FreeCalypso > hg > freecalypso-ui-dev
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author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Fri, 16 Mar 2018 03:50:38 +0000 |
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children | d584d7b50f10 |
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This repository contains a couple of hack-utilities that have been developed as attempts at displaying TI's 176x220 pixel demo/prototype phone UI on an external development host in the absence of a suitable Calypso target device with an LCD of the needed large size. Two approaches have been tried, separated in time by about 2.5 y: 2015-09 approach ================ A year before FreeCalypso Magnetite, when all we had was the TCS211 semi-src from Sotovik with its original all-Windows build system, with all of the blobs intact and no apparent hope of deblobbing, plus our first attempt at bottom-up GSM fw with completely broken L1, we had built two hacked-up versions of TI's TCS211 fw with TI's 176x220 pixel UI enabled: one running on the GTA02 modem, the other running on the Pirelli DP-L10. Both were hacked up to emit raster blits of the big 176x220 pix, 16 bits per pixel color UI on the RVTMUX serial channel, running at Calypso's maximum baud rate of 812500 bps. These hacks have not been touched since 2015-09, but they can still be found in the historical leo2moko-debug and tcs211-pirelli Hg repositories on Bitbucket. A host utility named fc-lcdemu had been written to display these LCD blits emitted by those hacked-up firmwares. It receives these blits via a pipe from rvinterf and displays them in an X11 window; it thus naturally requires libX11 to compile and an X11 display to run. X11 programming is a black art which this author (Mychaela Falconia) once knew but now largely forgot, hence fc-lcdemu was based on the HECterm project (an xterm-like terminal application for X11) by the same author, but from a much earlier life phase. If you wish to resurrect and play with one of these external LCD output hacks from 2015-09, you will need to invoke rvinterf with special arguments to tell it to launch fc-lcdemu and to pass the LCD blits to it; the synopsis is as follows: rvinterf -B812500 -X fc-lcdemu /dev/ttyXXX The -B812500 argument is needed to tell rvinterf to use this high baud rate, and the -X option tells rvinterf to invoke the following named program (can be a more complex shell command) with popen(3) and then feed it LCD blits received from the target. If you use the new version of rvinterf that is about to be released with fc-host-tools-r8, the old -v option is no longer needed and no longer accepted. This 2015-09 approach was putting a huge load on the RiViera Trace mechanism, hacks were required in the firmware to massively super-size the memory space allotted to RVT and to run the RVTMUX serial channel at 812500 baud, and even with the supersized memory allocation and the maximum serial baud rate there were still some 'Lost Message' traces. The hacks on the firmware side which implement this 2015-09 approach have NOT been included in our current Magnetite firmware. 2018-03 approach ================ Rivisiting the phone UI subproject of FreeCalypso in 2018, I got another idea for how to get the LCD framebuffer bits out of a Calypso device: instead of having the firmware push them out to the trace buffer every time r2d_refresh() is called, have the fw do nothing, and have the external host read the framebuffer memory out at its own pace via ETM memory read commands. The new fc-lcdpoll utility implements this approach; in order to avoid having to reopen the X11 can of worms, I made fc-lcdpoll output the blits in the form which the already-existing fc-lcdemu code from 2015 takes as input, so you run a pipeline like this: fc-lcdpoll framebuffer_base_addr | fc-lcdemu fc-lcdpoll connects to rvinterf as a regular client, thus you would typically have rvinterf running already when you run the above pipeline in another window. fc-lcdpoll needs to know the address of the in-RAM framebuffer maintained by the R2D firmware component, and this address needs to be given on the command line. You can find it by grepping the linker-generated map file (fwimage.map or ramimage.map as appropriate) for the _r2d_lcd_memory_words symbol. This new approach works with current FC Magnetite firmware, and has been tested in a few different ways: * We have a real TI-made D-Sample board and we can run our Magnetite firmware on it, but lacking the tpudrv10 driver code for Clara RF, we are running with a non-functional placeholder stub for the TPU driver. The D-Sample board thus has no GSM radio functionality when running our fw, and the firmware can only do what any regular phone would do in an area with zero coverage: limited to stepping through menus and examining SIM phonebook entries and stored messages. The physical LCD output works, but is often garbled due to what appears to be a hardware problem. Running fc-lcdpoll|fc-lcdemu against this setup results in the virtual LCD mirroring the physical one, albeit with some lag, and the virtual LCD shows what the physical one *should* display if it weren't garbled. * One can run a UI-enabled Magnetite build on our FCDEV3B modem board and use the fc-lcdpoll|fc-lcdemu pipe to display what the fw puts in the framebuffer. Unlike the D-Sample, our FCDEV3B has perfectly working GSM radio, thus this setup allows us to see the behaviour of the UI firmware with a working radio and thus a working GSM network connection underneath. By calling the number of the SIM inserted into this setup, one can see the incoming call screen followed by the missed call indication. Because there is no physical keypad on the FCDEV3B, it appears at first that the show stops here with no way to feed keypresses to the firmware, but TI's firmware does have a mechanism for sending simulated keystrokes via RVTMUX encoded in GPF system primitives, and we have recently figured out how to use it. Our fc-shell utility now offers the new key command for sending such simulated keypresses to the target, and by combining this key entry mechanism with the present fc-lcdpoll|fc-lcdemu display viewing mechanism, we've been able to exercise the UI a little further. This approach definitely shows some promise. * The Pirelli DP-L10 target has also been tried. I was hoping that it would make a good platform by virtue of having a working GSM radio (unlike the D-Sample sans tpudrv10 code) and a physical keypad that is just like the one on the D-Sample, but no joy. When running FreeCalypso on Pirelli's alien hardware, among many other issues that kill any possibility of turning this alien hw into a libre phone, we get this one highly bizarre misbehaviour for which we have absolutely no explanation: the radio works OK *only if* the firmware is built with deep sleep enabled in CST (i.e., enabled by default on boot), and the Calypso gets to do some deep sleeps prior to the operator manually bringing it up with AT commands. If deep sleep is disabled, as soon as you try to bring the radio up, the Calypso DSP falls over with errors which we naturally have no way of debugging. The most recent experiment has revealed that this same DSP death behaviour (resulting in no working GSM radio) occurs even when deep sleep is enabled if the firmware is built in the MFW configuration (UI layers included) - as the UI layers command the radio bring-up immediately on boot, the DSP falls over. Thus we are rudely reminded once more than the Pirelli target is a dead end. Baud rate considerations ======================== The ETM memory read approach implemented in fc-lcdpoll is a lock-step, one read transaction at a time mechanism, not a continuous unstoppable stream of data like the original 2015-09 approach - therefore, it does not impose any load on the firmware's trace buffers, and it can work with RVTMUX running at any baud rate, even plain 115200. However, the slower the RVTMUX serial channel runs, the slower will the virtual LCD update, hence running the serial line at 812500 baud is still preferable. To change the RVTMUX serial baud rate from 115200 bps to 812500 bps in your Magnetite firmware build, follow these steps: * Run ./configure.sh like you normally would, selecting the UI-enabled config of interest for your target. * Go into the build directory, and before running 'make', edit config/swconfig.cfg - it is one of the config headers generated by the configure.sh process. In that configuration header file, change the TR_BAUD_CONFIG setting from TR_BAUD_115200 to TR_BAUD_812500. * Run 'make' or 'make ram' as desired after editing the swconfig.cfg header. And of course remember to pass the -B812500 option to rvinterf when talking to such trace-speed-increased firmware.