/* -*- Mode: c; tab-width: 8; c-basic-offset: 4; indent-tabs-mode: t; -*- */ /* Cairo - a vector graphics library with display and print output * * Copyright © 2007 Mozilla Corporation * * This library is free software; you can redistribute it and/or * modify it either under the terms of the GNU Lesser General Public * License version 2.1 as published by the Free Software Foundation * (the "LGPL") or, at your option, under the terms of the Mozilla * Public License Version 1.1 (the "MPL"). If you do not alter this * notice, a recipient may use your version of this file under either * the MPL or the LGPL. * * You should have received a copy of the LGPL along with this library * in the file COPYING-LGPL-2.1; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA * You should have received a copy of the MPL along with this library * in the file COPYING-MPL-1.1 * * The contents of this file are subject to the Mozilla Public License * Version 1.1 (the "License"); you may not use this file except in * compliance with the License. You may obtain a copy of the License at * http://www.mozilla.org/MPL/ * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY * OF ANY KIND, either express or implied. See the LGPL or the MPL for * the specific language governing rights and limitations. * * The Original Code is the cairo graphics library. * * The Initial Developer of the Original Code is Mozilla Corporation * * Contributor(s): * Vladimir Vukicevic */ #ifndef CAIRO_FIXED_PRIVATE_H #define CAIRO_FIXED_PRIVATE_H #include "cairo-fixed-type-private.h" #include "cairo-wideint-private.h" /* Implementation */ #if (CAIRO_FIXED_BITS != 32) # error CAIRO_FIXED_BITS must be 32, and the type must be a 32-bit type. # error To remove this limitation, you will have to fix the tesselator. #endif #define CAIRO_FIXED_ONE ((cairo_fixed_t)(1 << CAIRO_FIXED_FRAC_BITS)) #define CAIRO_FIXED_ONE_DOUBLE ((double)(1 << CAIRO_FIXED_FRAC_BITS)) #define CAIRO_FIXED_EPSILON ((cairo_fixed_t)(1)) #define CAIRO_FIXED_FRAC_MASK (((cairo_fixed_unsigned_t)(-1)) >> (CAIRO_FIXED_BITS - CAIRO_FIXED_FRAC_BITS)) #define CAIRO_FIXED_WHOLE_MASK (~CAIRO_FIXED_FRAC_MASK) static inline cairo_fixed_t _cairo_fixed_from_int (int i) { return i << CAIRO_FIXED_FRAC_BITS; } /* This is the "magic number" approach to converting a double into fixed * point as described here: * * http://www.stereopsis.com/sree/fpu2006.html (an overview) * http://www.d6.com/users/checker/pdfs/gdmfp.pdf (in detail) * * The basic idea is to add a large enough number to the double that the * literal floating point is moved up to the extent that it forces the * double's value to be shifted down to the bottom of the mantissa (to make * room for the large number being added in). Since the mantissa is, at a * given moment in time, a fixed point integer itself, one can convert a * float to various fixed point representations by moving around the point * of a floating point number through arithmetic operations. This behavior * is reliable on most modern platforms as it is mandated by the IEEE-754 * standard for floating point arithmetic. * * For our purposes, a "magic number" must be carefully selected that is * both large enough to produce the desired point-shifting effect, and also * has no lower bits in its representation that would interfere with our * value at the bottom of the mantissa. The magic number is calculated as * follows: * * (2 ^ (MANTISSA_SIZE - FRACTIONAL_SIZE)) * 1.5 * * where in our case: * - MANTISSA_SIZE for 64-bit doubles is 52 * - FRACTIONAL_SIZE for 16.16 fixed point is 16 * * Although this approach provides a very large speedup of this function * on a wide-array of systems, it does come with two caveats: * * 1) It uses banker's rounding as opposed to arithmetic rounding. * 2) It doesn't function properly if the FPU is in single-precision * mode. */ /* The 16.16 number must always be available */ #define CAIRO_MAGIC_NUMBER_FIXED_16_16 (103079215104.0) #if CAIRO_FIXED_BITS <= 32 #define CAIRO_MAGIC_NUMBER_FIXED ((1LL << (52 - CAIRO_FIXED_FRAC_BITS)) * 1.5) /* For 32-bit fixed point numbers */ static inline cairo_fixed_t _cairo_fixed_from_double (double d) { union { double d; int32_t i[2]; } u; u.d = d + CAIRO_MAGIC_NUMBER_FIXED; #ifdef FLOAT_WORDS_BIGENDIAN return u.i[1]; #else return u.i[0]; #endif } #else # error Please define a magic number for your fixed point type! # error See cairo-fixed-private.h for details. #endif static inline cairo_fixed_t _cairo_fixed_from_26_6 (uint32_t i) { #if CAIRO_FIXED_FRAC_BITS > 6 return i << (CAIRO_FIXED_FRAC_BITS - 6); #else return i >> (6 - CAIRO_FIXED_FRAC_BITS); #endif } static inline double _cairo_fixed_to_double (cairo_fixed_t f) { return ((double) f) / CAIRO_FIXED_ONE_DOUBLE; } static inline int _cairo_fixed_is_integer (cairo_fixed_t f) { return (f & CAIRO_FIXED_FRAC_MASK) == 0; } static inline int _cairo_fixed_integer_part (cairo_fixed_t f) { return f >> CAIRO_FIXED_FRAC_BITS; } static inline int _cairo_fixed_integer_floor (cairo_fixed_t f) { if (f >= 0) return f >> CAIRO_FIXED_FRAC_BITS; else return -((-f - 1) >> CAIRO_FIXED_FRAC_BITS) - 1; } static inline int _cairo_fixed_integer_ceil (cairo_fixed_t f) { if (f > 0) return ((f - 1)>>CAIRO_FIXED_FRAC_BITS) + 1; else return - (-f >> CAIRO_FIXED_FRAC_BITS); } /* A bunch of explicit 16.16 operators; we need these * to interface with pixman and other backends that require * 16.16 fixed point types. */ static inline cairo_fixed_16_16_t _cairo_fixed_to_16_16 (cairo_fixed_t f) { #if (CAIRO_FIXED_FRAC_BITS == 16) && (CAIRO_FIXED_BITS == 32) return f; #elif CAIRO_FIXED_FRAC_BITS > 16 /* We're just dropping the low bits, so we won't ever got over/underflow here */ return f >> (CAIRO_FIXED_FRAC_BITS - 16); #else cairo_fixed_16_16_t x; /* Handle overflow/underflow by clamping to the lowest/highest * value representable as 16.16 */ if ((f >> CAIRO_FIXED_FRAC_BITS) < INT16_MIN) { x = INT32_MIN; } else if ((f >> CAIRO_FIXED_FRAC_BITS) > INT16_MAX) { x = INT32_MAX; } else { x = f << (16 - CAIRO_FIXED_FRAC_BITS); } return x; #endif } static inline cairo_fixed_16_16_t _cairo_fixed_16_16_from_double (double d) { union { double d; int32_t i[2]; } u; u.d = d + CAIRO_MAGIC_NUMBER_FIXED_16_16; #ifdef FLOAT_WORDS_BIGENDIAN return u.i[1]; #else return u.i[0]; #endif } #if CAIRO_FIXED_BITS == 32 static inline cairo_fixed_t _cairo_fixed_mul (cairo_fixed_t a, cairo_fixed_t b) { cairo_int64_t temp = _cairo_int32x32_64_mul (a, b); return _cairo_int64_to_int32(_cairo_int64_rsl (temp, CAIRO_FIXED_FRAC_BITS)); } /* computes round (a * b / c) */ static inline cairo_fixed_t _cairo_fixed_mul_div (cairo_fixed_t a, cairo_fixed_t b, cairo_fixed_t c) { cairo_int64_t ab = _cairo_int32x32_64_mul (a, b); cairo_int64_t c64 = _cairo_int32_to_int64 (c); return _cairo_int64_to_int32 (_cairo_int64_divrem (ab, c64).quo); } /* computes floor (a * b / c) */ static inline cairo_fixed_t _cairo_fixed_mul_div_floor (cairo_fixed_t a, cairo_fixed_t b, cairo_fixed_t c) { return _cairo_int64_32_div (_cairo_int32x32_64_mul (a, b), c); } static inline cairo_fixed_t _cairo_edge_compute_intersection_y_for_x (const cairo_point_t *p1, const cairo_point_t *p2, cairo_fixed_t x) { cairo_fixed_t y, dx; if (x == p1->x) return p1->y; if (x == p2->x) return p2->y; y = p1->y; dx = p2->x - p1->x; if (dx != 0) y += _cairo_fixed_mul_div_floor (x - p1->x, p2->y - p1->y, dx); return y; } static inline cairo_fixed_t _cairo_edge_compute_intersection_x_for_y (const cairo_point_t *p1, const cairo_point_t *p2, cairo_fixed_t y) { cairo_fixed_t x, dy; if (y == p1->y) return p1->x; if (y == p2->y) return p2->x; x = p1->x; dy = p2->y - p1->y; if (dy != 0) x += _cairo_fixed_mul_div_floor (y - p1->y, p2->x - p1->x, dy); return x; } #else # error Please define multiplication and other operands for your fixed-point type size #endif #endif /* CAIRO_FIXED_PRIVATE_H */