Pinscape_Controller_V2_arnoz - Mirror with some correction

Users » arnoz » Code » Pinscape_Controller_V2_arnoz

Arnaud VALLEY / Mbed 2 deprecated Pinscape_Controller_V2_arnoz

Mirror with some correction

Dependencies: mbed FastIO FastPWM USBDevice

main.cpp@75:677892300e7a, 2017-01-29 (annotated)

Committer:: mjr
Date:: Sun Jan 29 19:04:47 2017 +0000
Revision:: 75:677892300e7a
Parent:: 74:822a92bc11d2
Child:: 76:7f5912b6340e

Added SBX/PBX-is-supported flag to configuration report

Who changed what in which revision?

User	Revision	Line number	New contents of line
mjr	51:57eb311faafa	1	/* Copyright 2014, 2016 M J Roberts, MIT License
mjr	5:a70c0bce770d	2	*
mjr	5:a70c0bce770d	3	* Permission is hereby granted, free of charge, to any person obtaining a copy of this software
mjr	5:a70c0bce770d	4	* and associated documentation files (the "Software"), to deal in the Software without
mjr	5:a70c0bce770d	5	* restriction, including without limitation the rights to use, copy, modify, merge, publish,
mjr	5:a70c0bce770d	6	* distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the
mjr	5:a70c0bce770d	7	* Software is furnished to do so, subject to the following conditions:
mjr	5:a70c0bce770d	8	*
mjr	5:a70c0bce770d	9	* The above copyright notice and this permission notice shall be included in all copies or
mjr	5:a70c0bce770d	10	* substantial portions of the Software.
mjr	5:a70c0bce770d	11	*
mjr	5:a70c0bce770d	12	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING
mjr	48:058ace2aed1d	13	* BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILIT Y, FITNESS FOR A PARTICULAR PURPOSE AND
mjr	5:a70c0bce770d	14	* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM,
mjr	5:a70c0bce770d	15	* DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
mjr	5:a70c0bce770d	16	* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
mjr	5:a70c0bce770d	17	*/
mjr	5:a70c0bce770d	18
mjr	5:a70c0bce770d	19	//
mjr	35:e959ffba78fd	20	// The Pinscape Controller
mjr	35:e959ffba78fd	21	// A comprehensive input/output controller for virtual pinball machines
mjr	5:a70c0bce770d	22	//
mjr	48:058ace2aed1d	23	// This project implements an I/O controller for virtual pinball cabinets. The
mjr	48:058ace2aed1d	24	// controller's function is to connect Visual Pinball (and other Windows pinball
mjr	48:058ace2aed1d	25	// emulators) with physical devices in the cabinet: buttons, sensors, and
mjr	48:058ace2aed1d	26	// feedback devices that create visual or mechanical effects during play.
mjr	38:091e511ce8a0	27	//
mjr	48:058ace2aed1d	28	// The controller can perform several different functions, which can be used
mjr	38:091e511ce8a0	29	// individually or in any combination:
mjr	5:a70c0bce770d	30	//
mjr	38:091e511ce8a0	31	// - Nudge sensing. This uses the KL25Z's on-board accelerometer to sense the
mjr	38:091e511ce8a0	32	// motion of the cabinet when you nudge it. Visual Pinball and other pinball
mjr	38:091e511ce8a0	33	// emulators on the PC have native handling for this type of input, so that
mjr	38:091e511ce8a0	34	// physical nudges on the cabinet turn into simulated effects on the virtual
mjr	38:091e511ce8a0	35	// ball. The KL25Z measures accelerations as analog readings and is quite
mjr	38:091e511ce8a0	36	// sensitive, so the effect of a nudge on the simulation is proportional
mjr	38:091e511ce8a0	37	// to the strength of the nudge. Accelerations are reported to the PC via a
mjr	38:091e511ce8a0	38	// simulated joystick (using the X and Y axes); you just have to set some
mjr	38:091e511ce8a0	39	// preferences in your pinball software to tell it that an accelerometer
mjr	38:091e511ce8a0	40	// is attached.
mjr	5:a70c0bce770d	41	//
mjr	74:822a92bc11d2	42	// - Plunger position sensing, with multiple sensor options. To use this feature,
mjr	35:e959ffba78fd	43	// you need to choose a sensor and set it up, connect the sensor electrically to
mjr	35:e959ffba78fd	44	// the KL25Z, and configure the Pinscape software on the KL25Z to let it know how
mjr	35:e959ffba78fd	45	// the sensor is hooked up. The Pinscape software monitors the sensor and sends
mjr	35:e959ffba78fd	46	// readings to Visual Pinball via the joystick Z axis. VP and other PC software
mjr	38:091e511ce8a0	47	// have native support for this type of input; as with the nudge setup, you just
mjr	38:091e511ce8a0	48	// have to set some options in VP to activate the plunger.
mjr	17:ab3cec0c8bf4	49	//
mjr	35:e959ffba78fd	50	// The Pinscape software supports optical sensors (the TAOS TSL1410R and TSL1412R
mjr	35:e959ffba78fd	51	// linear sensor arrays) as well as slide potentiometers. The specific equipment
mjr	35:e959ffba78fd	52	// that's supported, along with physical mounting and wiring details, can be found
mjr	35:e959ffba78fd	53	// in the Build Guide.
mjr	35:e959ffba78fd	54	//
mjr	38:091e511ce8a0	55	// Note VP has built-in support for plunger devices like this one, but some VP
mjr	38:091e511ce8a0	56	// tables can't use it without some additional scripting work. The Build Guide has
mjr	38:091e511ce8a0	57	// advice on adjusting tables to add plunger support when necessary.
mjr	5:a70c0bce770d	58	//
mjr	6:cc35eb643e8f	59	// For best results, the plunger sensor should be calibrated. The calibration
mjr	6:cc35eb643e8f	60	// is stored in non-volatile memory on board the KL25Z, so it's only necessary
mjr	6:cc35eb643e8f	61	// to do the calibration once, when you first install everything. (You might
mjr	6:cc35eb643e8f	62	// also want to re-calibrate if you physically remove and reinstall the CCD
mjr	17:ab3cec0c8bf4	63	// sensor or the mechanical plunger, since their alignment shift change slightly
mjr	17:ab3cec0c8bf4	64	// when you put everything back together.) You can optionally install a
mjr	17:ab3cec0c8bf4	65	// dedicated momentary switch or pushbutton to activate the calibration mode;
mjr	17:ab3cec0c8bf4	66	// this is describe in the project documentation. If you don't want to bother
mjr	17:ab3cec0c8bf4	67	// with the extra button, you can also trigger calibration using the Windows
mjr	17:ab3cec0c8bf4	68	// setup software, which you can find on the Pinscape project page.
mjr	6:cc35eb643e8f	69	//
mjr	17:ab3cec0c8bf4	70	// The calibration procedure is described in the project documentation. Briefly,
mjr	17:ab3cec0c8bf4	71	// when you trigger calibration mode, the software will scan the CCD for about
mjr	17:ab3cec0c8bf4	72	// 15 seconds, during which you should simply pull the physical plunger back
mjr	17:ab3cec0c8bf4	73	// all the way, hold it for a moment, and then slowly return it to the rest
mjr	17:ab3cec0c8bf4	74	// position. (DON'T just release it from the retracted position, since that
mjr	17:ab3cec0c8bf4	75	// let it shoot forward too far. We want to measure the range from the park
mjr	17:ab3cec0c8bf4	76	// position to the fully retracted position only.)
mjr	5:a70c0bce770d	77	//
mjr	13:72dda449c3c0	78	// - Button input wiring. 24 of the KL25Z's GPIO ports are mapped as digital inputs
mjr	38:091e511ce8a0	79	// for buttons and switches. You can wire each input to a physical pinball-style
mjr	38:091e511ce8a0	80	// button or switch, such as flipper buttons, Start buttons, coin chute switches,
mjr	38:091e511ce8a0	81	// tilt bobs, and service buttons. Each button can be configured to be reported
mjr	38:091e511ce8a0	82	// to the PC as a joystick button or as a keyboard key (you can select which key
mjr	38:091e511ce8a0	83	// is used for each button).
mjr	13:72dda449c3c0	84	//
mjr	53:9b2611964afc	85	// - LedWiz emulation. The KL25Z can pretend to be an LedWiz device. This lets
mjr	53:9b2611964afc	86	// you connect feedback devices (lights, solenoids, motors) to GPIO ports on the
mjr	53:9b2611964afc	87	// KL25Z, and lets PC software (such as Visual Pinball) control them during game
mjr	53:9b2611964afc	88	// play to create a more immersive playing experience. The Pinscape software
mjr	53:9b2611964afc	89	// presents itself to the host as an LedWiz device and accepts the full LedWiz
mjr	53:9b2611964afc	90	// command set, so software on the PC designed for real LedWiz'es can control
mjr	53:9b2611964afc	91	// attached devices without any modifications.
mjr	5:a70c0bce770d	92	//
mjr	53:9b2611964afc	93	// Even though the software provides a very thorough LedWiz emulation, the KL25Z
mjr	53:9b2611964afc	94	// GPIO hardware design imposes some serious limitations. The big one is that
mjr	53:9b2611964afc	95	// the KL25Z only has 10 PWM channels, meaning that only 10 ports can have
mjr	53:9b2611964afc	96	// varying-intensity outputs (e.g., for controlling the brightness level of an
mjr	53:9b2611964afc	97	// LED or the speed or a motor). You can control more than 10 output ports, but
mjr	53:9b2611964afc	98	// only 10 can have PWM control; the rest are simple "digital" ports that can only
mjr	53:9b2611964afc	99	// be switched fully on or fully off. The second limitation is that the KL25Z
mjr	53:9b2611964afc	100	// just doesn't have that many GPIO ports overall. There are enough to populate
mjr	53:9b2611964afc	101	// all 32 button inputs OR all 32 LedWiz outputs, but not both. The default is
mjr	53:9b2611964afc	102	// to assign 24 buttons and 22 LedWiz ports; you can change this balance to trade
mjr	53:9b2611964afc	103	// off more outputs for fewer inputs, or vice versa. The third limitation is that
mjr	53:9b2611964afc	104	// the KL25Z GPIO pins have very tiny amperage limits - just 4mA, which isn't
mjr	53:9b2611964afc	105	// even enough to control a small LED. So in order to connect any kind of feedback
mjr	53:9b2611964afc	106	// device to an output, you must build some external circuitry to boost the
mjr	53:9b2611964afc	107	// current handing. The Build Guide has a reference circuit design for this
mjr	53:9b2611964afc	108	// purpose that's simple and inexpensive to build.
mjr	6:cc35eb643e8f	109	//
mjr	26:cb71c4af2912	110	// - Enhanced LedWiz emulation with TLC5940 PWM controller chips. You can attach
mjr	26:cb71c4af2912	111	// external PWM controller chips for controlling device outputs, instead of using
mjr	53:9b2611964afc	112	// the on-board GPIO ports as described above. The software can control a set of
mjr	53:9b2611964afc	113	// daisy-chained TLC5940 chips. Each chip provides 16 PWM outputs, so you just
mjr	53:9b2611964afc	114	// need two of them to get the full complement of 32 output ports of a real LedWiz.
mjr	53:9b2611964afc	115	// You can hook up even more, though. Four chips gives you 64 ports, which should
mjr	53:9b2611964afc	116	// be plenty for nearly any virtual pinball project. To accommodate the larger
mjr	53:9b2611964afc	117	// supply of ports possible with the PWM chips, the controller software provides
mjr	53:9b2611964afc	118	// a custom, extended version of the LedWiz protocol that can handle up to 128
mjr	53:9b2611964afc	119	// ports. PC software designed only for the real LedWiz obviously won't know
mjr	53:9b2611964afc	120	// about the extended protocol and won't be able to take advantage of its extra
mjr	53:9b2611964afc	121	// capabilities, but the latest version of DOF (DirectOutput Framework) does
mjr	53:9b2611964afc	122	// know the new language and can take full advantage. Older software will still
mjr	53:9b2611964afc	123	// work, though - the new extensions are all backward compatible, so old software
mjr	53:9b2611964afc	124	// that only knows about the original LedWiz protocol will still work, with the
mjr	53:9b2611964afc	125	// obvious limitation that it can only access the first 32 ports.
mjr	53:9b2611964afc	126	//
mjr	53:9b2611964afc	127	// The Pinscape Expansion Board project (which appeared in early 2016) provides
mjr	53:9b2611964afc	128	// a reference hardware design, with EAGLE circuit board layouts, that takes full
mjr	53:9b2611964afc	129	// advantage of the TLC5940 capability. It lets you create a customized set of
mjr	53:9b2611964afc	130	// outputs with full PWM control and power handling for high-current devices
mjr	53:9b2611964afc	131	// built in to the boards.
mjr	26:cb71c4af2912	132	//
mjr	38:091e511ce8a0	133	// - Night Mode control for output devices. You can connect a switch or button
mjr	38:091e511ce8a0	134	// to the controller to activate "Night Mode", which disables feedback devices
mjr	38:091e511ce8a0	135	// that you designate as noisy. You can designate outputs individually as being
mjr	38:091e511ce8a0	136	// included in this set or not. This is useful if you want to play a game on
mjr	38:091e511ce8a0	137	// your cabinet late at night without waking the kids and annoying the neighbors.
mjr	38:091e511ce8a0	138	//
mjr	38:091e511ce8a0	139	// - TV ON switch. The controller can pulse a relay to turn on your TVs after
mjr	38:091e511ce8a0	140	// power to the cabinet comes on, with a configurable delay timer. This feature
mjr	38:091e511ce8a0	141	// is for TVs that don't turn themselves on automatically when first plugged in.
mjr	38:091e511ce8a0	142	// To use this feature, you have to build some external circuitry to allow the
mjr	38:091e511ce8a0	143	// software to sense the power supply status, and you have to run wires to your
mjr	38:091e511ce8a0	144	// TV's on/off button, which requires opening the case on your TV. The Build
mjr	38:091e511ce8a0	145	// Guide has details on the necessary circuitry and connections to the TV.
mjr	38:091e511ce8a0	146	//
mjr	35:e959ffba78fd	147	//
mjr	35:e959ffba78fd	148	//
mjr	33:d832bcab089e	149	// STATUS LIGHTS: The on-board LED on the KL25Z flashes to indicate the current
mjr	33:d832bcab089e	150	// device status. The flash patterns are:
mjr	6:cc35eb643e8f	151	//
mjr	48:058ace2aed1d	152	// short yellow flash = waiting to connect
mjr	6:cc35eb643e8f	153	//
mjr	48:058ace2aed1d	154	// short red flash = the connection is suspended (the host is in sleep
mjr	48:058ace2aed1d	155	// or suspend mode, the USB cable is unplugged after a connection
mjr	48:058ace2aed1d	156	// has been established)
mjr	48:058ace2aed1d	157	//
mjr	48:058ace2aed1d	158	// two short red flashes = connection lost (the device should immediately
mjr	48:058ace2aed1d	159	// go back to short-yellow "waiting to reconnect" mode when a connection
mjr	48:058ace2aed1d	160	// is lost, so this display shouldn't normally appear)
mjr	6:cc35eb643e8f	161	//
mjr	38:091e511ce8a0	162	// long red/yellow = USB connection problem. The device still has a USB
mjr	48:058ace2aed1d	163	// connection to the host (or so it appears to the device), but data
mjr	48:058ace2aed1d	164	// transmissions are failing.
mjr	38:091e511ce8a0	165	//
mjr	73:4e8ce0b18915	166	// medium blue flash = TV ON delay timer running. This means that the
mjr	73:4e8ce0b18915	167	// power to the secondary PSU has just been turned on, and the TV ON
mjr	73:4e8ce0b18915	168	// timer is waiting for the configured delay time before pulsing the
mjr	73:4e8ce0b18915	169	// TV power button relay. This is only shown if the TV ON feature is
mjr	73:4e8ce0b18915	170	// enabled.
mjr	73:4e8ce0b18915	171	//
mjr	6:cc35eb643e8f	172	// long yellow/green = everything's working, but the plunger hasn't
mjr	38:091e511ce8a0	173	// been calibrated. Follow the calibration procedure described in
mjr	38:091e511ce8a0	174	// the project documentation. This flash mode won't appear if there's
mjr	38:091e511ce8a0	175	// no plunger sensor configured.
mjr	6:cc35eb643e8f	176	//
mjr	38:091e511ce8a0	177	// alternating blue/green = everything's working normally, and plunger
mjr	38:091e511ce8a0	178	// calibration has been completed (or there's no plunger attached)
mjr	10:976666ffa4ef	179	//
mjr	48:058ace2aed1d	180	// fast red/purple = out of memory. The controller halts and displays
mjr	48:058ace2aed1d	181	// this diagnostic code until you manually reset it. If this happens,
mjr	48:058ace2aed1d	182	// it's probably because the configuration is too complex, in which
mjr	48:058ace2aed1d	183	// case the same error will occur after the reset. If it's stuck
mjr	48:058ace2aed1d	184	// in this cycle, you'll have to restore the default configuration
mjr	48:058ace2aed1d	185	// by re-installing the controller software (the Pinscape .bin file).
mjr	10:976666ffa4ef	186	//
mjr	48:058ace2aed1d	187	//
mjr	48:058ace2aed1d	188	// USB PROTOCOL: Most of our USB messaging is through standard USB HID
mjr	48:058ace2aed1d	189	// classes (joystick, keyboard). We also accept control messages on our
mjr	48:058ace2aed1d	190	// primary HID interface "OUT endpoint" using a custom protocol that's
mjr	48:058ace2aed1d	191	// not defined in any USB standards (we do have to provide a USB HID
mjr	48:058ace2aed1d	192	// Report Descriptor for it, but this just describes the protocol as
mjr	48:058ace2aed1d	193	// opaque vendor-defined bytes). The control protocol incorporates the
mjr	48:058ace2aed1d	194	// LedWiz protocol as a subset, and adds our own private extensions.
mjr	48:058ace2aed1d	195	// For full details, see USBProtocol.h.
mjr	33:d832bcab089e	196
mjr	33:d832bcab089e	197
mjr	0:5acbbe3f4cf4	198	#include "mbed.h"
mjr	6:cc35eb643e8f	199	#include "math.h"
mjr	74:822a92bc11d2	200	#include "diags.h"
mjr	48:058ace2aed1d	201	#include "pinscape.h"
mjr	0:5acbbe3f4cf4	202	#include "USBJoystick.h"
mjr	0:5acbbe3f4cf4	203	#include "MMA8451Q.h"
mjr	1:d913e0afb2ac	204	#include "tsl1410r.h"
mjr	1:d913e0afb2ac	205	#include "FreescaleIAP.h"
mjr	2:c174f9ee414a	206	#include "crc32.h"
mjr	26:cb71c4af2912	207	#include "TLC5940.h"
mjr	34:6b981a2afab7	208	#include "74HC595.h"
mjr	35:e959ffba78fd	209	#include "nvm.h"
mjr	35:e959ffba78fd	210	#include "plunger.h"
mjr	35:e959ffba78fd	211	#include "ccdSensor.h"
mjr	35:e959ffba78fd	212	#include "potSensor.h"
mjr	35:e959ffba78fd	213	#include "nullSensor.h"
mjr	48:058ace2aed1d	214	#include "TinyDigitalIn.h"
mjr	74:822a92bc11d2	215
mjr	2:c174f9ee414a	216
mjr	21:5048e16cc9ef	217	#define DECL_EXTERNS
mjr	17:ab3cec0c8bf4	218	#include "config.h"
mjr	17:ab3cec0c8bf4	219
mjr	53:9b2611964afc	220
mjr	53:9b2611964afc	221	// --------------------------------------------------------------------------
mjr	53:9b2611964afc	222	//
mjr	53:9b2611964afc	223	// OpenSDA module identifier. This is for the benefit of the Windows
mjr	53:9b2611964afc	224	// configuration tool. When the config tool installs a .bin file onto
mjr	53:9b2611964afc	225	// the KL25Z, it will first find the sentinel string within the .bin file,
mjr	53:9b2611964afc	226	// and patch the "\0" bytes that follow the sentinel string with the
mjr	53:9b2611964afc	227	// OpenSDA module ID data. This allows us to report the OpenSDA
mjr	53:9b2611964afc	228	// identifiers back to the host system via USB, which in turn allows the
mjr	53:9b2611964afc	229	// config tool to figure out which OpenSDA MSD (mass storage device - a
mjr	53:9b2611964afc	230	// virtual disk drive) correlates to which Pinscape controller USB
mjr	53:9b2611964afc	231	// interface.
mjr	53:9b2611964afc	232	//
mjr	53:9b2611964afc	233	// This is only important if multiple Pinscape devices are attached to
mjr	53:9b2611964afc	234	// the same host. There doesn't seem to be any other way to figure out
mjr	53:9b2611964afc	235	// which OpenSDA MSD corresponds to which KL25Z USB interface; the OpenSDA
mjr	53:9b2611964afc	236	// MSD doesn't report the KL25Z CPU ID anywhere, and the KL25Z doesn't
mjr	53:9b2611964afc	237	// have any way to learn about the OpenSDA module it's connected to. The
mjr	53:9b2611964afc	238	// only way to pass this information to the KL25Z side that I can come up
mjr	53:9b2611964afc	239	// with is to have the Windows host embed it in the .bin file before
mjr	53:9b2611964afc	240	// downloading it to the OpenSDA MSD.
mjr	53:9b2611964afc	241	//
mjr	53:9b2611964afc	242	// We initialize the const data buffer (the part after the sentinel string)
mjr	53:9b2611964afc	243	// with all "\0" bytes, so that's what will be in the executable image that
mjr	53:9b2611964afc	244	// comes out of the mbed compiler. If you manually install the resulting
mjr	53:9b2611964afc	245	// .bin file onto the KL25Z (via the Windows desktop, say), the "\0" bytes
mjr	53:9b2611964afc	246	// will stay this way and read as all 0's at run-time. Since a real TUID
mjr	53:9b2611964afc	247	// would never be all 0's, that tells us that we were never patched and
mjr	53:9b2611964afc	248	// thus don't have any information on the OpenSDA module.
mjr	53:9b2611964afc	249	//
mjr	53:9b2611964afc	250	const char *getOpenSDAID()
mjr	53:9b2611964afc	251	{
mjr	53:9b2611964afc	252	#define OPENSDA_PREFIX "///Pinscape.OpenSDA.TUID///"
mjr	53:9b2611964afc	253	static const char OpenSDA[] = OPENSDA_PREFIX "\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0///";
mjr	53:9b2611964afc	254	const size_t OpenSDA_prefix_length = sizeof(OPENSDA_PREFIX) - 1;
mjr	53:9b2611964afc	255
mjr	53:9b2611964afc	256	return OpenSDA + OpenSDA_prefix_length;
mjr	53:9b2611964afc	257	}
mjr	53:9b2611964afc	258
mjr	53:9b2611964afc	259	// --------------------------------------------------------------------------
mjr	53:9b2611964afc	260	//
mjr	53:9b2611964afc	261	// Build ID. We use the date and time of compiling the program as a build
mjr	53:9b2611964afc	262	// identifier. It would be a little nicer to use a simple serial number
mjr	53:9b2611964afc	263	// instead, but the mbed platform doesn't have a way to automate that. The
mjr	53:9b2611964afc	264	// timestamp is a pretty good proxy for a serial number in that it will
mjr	53:9b2611964afc	265	// naturally increase on each new build, which is the primary property we
mjr	53:9b2611964afc	266	// want from this.
mjr	53:9b2611964afc	267	//
mjr	53:9b2611964afc	268	// As with the embedded OpenSDA ID, we store the build timestamp with a
mjr	53:9b2611964afc	269	// sentinel string prefix, to allow automated tools to find the static data
mjr	53:9b2611964afc	270	// in the .bin file by searching for the sentinel string. In contrast to
mjr	53:9b2611964afc	271	// the OpenSDA ID, the value we store here is for tools to extract rather
mjr	53:9b2611964afc	272	// than store, since we automatically populate it via the preprocessor
mjr	53:9b2611964afc	273	// macros.
mjr	53:9b2611964afc	274	//
mjr	53:9b2611964afc	275	const char *getBuildID()
mjr	53:9b2611964afc	276	{
mjr	53:9b2611964afc	277	#define BUILDID_PREFIX "///Pinscape.Build.ID///"
mjr	53:9b2611964afc	278	static const char BuildID[] = BUILDID_PREFIX __DATE__ " " __TIME__ "///";
mjr	53:9b2611964afc	279	const size_t BuildID_prefix_length = sizeof(BUILDID_PREFIX) - 1;
mjr	53:9b2611964afc	280
mjr	53:9b2611964afc	281	return BuildID + BuildID_prefix_length;
mjr	53:9b2611964afc	282	}
mjr	53:9b2611964afc	283
mjr	74:822a92bc11d2	284	// --------------------------------------------------------------------------
mjr	74:822a92bc11d2	285	// Main loop iteration timing statistics. Collected only if
mjr	74:822a92bc11d2	286	// ENABLE_DIAGNOSTICS is set in diags.h.
mjr	74:822a92bc11d2	287	float mainLoopIterTime, mainLoopIterCount;
mjr	74:822a92bc11d2	288	float mainLoopMsgTime, mainLoopMsgCount;
mjr	53:9b2611964afc	289
mjr	48:058ace2aed1d	290	// --------------------------------------------------------------------------
mjr	48:058ace2aed1d	291	//
mjr	59:94eb9265b6d7	292	// Custom memory allocator. We use our own version of malloc() for more
mjr	59:94eb9265b6d7	293	// efficient memory usage, and to provide diagnostics if we run out of heap.
mjr	48:058ace2aed1d	294	//
mjr	59:94eb9265b6d7	295	// We can implement a more efficient malloc than the library can because we
mjr	59:94eb9265b6d7	296	// can make an assumption that the library can't: allocations are permanent.
mjr	59:94eb9265b6d7	297	// The normal malloc has to assume that allocations can be freed, so it has
mjr	59:94eb9265b6d7	298	// to track blocks individually. For the purposes of this program, though,
mjr	59:94eb9265b6d7	299	// we don't have to do this because virtually all of our allocations are
mjr	59:94eb9265b6d7	300	// de facto permanent. We only allocate dyanmic memory during setup, and
mjr	59:94eb9265b6d7	301	// once we set things up, we never delete anything. This means that we can
mjr	59:94eb9265b6d7	302	// allocate memory in bare blocks without any bookkeeping overhead.
mjr	59:94eb9265b6d7	303	//
mjr	59:94eb9265b6d7	304	// In addition, we can make a much larger overall pool of memory available
mjr	59:94eb9265b6d7	305	// in a custom allocator. The mbed library malloc() seems to have a pool
mjr	59:94eb9265b6d7	306	// of about 3K to work with, even though there's really about 9K of RAM
mjr	59:94eb9265b6d7	307	// left over after counting the static writable data and reserving space
mjr	59:94eb9265b6d7	308	// for a reasonable stack. I haven't looked at the mbed malloc to see why
mjr	59:94eb9265b6d7	309	// they're so stingy, but it appears from empirical testing that we can
mjr	59:94eb9265b6d7	310	// create a static array up to about 9K before things get crashy.
mjr	59:94eb9265b6d7	311
mjr	73:4e8ce0b18915	312	// Dynamic memory pool. We'll reserve space for all dynamic
mjr	73:4e8ce0b18915	313	// allocations by creating a simple C array of bytes. The size
mjr	73:4e8ce0b18915	314	// of this array is the maximum number of bytes we can allocate
mjr	73:4e8ce0b18915	315	// with malloc or operator 'new'.
mjr	73:4e8ce0b18915	316	//
mjr	73:4e8ce0b18915	317	// The maximum safe size for this array is, in essence, the
mjr	73:4e8ce0b18915	318	// amount of physical KL25Z RAM left over after accounting for
mjr	73:4e8ce0b18915	319	// static data throughout the rest of the program, the run-time
mjr	73:4e8ce0b18915	320	// stack, and any other space reserved for compiler or MCU
mjr	73:4e8ce0b18915	321	// overhead. Unfortunately, it's not straightforward to
mjr	73:4e8ce0b18915	322	// determine this analytically. The big complication is that
mjr	73:4e8ce0b18915	323	// the minimum stack size isn't easily predictable, as the stack
mjr	73:4e8ce0b18915	324	// grows according to what the program does. In addition, the
mjr	73:4e8ce0b18915	325	// mbed platform tools don't give us detailed data on the
mjr	73:4e8ce0b18915	326	// compiler/linker memory map. All we get is a generic total
mjr	73:4e8ce0b18915	327	// RAM requirement, which doesn't necessarily account for all
mjr	73:4e8ce0b18915	328	// overhead (e.g., gaps inserted to get proper alignment for
mjr	73:4e8ce0b18915	329	// particular memory blocks).
mjr	73:4e8ce0b18915	330	//
mjr	73:4e8ce0b18915	331	// A very rough estimate: the total RAM size reported by the
mjr	73:4e8ce0b18915	332	// linker is about 3.5K (currently - that can obviously change
mjr	73:4e8ce0b18915	333	// as the project evolves) out of 16K total. Assuming about a
mjr	73:4e8ce0b18915	334	// 3K stack, that leaves in the ballpark of 10K. Empirically,
mjr	73:4e8ce0b18915	335	// that seems pretty close. In testing, we start to see some
mjr	73:4e8ce0b18915	336	// instability at 10K, while 9K seems safe. To be conservative,
mjr	73:4e8ce0b18915	337	// we'll reduce this to 8K.
mjr	73:4e8ce0b18915	338	//
mjr	73:4e8ce0b18915	339	// Our measured total usage in the base configuration (22 GPIO
mjr	73:4e8ce0b18915	340	// output ports, TSL1410R plunger sensor) is about 4000 bytes.
mjr	73:4e8ce0b18915	341	// A pretty fully decked-out configuration (121 output ports,
mjr	73:4e8ce0b18915	342	// with 8 TLC5940 chips and 3 74HC595 chips, plus the TSL1412R
mjr	73:4e8ce0b18915	343	// sensor with the higher pixel count, and all expansion board
mjr	73:4e8ce0b18915	344	// features enabled) comes to about 6700 bytes. That leaves
mjr	73:4e8ce0b18915	345	// us with about 1.5K free out of our 8K, so we still have a
mjr	73:4e8ce0b18915	346	// little more headroom for future expansion.
mjr	73:4e8ce0b18915	347	//
mjr	73:4e8ce0b18915	348	// For comparison, the standard mbed malloc() runs out of
mjr	73:4e8ce0b18915	349	// memory at about 6K. That's what led to this custom malloc:
mjr	73:4e8ce0b18915	350	// we can just fit the base configuration into that 4K, but
mjr	73:4e8ce0b18915	351	// it's not enough space for more complex setups. There's
mjr	73:4e8ce0b18915	352	// still a little room for squeezing out unnecessary space
mjr	73:4e8ce0b18915	353	// from the mbed library code, but at this point I'd prefer
mjr	73:4e8ce0b18915	354	// to treat that as a last resort, since it would mean having
mjr	73:4e8ce0b18915	355	// to fork private copies of the libraries.
mjr	73:4e8ce0b18915	356	static const size_t XMALLOC_POOL_SIZE = 8*1024;
mjr	73:4e8ce0b18915	357	static char xmalloc_pool[XMALLOC_POOL_SIZE];
mjr	73:4e8ce0b18915	358	static char *xmalloc_nxt = xmalloc_pool;
mjr	73:4e8ce0b18915	359	static size_t xmalloc_rem = XMALLOC_POOL_SIZE;
mjr	73:4e8ce0b18915	360
mjr	48:058ace2aed1d	361	void *xmalloc(size_t siz)
mjr	48:058ace2aed1d	362	{
mjr	59:94eb9265b6d7	363	// align to a 4-byte increment
mjr	59:94eb9265b6d7	364	siz = (siz + 3) & ~3;
mjr	59:94eb9265b6d7	365
mjr	59:94eb9265b6d7	366	// If insufficient memory is available, halt and show a fast red/purple
mjr	59:94eb9265b6d7	367	// diagnostic flash. We don't want to return, since we assume throughout
mjr	59:94eb9265b6d7	368	// the program that all memory allocations must succeed. Note that this
mjr	59:94eb9265b6d7	369	// is generally considered bad programming practice in applications on
mjr	59:94eb9265b6d7	370	// "real" computers, but for the purposes of this microcontroller app,
mjr	59:94eb9265b6d7	371	// there's no point in checking for failed allocations individually
mjr	59:94eb9265b6d7	372	// because there's no way to recover from them. It's better in this
mjr	59:94eb9265b6d7	373	// context to handle failed allocations as fatal errors centrally. We
mjr	59:94eb9265b6d7	374	// can't recover from these automatically, so we have to resort to user
mjr	59:94eb9265b6d7	375	// intervention, which we signal with the diagnostic LED flashes.
mjr	73:4e8ce0b18915	376	if (siz > xmalloc_rem)
mjr	59:94eb9265b6d7	377	{
mjr	59:94eb9265b6d7	378	// halt with the diagnostic display (by looping forever)
mjr	59:94eb9265b6d7	379	for (;;)
mjr	59:94eb9265b6d7	380	{
mjr	59:94eb9265b6d7	381	diagLED(1, 0, 0);
mjr	59:94eb9265b6d7	382	wait_us(200000);
mjr	59:94eb9265b6d7	383	diagLED(1, 0, 1);
mjr	59:94eb9265b6d7	384	wait_us(200000);
mjr	59:94eb9265b6d7	385	}
mjr	59:94eb9265b6d7	386	}
mjr	48:058ace2aed1d	387
mjr	59:94eb9265b6d7	388	// get the next free location from the pool to return
mjr	73:4e8ce0b18915	389	char *ret = xmalloc_nxt;
mjr	59:94eb9265b6d7	390
mjr	59:94eb9265b6d7	391	// advance the pool pointer and decrement the remaining size counter
mjr	73:4e8ce0b18915	392	xmalloc_nxt += siz;
mjr	73:4e8ce0b18915	393	xmalloc_rem -= siz;
mjr	59:94eb9265b6d7	394
mjr	59:94eb9265b6d7	395	// return the allocated block
mjr	59:94eb9265b6d7	396	return ret;
mjr	73:4e8ce0b18915	397	};
mjr	73:4e8ce0b18915	398
mjr	73:4e8ce0b18915	399	// our malloc() replacement
mjr	48:058ace2aed1d	400
mjr	59:94eb9265b6d7	401	// Overload operator new to call our custom malloc. This ensures that
mjr	59:94eb9265b6d7	402	// all 'new' allocations throughout the program (including library code)
mjr	59:94eb9265b6d7	403	// go through our private allocator.
mjr	48:058ace2aed1d	404	void *operator new(size_t siz) { return xmalloc(siz); }
mjr	48:058ace2aed1d	405	void *operator new[](size_t siz) { return xmalloc(siz); }
mjr	5:a70c0bce770d	406
mjr	59:94eb9265b6d7	407	// Since we don't do bookkeeping to track released memory, 'delete' does
mjr	59:94eb9265b6d7	408	// nothing. In actual testing, this routine appears to never be called.
mjr	59:94eb9265b6d7	409	// If it is ever called, it will simply leave the block in place, which
mjr	59:94eb9265b6d7	410	// will make it unavailable for re-use but will otherwise be harmless.
mjr	59:94eb9265b6d7	411	void operator delete(void *ptr) { }
mjr	59:94eb9265b6d7	412
mjr	59:94eb9265b6d7	413
mjr	5:a70c0bce770d	414	// ---------------------------------------------------------------------------
mjr	38:091e511ce8a0	415	//
mjr	38:091e511ce8a0	416	// Forward declarations
mjr	38:091e511ce8a0	417	//
mjr	38:091e511ce8a0	418	void setNightMode(bool on);
mjr	38:091e511ce8a0	419	void toggleNightMode();
mjr	38:091e511ce8a0	420
mjr	38:091e511ce8a0	421	// ---------------------------------------------------------------------------
mjr	17:ab3cec0c8bf4	422	// utilities
mjr	17:ab3cec0c8bf4	423
mjr	26:cb71c4af2912	424	// floating point square of a number
mjr	26:cb71c4af2912	425	inline float square(float x) { return x*x; }
mjr	26:cb71c4af2912	426
mjr	26:cb71c4af2912	427	// floating point rounding
mjr	26:cb71c4af2912	428	inline float round(float x) { return x > 0 ? floor(x + 0.5) : ceil(x - 0.5); }
mjr	26:cb71c4af2912	429
mjr	17:ab3cec0c8bf4	430
mjr	33:d832bcab089e	431	// --------------------------------------------------------------------------
mjr	33:d832bcab089e	432	//
mjr	40:cc0d9814522b	433	// Extended verison of Timer class. This adds the ability to interrogate
mjr	40:cc0d9814522b	434	// the running state.
mjr	40:cc0d9814522b	435	//
mjr	40:cc0d9814522b	436	class Timer2: public Timer
mjr	40:cc0d9814522b	437	{
mjr	40:cc0d9814522b	438	public:
mjr	40:cc0d9814522b	439	Timer2() : running(false) { }
mjr	40:cc0d9814522b	440
mjr	40:cc0d9814522b	441	void start() { running = true; Timer::start(); }
mjr	40:cc0d9814522b	442	void stop() { running = false; Timer::stop(); }
mjr	40:cc0d9814522b	443
mjr	40:cc0d9814522b	444	bool isRunning() const { return running; }
mjr	40:cc0d9814522b	445
mjr	40:cc0d9814522b	446	private:
mjr	40:cc0d9814522b	447	bool running;
mjr	40:cc0d9814522b	448	};
mjr	40:cc0d9814522b	449
mjr	53:9b2611964afc	450
mjr	53:9b2611964afc	451	// --------------------------------------------------------------------------
mjr	53:9b2611964afc	452	//
mjr	53:9b2611964afc	453	// Reboot timer. When we have a deferred reboot operation pending, we
mjr	53:9b2611964afc	454	// set the target time and start the timer.
mjr	53:9b2611964afc	455	Timer2 rebootTimer;
mjr	53:9b2611964afc	456	long rebootTime_us;
mjr	53:9b2611964afc	457
mjr	40:cc0d9814522b	458	// --------------------------------------------------------------------------
mjr	40:cc0d9814522b	459	//
mjr	33:d832bcab089e	460	// USB product version number
mjr	5:a70c0bce770d	461	//
mjr	47:df7a88cd249c	462	const uint16_t USB_VERSION_NO = 0x000A;
mjr	33:d832bcab089e	463
mjr	33:d832bcab089e	464	// --------------------------------------------------------------------------
mjr	33:d832bcab089e	465	//
mjr	6:cc35eb643e8f	466	// Joystick axis report range - we report from -JOYMAX to +JOYMAX
mjr	33:d832bcab089e	467	//
mjr	6:cc35eb643e8f	468	#define JOYMAX 4096
mjr	6:cc35eb643e8f	469
mjr	9:fd65b0a94720	470
mjr	17:ab3cec0c8bf4	471	// ---------------------------------------------------------------------------
mjr	17:ab3cec0c8bf4	472	//
mjr	40:cc0d9814522b	473	// Wire protocol value translations. These translate byte values to and
mjr	40:cc0d9814522b	474	// from the USB protocol to local native format.
mjr	35:e959ffba78fd	475	//
mjr	35:e959ffba78fd	476
mjr	35:e959ffba78fd	477	// unsigned 16-bit integer
mjr	35:e959ffba78fd	478	inline uint16_t wireUI16(const uint8_t *b)
mjr	35:e959ffba78fd	479	{
mjr	35:e959ffba78fd	480	return b[0] \| ((uint16_t)b[1] << 8);
mjr	35:e959ffba78fd	481	}
mjr	40:cc0d9814522b	482	inline void ui16Wire(uint8_t *b, uint16_t val)
mjr	40:cc0d9814522b	483	{
mjr	40:cc0d9814522b	484	b[0] = (uint8_t)(val & 0xff);
mjr	40:cc0d9814522b	485	b[1] = (uint8_t)((val >> 8) & 0xff);
mjr	40:cc0d9814522b	486	}
mjr	35:e959ffba78fd	487
mjr	35:e959ffba78fd	488	inline int16_t wireI16(const uint8_t *b)
mjr	35:e959ffba78fd	489	{
mjr	35:e959ffba78fd	490	return (int16_t)wireUI16(b);
mjr	35:e959ffba78fd	491	}
mjr	40:cc0d9814522b	492	inline void i16Wire(uint8_t *b, int16_t val)
mjr	40:cc0d9814522b	493	{
mjr	40:cc0d9814522b	494	ui16Wire(b, (uint16_t)val);
mjr	40:cc0d9814522b	495	}
mjr	35:e959ffba78fd	496
mjr	35:e959ffba78fd	497	inline uint32_t wireUI32(const uint8_t *b)
mjr	35:e959ffba78fd	498	{
mjr	35:e959ffba78fd	499	return b[0] \| ((uint32_t)b[1] << 8) \| ((uint32_t)b[2] << 16) \| ((uint32_t)b[3] << 24);
mjr	35:e959ffba78fd	500	}
mjr	40:cc0d9814522b	501	inline void ui32Wire(uint8_t *b, uint32_t val)
mjr	40:cc0d9814522b	502	{
mjr	40:cc0d9814522b	503	b[0] = (uint8_t)(val & 0xff);
mjr	40:cc0d9814522b	504	b[1] = (uint8_t)((val >> 8) & 0xff);
mjr	40:cc0d9814522b	505	b[2] = (uint8_t)((val >> 16) & 0xff);
mjr	40:cc0d9814522b	506	b[3] = (uint8_t)((val >> 24) & 0xff);
mjr	40:cc0d9814522b	507	}
mjr	35:e959ffba78fd	508
mjr	35:e959ffba78fd	509	inline int32_t wireI32(const uint8_t *b)
mjr	35:e959ffba78fd	510	{
mjr	35:e959ffba78fd	511	return (int32_t)wireUI32(b);
mjr	35:e959ffba78fd	512	}
mjr	35:e959ffba78fd	513
mjr	53:9b2611964afc	514	// Convert "wire" (USB) pin codes to/from PinName values.
mjr	53:9b2611964afc	515	//
mjr	53:9b2611964afc	516	// The internal mbed PinName format is
mjr	53:9b2611964afc	517	//
mjr	53:9b2611964afc	518	// ((port) << PORT_SHIFT) \| (pin << 2) // MBED FORMAT
mjr	53:9b2611964afc	519	//
mjr	53:9b2611964afc	520	// where 'port' is 0-4 for Port A to Port E, and 'pin' is
mjr	53:9b2611964afc	521	// 0 to 31. E.g., E31 is (4 << PORT_SHIFT) \| (31<<2).
mjr	53:9b2611964afc	522	//
mjr	53:9b2611964afc	523	// We remap this to our more compact wire format where each
mjr	53:9b2611964afc	524	// pin name fits in 8 bits:
mjr	53:9b2611964afc	525	//
mjr	53:9b2611964afc	526	// ((port) << 5) \| pin) // WIRE FORMAT
mjr	53:9b2611964afc	527	//
mjr	53:9b2611964afc	528	// E.g., E31 is (4 << 5) \| 31.
mjr	53:9b2611964afc	529	//
mjr	53:9b2611964afc	530	// Wire code FF corresponds to PinName NC (not connected).
mjr	53:9b2611964afc	531	//
mjr	53:9b2611964afc	532	inline PinName wirePinName(uint8_t c)
mjr	35:e959ffba78fd	533	{
mjr	53:9b2611964afc	534	if (c == 0xFF)
mjr	53:9b2611964afc	535	return NC; // 0xFF -> NC
mjr	53:9b2611964afc	536	else
mjr	53:9b2611964afc	537	return PinName(
mjr	53:9b2611964afc	538	(int(c & 0xE0) << (PORT_SHIFT - 5)) // top three bits are the port
mjr	53:9b2611964afc	539	\| (int(c & 0x1F) << 2)); // bottom five bits are pin
mjr	40:cc0d9814522b	540	}
mjr	40:cc0d9814522b	541	inline void pinNameWire(uint8_t *b, PinName n)
mjr	40:cc0d9814522b	542	{
mjr	53:9b2611964afc	543	*b = PINNAME_TO_WIRE(n);
mjr	35:e959ffba78fd	544	}
mjr	35:e959ffba78fd	545
mjr	35:e959ffba78fd	546
mjr	35:e959ffba78fd	547	// ---------------------------------------------------------------------------
mjr	35:e959ffba78fd	548	//
mjr	38:091e511ce8a0	549	// On-board RGB LED elements - we use these for diagnostic displays.
mjr	38:091e511ce8a0	550	//
mjr	38:091e511ce8a0	551	// Note that LED3 (the blue segment) is hard-wired on the KL25Z to PTD1,
mjr	38:091e511ce8a0	552	// so PTD1 shouldn't be used for any other purpose (e.g., as a keyboard
mjr	38:091e511ce8a0	553	// input or a device output). This is kind of unfortunate in that it's
mjr	38:091e511ce8a0	554	// one of only two ports exposed on the jumper pins that can be muxed to
mjr	38:091e511ce8a0	555	// SPI0 SCLK. This effectively limits us to PTC5 if we want to use the
mjr	38:091e511ce8a0	556	// SPI capability.
mjr	38:091e511ce8a0	557	//
mjr	38:091e511ce8a0	558	DigitalOut ledR, ledG, *ledB;
mjr	38:091e511ce8a0	559
mjr	73:4e8ce0b18915	560	// Power on timer state for diagnostics. We flash the blue LED when
mjr	73:4e8ce0b18915	561	// nothing else is going on. State 0-1 = off, 2-3 = on
mjr	73:4e8ce0b18915	562	uint8_t powerTimerDiagState = 0;
mjr	73:4e8ce0b18915	563
mjr	38:091e511ce8a0	564	// Show the indicated pattern on the diagnostic LEDs. 0 is off, 1 is
mjr	38:091e511ce8a0	565	// on, and -1 is no change (leaves the current setting intact).
mjr	73:4e8ce0b18915	566	static uint8_t diagLEDState = 0;
mjr	38:091e511ce8a0	567	void diagLED(int r, int g, int b)
mjr	38:091e511ce8a0	568	{
mjr	73:4e8ce0b18915	569	// remember the new state
mjr	73:4e8ce0b18915	570	diagLEDState = r \| (g << 1) \| (b << 2);
mjr	73:4e8ce0b18915	571
mjr	73:4e8ce0b18915	572	// if turning everything off, use the power timer state instead,
mjr	73:4e8ce0b18915	573	// applying it to the blue LED
mjr	73:4e8ce0b18915	574	if (diagLEDState == 0)
mjr	73:4e8ce0b18915	575	b = (powerTimerDiagState >= 2);
mjr	73:4e8ce0b18915	576
mjr	73:4e8ce0b18915	577	// set the new state
mjr	38:091e511ce8a0	578	if (ledR != 0 && r != -1) ledR->write(!r);
mjr	38:091e511ce8a0	579	if (ledG != 0 && g != -1) ledG->write(!g);
mjr	38:091e511ce8a0	580	if (ledB != 0 && b != -1) ledB->write(!b);
mjr	38:091e511ce8a0	581	}
mjr	38:091e511ce8a0	582
mjr	73:4e8ce0b18915	583	// update the LEDs with the current state
mjr	73:4e8ce0b18915	584	void diagLED(void)
mjr	73:4e8ce0b18915	585	{
mjr	73:4e8ce0b18915	586	diagLED(
mjr	73:4e8ce0b18915	587	diagLEDState & 0x01,
mjr	73:4e8ce0b18915	588	(diagLEDState >> 1) & 0x01,
mjr	73:4e8ce0b18915	589	(diagLEDState >> 1) & 0x02);
mjr	73:4e8ce0b18915	590	}
mjr	73:4e8ce0b18915	591
mjr	38:091e511ce8a0	592	// check an output port assignment to see if it conflicts with
mjr	38:091e511ce8a0	593	// an on-board LED segment
mjr	38:091e511ce8a0	594	struct LedSeg
mjr	38:091e511ce8a0	595	{
mjr	38:091e511ce8a0	596	bool r, g, b;
mjr	38:091e511ce8a0	597	LedSeg() { r = g = b = false; }
mjr	38:091e511ce8a0	598
mjr	38:091e511ce8a0	599	void check(LedWizPortCfg &pc)
mjr	38:091e511ce8a0	600	{
mjr	38:091e511ce8a0	601	// if it's a GPIO, check to see if it's assigned to one of
mjr	38:091e511ce8a0	602	// our on-board LED segments
mjr	38:091e511ce8a0	603	int t = pc.typ;
mjr	38:091e511ce8a0	604	if (t == PortTypeGPIOPWM \|\| t == PortTypeGPIODig)
mjr	38:091e511ce8a0	605	{
mjr	38:091e511ce8a0	606	// it's a GPIO port - check for a matching pin assignment
mjr	38:091e511ce8a0	607	PinName pin = wirePinName(pc.pin);
mjr	38:091e511ce8a0	608	if (pin == LED1)
mjr	38:091e511ce8a0	609	r = true;
mjr	38:091e511ce8a0	610	else if (pin == LED2)
mjr	38:091e511ce8a0	611	g = true;
mjr	38:091e511ce8a0	612	else if (pin == LED3)
mjr	38:091e511ce8a0	613	b = true;
mjr	38:091e511ce8a0	614	}
mjr	38:091e511ce8a0	615	}
mjr	38:091e511ce8a0	616	};
mjr	38:091e511ce8a0	617
mjr	38:091e511ce8a0	618	// Initialize the diagnostic LEDs. By default, we use the on-board
mjr	38:091e511ce8a0	619	// RGB LED to display the microcontroller status. However, we allow
mjr	38:091e511ce8a0	620	// the user to commandeer the on-board LED as an LedWiz output device,
mjr	38:091e511ce8a0	621	// which can be useful for testing a new installation. So we'll check
mjr	38:091e511ce8a0	622	// for LedWiz outputs assigned to the on-board LED segments, and turn
mjr	38:091e511ce8a0	623	// off the diagnostic use for any so assigned.
mjr	38:091e511ce8a0	624	void initDiagLEDs(Config &cfg)
mjr	38:091e511ce8a0	625	{
mjr	38:091e511ce8a0	626	// run through the configuration list and cross off any of the
mjr	38:091e511ce8a0	627	// LED segments assigned to LedWiz ports
mjr	38:091e511ce8a0	628	LedSeg l;
mjr	38:091e511ce8a0	629	for (int i = 0 ; i < MAX_OUT_PORTS && cfg.outPort[i].typ != PortTypeDisabled ; ++i)
mjr	38:091e511ce8a0	630	l.check(cfg.outPort[i]);
mjr	38:091e511ce8a0	631
mjr	38:091e511ce8a0	632	// We now know which segments are taken for LedWiz use and which
mjr	38:091e511ce8a0	633	// are free. Create diagnostic ports for the ones not claimed for
mjr	38:091e511ce8a0	634	// LedWiz use.
mjr	38:091e511ce8a0	635	if (!l.r) ledR = new DigitalOut(LED1, 1);
mjr	38:091e511ce8a0	636	if (!l.g) ledG = new DigitalOut(LED2, 1);
mjr	38:091e511ce8a0	637	if (!l.b) ledB = new DigitalOut(LED3, 1);
mjr	38:091e511ce8a0	638	}
mjr	38:091e511ce8a0	639
mjr	38:091e511ce8a0	640
mjr	38:091e511ce8a0	641	// ---------------------------------------------------------------------------
mjr	38:091e511ce8a0	642	//
mjr	29:582472d0bc57	643	// LedWiz emulation, and enhanced TLC5940 output controller
mjr	5:a70c0bce770d	644	//
mjr	26:cb71c4af2912	645	// There are two modes for this feature. The default mode uses the on-board
mjr	26:cb71c4af2912	646	// GPIO ports to implement device outputs - each LedWiz software port is
mjr	26:cb71c4af2912	647	// connected to a physical GPIO pin on the KL25Z. The KL25Z only has 10
mjr	26:cb71c4af2912	648	// PWM channels, so in this mode only 10 LedWiz ports will be dimmable; the
mjr	26:cb71c4af2912	649	// rest are strictly on/off. The KL25Z also has a limited number of GPIO
mjr	26:cb71c4af2912	650	// ports overall - not enough for the full complement of 32 LedWiz ports
mjr	26:cb71c4af2912	651	// and 24 VP joystick inputs, so it's necessary to trade one against the
mjr	26:cb71c4af2912	652	// other if both features are to be used.
mjr	26:cb71c4af2912	653	//
mjr	26:cb71c4af2912	654	// The alternative, enhanced mode uses external TLC5940 PWM controller
mjr	26:cb71c4af2912	655	// chips to control device outputs. In this mode, each LedWiz software
mjr	26:cb71c4af2912	656	// port is mapped to an output on one of the external TLC5940 chips.
mjr	26:cb71c4af2912	657	// Two 5940s is enough for the full set of 32 LedWiz ports, and we can
mjr	26:cb71c4af2912	658	// support even more chips for even more outputs (although doing so requires
mjr	26:cb71c4af2912	659	// breaking LedWiz compatibility, since the LedWiz USB protocol is hardwired
mjr	26:cb71c4af2912	660	// for 32 outputs). Every port in this mode has full PWM support.
mjr	26:cb71c4af2912	661	//
mjr	5:a70c0bce770d	662
mjr	29:582472d0bc57	663
mjr	26:cb71c4af2912	664	// Current starting output index for "PBA" messages from the PC (using
mjr	26:cb71c4af2912	665	// the LedWiz USB protocol). Each PBA message implicitly uses the
mjr	26:cb71c4af2912	666	// current index as the starting point for the ports referenced in
mjr	26:cb71c4af2912	667	// the message, and increases it (by 8) for the next call.
mjr	0:5acbbe3f4cf4	668	static int pbaIdx = 0;
mjr	0:5acbbe3f4cf4	669
mjr	26:cb71c4af2912	670	// Generic LedWiz output port interface. We create a cover class to
mjr	26:cb71c4af2912	671	// virtualize digital vs PWM outputs, and on-board KL25Z GPIO vs external
mjr	26:cb71c4af2912	672	// TLC5940 outputs, and give them all a common interface.
mjr	6:cc35eb643e8f	673	class LwOut
mjr	6:cc35eb643e8f	674	{
mjr	6:cc35eb643e8f	675	public:
mjr	40:cc0d9814522b	676	// Set the output intensity. 'val' is 0 for fully off, 255 for
mjr	40:cc0d9814522b	677	// fully on, with values in between signifying lower intensity.
mjr	40:cc0d9814522b	678	virtual void set(uint8_t val) = 0;
mjr	6:cc35eb643e8f	679	};
mjr	26:cb71c4af2912	680
mjr	35:e959ffba78fd	681	// LwOut class for virtual ports. This type of port is visible to
mjr	35:e959ffba78fd	682	// the host software, but isn't connected to any physical output.
mjr	35:e959ffba78fd	683	// This can be used for special software-only ports like the ZB
mjr	35:e959ffba78fd	684	// Launch Ball output, or simply for placeholders in the LedWiz port
mjr	35:e959ffba78fd	685	// numbering.
mjr	35:e959ffba78fd	686	class LwVirtualOut: public LwOut
mjr	33:d832bcab089e	687	{
mjr	33:d832bcab089e	688	public:
mjr	35:e959ffba78fd	689	LwVirtualOut() { }
mjr	40:cc0d9814522b	690	virtual void set(uint8_t ) { }
mjr	33:d832bcab089e	691	};
mjr	26:cb71c4af2912	692
mjr	34:6b981a2afab7	693	// Active Low out. For any output marked as active low, we layer this
mjr	34:6b981a2afab7	694	// on top of the physical pin interface. This simply inverts the value of
mjr	40:cc0d9814522b	695	// the output value, so that 255 means fully off and 0 means fully on.
mjr	34:6b981a2afab7	696	class LwInvertedOut: public LwOut
mjr	34:6b981a2afab7	697	{
mjr	34:6b981a2afab7	698	public:
mjr	34:6b981a2afab7	699	LwInvertedOut(LwOut *o) : out(o) { }
mjr	40:cc0d9814522b	700	virtual void set(uint8_t val) { out->set(255 - val); }
mjr	34:6b981a2afab7	701
mjr	34:6b981a2afab7	702	private:
mjr	53:9b2611964afc	703	// underlying physical output
mjr	34:6b981a2afab7	704	LwOut *out;
mjr	34:6b981a2afab7	705	};
mjr	34:6b981a2afab7	706
mjr	53:9b2611964afc	707	// Global ZB Launch Ball state
mjr	53:9b2611964afc	708	bool zbLaunchOn = false;
mjr	53:9b2611964afc	709
mjr	53:9b2611964afc	710	// ZB Launch Ball output. This is layered on a port (physical or virtual)
mjr	53:9b2611964afc	711	// to track the ZB Launch Ball signal.
mjr	53:9b2611964afc	712	class LwZbLaunchOut: public LwOut
mjr	53:9b2611964afc	713	{
mjr	53:9b2611964afc	714	public:
mjr	53:9b2611964afc	715	LwZbLaunchOut(LwOut *o) : out(o) { }
mjr	53:9b2611964afc	716	virtual void set(uint8_t val)
mjr	53:9b2611964afc	717	{
mjr	53:9b2611964afc	718	// update the global ZB Launch Ball state
mjr	53:9b2611964afc	719	zbLaunchOn = (val != 0);
mjr	53:9b2611964afc	720
mjr	53:9b2611964afc	721	// pass it along to the underlying port, in case it's a physical output
mjr	53:9b2611964afc	722	out->set(val);
mjr	53:9b2611964afc	723	}
mjr	53:9b2611964afc	724
mjr	53:9b2611964afc	725	private:
mjr	53:9b2611964afc	726	// underlying physical or virtual output
mjr	53:9b2611964afc	727	LwOut *out;
mjr	53:9b2611964afc	728	};
mjr	53:9b2611964afc	729
mjr	53:9b2611964afc	730
mjr	40:cc0d9814522b	731	// Gamma correction table for 8-bit input values
mjr	40:cc0d9814522b	732	static const uint8_t gamma[] = {
mjr	40:cc0d9814522b	733	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
mjr	40:cc0d9814522b	734	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1,
mjr	40:cc0d9814522b	735	1, 1, 1, 1, 1, 1, 1, 1, 1, 2, 2, 2, 2, 2, 2, 2,
mjr	40:cc0d9814522b	736	2, 3, 3, 3, 3, 3, 3, 3, 4, 4, 4, 4, 4, 5, 5, 5,
mjr	40:cc0d9814522b	737	5, 6, 6, 6, 6, 7, 7, 7, 7, 8, 8, 8, 9, 9, 9, 10,
mjr	40:cc0d9814522b	738	10, 10, 11, 11, 11, 12, 12, 13, 13, 13, 14, 14, 15, 15, 16, 16,
mjr	40:cc0d9814522b	739	17, 17, 18, 18, 19, 19, 20, 20, 21, 21, 22, 22, 23, 24, 24, 25,
mjr	40:cc0d9814522b	740	25, 26, 27, 27, 28, 29, 29, 30, 31, 32, 32, 33, 34, 35, 35, 36,
mjr	40:cc0d9814522b	741	37, 38, 39, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 50,
mjr	40:cc0d9814522b	742	51, 52, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 66, 67, 68,
mjr	40:cc0d9814522b	743	69, 70, 72, 73, 74, 75, 77, 78, 79, 81, 82, 83, 85, 86, 87, 89,
mjr	40:cc0d9814522b	744	90, 92, 93, 95, 96, 98, 99, 101, 102, 104, 105, 107, 109, 110, 112, 114,
mjr	40:cc0d9814522b	745	115, 117, 119, 120, 122, 124, 126, 127, 129, 131, 133, 135, 137, 138, 140, 142,
mjr	40:cc0d9814522b	746	144, 146, 148, 150, 152, 154, 156, 158, 160, 162, 164, 167, 169, 171, 173, 175,
mjr	40:cc0d9814522b	747	177, 180, 182, 184, 186, 189, 191, 193, 196, 198, 200, 203, 205, 208, 210, 213,
mjr	40:cc0d9814522b	748	215, 218, 220, 223, 225, 228, 231, 233, 236, 239, 241, 244, 247, 249, 252, 255
mjr	40:cc0d9814522b	749	};
mjr	40:cc0d9814522b	750
mjr	40:cc0d9814522b	751	// Gamma-corrected out. This is a filter object that we layer on top
mjr	40:cc0d9814522b	752	// of a physical pin interface. This applies gamma correction to the
mjr	40:cc0d9814522b	753	// input value and then passes it along to the underlying pin object.
mjr	40:cc0d9814522b	754	class LwGammaOut: public LwOut
mjr	40:cc0d9814522b	755	{
mjr	40:cc0d9814522b	756	public:
mjr	40:cc0d9814522b	757	LwGammaOut(LwOut *o) : out(o) { }
mjr	40:cc0d9814522b	758	virtual void set(uint8_t val) { out->set(gamma[val]); }
mjr	40:cc0d9814522b	759
mjr	40:cc0d9814522b	760	private:
mjr	40:cc0d9814522b	761	LwOut *out;
mjr	40:cc0d9814522b	762	};
mjr	40:cc0d9814522b	763
mjr	53:9b2611964afc	764	// global night mode flag
mjr	53:9b2611964afc	765	static bool nightMode = false;
mjr	53:9b2611964afc	766
mjr	40:cc0d9814522b	767	// Noisy output. This is a filter object that we layer on top of
mjr	40:cc0d9814522b	768	// a physical pin output. This filter disables the port when night
mjr	40:cc0d9814522b	769	// mode is engaged.
mjr	40:cc0d9814522b	770	class LwNoisyOut: public LwOut
mjr	40:cc0d9814522b	771	{
mjr	40:cc0d9814522b	772	public:
mjr	40:cc0d9814522b	773	LwNoisyOut(LwOut *o) : out(o) { }
mjr	40:cc0d9814522b	774	virtual void set(uint8_t val) { out->set(nightMode ? 0 : val); }
mjr	40:cc0d9814522b	775
mjr	53:9b2611964afc	776	private:
mjr	53:9b2611964afc	777	LwOut *out;
mjr	53:9b2611964afc	778	};
mjr	53:9b2611964afc	779
mjr	53:9b2611964afc	780	// Night Mode indicator output. This is a filter object that we
mjr	53:9b2611964afc	781	// layer on top of a physical pin output. This filter ignores the
mjr	53:9b2611964afc	782	// host value and simply shows the night mode status.
mjr	53:9b2611964afc	783	class LwNightModeIndicatorOut: public LwOut
mjr	53:9b2611964afc	784	{
mjr	53:9b2611964afc	785	public:
mjr	53:9b2611964afc	786	LwNightModeIndicatorOut(LwOut *o) : out(o) { }
mjr	53:9b2611964afc	787	virtual void set(uint8_t)
mjr	53:9b2611964afc	788	{
mjr	53:9b2611964afc	789	// ignore the host value and simply show the current
mjr	53:9b2611964afc	790	// night mode setting
mjr	53:9b2611964afc	791	out->set(nightMode ? 255 : 0);
mjr	53:9b2611964afc	792	}
mjr	40:cc0d9814522b	793
mjr	40:cc0d9814522b	794	private:
mjr	40:cc0d9814522b	795	LwOut *out;
mjr	40:cc0d9814522b	796	};
mjr	40:cc0d9814522b	797
mjr	26:cb71c4af2912	798
mjr	35:e959ffba78fd	799	//
mjr	35:e959ffba78fd	800	// The TLC5940 interface object. We'll set this up with the port
mjr	35:e959ffba78fd	801	// assignments set in config.h.
mjr	33:d832bcab089e	802	//
mjr	35:e959ffba78fd	803	TLC5940 *tlc5940 = 0;
mjr	35:e959ffba78fd	804	void init_tlc5940(Config &cfg)
mjr	35:e959ffba78fd	805	{
mjr	35:e959ffba78fd	806	if (cfg.tlc5940.nchips != 0)
mjr	35:e959ffba78fd	807	{
mjr	53:9b2611964afc	808	tlc5940 = new TLC5940(
mjr	53:9b2611964afc	809	wirePinName(cfg.tlc5940.sclk),
mjr	53:9b2611964afc	810	wirePinName(cfg.tlc5940.sin),
mjr	53:9b2611964afc	811	wirePinName(cfg.tlc5940.gsclk),
mjr	53:9b2611964afc	812	wirePinName(cfg.tlc5940.blank),
mjr	53:9b2611964afc	813	wirePinName(cfg.tlc5940.xlat),
mjr	53:9b2611964afc	814	cfg.tlc5940.nchips);
mjr	35:e959ffba78fd	815	}
mjr	35:e959ffba78fd	816	}
mjr	26:cb71c4af2912	817
mjr	40:cc0d9814522b	818	// Conversion table for 8-bit DOF level to 12-bit TLC5940 level
mjr	40:cc0d9814522b	819	static const uint16_t dof_to_tlc[] = {
mjr	40:cc0d9814522b	820	0, 16, 32, 48, 64, 80, 96, 112, 128, 145, 161, 177, 193, 209, 225, 241,
mjr	40:cc0d9814522b	821	257, 273, 289, 305, 321, 337, 353, 369, 385, 401, 418, 434, 450, 466, 482, 498,
mjr	40:cc0d9814522b	822	514, 530, 546, 562, 578, 594, 610, 626, 642, 658, 674, 691, 707, 723, 739, 755,
mjr	40:cc0d9814522b	823	771, 787, 803, 819, 835, 851, 867, 883, 899, 915, 931, 947, 964, 980, 996, 1012,
mjr	40:cc0d9814522b	824	1028, 1044, 1060, 1076, 1092, 1108, 1124, 1140, 1156, 1172, 1188, 1204, 1220, 1237, 1253, 1269,
mjr	40:cc0d9814522b	825	1285, 1301, 1317, 1333, 1349, 1365, 1381, 1397, 1413, 1429, 1445, 1461, 1477, 1493, 1510, 1526,
mjr	40:cc0d9814522b	826	1542, 1558, 1574, 1590, 1606, 1622, 1638, 1654, 1670, 1686, 1702, 1718, 1734, 1750, 1766, 1783,
mjr	40:cc0d9814522b	827	1799, 1815, 1831, 1847, 1863, 1879, 1895, 1911, 1927, 1943, 1959, 1975, 1991, 2007, 2023, 2039,
mjr	40:cc0d9814522b	828	2056, 2072, 2088, 2104, 2120, 2136, 2152, 2168, 2184, 2200, 2216, 2232, 2248, 2264, 2280, 2296,
mjr	40:cc0d9814522b	829	2312, 2329, 2345, 2361, 2377, 2393, 2409, 2425, 2441, 2457, 2473, 2489, 2505, 2521, 2537, 2553,
mjr	40:cc0d9814522b	830	2569, 2585, 2602, 2618, 2634, 2650, 2666, 2682, 2698, 2714, 2730, 2746, 2762, 2778, 2794, 2810,
mjr	40:cc0d9814522b	831	2826, 2842, 2858, 2875, 2891, 2907, 2923, 2939, 2955, 2971, 2987, 3003, 3019, 3035, 3051, 3067,
mjr	40:cc0d9814522b	832	3083, 3099, 3115, 3131, 3148, 3164, 3180, 3196, 3212, 3228, 3244, 3260, 3276, 3292, 3308, 3324,
mjr	40:cc0d9814522b	833	3340, 3356, 3372, 3388, 3404, 3421, 3437, 3453, 3469, 3485, 3501, 3517, 3533, 3549, 3565, 3581,
mjr	40:cc0d9814522b	834	3597, 3613, 3629, 3645, 3661, 3677, 3694, 3710, 3726, 3742, 3758, 3774, 3790, 3806, 3822, 3838,
mjr	40:cc0d9814522b	835	3854, 3870, 3886, 3902, 3918, 3934, 3950, 3967, 3983, 3999, 4015, 4031, 4047, 4063, 4079, 4095
mjr	40:cc0d9814522b	836	};
mjr	40:cc0d9814522b	837
mjr	40:cc0d9814522b	838	// Conversion table for 8-bit DOF level to 12-bit TLC5940 level, with
mjr	40:cc0d9814522b	839	// gamma correction. Note that the output layering scheme can handle
mjr	40:cc0d9814522b	840	// this without a separate table, by first applying gamma to the DOF
mjr	40:cc0d9814522b	841	// level to produce an 8-bit gamma-corrected value, then convert that
mjr	40:cc0d9814522b	842	// to the 12-bit TLC5940 value. But we get better precision by doing
mjr	40:cc0d9814522b	843	// the gamma correction in the 12-bit TLC5940 domain. We can only
mjr	40:cc0d9814522b	844	// get the 12-bit domain by combining both steps into one layering
mjr	40:cc0d9814522b	845	// object, though, since the intermediate values in the layering system
mjr	40:cc0d9814522b	846	// are always 8 bits.
mjr	40:cc0d9814522b	847	static const uint16_t dof_to_gamma_tlc[] = {
mjr	40:cc0d9814522b	848	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1,
mjr	40:cc0d9814522b	849	2, 2, 2, 3, 3, 4, 4, 5, 5, 6, 7, 8, 8, 9, 10, 11,
mjr	40:cc0d9814522b	850	12, 13, 15, 16, 17, 18, 20, 21, 23, 25, 26, 28, 30, 32, 34, 36,
mjr	40:cc0d9814522b	851	38, 40, 43, 45, 48, 50, 53, 56, 59, 62, 65, 68, 71, 75, 78, 82,
mjr	40:cc0d9814522b	852	85, 89, 93, 97, 101, 105, 110, 114, 119, 123, 128, 133, 138, 143, 149, 154,
mjr	40:cc0d9814522b	853	159, 165, 171, 177, 183, 189, 195, 202, 208, 215, 222, 229, 236, 243, 250, 258,
mjr	40:cc0d9814522b	854	266, 273, 281, 290, 298, 306, 315, 324, 332, 341, 351, 360, 369, 379, 389, 399,
mjr	40:cc0d9814522b	855	409, 419, 430, 440, 451, 462, 473, 485, 496, 508, 520, 532, 544, 556, 569, 582,
mjr	40:cc0d9814522b	856	594, 608, 621, 634, 648, 662, 676, 690, 704, 719, 734, 749, 764, 779, 795, 811,
mjr	40:cc0d9814522b	857	827, 843, 859, 876, 893, 910, 927, 944, 962, 980, 998, 1016, 1034, 1053, 1072, 1091,
mjr	40:cc0d9814522b	858	1110, 1130, 1150, 1170, 1190, 1210, 1231, 1252, 1273, 1294, 1316, 1338, 1360, 1382, 1404, 1427,
mjr	40:cc0d9814522b	859	1450, 1473, 1497, 1520, 1544, 1568, 1593, 1617, 1642, 1667, 1693, 1718, 1744, 1770, 1797, 1823,
mjr	40:cc0d9814522b	860	1850, 1877, 1905, 1932, 1960, 1988, 2017, 2045, 2074, 2103, 2133, 2162, 2192, 2223, 2253, 2284,
mjr	40:cc0d9814522b	861	2315, 2346, 2378, 2410, 2442, 2474, 2507, 2540, 2573, 2606, 2640, 2674, 2708, 2743, 2778, 2813,
mjr	40:cc0d9814522b	862	2849, 2884, 2920, 2957, 2993, 3030, 3067, 3105, 3143, 3181, 3219, 3258, 3297, 3336, 3376, 3416,
mjr	40:cc0d9814522b	863	3456, 3496, 3537, 3578, 3619, 3661, 3703, 3745, 3788, 3831, 3874, 3918, 3962, 4006, 4050, 4095
mjr	40:cc0d9814522b	864	};
mjr	40:cc0d9814522b	865
mjr	26:cb71c4af2912	866	// LwOut class for TLC5940 outputs. These are fully PWM capable.
mjr	26:cb71c4af2912	867	// The 'idx' value in the constructor is the output index in the
mjr	26:cb71c4af2912	868	// daisy-chained TLC5940 array. 0 is output #0 on the first chip,
mjr	26:cb71c4af2912	869	// 1 is #1 on the first chip, 15 is #15 on the first chip, 16 is
mjr	26:cb71c4af2912	870	// #0 on the second chip, 32 is #0 on the third chip, etc.
mjr	26:cb71c4af2912	871	class Lw5940Out: public LwOut
mjr	26:cb71c4af2912	872	{
mjr	26:cb71c4af2912	873	public:
mjr	60:f38da020aa13	874	Lw5940Out(uint8_t idx) : idx(idx) { prv = 0; }
mjr	40:cc0d9814522b	875	virtual void set(uint8_t val)
mjr	26:cb71c4af2912	876	{
mjr	26:cb71c4af2912	877	if (val != prv)
mjr	40:cc0d9814522b	878	tlc5940->set(idx, dof_to_tlc[prv = val]);
mjr	26:cb71c4af2912	879	}
mjr	60:f38da020aa13	880	uint8_t idx;
mjr	40:cc0d9814522b	881	uint8_t prv;
mjr	26:cb71c4af2912	882	};
mjr	26:cb71c4af2912	883
mjr	40:cc0d9814522b	884	// LwOut class for TLC5940 gamma-corrected outputs.
mjr	40:cc0d9814522b	885	class Lw5940GammaOut: public LwOut
mjr	40:cc0d9814522b	886	{
mjr	40:cc0d9814522b	887	public:
mjr	60:f38da020aa13	888	Lw5940GammaOut(uint8_t idx) : idx(idx) { prv = 0; }
mjr	40:cc0d9814522b	889	virtual void set(uint8_t val)
mjr	40:cc0d9814522b	890	{
mjr	40:cc0d9814522b	891	if (val != prv)
mjr	40:cc0d9814522b	892	tlc5940->set(idx, dof_to_gamma_tlc[prv = val]);
mjr	40:cc0d9814522b	893	}
mjr	60:f38da020aa13	894	uint8_t idx;
mjr	40:cc0d9814522b	895	uint8_t prv;
mjr	40:cc0d9814522b	896	};
mjr	40:cc0d9814522b	897
mjr	40:cc0d9814522b	898
mjr	33:d832bcab089e	899
mjr	34:6b981a2afab7	900	// 74HC595 interface object. Set this up with the port assignments in
mjr	34:6b981a2afab7	901	// config.h.
mjr	35:e959ffba78fd	902	HC595 *hc595 = 0;
mjr	35:e959ffba78fd	903
mjr	35:e959ffba78fd	904	// initialize the 74HC595 interface
mjr	35:e959ffba78fd	905	void init_hc595(Config &cfg)
mjr	35:e959ffba78fd	906	{
mjr	35:e959ffba78fd	907	if (cfg.hc595.nchips != 0)
mjr	35:e959ffba78fd	908	{
mjr	53:9b2611964afc	909	hc595 = new HC595(
mjr	53:9b2611964afc	910	wirePinName(cfg.hc595.nchips),
mjr	53:9b2611964afc	911	wirePinName(cfg.hc595.sin),
mjr	53:9b2611964afc	912	wirePinName(cfg.hc595.sclk),
mjr	53:9b2611964afc	913	wirePinName(cfg.hc595.latch),
mjr	53:9b2611964afc	914	wirePinName(cfg.hc595.ena));
mjr	35:e959ffba78fd	915	hc595->init();
mjr	35:e959ffba78fd	916	hc595->update();
mjr	35:e959ffba78fd	917	}
mjr	35:e959ffba78fd	918	}
mjr	34:6b981a2afab7	919
mjr	34:6b981a2afab7	920	// LwOut class for 74HC595 outputs. These are simple digial outs.
mjr	34:6b981a2afab7	921	// The 'idx' value in the constructor is the output index in the
mjr	34:6b981a2afab7	922	// daisy-chained 74HC595 array. 0 is output #0 on the first chip,
mjr	34:6b981a2afab7	923	// 1 is #1 on the first chip, 7 is #7 on the first chip, 8 is
mjr	34:6b981a2afab7	924	// #0 on the second chip, etc.
mjr	34:6b981a2afab7	925	class Lw595Out: public LwOut
mjr	33:d832bcab089e	926	{
mjr	33:d832bcab089e	927	public:
mjr	60:f38da020aa13	928	Lw595Out(uint8_t idx) : idx(idx) { prv = 0; }
mjr	40:cc0d9814522b	929	virtual void set(uint8_t val)
mjr	34:6b981a2afab7	930	{
mjr	34:6b981a2afab7	931	if (val != prv)
mjr	40:cc0d9814522b	932	hc595->set(idx, (prv = val) == 0 ? 0 : 1);
mjr	34:6b981a2afab7	933	}
mjr	60:f38da020aa13	934	uint8_t idx;
mjr	40:cc0d9814522b	935	uint8_t prv;
mjr	33:d832bcab089e	936	};
mjr	33:d832bcab089e	937
mjr	26:cb71c4af2912	938
mjr	40:cc0d9814522b	939
mjr	64:ef7ca92dff36	940	// Conversion table - 8-bit DOF output level to PWM duty cycle,
mjr	64:ef7ca92dff36	941	// normalized to 0.0 to 1.0 scale.
mjr	74:822a92bc11d2	942	static const float dof_to_pwm[] = {
mjr	64:ef7ca92dff36	943	0.000000f, 0.003922f, 0.007843f, 0.011765f, 0.015686f, 0.019608f, 0.023529f, 0.027451f,
mjr	64:ef7ca92dff36	944	0.031373f, 0.035294f, 0.039216f, 0.043137f, 0.047059f, 0.050980f, 0.054902f, 0.058824f,
mjr	64:ef7ca92dff36	945	0.062745f, 0.066667f, 0.070588f, 0.074510f, 0.078431f, 0.082353f, 0.086275f, 0.090196f,
mjr	64:ef7ca92dff36	946	0.094118f, 0.098039f, 0.101961f, 0.105882f, 0.109804f, 0.113725f, 0.117647f, 0.121569f,
mjr	64:ef7ca92dff36	947	0.125490f, 0.129412f, 0.133333f, 0.137255f, 0.141176f, 0.145098f, 0.149020f, 0.152941f,
mjr	64:ef7ca92dff36	948	0.156863f, 0.160784f, 0.164706f, 0.168627f, 0.172549f, 0.176471f, 0.180392f, 0.184314f,
mjr	64:ef7ca92dff36	949	0.188235f, 0.192157f, 0.196078f, 0.200000f, 0.203922f, 0.207843f, 0.211765f, 0.215686f,
mjr	64:ef7ca92dff36	950	0.219608f, 0.223529f, 0.227451f, 0.231373f, 0.235294f, 0.239216f, 0.243137f, 0.247059f,
mjr	64:ef7ca92dff36	951	0.250980f, 0.254902f, 0.258824f, 0.262745f, 0.266667f, 0.270588f, 0.274510f, 0.278431f,
mjr	64:ef7ca92dff36	952	0.282353f, 0.286275f, 0.290196f, 0.294118f, 0.298039f, 0.301961f, 0.305882f, 0.309804f,
mjr	64:ef7ca92dff36	953	0.313725f, 0.317647f, 0.321569f, 0.325490f, 0.329412f, 0.333333f, 0.337255f, 0.341176f,
mjr	64:ef7ca92dff36	954	0.345098f, 0.349020f, 0.352941f, 0.356863f, 0.360784f, 0.364706f, 0.368627f, 0.372549f,
mjr	64:ef7ca92dff36	955	0.376471f, 0.380392f, 0.384314f, 0.388235f, 0.392157f, 0.396078f, 0.400000f, 0.403922f,
mjr	64:ef7ca92dff36	956	0.407843f, 0.411765f, 0.415686f, 0.419608f, 0.423529f, 0.427451f, 0.431373f, 0.435294f,
mjr	64:ef7ca92dff36	957	0.439216f, 0.443137f, 0.447059f, 0.450980f, 0.454902f, 0.458824f, 0.462745f, 0.466667f,
mjr	64:ef7ca92dff36	958	0.470588f, 0.474510f, 0.478431f, 0.482353f, 0.486275f, 0.490196f, 0.494118f, 0.498039f,
mjr	64:ef7ca92dff36	959	0.501961f, 0.505882f, 0.509804f, 0.513725f, 0.517647f, 0.521569f, 0.525490f, 0.529412f,
mjr	64:ef7ca92dff36	960	0.533333f, 0.537255f, 0.541176f, 0.545098f, 0.549020f, 0.552941f, 0.556863f, 0.560784f,
mjr	64:ef7ca92dff36	961	0.564706f, 0.568627f, 0.572549f, 0.576471f, 0.580392f, 0.584314f, 0.588235f, 0.592157f,
mjr	64:ef7ca92dff36	962	0.596078f, 0.600000f, 0.603922f, 0.607843f, 0.611765f, 0.615686f, 0.619608f, 0.623529f,
mjr	64:ef7ca92dff36	963	0.627451f, 0.631373f, 0.635294f, 0.639216f, 0.643137f, 0.647059f, 0.650980f, 0.654902f,
mjr	64:ef7ca92dff36	964	0.658824f, 0.662745f, 0.666667f, 0.670588f, 0.674510f, 0.678431f, 0.682353f, 0.686275f,
mjr	64:ef7ca92dff36	965	0.690196f, 0.694118f, 0.698039f, 0.701961f, 0.705882f, 0.709804f, 0.713725f, 0.717647f,
mjr	64:ef7ca92dff36	966	0.721569f, 0.725490f, 0.729412f, 0.733333f, 0.737255f, 0.741176f, 0.745098f, 0.749020f,
mjr	64:ef7ca92dff36	967	0.752941f, 0.756863f, 0.760784f, 0.764706f, 0.768627f, 0.772549f, 0.776471f, 0.780392f,
mjr	64:ef7ca92dff36	968	0.784314f, 0.788235f, 0.792157f, 0.796078f, 0.800000f, 0.803922f, 0.807843f, 0.811765f,
mjr	64:ef7ca92dff36	969	0.815686f, 0.819608f, 0.823529f, 0.827451f, 0.831373f, 0.835294f, 0.839216f, 0.843137f,
mjr	64:ef7ca92dff36	970	0.847059f, 0.850980f, 0.854902f, 0.858824f, 0.862745f, 0.866667f, 0.870588f, 0.874510f,
mjr	64:ef7ca92dff36	971	0.878431f, 0.882353f, 0.886275f, 0.890196f, 0.894118f, 0.898039f, 0.901961f, 0.905882f,
mjr	64:ef7ca92dff36	972	0.909804f, 0.913725f, 0.917647f, 0.921569f, 0.925490f, 0.929412f, 0.933333f, 0.937255f,
mjr	64:ef7ca92dff36	973	0.941176f, 0.945098f, 0.949020f, 0.952941f, 0.956863f, 0.960784f, 0.964706f, 0.968627f,
mjr	64:ef7ca92dff36	974	0.972549f, 0.976471f, 0.980392f, 0.984314f, 0.988235f, 0.992157f, 0.996078f, 1.000000f
mjr	40:cc0d9814522b	975	};
mjr	26:cb71c4af2912	976
mjr	64:ef7ca92dff36	977
mjr	64:ef7ca92dff36	978	// Conversion table for 8-bit DOF level to pulse width in microseconds,
mjr	64:ef7ca92dff36	979	// with gamma correction. We could use the layered gamma output on top
mjr	64:ef7ca92dff36	980	// of the regular LwPwmOut class for this, but we get better precision
mjr	64:ef7ca92dff36	981	// with a dedicated table, because we apply gamma correction to the
mjr	64:ef7ca92dff36	982	// 32-bit microsecond values rather than the 8-bit DOF levels.
mjr	64:ef7ca92dff36	983	static const float dof_to_gamma_pwm[] = {
mjr	64:ef7ca92dff36	984	0.000000f, 0.000000f, 0.000001f, 0.000004f, 0.000009f, 0.000017f, 0.000028f, 0.000042f,
mjr	64:ef7ca92dff36	985	0.000062f, 0.000086f, 0.000115f, 0.000151f, 0.000192f, 0.000240f, 0.000296f, 0.000359f,
mjr	64:ef7ca92dff36	986	0.000430f, 0.000509f, 0.000598f, 0.000695f, 0.000803f, 0.000920f, 0.001048f, 0.001187f,
mjr	64:ef7ca92dff36	987	0.001337f, 0.001499f, 0.001673f, 0.001860f, 0.002059f, 0.002272f, 0.002498f, 0.002738f,
mjr	64:ef7ca92dff36	988	0.002993f, 0.003262f, 0.003547f, 0.003847f, 0.004162f, 0.004494f, 0.004843f, 0.005208f,
mjr	64:ef7ca92dff36	989	0.005591f, 0.005991f, 0.006409f, 0.006845f, 0.007301f, 0.007775f, 0.008268f, 0.008781f,
mjr	64:ef7ca92dff36	990	0.009315f, 0.009868f, 0.010442f, 0.011038f, 0.011655f, 0.012293f, 0.012954f, 0.013637f,
mjr	64:ef7ca92dff36	991	0.014342f, 0.015071f, 0.015823f, 0.016599f, 0.017398f, 0.018223f, 0.019071f, 0.019945f,
mjr	64:ef7ca92dff36	992	0.020844f, 0.021769f, 0.022720f, 0.023697f, 0.024701f, 0.025731f, 0.026789f, 0.027875f,
mjr	64:ef7ca92dff36	993	0.028988f, 0.030129f, 0.031299f, 0.032498f, 0.033726f, 0.034983f, 0.036270f, 0.037587f,
mjr	64:ef7ca92dff36	994	0.038935f, 0.040313f, 0.041722f, 0.043162f, 0.044634f, 0.046138f, 0.047674f, 0.049243f,
mjr	64:ef7ca92dff36	995	0.050844f, 0.052478f, 0.054146f, 0.055847f, 0.057583f, 0.059353f, 0.061157f, 0.062996f,
mjr	64:ef7ca92dff36	996	0.064870f, 0.066780f, 0.068726f, 0.070708f, 0.072726f, 0.074780f, 0.076872f, 0.079001f,
mjr	64:ef7ca92dff36	997	0.081167f, 0.083371f, 0.085614f, 0.087895f, 0.090214f, 0.092572f, 0.094970f, 0.097407f,
mjr	64:ef7ca92dff36	998	0.099884f, 0.102402f, 0.104959f, 0.107558f, 0.110197f, 0.112878f, 0.115600f, 0.118364f,
mjr	64:ef7ca92dff36	999	0.121170f, 0.124019f, 0.126910f, 0.129844f, 0.132821f, 0.135842f, 0.138907f, 0.142016f,
mjr	64:ef7ca92dff36	1000	0.145170f, 0.148367f, 0.151610f, 0.154898f, 0.158232f, 0.161611f, 0.165037f, 0.168509f,
mjr	64:ef7ca92dff36	1001	0.172027f, 0.175592f, 0.179205f, 0.182864f, 0.186572f, 0.190327f, 0.194131f, 0.197983f,
mjr	64:ef7ca92dff36	1002	0.201884f, 0.205834f, 0.209834f, 0.213883f, 0.217982f, 0.222131f, 0.226330f, 0.230581f,
mjr	64:ef7ca92dff36	1003	0.234882f, 0.239234f, 0.243638f, 0.248094f, 0.252602f, 0.257162f, 0.261774f, 0.266440f,
mjr	64:ef7ca92dff36	1004	0.271159f, 0.275931f, 0.280756f, 0.285636f, 0.290570f, 0.295558f, 0.300601f, 0.305699f,
mjr	64:ef7ca92dff36	1005	0.310852f, 0.316061f, 0.321325f, 0.326645f, 0.332022f, 0.337456f, 0.342946f, 0.348493f,
mjr	64:ef7ca92dff36	1006	0.354098f, 0.359760f, 0.365480f, 0.371258f, 0.377095f, 0.382990f, 0.388944f, 0.394958f,
mjr	64:ef7ca92dff36	1007	0.401030f, 0.407163f, 0.413356f, 0.419608f, 0.425921f, 0.432295f, 0.438730f, 0.445226f,
mjr	64:ef7ca92dff36	1008	0.451784f, 0.458404f, 0.465085f, 0.471829f, 0.478635f, 0.485504f, 0.492436f, 0.499432f,
mjr	64:ef7ca92dff36	1009	0.506491f, 0.513614f, 0.520800f, 0.528052f, 0.535367f, 0.542748f, 0.550194f, 0.557705f,
mjr	64:ef7ca92dff36	1010	0.565282f, 0.572924f, 0.580633f, 0.588408f, 0.596249f, 0.604158f, 0.612133f, 0.620176f,
mjr	64:ef7ca92dff36	1011	0.628287f, 0.636465f, 0.644712f, 0.653027f, 0.661410f, 0.669863f, 0.678384f, 0.686975f,
mjr	64:ef7ca92dff36	1012	0.695636f, 0.704366f, 0.713167f, 0.722038f, 0.730979f, 0.739992f, 0.749075f, 0.758230f,
mjr	64:ef7ca92dff36	1013	0.767457f, 0.776755f, 0.786126f, 0.795568f, 0.805084f, 0.814672f, 0.824334f, 0.834068f,
mjr	64:ef7ca92dff36	1014	0.843877f, 0.853759f, 0.863715f, 0.873746f, 0.883851f, 0.894031f, 0.904286f, 0.914616f,
mjr	64:ef7ca92dff36	1015	0.925022f, 0.935504f, 0.946062f, 0.956696f, 0.967407f, 0.978194f, 0.989058f, 1.000000f
mjr	64:ef7ca92dff36	1016	};
mjr	64:ef7ca92dff36	1017
mjr	74:822a92bc11d2	1018	// MyPwmOut - a slight customization of the base mbed PwmOut class. The
mjr	74:822a92bc11d2	1019	// mbed version of PwmOut.write() resets the PWM cycle counter on every
mjr	74:822a92bc11d2	1020	// update. That's problematic, because the counter reset interrupts the
mjr	74:822a92bc11d2	1021	// cycle in progress, causing a momentary drop in brightness that's visible
mjr	74:822a92bc11d2	1022	// to the eye if the output is connected to an LED or other light source.
mjr	74:822a92bc11d2	1023	// This is especially noticeable when making gradual changes consisting of
mjr	74:822a92bc11d2	1024	// many updates in a short time, such as a slow fade, because the light
mjr	74:822a92bc11d2	1025	// visibly flickers on every step of the transition. This customized
mjr	74:822a92bc11d2	1026	// version removes the cycle reset, which makes for glitch-free updates
mjr	74:822a92bc11d2	1027	// and nice smooth fades.
mjr	74:822a92bc11d2	1028	//
mjr	74:822a92bc11d2	1029	// Initially, I thought the counter reset in the mbed code was simply a
mjr	74:822a92bc11d2	1030	// bug. According to the KL25Z hardware reference, you update the duty
mjr	74:822a92bc11d2	1031	// cycle by writing to the "compare values" (CvN) register. There's no
mjr	74:822a92bc11d2	1032	// hint that you should reset the cycle counter, and indeed, the hardware
mjr	74:822a92bc11d2	1033	// goes out of its way to allow updates mid-cycle (as we'll see shortly).
mjr	74:822a92bc11d2	1034	// They went to lengths specifically so that you don't have to reset
mjr	74:822a92bc11d2	1035	// that counter. And there's no comment in the mbed code explaining the
mjr	74:822a92bc11d2	1036	// cycle reset, so it looked to me like something that must have been
mjr	74:822a92bc11d2	1037	// added by someone who didn't read the manual carefully enough and didn't
mjr	74:822a92bc11d2	1038	// test the result thoroughly enough to find the glitch it causes.
mjr	74:822a92bc11d2	1039	//
mjr	74:822a92bc11d2	1040	// After some experimentation, though, I've come to think the code was
mjr	74:822a92bc11d2	1041	// added intentionally, as a workaround for a rather nasty KL25Z hardware
mjr	74:822a92bc11d2	1042	// bug. Whoever wrote the code didn't add any comments explaning why it's
mjr	74:822a92bc11d2	1043	// there, so we can't know for sure, but it does happen to work around the
mjr	74:822a92bc11d2	1044	// bug, so it's a good bet the original programmer found the same hardware
mjr	74:822a92bc11d2	1045	// problem and came up with the counter reset as an imperfect solution.
mjr	74:822a92bc11d2	1046	//
mjr	74:822a92bc11d2	1047	// We'll get to the KL25Z hardware bug shortly, but first we need to look at
mjr	74:822a92bc11d2	1048	// how the hardware is supposed to work. The KL25Z is supposed to make
mjr	74:822a92bc11d2	1049	// it super easy for software to do glitch-free updates of the duty cycle of
mjr	74:822a92bc11d2	1050	// a PWM channel. With PWM hardware in general, you have to be careful to
mjr	74:822a92bc11d2	1051	// update the duty cycle counter between grayscale cycles, beacuse otherwise
mjr	74:822a92bc11d2	1052	// you might interrupt the cycle in progress and cause a brightness glitch.
mjr	74:822a92bc11d2	1053	// The KL25Z TPM simplifies this with a "staging" register for the duty
mjr	74:822a92bc11d2	1054	// cycle counter. At the end of each cycle, the TPM moves the value from
mjr	74:822a92bc11d2	1055	// the staging register into its internal register that actually controls
mjr	74:822a92bc11d2	1056	// the duty cycle. The idea is that the software can write a new value to
mjr	74:822a92bc11d2	1057	// the staging register at any time, and the hardware will take care of
mjr	74:822a92bc11d2	1058	// synchronizing the actual internal update with the grayscale cycle. In
mjr	74:822a92bc11d2	1059	// principle, this frees the software of any special timing considerations
mjr	74:822a92bc11d2	1060	// for PWM updates.
mjr	74:822a92bc11d2	1061	//
mjr	74:822a92bc11d2	1062	// Now for the bug. The staging register works as advertised, except for
mjr	74:822a92bc11d2	1063	// one little detail: it seems to be implemented as a one-element queue
mjr	74:822a92bc11d2	1064	// that won't accept a new write until the existing value has been read.
mjr	74:822a92bc11d2	1065	// The read only happens at the start of the new cycle. So the effect is
mjr	74:822a92bc11d2	1066	// that we can only write one update per cycle. Any writes after the first
mjr	74:822a92bc11d2	1067	// are simply dropped, lost forever. That causes even worse problems than
mjr	74:822a92bc11d2	1068	// the original glitch. For example, if we're doing a fade-out, the last
mjr	74:822a92bc11d2	1069	// couple of updates in the fade might get lost, leaving the output slightly
mjr	74:822a92bc11d2	1070	// on at the end, when it's supposed to be completely off.
mjr	74:822a92bc11d2	1071	//
mjr	74:822a92bc11d2	1072	// The mbed workaround of resetting the cycle counter fixes the lost-update
mjr	74:822a92bc11d2	1073	// problem, but it causes the constant glitching during fades. So we need
mjr	74:822a92bc11d2	1074	// a third way that works around the hardware problem without causing
mjr	74:822a92bc11d2	1075	// update glitches.
mjr	74:822a92bc11d2	1076	//
mjr	74:822a92bc11d2	1077	// Here's my solution: we basically implement our own staging register,
mjr	74:822a92bc11d2	1078	// using the same principle as the hardware staging register, but hopefully
mjr	74:822a92bc11d2	1079	// with an implementation that actually works! First, when we update a PWM
mjr	74:822a92bc11d2	1080	// output, we won't actually write the value to the hardware register.
mjr	74:822a92bc11d2	1081	// Instead, we'll just stash it internally, effectively in our own staging
mjr	74:822a92bc11d2	1082	// register (but actually just a member variable of this object). Then
mjr	74:822a92bc11d2	1083	// we'll periodically transfer these staged updates to the actual hardware
mjr	74:822a92bc11d2	1084	// registers, being careful to do this no more than once per PWM cycle.
mjr	74:822a92bc11d2	1085	// One way to do this would be to use an interrupt handler that fires at
mjr	74:822a92bc11d2	1086	// the end of the PWM cycle, but that would be fairly complex because we
mjr	74:822a92bc11d2	1087	// have many (up to 10) PWM channels. Instead, we'll just use polling:
mjr	74:822a92bc11d2	1088	// we'll call a routine periodically in our main loop, and we'll transfer
mjr	74:822a92bc11d2	1089	// updates for all of the channels that have been updated since the last
mjr	74:822a92bc11d2	1090	// pass. We can get away with this simple polling approach because the
mjr	74:822a92bc11d2	1091	// hardware design partially works: it does manage to free us from the
mjr	74:822a92bc11d2	1092	// need to synchronize updates with the exact end of a PWM cycle. As long
mjr	74:822a92bc11d2	1093	// as we do no more than one write per cycle, we're golden. That's easy
mjr	74:822a92bc11d2	1094	// to accomplish, too: all we need to do is make sure that our polling
mjr	74:822a92bc11d2	1095	// interval is slightly longer than the PWM period. That ensures that
mjr	74:822a92bc11d2	1096	// we can never have two updates during one PWM cycle. It does mean that
mjr	74:822a92bc11d2	1097	// we might have zero updates on some cycles, causing a one-cycle delay
mjr	74:822a92bc11d2	1098	// before an update is actually put into effect, but that shouldn't ever
mjr	74:822a92bc11d2	1099	// be noticeable since the cycles are so short. Specifically, we'll use
mjr	74:822a92bc11d2	1100	// the mbed default 20ms PWM period, and we'll do our update polling
mjr	74:822a92bc11d2	1101	// every 25ms.
mjr	74:822a92bc11d2	1102	class LessGlitchyPwmOut: public PwmOut
mjr	74:822a92bc11d2	1103	{
mjr	74:822a92bc11d2	1104	public:
mjr	74:822a92bc11d2	1105	LessGlitchyPwmOut(PinName pin) : PwmOut(pin) { }
mjr	74:822a92bc11d2	1106
mjr	74:822a92bc11d2	1107	void write(float value)
mjr	74:822a92bc11d2	1108	{
mjr	74:822a92bc11d2	1109	// Update the counter without resetting the counter.
mjr	74:822a92bc11d2	1110	//
mjr	74:822a92bc11d2	1111	// NB: this causes problems if there are multiple writes in one
mjr	74:822a92bc11d2	1112	// PWM cycle: the first write will be applied and later writes
mjr	74:822a92bc11d2	1113	// during the same cycle will be lost. Callers must take care
mjr	74:822a92bc11d2	1114	// to limit writes to one per cycle.
mjr	74:822a92bc11d2	1115	_pwm.CnV = uint32_t((_pwm.MOD + 1) * value);
mjr	74:822a92bc11d2	1116	}
mjr	74:822a92bc11d2	1117	};
mjr	74:822a92bc11d2	1118
mjr	74:822a92bc11d2	1119
mjr	74:822a92bc11d2	1120	// Collection of PwmOut objects to update on each polling cycle. The
mjr	74:822a92bc11d2	1121	// KL25Z has 10 physical PWM channels, so we need at most 10 polled outputs.
mjr	74:822a92bc11d2	1122	static int numPolledPwm;
mjr	74:822a92bc11d2	1123	static class LwPwmOut *polledPwm[10];
mjr	74:822a92bc11d2	1124
mjr	74:822a92bc11d2	1125	// LwOut class for a PWM-capable GPIO port.
mjr	6:cc35eb643e8f	1126	class LwPwmOut: public LwOut
mjr	6:cc35eb643e8f	1127	{
mjr	6:cc35eb643e8f	1128	public:
mjr	43:7a6364d82a41	1129	LwPwmOut(PinName pin, uint8_t initVal) : p(pin)
mjr	43:7a6364d82a41	1130	{
mjr	74:822a92bc11d2	1131	// set the cycle time to 20ms
mjr	74:822a92bc11d2	1132	p.period_ms(20);
mjr	74:822a92bc11d2	1133
mjr	74:822a92bc11d2	1134	// add myself to the list of polled outputs for periodic updates
mjr	74:822a92bc11d2	1135	if (numPolledPwm < countof(polledPwm))
mjr	74:822a92bc11d2	1136	polledPwm[numPolledPwm++] = this;
mjr	74:822a92bc11d2	1137
mjr	74:822a92bc11d2	1138	// set the initial value, and an explicitly different previous value
mjr	74:822a92bc11d2	1139	prv = ~initVal;
mjr	43:7a6364d82a41	1140	set(initVal);
mjr	43:7a6364d82a41	1141	}
mjr	74:822a92bc11d2	1142
mjr	40:cc0d9814522b	1143	virtual void set(uint8_t val)
mjr	74:822a92bc11d2	1144	{
mjr	74:822a92bc11d2	1145	// on set, just save the value for a later 'commit'
mjr	74:822a92bc11d2	1146	this->val = val;
mjr	13:72dda449c3c0	1147	}
mjr	74:822a92bc11d2	1148
mjr	74:822a92bc11d2	1149	// handle periodic update polling
mjr	74:822a92bc11d2	1150	void poll()
mjr	74:822a92bc11d2	1151	{
mjr	74:822a92bc11d2	1152	// if the value has changed, commit it
mjr	74:822a92bc11d2	1153	if (val != prv)
mjr	74:822a92bc11d2	1154	{
mjr	74:822a92bc11d2	1155	prv = val;
mjr	74:822a92bc11d2	1156	commit(val);
mjr	74:822a92bc11d2	1157	}
mjr	74:822a92bc11d2	1158	}
mjr	74:822a92bc11d2	1159
mjr	74:822a92bc11d2	1160	protected:
mjr	74:822a92bc11d2	1161	virtual void commit(uint8_t v)
mjr	74:822a92bc11d2	1162	{
mjr	74:822a92bc11d2	1163	// write the current value to the PWM controller if it's changed
mjr	74:822a92bc11d2	1164	p.write(dof_to_pwm[v]);
mjr	74:822a92bc11d2	1165	}
mjr	74:822a92bc11d2	1166
mjr	74:822a92bc11d2	1167	LessGlitchyPwmOut p;
mjr	74:822a92bc11d2	1168	uint8_t val, prv;
mjr	6:cc35eb643e8f	1169	};
mjr	26:cb71c4af2912	1170
mjr	74:822a92bc11d2	1171	// Gamma corrected PWM GPIO output. This works exactly like the regular
mjr	74:822a92bc11d2	1172	// PWM output, but translates DOF values through the gamma-corrected
mjr	74:822a92bc11d2	1173	// table instead of the regular linear table.
mjr	64:ef7ca92dff36	1174	class LwPwmGammaOut: public LwPwmOut
mjr	64:ef7ca92dff36	1175	{
mjr	64:ef7ca92dff36	1176	public:
mjr	64:ef7ca92dff36	1177	LwPwmGammaOut(PinName pin, uint8_t initVal)
mjr	64:ef7ca92dff36	1178	: LwPwmOut(pin, initVal)
mjr	64:ef7ca92dff36	1179	{
mjr	64:ef7ca92dff36	1180	}
mjr	74:822a92bc11d2	1181
mjr	74:822a92bc11d2	1182	protected:
mjr	74:822a92bc11d2	1183	virtual void commit(uint8_t v)
mjr	64:ef7ca92dff36	1184	{
mjr	74:822a92bc11d2	1185	// write the current value to the PWM controller if it's changed
mjr	74:822a92bc11d2	1186	p.write(dof_to_gamma_pwm[v]);
mjr	64:ef7ca92dff36	1187	}
mjr	64:ef7ca92dff36	1188	};
mjr	64:ef7ca92dff36	1189
mjr	74:822a92bc11d2	1190	// poll the PWM outputs
mjr	74:822a92bc11d2	1191	Timer polledPwmTimer;
mjr	74:822a92bc11d2	1192	float polledPwmTotalTime, polledPwmRunCount;
mjr	74:822a92bc11d2	1193	void pollPwmUpdates()
mjr	74:822a92bc11d2	1194	{
mjr	74:822a92bc11d2	1195	// if it's been at least 25ms since the last update, do another update
mjr	74:822a92bc11d2	1196	if (polledPwmTimer.read_us() >= 25000)
mjr	74:822a92bc11d2	1197	{
mjr	74:822a92bc11d2	1198	// time the run for statistics collection
mjr	74:822a92bc11d2	1199	IF_DIAG(
mjr	74:822a92bc11d2	1200	Timer t;
mjr	74:822a92bc11d2	1201	t.start();
mjr	74:822a92bc11d2	1202	)
mjr	74:822a92bc11d2	1203
mjr	74:822a92bc11d2	1204	// poll each output
mjr	74:822a92bc11d2	1205	for (int i = numPolledPwm ; i > 0 ; )
mjr	74:822a92bc11d2	1206	polledPwm[--i]->poll();
mjr	74:822a92bc11d2	1207
mjr	74:822a92bc11d2	1208	// reset the timer for the next cycle
mjr	74:822a92bc11d2	1209	polledPwmTimer.reset();
mjr	74:822a92bc11d2	1210
mjr	74:822a92bc11d2	1211	// collect statistics
mjr	74:822a92bc11d2	1212	IF_DIAG(
mjr	74:822a92bc11d2	1213	polledPwmTotalTime += t.read();
mjr	74:822a92bc11d2	1214	polledPwmRunCount += 1;
mjr	74:822a92bc11d2	1215	)
mjr	74:822a92bc11d2	1216	}
mjr	74:822a92bc11d2	1217	}
mjr	64:ef7ca92dff36	1218
mjr	26:cb71c4af2912	1219	// LwOut class for a Digital-Only (Non-PWM) GPIO port
mjr	6:cc35eb643e8f	1220	class LwDigOut: public LwOut
mjr	6:cc35eb643e8f	1221	{
mjr	6:cc35eb643e8f	1222	public:
mjr	43:7a6364d82a41	1223	LwDigOut(PinName pin, uint8_t initVal) : p(pin, initVal ? 1 : 0) { prv = initVal; }
mjr	40:cc0d9814522b	1224	virtual void set(uint8_t val)
mjr	13:72dda449c3c0	1225	{
mjr	13:72dda449c3c0	1226	if (val != prv)
mjr	40:cc0d9814522b	1227	p.write((prv = val) == 0 ? 0 : 1);
mjr	13:72dda449c3c0	1228	}
mjr	6:cc35eb643e8f	1229	DigitalOut p;
mjr	40:cc0d9814522b	1230	uint8_t prv;
mjr	6:cc35eb643e8f	1231	};
mjr	26:cb71c4af2912	1232
mjr	29:582472d0bc57	1233	// Array of output physical pin assignments. This array is indexed
mjr	29:582472d0bc57	1234	// by LedWiz logical port number - lwPin[n] is the maping for LedWiz
mjr	35:e959ffba78fd	1235	// port n (0-based).
mjr	35:e959ffba78fd	1236	//
mjr	35:e959ffba78fd	1237	// Each pin is handled by an interface object for the physical output
mjr	35:e959ffba78fd	1238	// type for the port, as set in the configuration. The interface
mjr	35:e959ffba78fd	1239	// objects handle the specifics of addressing the different hardware
mjr	35:e959ffba78fd	1240	// types (GPIO PWM ports, GPIO digital ports, TLC5940 ports, and
mjr	35:e959ffba78fd	1241	// 74HC595 ports).
mjr	33:d832bcab089e	1242	static int numOutputs;
mjr	33:d832bcab089e	1243	static LwOut **lwPin;
mjr	33:d832bcab089e	1244
mjr	73:4e8ce0b18915	1245	// LedWiz output states.
mjr	73:4e8ce0b18915	1246	//
mjr	73:4e8ce0b18915	1247	// The LedWiz protocol has two separate control axes for each output.
mjr	73:4e8ce0b18915	1248	// One axis is its on/off state; the other is its "profile" state, which
mjr	73:4e8ce0b18915	1249	// is either a fixed brightness or a blinking pattern for the light.
mjr	73:4e8ce0b18915	1250	// The two axes are independent.
mjr	73:4e8ce0b18915	1251	//
mjr	73:4e8ce0b18915	1252	// Even though the original LedWiz protocol can only access 32 ports, we
mjr	73:4e8ce0b18915	1253	// maintain LedWiz state for every port, even if we have more than 32. Our
mjr	74:822a92bc11d2	1254	// extended protocol allows the client to send LedWiz-style messages that
mjr	74:822a92bc11d2	1255	// control any set of ports. A replacement LEDWIZ.DLL can make a single
mjr	74:822a92bc11d2	1256	// Pinscape unit look like multiple virtual LedWiz units to legacy clients,
mjr	74:822a92bc11d2	1257	// allowing them to control all of our ports. The clients will still be
mjr	74:822a92bc11d2	1258	// using LedWiz-style states to control the ports, so we need to support
mjr	74:822a92bc11d2	1259	// the LedWiz scheme with separate on/off and brightness control per port.
mjr	73:4e8ce0b18915	1260
mjr	73:4e8ce0b18915	1261	// on/off state for each LedWiz output
mjr	73:4e8ce0b18915	1262	static uint8_t *wizOn;
mjr	73:4e8ce0b18915	1263
mjr	73:4e8ce0b18915	1264	// LedWiz "Profile State" (the LedWiz brightness level or blink mode)
mjr	73:4e8ce0b18915	1265	// for each LedWiz output. If the output was last updated through an
mjr	73:4e8ce0b18915	1266	// LedWiz protocol message, it will have one of these values:
mjr	73:4e8ce0b18915	1267	//
mjr	73:4e8ce0b18915	1268	// 0-48 = fixed brightness 0% to 100%
mjr	73:4e8ce0b18915	1269	// 49 = fixed brightness 100% (equivalent to 48)
mjr	73:4e8ce0b18915	1270	// 129 = ramp up / ramp down
mjr	73:4e8ce0b18915	1271	// 130 = flash on / off
mjr	73:4e8ce0b18915	1272	// 131 = on / ramp down
mjr	73:4e8ce0b18915	1273	// 132 = ramp up / on
mjr	73:4e8ce0b18915	1274	//
mjr	73:4e8ce0b18915	1275	// (Note that value 49 isn't documented in the LedWiz spec, but real
mjr	73:4e8ce0b18915	1276	// LedWiz units treat it as equivalent to 48, and some PC software uses
mjr	73:4e8ce0b18915	1277	// it, so we need to accept it for compatibility.)
mjr	73:4e8ce0b18915	1278	static uint8_t *wizVal;
mjr	73:4e8ce0b18915	1279
mjr	73:4e8ce0b18915	1280	// LedWiz flash speed. This is a value from 1 to 7 giving the pulse
mjr	74:822a92bc11d2	1281	// rate for lights in blinking states. The LedWiz API doesn't document
mjr	74:822a92bc11d2	1282	// what the numbers mean in real time units, but by observation, the
mjr	74:822a92bc11d2	1283	// "speed" setting represents the period of the flash cycle in 0.25s
mjr	74:822a92bc11d2	1284	// units, so speed 1 = 0.25 period = 4Hz, speed 7 = 1.75s period = 0.57Hz.
mjr	74:822a92bc11d2	1285	// The period is the full cycle time of the flash waveform.
mjr	74:822a92bc11d2	1286	//
mjr	74:822a92bc11d2	1287	// Each bank of 32 lights has its independent own pulse rate, so we need
mjr	74:822a92bc11d2	1288	// one entry per bank. Each bank has 32 outputs, so we need a total of
mjr	74:822a92bc11d2	1289	// ceil(number_of_physical_outputs/32) entries. Note that we could allocate
mjr	74:822a92bc11d2	1290	// this dynamically once we know the number of actual outputs, but the
mjr	74:822a92bc11d2	1291	// upper limit is low enough that it's more efficient to use a fixed array
mjr	74:822a92bc11d2	1292	// at the maximum size.
mjr	73:4e8ce0b18915	1293	static const int MAX_LW_BANKS = (MAX_OUT_PORTS+31)/32;
mjr	73:4e8ce0b18915	1294	static uint8_t wizSpeed[MAX_LW_BANKS];
mjr	73:4e8ce0b18915	1295
mjr	74:822a92bc11d2	1296	// LedWiz cycle counters. These must be updated before calling wizState().
mjr	73:4e8ce0b18915	1297	static uint8_t wizFlashCounter[MAX_LW_BANKS];
mjr	35:e959ffba78fd	1298
mjr	74:822a92bc11d2	1299
mjr	63:5cd1a5f3a41b	1300	// Current absolute brightness levels for all outputs. These are
mjr	63:5cd1a5f3a41b	1301	// DOF brightness level value, from 0 for fully off to 255 for fully
mjr	63:5cd1a5f3a41b	1302	// on. These are always used for extended ports (33 and above), and
mjr	63:5cd1a5f3a41b	1303	// are used for LedWiz ports (1-32) when we're in extended protocol
mjr	63:5cd1a5f3a41b	1304	// mode (i.e., ledWizMode == false).
mjr	40:cc0d9814522b	1305	static uint8_t *outLevel;
mjr	38:091e511ce8a0	1306
mjr	38:091e511ce8a0	1307	// create a single output pin
mjr	53:9b2611964afc	1308	LwOut *createLwPin(int portno, LedWizPortCfg &pc, Config &cfg)
mjr	38:091e511ce8a0	1309	{
mjr	38:091e511ce8a0	1310	// get this item's values
mjr	38:091e511ce8a0	1311	int typ = pc.typ;
mjr	38:091e511ce8a0	1312	int pin = pc.pin;
mjr	38:091e511ce8a0	1313	int flags = pc.flags;
mjr	40:cc0d9814522b	1314	int noisy = flags & PortFlagNoisemaker;
mjr	38:091e511ce8a0	1315	int activeLow = flags & PortFlagActiveLow;
mjr	40:cc0d9814522b	1316	int gamma = flags & PortFlagGamma;
mjr	38:091e511ce8a0	1317
mjr	38:091e511ce8a0	1318	// create the pin interface object according to the port type
mjr	38:091e511ce8a0	1319	LwOut *lwp;
mjr	38:091e511ce8a0	1320	switch (typ)
mjr	38:091e511ce8a0	1321	{
mjr	38:091e511ce8a0	1322	case PortTypeGPIOPWM:
mjr	48:058ace2aed1d	1323	// PWM GPIO port - assign if we have a valid pin
mjr	48:058ace2aed1d	1324	if (pin != 0)
mjr	64:ef7ca92dff36	1325	{
mjr	64:ef7ca92dff36	1326	// If gamma correction is to be used, and we're not inverting the output,
mjr	64:ef7ca92dff36	1327	// use the combined Pwmout + Gamma output class; otherwise use the plain
mjr	64:ef7ca92dff36	1328	// PwmOut class. We can't use the combined class for inverted outputs
mjr	64:ef7ca92dff36	1329	// because we have to apply gamma correction before the inversion.
mjr	64:ef7ca92dff36	1330	if (gamma && !activeLow)
mjr	64:ef7ca92dff36	1331	{
mjr	64:ef7ca92dff36	1332	// use the gamma-corrected PwmOut type
mjr	64:ef7ca92dff36	1333	lwp = new LwPwmGammaOut(wirePinName(pin), 0);
mjr	64:ef7ca92dff36	1334
mjr	64:ef7ca92dff36	1335	// don't apply further gamma correction to this output
mjr	64:ef7ca92dff36	1336	gamma = false;
mjr	64:ef7ca92dff36	1337	}
mjr	64:ef7ca92dff36	1338	else
mjr	64:ef7ca92dff36	1339	{
mjr	64:ef7ca92dff36	1340	// no gamma correction - use the standard PwmOut class
mjr	64:ef7ca92dff36	1341	lwp = new LwPwmOut(wirePinName(pin), activeLow ? 255 : 0);
mjr	64:ef7ca92dff36	1342	}
mjr	64:ef7ca92dff36	1343	}
mjr	48:058ace2aed1d	1344	else
mjr	48:058ace2aed1d	1345	lwp = new LwVirtualOut();
mjr	38:091e511ce8a0	1346	break;
mjr	38:091e511ce8a0	1347
mjr	38:091e511ce8a0	1348	case PortTypeGPIODig:
mjr	38:091e511ce8a0	1349	// Digital GPIO port
mjr	48:058ace2aed1d	1350	if (pin != 0)
mjr	48:058ace2aed1d	1351	lwp = new LwDigOut(wirePinName(pin), activeLow ? 255 : 0);
mjr	48:058ace2aed1d	1352	else
mjr	48:058ace2aed1d	1353	lwp = new LwVirtualOut();
mjr	38:091e511ce8a0	1354	break;
mjr	38:091e511ce8a0	1355
mjr	38:091e511ce8a0	1356	case PortTypeTLC5940:
mjr	38:091e511ce8a0	1357	// TLC5940 port (if we don't have a TLC controller object, or it's not a valid
mjr	38:091e511ce8a0	1358	// output port number on the chips we have, create a virtual port)
mjr	38:091e511ce8a0	1359	if (tlc5940 != 0 && pin < cfg.tlc5940.nchips*16)
mjr	40:cc0d9814522b	1360	{
mjr	40:cc0d9814522b	1361	// If gamma correction is to be used, and we're not inverting the output,
mjr	40:cc0d9814522b	1362	// use the combined TLC4950 + Gamma output class. Otherwise use the plain
mjr	40:cc0d9814522b	1363	// TLC5940 output. We skip the combined class if the output is inverted
mjr	40:cc0d9814522b	1364	// because we need to apply gamma BEFORE the inversion to get the right
mjr	40:cc0d9814522b	1365	// results, but the combined class would apply it after because of the
mjr	40:cc0d9814522b	1366	// layering scheme - the combined class is a physical device output class,
mjr	40:cc0d9814522b	1367	// and a physical device output class is necessarily at the bottom of
mjr	40:cc0d9814522b	1368	// the stack. We don't have a combined inverted+gamma+TLC class, because
mjr	40:cc0d9814522b	1369	// inversion isn't recommended for TLC5940 chips in the first place, so
mjr	40:cc0d9814522b	1370	// it's not worth the extra memory footprint to have a dedicated table
mjr	40:cc0d9814522b	1371	// for this unlikely case.
mjr	40:cc0d9814522b	1372	if (gamma && !activeLow)
mjr	40:cc0d9814522b	1373	{
mjr	40:cc0d9814522b	1374	// use the gamma-corrected 5940 output mapper
mjr	40:cc0d9814522b	1375	lwp = new Lw5940GammaOut(pin);
mjr	40:cc0d9814522b	1376
mjr	40:cc0d9814522b	1377	// DON'T apply further gamma correction to this output
mjr	40:cc0d9814522b	1378	gamma = false;
mjr	40:cc0d9814522b	1379	}
mjr	40:cc0d9814522b	1380	else
mjr	40:cc0d9814522b	1381	{
mjr	40:cc0d9814522b	1382	// no gamma - use the plain (linear) 5940 output class
mjr	40:cc0d9814522b	1383	lwp = new Lw5940Out(pin);
mjr	40:cc0d9814522b	1384	}
mjr	40:cc0d9814522b	1385	}
mjr	38:091e511ce8a0	1386	else
mjr	40:cc0d9814522b	1387	{
mjr	40:cc0d9814522b	1388	// no TLC5940 chips, or invalid port number - use a virtual out
mjr	38:091e511ce8a0	1389	lwp = new LwVirtualOut();
mjr	40:cc0d9814522b	1390	}
mjr	38:091e511ce8a0	1391	break;
mjr	38:091e511ce8a0	1392
mjr	38:091e511ce8a0	1393	case PortType74HC595:
mjr	38:091e511ce8a0	1394	// 74HC595 port (if we don't have an HC595 controller object, or it's not a valid
mjr	38:091e511ce8a0	1395	// output number, create a virtual port)
mjr	38:091e511ce8a0	1396	if (hc595 != 0 && pin < cfg.hc595.nchips*8)
mjr	38:091e511ce8a0	1397	lwp = new Lw595Out(pin);
mjr	38:091e511ce8a0	1398	else
mjr	38:091e511ce8a0	1399	lwp = new LwVirtualOut();
mjr	38:091e511ce8a0	1400	break;
mjr	38:091e511ce8a0	1401
mjr	38:091e511ce8a0	1402	case PortTypeVirtual:
mjr	43:7a6364d82a41	1403	case PortTypeDisabled:
mjr	38:091e511ce8a0	1404	default:
mjr	38:091e511ce8a0	1405	// virtual or unknown
mjr	38:091e511ce8a0	1406	lwp = new LwVirtualOut();
mjr	38:091e511ce8a0	1407	break;
mjr	38:091e511ce8a0	1408	}
mjr	38:091e511ce8a0	1409
mjr	40:cc0d9814522b	1410	// If it's Active Low, layer on an inverter. Note that an inverter
mjr	40:cc0d9814522b	1411	// needs to be the bottom-most layer, since all of the other filters
mjr	40:cc0d9814522b	1412	// assume that they're working with normal (non-inverted) values.
mjr	38:091e511ce8a0	1413	if (activeLow)
mjr	38:091e511ce8a0	1414	lwp = new LwInvertedOut(lwp);
mjr	40:cc0d9814522b	1415
mjr	40:cc0d9814522b	1416	// If it's a noisemaker, layer on a night mode switch. Note that this
mjr	40:cc0d9814522b	1417	// needs to be
mjr	40:cc0d9814522b	1418	if (noisy)
mjr	40:cc0d9814522b	1419	lwp = new LwNoisyOut(lwp);
mjr	40:cc0d9814522b	1420
mjr	40:cc0d9814522b	1421	// If it's gamma-corrected, layer on a gamma corrector
mjr	40:cc0d9814522b	1422	if (gamma)
mjr	40:cc0d9814522b	1423	lwp = new LwGammaOut(lwp);
mjr	53:9b2611964afc	1424
mjr	53:9b2611964afc	1425	// If this is the ZB Launch Ball port, layer a monitor object. Note
mjr	64:ef7ca92dff36	1426	// that the nominal port numbering in the config starts at 1, but we're
mjr	53:9b2611964afc	1427	// using an array index, so test against portno+1.
mjr	53:9b2611964afc	1428	if (portno + 1 == cfg.plunger.zbLaunchBall.port)
mjr	53:9b2611964afc	1429	lwp = new LwZbLaunchOut(lwp);
mjr	53:9b2611964afc	1430
mjr	53:9b2611964afc	1431	// If this is the Night Mode indicator port, layer a night mode object.
mjr	53:9b2611964afc	1432	if (portno + 1 == cfg.nightMode.port)
mjr	53:9b2611964afc	1433	lwp = new LwNightModeIndicatorOut(lwp);
mjr	38:091e511ce8a0	1434
mjr	38:091e511ce8a0	1435	// turn it off initially
mjr	38:091e511ce8a0	1436	lwp->set(0);
mjr	38:091e511ce8a0	1437
mjr	38:091e511ce8a0	1438	// return the pin
mjr	38:091e511ce8a0	1439	return lwp;
mjr	38:091e511ce8a0	1440	}
mjr	38:091e511ce8a0	1441
mjr	6:cc35eb643e8f	1442	// initialize the output pin array
mjr	35:e959ffba78fd	1443	void initLwOut(Config &cfg)
mjr	6:cc35eb643e8f	1444	{
mjr	35:e959ffba78fd	1445	// Count the outputs. The first disabled output determines the
mjr	35:e959ffba78fd	1446	// total number of ports.
mjr	35:e959ffba78fd	1447	numOutputs = MAX_OUT_PORTS;
mjr	33:d832bcab089e	1448	int i;
mjr	35:e959ffba78fd	1449	for (i = 0 ; i < MAX_OUT_PORTS ; ++i)
mjr	6:cc35eb643e8f	1450	{
mjr	35:e959ffba78fd	1451	if (cfg.outPort[i].typ == PortTypeDisabled)
mjr	34:6b981a2afab7	1452	{
mjr	35:e959ffba78fd	1453	numOutputs = i;
mjr	34:6b981a2afab7	1454	break;
mjr	34:6b981a2afab7	1455	}
mjr	33:d832bcab089e	1456	}
mjr	33:d832bcab089e	1457
mjr	73:4e8ce0b18915	1458	// allocate the pin array
mjr	73:4e8ce0b18915	1459	lwPin = new LwOut*[numOutputs];
mjr	35:e959ffba78fd	1460
mjr	73:4e8ce0b18915	1461	// Allocate the current brightness array
mjr	73:4e8ce0b18915	1462	outLevel = new uint8_t[numOutputs];
mjr	33:d832bcab089e	1463
mjr	73:4e8ce0b18915	1464	// allocate the LedWiz output state arrays
mjr	73:4e8ce0b18915	1465	wizOn = new uint8_t[numOutputs];
mjr	73:4e8ce0b18915	1466	wizVal = new uint8_t[numOutputs];
mjr	73:4e8ce0b18915	1467
mjr	73:4e8ce0b18915	1468	// initialize all LedWiz outputs to off and brightness 48
mjr	73:4e8ce0b18915	1469	memset(wizOn, 0, numOutputs);
mjr	73:4e8ce0b18915	1470	memset(wizVal, 48, numOutputs);
mjr	73:4e8ce0b18915	1471
mjr	73:4e8ce0b18915	1472	// set all LedWiz virtual unit flash speeds to 2
mjr	73:4e8ce0b18915	1473	for (i = 0 ; i < countof(wizSpeed) ; ++i)
mjr	73:4e8ce0b18915	1474	wizSpeed[i] = 2;
mjr	33:d832bcab089e	1475
mjr	35:e959ffba78fd	1476	// create the pin interface object for each port
mjr	35:e959ffba78fd	1477	for (i = 0 ; i < numOutputs ; ++i)
mjr	53:9b2611964afc	1478	lwPin[i] = createLwPin(i, cfg.outPort[i], cfg);
mjr	6:cc35eb643e8f	1479	}
mjr	6:cc35eb643e8f	1480
mjr	63:5cd1a5f3a41b	1481	// LedWiz/Extended protocol mode.
mjr	63:5cd1a5f3a41b	1482	//
mjr	63:5cd1a5f3a41b	1483	// We implement output port control using both the legacy LedWiz
mjr	63:5cd1a5f3a41b	1484	// protocol and a private extended protocol (which is 100% backwards
mjr	63:5cd1a5f3a41b	1485	// compatible with the LedWiz protocol: we recognize all valid legacy
mjr	63:5cd1a5f3a41b	1486	// protocol commands and handle them the same way a real LedWiz does).
mjr	74:822a92bc11d2	1487	//
mjr	74:822a92bc11d2	1488	// The legacy LedWiz protocol has only two message types, which
mjr	74:822a92bc11d2	1489	// set output port states for a fixed set of 32 outputs. One message
mjr	74:822a92bc11d2	1490	// sets the "switch" state (on/off) of the ports, and the other sets
mjr	74:822a92bc11d2	1491	// the "profile" state (brightness or flash pattern). The two states
mjr	74:822a92bc11d2	1492	// are stored independently, so turning a port off via the switch state
mjr	74:822a92bc11d2	1493	// doesn't forget or change its brightness: turning it back on will
mjr	74:822a92bc11d2	1494	// restore the same brightness or flash pattern as before. The "profile"
mjr	74:822a92bc11d2	1495	// state can be a brightness level from 1 to 49, or one of four flash
mjr	74:822a92bc11d2	1496	// patterns, identified by a value from 129 to 132. The flash pattern
mjr	74:822a92bc11d2	1497	// and brightness levels are mutually exclusive, since the single
mjr	74:822a92bc11d2	1498	// "profile" setting per port selects which is used.
mjr	63:5cd1a5f3a41b	1499	//
mjr	74:822a92bc11d2	1500	// The extended protocol discards the flash pattern options and instead
mjr	74:822a92bc11d2	1501	// uses the full byte range 0..255 for brightness levels. Modern clients
mjr	74:822a92bc11d2	1502	// based on DOF don't use the flash patterns, since DOF simply sends
mjr	74:822a92bc11d2	1503	// the individual brightness updates when it wants to create fades or
mjr	74:822a92bc11d2	1504	// flashes. What we gain by dropping the flash options is finer
mjr	74:822a92bc11d2	1505	// gradations of brightness - 256 levels rather than the LedWiz's 48.
mjr	74:822a92bc11d2	1506	// This makes for noticeably smoother fades and a wider gamut for RGB
mjr	74:822a92bc11d2	1507	// color mixing. The extended protocol also drops the LedWiz notion of
mjr	74:822a92bc11d2	1508	// separate "switch" and "profile" settings, and instead combines the
mjr	74:822a92bc11d2	1509	// two into the single brightness setting, with brightness 0 meaning off.
mjr	74:822a92bc11d2	1510	// This also is the way DOF thinks about the problem, so it's a better
mjr	74:822a92bc11d2	1511	// match to modern clients.
mjr	63:5cd1a5f3a41b	1512	//
mjr	74:822a92bc11d2	1513	// To reconcile the different approaches in the two protocols to setting
mjr	74:822a92bc11d2	1514	// output port states, we use a global mode: LedWiz mode or Pinscape mode.
mjr	74:822a92bc11d2	1515	// Whenever an output port message is received, we switch this flag to the
mjr	74:822a92bc11d2	1516	// mode of the message. The assumption is that only one client at a time
mjr	74:822a92bc11d2	1517	// will be manipulating output ports, and that any given client uses one
mjr	74:822a92bc11d2	1518	// protocol exclusively. There's no reason a client should mix the
mjr	74:822a92bc11d2	1519	// protocols; if a client is aware of the Pinscape protocol at all, it
mjr	74:822a92bc11d2	1520	// should use it exclusively.
mjr	63:5cd1a5f3a41b	1521	static uint8_t ledWizMode = true;
mjr	63:5cd1a5f3a41b	1522
mjr	40:cc0d9814522b	1523	// translate an LedWiz brightness level (0-49) to a DOF brightness
mjr	40:cc0d9814522b	1524	// level (0-255)
mjr	40:cc0d9814522b	1525	static const uint8_t lw_to_dof[] = {
mjr	40:cc0d9814522b	1526	0, 5, 11, 16, 21, 27, 32, 37,
mjr	40:cc0d9814522b	1527	43, 48, 53, 58, 64, 69, 74, 80,
mjr	40:cc0d9814522b	1528	85, 90, 96, 101, 106, 112, 117, 122,
mjr	40:cc0d9814522b	1529	128, 133, 138, 143, 149, 154, 159, 165,
mjr	40:cc0d9814522b	1530	170, 175, 181, 186, 191, 197, 202, 207,
mjr	40:cc0d9814522b	1531	213, 218, 223, 228, 234, 239, 244, 250,
mjr	40:cc0d9814522b	1532	255, 255
mjr	40:cc0d9814522b	1533	};
mjr	40:cc0d9814522b	1534
mjr	74:822a92bc11d2	1535	// LedWiz flash cycle tables. For efficiency, we use a lookup table
mjr	74:822a92bc11d2	1536	// rather than calculating these on the fly. The flash cycles are
mjr	74:822a92bc11d2	1537	// generated by the following formulas, where 'c' is the current
mjr	74:822a92bc11d2	1538	// cycle counter, from 0 to 255:
mjr	74:822a92bc11d2	1539	//
mjr	74:822a92bc11d2	1540	// mode 129 = sawtooth = (c < 128 ? c2 + 1 : (255-c)2)
mjr	74:822a92bc11d2	1541	// mode 130 = flash on/off = (c < 128 ? 255 : 0)
mjr	74:822a92bc11d2	1542	// mode 131 = on/ramp down = (c < 128 ? 255 : (255-c)*2)
mjr	74:822a92bc11d2	1543	// mode 132 = ramp up/on = (c < 128 ? c*2 : 255)
mjr	74:822a92bc11d2	1544	//
mjr	74:822a92bc11d2	1545	// To look up the current output value for a given mode and a given
mjr	74:822a92bc11d2	1546	// cycle counter 'c', index the table with ((mode-129)*256)+c.
mjr	74:822a92bc11d2	1547	static const uint8_t wizFlashLookup[] = {
mjr	74:822a92bc11d2	1548	// mode 129 = sawtooth = (c < 128 ? c2 + 1 : (255-c)2)
mjr	74:822a92bc11d2	1549	0x01, 0x03, 0x05, 0x07, 0x09, 0x0b, 0x0d, 0x0f, 0x11, 0x13, 0x15, 0x17, 0x19, 0x1b, 0x1d, 0x1f,
mjr	74:822a92bc11d2	1550	0x21, 0x23, 0x25, 0x27, 0x29, 0x2b, 0x2d, 0x2f, 0x31, 0x33, 0x35, 0x37, 0x39, 0x3b, 0x3d, 0x3f,
mjr	74:822a92bc11d2	1551	0x41, 0x43, 0x45, 0x47, 0x49, 0x4b, 0x4d, 0x4f, 0x51, 0x53, 0x55, 0x57, 0x59, 0x5b, 0x5d, 0x5f,
mjr	74:822a92bc11d2	1552	0x61, 0x63, 0x65, 0x67, 0x69, 0x6b, 0x6d, 0x6f, 0x71, 0x73, 0x75, 0x77, 0x79, 0x7b, 0x7d, 0x7f,
mjr	74:822a92bc11d2	1553	0x81, 0x83, 0x85, 0x87, 0x89, 0x8b, 0x8d, 0x8f, 0x91, 0x93, 0x95, 0x97, 0x99, 0x9b, 0x9d, 0x9f,
mjr	74:822a92bc11d2	1554	0xa1, 0xa3, 0xa5, 0xa7, 0xa9, 0xab, 0xad, 0xaf, 0xb1, 0xb3, 0xb5, 0xb7, 0xb9, 0xbb, 0xbd, 0xbf,
mjr	74:822a92bc11d2	1555	0xc1, 0xc3, 0xc5, 0xc7, 0xc9, 0xcb, 0xcd, 0xcf, 0xd1, 0xd3, 0xd5, 0xd7, 0xd9, 0xdb, 0xdd, 0xdf,
mjr	74:822a92bc11d2	1556	0xe1, 0xe3, 0xe5, 0xe7, 0xe9, 0xeb, 0xed, 0xef, 0xf1, 0xf3, 0xf5, 0xf7, 0xf9, 0xfb, 0xfd, 0xff,
mjr	74:822a92bc11d2	1557	0xfe, 0xfc, 0xfa, 0xf8, 0xf6, 0xf4, 0xf2, 0xf0, 0xee, 0xec, 0xea, 0xe8, 0xe6, 0xe4, 0xe2, 0xe0,
mjr	74:822a92bc11d2	1558	0xde, 0xdc, 0xda, 0xd8, 0xd6, 0xd4, 0xd2, 0xd0, 0xce, 0xcc, 0xca, 0xc8, 0xc6, 0xc4, 0xc2, 0xc0,
mjr	74:822a92bc11d2	1559	0xbe, 0xbc, 0xba, 0xb8, 0xb6, 0xb4, 0xb2, 0xb0, 0xae, 0xac, 0xaa, 0xa8, 0xa6, 0xa4, 0xa2, 0xa0,
mjr	74:822a92bc11d2	1560	0x9e, 0x9c, 0x9a, 0x98, 0x96, 0x94, 0x92, 0x90, 0x8e, 0x8c, 0x8a, 0x88, 0x86, 0x84, 0x82, 0x80,
mjr	74:822a92bc11d2	1561	0x7e, 0x7c, 0x7a, 0x78, 0x76, 0x74, 0x72, 0x70, 0x6e, 0x6c, 0x6a, 0x68, 0x66, 0x64, 0x62, 0x60,
mjr	74:822a92bc11d2	1562	0x5e, 0x5c, 0x5a, 0x58, 0x56, 0x54, 0x52, 0x50, 0x4e, 0x4c, 0x4a, 0x48, 0x46, 0x44, 0x42, 0x40,
mjr	74:822a92bc11d2	1563	0x3e, 0x3c, 0x3a, 0x38, 0x36, 0x34, 0x32, 0x30, 0x2e, 0x2c, 0x2a, 0x28, 0x26, 0x24, 0x22, 0x20,
mjr	74:822a92bc11d2	1564	0x1e, 0x1c, 0x1a, 0x18, 0x16, 0x14, 0x12, 0x10, 0x0e, 0x0c, 0x0a, 0x08, 0x06, 0x04, 0x02, 0x00,
mjr	74:822a92bc11d2	1565
mjr	74:822a92bc11d2	1566	// mode 130 = flash on/off = (c < 128 ? 255 : 0)
mjr	74:822a92bc11d2	1567	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1568	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1569	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1570	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1571	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1572	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1573	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1574	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1575	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
mjr	74:822a92bc11d2	1576	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
mjr	74:822a92bc11d2	1577	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
mjr	74:822a92bc11d2	1578	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
mjr	74:822a92bc11d2	1579	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
mjr	74:822a92bc11d2	1580	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
mjr	74:822a92bc11d2	1581	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
mjr	74:822a92bc11d2	1582	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
mjr	74:822a92bc11d2	1583
mjr	74:822a92bc11d2	1584	// mode 131 = on/ramp down = c < 128 ? 255 : (255 - c)*2
mjr	74:822a92bc11d2	1585	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1586	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1587	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1588	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1589	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1590	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1591	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1592	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1593	0xfe, 0xfc, 0xfa, 0xf8, 0xf6, 0xf4, 0xf2, 0xf0, 0xee, 0xec, 0xea, 0xe8, 0xe6, 0xe4, 0xe2, 0xe0,
mjr	74:822a92bc11d2	1594	0xde, 0xdc, 0xda, 0xd8, 0xd6, 0xd4, 0xd2, 0xd0, 0xce, 0xcc, 0xca, 0xc8, 0xc6, 0xc4, 0xc2, 0xc0,
mjr	74:822a92bc11d2	1595	0xbe, 0xbc, 0xba, 0xb8, 0xb6, 0xb4, 0xb2, 0xb0, 0xae, 0xac, 0xaa, 0xa8, 0xa6, 0xa4, 0xa2, 0xa0,
mjr	74:822a92bc11d2	1596	0x9e, 0x9c, 0x9a, 0x98, 0x96, 0x94, 0x92, 0x90, 0x8e, 0x8c, 0x8a, 0x88, 0x86, 0x84, 0x82, 0x80,
mjr	74:822a92bc11d2	1597	0x7e, 0x7c, 0x7a, 0x78, 0x76, 0x74, 0x72, 0x70, 0x6e, 0x6c, 0x6a, 0x68, 0x66, 0x64, 0x62, 0x60,
mjr	74:822a92bc11d2	1598	0x5e, 0x5c, 0x5a, 0x58, 0x56, 0x54, 0x52, 0x50, 0x4e, 0x4c, 0x4a, 0x48, 0x46, 0x44, 0x42, 0x40,
mjr	74:822a92bc11d2	1599	0x3e, 0x3c, 0x3a, 0x38, 0x36, 0x34, 0x32, 0x30, 0x2e, 0x2c, 0x2a, 0x28, 0x26, 0x24, 0x22, 0x20,
mjr	74:822a92bc11d2	1600	0x1e, 0x1c, 0x1a, 0x18, 0x16, 0x14, 0x12, 0x10, 0x0e, 0x0c, 0x0a, 0x08, 0x06, 0x04, 0x02, 0x00,
mjr	74:822a92bc11d2	1601
mjr	74:822a92bc11d2	1602	// mode 132 = ramp up/on = c < 128 ? c*2 : 255
mjr	74:822a92bc11d2	1603	0x00, 0x02, 0x04, 0x06, 0x08, 0x0a, 0x0c, 0x0e, 0x10, 0x12, 0x14, 0x16, 0x18, 0x1a, 0x1c, 0x1e,
mjr	74:822a92bc11d2	1604	0x20, 0x22, 0x24, 0x26, 0x28, 0x2a, 0x2c, 0x2e, 0x30, 0x32, 0x34, 0x36, 0x38, 0x3a, 0x3c, 0x3e,
mjr	74:822a92bc11d2	1605	0x40, 0x42, 0x44, 0x46, 0x48, 0x4a, 0x4c, 0x4e, 0x50, 0x52, 0x54, 0x56, 0x58, 0x5a, 0x5c, 0x5e,
mjr	74:822a92bc11d2	1606	0x60, 0x62, 0x64, 0x66, 0x68, 0x6a, 0x6c, 0x6e, 0x70, 0x72, 0x74, 0x76, 0x78, 0x7a, 0x7c, 0x7e,
mjr	74:822a92bc11d2	1607	0x80, 0x82, 0x84, 0x86, 0x88, 0x8a, 0x8c, 0x8e, 0x90, 0x92, 0x94, 0x96, 0x98, 0x9a, 0x9c, 0x9e,
mjr	74:822a92bc11d2	1608	0xa0, 0xa2, 0xa4, 0xa6, 0xa8, 0xaa, 0xac, 0xae, 0xb0, 0xb2, 0xb4, 0xb6, 0xb8, 0xba, 0xbc, 0xbe,
mjr	74:822a92bc11d2	1609	0xc0, 0xc2, 0xc4, 0xc6, 0xc8, 0xca, 0xcc, 0xce, 0xd0, 0xd2, 0xd4, 0xd6, 0xd8, 0xda, 0xdc, 0xde,
mjr	74:822a92bc11d2	1610	0xe0, 0xe2, 0xe4, 0xe6, 0xe8, 0xea, 0xec, 0xee, 0xf0, 0xf2, 0xf4, 0xf6, 0xf8, 0xfa, 0xfc, 0xfe,
mjr	74:822a92bc11d2	1611	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1612	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1613	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1614	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1615	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1616	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1617	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
mjr	74:822a92bc11d2	1618	0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff
mjr	74:822a92bc11d2	1619	};
mjr	74:822a92bc11d2	1620
mjr	40:cc0d9814522b	1621	// Translate an LedWiz output (ports 1-32) to a DOF brightness level.
mjr	74:822a92bc11d2	1622	// Note: update all wizFlashCounter[] entries before calling this to
mjr	74:822a92bc11d2	1623	// ensure that we're at the right place in each flash cycle.
mjr	74:822a92bc11d2	1624	//
mjr	74:822a92bc11d2	1625	// Important: the caller must update the wizFlashCounter[] array before
mjr	74:822a92bc11d2	1626	// calling this. We leave it to the caller to update the array rather
mjr	74:822a92bc11d2	1627	// than doing it here, because each set of 32 outputs shares the same
mjr	74:822a92bc11d2	1628	// counter entry.
mjr	40:cc0d9814522b	1629	static uint8_t wizState(int idx)
mjr	0:5acbbe3f4cf4	1630	{
mjr	63:5cd1a5f3a41b	1631	// If we're in extended protocol mode, ignore the LedWiz setting
mjr	63:5cd1a5f3a41b	1632	// for the port and use the new protocol setting instead.
mjr	63:5cd1a5f3a41b	1633	if (!ledWizMode)
mjr	29:582472d0bc57	1634	return outLevel[idx];
mjr	29:582472d0bc57	1635
mjr	29:582472d0bc57	1636	// if it's off, show at zero intensity
mjr	29:582472d0bc57	1637	if (!wizOn[idx])
mjr	29:582472d0bc57	1638	return 0;
mjr	29:582472d0bc57	1639
mjr	29:582472d0bc57	1640	// check the state
mjr	29:582472d0bc57	1641	uint8_t val = wizVal[idx];
mjr	40:cc0d9814522b	1642	if (val <= 49)
mjr	29:582472d0bc57	1643	{
mjr	29:582472d0bc57	1644	// PWM brightness/intensity level. Rescale from the LedWiz
mjr	29:582472d0bc57	1645	// 0..48 integer range to our internal PwmOut 0..1 float range.
mjr	29:582472d0bc57	1646	// Note that on the actual LedWiz, level 48 is actually about
mjr	29:582472d0bc57	1647	// 98% on - contrary to the LedWiz documentation, level 49 is
mjr	29:582472d0bc57	1648	// the true 100% level. (In the documentation, level 49 is
mjr	29:582472d0bc57	1649	// simply not a valid setting.) Even so, we treat level 48 as
mjr	29:582472d0bc57	1650	// 100% on to match the documentation. This won't be perfectly
mjr	73:4e8ce0b18915	1651	// compatible with the actual LedWiz, but it makes for such a
mjr	29:582472d0bc57	1652	// small difference in brightness (if the output device is an
mjr	29:582472d0bc57	1653	// LED, say) that no one should notice. It seems better to
mjr	29:582472d0bc57	1654	// err in this direction, because while the difference in
mjr	29:582472d0bc57	1655	// brightness when attached to an LED won't be noticeable, the
mjr	29:582472d0bc57	1656	// difference in duty cycle when attached to something like a
mjr	29:582472d0bc57	1657	// contactor can be noticeable - anything less than 100%
mjr	29:582472d0bc57	1658	// can cause a contactor or relay to chatter. There's almost
mjr	29:582472d0bc57	1659	// never a situation where you'd want values other than 0% and
mjr	29:582472d0bc57	1660	// 100% for a contactor or relay, so treating level 48 as 100%
mjr	29:582472d0bc57	1661	// makes us work properly with software that's expecting the
mjr	29:582472d0bc57	1662	// documented LedWiz behavior and therefore uses level 48 to
mjr	29:582472d0bc57	1663	// turn a contactor or relay fully on.
mjr	40:cc0d9814522b	1664	//
mjr	40:cc0d9814522b	1665	// Note that value 49 is undefined in the LedWiz documentation,
mjr	40:cc0d9814522b	1666	// but real LedWiz units treat it as 100%, equivalent to 48.
mjr	40:cc0d9814522b	1667	// Some software on the PC side uses this, so we need to treat
mjr	40:cc0d9814522b	1668	// it the same way for compatibility.
mjr	40:cc0d9814522b	1669	return lw_to_dof[val];
mjr	29:582472d0bc57	1670	}
mjr	74:822a92bc11d2	1671	else if (val >= 129 && val <= 132)
mjr	29:582472d0bc57	1672	{
mjr	74:822a92bc11d2	1673	// flash mode - get the current counter for the bank, and look
mjr	74:822a92bc11d2	1674	// up the current position in the cycle for the mode
mjr	73:4e8ce0b18915	1675	const int c = wizFlashCounter[idx/32];
mjr	74:822a92bc11d2	1676	return wizFlashLookup[((val-129)*256) + c];
mjr	29:582472d0bc57	1677	}
mjr	29:582472d0bc57	1678	else
mjr	13:72dda449c3c0	1679	{
mjr	29:582472d0bc57	1680	// Other values are undefined in the LedWiz documentation. Hosts
mjr	29:582472d0bc57	1681	// should never send undefined values, since whatever behavior an
mjr	29:582472d0bc57	1682	// LedWiz unit exhibits in response is accidental and could change
mjr	29:582472d0bc57	1683	// in a future version. We'll treat all undefined values as equivalent
mjr	29:582472d0bc57	1684	// to 48 (fully on).
mjr	40:cc0d9814522b	1685	return 255;
mjr	0:5acbbe3f4cf4	1686	}
mjr	0:5acbbe3f4cf4	1687	}
mjr	0:5acbbe3f4cf4	1688
mjr	74:822a92bc11d2	1689	// LedWiz flash cycle timer. This runs continuously. On each update,
mjr	74:822a92bc11d2	1690	// we use this to figure out where we are on the cycle for each bank.
mjr	74:822a92bc11d2	1691	Timer wizCycleTimer;
mjr	74:822a92bc11d2	1692
mjr	74:822a92bc11d2	1693	// Update the LedWiz flash cycle counters
mjr	74:822a92bc11d2	1694	static void updateWizCycleCounts()
mjr	74:822a92bc11d2	1695	{
mjr	74:822a92bc11d2	1696	// Update the LedWiz flash cycle positions. Each cycle is 2/N
mjr	74:822a92bc11d2	1697	// seconds long, where N is the speed setting for the bank. N
mjr	74:822a92bc11d2	1698	// ranges from 1 to 7.
mjr	74:822a92bc11d2	1699	//
mjr	74:822a92bc11d2	1700	// Note that we treat the microsecond clock as a 32-bit unsigned
mjr	74:822a92bc11d2	1701	// int. This rolls over (i.e., exceeds 0xffffffff) every 71 minutes.
mjr	74:822a92bc11d2	1702	// We only care about the phase of the current LedWiz cycle, so we
mjr	74:822a92bc11d2	1703	// don't actually care about the absolute time - we only care about
mjr	74:822a92bc11d2	1704	// the time relative to some arbitrary starting point. Whenever the
mjr	74:822a92bc11d2	1705	// clock rolls over, it effectively sets a new starting point; since
mjr	74:822a92bc11d2	1706	// we only need an arbitrary starting point, that's largely okay.
mjr	74:822a92bc11d2	1707	// The one drawback is that these epoch resets can obviously occur
mjr	74:822a92bc11d2	1708	// in the middle of a cycle. When this occurs, the update just before
mjr	74:822a92bc11d2	1709	// the rollover and the update just after the rollover will use
mjr	74:822a92bc11d2	1710	// different epochs, so their phases might be misaligned. That could
mjr	74:822a92bc11d2	1711	// cause a sudden jump in brightness between the two updates and a
mjr	74:822a92bc11d2	1712	// shorter-than-usual or longer-than-usual time for that cycle. To
mjr	74:822a92bc11d2	1713	// avoid that, we'd have to use a higher-precision clock (say, a 64-bit
mjr	74:822a92bc11d2	1714	// microsecond counter) and do all of the calculations at the higher
mjr	74:822a92bc11d2	1715	// precision. Given that the rollover only happens once every 71
mjr	74:822a92bc11d2	1716	// minutes, and that the only problem it causes is a momentary glitch
mjr	74:822a92bc11d2	1717	// in the flash pattern, I think it's an equitable trade for the slightly
mjr	74:822a92bc11d2	1718	// faster processing in the 32-bit domain. This routine is called
mjr	74:822a92bc11d2	1719	// frequently from the main loop, so it's critial to minimize execution
mjr	74:822a92bc11d2	1720	// time.
mjr	74:822a92bc11d2	1721	uint32_t tcur = wizCycleTimer.read_us();
mjr	74:822a92bc11d2	1722	for (int i = 0 ; i < MAX_LW_BANKS ; ++i)
mjr	74:822a92bc11d2	1723	{
mjr	74:822a92bc11d2	1724	// Figure the point in the cycle. The LedWiz "speed" setting is
mjr	74:822a92bc11d2	1725	// waveform period in 0.25s units. (There's no official LedWiz
mjr	74:822a92bc11d2	1726	// documentation of what the speed means in real units, so this is
mjr	74:822a92bc11d2	1727	// based on observations.)
mjr	74:822a92bc11d2	1728	//
mjr	74:822a92bc11d2	1729	// We do this calculation frequently from the main loop, since we
mjr	74:822a92bc11d2	1730	// have to do it every time we update the output flash cycles,
mjr	74:822a92bc11d2	1731	// which in turn has to be done frequently to make the cycles
mjr	74:822a92bc11d2	1732	// appear smooth to users. So we're going to get a bit tricky
mjr	74:822a92bc11d2	1733	// with integer arithmetic to streamline it. The goal is to find
mjr	74:822a92bc11d2	1734	// the current phase position in the output waveform; in abstract
mjr	74:822a92bc11d2	1735	// terms, we're trying to find the angle, 0 to 2*pi, in the current
mjr	74:822a92bc11d2	1736	// cycle. Floating point arithmetic is expensive on the KL25Z
mjr	74:822a92bc11d2	1737	// since it's all done in software, so we'll do everything in
mjr	74:822a92bc11d2	1738	// integers. To do that, rather than trying to find the phase
mjr	74:822a92bc11d2	1739	// angle as a continuous quantity, we'll quantize it, into 256
mjr	74:822a92bc11d2	1740	// quanta per cycle. Each quantum is 1/256 of the cycle length,
mjr	74:822a92bc11d2	1741	// so for a 1-second cycle (LedWiz speed 4), each quantum is
mjr	74:822a92bc11d2	1742	// 1/256 of second or about 3.9ms. To find the phase, then, we
mjr	74:822a92bc11d2	1743	// simply take the current time (as an elapsed time from an
mjr	74:822a92bc11d2	1744	// arbitrary zero point aka epoch), quantize it into 3.9ms chunks,
mjr	74:822a92bc11d2	1745	// and calculate the remainder mod 256. Remainder mod 256 is a
mjr	74:822a92bc11d2	1746	// fast operation since it's equivalent to bit masking with 0xFF.
mjr	74:822a92bc11d2	1747	// (That's why we chose a power of two for the number of quanta
mjr	74:822a92bc11d2	1748	// per cycle.) Our timer gives us microseconds since it started,
mjr	74:822a92bc11d2	1749	// so to convert to quanta, we divide by microseconds per quantum;
mjr	74:822a92bc11d2	1750	// in the case of speed 1 with its 3.906ms quanta, we divide by
mjr	74:822a92bc11d2	1751	// 3906. But we can take this one step further, getting really
mjr	74:822a92bc11d2	1752	// tricky now. Dividing by N is the same as muliplying by X/N
mjr	74:822a92bc11d2	1753	// for some X, and then dividing the result by X. Why, you ask,
mjr	74:822a92bc11d2	1754	// would we want to do two operations where we could do one?
mjr	74:822a92bc11d2	1755	// Because if we're clever, the two operations will be much
mjr	74:822a92bc11d2	1756	// faster the the one. The M0+ has no DIVIDE instruction, so
mjr	74:822a92bc11d2	1757	// integer division has to be done in software, at a cost of about
mjr	74:822a92bc11d2	1758	// 100 clocks per operation. The KL25Z M0+ has a one-cycle
mjr	74:822a92bc11d2	1759	// hardware multiplier, though. But doesn't that leave that
mjr	74:822a92bc11d2	1760	// second division still to do? Yes, but if we choose a power
mjr	74:822a92bc11d2	1761	// of 2 for X, we can do that division with a bit shift, another
mjr	74:822a92bc11d2	1762	// single-cycle operation. So we can do the division in two
mjr	74:822a92bc11d2	1763	// cycles by breaking it up into a multiply + shift.
mjr	74:822a92bc11d2	1764	//
mjr	74:822a92bc11d2	1765	// Each entry in this array represents X/N for the corresponding
mjr	74:822a92bc11d2	1766	// LedWiz speed, where N is the number of time quanta per cycle
mjr	74:822a92bc11d2	1767	// and X is 2^24. The time quanta are chosen such that 256
mjr	74:822a92bc11d2	1768	// quanta add up to approximately (LedWiz speed setting * 0.25s).
mjr	74:822a92bc11d2	1769	//
mjr	74:822a92bc11d2	1770	// Note that the calculation has an implicit bit mask (result & 0xFF)
mjr	74:822a92bc11d2	1771	// to get the final result mod 256. But we don't have to actually
mjr	74:822a92bc11d2	1772	// do that work because we're using 32-bit ints and a 2^24 fixed
mjr	74:822a92bc11d2	1773	// point base (X in the narrative above). The final shift right by
mjr	74:822a92bc11d2	1774	// 24 bits to divide out the base will leave us with only 8 bits in
mjr	74:822a92bc11d2	1775	// the result, since we started with 32.
mjr	74:822a92bc11d2	1776	static const uint32_t inv_us_per_quantum[] = { // indexed by LedWiz speed
mjr	74:822a92bc11d2	1777	0, 17172, 8590, 5726, 4295, 3436, 2863, 2454
mjr	74:822a92bc11d2	1778	};
mjr	74:822a92bc11d2	1779	wizFlashCounter[i] = ((tcur * inv_us_per_quantum[wizSpeed[i]]) >> 24);
mjr	74:822a92bc11d2	1780	}
mjr	74:822a92bc11d2	1781	}
mjr	74:822a92bc11d2	1782
mjr	74:822a92bc11d2	1783	// LedWiz flash timer pulse. The main loop calls this periodically
mjr	74:822a92bc11d2	1784	// to update outputs set to LedWiz flash modes.
mjr	74:822a92bc11d2	1785	Timer wizPulseTimer;
mjr	74:822a92bc11d2	1786	float wizPulseTotalTime, wizPulseRunCount;
mjr	74:822a92bc11d2	1787	const uint32_t WIZ_INTERVAL_US = 8000;
mjr	29:582472d0bc57	1788	static void wizPulse()
mjr	29:582472d0bc57	1789	{
mjr	74:822a92bc11d2	1790	// if it's been long enough, update the LedWiz outputs
mjr	74:822a92bc11d2	1791	if (wizPulseTimer.read_us() >= WIZ_INTERVAL_US)
mjr	73:4e8ce0b18915	1792	{
mjr	74:822a92bc11d2	1793	// reset the timer for the next round
mjr	74:822a92bc11d2	1794	wizPulseTimer.reset();
mjr	74:822a92bc11d2	1795
mjr	74:822a92bc11d2	1796	// if we're in LedWiz mode, update flashing outputs
mjr	74:822a92bc11d2	1797	if (ledWizMode)
mjr	29:582472d0bc57	1798	{
mjr	74:822a92bc11d2	1799	// start a timer for statistics collection
mjr	74:822a92bc11d2	1800	IF_DIAG(
mjr	74:822a92bc11d2	1801	Timer t;
mjr	74:822a92bc11d2	1802	t.start();
mjr	74:822a92bc11d2	1803	)
mjr	74:822a92bc11d2	1804
mjr	74:822a92bc11d2	1805	// update the cycle counters
mjr	74:822a92bc11d2	1806	updateWizCycleCounts();
mjr	74:822a92bc11d2	1807
mjr	74:822a92bc11d2	1808	// update all outputs set to flashing values
mjr	74:822a92bc11d2	1809	for (int i = numOutputs ; i > 0 ; )
mjr	29:582472d0bc57	1810	{
mjr	74:822a92bc11d2	1811	if (wizOn[--i])
mjr	74:822a92bc11d2	1812	{
mjr	74:822a92bc11d2	1813	// If the "brightness" is in the range 129..132, it's a
mjr	74:822a92bc11d2	1814	// flash mode. Note that we only have to check the high
mjr	74:822a92bc11d2	1815	// bit here, because the protocol message handler validates
mjr	74:822a92bc11d2	1816	// the wizVal[] entries when storing them: the only valid
mjr	74:822a92bc11d2	1817	// values with the high bit set are 129..132. Skipping
mjr	74:822a92bc11d2	1818	// validation here saves us a tiny bit of work, which we
mjr	74:822a92bc11d2	1819	// care about because we have to loop over all outputs
mjr	74:822a92bc11d2	1820	// here, and we invoke this frequently from the main loop.
mjr	74:822a92bc11d2	1821	const uint8_t val = wizVal[i];
mjr	74:822a92bc11d2	1822	if ((val & 0x80) != 0)
mjr	74:822a92bc11d2	1823	{
mjr	74:822a92bc11d2	1824	// get the current cycle time, then look up the
mjr	74:822a92bc11d2	1825	// value for the mode at the cycle time
mjr	74:822a92bc11d2	1826	const int c = wizFlashCounter[i >> 5];
mjr	74:822a92bc11d2	1827	lwPin[i]->set(wizFlashLookup[((val-129) << 8) + c]);
mjr	74:822a92bc11d2	1828	}
mjr	74:822a92bc11d2	1829	}
mjr	29:582472d0bc57	1830	}
mjr	74:822a92bc11d2	1831
mjr	74:822a92bc11d2	1832	// flush changes to 74HC595 chips, if attached
mjr	74:822a92bc11d2	1833	if (hc595 != 0)
mjr	74:822a92bc11d2	1834	hc595->update();
mjr	74:822a92bc11d2	1835
mjr	74:822a92bc11d2	1836	// collect timing statistics
mjr	74:822a92bc11d2	1837	IF_DIAG(
mjr	74:822a92bc11d2	1838	wizPulseTotalTime += t.read();
mjr	74:822a92bc11d2	1839	wizPulseRunCount += 1;
mjr	74:822a92bc11d2	1840	)
mjr	29:582472d0bc57	1841	}
mjr	29:582472d0bc57	1842	}
mjr	29:582472d0bc57	1843	}
mjr	29:582472d0bc57	1844
mjr	29:582472d0bc57	1845	// Update the physical outputs connected to the LedWiz ports. This is
mjr	29:582472d0bc57	1846	// called after any update from an LedWiz protocol message.
mjr	1:d913e0afb2ac	1847	static void updateWizOuts()
mjr	1:d913e0afb2ac	1848	{
mjr	74:822a92bc11d2	1849	// update the cycle counters
mjr	74:822a92bc11d2	1850	updateWizCycleCounts();
mjr	74:822a92bc11d2	1851
mjr	29:582472d0bc57	1852	// update each output
mjr	73:4e8ce0b18915	1853	for (int i = 0 ; i < numOutputs ; ++i)
mjr	40:cc0d9814522b	1854	lwPin[i]->set(wizState(i));
mjr	29:582472d0bc57	1855
mjr	34:6b981a2afab7	1856	// flush changes to 74HC595 chips, if attached
mjr	35:e959ffba78fd	1857	if (hc595 != 0)
mjr	35:e959ffba78fd	1858	hc595->update();
mjr	1:d913e0afb2ac	1859	}
mjr	38:091e511ce8a0	1860
mjr	38:091e511ce8a0	1861	// Update all physical outputs. This is called after a change to a global
mjr	38:091e511ce8a0	1862	// setting that affects all outputs, such as engaging or canceling Night Mode.
mjr	38:091e511ce8a0	1863	static void updateAllOuts()
mjr	38:091e511ce8a0	1864	{
mjr	74:822a92bc11d2	1865	// update LedWiz states
mjr	74:822a92bc11d2	1866	updateWizOuts();
mjr	73:4e8ce0b18915	1867	}
mjr	73:4e8ce0b18915	1868
mjr	73:4e8ce0b18915	1869	//
mjr	73:4e8ce0b18915	1870	// Turn off all outputs and restore everything to the default LedWiz
mjr	73:4e8ce0b18915	1871	// state. This sets outputs #1-32 to LedWiz profile value 48 (full
mjr	73:4e8ce0b18915	1872	// brightness) and switch state Off, sets all extended outputs (#33
mjr	73:4e8ce0b18915	1873	// and above) to zero brightness, and sets the LedWiz flash rate to 2.
mjr	73:4e8ce0b18915	1874	// This effectively restores the power-on conditions.
mjr	73:4e8ce0b18915	1875	//
mjr	73:4e8ce0b18915	1876	void allOutputsOff()
mjr	73:4e8ce0b18915	1877	{
mjr	73:4e8ce0b18915	1878	// reset all LedWiz outputs to OFF/48
mjr	73:4e8ce0b18915	1879	for (int i = 0 ; i < numOutputs ; ++i)
mjr	73:4e8ce0b18915	1880	{
mjr	73:4e8ce0b18915	1881	outLevel[i] = 0;
mjr	73:4e8ce0b18915	1882	wizOn[i] = 0;
mjr	73:4e8ce0b18915	1883	wizVal[i] = 48;
mjr	73:4e8ce0b18915	1884	lwPin[i]->set(0);
mjr	73:4e8ce0b18915	1885	}
mjr	73:4e8ce0b18915	1886
mjr	73:4e8ce0b18915	1887	// restore default LedWiz flash rate
mjr	73:4e8ce0b18915	1888	for (int i = 0 ; i < countof(wizSpeed) ; ++i)
mjr	73:4e8ce0b18915	1889	wizSpeed[i] = 2;
mjr	38:091e511ce8a0	1890
mjr	74:822a92bc11d2	1891	// revert to LedWiz mode for output controls
mjr	74:822a92bc11d2	1892	ledWizMode = true;
mjr	73:4e8ce0b18915	1893
mjr	73:4e8ce0b18915	1894	// flush changes to hc595, if applicable
mjr	38:091e511ce8a0	1895	if (hc595 != 0)
mjr	38:091e511ce8a0	1896	hc595->update();
mjr	38:091e511ce8a0	1897	}
mjr	38:091e511ce8a0	1898
mjr	74:822a92bc11d2	1899	// Cary out an SBA or SBX message. portGroup is 0 for ports 1-32,
mjr	74:822a92bc11d2	1900	// 1 for ports 33-64, etc. Original protocol SBA messages always
mjr	74:822a92bc11d2	1901	// address port group 0; our private SBX extension messages can
mjr	74:822a92bc11d2	1902	// address any port group.
mjr	74:822a92bc11d2	1903	void sba_sbx(int portGroup, const uint8_t *data)
mjr	74:822a92bc11d2	1904	{
mjr	74:822a92bc11d2	1905	// switch to LedWiz protocol mode
mjr	74:822a92bc11d2	1906	ledWizMode = true;
mjr	74:822a92bc11d2	1907
mjr	74:822a92bc11d2	1908	// update all on/off states
mjr	74:822a92bc11d2	1909	for (int i = 0, bit = 1, imsg = 1, port = portGroup*32 ;
mjr	74:822a92bc11d2	1910	i < 32 && port < numOutputs ;
mjr	74:822a92bc11d2	1911	++i, bit <<= 1, ++port)
mjr	74:822a92bc11d2	1912	{
mjr	74:822a92bc11d2	1913	// figure the on/off state bit for this output
mjr	74:822a92bc11d2	1914	if (bit == 0x100) {
mjr	74:822a92bc11d2	1915	bit = 1;
mjr	74:822a92bc11d2	1916	++imsg;
mjr	74:822a92bc11d2	1917	}
mjr	74:822a92bc11d2	1918
mjr	74:822a92bc11d2	1919	// set the on/off state
mjr	74:822a92bc11d2	1920	wizOn[port] = ((data[imsg] & bit) != 0);
mjr	74:822a92bc11d2	1921	}
mjr	74:822a92bc11d2	1922
mjr	74:822a92bc11d2	1923	// set the flash speed for the port group
mjr	74:822a92bc11d2	1924	if (portGroup < countof(wizSpeed))
mjr	74:822a92bc11d2	1925	wizSpeed[portGroup] = (data[5] < 1 ? 1 : data[5] > 7 ? 7 : data[5]);
mjr	74:822a92bc11d2	1926
mjr	74:822a92bc11d2	1927	// update the physical outputs with the new LedWiz states
mjr	74:822a92bc11d2	1928	updateWizOuts();
mjr	74:822a92bc11d2	1929	}
mjr	74:822a92bc11d2	1930
mjr	74:822a92bc11d2	1931	// Carry out a PBA or PBX message.
mjr	74:822a92bc11d2	1932	void pba_pbx(int basePort, const uint8_t *data)
mjr	74:822a92bc11d2	1933	{
mjr	74:822a92bc11d2	1934	// switch LedWiz protocol mode
mjr	74:822a92bc11d2	1935	ledWizMode = true;
mjr	74:822a92bc11d2	1936
mjr	74:822a92bc11d2	1937	// update each wizVal entry from the brightness data
mjr	74:822a92bc11d2	1938	for (int i = 0, iwiz = basePort ; i < 8 && iwiz < numOutputs ; ++i, ++iwiz)
mjr	74:822a92bc11d2	1939	{
mjr	74:822a92bc11d2	1940	// get the value
mjr	74:822a92bc11d2	1941	uint8_t v = data[i];
mjr	74:822a92bc11d2	1942
mjr	74:822a92bc11d2	1943	// Validate it. The legal values are 0..49 for brightness
mjr	74:822a92bc11d2	1944	// levels, and 128..132 for flash modes. Set anything invalid
mjr	74:822a92bc11d2	1945	// to full brightness (48) instead. Note that 49 isn't actually
mjr	74:822a92bc11d2	1946	// a valid documented value, but in practice some clients send
mjr	74:822a92bc11d2	1947	// this to mean 100% brightness, and the real LedWiz treats it
mjr	74:822a92bc11d2	1948	// as such.
mjr	74:822a92bc11d2	1949	if ((v > 49 && v < 129) \|\| v > 132)
mjr	74:822a92bc11d2	1950	v = 48;
mjr	74:822a92bc11d2	1951
mjr	74:822a92bc11d2	1952	// store it
mjr	74:822a92bc11d2	1953	wizVal[iwiz] = v;
mjr	74:822a92bc11d2	1954	}
mjr	74:822a92bc11d2	1955
mjr	74:822a92bc11d2	1956	// update the physical outputs
mjr	74:822a92bc11d2	1957	updateWizOuts();
mjr	74:822a92bc11d2	1958	}
mjr	74:822a92bc11d2	1959
mjr	74:822a92bc11d2	1960
mjr	11:bd9da7088e6e	1961	// ---------------------------------------------------------------------------
mjr	11:bd9da7088e6e	1962	//
mjr	11:bd9da7088e6e	1963	// Button input
mjr	11:bd9da7088e6e	1964	//
mjr	11:bd9da7088e6e	1965
mjr	18:5e890ebd0023	1966	// button state
mjr	18:5e890ebd0023	1967	struct ButtonState
mjr	18:5e890ebd0023	1968	{
mjr	38:091e511ce8a0	1969	ButtonState()
mjr	38:091e511ce8a0	1970	{
mjr	53:9b2611964afc	1971	physState = logState = prevLogState = 0;
mjr	53:9b2611964afc	1972	virtState = 0;
mjr	53:9b2611964afc	1973	dbState = 0;
mjr	38:091e511ce8a0	1974	pulseState = 0;
mjr	53:9b2611964afc	1975	pulseTime = 0;
mjr	38:091e511ce8a0	1976	}
mjr	35:e959ffba78fd	1977
mjr	53:9b2611964afc	1978	// "Virtually" press or un-press the button. This can be used to
mjr	53:9b2611964afc	1979	// control the button state via a software (virtual) source, such as
mjr	53:9b2611964afc	1980	// the ZB Launch Ball feature.
mjr	53:9b2611964afc	1981	//
mjr	53:9b2611964afc	1982	// To allow sharing of one button by multiple virtual sources, each
mjr	53:9b2611964afc	1983	// virtual source must keep track of its own state internally, and
mjr	53:9b2611964afc	1984	// only call this routine to CHANGE the state. This is because calls
mjr	53:9b2611964afc	1985	// to this routine are additive: turning the button ON twice will
mjr	53:9b2611964afc	1986	// require turning it OFF twice before it actually turns off.
mjr	53:9b2611964afc	1987	void virtPress(bool on)
mjr	53:9b2611964afc	1988	{
mjr	53:9b2611964afc	1989	// Increment or decrement the current state
mjr	53:9b2611964afc	1990	virtState += on ? 1 : -1;
mjr	53:9b2611964afc	1991	}
mjr	53:9b2611964afc	1992
mjr	53:9b2611964afc	1993	// DigitalIn for the button, if connected to a physical input
mjr	73:4e8ce0b18915	1994	TinyDigitalIn di;
mjr	38:091e511ce8a0	1995
mjr	65:739875521aae	1996	// Time of last pulse state transition.
mjr	65:739875521aae	1997	//
mjr	65:739875521aae	1998	// Each state change sticks for a minimum period; when the timer expires,
mjr	65:739875521aae	1999	// if the underlying physical switch is in a different state, we switch
mjr	65:739875521aae	2000	// to the next state and restart the timer. pulseTime is the time remaining
mjr	65:739875521aae	2001	// remaining before we can make another state transition, in microseconds.
mjr	65:739875521aae	2002	// The state transitions require a complete cycle, 1 -> 2 -> 3 -> 4 -> 1...;
mjr	65:739875521aae	2003	// this guarantees that the parity of the pulse count always matches the
mjr	65:739875521aae	2004	// current physical switch state when the latter is stable, which makes
mjr	65:739875521aae	2005	// it impossible to "trick" the host by rapidly toggling the switch state.
mjr	65:739875521aae	2006	// (On my original Pinscape cabinet, I had a hardware pulse generator
mjr	65:739875521aae	2007	// for coin door, and that was possible to trick by rapid toggling.
mjr	65:739875521aae	2008	// This software system can't be fooled that way.)
mjr	65:739875521aae	2009	uint32_t pulseTime;
mjr	18:5e890ebd0023	2010
mjr	65:739875521aae	2011	// Config key index. This points to the ButtonCfg structure in the
mjr	65:739875521aae	2012	// configuration that contains the PC key mapping for the button.
mjr	65:739875521aae	2013	uint8_t cfgIndex;
mjr	53:9b2611964afc	2014
mjr	53:9b2611964afc	2015	// Virtual press state. This is used to simulate pressing the button via
mjr	53:9b2611964afc	2016	// software inputs rather than physical inputs. To allow one button to be
mjr	53:9b2611964afc	2017	// controlled by mulitple software sources, each source should keep track
mjr	53:9b2611964afc	2018	// of its own virtual state for the button independently, and then INCREMENT
mjr	53:9b2611964afc	2019	// this variable when the source's state transitions from off to on, and
mjr	53:9b2611964afc	2020	// DECREMENT it when the source's state transitions from on to off. That
mjr	53:9b2611964afc	2021	// will make the button's pressed state the logical OR of all of the virtual
mjr	53:9b2611964afc	2022	// and physical source states.
mjr	53:9b2611964afc	2023	uint8_t virtState;
mjr	38:091e511ce8a0	2024
mjr	38:091e511ce8a0	2025	// Debounce history. On each scan, we shift in a 1 bit to the lsb if
mjr	38:091e511ce8a0	2026	// the physical key is reporting ON, and shift in a 0 bit if the physical
mjr	38:091e511ce8a0	2027	// key is reporting OFF. We consider the key to have a new stable state
mjr	38:091e511ce8a0	2028	// if we have N consecutive 0's or 1's in the low N bits (where N is
mjr	38:091e511ce8a0	2029	// a parameter that determines how long we wait for transients to settle).
mjr	53:9b2611964afc	2030	uint8_t dbState;
mjr	38:091e511ce8a0	2031
mjr	65:739875521aae	2032	// current PHYSICAL on/off state, after debouncing
mjr	65:739875521aae	2033	uint8_t physState : 1;
mjr	65:739875521aae	2034
mjr	65:739875521aae	2035	// current LOGICAL on/off state as reported to the host.
mjr	65:739875521aae	2036	uint8_t logState : 1;
mjr	65:739875521aae	2037
mjr	65:739875521aae	2038	// previous logical on/off state, when keys were last processed for USB
mjr	65:739875521aae	2039	// reports and local effects
mjr	65:739875521aae	2040	uint8_t prevLogState : 1;
mjr	65:739875521aae	2041
mjr	65:739875521aae	2042	// Pulse state
mjr	65:739875521aae	2043	//
mjr	65:739875521aae	2044	// A button in pulse mode (selected via the config flags for the button)
mjr	65:739875521aae	2045	// transmits a brief logical button press and release each time the attached
mjr	65:739875521aae	2046	// physical switch changes state. This is useful for cases where the host
mjr	65:739875521aae	2047	// expects a key press for each change in the state of the physical switch.
mjr	65:739875521aae	2048	// The canonical example is the Coin Door switch in VPinMAME, which requires
mjr	65:739875521aae	2049	// pressing the END key to toggle the open/closed state. This software design
mjr	65:739875521aae	2050	// isn't easily implemented in a physical coin door, though; the simplest
mjr	65:739875521aae	2051	// physical sensor for the coin door state is a switch that's on when the
mjr	65:739875521aae	2052	// door is open and off when the door is closed (or vice versa, but in either
mjr	65:739875521aae	2053	// case, the switch state corresponds to the current state of the door at any
mjr	65:739875521aae	2054	// given time, rather than pulsing on state changes). The "pulse mode"
mjr	65:739875521aae	2055	// option brdiges this gap by generating a toggle key event each time
mjr	65:739875521aae	2056	// there's a change to the physical switch's state.
mjr	38:091e511ce8a0	2057	//
mjr	38:091e511ce8a0	2058	// Pulse state:
mjr	38:091e511ce8a0	2059	// 0 -> not a pulse switch - logical key state equals physical switch state
mjr	38:091e511ce8a0	2060	// 1 -> off
mjr	38:091e511ce8a0	2061	// 2 -> transitioning off-on
mjr	38:091e511ce8a0	2062	// 3 -> on
mjr	38:091e511ce8a0	2063	// 4 -> transitioning on-off
mjr	65:739875521aae	2064	uint8_t pulseState : 3; // 5 states -> we need 3 bits
mjr	65:739875521aae	2065
mjr	65:739875521aae	2066	} __attribute__((packed));
mjr	65:739875521aae	2067
mjr	65:739875521aae	2068	ButtonState *buttonState; // live button slots, allocated on startup
mjr	65:739875521aae	2069	int8_t nButtons; // number of live button slots allocated
mjr	65:739875521aae	2070	int8_t zblButtonIndex = -1; // index of ZB Launch button slot; -1 if unused
mjr	18:5e890ebd0023	2071
mjr	66:2e3583fbd2f4	2072	// Shift button state
mjr	66:2e3583fbd2f4	2073	struct
mjr	66:2e3583fbd2f4	2074	{
mjr	66:2e3583fbd2f4	2075	int8_t index; // buttonState[] index of shift button; -1 if none
mjr	66:2e3583fbd2f4	2076	uint8_t state : 2; // current shift state:
mjr	66:2e3583fbd2f4	2077	// 0 = not shifted
mjr	66:2e3583fbd2f4	2078	// 1 = shift button down, no key pressed yet
mjr	66:2e3583fbd2f4	2079	// 2 = shift button down, key pressed
mjr	66:2e3583fbd2f4	2080	uint8_t pulse : 1; // sending pulsed keystroke on release
mjr	66:2e3583fbd2f4	2081	uint32_t pulseTime; // time of start of pulsed keystroke
mjr	66:2e3583fbd2f4	2082	}
mjr	66:2e3583fbd2f4	2083	__attribute__((packed)) shiftButton;
mjr	38:091e511ce8a0	2084
mjr	38:091e511ce8a0	2085	// Button data
mjr	38:091e511ce8a0	2086	uint32_t jsButtons = 0;
mjr	38:091e511ce8a0	2087
mjr	38:091e511ce8a0	2088	// Keyboard report state. This tracks the USB keyboard state. We can
mjr	38:091e511ce8a0	2089	// report at most 6 simultaneous non-modifier keys here, plus the 8
mjr	38:091e511ce8a0	2090	// modifier keys.
mjr	38:091e511ce8a0	2091	struct
mjr	38:091e511ce8a0	2092	{
mjr	38:091e511ce8a0	2093	bool changed; // flag: changed since last report sent
mjr	48:058ace2aed1d	2094	uint8_t nkeys; // number of active keys in the list
mjr	38:091e511ce8a0	2095	uint8_t data[8]; // key state, in USB report format: byte 0 is the modifier key mask,
mjr	38:091e511ce8a0	2096	// byte 1 is reserved, and bytes 2-7 are the currently pressed key codes
mjr	38:091e511ce8a0	2097	} kbState = { false, 0, { 0, 0, 0, 0, 0, 0, 0, 0 } };
mjr	38:091e511ce8a0	2098
mjr	38:091e511ce8a0	2099	// Media key state
mjr	38:091e511ce8a0	2100	struct
mjr	38:091e511ce8a0	2101	{
mjr	38:091e511ce8a0	2102	bool changed; // flag: changed since last report sent
mjr	38:091e511ce8a0	2103	uint8_t data; // key state byte for USB reports
mjr	38:091e511ce8a0	2104	} mediaState = { false, 0 };
mjr	38:091e511ce8a0	2105
mjr	38:091e511ce8a0	2106	// button scan interrupt ticker
mjr	38:091e511ce8a0	2107	Ticker buttonTicker;
mjr	38:091e511ce8a0	2108
mjr	38:091e511ce8a0	2109	// Button scan interrupt handler. We call this periodically via
mjr	38:091e511ce8a0	2110	// a timer interrupt to scan the physical button states.
mjr	38:091e511ce8a0	2111	void scanButtons()
mjr	38:091e511ce8a0	2112	{
mjr	38:091e511ce8a0	2113	// scan all button input pins
mjr	73:4e8ce0b18915	2114	ButtonState bs = buttonState, last = bs + nButtons;
mjr	73:4e8ce0b18915	2115	for ( ; bs < last ; ++bs)
mjr	38:091e511ce8a0	2116	{
mjr	73:4e8ce0b18915	2117	// Shift the new state into the debounce history
mjr	73:4e8ce0b18915	2118	uint8_t db = (bs->dbState << 1) \| bs->di.read();
mjr	73:4e8ce0b18915	2119	bs->dbState = db;
mjr	73:4e8ce0b18915	2120
mjr	73:4e8ce0b18915	2121	// If we have all 0's or 1's in the history for the required
mjr	73:4e8ce0b18915	2122	// debounce period, the key state is stable, so apply the new
mjr	73:4e8ce0b18915	2123	// physical state. Note that the pins are active low, so the
mjr	73:4e8ce0b18915	2124	// new button on/off state is the inverse of the GPIO state.
mjr	73:4e8ce0b18915	2125	const uint8_t stable = 0x1F; // 00011111b -> low 5 bits = last 5 readings
mjr	73:4e8ce0b18915	2126	db &= stable;
mjr	73:4e8ce0b18915	2127	if (db == 0 \|\| db == stable)
mjr	73:4e8ce0b18915	2128	bs->physState = !db;
mjr	38:091e511ce8a0	2129	}
mjr	38:091e511ce8a0	2130	}
mjr	38:091e511ce8a0	2131
mjr	38:091e511ce8a0	2132	// Button state transition timer. This is used for pulse buttons, to
mjr	38:091e511ce8a0	2133	// control the timing of the logical key presses generated by transitions
mjr	38:091e511ce8a0	2134	// in the physical button state.
mjr	38:091e511ce8a0	2135	Timer buttonTimer;
mjr	12:669df364a565	2136
mjr	65:739875521aae	2137	// Count a button during the initial setup scan
mjr	72:884207c0aab0	2138	void countButton(uint8_t typ, uint8_t shiftTyp, bool &kbKeys)
mjr	65:739875521aae	2139	{
mjr	65:739875521aae	2140	// count it
mjr	65:739875521aae	2141	++nButtons;
mjr	65:739875521aae	2142
mjr	67:c39e66c4e000	2143	// if it's a keyboard key or media key, note that we need a USB
mjr	67:c39e66c4e000	2144	// keyboard interface
mjr	72:884207c0aab0	2145	if (typ == BtnTypeKey \|\| typ == BtnTypeMedia
mjr	72:884207c0aab0	2146	\|\| shiftTyp == BtnTypeKey \|\| shiftTyp == BtnTypeMedia)
mjr	65:739875521aae	2147	kbKeys = true;
mjr	65:739875521aae	2148	}
mjr	65:739875521aae	2149
mjr	11:bd9da7088e6e	2150	// initialize the button inputs
mjr	35:e959ffba78fd	2151	void initButtons(Config &cfg, bool &kbKeys)
mjr	11:bd9da7088e6e	2152	{
mjr	35:e959ffba78fd	2153	// presume we'll find no keyboard keys
mjr	35:e959ffba78fd	2154	kbKeys = false;
mjr	35:e959ffba78fd	2155
mjr	66:2e3583fbd2f4	2156	// presume no shift key
mjr	66:2e3583fbd2f4	2157	shiftButton.index = -1;
mjr	66:2e3583fbd2f4	2158
mjr	65:739875521aae	2159	// Count up how many button slots we'll need to allocate. Start
mjr	65:739875521aae	2160	// with assigned buttons from the configuration, noting that we
mjr	65:739875521aae	2161	// only need to create slots for buttons that are actually wired.
mjr	65:739875521aae	2162	nButtons = 0;
mjr	65:739875521aae	2163	for (int i = 0 ; i < MAX_BUTTONS ; ++i)
mjr	65:739875521aae	2164	{
mjr	65:739875521aae	2165	// it's valid if it's wired to a real input pin
mjr	65:739875521aae	2166	if (wirePinName(cfg.button[i].pin) != NC)
mjr	72:884207c0aab0	2167	countButton(cfg.button[i].typ, cfg.button[i].typ2, kbKeys);
mjr	65:739875521aae	2168	}
mjr	65:739875521aae	2169
mjr	65:739875521aae	2170	// Count virtual buttons
mjr	65:739875521aae	2171
mjr	65:739875521aae	2172	// ZB Launch
mjr	65:739875521aae	2173	if (cfg.plunger.zbLaunchBall.port != 0)
mjr	65:739875521aae	2174	{
mjr	65:739875521aae	2175	// valid - remember the live button index
mjr	65:739875521aae	2176	zblButtonIndex = nButtons;
mjr	65:739875521aae	2177
mjr	65:739875521aae	2178	// count it
mjr	72:884207c0aab0	2179	countButton(cfg.plunger.zbLaunchBall.keytype, BtnTypeNone, kbKeys);
mjr	65:739875521aae	2180	}
mjr	65:739875521aae	2181
mjr	65:739875521aae	2182	// Allocate the live button slots
mjr	65:739875521aae	2183	ButtonState *bs = buttonState = new ButtonState[nButtons];
mjr	65:739875521aae	2184
mjr	65:739875521aae	2185	// Configure the physical inputs
mjr	65:739875521aae	2186	for (int i = 0 ; i < MAX_BUTTONS ; ++i)
mjr	65:739875521aae	2187	{
mjr	65:739875521aae	2188	PinName pin = wirePinName(cfg.button[i].pin);
mjr	65:739875521aae	2189	if (pin != NC)
mjr	65:739875521aae	2190	{
mjr	65:739875521aae	2191	// point back to the config slot for the keyboard data
mjr	65:739875521aae	2192	bs->cfgIndex = i;
mjr	65:739875521aae	2193
mjr	65:739875521aae	2194	// set up the GPIO input pin for this button
mjr	73:4e8ce0b18915	2195	bs->di.assignPin(pin);
mjr	65:739875521aae	2196
mjr	65:739875521aae	2197	// if it's a pulse mode button, set the initial pulse state to Off
mjr	65:739875521aae	2198	if (cfg.button[i].flags & BtnFlagPulse)
mjr	65:739875521aae	2199	bs->pulseState = 1;
mjr	65:739875521aae	2200
mjr	66:2e3583fbd2f4	2201	// If this is the shift button, note its buttonState[] index.
mjr	66:2e3583fbd2f4	2202	// We have to figure the buttonState[] index separately from
mjr	66:2e3583fbd2f4	2203	// the config index, because the indices can differ if some
mjr	66:2e3583fbd2f4	2204	// config slots are left unused.
mjr	66:2e3583fbd2f4	2205	if (cfg.shiftButton == i+1)
mjr	66:2e3583fbd2f4	2206	shiftButton.index = bs - buttonState;
mjr	66:2e3583fbd2f4	2207
mjr	65:739875521aae	2208	// advance to the next button
mjr	65:739875521aae	2209	++bs;
mjr	65:739875521aae	2210	}
mjr	65:739875521aae	2211	}
mjr	65:739875521aae	2212
mjr	53:9b2611964afc	2213	// Configure the virtual buttons. These are buttons controlled via
mjr	53:9b2611964afc	2214	// software triggers rather than physical GPIO inputs. The virtual
mjr	53:9b2611964afc	2215	// buttons have the same control structures as regular buttons, but
mjr	53:9b2611964afc	2216	// they get their configuration data from other config variables.
mjr	53:9b2611964afc	2217
mjr	53:9b2611964afc	2218	// ZB Launch Ball button
mjr	65:739875521aae	2219	if (cfg.plunger.zbLaunchBall.port != 0)
mjr	11:bd9da7088e6e	2220	{
mjr	65:739875521aae	2221	// Point back to the config slot for the keyboard data.
mjr	66:2e3583fbd2f4	2222	// We use a special extra slot for virtual buttons,
mjr	66:2e3583fbd2f4	2223	// so we also need to set up the slot data by copying
mjr	66:2e3583fbd2f4	2224	// the ZBL config data to our virtual button slot.
mjr	65:739875521aae	2225	bs->cfgIndex = ZBL_BUTTON_CFG;
mjr	65:739875521aae	2226	cfg.button[ZBL_BUTTON_CFG].pin = PINNAME_TO_WIRE(NC);
mjr	65:739875521aae	2227	cfg.button[ZBL_BUTTON_CFG].typ = cfg.plunger.zbLaunchBall.keytype;
mjr	65:739875521aae	2228	cfg.button[ZBL_BUTTON_CFG].val = cfg.plunger.zbLaunchBall.keycode;
mjr	65:739875521aae	2229
mjr	66:2e3583fbd2f4	2230	// advance to the next button
mjr	65:739875521aae	2231	++bs;
mjr	11:bd9da7088e6e	2232	}
mjr	12:669df364a565	2233
mjr	38:091e511ce8a0	2234	// start the button scan thread
mjr	38:091e511ce8a0	2235	buttonTicker.attach_us(scanButtons, 1000);
mjr	38:091e511ce8a0	2236
mjr	38:091e511ce8a0	2237	// start the button state transition timer
mjr	12:669df364a565	2238	buttonTimer.start();
mjr	11:bd9da7088e6e	2239	}
mjr	11:bd9da7088e6e	2240
mjr	67:c39e66c4e000	2241	// Media key mapping. This maps from an 8-bit USB media key
mjr	67:c39e66c4e000	2242	// code to the corresponding bit in our USB report descriptor.
mjr	67:c39e66c4e000	2243	// The USB key code is the index, and the value at the index
mjr	67:c39e66c4e000	2244	// is the report descriptor bit. See joystick.cpp for the
mjr	67:c39e66c4e000	2245	// media descriptor details. Our currently mapped keys are:
mjr	67:c39e66c4e000	2246	//
mjr	67:c39e66c4e000	2247	// 0xE2 -> Mute -> 0x01
mjr	67:c39e66c4e000	2248	// 0xE9 -> Volume Up -> 0x02
mjr	67:c39e66c4e000	2249	// 0xEA -> Volume Down -> 0x04
mjr	67:c39e66c4e000	2250	// 0xB5 -> Next Track -> 0x08
mjr	67:c39e66c4e000	2251	// 0xB6 -> Previous Track -> 0x10
mjr	67:c39e66c4e000	2252	// 0xB7 -> Stop -> 0x20
mjr	67:c39e66c4e000	2253	// 0xCD -> Play / Pause -> 0x40
mjr	67:c39e66c4e000	2254	//
mjr	67:c39e66c4e000	2255	static const uint8_t mediaKeyMap[] = {
mjr	67:c39e66c4e000	2256	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 00-0F
mjr	67:c39e66c4e000	2257	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 10-1F
mjr	67:c39e66c4e000	2258	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 20-2F
mjr	67:c39e66c4e000	2259	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 30-3F
mjr	67:c39e66c4e000	2260	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 40-4F
mjr	67:c39e66c4e000	2261	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 50-5F
mjr	67:c39e66c4e000	2262	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 60-6F
mjr	67:c39e66c4e000	2263	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 70-7F
mjr	67:c39e66c4e000	2264	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 80-8F
mjr	67:c39e66c4e000	2265	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 90-9F
mjr	67:c39e66c4e000	2266	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // A0-AF
mjr	67:c39e66c4e000	2267	0, 0, 0, 0, 0, 8, 16, 32, 0, 0, 0, 0, 0, 0, 0, 0, // B0-BF
mjr	67:c39e66c4e000	2268	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 64, 0, 0, // C0-CF
mjr	67:c39e66c4e000	2269	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // D0-DF
mjr	67:c39e66c4e000	2270	0, 0, 1, 0, 0, 0, 0, 0, 0, 2, 4, 0, 0, 0, 0, 0, // E0-EF
mjr	67:c39e66c4e000	2271	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 // F0-FF
mjr	67:c39e66c4e000	2272	};
mjr	67:c39e66c4e000	2273
mjr	67:c39e66c4e000	2274
mjr	38:091e511ce8a0	2275	// Process the button state. This sets up the joystick, keyboard, and
mjr	38:091e511ce8a0	2276	// media control descriptors with the current state of keys mapped to
mjr	38:091e511ce8a0	2277	// those HID interfaces, and executes the local effects for any keys
mjr	38:091e511ce8a0	2278	// mapped to special device functions (e.g., Night Mode).
mjr	53:9b2611964afc	2279	void processButtons(Config &cfg)
mjr	35:e959ffba78fd	2280	{
mjr	35:e959ffba78fd	2281	// start with an empty list of USB key codes
mjr	35:e959ffba78fd	2282	uint8_t modkeys = 0;
mjr	35:e959ffba78fd	2283	uint8_t keys[7] = { 0, 0, 0, 0, 0, 0, 0 };
mjr	35:e959ffba78fd	2284	int nkeys = 0;
mjr	11:bd9da7088e6e	2285
mjr	35:e959ffba78fd	2286	// clear the joystick buttons
mjr	36:b9747461331e	2287	uint32_t newjs = 0;
mjr	35:e959ffba78fd	2288
mjr	35:e959ffba78fd	2289	// start with no media keys pressed
mjr	35:e959ffba78fd	2290	uint8_t mediakeys = 0;
mjr	38:091e511ce8a0	2291
mjr	38:091e511ce8a0	2292	// calculate the time since the last run
mjr	53:9b2611964afc	2293	uint32_t dt = buttonTimer.read_us();
mjr	18:5e890ebd0023	2294	buttonTimer.reset();
mjr	66:2e3583fbd2f4	2295
mjr	66:2e3583fbd2f4	2296	// check the shift button state
mjr	66:2e3583fbd2f4	2297	if (shiftButton.index != -1)
mjr	66:2e3583fbd2f4	2298	{
mjr	66:2e3583fbd2f4	2299	ButtonState *sbs = &buttonState[shiftButton.index];
mjr	66:2e3583fbd2f4	2300	switch (shiftButton.state)
mjr	66:2e3583fbd2f4	2301	{
mjr	66:2e3583fbd2f4	2302	case 0:
mjr	66:2e3583fbd2f4	2303	// Not shifted. Check if the button is now down: if so,
mjr	66:2e3583fbd2f4	2304	// switch to state 1 (shift button down, no key pressed yet).
mjr	66:2e3583fbd2f4	2305	if (sbs->physState)
mjr	66:2e3583fbd2f4	2306	shiftButton.state = 1;
mjr	66:2e3583fbd2f4	2307	break;
mjr	66:2e3583fbd2f4	2308
mjr	66:2e3583fbd2f4	2309	case 1:
mjr	66:2e3583fbd2f4	2310	// Shift button down, no key pressed yet. If the button is
mjr	66:2e3583fbd2f4	2311	// now up, it counts as an ordinary button press instead of
mjr	66:2e3583fbd2f4	2312	// a shift button press, since the shift function was never
mjr	66:2e3583fbd2f4	2313	// used. Return to unshifted state and start a timed key
mjr	66:2e3583fbd2f4	2314	// pulse event.
mjr	66:2e3583fbd2f4	2315	if (!sbs->physState)
mjr	66:2e3583fbd2f4	2316	{
mjr	66:2e3583fbd2f4	2317	shiftButton.state = 0;
mjr	66:2e3583fbd2f4	2318	shiftButton.pulse = 1;
mjr	66:2e3583fbd2f4	2319	shiftButton.pulseTime = 50000+dt; // 50 ms left on the key pulse
mjr	66:2e3583fbd2f4	2320	}
mjr	66:2e3583fbd2f4	2321	break;
mjr	66:2e3583fbd2f4	2322
mjr	66:2e3583fbd2f4	2323	case 2:
mjr	66:2e3583fbd2f4	2324	// Shift button down, other key was pressed. If the button is
mjr	66:2e3583fbd2f4	2325	// now up, simply clear the shift state without sending a key
mjr	66:2e3583fbd2f4	2326	// press for the shift button itself to the PC. The shift
mjr	66:2e3583fbd2f4	2327	// function was used, so its ordinary key press function is
mjr	66:2e3583fbd2f4	2328	// suppressed.
mjr	66:2e3583fbd2f4	2329	if (!sbs->physState)
mjr	66:2e3583fbd2f4	2330	shiftButton.state = 0;
mjr	66:2e3583fbd2f4	2331	break;
mjr	66:2e3583fbd2f4	2332	}
mjr	66:2e3583fbd2f4	2333	}
mjr	38:091e511ce8a0	2334
mjr	11:bd9da7088e6e	2335	// scan the button list
mjr	18:5e890ebd0023	2336	ButtonState *bs = buttonState;
mjr	65:739875521aae	2337	for (int i = 0 ; i < nButtons ; ++i, ++bs)
mjr	11:bd9da7088e6e	2338	{
mjr	66:2e3583fbd2f4	2339	// Check the button type:
mjr	66:2e3583fbd2f4	2340	// - shift button
mjr	66:2e3583fbd2f4	2341	// - pulsed button
mjr	66:2e3583fbd2f4	2342	// - regular button
mjr	66:2e3583fbd2f4	2343	if (shiftButton.index == i)
mjr	66:2e3583fbd2f4	2344	{
mjr	66:2e3583fbd2f4	2345	// This is the shift button. Its logical state for key
mjr	66:2e3583fbd2f4	2346	// reporting purposes is controlled by the shift buttton
mjr	66:2e3583fbd2f4	2347	// pulse timer. If we're in a pulse, its logical state
mjr	66:2e3583fbd2f4	2348	// is pressed.
mjr	66:2e3583fbd2f4	2349	if (shiftButton.pulse)
mjr	66:2e3583fbd2f4	2350	{
mjr	66:2e3583fbd2f4	2351	// deduct the current interval from the pulse time, ending
mjr	66:2e3583fbd2f4	2352	// the pulse if the time has expired
mjr	66:2e3583fbd2f4	2353	if (shiftButton.pulseTime > dt)
mjr	66:2e3583fbd2f4	2354	shiftButton.pulseTime -= dt;
mjr	66:2e3583fbd2f4	2355	else
mjr	66:2e3583fbd2f4	2356	shiftButton.pulse = 0;
mjr	66:2e3583fbd2f4	2357	}
mjr	66:2e3583fbd2f4	2358
mjr	66:2e3583fbd2f4	2359	// the button is logically pressed if we're in a pulse
mjr	66:2e3583fbd2f4	2360	bs->logState = shiftButton.pulse;
mjr	66:2e3583fbd2f4	2361	}
mjr	66:2e3583fbd2f4	2362	else if (bs->pulseState != 0)
mjr	18:5e890ebd0023	2363	{
mjr	38:091e511ce8a0	2364	// if the timer has expired, check for state changes
mjr	53:9b2611964afc	2365	if (bs->pulseTime > dt)
mjr	18:5e890ebd0023	2366	{
mjr	53:9b2611964afc	2367	// not expired yet - deduct the last interval
mjr	53:9b2611964afc	2368	bs->pulseTime -= dt;
mjr	53:9b2611964afc	2369	}
mjr	53:9b2611964afc	2370	else
mjr	53:9b2611964afc	2371	{
mjr	53:9b2611964afc	2372	// pulse time expired - check for a state change
mjr	53:9b2611964afc	2373	const uint32_t pulseLength = 200000UL; // 200 milliseconds
mjr	38:091e511ce8a0	2374	switch (bs->pulseState)
mjr	18:5e890ebd0023	2375	{
mjr	38:091e511ce8a0	2376	case 1:
mjr	38:091e511ce8a0	2377	// off - if the physical switch is now on, start a button pulse
mjr	53:9b2611964afc	2378	if (bs->physState)
mjr	53:9b2611964afc	2379	{
mjr	38:091e511ce8a0	2380	bs->pulseTime = pulseLength;
mjr	38:091e511ce8a0	2381	bs->pulseState = 2;
mjr	53:9b2611964afc	2382	bs->logState = 1;
mjr	38:091e511ce8a0	2383	}
mjr	38:091e511ce8a0	2384	break;
mjr	18:5e890ebd0023	2385
mjr	38:091e511ce8a0	2386	case 2:
mjr	38:091e511ce8a0	2387	// transitioning off to on - end the pulse, and start a gap
mjr	38:091e511ce8a0	2388	// equal to the pulse time so that the host can observe the
mjr	38:091e511ce8a0	2389	// change in state in the logical button
mjr	38:091e511ce8a0	2390	bs->pulseState = 3;
mjr	38:091e511ce8a0	2391	bs->pulseTime = pulseLength;
mjr	53:9b2611964afc	2392	bs->logState = 0;
mjr	38:091e511ce8a0	2393	break;
mjr	38:091e511ce8a0	2394
mjr	38:091e511ce8a0	2395	case 3:
mjr	38:091e511ce8a0	2396	// on - if the physical switch is now off, start a button pulse
mjr	53:9b2611964afc	2397	if (!bs->physState)
mjr	53:9b2611964afc	2398	{
mjr	38:091e511ce8a0	2399	bs->pulseTime = pulseLength;
mjr	38:091e511ce8a0	2400	bs->pulseState = 4;
mjr	53:9b2611964afc	2401	bs->logState = 1;
mjr	38:091e511ce8a0	2402	}
mjr	38:091e511ce8a0	2403	break;
mjr	38:091e511ce8a0	2404
mjr	38:091e511ce8a0	2405	case 4:
mjr	38:091e511ce8a0	2406	// transitioning on to off - end the pulse, and start a gap
mjr	38:091e511ce8a0	2407	bs->pulseState = 1;
mjr	38:091e511ce8a0	2408	bs->pulseTime = pulseLength;
mjr	53:9b2611964afc	2409	bs->logState = 0;
mjr	38:091e511ce8a0	2410	break;
mjr	18:5e890ebd0023	2411	}
mjr	18:5e890ebd0023	2412	}
mjr	38:091e511ce8a0	2413	}
mjr	38:091e511ce8a0	2414	else
mjr	38:091e511ce8a0	2415	{
mjr	38:091e511ce8a0	2416	// not a pulse switch - the logical state is the same as the physical state
mjr	53:9b2611964afc	2417	bs->logState = bs->physState;
mjr	38:091e511ce8a0	2418	}
mjr	35:e959ffba78fd	2419
mjr	38:091e511ce8a0	2420	// carry out any edge effects from buttons changing states
mjr	53:9b2611964afc	2421	if (bs->logState != bs->prevLogState)
mjr	38:091e511ce8a0	2422	{
mjr	38:091e511ce8a0	2423	// check for special key transitions
mjr	53:9b2611964afc	2424	if (cfg.nightMode.btn == i + 1)
mjr	35:e959ffba78fd	2425	{
mjr	53:9b2611964afc	2426	// Check the switch type in the config flags. If flag 0x01 is set,
mjr	53:9b2611964afc	2427	// it's a persistent on/off switch, so the night mode state simply
mjr	53:9b2611964afc	2428	// follows the current state of the switch. Otherwise, it's a
mjr	53:9b2611964afc	2429	// momentary button, so each button push (i.e., each transition from
mjr	53:9b2611964afc	2430	// logical state OFF to ON) toggles the current night mode state.
mjr	53:9b2611964afc	2431	if (cfg.nightMode.flags & 0x01)
mjr	53:9b2611964afc	2432	{
mjr	69:cc5039284fac	2433	// on/off switch - when the button changes state, change
mjr	53:9b2611964afc	2434	// night mode to match the new state
mjr	53:9b2611964afc	2435	setNightMode(bs->logState);
mjr	53:9b2611964afc	2436	}
mjr	53:9b2611964afc	2437	else
mjr	53:9b2611964afc	2438	{
mjr	66:2e3583fbd2f4	2439	// Momentary switch - toggle the night mode state when the
mjr	53:9b2611964afc	2440	// physical button is pushed (i.e., when its logical state
mjr	66:2e3583fbd2f4	2441	// transitions from OFF to ON).
mjr	66:2e3583fbd2f4	2442	//
mjr	66:2e3583fbd2f4	2443	// In momentary mode, night mode flag 0x02 makes it the
mjr	66:2e3583fbd2f4	2444	// shifted version of the button. In this case, only
mjr	66:2e3583fbd2f4	2445	// proceed if the shift button is pressed.
mjr	66:2e3583fbd2f4	2446	bool pressed = bs->logState;
mjr	66:2e3583fbd2f4	2447	if ((cfg.nightMode.flags & 0x02) != 0)
mjr	66:2e3583fbd2f4	2448	{
mjr	66:2e3583fbd2f4	2449	// if the shift button is pressed but hasn't been used
mjr	66:2e3583fbd2f4	2450	// as a shift yet, mark it as used, so that it doesn't
mjr	66:2e3583fbd2f4	2451	// also generate its own key code on release
mjr	66:2e3583fbd2f4	2452	if (shiftButton.state == 1)
mjr	66:2e3583fbd2f4	2453	shiftButton.state = 2;
mjr	66:2e3583fbd2f4	2454
mjr	66:2e3583fbd2f4	2455	// if the shift button isn't even pressed
mjr	66:2e3583fbd2f4	2456	if (shiftButton.state == 0)
mjr	66:2e3583fbd2f4	2457	pressed = false;
mjr	66:2e3583fbd2f4	2458	}
mjr	66:2e3583fbd2f4	2459
mjr	66:2e3583fbd2f4	2460	// if it's pressed (even after considering the shift mode),
mjr	66:2e3583fbd2f4	2461	// toggle night mode
mjr	66:2e3583fbd2f4	2462	if (pressed)
mjr	53:9b2611964afc	2463	toggleNightMode();
mjr	53:9b2611964afc	2464	}
mjr	35:e959ffba78fd	2465	}
mjr	38:091e511ce8a0	2466
mjr	38:091e511ce8a0	2467	// remember the new state for comparison on the next run
mjr	53:9b2611964afc	2468	bs->prevLogState = bs->logState;
mjr	38:091e511ce8a0	2469	}
mjr	38:091e511ce8a0	2470
mjr	53:9b2611964afc	2471	// if it's pressed, physically or virtually, add it to the appropriate
mjr	53:9b2611964afc	2472	// key state list
mjr	53:9b2611964afc	2473	if (bs->logState \|\| bs->virtState)
mjr	38:091e511ce8a0	2474	{
mjr	70:9f58735a1732	2475	// Get the key type and code. Start by assuming that we're
mjr	70:9f58735a1732	2476	// going to use the normal unshifted meaning.
mjr	65:739875521aae	2477	ButtonCfg *bc = &cfg.button[bs->cfgIndex];
mjr	70:9f58735a1732	2478	uint8_t typ = bc->typ;
mjr	70:9f58735a1732	2479	uint8_t val = bc->val;
mjr	70:9f58735a1732	2480
mjr	70:9f58735a1732	2481	// If the shift button is down, check for a shifted meaning.
mjr	70:9f58735a1732	2482	if (shiftButton.state)
mjr	66:2e3583fbd2f4	2483	{
mjr	70:9f58735a1732	2484	// assume there's no shifted meaning
mjr	70:9f58735a1732	2485	bool useShift = false;
mjr	66:2e3583fbd2f4	2486
mjr	70:9f58735a1732	2487	// If the button has a shifted meaning, use that. The
mjr	70:9f58735a1732	2488	// meaning might be a keyboard key or joystick button,
mjr	70:9f58735a1732	2489	// but it could also be as the Night Mode toggle.
mjr	70:9f58735a1732	2490	//
mjr	70:9f58735a1732	2491	// The condition to check if it's the Night Mode toggle
mjr	70:9f58735a1732	2492	// is a little complicated. First, the easy part: our
mjr	70:9f58735a1732	2493	// button index has to match the Night Mode button index.
mjr	70:9f58735a1732	2494	// Now the hard part: the Night Mode button flags have
mjr	70:9f58735a1732	2495	// to be set to 0x01 OFF and 0x02 ON: toggle mode (not
mjr	70:9f58735a1732	2496	// switch mode, 0x01), and shift mode, 0x02. So AND the
mjr	70:9f58735a1732	2497	// flags with 0x03 to get these two bits, and check that
mjr	70:9f58735a1732	2498	// the result is 0x02, meaning that only shift mode is on.
mjr	70:9f58735a1732	2499	if (bc->typ2 != BtnTypeNone)
mjr	70:9f58735a1732	2500	{
mjr	70:9f58735a1732	2501	// there's a shifted key assignment - use it
mjr	70:9f58735a1732	2502	typ = bc->typ2;
mjr	70:9f58735a1732	2503	val = bc->val2;
mjr	70:9f58735a1732	2504	useShift = true;
mjr	70:9f58735a1732	2505	}
mjr	70:9f58735a1732	2506	else if (cfg.nightMode.btn == i+1
mjr	70:9f58735a1732	2507	&& (cfg.nightMode.flags & 0x03) == 0x02)
mjr	70:9f58735a1732	2508	{
mjr	70:9f58735a1732	2509	// shift+button = night mode toggle
mjr	70:9f58735a1732	2510	typ = BtnTypeNone;
mjr	70:9f58735a1732	2511	val = 0;
mjr	70:9f58735a1732	2512	useShift = true;
mjr	70:9f58735a1732	2513	}
mjr	70:9f58735a1732	2514
mjr	70:9f58735a1732	2515	// If there's a shifted meaning, advance the shift
mjr	70:9f58735a1732	2516	// button state from 1 to 2 if applicable. This signals
mjr	70:9f58735a1732	2517	// that we've "consumed" the shift button press as the
mjr	70:9f58735a1732	2518	// shift button, so it shouldn't generate its own key
mjr	70:9f58735a1732	2519	// code event when released.
mjr	70:9f58735a1732	2520	if (useShift && shiftButton.state == 1)
mjr	66:2e3583fbd2f4	2521	shiftButton.state = 2;
mjr	66:2e3583fbd2f4	2522	}
mjr	66:2e3583fbd2f4	2523
mjr	70:9f58735a1732	2524	// We've decided on the meaning of the button, so process
mjr	70:9f58735a1732	2525	// the keyboard or joystick event.
mjr	66:2e3583fbd2f4	2526	switch (typ)
mjr	53:9b2611964afc	2527	{
mjr	53:9b2611964afc	2528	case BtnTypeJoystick:
mjr	53:9b2611964afc	2529	// joystick button
mjr	53:9b2611964afc	2530	newjs \|= (1 << (val - 1));
mjr	53:9b2611964afc	2531	break;
mjr	53:9b2611964afc	2532
mjr	53:9b2611964afc	2533	case BtnTypeKey:
mjr	67:c39e66c4e000	2534	// Keyboard key. The USB keyboard report encodes regular
mjr	67:c39e66c4e000	2535	// keys and modifier keys separately, so we need to check
mjr	67:c39e66c4e000	2536	// which type we have. Note that past versions mapped the
mjr	67:c39e66c4e000	2537	// Keyboard Volume Up, Keyboard Volume Down, and Keyboard
mjr	67:c39e66c4e000	2538	// Mute keys to the corresponding Media keys. We no longer
mjr	67:c39e66c4e000	2539	// do this; instead, we have the separate BtnTypeMedia for
mjr	67:c39e66c4e000	2540	// explicitly using media keys if desired.
mjr	67:c39e66c4e000	2541	if (val >= 0xE0 && val <= 0xE7)
mjr	53:9b2611964afc	2542	{
mjr	67:c39e66c4e000	2543	// It's a modifier key. These are represented in the USB
mjr	67:c39e66c4e000	2544	// reports with a bit mask. We arrange the mask bits in
mjr	67:c39e66c4e000	2545	// the same order as the scan codes, so we can figure the
mjr	67:c39e66c4e000	2546	// appropriate bit with a simple shift.
mjr	53:9b2611964afc	2547	modkeys \|= (1 << (val - 0xE0));
mjr	53:9b2611964afc	2548	}
mjr	53:9b2611964afc	2549	else
mjr	53:9b2611964afc	2550	{
mjr	67:c39e66c4e000	2551	// It's a regular key. Make sure it's not already in the
mjr	67:c39e66c4e000	2552	// list, and that the list isn't full. If neither of these
mjr	67:c39e66c4e000	2553	// apply, add the key to the key array.
mjr	53:9b2611964afc	2554	if (nkeys < 7)
mjr	53:9b2611964afc	2555	{
mjr	57:cc03231f676b	2556	bool found = false;
mjr	53:9b2611964afc	2557	for (int j = 0 ; j < nkeys ; ++j)
mjr	53:9b2611964afc	2558	{
mjr	53:9b2611964afc	2559	if (keys[j] == val)
mjr	53:9b2611964afc	2560	{
mjr	53:9b2611964afc	2561	found = true;
mjr	53:9b2611964afc	2562	break;
mjr	53:9b2611964afc	2563	}
mjr	53:9b2611964afc	2564	}
mjr	53:9b2611964afc	2565	if (!found)
mjr	53:9b2611964afc	2566	keys[nkeys++] = val;
mjr	53:9b2611964afc	2567	}
mjr	53:9b2611964afc	2568	}
mjr	53:9b2611964afc	2569	break;
mjr	67:c39e66c4e000	2570
mjr	67:c39e66c4e000	2571	case BtnTypeMedia:
mjr	67:c39e66c4e000	2572	// Media control key. The media keys are mapped in the USB
mjr	67:c39e66c4e000	2573	// report to bits, whereas the key codes are specified in the
mjr	67:c39e66c4e000	2574	// config with their USB usage numbers. E.g., the config val
mjr	67:c39e66c4e000	2575	// for Media Next Track is 0xB5, but we encode this in the USB
mjr	67:c39e66c4e000	2576	// report as bit 0x08. The mediaKeyMap[] table translates
mjr	67:c39e66c4e000	2577	// from the USB usage number to the mask bit. If the key isn't
mjr	67:c39e66c4e000	2578	// among the subset we support, the mapped bit will be zero, so
mjr	67:c39e66c4e000	2579	// the "\|=" will have no effect and the key will be ignored.
mjr	67:c39e66c4e000	2580	mediakeys \|= mediaKeyMap[val];
mjr	67:c39e66c4e000	2581	break;
mjr	53:9b2611964afc	2582	}
mjr	18:5e890ebd0023	2583	}
mjr	11:bd9da7088e6e	2584	}
mjr	36:b9747461331e	2585
mjr	36:b9747461331e	2586	// check for joystick button changes
mjr	36:b9747461331e	2587	if (jsButtons != newjs)
mjr	36:b9747461331e	2588	jsButtons = newjs;
mjr	11:bd9da7088e6e	2589
mjr	35:e959ffba78fd	2590	// Check for changes to the keyboard keys
mjr	35:e959ffba78fd	2591	if (kbState.data[0] != modkeys
mjr	35:e959ffba78fd	2592	\|\| kbState.nkeys != nkeys
mjr	35:e959ffba78fd	2593	\|\| memcmp(keys, &kbState.data[2], 6) != 0)
mjr	35:e959ffba78fd	2594	{
mjr	35:e959ffba78fd	2595	// we have changes - set the change flag and store the new key data
mjr	35:e959ffba78fd	2596	kbState.changed = true;
mjr	35:e959ffba78fd	2597	kbState.data[0] = modkeys;
mjr	35:e959ffba78fd	2598	if (nkeys <= 6) {
mjr	35:e959ffba78fd	2599	// 6 or fewer simultaneous keys - report the key codes
mjr	35:e959ffba78fd	2600	kbState.nkeys = nkeys;
mjr	35:e959ffba78fd	2601	memcpy(&kbState.data[2], keys, 6);
mjr	35:e959ffba78fd	2602	}
mjr	35:e959ffba78fd	2603	else {
mjr	35:e959ffba78fd	2604	// more than 6 simultaneous keys - report rollover (all '1' key codes)
mjr	35:e959ffba78fd	2605	kbState.nkeys = 6;
mjr	35:e959ffba78fd	2606	memset(&kbState.data[2], 1, 6);
mjr	35:e959ffba78fd	2607	}
mjr	35:e959ffba78fd	2608	}
mjr	35:e959ffba78fd	2609
mjr	35:e959ffba78fd	2610	// Check for changes to media keys
mjr	35:e959ffba78fd	2611	if (mediaState.data != mediakeys)
mjr	35:e959ffba78fd	2612	{
mjr	35:e959ffba78fd	2613	mediaState.changed = true;
mjr	35:e959ffba78fd	2614	mediaState.data = mediakeys;
mjr	35:e959ffba78fd	2615	}
mjr	11:bd9da7088e6e	2616	}
mjr	11:bd9da7088e6e	2617
mjr	73:4e8ce0b18915	2618	// Send a button status report
mjr	73:4e8ce0b18915	2619	void reportButtonStatus(USBJoystick &js)
mjr	73:4e8ce0b18915	2620	{
mjr	73:4e8ce0b18915	2621	// start with all buttons off
mjr	73:4e8ce0b18915	2622	uint8_t state[(MAX_BUTTONS+7)/8];
mjr	73:4e8ce0b18915	2623	memset(state, 0, sizeof(state));
mjr	73:4e8ce0b18915	2624
mjr	73:4e8ce0b18915	2625	// pack the button states into bytes, one bit per button
mjr	73:4e8ce0b18915	2626	ButtonState *bs = buttonState;
mjr	73:4e8ce0b18915	2627	for (int i = 0 ; i < nButtons ; ++i, ++bs)
mjr	73:4e8ce0b18915	2628	{
mjr	73:4e8ce0b18915	2629	// get the physical state
mjr	73:4e8ce0b18915	2630	int b = bs->physState;
mjr	73:4e8ce0b18915	2631
mjr	73:4e8ce0b18915	2632	// pack it into the appropriate bit
mjr	73:4e8ce0b18915	2633	int idx = bs->cfgIndex;
mjr	73:4e8ce0b18915	2634	int si = idx / 8;
mjr	73:4e8ce0b18915	2635	int shift = idx & 0x07;
mjr	73:4e8ce0b18915	2636	state[si] \|= b << shift;
mjr	73:4e8ce0b18915	2637	}
mjr	73:4e8ce0b18915	2638
mjr	73:4e8ce0b18915	2639	// send the report
mjr	73:4e8ce0b18915	2640	js.reportButtonStatus(MAX_BUTTONS, state);
mjr	73:4e8ce0b18915	2641	}
mjr	73:4e8ce0b18915	2642
mjr	5:a70c0bce770d	2643	// ---------------------------------------------------------------------------
mjr	5:a70c0bce770d	2644	//
mjr	5:a70c0bce770d	2645	// Customization joystick subbclass
mjr	5:a70c0bce770d	2646	//
mjr	5:a70c0bce770d	2647
mjr	5:a70c0bce770d	2648	class MyUSBJoystick: public USBJoystick
mjr	5:a70c0bce770d	2649	{
mjr	5:a70c0bce770d	2650	public:
mjr	35:e959ffba78fd	2651	MyUSBJoystick(uint16_t vendor_id, uint16_t product_id, uint16_t product_release,
mjr	35:e959ffba78fd	2652	bool waitForConnect, bool enableJoystick, bool useKB)
mjr	35:e959ffba78fd	2653	: USBJoystick(vendor_id, product_id, product_release, waitForConnect, enableJoystick, useKB)
mjr	5:a70c0bce770d	2654	{
mjr	54:fd77a6b2f76c	2655	sleeping_ = false;
mjr	54:fd77a6b2f76c	2656	reconnectPending_ = false;
mjr	54:fd77a6b2f76c	2657	timer_.start();
mjr	54:fd77a6b2f76c	2658	}
mjr	54:fd77a6b2f76c	2659
mjr	54:fd77a6b2f76c	2660	// show diagnostic LED feedback for connect state
mjr	54:fd77a6b2f76c	2661	void diagFlash()
mjr	54:fd77a6b2f76c	2662	{
mjr	54:fd77a6b2f76c	2663	if (!configured() \|\| sleeping_)
mjr	54:fd77a6b2f76c	2664	{
mjr	54:fd77a6b2f76c	2665	// flash once if sleeping or twice if disconnected
mjr	54:fd77a6b2f76c	2666	for (int j = isConnected() ? 1 : 2 ; j > 0 ; --j)
mjr	54:fd77a6b2f76c	2667	{
mjr	54:fd77a6b2f76c	2668	// short red flash
mjr	54:fd77a6b2f76c	2669	diagLED(1, 0, 0);
mjr	54:fd77a6b2f76c	2670	wait_us(50000);
mjr	54:fd77a6b2f76c	2671	diagLED(0, 0, 0);
mjr	54:fd77a6b2f76c	2672	wait_us(50000);
mjr	54:fd77a6b2f76c	2673	}
mjr	54:fd77a6b2f76c	2674	}
mjr	5:a70c0bce770d	2675	}
mjr	5:a70c0bce770d	2676
mjr	5:a70c0bce770d	2677	// are we connected?
mjr	5:a70c0bce770d	2678	int isConnected() { return configured(); }
mjr	5:a70c0bce770d	2679
mjr	54:fd77a6b2f76c	2680	// Are we in sleep mode? If true, this means that the hardware has
mjr	54:fd77a6b2f76c	2681	// detected no activity on the bus for 3ms. This happens when the
mjr	54:fd77a6b2f76c	2682	// cable is physically disconnected, the computer is turned off, or
mjr	54:fd77a6b2f76c	2683	// the connection is otherwise disabled.
mjr	54:fd77a6b2f76c	2684	bool isSleeping() const { return sleeping_; }
mjr	54:fd77a6b2f76c	2685
mjr	54:fd77a6b2f76c	2686	// If necessary, attempt to recover from a broken connection.
mjr	54:fd77a6b2f76c	2687	//
mjr	54:fd77a6b2f76c	2688	// This is a hack, to work around an apparent timing bug in the
mjr	54:fd77a6b2f76c	2689	// KL25Z USB implementation that I haven't been able to solve any
mjr	54:fd77a6b2f76c	2690	// other way.
mjr	54:fd77a6b2f76c	2691	//
mjr	54:fd77a6b2f76c	2692	// The issue: when we have an established connection, and the
mjr	54:fd77a6b2f76c	2693	// connection is broken by physically unplugging the cable or by
mjr	54:fd77a6b2f76c	2694	// rebooting the PC, the KL25Z sometimes fails to reconnect when
mjr	54:fd77a6b2f76c	2695	// the physical connection is re-established. The failure is
mjr	54:fd77a6b2f76c	2696	// sporadic; I'd guess it happens about 25% of the time, but I
mjr	54:fd77a6b2f76c	2697	// haven't collected any real statistics on it.
mjr	54:fd77a6b2f76c	2698	//
mjr	54:fd77a6b2f76c	2699	// The proximate cause of the failure is a deadlock in the SETUP
mjr	54:fd77a6b2f76c	2700	// protocol between the host and device that happens around the
mjr	54:fd77a6b2f76c	2701	// point where the PC is requesting the configuration descriptor.
mjr	54:fd77a6b2f76c	2702	// The exact point in the protocol where this occurs varies slightly;
mjr	54:fd77a6b2f76c	2703	// it can occur a message or two before or after the Get Config
mjr	54:fd77a6b2f76c	2704	// Descriptor packet. No matter where it happens, the nature of
mjr	54:fd77a6b2f76c	2705	// the deadlock is the same: the PC thinks it sees a STALL on EP0
mjr	54:fd77a6b2f76c	2706	// from the device, so it terminates the connection attempt, which
mjr	54:fd77a6b2f76c	2707	// stops further traffic on the cable. The KL25Z USB hardware sees
mjr	54:fd77a6b2f76c	2708	// the lack of traffic and triggers a SLEEP interrupt (a misnomer
mjr	54:fd77a6b2f76c	2709	// for what should have been called a BROKEN CONNECTION interrupt).
mjr	54:fd77a6b2f76c	2710	// Both sides simply stop talking at this point, so the connection
mjr	54:fd77a6b2f76c	2711	// is effectively dead.
mjr	54:fd77a6b2f76c	2712	//
mjr	54:fd77a6b2f76c	2713	// The strange thing is that, as far as I can tell, the KL25Z isn't
mjr	54:fd77a6b2f76c	2714	// doing anything to trigger the STALL on its end. Both the PC
mjr	54:fd77a6b2f76c	2715	// and the KL25Z are happy up until the very point of the failure
mjr	54:fd77a6b2f76c	2716	// and show no signs of anything wrong in the protocol exchange.
mjr	54:fd77a6b2f76c	2717	// In fact, every detail of the protocol exchange up to this point
mjr	54:fd77a6b2f76c	2718	// is identical to every successful exchange that does finish the
mjr	54:fd77a6b2f76c	2719	// whole setup process successfully, on both the KL25Z and Windows
mjr	54:fd77a6b2f76c	2720	// sides of the connection. I can't find any point of difference
mjr	54:fd77a6b2f76c	2721	// between successful and unsuccessful sequences that suggests why
mjr	54:fd77a6b2f76c	2722	// the fateful message fails. This makes me suspect that whatever
mjr	54:fd77a6b2f76c	2723	// is going wrong is inside the KL25Z USB hardware module, which
mjr	54:fd77a6b2f76c	2724	// is a pretty substantial black box - it has a lot of internal
mjr	54:fd77a6b2f76c	2725	// state that's inaccessible to the software. Further bolstering
mjr	54:fd77a6b2f76c	2726	// this theory is a little experiment where I found that I could
mjr	54:fd77a6b2f76c	2727	// reproduce the exact sequence of events of a failed reconnect
mjr	54:fd77a6b2f76c	2728	// attempt in an initial connection, which is otherwise 100%
mjr	54:fd77a6b2f76c	2729	// reliable, by inserting a little bit of artifical time padding
mjr	54:fd77a6b2f76c	2730	// (200us per event) into the SETUP interrupt handler. My
mjr	54:fd77a6b2f76c	2731	// hypothesis is that the STALL event happens because the KL25Z
mjr	54:fd77a6b2f76c	2732	// USB hardware is too slow to respond to a message. I'm not
mjr	54:fd77a6b2f76c	2733	// sure why this would only happen after a disconnect and not
mjr	54:fd77a6b2f76c	2734	// during the initial connection; maybe there's some reset work
mjr	54:fd77a6b2f76c	2735	// in the hardware that takes a substantial amount of time after
mjr	54:fd77a6b2f76c	2736	// a disconnect.
mjr	54:fd77a6b2f76c	2737	//
mjr	54:fd77a6b2f76c	2738	// The solution: the problem happens during the SETUP exchange,
mjr	54:fd77a6b2f76c	2739	// after we've been assigned a bus address. It only happens on
mjr	54:fd77a6b2f76c	2740	// some percentage of connection requests, so if we can simply
mjr	54:fd77a6b2f76c	2741	// start over when the failure occurs, we'll eventually succeed
mjr	54:fd77a6b2f76c	2742	// simply because not every attempt fails. The ideal would be
mjr	54:fd77a6b2f76c	2743	// to get the success rate up to 100%, but I can't figure out how
mjr	54:fd77a6b2f76c	2744	// to fix the underlying problem, so this is the next best thing.
mjr	54:fd77a6b2f76c	2745	//
mjr	54:fd77a6b2f76c	2746	// We can detect when the failure occurs by noticing when a SLEEP
mjr	54:fd77a6b2f76c	2747	// interrupt happens while we have an assigned bus address.
mjr	54:fd77a6b2f76c	2748	//
mjr	54:fd77a6b2f76c	2749	// To start a new connection attempt, we have to make the host
mjr	54:fd77a6b2f76c	2750	// try again. The logical connection is initiated solely by the
mjr	54:fd77a6b2f76c	2751	// host. Fortunately, it's easy to get the host to initiate the
mjr	54:fd77a6b2f76c	2752	// process: if we disconnect on the device side, it effectively
mjr	54:fd77a6b2f76c	2753	// makes the device look to the PC like it's electrically unplugged.
mjr	54:fd77a6b2f76c	2754	// When we reconnect on the device side, the PC thinks a new device
mjr	54:fd77a6b2f76c	2755	// has been plugged in and initiates the logical connection setup.
mjr	74:822a92bc11d2	2756	// We have to remain disconnected for some minimum interval before
mjr	74:822a92bc11d2	2757	// the host notices; the exact minimum is unclear, but 5ms seems
mjr	74:822a92bc11d2	2758	// reliable in practice.
mjr	54:fd77a6b2f76c	2759	//
mjr	54:fd77a6b2f76c	2760	// Here's the full algorithm:
mjr	54:fd77a6b2f76c	2761	//
mjr	54:fd77a6b2f76c	2762	// 1. In the SLEEP interrupt handler, if we have a bus address,
mjr	54:fd77a6b2f76c	2763	// we disconnect the device. This happens in ISR context, so we
mjr	54:fd77a6b2f76c	2764	// can't wait around for 5ms. Instead, we simply set a flag noting
mjr	54:fd77a6b2f76c	2765	// that the connection has been broken, and we note the time and
mjr	54:fd77a6b2f76c	2766	// return.
mjr	54:fd77a6b2f76c	2767	//
mjr	54:fd77a6b2f76c	2768	// 2. In our main loop, whenever we find that we're disconnected,
mjr	54:fd77a6b2f76c	2769	// we call recoverConnection(). The main loop's job is basically a
mjr	54:fd77a6b2f76c	2770	// bunch of device polling. We're just one more device to poll, so
mjr	54:fd77a6b2f76c	2771	// recoverConnection() will be called soon after a disconnect, and
mjr	54:fd77a6b2f76c	2772	// then will be called in a loop for as long as we're disconnected.
mjr	54:fd77a6b2f76c	2773	//
mjr	54:fd77a6b2f76c	2774	// 3. In recoverConnection(), we check the flag we set in the SLEEP
mjr	54:fd77a6b2f76c	2775	// handler. If set, we wait until 5ms has elapsed from the SLEEP
mjr	54:fd77a6b2f76c	2776	// event time that we noted, then we'll reconnect and clear the flag.
mjr	54:fd77a6b2f76c	2777	// This gives us the required 5ms (or longer) delay between the
mjr	54:fd77a6b2f76c	2778	// disconnect and reconnect, ensuring that the PC will notice and
mjr	54:fd77a6b2f76c	2779	// will start over with the connection protocol.
mjr	54:fd77a6b2f76c	2780	//
mjr	54:fd77a6b2f76c	2781	// 4. The main loop keeps calling recoverConnection() in a loop for
mjr	54:fd77a6b2f76c	2782	// as long as we're disconnected, so if the new connection attempt
mjr	54:fd77a6b2f76c	2783	// triggered in step 3 fails, the SLEEP interrupt will happen again,
mjr	54:fd77a6b2f76c	2784	// we'll disconnect again, the flag will get set again, and
mjr	54:fd77a6b2f76c	2785	// recoverConnection() will reconnect again after another suitable
mjr	54:fd77a6b2f76c	2786	// delay. This will repeat until the connection succeeds or hell
mjr	54:fd77a6b2f76c	2787	// freezes over.
mjr	54:fd77a6b2f76c	2788	//
mjr	54:fd77a6b2f76c	2789	// Each disconnect happens immediately when a reconnect attempt
mjr	54:fd77a6b2f76c	2790	// fails, and an entire successful connection only takes about 25ms,
mjr	54:fd77a6b2f76c	2791	// so our loop can retry at more than 30 attempts per second.
mjr	54:fd77a6b2f76c	2792	// In my testing, lost connections almost always reconnect in
mjr	54:fd77a6b2f76c	2793	// less than second with this code in place.
mjr	54:fd77a6b2f76c	2794	void recoverConnection()
mjr	54:fd77a6b2f76c	2795	{
mjr	54:fd77a6b2f76c	2796	// if a reconnect is pending, reconnect
mjr	54:fd77a6b2f76c	2797	if (reconnectPending_)
mjr	54:fd77a6b2f76c	2798	{
mjr	54:fd77a6b2f76c	2799	// Loop until we reach 5ms after the last sleep event.
mjr	54:fd77a6b2f76c	2800	for (bool done = false ; !done ; )
mjr	54:fd77a6b2f76c	2801	{
mjr	54:fd77a6b2f76c	2802	// If we've reached the target time, reconnect. Do the
mjr	54:fd77a6b2f76c	2803	// time check and flag reset atomically, so that we can't
mjr	54:fd77a6b2f76c	2804	// have another sleep event sneak in after we've verified
mjr	54:fd77a6b2f76c	2805	// the time. If another event occurs, it has to happen
mjr	54:fd77a6b2f76c	2806	// before we check, in which case it'll update the time
mjr	54:fd77a6b2f76c	2807	// before we check it, or after we clear the flag, in
mjr	54:fd77a6b2f76c	2808	// which case it will reset the flag and we'll do another
mjr	54:fd77a6b2f76c	2809	// round the next time we call this routine.
mjr	54:fd77a6b2f76c	2810	__disable_irq();
mjr	54:fd77a6b2f76c	2811	if (uint32_t(timer_.read_us() - lastSleepTime_) > 5000)
mjr	54:fd77a6b2f76c	2812	{
mjr	54:fd77a6b2f76c	2813	connect(false);
mjr	54:fd77a6b2f76c	2814	reconnectPending_ = false;
mjr	54:fd77a6b2f76c	2815	done = true;
mjr	54:fd77a6b2f76c	2816	}
mjr	54:fd77a6b2f76c	2817	__enable_irq();
mjr	54:fd77a6b2f76c	2818	}
mjr	54:fd77a6b2f76c	2819	}
mjr	54:fd77a6b2f76c	2820	}
mjr	5:a70c0bce770d	2821
mjr	5:a70c0bce770d	2822	protected:
mjr	54:fd77a6b2f76c	2823	// Handle a USB SLEEP interrupt. This interrupt signifies that the
mjr	54:fd77a6b2f76c	2824	// USB hardware module hasn't seen any token traffic for 3ms, which
mjr	54:fd77a6b2f76c	2825	// means that we're either physically or logically disconnected.
mjr	54:fd77a6b2f76c	2826	//
mjr	54:fd77a6b2f76c	2827	// Important: this runs in ISR context.
mjr	54:fd77a6b2f76c	2828	//
mjr	54:fd77a6b2f76c	2829	// Note that this is a specialized sense of "sleep" that's unrelated
mjr	54:fd77a6b2f76c	2830	// to the similarly named power modes on the PC. This has nothing
mjr	54:fd77a6b2f76c	2831	// to do with suspend/sleep mode on the PC, and it's not a low-power
mjr	54:fd77a6b2f76c	2832	// mode on the KL25Z. They really should have called this interrupt
mjr	54:fd77a6b2f76c	2833	// DISCONNECT or BROKEN CONNECTION.)
mjr	54:fd77a6b2f76c	2834	virtual void sleepStateChanged(unsigned int sleeping)
mjr	54:fd77a6b2f76c	2835	{
mjr	54:fd77a6b2f76c	2836	// note the new state
mjr	54:fd77a6b2f76c	2837	sleeping_ = sleeping;
mjr	54:fd77a6b2f76c	2838
mjr	54:fd77a6b2f76c	2839	// If we have a non-zero bus address, we have at least a partial
mjr	54:fd77a6b2f76c	2840	// connection to the host (we've made it at least as far as the
mjr	54:fd77a6b2f76c	2841	// SETUP stage). Explicitly disconnect, and the pending reconnect
mjr	54:fd77a6b2f76c	2842	// flag, and remember the time of the sleep event.
mjr	54:fd77a6b2f76c	2843	if (USB0->ADDR != 0x00)
mjr	54:fd77a6b2f76c	2844	{
mjr	54:fd77a6b2f76c	2845	disconnect();
mjr	54:fd77a6b2f76c	2846	lastSleepTime_ = timer_.read_us();
mjr	54:fd77a6b2f76c	2847	reconnectPending_ = true;
mjr	54:fd77a6b2f76c	2848	}
mjr	54:fd77a6b2f76c	2849	}
mjr	54:fd77a6b2f76c	2850
mjr	54:fd77a6b2f76c	2851	// is the USB connection asleep?
mjr	54:fd77a6b2f76c	2852	volatile bool sleeping_;
mjr	54:fd77a6b2f76c	2853
mjr	54:fd77a6b2f76c	2854	// flag: reconnect pending after sleep event
mjr	54:fd77a6b2f76c	2855	volatile bool reconnectPending_;
mjr	54:fd77a6b2f76c	2856
mjr	54:fd77a6b2f76c	2857	// time of last sleep event while connected
mjr	54:fd77a6b2f76c	2858	volatile uint32_t lastSleepTime_;
mjr	54:fd77a6b2f76c	2859
mjr	54:fd77a6b2f76c	2860	// timer to keep track of interval since last sleep event
mjr	54:fd77a6b2f76c	2861	Timer timer_;
mjr	5:a70c0bce770d	2862	};
mjr	5:a70c0bce770d	2863
mjr	5:a70c0bce770d	2864	// ---------------------------------------------------------------------------
mjr	5:a70c0bce770d	2865	//
mjr	5:a70c0bce770d	2866	// Accelerometer (MMA8451Q)
mjr	5:a70c0bce770d	2867	//
mjr	5:a70c0bce770d	2868
mjr	5:a70c0bce770d	2869	// The MMA8451Q is the KL25Z's on-board 3-axis accelerometer.
mjr	5:a70c0bce770d	2870	//
mjr	5:a70c0bce770d	2871	// This is a custom wrapper for the library code to interface to the
mjr	6:cc35eb643e8f	2872	// MMA8451Q. This class encapsulates an interrupt handler and
mjr	6:cc35eb643e8f	2873	// automatic calibration.
mjr	5:a70c0bce770d	2874	//
mjr	5:a70c0bce770d	2875	// We install an interrupt handler on the accelerometer "data ready"
mjr	6:cc35eb643e8f	2876	// interrupt to ensure that we fetch each sample immediately when it
mjr	74:822a92bc11d2	2877	// becomes available. The accelerometer data rate is fairly high
mjr	6:cc35eb643e8f	2878	// (800 Hz), so it's not practical to keep up with it by polling.
mjr	6:cc35eb643e8f	2879	// Using an interrupt handler lets us respond quickly and read
mjr	6:cc35eb643e8f	2880	// every sample.
mjr	5:a70c0bce770d	2881	//
mjr	6:cc35eb643e8f	2882	// We automatically calibrate the accelerometer so that it's not
mjr	6:cc35eb643e8f	2883	// necessary to get it exactly level when installing it, and so
mjr	6:cc35eb643e8f	2884	// that it's also not necessary to calibrate it manually. There's
mjr	6:cc35eb643e8f	2885	// lots of experience that tells us that manual calibration is a
mjr	6:cc35eb643e8f	2886	// terrible solution, mostly because cabinets tend to shift slightly
mjr	6:cc35eb643e8f	2887	// during use, requiring frequent recalibration. Instead, we
mjr	6:cc35eb643e8f	2888	// calibrate automatically. We continuously monitor the acceleration
mjr	6:cc35eb643e8f	2889	// data, watching for periods of constant (or nearly constant) values.
mjr	6:cc35eb643e8f	2890	// Any time it appears that the machine has been at rest for a while
mjr	6:cc35eb643e8f	2891	// (about 5 seconds), we'll average the readings during that rest
mjr	6:cc35eb643e8f	2892	// period and use the result as the level rest position. This is
mjr	6:cc35eb643e8f	2893	// is ongoing, so we'll quickly find the center point again if the
mjr	6:cc35eb643e8f	2894	// machine is moved during play (by an especially aggressive bout
mjr	6:cc35eb643e8f	2895	// of nudging, say).
mjr	5:a70c0bce770d	2896	//
mjr	5:a70c0bce770d	2897
mjr	17:ab3cec0c8bf4	2898	// I2C address of the accelerometer (this is a constant of the KL25Z)
mjr	17:ab3cec0c8bf4	2899	const int MMA8451_I2C_ADDRESS = (0x1d<<1);
mjr	17:ab3cec0c8bf4	2900
mjr	17:ab3cec0c8bf4	2901	// SCL and SDA pins for the accelerometer (constant for the KL25Z)
mjr	17:ab3cec0c8bf4	2902	#define MMA8451_SCL_PIN PTE25
mjr	17:ab3cec0c8bf4	2903	#define MMA8451_SDA_PIN PTE24
mjr	17:ab3cec0c8bf4	2904
mjr	17:ab3cec0c8bf4	2905	// Digital in pin to use for the accelerometer interrupt. For the KL25Z,
mjr	17:ab3cec0c8bf4	2906	// this can be either PTA14 or PTA15, since those are the pins physically
mjr	17:ab3cec0c8bf4	2907	// wired on this board to the MMA8451 interrupt controller.
mjr	17:ab3cec0c8bf4	2908	#define MMA8451_INT_PIN PTA15
mjr	17:ab3cec0c8bf4	2909
mjr	17:ab3cec0c8bf4	2910
mjr	6:cc35eb643e8f	2911	// accelerometer input history item, for gathering calibration data
mjr	6:cc35eb643e8f	2912	struct AccHist
mjr	5:a70c0bce770d	2913	{
mjr	6:cc35eb643e8f	2914	AccHist() { x = y = d = 0.0; xtot = ytot = 0.0; cnt = 0; }
mjr	6:cc35eb643e8f	2915	void set(float x, float y, AccHist *prv)
mjr	6:cc35eb643e8f	2916	{
mjr	6:cc35eb643e8f	2917	// save the raw position
mjr	6:cc35eb643e8f	2918	this->x = x;
mjr	6:cc35eb643e8f	2919	this->y = y;
mjr	6:cc35eb643e8f	2920	this->d = distance(prv);
mjr	6:cc35eb643e8f	2921	}
mjr	6:cc35eb643e8f	2922
mjr	6:cc35eb643e8f	2923	// reading for this entry
mjr	5:a70c0bce770d	2924	float x, y;
mjr	5:a70c0bce770d	2925
mjr	6:cc35eb643e8f	2926	// distance from previous entry
mjr	6:cc35eb643e8f	2927	float d;
mjr	5:a70c0bce770d	2928
mjr	6:cc35eb643e8f	2929	// total and count of samples averaged over this period
mjr	6:cc35eb643e8f	2930	float xtot, ytot;
mjr	6:cc35eb643e8f	2931	int cnt;
mjr	6:cc35eb643e8f	2932
mjr	6:cc35eb643e8f	2933	void clearAvg() { xtot = ytot = 0.0; cnt = 0; }
mjr	6:cc35eb643e8f	2934	void addAvg(float x, float y) { xtot += x; ytot += y; ++cnt; }
mjr	6:cc35eb643e8f	2935	float xAvg() const { return xtot/cnt; }
mjr	6:cc35eb643e8f	2936	float yAvg() const { return ytot/cnt; }
mjr	5:a70c0bce770d	2937
mjr	6:cc35eb643e8f	2938	float distance(AccHist *p)
mjr	6:cc35eb643e8f	2939	{ return sqrt(square(p->x - x) + square(p->y - y)); }
mjr	5:a70c0bce770d	2940	};
mjr	5:a70c0bce770d	2941
mjr	5:a70c0bce770d	2942	// accelerometer wrapper class
mjr	3:3514575d4f86	2943	class Accel
mjr	3:3514575d4f86	2944	{
mjr	3:3514575d4f86	2945	public:
mjr	3:3514575d4f86	2946	Accel(PinName sda, PinName scl, int i2cAddr, PinName irqPin)
mjr	3:3514575d4f86	2947	: mma_(sda, scl, i2cAddr), intIn_(irqPin)
mjr	3:3514575d4f86	2948	{
mjr	5:a70c0bce770d	2949	// remember the interrupt pin assignment
mjr	5:a70c0bce770d	2950	irqPin_ = irqPin;
mjr	5:a70c0bce770d	2951
mjr	5:a70c0bce770d	2952	// reset and initialize
mjr	5:a70c0bce770d	2953	reset();
mjr	5:a70c0bce770d	2954	}
mjr	5:a70c0bce770d	2955
mjr	5:a70c0bce770d	2956	void reset()
mjr	5:a70c0bce770d	2957	{
mjr	6:cc35eb643e8f	2958	// clear the center point
mjr	6:cc35eb643e8f	2959	cx_ = cy_ = 0.0;
mjr	6:cc35eb643e8f	2960
mjr	6:cc35eb643e8f	2961	// start the calibration timer
mjr	5:a70c0bce770d	2962	tCenter_.start();
mjr	5:a70c0bce770d	2963	iAccPrv_ = nAccPrv_ = 0;
mjr	6:cc35eb643e8f	2964
mjr	5:a70c0bce770d	2965	// reset and initialize the MMA8451Q
mjr	5:a70c0bce770d	2966	mma_.init();
mjr	6:cc35eb643e8f	2967
mjr	6:cc35eb643e8f	2968	// set the initial integrated velocity reading to zero
mjr	6:cc35eb643e8f	2969	vx_ = vy_ = 0;
mjr	3:3514575d4f86	2970
mjr	6:cc35eb643e8f	2971	// set up our accelerometer interrupt handling
mjr	6:cc35eb643e8f	2972	intIn_.rise(this, &Accel::isr);
mjr	5:a70c0bce770d	2973	mma_.setInterruptMode(irqPin_ == PTA14 ? 1 : 2);
mjr	3:3514575d4f86	2974
mjr	3:3514575d4f86	2975	// read the current registers to clear the data ready flag
mjr	6:cc35eb643e8f	2976	mma_.getAccXYZ(ax_, ay_, az_);
mjr	3:3514575d4f86	2977
mjr	3:3514575d4f86	2978	// start our timers
mjr	3:3514575d4f86	2979	tGet_.start();
mjr	3:3514575d4f86	2980	tInt_.start();
mjr	3:3514575d4f86	2981	}
mjr	3:3514575d4f86	2982
mjr	9:fd65b0a94720	2983	void get(int &x, int &y)
mjr	3:3514575d4f86	2984	{
mjr	3:3514575d4f86	2985	// disable interrupts while manipulating the shared data
mjr	3:3514575d4f86	2986	__disable_irq();
mjr	3:3514575d4f86	2987
mjr	3:3514575d4f86	2988	// read the shared data and store locally for calculations
mjr	6:cc35eb643e8f	2989	float ax = ax_, ay = ay_;
mjr	6:cc35eb643e8f	2990	float vx = vx_, vy = vy_;
mjr	5:a70c0bce770d	2991
mjr	6:cc35eb643e8f	2992	// reset the velocity sum for the next run
mjr	6:cc35eb643e8f	2993	vx_ = vy_ = 0;
mjr	3:3514575d4f86	2994
mjr	3:3514575d4f86	2995	// get the time since the last get() sample
mjr	73:4e8ce0b18915	2996	int dtus = tGet_.read_us();
mjr	3:3514575d4f86	2997	tGet_.reset();
mjr	3:3514575d4f86	2998
mjr	3:3514575d4f86	2999	// done manipulating the shared data
mjr	3:3514575d4f86	3000	__enable_irq();
mjr	3:3514575d4f86	3001
mjr	6:cc35eb643e8f	3002	// adjust the readings for the integration time
mjr	73:4e8ce0b18915	3003	float dt = dtus/1000000.0f;
mjr	6:cc35eb643e8f	3004	vx /= dt;
mjr	6:cc35eb643e8f	3005	vy /= dt;
mjr	6:cc35eb643e8f	3006
mjr	6:cc35eb643e8f	3007	// add this sample to the current calibration interval's running total
mjr	6:cc35eb643e8f	3008	AccHist *p = accPrv_ + iAccPrv_;
mjr	6:cc35eb643e8f	3009	p->addAvg(ax, ay);
mjr	6:cc35eb643e8f	3010
mjr	5:a70c0bce770d	3011	// check for auto-centering every so often
mjr	48:058ace2aed1d	3012	if (tCenter_.read_us() > 1000000)
mjr	5:a70c0bce770d	3013	{
mjr	5:a70c0bce770d	3014	// add the latest raw sample to the history list
mjr	6:cc35eb643e8f	3015	AccHist *prv = p;
mjr	5:a70c0bce770d	3016	iAccPrv_ = (iAccPrv_ + 1) % maxAccPrv;
mjr	6:cc35eb643e8f	3017	p = accPrv_ + iAccPrv_;
mjr	6:cc35eb643e8f	3018	p->set(ax, ay, prv);
mjr	5:a70c0bce770d	3019
mjr	5:a70c0bce770d	3020	// if we have a full complement, check for stability
mjr	5:a70c0bce770d	3021	if (nAccPrv_ >= maxAccPrv)
mjr	5:a70c0bce770d	3022	{
mjr	5:a70c0bce770d	3023	// check if we've been stable for all recent samples
mjr	75:677892300e7a	3024	static const float accTol = .01f;
mjr	6:cc35eb643e8f	3025	AccHist *p0 = accPrv_;
mjr	6:cc35eb643e8f	3026	if (p0[0].d < accTol
mjr	6:cc35eb643e8f	3027	&& p0[1].d < accTol
mjr	6:cc35eb643e8f	3028	&& p0[2].d < accTol
mjr	6:cc35eb643e8f	3029	&& p0[3].d < accTol
mjr	6:cc35eb643e8f	3030	&& p0[4].d < accTol)
mjr	5:a70c0bce770d	3031	{
mjr	6:cc35eb643e8f	3032	// Figure the new calibration point as the average of
mjr	6:cc35eb643e8f	3033	// the samples over the rest period
mjr	75:677892300e7a	3034	cx_ = (p0[0].xAvg() + p0[1].xAvg() + p0[2].xAvg() + p0[3].xAvg() + p0[4].xAvg())/5.0f;
mjr	75:677892300e7a	3035	cy_ = (p0[0].yAvg() + p0[1].yAvg() + p0[2].yAvg() + p0[3].yAvg() + p0[4].yAvg())/5.0f;
mjr	5:a70c0bce770d	3036	}
mjr	5:a70c0bce770d	3037	}
mjr	5:a70c0bce770d	3038	else
mjr	5:a70c0bce770d	3039	{
mjr	5:a70c0bce770d	3040	// not enough samples yet; just up the count
mjr	5:a70c0bce770d	3041	++nAccPrv_;
mjr	5:a70c0bce770d	3042	}
mjr	6:cc35eb643e8f	3043
mjr	6:cc35eb643e8f	3044	// clear the new item's running totals
mjr	6:cc35eb643e8f	3045	p->clearAvg();
mjr	5:a70c0bce770d	3046
mjr	5:a70c0bce770d	3047	// reset the timer
mjr	5:a70c0bce770d	3048	tCenter_.reset();
mjr	39:b3815a1c3802	3049
mjr	39:b3815a1c3802	3050	// If we haven't seen an interrupt in a while, do an explicit read to
mjr	39:b3815a1c3802	3051	// "unstick" the device. The device can become stuck - which is to say,
mjr	39:b3815a1c3802	3052	// it will stop delivering data-ready interrupts - if we fail to service
mjr	39:b3815a1c3802	3053	// one data-ready interrupt before the next one occurs. Reading a sample
mjr	39:b3815a1c3802	3054	// will clear up this overrun condition and allow normal interrupt
mjr	39:b3815a1c3802	3055	// generation to continue.
mjr	39:b3815a1c3802	3056	//
mjr	39:b3815a1c3802	3057	// Note that this stuck condition shouldn't ever occur - if it does,
mjr	39:b3815a1c3802	3058	// it means that we're spending a long period with interrupts disabled
mjr	39:b3815a1c3802	3059	// (either in a critical section or in another interrupt handler), which
mjr	39:b3815a1c3802	3060	// will likely cause other worse problems beyond the sticky accelerometer.
mjr	39:b3815a1c3802	3061	// Even so, it's easy to detect and correct, so we'll do so for the sake
mjr	39:b3815a1c3802	3062	// of making the system more fault-tolerant.
mjr	39:b3815a1c3802	3063	if (tInt_.read() > 1.0f)
mjr	39:b3815a1c3802	3064	{
mjr	39:b3815a1c3802	3065	float x, y, z;
mjr	39:b3815a1c3802	3066	mma_.getAccXYZ(x, y, z);
mjr	39:b3815a1c3802	3067	}
mjr	5:a70c0bce770d	3068	}
mjr	5:a70c0bce770d	3069
mjr	6:cc35eb643e8f	3070	// report our integrated velocity reading in x,y
mjr	6:cc35eb643e8f	3071	x = rawToReport(vx);
mjr	6:cc35eb643e8f	3072	y = rawToReport(vy);
mjr	5:a70c0bce770d	3073
mjr	6:cc35eb643e8f	3074	#ifdef DEBUG_PRINTF
mjr	6:cc35eb643e8f	3075	if (x != 0 \|\| y != 0)
mjr	6:cc35eb643e8f	3076	printf("%f %f %d %d %f\r\n", vx, vy, x, y, dt);
mjr	6:cc35eb643e8f	3077	#endif
mjr	3:3514575d4f86	3078	}
mjr	29:582472d0bc57	3079
mjr	3:3514575d4f86	3080	private:
mjr	6:cc35eb643e8f	3081	// adjust a raw acceleration figure to a usb report value
mjr	6:cc35eb643e8f	3082	int rawToReport(float v)
mjr	5:a70c0bce770d	3083	{
mjr	6:cc35eb643e8f	3084	// scale to the joystick report range and round to integer
mjr	6:cc35eb643e8f	3085	int i = int(round(v*JOYMAX));
mjr	5:a70c0bce770d	3086
mjr	6:cc35eb643e8f	3087	// if it's near the center, scale it roughly as 20*(i/20)^2,
mjr	6:cc35eb643e8f	3088	// to suppress noise near the rest position
mjr	6:cc35eb643e8f	3089	static const int filter[] = {
mjr	6:cc35eb643e8f	3090	-18, -16, -14, -13, -11, -10, -8, -7, -6, -5, -4, -3, -2, -2, -1, -1, 0, 0, 0, 0,
mjr	6:cc35eb643e8f	3091	0,
mjr	6:cc35eb643e8f	3092	0, 0, 0, 0, 1, 1, 2, 2, 3, 4, 5, 6, 7, 8, 10, 11, 13, 14, 16, 18
mjr	6:cc35eb643e8f	3093	};
mjr	6:cc35eb643e8f	3094	return (i > 20 \|\| i < -20 ? i : filter[i+20]);
mjr	5:a70c0bce770d	3095	}
mjr	5:a70c0bce770d	3096
mjr	3:3514575d4f86	3097	// interrupt handler
mjr	3:3514575d4f86	3098	void isr()
mjr	3:3514575d4f86	3099	{
mjr	3:3514575d4f86	3100	// Read the axes. Note that we have to read all three axes
mjr	3:3514575d4f86	3101	// (even though we only really use x and y) in order to clear
mjr	3:3514575d4f86	3102	// the "data ready" status bit in the accelerometer. The
mjr	3:3514575d4f86	3103	// interrupt only occurs when the "ready" bit transitions from
mjr	3:3514575d4f86	3104	// off to on, so we have to make sure it's off.
mjr	5:a70c0bce770d	3105	float x, y, z;
mjr	5:a70c0bce770d	3106	mma_.getAccXYZ(x, y, z);
mjr	3:3514575d4f86	3107
mjr	3:3514575d4f86	3108	// calculate the time since the last interrupt
mjr	39:b3815a1c3802	3109	float dt = tInt_.read();
mjr	3:3514575d4f86	3110	tInt_.reset();
mjr	6:cc35eb643e8f	3111
mjr	6:cc35eb643e8f	3112	// integrate the time slice from the previous reading to this reading
mjr	6:cc35eb643e8f	3113	vx_ += (x + ax_ - 2cx_)dt/2;
mjr	6:cc35eb643e8f	3114	vy_ += (y + ay_ - 2cy_)dt/2;
mjr	3:3514575d4f86	3115
mjr	6:cc35eb643e8f	3116	// store the updates
mjr	6:cc35eb643e8f	3117	ax_ = x;
mjr	6:cc35eb643e8f	3118	ay_ = y;
mjr	6:cc35eb643e8f	3119	az_ = z;
mjr	3:3514575d4f86	3120	}
mjr	3:3514575d4f86	3121
mjr	3:3514575d4f86	3122	// underlying accelerometer object
mjr	3:3514575d4f86	3123	MMA8451Q mma_;
mjr	3:3514575d4f86	3124
mjr	5:a70c0bce770d	3125	// last raw acceleration readings
mjr	6:cc35eb643e8f	3126	float ax_, ay_, az_;
mjr	5:a70c0bce770d	3127
mjr	6:cc35eb643e8f	3128	// integrated velocity reading since last get()
mjr	6:cc35eb643e8f	3129	float vx_, vy_;
mjr	6:cc35eb643e8f	3130
mjr	3:3514575d4f86	3131	// timer for measuring time between get() samples
mjr	3:3514575d4f86	3132	Timer tGet_;
mjr	3:3514575d4f86	3133
mjr	3:3514575d4f86	3134	// timer for measuring time between interrupts
mjr	3:3514575d4f86	3135	Timer tInt_;
mjr	5:a70c0bce770d	3136
mjr	6:cc35eb643e8f	3137	// Calibration reference point for accelerometer. This is the
mjr	6:cc35eb643e8f	3138	// average reading on the accelerometer when in the neutral position
mjr	6:cc35eb643e8f	3139	// at rest.
mjr	6:cc35eb643e8f	3140	float cx_, cy_;
mjr	5:a70c0bce770d	3141
mjr	5:a70c0bce770d	3142	// timer for atuo-centering
mjr	5:a70c0bce770d	3143	Timer tCenter_;
mjr	6:cc35eb643e8f	3144
mjr	6:cc35eb643e8f	3145	// Auto-centering history. This is a separate history list that
mjr	6:cc35eb643e8f	3146	// records results spaced out sparesely over time, so that we can
mjr	6:cc35eb643e8f	3147	// watch for long-lasting periods of rest. When we observe nearly
mjr	6:cc35eb643e8f	3148	// no motion for an extended period (on the order of 5 seconds), we
mjr	6:cc35eb643e8f	3149	// take this to mean that the cabinet is at rest in its neutral
mjr	6:cc35eb643e8f	3150	// position, so we take this as the calibration zero point for the
mjr	6:cc35eb643e8f	3151	// accelerometer. We update this history continuously, which allows
mjr	6:cc35eb643e8f	3152	// us to continuously re-calibrate the accelerometer. This ensures
mjr	6:cc35eb643e8f	3153	// that we'll automatically adjust to any actual changes in the
mjr	6:cc35eb643e8f	3154	// cabinet's orientation (e.g., if it gets moved slightly by an
mjr	6:cc35eb643e8f	3155	// especially strong nudge) as well as any systematic drift in the
mjr	6:cc35eb643e8f	3156	// accelerometer measurement bias (e.g., from temperature changes).
mjr	5:a70c0bce770d	3157	int iAccPrv_, nAccPrv_;
mjr	5:a70c0bce770d	3158	static const int maxAccPrv = 5;
mjr	6:cc35eb643e8f	3159	AccHist accPrv_[maxAccPrv];
mjr	6:cc35eb643e8f	3160
mjr	5:a70c0bce770d	3161	// interurupt pin name
mjr	5:a70c0bce770d	3162	PinName irqPin_;
mjr	5:a70c0bce770d	3163
mjr	5:a70c0bce770d	3164	// interrupt router
mjr	5:a70c0bce770d	3165	InterruptIn intIn_;
mjr	3:3514575d4f86	3166	};
mjr	3:3514575d4f86	3167
mjr	5:a70c0bce770d	3168
mjr	5:a70c0bce770d	3169	// ---------------------------------------------------------------------------
mjr	5:a70c0bce770d	3170	//
mjr	14:df700b22ca08	3171	// Clear the I2C bus for the MMA8451Q. This seems necessary some of the time
mjr	5:a70c0bce770d	3172	// for reasons that aren't clear to me. Doing a hard power cycle has the same
mjr	5:a70c0bce770d	3173	// effect, but when we do a soft reset, the hardware sometimes seems to leave
mjr	5:a70c0bce770d	3174	// the MMA's SDA line stuck low. Forcing a series of 9 clock pulses through
mjr	14:df700b22ca08	3175	// the SCL line is supposed to clear this condition. I'm not convinced this
mjr	14:df700b22ca08	3176	// actually works with the way this component is wired on the KL25Z, but it
mjr	14:df700b22ca08	3177	// seems harmless, so we'll do it on reset in case it does some good. What
mjr	14:df700b22ca08	3178	// we really seem to need is a way to power cycle the MMA8451Q if it ever
mjr	14:df700b22ca08	3179	// gets stuck, but this is simply not possible in software on the KL25Z.
mjr	14:df700b22ca08	3180	//
mjr	14:df700b22ca08	3181	// If the accelerometer does get stuck, and a software reboot doesn't reset
mjr	14:df700b22ca08	3182	// it, the only workaround is to manually power cycle the whole KL25Z by
mjr	14:df700b22ca08	3183	// unplugging both of its USB connections.
mjr	5:a70c0bce770d	3184	//
mjr	5:a70c0bce770d	3185	void clear_i2c()
mjr	5:a70c0bce770d	3186	{
mjr	38:091e511ce8a0	3187	// set up general-purpose output pins to the I2C lines
mjr	5:a70c0bce770d	3188	DigitalOut scl(MMA8451_SCL_PIN);
mjr	5:a70c0bce770d	3189	DigitalIn sda(MMA8451_SDA_PIN);
mjr	5:a70c0bce770d	3190
mjr	5:a70c0bce770d	3191	// clock the SCL 9 times
mjr	5:a70c0bce770d	3192	for (int i = 0 ; i < 9 ; ++i)
mjr	5:a70c0bce770d	3193	{
mjr	5:a70c0bce770d	3194	scl = 1;
mjr	5:a70c0bce770d	3195	wait_us(20);
mjr	5:a70c0bce770d	3196	scl = 0;
mjr	5:a70c0bce770d	3197	wait_us(20);
mjr	5:a70c0bce770d	3198	}
mjr	5:a70c0bce770d	3199	}
mjr	14:df700b22ca08	3200
mjr	14:df700b22ca08	3201	// ---------------------------------------------------------------------------
mjr	14:df700b22ca08	3202	//
mjr	33:d832bcab089e	3203	// Simple binary (on/off) input debouncer. Requires an input to be stable
mjr	33:d832bcab089e	3204	// for a given interval before allowing an update.
mjr	33:d832bcab089e	3205	//
mjr	33:d832bcab089e	3206	class Debouncer
mjr	33:d832bcab089e	3207	{
mjr	33:d832bcab089e	3208	public:
mjr	33:d832bcab089e	3209	Debouncer(bool initVal, float tmin)
mjr	33:d832bcab089e	3210	{
mjr	33:d832bcab089e	3211	t.start();
mjr	33:d832bcab089e	3212	this->stable = this->prv = initVal;
mjr	33:d832bcab089e	3213	this->tmin = tmin;
mjr	33:d832bcab089e	3214	}
mjr	33:d832bcab089e	3215
mjr	33:d832bcab089e	3216	// Get the current stable value
mjr	33:d832bcab089e	3217	bool val() const { return stable; }
mjr	33:d832bcab089e	3218
mjr	33:d832bcab089e	3219	// Apply a new sample. This tells us the new raw reading from the
mjr	33:d832bcab089e	3220	// input device.
mjr	33:d832bcab089e	3221	void sampleIn(bool val)
mjr	33:d832bcab089e	3222	{
mjr	33:d832bcab089e	3223	// If the new raw reading is different from the previous
mjr	33:d832bcab089e	3224	// raw reading, we've detected an edge - start the clock
mjr	33:d832bcab089e	3225	// on the sample reader.
mjr	33:d832bcab089e	3226	if (val != prv)
mjr	33:d832bcab089e	3227	{
mjr	33:d832bcab089e	3228	// we have an edge - reset the sample clock
mjr	33:d832bcab089e	3229	t.reset();
mjr	33:d832bcab089e	3230
mjr	33:d832bcab089e	3231	// this is now the previous raw sample for nxt time
mjr	33:d832bcab089e	3232	prv = val;
mjr	33:d832bcab089e	3233	}
mjr	33:d832bcab089e	3234	else if (val != stable)
mjr	33:d832bcab089e	3235	{
mjr	33:d832bcab089e	3236	// The new raw sample is the same as the last raw sample,
mjr	33:d832bcab089e	3237	// and different from the stable value. This means that
mjr	33:d832bcab089e	3238	// the sample value has been the same for the time currently
mjr	33:d832bcab089e	3239	// indicated by our timer. If enough time has elapsed to
mjr	33:d832bcab089e	3240	// consider the value stable, apply the new value.
mjr	33:d832bcab089e	3241	if (t.read() > tmin)
mjr	33:d832bcab089e	3242	stable = val;
mjr	33:d832bcab089e	3243	}
mjr	33:d832bcab089e	3244	}
mjr	33:d832bcab089e	3245
mjr	33:d832bcab089e	3246	private:
mjr	33:d832bcab089e	3247	// current stable value
mjr	33:d832bcab089e	3248	bool stable;
mjr	33:d832bcab089e	3249
mjr	33:d832bcab089e	3250	// last raw sample value
mjr	33:d832bcab089e	3251	bool prv;
mjr	33:d832bcab089e	3252
mjr	33:d832bcab089e	3253	// elapsed time since last raw input change
mjr	33:d832bcab089e	3254	Timer t;
mjr	33:d832bcab089e	3255
mjr	33:d832bcab089e	3256	// Minimum time interval for stability, in seconds. Input readings
mjr	33:d832bcab089e	3257	// must be stable for this long before the stable value is updated.
mjr	33:d832bcab089e	3258	float tmin;
mjr	33:d832bcab089e	3259	};
mjr	33:d832bcab089e	3260
mjr	33:d832bcab089e	3261
mjr	33:d832bcab089e	3262	// ---------------------------------------------------------------------------
mjr	33:d832bcab089e	3263	//
mjr	33:d832bcab089e	3264	// TV ON timer. If this feature is enabled, we toggle a TV power switch
mjr	33:d832bcab089e	3265	// relay (connected to a GPIO pin) to turn on the cab's TV monitors shortly
mjr	33:d832bcab089e	3266	// after the system is powered. This is useful for TVs that don't remember
mjr	33:d832bcab089e	3267	// their power state and don't turn back on automatically after being
mjr	33:d832bcab089e	3268	// unplugged and plugged in again. This feature requires external
mjr	33:d832bcab089e	3269	// circuitry, which is built in to the expansion board and can also be
mjr	33:d832bcab089e	3270	// built separately - see the Build Guide for the circuit plan.
mjr	33:d832bcab089e	3271	//
mjr	33:d832bcab089e	3272	// Theory of operation: to use this feature, the cabinet must have a
mjr	33:d832bcab089e	3273	// secondary PC-style power supply (PSU2) for the feedback devices, and
mjr	33:d832bcab089e	3274	// this secondary supply must be plugged in to the same power strip or
mjr	33:d832bcab089e	3275	// switched outlet that controls power to the TVs. This lets us use PSU2
mjr	33:d832bcab089e	3276	// as a proxy for the TV power state - when PSU2 is on, the TV outlet is
mjr	33:d832bcab089e	3277	// powered, and when PSU2 is off, the TV outlet is off. We use a little
mjr	33:d832bcab089e	3278	// latch circuit powered by PSU2 to monitor the status. The latch has a
mjr	33:d832bcab089e	3279	// current state, ON or OFF, that we can read via a GPIO input pin, and
mjr	33:d832bcab089e	3280	// we can set the state to ON by pulsing a separate GPIO output pin. As
mjr	33:d832bcab089e	3281	// long as PSU2 is powered off, the latch stays in the OFF state, even if
mjr	33:d832bcab089e	3282	// we try to set it by pulsing the SET pin. When PSU2 is turned on after
mjr	33:d832bcab089e	3283	// being off, the latch starts receiving power but stays in the OFF state,
mjr	33:d832bcab089e	3284	// since this is the initial condition when the power first comes on. So
mjr	33:d832bcab089e	3285	// if our latch state pin is reading OFF, we know that PSU2 is either off
mjr	33:d832bcab089e	3286	// now or was off some time since we last checked. We use a timer to
mjr	33:d832bcab089e	3287	// check the state periodically. Each time we see the state is OFF, we
mjr	33:d832bcab089e	3288	// try pulsing the SET pin. If the state still reads as OFF, we know
mjr	33:d832bcab089e	3289	// that PSU2 is currently off; if the state changes to ON, though, we
mjr	33:d832bcab089e	3290	// know that PSU2 has gone from OFF to ON some time between now and the
mjr	33:d832bcab089e	3291	// previous check. When we see this condition, we start a countdown
mjr	33:d832bcab089e	3292	// timer, and pulse the TV switch relay when the countdown ends.
mjr	33:d832bcab089e	3293	//
mjr	40:cc0d9814522b	3294	// This scheme might seem a little convoluted, but it handles a number
mjr	40:cc0d9814522b	3295	// of tricky but likely scenarios:
mjr	33:d832bcab089e	3296	//
mjr	33:d832bcab089e	3297	// - Most cabinets systems are set up with "soft" PC power switches,
mjr	40:cc0d9814522b	3298	// so that the PC goes into "Soft Off" mode when the user turns off
mjr	40:cc0d9814522b	3299	// the cabinet by pushing the power button or using the Shut Down
mjr	40:cc0d9814522b	3300	// command from within Windows. In Windows parlance, this "soft off"
mjr	40:cc0d9814522b	3301	// condition is called ACPI State S5. In this state, the main CPU
mjr	40:cc0d9814522b	3302	// power is turned off, but the motherboard still provides power to
mjr	40:cc0d9814522b	3303	// USB devices. This means that the KL25Z keeps running. Without
mjr	40:cc0d9814522b	3304	// the external power sensing circuit, the only hint that we're in
mjr	40:cc0d9814522b	3305	// this state is that the USB connection to the host goes into Suspend
mjr	40:cc0d9814522b	3306	// mode, but that could mean other things as well. The latch circuit
mjr	40:cc0d9814522b	3307	// lets us tell for sure that we're in this state.
mjr	33:d832bcab089e	3308	//
mjr	33:d832bcab089e	3309	// - Some cabinet builders might prefer to use "hard" power switches,
mjr	33:d832bcab089e	3310	// cutting all power to the cabinet, including the PC motherboard (and
mjr	33:d832bcab089e	3311	// thus the KL25Z) every time the machine is turned off. This also
mjr	33:d832bcab089e	3312	// applies to the "soft" switch case above when the cabinet is unplugged,
mjr	33:d832bcab089e	3313	// a power outage occurs, etc. In these cases, the KL25Z will do a cold
mjr	33:d832bcab089e	3314	// boot when the PC is turned on. We don't know whether the KL25Z
mjr	33:d832bcab089e	3315	// will power up before or after PSU2, so it's not good enough to
mjr	40:cc0d9814522b	3316	// observe the current state of PSU2 when we first check. If PSU2
mjr	40:cc0d9814522b	3317	// were to come on first, checking only the current state would fool
mjr	40:cc0d9814522b	3318	// us into thinking that no action is required, because we'd only see
mjr	40:cc0d9814522b	3319	// that PSU2 is turned on any time we check. The latch handles this
mjr	40:cc0d9814522b	3320	// case by letting us see that PSU2 was indeed off some time before our
mjr	40:cc0d9814522b	3321	// first check.
mjr	33:d832bcab089e	3322	//
mjr	33:d832bcab089e	3323	// - If the KL25Z is rebooted while the main system is running, or the
mjr	40:cc0d9814522b	3324	// KL25Z is unplugged and plugged back in, we'll correctly leave the
mjr	33:d832bcab089e	3325	// TVs as they are. The latch state is independent of the KL25Z's
mjr	33:d832bcab089e	3326	// power or software state, so it's won't affect the latch state when
mjr	33:d832bcab089e	3327	// the KL25Z is unplugged or rebooted; when we boot, we'll see that
mjr	33:d832bcab089e	3328	// the latch is already on and that we don't have to turn on the TVs.
mjr	33:d832bcab089e	3329	// This is important because TV ON buttons are usually on/off toggles,
mjr	33:d832bcab089e	3330	// so we don't want to push the button on a TV that's already on.
mjr	33:d832bcab089e	3331	//
mjr	33:d832bcab089e	3332
mjr	33:d832bcab089e	3333	// Current PSU2 state:
mjr	33:d832bcab089e	3334	// 1 -> default: latch was on at last check, or we haven't checked yet
mjr	33:d832bcab089e	3335	// 2 -> latch was off at last check, SET pulsed high
mjr	33:d832bcab089e	3336	// 3 -> SET pulsed low, ready to check status
mjr	33:d832bcab089e	3337	// 4 -> TV timer countdown in progress
mjr	33:d832bcab089e	3338	// 5 -> TV relay on
mjr	73:4e8ce0b18915	3339	uint8_t psu2_state = 1;
mjr	73:4e8ce0b18915	3340
mjr	73:4e8ce0b18915	3341	// TV relay state. The TV relay can be controlled by the power-on
mjr	73:4e8ce0b18915	3342	// timer and directly from the PC (via USB commands), so keep a
mjr	73:4e8ce0b18915	3343	// separate state for each:
mjr	73:4e8ce0b18915	3344	//
mjr	73:4e8ce0b18915	3345	// 0x01 -> turned on by power-on timer
mjr	73:4e8ce0b18915	3346	// 0x02 -> turned on by USB command
mjr	73:4e8ce0b18915	3347	uint8_t tv_relay_state = 0x00;
mjr	73:4e8ce0b18915	3348	const uint8_t TV_RELAY_POWERON = 0x01;
mjr	73:4e8ce0b18915	3349	const uint8_t TV_RELAY_USB = 0x02;
mjr	73:4e8ce0b18915	3350
mjr	73:4e8ce0b18915	3351	// TV ON switch relay control
mjr	73:4e8ce0b18915	3352	DigitalOut *tv_relay;
mjr	35:e959ffba78fd	3353
mjr	35:e959ffba78fd	3354	// PSU2 power sensing circuit connections
mjr	35:e959ffba78fd	3355	DigitalIn *psu2_status_sense;
mjr	35:e959ffba78fd	3356	DigitalOut *psu2_status_set;
mjr	35:e959ffba78fd	3357
mjr	73:4e8ce0b18915	3358	// Apply the current TV relay state
mjr	73:4e8ce0b18915	3359	void tvRelayUpdate(uint8_t bit, bool state)
mjr	73:4e8ce0b18915	3360	{
mjr	73:4e8ce0b18915	3361	// update the state
mjr	73:4e8ce0b18915	3362	if (state)
mjr	73:4e8ce0b18915	3363	tv_relay_state \|= bit;
mjr	73:4e8ce0b18915	3364	else
mjr	73:4e8ce0b18915	3365	tv_relay_state &= ~bit;
mjr	73:4e8ce0b18915	3366
mjr	73:4e8ce0b18915	3367	// set the relay GPIO to the new state
mjr	73:4e8ce0b18915	3368	if (tv_relay != 0)
mjr	73:4e8ce0b18915	3369	tv_relay->write(tv_relay_state != 0);
mjr	73:4e8ce0b18915	3370	}
mjr	35:e959ffba78fd	3371
mjr	35:e959ffba78fd	3372	// Timer interrupt
mjr	35:e959ffba78fd	3373	Ticker tv_ticker;
mjr	35:e959ffba78fd	3374	float tv_delay_time;
mjr	33:d832bcab089e	3375	void TVTimerInt()
mjr	33:d832bcab089e	3376	{
mjr	35:e959ffba78fd	3377	// time since last state change
mjr	35:e959ffba78fd	3378	static Timer tv_timer;
mjr	35:e959ffba78fd	3379
mjr	33:d832bcab089e	3380	// Check our internal state
mjr	33:d832bcab089e	3381	switch (psu2_state)
mjr	33:d832bcab089e	3382	{
mjr	33:d832bcab089e	3383	case 1:
mjr	33:d832bcab089e	3384	// Default state. This means that the latch was on last
mjr	33:d832bcab089e	3385	// time we checked or that this is the first check. In
mjr	33:d832bcab089e	3386	// either case, if the latch is off, switch to state 2 and
mjr	33:d832bcab089e	3387	// try pulsing the latch. Next time we check, if the latch
mjr	33:d832bcab089e	3388	// stuck, it means that PSU2 is now on after being off.
mjr	35:e959ffba78fd	3389	if (!psu2_status_sense->read())
mjr	33:d832bcab089e	3390	{
mjr	33:d832bcab089e	3391	// switch to OFF state
mjr	33:d832bcab089e	3392	psu2_state = 2;
mjr	33:d832bcab089e	3393
mjr	33:d832bcab089e	3394	// try setting the latch
mjr	35:e959ffba78fd	3395	psu2_status_set->write(1);
mjr	33:d832bcab089e	3396	}
mjr	33:d832bcab089e	3397	break;
mjr	33:d832bcab089e	3398
mjr	33:d832bcab089e	3399	case 2:
mjr	33:d832bcab089e	3400	// PSU2 was off last time we checked, and we tried setting
mjr	33:d832bcab089e	3401	// the latch. Drop the SET signal and go to CHECK state.
mjr	35:e959ffba78fd	3402	psu2_status_set->write(0);
mjr	33:d832bcab089e	3403	psu2_state = 3;
mjr	33:d832bcab089e	3404	break;
mjr	33:d832bcab089e	3405
mjr	33:d832bcab089e	3406	case 3:
mjr	33:d832bcab089e	3407	// CHECK state: we pulsed SET, and we're now ready to see
mjr	40:cc0d9814522b	3408	// if it stuck. If the latch is now on, PSU2 has transitioned
mjr	33:d832bcab089e	3409	// from OFF to ON, so start the TV countdown. If the latch is
mjr	33:d832bcab089e	3410	// off, our SET command didn't stick, so PSU2 is still off.
mjr	35:e959ffba78fd	3411	if (psu2_status_sense->read())
mjr	33:d832bcab089e	3412	{
mjr	33:d832bcab089e	3413	// The latch stuck, so PSU2 has transitioned from OFF
mjr	33:d832bcab089e	3414	// to ON. Start the TV countdown timer.
mjr	33:d832bcab089e	3415	tv_timer.reset();
mjr	33:d832bcab089e	3416	tv_timer.start();
mjr	33:d832bcab089e	3417	psu2_state = 4;
mjr	73:4e8ce0b18915	3418
mjr	73:4e8ce0b18915	3419	// start the power timer diagnostic flashes
mjr	73:4e8ce0b18915	3420	powerTimerDiagState = 2;
mjr	73:4e8ce0b18915	3421	diagLED();
mjr	33:d832bcab089e	3422	}
mjr	33:d832bcab089e	3423	else
mjr	33:d832bcab089e	3424	{
mjr	33:d832bcab089e	3425	// The latch didn't stick, so PSU2 was still off at
mjr	33:d832bcab089e	3426	// our last check. Try pulsing it again in case PSU2
mjr	33:d832bcab089e	3427	// was turned on since the last check.
mjr	35:e959ffba78fd	3428	psu2_status_set->write(1);
mjr	33:d832bcab089e	3429	psu2_state = 2;
mjr	33:d832bcab089e	3430	}
mjr	33:d832bcab089e	3431	break;
mjr	33:d832bcab089e	3432
mjr	33:d832bcab089e	3433	case 4:
mjr	33:d832bcab089e	3434	// TV timer countdown in progress. If we've reached the
mjr	33:d832bcab089e	3435	// delay time, pulse the relay.
mjr	35:e959ffba78fd	3436	if (tv_timer.read() >= tv_delay_time)
mjr	33:d832bcab089e	3437	{
mjr	33:d832bcab089e	3438	// turn on the relay for one timer interval
mjr	73:4e8ce0b18915	3439	tvRelayUpdate(TV_RELAY_POWERON, true);
mjr	33:d832bcab089e	3440	psu2_state = 5;
mjr	33:d832bcab089e	3441	}
mjr	73:4e8ce0b18915	3442
mjr	73:4e8ce0b18915	3443	// flash the power time diagnostic every two interrupts
mjr	73:4e8ce0b18915	3444	powerTimerDiagState = (powerTimerDiagState + 1) & 0x03;
mjr	73:4e8ce0b18915	3445	diagLED();
mjr	33:d832bcab089e	3446	break;
mjr	33:d832bcab089e	3447
mjr	33:d832bcab089e	3448	case 5:
mjr	33:d832bcab089e	3449	// TV timer relay on. We pulse this for one interval, so
mjr	33:d832bcab089e	3450	// it's now time to turn it off and return to the default state.
mjr	73:4e8ce0b18915	3451	tvRelayUpdate(TV_RELAY_POWERON, false);
mjr	33:d832bcab089e	3452	psu2_state = 1;
mjr	73:4e8ce0b18915	3453
mjr	73:4e8ce0b18915	3454	// done with the diagnostic flashes
mjr	73:4e8ce0b18915	3455	powerTimerDiagState = 0;
mjr	73:4e8ce0b18915	3456	diagLED();
mjr	33:d832bcab089e	3457	break;
mjr	33:d832bcab089e	3458	}
mjr	33:d832bcab089e	3459	}
mjr	33:d832bcab089e	3460
mjr	35:e959ffba78fd	3461	// Start the TV ON checker. If the status sense circuit is enabled in
mjr	35:e959ffba78fd	3462	// the configuration, we'll set up the pin connections and start the
mjr	35:e959ffba78fd	3463	// interrupt handler that periodically checks the status. Does nothing
mjr	35:e959ffba78fd	3464	// if any of the pins are configured as NC.
mjr	35:e959ffba78fd	3465	void startTVTimer(Config &cfg)
mjr	35:e959ffba78fd	3466	{
mjr	55:4db125cd11a0	3467	// only start the timer if the pins are configured and the delay
mjr	55:4db125cd11a0	3468	// time is nonzero
mjr	55:4db125cd11a0	3469	if (cfg.TVON.delayTime != 0
mjr	55:4db125cd11a0	3470	&& cfg.TVON.statusPin != 0xFF
mjr	53:9b2611964afc	3471	&& cfg.TVON.latchPin != 0xFF
mjr	53:9b2611964afc	3472	&& cfg.TVON.relayPin != 0xFF)
mjr	35:e959ffba78fd	3473	{
mjr	53:9b2611964afc	3474	psu2_status_sense = new DigitalIn(wirePinName(cfg.TVON.statusPin));
mjr	53:9b2611964afc	3475	psu2_status_set = new DigitalOut(wirePinName(cfg.TVON.latchPin));
mjr	53:9b2611964afc	3476	tv_relay = new DigitalOut(wirePinName(cfg.TVON.relayPin));
mjr	73:4e8ce0b18915	3477	tv_delay_time = cfg.TVON.delayTime/100.0f;
mjr	35:e959ffba78fd	3478
mjr	35:e959ffba78fd	3479	// Set up our time routine to run every 1/4 second.
mjr	35:e959ffba78fd	3480	tv_ticker.attach(&TVTimerInt, 0.25);
mjr	35:e959ffba78fd	3481	}
mjr	35:e959ffba78fd	3482	}
mjr	35:e959ffba78fd	3483
mjr	73:4e8ce0b18915	3484	// TV relay manual control timer. This lets us pulse the TV relay
mjr	73:4e8ce0b18915	3485	// under manual control, separately from the TV ON timer.
mjr	73:4e8ce0b18915	3486	Ticker tv_manualTicker;
mjr	73:4e8ce0b18915	3487	void TVManualInt()
mjr	73:4e8ce0b18915	3488	{
mjr	73:4e8ce0b18915	3489	tv_manualTicker.detach();
mjr	73:4e8ce0b18915	3490	tvRelayUpdate(TV_RELAY_USB, false);
mjr	73:4e8ce0b18915	3491	}
mjr	73:4e8ce0b18915	3492
mjr	73:4e8ce0b18915	3493	// Operate the TV ON relay. This allows manual control of the relay
mjr	73:4e8ce0b18915	3494	// from the PC. See protocol message 65 submessage 11.
mjr	73:4e8ce0b18915	3495	//
mjr	73:4e8ce0b18915	3496	// Mode:
mjr	73:4e8ce0b18915	3497	// 0 = turn relay off
mjr	73:4e8ce0b18915	3498	// 1 = turn relay on
mjr	73:4e8ce0b18915	3499	// 2 = pulse relay
mjr	73:4e8ce0b18915	3500	void TVRelay(int mode)
mjr	73:4e8ce0b18915	3501	{
mjr	73:4e8ce0b18915	3502	// if there's no TV relay control pin, ignore this
mjr	73:4e8ce0b18915	3503	if (tv_relay == 0)
mjr	73:4e8ce0b18915	3504	return;
mjr	73:4e8ce0b18915	3505
mjr	73:4e8ce0b18915	3506	switch (mode)
mjr	73:4e8ce0b18915	3507	{
mjr	73:4e8ce0b18915	3508	case 0:
mjr	73:4e8ce0b18915	3509	// relay off
mjr	73:4e8ce0b18915	3510	tvRelayUpdate(TV_RELAY_USB, false);
mjr	73:4e8ce0b18915	3511	break;
mjr	73:4e8ce0b18915	3512
mjr	73:4e8ce0b18915	3513	case 1:
mjr	73:4e8ce0b18915	3514	// relay on
mjr	73:4e8ce0b18915	3515	tvRelayUpdate(TV_RELAY_USB, true);
mjr	73:4e8ce0b18915	3516	break;
mjr	73:4e8ce0b18915	3517
mjr	73:4e8ce0b18915	3518	case 2:
mjr	73:4e8ce0b18915	3519	// Pulse the relay. Turn it on, then set our timer for 250ms.
mjr	73:4e8ce0b18915	3520	tvRelayUpdate(TV_RELAY_USB, true);
mjr	73:4e8ce0b18915	3521	tv_manualTicker.attach(&TVManualInt, 0.25);
mjr	73:4e8ce0b18915	3522	break;
mjr	73:4e8ce0b18915	3523	}
mjr	73:4e8ce0b18915	3524	}
mjr	73:4e8ce0b18915	3525
mjr	73:4e8ce0b18915	3526
mjr	35:e959ffba78fd	3527	// ---------------------------------------------------------------------------
mjr	35:e959ffba78fd	3528	//
mjr	35:e959ffba78fd	3529	// In-memory configuration data structure. This is the live version in RAM
mjr	35:e959ffba78fd	3530	// that we use to determine how things are set up.
mjr	35:e959ffba78fd	3531	//
mjr	35:e959ffba78fd	3532	// When we save the configuration settings, we copy this structure to
mjr	35:e959ffba78fd	3533	// non-volatile flash memory. At startup, we check the flash location where
mjr	35:e959ffba78fd	3534	// we might have saved settings on a previous run, and it's valid, we copy
mjr	35:e959ffba78fd	3535	// the flash data to this structure. Firmware updates wipe the flash
mjr	35:e959ffba78fd	3536	// memory area, so you have to use the PC config tool to send the settings
mjr	35:e959ffba78fd	3537	// again each time the firmware is updated.
mjr	35:e959ffba78fd	3538	//
mjr	35:e959ffba78fd	3539	NVM nvm;
mjr	35:e959ffba78fd	3540
mjr	35:e959ffba78fd	3541	// For convenience, a macro for the Config part of the NVM structure
mjr	35:e959ffba78fd	3542	#define cfg (nvm.d.c)
mjr	35:e959ffba78fd	3543
mjr	35:e959ffba78fd	3544	// flash memory controller interface
mjr	35:e959ffba78fd	3545	FreescaleIAP iap;
mjr	35:e959ffba78fd	3546
mjr	35:e959ffba78fd	3547	// figure the flash address as a pointer along with the number of sectors
mjr	35:e959ffba78fd	3548	// required to store the structure
mjr	35:e959ffba78fd	3549	NVM *configFlashAddr(int &addr, int &numSectors)
mjr	35:e959ffba78fd	3550	{
mjr	35:e959ffba78fd	3551	// figure how many flash sectors we span, rounding up to whole sectors
mjr	35:e959ffba78fd	3552	numSectors = (sizeof(NVM) + SECTOR_SIZE - 1)/SECTOR_SIZE;
mjr	35:e959ffba78fd	3553
mjr	35:e959ffba78fd	3554	// figure the address - this is the highest flash address where the
mjr	35:e959ffba78fd	3555	// structure will fit with the start aligned on a sector boundary
mjr	35:e959ffba78fd	3556	addr = iap.flash_size() - (numSectors * SECTOR_SIZE);
mjr	35:e959ffba78fd	3557
mjr	35:e959ffba78fd	3558	// return the address as a pointer
mjr	35:e959ffba78fd	3559	return (NVM *)addr;
mjr	35:e959ffba78fd	3560	}
mjr	35:e959ffba78fd	3561
mjr	35:e959ffba78fd	3562	// figure the flash address as a pointer
mjr	35:e959ffba78fd	3563	NVM *configFlashAddr()
mjr	35:e959ffba78fd	3564	{
mjr	35:e959ffba78fd	3565	int addr, numSectors;
mjr	35:e959ffba78fd	3566	return configFlashAddr(addr, numSectors);
mjr	35:e959ffba78fd	3567	}
mjr	35:e959ffba78fd	3568
mjr	35:e959ffba78fd	3569	// Load the config from flash
mjr	35:e959ffba78fd	3570	void loadConfigFromFlash()
mjr	35:e959ffba78fd	3571	{
mjr	35:e959ffba78fd	3572	// We want to use the KL25Z's on-board flash to store our configuration
mjr	35:e959ffba78fd	3573	// data persistently, so that we can restore it across power cycles.
mjr	35:e959ffba78fd	3574	// Unfortunatly, the mbed platform doesn't explicitly support this.
mjr	35:e959ffba78fd	3575	// mbed treats the on-board flash as a raw storage device for linker
mjr	35:e959ffba78fd	3576	// output, and assumes that the linker output is the only thing
mjr	35:e959ffba78fd	3577	// stored there. There's no file system and no allowance for shared
mjr	35:e959ffba78fd	3578	// use for other purposes. Fortunately, the linker ues the space in
mjr	35:e959ffba78fd	3579	// the obvious way, storing the entire linked program in a contiguous
mjr	35:e959ffba78fd	3580	// block starting at the lowest flash address. This means that the
mjr	35:e959ffba78fd	3581	// rest of flash - from the end of the linked program to the highest
mjr	35:e959ffba78fd	3582	// flash address - is all unused free space. Writing our data there
mjr	35:e959ffba78fd	3583	// won't conflict with anything else. Since the linker doesn't give
mjr	35:e959ffba78fd	3584	// us any programmatic access to the total linker output size, it's
mjr	35:e959ffba78fd	3585	// safest to just store our config data at the very end of the flash
mjr	35:e959ffba78fd	3586	// region (i.e., the highest address). As long as it's smaller than
mjr	35:e959ffba78fd	3587	// the free space, it won't collide with the linker area.
mjr	35:e959ffba78fd	3588
mjr	35:e959ffba78fd	3589	// Figure how many sectors we need for our structure
mjr	35:e959ffba78fd	3590	NVM *flash = configFlashAddr();
mjr	35:e959ffba78fd	3591
mjr	35:e959ffba78fd	3592	// if the flash is valid, load it; otherwise initialize to defaults
mjr	35:e959ffba78fd	3593	if (flash->valid())
mjr	35:e959ffba78fd	3594	{
mjr	35:e959ffba78fd	3595	// flash is valid - load it into the RAM copy of the structure
mjr	35:e959ffba78fd	3596	memcpy(&nvm, flash, sizeof(NVM));
mjr	35:e959ffba78fd	3597	}
mjr	35:e959ffba78fd	3598	else
mjr	35:e959ffba78fd	3599	{
mjr	35:e959ffba78fd	3600	// flash is invalid - load factory settings nito RAM structure
mjr	35:e959ffba78fd	3601	cfg.setFactoryDefaults();
mjr	35:e959ffba78fd	3602	}
mjr	35:e959ffba78fd	3603	}
mjr	35:e959ffba78fd	3604
mjr	35:e959ffba78fd	3605	void saveConfigToFlash()
mjr	33:d832bcab089e	3606	{
mjr	35:e959ffba78fd	3607	int addr, sectors;
mjr	35:e959ffba78fd	3608	configFlashAddr(addr, sectors);
mjr	35:e959ffba78fd	3609	nvm.save(iap, addr);
mjr	35:e959ffba78fd	3610	}
mjr	35:e959ffba78fd	3611
mjr	35:e959ffba78fd	3612	// ---------------------------------------------------------------------------
mjr	35:e959ffba78fd	3613	//
mjr	55:4db125cd11a0	3614	// Pixel dump mode - the host requested a dump of image sensor pixels
mjr	55:4db125cd11a0	3615	// (helpful for installing and setting up the sensor and light source)
mjr	55:4db125cd11a0	3616	//
mjr	55:4db125cd11a0	3617	bool reportPlungerStat = false;
mjr	55:4db125cd11a0	3618	uint8_t reportPlungerStatFlags; // plunger pixel report flag bits (see ccdSensor.h)
mjr	55:4db125cd11a0	3619	uint8_t reportPlungerStatTime; // extra exposure time for plunger pixel report
mjr	55:4db125cd11a0	3620
mjr	55:4db125cd11a0	3621
mjr	55:4db125cd11a0	3622
mjr	55:4db125cd11a0	3623	// ---------------------------------------------------------------------------
mjr	55:4db125cd11a0	3624	//
mjr	40:cc0d9814522b	3625	// Night mode setting updates
mjr	40:cc0d9814522b	3626	//
mjr	38:091e511ce8a0	3627
mjr	38:091e511ce8a0	3628	// Turn night mode on or off
mjr	38:091e511ce8a0	3629	static void setNightMode(bool on)
mjr	38:091e511ce8a0	3630	{
mjr	40:cc0d9814522b	3631	// set the new night mode flag in the noisy output class
mjr	53:9b2611964afc	3632	nightMode = on;
mjr	55:4db125cd11a0	3633
mjr	40:cc0d9814522b	3634	// update the special output pin that shows the night mode state
mjr	53:9b2611964afc	3635	int port = int(cfg.nightMode.port) - 1;
mjr	53:9b2611964afc	3636	if (port >= 0 && port < numOutputs)
mjr	53:9b2611964afc	3637	lwPin[port]->set(nightMode ? 255 : 0);
mjr	40:cc0d9814522b	3638
mjr	40:cc0d9814522b	3639	// update all outputs for the mode change
mjr	40:cc0d9814522b	3640	updateAllOuts();
mjr	38:091e511ce8a0	3641	}
mjr	38:091e511ce8a0	3642
mjr	38:091e511ce8a0	3643	// Toggle night mode
mjr	38:091e511ce8a0	3644	static void toggleNightMode()
mjr	38:091e511ce8a0	3645	{
mjr	53:9b2611964afc	3646	setNightMode(!nightMode);
mjr	38:091e511ce8a0	3647	}
mjr	38:091e511ce8a0	3648
mjr	38:091e511ce8a0	3649
mjr	38:091e511ce8a0	3650	// ---------------------------------------------------------------------------
mjr	38:091e511ce8a0	3651	//
mjr	35:e959ffba78fd	3652	// Plunger Sensor
mjr	35:e959ffba78fd	3653	//
mjr	35:e959ffba78fd	3654
mjr	35:e959ffba78fd	3655	// the plunger sensor interface object
mjr	35:e959ffba78fd	3656	PlungerSensor *plungerSensor = 0;
mjr	35:e959ffba78fd	3657
mjr	35:e959ffba78fd	3658	// Create the plunger sensor based on the current configuration. If
mjr	35:e959ffba78fd	3659	// there's already a sensor object, we'll delete it.
mjr	35:e959ffba78fd	3660	void createPlunger()
mjr	35:e959ffba78fd	3661	{
mjr	35:e959ffba78fd	3662	// create the new sensor object according to the type
mjr	35:e959ffba78fd	3663	switch (cfg.plunger.sensorType)
mjr	35:e959ffba78fd	3664	{
mjr	35:e959ffba78fd	3665	case PlungerType_TSL1410RS:
mjr	69:cc5039284fac	3666	// TSL1410R, serial mode (all pixels read in one file)
mjr	35:e959ffba78fd	3667	// pins are: SI, CLOCK, AO
mjr	53:9b2611964afc	3668	plungerSensor = new PlungerSensorTSL1410R(
mjr	53:9b2611964afc	3669	wirePinName(cfg.plunger.sensorPin[0]),
mjr	53:9b2611964afc	3670	wirePinName(cfg.plunger.sensorPin[1]),
mjr	53:9b2611964afc	3671	wirePinName(cfg.plunger.sensorPin[2]),
mjr	53:9b2611964afc	3672	NC);
mjr	35:e959ffba78fd	3673	break;
mjr	35:e959ffba78fd	3674
mjr	35:e959ffba78fd	3675	case PlungerType_TSL1410RP:
mjr	69:cc5039284fac	3676	// TSL1410R, parallel mode (each half-sensor's pixels read separately)
mjr	35:e959ffba78fd	3677	// pins are: SI, CLOCK, AO1, AO2
mjr	53:9b2611964afc	3678	plungerSensor = new PlungerSensorTSL1410R(
mjr	53:9b2611964afc	3679	wirePinName(cfg.plunger.sensorPin[0]),
mjr	53:9b2611964afc	3680	wirePinName(cfg.plunger.sensorPin[1]),
mjr	53:9b2611964afc	3681	wirePinName(cfg.plunger.sensorPin[2]),
mjr	53:9b2611964afc	3682	wirePinName(cfg.plunger.sensorPin[3]));
mjr	35:e959ffba78fd	3683	break;
mjr	35:e959ffba78fd	3684
mjr	69:cc5039284fac	3685	case PlungerType_TSL1412SS:
mjr	69:cc5039284fac	3686	// TSL1412S, serial mode
mjr	35:e959ffba78fd	3687	// pins are: SI, CLOCK, AO1, AO2
mjr	53:9b2611964afc	3688	plungerSensor = new PlungerSensorTSL1412R(
mjr	53:9b2611964afc	3689	wirePinName(cfg.plunger.sensorPin[0]),
mjr	53:9b2611964afc	3690	wirePinName(cfg.plunger.sensorPin[1]),
mjr	53:9b2611964afc	3691	wirePinName(cfg.plunger.sensorPin[2]),
mjr	53:9b2611964afc	3692	NC);
mjr	35:e959ffba78fd	3693	break;
mjr	35:e959ffba78fd	3694
mjr	69:cc5039284fac	3695	case PlungerType_TSL1412SP:
mjr	69:cc5039284fac	3696	// TSL1412S, parallel mode
mjr	35:e959ffba78fd	3697	// pins are: SI, CLOCK, AO1, AO2
mjr	53:9b2611964afc	3698	plungerSensor = new PlungerSensorTSL1412R(
mjr	53:9b2611964afc	3699	wirePinName(cfg.plunger.sensorPin[0]),
mjr	53:9b2611964afc	3700	wirePinName(cfg.plunger.sensorPin[1]),
mjr	53:9b2611964afc	3701	wirePinName(cfg.plunger.sensorPin[2]),
mjr	53:9b2611964afc	3702	wirePinName(cfg.plunger.sensorPin[3]));
mjr	35:e959ffba78fd	3703	break;
mjr	35:e959ffba78fd	3704
mjr	35:e959ffba78fd	3705	case PlungerType_Pot:
mjr	35:e959ffba78fd	3706	// pins are: AO
mjr	53:9b2611964afc	3707	plungerSensor = new PlungerSensorPot(
mjr	53:9b2611964afc	3708	wirePinName(cfg.plunger.sensorPin[0]));
mjr	35:e959ffba78fd	3709	break;
mjr	35:e959ffba78fd	3710
mjr	35:e959ffba78fd	3711	case PlungerType_None:
mjr	35:e959ffba78fd	3712	default:
mjr	35:e959ffba78fd	3713	plungerSensor = new PlungerSensorNull();
mjr	35:e959ffba78fd	3714	break;
mjr	35:e959ffba78fd	3715	}
mjr	33:d832bcab089e	3716	}
mjr	33:d832bcab089e	3717
mjr	52:8298b2a73eb2	3718	// Global plunger calibration mode flag
mjr	52:8298b2a73eb2	3719	bool plungerCalMode;
mjr	52:8298b2a73eb2	3720
mjr	48:058ace2aed1d	3721	// Plunger reader
mjr	51:57eb311faafa	3722	//
mjr	51:57eb311faafa	3723	// This class encapsulates our plunger data processing. At the simplest
mjr	51:57eb311faafa	3724	// level, we read the position from the sensor, adjust it for the
mjr	51:57eb311faafa	3725	// calibration settings, and report the calibrated position to the host.
mjr	51:57eb311faafa	3726	//
mjr	51:57eb311faafa	3727	// In addition, we constantly monitor the data for "firing" motions.
mjr	51:57eb311faafa	3728	// A firing motion is when the user pulls back the plunger and releases
mjr	51:57eb311faafa	3729	// it, allowing it to shoot forward under the force of the main spring.
mjr	51:57eb311faafa	3730	// When we detect that this is happening, we briefly stop reporting the
mjr	51:57eb311faafa	3731	// real physical position that we're reading from the sensor, and instead
mjr	51:57eb311faafa	3732	// report a synthetic series of positions that depicts an idealized
mjr	51:57eb311faafa	3733	// firing motion.
mjr	51:57eb311faafa	3734	//
mjr	51:57eb311faafa	3735	// The point of the synthetic reports is to correct for distortions
mjr	51:57eb311faafa	3736	// created by the joystick interface conventions used by VP and other
mjr	51:57eb311faafa	3737	// PC pinball emulators. The convention they use is simply to have the
mjr	51:57eb311faafa	3738	// plunger device report the instantaneous position of the real plunger.
mjr	51:57eb311faafa	3739	// The PC software polls this reported position periodically, and moves
mjr	51:57eb311faafa	3740	// the on-screen virtual plunger in sync with the real plunger. This
mjr	51:57eb311faafa	3741	// works fine for human-scale motion when the user is manually moving
mjr	51:57eb311faafa	3742	// the plunger. But it doesn't work for the high speed motion of a
mjr	51:57eb311faafa	3743	// release. The plunger simply moves too fast. VP polls in about 10ms
mjr	51:57eb311faafa	3744	// intervals; the plunger takes about 50ms to travel from fully
mjr	51:57eb311faafa	3745	// retracted to the park position when released. The low sampling
mjr	51:57eb311faafa	3746	// rate relative to the rate of change of the sampled data creates
mjr	51:57eb311faafa	3747	// a classic digital aliasing effect.
mjr	51:57eb311faafa	3748	//
mjr	51:57eb311faafa	3749	// The synthetic reporting scheme compensates for the interface
mjr	51:57eb311faafa	3750	// distortions by essentially changing to a coarse enough timescale
mjr	51:57eb311faafa	3751	// that VP can reliably interpret the readings. Conceptually, there
mjr	51:57eb311faafa	3752	// are three steps involved in doing this. First, we analyze the
mjr	51:57eb311faafa	3753	// actual sensor data to detect and characterize the release motion.
mjr	51:57eb311faafa	3754	// Second, once we think we have a release in progress, we fit the
mjr	51:57eb311faafa	3755	// data to a mathematical model of the release. The model we use is
mjr	51:57eb311faafa	3756	// dead simple: we consider the release to have one parameter, namely
mjr	51:57eb311faafa	3757	// the retraction distance at the moment the user lets go. This is an
mjr	51:57eb311faafa	3758	// excellent proxy in the real physical system for the final speed
mjr	51:57eb311faafa	3759	// when the plunger hits the ball, and it also happens to match how
mjr	51:57eb311faafa	3760	// VP models it internally. Third, we construct synthetic reports
mjr	51:57eb311faafa	3761	// that will make VP's internal state match our model. This is also
mjr	51:57eb311faafa	3762	// pretty simple: we just need to send VP the maximum retraction
mjr	51:57eb311faafa	3763	// distance for long enough to be sure that it polls it at least
mjr	51:57eb311faafa	3764	// once, and then send it the park position for long enough to
mjr	51:57eb311faafa	3765	// ensure that VP will complete the same firing motion. The
mjr	51:57eb311faafa	3766	// immediate jump from the maximum point to the zero point will
mjr	51:57eb311faafa	3767	// cause VP to move its simulation model plunger forward from the
mjr	51:57eb311faafa	3768	// starting point at its natural spring acceleration rate, which
mjr	51:57eb311faafa	3769	// is exactly what the real plunger just did.
mjr	51:57eb311faafa	3770	//
mjr	48:058ace2aed1d	3771	class PlungerReader
mjr	48:058ace2aed1d	3772	{
mjr	48:058ace2aed1d	3773	public:
mjr	48:058ace2aed1d	3774	PlungerReader()
mjr	48:058ace2aed1d	3775	{
mjr	48:058ace2aed1d	3776	// not in a firing event yet
mjr	48:058ace2aed1d	3777	firing = 0;
mjr	48:058ace2aed1d	3778
mjr	48:058ace2aed1d	3779	// no history yet
mjr	48:058ace2aed1d	3780	histIdx = 0;
mjr	55:4db125cd11a0	3781
mjr	55:4db125cd11a0	3782	// initialize the filter
mjr	55:4db125cd11a0	3783	initFilter();
mjr	48:058ace2aed1d	3784	}
mjr	48:058ace2aed1d	3785
mjr	48:058ace2aed1d	3786	// Collect a reading from the plunger sensor. The main loop calls
mjr	48:058ace2aed1d	3787	// this frequently to read the current raw position data from the
mjr	48:058ace2aed1d	3788	// sensor. We analyze the raw data to produce the calibrated
mjr	48:058ace2aed1d	3789	// position that we report to the PC via the joystick interface.
mjr	48:058ace2aed1d	3790	void read()
mjr	48:058ace2aed1d	3791	{
mjr	48:058ace2aed1d	3792	// Read a sample from the sensor
mjr	48:058ace2aed1d	3793	PlungerReading r;
mjr	48:058ace2aed1d	3794	if (plungerSensor->read(r))
mjr	48:058ace2aed1d	3795	{
mjr	69:cc5039284fac	3796	// filter the raw sensor reading
mjr	69:cc5039284fac	3797	applyPreFilter(r);
mjr	69:cc5039284fac	3798
mjr	51:57eb311faafa	3799	// Pull the previous reading from the history
mjr	50:40015764bbe6	3800	const PlungerReading &prv = nthHist(0);
mjr	48:058ace2aed1d	3801
mjr	69:cc5039284fac	3802	// If the new reading is within 1ms of the previous reading,
mjr	48:058ace2aed1d	3803	// ignore it. We require a minimum time between samples to
mjr	48:058ace2aed1d	3804	// ensure that we have a usable amount of precision in the
mjr	48:058ace2aed1d	3805	// denominator (the time interval) for calculating the plunger
mjr	69:cc5039284fac	3806	// velocity. The CCD sensor hardware takes about 2.5ms to
mjr	69:cc5039284fac	3807	// read, so it will never be affected by this, but other sensor
mjr	69:cc5039284fac	3808	// types don't all have the same hardware cycle time, so we need
mjr	69:cc5039284fac	3809	// to throttle them artificially. E.g., the potentiometer only
mjr	69:cc5039284fac	3810	// needs one ADC sample per reading, which only takes about 15us.
mjr	69:cc5039284fac	3811	// We don't need to check which sensor type we have here; we
mjr	69:cc5039284fac	3812	// just ignore readings until the minimum interval has passed,
mjr	69:cc5039284fac	3813	// so if the sensor is already slower than this, we'll end up
mjr	69:cc5039284fac	3814	// using all of its readings.
mjr	69:cc5039284fac	3815	if (uint32_t(r.t - prv.t) < 1000UL)
mjr	48:058ace2aed1d	3816	return;
mjr	53:9b2611964afc	3817
mjr	53:9b2611964afc	3818	// check for calibration mode
mjr	53:9b2611964afc	3819	if (plungerCalMode)
mjr	53:9b2611964afc	3820	{
mjr	53:9b2611964afc	3821	// Calibration mode. Adjust the calibration bounds to fit
mjr	53:9b2611964afc	3822	// the value. If this value is beyond the current min or max,
mjr	53:9b2611964afc	3823	// expand the envelope to include this new value.
mjr	53:9b2611964afc	3824	if (r.pos > cfg.plunger.cal.max)
mjr	53:9b2611964afc	3825	cfg.plunger.cal.max = r.pos;
mjr	53:9b2611964afc	3826	if (r.pos < cfg.plunger.cal.min)
mjr	53:9b2611964afc	3827	cfg.plunger.cal.min = r.pos;
mjr	50:40015764bbe6	3828
mjr	53:9b2611964afc	3829	// If we're in calibration state 0, we're waiting for the
mjr	53:9b2611964afc	3830	// plunger to come to rest at the park position so that we
mjr	53:9b2611964afc	3831	// can take a sample of the park position. Check to see if
mjr	53:9b2611964afc	3832	// we've been at rest for a minimum interval.
mjr	53:9b2611964afc	3833	if (calState == 0)
mjr	53:9b2611964afc	3834	{
mjr	53:9b2611964afc	3835	if (abs(r.pos - calZeroStart.pos) < 65535/3/50)
mjr	53:9b2611964afc	3836	{
mjr	53:9b2611964afc	3837	// we're close enough - make sure we've been here long enough
mjr	53:9b2611964afc	3838	if (uint32_t(r.t - calZeroStart.t) > 100000UL)
mjr	53:9b2611964afc	3839	{
mjr	53:9b2611964afc	3840	// we've been at rest long enough - count it
mjr	53:9b2611964afc	3841	calZeroPosSum += r.pos;
mjr	53:9b2611964afc	3842	calZeroPosN += 1;
mjr	53:9b2611964afc	3843
mjr	53:9b2611964afc	3844	// update the zero position from the new average
mjr	53:9b2611964afc	3845	cfg.plunger.cal.zero = uint16_t(calZeroPosSum / calZeroPosN);
mjr	53:9b2611964afc	3846
mjr	53:9b2611964afc	3847	// switch to calibration state 1 - at rest
mjr	53:9b2611964afc	3848	calState = 1;
mjr	53:9b2611964afc	3849	}
mjr	53:9b2611964afc	3850	}
mjr	53:9b2611964afc	3851	else
mjr	53:9b2611964afc	3852	{
mjr	53:9b2611964afc	3853	// we're not close to the last position - start again here
mjr	53:9b2611964afc	3854	calZeroStart = r;
mjr	53:9b2611964afc	3855	}
mjr	53:9b2611964afc	3856	}
mjr	53:9b2611964afc	3857
mjr	53:9b2611964afc	3858	// Rescale to the joystick range, and adjust for the current
mjr	53:9b2611964afc	3859	// park position, but don't calibrate. We don't know the maximum
mjr	53:9b2611964afc	3860	// point yet, so we can't calibrate the range.
mjr	53:9b2611964afc	3861	r.pos = int(
mjr	53:9b2611964afc	3862	(long(r.pos - cfg.plunger.cal.zero) * JOYMAX)
mjr	53:9b2611964afc	3863	/ (65535 - cfg.plunger.cal.zero));
mjr	53:9b2611964afc	3864	}
mjr	53:9b2611964afc	3865	else
mjr	53:9b2611964afc	3866	{
mjr	53:9b2611964afc	3867	// Not in calibration mode. Apply the existing calibration and
mjr	53:9b2611964afc	3868	// rescale to the joystick range.
mjr	53:9b2611964afc	3869	r.pos = int(
mjr	53:9b2611964afc	3870	(long(r.pos - cfg.plunger.cal.zero) * JOYMAX)
mjr	53:9b2611964afc	3871	/ (cfg.plunger.cal.max - cfg.plunger.cal.zero));
mjr	53:9b2611964afc	3872
mjr	53:9b2611964afc	3873	// limit the result to the valid joystick range
mjr	53:9b2611964afc	3874	if (r.pos > JOYMAX)
mjr	53:9b2611964afc	3875	r.pos = JOYMAX;
mjr	53:9b2611964afc	3876	else if (r.pos < -JOYMAX)
mjr	53:9b2611964afc	3877	r.pos = -JOYMAX;
mjr	53:9b2611964afc	3878	}
mjr	50:40015764bbe6	3879
mjr	50:40015764bbe6	3880	// Calculate the velocity from the second-to-last reading
mjr	50:40015764bbe6	3881	// to here, in joystick distance units per microsecond.
mjr	50:40015764bbe6	3882	// Note that we use the second-to-last reading rather than
mjr	50:40015764bbe6	3883	// the very last reading to give ourselves a little longer
mjr	50:40015764bbe6	3884	// time base. The time base is so short between consecutive
mjr	50:40015764bbe6	3885	// readings that the error bars in the position would be too
mjr	50:40015764bbe6	3886	// large.
mjr	50:40015764bbe6	3887	//
mjr	50:40015764bbe6	3888	// For reference, the physical plunger velocity ranges up
mjr	50:40015764bbe6	3889	// to about 100,000 joystick distance units/sec. This is
mjr	50:40015764bbe6	3890	// based on empirical measurements. The typical time for
mjr	50:40015764bbe6	3891	// a real plunger to travel the full distance when released
mjr	50:40015764bbe6	3892	// from full retraction is about 85ms, so the average velocity
mjr	50:40015764bbe6	3893	// covering this distance is about 56,000 units/sec. The
mjr	50:40015764bbe6	3894	// peak is probably about twice that. In real-world units,
mjr	50:40015764bbe6	3895	// this translates to an average speed of about .75 m/s and
mjr	50:40015764bbe6	3896	// a peak of about 1.5 m/s.
mjr	50:40015764bbe6	3897	//
mjr	50:40015764bbe6	3898	// Note that we actually calculate the value here in units
mjr	50:40015764bbe6	3899	// per microsecond - the discussion above is in terms of
mjr	50:40015764bbe6	3900	// units/sec because that's more on a human scale. Our
mjr	50:40015764bbe6	3901	// choice of internal units here really isn't important,
mjr	50:40015764bbe6	3902	// since we only use the velocity for comparison purposes,
mjr	50:40015764bbe6	3903	// to detect acceleration trends. We therefore save ourselves
mjr	50:40015764bbe6	3904	// a little CPU time by using the natural units of our inputs.
mjr	51:57eb311faafa	3905	const PlungerReading &prv2 = nthHist(1);
mjr	50:40015764bbe6	3906	float v = float(r.pos - prv2.pos)/float(r.t - prv2.t);
mjr	50:40015764bbe6	3907
mjr	50:40015764bbe6	3908	// presume we'll report the latest instantaneous reading
mjr	50:40015764bbe6	3909	z = r.pos;
mjr	50:40015764bbe6	3910	vz = v;
mjr	48:058ace2aed1d	3911
mjr	50:40015764bbe6	3912	// Check firing events
mjr	50:40015764bbe6	3913	switch (firing)
mjr	50:40015764bbe6	3914	{
mjr	50:40015764bbe6	3915	case 0:
mjr	50:40015764bbe6	3916	// Default state - not in a firing event.
mjr	50:40015764bbe6	3917
mjr	50:40015764bbe6	3918	// If we have forward motion from a position that's retracted
mjr	50:40015764bbe6	3919	// beyond a threshold, enter phase 1. If we're not pulled back
mjr	50:40015764bbe6	3920	// far enough, don't bother with this, as a release wouldn't
mjr	50:40015764bbe6	3921	// be strong enough to require the synthetic firing treatment.
mjr	50:40015764bbe6	3922	if (v < 0 && r.pos > JOYMAX/6)
mjr	50:40015764bbe6	3923	{
mjr	53:9b2611964afc	3924	// enter firing phase 1
mjr	50:40015764bbe6	3925	firingMode(1);
mjr	50:40015764bbe6	3926
mjr	53:9b2611964afc	3927	// if in calibration state 1 (at rest), switch to state 2 (not
mjr	53:9b2611964afc	3928	// at rest)
mjr	53:9b2611964afc	3929	if (calState == 1)
mjr	53:9b2611964afc	3930	calState = 2;
mjr	53:9b2611964afc	3931
mjr	50:40015764bbe6	3932	// we don't have a freeze position yet, but note the start time
mjr	50:40015764bbe6	3933	f1.pos = 0;
mjr	50:40015764bbe6	3934	f1.t = r.t;
mjr	50:40015764bbe6	3935
mjr	50:40015764bbe6	3936	// Figure the barrel spring "bounce" position in case we complete
mjr	50:40015764bbe6	3937	// the firing event. This is the amount that the forward momentum
mjr	50:40015764bbe6	3938	// of the plunger will compress the barrel spring at the peak of
mjr	50:40015764bbe6	3939	// the forward travel during the release. Assume that this is
mjr	50:40015764bbe6	3940	// linearly proportional to the starting retraction distance.
mjr	50:40015764bbe6	3941	// The barrel spring is about 1/6 the length of the main spring,
mjr	50:40015764bbe6	3942	// so figure it compresses by 1/6 the distance. (This is overly
mjr	53:9b2611964afc	3943	// simplistic and not very accurate, but it seems to give good
mjr	50:40015764bbe6	3944	// visual results, and that's all it's for.)
mjr	50:40015764bbe6	3945	f2.pos = -r.pos/6;
mjr	50:40015764bbe6	3946	}
mjr	50:40015764bbe6	3947	break;
mjr	50:40015764bbe6	3948
mjr	50:40015764bbe6	3949	case 1:
mjr	50:40015764bbe6	3950	// Phase 1 - acceleration. If we cross the zero point, trigger
mjr	50:40015764bbe6	3951	// the firing event. Otherwise, continue monitoring as long as we
mjr	50:40015764bbe6	3952	// see acceleration in the forward direction.
mjr	50:40015764bbe6	3953	if (r.pos <= 0)
mjr	50:40015764bbe6	3954	{
mjr	50:40015764bbe6	3955	// switch to the synthetic firing mode
mjr	50:40015764bbe6	3956	firingMode(2);
mjr	50:40015764bbe6	3957	z = f2.pos;
mjr	50:40015764bbe6	3958
mjr	50:40015764bbe6	3959	// note the start time for the firing phase
mjr	50:40015764bbe6	3960	f2.t = r.t;
mjr	53:9b2611964afc	3961
mjr	53:9b2611964afc	3962	// if in calibration mode, and we're in state 2 (moving),
mjr	53:9b2611964afc	3963	// collect firing statistics for calibration purposes
mjr	53:9b2611964afc	3964	if (plungerCalMode && calState == 2)
mjr	53:9b2611964afc	3965	{
mjr	53:9b2611964afc	3966	// collect a new zero point for the average when we
mjr	53:9b2611964afc	3967	// come to rest
mjr	53:9b2611964afc	3968	calState = 0;
mjr	53:9b2611964afc	3969
mjr	53:9b2611964afc	3970	// collect average firing time statistics in millseconds, if
mjr	53:9b2611964afc	3971	// it's in range (20 to 255 ms)
mjr	53:9b2611964afc	3972	int dt = uint32_t(r.t - f1.t)/1000UL;
mjr	53:9b2611964afc	3973	if (dt >= 20 && dt <= 255)
mjr	53:9b2611964afc	3974	{
mjr	53:9b2611964afc	3975	calRlsTimeSum += dt;
mjr	53:9b2611964afc	3976	calRlsTimeN += 1;
mjr	53:9b2611964afc	3977	cfg.plunger.cal.tRelease = uint8_t(calRlsTimeSum / calRlsTimeN);
mjr	53:9b2611964afc	3978	}
mjr	53:9b2611964afc	3979	}
mjr	50:40015764bbe6	3980	}
mjr	50:40015764bbe6	3981	else if (v < vprv2)
mjr	50:40015764bbe6	3982	{
mjr	50:40015764bbe6	3983	// We're still accelerating, and we haven't crossed the zero
mjr	50:40015764bbe6	3984	// point yet - stay in phase 1. (Note that forward motion is
mjr	50:40015764bbe6	3985	// negative velocity, so accelerating means that the new
mjr	50:40015764bbe6	3986	// velocity is more negative than the previous one, which
mjr	50:40015764bbe6	3987	// is to say numerically less than - that's why the test
mjr	50:40015764bbe6	3988	// for acceleration is the seemingly backwards 'v < vprv'.)
mjr	50:40015764bbe6	3989
mjr	50:40015764bbe6	3990	// If we've been accelerating for at least 20ms, we're probably
mjr	50:40015764bbe6	3991	// really doing a release. Jump back to the recent local
mjr	50:40015764bbe6	3992	// maximum where the release really started. This is always
mjr	50:40015764bbe6	3993	// a bit before we started seeing sustained accleration, because
mjr	50:40015764bbe6	3994	// the plunger motion for the first few milliseconds is too slow
mjr	50:40015764bbe6	3995	// for our sensor precision to reliably detect acceleration.
mjr	50:40015764bbe6	3996	if (f1.pos != 0)
mjr	50:40015764bbe6	3997	{
mjr	50:40015764bbe6	3998	// we have a reset point - freeze there
mjr	50:40015764bbe6	3999	z = f1.pos;
mjr	50:40015764bbe6	4000	}
mjr	50:40015764bbe6	4001	else if (uint32_t(r.t - f1.t) >= 20000UL)
mjr	50:40015764bbe6	4002	{
mjr	50:40015764bbe6	4003	// it's been long enough - set a reset point.
mjr	50:40015764bbe6	4004	f1.pos = z = histLocalMax(r.t, 50000UL);
mjr	50:40015764bbe6	4005	}
mjr	50:40015764bbe6	4006	}
mjr	50:40015764bbe6	4007	else
mjr	50:40015764bbe6	4008	{
mjr	50:40015764bbe6	4009	// We're not accelerating. Cancel the firing event.
mjr	50:40015764bbe6	4010	firingMode(0);
mjr	53:9b2611964afc	4011	calState = 1;
mjr	50:40015764bbe6	4012	}
mjr	50:40015764bbe6	4013	break;
mjr	50:40015764bbe6	4014
mjr	50:40015764bbe6	4015	case 2:
mjr	50:40015764bbe6	4016	// Phase 2 - start of synthetic firing event. Report the fake
mjr	50:40015764bbe6	4017	// bounce for 25ms. VP polls the joystick about every 10ms, so
mjr	50:40015764bbe6	4018	// this should be enough time to guarantee that VP sees this
mjr	50:40015764bbe6	4019	// report at least once.
mjr	50:40015764bbe6	4020	if (uint32_t(r.t - f2.t) < 25000UL)
mjr	50:40015764bbe6	4021	{
mjr	50:40015764bbe6	4022	// report the bounce position
mjr	50:40015764bbe6	4023	z = f2.pos;
mjr	50:40015764bbe6	4024	}
mjr	50:40015764bbe6	4025	else
mjr	50:40015764bbe6	4026	{
mjr	50:40015764bbe6	4027	// it's been long enough - switch to phase 3, where we
mjr	50:40015764bbe6	4028	// report the park position until the real plunger comes
mjr	50:40015764bbe6	4029	// to rest
mjr	50:40015764bbe6	4030	firingMode(3);
mjr	50:40015764bbe6	4031	z = 0;
mjr	50:40015764bbe6	4032
mjr	50:40015764bbe6	4033	// set the start of the "stability window" to the rest position
mjr	50:40015764bbe6	4034	f3s.t = r.t;
mjr	50:40015764bbe6	4035	f3s.pos = 0;
mjr	50:40015764bbe6	4036
mjr	50:40015764bbe6	4037	// set the start of the "retraction window" to the actual position
mjr	50:40015764bbe6	4038	f3r = r;
mjr	50:40015764bbe6	4039	}
mjr	50:40015764bbe6	4040	break;
mjr	50:40015764bbe6	4041
mjr	50:40015764bbe6	4042	case 3:
mjr	50:40015764bbe6	4043	// Phase 3 - in synthetic firing event. Report the park position
mjr	50:40015764bbe6	4044	// until the plunger position stabilizes. Left to its own devices,
mjr	50:40015764bbe6	4045	// the plunger will usualy bounce off the barrel spring several
mjr	50:40015764bbe6	4046	// times before coming to rest, so we'll see oscillating motion
mjr	50:40015764bbe6	4047	// for a second or two. In the simplest case, we can aimply wait
mjr	50:40015764bbe6	4048	// for the plunger to stop moving for a short time. However, the
mjr	50:40015764bbe6	4049	// player might intervene by pulling the plunger back again, so
mjr	50:40015764bbe6	4050	// watch for that motion as well. If we're just bouncing freely,
mjr	50:40015764bbe6	4051	// we'll see the direction change frequently. If the player is
mjr	50:40015764bbe6	4052	// moving the plunger manually, the direction will be constant
mjr	50:40015764bbe6	4053	// for longer.
mjr	50:40015764bbe6	4054	if (v >= 0)
mjr	50:40015764bbe6	4055	{
mjr	50:40015764bbe6	4056	// We're moving back (or standing still). If this has been
mjr	50:40015764bbe6	4057	// going on for a while, the user must have taken control.
mjr	50:40015764bbe6	4058	if (uint32_t(r.t - f3r.t) > 65000UL)
mjr	50:40015764bbe6	4059	{
mjr	50:40015764bbe6	4060	// user has taken control - cancel firing mode
mjr	50:40015764bbe6	4061	firingMode(0);
mjr	50:40015764bbe6	4062	break;
mjr	50:40015764bbe6	4063	}
mjr	50:40015764bbe6	4064	}
mjr	50:40015764bbe6	4065	else
mjr	50:40015764bbe6	4066	{
mjr	50:40015764bbe6	4067	// forward motion - reset retraction window
mjr	50:40015764bbe6	4068	f3r.t = r.t;
mjr	50:40015764bbe6	4069	}
mjr	50:40015764bbe6	4070
mjr	53:9b2611964afc	4071	// Check if we're close to the last starting point. The joystick
mjr	53:9b2611964afc	4072	// positive axis range (0..4096) covers the retraction distance of
mjr	53:9b2611964afc	4073	// about 2.5", so 1" is about 1638 joystick units, hence 1/16" is
mjr	53:9b2611964afc	4074	// about 100 units.
mjr	53:9b2611964afc	4075	if (abs(r.pos - f3s.pos) < 100)
mjr	50:40015764bbe6	4076	{
mjr	53:9b2611964afc	4077	// It's at roughly the same position as the starting point.
mjr	53:9b2611964afc	4078	// Consider it stable if this has been true for 300ms.
mjr	50:40015764bbe6	4079	if (uint32_t(r.t - f3s.t) > 30000UL)
mjr	50:40015764bbe6	4080	{
mjr	50:40015764bbe6	4081	// we're done with the firing event
mjr	50:40015764bbe6	4082	firingMode(0);
mjr	50:40015764bbe6	4083	}
mjr	50:40015764bbe6	4084	else
mjr	50:40015764bbe6	4085	{
mjr	50:40015764bbe6	4086	// it's close to the last position but hasn't been
mjr	50:40015764bbe6	4087	// here long enough; stay in firing mode and continue
mjr	50:40015764bbe6	4088	// to report the park position
mjr	50:40015764bbe6	4089	z = 0;
mjr	50:40015764bbe6	4090	}
mjr	50:40015764bbe6	4091	}
mjr	50:40015764bbe6	4092	else
mjr	50:40015764bbe6	4093	{
mjr	50:40015764bbe6	4094	// It's not close enough to the last starting point, so use
mjr	50:40015764bbe6	4095	// this as a new starting point, and stay in firing mode.
mjr	50:40015764bbe6	4096	f3s = r;
mjr	50:40015764bbe6	4097	z = 0;
mjr	50:40015764bbe6	4098	}
mjr	50:40015764bbe6	4099	break;
mjr	50:40015764bbe6	4100	}
mjr	50:40015764bbe6	4101
mjr	50:40015764bbe6	4102	// save the velocity reading for next time
mjr	50:40015764bbe6	4103	vprv2 = vprv;
mjr	50:40015764bbe6	4104	vprv = v;
mjr	50:40015764bbe6	4105
mjr	50:40015764bbe6	4106	// add the new reading to the history
mjr	50:40015764bbe6	4107	hist[histIdx++] = r;
mjr	50:40015764bbe6	4108	histIdx %= countof(hist);
mjr	58:523fdcffbe6d	4109
mjr	69:cc5039284fac	4110	// apply the post-processing filter
mjr	69:cc5039284fac	4111	zf = applyPostFilter();
mjr	48:058ace2aed1d	4112	}
mjr	48:058ace2aed1d	4113	}
mjr	48:058ace2aed1d	4114
mjr	48:058ace2aed1d	4115	// Get the current value to report through the joystick interface
mjr	58:523fdcffbe6d	4116	int16_t getPosition()
mjr	58:523fdcffbe6d	4117	{
mjr	58:523fdcffbe6d	4118	// return the last filtered reading
mjr	58:523fdcffbe6d	4119	return zf;
mjr	55:4db125cd11a0	4120	}
mjr	58:523fdcffbe6d	4121
mjr	48:058ace2aed1d	4122	// Get the current velocity (joystick distance units per microsecond)
mjr	48:058ace2aed1d	4123	float getVelocity() const { return vz; }
mjr	48:058ace2aed1d	4124
mjr	48:058ace2aed1d	4125	// get the timestamp of the current joystick report (microseconds)
mjr	50:40015764bbe6	4126	uint32_t getTimestamp() const { return nthHist(0).t; }
mjr	48:058ace2aed1d	4127
mjr	48:058ace2aed1d	4128	// Set calibration mode on or off
mjr	52:8298b2a73eb2	4129	void setCalMode(bool f)
mjr	48:058ace2aed1d	4130	{
mjr	52:8298b2a73eb2	4131	// check to see if we're entering calibration mode
mjr	52:8298b2a73eb2	4132	if (f && !plungerCalMode)
mjr	52:8298b2a73eb2	4133	{
mjr	52:8298b2a73eb2	4134	// reset the calibration in the configuration
mjr	48:058ace2aed1d	4135	cfg.plunger.cal.begin();
mjr	52:8298b2a73eb2	4136
mjr	52:8298b2a73eb2	4137	// start in state 0 (waiting to settle)
mjr	52:8298b2a73eb2	4138	calState = 0;
mjr	52:8298b2a73eb2	4139	calZeroPosSum = 0;
mjr	52:8298b2a73eb2	4140	calZeroPosN = 0;
mjr	52:8298b2a73eb2	4141	calRlsTimeSum = 0;
mjr	52:8298b2a73eb2	4142	calRlsTimeN = 0;
mjr	52:8298b2a73eb2	4143
mjr	52:8298b2a73eb2	4144	// set the initial zero point to the current position
mjr	52:8298b2a73eb2	4145	PlungerReading r;
mjr	52:8298b2a73eb2	4146	if (plungerSensor->read(r))
mjr	52:8298b2a73eb2	4147	{
mjr	52:8298b2a73eb2	4148	// got a reading - use it as the initial zero point
mjr	69:cc5039284fac	4149	applyPreFilter(r);
mjr	52:8298b2a73eb2	4150	cfg.plunger.cal.zero = r.pos;
mjr	52:8298b2a73eb2	4151
mjr	52:8298b2a73eb2	4152	// use it as the starting point for the settling watch
mjr	53:9b2611964afc	4153	calZeroStart = r;
mjr	52:8298b2a73eb2	4154	}
mjr	52:8298b2a73eb2	4155	else
mjr	52:8298b2a73eb2	4156	{
mjr	52:8298b2a73eb2	4157	// no reading available - use the default 1/6 position
mjr	52:8298b2a73eb2	4158	cfg.plunger.cal.zero = 0xffff/6;
mjr	52:8298b2a73eb2	4159
mjr	52:8298b2a73eb2	4160	// we don't have a starting point for the setting watch
mjr	53:9b2611964afc	4161	calZeroStart.pos = -65535;
mjr	53:9b2611964afc	4162	calZeroStart.t = 0;
mjr	53:9b2611964afc	4163	}
mjr	53:9b2611964afc	4164	}
mjr	53:9b2611964afc	4165	else if (!f && plungerCalMode)
mjr	53:9b2611964afc	4166	{
mjr	53:9b2611964afc	4167	// Leaving calibration mode. Make sure the max is past the
mjr	53:9b2611964afc	4168	// zero point - if it's not, we'd have a zero or negative
mjr	53:9b2611964afc	4169	// denominator for the scaling calculation, which would be
mjr	53:9b2611964afc	4170	// physically meaningless.
mjr	53:9b2611964afc	4171	if (cfg.plunger.cal.max <= cfg.plunger.cal.zero)
mjr	53:9b2611964afc	4172	{
mjr	53:9b2611964afc	4173	// bad settings - reset to defaults
mjr	53:9b2611964afc	4174	cfg.plunger.cal.max = 0xffff;
mjr	53:9b2611964afc	4175	cfg.plunger.cal.zero = 0xffff/6;
mjr	52:8298b2a73eb2	4176	}
mjr	52:8298b2a73eb2	4177	}
mjr	52:8298b2a73eb2	4178
mjr	48:058ace2aed1d	4179	// remember the new mode
mjr	52:8298b2a73eb2	4180	plungerCalMode = f;
mjr	48:058ace2aed1d	4181	}
mjr	48:058ace2aed1d	4182
mjr	48:058ace2aed1d	4183	// is a firing event in progress?
mjr	53:9b2611964afc	4184	bool isFiring() { return firing == 3; }
mjr	48:058ace2aed1d	4185
mjr	48:058ace2aed1d	4186	private:
mjr	52:8298b2a73eb2	4187
mjr	74:822a92bc11d2	4188	// Plunger data filtering mode: optionally apply filtering to the raw
mjr	74:822a92bc11d2	4189	// plunger sensor readings to try to reduce noise in the signal. This
mjr	74:822a92bc11d2	4190	// is designed for the TSL1410/12 optical sensors, where essentially all
mjr	74:822a92bc11d2	4191	// of the noise in the signal comes from lack of sharpness in the shadow
mjr	74:822a92bc11d2	4192	// edge. When the shadow is blurry, the edge detector has to pick a pixel,
mjr	74:822a92bc11d2	4193	// even though the edge is actually a gradient spanning several pixels.
mjr	74:822a92bc11d2	4194	// The edge detection algorithm decides on the exact pixel, but whatever
mjr	74:822a92bc11d2	4195	// the algorithm, the choice is going to be somewhat arbitrary given that
mjr	74:822a92bc11d2	4196	// there's really no one pixel that's "the edge" when the edge actually
mjr	74:822a92bc11d2	4197	// covers multiple pixels. This can make the choice of pixel sensitive to
mjr	74:822a92bc11d2	4198	// small changes in exposure and pixel respose from frame to frame, which
mjr	74:822a92bc11d2	4199	// means that the reported edge position can move by a pixel or two from
mjr	74:822a92bc11d2	4200	// one frame to the next even when the physical plunger is perfectly still.
mjr	74:822a92bc11d2	4201	// That's the noise we're talking about.
mjr	74:822a92bc11d2	4202	//
mjr	74:822a92bc11d2	4203	// We previously applied a mild hysteresis filter to the signal to try to
mjr	74:822a92bc11d2	4204	// eliminate this noise. The filter tracked the average over the last
mjr	74:822a92bc11d2	4205	// several samples, and rejected readings that wandered within a few
mjr	74:822a92bc11d2	4206	// pixels of the average. If a certain number of readings moved away from
mjr	74:822a92bc11d2	4207	// the average in the same direction, even by small amounts, the filter
mjr	74:822a92bc11d2	4208	// accepted the changes, on the assumption that they represented actual
mjr	74:822a92bc11d2	4209	// slow movement of the plunger. This filter was applied after the firing
mjr	74:822a92bc11d2	4210	// detection.
mjr	74:822a92bc11d2	4211	//
mjr	74:822a92bc11d2	4212	// I also tried a simpler filter that rejected changes that were too fast
mjr	74:822a92bc11d2	4213	// to be physically possible, as well as changes that were very close to
mjr	74:822a92bc11d2	4214	// the last reported position (i.e., simple hysteresis). The "too fast"
mjr	74:822a92bc11d2	4215	// filter was there to reject spurious readings where the edge detector
mjr	74:822a92bc11d2	4216	// mistook a bad pixel value as an edge.
mjr	74:822a92bc11d2	4217	//
mjr	74:822a92bc11d2	4218	// The new "mode 2" edge detector (see ccdSensor.h) seems to do a better
mjr	74:822a92bc11d2	4219	// job of rejecting pixel-level noise by itself than the older "mode 0"
mjr	74:822a92bc11d2	4220	// algorithm did, so I removed the filtering entirely. Any filtering has
mjr	74:822a92bc11d2	4221	// some downsides, so it's better to reduce noise in the underlying signal
mjr	74:822a92bc11d2	4222	// as much as possible first. It seems possible to get a very stable signal
mjr	74:822a92bc11d2	4223	// now with a combination of the mode 2 edge detector and optimizing the
mjr	74:822a92bc11d2	4224	// physical sensor arrangement, especially optimizing the light source to
mjr	74:822a92bc11d2	4225	// cast as sharp as shadow as possible and adjusting the brightness to
mjr	74:822a92bc11d2	4226	// maximize bright/dark contrast in the image.
mjr	74:822a92bc11d2	4227	//
mjr	74:822a92bc11d2	4228	// 0 = No filtering (current default)
mjr	74:822a92bc11d2	4229	// 1 = Filter the data after firing detection using moving average
mjr	74:822a92bc11d2	4230	// hysteresis filter (old version, used in most 2016 releases)
mjr	74:822a92bc11d2	4231	// 2 = Filter the data before firing detection using simple hysteresis
mjr	74:822a92bc11d2	4232	// plus spurious "too fast" motion rejection
mjr	74:822a92bc11d2	4233	//
mjr	73:4e8ce0b18915	4234	#define PLUNGER_FILTERING_MODE 0
mjr	73:4e8ce0b18915	4235
mjr	73:4e8ce0b18915	4236	#if PLUNGER_FILTERING_MODE == 0
mjr	69:cc5039284fac	4237	// Disable all filtering
mjr	74:822a92bc11d2	4238	inline void applyPreFilter(PlungerReading &r) { }
mjr	74:822a92bc11d2	4239	inline int applyPostFilter() { return z; }
mjr	73:4e8ce0b18915	4240	#elif PLUNGER_FILTERING_MODE == 1
mjr	73:4e8ce0b18915	4241	// Apply pre-processing filter. This filter is applied to the raw
mjr	73:4e8ce0b18915	4242	// value coming off the sensor, before calibration or fire-event
mjr	73:4e8ce0b18915	4243	// processing.
mjr	73:4e8ce0b18915	4244	void applyPreFilter(PlungerReading &r)
mjr	73:4e8ce0b18915	4245	{
mjr	73:4e8ce0b18915	4246	}
mjr	73:4e8ce0b18915	4247
mjr	73:4e8ce0b18915	4248	// Figure the next post-processing filtered value. This applies a
mjr	73:4e8ce0b18915	4249	// hysteresis filter to the last raw z value and returns the
mjr	73:4e8ce0b18915	4250	// filtered result.
mjr	73:4e8ce0b18915	4251	int applyPostFilter()
mjr	73:4e8ce0b18915	4252	{
mjr	73:4e8ce0b18915	4253	if (firing <= 1)
mjr	73:4e8ce0b18915	4254	{
mjr	73:4e8ce0b18915	4255	// Filter limit - 5 samples. Once we've been moving
mjr	73:4e8ce0b18915	4256	// in the same direction for this many samples, we'll
mjr	73:4e8ce0b18915	4257	// clear the history and start over.
mjr	73:4e8ce0b18915	4258	const int filterMask = 0x1f;
mjr	73:4e8ce0b18915	4259
mjr	73:4e8ce0b18915	4260	// figure the last average
mjr	73:4e8ce0b18915	4261	int lastAvg = int(filterSum / filterN);
mjr	73:4e8ce0b18915	4262
mjr	73:4e8ce0b18915	4263	// figure the direction of this sample relative to the average,
mjr	73:4e8ce0b18915	4264	// and shift it in to our bit mask of recent direction data
mjr	73:4e8ce0b18915	4265	if (z != lastAvg)
mjr	73:4e8ce0b18915	4266	{
mjr	73:4e8ce0b18915	4267	// shift the new direction bit into the vector
mjr	73:4e8ce0b18915	4268	filterDir <<= 1;
mjr	73:4e8ce0b18915	4269	if (z > lastAvg) filterDir \|= 1;
mjr	73:4e8ce0b18915	4270	}
mjr	73:4e8ce0b18915	4271
mjr	73:4e8ce0b18915	4272	// keep only the last N readings, up to the filter limit
mjr	73:4e8ce0b18915	4273	filterDir &= filterMask;
mjr	73:4e8ce0b18915	4274
mjr	73:4e8ce0b18915	4275	// if we've been moving consistently in one direction (all 1's
mjr	73:4e8ce0b18915	4276	// or all 0's in the direction history vector), reset the average
mjr	73:4e8ce0b18915	4277	if (filterDir == 0x00 \|\| filterDir == filterMask)
mjr	73:4e8ce0b18915	4278	{
mjr	73:4e8ce0b18915	4279	// motion away from the average - reset the average
mjr	73:4e8ce0b18915	4280	filterDir = 0x5555;
mjr	73:4e8ce0b18915	4281	filterN = 1;
mjr	73:4e8ce0b18915	4282	filterSum = (lastAvg + z)/2;
mjr	73:4e8ce0b18915	4283	return int16_t(filterSum);
mjr	73:4e8ce0b18915	4284	}
mjr	73:4e8ce0b18915	4285	else
mjr	73:4e8ce0b18915	4286	{
mjr	73:4e8ce0b18915	4287	// we're directionless - return the new average, with the
mjr	73:4e8ce0b18915	4288	// new sample included
mjr	73:4e8ce0b18915	4289	filterSum += z;
mjr	73:4e8ce0b18915	4290	++filterN;
mjr	73:4e8ce0b18915	4291	return int16_t(filterSum / filterN);
mjr	73:4e8ce0b18915	4292	}
mjr	73:4e8ce0b18915	4293	}
mjr	73:4e8ce0b18915	4294	else
mjr	73:4e8ce0b18915	4295	{
mjr	73:4e8ce0b18915	4296	// firing mode - skip the filter
mjr	73:4e8ce0b18915	4297	filterN = 1;
mjr	73:4e8ce0b18915	4298	filterSum = z;
mjr	73:4e8ce0b18915	4299	filterDir = 0x5555;
mjr	73:4e8ce0b18915	4300	return z;
mjr	73:4e8ce0b18915	4301	}
mjr	73:4e8ce0b18915	4302	}
mjr	73:4e8ce0b18915	4303	#elif PLUNGER_FILTERING_MODE == 2
mjr	69:cc5039284fac	4304	// Apply pre-processing filter. This filter is applied to the raw
mjr	69:cc5039284fac	4305	// value coming off the sensor, before calibration or fire-event
mjr	69:cc5039284fac	4306	// processing.
mjr	69:cc5039284fac	4307	void applyPreFilter(PlungerReading &r)
mjr	69:cc5039284fac	4308	{
mjr	69:cc5039284fac	4309	// get the previous raw reading
mjr	69:cc5039284fac	4310	PlungerReading prv = pre.raw;
mjr	69:cc5039284fac	4311
mjr	69:cc5039284fac	4312	// the new reading is the previous raw reading next time, no
mjr	69:cc5039284fac	4313	// matter how we end up filtering it
mjr	69:cc5039284fac	4314	pre.raw = r;
mjr	69:cc5039284fac	4315
mjr	69:cc5039284fac	4316	// If it's too big an excursion from the previous raw reading,
mjr	69:cc5039284fac	4317	// ignore it and repeat the previous reported reading. This
mjr	69:cc5039284fac	4318	// filters out anomalous spikes where we suddenly jump to a
mjr	69:cc5039284fac	4319	// level that's too far away to be possible. Real plungers
mjr	69:cc5039284fac	4320	// take about 60ms to travel the full distance when released,
mjr	69:cc5039284fac	4321	// so assuming constant acceleration, the maximum realistic
mjr	69:cc5039284fac	4322	// speed is about 2.200 distance units (on our 0..0xffff scale)
mjr	69:cc5039284fac	4323	// per microsecond.
mjr	69:cc5039284fac	4324	//
mjr	69:cc5039284fac	4325	// On the other hand, if the new reading is too close to the
mjr	69:cc5039284fac	4326	// previous reading, use the previous reported reading. This
mjr	69:cc5039284fac	4327	// filters out jitter around a stationary position.
mjr	69:cc5039284fac	4328	const float maxDist = 2.184f*uint32_t(r.t - prv.t);
mjr	69:cc5039284fac	4329	const int minDist = 256;
mjr	69:cc5039284fac	4330	const int delta = abs(r.pos - prv.pos);
mjr	69:cc5039284fac	4331	if (maxDist > minDist && delta > maxDist)
mjr	69:cc5039284fac	4332	{
mjr	69:cc5039284fac	4333	// too big an excursion - discard this reading by reporting
mjr	69:cc5039284fac	4334	// the last reported reading instead
mjr	69:cc5039284fac	4335	r.pos = pre.reported;
mjr	69:cc5039284fac	4336	}
mjr	69:cc5039284fac	4337	else if (delta < minDist)
mjr	69:cc5039284fac	4338	{
mjr	69:cc5039284fac	4339	// too close to the prior reading - apply hysteresis
mjr	69:cc5039284fac	4340	r.pos = pre.reported;
mjr	69:cc5039284fac	4341	}
mjr	69:cc5039284fac	4342	else
mjr	69:cc5039284fac	4343	{
mjr	69:cc5039284fac	4344	// the reading is in range - keep it, and remember it as
mjr	69:cc5039284fac	4345	// the last reported reading
mjr	69:cc5039284fac	4346	pre.reported = r.pos;
mjr	69:cc5039284fac	4347	}
mjr	69:cc5039284fac	4348	}
mjr	69:cc5039284fac	4349
mjr	69:cc5039284fac	4350	// pre-filter data
mjr	69:cc5039284fac	4351	struct PreFilterData {
mjr	69:cc5039284fac	4352	PreFilterData()
mjr	69:cc5039284fac	4353	: reported(0)
mjr	69:cc5039284fac	4354	{
mjr	69:cc5039284fac	4355	raw.t = 0;
mjr	69:cc5039284fac	4356	raw.pos = 0;
mjr	69:cc5039284fac	4357	}
mjr	69:cc5039284fac	4358	PlungerReading raw; // previous raw sensor reading
mjr	69:cc5039284fac	4359	int reported; // previous reported reading
mjr	69:cc5039284fac	4360	} pre;
mjr	69:cc5039284fac	4361
mjr	69:cc5039284fac	4362
mjr	69:cc5039284fac	4363	// Apply the post-processing filter. This filter is applied after
mjr	69:cc5039284fac	4364	// the fire-event processing. In the past, this used hysteresis to
mjr	69:cc5039284fac	4365	// try to smooth out jittering readings for a stationary plunger.
mjr	69:cc5039284fac	4366	// We've switched to a different approach that massages the readings
mjr	69:cc5039284fac	4367	// coming off the sensor before
mjr	69:cc5039284fac	4368	int applyPostFilter()
mjr	69:cc5039284fac	4369	{
mjr	69:cc5039284fac	4370	return z;
mjr	69:cc5039284fac	4371	}
mjr	69:cc5039284fac	4372	#endif
mjr	58:523fdcffbe6d	4373
mjr	58:523fdcffbe6d	4374	void initFilter()
mjr	58:523fdcffbe6d	4375	{
mjr	58:523fdcffbe6d	4376	filterSum = 0;
mjr	58:523fdcffbe6d	4377	filterN = 1;
mjr	58:523fdcffbe6d	4378	filterDir = 0x5555;
mjr	58:523fdcffbe6d	4379	}
mjr	58:523fdcffbe6d	4380	int64_t filterSum;
mjr	58:523fdcffbe6d	4381	int64_t filterN;
mjr	58:523fdcffbe6d	4382	uint16_t filterDir;
mjr	58:523fdcffbe6d	4383
mjr	58:523fdcffbe6d	4384
mjr	52:8298b2a73eb2	4385	// Calibration state. During calibration mode, we watch for release
mjr	52:8298b2a73eb2	4386	// events, to measure the time it takes to complete the release
mjr	52:8298b2a73eb2	4387	// motion; and we watch for the plunger to come to reset after a
mjr	52:8298b2a73eb2	4388	// release, to gather statistics on the rest position.
mjr	52:8298b2a73eb2	4389	// 0 = waiting to settle
mjr	52:8298b2a73eb2	4390	// 1 = at rest
mjr	52:8298b2a73eb2	4391	// 2 = retracting
mjr	52:8298b2a73eb2	4392	// 3 = possibly releasing
mjr	52:8298b2a73eb2	4393	uint8_t calState;
mjr	52:8298b2a73eb2	4394
mjr	52:8298b2a73eb2	4395	// Calibration zero point statistics.
mjr	52:8298b2a73eb2	4396	// During calibration mode, we collect data on the rest position (the
mjr	52:8298b2a73eb2	4397	// zero point) by watching for the plunger to come to rest after each
mjr	52:8298b2a73eb2	4398	// release. We average these rest positions to get the calibrated
mjr	52:8298b2a73eb2	4399	// zero point. We use the average because the real physical plunger
mjr	52:8298b2a73eb2	4400	// itself doesn't come to rest at exactly the same spot every time,
mjr	52:8298b2a73eb2	4401	// largely due to friction in the mechanism. To calculate the average,
mjr	52:8298b2a73eb2	4402	// we keep a sum of the readings and a count of samples.
mjr	53:9b2611964afc	4403	PlungerReading calZeroStart;
mjr	52:8298b2a73eb2	4404	long calZeroPosSum;
mjr	52:8298b2a73eb2	4405	int calZeroPosN;
mjr	52:8298b2a73eb2	4406
mjr	52:8298b2a73eb2	4407	// Calibration release time statistics.
mjr	52:8298b2a73eb2	4408	// During calibration, we collect an average for the release time.
mjr	52:8298b2a73eb2	4409	long calRlsTimeSum;
mjr	52:8298b2a73eb2	4410	int calRlsTimeN;
mjr	52:8298b2a73eb2	4411
mjr	48:058ace2aed1d	4412	// set a firing mode
mjr	48:058ace2aed1d	4413	inline void firingMode(int m)
mjr	48:058ace2aed1d	4414	{
mjr	48:058ace2aed1d	4415	firing = m;
mjr	48:058ace2aed1d	4416	}
mjr	48:058ace2aed1d	4417
mjr	48:058ace2aed1d	4418	// Find the most recent local maximum in the history data, up to
mjr	48:058ace2aed1d	4419	// the given time limit.
mjr	48:058ace2aed1d	4420	int histLocalMax(uint32_t tcur, uint32_t dt)
mjr	48:058ace2aed1d	4421	{
mjr	48:058ace2aed1d	4422	// start with the prior entry
mjr	48:058ace2aed1d	4423	int idx = (histIdx == 0 ? countof(hist) : histIdx) - 1;
mjr	48:058ace2aed1d	4424	int hi = hist[idx].pos;
mjr	48:058ace2aed1d	4425
mjr	48:058ace2aed1d	4426	// scan backwards for a local maximum
mjr	48:058ace2aed1d	4427	for (int n = countof(hist) - 1 ; n > 0 ; idx = (idx == 0 ? countof(hist) : idx) - 1)
mjr	48:058ace2aed1d	4428	{
mjr	48:058ace2aed1d	4429	// if this isn't within the time window, stop
mjr	48:058ace2aed1d	4430	if (uint32_t(tcur - hist[idx].t) > dt)
mjr	48:058ace2aed1d	4431	break;
mjr	48:058ace2aed1d	4432
mjr	48:058ace2aed1d	4433	// if this isn't above the current hith, stop
mjr	48:058ace2aed1d	4434	if (hist[idx].pos < hi)
mjr	48:058ace2aed1d	4435	break;
mjr	48:058ace2aed1d	4436
mjr	48:058ace2aed1d	4437	// this is the new high
mjr	48:058ace2aed1d	4438	hi = hist[idx].pos;
mjr	48:058ace2aed1d	4439	}
mjr	48:058ace2aed1d	4440
mjr	48:058ace2aed1d	4441	// return the local maximum
mjr	48:058ace2aed1d	4442	return hi;
mjr	48:058ace2aed1d	4443	}
mjr	48:058ace2aed1d	4444
mjr	50:40015764bbe6	4445	// velocity at previous reading, and the one before that
mjr	50:40015764bbe6	4446	float vprv, vprv2;
mjr	48:058ace2aed1d	4447
mjr	48:058ace2aed1d	4448	// Circular buffer of recent readings. We keep a short history
mjr	48:058ace2aed1d	4449	// of readings to analyze during firing events. We can only identify
mjr	48:058ace2aed1d	4450	// a firing event once it's somewhat under way, so we need a little
mjr	48:058ace2aed1d	4451	// retrospective information to accurately determine after the fact
mjr	48:058ace2aed1d	4452	// exactly when it started. We throttle our readings to no more
mjr	74:822a92bc11d2	4453	// than one every 1ms, so we have at least N*1ms of history in this
mjr	48:058ace2aed1d	4454	// array.
mjr	74:822a92bc11d2	4455	PlungerReading hist[32];
mjr	48:058ace2aed1d	4456	int histIdx;
mjr	49:37bd97eb7688	4457
mjr	50:40015764bbe6	4458	// get the nth history item (0=last, 1=2nd to last, etc)
mjr	74:822a92bc11d2	4459	inline const PlungerReading &nthHist(int n) const
mjr	50:40015764bbe6	4460	{
mjr	50:40015764bbe6	4461	// histIdx-1 is the last written; go from there
mjr	50:40015764bbe6	4462	n = histIdx - 1 - n;
mjr	50:40015764bbe6	4463
mjr	50:40015764bbe6	4464	// adjust for wrapping
mjr	50:40015764bbe6	4465	if (n < 0)
mjr	50:40015764bbe6	4466	n += countof(hist);
mjr	50:40015764bbe6	4467
mjr	50:40015764bbe6	4468	// return the item
mjr	50:40015764bbe6	4469	return hist[n];
mjr	50:40015764bbe6	4470	}
mjr	48:058ace2aed1d	4471
mjr	48:058ace2aed1d	4472	// Firing event state.
mjr	48:058ace2aed1d	4473	//
mjr	48:058ace2aed1d	4474	// 0 - Default state. We report the real instantaneous plunger
mjr	48:058ace2aed1d	4475	// position to the joystick interface.
mjr	48:058ace2aed1d	4476	//
mjr	53:9b2611964afc	4477	// 1 - Moving forward
mjr	48:058ace2aed1d	4478	//
mjr	53:9b2611964afc	4479	// 2 - Accelerating
mjr	48:058ace2aed1d	4480	//
mjr	53:9b2611964afc	4481	// 3 - Firing. We report the rest position for a minimum interval,
mjr	53:9b2611964afc	4482	// or until the real plunger comes to rest somewhere.
mjr	48:058ace2aed1d	4483	//
mjr	48:058ace2aed1d	4484	int firing;
mjr	48:058ace2aed1d	4485
mjr	51:57eb311faafa	4486	// Position/timestamp at start of firing phase 1. When we see a
mjr	51:57eb311faafa	4487	// sustained forward acceleration, we freeze joystick reports at
mjr	51:57eb311faafa	4488	// the recent local maximum, on the assumption that this was the
mjr	51:57eb311faafa	4489	// start of the release. If this is zero, it means that we're
mjr	51:57eb311faafa	4490	// monitoring accelerating motion but haven't seen it for long
mjr	51:57eb311faafa	4491	// enough yet to be confident that a release is in progress.
mjr	48:058ace2aed1d	4492	PlungerReading f1;
mjr	48:058ace2aed1d	4493
mjr	48:058ace2aed1d	4494	// Position/timestamp at start of firing phase 2. The position is
mjr	48:058ace2aed1d	4495	// the fake "bounce" position we report during this phase, and the
mjr	48:058ace2aed1d	4496	// timestamp tells us when the phase began so that we can end it
mjr	48:058ace2aed1d	4497	// after enough time elapses.
mjr	48:058ace2aed1d	4498	PlungerReading f2;
mjr	48:058ace2aed1d	4499
mjr	48:058ace2aed1d	4500	// Position/timestamp of start of stability window during phase 3.
mjr	48:058ace2aed1d	4501	// We use this to determine when the plunger comes to rest. We set
mjr	51:57eb311faafa	4502	// this at the beginning of phase 3, and then reset it when the
mjr	48:058ace2aed1d	4503	// plunger moves too far from the last position.
mjr	48:058ace2aed1d	4504	PlungerReading f3s;
mjr	48:058ace2aed1d	4505
mjr	48:058ace2aed1d	4506	// Position/timestamp of start of retraction window during phase 3.
mjr	48:058ace2aed1d	4507	// We use this to determine if the user is drawing the plunger back.
mjr	48:058ace2aed1d	4508	// If we see retraction motion for more than about 65ms, we assume
mjr	48:058ace2aed1d	4509	// that the user has taken over, because we should see forward
mjr	48:058ace2aed1d	4510	// motion within this timeframe if the plunger is just bouncing
mjr	48:058ace2aed1d	4511	// freely.
mjr	48:058ace2aed1d	4512	PlungerReading f3r;
mjr	48:058ace2aed1d	4513
mjr	58:523fdcffbe6d	4514	// next raw (unfiltered) Z value to report to the joystick interface
mjr	58:523fdcffbe6d	4515	// (in joystick distance units)
mjr	48:058ace2aed1d	4516	int z;
mjr	48:058ace2aed1d	4517
mjr	48:058ace2aed1d	4518	// velocity of this reading (joystick distance units per microsecond)
mjr	48:058ace2aed1d	4519	float vz;
mjr	58:523fdcffbe6d	4520
mjr	58:523fdcffbe6d	4521	// next filtered Z value to report to the joystick interface
mjr	58:523fdcffbe6d	4522	int zf;
mjr	48:058ace2aed1d	4523	};
mjr	48:058ace2aed1d	4524
mjr	48:058ace2aed1d	4525	// plunger reader singleton
mjr	48:058ace2aed1d	4526	PlungerReader plungerReader;
mjr	48:058ace2aed1d	4527
mjr	48:058ace2aed1d	4528	// ---------------------------------------------------------------------------
mjr	48:058ace2aed1d	4529	//
mjr	48:058ace2aed1d	4530	// Handle the ZB Launch Ball feature.
mjr	48:058ace2aed1d	4531	//
mjr	48:058ace2aed1d	4532	// The ZB Launch Ball feature, if enabled, lets the mechanical plunger
mjr	48:058ace2aed1d	4533	// serve as a substitute for a physical Launch Ball button. When a table
mjr	48:058ace2aed1d	4534	// is loaded in VP, and the table has the ZB Launch Ball LedWiz port
mjr	48:058ace2aed1d	4535	// turned on, we'll disable mechanical plunger reports through the
mjr	48:058ace2aed1d	4536	// joystick interface and instead use the plunger only to simulate the
mjr	48:058ace2aed1d	4537	// Launch Ball button. When the mode is active, pulling back and
mjr	48:058ace2aed1d	4538	// releasing the plunger causes a brief simulated press of the Launch
mjr	48:058ace2aed1d	4539	// button, and pushing the plunger forward of the rest position presses
mjr	48:058ace2aed1d	4540	// the Launch button as long as the plunger is pressed forward.
mjr	48:058ace2aed1d	4541	//
mjr	48:058ace2aed1d	4542	// This feature has two configuration components:
mjr	48:058ace2aed1d	4543	//
mjr	48:058ace2aed1d	4544	// - An LedWiz port number. This port is a "virtual" port that doesn't
mjr	48:058ace2aed1d	4545	// have to be attached to any actual output. DOF uses it to signal
mjr	48:058ace2aed1d	4546	// that the current table uses a Launch button instead of a plunger.
mjr	48:058ace2aed1d	4547	// DOF simply turns the port on when such a table is loaded and turns
mjr	48:058ace2aed1d	4548	// it off at all other times. We use it to enable and disable the
mjr	48:058ace2aed1d	4549	// plunger/launch button connection.
mjr	48:058ace2aed1d	4550	//
mjr	48:058ace2aed1d	4551	// - A joystick button ID. We simulate pressing this button when the
mjr	48:058ace2aed1d	4552	// launch feature is activated via the LedWiz port and the plunger is
mjr	48:058ace2aed1d	4553	// either pulled back and releasd, or pushed forward past the rest
mjr	48:058ace2aed1d	4554	// position.
mjr	48:058ace2aed1d	4555	//
mjr	48:058ace2aed1d	4556	class ZBLaunchBall
mjr	48:058ace2aed1d	4557	{
mjr	48:058ace2aed1d	4558	public:
mjr	48:058ace2aed1d	4559	ZBLaunchBall()
mjr	48:058ace2aed1d	4560	{
mjr	48:058ace2aed1d	4561	// start in the default state
mjr	48:058ace2aed1d	4562	lbState = 0;
mjr	53:9b2611964afc	4563	btnState = false;
mjr	48:058ace2aed1d	4564	}
mjr	48:058ace2aed1d	4565
mjr	48:058ace2aed1d	4566	// Update state. This checks the current plunger position and
mjr	48:058ace2aed1d	4567	// the timers to see if the plunger is in a position that simulates
mjr	48:058ace2aed1d	4568	// a Launch Ball button press via the ZB Launch Ball feature.
mjr	48:058ace2aed1d	4569	// Updates the simulated button vector according to the current
mjr	48:058ace2aed1d	4570	// launch ball state. The main loop calls this before each
mjr	48:058ace2aed1d	4571	// joystick update to figure the new simulated button state.
mjr	53:9b2611964afc	4572	void update()
mjr	48:058ace2aed1d	4573	{
mjr	53:9b2611964afc	4574	// If the ZB Launch Ball led wiz output is ON, check for a
mjr	53:9b2611964afc	4575	// plunger firing event
mjr	53:9b2611964afc	4576	if (zbLaunchOn)
mjr	48:058ace2aed1d	4577	{
mjr	53:9b2611964afc	4578	// note the new position
mjr	48:058ace2aed1d	4579	int znew = plungerReader.getPosition();
mjr	53:9b2611964afc	4580
mjr	53:9b2611964afc	4581	// figure the push threshold from the configuration data
mjr	51:57eb311faafa	4582	const int pushThreshold = int(-JOYMAX/3.0 * cfg.plunger.zbLaunchBall.pushDistance/1000.0);
mjr	53:9b2611964afc	4583
mjr	53:9b2611964afc	4584	// check the state
mjr	48:058ace2aed1d	4585	switch (lbState)
mjr	48:058ace2aed1d	4586	{
mjr	48:058ace2aed1d	4587	case 0:
mjr	53:9b2611964afc	4588	// Default state. If a launch event has been detected on
mjr	53:9b2611964afc	4589	// the plunger, activate a timed pulse and switch to state 1.
mjr	53:9b2611964afc	4590	// If the plunger is pushed forward of the threshold, push
mjr	53:9b2611964afc	4591	// the button.
mjr	53:9b2611964afc	4592	if (plungerReader.isFiring())
mjr	53:9b2611964afc	4593	{
mjr	53:9b2611964afc	4594	// firing event - start a timed Launch button pulse
mjr	53:9b2611964afc	4595	lbTimer.reset();
mjr	53:9b2611964afc	4596	lbTimer.start();
mjr	53:9b2611964afc	4597	setButton(true);
mjr	53:9b2611964afc	4598
mjr	53:9b2611964afc	4599	// switch to state 1
mjr	53:9b2611964afc	4600	lbState = 1;
mjr	53:9b2611964afc	4601	}
mjr	48:058ace2aed1d	4602	else if (znew <= pushThreshold)
mjr	53:9b2611964afc	4603	{
mjr	53:9b2611964afc	4604	// pushed forward without a firing event - hold the
mjr	53:9b2611964afc	4605	// button as long as we're pushed forward
mjr	53:9b2611964afc	4606	setButton(true);
mjr	53:9b2611964afc	4607	}
mjr	53:9b2611964afc	4608	else
mjr	53:9b2611964afc	4609	{
mjr	53:9b2611964afc	4610	// not pushed forward - turn off the Launch button
mjr	53:9b2611964afc	4611	setButton(false);
mjr	53:9b2611964afc	4612	}
mjr	48:058ace2aed1d	4613	break;
mjr	48:058ace2aed1d	4614
mjr	48:058ace2aed1d	4615	case 1:
mjr	53:9b2611964afc	4616	// State 1: Timed Launch button pulse in progress after a
mjr	53:9b2611964afc	4617	// firing event. Wait for the timer to expire.
mjr	53:9b2611964afc	4618	if (lbTimer.read_us() > 200000UL)
mjr	53:9b2611964afc	4619	{
mjr	53:9b2611964afc	4620	// timer expired - turn off the button
mjr	53:9b2611964afc	4621	setButton(false);
mjr	53:9b2611964afc	4622
mjr	53:9b2611964afc	4623	// switch to state 2
mjr	53:9b2611964afc	4624	lbState = 2;
mjr	53:9b2611964afc	4625	}
mjr	48:058ace2aed1d	4626	break;
mjr	48:058ace2aed1d	4627
mjr	48:058ace2aed1d	4628	case 2:
mjr	53:9b2611964afc	4629	// State 2: Timed Launch button pulse done. Wait for the
mjr	53:9b2611964afc	4630	// plunger launch event to end.
mjr	53:9b2611964afc	4631	if (!plungerReader.isFiring())
mjr	53:9b2611964afc	4632	{
mjr	53:9b2611964afc	4633	// firing event done - return to default state
mjr	53:9b2611964afc	4634	lbState = 0;
mjr	53:9b2611964afc	4635	}
mjr	48:058ace2aed1d	4636	break;
mjr	48:058ace2aed1d	4637	}
mjr	53:9b2611964afc	4638	}
mjr	53:9b2611964afc	4639	else
mjr	53:9b2611964afc	4640	{
mjr	53:9b2611964afc	4641	// ZB Launch Ball disabled - turn off the button if it was on
mjr	53:9b2611964afc	4642	setButton(false);
mjr	48:058ace2aed1d	4643
mjr	53:9b2611964afc	4644	// return to the default state
mjr	53:9b2611964afc	4645	lbState = 0;
mjr	48:058ace2aed1d	4646	}
mjr	48:058ace2aed1d	4647	}
mjr	53:9b2611964afc	4648
mjr	53:9b2611964afc	4649	// Set the button state
mjr	53:9b2611964afc	4650	void setButton(bool on)
mjr	53:9b2611964afc	4651	{
mjr	53:9b2611964afc	4652	if (btnState != on)
mjr	53:9b2611964afc	4653	{
mjr	53:9b2611964afc	4654	// remember the new state
mjr	53:9b2611964afc	4655	btnState = on;
mjr	53:9b2611964afc	4656
mjr	53:9b2611964afc	4657	// update the virtual button state
mjr	65:739875521aae	4658	buttonState[zblButtonIndex].virtPress(on);
mjr	53:9b2611964afc	4659	}
mjr	53:9b2611964afc	4660	}
mjr	53:9b2611964afc	4661
mjr	48:058ace2aed1d	4662	private:
mjr	48:058ace2aed1d	4663	// Simulated Launch Ball button state. If a "ZB Launch Ball" port is
mjr	48:058ace2aed1d	4664	// defined for our LedWiz port mapping, any time that port is turned ON,
mjr	48:058ace2aed1d	4665	// we'll simulate pushing the Launch Ball button if the player pulls
mjr	48:058ace2aed1d	4666	// back and releases the plunger, or simply pushes on the plunger from
mjr	48:058ace2aed1d	4667	// the rest position. This allows the plunger to be used in lieu of a
mjr	48:058ace2aed1d	4668	// physical Launch Ball button for tables that don't have plungers.
mjr	48:058ace2aed1d	4669	//
mjr	48:058ace2aed1d	4670	// States:
mjr	48:058ace2aed1d	4671	// 0 = default
mjr	53:9b2611964afc	4672	// 1 = firing (firing event has activated a Launch button pulse)
mjr	53:9b2611964afc	4673	// 2 = firing done (Launch button pulse ended, waiting for plunger
mjr	53:9b2611964afc	4674	// firing event to end)
mjr	53:9b2611964afc	4675	uint8_t lbState;
mjr	48:058ace2aed1d	4676
mjr	53:9b2611964afc	4677	// button state
mjr	53:9b2611964afc	4678	bool btnState;
mjr	48:058ace2aed1d	4679
mjr	48:058ace2aed1d	4680	// Time since last lbState transition. Some of the states are time-
mjr	48:058ace2aed1d	4681	// sensitive. In the "uncocked" state, we'll return to state 0 if
mjr	48:058ace2aed1d	4682	// we remain in this state for more than a few milliseconds, since
mjr	48:058ace2aed1d	4683	// it indicates that the plunger is being slowly returned to rest
mjr	48:058ace2aed1d	4684	// rather than released. In the "launching" state, we need to release
mjr	48:058ace2aed1d	4685	// the Launch Ball button after a moment, and we need to wait for
mjr	48:058ace2aed1d	4686	// the plunger to come to rest before returning to state 0.
mjr	48:058ace2aed1d	4687	Timer lbTimer;
mjr	48:058ace2aed1d	4688	};
mjr	48:058ace2aed1d	4689
mjr	35:e959ffba78fd	4690	// ---------------------------------------------------------------------------
mjr	35:e959ffba78fd	4691	//
mjr	35:e959ffba78fd	4692	// Reboot - resets the microcontroller
mjr	35:e959ffba78fd	4693	//
mjr	54:fd77a6b2f76c	4694	void reboot(USBJoystick &js, bool disconnect = true, long pause_us = 2000000L)
mjr	35:e959ffba78fd	4695	{
mjr	35:e959ffba78fd	4696	// disconnect from USB
mjr	54:fd77a6b2f76c	4697	if (disconnect)
mjr	54:fd77a6b2f76c	4698	js.disconnect();
mjr	35:e959ffba78fd	4699
mjr	35:e959ffba78fd	4700	// wait a few seconds to make sure the host notices the disconnect
mjr	54:fd77a6b2f76c	4701	wait_us(pause_us);
mjr	35:e959ffba78fd	4702
mjr	35:e959ffba78fd	4703	// reset the device
mjr	35:e959ffba78fd	4704	NVIC_SystemReset();
mjr	35:e959ffba78fd	4705	while (true) { }
mjr	35:e959ffba78fd	4706	}
mjr	35:e959ffba78fd	4707
mjr	35:e959ffba78fd	4708	// ---------------------------------------------------------------------------
mjr	35:e959ffba78fd	4709	//
mjr	35:e959ffba78fd	4710	// Translate joystick readings from raw values to reported values, based
mjr	35:e959ffba78fd	4711	// on the orientation of the controller card in the cabinet.
mjr	35:e959ffba78fd	4712	//
mjr	35:e959ffba78fd	4713	void accelRotate(int &x, int &y)
mjr	35:e959ffba78fd	4714	{
mjr	35:e959ffba78fd	4715	int tmp;
mjr	35:e959ffba78fd	4716	switch (cfg.orientation)
mjr	35:e959ffba78fd	4717	{
mjr	35:e959ffba78fd	4718	case OrientationFront:
mjr	35:e959ffba78fd	4719	tmp = x;
mjr	35:e959ffba78fd	4720	x = y;
mjr	35:e959ffba78fd	4721	y = tmp;
mjr	35:e959ffba78fd	4722	break;
mjr	35:e959ffba78fd	4723
mjr	35:e959ffba78fd	4724	case OrientationLeft:
mjr	35:e959ffba78fd	4725	x = -x;
mjr	35:e959ffba78fd	4726	break;
mjr	35:e959ffba78fd	4727
mjr	35:e959ffba78fd	4728	case OrientationRight:
mjr	35:e959ffba78fd	4729	y = -y;
mjr	35:e959ffba78fd	4730	break;
mjr	35:e959ffba78fd	4731
mjr	35:e959ffba78fd	4732	case OrientationRear:
mjr	35:e959ffba78fd	4733	tmp = -x;
mjr	35:e959ffba78fd	4734	x = -y;
mjr	35:e959ffba78fd	4735	y = tmp;
mjr	35:e959ffba78fd	4736	break;
mjr	35:e959ffba78fd	4737	}
mjr	35:e959ffba78fd	4738	}
mjr	35:e959ffba78fd	4739
mjr	35:e959ffba78fd	4740	// ---------------------------------------------------------------------------
mjr	35:e959ffba78fd	4741	//
mjr	35:e959ffba78fd	4742	// Calibration button state:
mjr	35:e959ffba78fd	4743	// 0 = not pushed
mjr	35:e959ffba78fd	4744	// 1 = pushed, not yet debounced
mjr	35:e959ffba78fd	4745	// 2 = pushed, debounced, waiting for hold time
mjr	35:e959ffba78fd	4746	// 3 = pushed, hold time completed - in calibration mode
mjr	35:e959ffba78fd	4747	int calBtnState = 0;
mjr	35:e959ffba78fd	4748
mjr	35:e959ffba78fd	4749	// calibration button debounce timer
mjr	35:e959ffba78fd	4750	Timer calBtnTimer;
mjr	35:e959ffba78fd	4751
mjr	35:e959ffba78fd	4752	// calibration button light state
mjr	35:e959ffba78fd	4753	int calBtnLit = false;
mjr	35:e959ffba78fd	4754
mjr	35:e959ffba78fd	4755
mjr	35:e959ffba78fd	4756	// ---------------------------------------------------------------------------
mjr	35:e959ffba78fd	4757	//
mjr	40:cc0d9814522b	4758	// Configuration variable get/set message handling
mjr	35:e959ffba78fd	4759	//
mjr	40:cc0d9814522b	4760
mjr	40:cc0d9814522b	4761	// Handle SET messages - write configuration variables from USB message data
mjr	40:cc0d9814522b	4762	#define if_msg_valid(test) if (test)
mjr	53:9b2611964afc	4763	#define v_byte(var, ofs) cfg.var = data[ofs]
mjr	53:9b2611964afc	4764	#define v_ui16(var, ofs) cfg.var = wireUI16(data+(ofs))
mjr	53:9b2611964afc	4765	#define v_pin(var, ofs) cfg.var = wirePinName(data[ofs])
mjr	53:9b2611964afc	4766	#define v_byte_ro(val, ofs) // ignore read-only variables on SET
mjr	74:822a92bc11d2	4767	#define v_ui32_ro(val, ofs) // ignore read-only variables on SET
mjr	74:822a92bc11d2	4768	#define VAR_MODE_SET 1 // we're in SET mode
mjr	40:cc0d9814522b	4769	#define v_func configVarSet
mjr	40:cc0d9814522b	4770	#include "cfgVarMsgMap.h"
mjr	35:e959ffba78fd	4771
mjr	40:cc0d9814522b	4772	// redefine everything for the SET messages
mjr	40:cc0d9814522b	4773	#undef if_msg_valid
mjr	40:cc0d9814522b	4774	#undef v_byte
mjr	40:cc0d9814522b	4775	#undef v_ui16
mjr	40:cc0d9814522b	4776	#undef v_pin
mjr	53:9b2611964afc	4777	#undef v_byte_ro
mjr	74:822a92bc11d2	4778	#undef v_ui32_ro
mjr	74:822a92bc11d2	4779	#undef VAR_MODE_SET
mjr	40:cc0d9814522b	4780	#undef v_func
mjr	38:091e511ce8a0	4781
mjr	40:cc0d9814522b	4782	// Handle GET messages - read variable values and return in USB message daa
mjr	40:cc0d9814522b	4783	#define if_msg_valid(test)
mjr	53:9b2611964afc	4784	#define v_byte(var, ofs) data[ofs] = cfg.var
mjr	53:9b2611964afc	4785	#define v_ui16(var, ofs) ui16Wire(data+(ofs), cfg.var)
mjr	53:9b2611964afc	4786	#define v_pin(var, ofs) pinNameWire(data+(ofs), cfg.var)
mjr	73:4e8ce0b18915	4787	#define v_byte_ro(val, ofs) data[ofs] = (val)
mjr	74:822a92bc11d2	4788	#define v_ui32_ro(val, ofs) ui32Wire(data+(ofs), val);
mjr	74:822a92bc11d2	4789	#define VAR_MODE_SET 0 // we're in GET mode
mjr	40:cc0d9814522b	4790	#define v_func configVarGet
mjr	40:cc0d9814522b	4791	#include "cfgVarMsgMap.h"
mjr	40:cc0d9814522b	4792
mjr	35:e959ffba78fd	4793
mjr	35:e959ffba78fd	4794	// ---------------------------------------------------------------------------
mjr	35:e959ffba78fd	4795	//
mjr	35:e959ffba78fd	4796	// Handle an input report from the USB host. Input reports use our extended
mjr	35:e959ffba78fd	4797	// LedWiz protocol.
mjr	33:d832bcab089e	4798	//
mjr	48:058ace2aed1d	4799	void handleInputMsg(LedWizMsg &lwm, USBJoystick &js)
mjr	35:e959ffba78fd	4800	{
mjr	38:091e511ce8a0	4801	// LedWiz commands come in two varieties: SBA and PBA. An
mjr	38:091e511ce8a0	4802	// SBA is marked by the first byte having value 64 (0x40). In
mjr	38:091e511ce8a0	4803	// the real LedWiz protocol, any other value in the first byte
mjr	38:091e511ce8a0	4804	// means it's a PBA message. However, valid PBA messages
mjr	38:091e511ce8a0	4805	// always have a first byte (and in fact all 8 bytes) in the
mjr	38:091e511ce8a0	4806	// range 0-49 or 129-132. Anything else is invalid. We take
mjr	38:091e511ce8a0	4807	// advantage of this to implement private protocol extensions.
mjr	38:091e511ce8a0	4808	// So our full protocol is as follows:
mjr	38:091e511ce8a0	4809	//
mjr	38:091e511ce8a0	4810	// first byte =
mjr	74:822a92bc11d2	4811	// 0-48 -> PBA
mjr	74:822a92bc11d2	4812	// 64 -> SBA
mjr	38:091e511ce8a0	4813	// 65 -> private control message; second byte specifies subtype
mjr	74:822a92bc11d2	4814	// 129-132 -> PBA
mjr	38:091e511ce8a0	4815	// 200-228 -> extended bank brightness set for outputs N to N+6, where
mjr	38:091e511ce8a0	4816	// N is (first byte - 200)*7
mjr	38:091e511ce8a0	4817	// other -> reserved for future use
mjr	38:091e511ce8a0	4818	//
mjr	39:b3815a1c3802	4819	uint8_t *data = lwm.data;
mjr	74:822a92bc11d2	4820	if (data[0] == 64)
mjr	35:e959ffba78fd	4821	{
mjr	74:822a92bc11d2	4822	// 64 = SBA (original LedWiz command to set on/off switches for ports 1-32)
mjr	74:822a92bc11d2	4823	//printf("SBA %02x %02x %02x %02x, speed %02x\r\n",
mjr	38:091e511ce8a0	4824	// data[1], data[2], data[3], data[4], data[5]);
mjr	74:822a92bc11d2	4825	sba_sbx(0, data);
mjr	74:822a92bc11d2	4826
mjr	74:822a92bc11d2	4827	// SBA resets the PBA port group counter
mjr	38:091e511ce8a0	4828	pbaIdx = 0;
mjr	38:091e511ce8a0	4829	}
mjr	38:091e511ce8a0	4830	else if (data[0] == 65)
mjr	38:091e511ce8a0	4831	{
mjr	38:091e511ce8a0	4832	// Private control message. This isn't an LedWiz message - it's
mjr	38:091e511ce8a0	4833	// an extension for this device. 65 is an invalid PBA setting,
mjr	38:091e511ce8a0	4834	// and isn't used for any other LedWiz message, so we appropriate
mjr	38:091e511ce8a0	4835	// it for our own private use. The first byte specifies the
mjr	38:091e511ce8a0	4836	// message type.
mjr	39:b3815a1c3802	4837	switch (data[1])
mjr	38:091e511ce8a0	4838	{
mjr	39:b3815a1c3802	4839	case 0:
mjr	39:b3815a1c3802	4840	// No Op
mjr	39:b3815a1c3802	4841	break;
mjr	39:b3815a1c3802	4842
mjr	39:b3815a1c3802	4843	case 1:
mjr	38:091e511ce8a0	4844	// 1 = Old Set Configuration:
mjr	38:091e511ce8a0	4845	// data[2] = LedWiz unit number (0x00 to 0x0f)
mjr	38:091e511ce8a0	4846	// data[3] = feature enable bit mask:
mjr	38:091e511ce8a0	4847	// 0x01 = enable plunger sensor
mjr	39:b3815a1c3802	4848	{
mjr	39:b3815a1c3802	4849
mjr	39:b3815a1c3802	4850	// get the new LedWiz unit number - this is 0-15, whereas we
mjr	39:b3815a1c3802	4851	// we save the nominal unit number 1-16 in the config
mjr	39:b3815a1c3802	4852	uint8_t newUnitNo = (data[2] & 0x0f) + 1;
mjr	39:b3815a1c3802	4853
mjr	39:b3815a1c3802	4854	// we'll need a reset if the LedWiz unit number is changing
mjr	39:b3815a1c3802	4855	bool needReset = (newUnitNo != cfg.psUnitNo);
mjr	39:b3815a1c3802	4856
mjr	39:b3815a1c3802	4857	// set the configuration parameters from the message
mjr	39:b3815a1c3802	4858	cfg.psUnitNo = newUnitNo;
mjr	39:b3815a1c3802	4859	cfg.plunger.enabled = data[3] & 0x01;
mjr	39:b3815a1c3802	4860
mjr	39:b3815a1c3802	4861	// save the configuration
mjr	39:b3815a1c3802	4862	saveConfigToFlash();
mjr	39:b3815a1c3802	4863
mjr	39:b3815a1c3802	4864	// reboot if necessary
mjr	39:b3815a1c3802	4865	if (needReset)
mjr	39:b3815a1c3802	4866	reboot(js);
mjr	39:b3815a1c3802	4867	}
mjr	39:b3815a1c3802	4868	break;
mjr	38:091e511ce8a0	4869
mjr	39:b3815a1c3802	4870	case 2:
mjr	38:091e511ce8a0	4871	// 2 = Calibrate plunger
mjr	38:091e511ce8a0	4872	// (No parameters)
mjr	38:091e511ce8a0	4873
mjr	38:091e511ce8a0	4874	// enter calibration mode
mjr	38:091e511ce8a0	4875	calBtnState = 3;
mjr	52:8298b2a73eb2	4876	plungerReader.setCalMode(true);
mjr	38:091e511ce8a0	4877	calBtnTimer.reset();
mjr	39:b3815a1c3802	4878	break;
mjr	39:b3815a1c3802	4879
mjr	39:b3815a1c3802	4880	case 3:
mjr	52:8298b2a73eb2	4881	// 3 = plunger sensor status report
mjr	48:058ace2aed1d	4882	// data[2] = flag bits
mjr	53:9b2611964afc	4883	// data[3] = extra exposure time, 100us (.1ms) increments
mjr	52:8298b2a73eb2	4884	reportPlungerStat = true;
mjr	53:9b2611964afc	4885	reportPlungerStatFlags = data[2];
mjr	53:9b2611964afc	4886	reportPlungerStatTime = data[3];
mjr	38:091e511ce8a0	4887
mjr	38:091e511ce8a0	4888	// show purple until we finish sending the report
mjr	38:091e511ce8a0	4889	diagLED(1, 0, 1);
mjr	39:b3815a1c3802	4890	break;
mjr	39:b3815a1c3802	4891
mjr	39:b3815a1c3802	4892	case 4:
mjr	38:091e511ce8a0	4893	// 4 = hardware configuration query
mjr	38:091e511ce8a0	4894	// (No parameters)
mjr	38:091e511ce8a0	4895	js.reportConfig(
mjr	38:091e511ce8a0	4896	numOutputs,
mjr	38:091e511ce8a0	4897	cfg.psUnitNo - 1, // report 0-15 range for unit number (we store 1-16 internally)
mjr	52:8298b2a73eb2	4898	cfg.plunger.cal.zero, cfg.plunger.cal.max, cfg.plunger.cal.tRelease,
mjr	75:677892300e7a	4899	nvm.valid(), // a config is loaded if the config memory block is valid
mjr	75:677892300e7a	4900	true, // we support sbx/pbx extensions
mjr	75:677892300e7a	4901	xmalloc_rem); // remaining memory size
mjr	39:b3815a1c3802	4902	break;
mjr	39:b3815a1c3802	4903
mjr	39:b3815a1c3802	4904	case 5:
mjr	38:091e511ce8a0	4905	// 5 = all outputs off, reset to LedWiz defaults
mjr	38:091e511ce8a0	4906	allOutputsOff();
mjr	39:b3815a1c3802	4907	break;
mjr	39:b3815a1c3802	4908
mjr	39:b3815a1c3802	4909	case 6:
mjr	38:091e511ce8a0	4910	// 6 = Save configuration to flash.
mjr	38:091e511ce8a0	4911	saveConfigToFlash();
mjr	38:091e511ce8a0	4912
mjr	53:9b2611964afc	4913	// before disconnecting, pause for the delay time specified in
mjr	53:9b2611964afc	4914	// the parameter byte (in seconds)
mjr	53:9b2611964afc	4915	rebootTime_us = data[2] * 1000000L;
mjr	53:9b2611964afc	4916	rebootTimer.start();
mjr	39:b3815a1c3802	4917	break;
mjr	40:cc0d9814522b	4918
mjr	40:cc0d9814522b	4919	case 7:
mjr	40:cc0d9814522b	4920	// 7 = Device ID report
mjr	53:9b2611964afc	4921	// data[2] = ID index: 1=CPU ID, 2=OpenSDA TUID
mjr	53:9b2611964afc	4922	js.reportID(data[2]);
mjr	40:cc0d9814522b	4923	break;
mjr	40:cc0d9814522b	4924
mjr	40:cc0d9814522b	4925	case 8:
mjr	40:cc0d9814522b	4926	// 8 = Engage/disengage night mode.
mjr	40:cc0d9814522b	4927	// data[2] = 1 to engage, 0 to disengage
mjr	40:cc0d9814522b	4928	setNightMode(data[2]);
mjr	40:cc0d9814522b	4929	break;
mjr	52:8298b2a73eb2	4930
mjr	52:8298b2a73eb2	4931	case 9:
mjr	52:8298b2a73eb2	4932	// 9 = Config variable query.
mjr	52:8298b2a73eb2	4933	// data[2] = config var ID
mjr	52:8298b2a73eb2	4934	// data[3] = array index (for array vars: button assignments, output ports)
mjr	52:8298b2a73eb2	4935	{
mjr	53:9b2611964afc	4936	// set up the reply buffer with the variable ID data, and zero out
mjr	53:9b2611964afc	4937	// the rest of the buffer
mjr	52:8298b2a73eb2	4938	uint8_t reply[8];
mjr	52:8298b2a73eb2	4939	reply[1] = data[2];
mjr	52:8298b2a73eb2	4940	reply[2] = data[3];
mjr	53:9b2611964afc	4941	memset(reply+3, 0, sizeof(reply)-3);
mjr	52:8298b2a73eb2	4942
mjr	52:8298b2a73eb2	4943	// query the value
mjr	52:8298b2a73eb2	4944	configVarGet(reply);
mjr	52:8298b2a73eb2	4945
mjr	52:8298b2a73eb2	4946	// send the reply
mjr	52:8298b2a73eb2	4947	js.reportConfigVar(reply + 1);
mjr	52:8298b2a73eb2	4948	}
mjr	52:8298b2a73eb2	4949	break;
mjr	53:9b2611964afc	4950
mjr	53:9b2611964afc	4951	case 10:
mjr	53:9b2611964afc	4952	// 10 = Build ID query.
mjr	53:9b2611964afc	4953	js.reportBuildInfo(getBuildID());
mjr	53:9b2611964afc	4954	break;
mjr	73:4e8ce0b18915	4955
mjr	73:4e8ce0b18915	4956	case 11:
mjr	73:4e8ce0b18915	4957	// 11 = TV ON relay control.
mjr	73:4e8ce0b18915	4958	// data[2] = operation:
mjr	73:4e8ce0b18915	4959	// 0 = turn relay off
mjr	73:4e8ce0b18915	4960	// 1 = turn relay on
mjr	73:4e8ce0b18915	4961	// 2 = pulse relay (as though the power-on timer fired)
mjr	73:4e8ce0b18915	4962	TVRelay(data[2]);
mjr	73:4e8ce0b18915	4963	break;
mjr	73:4e8ce0b18915	4964
mjr	73:4e8ce0b18915	4965	case 12:
mjr	74:822a92bc11d2	4966	// Unused
mjr	73:4e8ce0b18915	4967	break;
mjr	73:4e8ce0b18915	4968
mjr	73:4e8ce0b18915	4969	case 13:
mjr	73:4e8ce0b18915	4970	// 13 = Send button status report
mjr	73:4e8ce0b18915	4971	reportButtonStatus(js);
mjr	73:4e8ce0b18915	4972	break;
mjr	38:091e511ce8a0	4973	}
mjr	38:091e511ce8a0	4974	}
mjr	38:091e511ce8a0	4975	else if (data[0] == 66)
mjr	38:091e511ce8a0	4976	{
mjr	38:091e511ce8a0	4977	// Extended protocol - Set configuration variable.
mjr	38:091e511ce8a0	4978	// The second byte of the message is the ID of the variable
mjr	38:091e511ce8a0	4979	// to update, and the remaining bytes give the new value,
mjr	38:091e511ce8a0	4980	// in a variable-dependent format.
mjr	40:cc0d9814522b	4981	configVarSet(data);
mjr	38:091e511ce8a0	4982	}
mjr	74:822a92bc11d2	4983	else if (data[0] == 67)
mjr	74:822a92bc11d2	4984	{
mjr	74:822a92bc11d2	4985	// SBX - extended SBA message. This is the same as SBA, except
mjr	74:822a92bc11d2	4986	// that the 7th byte selects a group of 32 ports, to allow access
mjr	74:822a92bc11d2	4987	// to ports beyond the first 32.
mjr	74:822a92bc11d2	4988	sba_sbx(data[6], data);
mjr	74:822a92bc11d2	4989	}
mjr	74:822a92bc11d2	4990	else if (data[0] == 68)
mjr	74:822a92bc11d2	4991	{
mjr	74:822a92bc11d2	4992	// PBX - extended PBA message. This is similar to PBA, but
mjr	74:822a92bc11d2	4993	// allows access to more than the first 32 ports by encoding
mjr	74:822a92bc11d2	4994	// a port group byte that selects a block of 8 ports.
mjr	74:822a92bc11d2	4995
mjr	74:822a92bc11d2	4996	// get the port group - the first port is 8*group
mjr	74:822a92bc11d2	4997	int portGroup = data[1];
mjr	74:822a92bc11d2	4998
mjr	74:822a92bc11d2	4999	// unpack the brightness values
mjr	74:822a92bc11d2	5000	uint32_t tmp1 = data[2] \| (data[3]<<8) \| (data[4]<<16);
mjr	74:822a92bc11d2	5001	uint32_t tmp2 = data[5] \| (data[6]<<8) \| (data[7]<<16);
mjr	74:822a92bc11d2	5002	uint8_t bri[8] = {
mjr	74:822a92bc11d2	5003	tmp1 & 0x3F, (tmp1>>6) & 0x3F, (tmp1>>12) & 0x3F, (tmp1>>18) & 0x3F,
mjr	74:822a92bc11d2	5004	tmp2 & 0x3F, (tmp2>>6) & 0x3F, (tmp2>>12) & 0x3F, (tmp2>>18) & 0x3F
mjr	74:822a92bc11d2	5005	};
mjr	74:822a92bc11d2	5006
mjr	74:822a92bc11d2	5007	// map the flash levels: 60->129, 61->130, 62->131, 63->132
mjr	74:822a92bc11d2	5008	for (int i = 0 ; i < 8 ; ++i)
mjr	74:822a92bc11d2	5009	{
mjr	74:822a92bc11d2	5010	if (bri[i] >= 60)
mjr	74:822a92bc11d2	5011	bri[i] += 129-60;
mjr	74:822a92bc11d2	5012	}
mjr	74:822a92bc11d2	5013
mjr	74:822a92bc11d2	5014	// Carry out the PBA
mjr	74:822a92bc11d2	5015	pba_pbx(portGroup*8, bri);
mjr	74:822a92bc11d2	5016	}
mjr	38:091e511ce8a0	5017	else if (data[0] >= 200 && data[0] <= 228)
mjr	38:091e511ce8a0	5018	{
mjr	38:091e511ce8a0	5019	// Extended protocol - Extended output port brightness update.
mjr	38:091e511ce8a0	5020	// data[0]-200 gives us the bank of 7 outputs we're setting:
mjr	38:091e511ce8a0	5021	// 200 is outputs 0-6, 201 is outputs 7-13, 202 is 14-20, etc.
mjr	38:091e511ce8a0	5022	// The remaining bytes are brightness levels, 0-255, for the
mjr	38:091e511ce8a0	5023	// seven outputs in the selected bank. The LedWiz flashing
mjr	38:091e511ce8a0	5024	// modes aren't accessible in this message type; we can only
mjr	38:091e511ce8a0	5025	// set a fixed brightness, but in exchange we get 8-bit
mjr	38:091e511ce8a0	5026	// resolution rather than the paltry 0-48 scale that the real
mjr	38:091e511ce8a0	5027	// LedWiz uses. There's no separate on/off status for outputs
mjr	38:091e511ce8a0	5028	// adjusted with this message type, either, as there would be
mjr	38:091e511ce8a0	5029	// for a PBA message - setting a non-zero value immediately
mjr	38:091e511ce8a0	5030	// turns the output, overriding the last SBA setting.
mjr	38:091e511ce8a0	5031	//
mjr	38:091e511ce8a0	5032	// For outputs 0-31, this overrides any previous PBA/SBA
mjr	38:091e511ce8a0	5033	// settings for the port. Any subsequent PBA/SBA message will
mjr	38:091e511ce8a0	5034	// in turn override the setting made here. It's simple - the
mjr	38:091e511ce8a0	5035	// most recent message of either type takes precedence. For
mjr	38:091e511ce8a0	5036	// outputs above the LedWiz range, PBA/SBA messages can't
mjr	38:091e511ce8a0	5037	// address those ports anyway.
mjr	63:5cd1a5f3a41b	5038
mjr	63:5cd1a5f3a41b	5039	// flag that we're in extended protocol mode
mjr	74:822a92bc11d2	5040	ledWizMode = true;
mjr	63:5cd1a5f3a41b	5041
mjr	63:5cd1a5f3a41b	5042	// figure the block of 7 ports covered in the message
mjr	38:091e511ce8a0	5043	int i0 = (data[0] - 200)*7;
mjr	38:091e511ce8a0	5044	int i1 = i0 + 7 < numOutputs ? i0 + 7 : numOutputs;
mjr	63:5cd1a5f3a41b	5045
mjr	63:5cd1a5f3a41b	5046	// update each port
mjr	38:091e511ce8a0	5047	for (int i = i0 ; i < i1 ; ++i)
mjr	38:091e511ce8a0	5048	{
mjr	38:091e511ce8a0	5049	// set the brightness level for the output
mjr	40:cc0d9814522b	5050	uint8_t b = data[i-i0+1];
mjr	38:091e511ce8a0	5051	outLevel[i] = b;
mjr	38:091e511ce8a0	5052
mjr	74:822a92bc11d2	5053	// set the port's LedWiz state to the nearest equivalent, so
mjr	74:822a92bc11d2	5054	// that it maintains its current setting if we switch back to
mjr	74:822a92bc11d2	5055	// LedWiz mode on a future update
mjr	74:822a92bc11d2	5056	wizOn[i] = (b != 0);
mjr	74:822a92bc11d2	5057	wizVal[i] = (b*48)/255;
mjr	74:822a92bc11d2	5058
mjr	38:091e511ce8a0	5059	// set the output
mjr	40:cc0d9814522b	5060	lwPin[i]->set(b);
mjr	38:091e511ce8a0	5061	}
mjr	38:091e511ce8a0	5062
mjr	38:091e511ce8a0	5063	// update 74HC595 outputs, if attached
mjr	38:091e511ce8a0	5064	if (hc595 != 0)
mjr	38:091e511ce8a0	5065	hc595->update();
mjr	38:091e511ce8a0	5066	}
mjr	38:091e511ce8a0	5067	else
mjr	38:091e511ce8a0	5068	{
mjr	74:822a92bc11d2	5069	// Everything else is an LedWiz PBA message. This is a full
mjr	74:822a92bc11d2	5070	// "profile" dump from the host for one bank of 8 outputs. Each
mjr	74:822a92bc11d2	5071	// byte sets one output in the current bank. The current bank
mjr	74:822a92bc11d2	5072	// is implied; the bank starts at 0 and is reset to 0 by any SBA
mjr	74:822a92bc11d2	5073	// message, and is incremented to the next bank by each PBA. Our
mjr	74:822a92bc11d2	5074	// variable pbaIdx keeps track of the current bank. There's no
mjr	74:822a92bc11d2	5075	// direct way for the host to select the bank; it just has to count
mjr	74:822a92bc11d2	5076	// on us staying in sync. In practice, clients always send the
mjr	74:822a92bc11d2	5077	// full set of 4 PBA messages in a row to set all 32 outputs.
mjr	38:091e511ce8a0	5078	//
mjr	38:091e511ce8a0	5079	// Note that a PBA implicitly overrides our extended profile
mjr	38:091e511ce8a0	5080	// messages (message prefix 200-219), because this sets the
mjr	38:091e511ce8a0	5081	// wizVal[] entry for each output, and that takes precedence
mjr	63:5cd1a5f3a41b	5082	// over the extended protocol settings when we're in LedWiz
mjr	63:5cd1a5f3a41b	5083	// protocol mode.
mjr	38:091e511ce8a0	5084	//
mjr	38:091e511ce8a0	5085	//printf("LWZ-PBA[%d] %02x %02x %02x %02x %02x %02x %02x %02x\r\n",
mjr	38:091e511ce8a0	5086	// pbaIdx, data[0], data[1], data[2], data[3], data[4], data[5], data[6], data[7]);
mjr	38:091e511ce8a0	5087
mjr	74:822a92bc11d2	5088	// carry out the PBA
mjr	74:822a92bc11d2	5089	pba_pbx(pbaIdx, data);
mjr	74:822a92bc11d2	5090
mjr	74:822a92bc11d2	5091	// update the PBX index state for the next message
mjr	74:822a92bc11d2	5092	pbaIdx = (pbaIdx + 8) % 32;
mjr	38:091e511ce8a0	5093	}
mjr	38:091e511ce8a0	5094	}
mjr	35:e959ffba78fd	5095
mjr	38:091e511ce8a0	5096	// ---------------------------------------------------------------------------
mjr	38:091e511ce8a0	5097	//
mjr	5:a70c0bce770d	5098	// Main program loop. This is invoked on startup and runs forever. Our
mjr	5:a70c0bce770d	5099	// main work is to read our devices (the accelerometer and the CCD), process
mjr	5:a70c0bce770d	5100	// the readings into nudge and plunger position data, and send the results
mjr	5:a70c0bce770d	5101	// to the host computer via the USB joystick interface. We also monitor
mjr	5:a70c0bce770d	5102	// the USB connection for incoming LedWiz commands and process those into
mjr	5:a70c0bce770d	5103	// port outputs.
mjr	5:a70c0bce770d	5104	//
mjr	0:5acbbe3f4cf4	5105	int main(void)
mjr	0:5acbbe3f4cf4	5106	{
mjr	60:f38da020aa13	5107	// say hello to the debug console, in case it's connected
mjr	39:b3815a1c3802	5108	printf("\r\nPinscape Controller starting\r\n");
mjr	60:f38da020aa13	5109
mjr	60:f38da020aa13	5110	// debugging: print memory config info
mjr	59:94eb9265b6d7	5111	// -> no longer very useful, since we use our own custom malloc/new allocator (see xmalloc() above)
mjr	60:f38da020aa13	5112	// {int *a = new int; printf("Stack=%lx, heap=%lx, free=%ld\r\n", (long)&a, (long)a, (long)&a - (long)a);}
mjr	1:d913e0afb2ac	5113
mjr	39:b3815a1c3802	5114	// clear the I2C bus (for the accelerometer)
mjr	35:e959ffba78fd	5115	clear_i2c();
mjr	38:091e511ce8a0	5116
mjr	43:7a6364d82a41	5117	// load the saved configuration (or set factory defaults if no flash
mjr	43:7a6364d82a41	5118	// configuration has ever been saved)
mjr	35:e959ffba78fd	5119	loadConfigFromFlash();
mjr	35:e959ffba78fd	5120
mjr	38:091e511ce8a0	5121	// initialize the diagnostic LEDs
mjr	38:091e511ce8a0	5122	initDiagLEDs(cfg);
mjr	38:091e511ce8a0	5123
mjr	33:d832bcab089e	5124	// we're not connected/awake yet
mjr	33:d832bcab089e	5125	bool connected = false;
mjr	40:cc0d9814522b	5126	Timer connectChangeTimer;
mjr	33:d832bcab089e	5127
mjr	35:e959ffba78fd	5128	// create the plunger sensor interface
mjr	35:e959ffba78fd	5129	createPlunger();
mjr	33:d832bcab089e	5130
mjr	60:f38da020aa13	5131	// set up the TLC5940 interface, if these chips are present
mjr	35:e959ffba78fd	5132	init_tlc5940(cfg);
mjr	34:6b981a2afab7	5133
mjr	60:f38da020aa13	5134	// set up 74HC595 interface, if these chips are present
mjr	35:e959ffba78fd	5135	init_hc595(cfg);
mjr	6:cc35eb643e8f	5136
mjr	54:fd77a6b2f76c	5137	// Initialize the LedWiz ports. Note that the ordering here is important:
mjr	54:fd77a6b2f76c	5138	// this has to come after we create the TLC5940 and 74HC595 object instances
mjr	54:fd77a6b2f76c	5139	// (which we just did above), since we need to access those objects to set
mjr	54:fd77a6b2f76c	5140	// up ports assigned to the respective chips.
mjr	35:e959ffba78fd	5141	initLwOut(cfg);
mjr	48:058ace2aed1d	5142
mjr	60:f38da020aa13	5143	// start the TLC5940 refresh cycle clock
mjr	35:e959ffba78fd	5144	if (tlc5940 != 0)
mjr	35:e959ffba78fd	5145	tlc5940->start();
mjr	35:e959ffba78fd	5146
mjr	40:cc0d9814522b	5147	// start the TV timer, if applicable
mjr	40:cc0d9814522b	5148	startTVTimer(cfg);
mjr	48:058ace2aed1d	5149
mjr	35:e959ffba78fd	5150	// initialize the button input ports
mjr	35:e959ffba78fd	5151	bool kbKeys = false;
mjr	35:e959ffba78fd	5152	initButtons(cfg, kbKeys);
mjr	38:091e511ce8a0	5153
mjr	60:f38da020aa13	5154	// Create the joystick USB client. Note that the USB vendor/product ID
mjr	60:f38da020aa13	5155	// information comes from the saved configuration. Also note that we have
mjr	60:f38da020aa13	5156	// to wait until after initializing the input buttons (which we just did
mjr	60:f38da020aa13	5157	// above) to set up the interface, since the button setup will determine
mjr	60:f38da020aa13	5158	// whether or not we need to present a USB keyboard interface in addition
mjr	60:f38da020aa13	5159	// to the joystick interface.
mjr	51:57eb311faafa	5160	MyUSBJoystick js(cfg.usbVendorID, cfg.usbProductID, USB_VERSION_NO, false,
mjr	51:57eb311faafa	5161	cfg.joystickEnabled, kbKeys);
mjr	51:57eb311faafa	5162
mjr	60:f38da020aa13	5163	// Wait for the USB connection to start up. Show a distinctive diagnostic
mjr	60:f38da020aa13	5164	// flash pattern while waiting.
mjr	70:9f58735a1732	5165	Timer connTimeoutTimer, connFlashTimer;
mjr	70:9f58735a1732	5166	connTimeoutTimer.start();
mjr	70:9f58735a1732	5167	connFlashTimer.start();
mjr	51:57eb311faafa	5168	while (!js.configured())
mjr	51:57eb311faafa	5169	{
mjr	51:57eb311faafa	5170	// show one short yellow flash at 2-second intervals
mjr	70:9f58735a1732	5171	if (connFlashTimer.read_us() > 2000000)
mjr	51:57eb311faafa	5172	{
mjr	51:57eb311faafa	5173	// short yellow flash
mjr	51:57eb311faafa	5174	diagLED(1, 1, 0);
mjr	54:fd77a6b2f76c	5175	wait_us(50000);
mjr	51:57eb311faafa	5176	diagLED(0, 0, 0);
mjr	51:57eb311faafa	5177
mjr	51:57eb311faafa	5178	// reset the flash timer
mjr	70:9f58735a1732	5179	connFlashTimer.reset();
mjr	51:57eb311faafa	5180	}
mjr	70:9f58735a1732	5181
mjr	70:9f58735a1732	5182	if (cfg.disconnectRebootTimeout != 0
mjr	70:9f58735a1732	5183	&& connTimeoutTimer.read() > cfg.disconnectRebootTimeout)
mjr	70:9f58735a1732	5184	reboot(js, false, 0);
mjr	51:57eb311faafa	5185	}
mjr	60:f38da020aa13	5186
mjr	60:f38da020aa13	5187	// we're now connected to the host
mjr	54:fd77a6b2f76c	5188	connected = true;
mjr	40:cc0d9814522b	5189
mjr	60:f38da020aa13	5190	// Last report timer for the joytick interface. We use this timer to
mjr	60:f38da020aa13	5191	// throttle the report rate to a pace that's suitable for VP. Without
mjr	60:f38da020aa13	5192	// any artificial delays, we could generate data to send on the joystick
mjr	60:f38da020aa13	5193	// interface on every loop iteration. The loop iteration time depends
mjr	60:f38da020aa13	5194	// on which devices are attached, since most of the work in our main
mjr	60:f38da020aa13	5195	// loop is simply polling our devices. For typical setups, the loop
mjr	60:f38da020aa13	5196	// time ranges from about 0.25ms to 2.5ms; the biggest factor is the
mjr	60:f38da020aa13	5197	// plunger sensor. But VP polls for input about every 10ms, so there's
mjr	60:f38da020aa13	5198	// no benefit in sending data faster than that, and there's some harm,
mjr	60:f38da020aa13	5199	// in that it creates USB overhead (both on the wire and on the host
mjr	60:f38da020aa13	5200	// CPU). We therefore use this timer to pace our reports to roughly
mjr	60:f38da020aa13	5201	// the VP input polling rate. Note that there's no way to actually
mjr	60:f38da020aa13	5202	// synchronize with VP's polling, but there's also no need to, as the
mjr	60:f38da020aa13	5203	// input model is designed to reflect the overall current state at any
mjr	60:f38da020aa13	5204	// given time rather than events or deltas. If VP polls twice between
mjr	60:f38da020aa13	5205	// two updates, it simply sees no state change; if we send two updates
mjr	60:f38da020aa13	5206	// between VP polls, VP simply sees the latest state when it does get
mjr	60:f38da020aa13	5207	// around to polling.
mjr	38:091e511ce8a0	5208	Timer jsReportTimer;
mjr	38:091e511ce8a0	5209	jsReportTimer.start();
mjr	38:091e511ce8a0	5210
mjr	60:f38da020aa13	5211	// Time since we successfully sent a USB report. This is a hacky
mjr	60:f38da020aa13	5212	// workaround to deal with any remaining sporadic problems in the USB
mjr	60:f38da020aa13	5213	// stack. I've been trying to bulletproof the USB code over time to
mjr	60:f38da020aa13	5214	// remove all such problems at their source, but it seems unlikely that
mjr	60:f38da020aa13	5215	// we'll ever get them all. Thus this hack. The idea here is that if
mjr	60:f38da020aa13	5216	// we go too long without successfully sending a USB report, we'll
mjr	60:f38da020aa13	5217	// assume that the connection is broken (and the KL25Z USB hardware
mjr	60:f38da020aa13	5218	// hasn't noticed this), and we'll try taking measures to recover.
mjr	38:091e511ce8a0	5219	Timer jsOKTimer;
mjr	38:091e511ce8a0	5220	jsOKTimer.start();
mjr	35:e959ffba78fd	5221
mjr	55:4db125cd11a0	5222	// Initialize the calibration button and lamp, if enabled. To be enabled,
mjr	55:4db125cd11a0	5223	// the pin has to be assigned to something other than NC (0xFF), AND the
mjr	55:4db125cd11a0	5224	// corresponding feature enable flag has to be set.
mjr	55:4db125cd11a0	5225	DigitalIn *calBtn = 0;
mjr	55:4db125cd11a0	5226	DigitalOut *calBtnLed = 0;
mjr	55:4db125cd11a0	5227
mjr	55:4db125cd11a0	5228	// calibration button input - feature flag 0x01
mjr	55:4db125cd11a0	5229	if ((cfg.plunger.cal.features & 0x01) && cfg.plunger.cal.btn != 0xFF)
mjr	55:4db125cd11a0	5230	calBtn = new DigitalIn(wirePinName(cfg.plunger.cal.btn));
mjr	55:4db125cd11a0	5231
mjr	55:4db125cd11a0	5232	// calibration button indicator lamp output - feature flag 0x02
mjr	55:4db125cd11a0	5233	if ((cfg.plunger.cal.features & 0x02) && cfg.plunger.cal.led != 0xFF)
mjr	55:4db125cd11a0	5234	calBtnLed = new DigitalOut(wirePinName(cfg.plunger.cal.led));
mjr	6:cc35eb643e8f	5235
mjr	35:e959ffba78fd	5236	// initialize the calibration button
mjr	1:d913e0afb2ac	5237	calBtnTimer.start();
mjr	35:e959ffba78fd	5238	calBtnState = 0;
mjr	1:d913e0afb2ac	5239
mjr	1:d913e0afb2ac	5240	// set up a timer for our heartbeat indicator
mjr	1:d913e0afb2ac	5241	Timer hbTimer;
mjr	1:d913e0afb2ac	5242	hbTimer.start();
mjr	1:d913e0afb2ac	5243	int hb = 0;
mjr	5:a70c0bce770d	5244	uint16_t hbcnt = 0;
mjr	1:d913e0afb2ac	5245
mjr	1:d913e0afb2ac	5246	// set a timer for accelerometer auto-centering
mjr	1:d913e0afb2ac	5247	Timer acTimer;
mjr	1:d913e0afb2ac	5248	acTimer.start();
mjr	1:d913e0afb2ac	5249
mjr	0:5acbbe3f4cf4	5250	// create the accelerometer object
mjr	5:a70c0bce770d	5251	Accel accel(MMA8451_SCL_PIN, MMA8451_SDA_PIN, MMA8451_I2C_ADDRESS, MMA8451_INT_PIN);
mjr	48:058ace2aed1d	5252
mjr	17:ab3cec0c8bf4	5253	// last accelerometer report, in joystick units (we report the nudge
mjr	17:ab3cec0c8bf4	5254	// acceleration via the joystick x & y axes, per the VP convention)
mjr	17:ab3cec0c8bf4	5255	int x = 0, y = 0;
mjr	17:ab3cec0c8bf4	5256
mjr	48:058ace2aed1d	5257	// initialize the plunger sensor
mjr	35:e959ffba78fd	5258	plungerSensor->init();
mjr	10:976666ffa4ef	5259
mjr	48:058ace2aed1d	5260	// set up the ZB Launch Ball monitor
mjr	48:058ace2aed1d	5261	ZBLaunchBall zbLaunchBall;
mjr	48:058ace2aed1d	5262
mjr	54:fd77a6b2f76c	5263	// enable the peripheral chips
mjr	54:fd77a6b2f76c	5264	if (tlc5940 != 0)
mjr	54:fd77a6b2f76c	5265	tlc5940->enable(true);
mjr	54:fd77a6b2f76c	5266	if (hc595 != 0)
mjr	54:fd77a6b2f76c	5267	hc595->enable(true);
mjr	74:822a92bc11d2	5268
mjr	74:822a92bc11d2	5269	// start the LedWiz flash cycle timers
mjr	74:822a92bc11d2	5270	wizPulseTimer.start();
mjr	74:822a92bc11d2	5271	wizCycleTimer.start();
mjr	74:822a92bc11d2	5272
mjr	74:822a92bc11d2	5273	// start the PWM update polling timer
mjr	74:822a92bc11d2	5274	polledPwmTimer.start();
mjr	43:7a6364d82a41	5275
mjr	1:d913e0afb2ac	5276	// we're all set up - now just loop, processing sensor reports and
mjr	1:d913e0afb2ac	5277	// host requests
mjr	0:5acbbe3f4cf4	5278	for (;;)
mjr	0:5acbbe3f4cf4	5279	{
mjr	74:822a92bc11d2	5280	// start the main loop timer for diagnostic data collection
mjr	74:822a92bc11d2	5281	IF_DIAG(
mjr	74:822a92bc11d2	5282	Timer mainLoopTimer;
mjr	74:822a92bc11d2	5283	mainLoopTimer.start();
mjr	74:822a92bc11d2	5284	)
mjr	74:822a92bc11d2	5285
mjr	48:058ace2aed1d	5286	// Process incoming reports on the joystick interface. The joystick
mjr	48:058ace2aed1d	5287	// "out" (receive) endpoint is used for LedWiz commands and our
mjr	48:058ace2aed1d	5288	// extended protocol commands. Limit processing time to 5ms to
mjr	48:058ace2aed1d	5289	// ensure we don't starve the input side.
mjr	39:b3815a1c3802	5290	LedWizMsg lwm;
mjr	48:058ace2aed1d	5291	Timer lwt;
mjr	48:058ace2aed1d	5292	lwt.start();
mjr	74:822a92bc11d2	5293	IF_DIAG(int msgCount = 0;)
mjr	48:058ace2aed1d	5294	while (js.readLedWizMsg(lwm) && lwt.read_us() < 5000)
mjr	74:822a92bc11d2	5295	{
mjr	48:058ace2aed1d	5296	handleInputMsg(lwm, js);
mjr	74:822a92bc11d2	5297	IF_DIAG(++msgCount;)
mjr	74:822a92bc11d2	5298	}
mjr	74:822a92bc11d2	5299
mjr	74:822a92bc11d2	5300	// collect performance statistics on the message reader, if desired
mjr	74:822a92bc11d2	5301	IF_DIAG(
mjr	74:822a92bc11d2	5302	if (msgCount != 0)
mjr	74:822a92bc11d2	5303	{
mjr	74:822a92bc11d2	5304	mainLoopMsgTime += lwt.read();
mjr	74:822a92bc11d2	5305	mainLoopMsgCount++;
mjr	74:822a92bc11d2	5306	}
mjr	74:822a92bc11d2	5307	)
mjr	74:822a92bc11d2	5308
mjr	74:822a92bc11d2	5309	// update flashing LedWiz outputs periodically
mjr	74:822a92bc11d2	5310	wizPulse();
mjr	74:822a92bc11d2	5311
mjr	74:822a92bc11d2	5312	// update PWM outputs
mjr	74:822a92bc11d2	5313	pollPwmUpdates();
mjr	55:4db125cd11a0	5314
mjr	55:4db125cd11a0	5315	// send TLC5940 data updates if applicable
mjr	55:4db125cd11a0	5316	if (tlc5940 != 0)
mjr	55:4db125cd11a0	5317	tlc5940->send();
mjr	1:d913e0afb2ac	5318
mjr	1:d913e0afb2ac	5319	// check for plunger calibration
mjr	17:ab3cec0c8bf4	5320	if (calBtn != 0 && !calBtn->read())
mjr	0:5acbbe3f4cf4	5321	{
mjr	1:d913e0afb2ac	5322	// check the state
mjr	1:d913e0afb2ac	5323	switch (calBtnState)
mjr	0:5acbbe3f4cf4	5324	{
mjr	1:d913e0afb2ac	5325	case 0:
mjr	1:d913e0afb2ac	5326	// button not yet pushed - start debouncing
mjr	1:d913e0afb2ac	5327	calBtnTimer.reset();
mjr	1:d913e0afb2ac	5328	calBtnState = 1;
mjr	1:d913e0afb2ac	5329	break;
mjr	1:d913e0afb2ac	5330
mjr	1:d913e0afb2ac	5331	case 1:
mjr	1:d913e0afb2ac	5332	// pushed, not yet debounced - if the debounce time has
mjr	1:d913e0afb2ac	5333	// passed, start the hold period
mjr	48:058ace2aed1d	5334	if (calBtnTimer.read_us() > 50000)
mjr	1:d913e0afb2ac	5335	calBtnState = 2;
mjr	1:d913e0afb2ac	5336	break;
mjr	1:d913e0afb2ac	5337
mjr	1:d913e0afb2ac	5338	case 2:
mjr	1:d913e0afb2ac	5339	// in the hold period - if the button has been held down
mjr	1:d913e0afb2ac	5340	// for the entire hold period, move to calibration mode
mjr	48:058ace2aed1d	5341	if (calBtnTimer.read_us() > 2050000)
mjr	1:d913e0afb2ac	5342	{
mjr	1:d913e0afb2ac	5343	// enter calibration mode
mjr	1:d913e0afb2ac	5344	calBtnState = 3;
mjr	9:fd65b0a94720	5345	calBtnTimer.reset();
mjr	35:e959ffba78fd	5346
mjr	44:b5ac89b9cd5d	5347	// begin the plunger calibration limits
mjr	52:8298b2a73eb2	5348	plungerReader.setCalMode(true);
mjr	1:d913e0afb2ac	5349	}
mjr	1:d913e0afb2ac	5350	break;
mjr	2:c174f9ee414a	5351
mjr	2:c174f9ee414a	5352	case 3:
mjr	9:fd65b0a94720	5353	// Already in calibration mode - pushing the button here
mjr	9:fd65b0a94720	5354	// doesn't change the current state, but we won't leave this
mjr	9:fd65b0a94720	5355	// state as long as it's held down. So nothing changes here.
mjr	2:c174f9ee414a	5356	break;
mjr	0:5acbbe3f4cf4	5357	}
mjr	0:5acbbe3f4cf4	5358	}
mjr	1:d913e0afb2ac	5359	else
mjr	1:d913e0afb2ac	5360	{
mjr	2:c174f9ee414a	5361	// Button released. If we're in calibration mode, and
mjr	2:c174f9ee414a	5362	// the calibration time has elapsed, end the calibration
mjr	2:c174f9ee414a	5363	// and save the results to flash.
mjr	2:c174f9ee414a	5364	//
mjr	2:c174f9ee414a	5365	// Otherwise, return to the base state without saving anything.
mjr	2:c174f9ee414a	5366	// If the button is released before we make it to calibration
mjr	2:c174f9ee414a	5367	// mode, it simply cancels the attempt.
mjr	48:058ace2aed1d	5368	if (calBtnState == 3 && calBtnTimer.read_us() > 15000000)
mjr	2:c174f9ee414a	5369	{
mjr	2:c174f9ee414a	5370	// exit calibration mode
mjr	1:d913e0afb2ac	5371	calBtnState = 0;
mjr	52:8298b2a73eb2	5372	plungerReader.setCalMode(false);
mjr	2:c174f9ee414a	5373
mjr	6:cc35eb643e8f	5374	// save the updated configuration
mjr	35:e959ffba78fd	5375	cfg.plunger.cal.calibrated = 1;
mjr	35:e959ffba78fd	5376	saveConfigToFlash();
mjr	2:c174f9ee414a	5377	}
mjr	2:c174f9ee414a	5378	else if (calBtnState != 3)
mjr	2:c174f9ee414a	5379	{
mjr	2:c174f9ee414a	5380	// didn't make it to calibration mode - cancel the operation
mjr	1:d913e0afb2ac	5381	calBtnState = 0;
mjr	2:c174f9ee414a	5382	}
mjr	1:d913e0afb2ac	5383	}
mjr	1:d913e0afb2ac	5384
mjr	1:d913e0afb2ac	5385	// light/flash the calibration button light, if applicable
mjr	1:d913e0afb2ac	5386	int newCalBtnLit = calBtnLit;
mjr	1:d913e0afb2ac	5387	switch (calBtnState)
mjr	0:5acbbe3f4cf4	5388	{
mjr	1:d913e0afb2ac	5389	case 2:
mjr	1:d913e0afb2ac	5390	// in the hold period - flash the light
mjr	48:058ace2aed1d	5391	newCalBtnLit = ((calBtnTimer.read_us()/250000) & 1);
mjr	1:d913e0afb2ac	5392	break;
mjr	1:d913e0afb2ac	5393
mjr	1:d913e0afb2ac	5394	case 3:
mjr	1:d913e0afb2ac	5395	// calibration mode - show steady on
mjr	1:d913e0afb2ac	5396	newCalBtnLit = true;
mjr	1:d913e0afb2ac	5397	break;
mjr	1:d913e0afb2ac	5398
mjr	1:d913e0afb2ac	5399	default:
mjr	1:d913e0afb2ac	5400	// not calibrating/holding - show steady off
mjr	1:d913e0afb2ac	5401	newCalBtnLit = false;
mjr	1:d913e0afb2ac	5402	break;
mjr	1:d913e0afb2ac	5403	}
mjr	3:3514575d4f86	5404
mjr	3:3514575d4f86	5405	// light or flash the external calibration button LED, and
mjr	3:3514575d4f86	5406	// do the same with the on-board blue LED
mjr	1:d913e0afb2ac	5407	if (calBtnLit != newCalBtnLit)
mjr	1:d913e0afb2ac	5408	{
mjr	1:d913e0afb2ac	5409	calBtnLit = newCalBtnLit;
mjr	2:c174f9ee414a	5410	if (calBtnLit) {
mjr	17:ab3cec0c8bf4	5411	if (calBtnLed != 0)
mjr	17:ab3cec0c8bf4	5412	calBtnLed->write(1);
mjr	38:091e511ce8a0	5413	diagLED(0, 0, 1); // blue
mjr	2:c174f9ee414a	5414	}
mjr	2:c174f9ee414a	5415	else {
mjr	17:ab3cec0c8bf4	5416	if (calBtnLed != 0)
mjr	17:ab3cec0c8bf4	5417	calBtnLed->write(0);
mjr	38:091e511ce8a0	5418	diagLED(0, 0, 0); // off
mjr	2:c174f9ee414a	5419	}
mjr	1:d913e0afb2ac	5420	}
mjr	35:e959ffba78fd	5421
mjr	48:058ace2aed1d	5422	// read the plunger sensor
mjr	48:058ace2aed1d	5423	plungerReader.read();
mjr	48:058ace2aed1d	5424
mjr	53:9b2611964afc	5425	// update the ZB Launch Ball status
mjr	53:9b2611964afc	5426	zbLaunchBall.update();
mjr	37:ed52738445fc	5427
mjr	53:9b2611964afc	5428	// process button updates
mjr	53:9b2611964afc	5429	processButtons(cfg);
mjr	53:9b2611964afc	5430
mjr	38:091e511ce8a0	5431	// send a keyboard report if we have new data
mjr	37:ed52738445fc	5432	if (kbState.changed)
mjr	37:ed52738445fc	5433	{
mjr	38:091e511ce8a0	5434	// send a keyboard report
mjr	37:ed52738445fc	5435	js.kbUpdate(kbState.data);
mjr	37:ed52738445fc	5436	kbState.changed = false;
mjr	37:ed52738445fc	5437	}
mjr	38:091e511ce8a0	5438
mjr	38:091e511ce8a0	5439	// likewise for the media controller
mjr	37:ed52738445fc	5440	if (mediaState.changed)
mjr	37:ed52738445fc	5441	{
mjr	38:091e511ce8a0	5442	// send a media report
mjr	37:ed52738445fc	5443	js.mediaUpdate(mediaState.data);
mjr	37:ed52738445fc	5444	mediaState.changed = false;
mjr	37:ed52738445fc	5445	}
mjr	38:091e511ce8a0	5446
mjr	38:091e511ce8a0	5447	// flag: did we successfully send a joystick report on this round?
mjr	38:091e511ce8a0	5448	bool jsOK = false;
mjr	55:4db125cd11a0	5449
mjr	55:4db125cd11a0	5450	// figure the current status flags for joystick reports
mjr	55:4db125cd11a0	5451	uint16_t statusFlags =
mjr	55:4db125cd11a0	5452	(cfg.plunger.enabled ? 0x01 : 0x00)
mjr	73:4e8ce0b18915	5453	\| (nightMode ? 0x02 : 0x00)
mjr	73:4e8ce0b18915	5454	\| ((psu2_state & 0x07) << 2);
mjr	17:ab3cec0c8bf4	5455
mjr	50:40015764bbe6	5456	// If it's been long enough since our last USB status report, send
mjr	50:40015764bbe6	5457	// the new report. VP only polls for input in 10ms intervals, so
mjr	50:40015764bbe6	5458	// there's no benefit in sending reports more frequently than this.
mjr	50:40015764bbe6	5459	// More frequent reporting would only add USB I/O overhead.
mjr	50:40015764bbe6	5460	if (cfg.joystickEnabled && jsReportTimer.read_us() > 10000UL)
mjr	17:ab3cec0c8bf4	5461	{
mjr	17:ab3cec0c8bf4	5462	// read the accelerometer
mjr	17:ab3cec0c8bf4	5463	int xa, ya;
mjr	17:ab3cec0c8bf4	5464	accel.get(xa, ya);
mjr	17:ab3cec0c8bf4	5465
mjr	17:ab3cec0c8bf4	5466	// confine the results to our joystick axis range
mjr	17:ab3cec0c8bf4	5467	if (xa < -JOYMAX) xa = -JOYMAX;
mjr	17:ab3cec0c8bf4	5468	if (xa > JOYMAX) xa = JOYMAX;
mjr	17:ab3cec0c8bf4	5469	if (ya < -JOYMAX) ya = -JOYMAX;
mjr	17:ab3cec0c8bf4	5470	if (ya > JOYMAX) ya = JOYMAX;
mjr	17:ab3cec0c8bf4	5471
mjr	17:ab3cec0c8bf4	5472	// store the updated accelerometer coordinates
mjr	17:ab3cec0c8bf4	5473	x = xa;
mjr	17:ab3cec0c8bf4	5474	y = ya;
mjr	17:ab3cec0c8bf4	5475
mjr	48:058ace2aed1d	5476	// Report the current plunger position unless the plunger is
mjr	48:058ace2aed1d	5477	// disabled, or the ZB Launch Ball signal is on. In either of
mjr	48:058ace2aed1d	5478	// those cases, just report a constant 0 value. ZB Launch Ball
mjr	48:058ace2aed1d	5479	// temporarily disables mechanical plunger reporting because it
mjr	21:5048e16cc9ef	5480	// tells us that the table has a Launch Ball button instead of
mjr	48:058ace2aed1d	5481	// a traditional plunger, so we don't want to confuse VP with
mjr	48:058ace2aed1d	5482	// regular plunger inputs.
mjr	48:058ace2aed1d	5483	int z = plungerReader.getPosition();
mjr	53:9b2611964afc	5484	int zrep = (!cfg.plunger.enabled \|\| zbLaunchOn ? 0 : z);
mjr	35:e959ffba78fd	5485
mjr	35:e959ffba78fd	5486	// rotate X and Y according to the device orientation in the cabinet
mjr	35:e959ffba78fd	5487	accelRotate(x, y);
mjr	35:e959ffba78fd	5488
mjr	35:e959ffba78fd	5489	// send the joystick report
mjr	53:9b2611964afc	5490	jsOK = js.update(x, y, zrep, jsButtons, statusFlags);
mjr	21:5048e16cc9ef	5491
mjr	17:ab3cec0c8bf4	5492	// we've just started a new report interval, so reset the timer
mjr	38:091e511ce8a0	5493	jsReportTimer.reset();
mjr	17:ab3cec0c8bf4	5494	}
mjr	21:5048e16cc9ef	5495
mjr	52:8298b2a73eb2	5496	// If we're in sensor status mode, report all pixel exposure values
mjr	52:8298b2a73eb2	5497	if (reportPlungerStat)
mjr	10:976666ffa4ef	5498	{
mjr	17:ab3cec0c8bf4	5499	// send the report
mjr	53:9b2611964afc	5500	plungerSensor->sendStatusReport(js, reportPlungerStatFlags, reportPlungerStatTime);
mjr	17:ab3cec0c8bf4	5501
mjr	10:976666ffa4ef	5502	// we have satisfied this request
mjr	52:8298b2a73eb2	5503	reportPlungerStat = false;
mjr	10:976666ffa4ef	5504	}
mjr	10:976666ffa4ef	5505
mjr	35:e959ffba78fd	5506	// If joystick reports are turned off, send a generic status report
mjr	35:e959ffba78fd	5507	// periodically for the sake of the Windows config tool.
mjr	55:4db125cd11a0	5508	if (!cfg.joystickEnabled && jsReportTimer.read_us() > 5000)
mjr	21:5048e16cc9ef	5509	{
mjr	55:4db125cd11a0	5510	jsOK = js.updateStatus(statusFlags);
mjr	38:091e511ce8a0	5511	jsReportTimer.reset();
mjr	38:091e511ce8a0	5512	}
mjr	38:091e511ce8a0	5513
mjr	38:091e511ce8a0	5514	// if we successfully sent a joystick report, reset the watchdog timer
mjr	38:091e511ce8a0	5515	if (jsOK)
mjr	38:091e511ce8a0	5516	{
mjr	38:091e511ce8a0	5517	jsOKTimer.reset();
mjr	38:091e511ce8a0	5518	jsOKTimer.start();
mjr	21:5048e16cc9ef	5519	}
mjr	21:5048e16cc9ef	5520
mjr	6:cc35eb643e8f	5521	#ifdef DEBUG_PRINTF
mjr	6:cc35eb643e8f	5522	if (x != 0 \|\| y != 0)
mjr	6:cc35eb643e8f	5523	printf("%d,%d\r\n", x, y);
mjr	6:cc35eb643e8f	5524	#endif
mjr	6:cc35eb643e8f	5525
mjr	33:d832bcab089e	5526	// check for connection status changes
mjr	54:fd77a6b2f76c	5527	bool newConnected = js.isConnected() && !js.isSleeping();
mjr	33:d832bcab089e	5528	if (newConnected != connected)
mjr	33:d832bcab089e	5529	{
mjr	54:fd77a6b2f76c	5530	// give it a moment to stabilize
mjr	40:cc0d9814522b	5531	connectChangeTimer.start();
mjr	55:4db125cd11a0	5532	if (connectChangeTimer.read_us() > 1000000)
mjr	33:d832bcab089e	5533	{
mjr	33:d832bcab089e	5534	// note the new status
mjr	33:d832bcab089e	5535	connected = newConnected;
mjr	40:cc0d9814522b	5536
mjr	40:cc0d9814522b	5537	// done with the change timer for this round - reset it for next time
mjr	40:cc0d9814522b	5538	connectChangeTimer.stop();
mjr	40:cc0d9814522b	5539	connectChangeTimer.reset();
mjr	33:d832bcab089e	5540
mjr	54:fd77a6b2f76c	5541	// if we're newly disconnected, clean up for PC suspend mode or power off
mjr	54:fd77a6b2f76c	5542	if (!connected)
mjr	40:cc0d9814522b	5543	{
mjr	54:fd77a6b2f76c	5544	// turn off all outputs
mjr	33:d832bcab089e	5545	allOutputsOff();
mjr	40:cc0d9814522b	5546
mjr	40:cc0d9814522b	5547	// The KL25Z runs off of USB power, so we might (depending on the PC
mjr	40:cc0d9814522b	5548	// and OS configuration) continue to receive power even when the main
mjr	40:cc0d9814522b	5549	// PC power supply is turned off, such as in soft-off or suspend/sleep
mjr	40:cc0d9814522b	5550	// mode. Any external output controller chips (TLC5940, 74HC595) might
mjr	40:cc0d9814522b	5551	// be powered from the PC power supply directly rather than from our
mjr	40:cc0d9814522b	5552	// USB power, so they might be powered off even when we're still running.
mjr	40:cc0d9814522b	5553	// To ensure cleaner startup when the power comes back on, globally
mjr	40:cc0d9814522b	5554	// disable the outputs. The global disable signals come from GPIO lines
mjr	40:cc0d9814522b	5555	// that remain powered as long as the KL25Z is powered, so these modes
mjr	40:cc0d9814522b	5556	// will apply smoothly across power state transitions in the external
mjr	40:cc0d9814522b	5557	// hardware. That is, when the external chips are powered up, they'll
mjr	40:cc0d9814522b	5558	// see the global disable signals as stable voltage inputs immediately,
mjr	40:cc0d9814522b	5559	// which will cause them to suppress any output triggering. This ensures
mjr	40:cc0d9814522b	5560	// that we don't fire any solenoids or flash any lights spuriously when
mjr	40:cc0d9814522b	5561	// the power first comes on.
mjr	40:cc0d9814522b	5562	if (tlc5940 != 0)
mjr	40:cc0d9814522b	5563	tlc5940->enable(false);
mjr	40:cc0d9814522b	5564	if (hc595 != 0)
mjr	40:cc0d9814522b	5565	hc595->enable(false);
mjr	40:cc0d9814522b	5566	}
mjr	33:d832bcab089e	5567	}
mjr	33:d832bcab089e	5568	}
mjr	48:058ace2aed1d	5569
mjr	53:9b2611964afc	5570	// if we have a reboot timer pending, check for completion
mjr	53:9b2611964afc	5571	if (rebootTimer.isRunning() && rebootTimer.read_us() > rebootTime_us)
mjr	53:9b2611964afc	5572	reboot(js);
mjr	53:9b2611964afc	5573
mjr	48:058ace2aed1d	5574	// if we're disconnected, initiate a new connection
mjr	51:57eb311faafa	5575	if (!connected)
mjr	48:058ace2aed1d	5576	{
mjr	54:fd77a6b2f76c	5577	// show USB HAL debug events
mjr	54:fd77a6b2f76c	5578	extern void HAL_DEBUG_PRINTEVENTS(const char *prefix);
mjr	54:fd77a6b2f76c	5579	HAL_DEBUG_PRINTEVENTS(">DISC");
mjr	54:fd77a6b2f76c	5580
mjr	54:fd77a6b2f76c	5581	// show immediate diagnostic feedback
mjr	54:fd77a6b2f76c	5582	js.diagFlash();
mjr	54:fd77a6b2f76c	5583
mjr	54:fd77a6b2f76c	5584	// clear any previous diagnostic LED display
mjr	54:fd77a6b2f76c	5585	diagLED(0, 0, 0);
mjr	51:57eb311faafa	5586
mjr	51:57eb311faafa	5587	// set up a timer to monitor the reboot timeout
mjr	70:9f58735a1732	5588	Timer reconnTimeoutTimer;
mjr	70:9f58735a1732	5589	reconnTimeoutTimer.start();
mjr	48:058ace2aed1d	5590
mjr	54:fd77a6b2f76c	5591	// set up a timer for diagnostic displays
mjr	54:fd77a6b2f76c	5592	Timer diagTimer;
mjr	54:fd77a6b2f76c	5593	diagTimer.reset();
mjr	54:fd77a6b2f76c	5594	diagTimer.start();
mjr	74:822a92bc11d2	5595
mjr	74:822a92bc11d2	5596	// turn off the main loop timer while spinning
mjr	74:822a92bc11d2	5597	IF_DIAG(mainLoopTimer.stop();)
mjr	54:fd77a6b2f76c	5598
mjr	54:fd77a6b2f76c	5599	// loop until we get our connection back
mjr	54:fd77a6b2f76c	5600	while (!js.isConnected() \|\| js.isSleeping())
mjr	51:57eb311faafa	5601	{
mjr	54:fd77a6b2f76c	5602	// try to recover the connection
mjr	54:fd77a6b2f76c	5603	js.recoverConnection();
mjr	54:fd77a6b2f76c	5604
mjr	55:4db125cd11a0	5605	// send TLC5940 data if necessary
mjr	55:4db125cd11a0	5606	if (tlc5940 != 0)
mjr	55:4db125cd11a0	5607	tlc5940->send();
mjr	55:4db125cd11a0	5608
mjr	54:fd77a6b2f76c	5609	// show a diagnostic flash every couple of seconds
mjr	54:fd77a6b2f76c	5610	if (diagTimer.read_us() > 2000000)
mjr	51:57eb311faafa	5611	{
mjr	54:fd77a6b2f76c	5612	// flush the USB HAL debug events, if in debug mode
mjr	54:fd77a6b2f76c	5613	HAL_DEBUG_PRINTEVENTS(">NC");
mjr	54:fd77a6b2f76c	5614
mjr	54:fd77a6b2f76c	5615	// show diagnostic feedback
mjr	54:fd77a6b2f76c	5616	js.diagFlash();
mjr	51:57eb311faafa	5617
mjr	51:57eb311faafa	5618	// reset the flash timer
mjr	54:fd77a6b2f76c	5619	diagTimer.reset();
mjr	51:57eb311faafa	5620	}
mjr	51:57eb311faafa	5621
mjr	51:57eb311faafa	5622	// if the disconnect reboot timeout has expired, reboot
mjr	51:57eb311faafa	5623	if (cfg.disconnectRebootTimeout != 0
mjr	70:9f58735a1732	5624	&& reconnTimeoutTimer.read() > cfg.disconnectRebootTimeout)
mjr	54:fd77a6b2f76c	5625	reboot(js, false, 0);
mjr	54:fd77a6b2f76c	5626	}
mjr	54:fd77a6b2f76c	5627
mjr	74:822a92bc11d2	5628	// resume the main loop timer
mjr	74:822a92bc11d2	5629	IF_DIAG(mainLoopTimer.start();)
mjr	74:822a92bc11d2	5630
mjr	54:fd77a6b2f76c	5631	// if we made it out of that loop alive, we're connected again!
mjr	54:fd77a6b2f76c	5632	connected = true;
mjr	54:fd77a6b2f76c	5633	HAL_DEBUG_PRINTEVENTS(">C");
mjr	54:fd77a6b2f76c	5634
mjr	54:fd77a6b2f76c	5635	// Enable peripheral chips and update them with current output data
mjr	54:fd77a6b2f76c	5636	if (tlc5940 != 0)
mjr	54:fd77a6b2f76c	5637	{
mjr	55:4db125cd11a0	5638	tlc5940->enable(true);
mjr	54:fd77a6b2f76c	5639	tlc5940->update(true);
mjr	54:fd77a6b2f76c	5640	}
mjr	54:fd77a6b2f76c	5641	if (hc595 != 0)
mjr	54:fd77a6b2f76c	5642	{
mjr	55:4db125cd11a0	5643	hc595->enable(true);
mjr	54:fd77a6b2f76c	5644	hc595->update(true);
mjr	51:57eb311faafa	5645	}
mjr	48:058ace2aed1d	5646	}
mjr	43:7a6364d82a41	5647
mjr	6:cc35eb643e8f	5648	// provide a visual status indication on the on-board LED
mjr	48:058ace2aed1d	5649	if (calBtnState < 2 && hbTimer.read_us() > 1000000)
mjr	1:d913e0afb2ac	5650	{
mjr	54:fd77a6b2f76c	5651	if (jsOKTimer.read_us() > 1000000)
mjr	38:091e511ce8a0	5652	{
mjr	39:b3815a1c3802	5653	// USB freeze - show red/yellow.
mjr	40:cc0d9814522b	5654	//
mjr	54:fd77a6b2f76c	5655	// It's been more than a second since we successfully sent a joystick
mjr	54:fd77a6b2f76c	5656	// update message. This must mean that something's wrong on the USB
mjr	54:fd77a6b2f76c	5657	// connection, even though we haven't detected an outright disconnect.
mjr	54:fd77a6b2f76c	5658	// Show a distinctive diagnostic LED pattern when this occurs.
mjr	38:091e511ce8a0	5659	hb = !hb;
mjr	38:091e511ce8a0	5660	diagLED(1, hb, 0);
mjr	54:fd77a6b2f76c	5661
mjr	54:fd77a6b2f76c	5662	// If the reboot-on-disconnect option is in effect, treat this condition
mjr	54:fd77a6b2f76c	5663	// as equivalent to a disconnect, since something is obviously wrong
mjr	54:fd77a6b2f76c	5664	// with the USB connection.
mjr	54:fd77a6b2f76c	5665	if (cfg.disconnectRebootTimeout != 0)
mjr	54:fd77a6b2f76c	5666	{
mjr	54:fd77a6b2f76c	5667	// The reboot timeout is in effect. If we've been incommunicado for
mjr	54:fd77a6b2f76c	5668	// longer than the timeout, reboot. If we haven't reached the time
mjr	54:fd77a6b2f76c	5669	// limit, keep running for now, and leave the OK timer running so
mjr	54:fd77a6b2f76c	5670	// that we can continue to monitor this.
mjr	54:fd77a6b2f76c	5671	if (jsOKTimer.read() > cfg.disconnectRebootTimeout)
mjr	54:fd77a6b2f76c	5672	reboot(js, false, 0);
mjr	54:fd77a6b2f76c	5673	}
mjr	54:fd77a6b2f76c	5674	else
mjr	54:fd77a6b2f76c	5675	{
mjr	54:fd77a6b2f76c	5676	// There's no reboot timer, so just keep running with the diagnostic
mjr	54:fd77a6b2f76c	5677	// pattern displayed. Since we're not waiting for any other timed
mjr	54:fd77a6b2f76c	5678	// conditions in this state, stop the timer so that it doesn't
mjr	54:fd77a6b2f76c	5679	// overflow if this condition persists for a long time.
mjr	54:fd77a6b2f76c	5680	jsOKTimer.stop();
mjr	54:fd77a6b2f76c	5681	}
mjr	38:091e511ce8a0	5682	}
mjr	73:4e8ce0b18915	5683	else if (psu2_state >= 4)
mjr	73:4e8ce0b18915	5684	{
mjr	73:4e8ce0b18915	5685	// We're in the TV timer countdown. Skip the normal heartbeat
mjr	73:4e8ce0b18915	5686	// flashes and show the TV timer flashes instead.
mjr	73:4e8ce0b18915	5687	diagLED(0, 0, 0);
mjr	73:4e8ce0b18915	5688	}
mjr	35:e959ffba78fd	5689	else if (cfg.plunger.enabled && !cfg.plunger.cal.calibrated)
mjr	6:cc35eb643e8f	5690	{
mjr	6:cc35eb643e8f	5691	// connected, plunger calibration needed - flash yellow/green
mjr	6:cc35eb643e8f	5692	hb = !hb;
mjr	38:091e511ce8a0	5693	diagLED(hb, 1, 0);
mjr	6:cc35eb643e8f	5694	}
mjr	6:cc35eb643e8f	5695	else
mjr	6:cc35eb643e8f	5696	{
mjr	6:cc35eb643e8f	5697	// connected - flash blue/green
mjr	2:c174f9ee414a	5698	hb = !hb;
mjr	38:091e511ce8a0	5699	diagLED(0, hb, !hb);
mjr	2:c174f9ee414a	5700	}
mjr	1:d913e0afb2ac	5701
mjr	1:d913e0afb2ac	5702	// reset the heartbeat timer
mjr	1:d913e0afb2ac	5703	hbTimer.reset();
mjr	5:a70c0bce770d	5704	++hbcnt;
mjr	1:d913e0afb2ac	5705	}
mjr	74:822a92bc11d2	5706
mjr	74:822a92bc11d2	5707	// collect statistics on the main loop time, if desired
mjr	74:822a92bc11d2	5708	IF_DIAG(
mjr	74:822a92bc11d2	5709	mainLoopIterTime += mainLoopTimer.read();
mjr	74:822a92bc11d2	5710	mainLoopIterCount++;
mjr	74:822a92bc11d2	5711	)
mjr	1:d913e0afb2ac	5712	}
mjr	0:5acbbe3f4cf4	5713	}

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Type:	Program
Mbed OS support:	Mbed 2 deprecated
Created:	01 Oct 2021
Imports:	0
Forks:	0
Commits:	117
Dependents:	0
Dependencies:	4
Followers:	1

main.cpp@75:677892300e7a, 2017-01-29 (annotated)

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