FreeCalypso > hg > gsm-codec-lib
view libgsmefr/dec_main.c @ 242:f081a6850fb5
libgsmfrp: new refined implementation
The previous implementation exhibited the following defects,
which are now fixed:
1) The last received valid SID was cached forever for the purpose of
handling future invalid SIDs - we could have received some valid
SID ages ago, then lots of speech or NO_DATA, and if we then get
an invalid SID, we would resurrect the last valid SID from ancient
history - a bad design. In our new design, we handle invalid SID
based on the current state, much like BFI.
2) GSM 06.11 spec says clearly that after the second lost SID
(received BFI=1 && TAF=1 in CN state) we need to gradually decrease
the output level, rather than jump directly to emitting silence
frames - we previously failed to implement such logic.
3) Per GSM 06.12 section 5.2, Xmaxc should be the same in all 4 subframes
in a SID frame. What should we do if we receive an otherwise valid
SID frame with different Xmaxc? Our previous approach would
replicate this Xmaxc oddity in every subsequent generated CN frame,
which is rather bad. In our new design, the very first CN frame
(which can be seen as a transformation of the SID frame itself)
retains the original 4 distinct Xmaxc, but all subsequent CN frames
are based on the Xmaxc from the last subframe of the most recent SID.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Tue, 09 May 2023 05:16:31 +0000 |
| parents | 18866c0354ef |
| children |
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/* * This module contains our GSM EFR decoder main function, EFR_decode_params(), * that stands at the boundary between our public interface and the guts of * ETSI-based codec. */ #include "gsm_efr.h" #include "typedef.h" #include "namespace.h" #include "basic_op.h" #include "cnst.h" #include "codec.h" #include "sig_proc.h" #include "memops.h" #include "dec_state.h" #include "d_homing.h" /* These constants define the number of consecutive parameters that function decoder_homing_frame_test() checks */ #define WHOLE_FRAME 57 #define TO_FIRST_SUBFRAME 18 void EFR_decode_params(struct EFR_decoder_state *st, const int16_t *params, int bfi, int SID_flag, int TAF, int16_t *pcm_out) { Word16 *synth = st->synth_buf + M; Word16 Az_dec[AZ_SIZE]; Word16 i, temp; Word16 reset_flag; if (!bfi) /* BFI == 0, perform DHF check */ { if (st->reset_flag_old) /* Check for second and further successive DHF (to first subfr.) */ { reset_flag = decoder_homing_frame_test (params, TO_FIRST_SUBFRAME); } else { reset_flag = 0; } } else /* BFI==1, bypass DHF check (frame is taken as not being a DHF) */ { reset_flag = 0; } if (reset_flag && st->reset_flag_old) { /* Force the output to be the encoder homing frame pattern */ for (i = 0; i < L_FRAME; i++) { synth[i] = EHF_MASK; } } else { /* Synthesis */ Decoder_12k2 (st, bfi, params, synth, Az_dec, TAF, SID_flag); Post_Filter (st, synth, Az_dec); /* Post-filter */ for (i = 0; i < L_FRAME; i++) /* Upscale the 15 bit linear PCM to 16 bits, then truncate to 13 bits */ { temp = shl (synth[i], 1); synth[i] = temp & 0xfff8; } } /* else */ Copy (synth, pcm_out, L_FRAME); /* BFI == 0, perform check for first DHF (whole frame) */ if (!bfi && !st->reset_flag_old) { reset_flag = decoder_homing_frame_test (params, WHOLE_FRAME); } if (reset_flag) { /* Bring the decoder and receive DTX to the home state */ EFR_decoder_reset(st); } else { st->reset_flag_old = 0; } }