1*8ec969ceSTreehugger Robot /* 2*8ec969ceSTreehugger Robot * Copyright 1992 by Jutta Degener and Carsten Bormann, Technische 3*8ec969ceSTreehugger Robot * Universitaet Berlin. See the accompanying file "COPYRIGHT" for 4*8ec969ceSTreehugger Robot * details. THERE IS ABSOLUTELY NO WARRANTY FOR THIS SOFTWARE. 5*8ec969ceSTreehugger Robot */ 6*8ec969ceSTreehugger Robot 7*8ec969ceSTreehugger Robot /* $Header: /tmp_amd/presto/export/kbs/jutta/src/gsm/RCS/preprocess.c,v 1.2 1994/05/10 20:18:45 jutta Exp $ */ 8*8ec969ceSTreehugger Robot 9*8ec969ceSTreehugger Robot #include <stdio.h> 10*8ec969ceSTreehugger Robot #include <assert.h> 11*8ec969ceSTreehugger Robot 12*8ec969ceSTreehugger Robot #include "private.h" 13*8ec969ceSTreehugger Robot 14*8ec969ceSTreehugger Robot #include "gsm.h" 15*8ec969ceSTreehugger Robot #include "proto.h" 16*8ec969ceSTreehugger Robot 17*8ec969ceSTreehugger Robot /* 4.2.0 .. 4.2.3 PREPROCESSING SECTION 18*8ec969ceSTreehugger Robot * 19*8ec969ceSTreehugger Robot * After A-law to linear conversion (or directly from the 20*8ec969ceSTreehugger Robot * Ato D converter) the following scaling is assumed for 21*8ec969ceSTreehugger Robot * input to the RPE-LTP algorithm: 22*8ec969ceSTreehugger Robot * 23*8ec969ceSTreehugger Robot * in: 0.1.....................12 24*8ec969ceSTreehugger Robot * S.v.v.v.v.v.v.v.v.v.v.v.v.*.*.* 25*8ec969ceSTreehugger Robot * 26*8ec969ceSTreehugger Robot * Where S is the sign bit, v a valid bit, and * a "don't care" bit. 27*8ec969ceSTreehugger Robot * The original signal is called sop[..] 28*8ec969ceSTreehugger Robot * 29*8ec969ceSTreehugger Robot * out: 0.1................... 12 30*8ec969ceSTreehugger Robot * S.S.v.v.v.v.v.v.v.v.v.v.v.v.0.0 31*8ec969ceSTreehugger Robot */ 32*8ec969ceSTreehugger Robot 33*8ec969ceSTreehugger Robot 34*8ec969ceSTreehugger Robot void Gsm_Preprocess P3((S, s, so), 35*8ec969ceSTreehugger Robot struct gsm_state * S, 36*8ec969ceSTreehugger Robot word * s, 37*8ec969ceSTreehugger Robot word * so ) /* [0..159] IN/OUT */ 38*8ec969ceSTreehugger Robot { 39*8ec969ceSTreehugger Robot 40*8ec969ceSTreehugger Robot word z1 = S->z1; 41*8ec969ceSTreehugger Robot longword L_z2 = S->L_z2; 42*8ec969ceSTreehugger Robot word mp = S->mp; 43*8ec969ceSTreehugger Robot 44*8ec969ceSTreehugger Robot word s1; 45*8ec969ceSTreehugger Robot longword L_s2; 46*8ec969ceSTreehugger Robot 47*8ec969ceSTreehugger Robot longword L_temp; 48*8ec969ceSTreehugger Robot 49*8ec969ceSTreehugger Robot word msp, lsp; 50*8ec969ceSTreehugger Robot word SO; 51*8ec969ceSTreehugger Robot 52*8ec969ceSTreehugger Robot longword ltmp; /* for ADD */ 53*8ec969ceSTreehugger Robot ulongword utmp; /* for L_ADD */ 54*8ec969ceSTreehugger Robot 55*8ec969ceSTreehugger Robot register int k = 160; 56*8ec969ceSTreehugger Robot 57*8ec969ceSTreehugger Robot while (k--) { 58*8ec969ceSTreehugger Robot 59*8ec969ceSTreehugger Robot /* 4.2.1 Downscaling of the input signal 60*8ec969ceSTreehugger Robot */ 61*8ec969ceSTreehugger Robot SO = SASR( *s, 3 ) << 2; 62*8ec969ceSTreehugger Robot s++; 63*8ec969ceSTreehugger Robot 64*8ec969ceSTreehugger Robot assert (SO >= -0x4000); /* downscaled by */ 65*8ec969ceSTreehugger Robot assert (SO <= 0x3FFC); /* previous routine. */ 66*8ec969ceSTreehugger Robot 67*8ec969ceSTreehugger Robot 68*8ec969ceSTreehugger Robot /* 4.2.2 Offset compensation 69*8ec969ceSTreehugger Robot * 70*8ec969ceSTreehugger Robot * This part implements a high-pass filter and requires extended 71*8ec969ceSTreehugger Robot * arithmetic precision for the recursive part of this filter. 72*8ec969ceSTreehugger Robot * The input of this procedure is the array so[0...159] and the 73*8ec969ceSTreehugger Robot * output the array sof[ 0...159 ]. 74*8ec969ceSTreehugger Robot */ 75*8ec969ceSTreehugger Robot /* Compute the non-recursive part 76*8ec969ceSTreehugger Robot */ 77*8ec969ceSTreehugger Robot 78*8ec969ceSTreehugger Robot s1 = SO - z1; /* s1 = gsm_sub( *so, z1 ); */ 79*8ec969ceSTreehugger Robot z1 = SO; 80*8ec969ceSTreehugger Robot 81*8ec969ceSTreehugger Robot assert(s1 != MIN_WORD); 82*8ec969ceSTreehugger Robot 83*8ec969ceSTreehugger Robot /* Compute the recursive part 84*8ec969ceSTreehugger Robot */ 85*8ec969ceSTreehugger Robot L_s2 = s1; 86*8ec969ceSTreehugger Robot L_s2 <<= 15; 87*8ec969ceSTreehugger Robot 88*8ec969ceSTreehugger Robot /* Execution of a 31 bv 16 bits multiplication 89*8ec969ceSTreehugger Robot */ 90*8ec969ceSTreehugger Robot 91*8ec969ceSTreehugger Robot msp = SASR( L_z2, 15 ); 92*8ec969ceSTreehugger Robot lsp = L_z2-((longword)msp<<15); /* gsm_L_sub(L_z2,(msp<<15)); */ 93*8ec969ceSTreehugger Robot 94*8ec969ceSTreehugger Robot L_s2 += GSM_MULT_R( lsp, 32735 ); 95*8ec969ceSTreehugger Robot L_temp = (longword)msp * 32735; /* GSM_L_MULT(msp,32735) >> 1;*/ 96*8ec969ceSTreehugger Robot L_z2 = GSM_L_ADD( L_temp, L_s2 ); 97*8ec969ceSTreehugger Robot 98*8ec969ceSTreehugger Robot /* Compute sof[k] with rounding 99*8ec969ceSTreehugger Robot */ 100*8ec969ceSTreehugger Robot L_temp = GSM_L_ADD( L_z2, 16384 ); 101*8ec969ceSTreehugger Robot 102*8ec969ceSTreehugger Robot /* 4.2.3 Preemphasis 103*8ec969ceSTreehugger Robot */ 104*8ec969ceSTreehugger Robot 105*8ec969ceSTreehugger Robot msp = GSM_MULT_R( mp, -28180 ); 106*8ec969ceSTreehugger Robot mp = SASR( L_temp, 15 ); 107*8ec969ceSTreehugger Robot *so++ = GSM_ADD( mp, msp ); 108*8ec969ceSTreehugger Robot } 109*8ec969ceSTreehugger Robot 110*8ec969ceSTreehugger Robot S->z1 = z1; 111*8ec969ceSTreehugger Robot S->L_z2 = L_z2; 112*8ec969ceSTreehugger Robot S->mp = mp; 113*8ec969ceSTreehugger Robot } 114