//NOTE DO NOT EDIT THIS FILE WITHOUT ALSO EDITING DFT12SMALL!!! #include #include #include "DFT8Turbo.h" #include #include #define MAX_FREQS (12) #define OCTAVES (4) /* General procedure - use this code, with uint16_t or uint32_t buffers, and make sure none of the alarms go off. All of the paths still require no more than an 8-bit multiply. You should test with extreme cases, like square wave sweeps in, etc. */ //No larger than 8-bit signed values for integration or sincos #define FRONTEND_AMPLITUDE (2) #define INITIAL_DECIMATE (5) //Yurgh... only 3 bits of ADC data. That's 8 unique levels :( #define INTEGRATOR_DECIMATE (8) #define FINAL_DECIMATE (1) #define OPTABLETYPE uint16_t //Make uint8_t if on attiny. //4x the hits (sin/cos and we need to do it once for each edge) //8x for selecting a higher octave. #define FREQREBASE 8.0 #define TARGFREQ 10000.0 //These live in RAM. int8_t running_integral; //Realistically treat as 12-bits on ramjet8 int8_t integral_at[MAX_FREQS*OCTAVES]; //For ramjet8, make 12-bits int8_t cossindata[MAX_FREQS*OCTAVES*2]; //Contains COS and SIN data. (32-bit for now, will be 16-bit, potentially even 8.) uint8_t which_octave_for_op[MAX_FREQS]; //counts up, tells you which ocative you are operating on. PUT IN RAM. uint8_t actiontableplace; #define NR_OF_OPS (4< hits per %d: %f %d (%.2f%% error)\n", topbin, f, ACTIONTABLESIZE, (float)ACTIONTABLESIZE/f, dhrpertable, err * 100.0 ); if( dhrpertable >= ACTIONTABLESIZE ) { fprintf( stderr, "Error: Too many hits.\n" ); exit(0); } float advance_per_step = dhrpertable/(float)ACTIONTABLESIZE; float fvadv = 0.5; int j; int countset = 0; //Tricky: We need to start fadv off at such a place that there won't be a hicchup when going back around to 0. // I believe this is done by setting fvadv to 0.5 initially. Unsure. for( j = 0; j < ACTIONTABLESIZE; j++ ) { if( fvadv >= 0.5 ) { actiontable[j] |= 1<> longestzeroes) & 1) == 0 ); longestzeroes++ ); //longestzeroes goes: 255, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, ... //This isn't great, because we need to also know whether we are attacking the SIN side or the COS side, and if it's + or -. //We can actually decide that out. if( longestzeroes == 255 ) { //This is a nop. Emit a nop. optable[i] = 255; } else { longestzeroes = OCTAVES-1-longestzeroes; //Actually do octave 0 least often. int iop = phaseinop[longestzeroes]++; int toop = longestzeroes; int toopmon = (longestzeroes<<1) | (iop & 1); //if it's the first time an octave happened this set, flag it. This may be used later in the process. if( !already_hit_octaveplace[toopmon] ) { already_hit_octaveplace[toopmon] = 1; toop |= 1<<5; } if( iop & 1 ) { toop |= 1<<6; } //Handle add/subtract bit. if( iop & 2 ) toop |= 1<<4; optable[i] = toop; //printf( " %d %d %d\n", iop, val, longestzeroes ); } //printf( "HBT: %d = %d\n", i, optable[i] ); } //exit(1); return 0; } void Turbo8BitRun( int8_t adcval ) { int16_t adcv = adcval; adcv *= FRONTEND_AMPLITUDE; if( adcv > 127 ) adcv = 127; if( adcv < -128 ) adcv = -128; running_integral += adcv>>INITIAL_DECIMATE; uint16_t action = actiontable[actiontableplace++]; uint8_t n; //Counts are approximate counts for PMS133 for( n = 0; //1CYC n < MAX_FREQS; //2CYC n++, //1CYC action>>=1 //2CYC ) { //Everything inside this loop is executed ~3/4 * MAX_FREQS. so.. ~9x. //If op @ 4MHz, we get 44 cycles in here. //If no operation is scheduled, continue. if( !( action & 1 ) ) continue; //1CYC uint8_t ao = which_octave_for_op[n]; //4CYC ao++; //1CYC if( ao >= NR_OF_OPS ) ao = 0; //2CYC which_octave_for_op[n] = ao; //2CYC (idxm) uint8_t op = optable[ao]; //"theoretically" 3CYC (if you align things right) //1CYC (Put A into specific RAM location) //If we are on the one thing we aren't supposed to operate within, cancel. if( op == 255 ) continue; //2CYC (if op is in A) //Tricky: We share the integral with SIN and COS. //We don't need to. It would produce a slightly cleaner signal. See: NOTE 3 uint8_t octave = op & 0xf; //1CYC (if op is in A) uint8_t intindex = octave * MAX_FREQS //Load mulop with 12 [2CYC]; mul [1CYC] + n; //Add [1CYC] //[1CYC] more cycle to write A into RAM[(intindex) //int invoct = OCTAVES-1-octaveplace; int8_t diff; if( op & 0x10 ) //ADD //2CYC { diff = integral_at[intindex] //Assume "IntIndex" is in A, add integral_at to A [1], move A to an index [1]. [2] to read into acc. [4CYC] - running_integral; //1CYC to subtract. //1CYC to write diff into a memory location. } else //SUBTRACT { diff = running_integral - integral_at[intindex]; } //30 cycles so far. integral_at[intindex] = running_integral; //[3CYC] //if( diff > 124 || diff < -124 ) printf( "!!!!!!!!!!!! %d !!!!!!!!!!!\n", diff ); //uint8_t idx = ( intindex << 1 ); //Overwrite intindex. intindex <<= 1; //1CYC if( op&(1<<6) ) //2CYC { intindex |= 1; //1CYC } uint8_t mulmuxval = mulmux[n]; //[4CYC] //Do you live on a super lame processor? {NOTE 4} //If you do, you might not have good signed multiply operations. So, an alternative mechanism is found here. // +) Able to more cleanly crush to an 8-bit multiply. // +) Gets extra bit of precision back, i.e. the sign bit is now used as a data bit. // -) More than 1 line of C code. Requires possible double invert. #if 1 //rough processor, i.e. PMS133 if( diff < 0 ) //[2CYC] { diff *= -1; //[1CYC] diff >>= (OCTAVES-1-octave); // ???TRICKY??? //if( diff > 250 ) printf( "!!!!!!!**** %d ****!!!!!!!\n", diff ); diff = ((uint16_t)diff * (uint16_t)mulmuxval)>>INTEGRATOR_DECIMATE; //[3CYC] diff *= -1; //[1CYC] } else { diff >>= (OCTAVES-1-octave); //if( diff > 250 ) printf( "!!!!!!!**** %d ****!!!!!!!\n", diff ); diff = ((uint16_t)diff * (uint16_t)mulmuxval)>>INTEGRATOR_DECIMATE; } //@48 cycles :( :( :( #else //Decent processor, i.e. ATTiny85. diff = ((diff>>(OCTAVES-1-octave)) * mulmuxval ) >> 6; #endif //printf( "%d\n", diff ); cossindata[intindex] = cossindata[intindex] + diff - (cossindata[intindex]>>4) ; if( cossindata[intindex] > 0 ) cossindata[intindex]--; if( cossindata[intindex] < 0 ) cossindata[intindex]++; } } void DoDFT8BitTurbo( float * outbins, float * frequencies, int bins, const float * databuffer, int place_in_data_buffer, int size_of_data_buffer, float q, float speedup ) { static int is_setup; if( !is_setup ) { is_setup = 1; Setup( frequencies, bins ); } static int last_place; int i; for( i = last_place; i != place_in_data_buffer; i = (i+1)%size_of_data_buffer ) { int16_t ifr1 = (int16_t)( ((databuffer[i]) ) * 4095 ); Turbo8BitRun( ifr1>>5 ); //5 = Actually only feed algorithm numbers from -128 to 127. } last_place = place_in_data_buffer; static int idiv; idiv++; #if 1 for( i = 0; i < bins; i++ ) { int iss = cossindata[i*2+0]>>FINAL_DECIMATE; int isc = cossindata[i*2+1]>>FINAL_DECIMATE; int mux = iss * iss + isc * isc; if( mux <= 0 ) { outbins[i] = 0; } else { outbins[i] = sqrt((float)mux)/50.0; if( abs( cossindata[i*2+0] ) > 120 || abs( cossindata[i*2+1] ) > 120 ) printf( "CS OVF %d/%d/%d/%f\n", i, cossindata[i*2+0], cossindata[i*2+1],outbins[i] ); } } #endif }