Pinscape_Controller_V2_arnoz

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Arnaud VALLEY / Mbed 2 deprecated Pinscape_Controller_V2_arnoz

Dependencies: mbed FastIO FastPWM USBDevice

config.h@66:2e3583fbd2f4, 2016-11-27 (annotated)

Committer:: mjr
Date:: Sun Nov 27 06:37:47 2016 +0000
Revision:: 66:2e3583fbd2f4
Parent:: 65:739875521aae
Child:: 67:c39e66c4e000

Add "local shift button", which allows each physical button to have two key mappings (normal and shifted)

Who changed what in which revision?

User	Revision	Line number	New contents of line
mjr	17:ab3cec0c8bf4	1	// Pinscape Controller Configuration
mjr	17:ab3cec0c8bf4	2	//
mjr	55:4db125cd11a0	3	// New for 2016: dynamic configuration! To configure the controller,
mjr	55:4db125cd11a0	4	// connect the KL25Z to your PC, install the STANDARD pre-compiled .bin
mjr	55:4db125cd11a0	5	// file, and run the Windows config tool. There's no need (as there was in
mjr	55:4db125cd11a0	6	// the past) to edit the source code or to compile a custom version of the
mjr	55:4db125cd11a0	7	// binary just to customize setup options.
mjr	35:e959ffba78fd	8	//
mjr	55:4db125cd11a0	9	// In earlier versions, configuration was handled mostly with #ifdef and
mjr	55:4db125cd11a0	10	// similar constructs. To customize the setup, you had to create a private
mjr	55:4db125cd11a0	11	// forked copy of the source code, edit the constants defined in config.h,
mjr	55:4db125cd11a0	12	// and compile a custom binary. That's no longer necessary!
mjr	35:e959ffba78fd	13	//
mjr	35:e959ffba78fd	14	// The new approach is to do everything (or as much as possible, anyway)
mjr	35:e959ffba78fd	15	// via the Windows config tool. You shouldn't have to recompile a custom
mjr	35:e959ffba78fd	16	// version just to make a configurable change. Of course, you're still free
mjr	55:4db125cd11a0	17	// to create a custom version if you want to add entirely new features or
mjr	55:4db125cd11a0	18	// make changes that go beyond what the setup tool exposes.
mjr	35:e959ffba78fd	19	//
mjr	35:e959ffba78fd	20
mjr	55:4db125cd11a0	21	// Pre-packaged configuration selection.
mjr	55:4db125cd11a0	22	//
mjr	55:4db125cd11a0	23	// IMPORTANT! If you just want to create a custom configuration, DON'T
mjr	55:4db125cd11a0	24	// modify this file, DON'T use these macros, and DON'T compiler on mbed.
mjr	55:4db125cd11a0	25	// Instead, use the unmodified standard build and configure your system
mjr	55:4db125cd11a0	26	// using the Pinscape Config Tool on Windows. That's easier and better
mjr	55:4db125cd11a0	27	// because the config tool will be able to back up your settings to a
mjr	55:4db125cd11a0	28	// local file on your PC, and will automatically preserve your settings
mjr	55:4db125cd11a0	29	// across upgrades. You won't have to worry about merging your changes
mjr	55:4db125cd11a0	30	// into every update of the repository source code, since you'll never
mjr	55:4db125cd11a0	31	// have to change the source code.
mjr	55:4db125cd11a0	32	//
mjr	55:4db125cd11a0	33	// The different configurations here are purely for testing purposes.
mjr	55:4db125cd11a0	34	// The standard build uses the STANDARD_CONFIG settings, which are the
mjr	55:4db125cd11a0	35	// same as the original version where you had to modify config.h by hand
mjr	55:4db125cd11a0	36	// to customize your system.
mjr	55:4db125cd11a0	37	//
mjr	55:4db125cd11a0	38	#define STANDARD_CONFIG 1 // standard settings, based on v1 base settings
mjr	55:4db125cd11a0	39	#define TEST_CONFIG_EXPAN 0 // configuration for the expansion boards
mjr	55:4db125cd11a0	40	#define TEST_KEEP_PRINTF 0 // for debugging purposes, keep printf() enabled
mjr	55:4db125cd11a0	41	// by leaving the SDA UART GPIO pins unallocated
mjr	48:058ace2aed1d	42
mjr	17:ab3cec0c8bf4	43
mjr	25:e22b88bd783a	44	#ifndef CONFIG_H
mjr	25:e22b88bd783a	45	#define CONFIG_H
mjr	17:ab3cec0c8bf4	46
mjr	35:e959ffba78fd	47	// Plunger type codes
mjr	35:e959ffba78fd	48	// NOTE! These values are part of the external USB interface. New
mjr	35:e959ffba78fd	49	// values can be added, but the meaning of an existing assigned number
mjr	35:e959ffba78fd	50	// should remain fixed to keep the PC-side config tool compatible across
mjr	35:e959ffba78fd	51	// versions.
mjr	35:e959ffba78fd	52	const int PlungerType_None = 0; // no plunger
mjr	35:e959ffba78fd	53	const int PlungerType_TSL1410RS = 1; // TSL1410R linear image sensor (1280x1 pixels, 400dpi), serial mode
mjr	35:e959ffba78fd	54	const int PlungerType_TSL1410RP = 2; // TSL1410R, parallel mode (reads the two sensor sections concurrently)
mjr	35:e959ffba78fd	55	const int PlungerType_TSL1412RS = 3; // TSL1412R linear image sensor (1536x1 pixels, 400dpi), serial mode
mjr	35:e959ffba78fd	56	const int PlungerType_TSL1412RP = 4; // TSL1412R, parallel mode
mjr	35:e959ffba78fd	57	const int PlungerType_Pot = 5; // potentionmeter
mjr	35:e959ffba78fd	58	const int PlungerType_OptQuad = 6; // AEDR8300 optical quadrature sensor
mjr	35:e959ffba78fd	59	const int PlungerType_MagQuad = 7; // AS5304 magnetic quadrature sensor
mjr	21:5048e16cc9ef	60
mjr	35:e959ffba78fd	61	// Accelerometer orientation codes
mjr	35:e959ffba78fd	62	// These values are part of the external USB interface
mjr	35:e959ffba78fd	63	const int OrientationFront = 0; // USB ports pointed toward front of cabinet
mjr	35:e959ffba78fd	64	const int OrientationLeft = 1; // ports pointed toward left side of cabinet
mjr	35:e959ffba78fd	65	const int OrientationRight = 2; // ports pointed toward right side of cabinet
mjr	35:e959ffba78fd	66	const int OrientationRear = 3; // ports pointed toward back of cabinet
mjr	25:e22b88bd783a	67
mjr	35:e959ffba78fd	68	// input button types
mjr	53:9b2611964afc	69	const int BtnTypeNone = 0; // unused
mjr	35:e959ffba78fd	70	const int BtnTypeJoystick = 1; // joystick button
mjr	53:9b2611964afc	71	const int BtnTypeKey = 2; // keyboard key
mjr	38:091e511ce8a0	72
mjr	38:091e511ce8a0	73	// input button flags
mjr	38:091e511ce8a0	74	const uint8_t BtnFlagPulse = 0x01; // pulse mode - reports each change in the physical switch state
mjr	38:091e511ce8a0	75	// as a brief press of the logical button/keyboard key
mjr	40:cc0d9814522b	76
mjr	40:cc0d9814522b	77	// button setup structure
mjr	40:cc0d9814522b	78	struct ButtonCfg
mjr	40:cc0d9814522b	79	{
mjr	66:2e3583fbd2f4	80	// physical GPIO pin - a Wire-to-PinName mapping index
mjr	66:2e3583fbd2f4	81	uint8_t pin;
mjr	66:2e3583fbd2f4	82
mjr	66:2e3583fbd2f4	83	// Key type and value reported to the PC
mjr	40:cc0d9814522b	84	uint8_t typ; // key type reported to PC - a BtnTypeXxx value
mjr	53:9b2611964afc	85	uint8_t val; // key value reported - meaning depends on 'typ' value:
mjr	53:9b2611964afc	86	// none -> no PC input reports (val is unused)
mjr	53:9b2611964afc	87	// joystick -> val is joystick button number (1..32)
mjr	53:9b2611964afc	88	// keyboard -> val is USB scan code
mjr	66:2e3583fbd2f4	89
mjr	66:2e3583fbd2f4	90	// Shifted key type and value. These used when the button is pressed
mjr	66:2e3583fbd2f4	91	// while the Local Shift Button is being held down. We send the key
mjr	66:2e3583fbd2f4	92	// code given here instead of the regular typ/val code in this case.
mjr	66:2e3583fbd2f4	93	// If typ2 is BtnTypeNone, we use the regular typ/val code whether or
mjr	66:2e3583fbd2f4	94	// not the shift button is being held.
mjr	66:2e3583fbd2f4	95	uint8_t typ2; // shifted key type
mjr	66:2e3583fbd2f4	96	uint8_t val2; // shifted key value
mjr	66:2e3583fbd2f4	97
mjr	66:2e3583fbd2f4	98	// key flags - a bitwise combination of BtnFlagXxx values
mjr	66:2e3583fbd2f4	99	uint8_t flags;
mjr	40:cc0d9814522b	100
mjr	40:cc0d9814522b	101	void set(uint8_t pin, uint8_t typ, uint8_t val, uint8_t flags = 0)
mjr	40:cc0d9814522b	102	{
mjr	40:cc0d9814522b	103	this->pin = pin;
mjr	40:cc0d9814522b	104	this->typ = typ;
mjr	40:cc0d9814522b	105	this->val = val;
mjr	40:cc0d9814522b	106	this->flags = flags;
mjr	40:cc0d9814522b	107	}
mjr	40:cc0d9814522b	108
mjr	40:cc0d9814522b	109	} __attribute__((packed));
mjr	40:cc0d9814522b	110
mjr	33:d832bcab089e	111
mjr	65:739875521aae	112	// maximum number of input button mappings in configuration
mjr	65:739875521aae	113	const int MAX_BUTTONS = 48;
mjr	65:739875521aae	114
mjr	65:739875521aae	115	// extra slots for virtual buttons (ZB Launch Ball)
mjr	65:739875521aae	116	const int VIRTUAL_BUTTONS = 1; // total number of buttons
mjr	65:739875521aae	117	const int ZBL_BUTTON_CFG = MAX_BUTTONS; // index of ZB Launch Ball slot
mjr	33:d832bcab089e	118
mjr	35:e959ffba78fd	119	// LedWiz output port type codes
mjr	35:e959ffba78fd	120	// These values are part of the external USB interface
mjr	35:e959ffba78fd	121	const int PortTypeDisabled = 0; // port is disabled - not visible to LedWiz/DOF host
mjr	35:e959ffba78fd	122	const int PortTypeGPIOPWM = 1; // GPIO port, PWM enabled
mjr	35:e959ffba78fd	123	const int PortTypeGPIODig = 2; // GPIO port, digital out
mjr	35:e959ffba78fd	124	const int PortTypeTLC5940 = 3; // TLC5940 port
mjr	35:e959ffba78fd	125	const int PortType74HC595 = 4; // 74HC595 port
mjr	53:9b2611964afc	126	const int PortTypeVirtual = 5; // Virtual port - visible to host software, but not connected
mjr	53:9b2611964afc	127	// to a physical output
mjr	17:ab3cec0c8bf4	128
mjr	35:e959ffba78fd	129	// LedWiz output port flag bits
mjr	38:091e511ce8a0	130	const uint8_t PortFlagActiveLow = 0x01; // physical output is active-low
mjr	38:091e511ce8a0	131	const uint8_t PortFlagNoisemaker = 0x02; // noisemaker device - disable when night mode is engaged
mjr	40:cc0d9814522b	132	const uint8_t PortFlagGamma = 0x04; // apply gamma correction to this output
mjr	35:e959ffba78fd	133
mjr	35:e959ffba78fd	134	// maximum number of output ports
mjr	48:058ace2aed1d	135	const int MAX_OUT_PORTS = 128;
mjr	33:d832bcab089e	136
mjr	38:091e511ce8a0	137	// port configuration data
mjr	38:091e511ce8a0	138	struct LedWizPortCfg
mjr	38:091e511ce8a0	139	{
mjr	38:091e511ce8a0	140	uint8_t typ; // port type: a PortTypeXxx value
mjr	38:091e511ce8a0	141	uint8_t pin; // physical output pin: for a GPIO port, this is an index in the
mjr	38:091e511ce8a0	142	// USB-to-PinName mapping list; for a TLC5940 or 74HC595 port, it's
mjr	38:091e511ce8a0	143	// the output number, starting from 0 for OUT0 on the first chip in
mjr	38:091e511ce8a0	144	// the daisy chain. For inactive and virtual ports, it's unused.
mjr	38:091e511ce8a0	145	uint8_t flags; // flags: a combination of PortFlagXxx values
mjr	40:cc0d9814522b	146
mjr	40:cc0d9814522b	147	void set(uint8_t typ, uint8_t pin, uint8_t flags = 0)
mjr	40:cc0d9814522b	148	{
mjr	40:cc0d9814522b	149	this->typ = typ;
mjr	40:cc0d9814522b	150	this->pin = pin;
mjr	40:cc0d9814522b	151	this->flags = flags;
mjr	40:cc0d9814522b	152	}
mjr	40:cc0d9814522b	153
mjr	38:091e511ce8a0	154	} __attribute__((packed));
mjr	38:091e511ce8a0	155
mjr	38:091e511ce8a0	156
mjr	53:9b2611964afc	157	// Convert a physical pin name to a wire pin name
mjr	53:9b2611964afc	158	#define PINNAME_TO_WIRE(p) \
mjr	53:9b2611964afc	159	uint8_t((p) == NC ? 0xFF : \
mjr	53:9b2611964afc	160	(((p) & 0xF000 ) >> (PORT_SHIFT - 5)) \| (((p) & 0xFF) >> 2))
mjr	53:9b2611964afc	161
mjr	35:e959ffba78fd	162	struct Config
mjr	35:e959ffba78fd	163	{
mjr	35:e959ffba78fd	164	// set all values to factory defaults
mjr	35:e959ffba78fd	165	void setFactoryDefaults()
mjr	35:e959ffba78fd	166	{
mjr	35:e959ffba78fd	167	// By default, pretend to be LedWiz unit #8. This can be from 1 to 16. Real
mjr	35:e959ffba78fd	168	// LedWiz units have their unit number set at the factory, and the vast majority
mjr	35:e959ffba78fd	169	// are set up as unit #1, since that's the default for anyone who doesn't ask
mjr	35:e959ffba78fd	170	// for a different setting. It seems rare for anyone to use more than one unit
mjr	35:e959ffba78fd	171	// in a pin cab, but for the few who do, the others will probably be numbered
mjr	35:e959ffba78fd	172	// sequentially as #2, #3, etc. It seems safe to assume that no one out there
mjr	48:058ace2aed1d	173	// has a unit #8, so we'll use that as our default. This can be changed from
mjr	48:058ace2aed1d	174	// the config tool, but for the sake of convenience, it's better to pick a
mjr	48:058ace2aed1d	175	// default that most people won't have to change.
mjr	54:fd77a6b2f76c	176	usbVendorID = 0xFAFA; // LedWiz vendor code
mjr	48:058ace2aed1d	177	usbProductID = 0x00F7; // LedWiz product code for unit #8
mjr	61:3c7e6e9ec355	178
mjr	55:4db125cd11a0	179	// Set the default Pinscape unit number to #1. This is a separate identifier
mjr	55:4db125cd11a0	180	// from the LedWiz ID, so you don't have to worry about making this different
mjr	55:4db125cd11a0	181	// from your LedWiz units. Each Pinscape unit should have a unique value for
mjr	55:4db125cd11a0	182	// this ID, though.
mjr	55:4db125cd11a0	183	//
mjr	55:4db125cd11a0	184	// Note that Pinscape unit #1 corresponds to DOF Pinscape #51, PS 2 -> DOF 52,
mjr	55:4db125cd11a0	185	// and so on - just add 50 to get the DOF ID.
mjr	55:4db125cd11a0	186	psUnitNo = 1;
mjr	35:e959ffba78fd	187
mjr	51:57eb311faafa	188	// set a disconnect reboot timeout of 10 seconds by default
mjr	55:4db125cd11a0	189	disconnectRebootTimeout = 10;
mjr	51:57eb311faafa	190
mjr	35:e959ffba78fd	191	// enable joystick reports
mjr	35:e959ffba78fd	192	joystickEnabled = true;
mjr	35:e959ffba78fd	193
mjr	35:e959ffba78fd	194	// assume standard orientation, with USB ports toward front of cabinet
mjr	35:e959ffba78fd	195	orientation = OrientationFront;
mjr	25:e22b88bd783a	196
mjr	52:8298b2a73eb2	197	// assume a basic setup with no expansion boards
mjr	53:9b2611964afc	198	expan.typ = 0;
mjr	53:9b2611964afc	199	expan.vsn = 0;
mjr	53:9b2611964afc	200	memset(expan.ext, 0, sizeof(expan.ext));
mjr	52:8298b2a73eb2	201
mjr	35:e959ffba78fd	202	// assume no plunger is attached
mjr	35:e959ffba78fd	203	plunger.enabled = false;
mjr	35:e959ffba78fd	204	plunger.sensorType = PlungerType_None;
mjr	35:e959ffba78fd	205
mjr	55:4db125cd11a0	206	#if TEST_CONFIG_EXPAN \|\| STANDARD_CONFIG
mjr	43:7a6364d82a41	207	plunger.enabled = true;
mjr	43:7a6364d82a41	208	plunger.sensorType = PlungerType_TSL1410RS;
mjr	53:9b2611964afc	209	plunger.sensorPin[0] = PINNAME_TO_WIRE(PTE20); // SI
mjr	53:9b2611964afc	210	plunger.sensorPin[1] = PINNAME_TO_WIRE(PTE21); // SCLK
mjr	53:9b2611964afc	211	plunger.sensorPin[2] = PINNAME_TO_WIRE(PTB0); // AO1 = PTB0 = ADC0_SE8
mjr	53:9b2611964afc	212	plunger.sensorPin[3] = PINNAME_TO_WIRE(PTE22); // AO2 (parallel mode) = PTE22 = ADC0_SE3
mjr	43:7a6364d82a41	213	#endif
mjr	43:7a6364d82a41	214
mjr	48:058ace2aed1d	215	// default plunger calibration button settings
mjr	55:4db125cd11a0	216	plunger.cal.features = 0x03; // 0x01 = enable button, 0x02 = enable indicator lamp
mjr	55:4db125cd11a0	217	plunger.cal.btn = PINNAME_TO_WIRE(PTE29); // button input (DigitalIn port)
mjr	55:4db125cd11a0	218	plunger.cal.led = PINNAME_TO_WIRE(PTE23); // button output (DigitalOut port)
mjr	35:e959ffba78fd	219
mjr	44:b5ac89b9cd5d	220	// set the default plunger calibration
mjr	44:b5ac89b9cd5d	221	plunger.cal.setDefaults();
mjr	35:e959ffba78fd	222
mjr	35:e959ffba78fd	223	// disable the ZB Launch Ball by default
mjr	53:9b2611964afc	224	plunger.zbLaunchBall.port = 0; // 0 = disabled
mjr	65:739875521aae	225	plunger.zbLaunchBall.keytype = BtnTypeKey; // keyboard key
mjr	61:3c7e6e9ec355	226	plunger.zbLaunchBall.keycode = 0x28; // USB keyboard scan code for Enter key
mjr	61:3c7e6e9ec355	227	plunger.zbLaunchBall.pushDistance = 63; // 63/1000 in == .063" == about 1/16"
mjr	35:e959ffba78fd	228
mjr	35:e959ffba78fd	229	// assume no TV ON switch
mjr	53:9b2611964afc	230	TVON.statusPin = PINNAME_TO_WIRE(NC);
mjr	53:9b2611964afc	231	TVON.latchPin = PINNAME_TO_WIRE(NC);
mjr	53:9b2611964afc	232	TVON.relayPin = PINNAME_TO_WIRE(NC);
mjr	53:9b2611964afc	233	TVON.delayTime = 700; // 7 seconds
mjr	55:4db125cd11a0	234
mjr	55:4db125cd11a0	235	#if TEST_CONFIG_EXPAN
mjr	55:4db125cd11a0	236	// expansion board TV ON wiring
mjr	53:9b2611964afc	237	TVON.statusPin = PINNAME_TO_WIRE(PTD2);
mjr	53:9b2611964afc	238	TVON.latchPin = PINNAME_TO_WIRE(PTE0);
mjr	53:9b2611964afc	239	TVON.relayPin = PINNAME_TO_WIRE(PTD3);
mjr	53:9b2611964afc	240	TVON.delayTime = 700; // 7 seconds
mjr	38:091e511ce8a0	241	#endif
mjr	53:9b2611964afc	242
mjr	53:9b2611964afc	243	// assume no night mode switch or indicator lamp
mjr	53:9b2611964afc	244	nightMode.btn = 0;
mjr	53:9b2611964afc	245	nightMode.flags = 0;
mjr	53:9b2611964afc	246	nightMode.port = 0;
mjr	35:e959ffba78fd	247
mjr	35:e959ffba78fd	248	// assume no TLC5940 chips
mjr	35:e959ffba78fd	249	tlc5940.nchips = 0;
mjr	55:4db125cd11a0	250
mjr	55:4db125cd11a0	251	#if TEST_CONFIG_EXPAN
mjr	55:4db125cd11a0	252	// for expansion board testing purposes, assume the common setup
mjr	55:4db125cd11a0	253	// with one main board and one power board
mjr	48:058ace2aed1d	254	tlc5940.nchips = 4;
mjr	38:091e511ce8a0	255	#endif
mjr	38:091e511ce8a0	256
mjr	55:4db125cd11a0	257	// Default TLC5940 pin assignments. Note that it's harmless to set
mjr	55:4db125cd11a0	258	// these to valid pins even if no TLC5940 chips are actually present,
mjr	55:4db125cd11a0	259	// since the main program won't allocate the connections if 'nchips'
mjr	55:4db125cd11a0	260	// is zero. This means that the pins are free to be used for other
mjr	55:4db125cd11a0	261	// purposes (such as output ports) if not using TLC5940 chips.
mjr	53:9b2611964afc	262	tlc5940.sin = PINNAME_TO_WIRE(PTC6);
mjr	53:9b2611964afc	263	tlc5940.sclk = PINNAME_TO_WIRE(PTC5);
mjr	53:9b2611964afc	264	tlc5940.xlat = PINNAME_TO_WIRE(PTC10);
mjr	59:94eb9265b6d7	265	tlc5940.blank = PINNAME_TO_WIRE(PTC7);
mjr	59:94eb9265b6d7	266	#if TEST_KEEP_PRINTF
mjr	59:94eb9265b6d7	267	tlc5940.gsclk = PINNAME_TO_WIRE(PTA13); // PTA1 is reserved for SDA printf()
mjr	59:94eb9265b6d7	268	#else
mjr	53:9b2611964afc	269	tlc5940.gsclk = PINNAME_TO_WIRE(PTA1);
mjr	59:94eb9265b6d7	270	#endif
mjr	35:e959ffba78fd	271
mjr	35:e959ffba78fd	272	// assume no 74HC595 chips
mjr	35:e959ffba78fd	273	hc595.nchips = 0;
mjr	55:4db125cd11a0	274
mjr	55:4db125cd11a0	275	#if TEST_CONFIG_EXPAN
mjr	55:4db125cd11a0	276	// for expansion board testing purposes, assume one chime board
mjr	48:058ace2aed1d	277	hc595.nchips = 1;
mjr	40:cc0d9814522b	278	#endif
mjr	40:cc0d9814522b	279
mjr	55:4db125cd11a0	280	// Default 74HC595 pin assignments. As with the TLC5940 pins, it's
mjr	55:4db125cd11a0	281	// harmless to assign pins here even if no 74HC595 chips are used,
mjr	55:4db125cd11a0	282	// since the main program won't actually allocate the pins if 'nchips'
mjr	55:4db125cd11a0	283	// is zero.
mjr	53:9b2611964afc	284	hc595.sin = PINNAME_TO_WIRE(PTA5);
mjr	53:9b2611964afc	285	hc595.sclk = PINNAME_TO_WIRE(PTA4);
mjr	53:9b2611964afc	286	hc595.latch = PINNAME_TO_WIRE(PTA12);
mjr	53:9b2611964afc	287	hc595.ena = PINNAME_TO_WIRE(PTD4);
mjr	38:091e511ce8a0	288
mjr	35:e959ffba78fd	289	// initially configure with no LedWiz output ports
mjr	35:e959ffba78fd	290	outPort[0].typ = PortTypeDisabled;
mjr	66:2e3583fbd2f4	291
mjr	66:2e3583fbd2f4	292	// initially configure with no shift key
mjr	66:2e3583fbd2f4	293	shiftButton = 0;
mjr	53:9b2611964afc	294
mjr	35:e959ffba78fd	295	// initially configure with no input buttons
mjr	35:e959ffba78fd	296	for (int i = 0 ; i < MAX_BUTTONS ; ++i)
mjr	53:9b2611964afc	297	button[i].set(PINNAME_TO_WIRE(NC), BtnTypeNone, 0);
mjr	38:091e511ce8a0	298
mjr	55:4db125cd11a0	299	#if STANDARD_CONFIG \| TEST_CONFIG_EXPAN
mjr	55:4db125cd11a0	300	// For the standard configuration, assign 24 input ports to
mjr	55:4db125cd11a0	301	// joystick buttons 1-24. Assign the same GPIO pins used
mjr	55:4db125cd11a0	302	// in the original v1 default configuration. For expansion
mjr	55:4db125cd11a0	303	// board testing purposes, also assign the input ports, with
mjr	55:4db125cd11a0	304	// the noted differences.
mjr	38:091e511ce8a0	305	for (int i = 0 ; i < 24 ; ++i) {
mjr	55:4db125cd11a0	306	static const int bp[] = {
mjr	53:9b2611964afc	307	PINNAME_TO_WIRE(PTC2), // 1
mjr	53:9b2611964afc	308	PINNAME_TO_WIRE(PTB3), // 2
mjr	53:9b2611964afc	309	PINNAME_TO_WIRE(PTB2), // 3
mjr	53:9b2611964afc	310	PINNAME_TO_WIRE(PTB1), // 4
mjr	53:9b2611964afc	311	PINNAME_TO_WIRE(PTE30), // 5
mjr	48:058ace2aed1d	312	#if TEST_CONFIG_EXPAN
mjr	55:4db125cd11a0	313	PINNAME_TO_WIRE(PTC11), // 6 - expansion boards use PTC11 for this, since PTE22
mjr	55:4db125cd11a0	314	// is reserved for a plunger connection
mjr	55:4db125cd11a0	315	#elif STANDARD_CONFIG
mjr	55:4db125cd11a0	316	PINNAME_TO_WIRE(PTE22), // 6 - original standalone setup uses PTE22
mjr	48:058ace2aed1d	317	#endif
mjr	53:9b2611964afc	318	PINNAME_TO_WIRE(PTE5), // 7
mjr	53:9b2611964afc	319	PINNAME_TO_WIRE(PTE4), // 8
mjr	53:9b2611964afc	320	PINNAME_TO_WIRE(PTE3), // 9
mjr	53:9b2611964afc	321	PINNAME_TO_WIRE(PTE2), // 10
mjr	53:9b2611964afc	322	PINNAME_TO_WIRE(PTB11), // 11
mjr	53:9b2611964afc	323	PINNAME_TO_WIRE(PTB10), // 12
mjr	53:9b2611964afc	324	PINNAME_TO_WIRE(PTB9), // 13
mjr	53:9b2611964afc	325	PINNAME_TO_WIRE(PTB8), // 14
mjr	53:9b2611964afc	326	PINNAME_TO_WIRE(PTC12), // 15
mjr	53:9b2611964afc	327	PINNAME_TO_WIRE(PTC13), // 16
mjr	53:9b2611964afc	328	PINNAME_TO_WIRE(PTC16), // 17
mjr	53:9b2611964afc	329	PINNAME_TO_WIRE(PTC17), // 18
mjr	53:9b2611964afc	330	PINNAME_TO_WIRE(PTA16), // 19
mjr	53:9b2611964afc	331	PINNAME_TO_WIRE(PTA17), // 20
mjr	53:9b2611964afc	332	PINNAME_TO_WIRE(PTE31), // 21
mjr	53:9b2611964afc	333	PINNAME_TO_WIRE(PTD6), // 22
mjr	53:9b2611964afc	334	PINNAME_TO_WIRE(PTD7), // 23
mjr	53:9b2611964afc	335	PINNAME_TO_WIRE(PTE1) // 24
mjr	40:cc0d9814522b	336	};
mjr	48:058ace2aed1d	337	button[i].set(bp[i],
mjr	48:058ace2aed1d	338	#if TEST_CONFIG_EXPAN
mjr	55:4db125cd11a0	339	// For expansion board testing only, assign the inputs
mjr	55:4db125cd11a0	340	// to keyboard keys A, B, etc. This isn't useful; it's
mjr	55:4db125cd11a0	341	// just for testing purposes. Note that the USB key code
mjr	55:4db125cd11a0	342	// for "A" is 4, "B" is 5, and so on sequentially through
mjr	55:4db125cd11a0	343	// the alphabet.
mjr	55:4db125cd11a0	344	BtnTypeKey, i+4);
mjr	55:4db125cd11a0	345	#elif STANDARD_CONFIG
mjr	55:4db125cd11a0	346	// For the standard configuration, assign the input to
mjr	55:4db125cd11a0	347	// joystick buttons 1-24, as in the original v1 default
mjr	55:4db125cd11a0	348	// configuration.
mjr	55:4db125cd11a0	349	BtnTypeJoystick, i+1);
mjr	48:058ace2aed1d	350	#endif
mjr	48:058ace2aed1d	351
mjr	38:091e511ce8a0	352	}
mjr	38:091e511ce8a0	353	#endif
mjr	38:091e511ce8a0	354
mjr	55:4db125cd11a0	355	#if TEST_CONFIG_EXPAN
mjr	55:4db125cd11a0	356	// For testing purposes, configure the basic complement of
mjr	55:4db125cd11a0	357	// expansion board ports. AS MENTIONED ABOVE, THIS IS PURELY FOR
mjr	55:4db125cd11a0	358	// TESTING. DON'T USE THIS METHOD TO CONFIGURE YOUR EXPANSION
mjr	55:4db125cd11a0	359	// BOARDS FOR ACTUAL DEPLOYMENT. It's much easier and cleaner
mjr	55:4db125cd11a0	360	// to use the unmodified standard build, and customize your
mjr	55:4db125cd11a0	361	// installation with the Pinscape Config Tool on Windows.
mjr	40:cc0d9814522b	362	//
mjr	55:4db125cd11a0	363	// For this testing setup, we'll configure one main board, one
mjr	55:4db125cd11a0	364	// power board, and one chime board. The physical ports on
mjr	55:4db125cd11a0	365	// the board are shown below. The logical (LedWiz/DOF) numbering
mjr	55:4db125cd11a0	366	// ISN'T sequential through the physical ports, because we want
mjr	55:4db125cd11a0	367	// to arrange the DOF ports so that the most important and most
mjr	55:4db125cd11a0	368	// common toys are assigned to ports 1-32. Those ports are
mjr	55:4db125cd11a0	369	// special because they're accessible to ALL software on the PC,
mjr	55:4db125cd11a0	370	// including older LedWiz-only software such as Future Pinball.
mjr	55:4db125cd11a0	371	// Ports above 32 are accessible only to modern DOF software,
mjr	55:4db125cd11a0	372	// like Visual Pinball and PinballX.
mjr	40:cc0d9814522b	373	//
mjr	40:cc0d9814522b	374	// Main board
mjr	40:cc0d9814522b	375	// TLC ports 0-15 -> flashers
mjr	40:cc0d9814522b	376	// TLC ports 16 -> strobe
mjr	40:cc0d9814522b	377	// TLC ports 17-31 -> flippers
mjr	40:cc0d9814522b	378	// Dig GPIO PTC8 -> knocker (timer-protected outputs)
mjr	40:cc0d9814522b	379	//
mjr	40:cc0d9814522b	380	// Power board:
mjr	40:cc0d9814522b	381	// TLC ports 32-63 -> general purpose outputs
mjr	40:cc0d9814522b	382	//
mjr	40:cc0d9814522b	383	// Chime board:
mjr	40:cc0d9814522b	384	// HC595 ports 0-7 -> timer-protected outputs
mjr	40:cc0d9814522b	385	//
mjr	38:091e511ce8a0	386	{
mjr	38:091e511ce8a0	387	int n = 0;
mjr	40:cc0d9814522b	388
mjr	40:cc0d9814522b	389	// 1-15 = flashers (TLC ports 0-15)
mjr	40:cc0d9814522b	390	// 16 = strobe (TLC port 15)
mjr	40:cc0d9814522b	391	for (int i = 0 ; i < 16 ; ++i)
mjr	40:cc0d9814522b	392	outPort[n++].set(PortTypeTLC5940, i, PortFlagGamma);
mjr	40:cc0d9814522b	393
mjr	53:9b2611964afc	394	// 17 = knocker (PTC8)
mjr	53:9b2611964afc	395	outPort[n++].set(PortTypeGPIODig, PINNAME_TO_WIRE(PTC8));
mjr	35:e959ffba78fd	396
mjr	40:cc0d9814522b	397	// 18-49 = power board outputs 1-32 (TLC ports 32-63)
mjr	40:cc0d9814522b	398	for (int i = 0 ; i < 32 ; ++i)
mjr	40:cc0d9814522b	399	outPort[n++].set(PortTypeTLC5940, i+32);
mjr	40:cc0d9814522b	400
mjr	40:cc0d9814522b	401	// 50-65 = flipper RGB (TLC ports 16-31)
mjr	40:cc0d9814522b	402	for (int i = 0 ; i < 16 ; ++i)
mjr	40:cc0d9814522b	403	outPort[n++].set(PortTypeTLC5940, i+16, PortFlagGamma);
mjr	59:94eb9265b6d7	404
mjr	40:cc0d9814522b	405	// 66-73 = chime board ports 1-8 (74HC595 ports 0-7)
mjr	40:cc0d9814522b	406	for (int i = 0 ; i < 8 ; ++i)
mjr	40:cc0d9814522b	407	outPort[n++].set(PortType74HC595, i);
mjr	59:94eb9265b6d7	408
mjr	40:cc0d9814522b	409	// set Disabled to signify end of configured outputs
mjr	38:091e511ce8a0	410	outPort[n].typ = PortTypeDisabled;
mjr	38:091e511ce8a0	411	}
mjr	38:091e511ce8a0	412	#endif
mjr	48:058ace2aed1d	413
mjr	55:4db125cd11a0	414	#if STANDARD_CONFIG
mjr	55:4db125cd11a0	415	//
mjr	55:4db125cd11a0	416	// For the standard build, set up the original complement
mjr	55:4db125cd11a0	417	// of 22 ports from the v1 default onfiguration.
mjr	55:4db125cd11a0	418	//
mjr	55:4db125cd11a0	419	// IMPORTANT! As mentioned above, don't edit this file to
mjr	55:4db125cd11a0	420	// customize this for your machine. Instead, use the unmodified
mjr	55:4db125cd11a0	421	// standard build, and customize your installation using the
mjr	55:4db125cd11a0	422	// Pinscape Config Tool on Windows.
mjr	55:4db125cd11a0	423	//
mjr	48:058ace2aed1d	424	#if TEST_KEEP_PRINTF
mjr	55:4db125cd11a0	425	outPort[ 0].set(PortTypeVirtual, PINNAME_TO_WIRE(NC)); // port 1 = NC to keep debug printf (PTA1 is SDA UART)
mjr	55:4db125cd11a0	426	outPort[ 1].set(PortTypeVirtual, PINNAME_TO_WIRE(NC)); // port 2 = NC to keep debug printf (PTA2 is SDA UART)
mjr	48:058ace2aed1d	427	#else
mjr	53:9b2611964afc	428	outPort[ 0].set(PortTypeGPIOPWM, PINNAME_TO_WIRE(PTA1)); // port 1 = PTA1
mjr	53:9b2611964afc	429	outPort[ 1].set(PortTypeGPIOPWM, PINNAME_TO_WIRE(PTA2)); // port 2 = PTA2
mjr	48:058ace2aed1d	430	#endif
mjr	53:9b2611964afc	431	outPort[ 2].set(PortTypeGPIOPWM, PINNAME_TO_WIRE(PTD4)); // port 3 = PTD4
mjr	53:9b2611964afc	432	outPort[ 3].set(PortTypeGPIOPWM, PINNAME_TO_WIRE(PTA12)); // port 4 = PTA12
mjr	53:9b2611964afc	433	outPort[ 4].set(PortTypeGPIOPWM, PINNAME_TO_WIRE(PTA4)); // port 5 = PTA4
mjr	53:9b2611964afc	434	outPort[ 5].set(PortTypeGPIOPWM, PINNAME_TO_WIRE(PTA5)); // port 6 = PTA5
mjr	53:9b2611964afc	435	outPort[ 6].set(PortTypeGPIOPWM, PINNAME_TO_WIRE(PTA13)); // port 7 = PTA13
mjr	53:9b2611964afc	436	outPort[ 7].set(PortTypeGPIOPWM, PINNAME_TO_WIRE(PTD5)); // port 8 = PTD5
mjr	53:9b2611964afc	437	outPort[ 8].set(PortTypeGPIOPWM, PINNAME_TO_WIRE(PTD0)); // port 9 = PTD0
mjr	53:9b2611964afc	438	outPort[ 9].set(PortTypeGPIOPWM, PINNAME_TO_WIRE(PTD3)); // port 10 = PTD3
mjr	53:9b2611964afc	439	outPort[10].set(PortTypeGPIODig, PINNAME_TO_WIRE(PTD2)); // port 11 = PTD2
mjr	53:9b2611964afc	440	outPort[11].set(PortTypeGPIODig, PINNAME_TO_WIRE(PTC8)); // port 12 = PTC8
mjr	53:9b2611964afc	441	outPort[12].set(PortTypeGPIODig, PINNAME_TO_WIRE(PTC9)); // port 13 = PTC9
mjr	53:9b2611964afc	442	outPort[13].set(PortTypeGPIODig, PINNAME_TO_WIRE(PTC7)); // port 14 = PTC7
mjr	53:9b2611964afc	443	outPort[14].set(PortTypeGPIODig, PINNAME_TO_WIRE(PTC0)); // port 15 = PTC0
mjr	53:9b2611964afc	444	outPort[15].set(PortTypeGPIODig, PINNAME_TO_WIRE(PTC3)); // port 16 = PTC3
mjr	53:9b2611964afc	445	outPort[16].set(PortTypeGPIODig, PINNAME_TO_WIRE(PTC4)); // port 17 = PTC4
mjr	53:9b2611964afc	446	outPort[17].set(PortTypeGPIODig, PINNAME_TO_WIRE(PTC5)); // port 18 = PTC5
mjr	53:9b2611964afc	447	outPort[18].set(PortTypeGPIODig, PINNAME_TO_WIRE(PTC6)); // port 19 = PTC6
mjr	53:9b2611964afc	448	outPort[19].set(PortTypeGPIODig, PINNAME_TO_WIRE(PTC10)); // port 20 = PTC10
mjr	53:9b2611964afc	449	outPort[20].set(PortTypeGPIODig, PINNAME_TO_WIRE(PTC11)); // port 21 = PTC11
mjr	53:9b2611964afc	450	outPort[21].set(PortTypeGPIODig, PINNAME_TO_WIRE(PTE0)); // port 22 = PTE0
mjr	48:058ace2aed1d	451	#endif
mjr	35:e959ffba78fd	452	}
mjr	35:e959ffba78fd	453
mjr	35:e959ffba78fd	454	// --- USB DEVICE CONFIGURATION ---
mjr	35:e959ffba78fd	455
mjr	35:e959ffba78fd	456	// USB device identification - vendor ID and product ID. For LedLWiz
mjr	35:e959ffba78fd	457	// emulation, use vendor ID 0xFAFA and product ID 0x00EF + unit#, where
mjr	35:e959ffba78fd	458	// unit# is the nominal LedWiz unit number from 1 to 16. Alternatively,
mjr	35:e959ffba78fd	459	// if LedWiz emulation isn't desired or causes any driver conflicts on
mjr	35:e959ffba78fd	460	// the host, we have a private Pinscape assignment as vendor ID 0x1209
mjr	35:e959ffba78fd	461	// and product ID 0xEAEA (registered with http://pid.codes, a registry
mjr	35:e959ffba78fd	462	// for open-source USB projects).
mjr	35:e959ffba78fd	463	uint16_t usbVendorID;
mjr	35:e959ffba78fd	464	uint16_t usbProductID;
mjr	35:e959ffba78fd	465
mjr	35:e959ffba78fd	466	// Pinscape Controller unit number. This is the nominal unit number,
mjr	35:e959ffba78fd	467	// from 1 to 16. We report this in the status query; DOF uses it to
mjr	53:9b2611964afc	468	// distinguish among Pinscape units. Note that this doesn't affect
mjr	35:e959ffba78fd	469	// the LedWiz unit numbering, which is implied by the USB Product ID.
mjr	35:e959ffba78fd	470	uint8_t psUnitNo;
mjr	35:e959ffba78fd	471
mjr	35:e959ffba78fd	472	// Are joystick reports enabled? Joystick reports can be turned off, to
mjr	35:e959ffba78fd	473	// use the device as purely an output controller.
mjr	35:e959ffba78fd	474	char joystickEnabled;
mjr	35:e959ffba78fd	475
mjr	51:57eb311faafa	476	// Timeout for rebooting the KL25Z when the connection is lost. On some
mjr	51:57eb311faafa	477	// hosts, the mbed USB stack has problems reconnecting after an initial
mjr	51:57eb311faafa	478	// connection is dropped. As a workaround, we can automatically reboot
mjr	51:57eb311faafa	479	// the KL25Z when it detects that it's no longer connected, after the
mjr	51:57eb311faafa	480	// interval set here expires. The timeout is in seconds; setting this
mjr	51:57eb311faafa	481	// to 0 disables the automatic reboot.
mjr	51:57eb311faafa	482	uint8_t disconnectRebootTimeout;
mjr	35:e959ffba78fd	483
mjr	35:e959ffba78fd	484	// --- ACCELEROMETER ---
mjr	35:e959ffba78fd	485
mjr	35:e959ffba78fd	486	// accelerometer orientation (ORIENTATION_xxx value)
mjr	35:e959ffba78fd	487	char orientation;
mjr	35:e959ffba78fd	488
mjr	35:e959ffba78fd	489
mjr	52:8298b2a73eb2	490	// --- EXPANSION BOARDS ---
mjr	52:8298b2a73eb2	491	struct
mjr	52:8298b2a73eb2	492	{
mjr	53:9b2611964afc	493	uint8_t typ; // expansion board set type:
mjr	53:9b2611964afc	494	// 1 -> Pinscape expansion boards
mjr	53:9b2611964afc	495	uint8_t vsn; // board set interface version
mjr	53:9b2611964afc	496	uint8_t ext[3]; // board set type-specific extended data
mjr	52:8298b2a73eb2	497
mjr	52:8298b2a73eb2	498	} expan;
mjr	52:8298b2a73eb2	499
mjr	52:8298b2a73eb2	500
mjr	35:e959ffba78fd	501	// --- PLUNGER CONFIGURATION ---
mjr	35:e959ffba78fd	502	struct
mjr	35:e959ffba78fd	503	{
mjr	35:e959ffba78fd	504	// plunger enabled/disabled
mjr	35:e959ffba78fd	505	char enabled;
mjr	33:d832bcab089e	506
mjr	35:e959ffba78fd	507	// plunger sensor type
mjr	35:e959ffba78fd	508	char sensorType;
mjr	35:e959ffba78fd	509
mjr	35:e959ffba78fd	510	// Plunger sensor pins. To accommodate a wide range of sensor types,
mjr	35:e959ffba78fd	511	// we keep a generic list of 4 pin assignments. The use of each pin
mjr	35:e959ffba78fd	512	// varies by sensor. The lists below are in order of the generic
mjr	35:e959ffba78fd	513	// pins; NC means that the pin isn't used by the sensor. Each pin's
mjr	35:e959ffba78fd	514	// GPIO usage is also listed. Certain usages limit which physical
mjr	35:e959ffba78fd	515	// pins can be assigned (e.g., AnalogIn or PwmOut).
mjr	35:e959ffba78fd	516	//
mjr	35:e959ffba78fd	517	// TSL1410R/1412R, serial: SI (DigitalOut), CLK (DigitalOut), AO (AnalogIn), NC
mjr	35:e959ffba78fd	518	// TSL1410R/1412R, parallel: SI (DigitalOut), CLK (DigitalOut), AO1 (AnalogIn), AO2 (AnalogIn)
mjr	35:e959ffba78fd	519	// Potentiometer: AO (AnalogIn), NC, NC, NC
mjr	35:e959ffba78fd	520	// AEDR8300: A (InterruptIn), B (InterruptIn), NC, NC
mjr	35:e959ffba78fd	521	// AS5304: A (InterruptIn), B (InterruptIn), NC, NC
mjr	53:9b2611964afc	522	//
mjr	53:9b2611964afc	523	// Note! These are stored in uint8_t WIRE format, not PinName format.
mjr	53:9b2611964afc	524	uint8_t sensorPin[4];
mjr	35:e959ffba78fd	525
mjr	53:9b2611964afc	526	// ZB LAUNCH BALL button setup.
mjr	35:e959ffba78fd	527	//
mjr	35:e959ffba78fd	528	// This configures the "ZB Launch Ball" feature in DOF, based on Zeb's (of
mjr	35:e959ffba78fd	529	// zebsboards.com) scheme for using a mechanical plunger as a Launch button.
mjr	35:e959ffba78fd	530	// Set the port to 0 to disable the feature.
mjr	35:e959ffba78fd	531	//
mjr	35:e959ffba78fd	532	// The port number is an LedWiz port number that we monitor for activation.
mjr	53:9b2611964afc	533	// This port isn't meant to be connected to a physical device, although it
mjr	53:9b2611964afc	534	// can be if desired. It's primarily to let the host tell the controller
mjr	53:9b2611964afc	535	// when the ZB Launch feature is active. The port numbering starts at 1;
mjr	53:9b2611964afc	536	// set this to zero to disable the feature.
mjr	35:e959ffba78fd	537	//
mjr	53:9b2611964afc	538	// The key type and code has the same meaning as for a button mapping. This
mjr	53:9b2611964afc	539	// sets the key input sent to the PC when the plunger triggers a launch when
mjr	53:9b2611964afc	540	// the mode is active. For example, set keytype=2 and keycode=0x28 to send
mjr	53:9b2611964afc	541	// the Enter key (which is the key almost all PC pinball software uses for
mjr	53:9b2611964afc	542	// plunger and Launch button input).
mjr	35:e959ffba78fd	543	//
mjr	40:cc0d9814522b	544	// The "push distance" is the distance, in 1/1000 inch units, for registering a
mjr	40:cc0d9814522b	545	// push on the plunger as a button push. If the player pushes the plunger
mjr	40:cc0d9814522b	546	// forward of the rest position by this amount, we'll treat it as pushing the
mjr	40:cc0d9814522b	547	// button, even if the player didn't pull back the plunger first. This lets
mjr	40:cc0d9814522b	548	// the player treat the plunger knob as a button for games where it's meaningful
mjr	35:e959ffba78fd	549	// to hold down the Launch button for specific intervals (e.g., "Championship
mjr	35:e959ffba78fd	550	// Pub").
mjr	35:e959ffba78fd	551	struct
mjr	35:e959ffba78fd	552	{
mjr	53:9b2611964afc	553	uint8_t port;
mjr	53:9b2611964afc	554	uint8_t keytype;
mjr	53:9b2611964afc	555	uint8_t keycode;
mjr	53:9b2611964afc	556	uint16_t pushDistance;
mjr	35:e959ffba78fd	557
mjr	35:e959ffba78fd	558	} zbLaunchBall;
mjr	35:e959ffba78fd	559
mjr	35:e959ffba78fd	560	// --- PLUNGER CALIBRATION ---
mjr	35:e959ffba78fd	561	struct
mjr	35:e959ffba78fd	562	{
mjr	35:e959ffba78fd	563	// has the plunger been calibrated?
mjr	53:9b2611964afc	564	bool calibrated;
mjr	55:4db125cd11a0	565
mjr	55:4db125cd11a0	566	// Feature enable mask:
mjr	55:4db125cd11a0	567	//
mjr	55:4db125cd11a0	568	// 0x01 = calibration button enabled
mjr	55:4db125cd11a0	569	// 0x02 = indicator light enabled
mjr	55:4db125cd11a0	570	uint8_t features;
mjr	35:e959ffba78fd	571
mjr	35:e959ffba78fd	572	// calibration button switch pin
mjr	53:9b2611964afc	573	uint8_t btn;
mjr	35:e959ffba78fd	574
mjr	35:e959ffba78fd	575	// calibration button indicator light pin
mjr	53:9b2611964afc	576	uint8_t led;
mjr	35:e959ffba78fd	577
mjr	48:058ace2aed1d	578	// Plunger calibration min, zero, and max. These are in terms of the
mjr	48:058ace2aed1d	579	// unsigned 16-bit scale (0x0000..0xffff) that we use for the raw sensor
mjr	48:058ace2aed1d	580	// readings.
mjr	48:058ace2aed1d	581	//
mjr	48:058ace2aed1d	582	// The zero point is the rest position (aka park position), where the
mjr	48:058ace2aed1d	583	// plunger is in equilibrium between the main spring and the barrel
mjr	48:058ace2aed1d	584	// spring. In the standard setup, the plunger can travel a small
mjr	48:058ace2aed1d	585	// distance forward of the rest position, because the barrel spring
mjr	48:058ace2aed1d	586	// can be compressed a bit. The minimum is the maximum forward point
mjr	48:058ace2aed1d	587	// where the barrel spring can't be compressed any further.
mjr	48:058ace2aed1d	588	uint16_t min;
mjr	48:058ace2aed1d	589	uint16_t zero;
mjr	48:058ace2aed1d	590	uint16_t max;
mjr	52:8298b2a73eb2	591
mjr	52:8298b2a73eb2	592	// Measured release time, in milliseconds.
mjr	52:8298b2a73eb2	593	uint8_t tRelease;
mjr	35:e959ffba78fd	594
mjr	44:b5ac89b9cd5d	595	// Reset the plunger calibration
mjr	44:b5ac89b9cd5d	596	void setDefaults()
mjr	35:e959ffba78fd	597	{
mjr	44:b5ac89b9cd5d	598	calibrated = false; // not calibrated
mjr	48:058ace2aed1d	599	min = 0; // assume we can go all the way forward...
mjr	48:058ace2aed1d	600	max = 0xffff; // ...and all the way back
mjr	48:058ace2aed1d	601	zero = max/6; // the rest position is usually around 1/2" back = 1/6 of total travel
mjr	52:8298b2a73eb2	602	tRelease = 65; // standard 65ms release time
mjr	44:b5ac89b9cd5d	603	}
mjr	44:b5ac89b9cd5d	604
mjr	44:b5ac89b9cd5d	605	// Begin calibration. This sets each limit to the worst
mjr	44:b5ac89b9cd5d	606	// case point - for example, we set the retracted position
mjr	44:b5ac89b9cd5d	607	// to all the way forward. Each actual reading that comes
mjr	44:b5ac89b9cd5d	608	// in is then checked against the current limit, and if it's
mjr	44:b5ac89b9cd5d	609	// outside of the limit, we reset the limit to the new reading.
mjr	44:b5ac89b9cd5d	610	void begin()
mjr	44:b5ac89b9cd5d	611	{
mjr	48:058ace2aed1d	612	min = 0; // we don't calibrate the maximum forward position, so keep this at zero
mjr	48:058ace2aed1d	613	zero = 0xffff; // set the zero position all the way back
mjr	48:058ace2aed1d	614	max = 0; // set the retracted position all the way forward
mjr	52:8298b2a73eb2	615	tRelease = 65; // revert to a default release time
mjr	35:e959ffba78fd	616	}
mjr	17:ab3cec0c8bf4	617
mjr	35:e959ffba78fd	618	} cal;
mjr	18:5e890ebd0023	619
mjr	35:e959ffba78fd	620	} plunger;
mjr	29:582472d0bc57	621
mjr	35:e959ffba78fd	622
mjr	35:e959ffba78fd	623	// --- TV ON SWITCH ---
mjr	35:e959ffba78fd	624	//
mjr	35:e959ffba78fd	625	// To use the TV ON switch feature, the special power sensing circuitry
mjr	35:e959ffba78fd	626	// implemented on the Expansion Board must be attached (or an equivalent
mjr	35:e959ffba78fd	627	// circuit, as described in the Build Guide). The circuitry lets us
mjr	35:e959ffba78fd	628	// detect power state changes on the secondary power supply.
mjr	35:e959ffba78fd	629	struct
mjr	35:e959ffba78fd	630	{
mjr	35:e959ffba78fd	631	// PSU2 power status sense (DigitalIn pin). This pin goes LOW when the
mjr	35:e959ffba78fd	632	// secondary power supply is turned off, and remains LOW until the LATCH
mjr	35:e959ffba78fd	633	// pin is raised high AND the secondary PSU is turned on. Once HIGH,
mjr	35:e959ffba78fd	634	// it remains HIGH as long as the secondary PSU is on.
mjr	53:9b2611964afc	635	uint8_t statusPin;
mjr	35:e959ffba78fd	636
mjr	35:e959ffba78fd	637	// PSU2 power status latch (DigitalOut pin)
mjr	53:9b2611964afc	638	uint8_t latchPin;
mjr	35:e959ffba78fd	639
mjr	35:e959ffba78fd	640	// TV ON relay pin (DigitalOut pin). This pin controls the TV switch
mjr	35:e959ffba78fd	641	// relay. Raising the pin HIGH turns the relay ON (energizes the coil).
mjr	53:9b2611964afc	642	uint8_t relayPin;
mjr	35:e959ffba78fd	643
mjr	40:cc0d9814522b	644	// TV ON delay time, in 1/100 second units. This is the interval between
mjr	40:cc0d9814522b	645	// sensing that the secondary power supply has turned on and pulsing the
mjr	40:cc0d9814522b	646	// TV ON switch relay.
mjr	40:cc0d9814522b	647	int delayTime;
mjr	35:e959ffba78fd	648
mjr	35:e959ffba78fd	649	} TVON;
mjr	35:e959ffba78fd	650
mjr	53:9b2611964afc	651	// --- Night Mode ---
mjr	53:9b2611964afc	652	struct
mjr	53:9b2611964afc	653	{
mjr	55:4db125cd11a0	654	uint8_t btn; // night mode button number (1..MAX_BUTTONS, 0 = no button)
mjr	53:9b2611964afc	655	uint8_t flags; // flags:
mjr	53:9b2611964afc	656	// 0x01 = on/off switch (if not set, it's a momentary button)
mjr	55:4db125cd11a0	657	uint8_t port; // indicator output port number (1..MAX_OUT_PORTS, 0 = no indicator)
mjr	53:9b2611964afc	658	} nightMode;
mjr	53:9b2611964afc	659
mjr	29:582472d0bc57	660
mjr	35:e959ffba78fd	661	// --- TLC5940NT PWM Controller Chip Setup ---
mjr	35:e959ffba78fd	662	struct
mjr	35:e959ffba78fd	663	{
mjr	35:e959ffba78fd	664	// number of TLC5940NT chips connected in daisy chain
mjr	35:e959ffba78fd	665	int nchips;
mjr	35:e959ffba78fd	666
mjr	53:9b2611964afc	667	// pin connections (wire pin IDs)
mjr	53:9b2611964afc	668	uint8_t sin; // Serial data - must connect to SPIO MOSI -> PTC6 or PTD2
mjr	53:9b2611964afc	669	uint8_t sclk; // Serial clock - must connect to SPIO SCLK -> PTC5 or PTD1
mjr	35:e959ffba78fd	670	// (but don't use PTD1, since it's hard-wired to the on-board blue LED)
mjr	53:9b2611964afc	671	uint8_t xlat; // XLAT (latch) signal - connect to any GPIO pin
mjr	53:9b2611964afc	672	uint8_t blank; // BLANK signal - connect to any GPIO pin
mjr	53:9b2611964afc	673	uint8_t gsclk; // Grayscale clock - must connect to a PWM-out capable pin
mjr	29:582472d0bc57	674
mjr	35:e959ffba78fd	675	} tlc5940;
mjr	35:e959ffba78fd	676
mjr	35:e959ffba78fd	677
mjr	35:e959ffba78fd	678	// --- 74HC595 Shift Register Setup ---
mjr	35:e959ffba78fd	679	struct
mjr	35:e959ffba78fd	680	{
mjr	35:e959ffba78fd	681	// number of 74HC595 chips attached in daisy chain
mjr	35:e959ffba78fd	682	int nchips;
mjr	35:e959ffba78fd	683
mjr	35:e959ffba78fd	684	// pin connections
mjr	53:9b2611964afc	685	uint8_t sin; // Serial data - use any GPIO pin
mjr	53:9b2611964afc	686	uint8_t sclk; // Serial clock - use any GPIO pin
mjr	53:9b2611964afc	687	uint8_t latch; // Latch - use any GPIO pin
mjr	53:9b2611964afc	688	uint8_t ena; // Enable signal - use any GPIO pin
mjr	35:e959ffba78fd	689
mjr	35:e959ffba78fd	690	} hc595;
mjr	34:6b981a2afab7	691
mjr	25:e22b88bd783a	692
mjr	35:e959ffba78fd	693	// --- Button Input Setup ---
mjr	65:739875521aae	694	ButtonCfg button[MAX_BUTTONS + VIRTUAL_BUTTONS] __attribute__((packed));
mjr	66:2e3583fbd2f4	695
mjr	66:2e3583fbd2f4	696	// Shift button index. If this is zero, there's no shift button. If this
mjr	66:2e3583fbd2f4	697	// is nonzero, it's the 1-based index of the shift button in the button[]
mjr	66:2e3583fbd2f4	698	// list.
mjr	66:2e3583fbd2f4	699	//
mjr	66:2e3583fbd2f4	700	// The shift button can also be used as a regular input key. If it is,
mjr	66:2e3583fbd2f4	701	// we DON'T send the input key to the PC as usual when the button is
mjr	66:2e3583fbd2f4	702	// pressed. Instead, we wait to see if the shift function is used:
mjr	66:2e3583fbd2f4	703	//
mjr	66:2e3583fbd2f4	704	// - If another button is pressed while the shift button is held down,
mjr	66:2e3583fbd2f4	705	// and the other button is programmed with a valid key for the shifted/
mjr	66:2e3583fbd2f4	706	// secondary meaning (i.e., typ2 is not BtnTypeNone), the shift function
mjr	66:2e3583fbd2f4	707	// is considered to have been used. We send the secondary meaning of
mjr	66:2e3583fbd2f4	708	// the other button to the PC. The shift key itself generates no PC
mjr	66:2e3583fbd2f4	709	// input in this case, since it has now performed its shift function.
mjr	66:2e3583fbd2f4	710	// Other shifted keys can also be pressed as long as the shift button
mjr	66:2e3583fbd2f4	711	// is held down, and they'll be sent to the PC with their shifted values
mjr	66:2e3583fbd2f4	712	// as well.
mjr	66:2e3583fbd2f4	713	//
mjr	66:2e3583fbd2f4	714	// - If the shift button is released before any other button with a
mjr	66:2e3583fbd2f4	715	// shifted key value is pressed, then the shift button press is taken to
mjr	66:2e3583fbd2f4	716	// be an ordinary key press instead of the shift function. In this case,
mjr	66:2e3583fbd2f4	717	// we report the shift button's key code to the PC when the button is
mjr	66:2e3583fbd2f4	718	// released. We can't report the key code to the PC until then because
mjr	66:2e3583fbd2f4	719	// we don't know until then that another key won't be pressed first.
mjr	66:2e3583fbd2f4	720	// The key press on release is a single timed pulse that's long enough
mjr	66:2e3583fbd2f4	721	// to register as a single key press on the PC, but not long enough to
mjr	66:2e3583fbd2f4	722	// trigger auto-repeat on the PC.
mjr	66:2e3583fbd2f4	723	uint8_t shiftButton;
mjr	17:ab3cec0c8bf4	724
mjr	35:e959ffba78fd	725	// --- LedWiz Output Port Setup ---
mjr	38:091e511ce8a0	726	LedWizPortCfg outPort[MAX_OUT_PORTS] __attribute__((packed)); // LedWiz & extended output ports
mjr	48:058ace2aed1d	727
mjr	17:ab3cec0c8bf4	728	};
mjr	17:ab3cec0c8bf4	729
mjr	35:e959ffba78fd	730	#endif

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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

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