FreeCalypso > hg > gsmhr-codec-ref
view utils.c @ 2:aa7cc4333d95
Makefile: suppress some of the noise
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Fri, 14 Jun 2024 23:57:53 +0000 |
parents | 9008dbc8ca74 |
children |
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/*___________________________________________________________________________ | | | | | Residual Error Insertion Device | | | | | | File : REID.C | | | | Date : February 03, 1995 | | | | Version: 4.1 | | | | | | Description: | | ------------ | | This routine transforms the output file format of the GSM Half | | Rate Encoder module consisting of: | | * 18 speech parameters (see GSM TS 06.20) | | * 1 speech flag SP (see GSM TS 06.41) | | * 1 voice activity flag VAD (see GSM TS 06.42) | | | | to the input file format of the GSM Half Rate Decoder module | | requiring: | | * 18 speech parameters (see GSM TS 06.20) | | * 1 channel condition flag BFI (see GSM TS 06.21, 05.05) | | * 1 channel condition flag UFI (see GSM TS 06.21, 05.05) | | * 1 SID flag (2 bits) (see GSM TS 06.41, 05.05) | | * 1 time alignment flag TAF (see GSM TS 06.41) | | | | Between SID updates the speech parameters are replaced by random | | values simulating an interrupted transmission on the air interface | | | | The actual implementation only supports error free transmission (EP0)| | | | The shell for the future use of error patterns (residual error | | pattern insertion) is already included. If necessary, byte swapping | | is performed on the input speech parameters so that they are always | | represented internally in PC byte order (assuming that the byte | | order of the input file is compatible with the machine on which the | | program is run). However, byte swapping is not done on the flag | | words (input: SP and VAD, output: BFI, UFI, SID, and TAF). Thus, | | the residual error pattern insertion code may be written to handle | | the speech parameter words on a byte basis, but the flag words must | | always be handled on a word basis. | |___________________________________________________________________________| */ /*___________________________________________________________________________ | | | Creation: 19.12.94 | | | | Changes: | | 22.12.94: Removal of BCI flag, instead: determination of SID flag | | 12.01.95: SID update period = 12 (instead of 24) | | 13.01.95: When in CNI mode, the parameters between SID updates are | | random values. This simulates the interrupted transmission| | 03.02.95: Longword main( Longword...) replaced by int main(int ...),| | initial value of swTAFCnt set to 1 | |___________________________________________________________________________| */ /*___________________________________________________________________________ | | | Include-Files | |___________________________________________________________________________| */ #include <stdlib.h> #include <stdio.h> #include <string.h> #include <ctype.h> #ifdef VAX # define OPEN_WI "wb","mrs=512","rfm=fix","ctx=stm" # define OPEN_RI "rb","mrs=512","rfm=fix","ctx=stm" # define OPEN_WB "wb","mrs=512","rfm=fix","ctx=stm" # define OPEN_RB "rb","mrs=2","rfm=fix","ctx=stm" # define OPEN_WT "w","mrs=256","rat=cr","rfm=var" # define OPEN_RT "r","mrs=256","rat=cr","rfm=var" #else # define OPEN_WB "wb" # define OPEN_RB "rb" # define OPEN_WI "wb" # define OPEN_RI "rb" # define OPEN_WT "wt" # define OPEN_RT "rt" #endif #define LW_SIGN (long)0x80000000 /* sign bit */ #define LW_MIN (long)0x80000000 #define LW_MAX (long)0x7fffffff #define SW_MIN (short)0x8000 /* smallest Ram */ #define SW_MAX (short)0x7fff /* largest Ram */ typedef char Byte; typedef long int Longword; /* 32 bit "accumulator" (L_*) */ typedef short int Shortword; /* 16 bit "register" (sw*) */ /*___________________________________________________________________________ | | | local Functions | |___________________________________________________________________________| */ static Longword error_free( FILE *infile, FILE *outfile); static void SwapBytes( Shortword buffer[], Longword len ); static Longword ByteOrder( void ); static size_t ReadInputFile( Shortword buffer[], FILE *fp ); static size_t WriteOutputFile( Shortword buffer[], FILE *fp ); static Longword EncoderInterface( FILE *infile, Shortword swInPara[] ); static Shortword swSidDetection(Shortword pswParameters[], Shortword pswErrorFlag[]); static void RandomParameters(Shortword pswParameters[]); static Shortword getPnBits(Shortword iBits, Longword *pL_PNSeed); FILE *OpenBinfile( char *name, char *mode ); Longword Strincmp( const char *s, const char *t, size_t max ); Longword Stricmp( const char *s, const char *t ); Longword L_shr(Longword L_var1, Shortword var2); /* 2 ops */ Longword L_shl(Longword L_var1, Shortword var2); /* 2 ops */ Shortword shr(Shortword var1, Shortword var2); /* 1 ops */ Shortword shl(Shortword var1, Shortword var2); /* 1 ops */ /*___________________________________________________________________________ | | | Subroutines | |___________________________________________________________________________| */ static Longword error_free( FILE *infile, FILE *outfile) { #define SPEECH 1 #define CNIFIRSTSID 2 #define CNICONT 3 #define VALIDSID 11 #define GOODSPEECH 33 static Shortword swDecoMode = {SPEECH}; static Shortword swTAFCnt = {1}; Shortword swInPara[20], i, swFrameType; Shortword swOutPara[22],pswErrorFlag[3]; if( EncoderInterface( infile, swInPara )) return( 1 ); /* Copy input parameters to output parameters (error free transmission) */ /* -------------------------------------------------------------------- */ for (i=0;i<18;i++) swOutPara[i] = swInPara[i]; /* Set channel status flags (error free transmission) */ /* -------------------------------------------------- */ swOutPara[18] = 0; /* BFI flag */ swOutPara[19] = 0; /* UFI flag */ /* Evaluate SID flag */ /* ----------------- */ pswErrorFlag[0] = 0; /* BFI flag */ pswErrorFlag[1] = 0; /* UFI flag */ pswErrorFlag[2] = 0; /* BCI flag */ swOutPara[20] = swSidDetection(swOutPara, pswErrorFlag); /* Evaluate TAF flag */ /* ----------------- */ if (swTAFCnt == 0) swOutPara[21] = 1; else swOutPara[21] = 0; swTAFCnt = (swTAFCnt + 1) % 12; /* Frame classification: */ /* Since the transmission is error free, the received frames are either */ /* valid speech or valid SID frames */ /* -------------------------------------------------------------------- */ if ( swOutPara[20] == 2) swFrameType = VALIDSID; else if ( swOutPara[20] == 0) swFrameType = GOODSPEECH; else { printf( "Error in SID detection\n" ); return( 1 ); } /* Update of decoder state */ /* ----------------------- */ if (swDecoMode == SPEECH) { if (swFrameType == VALIDSID) swDecoMode = CNIFIRSTSID; else if (swFrameType == GOODSPEECH) swDecoMode = SPEECH; } else { /* comfort noise insertion mode */ if (swFrameType == VALIDSID) swDecoMode = CNICONT; else if (swFrameType == GOODSPEECH) swDecoMode = SPEECH; } /* Replace parameters by random data if in CNICONT-mode and TAF=0 */ /* -------------------------------------------------------------- */ if ((swDecoMode == CNICONT) && (swOutPara[21] == 0)){ RandomParameters(swOutPara); /* Set flags such, that an "unusable frame" is produced */ swOutPara[18] = 1; /* BFI flag */ swOutPara[19] = 1; /* UFI flag */ swOutPara[20] = 0; /* SID flag */ } if( outfile ) { if( WriteOutputFile( swOutPara, outfile )) { printf( "Error writing File\n" ); return( 1 ); } } return( 0 ); } static Longword EncoderInterface( FILE *infile, Shortword swInPara[] ) { size_t i = 0; i = ReadInputFile( swInPara, infile ); return(( i == 0 ) ? 1 : 0 ); } static size_t ReadInputFile( Shortword buffer[], FILE *fp ) { size_t i; i = fread( buffer, sizeof( Shortword ), 20, fp ); SwapBytes( buffer, 18 ); return( i ); } static size_t WriteOutputFile( Shortword buffer[], FILE *fp ) { size_t i; SwapBytes( buffer, 18 ); i = fwrite( buffer, sizeof( Shortword ), 22, fp ); return( ( i == 22 ) ? 0 : 1 ); } static void SwapBytes( Shortword buffer[], Longword len ) { Byte *pc, tmp; Longword i; if( !ByteOrder()) return; pc = (Byte *)buffer; for( i = 0; i < len; i++ ) { tmp = pc[0]; pc[0] = pc[1]; pc[1] = tmp; pc += 2; } } static Longword ByteOrder( void ) { Shortword si; Byte *pc; si = 0x1234; pc = (Byte *)&si; if (pc[1] == 0x12 && pc[0] == 0x34 ) return( 0 ); if (pc[0] == 0x12 && pc[1] == 0x34 ) return( 1 ); printf( "Error in ByteOrder: %X, %X\n", (int)pc[0], (int)pc[1] ); exit( 1 ); return( 2 ); } FILE *OpenBinfile( char *name, char *mode ) { FILE *fp; if( toupper( *mode ) == 'W' ) { /* Write access */ if(( fp = fopen( name, OPEN_WB )) == NULL ) { printf( "Can't open output file '%s'\n", name ); exit( 1 ); } } else { /* Read access */ if(( fp = fopen( name, OPEN_RB )) == NULL ) { printf( "Can't open file '%s'\n", name ); exit( 1 ); } } return( fp ); } Longword Strincmp( const char *s, const char *t, size_t max ) { for( ; max > 1; ++s, ++t, --max ) { if( toupper( *s ) != toupper( *t )) break; if( *s == '\0' ) return( 0 ); } return( toupper( *s ) - toupper( *t )); } Longword Stricmp( const char *s, const char *t ) { for(; toupper( *s ) == toupper( *t ); ++s, ++t ) { if( *s == '\0' ) return( 0 ); } return( toupper( *s ) - toupper( *t )); } /************************************************************************* * * FUNCTION NAME: getPnBits * * PURPOSE: * * Generate iBits pseudo-random bits using *pL_PNSeed as the * pn-generators seed. * * INPUTS: * * iBits - integer indicating how many random bits to return. * range [0,15], 0 yields 1 bit output * * *pL_PNSeed - 32 bit seed (changed by function) * * OUTPUTS: * * *pL_PNSeed - 32 bit seed, modified. * * RETURN VALUE: * * random bits in iBits LSB's. * * * IMPLEMENTATION: * * implementation of x**31 + x**3 + 1 == PN_XOR_REG | PN_XOR_ADD a * PN sequence generator using Longwords generating a 2**31 -1 * length pn-sequence. * *************************************************************************/ static Shortword getPnBits(Shortword iBits, Longword *pL_PNSeed){ #define PN_XOR_REG (Longword)0x00000005L #define PN_XOR_ADD (Longword)0x40000000L Shortword swPnBits=0; Longword L_Taps,L_FeedBack; Shortword i; for (i=0; i < iBits; i++){ /* update the state */ /********************/ L_Taps = *pL_PNSeed & PN_XOR_REG; L_FeedBack = L_Taps; /* Xor tap bits to yield feedback bit */ L_Taps = L_shr(L_Taps,1); while(L_Taps){ L_FeedBack = L_FeedBack ^ L_Taps; L_Taps = L_shr(L_Taps,1); } /* LSB of L_FeedBack is next MSB of PN register */ *pL_PNSeed = L_shr(*pL_PNSeed,1); if (L_FeedBack & 1) *pL_PNSeed = *pL_PNSeed | PN_XOR_ADD; /* State update complete. Get the output bit from the state, add/or it into output */ swPnBits = shl(swPnBits,1); swPnBits = swPnBits | (*pL_PNSeed & 1); } return(swPnBits); } /*************************************************************************** * * FUNCTION NAME: L_shl * * PURPOSE: * * Arithmetic shift left (or right). * Arithmetically shift the input left by var2. If var2 is * negative then an arithmetic shift right (L_shr) of L_var1 by * -var2 is performed. * * INPUTS: * * var2 * 16 bit short signed integer (Shortword) whose value * falls in the range 0xffff 8000 <= var2 <= 0x0000 7fff. * L_var1 * 32 bit long signed integer (Longword) whose value * falls in the range * 0x8000 0000 <= L_var1 <= 0x7fff ffff. * OUTPUTS: * * none * * RETURN VALUE: * * L_Out * 32 bit long signed integer (Longword) whose value * falls in the range * 0x8000 0000 <= L_var1 <= 0x7fff ffff. * * * IMPLEMENTATION: * * Arithmetically shift the 32 bit input left by var2. This * operation maintains the sign of the input number. If var2 is * negative then an arithmetic shift right (L_shr) of L_var1 by * -var2 is performed. See description of L_shr for details. * * Equivalent to the Full-Rate GSM ">> n" operation. Note that * ANSI-C does not guarantee operation of the C ">>" or "<<" * operator for negative numbers. * * KEYWORDS: shift, arithmetic shift left, * *************************************************************************/ Longword L_shl(Longword L_var1, Shortword var2) { Longword L_Mask, L_Out; int i, iOverflow = 0; if (var2 == 0 || L_var1 == 0) { L_Out = L_var1; } else if (var2 < 0) { if (var2 <= -31) { if (L_var1 > 0) L_Out = 0; else L_Out = 0xffffffffL; } else L_Out = L_shr(L_var1, -var2); } else { if (var2 >= 31) iOverflow = 1; else { if (L_var1 < 0) L_Mask = LW_SIGN; /* sign bit mask */ else L_Mask = 0x0; L_Out = L_var1; for (i = 0; i < var2 && !iOverflow; i++) { /* check the sign bit */ L_Out = (L_Out & 0x7fffffffL) << 1; if ((L_Mask ^ L_Out) & LW_SIGN) iOverflow = 1; } } if (iOverflow) { /* saturate */ if (L_var1 > 0) L_Out = LW_MAX; else L_Out = LW_MIN; } } return (L_Out); } /*************************************************************************** * * FUNCTION NAME: L_shr * * PURPOSE: * * Arithmetic shift right (or left). * Arithmetically shift the input right by var2. If var2 is * negative then an arithmetic shift left (shl) of var1 by * -var2 is performed. * * INPUTS: * * var2 * 16 bit short signed integer (Shortword) whose value * falls in the range 0xffff 8000 <= var2 <= 0x0000 7fff. * L_var1 * 32 bit long signed integer (Longword) whose value * falls in the range * 0x8000 0000 <= L_var1 <= 0x7fff ffff. * OUTPUTS: * * none * * RETURN VALUE: * * L_Out * 32 bit long signed integer (Longword) whose value * falls in the range * 0x8000 0000 <= L_var1 <= 0x7fff ffff. * * * IMPLEMENTATION: * * Arithmetically shift the input right by var2. This * operation maintains the sign of the input number. If var2 is * negative then an arithmetic shift left (shl) of L_var1 by * -var2 is performed. See description of L_shl for details. * * The input is a 32 bit number, as is the output. * * Equivalent to the Full-Rate GSM ">> n" operation. Note that * ANSI-C does not guarantee operation of the C ">>" or "<<" * operator for negative numbers. * * KEYWORDS: shift, arithmetic shift right, * *************************************************************************/ Longword L_shr(Longword L_var1, Shortword var2) { Longword L_Mask, L_Out; if (var2 == 0 || L_var1 == 0) { L_Out = L_var1; } else if (var2 < 0) { /* perform a left shift */ /*----------------------*/ if (var2 <= -31) { /* saturate */ if (L_var1 > 0) L_Out = LW_MAX; else L_Out = LW_MIN; } else L_Out = L_shl(L_var1, -var2); } else { if (var2 >= 31) { if (L_var1 > 0) L_Out = 0; else L_Out = 0xffffffffL; } else { L_Mask = 0; if (L_var1 < 0) { L_Mask = ~L_Mask << (32 - var2); } L_var1 >>= var2; L_Out = L_Mask | L_var1; } } return (L_Out); } /*************************************************************************** * * FUNCTION NAME: shl * * PURPOSE: * * Arithmetically shift the input left by var2. * * * INPUTS: * * var1 * 16 bit short signed integer (Shortword) whose value * falls in the range 0xffff 8000 <= var1 <= 0x0000 7fff. * var2 * 16 bit short signed integer (Shortword) whose value * falls in the range 0xffff 8000 <= var2 <= 0x0000 7fff. * * OUTPUTS: * * none * * RETURN VALUE: * * swOut * 16 bit short signed integer (Shortword) whose value * falls in the range * 0xffff 8000 <= swOut <= 0x0000 7fff. * * IMPLEMENTATION: * * If Arithmetically shift the input left by var2. If var2 is * negative then an arithmetic shift right (shr) of var1 by * -var2 is performed. See description of shr for details. * When an arithmetic shift left is performed the var2 LS bits * are zero filled. * * The only exception is if the left shift causes an overflow * or underflow. In this case the LS bits are not modified. * The number returned is 0x8000 in the case of an underflow or * 0x7fff in the case of an overflow. * * The shl is equivalent to the Full-Rate GSM "<< n" operation. * Note that ANSI-C does not guarantee operation of the C ">>" * or "<<" operator for negative numbers - it is not specified * whether this shift is an arithmetic or logical shift. * * KEYWORDS: asl, arithmetic shift left, shift * *************************************************************************/ Shortword shl(Shortword var1, Shortword var2) { Shortword swOut; Longword L_Out; if (var2 == 0 || var1 == 0) { swOut = var1; } else if (var2 < 0) { /* perform a right shift */ /*-----------------------*/ if (var2 <= -15) { if (var1 < 0) swOut = (Shortword) 0xffff; else swOut = 0x0; } else swOut = shr(var1, -var2); } else { /* var2 > 0 */ if (var2 >= 15) { /* saturate */ if (var1 > 0) swOut = SW_MAX; else swOut = SW_MIN; } else { L_Out = (Longword) var1 *(1 << var2); swOut = (Shortword) L_Out; /* copy low portion to swOut, * overflow could have hpnd */ if (swOut != L_Out) { /* overflow */ if (var1 > 0) swOut = SW_MAX; /* saturate */ else swOut = SW_MIN; /* saturate */ } } } return (swOut); } /*************************************************************************** * * FUNCTION NAME: shr * * PURPOSE: * * Arithmetic shift right (or left). * Arithmetically shift the input right by var2. If var2 is * negative then an arithmetic shift left (shl) of var1 by * -var2 is performed. * * INPUTS: * * var1 * 16 bit short signed integer (Shortword) whose value * falls in the range 0xffff 8000 <= var1 <= 0x0000 7fff. * var2 * 16 bit short signed integer (Shortword) whose value * falls in the range 0xffff 8000 <= var2 <= 0x0000 7fff. * * OUTPUTS: * * none * * RETURN VALUE: * * swOut * 16 bit short signed integer (Shortword) whose value * falls in the range * 0xffff 8000 <= swOut <= 0x0000 7fff. * * IMPLEMENTATION: * * Arithmetically shift the input right by var2. This * operation maintains the sign of the input number. If var2 is * negative then an arithmetic shift left (shl) of var1 by * -var2 is performed. See description of shl for details. * * Equivalent to the Full-Rate GSM ">> n" operation. Note that * ANSI-C does not guarantee operation of the C ">>" or "<<" * operator for negative numbers. * * KEYWORDS: shift, arithmetic shift right, * *************************************************************************/ Shortword shr(Shortword var1, Shortword var2) { Shortword swMask, swOut; if (var2 == 0 || var1 == 0) swOut = var1; else if (var2 < 0) { /* perform an arithmetic left shift */ /*----------------------------------*/ if (var2 <= -15) { /* saturate */ if (var1 > 0) swOut = SW_MAX; else swOut = SW_MIN; } else swOut = shl(var1, -var2); } else { /* positive shift count */ /*----------------------*/ if (var2 >= 15) { if (var1 < 0) swOut = (Shortword) 0xffff; else swOut = 0x0; } else { /* take care of sign extension */ /*-----------------------------*/ swMask = 0; if (var1 < 0) { swMask = ~swMask << (16 - var2); } var1 >>= var2; swOut = swMask | var1; } } return (swOut); } /*___________________________________________________________________________ | | | This subroutine calculates the 'SID flag' | | | | Input: pswParameters[18] | | input parameters of the speech decoder | | | | pswErrorFlag[3] | | error flags, generated by channel decoder | | | | Return Value: | | 0: speech frame detected | | 1: most likely SID frame received | | 2: SID frame detected | | | |___________________________________________________________________________| | | | History: | | | | 12-Oct-1994: Bug removed: error corrected in case of a mode (unvoiced/| | voiced) mismatch, if a SID frame was received as an | | unvoiced frame | |___________________________________________________________________________| */ static Shortword swSidDetection(Shortword pswParameters[], Shortword pswErrorFlag[]) { static Shortword ppswIBit[2][18] = { 5, 11,9,8, 1, 2, 7,7,5, 7,7,5, 7,7,5, 7,7,5, /* unvoiced */ 5, 11,9,8, 1, 2, 8,9,5, 4,9,5, 4,9,5, 4,9,5}; /* voiced */ static Shortword ppswCL1pCL2[2][18] = { 0x0001, /* R0 */ /* unvoiced */ 0x00ef, /* LPC1 */ 0x003e, /* LPC2 */ 0x007f, /* LPC3 */ 0x0001, /* INT LPC */ 0x0003, /* Mode */ 0x001f, /* Code1_1 */ 0x0072, /* Code2_1 */ 0x0012, /* GSP0_1 */ 0x003f, /* Code1_2 */ 0x007f, /* Code2_2 */ 0x0008, /* GSP0_2 */ 0x007f, /* Code1_3 */ 0x007f, /* Code2_3 */ 0x0008, /* GSP0_3 */ 0x007f, /* Code1_4 */ 0x007f, /* Code2_4 */ 0x000c, /* GSP0_4 */ 0x0000, /* R0 */ /* voiced */ 0x0000, /* LPC1 */ 0x0000, /* LPC2 */ 0x0000, /* LPC3 */ 0x0001, /* INT LPC */ 0x0003, /* Mode */ 0x00ff, /* Lag_1 */ 0x01ff, /* Code_1 */ 0x001f, /* GSP0_1 */ 0x000f, /* Lag_2 */ 0x01ff, /* Code_2 */ 0x001f, /* GSP0_2 */ 0x000f, /* Lag_3 */ 0x01ff, /* Code_3 */ 0x001f, /* GSP0_3 */ 0x000f, /* Lag_4 */ 0x01ff, /* Code_4 */ 0x001f}; /* GSP0_4 */ static Shortword ppswCL2[2][18] = { 0x0000, /* R0 */ /* unvoiced */ 0x0000, /* LPC1 */ 0x0000, /* LPC2 */ 0x0000, /* LPC3 */ 0x0000, /* INT LPC */ 0x0000, /* Mode */ 0x0000, /* Code1_1 */ 0x0000, /* Code2_1 */ 0x0000, /* GSP0_1 */ 0x0000, /* Code1_2 */ 0x0000, /* Code2_2 */ 0x0000, /* GSP0_2 */ 0x0000, /* Code1_3 */ 0x0007, /* Code2_3 */ /* 3 bits */ 0x0000, /* GSP0_3 */ 0x007f, /* Code1_4 */ /* 7 bits */ 0x007f, /* Code2_4 */ /* 7 bits */ 0x0000, /* GSP0_4 */ 0x0000, /* R0 */ /* voiced */ 0x0000, /* LPC1 */ 0x0000, /* LPC2 */ 0x0000, /* LPC3 */ 0x0000, /* INT LPC */ 0x0000, /* Mode */ 0x0000, /* Lag_1 */ 0x0000, /* Code_1 */ 0x0000, /* GSP0_1 */ 0x0000, /* Lag_2 */ 0x0000, /* Code_2 */ 0x0000, /* GSP0_2 */ 0x0000, /* Lag_3 */ 0x00ff, /* Code_3 */ /* 8 bits */ 0x0000, /* GSP0_3 */ 0x0000, /* Lag_4 */ 0x01ff, /* Code_4 */ /* 9 bits */ 0x0000}; /* GSP0_4 */ static int first = 1; Shortword swMode, swBitMask; Shortword swSidN1, swSidN2, swSidN1pN2; Shortword swSid ; short siI, siII; if (first) { /* Force Sid codewords to be represented */ /* internally in PC byte order */ /* ------------------------------------- */ SwapBytes(ppswCL1pCL2[0], 18); SwapBytes(ppswCL1pCL2[1], 18); SwapBytes(ppswCL2[0], 18); SwapBytes(ppswCL2[1], 18); first = 0; } /* count transmission errors within the SID codeword */ /* count number of bits equal '0' within the SID codeword */ /* ------------------------------------------------------ */ if (pswParameters[5] == 0) swMode = 0; else swMode = 1; swSidN1pN2 = 0; /* N1 + N2 */ swSidN2 = 0; swSidN1 = 0; for (siI = 0; siI < 18; siI++) { swBitMask = 0x0001; SwapBytes(&swBitMask, 1); /* force swBitMask to PC byte order */ for (siII = 0; siII < ppswIBit[swMode][siI]; siII++) { if ( (pswParameters[siI] & swBitMask) == 0 ) { if ( (ppswCL1pCL2[swMode][siI] & swBitMask) != 0 ) swSidN1pN2++; if ( (ppswCL2[swMode][siI] & swBitMask) != 0 ) swSidN2++; } SwapBytes(&swBitMask, 1); /* return swBitMask to native byte order */ swBitMask = swBitMask << 1; SwapBytes(&swBitMask, 1); /* force swBitMask to PC byte order */ } } swSidN1 = swSidN1pN2 - swSidN2; /* frame classification */ /* -------------------- */ if (pswErrorFlag[2]) { if (swSidN1 < 3) swSid = 2; else if (swSidN1pN2 < 16) swSid = 1; else swSid = 0; if ( (swSidN1pN2 >= 16) && (swSidN1pN2 <= 25) ) { pswErrorFlag[0] = 1; } } else { if (swSidN1 < 3) swSid = 2; else if (swSidN1pN2 < 11) swSid = 1; else swSid = 0; } /* in case of a mode mismatch */ /*----------------------------*/ if ( (swSid == 2) && (swMode == 0) ) swSid = 1; return(swSid); } /*___________________________________________________________________________ | | | This subroutine sets the 18 speech parameters to random values | | | | Input: pswParameters[18] | | input parameters of the speech decoder | | | |___________________________________________________________________________| */ static void RandomParameters(Shortword pswParameters[]) { static Shortword ppswIBit[2][18] = { 5, 11,9,8, 1, 2, 7,7,5, 7,7,5, 7,7,5, 7,7,5, /* unvoiced */ 5, 11,9,8, 1, 2, 8,9,5, 4,9,5, 4,9,5, 4,9,5}; /* voiced */ static Longword L_PNSeed=(Longword)0x1091988L; Shortword i,ind; /* Determine mode bit */ /* ------------------ */ pswParameters[5] = getPnBits(2, &L_PNSeed); /* Switch bit allocation accordingly */ /* --------------------------------- */ ind = 0; if (pswParameters[5] > 0) ind = 1; for (i=0; i < 5; i++){ pswParameters[i] = getPnBits(ppswIBit[ind][i], &L_PNSeed); } for (i=6; i < 18; i++){ pswParameters[i] = getPnBits(ppswIBit[ind][i], &L_PNSeed); } /* force random parameters to PC byte order */ /* ---------------------------------------- */ SwapBytes(pswParameters, 18); } /*___________________________________________________________________________ | | | Main - Program | | | |___________________________________________________________________________| */ int main( int argc, char *argv[] ) { FILE *infile, *outfile; Shortword errpat, i = 0; if( argc < 4 || argc > 4 ) { fprintf( stderr, "\tUsage: REID input output EPx \n" ); fprintf( stderr, "\tEPx: EP0\n" ); fprintf( stderr, "\t EP1 (not implemented)\n" ); fprintf( stderr, "\t EP2 (not implemented)\n" ); fprintf( stderr, "\t EP3 (not implemented)\n" ); return( 1 ); } if( !Strincmp( argv[3], "ep", 2 )) errpat = atoi( &argv[3][2] ); printf( " _____________________________________________\n" ); printf( " | |\n" ); printf( " | Residual Error Insertion Device |\n" ); printf( " | for |\n" ); printf( " | GSM Half-Rate Codec Simulation |\n" ); printf( " | |\n" ); printf( " |_____________________________________________|\n\n" ); printf( " Input File : %s\n", argv[1] ); printf( " Output File : %s\n", argv[2] ); if( errpat ){ printf( " Error Pattern : EP%d (not implemented)\n", errpat); return (1); } else printf( " Error Pattern : EP%d (error free)\n", errpat ); printf( "\n" ); infile = OpenBinfile( argv[1], "r" ); outfile = OpenBinfile( argv[2], "w" ); if (errpat == 0) { for (i=0;i<6000;i++) if( error_free( infile, outfile)) break; } /*else for (i=0;i<6000;i++) if( residual_error_pattern( infile, outfile)) break; EP1-3 not implemented */ fclose( infile ); fclose( outfile ); printf( " %d Frame%s processed \n\n", i,( i != 1 ) ? "s" : "" ); return( 0 ); }