FreeCalypso > hg > freecalypso-sw
diff doc/Firmware_Architecture @ 868:d92b110e06e0
doc/Firmware_Architecture written
author | Space Falcon <falcon@ivan.Harhan.ORG> |
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date | Sun, 17 May 2015 03:45:19 +0000 |
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--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/doc/Firmware_Architecture Sun May 17 03:45:19 2015 +0000 @@ -0,0 +1,760 @@ +Our FreeCalypso GSM firmware follows the same architecture as TI's TCS211; +this document is an attempt to describe this architecture. + +Nucleus environment +=================== + +Like all classic TI firmwares, ours is based on the Nucleus PLUS RTOS. Just +like TI's original code on which we are based, we use only a small subset of +the functionality provided by Nucleus - but because the latter is a library, +the pieces we don't use simply don't get pulled into the link. The main +function we get out of Nucleus is the scheduling of threads, or tasks as +Nucleus calls them. + +Our entry point code as we receive control from the Calypso boot ROM or from +other bootloaders on crippled targets or from loadagent in the case of fc-xram +loadable builds does some absolutely minimal initialization (set up sensible +memory access timings, copy iram.text to IRAM and .data to XRAM if we are +booting from flash, zero out our two bss segments (int.bss and ext.bss)) and +jumps to Nucleus' assembly init entry point. Prior to jumping to Nucleus, we +don't even have a stack (all init code prior to that point is pure assembly and +uses only ARM registers); Nucleus then sets up the stack pointer for everything +running under its control. + +Aside from just a few exceptions (ARM exception handlers come to mind, never +mind the pun), every piece of code in the firmware executes in one of the +following contexts: + +* Application_Initialize(): this function and everything called from it execute + just before Nucleus' thread scheduler starts; at this point interrupts are + disabled at the ARM7 core level (in the CPSR) and must not be enabled; the + stack is Nucleus' "system stack" which is also used by the scheduler and LISRs + as explained below. + +* Regular threads or tasks: once Application_Initialize() finishes, all code + with the exception of interrupt handlers (LISRs and HISRs as explained below) + runs in the context of some Nucleus task. Whenever you are trying to debug + or simply understand some piece of code in the firmware, the first question + you should ask is "which task does this code execute in?". Most functional + components run in their own tasks, i.e., a given piece of code is only + intended to run within the Nucleus task that belongs to the component in + question. On the other hand, some components are implemented as APIs, + functions to be called from other components: these don't have their own task + associated with them, and instead they run in the context of whatever task + they were called from. Some only get called from one task: for example, the + "uartfax" driver API calls only get called from the protocol stack's UART + entity, which is its own task. Other component API functions like FFS and + trace can get called from just about any task in the system. Many components + have both their own task and some API functions to be called from other tasks, + and the API functions oftentimes post messages to the task to be worked on by + the latter; the just-mentioned FFS and trace functions work in this manner. + + In our current GSM firmware (just like in TCS211) every Nucleus task is + created either through Riviera or through GPF, and not in any other way - see + the description of Riviera and GPF below. + +* LISRs (Low level Interrupt Service Routines): these are the interrupt handlers + that run immediately when an ARM IRQ or FIQ comes in. The code at the IRQ and + FIQ vector entry points calls Nucleus' magic stack switching function + (switches the CPU from IRQ/FIQ into SVC mode, saves the interrupted thread's + registers on that thread's stack, and switches to the "system" stack) and + then calls TI's IRQ dispatcher implemented in C. The latter figures out + which Calypso interrupt needs to be handled and calls the handler configured + in the compiled-in table. Nucleus' LISR registration framework is not used + by the GSM fw, but these interrupt handlers should be viewed as LISRs + nonetheless. + + There is one additional difference between canonical Nucleus and TI's version + (we've replicated the latter): canonical Nucleus was designed to support + nested LISRs, i.e., IRQs re-enabled in the magic stack switching function, + but in TI's version which we follow this IRQ re-enabling is removed: each LISR + runs with interrupts disabled and cannot be interrupted. (The corner case of + an FIQ interruping an IRQ remains to be looked at more closely as bugs may be + hiding there, but Calypso doesn't really use FIQ interrupts.) There is really + no need for LISR nesting in our GSM fw, as each LISR is very short: most LISRs + do nothing more than trigger the corresponding HISR. + +* HISRs (High level Interrupt Service Routines): these hold an intermediate + place between LISRs and tasks, similar to softirqs in the Linux kernel. A + HISR can be activated by a LISR calling NU_Activate_HISR(), and when the LISR + returns, the HISR will run before the interrupted task (or some higher + priority task, see below) can resume. HISRs run with CPU interrupts enabled, + thus more interrupts can occur, with their LISRs executing and possibly + triggering other HISRs. All triggered HISRs must complete and thereby go + "quiescent" before task scheduling resumes, i.e., all HISRs as a group have a + higher scheduling priority than tasks. + +Nucleus implements priority scheduling for tasks. Tasks have their priority set +when they are created (through Riviera or GPF, see below), and a higher priority +task will run until it gets blocked waiting for something, at which time lower +priority tasks will run. If a lower priority task sends a message to a higher +priority task, unblocking the latter which was waiting for incoming messages, +the lower priority task will effectively suspend itself immediately while the +higher priority task runs to process the message it was sent. + +HISRs oftentimes post messages to their associated tasks as well; if one of +these messages unblocks a higher priority task, that unblocked task will run +upon the completion of the HISR instead of the original lower priority task +that was interrupted by the LISR that triggered the HISR. Nucleus' scheduler +is fun! + +Major functional blocks +======================= + +At the highest level, all code in TI's classic firmwares and in our FreeCalypso +fw can be divided into 3 broad groupings: + +* GSM Layer 1: this code was developed by TI, is highly specific to TI's + baseband chipset family in general and to specific individual chips in + particular (the code is liberally sprinkled with conditional compilation + based on DBB type, ABB type, DSP ROM version and so on), and is absolutely + necessary in order to operate a Calypso device as a GSM MS (mobile station) + and not merely as a general purpose microprocessor platform. This code can + be considered to be the most important part of the entire firmware. + + L1 interties with Nucleus and with the G23M stack (with which it needs to + communicate) in a very peculiar way described later in this article. + +* G23M protocol stack: at the beginning of TI's involvement in the GSM baseband + chipset business, they only developed and maintained their own L1 code, while + the rest of the protocol stack (which is hardware-independent) was licensed + from another company called Condat. Later Condat as a company was fully + acquired by TI, and the once-customer of this code became its owner. The + name of TI/Condat's implementation of GSM layers 2&3 for the MS side is G23M, + and it forms its own major division of the overall fw architecture. + + Underlying the G23M stack is a special layer called GPF, which was originally + Condat's Generic Protocol stack Framework. Apparently Condat was in the + business of developing and maintaining a whole bunch of protocol stacks: GSM + MS side, GSM network side, TETRA and who knows what else. GPF was their + common underpinning for all of their protocol stack projects, which ran on top + of many different OS environments: Nucleus, pSOS, VxWorks, Unix/Linux, Win32 + and who knows what else. + + In the case of FreeCalypso GSM fw, both the protocol stack and the underlying + OS environment are fixed: GSM and Nucleus, respectively. But GPF is still a + critically important layer in the firmware architecture: in addition to + serving as the glue between the G23M stack and Nucleus, it provides some + important support infrastructure for the protocol stack. + +* Miscellaneous peripheral accessories: under this category I (Space Falcon) + place everything implemented through TI's Riviera framework. Historical + evidence indicates that TI's earliest firmwares did not have this part, i.e., + Riviera and everything built on top of it is a "non-essential" later + addition. It appears that TI originally invented Riviera in order to support + the development of fancy "feature phone" UI/application layers, complete with + Java, MMS, WAP, games and whatnot - things upon which our FreeCalypso project + looks with disdain - but in the TCS211 firmware from 2007 which I used as the + reference for FreeCalypso this Riviera framework serves as the foundation for + some small but essential pieces of functionality: the FFS implementation, the + SPI-based ABB access driver, the RTC driver and the debug trace facility. + + While it is certain that TI had some non-Riviera implementation of the just- + listed essential pieces in their earliest pre-Riviera days, trying to find + surviving sources from those days would be a "mission impossible" task. OTOH, + reusing the Riviera code from TCS211 was quite easy, as the copy of TCS211 we + got has it in full source form with nothing omitted. Therefore, I took the + sensible easy road and kept Riviera in FreeCalypso. + +The above division of the firmware into 3 broad functional groupings also +corresponds quite neatly with where each piece of our source code originally +came from. Our versions of L1 and G23M came in their entirety from TI's TCS3.2 +program targeting their later LoCosto chipset (specifically from the +TCS3.2_N5.24_M18_V1.11_M23BTH_PSL1_src.zip release from Peek/FGW), whereas +everything in the 3rd division (Riviera and everything built on top of it) came +from our TCS211/Leonardo source from Sotovik. + +The just-listed divisions of the firmware are really separate software +environments which are linked together into one final image, but which have +very little in the way of interties. Each of the 3 realms has its own very +different coding style, its own set of header files and its own defined types. +It is very rare for a module from one realm to include any header files or call +any functions from another realm, and while they all ultimately run on top of +Nucleus, they interface with Nucleus in different ways: G23M goes through GPF, +everything in Riviera land goes through Riviera, and L1 uses its own bizarre +mechanism which in our fw ends up going through GPF but hasn't always been this +way - to be explained lated in this article. + +Also note that there is no mention of any handset UI code (or MMI in the GSM +industry's sexist speak) in the above breakdown of code divisions. This +document describes the architecture of TI's modem firmware in which the highest +layer is the AT command interface (part of the G23M suite, or its uppermost +layer to be precise), and which does not include any UI code. Our TI reference +sources do include their "MMI" code, but I haven't studied it closely enough +yet to comment on it properly, and the version of TCS211 which serves as our +primary reference is set up for the modem configuration without this "MMI" part. +Making sense of TI's "MMI" code is a task to be tackled later in the project +when we have a working modem and are ready to start building a usable handset +with UI. + +Riviera and GPF +=============== + +Riviera and GPF are two parallel/independent/competing wrappers around or +layers above Nucleus. The way in which they are treated in our FreeCalypso fw +architecture is somewhat inverted: originally GPF was the essential framework +underlying the G23M stack (and to which L1 was also attached in a hacky way) +while Riviera was added to support non-essential frills, but in our current FC +fw Riviera is always included just like Nucleus, whereas GPF only needs to be +included in the build when building with feature gsm (full GSM MS functionality) +or feature l1stand (L1 standalone) - but is not needed if one wishes to build +an "in vivo" FFS editing agent, for example. + +This peculiar arrangement happened because of the source code availability +situation we found ourselves in. TCS211 uses real Riviera that is fully +independent of GPF (see below), and our copy thereof came with this part in +full source form. On the other hand, we never got the complete original source +for GPF in one piece, thus our FC version of GPF had to be reconstructed from +bits and pieces. For this reason I made the decision early on to include +Riviera and some RV-based components in the "mandatory core" part of our FC fw +architecture, while leaving GPF to be worked on later. And when I did get to +reintegrating GPF, at that point it was natural to make it into an "optional" +component that is included only when needed. + +At some point in their post-Calypso TCS3.x program TI decided to eliminate +Riviera as an independent framework and to reimplement Riviera APIs (used by +peripheral but necessary code such as FFS, ETM, various drivers etc) over GPF. +This arrangement is used in the TCS3.2 LoCosto code from which we lifted our +versions of L1 and G23M. However, I (Space Falcon) chose not to adopt this +approach for FreeCalypso, and mimic the TCS211 way (Riviera entirely +independent of GPF) instead. The reasons were twofold: (1) there was no full +source for GPF and a painstaking reconstruction effort was required before we +could have our own working version of GPF in our gcc-built fw, and (2) I felt +more comfortable and familiar with following TCS211. + +Start-up process +================ + +I mentioned earlier that every Nucleus task in our firmware gets created and +started either through Riviera or through GPF. All GPF tasks are created and +placed into the runable state in the Application_Initialize() context: the work +is done by GPF init code in gsm-fw/gpf/frame/frame.c, and the top level GPF +init function called from Application_Initialize() is StartFrame(). Thus when +Application_Initialize() finishes and the Nucleus thread scheduler starts +running for the first time, all GPF tasks are there to be scheduled. + +There is a compiled-in table of all protocol stack entities and the tasks in +which they need to run which (in our fw) lives under gsm-fw/gpf/conf and which +logically belongs to GPF. Canonically each protocol stack entities runs in its +own task, but sometimes two or more are combined to run in the same task: for +example, in the minimal GSM "voice only" configuration (no CSD, fax or GPRS) +CC, SMS and SS entities share the same task named CM. Unlike Riviera, GPF does +not support dynamic starting and stopping of tasks. + +As each GPF task starts running (immediately upon entry into Nucleus' scheduling +loop as Application_Initialize() finishes), pf_TaskEntry() function in +gsm-fw/gpf/frame/frame.c is the first code it runs. This function creates the +queue for messages to be sent to all entities running within the task in +question, calls each entity's pei_init() function (repeatedly until it succeeds: +it will fail until the other entities to which this entity needs to send +messages have created their message queues), and then falls into the main body +of the task: for all "regular" entities/tasks except L1, this main body consists +of waiting for messages (or signals or timeouts) to arrive on the queue and +dispatching each received message to the appropriate handler in the right +entity. + +Riviera tasks get started in a different way. The same Application_Initialize() +function that calls StartFrame() to create and start all GPF tasks also calls +create_tasks() (found in gsm-fw/riviera/init/create_RVtasks.c), the appinit-time +function for starting the Riviera environment. But this function does not +create and start every configured Riviera task like StartFrame() does for GPF. +Instead it creates a special helper task which will do this work once scheduled. +Thus at the completion of Application_Initialize() and the beginning of +scheduling the set of runable Nucleus tasks consists of all GPF ones plus the +special RV starter task. Once the RV starter task gets scheduled, it will call +rvm_start_swe() to launch every configured Riviera SWE (SoftWare Entity), which +in turns entails creating the tasks in which these SWEs are to run. + +Dynamic memory allocation +========================= + +All dynamic memory allocation (i.e., all RAM usage beyond statically allocated +variables and buffers) is once again done either through Riviera or through GPF, +and in no other way. Ultimately all areas of the physical RAM that will ever +be used by the fw in any way are allocated when the fw is compiled and linked: +the areas from which Riviera and GPF serve their dynamic memory allocations are +statically allocated as char arrays in the respective C modules and placed in +the int.ram or ext.ram section as appropriate; Riviera and GPF then provide +API functions that allocate memory dynamically from these statically allocated +large pools. + +Riviera and GPF have entirely separate memory pools from which they serve their +respective clients, hence there is no possibility of one affecting the other. +Riviera's memory allocation scheme is very much like the classic malloc&free: +there is one large unstructured pool from which all allocations are made, one +can allocate a chunk of any size, free chunks are merged when physically +adjacent, and fragmentation is an issue: a memory allocation request may fail +even when there is enough memory available in total if it is too fragmented. + +GPF's dynamic memory allocation facility is considerably more robust: while it +does maintain one or two (depending on configuration) memory pools of the +traditional "dynamic" kind (like malloc&free, susceptible to fragmentation), +most GPF memory allocation works on "partition" memory instead. Here GPF +maintains 3 separate groups of pools: PRIM, TEST and DMEM; each allocation +request must specify the appropriate pool group and cannot affect the others. +Within each pool there is a fixed number of partitions of a fixed size: for +example, in TI's TCS211 GSM+GPRS configuration the PRIM pool group consists of +190 partitions of 60 bytes, 110 partitions of 128 bytes, 50 partitions of 632 +bytes and 7 partitions of 1600 bytes. An allocation request from a given pool +group (e.g., PRIM) can request any arbitrary size in bytes, but it gets rounded +up to the nearest partition size and allocated out of the respective pool. If +no free partitions are available, the requesting task is suspended until another +task frees on. Because these partitions are used primarily for intertask +communication, if none are free, it can only mean (assuming that the firmware +functions correcly) that all partitions have been allocated and sent to some +queue for some task to work on, hence eventually they will get freed. + +This scheme implemented in GPF is extremely robust in the opinion of this +author, and the other purely "dynamic" scheme is used (in the case of GPF) only +for init-time allocations which are never freed, such as task stacks - hence +the GPF-based part of the firmware is not suspectible at all to the problem of +memory fragmentation. But Riviera does suffer from this problem, and the +concern is more than just theoretical: one major user of Riviera-based dynamic +memory allocation is the trace facility (described in its own section below), +and my observation of the trace output from Pirelli's proprietary fw (which +appears to use the same architecture with separate Riviera and GPF) suggests +that after the fw has been running for a while, Riviera memory gets fragmented +to a point where many traces are being dropped. Replacing Riviera's poor +dynamic memory allocation scheme with a GPF-like partition-based one is a to-do +item for our project. + +Message-based intertask communication +===================================== + +Even though all entities of the G23M protocol stack are linked together into +one monolithic fw image and there is nothing to stop them from calling each +other's functions and accessing each other's variables, they don't work that +way. Instead all communication between entities is done through messages, just +as if they ran in separate address spaces or even on separate processors. +Buffers for this message exchange are allocated from a GPF partition pool: an +entity that needs to send a message to another entity allocates a buffer of the +needed size, fills it with the message to be sent, and posts it on the recipient +entity's message queue, all through GPF services. The other entity simply +processes the stream of messages that arrives on its message queue, freeing each +message (returning the buffer to the partition pool in came from) as it is +processed. + +Riviera-based tasks use a similar mechanism: unlike G23M protocol stack +entities, most Riviera-based functional modules provide APIs that are called as +functions from other tasks, but these API functions typically allocate a memory +buffer (through Riviera), fill it with the call parameters, and post it to the +associated task's message queue (also in the Riviera land) to be worked on. +Once the worker task gets the job done, it will either call a callback function +or post a response message back to the requestor - the latter option is only +possible if the requesting entity is also Riviera-based. + +A closer look at GPF +==================== + +There are certain sublayers within GPF which need to be pointed out. The 3 +major subdivisions within GPF are: + +* The meaty core of GPF: this part is the code under gsm-fw/gpf/frame in our + source tree. It appears that this part was originally intended to be both + project-independent (same for GSM, TETRA etc) and OS-independent (same for + Nucleus, pSOS, VxWorks etc). This is the part of GPF that matters for the + G23M stack: all APIs called by PS entities are implemented here, and so are + all other PS-facing functions such as startup. (PS = protocol stack) + +* OS adaptation layer (OSL): this is the part of GPF that adapts it to a given + underlying OS, in our case Nucleus. + +* Test interface: see the code under gsm-fw/gpf/tst_drv and gsm-fw/gpf/tst_pei. + This part handles the trace output from all entities that run under GPF and + the mechanism for sending external debug commands to the GPF+PS subsystem. + +GPF was a difficult step in our GSM firmware reintegration process because no +complete source for it could be found anywhere: apparently GPF was so stable +and so independent of firmware particulars (Calypso or LoCosto, GSM only or +GSM+GPRS, modem or complete phone with UI etc) that it appears to have been +used and distributed as prebuilt binary libraries even inside TI. All TI fw +(semi-)sources we have use GPF in prebuilt library form and are not set up to +recompile any part of it from source. (They had to include all GPF header +files though, as most of them are included by G23M C modules, and it would be +too much hassle to figure out which ones are or aren't needed, hence all were +included.) + +Fortunately though, we were able to find the sources for most parts of GPF: + +* The LoCosto source in TCS3.2_N5.24_M18_V1.11_M23BTH_PSL1_src.zip features the + source for the "core" part of GPF under gpf/FRAME - these sources aren't + actually used by that fw's build system (it only uses the prebuilt binary + libs for GPF), but they are there. + +* Our TCS211 semi-src doesn't have any sources for the core part of GPF, but + instead it features the source for the test interface and some "misc" parts: + under gpf/MISC and gpf/tst in that source tree - these sources are not present + in the LoCosto version from Peek. + +But one critical piece was still missing: the OS adaptation layer. It appears +that the GPF core (vsi_??? modules) and OSL (os_??? modules) were maintained +and built together, ending up together in frame_<blah>.lib files in the binary +form used to build firmwares, but the source for the "frame" part in the Peek +find contained only vsi_*.c and others, but not any of os_*.c. + +Thus we had to reconstruct GPF from the shattered bits and pieces we had. I +took the frame sources from Peek and the misc and tst sources from Sotovik, and +saw that they compiled w/o problems in our gcc environment. Attempting to link +any firmware that uses GPF would have been futile at this point, as it would +have failed with undefined references to os_*() functions. Then I had to do +the hard work: disassemble the missing os_??? modules from the binary libs in +the TCS211 version (hey, at least this one was known to work reliably) and write +new C code replicating the exact logic found in the disassembly of the known +working and fitting binary. This work is now mostly done (some non-essential +functions have been stubbed out to be revisited later), and the version of GPF +used by FreeCalypso is a significant work of reconstruction, not merely lifted +from a readily available source and plopped in. + +A closer look at L1 +=================== + +The L1 code is remarkable in how little intertie it has with the rest of the +firmware it is linked into. It is almost entirely self-contained, expecting +only 4 functions to be provided by the underlying OS environment: + +os_alloc_sig -- allocate message buffer +os_free_sig -- free message buffer +os_send_sig -- send message to upper layers +os_receive_sig -- receive message from upper layers + +It helps to remember that at the beginning of TI's involvement in the GSM +baseband chipset business, L1 was the only thing they "owned", while Condat, +the maintainers of the higher level protocol stack, was a separate company. +TI's "turnkey" solution must have consisted of their own L1 code plus G23M code +(including GPF etc) licensed from Condat, but I'm guessing that TI probably +wanted to retain the ability to sell their chips with their L1 without being +entangled by Condat: let the customer use their own GSM L23 stack, or perhaps +work out their own independent licensing arrangements with Condat. I'm +guessing that L1 was maintained as its own highly independent and at least +conceptually portable entity for these reasons. + +The way in which L1 is intertied into our FreeCalypso GSM fw is the same as how +it is done in TI's production firmwares, including both our TCS211 reference +and the TCS3.2 version from which we got our L1 source. There is a module +called OSX, which is an extremely thin adaptation layer that implements the +APIs expected by L1 in terms of GPF. Furthermore, this OSX layer provides +header file isolation: the only "outside" (non-L1) header included by L1 is +cust_os.h, and it defines the necessary interface to OSX *without* including +any other headers (no GPF headers in particular), using only the C language's +native types. Apart from this cust_os.h header, the entire OSX layer is +implemented in one C module (osx.c, which we had to reconstruct from osx.obj as +the source was missing - but it's very simple) which does include some GPF +headers and implements the OSX API in terms of GPF services. Thus in TI's +production firmwares and in our FC GSM fw L1 does sit on top of GPF, but very +indirectly. + +More specifically, the "production" version of OSX implements its API in terms +of *high-level* GPF functions, i.e., VSI. However, they also had an interesting +OP_L1_STANDALONE configuration which omitted not only all of G23M, but also the +core of GPF and possibly the Riviera environment as well. We don't have a way +to recreate this configuration exactly as it existed inside TI because we don't +have the source bits specific to this configuration (our own standalone L1 +configuration is implemented differently, see below), but we do have a little +bit of insight into how it worked. + +It appears that TI's OP_L1_STANDALONE build used a special "gutted" version of +GPF in which the "meaty core" (VSI etc) was removed. The OS layer (os_??? +modules implementing os_*() functions) that interfaces to Nucleus was kept, and +so was OSX used by L1 - but this time the OSX API functions were implemented in +terms of os_*() ones (low-level wrappers around Nucleus) instead of the higher- +level VSI APIs provided by the "meaty core" of GPF. It is purely a guess on my +part, but perhaps this hack was also done in the days before TI's acquisition +of Condat, and by omitting the "meaty core" of GPF, TI could claim that their +OP_L1_STANDALONE configuration did not contain any of Condat's "intellectual +property". + +In FreeCalypso we do have a way to build a firmware image that includes L1 but +not G23M: it is our own L1 standalone configuration, enabled with a +feature l1stand line in build.conf. However, because IP considerations don't +apply to us (we operate under the doctrine of eminent domain), we are not +replicating TI's gutting of GPF: *our* L1 standalone configuration includes the +full GPF (with OSX for L1 implemented in terms of VSI), but with a greatly +reduced set of tasks when G23M is omitted. + +Run-time structure of L1 +======================== + +L1 consists of two major parts: L1S and L1A. L1S is the synchronous part where +the most time-critical functions are performed; it runs as a Nucleus HISR. The +hardware in the Calypso generates an interrupt on every TDMA frame (4.615 ms), +and the LISR handler for this interrupt triggers the L1S HISR. L1S communicates +with L1A through a shared memory data structure, and also sometimes allocates +message buffers and posts them to L1A's incoming message queue (both via OSX +API functions, i.e., via GPF in disguise). + +L1A runs as a regular task under Nucleus, and includes a blocking call (to GPF +via OSX) to wait for incoming messages on its queue. It is one big loop that +waits for incoming messages, then processes each received message and commands +L1S to do most of the work. The entry point to L1A in the L1 code proper is +l1a_task(), although the responsibility for running it as a task falls on some +"glue" code outside of L1 proper. TI's production firmwares with G23M included +have an L1 protocol stack entity within G23M whose only job (aside from some +initialization) is to run l1a_task() in the Nucleus task created by GPF for +that protocol stack entity; we do the same in our firmware. + +Communication between L1 and G23M +================================= + +It is remarkable that L1 and G23M don't have any header files in common: L1 +uses its own (almost fully self-contained), whereas the G23M+GPF realm is its +own world with its own header files. One has to ask then: how do they +communicate? OK, we know they communicate through primitives (messages in +buffers allocated from GPF's PRIM partition memory pool) passes via message +queues, but what about the data structures in these messages? Where are those +defined if there are no header files in common between L1 and G23M? + +The answer is that there are separate definitions of the L1<->G23M interface on +each side, and TI must have kept them in sync manually. Not exactly a +recommended programming or software maintenance practice for sure, but TI took +care of it, and the existing proprietary products based on TI's firmware are +rock solid, so it is not really our place to complain. + +TI's firmwares from the era we are working with (the TCS3.2/LoCosto source from +20090327 from which we took our L1 and G23M and the binary libs version of +TCS211 from 20070608 which serves as our reference) also include a component +called ALR. It resides in the G23M code realm: G23M coding style, uses Condat +header files, runs as its own protocol stack entity under GPF. This component +appears to serve as a glue layer between the rest of the G23M stack (which is +supposed to be truly hardware-independent) and TI's L1. + +Speaking of ALR, it is worth mentioning that there is a little naming +inconsistency here. ALR is known to the connect-by-name logic in GPF as "PL" +(physical layer, apparently), while the ACI entity (Application Control +Interface, the top level entity) is known to the same logic as "MMI". No big +deal really, but hopefully knowing this quirk will save someone some confusion. + +Debug trace facility +==================== + +See the RVTMUX document in the same directory as this one for general background +information about the debug and development interface provided by TI-based +firmwares. Our FreeCalypso GSM firmware implements an RVTMUX interface as well, +and the most immediate use to which it is put is debug trace output. In this +section I'm going to describe how this debug trace output is generated inside +the fw. + +The firmware component that "owns" the physical UART channel assigned to RVTMUX +is RVT, implemented in gsm-fw/riviera/rvt. It is a Riviera-based component, +and it has a Nucleus task that is created and started through Riviera. All +calls to the actual driver for the UART are made from RVT. In the case of +output from the Calypso GSM device to an external host, all such output is +performed in the context of RVT's Nucleus task; this task drains RVT's message +queue and emits the content of allocated buffers posted to it, freeing them +afterward. (The dynamic memory allocation system in this case is Riviera's, +which is susceptible to fragmentation - see discussion earlier in this article.) +Therefore, every trace or other output packet emitted from a GSM device running +our fw (or any of the proprietary firmwares based on the same architecture) +appears as a result of a message in a dynamically allocated buffer having been +posted to RVT's queue. + +RVT exports several API functions that are intended to be called from other +tasks, it is by way of these functions that most output is submitted to RVT. +One can call rvt_send_trace_cpy() with a fully prepared output message, and +that function will allocate a buffer from Riviera's dynamic memory allocator +properly accounted to RVT, fill it and post it to the RVT task's queue. +Alternatively, one can can rvt_mem_alloc() to allocate the buffer, fill it in +and then pass it to rvt_send_trace_no_cpy(). + +At higher levels, there are a total of 3 kinds of debug traces that can be +emitted: + +* Riviera traces: these are generated by various components implemented in + Riviera land, although in reality any component can generate a trace of this + form by calling rvf_send_trace() - this function can be called from any task. + +* L1 traces: L1 has its own trace facility implemented in + gsm-fw/L1/cfile/l1_trace.c; it generates its traces as ASCII messages and + sends them out via rvt_send_trace_cpy(). + +* GPF traces: code that runs in GPF/G23M land and uses those header files and + coding conventions etc can emit traces through GPF. GPF's trace functions + (implemented in gsm-fw/gpf/frame/vsi_trc.c) allocate a memory partition from + GPF's TEST pool, format the trace into it, and send the trace primitive to + GPF's special test interface task. That task receives trace and other GPF + test interface primitives on its queue, performs some manipulations on them, + and ultimately generates RVT trace output, i.e., a new dynamic memory buffer + is allocated in the Riviera land, the trace is copied there, and the Riviera + buffer goes to the RVT task for the actual output. + +Trace masking +============= + +The RV trace facility invoked via rvf_send_trace() has a crude masking ability, +but by default all traces are enabled. In TI's standard firmwares most of the +trace output comes from L1: L1's trace output is very voluminous, and appears +to be fully enabled by default. I have yet to look more closely if there is +any trace masking functionality in L1 and what the default trace verbosity +level should be. + +On the other hand, GPF and therefore G23M traces are mostly disabled by default. +One can turn the trace verbosity level from any GPF-based entity up or down by +sending a "system primitive" command to the running fw, and another such command +can be used to save these masks in FFS, so that they will be restored on the +next boot cycle and be effective at the earliest possible time. Enabling *all* +GPF trace output for all entities is generally not useful though, as it is so +verbose that a developer trying to make sense of it will likely drown in it. + +GPF compressed trace hack +========================= + +TI's Windows-based GSM firmware build systems include a hack called str2ind. +Seeking to reduce the fw image size by eliminating trace ASCII strings from it, +and seeking to reduce the load on the RVTMUX serial interface by eliminating +the transmission time of these strings, they passed their sources through an +ad hoc preprocessor that replaces these ASCII strings with numeric indices. +The compilation process with this str2ind hack becomes very messy: each source +file is first passed through the C preprocessor, then the intermediate form is +passed through str2ind, and finally the de-string-ified form is compiled, with +the compiler being told not to run the C preprocessor again. + +TI's str2ind tool maintains a table of correspondence between the original trace +ASCII strings and the indices they've been turned into, and a copy of this table +becomes essential for making sense of GPF trace output: the firmware now emits +only numeric indices which are useless without this str2ind.tab mapping table. + +Our FreeCalypso firmware does not currently implement this str2ind aka +compressed trace hack, i.e., all GPF trace output from our fw is in full ASCII +string form. I have not bothered to implement compressed traces because: + +* We have not yet encountered a case of the full ASCII strings causing a problem + either with fw images not fitting into the available memory or excessive load + on the RVTMUX interface; + +* Implementing the hack in question would require extra work: the str2ind tool + would have to be reimplemented anew, as of the original we have no source, + only a Windows binary, and requiring our free fw build process to run a + Windows binary under Wine is a no-no; + +* I don't feel like doing all that extra work for what appears to be no real + gain; + +* Having to run gcc with separate cpp and actual compilation steps with str2ind + sandwiched in between would be ugly and gross; + +* Having to keep track of which str2ind.tab goes with which fw image and supply + the right table to our rvinterf tools would likely be a pita. + +So we shall stick with full ASCII string traces until and unless we run into an +actual (as opposed to hypothetical) problem with either fw image size or serial +interface load. + +RVTMUX command input +==================== + +RVTMUX is not just debug trace output: it is also possible for an external host +to send commands to the running fw via RVTMUX. + +Inside the fw RVTMUX input is handled by the RVT entity by way of a Nucleus +HISR. This HISR gets triggered when Rx bytes arrive at the designated UART, +and it calls the UART driver to collect the input. RVT code running in this +HISR parses the message structure and figures out which fw component the +incoming message is addressed to. Any fw component can register to receive +RVTMUX packets, and provides a callback function with this registration; this +callback function is called in the context of the HISR. + +In our current FC GSM fw there are two components that register to receive +external host commands via RVTMUX: ETM and GPF. ETM is described in my earlier +RVTMUX write-up. ETM is implemented as a Riviera SWE and has its own Nucleus +task; the callback function that gets called from the RVT HISR posts received +messages onto ETM's own queue drained by its task. The ETM task gets scheduled, +picks up the command posted to its queue, executes it, and sends a response +message back to the external host through RVT. + +Because all ETM commands funnel through ETM's queue and task, and that task +won't start looking at a new command until it finished handling the previous +one, all ETM commands and responses are in strict lock-step: it is not possible +to send two commands and have their responses come in out of order, and it makes +no sense to send another ETM command prior to receiving the response to the +previous one. (But there can still be debug traces or other traffic intermixed +on RVTMUX in between an ETM command and the corresponding response!) + +The other component that can receive external commands is GPF. GPF's test +interface can receive so-called "system primitives", which are ASCII string +commands parsed and acted upon by GPF, and also binary protocol stack +primitives. Remember how all entities in the G23M stack communicate by sending +messages to each other? Well, GPF's test interface allows such messages to be +injected externally as well, directed to any entity in the running fw. System +primitive commands can also be used to cause entities to send their outgoing +primitives to the test interface, either instead of or in addition to the +originally intended recipient. + +Firmware subsetting +=================== + +We have built our firmware up incrementally, piece by piece, starting from a +very small skeleton. As we added pieces working toward full GSM MS +functionality, the ability to build less functional fw images corresponding to +our earlier stages of development has been retained. Each piece we added is +"optional" from the viewpoint of our build system, even if it is absolutely +required for normal usage, and is enabled by the appropriate feature line in +build.conf. + +Our minimal baseline with absolutely no "features" enabled consists of: + +* Nucleus +* Riviera +* TI's basic drivers for GPIO, ABB etc +* RVTMUX on the UART port chosen by the user (RVTMUX_UART_port Bourne shell + variable in build.conf) and the UART driver for it +* FFS code operating on a fake FFS image in RAM + +If one runs this minimal "firmware" on a Calypso device, one will see some +startup messages in RV trace format followed by a System Time trace every 20 s. +This "firmware" can't do anything more, there is not even a way to command it +to power off or reboot. + +Working toward full GSM MS functionality, pieces can be added to this skeleton +in this order: + +* GPF +* L1 +* G23M + +feature gsm enables all of the above for normal usage; feature l1stand can be +used alternatively to build an L1 standalone image without G23M - we expect +that we may end up using a ramImage form of the latter for RF calibration on +our own Calypso hardware. + +ETM and various FFS configurations are orthogonal features to the choice of +core functionality level. + +Further reading +=============== + +Believe it or not, some of the documentation that was written by the original +vendors of the software in question and which we've been able to locate turns +out to be fairly relevant and helpful, such that I recommend reading it. + +Documentation for Nucleus PLUS RTOS: + + ftp://ftp.ifctf.org/pub/embedded/Nucleus/nucleus_manuals.tar.bz2 + + Quite informative, and fits our version of Nucleus just fine. + +Riviera environment: + + ftp://ftp.ifctf.org/pub/GSM/Calypso/riviera_preso.pdf + + It's in slide presentation form, not a detailed technical document, but + it covers a lot of points, and all that Riviera stuff described in the + preso *is* present in our fw for real, hence it should be considered + relevant. + +GPF documentation: + + http://scottn.us/downloads/peek/SW%20doc/frame_users_guide.pdf + http://scottn.us/downloads/peek/SW%20doc/vsipei_api.pdf + + Very good reading, helped me understand GPF when I first reached this + part of firmware reintegration. + +TCS3.x/LoCosto fw architecture: + + http://scottn.us/downloads/peek/SW%20doc/TCS2_1_to_3_2_Migration_v0_8.pdf + ftp://ftp.ifctf.org/pub/GSM/LoCosto/LoCosto_Software_Architecture_Specification_Document.pdf + + These TI docs focus mostly on how they changed the fw architecture from + their TCS2.x program (Calypso) to their newer TCS3.x (LoCosto), but one + can still get a little insight into the "old" TCS211 architecture they + were moving away from, which is the architecture I've adopted for + FreeCalypso.