third_party/cython/src/Cython/Utility/Overflow.c - mojo - Git at Google

 /*
 These functions provide integer arithmetic with integer checking.  They do not
 actually raise an exception when an overflow is detected, but rather set a bit
 in the overflow parameter.  (This parameter may be re-used accross several
 arithmetic operations, so should be or-ed rather than assigned to.)

 The implementation is divided into two parts, the signed and unsigned basecases,
 which is where the magic happens, and a generic template matching a specific
 type to an implementation based on its (c-compile-time) size and signedness.

 When possible, branching is avoided, and preference is given to speed over
 accuracy (a low rate of falsely "detected" overflows are acceptable,
 undetected overflows are not).


 TODO: Hook up checking.
 TODO: Conditionally support 128-bit with intmax_t?
 */

 /////////////// Common.proto ///////////////

 static int __Pyx_check_twos_complement(void) {
     if (-1 != ~0) {
         PyErr_SetString(PyExc_RuntimeError, "Two's complement required for overflow checks.");
         return 1;
     } else if (sizeof(short) == sizeof(int)) {
         PyErr_SetString(PyExc_RuntimeError, "sizeof(short) < sizeof(int) required for overflow checks.");
         return 1;
     } else {
         return 0;
     }
 }

 #define __PYX_IS_UNSIGNED(type) (((type) -1) > 0)
 #define __PYX_SIGN_BIT(type)    (((unsigned type) 1) << (sizeof(type) * 8 - 1))
 #define __PYX_HALF_MAX(type)    (((type) 1) << (sizeof(type) * 8 - 2))
 #define __PYX_MIN(type)         (__PYX_IS_UNSIGNED(type) ? (type) 0 : 0 - __PYX_HALF_MAX(type) - __PYX_HALF_MAX(type))
 #define __PYX_MAX(type)         (~__PYX_MIN(type))

 #define __Pyx_add_no_overflow(a, b, overflow) ((a) + (b))
 #define __Pyx_add_const_no_overflow(a, b, overflow) ((a) + (b))
 #define __Pyx_sub_no_overflow(a, b, overflow) ((a) - (b))
 #define __Pyx_sub_const_no_overflow(a, b, overflow) ((a) - (b))
 #define __Pyx_mul_no_overflow(a, b, overflow) ((a) * (b))
 #define __Pyx_mul_const_no_overflow(a, b, overflow) ((a) * (b))
 #define __Pyx_div_no_overflow(a, b, overflow) ((a) / (b))
 #define __Pyx_div_const_no_overflow(a, b, overflow) ((a) / (b))

 /////////////// Common.init ///////////////

 __Pyx_check_twos_complement();

 /////////////// BaseCaseUnsigned.proto ///////////////

 static CYTHON_INLINE {{UINT}} __Pyx_add_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow);
 static CYTHON_INLINE {{UINT}} __Pyx_sub_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow);
 static CYTHON_INLINE {{UINT}} __Pyx_mul_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow);
 static CYTHON_INLINE {{UINT}} __Pyx_div_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow);

 // Use these when b is known at compile time.
 #define __Pyx_add_const_{{NAME}}_checking_overflow __Pyx_add_{{NAME}}_checking_overflow
 #define __Pyx_sub_const_{{NAME}}_checking_overflow __Pyx_sub_{{NAME}}_checking_overflow
 static CYTHON_INLINE {{UINT}} __Pyx_mul_const_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} constant, int *overflow);
 #define __Pyx_div_const_{{NAME}}_checking_overflow __Pyx_div_{{NAME}}_checking_overflow

 /////////////// BaseCaseUnsigned ///////////////

 static CYTHON_INLINE {{UINT}} __Pyx_add_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow) {
     {{UINT}} r = a + b;
     *overflow |= r < a;
     return r;
 }

 static CYTHON_INLINE {{UINT}} __Pyx_sub_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow) {
     {{UINT}} r = a - b;
     *overflow |= r > a;
     return r;
 }

 static CYTHON_INLINE {{UINT}} __Pyx_mul_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow) {
     if (sizeof({{UINT}}) < sizeof(unsigned long)) {
         unsigned long big_r = ((unsigned long) a) * ((unsigned long) b);
         {{UINT}} r = ({{UINT}}) big_r;
         *overflow |= big_r != r;
         return r;
     } else if (sizeof({{UINT}}) < sizeof(unsigned long long)) {
         unsigned long long big_r = ((unsigned long long) a) * ((unsigned long long) b);
         {{UINT}} r = ({{UINT}}) big_r;
         *overflow |= big_r != r;
         return r;
     } else {
         {{UINT}} prod = a * b;
         double dprod = ((double) a) * ((double) b);
         // Overflow results in an error of at least 2^sizeof(UINT),
         // whereas rounding represents an error on the order of 2^(sizeof(UINT)-53).
         *overflow |= fabs(dprod - prod) > (__PYX_MAX({{UINT}}) / 2);
         return prod;
     }
 }

 static CYTHON_INLINE {{UINT}} __Pyx_mul_const_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow) {
     if (b > 1) {
         *overflow |= a > __PYX_MAX({{UINT}}) / b;
     }
     return a * b;
 }


 static CYTHON_INLINE {{UINT}} __Pyx_div_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow) {
     if (b == 0) {
         *overflow |= 1;
         return 0;
     }
     return a / b;
 }


 /////////////// BaseCaseSigned.proto ///////////////

 static CYTHON_INLINE {{INT}} __Pyx_add_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow);
 static CYTHON_INLINE {{INT}} __Pyx_sub_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow);
 static CYTHON_INLINE {{INT}} __Pyx_mul_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow);
 static CYTHON_INLINE {{INT}} __Pyx_div_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow);


 // Use when b is known at compile time.
 static CYTHON_INLINE {{INT}} __Pyx_add_const_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow);
 static CYTHON_INLINE {{INT}} __Pyx_sub_const_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow);
 static CYTHON_INLINE {{INT}} __Pyx_mul_const_{{NAME}}_checking_overflow({{INT}} a, {{INT}} constant, int *overflow);
 #define __Pyx_div_const_{{NAME}}_checking_overflow __Pyx_div_{{NAME}}_checking_overflow

 /////////////// BaseCaseSigned ///////////////

 static CYTHON_INLINE {{INT}} __Pyx_add_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow) {
     if (sizeof({{INT}}) < sizeof(long)) {
         long big_r = ((long) a) + ((long) b);
         {{INT}} r = ({{INT}}) big_r;
         *overflow |= big_r != r;
         return r;
     } else if (sizeof({{INT}}) < sizeof(long long)) {
         long long big_r = ((long long) a) + ((long long) b);
         {{INT}} r = ({{INT}}) big_r;
         *overflow |= big_r != r;
         return r;
     } else {
         // Signed overflow undefined, but unsigned overflow is well defined.
         {{INT}} r = ({{INT}}) ((unsigned {{INT}}) a + (unsigned {{INT}}) b);
         // Overflow happened if the operands have the same sign, but the result
         // has opposite sign.
         // sign(a) == sign(b) != sign(r)
         {{INT}} sign_a = __PYX_SIGN_BIT({{INT}}) & a;
         {{INT}} sign_b = __PYX_SIGN_BIT({{INT}}) & b;
         {{INT}} sign_r = __PYX_SIGN_BIT({{INT}}) & r;
         *overflow |= (sign_a == sign_b) & (sign_a != sign_r);
         return r;
     }
 }

 static CYTHON_INLINE {{INT}} __Pyx_add_const_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow) {
     if (b > 0) {
         *overflow |= a > __PYX_MAX({{INT}}) - b;
     } else if (b < 0) {
         *overflow |= a < __PYX_MIN({{INT}}) - b;
     }
     return a + b;
 }

 static CYTHON_INLINE {{INT}} __Pyx_sub_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow) {
     *overflow |= b == __PYX_MIN({{INT}});
     return __Pyx_add_{{NAME}}_checking_overflow(a, -b, overflow);
 }

 static CYTHON_INLINE {{INT}} __Pyx_sub_const_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow) {
     *overflow |= b == __PYX_MIN({{INT}});
     return __Pyx_add_const_{{NAME}}_checking_overflow(a, -b, overflow);
 }

 static CYTHON_INLINE {{INT}} __Pyx_mul_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow) {
     if (sizeof({{INT}}) < sizeof(long)) {
         long big_r = ((long) a) * ((long) b);
         {{INT}} r = ({{INT}}) big_r;
         *overflow |= big_r != r;
         return ({{INT}}) r;
     } else if (sizeof({{INT}}) < sizeof(long long)) {
         long long big_r = ((long long) a) * ((long long) b);
         {{INT}} r = ({{INT}}) big_r;
         *overflow |= big_r != r;
         return ({{INT}}) r;
     } else {
         {{INT}} prod = a * b;
         double dprod = ((double) a) * ((double) b);
         // Overflow results in an error of at least 2^sizeof(INT),
         // whereas rounding represents an error on the order of 2^(sizeof(INT)-53).
         *overflow |= fabs(dprod - prod) > (__PYX_MAX({{INT}}) / 2);
         return prod;
     }
 }

 static CYTHON_INLINE {{INT}} __Pyx_mul_const_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow) {
     if (b > 1) {
         *overflow |= a > __PYX_MAX({{INT}}) / b;
         *overflow |= a < __PYX_MIN({{INT}}) / b;
     } else if (b == -1) {
         *overflow |= a == __PYX_MIN({{INT}});
     } else if (b < -1) {
         *overflow |= a > __PYX_MIN({{INT}}) / b;
         *overflow |= a < __PYX_MAX({{INT}}) / b;
     }
     return a * b;
 }

 static CYTHON_INLINE {{INT}} __Pyx_div_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow) {
     if (b == 0) {
         *overflow |= 1;
         return 0;
     }
     *overflow |= (a == __PYX_MIN({{INT}})) & (b == -1);
     return a / b;
 }


 /////////////// SizeCheck.init ///////////////

 __Pyx_check_sane_{{NAME}}();

 /////////////// SizeCheck.proto ///////////////

 static int __Pyx_check_sane_{{NAME}}(void) {
     if (sizeof({{TYPE}}) <= sizeof(int) ||
         sizeof({{TYPE}}) == sizeof(long) ||
         sizeof({{TYPE}}) == sizeof(long long)) {
         return 0;
     } else {
         PyErr_Format(PyExc_RuntimeError, \
             "Bad size for int type %.{{max(60, len(TYPE))}}s: %d", "{{TYPE}}", (int) sizeof({{TYPE}}));
         return 1;
     }
 }


 /////////////// Binop.proto ///////////////

 static CYTHON_INLINE {{TYPE}} __Pyx_{{BINOP}}_{{NAME}}_checking_overflow({{TYPE}} a, {{TYPE}} b, int *overflow);

 /////////////// Binop ///////////////

 static CYTHON_INLINE {{TYPE}} __Pyx_{{BINOP}}_{{NAME}}_checking_overflow({{TYPE}} a, {{TYPE}} b, int *overflow) {
     if (sizeof({{TYPE}}) < sizeof(int)) {
         return __Pyx_{{BINOP}}_no_overflow(a, b, overflow);
     } else if (__PYX_IS_UNSIGNED({{TYPE}})) {
         if (sizeof({{TYPE}}) == sizeof(unsigned int)) {
             return __Pyx_{{BINOP}}_unsigned_int_checking_overflow(a, b, overflow);
         } else if (sizeof({{TYPE}}) == sizeof(unsigned long)) {
             return __Pyx_{{BINOP}}_unsigned_long_checking_overflow(a, b, overflow);
         } else if (sizeof({{TYPE}}) == sizeof(unsigned long long)) {
             return __Pyx_{{BINOP}}_unsigned_long_long_checking_overflow(a, b, overflow);
         } else {
             abort(); return 0; // handled elsewhere
         }
     } else {
         if (sizeof({{TYPE}}) == sizeof(int)) {
             return __Pyx_{{BINOP}}_int_checking_overflow(a, b, overflow);
         } else if (sizeof({{TYPE}}) == sizeof(long)) {
             return __Pyx_{{BINOP}}_long_checking_overflow(a, b, overflow);
         } else if (sizeof({{TYPE}}) == sizeof(long long)) {
             return __Pyx_{{BINOP}}_long_long_checking_overflow(a, b, overflow);
         } else {
             abort(); return 0; // handled elsewhere
         }
     }
 }

 /////////////// LeftShift.proto ///////////////

 static CYTHON_INLINE {{TYPE}} __Pyx_lshift_{{NAME}}_checking_overflow({{TYPE}} a, {{TYPE}} b, int *overflow) {
     *overflow |=
 #if {{SIGNED}}
         (b < 0) |
 #endif
         (b > ({{TYPE}}) (8 * sizeof({{TYPE}}))) | (a > (__PYX_MAX({{TYPE}}) >> b));
     return a << b;
 }
 #define __Pyx_lshift_const_{{NAME}}_checking_overflow __Pyx_lshift_{{NAME}}_checking_overflow
	/*
	These functions provide integer arithmetic with integer checking. They do not
	actually raise an exception when an overflow is detected, but rather set a bit
	in the overflow parameter. (This parameter may be re-used accross several
	arithmetic operations, so should be or-ed rather than assigned to.)

	The implementation is divided into two parts, the signed and unsigned basecases,
	which is where the magic happens, and a generic template matching a specific
	type to an implementation based on its (c-compile-time) size and signedness.

	When possible, branching is avoided, and preference is given to speed over
	accuracy (a low rate of falsely "detected" overflows are acceptable,
	undetected overflows are not).


	TODO: Hook up checking.
	TODO: Conditionally support 128-bit with intmax_t?
	*/

	/////////////// Common.proto ///////////////

	static int __Pyx_check_twos_complement(void) {
	if (-1 != ~0) {
	PyErr_SetString(PyExc_RuntimeError, "Two's complement required for overflow checks.");
	return 1;
	} else if (sizeof(short) == sizeof(int)) {
	PyErr_SetString(PyExc_RuntimeError, "sizeof(short) < sizeof(int) required for overflow checks.");
	return 1;
	} else {
	return 0;
	}
	}

	#define __PYX_IS_UNSIGNED(type) (((type) -1) > 0)
	#define __PYX_SIGN_BIT(type) (((unsigned type) 1) << (sizeof(type) * 8 - 1))
	#define __PYX_HALF_MAX(type) (((type) 1) << (sizeof(type) * 8 - 2))
	#define __PYX_MIN(type) (__PYX_IS_UNSIGNED(type) ? (type) 0 : 0 - __PYX_HALF_MAX(type) - __PYX_HALF_MAX(type))
	#define __PYX_MAX(type) (~__PYX_MIN(type))

	#define __Pyx_add_no_overflow(a, b, overflow) ((a) + (b))
	#define __Pyx_add_const_no_overflow(a, b, overflow) ((a) + (b))
	#define __Pyx_sub_no_overflow(a, b, overflow) ((a) - (b))
	#define __Pyx_sub_const_no_overflow(a, b, overflow) ((a) - (b))
	#define __Pyx_mul_no_overflow(a, b, overflow) ((a) * (b))
	#define __Pyx_mul_const_no_overflow(a, b, overflow) ((a) * (b))
	#define __Pyx_div_no_overflow(a, b, overflow) ((a) / (b))
	#define __Pyx_div_const_no_overflow(a, b, overflow) ((a) / (b))

	/////////////// Common.init ///////////////

	__Pyx_check_twos_complement();

	/////////////// BaseCaseUnsigned.proto ///////////////

	static CYTHON_INLINE {{UINT}} __Pyx_add_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow);
	static CYTHON_INLINE {{UINT}} __Pyx_sub_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow);
	static CYTHON_INLINE {{UINT}} __Pyx_mul_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow);
	static CYTHON_INLINE {{UINT}} __Pyx_div_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow);

	// Use these when b is known at compile time.
	#define __Pyx_add_const_{{NAME}}_checking_overflow __Pyx_add_{{NAME}}_checking_overflow
	#define __Pyx_sub_const_{{NAME}}_checking_overflow __Pyx_sub_{{NAME}}_checking_overflow
	static CYTHON_INLINE {{UINT}} __Pyx_mul_const_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} constant, int *overflow);
	#define __Pyx_div_const_{{NAME}}_checking_overflow __Pyx_div_{{NAME}}_checking_overflow

	/////////////// BaseCaseUnsigned ///////////////

	static CYTHON_INLINE {{UINT}} __Pyx_add_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow) {
	{{UINT}} r = a + b;
	*overflow \|= r < a;
	return r;
	}

	static CYTHON_INLINE {{UINT}} __Pyx_sub_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow) {
	{{UINT}} r = a - b;
	*overflow \|= r > a;
	return r;
	}

	static CYTHON_INLINE {{UINT}} __Pyx_mul_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow) {
	if (sizeof({{UINT}}) < sizeof(unsigned long)) {
	unsigned long big_r = ((unsigned long) a) * ((unsigned long) b);
	{{UINT}} r = ({{UINT}}) big_r;
	*overflow \|= big_r != r;
	return r;
	} else if (sizeof({{UINT}}) < sizeof(unsigned long long)) {
	unsigned long long big_r = ((unsigned long long) a) * ((unsigned long long) b);
	{{UINT}} r = ({{UINT}}) big_r;
	*overflow \|= big_r != r;
	return r;
	} else {
	{{UINT}} prod = a * b;
	double dprod = ((double) a) * ((double) b);
	// Overflow results in an error of at least 2^sizeof(UINT),
	// whereas rounding represents an error on the order of 2^(sizeof(UINT)-53).
	*overflow \|= fabs(dprod - prod) > (__PYX_MAX({{UINT}}) / 2);
	return prod;
	}
	}

	static CYTHON_INLINE {{UINT}} __Pyx_mul_const_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow) {
	if (b > 1) {
	*overflow \|= a > __PYX_MAX({{UINT}}) / b;
	}
	return a * b;
	}


	static CYTHON_INLINE {{UINT}} __Pyx_div_{{NAME}}_checking_overflow({{UINT}} a, {{UINT}} b, int *overflow) {
	if (b == 0) {
	*overflow \|= 1;
	return 0;
	}
	return a / b;
	}


	/////////////// BaseCaseSigned.proto ///////////////

	static CYTHON_INLINE {{INT}} __Pyx_add_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow);
	static CYTHON_INLINE {{INT}} __Pyx_sub_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow);
	static CYTHON_INLINE {{INT}} __Pyx_mul_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow);
	static CYTHON_INLINE {{INT}} __Pyx_div_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow);


	// Use when b is known at compile time.
	static CYTHON_INLINE {{INT}} __Pyx_add_const_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow);
	static CYTHON_INLINE {{INT}} __Pyx_sub_const_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow);
	static CYTHON_INLINE {{INT}} __Pyx_mul_const_{{NAME}}_checking_overflow({{INT}} a, {{INT}} constant, int *overflow);
	#define __Pyx_div_const_{{NAME}}_checking_overflow __Pyx_div_{{NAME}}_checking_overflow

	/////////////// BaseCaseSigned ///////////////

	static CYTHON_INLINE {{INT}} __Pyx_add_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow) {
	if (sizeof({{INT}}) < sizeof(long)) {
	long big_r = ((long) a) + ((long) b);
	{{INT}} r = ({{INT}}) big_r;
	*overflow \|= big_r != r;
	return r;
	} else if (sizeof({{INT}}) < sizeof(long long)) {
	long long big_r = ((long long) a) + ((long long) b);
	{{INT}} r = ({{INT}}) big_r;
	*overflow \|= big_r != r;
	return r;
	} else {
	// Signed overflow undefined, but unsigned overflow is well defined.
	{{INT}} r = ({{INT}}) ((unsigned {{INT}}) a + (unsigned {{INT}}) b);
	// Overflow happened if the operands have the same sign, but the result
	// has opposite sign.
	// sign(a) == sign(b) != sign(r)
	{{INT}} sign_a = __PYX_SIGN_BIT({{INT}}) & a;
	{{INT}} sign_b = __PYX_SIGN_BIT({{INT}}) & b;
	{{INT}} sign_r = __PYX_SIGN_BIT({{INT}}) & r;
	*overflow \|= (sign_a == sign_b) & (sign_a != sign_r);
	return r;
	}
	}

	static CYTHON_INLINE {{INT}} __Pyx_add_const_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow) {
	if (b > 0) {
	*overflow \|= a > __PYX_MAX({{INT}}) - b;
	} else if (b < 0) {
	*overflow \|= a < __PYX_MIN({{INT}}) - b;
	}
	return a + b;
	}

	static CYTHON_INLINE {{INT}} __Pyx_sub_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow) {
	*overflow \|= b == __PYX_MIN({{INT}});
	return __Pyx_add_{{NAME}}_checking_overflow(a, -b, overflow);
	}

	static CYTHON_INLINE {{INT}} __Pyx_sub_const_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow) {
	*overflow \|= b == __PYX_MIN({{INT}});
	return __Pyx_add_const_{{NAME}}_checking_overflow(a, -b, overflow);
	}

	static CYTHON_INLINE {{INT}} __Pyx_mul_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow) {
	if (sizeof({{INT}}) < sizeof(long)) {
	long big_r = ((long) a) * ((long) b);
	{{INT}} r = ({{INT}}) big_r;
	*overflow \|= big_r != r;
	return ({{INT}}) r;
	} else if (sizeof({{INT}}) < sizeof(long long)) {
	long long big_r = ((long long) a) * ((long long) b);
	{{INT}} r = ({{INT}}) big_r;
	*overflow \|= big_r != r;
	return ({{INT}}) r;
	} else {
	{{INT}} prod = a * b;
	double dprod = ((double) a) * ((double) b);
	// Overflow results in an error of at least 2^sizeof(INT),
	// whereas rounding represents an error on the order of 2^(sizeof(INT)-53).
	*overflow \|= fabs(dprod - prod) > (__PYX_MAX({{INT}}) / 2);
	return prod;
	}
	}

	static CYTHON_INLINE {{INT}} __Pyx_mul_const_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow) {
	if (b > 1) {
	*overflow \|= a > __PYX_MAX({{INT}}) / b;
	*overflow \|= a < __PYX_MIN({{INT}}) / b;
	} else if (b == -1) {
	*overflow \|= a == __PYX_MIN({{INT}});
	} else if (b < -1) {
	*overflow \|= a > __PYX_MIN({{INT}}) / b;
	*overflow \|= a < __PYX_MAX({{INT}}) / b;
	}
	return a * b;
	}

	static CYTHON_INLINE {{INT}} __Pyx_div_{{NAME}}_checking_overflow({{INT}} a, {{INT}} b, int *overflow) {
	if (b == 0) {
	*overflow \|= 1;
	return 0;
	}
	*overflow \|= (a == __PYX_MIN({{INT}})) & (b == -1);
	return a / b;
	}


	/////////////// SizeCheck.init ///////////////

	__Pyx_check_sane_{{NAME}}();

	/////////////// SizeCheck.proto ///////////////

	static int __Pyx_check_sane_{{NAME}}(void) {
	if (sizeof({{TYPE}}) <= sizeof(int) \|\|
	sizeof({{TYPE}}) == sizeof(long) \|\|
	sizeof({{TYPE}}) == sizeof(long long)) {
	return 0;
	} else {
	PyErr_Format(PyExc_RuntimeError, \
	"Bad size for int type %.{{max(60, len(TYPE))}}s: %d", "{{TYPE}}", (int) sizeof({{TYPE}}));
	return 1;
	}
	}


	/////////////// Binop.proto ///////////////

	static CYTHON_INLINE {{TYPE}} __Pyx_{{BINOP}}_{{NAME}}_checking_overflow({{TYPE}} a, {{TYPE}} b, int *overflow);

	/////////////// Binop ///////////////

	static CYTHON_INLINE {{TYPE}} __Pyx_{{BINOP}}_{{NAME}}_checking_overflow({{TYPE}} a, {{TYPE}} b, int *overflow) {
	if (sizeof({{TYPE}}) < sizeof(int)) {
	return __Pyx_{{BINOP}}_no_overflow(a, b, overflow);
	} else if (__PYX_IS_UNSIGNED({{TYPE}})) {
	if (sizeof({{TYPE}}) == sizeof(unsigned int)) {
	return __Pyx_{{BINOP}}_unsigned_int_checking_overflow(a, b, overflow);
	} else if (sizeof({{TYPE}}) == sizeof(unsigned long)) {
	return __Pyx_{{BINOP}}_unsigned_long_checking_overflow(a, b, overflow);
	} else if (sizeof({{TYPE}}) == sizeof(unsigned long long)) {
	return __Pyx_{{BINOP}}_unsigned_long_long_checking_overflow(a, b, overflow);
	} else {
	abort(); return 0; // handled elsewhere
	}
	} else {
	if (sizeof({{TYPE}}) == sizeof(int)) {
	return __Pyx_{{BINOP}}_int_checking_overflow(a, b, overflow);
	} else if (sizeof({{TYPE}}) == sizeof(long)) {
	return __Pyx_{{BINOP}}_long_checking_overflow(a, b, overflow);
	} else if (sizeof({{TYPE}}) == sizeof(long long)) {
	return __Pyx_{{BINOP}}_long_long_checking_overflow(a, b, overflow);
	} else {
	abort(); return 0; // handled elsewhere
	}
	}
	}

	/////////////// LeftShift.proto ///////////////

	static CYTHON_INLINE {{TYPE}} __Pyx_lshift_{{NAME}}_checking_overflow({{TYPE}} a, {{TYPE}} b, int *overflow) {
	*overflow \|=
	#if {{SIGNED}}
	(b < 0) \|
	#endif
	(b > ({{TYPE}}) (8 * sizeof({{TYPE}}))) \| (a > (__PYX_MAX({{TYPE}}) >> b));
	return a << b;
	}
	#define __Pyx_lshift_const_{{NAME}}_checking_overflow __Pyx_lshift_{{NAME}}_checking_overflow