Modules/cmathmodule.c - platform/external/python/cpython3 - Gitiles

 /* Complex math module */

 /* much code borrowed from mathmodule.c */

 #include "Python.h"

 #ifndef M_PI
 #define M_PI (3.141592653589793239)
 #endif

 /* First, the C functions that do the real work */

 /* constants */
 static Py_complex c_one = {1., 0.};
 static Py_complex c_half = {0.5, 0.};
 static Py_complex c_i = {0., 1.};
 static Py_complex c_halfi = {0., 0.5};

 /* forward declarations */
 staticforward Py_complex c_log(Py_complex);
 staticforward Py_complex c_prodi(Py_complex);
 staticforward Py_complex c_sqrt(Py_complex);


 static Py_complex
 c_acos(Py_complex x)
 {
 	return c_neg(c_prodi(c_log(c_sum(x,c_prod(c_i,
 		    c_sqrt(c_diff(c_one,c_prod(x,x))))))));
 }

 static char c_acos_doc[] =
 "acos(x)\n"
 "\n"
 "Return the arc cosine of x.";


 static Py_complex
 c_acosh(Py_complex x)
 {
 	Py_complex z;
 	z = c_sqrt(c_half);
 	z = c_log(c_prod(z, c_sum(c_sqrt(c_sum(x,c_one)),
 				  c_sqrt(c_diff(x,c_one)))));
 	return c_sum(z, z);
 }

 static char c_acosh_doc[] =
 "acosh(x)\n"
 "\n"
 "Return the hyperbolic arccosine of x.";


 static Py_complex
 c_asin(Py_complex x)
 {
 	/* -i * log[(sqrt(1-x**2) + i*x] */
 	const Py_complex squared = c_prod(x, x);
 	const Py_complex sqrt_1_minus_x_sq = c_sqrt(c_diff(c_one, squared));
         return c_neg(c_prodi(c_log(
         		c_sum(sqrt_1_minus_x_sq, c_prodi(x))
 		    )       )     );
 }

 static char c_asin_doc[] =
 "asin(x)\n"
 "\n"
 "Return the arc sine of x.";


 static Py_complex
 c_asinh(Py_complex x)
 {
 	Py_complex z;
 	z = c_sqrt(c_half);
 	z = c_log(c_prod(z, c_sum(c_sqrt(c_sum(x, c_i)),
 				  c_sqrt(c_diff(x, c_i)))));
 	return c_sum(z, z);
 }

 static char c_asinh_doc[] =
 "asinh(x)\n"
 "\n"
 "Return the hyperbolic arc sine of x.";


 static Py_complex
 c_atan(Py_complex x)
 {
 	return c_prod(c_halfi,c_log(c_quot(c_sum(c_i,x),c_diff(c_i,x))));
 }

 static char c_atan_doc[] =
 "atan(x)\n"
 "\n"
 "Return the arc tangent of x.";


 static Py_complex
 c_atanh(Py_complex x)
 {
 	return c_prod(c_half,c_log(c_quot(c_sum(c_one,x),c_diff(c_one,x))));
 }

 static char c_atanh_doc[] =
 "atanh(x)\n"
 "\n"
 "Return the hyperbolic arc tangent of x.";


 static Py_complex
 c_cos(Py_complex x)
 {
 	Py_complex r;
 	r.real = cos(x.real)*cosh(x.imag);
 	r.imag = -sin(x.real)*sinh(x.imag);
 	return r;
 }

 static char c_cos_doc[] =
 "cos(x)\n"
 "n"
 "Return the cosine of x.";


 static Py_complex
 c_cosh(Py_complex x)
 {
 	Py_complex r;
 	r.real = cos(x.imag)*cosh(x.real);
 	r.imag = sin(x.imag)*sinh(x.real);
 	return r;
 }

 static char c_cosh_doc[] =
 "cosh(x)\n"
 "n"
 "Return the hyperbolic cosine of x.";


 static Py_complex
 c_exp(Py_complex x)
 {
 	Py_complex r;
 	double l = exp(x.real);
 	r.real = l*cos(x.imag);
 	r.imag = l*sin(x.imag);
 	return r;
 }

 static char c_exp_doc[] =
 "exp(x)\n"
 "\n"
 "Return the exponential value e**x.";


 static Py_complex
 c_log(Py_complex x)
 {
 	Py_complex r;
 	double l = hypot(x.real,x.imag);
 	r.imag = atan2(x.imag, x.real);
 	r.real = log(l);
 	return r;
 }

 static char c_log_doc[] =
 "log(x)\n"
 "\n"
 "Return the natural logarithm of x.";


 static Py_complex
 c_log10(Py_complex x)
 {
 	Py_complex r;
 	double l = hypot(x.real,x.imag);
 	r.imag = atan2(x.imag, x.real)/log(10.);
 	r.real = log10(l);
 	return r;
 }

 static char c_log10_doc[] =
 "log10(x)\n"
 "\n"
 "Return the base-10 logarithm of x.";


 /* internal function not available from Python */
 static Py_complex
 c_prodi(Py_complex x)
 {
 	Py_complex r;
 	r.real = -x.imag;
 	r.imag = x.real;
 	return r;
 }


 static Py_complex
 c_sin(Py_complex x)
 {
 	Py_complex r;
 	r.real = sin(x.real) * cosh(x.imag);
 	r.imag = cos(x.real) * sinh(x.imag);
 	return r;
 }

 static char c_sin_doc[] =
 "sin(x)\n"
 "\n"
 "Return the sine of x.";


 static Py_complex
 c_sinh(Py_complex x)
 {
 	Py_complex r;
 	r.real = cos(x.imag) * sinh(x.real);
 	r.imag = sin(x.imag) * cosh(x.real);
 	return r;
 }

 static char c_sinh_doc[] =
 "sinh(x)\n"
 "\n"
 "Return the hyperbolic sine of x.";


 static Py_complex
 c_sqrt(Py_complex x)
 {
 	Py_complex r;
 	double s,d;
 	if (x.real == 0. && x.imag == 0.)
 		r = x;
 	else {
 		s = sqrt(0.5*(fabs(x.real) + hypot(x.real,x.imag)));
 		d = 0.5*x.imag/s;
 		if (x.real > 0.) {
 			r.real = s;
 			r.imag = d;
 		}
 		else if (x.imag >= 0.) {
 			r.real = d;
 			r.imag = s;
 		}
 		else {
 			r.real = -d;
 			r.imag = -s;
 		}
 	}
 	return r;
 }

 static char c_sqrt_doc[] =
 "sqrt(x)\n"
 "\n"
 "Return the square root of x.";


 static Py_complex
 c_tan(Py_complex x)
 {
 	Py_complex r;
 	double sr,cr,shi,chi;
 	double rs,is,rc,ic;
 	double d;
 	sr = sin(x.real);
 	cr = cos(x.real);
 	shi = sinh(x.imag);
 	chi = cosh(x.imag);
 	rs = sr * chi;
 	is = cr * shi;
 	rc = cr * chi;
 	ic = -sr * shi;
 	d = rc*rc + ic * ic;
 	r.real = (rs*rc + is*ic) / d;
 	r.imag = (is*rc - rs*ic) / d;
 	return r;
 }

 static char c_tan_doc[] =
 "tan(x)\n"
 "\n"
 "Return the tangent of x.";


 static Py_complex
 c_tanh(Py_complex x)
 {
 	Py_complex r;
 	double si,ci,shr,chr;
 	double rs,is,rc,ic;
 	double d;
 	si = sin(x.imag);
 	ci = cos(x.imag);
 	shr = sinh(x.real);
 	chr = cosh(x.real);
 	rs = ci * shr;
 	is = si * chr;
 	rc = ci * chr;
 	ic = si * shr;
 	d = rc*rc + ic*ic;
 	r.real = (rs*rc + is*ic) / d;
 	r.imag = (is*rc - rs*ic) / d;
 	return r;
 }

 static char c_tanh_doc[] =
 "tanh(x)\n"
 "\n"
 "Return the hyperbolic tangent of x.";


 /* And now the glue to make them available from Python: */

 static PyObject *
 math_error(void)
 {
 	if (errno == EDOM)
 		PyErr_SetString(PyExc_ValueError, "math domain error");
 	else if (errno == ERANGE)
 		PyErr_SetString(PyExc_OverflowError, "math range error");
 	else    /* Unexpected math error */
 		PyErr_SetFromErrno(PyExc_ValueError);
 	return NULL;
 }

 static PyObject *
 math_1(PyObject *args, Py_complex (*func)(Py_complex))
 {
 	Py_complex x;
 	if (!PyArg_ParseTuple(args, "D", &x))
 		return NULL;
 	errno = 0;
 	PyFPE_START_PROTECT("complex function", return 0)
 	x = (*func)(x);
 	PyFPE_END_PROTECT(x)
 	Py_SET_ERANGE_IF_OVERFLOW(x.real);
 	Py_SET_ERANGE_IF_OVERFLOW(x.imag);
 	if (errno != 0)
 		return math_error();
 	else
 		return PyComplex_FromCComplex(x);
 }

 #define FUNC1(stubname, func) \
 	static PyObject * stubname(PyObject *self, PyObject *args) { \
 		return math_1(args, func); \
 	}

 FUNC1(cmath_acos, c_acos)
 FUNC1(cmath_acosh, c_acosh)
 FUNC1(cmath_asin, c_asin)
 FUNC1(cmath_asinh, c_asinh)
 FUNC1(cmath_atan, c_atan)
 FUNC1(cmath_atanh, c_atanh)
 FUNC1(cmath_cos, c_cos)
 FUNC1(cmath_cosh, c_cosh)
 FUNC1(cmath_exp, c_exp)
 FUNC1(cmath_log, c_log)
 FUNC1(cmath_log10, c_log10)
 FUNC1(cmath_sin, c_sin)
 FUNC1(cmath_sinh, c_sinh)
 FUNC1(cmath_sqrt, c_sqrt)
 FUNC1(cmath_tan, c_tan)
 FUNC1(cmath_tanh, c_tanh)


 static char module_doc[] =
 "This module is always available. It provides access to mathematical\n"
 "functions for complex numbers.";

 static PyMethodDef cmath_methods[] = {
 	{"acos",   cmath_acos,  METH_VARARGS, c_acos_doc},
 	{"acosh",  cmath_acosh, METH_VARARGS, c_acosh_doc},
 	{"asin",   cmath_asin,  METH_VARARGS, c_asin_doc},
 	{"asinh",  cmath_asinh, METH_VARARGS, c_asinh_doc},
 	{"atan",   cmath_atan,  METH_VARARGS, c_atan_doc},
 	{"atanh",  cmath_atanh, METH_VARARGS, c_atanh_doc},
 	{"cos",    cmath_cos,   METH_VARARGS, c_cos_doc},
 	{"cosh",   cmath_cosh,  METH_VARARGS, c_cosh_doc},
 	{"exp",    cmath_exp,   METH_VARARGS, c_exp_doc},
 	{"log",    cmath_log,   METH_VARARGS, c_log_doc},
 	{"log10",  cmath_log10, METH_VARARGS, c_log10_doc},
 	{"sin",    cmath_sin,   METH_VARARGS, c_sin_doc},
 	{"sinh",   cmath_sinh,  METH_VARARGS, c_sinh_doc},
 	{"sqrt",   cmath_sqrt,  METH_VARARGS, c_sqrt_doc},
 	{"tan",    cmath_tan,   METH_VARARGS, c_tan_doc},
 	{"tanh",   cmath_tanh,  METH_VARARGS, c_tanh_doc},
 	{NULL,		NULL}		/* sentinel */
 };

 DL_EXPORT(void)
 initcmath(void)
 {
 	PyObject *m, *d, *v;

 	m = Py_InitModule3("cmath", cmath_methods, module_doc);
 	d = PyModule_GetDict(m);
 	PyDict_SetItemString(d, "pi",
 			     v = PyFloat_FromDouble(atan(1.0) * 4.0));
 	Py_DECREF(v);
 	PyDict_SetItemString(d, "e", v = PyFloat_FromDouble(exp(1.0)));
 	Py_DECREF(v);
 }
	/* Complex math module */

	/* much code borrowed from mathmodule.c */

	#include "Python.h"

	#ifndef M_PI
	#define M_PI (3.141592653589793239)
	#endif

	/* First, the C functions that do the real work */

	/* constants */
	static Py_complex c_one = {1., 0.};
	static Py_complex c_half = {0.5, 0.};
	static Py_complex c_i = {0., 1.};
	static Py_complex c_halfi = {0., 0.5};

	/* forward declarations */
	staticforward Py_complex c_log(Py_complex);
	staticforward Py_complex c_prodi(Py_complex);
	staticforward Py_complex c_sqrt(Py_complex);


	static Py_complex
	c_acos(Py_complex x)
	{
	return c_neg(c_prodi(c_log(c_sum(x,c_prod(c_i,
	c_sqrt(c_diff(c_one,c_prod(x,x))))))));
	}

	static char c_acos_doc[] =
	"acos(x)\n"
	"\n"
	"Return the arc cosine of x.";


	static Py_complex
	c_acosh(Py_complex x)
	{
	Py_complex z;
	z = c_sqrt(c_half);
	z = c_log(c_prod(z, c_sum(c_sqrt(c_sum(x,c_one)),
	c_sqrt(c_diff(x,c_one)))));
	return c_sum(z, z);
	}

	static char c_acosh_doc[] =
	"acosh(x)\n"
	"\n"
	"Return the hyperbolic arccosine of x.";


	static Py_complex
	c_asin(Py_complex x)
	{
	/* -i * log[(sqrt(1-x*2) + ix] */
	const Py_complex squared = c_prod(x, x);
	const Py_complex sqrt_1_minus_x_sq = c_sqrt(c_diff(c_one, squared));
	return c_neg(c_prodi(c_log(
	c_sum(sqrt_1_minus_x_sq, c_prodi(x))
	) ) );
	}

	static char c_asin_doc[] =
	"asin(x)\n"
	"\n"
	"Return the arc sine of x.";


	static Py_complex
	c_asinh(Py_complex x)
	{
	Py_complex z;
	z = c_sqrt(c_half);
	z = c_log(c_prod(z, c_sum(c_sqrt(c_sum(x, c_i)),
	c_sqrt(c_diff(x, c_i)))));
	return c_sum(z, z);
	}

	static char c_asinh_doc[] =
	"asinh(x)\n"
	"\n"
	"Return the hyperbolic arc sine of x.";


	static Py_complex
	c_atan(Py_complex x)
	{
	return c_prod(c_halfi,c_log(c_quot(c_sum(c_i,x),c_diff(c_i,x))));
	}

	static char c_atan_doc[] =
	"atan(x)\n"
	"\n"
	"Return the arc tangent of x.";


	static Py_complex
	c_atanh(Py_complex x)
	{
	return c_prod(c_half,c_log(c_quot(c_sum(c_one,x),c_diff(c_one,x))));
	}

	static char c_atanh_doc[] =
	"atanh(x)\n"
	"\n"
	"Return the hyperbolic arc tangent of x.";


	static Py_complex
	c_cos(Py_complex x)
	{
	Py_complex r;
	r.real = cos(x.real)*cosh(x.imag);
	r.imag = -sin(x.real)*sinh(x.imag);
	return r;
	}

	static char c_cos_doc[] =
	"cos(x)\n"
	"n"
	"Return the cosine of x.";


	static Py_complex
	c_cosh(Py_complex x)
	{
	Py_complex r;
	r.real = cos(x.imag)*cosh(x.real);
	r.imag = sin(x.imag)*sinh(x.real);
	return r;
	}

	static char c_cosh_doc[] =
	"cosh(x)\n"
	"n"
	"Return the hyperbolic cosine of x.";


	static Py_complex
	c_exp(Py_complex x)
	{
	Py_complex r;
	double l = exp(x.real);
	r.real = l*cos(x.imag);
	r.imag = l*sin(x.imag);
	return r;
	}

	static char c_exp_doc[] =
	"exp(x)\n"
	"\n"
	"Return the exponential value e**x.";


	static Py_complex
	c_log(Py_complex x)
	{
	Py_complex r;
	double l = hypot(x.real,x.imag);
	r.imag = atan2(x.imag, x.real);
	r.real = log(l);
	return r;
	}

	static char c_log_doc[] =
	"log(x)\n"
	"\n"
	"Return the natural logarithm of x.";


	static Py_complex
	c_log10(Py_complex x)
	{
	Py_complex r;
	double l = hypot(x.real,x.imag);
	r.imag = atan2(x.imag, x.real)/log(10.);
	r.real = log10(l);
	return r;
	}

	static char c_log10_doc[] =
	"log10(x)\n"
	"\n"
	"Return the base-10 logarithm of x.";


	/* internal function not available from Python */
	static Py_complex
	c_prodi(Py_complex x)
	{
	Py_complex r;
	r.real = -x.imag;
	r.imag = x.real;
	return r;
	}


	static Py_complex
	c_sin(Py_complex x)
	{
	Py_complex r;
	r.real = sin(x.real) * cosh(x.imag);
	r.imag = cos(x.real) * sinh(x.imag);
	return r;
	}

	static char c_sin_doc[] =
	"sin(x)\n"
	"\n"
	"Return the sine of x.";


	static Py_complex
	c_sinh(Py_complex x)
	{
	Py_complex r;
	r.real = cos(x.imag) * sinh(x.real);
	r.imag = sin(x.imag) * cosh(x.real);
	return r;
	}

	static char c_sinh_doc[] =
	"sinh(x)\n"
	"\n"
	"Return the hyperbolic sine of x.";


	static Py_complex
	c_sqrt(Py_complex x)
	{
	Py_complex r;
	double s,d;
	if (x.real == 0. && x.imag == 0.)
	r = x;
	else {
	s = sqrt(0.5*(fabs(x.real) + hypot(x.real,x.imag)));
	d = 0.5*x.imag/s;
	if (x.real > 0.) {
	r.real = s;
	r.imag = d;
	}
	else if (x.imag >= 0.) {
	r.real = d;
	r.imag = s;
	}
	else {
	r.real = -d;
	r.imag = -s;
	}
	}
	return r;
	}

	static char c_sqrt_doc[] =
	"sqrt(x)\n"
	"\n"
	"Return the square root of x.";


	static Py_complex
	c_tan(Py_complex x)
	{
	Py_complex r;
	double sr,cr,shi,chi;
	double rs,is,rc,ic;
	double d;
	sr = sin(x.real);
	cr = cos(x.real);
	shi = sinh(x.imag);
	chi = cosh(x.imag);
	rs = sr * chi;
	is = cr * shi;
	rc = cr * chi;
	ic = -sr * shi;
	d = rcrc + ic ic;
	r.real = (rsrc + isic) / d;
	r.imag = (isrc - rsic) / d;
	return r;
	}

	static char c_tan_doc[] =
	"tan(x)\n"
	"\n"
	"Return the tangent of x.";


	static Py_complex
	c_tanh(Py_complex x)
	{
	Py_complex r;
	double si,ci,shr,chr;
	double rs,is,rc,ic;
	double d;
	si = sin(x.imag);
	ci = cos(x.imag);
	shr = sinh(x.real);
	chr = cosh(x.real);
	rs = ci * shr;
	is = si * chr;
	rc = ci * chr;
	ic = si * shr;
	d = rcrc + icic;
	r.real = (rsrc + isic) / d;
	r.imag = (isrc - rsic) / d;
	return r;
	}

	static char c_tanh_doc[] =
	"tanh(x)\n"
	"\n"
	"Return the hyperbolic tangent of x.";


	/* And now the glue to make them available from Python: */

	static PyObject *
	math_error(void)
	{
	if (errno == EDOM)
	PyErr_SetString(PyExc_ValueError, "math domain error");
	else if (errno == ERANGE)
	PyErr_SetString(PyExc_OverflowError, "math range error");
	else /* Unexpected math error */
	PyErr_SetFromErrno(PyExc_ValueError);
	return NULL;
	}

	static PyObject *
	math_1(PyObject args, Py_complex (func)(Py_complex))
	{
	Py_complex x;
	if (!PyArg_ParseTuple(args, "D", &x))
	return NULL;
	errno = 0;
	PyFPE_START_PROTECT("complex function", return 0)
	x = (*func)(x);
	PyFPE_END_PROTECT(x)
	Py_SET_ERANGE_IF_OVERFLOW(x.real);
	Py_SET_ERANGE_IF_OVERFLOW(x.imag);
	if (errno != 0)
	return math_error();
	else
	return PyComplex_FromCComplex(x);
	}

	#define FUNC1(stubname, func) \
	static PyObject * stubname(PyObject self, PyObject args) { \
	return math_1(args, func); \
	}

	FUNC1(cmath_acos, c_acos)
	FUNC1(cmath_acosh, c_acosh)
	FUNC1(cmath_asin, c_asin)
	FUNC1(cmath_asinh, c_asinh)
	FUNC1(cmath_atan, c_atan)
	FUNC1(cmath_atanh, c_atanh)
	FUNC1(cmath_cos, c_cos)
	FUNC1(cmath_cosh, c_cosh)
	FUNC1(cmath_exp, c_exp)
	FUNC1(cmath_log, c_log)
	FUNC1(cmath_log10, c_log10)
	FUNC1(cmath_sin, c_sin)
	FUNC1(cmath_sinh, c_sinh)
	FUNC1(cmath_sqrt, c_sqrt)
	FUNC1(cmath_tan, c_tan)
	FUNC1(cmath_tanh, c_tanh)


	static char module_doc[] =
	"This module is always available. It provides access to mathematical\n"
	"functions for complex numbers.";

	static PyMethodDef cmath_methods[] = {
	{"acos", cmath_acos, METH_VARARGS, c_acos_doc},
	{"acosh", cmath_acosh, METH_VARARGS, c_acosh_doc},
	{"asin", cmath_asin, METH_VARARGS, c_asin_doc},
	{"asinh", cmath_asinh, METH_VARARGS, c_asinh_doc},
	{"atan", cmath_atan, METH_VARARGS, c_atan_doc},
	{"atanh", cmath_atanh, METH_VARARGS, c_atanh_doc},
	{"cos", cmath_cos, METH_VARARGS, c_cos_doc},
	{"cosh", cmath_cosh, METH_VARARGS, c_cosh_doc},
	{"exp", cmath_exp, METH_VARARGS, c_exp_doc},
	{"log", cmath_log, METH_VARARGS, c_log_doc},
	{"log10", cmath_log10, METH_VARARGS, c_log10_doc},
	{"sin", cmath_sin, METH_VARARGS, c_sin_doc},
	{"sinh", cmath_sinh, METH_VARARGS, c_sinh_doc},
	{"sqrt", cmath_sqrt, METH_VARARGS, c_sqrt_doc},
	{"tan", cmath_tan, METH_VARARGS, c_tan_doc},
	{"tanh", cmath_tanh, METH_VARARGS, c_tanh_doc},
	{NULL, NULL} /* sentinel */
	};

	DL_EXPORT(void)
	initcmath(void)
	{
	PyObject m, d, *v;

	m = Py_InitModule3("cmath", cmath_methods, module_doc);
	d = PyModule_GetDict(m);
	PyDict_SetItemString(d, "pi",
	v = PyFloat_FromDouble(atan(1.0) * 4.0));
	Py_DECREF(v);
	PyDict_SetItemString(d, "e", v = PyFloat_FromDouble(exp(1.0)));
	Py_DECREF(v);
	}