/* Copyright (c) 2002-2008 Jean-Marc Valin Copyright (c) 2007-2008 CSIRO Copyright (c) 2007-2009 Xiph.Org Foundation Written by Jean-Marc Valin */ /** @file mathops.h @brief Various math functions */ /* Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: - Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. - 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. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS 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 COPYRIGHT OWNER 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. */ #ifdef OPUS_ENABLED #include "opus/opus_config.h" #endif #include "opus/celt/mathops.h" /*Compute floor(sqrt(_val)) with exact arithmetic. This has been tested on all possible 32-bit inputs.*/ unsigned isqrt32(opus_uint32 _val){ unsigned b; unsigned g; int bshift; /*Uses the second method from http://www.azillionmonkeys.com/qed/sqroot.html The main idea is to search for the largest binary digit b such that (g+b)*(g+b) <= _val, and add it to the solution g.*/ g=0; bshift=(EC_ILOG(_val)-1)>>1; b=1U<>=1; bshift--; } while(bshift>=0); return g; } #ifdef OPUS_FIXED_POINT opus_val32 frac_div32(opus_val32 a, opus_val32 b) { opus_val16 rcp; opus_val32 result, rem; int shift = celt_ilog2(b)-29; a = VSHR32(a,shift); b = VSHR32(b,shift); /* 16-bit reciprocal */ rcp = ROUND16(celt_rcp(ROUND16(b,16)),3); result = MULT16_32_Q15(rcp, a); rem = PSHR32(a,2)-MULT32_32_Q31(result, b); result = ADD32(result, SHL32(MULT16_32_Q15(rcp, rem),2)); if (result >= 536870912) /* 2^29 */ return 2147483647; /* 2^31 - 1 */ else if (result <= -536870912) /* -2^29 */ return -2147483647; /* -2^31 */ else return SHL32(result, 2); } /** Reciprocal sqrt approximation in the range [0.25,1) (Q16 in, Q14 out) */ opus_val16 celt_rsqrt_norm(opus_val32 x) { opus_val16 n; opus_val16 r; opus_val16 r2; opus_val16 y; /* Range of n is [-16384,32767] ([-0.5,1) in Q15). */ n = x-32768; /* Get a rough initial guess for the root. The optimal minimax quadratic approximation (using relative error) is r = 1.437799046117536+n*(-0.823394375837328+n*0.4096419668459485). Coefficients here, and the final result r, are Q14.*/ r = ADD16(23557, MULT16_16_Q15(n, ADD16(-13490, MULT16_16_Q15(n, 6713)))); /* We want y = x*r*r-1 in Q15, but x is 32-bit Q16 and r is Q14. We can compute the result from n and r using Q15 multiplies with some adjustment, carefully done to avoid overflow. Range of y is [-1564,1594]. */ r2 = MULT16_16_Q15(r, r); y = SHL16(SUB16(ADD16(MULT16_16_Q15(r2, n), r2), 16384), 1); /* Apply a 2nd-order Householder iteration: r += r*y*(y*0.375-0.5). This yields the Q14 reciprocal square root of the Q16 x, with a maximum relative error of 1.04956E-4, a (relative) RMSE of 2.80979E-5, and a peak absolute error of 2.26591/16384. */ return ADD16(r, MULT16_16_Q15(r, MULT16_16_Q15(y, SUB16(MULT16_16_Q15(y, 12288), 16384)))); } /** Sqrt approximation (QX input, QX/2 output) */ opus_val32 celt_sqrt(opus_val32 x) { int k; opus_val16 n; opus_val32 rt; static const opus_val16 C[5] = {23175, 11561, -3011, 1699, -664}; if (x==0) return 0; else if (x>=1073741824) return 32767; k = (celt_ilog2(x)>>1)-7; x = VSHR32(x, 2*k); n = x-32768; rt = ADD16(C[0], MULT16_16_Q15(n, ADD16(C[1], MULT16_16_Q15(n, ADD16(C[2], MULT16_16_Q15(n, ADD16(C[3], MULT16_16_Q15(n, (C[4]))))))))); rt = VSHR32(rt,7-k); return rt; } #define L1 32767 #define L2 -7651 #define L3 8277 #define L4 -626 static OPUS_INLINE opus_val16 _celt_cos_pi_2(opus_val16 x) { opus_val16 x2; x2 = MULT16_16_P15(x,x); return ADD16(1,MIN16(32766,ADD32(SUB16(L1,x2), MULT16_16_P15(x2, ADD32(L2, MULT16_16_P15(x2, ADD32(L3, MULT16_16_P15(L4, x2 )))))))); } #undef L1 #undef L2 #undef L3 #undef L4 opus_val16 celt_cos_norm(opus_val32 x) { x = x&0x0001ffff; if (x>SHL32(EXTEND32(1), 16)) x = SUB32(SHL32(EXTEND32(1), 17),x); if (x&0x00007fff) { if (x0, "celt_rcp() only defined for positive values"); i = celt_ilog2(x); /* n is Q15 with range [0,1). */ n = VSHR32(x,i-15)-32768; /* Start with a linear approximation: r = 1.8823529411764706-0.9411764705882353*n. The coefficients and the result are Q14 in the range [15420,30840].*/ r = ADD16(30840, MULT16_16_Q15(-15420, n)); /* Perform two Newton iterations: r -= r*((r*n)-1.Q15) = r*((r*n)+(r-1.Q15)). */ r = SUB16(r, MULT16_16_Q15(r, ADD16(MULT16_16_Q15(r, n), ADD16(r, -32768)))); /* We subtract an extra 1 in the second iteration to avoid overflow; it also neatly compensates for truncation error in the rest of the process. */ r = SUB16(r, ADD16(1, MULT16_16_Q15(r, ADD16(MULT16_16_Q15(r, n), ADD16(r, -32768))))); /* r is now the Q15 solution to 2/(n+1), with a maximum relative error of 7.05346E-5, a (relative) RMSE of 2.14418E-5, and a peak absolute error of 1.24665/32768. */ return VSHR32(EXTEND32(r),i-16); } #endif