/* $OpenBSD: fpu_sqrt.c,v 1.5 2021/03/11 11:17:00 jsg Exp $ */ /* $NetBSD: fpu_sqrt.c,v 1.2 1994/11/20 20:52:46 deraadt Exp $ */ /* * Copyright (c) 1992, 1993 * The Regents of the University of California. All rights reserved. * * This software was developed by the Computer Systems Engineering group * at Lawrence Berkeley Laboratory under DARPA contract BG 91-66 and * contributed to Berkeley. * * All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Lawrence Berkeley Laboratory. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * @(#)fpu_sqrt.c 8.1 (Berkeley) 6/11/93 */ /* * Perform an FPU square root (return sqrt(x)). */ #include #include #include #include /* * Our task is to calculate the square root of a floating point number x0. * This number x normally has the form: * * exp * x = mant * 2 (where 1 <= mant < 2 and exp is an integer) * * This can be left as it stands, or the mantissa can be doubled and the * exponent decremented: * * exp-1 * x = (2 * mant) * 2 (where 2 <= 2 * mant < 4) * * If the exponent `exp' is even, the square root of the number is best * handled using the first form, and is by definition equal to: * * exp/2 * sqrt(x) = sqrt(mant) * 2 * * If exp is odd, on the other hand, it is convenient to use the second * form, giving: * * (exp-1)/2 * sqrt(x) = sqrt(2 * mant) * 2 * * In the first case, we have * * 1 <= mant < 2 * * and therefore * * sqrt(1) <= sqrt(mant) < sqrt(2) * * while in the second case we have * * 2 <= 2*mant < 4 * * and therefore * * sqrt(2) <= sqrt(2*mant) < sqrt(4) * * so that in any case, we are sure that * * sqrt(1) <= sqrt(n * mant) < sqrt(4), n = 1 or 2 * * or * * 1 <= sqrt(n * mant) < 2, n = 1 or 2. * * This root is therefore a properly formed mantissa for a floating * point number. The exponent of sqrt(x) is either exp/2 or (exp-1)/2 * as above. This leaves us with the problem of finding the square root * of a fixed-point number in the range [1..4). * * Though it may not be instantly obvious, the following square root * algorithm works for any integer x of an even number of bits, provided * that no overflows occur: * * let q = 0 * for k = NBITS-1 to 0 step -1 do -- for each digit in the answer... * x *= 2 -- multiply by radix, for next digit * if x >= 2q + 2^k then -- if adding 2^k does not * x -= 2q + 2^k -- exceed the correct root, * q += 2^k -- add 2^k and adjust x * fi * done * sqrt = q / 2^(NBITS/2) -- (and any remainder is in x) * * If NBITS is odd (so that k is initially even), we can just add another * zero bit at the top of x. Doing so means that q is not going to acquire * a 1 bit in the first trip around the loop (since x0 < 2^NBITS). If the * final value in x is not needed, or can be off by a factor of 2, this is * equivalent to moving the `x *= 2' step to the bottom of the loop: * * for k = NBITS-1 to 0 step -1 do if ... fi; x *= 2; done * * and the result q will then be sqrt(x0) * 2^floor(NBITS / 2). * (Since the algorithm is destructive on x, we will call x's initial * value, for which q is some power of two times its square root, x0.) * * If we insert a loop invariant y = 2q, we can then rewrite this using * C notation as: * * q = y = 0; x = x0; * for (k = NBITS; --k >= 0;) { * #if (NBITS is even) * x *= 2; * #endif * t = y + (1 << k); * if (x >= t) { * x -= t; * q += 1 << k; * y += 1 << (k + 1); * } * #if (NBITS is odd) * x *= 2; * #endif * } * * If x0 is fixed point, rather than an integer, we can simply alter the * scale factor between q and sqrt(x0). As it happens, we can easily arrange * for the scale factor to be 2**0 or 1, so that sqrt(x0) == q. * * In our case, however, x0 (and therefore x, y, q, and t) are multiword * integers, which adds some complication. But note that q is built one * bit at a time, from the top down, and is not used itself in the loop * (we use 2q as held in y instead). This means we can build our answer * in an integer, one word at a time, which saves a bit of work. Also, * since 1 << k is always a `new' bit in q, 1 << k and 1 << (k+1) are * `new' bits in y and we can set them with an `or' operation rather than * a full-blown multiword add. * * We are almost done, except for one snag. We must prove that none of our * intermediate calculations can overflow. We know that x0 is in [1..4) * and therefore the square root in q will be in [1..2), but what about x, * y, and t? * * We know that y = 2q at the beginning of each loop. (The relation only * fails temporarily while y and q are being updated.) Since q < 2, y < 4. * The sum in t can, in our case, be as much as y+(1<<1) = y+2 < 6, and. * Furthermore, we can prove with a bit of work that x never exceeds y by * more than 2, so that even after doubling, 0 <= x < 8. (This is left as * an exercise to the reader, mostly because I have become tired of working * on this comment.) * * If our floating point mantissas (which are of the form 1.frac) occupy * B+1 bits, our largest intermediary needs at most B+3 bits, or two extra. * In fact, we want even one more bit (for a carry, to avoid compares), or * three extra. There is a comment in fpu_emu.h reminding maintainers of * this, so we have some justification in assuming it. */ struct fpn * fpu_sqrt(fe) struct fpemu *fe; { register struct fpn *x = &fe->fe_f1; register u_int bit, q, tt; register u_int x0, x1, x2, x3; register u_int y0, y1, y2, y3; register u_int d0, d1, d2, d3; register int e; /* * Take care of special cases first. In order: * * sqrt(NaN) = NaN * sqrt(+0) = +0 * sqrt(-0) = -0 * sqrt(x < 0) = NaN (including sqrt(-Inf)) * sqrt(+Inf) = +Inf * * Then all that remains are numbers with mantissas in [1..2). */ if (ISNAN(x) || ISZERO(x)) return (x); if (x->fp_sign) return (fpu_newnan(fe)); if (ISINF(x)) return (x); /* * Calculate result exponent. As noted above, this may involve * doubling the mantissa. We will also need to double x each * time around the loop, so we define a macro for this here, and * we break out the multiword mantissa. */ #ifdef FPU_SHL1_BY_ADD #define DOUBLE_X { \ FPU_ADDS(x3, x3, x3); FPU_ADDCS(x2, x2, x2); \ FPU_ADDCS(x1, x1, x1); FPU_ADDC(x0, x0, x0); \ } #else #define DOUBLE_X { \ x0 = (x0 << 1) | (x1 >> 31); x1 = (x1 << 1) | (x2 >> 31); \ x2 = (x2 << 1) | (x3 >> 31); x3 <<= 1; \ } #endif #if (FP_NMANT & 1) != 0 # define ODD_DOUBLE DOUBLE_X # define EVEN_DOUBLE /* nothing */ #else # define ODD_DOUBLE /* nothing */ # define EVEN_DOUBLE DOUBLE_X #endif x0 = x->fp_mant[0]; x1 = x->fp_mant[1]; x2 = x->fp_mant[2]; x3 = x->fp_mant[3]; e = x->fp_exp; if (e & 1) /* exponent is odd; use sqrt(2mant) */ DOUBLE_X; /* THE FOLLOWING ASSUMES THAT RIGHT SHIFT DOES SIGN EXTENSION */ x->fp_exp = e >> 1; /* calculates (e&1 ? (e-1)/2 : e/2 */ /* * Now calculate the mantissa root. Since x is now in [1..4), * we know that the first trip around the loop will definitely * set the top bit in q, so we can do that manually and start * the loop at the next bit down instead. We must be sure to * double x correctly while doing the `known q=1.0'. * * We do this one mantissa-word at a time, as noted above, to * save work. To avoid `(1U << 31) << 1', we also do the top bit * outside of each per-word loop. * * The calculation `t = y + bit' breaks down into `t0 = y0, ..., * t3 = y3, t? |= bit' for the appropriate word. Since the bit * is always a `new' one, this means that three of the `t?'s are * just the corresponding `y?'; we use `#define's here for this. * The variable `tt' holds the actual `t?' variable. */ /* calculate q0 */ #define t0 tt bit = FP_1; EVEN_DOUBLE; /* if (x >= (t0 = y0 | bit)) { */ /* always true */ q = bit; x0 -= bit; y0 = bit << 1; /* } */ ODD_DOUBLE; while ((bit >>= 1) != 0) { /* for remaining bits in q0 */ EVEN_DOUBLE; t0 = y0 | bit; /* t = y + bit */ if (x0 >= t0) { /* if x >= t then */ x0 -= t0; /* x -= t */ q |= bit; /* q += bit */ y0 |= bit << 1; /* y += bit << 1 */ } ODD_DOUBLE; } x->fp_mant[0] = q; #undef t0 /* calculate q1. note (y0&1)==0. */ #define t0 y0 #define t1 tt q = 0; y1 = 0; bit = 1U << 31; EVEN_DOUBLE; t1 = bit; FPU_SUBS(d1, x1, t1); FPU_SUBC(d0, x0, t0); /* d = x - t */ if ((int)d0 >= 0) { /* if d >= 0 (i.e., x >= t) then */ x0 = d0, x1 = d1; /* x -= t */ q = bit; /* q += bit */ y0 |= 1; /* y += bit << 1 */ } ODD_DOUBLE; while ((bit >>= 1) != 0) { /* for remaining bits in q1 */ EVEN_DOUBLE; /* as before */ t1 = y1 | bit; FPU_SUBS(d1, x1, t1); FPU_SUBC(d0, x0, t0); if ((int)d0 >= 0) { x0 = d0, x1 = d1; q |= bit; y1 |= bit << 1; } ODD_DOUBLE; } x->fp_mant[1] = q; #undef t1 /* calculate q2. note (y1&1)==0; y0 (aka t0) is fixed. */ #define t1 y1 #define t2 tt q = 0; y2 = 0; bit = 1U << 31; EVEN_DOUBLE; t2 = bit; FPU_SUBS(d2, x2, t2); FPU_SUBCS(d1, x1, t1); FPU_SUBC(d0, x0, t0); if ((int)d0 >= 0) { x0 = d0, x1 = d1, x2 = d2; q |= bit; y1 |= 1; /* now t1, y1 are set in concrete */ } ODD_DOUBLE; while ((bit >>= 1) != 0) { EVEN_DOUBLE; t2 = y2 | bit; FPU_SUBS(d2, x2, t2); FPU_SUBCS(d1, x1, t1); FPU_SUBC(d0, x0, t0); if ((int)d0 >= 0) { x0 = d0, x1 = d1, x2 = d2; q |= bit; y2 |= bit << 1; } ODD_DOUBLE; } x->fp_mant[2] = q; #undef t2 /* calculate q3. y0, t0, y1, t1 all fixed; y2, t2, almost done. */ #define t2 y2 #define t3 tt q = 0; y3 = 0; bit = 1U << 31; EVEN_DOUBLE; t3 = bit; FPU_SUBS(d3, x3, t3); FPU_SUBCS(d2, x2, t2); FPU_SUBCS(d1, x1, t1); FPU_SUBC(d0, x0, t0); if ((int)d0 >= 0) { x0 = d0, x1 = d1, x2 = d2, x3 = d3; q |= bit; y2 |= 1; } ODD_DOUBLE; while ((bit >>= 1) != 0) { EVEN_DOUBLE; t3 = y3 | bit; FPU_SUBS(d3, x3, t3); FPU_SUBCS(d2, x2, t2); FPU_SUBCS(d1, x1, t1); FPU_SUBC(d0, x0, t0); if ((int)d0 >= 0) { x0 = d0, x1 = d1, x2 = d2, x3 = d3; q |= bit; y3 |= bit << 1; } ODD_DOUBLE; } x->fp_mant[3] = q; /* * The result, which includes guard and round bits, is exact iff * x is now zero; any nonzero bits in x represent sticky bits. */ x->fp_sticky = x0 | x1 | x2 | x3; return (x); }