FreeCalypso > hg > gsm-codec-lib
view doc/EFR-rationale @ 466:0c4e1bc06740
amrefr-encode-r: use the new DHF xform that matches T-Mobile
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Sun, 12 May 2024 21:44:59 +0000 |
parents | 69b9a1eeb5a2 |
children |
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Problem in need of solving ========================== At the time of the undertaking of Themyscira libgsmefr project (late 2022), there did not exist any readily available library solution for GSM EFR codec. The community of FOSS offers classic libgsm from 1990s for FR1 codec (it's an implementation of GSM 06.10, on top of which we had to implement our own Rx DTX handler) and opencore-amrnb for AMR (based on Android OpenCORE framework) - but nothing for EFR. This situation creates a problem for anyone seeking to deploy their own GSM network with a voice interface to PSTN or other networks: such voice interface generally requires implementing a transcoder, and doing the latter in turn requires a library that implements the codec to be supported. In the present situation, anyone who wishes to implement a speech transcoder for GSM networks can easily support FR1 and AMR codecs, but not EFR. EFR is more than just 12k2 mode of AMR! ======================================= There is a common misconception in the GSM hacker community that EFR is nothing but the highest 12k2 mode of AMR, and that any library that implements AMR, such as opencore-amrnb, is thus sufficient to support EFR as well. However, the reality is more complex: * If an AMR encoder operates with DTX disabled, such that the output contains only speech frames and no SID, and the mode is forced to 12k2, then indeed a simple reshuffling of bits will produce speech frames that can be fed to an EFR decoder on the other end. Note that the two encoders (EFR and AMR 12k2) will produce *different* encoded speech parameters from the same input, and the decoded speech output on the other end will also be different, but the two versions are expected to be equally good for human ears. * In the other direction, if an EFR input stream contains only good speech frames (no SID and no lost, FACCH-stolen or DTX-suppressed frames), one can likewise do a simple bit reordering and feed these frames to an AMR decoder. The output of this AMR decoder will once again be different from a proper (bit-exact) EFR decoder for the same speech parameter inputs, but as long as the EFR input stream is all good speech frames, the output will be good enough for human ears. * The real problem occurs when the EFR input stream contains SID frames and BFI frame gaps, as will always happen in reality if this stream is an uplink from a GSM call. AMR SID mechanism is different from that of EFR, and an AMR decoder will NOT recognize EFR SID frames. A quick experiment confirms that when a real GSM EFR uplink RTP capture is converted to AMR by non-SID-aware bit reshuffling and then fed to amrnb-dec from opencore-amrnb, unpleasant sounds appear in the output whenever GSM uplink goes into SID. EFR reference code from ETSI ============================ A published-source bit-exact implementation of GSM EFR encoder and decoder, complete with all beyond-speech functions of DTX, VAD, comfort noise generation, error concealment etc does exist in the form of reference code from ETSI. However, this code has never been turned into a usable codec library by anyone prior to us (at least not by anyone who freely published their work), and doing such librification (producing an EFR analogue to what Android OpenCORE people did with AMR) is no easy feat! The original EFR code from ETSI exhibits two problems which need to be remedied in the librification project: 1) The original code maintains all codec state in global variables (lots of them) that are scattered throughout. 3GPP reference code for AMR (naturally later than EFR in chronological order) is better in this regard (in the AMR version they gathered their global vars into structs and pass pointers to these structs, although still many separately-malloc'ed structs instead of single unified encoder state and decoder state), but we need the EFR version for correct handling of all beyond-speech aspects, and this version is all global vars. 2) These reference codes from ETSI/3GPP (both EFR and AMR versions, it seems) were intended to serve as simulations, not as production code, and the code is very inefficient. Themyscira libgsmefr ==================== Libgsmefr presented in this code repository is our current solution for EFR. It is a library styled after classic libgsm for FR1, but its guts consist of a librified derivative of ETSI EFR code. The problem of global vars has been solved in this library version - they've been gathered into one unified struct for encoder state and another unified struct for decoder state - but the problem of poor performance (significantly worse than opencore-amrnb) still remains for now. Future roadmap ============== When this article was originally written in late 2022, my thoughts were that we would go in the direction of a single library supporting both AMR and EFR, sharing most code in common and handling the differences between EFR and MR122 similarly to how most proprietary implementations have done it, following the "alternative" of GSM 06.54 chapter 10. However, that plan has been revised; our current approach (as of 2024-04) is that we are developing a separate library for AMR (libtwamr, librifying 3GPP AMR code in the same way how we librified ETSI EFR in libgsmefr), while libgsmefr remains as it is, a pristine implementation of GSM-EFR in its *original* bit-exact form. Please refer to AMR-EFR-philosophy article for more information.