/src/opus/celt/mathops.c

Source
/* Copyright (c) 2002-2008 Jean-Marc Valin
   Copyright (c) 2007-2008 CSIRO
   Copyright (c) 2007-2009 Xiph.Org Foundation
   Copyright (c) 2024 Arm Limited
   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 HAVE_CONFIG_H
#include "config.h"
#endif

#include "float_cast.h"
#include "mathops.h"

/*Compute floor(sqrt(_val)) with exact arithmetic.
  _val must be greater than 0.
  This has been tested on all possible 32-bit inputs greater than 0.*/
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<<bshift;
  do{
    opus_uint32 t;
    t=(((opus_uint32)g<<1)+b)<<bshift;
    if(t<=_val){
      g+=b;
      _val-=t;
    }
    b>>=1;
    bshift--;
  }
  while(bshift>=0);
  return g;
}

#ifdef FIXED_POINT

opus_val32 frac_div32_q29(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));
   return result;
}

opus_val32 frac_div32(opus_val32 a, opus_val32 b) {
   opus_val32 result = frac_div32_q29(a,b);
   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))));
}

/** Reciprocal sqrt approximation in the range [0.25,1) (Q31 in, Q29 out) */
opus_val32 celt_rsqrt_norm32(opus_val32 x)
{
   opus_int32 tmp;
   /* Use the first-order Newton-Raphson method to refine the root estimate.
    * r = r * (1.5 - 0.5*x*r*r) */
   opus_int32 r_q29 = SHL32(celt_rsqrt_norm(SHR32(x, 31-16)), 15);
   /* Split evaluation in steps to avoid exploding macro expansion. */
   tmp = MULT32_32_Q31(r_q29, r_q29);
   tmp = MULT32_32_Q31(1073741824 /* Q31 */, tmp);
   tmp = MULT32_32_Q31(x, tmp);
   return SHL32(MULT32_32_Q31(r_q29, SUB32(201326592 /* Q27 */, tmp)), 4);
}

/** Sqrt approximation (QX input, QX/2 output) */
opus_val32 celt_sqrt(opus_val32 x)
{
   int k;
   opus_val16 n;
   opus_val32 rt;
   /* These coeffs are optimized in fixed-point to minimize both RMS and max error
      of sqrt(x) over .25<x<1 without exceeding 32767.
      The RMS error is 3.4e-5 and the max is 8.2e-5. */
   static const opus_val16 C[6] = {23171, 11574, -2901, 1592, -1002, 336};
   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 = ADD32(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, ADD16(C[4], MULT16_16_Q15(n, (C[5])))))))))));
   rt = VSHR32(rt,7-k);
   return rt;
}

/* Perform fixed-point arithmetic to approximate the square root. When the input
 * is in Qx format, the output will be in Q(x/2 + 16) format. */
opus_val32 celt_sqrt32(opus_val32 x)
{
   int k;
   opus_int32 x_frac;
   if (x==0)
      return 0;
   else if (x>=1073741824)
      return 2147483647; /* 2^31 -1 */
   k = (celt_ilog2(x)>>1);
   x_frac = VSHR32(x, 2*(k-14)-1);
   x_frac = MULT32_32_Q31(celt_rsqrt_norm32(x_frac), x_frac);
   if (k < 12) return PSHR32(x_frac, 12-k);
   else return SHL32(x_frac, k-12);
}

#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 (x<SHL32(EXTEND32(1), 15))
      {
         return _celt_cos_pi_2(EXTRACT16(x));
      } else {
         return NEG16(_celt_cos_pi_2(EXTRACT16(65536-x)));
      }
   } else {
      if (x&0x0000ffff)
         return 0;
      else if (x&0x0001ffff)
         return -32767;
      else
         return 32767;
   }
}

/* Calculates the cosine of (PI*0.5*x) where the input x ranges from -1 to 1 and
 * is in Q30 format. The output will also be in Q31 format. */
opus_val32 celt_cos_norm32(opus_val32 x)
{
   static const opus_val32 COS_NORM_COEFF_A0 = 134217720;   /* Q27 */
   static const opus_val32 COS_NORM_COEFF_A1 = -662336704;  /* Q29 */
   static const opus_val32 COS_NORM_COEFF_A2 = 544710848;   /* Q31 */
   static const opus_val32 COS_NORM_COEFF_A3 = -178761936;  /* Q33 */
   static const opus_val32 COS_NORM_COEFF_A4 = 29487206;    /* Q35 */
   opus_int32 x_sq_q29, tmp;
   /* The expected x is in the range of [-1.0f, 1.0f] */
   celt_sig_assert((x >= -1073741824) && (x <= 1073741824));
   /* Make cos(+/- pi/2) exactly zero. */
   if (ABS32(x) == 1<<30) return 0;
   x_sq_q29 = MULT32_32_Q31(x, x);
   /* Split evaluation in steps to avoid exploding macro expansion. */
   tmp = ADD32(COS_NORM_COEFF_A3, MULT32_32_Q31(x_sq_q29, COS_NORM_COEFF_A4));
   tmp = ADD32(COS_NORM_COEFF_A2, MULT32_32_Q31(x_sq_q29, tmp));
   tmp = ADD32(COS_NORM_COEFF_A1, MULT32_32_Q31(x_sq_q29, tmp));
   return SHL32(ADD32(COS_NORM_COEFF_A0, MULT32_32_Q31(x_sq_q29, tmp)), 4);
}

/* Computes a 16 bit approximate reciprocal (1/x) for a normalized Q15 input,
 * resulting in a Q15 output. */
opus_val16 celt_rcp_norm16(opus_val16 x)
{
   opus_val16 r;
   /* 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, x));
   /* Perform two Newton iterations:
      r -= r*((r*n)+(r-1.Q15))
         = r*((r*n)+(r-1.Q15)). */
   r = SUB16(r, MULT16_16_Q15(r,
             ADD16(MULT16_16_Q15(r, x), 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. */
   return SUB16(r, ADD16(1, MULT16_16_Q15(r,
                ADD16(MULT16_16_Q15(r, x), ADD16(r, -32768)))));
}

/* Computes a 32 bit approximated reciprocal (1/x) for a normalized Q31 input,
 * resulting in a Q30 output. The expected input range is [0.5f, 1.0f) in Q31
 * and the expected output range is [1.0f, 2.0f) in Q30. */
opus_val32 celt_rcp_norm32(opus_val32 x)
{
   opus_val32 r_q30;
   celt_sig_assert(x >= 1073741824);
   r_q30 = SHL32(EXTEND32(celt_rcp_norm16(SHR32(x, 15)-32768)), 16);
   /* Solving f(y) = a - 1/y using the Newton Method
    * Note: f(y)' = 1/y^2
    * r = r - f(r)/f(r)' = r - (x * r*r - r)
    *   = r - r*(r*x - 1)
    * where
    *   - r means 1/y's approximation.
    *   - x means a, the input of function.
    * Please note that:
    *   - It adds 1 to avoid overflow
    *   - -1.0f in Q30 is -1073741824. */
   return SUB32(r_q30, ADD32(SHL32(
                MULT32_32_Q31(ADD32(MULT32_32_Q31(r_q30, x), -1073741824),
                              r_q30), 1), 1));
}

/** Reciprocal approximation (Q15 input, Q16 output) */
opus_val32 celt_rcp(opus_val32 x)
{
   int i;
   opus_val16 r;
   celt_sig_assert(x>0);
   i = celt_ilog2(x);

   /* Compute the reciprocal of a Q15 number in the range [0, 1). */
   r = celt_rcp_norm16(VSHR32(x,i-15)-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

#ifndef DISABLE_FLOAT_API

void celt_float2int16_c(const float * OPUS_RESTRICT in, short * OPUS_RESTRICT out, int cnt)
{
   int i;
   for (i = 0; i < cnt; i++)
   {
      out[i] = FLOAT2INT16(in[i]);
   }
}

int opus_limit2_checkwithin1_c(float * samples, int cnt)
{
   int i;
   if (cnt <= 0)
   {
      return 1;
   }

   for (i = 0; i < cnt; i++)
   {
      float clippedVal = samples[i];
      clippedVal = FMAX(-2.0f, clippedVal);
      clippedVal = FMIN(2.0f, clippedVal);
      samples[i] = clippedVal;
   }

   /* C implementation can't provide quick hint. Assume it might exceed -1/+1. */
   return 0;
}

#endif /* DISABLE_FLOAT_API */

Coverage Report

Created: 2026-04-12 08:01

Line	Count	Source
1		/* Copyright (c) 2002-2008 Jean-Marc Valin
2		Copyright (c) 2007-2008 CSIRO
3		Copyright (c) 2007-2009 Xiph.Org Foundation
4		Copyright (c) 2024 Arm Limited
5		Written by Jean-Marc Valin */
6		/**
7		@file mathops.h
8		@brief Various math functions
9		*/
10		/*
11		Redistribution and use in source and binary forms, with or without
12		modification, are permitted provided that the following conditions
13		are met:
14
15		- Redistributions of source code must retain the above copyright
16		notice, this list of conditions and the following disclaimer.
17
18		- Redistributions in binary form must reproduce the above copyright
19		notice, this list of conditions and the following disclaimer in the
20		documentation and/or other materials provided with the distribution.
21
22		THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
23		``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
24		LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
25		A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER
26		OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
27		EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
28		PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
29		PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
30		LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
31		NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
32		SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
33		*/
34
35		#ifdef HAVE_CONFIG_H
36		#include "config.h"
37		#endif
38
39		#include "float_cast.h"
40		#include "mathops.h"
41
42		/*Compute floor(sqrt(_val)) with exact arithmetic.
43		_val must be greater than 0.
44		This has been tested on all possible 32-bit inputs greater than 0.*/
45	0	unsigned isqrt32(opus_uint32 _val){
46	0	unsigned b;
47	0	unsigned g;
48	0	int bshift;
49		/*Uses the second method from
50		http://www.azillionmonkeys.com/qed/sqroot.html
51		The main idea is to search for the largest binary digit b such that
52		(g+b)(g+b) <= _val, and add it to the solution g./
53	0	g=0;
54	0	bshift=(EC_ILOG(_val)-1)>>1;
55	0	b=1U<<bshift;
56	0	do{
57	0	opus_uint32 t;
58	0	t=(((opus_uint32)g<<1)+b)<<bshift;
59	0	if(t<=_val){
60	0	g+=b;
61	0	_val-=t;
62	0	}
63	0	b>>=1;
64	0	bshift--;
65	0	}
66	0	while(bshift>=0);
67	0	return g;
68	0	}
69
70		#ifdef FIXED_POINT
71
72		opus_val32 frac_div32_q29(opus_val32 a, opus_val32 b)
73	68.9M	{
74	68.9M	opus_val16 rcp;
75	68.9M	opus_val32 result, rem;
76	68.9M	int shift = celt_ilog2(b)-29;
77	68.9M	a = VSHR32(a,shift);
78	68.9M	b = VSHR32(b,shift);
79		/* 16-bit reciprocal */
80	68.9M	rcp = ROUND16(celt_rcp(ROUND16(b,16)),3);
81	68.9M	result = MULT16_32_Q15(rcp, a);
82	68.9M	rem = PSHR32(a,2)-MULT32_32_Q31(result, b);
83	68.9M	result = ADD32(result, SHL32(MULT16_32_Q15(rcp, rem),2));
84	68.9M	return result;
85	68.9M	}
86
87	66.1M	opus_val32 frac_div32(opus_val32 a, opus_val32 b) {
88	66.1M	opus_val32 result = frac_div32_q29(a,b);
89	66.1M	if (result >= 536870912) /* 2^29 */
90	1.45M	return 2147483647; /* 2^31 - 1 */
91	64.7M	else if (result <= -536870912) /* -2^29 */
92	0	return -2147483647; /* -2^31 */
93	64.7M	else
94	64.7M	return SHL32(result, 2);
95	66.1M	}
96
97		/** Reciprocal sqrt approximation in the range [0.25,1) (Q16 in, Q14 out) */
98		opus_val16 celt_rsqrt_norm(opus_val32 x)
99	607M	{
100	607M	opus_val16 n;
101	607M	opus_val16 r;
102	607M	opus_val16 r2;
103	607M	opus_val16 y;
104		/* Range of n is [-16384,32767] ([-0.5,1) in Q15). */
105	607M	n = x-32768;
106		/* Get a rough initial guess for the root.
107		The optimal minimax quadratic approximation (using relative error) is
108		r = 1.437799046117536+n(-0.823394375837328+n0.4096419668459485).
109		Coefficients here, and the final result r, are Q14.*/
110	607M	r = ADD16(23557, MULT16_16_Q15(n, ADD16(-13490, MULT16_16_Q15(n, 6713))));
111		/* We want y = xrr-1 in Q15, but x is 32-bit Q16 and r is Q14.
112		We can compute the result from n and r using Q15 multiplies with some
113		adjustment, carefully done to avoid overflow.
114		Range of y is [-1564,1594]. */
115	607M	r2 = MULT16_16_Q15(r, r);
116	607M	y = SHL16(SUB16(ADD16(MULT16_16_Q15(r2, n), r2), 16384), 1);
117		/* Apply a 2nd-order Householder iteration: r += ry(y*0.375-0.5).
118		This yields the Q14 reciprocal square root of the Q16 x, with a maximum
119		relative error of 1.04956E-4, a (relative) RMSE of 2.80979E-5, and a
120		peak absolute error of 2.26591/16384. */
121	607M	return ADD16(r, MULT16_16_Q15(r, MULT16_16_Q15(y,
122	607M	SUB16(MULT16_16_Q15(y, 12288), 16384))));
123	607M	}
124
125		/** Reciprocal sqrt approximation in the range [0.25,1) (Q31 in, Q29 out) */
126		opus_val32 celt_rsqrt_norm32(opus_val32 x)
127	533M	{
128	533M	opus_int32 tmp;
129		/* Use the first-order Newton-Raphson method to refine the root estimate.
130		* r = r * (1.5 - 0.5xrr) /
131	533M	opus_int32 r_q29 = SHL32(celt_rsqrt_norm(SHR32(x, 31-16)), 15);
132		/* Split evaluation in steps to avoid exploding macro expansion. */
133	533M	tmp = MULT32_32_Q31(r_q29, r_q29);
134	533M	tmp = MULT32_32_Q31(1073741824 /* Q31 */, tmp);
135	533M	tmp = MULT32_32_Q31(x, tmp);
136	533M	return SHL32(MULT32_32_Q31(r_q29, SUB32(201326592 /* Q27 */, tmp)), 4);
137	533M	}
138
139		/** Sqrt approximation (QX input, QX/2 output) */
140		opus_val32 celt_sqrt(opus_val32 x)
141	367M	{
142	367M	int k;
143	367M	opus_val16 n;
144	367M	opus_val32 rt;
145		/* These coeffs are optimized in fixed-point to minimize both RMS and max error
146		of sqrt(x) over .25<x<1 without exceeding 32767.
147		The RMS error is 3.4e-5 and the max is 8.2e-5. */
148	367M	static const opus_val16 C[6] = {23171, 11574, -2901, 1592, -1002, 336};
149	367M	if (x==0)
150	86.0M	return 0;
151	281M	else if (x>=1073741824)
152	121k	return 32767;
153	281M	k = (celt_ilog2(x)>>1)-7;
154	281M	x = VSHR32(x, 2*k);
155	281M	n = x-32768;
156	281M	rt = ADD32(C[0], MULT16_16_Q15(n, ADD16(C[1], MULT16_16_Q15(n, ADD16(C[2],
157	281M	MULT16_16_Q15(n, ADD16(C[3], MULT16_16_Q15(n, ADD16(C[4], MULT16_16_Q15(n, (C[5])))))))))));
158	281M	rt = VSHR32(rt,7-k);
159	281M	return rt;
160	367M	}
161
162		/* Perform fixed-point arithmetic to approximate the square root. When the input
163		* is in Qx format, the output will be in Q(x/2 + 16) format. */
164		opus_val32 celt_sqrt32(opus_val32 x)
165	857M	{
166	857M	int k;
167	857M	opus_int32 x_frac;
168	857M	if (x==0)
169	467M	return 0;
170	389M	else if (x>=1073741824)
171	0	return 2147483647; /* 2^31 -1 */
172	389M	k = (celt_ilog2(x)>>1);
173	389M	x_frac = VSHR32(x, 2*(k-14)-1);
174	389M	x_frac = MULT32_32_Q31(celt_rsqrt_norm32(x_frac), x_frac);
175	389M	if (k < 12) return PSHR32(x_frac, 12-k);
176	370M	else return SHL32(x_frac, k-12);
177	389M	}
178
179		#define L1 32767
180		#define L2 -7651
181		#define L3 8277
182		#define L4 -626
183
184		static OPUS_INLINE opus_val16 _celt_cos_pi_2(opus_val16 x)
185	24.1M	{
186	24.1M	opus_val16 x2;
187
188	24.1M	x2 = MULT16_16_P15(x,x);
189	24.1M	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
190	24.1M	))))))));
191	24.1M	}
192
193		#undef L1
194		#undef L2
195		#undef L3
196		#undef L4
197
198		opus_val16 celt_cos_norm(opus_val32 x)
199	24.1M	{
200	24.1M	x = x&0x0001ffff;
201	24.1M	if (x>SHL32(EXTEND32(1), 16))
202	0	x = SUB32(SHL32(EXTEND32(1), 17),x);
203	24.1M	if (x&0x00007fff)
204	24.1M	{
205	24.1M	if (x<SHL32(EXTEND32(1), 15))
206	24.1M	{
207	24.1M	return _celt_cos_pi_2(EXTRACT16(x));
208	24.1M	} else {
209	0	return NEG16(_celt_cos_pi_2(EXTRACT16(65536-x)));
210	0	}
211	24.1M	} else {
212	0	if (x&0x0000ffff)
213	0	return 0;
214	0	else if (x&0x0001ffff)
215	0	return -32767;
216	0	else
217	0	return 32767;
218	0	}
219	24.1M	}
220
221		/* Calculates the cosine of (PI0.5x) where the input x ranges from -1 to 1 and
222		* is in Q30 format. The output will also be in Q31 format. */
223		opus_val32 celt_cos_norm32(opus_val32 x)
224	0	{
225	0	static const opus_val32 COS_NORM_COEFF_A0 = 134217720; /* Q27 */
226	0	static const opus_val32 COS_NORM_COEFF_A1 = -662336704; /* Q29 */
227	0	static const opus_val32 COS_NORM_COEFF_A2 = 544710848; /* Q31 */
228	0	static const opus_val32 COS_NORM_COEFF_A3 = -178761936; /* Q33 */
229	0	static const opus_val32 COS_NORM_COEFF_A4 = 29487206; /* Q35 */
230	0	opus_int32 x_sq_q29, tmp;
231		/* The expected x is in the range of [-1.0f, 1.0f] */
232	0	celt_sig_assert((x >= -1073741824) && (x <= 1073741824));
233		/* Make cos(+/- pi/2) exactly zero. */
234	0	if (ABS32(x) == 1<<30) return 0;
235	0	x_sq_q29 = MULT32_32_Q31(x, x);
236		/* Split evaluation in steps to avoid exploding macro expansion. */
237	0	tmp = ADD32(COS_NORM_COEFF_A3, MULT32_32_Q31(x_sq_q29, COS_NORM_COEFF_A4));
238	0	tmp = ADD32(COS_NORM_COEFF_A2, MULT32_32_Q31(x_sq_q29, tmp));
239	0	tmp = ADD32(COS_NORM_COEFF_A1, MULT32_32_Q31(x_sq_q29, tmp));
240	0	return SHL32(ADD32(COS_NORM_COEFF_A0, MULT32_32_Q31(x_sq_q29, tmp)), 4);
241	0	}
242
243		/* Computes a 16 bit approximate reciprocal (1/x) for a normalized Q15 input,
244		* resulting in a Q15 output. */
245		opus_val16 celt_rcp_norm16(opus_val16 x)
246	1.23G	{
247	1.23G	opus_val16 r;
248		/* Start with a linear approximation:
249		r = 1.8823529411764706-0.9411764705882353*n.
250		The coefficients and the result are Q14 in the range [15420,30840].*/
251	1.23G	r = ADD16(30840, MULT16_16_Q15(-15420, x));
252		/* Perform two Newton iterations:
253		r -= r((rn)+(r-1.Q15))
254		= r((rn)+(r-1.Q15)). */
255	1.23G	r = SUB16(r, MULT16_16_Q15(r,
256	1.23G	ADD16(MULT16_16_Q15(r, x), ADD16(r, -32768))));
257		/* We subtract an extra 1 in the second iteration to avoid overflow; it also
258		neatly compensates for truncation error in the rest of the process. */
259	1.23G	return SUB16(r, ADD16(1, MULT16_16_Q15(r,
260	1.23G	ADD16(MULT16_16_Q15(r, x), ADD16(r, -32768)))));
261	1.23G	}
262
263		/* Computes a 32 bit approximated reciprocal (1/x) for a normalized Q31 input,
264		* resulting in a Q30 output. The expected input range is [0.5f, 1.0f) in Q31
265		* and the expected output range is [1.0f, 2.0f) in Q30. */
266		opus_val32 celt_rcp_norm32(opus_val32 x)
267	933M	{
268	933M	opus_val32 r_q30;
269	933M	celt_sig_assert(x >= 1073741824);
270	933M	r_q30 = SHL32(EXTEND32(celt_rcp_norm16(SHR32(x, 15)-32768)), 16);
271		/* Solving f(y) = a - 1/y using the Newton Method
272		* Note: f(y)' = 1/y^2
273		* r = r - f(r)/f(r)' = r - (x * r*r - r)
274		* = r - r(rx - 1)
275		* where
276		* - r means 1/y's approximation.
277		* - x means a, the input of function.
278		* Please note that:
279		* - It adds 1 to avoid overflow
280		* - -1.0f in Q30 is -1073741824. */
281	933M	return SUB32(r_q30, ADD32(SHL32(
282	933M	MULT32_32_Q31(ADD32(MULT32_32_Q31(r_q30, x), -1073741824),
283	933M	r_q30), 1), 1));
284	933M	}
285
286		/** Reciprocal approximation (Q15 input, Q16 output) */
287		opus_val32 celt_rcp(opus_val32 x)
288	299M	{
289	299M	int i;
290	299M	opus_val16 r;
291	299M	celt_sig_assert(x>0);
292	299M	i = celt_ilog2(x);
293
294		/* Compute the reciprocal of a Q15 number in the range [0, 1). */
295	299M	r = celt_rcp_norm16(VSHR32(x,i-15)-32768);
296
297		/* r is now the Q15 solution to 2/(n+1), with a maximum relative error
298		of 7.05346E-5, a (relative) RMSE of 2.14418E-5, and a peak absolute
299		error of 1.24665/32768. */
300	299M	return VSHR32(EXTEND32(r),i-16);
301	299M	}
302
303		#endif
304
305		#ifndef DISABLE_FLOAT_API
306
307		void celt_float2int16_c(const float * OPUS_RESTRICT in, short * OPUS_RESTRICT out, int cnt)
308	0	{
309	0	int i;
310	0	for (i = 0; i < cnt; i++)
311	0	{
312	0	out[i] = FLOAT2INT16(in[i]);
313	0	}
314	0	}
315
316		int opus_limit2_checkwithin1_c(float * samples, int cnt)
317	0	{
318	0	int i;
319	0	if (cnt <= 0)
320	0	{
321	0	return 1;
322	0	}
323
324	0	for (i = 0; i < cnt; i++)
325	0	{
326	0	float clippedVal = samples[i];
327	0	clippedVal = FMAX(-2.0f, clippedVal);
328	0	clippedVal = FMIN(2.0f, clippedVal);
329	0	samples[i] = clippedVal;
330	0	}
331
332		/* C implementation can't provide quick hint. Assume it might exceed -1/+1. */
333	0	return 0;
334	0	}
335
336		#endif /* DISABLE_FLOAT_API */