(x**2 + y)) == \ "Math.pow(3.5*2*x, -x + Math.pow(y, x))/(Math.pow(x, 2) + y)" assert jscode(x**-1.0) == '1/x'
def entity(self): return dict( x = self.x, y = self.y, color = self.color, formula = '[%s,%s]' % (jscode(self.fx), jscode(self.fy)), )
def test_jscode_constants_other(): assert jscode( 2 * GoldenRatio ) == "var GoldenRatio = %s;\n2*GoldenRatio" % GoldenRatio.evalf(17) assert jscode( 2 * Catalan) == "var Catalan = %s;\n2*Catalan" % Catalan.evalf(17) assert jscode( 2 * EulerGamma ) == "var EulerGamma = %s;\n2*EulerGamma" % EulerGamma.evalf(17)
def test_MatrixElement_printing(): # test cases for issue #11821 A = MatrixSymbol("A", 1, 3) B = MatrixSymbol("B", 1, 3) C = MatrixSymbol("C", 1, 3) assert (jscode(A[0, 0]) == "A[0]") assert (jscode(3 * A[0, 0]) == "3*A[0]") F = C[0, 0].subs(C, A - B) assert (jscode(F) == "(A - B)[0]")
def test_jscode_inline_function(): x = symbols('x') g = implemented_function('g', Lambda(x, 2 * x)) assert jscode(g(x)) == "2*x" g = implemented_function('g', Lambda(x, 2 * x / Catalan)) assert jscode(g(x)) == "var Catalan = %s;\n2*x/Catalan" % Catalan.evalf(17) A = IndexedBase('A') i = Idx('i', symbols('n', integer=True)) g = implemented_function('g', Lambda(x, x * (1 + x) * (2 + x))) assert jscode(g(A[i]), assign_to=A[i]) == ("for (var i=0; i<n; i++){\n" " A[i] = (A[i] + 1)*(A[i] + 2)*A[i];\n" "}")
def serialize(self): arr = [] for i in range(0, len(self.functions)): f = self.functions[i] if not isinstance(f, Expr): raise Exception( "Must only use sympy expressions when serializing") arr.append({ "type": "Function", "lineWidth": self.figure.raw2px( self.lw[i]), # TODO: We need to convert from pt to px "edgeColor": self.color[i], "lineStyle": self.mplprops["ls"] if self.mplprops != None and "ls" in self.mplprops else None, "value": jscode(f), "variable": str(self.variable[i]) if self.variable[i] != None else None, "domain": self.xyranges[i][0] if self.xyranges[i] else None }) return arr
def test_jscode_loops_addfactor(): n, m, o, p = symbols('n m o p', integer=True) a = IndexedBase('a') b = IndexedBase('b') c = IndexedBase('c') y = IndexedBase('y') i = Idx('i', m) j = Idx('j', n) k = Idx('k', o) l = Idx('l', p) s = ( 'for (var i=0; i<m; i++){\n' ' y[i] = 0;\n' '}\n' 'for (var i=0; i<m; i++){\n' ' for (var j=0; j<n; j++){\n' ' for (var k=0; k<o; k++){\n' ' for (var l=0; l<p; l++){\n' ' y[i] = (a[%s] + b[%s])*c[%s] + y[i];\n' % (i*n*o*p + j*o*p + k*p + l, i*n*o*p + j*o*p + k*p + l, j*o*p + k*p + l) +\ ' }\n' ' }\n' ' }\n' '}' ) c = jscode((a[i, j, k, l] + b[i, j, k, l]) * c[j, k, l], assign_to=y[i]) assert c == s
def test_jscode_boolean(): assert jscode(x & y) == "x && y" assert jscode(x | y) == "x || y" assert jscode(~x) == "!x" assert jscode(x & y & z) == "x && y && z" assert jscode(x | y | z) == "x || y || z" assert jscode((x & y) | z) == "z || x && y" assert jscode((x | y) & z) == "z && (x || y)"
def test_Mod(): assert jscode(Mod(x, y)) == '((x % y) + y) % y' assert jscode(Mod(x, x + y)) == '((x % (x + y)) + (x + y)) % (x + y)' p1, p2 = symbols('p1 p2', positive=True) assert jscode(Mod(p1, p2)) == 'p1 % p2' assert jscode(Mod(p1, p2 + 3)) == 'p1 % (p2 + 3)' assert jscode(Mod(-3, -7, evaluate=False)) == '(-3) % (-7)' assert jscode(-Mod(p1, p2)) == '-(p1 % p2)' assert jscode(x * Mod(p1, p2)) == 'x*(p1 % p2)'
def test_jscode_Piecewise_deep(): p = jscode(2 * Piecewise((x, x < 1), (x**2, True))) s = \ """\ 2*((x < 1) ? ( x ) : ( Math.pow(x, 2) ))\ """ assert p == s
def test_Relational(): assert jscode(Eq(x, y)) == "x == y" assert jscode(Ne(x, y)) == "x != y" assert jscode(Le(x, y)) == "x <= y" assert jscode(Lt(x, y)) == "x < y" assert jscode(Gt(x, y)) == "x > y" assert jscode(Ge(x, y)) == "x >= y"
def test_jscode_Piecewise(): expr = Piecewise((x, x < 1), (x**2, True)) p = jscode(expr) s = \ """\ ((x < 1) ? ( x ) : ( Math.pow(x, 2) ))\ """ assert p == s assert jscode(expr, assign_to="c") == ("if (x < 1) {\n" " c = x;\n" "}\n" "else {\n" " c = Math.pow(x, 2);\n" "}") # Check that Piecewise without a True (default) condition error expr = Piecewise((x, x < 1), (x**2, x > 1), (sin(x), x > 0)) raises(ValueError, lambda: jscode(expr))
def test_Matrix_printing(): # Test returning a Matrix mat = Matrix([x * y, Piecewise((2 + x, y > 0), (y, True)), sin(z)]) A = MatrixSymbol('A', 3, 1) assert jscode(mat, A) == ("A[0] = x*y;\n" "if (y > 0) {\n" " A[1] = x + 2;\n" "}\n" "else {\n" " A[1] = y;\n" "}\n" "A[2] = Math.sin(z);") # Test using MatrixElements in expressions expr = Piecewise((2 * A[2, 0], x > 0), (A[2, 0], True)) + sin(A[1, 0]) + A[0, 0] assert jscode(expr) == ("((x > 0) ? (\n" " 2*A[2]\n" ")\n" ": (\n" " A[2]\n" ")) + Math.sin(A[1]) + A[0]") # Test using MatrixElements in a Matrix q = MatrixSymbol('q', 5, 1) M = MatrixSymbol('M', 3, 3) m = Matrix([[sin(q[1, 0]), 0, cos(q[2, 0])], [q[1, 0] + q[2, 0], q[3, 0], 5], [2 * q[4, 0] / q[1, 0], sqrt(q[0, 0]) + 4, 0]]) assert jscode(m, M) == ("M[0] = Math.sin(q[1]);\n" "M[1] = 0;\n" "M[2] = Math.cos(q[2]);\n" "M[3] = q[1] + q[2];\n" "M[4] = q[3];\n" "M[5] = 5;\n" "M[6] = 2*q[4]/q[1];\n" "M[7] = Math.sqrt(q[0]) + 4;\n" "M[8] = 0;")
def test_dummy_loops(): i, m = symbols('i m', integer=True, cls=Dummy) x = IndexedBase('x') y = IndexedBase('y') i = Idx(i, m) expected = ( 'for (var i_%(icount)i=0; i_%(icount)i<m_%(mcount)i; i_%(icount)i++){\n' ' y[i_%(icount)i] = x[i_%(icount)i];\n' '}') % { 'icount': i.label.dummy_index, 'mcount': m.dummy_index } code = jscode(x[i], assign_to=y[i]) assert code == expected
def test_jscode_loops_matrix_vector(): n, m = symbols('n m', integer=True) A = IndexedBase('A') x = IndexedBase('x') y = IndexedBase('y') i = Idx('i', m) j = Idx('j', n) s = ('for (var i=0; i<m; i++){\n' ' y[i] = 0;\n' '}\n' 'for (var i=0; i<m; i++){\n' ' for (var j=0; j<n; j++){\n' ' y[i] = A[n*i + j]*x[j] + y[i];\n' ' }\n' '}') c = jscode(A[i, j] * x[j], assign_to=y[i]) assert c == s
def test_jscode_loops_multiple_terms(): n, m, o, p = symbols('n m o p', integer=True) a = IndexedBase('a') b = IndexedBase('b') c = IndexedBase('c') y = IndexedBase('y') i = Idx('i', m) j = Idx('j', n) k = Idx('k', o) s0 = ('for (var i=0; i<m; i++){\n' ' y[i] = 0;\n' '}\n') s1 = ( 'for (var i=0; i<m; i++){\n' ' for (var j=0; j<n; j++){\n' ' for (var k=0; k<o; k++){\n' ' y[i] = b[j]*b[k]*c[%s] + y[i];\n' % (i*n*o + j*o + k) +\ ' }\n' ' }\n' '}\n' ) s2 = ( 'for (var i=0; i<m; i++){\n' ' for (var k=0; k<o; k++){\n' ' y[i] = a[%s]*b[k] + y[i];\n' % (i*o + k) +\ ' }\n' '}\n' ) s3 = ( 'for (var i=0; i<m; i++){\n' ' for (var j=0; j<n; j++){\n' ' y[i] = a[%s]*b[j] + y[i];\n' % (i*n + j) +\ ' }\n' '}\n' ) c = jscode(b[j] * a[i, j] + b[k] * a[i, k] + b[j] * b[k] * c[i, j, k], assign_to=y[i]) assert (c == s0 + s1 + s2 + s3[:-1] or c == s0 + s1 + s3 + s2[:-1] or c == s0 + s2 + s1 + s3[:-1] or c == s0 + s2 + s3 + s1[:-1] or c == s0 + s3 + s1 + s2[:-1] or c == s0 + s3 + s2 + s1[:-1])
def test_jscode_settings(): raises(TypeError, lambda: jscode(sin(x), method="garbage"))
def test_jscode_exceptions(): assert jscode(ceiling(x)) == "Math.ceil(x)" assert jscode(Abs(x)) == "Math.abs(x)"
def test_jscode_functions(): assert jscode(sin(x)**cos(x)) == "Math.pow(Math.sin(x), Math.cos(x))" assert jscode(sinh(x) * cosh(x)) == "Math.sinh(x)*Math.cosh(x)" assert jscode(Max(x, y) + Min(x, y)) == "Math.max(x, y) + Math.min(x, y)" assert jscode(tanh(x) * acosh(y)) == "Math.tanh(x)*Math.acosh(y)" assert jscode(asin(x) - acos(y)) == "-Math.acos(y) + Math.asin(x)"
def test_jscode_Integer(): assert jscode(Integer(67)) == "67" assert jscode(Integer(-1)) == "-1"
def test_jscode_sqrt(): assert jscode(sqrt(x)) == "Math.sqrt(x)" assert jscode(x**0.5) == "Math.sqrt(x)" assert jscode(x**(S.One / 3)) == "Math.cbrt(x)"
def test_jscode_Rational(): assert jscode(Rational(3, 7)) == "3/7" assert jscode(Rational(18, 9)) == "2" assert jscode(Rational(3, -7)) == "-3/7" assert jscode(Rational(-3, -7)) == "3/7"
def test_printmethod(): assert jscode(Abs(x)) == "Math.abs(x)"
def test_jscode_constants_mathh(): assert jscode(exp(1)) == "Math.E" assert jscode(pi) == "Math.PI" assert jscode(oo) == "Number.POSITIVE_INFINITY" assert jscode(-oo) == "Number.NEGATIVE_INFINITY"