1 /*
2  * Copyright (C) 2004-2010 NXP Software
3  * Copyright (C) 2010 The Android Open Source Project
4  *
5  * Licensed under the Apache License, Version 2.0 (the "License");
6  * you may not use this file except in compliance with the License.
7  * You may obtain a copy of the License at
8  *
9  *      http://www.apache.org/licenses/LICENSE-2.0
10  *
11  * Unless required by applicable law or agreed to in writing, software
12  * distributed under the License is distributed on an "AS IS" BASIS,
13  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
14  * See the License for the specific language governing permissions and
15  * limitations under the License.
16  */
17 
18 #include "BIQUAD.h"
19 #include "BQ_2I_D16F16Css_TRC_WRA_01_Private.h"
20 #include "LVM_Macros.h"
21 
22 /**************************************************************************
23  ASSUMPTIONS:
24  COEFS-
25  pBiquadState->coefs[0] is A2, pBiquadState->coefs[1] is A1
26  pBiquadState->coefs[2] is A0, pBiquadState->coefs[3] is -B2
27  pBiquadState->coefs[4] is -B1, these are in Q14 format
28 
29  DELAYS-
30  pBiquadState->pDelays[0] is x(n-1)L in Q0 format
31  pBiquadState->pDelays[1] is x(n-1)R in Q0 format
32  pBiquadState->pDelays[2] is x(n-2)L in Q0 format
33  pBiquadState->pDelays[3] is x(n-2)R in Q0 format
34  pBiquadState->pDelays[4] is y(n-1)L in Q0 format
35  pBiquadState->pDelays[5] is y(n-1)R in Q0 format
36  pBiquadState->pDelays[6] is y(n-2)L in Q0 format
37  pBiquadState->pDelays[7] is y(n-2)R in Q0 format
38 ***************************************************************************/
BQ_2I_D16F16C14_TRC_WRA_01(Biquad_FLOAT_Instance_t * pInstance,LVM_FLOAT * pDataIn,LVM_FLOAT * pDataOut,LVM_INT16 NrSamples)39 void BQ_2I_D16F16C14_TRC_WRA_01 ( Biquad_FLOAT_Instance_t       *pInstance,
40                                   LVM_FLOAT               *pDataIn,
41                                   LVM_FLOAT               *pDataOut,
42                                   LVM_INT16               NrSamples)
43     {
44         LVM_FLOAT  ynL,ynR;
45         LVM_INT16 ii;
46         PFilter_State_FLOAT pBiquadState = (PFilter_State_FLOAT) pInstance;
47 
48          for (ii = NrSamples; ii != 0; ii--)
49          {
50 
51             /**************************************************************************
52                             PROCESSING OF THE LEFT CHANNEL
53             ***************************************************************************/
54             // ynL=A2  * x(n-2)L
55             ynL = (LVM_FLOAT)pBiquadState->coefs[0] * pBiquadState->pDelays[2];
56 
57             // ynL+=A1  * x(n-1)L
58             ynL += (LVM_FLOAT)pBiquadState->coefs[1] * pBiquadState->pDelays[0];
59 
60             // ynL+=A0  * x(n)L
61             ynL += (LVM_FLOAT)pBiquadState->coefs[2] * (*pDataIn);
62 
63             // ynL+= ( -B2  * y(n-2)L  )
64             ynL += (LVM_FLOAT)pBiquadState->coefs[3] * pBiquadState->pDelays[6];
65 
66             // ynL+=( -B1  * y(n-1)L )
67             ynL += (LVM_FLOAT)pBiquadState->coefs[4] * pBiquadState->pDelays[4];
68 
69             /**************************************************************************
70                             PROCESSING OF THE RIGHT CHANNEL
71             ***************************************************************************/
72             // ynR=A2  * x(n-2)R
73             ynR = (LVM_FLOAT)pBiquadState->coefs[0] * pBiquadState->pDelays[3];
74 
75             // ynR+=A1  * x(n-1)R
76             ynR += (LVM_FLOAT)pBiquadState->coefs[1] * pBiquadState->pDelays[1];
77 
78             // ynR+=A0  * x(n)R
79             ynR += (LVM_FLOAT)pBiquadState->coefs[2] * (*(pDataIn+1));
80 
81             // ynR+= ( -B2  * y(n-2)R  )
82             ynR += (LVM_FLOAT)pBiquadState->coefs[3] * pBiquadState->pDelays[7];
83 
84             // ynR+=( -B1  * y(n-1)R  )
85             ynR += (LVM_FLOAT)pBiquadState->coefs[4] * pBiquadState->pDelays[5];
86 
87             /**************************************************************************
88                             UPDATING THE DELAYS
89             ***************************************************************************/
90             pBiquadState->pDelays[7] = pBiquadState->pDelays[5];  // y(n-2)R=y(n-1)R
91             pBiquadState->pDelays[6] = pBiquadState->pDelays[4];  // y(n-2)L=y(n-1)L
92             pBiquadState->pDelays[3] = pBiquadState->pDelays[1];  // x(n-2)R=x(n-1)R
93             pBiquadState->pDelays[2] = pBiquadState->pDelays[0];  // x(n-2)L=x(n-1)L
94             pBiquadState->pDelays[5] = ynR;                       // Update y(n-1)R
95             pBiquadState->pDelays[4] = ynL;                       // Update y(n-1)L
96             pBiquadState->pDelays[0] = (*pDataIn++);              // Update x(n-1)L
97             pBiquadState->pDelays[1] = (*pDataIn++);              // Update x(n-1)R
98 
99             /**************************************************************************
100                             WRITING THE OUTPUT
101             ***************************************************************************/
102             *pDataOut++ = (LVM_FLOAT)ynL; // Write Left output
103             *pDataOut++ = (LVM_FLOAT)ynR; // Write Right ouput
104 
105         }
106 
107     }
108