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view spandsp-0.0.6pre17/src/v17tx.c @ 4:26cd8f1ef0b1
import spandsp-0.0.6pre17
| author | Peter Meerwald <pmeerw@cosy.sbg.ac.at> |
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| date | Fri, 25 Jun 2010 15:50:58 +0200 |
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/* * SpanDSP - a series of DSP components for telephony * * v17tx.c - ITU V.17 modem transmit part * * Written by Steve Underwood <steveu@coppice.org> * * Copyright (C) 2004 Steve Underwood * * All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License version 2.1, * as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this program; if not, write to the Free Software * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. * * $Id: v17tx.c,v 1.75.4.1 2009/12/24 16:52:30 steveu Exp $ */ /*! \file */ #if defined(HAVE_CONFIG_H) #include "config.h" #endif #include <stdio.h> #include <inttypes.h> #include <stdlib.h> #include <string.h> #if defined(HAVE_TGMATH_H) #include <tgmath.h> #endif #if defined(HAVE_MATH_H) #include <math.h> #endif #include "floating_fudge.h" #include "spandsp/telephony.h" #include "spandsp/fast_convert.h" #include "spandsp/logging.h" #include "spandsp/complex.h" #include "spandsp/vector_float.h" #include "spandsp/complex_vector_float.h" #include "spandsp/async.h" #include "spandsp/dds.h" #include "spandsp/power_meter.h" #include "spandsp/v17tx.h" #include "spandsp/private/logging.h" #include "spandsp/private/v17tx.h" #if defined(SPANDSP_USE_FIXED_POINT) #define SPANDSP_USE_FIXED_POINTx #endif #include "v17_v32bis_tx_constellation_maps.h" #if defined(SPANDSP_USE_FIXED_POINT) #include "v17_v32bis_tx_fixed_rrc.h" #else #include "v17_v32bis_tx_floating_rrc.h" #endif /*! The nominal frequency of the carrier, in Hertz */ #define CARRIER_NOMINAL_FREQ 1800.0f /* Segments of the training sequence */ /*! The start of the optional TEP, that may preceed the actual training, in symbols */ #define V17_TRAINING_SEG_TEP_A 0 /*! The mid point of the optional TEP, that may preceed the actual training, in symbols */ #define V17_TRAINING_SEG_TEP_B (V17_TRAINING_SEG_TEP_A + 480) /*! The start of training segment 1, in symbols */ #define V17_TRAINING_SEG_1 (V17_TRAINING_SEG_TEP_B + 48) /*! The start of training segment 2, in symbols */ #define V17_TRAINING_SEG_2 (V17_TRAINING_SEG_1 + 256) /*! The start of training segment 3, in symbols */ #define V17_TRAINING_SEG_3 (V17_TRAINING_SEG_2 + 2976) /*! The start of training segment 4, in symbols */ #define V17_TRAINING_SEG_4 (V17_TRAINING_SEG_3 + 64) /*! The start of training segment 4 in short training mode, in symbols */ #define V17_TRAINING_SHORT_SEG_4 (V17_TRAINING_SEG_2 + 38) /*! The end of the training, in symbols */ #define V17_TRAINING_END (V17_TRAINING_SEG_4 + 48) #define V17_TRAINING_SHUTDOWN_A (V17_TRAINING_END + 32) /*! The end of the shutdown sequence, in symbols */ #define V17_TRAINING_SHUTDOWN_END (V17_TRAINING_SHUTDOWN_A + 48) /*! The 16 bit pattern used in the bridge section of the training sequence */ #define V17_BRIDGE_WORD 0x8880 static __inline__ int scramble(v17_tx_state_t *s, int in_bit) { int out_bit; //out_bit = (in_bit ^ (s->scramble_reg >> s->scrambler_tap) ^ (s->scramble_reg >> (23 - 1))) & 1; out_bit = (in_bit ^ (s->scramble_reg >> (18 - 1)) ^ (s->scramble_reg >> (23 - 1))) & 1; s->scramble_reg = (s->scramble_reg << 1) | out_bit; return out_bit; } /*- End of function --------------------------------------------------------*/ #if defined(SPANDSP_USE_FIXED_POINT) static __inline__ complexi16_t training_get(v17_tx_state_t *s) #else static __inline__ complexf_t training_get(v17_tx_state_t *s) #endif { static const int cdba_to_abcd[4] = { 2, 3, 1, 0 }; static const int dibit_to_step[4] = { 1, 0, 2, 3 }; #if defined(SPANDSP_USE_FIXED_POINT) static const complexi16_t zero = {0, 0}; #else static const complexf_t zero = {0.0f, 0.0f}; #endif int bits; int shift; if (++s->training_step <= V17_TRAINING_SEG_3) { if (s->training_step <= V17_TRAINING_SEG_2) { if (s->training_step <= V17_TRAINING_SEG_TEP_B) { /* Optional segment: Unmodulated carrier (talker echo protection) */ return v17_v32bis_abcd_constellation[0]; } if (s->training_step <= V17_TRAINING_SEG_1) { /* Optional segment: silence (talker echo protection) */ return zero; } /* Segment 1: ABAB... */ return v17_v32bis_abcd_constellation[(s->training_step & 1) ^ 1]; } /* Segment 2: CDBA... */ /* Apply the scrambler */ bits = scramble(s, 1); bits = (bits << 1) | scramble(s, 1); s->constellation_state = cdba_to_abcd[bits]; if (s->short_train && s->training_step == V17_TRAINING_SHORT_SEG_4) { /* Go straight to the ones test. */ s->training_step = V17_TRAINING_SEG_4; } return v17_v32bis_abcd_constellation[s->constellation_state]; } /* Segment 3: Bridge... */ shift = ((s->training_step - V17_TRAINING_SEG_3 - 1) & 0x7) << 1; //span_log(&s->logging, SPAN_LOG_FLOW, "Seg 3 shift %d\n", shift); bits = scramble(s, V17_BRIDGE_WORD >> shift); bits = (bits << 1) | scramble(s, V17_BRIDGE_WORD >> (shift + 1)); s->constellation_state = (s->constellation_state + dibit_to_step[bits]) & 3; return v17_v32bis_abcd_constellation[s->constellation_state]; } /*- End of function --------------------------------------------------------*/ static __inline__ int diff_and_convolutional_encode(v17_tx_state_t *s, int q) { static const uint8_t v32bis_4800_differential_encoder[4][4] = { {2, 3, 0, 1}, {0, 2, 1, 3}, {3, 1, 2, 0}, {1, 0, 3, 2} }; static const uint8_t v17_differential_encoder[4][4] = { {0, 1, 2, 3}, {1, 2, 3, 0}, {2, 3, 0, 1}, {3, 0, 1, 2} }; static const uint8_t v17_convolutional_coder[8][4] = { {0, 2, 3, 1}, {4, 7, 5, 6}, {1, 3, 2, 0}, {7, 4, 6, 5}, {2, 0, 1, 3}, {6, 5, 7, 4}, {3, 1, 0, 2}, {5, 6, 4, 7} }; if (s->bits_per_symbol == 2) { /* 4800bps mode for V.32bis */ /* There is no trellis. We just differentially encode. */ s->diff = v32bis_4800_differential_encoder[s->diff][q & 0x03]; return s->diff; } /* Differentially encode */ s->diff = v17_differential_encoder[s->diff][q & 0x03]; /* Convolutionally encode the redundant bit */ s->convolution = v17_convolutional_coder[s->convolution][s->diff]; /* The final result is the combination of some uncoded bits, 2 differentially encoded bits, and the convolutionally encoded redundant bit. */ return ((q << 1) & 0x78) | (s->diff << 1) | ((s->convolution >> 2) & 1); } /*- End of function --------------------------------------------------------*/ static int fake_get_bit(void *user_data) { return 1; } /*- End of function --------------------------------------------------------*/ #if defined(SPANDSP_USE_FIXED_POINT) static __inline__ complexi16_t getbaud(v17_tx_state_t *s) #else static __inline__ complexf_t getbaud(v17_tx_state_t *s) #endif { int i; int bit; int bits; if (s->in_training) { if (s->training_step <= V17_TRAINING_END) { /* Send the training sequence */ if (s->training_step < V17_TRAINING_SEG_4) return training_get(s); /* The last step in training is to send some 1's */ if (++s->training_step > V17_TRAINING_END) { /* Training finished - commence normal operation. */ s->current_get_bit = s->get_bit; s->in_training = FALSE; } } else { if (++s->training_step > V17_TRAINING_SHUTDOWN_A) { /* The shutdown sequence is 32 bauds of all 1's, then 48 bauds of silence */ #if defined(SPANDSP_USE_FIXED_POINT) return complex_seti16(0, 0); #else return complex_setf(0.0f, 0.0f); #endif } if (s->training_step == V17_TRAINING_SHUTDOWN_END) { if (s->status_handler) s->status_handler(s->status_user_data, SIG_STATUS_SHUTDOWN_COMPLETE); } } } bits = 0; for (i = 0; i < s->bits_per_symbol; i++) { if ((bit = s->current_get_bit(s->get_bit_user_data)) == SIG_STATUS_END_OF_DATA) { /* End of real data. Switch to the fake get_bit routine, until we have shut down completely. */ if (s->status_handler) s->status_handler(s->status_user_data, SIG_STATUS_END_OF_DATA); s->current_get_bit = fake_get_bit; s->in_training = TRUE; bit = 1; } bits |= (scramble(s, bit) << i); } return s->constellation[diff_and_convolutional_encode(s, bits)]; } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE_NONSTD(int) v17_tx(v17_tx_state_t *s, int16_t amp[], int len) { #if defined(SPANDSP_USE_FIXED_POINT) complexi_t x; complexi_t z; #else complexf_t x; complexf_t z; #endif int i; int sample; if (s->training_step >= V17_TRAINING_SHUTDOWN_END) { /* Once we have sent the shutdown sequence, we stop sending completely. */ return 0; } for (sample = 0; sample < len; sample++) { if ((s->baud_phase += 3) >= 10) { s->baud_phase -= 10; s->rrc_filter[s->rrc_filter_step] = s->rrc_filter[s->rrc_filter_step + V17_TX_FILTER_STEPS] = getbaud(s); if (++s->rrc_filter_step >= V17_TX_FILTER_STEPS) s->rrc_filter_step = 0; } /* Root raised cosine pulse shaping at baseband */ #if defined(SPANDSP_USE_FIXED_POINT) x = complex_seti(0, 0); for (i = 0; i < V17_TX_FILTER_STEPS; i++) { x.re += (int32_t) tx_pulseshaper[TX_PULSESHAPER_COEFF_SETS - 1 - s->baud_phase][i]*(int32_t) s->rrc_filter[i + s->rrc_filter_step].re; x.im += (int32_t) tx_pulseshaper[TX_PULSESHAPER_COEFF_SETS - 1 - s->baud_phase][i]*(int32_t) s->rrc_filter[i + s->rrc_filter_step].im; } /* Now create and modulate the carrier */ x.re >>= 4; x.im >>= 4; z = dds_complexi(&(s->carrier_phase), s->carrier_phase_rate); /* Don't bother saturating. We should never clip. */ i = (x.re*z.re - x.im*z.im) >> 15; amp[sample] = (int16_t) ((i*s->gain) >> 15); #else x = complex_setf(0.0f, 0.0f); for (i = 0; i < V17_TX_FILTER_STEPS; i++) { x.re += tx_pulseshaper[TX_PULSESHAPER_COEFF_SETS - 1 - s->baud_phase][i]*s->rrc_filter[i + s->rrc_filter_step].re; x.im += tx_pulseshaper[TX_PULSESHAPER_COEFF_SETS - 1 - s->baud_phase][i]*s->rrc_filter[i + s->rrc_filter_step].im; } /* Now create and modulate the carrier */ z = dds_complexf(&(s->carrier_phase), s->carrier_phase_rate); /* Don't bother saturating. We should never clip. */ amp[sample] = (int16_t) lfastrintf((x.re*z.re - x.im*z.im)*s->gain); #endif } return sample; } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE(void) v17_tx_power(v17_tx_state_t *s, float power) { /* The constellation design seems to keep the average power the same, regardless of which bit rate is in use. */ #if defined(SPANDSP_USE_FIXED_POINT) s->gain = 0.223f*powf(10.0f, (power - DBM0_MAX_POWER)/20.0f)*16.0f*(32767.0f/30672.52f)*32768.0f/TX_PULSESHAPER_GAIN; #else s->gain = 0.223f*powf(10.0f, (power - DBM0_MAX_POWER)/20.0f)*32768.0f/TX_PULSESHAPER_GAIN; #endif } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE(void) v17_tx_set_get_bit(v17_tx_state_t *s, get_bit_func_t get_bit, void *user_data) { if (s->get_bit == s->current_get_bit) s->current_get_bit = get_bit; s->get_bit = get_bit; s->get_bit_user_data = user_data; } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE(void) v17_tx_set_modem_status_handler(v17_tx_state_t *s, modem_tx_status_func_t handler, void *user_data) { s->status_handler = handler; s->status_user_data = user_data; } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE(logging_state_t *) v17_tx_get_logging_state(v17_tx_state_t *s) { return &s->logging; } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE(int) v17_tx_restart(v17_tx_state_t *s, int bit_rate, int tep, int short_train) { switch (bit_rate) { case 14400: s->bits_per_symbol = 6; s->constellation = v17_v32bis_14400_constellation; break; case 12000: s->bits_per_symbol = 5; s->constellation = v17_v32bis_12000_constellation; break; case 9600: s->bits_per_symbol = 4; s->constellation = v17_v32bis_9600_constellation; break; case 7200: s->bits_per_symbol = 3; s->constellation = v17_v32bis_7200_constellation; break; case 4800: /* This does not exist in the V.17 spec as a valid mode of operation. However, it does exist in V.32bis, so it is here for completeness. */ s->bits_per_symbol = 2; s->constellation = v17_v32bis_4800_constellation; break; default: return -1; } s->bit_rate = bit_rate; /* NB: some modems seem to use 3 instead of 1 for long training */ s->diff = (short_train) ? 0 : 1; #if defined(SPANDSP_USE_FIXED_POINT) memset(s->rrc_filter, 0, sizeof(s->rrc_filter)); #else cvec_zerof(s->rrc_filter, sizeof(s->rrc_filter)/sizeof(s->rrc_filter[0])); #endif s->rrc_filter_step = 0; s->convolution = 0; s->scramble_reg = 0x2ECDD5; s->in_training = TRUE; s->short_train = short_train; s->training_step = (tep) ? V17_TRAINING_SEG_TEP_A : V17_TRAINING_SEG_1; s->carrier_phase = 0; s->baud_phase = 0; s->constellation_state = 0; s->current_get_bit = fake_get_bit; return 0; } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE(v17_tx_state_t *) v17_tx_init(v17_tx_state_t *s, int bit_rate, int tep, get_bit_func_t get_bit, void *user_data) { switch (bit_rate) { case 14400: case 12000: case 9600: case 7200: case 4800: /* 4800 is an extension of V.17, to provide full converage of the V.32bis modes */ break; default: return NULL; } if (s == NULL) { if ((s = (v17_tx_state_t *) malloc(sizeof(*s))) == NULL) return NULL; } memset(s, 0, sizeof(*s)); span_log_init(&s->logging, SPAN_LOG_NONE, NULL); span_log_set_protocol(&s->logging, "V.17 TX"); s->get_bit = get_bit; s->get_bit_user_data = user_data; //s->scrambler_tap = 18 - 1; s->carrier_phase_rate = dds_phase_ratef(CARRIER_NOMINAL_FREQ); v17_tx_power(s, -14.0f); v17_tx_restart(s, bit_rate, tep, FALSE); return s; } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE(int) v17_tx_release(v17_tx_state_t *s) { return 0; } /*- End of function --------------------------------------------------------*/ SPAN_DECLARE(int) v17_tx_free(v17_tx_state_t *s) { free(s); return 0; } /*- End of function --------------------------------------------------------*/ /*- End of file ------------------------------------------------------------*/