/src/opus/silk/resampler.c

Source
/***********************************************************************
Copyright (c) 2006-2011, Skype Limited. All rights reserved.
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.
- Neither the name of Internet Society, IETF or IETF Trust, nor the
names of specific contributors, may be used to endorse or promote
products derived from this software without specific prior written
permission.
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

/*
 * Matrix of resampling methods used:
 *                                 Fs_out (kHz)
 *                        8      12     16     24     48
 *
 *               8        C      UF     U      UF     UF
 *              12        AF     C      UF     U      UF
 * Fs_in (kHz)  16        D      AF     C      UF     UF
 *              24        AF     D      AF     C      U
 *              48        AF     AF     AF     D      C
 *
 * C   -> Copy (no resampling)
 * D   -> Allpass-based 2x downsampling
 * U   -> Allpass-based 2x upsampling
 * UF  -> Allpass-based 2x upsampling followed by FIR interpolation
 * AF  -> AR2 filter followed by FIR interpolation
 */

#include "resampler_private.h"

/* Tables with delay compensation values to equalize total delay for different modes */
static const opus_int8 delay_matrix_enc[ 6 ][ 3 ] = {
/* in  \ out  8  12  16 */
/*  8 */   {  6,  0,  3 },
/* 12 */   {  0,  7,  3 },
/* 16 */   {  0,  1, 10 },
/* 24 */   {  0,  2,  6 },
/* 48 */   { 18, 10, 12 },
/* 96 */   {  0,  0,  44 }
};

static const opus_int8 delay_matrix_dec[ 3 ][ 6 ] = {
/* in  \ out  8  12  16  24  48  96*/
/*  8 */   {  4,  0,  2,  0,  0,  0 },
/* 12 */   {  0,  9,  4,  7,  4,  4 },
/* 16 */   {  0,  3, 12,  7,  7,  7 }
};

/* Simple way to make [8000, 12000, 16000, 24000, 48000] to [0, 1, 2, 3, 4] */
#define rateID(R) IMIN(5, ( ( ( ((R)>>12) - ((R)>16000) ) >> ((R)>24000) ) - 1 ))

#define USE_silk_resampler_copy                     (0)
#define USE_silk_resampler_private_up2_HQ_wrapper   (1)
#define USE_silk_resampler_private_IIR_FIR          (2)
#define USE_silk_resampler_private_down_FIR         (3)

/* Initialize/reset the resampler state for a given pair of input/output sampling rates */
opus_int silk_resampler_init(
    silk_resampler_state_struct *S,                 /* I/O  Resampler state                                             */
    opus_int32                  Fs_Hz_in,           /* I    Input sampling rate (Hz)                                    */
    opus_int32                  Fs_Hz_out,          /* I    Output sampling rate (Hz)                                   */
    opus_int                    forEnc              /* I    If 1: encoder; if 0: decoder                                */
)
{
    opus_int up2x;

    /* Clear state */
    silk_memset( S, 0, sizeof( silk_resampler_state_struct ) );

    /* Input checking */
    if( forEnc ) {
        if( ( Fs_Hz_in  != 8000 && Fs_Hz_in  != 12000 && Fs_Hz_in  != 16000 && Fs_Hz_in  != 24000 && Fs_Hz_in  != 48000
#ifdef ENABLE_QEXT
                  && Fs_Hz_in != 96000
#endif
              ) ||
            ( Fs_Hz_out != 8000 && Fs_Hz_out != 12000 && Fs_Hz_out != 16000 ) ) {
            celt_assert( 0 );
            return -1;
        }
        S->inputDelay = delay_matrix_enc[ rateID( Fs_Hz_in ) ][ rateID( Fs_Hz_out ) ];
    } else {
        if( ( Fs_Hz_in  != 8000 && Fs_Hz_in  != 12000 && Fs_Hz_in  != 16000 ) ||
            ( Fs_Hz_out != 8000 && Fs_Hz_out != 12000 && Fs_Hz_out != 16000 && Fs_Hz_out != 24000 && Fs_Hz_out != 48000
#ifdef ENABLE_QEXT
                  && Fs_Hz_out != 96000
#endif
                  ) ) {
            celt_assert( 0 );
            return -1;
        }
        S->inputDelay = delay_matrix_dec[ rateID( Fs_Hz_in ) ][ rateID( Fs_Hz_out ) ];
    }

    S->Fs_in_kHz  = silk_DIV32_16( Fs_Hz_in,  1000 );
    S->Fs_out_kHz = silk_DIV32_16( Fs_Hz_out, 1000 );

    /* Number of samples processed per batch */
    S->batchSize = S->Fs_in_kHz * RESAMPLER_MAX_BATCH_SIZE_MS;

    /* Find resampler with the right sampling ratio */
    up2x = 0;
    if( Fs_Hz_out > Fs_Hz_in ) {
        /* Upsample */
        if( Fs_Hz_out == silk_MUL( Fs_Hz_in, 2 ) ) {                            /* Fs_out : Fs_in = 2 : 1 */
            /* Special case: directly use 2x upsampler */
            S->resampler_function = USE_silk_resampler_private_up2_HQ_wrapper;
        } else {
            /* Default resampler */
            S->resampler_function = USE_silk_resampler_private_IIR_FIR;
            up2x = 1;
        }
    } else if ( Fs_Hz_out < Fs_Hz_in ) {
        /* Downsample */
         S->resampler_function = USE_silk_resampler_private_down_FIR;
        if( silk_MUL( Fs_Hz_out, 4 ) == silk_MUL( Fs_Hz_in, 3 ) ) {             /* Fs_out : Fs_in = 3 : 4 */
            S->FIR_Fracs = 3;
            S->FIR_Order = RESAMPLER_DOWN_ORDER_FIR0;
            S->Coefs = silk_Resampler_3_4_COEFS;
        } else if( silk_MUL( Fs_Hz_out, 3 ) == silk_MUL( Fs_Hz_in, 2 ) ) {      /* Fs_out : Fs_in = 2 : 3 */
            S->FIR_Fracs = 2;
            S->FIR_Order = RESAMPLER_DOWN_ORDER_FIR0;
            S->Coefs = silk_Resampler_2_3_COEFS;
        } else if( silk_MUL( Fs_Hz_out, 2 ) == Fs_Hz_in ) {                     /* Fs_out : Fs_in = 1 : 2 */
            S->FIR_Fracs = 1;
            S->FIR_Order = RESAMPLER_DOWN_ORDER_FIR1;
            S->Coefs = silk_Resampler_1_2_COEFS;
        } else if( silk_MUL( Fs_Hz_out, 3 ) == Fs_Hz_in ) {                     /* Fs_out : Fs_in = 1 : 3 */
            S->FIR_Fracs = 1;
            S->FIR_Order = RESAMPLER_DOWN_ORDER_FIR2;
            S->Coefs = silk_Resampler_1_3_COEFS;
        } else if( silk_MUL( Fs_Hz_out, 4 ) == Fs_Hz_in ) {                     /* Fs_out : Fs_in = 1 : 4 */
            S->FIR_Fracs = 1;
            S->FIR_Order = RESAMPLER_DOWN_ORDER_FIR2;
            S->Coefs = silk_Resampler_1_4_COEFS;
        } else if( silk_MUL( Fs_Hz_out, 6 ) == Fs_Hz_in ) {                     /* Fs_out : Fs_in = 1 : 6 */
            S->FIR_Fracs = 1;
            S->FIR_Order = RESAMPLER_DOWN_ORDER_FIR2;
            S->Coefs = silk_Resampler_1_6_COEFS;
        } else {
            /* None available */
            celt_assert( 0 );
            return -1;
        }
    } else {
        /* Input and output sampling rates are equal: copy */
        S->resampler_function = USE_silk_resampler_copy;
    }

    /* Ratio of input/output samples */
    S->invRatio_Q16 = silk_LSHIFT32( silk_DIV32( silk_LSHIFT32( Fs_Hz_in, 14 + up2x ), Fs_Hz_out ), 2 );
    /* Make sure the ratio is rounded up */
    while( silk_SMULWW( S->invRatio_Q16, Fs_Hz_out ) < silk_LSHIFT32( Fs_Hz_in, up2x ) ) {
        S->invRatio_Q16++;
    }

    return 0;
}

/* Resampler: convert from one sampling rate to another */
/* Input and output sampling rate are at most 48000 Hz  */
opus_int silk_resampler(
    silk_resampler_state_struct *S,                 /* I/O  Resampler state                                             */
    opus_int16                  out[],              /* O    Output signal                                               */
    const opus_int16            in[],               /* I    Input signal                                                */
    opus_int32                  inLen               /* I    Number of input samples                                     */
)
{
    opus_int nSamples;

    /* Need at least 1 ms of input data */
    celt_assert( inLen >= S->Fs_in_kHz );
    /* Delay can't exceed the 1 ms of buffering */
    celt_assert( S->inputDelay <= S->Fs_in_kHz );

    nSamples = S->Fs_in_kHz - S->inputDelay;

    /* Copy to delay buffer */
    silk_memcpy( &S->delayBuf[ S->inputDelay ], in, nSamples * sizeof( opus_int16 ) );

    switch( S->resampler_function ) {
        case USE_silk_resampler_private_up2_HQ_wrapper:
            silk_resampler_private_up2_HQ_wrapper( S, out, S->delayBuf, S->Fs_in_kHz );
            silk_resampler_private_up2_HQ_wrapper( S, &out[ S->Fs_out_kHz ], &in[ nSamples ], inLen - S->Fs_in_kHz );
            break;
        case USE_silk_resampler_private_IIR_FIR:
            silk_resampler_private_IIR_FIR( S, out, S->delayBuf, S->Fs_in_kHz );
            silk_resampler_private_IIR_FIR( S, &out[ S->Fs_out_kHz ], &in[ nSamples ], inLen - S->Fs_in_kHz );
            break;
        case USE_silk_resampler_private_down_FIR:
            silk_resampler_private_down_FIR( S, out, S->delayBuf, S->Fs_in_kHz );
            silk_resampler_private_down_FIR( S, &out[ S->Fs_out_kHz ], &in[ nSamples ], inLen - S->Fs_in_kHz );
            break;
        default:
            silk_memcpy( out, S->delayBuf, S->Fs_in_kHz * sizeof( opus_int16 ) );
            silk_memcpy( &out[ S->Fs_out_kHz ], &in[ nSamples ], ( inLen - S->Fs_in_kHz ) * sizeof( opus_int16 ) );
    }

    /* Copy to delay buffer */
    silk_memcpy( S->delayBuf, &in[ inLen - S->inputDelay ], S->inputDelay * sizeof( opus_int16 ) );

    return 0;
}

Coverage Report

Created: 2026-01-17 07:44

Line	Count	Source
1		/***********************************************************************
2		Copyright (c) 2006-2011, Skype Limited. All rights reserved.
3		Redistribution and use in source and binary forms, with or without
4		modification, are permitted provided that the following conditions
5		are met:
6		- Redistributions of source code must retain the above copyright notice,
7		this list of conditions and the following disclaimer.
8		- Redistributions in binary form must reproduce the above copyright
9		notice, this list of conditions and the following disclaimer in the
10		documentation and/or other materials provided with the distribution.
11		- Neither the name of Internet Society, IETF or IETF Trust, nor the
12		names of specific contributors, may be used to endorse or promote
13		products derived from this software without specific prior written
14		permission.
15		THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
16		AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
17		IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
18		ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
19		LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
20		CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
21		SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
22		INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
23		CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
24		ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
25		POSSIBILITY OF SUCH DAMAGE.
26		***********************************************************************/
27
28		#ifdef HAVE_CONFIG_H
29		#include "config.h"
30		#endif
31
32		/*
33		* Matrix of resampling methods used:
34		* Fs_out (kHz)
35		* 8 12 16 24 48
36		*
37		* 8 C UF U UF UF
38		* 12 AF C UF U UF
39		* Fs_in (kHz) 16 D AF C UF UF
40		* 24 AF D AF C U
41		* 48 AF AF AF D C
42		*
43		* C -> Copy (no resampling)
44		* D -> Allpass-based 2x downsampling
45		* U -> Allpass-based 2x upsampling
46		* UF -> Allpass-based 2x upsampling followed by FIR interpolation
47		* AF -> AR2 filter followed by FIR interpolation
48		*/
49
50		#include "resampler_private.h"
51
52		/* Tables with delay compensation values to equalize total delay for different modes */
53		static const opus_int8 delay_matrix_enc[ 6 ][ 3 ] = {
54		/* in \ out 8 12 16 */
55		/* 8 */ { 6, 0, 3 },
56		/* 12 */ { 0, 7, 3 },
57		/* 16 */ { 0, 1, 10 },
58		/* 24 */ { 0, 2, 6 },
59		/* 48 */ { 18, 10, 12 },
60		/* 96 */ { 0, 0, 44 }
61		};
62
63		static const opus_int8 delay_matrix_dec[ 3 ][ 6 ] = {
64		/* in \ out 8 12 16 24 48 96*/
65		/* 8 */ { 4, 0, 2, 0, 0, 0 },
66		/* 12 */ { 0, 9, 4, 7, 4, 4 },
67		/* 16 */ { 0, 3, 12, 7, 7, 7 }
68		};
69
70		/* Simple way to make [8000, 12000, 16000, 24000, 48000] to [0, 1, 2, 3, 4] */
71	9.38k	#define rateID(R) IMIN(5, ( ( ( ((R)>>12) - ((R)>16000) ) >> ((R)>24000) ) - 1 ))
72
73	2.08k	#define USE_silk_resampler_copy (0)
74	74	#define USE_silk_resampler_private_up2_HQ_wrapper (1)
75	96	#define USE_silk_resampler_private_IIR_FIR (2)
76	13.2M	#define USE_silk_resampler_private_down_FIR (3)
77
78		/* Initialize/reset the resampler state for a given pair of input/output sampling rates */
79		opus_int silk_resampler_init(
80		silk_resampler_state_struct S, / I/O Resampler state */
81		opus_int32 Fs_Hz_in, /* I Input sampling rate (Hz) */
82		opus_int32 Fs_Hz_out, /* I Output sampling rate (Hz) */
83		opus_int forEnc /* I If 1: encoder; if 0: decoder */
84		)
85	4.69k	{
86	4.69k	opus_int up2x;
87
88		/* Clear state */
89	4.69k	silk_memset( S, 0, sizeof( silk_resampler_state_struct ) );
90
91		/* Input checking */
92	4.69k	if( forEnc ) {
93	4.60k	if( ( Fs_Hz_in != 8000 && Fs_Hz_in != 12000 && Fs_Hz_in != 16000 && Fs_Hz_in != 24000 && Fs_Hz_in != 48000
94		#ifdef ENABLE_QEXT
95		&& Fs_Hz_in != 96000
96		#endif
97	4.60k	) \|\|
98	4.60k	( Fs_Hz_out != 8000 && Fs_Hz_out != 12000 && Fs_Hz_out != 16000 ) ) {
99	0	celt_assert( 0 );
100	0	return -1;
101	0	}
102	4.60k	S->inputDelay = delay_matrix_enc[ rateID( Fs_Hz_in ) ][ rateID( Fs_Hz_out ) ];
103	4.60k	} else {
104	85	if( ( Fs_Hz_in != 8000 && Fs_Hz_in != 12000 && Fs_Hz_in != 16000 ) \|\|
105	85	( Fs_Hz_out != 8000 && Fs_Hz_out != 12000 && Fs_Hz_out != 16000 && Fs_Hz_out != 24000 && Fs_Hz_out != 48000
106		#ifdef ENABLE_QEXT
107		&& Fs_Hz_out != 96000
108		#endif
109	85	) ) {
110	0	celt_assert( 0 );
111	0	return -1;
112	0	}
113	85	S->inputDelay = delay_matrix_dec[ rateID( Fs_Hz_in ) ][ rateID( Fs_Hz_out ) ];
114	85	}
115
116	4.69k	S->Fs_in_kHz = silk_DIV32_16( Fs_Hz_in, 1000 );
117	4.69k	S->Fs_out_kHz = silk_DIV32_16( Fs_Hz_out, 1000 );
118
119		/* Number of samples processed per batch */
120	4.69k	S->batchSize = S->Fs_in_kHz * RESAMPLER_MAX_BATCH_SIZE_MS;
121
122		/* Find resampler with the right sampling ratio */
123	4.69k	up2x = 0;
124	4.69k	if( Fs_Hz_out > Fs_Hz_in ) {
125		/* Upsample */
126	85	if( Fs_Hz_out == silk_MUL( Fs_Hz_in, 2 ) ) { /* Fs_out : Fs_in = 2 : 1 */
127		/* Special case: directly use 2x upsampler */
128	37	S->resampler_function = USE_silk_resampler_private_up2_HQ_wrapper;
129	48	} else {
130		/* Default resampler */
131	48	S->resampler_function = USE_silk_resampler_private_IIR_FIR;
132	48	up2x = 1;
133	48	}
134	4.60k	} else if ( Fs_Hz_out < Fs_Hz_in ) {
135		/* Downsample */
136	2.52k	S->resampler_function = USE_silk_resampler_private_down_FIR;
137	2.52k	if( silk_MUL( Fs_Hz_out, 4 ) == silk_MUL( Fs_Hz_in, 3 ) ) { /* Fs_out : Fs_in = 3 : 4 */
138	244	S->FIR_Fracs = 3;
139	244	S->FIR_Order = RESAMPLER_DOWN_ORDER_FIR0;
140	244	S->Coefs = silk_Resampler_3_4_COEFS;
141	2.28k	} else if( silk_MUL( Fs_Hz_out, 3 ) == silk_MUL( Fs_Hz_in, 2 ) ) { /* Fs_out : Fs_in = 2 : 3 */
142	800	S->FIR_Fracs = 2;
143	800	S->FIR_Order = RESAMPLER_DOWN_ORDER_FIR0;
144	800	S->Coefs = silk_Resampler_2_3_COEFS;
145	1.48k	} else if( silk_MUL( Fs_Hz_out, 2 ) == Fs_Hz_in ) { /* Fs_out : Fs_in = 1 : 2 */
146	547	S->FIR_Fracs = 1;
147	547	S->FIR_Order = RESAMPLER_DOWN_ORDER_FIR1;
148	547	S->Coefs = silk_Resampler_1_2_COEFS;
149	935	} else if( silk_MUL( Fs_Hz_out, 3 ) == Fs_Hz_in ) { /* Fs_out : Fs_in = 1 : 3 */
150	576	S->FIR_Fracs = 1;
151	576	S->FIR_Order = RESAMPLER_DOWN_ORDER_FIR2;
152	576	S->Coefs = silk_Resampler_1_3_COEFS;
153	576	} else if( silk_MUL( Fs_Hz_out, 4 ) == Fs_Hz_in ) { /* Fs_out : Fs_in = 1 : 4 */
154	106	S->FIR_Fracs = 1;
155	106	S->FIR_Order = RESAMPLER_DOWN_ORDER_FIR2;
156	106	S->Coefs = silk_Resampler_1_4_COEFS;
157	253	} else if( silk_MUL( Fs_Hz_out, 6 ) == Fs_Hz_in ) { /* Fs_out : Fs_in = 1 : 6 */
158	253	S->FIR_Fracs = 1;
159	253	S->FIR_Order = RESAMPLER_DOWN_ORDER_FIR2;
160	253	S->Coefs = silk_Resampler_1_6_COEFS;
161	253	} else {
162		/* None available */
163	0	celt_assert( 0 );
164	0	return -1;
165	0	}
166	2.52k	} else {
167		/* Input and output sampling rates are equal: copy */
168	2.08k	S->resampler_function = USE_silk_resampler_copy;
169	2.08k	}
170
171		/* Ratio of input/output samples */
172	4.69k	S->invRatio_Q16 = silk_LSHIFT32( silk_DIV32( silk_LSHIFT32( Fs_Hz_in, 14 + up2x ), Fs_Hz_out ), 2 );
173		/* Make sure the ratio is rounded up */
174	5.27k	while( silk_SMULWW( S->invRatio_Q16, Fs_Hz_out ) < silk_LSHIFT32( Fs_Hz_in, up2x ) ) {
175	576	S->invRatio_Q16++;
176	576	}
177
178	4.69k	return 0;
179	4.69k	}
180
181		/* Resampler: convert from one sampling rate to another */
182		/* Input and output sampling rate are at most 48000 Hz */
183		opus_int silk_resampler(
184		silk_resampler_state_struct S, / I/O Resampler state */
185		opus_int16 out[], /* O Output signal */
186		const opus_int16 in[], /* I Input signal */
187		opus_int32 inLen /* I Number of input samples */
188		)
189	28.2M	{
190	28.2M	opus_int nSamples;
191
192		/* Need at least 1 ms of input data */
193	28.2M	celt_assert( inLen >= S->Fs_in_kHz );
194		/* Delay can't exceed the 1 ms of buffering */
195	28.2M	celt_assert( S->inputDelay <= S->Fs_in_kHz );
196
197	28.2M	nSamples = S->Fs_in_kHz - S->inputDelay;
198
199		/* Copy to delay buffer */
200	28.2M	silk_memcpy( &S->delayBuf[ S->inputDelay ], in, nSamples * sizeof( opus_int16 ) );
201
202	28.2M	switch( S->resampler_function ) {
203	37	case USE_silk_resampler_private_up2_HQ_wrapper:
204	37	silk_resampler_private_up2_HQ_wrapper( S, out, S->delayBuf, S->Fs_in_kHz );
205	37	silk_resampler_private_up2_HQ_wrapper( S, &out[ S->Fs_out_kHz ], &in[ nSamples ], inLen - S->Fs_in_kHz );
206	37	break;
207	48	case USE_silk_resampler_private_IIR_FIR:
208	48	silk_resampler_private_IIR_FIR( S, out, S->delayBuf, S->Fs_in_kHz );
209	48	silk_resampler_private_IIR_FIR( S, &out[ S->Fs_out_kHz ], &in[ nSamples ], inLen - S->Fs_in_kHz );
210	48	break;
211	13.2M	case USE_silk_resampler_private_down_FIR:
212	13.2M	silk_resampler_private_down_FIR( S, out, S->delayBuf, S->Fs_in_kHz );
213	13.2M	silk_resampler_private_down_FIR( S, &out[ S->Fs_out_kHz ], &in[ nSamples ], inLen - S->Fs_in_kHz );
214	13.2M	break;
215	14.9M	default:
216	14.9M	silk_memcpy( out, S->delayBuf, S->Fs_in_kHz * sizeof( opus_int16 ) );
217	14.9M	silk_memcpy( &out[ S->Fs_out_kHz ], &in[ nSamples ], ( inLen - S->Fs_in_kHz ) * sizeof( opus_int16 ) );
218	28.2M	}
219
220		/* Copy to delay buffer */
221	28.2M	silk_memcpy( S->delayBuf, &in[ inLen - S->inputDelay ], S->inputDelay * sizeof( opus_int16 ) );
222
223	28.2M	return 0;
224	28.2M	}