/* USB API for Teensy USB Development Board
 * http://www.pjrc.com/teensy/teensyduino.html
 * Copyright (c) 2008 PJRC.COM, LLC
 * 
 * Permission is hereby granted, free of charge, to any person obtaining a copy
 * of this software and associated documentation files (the "Software"), to deal
 * in the Software without restriction, including without limitation the rights
 * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
 * copies of the Software, and to permit persons to whom the Software is
 * furnished to do so, subject to the following conditions:
 * 
 * The above copyright notice and this permission notice shall be included in
 * all copies or substantial portions of the Software.
 * 
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
 * THE SOFTWARE.
 */

#include <avr/io.h>
#include <avr/pgmspace.h>
#include <stdint.h>
#include "usb_common.h"
#include "usb_private.h"
#include "usb_api.h"
#include "keylayouts.h"
#include "wiring.h"




// Step #1, decode UTF8 to Unicode code points
//
#if ARDUINO >= 100
size_t usb_keyboard_class::write(uint8_t c)
#else
void usb_keyboard_class::write(uint8_t c)
#endif
{
	if (c < 0x80) {
		// single byte encoded, 0x00 to 0x7F
		utf8_state = 0;
		write_unicode(c);
	} else if (c < 0xC0) {
		// 2nd, 3rd or 4th byte, 0x80 to 0xBF
		c &= 0x3F;
		if (utf8_state == 1) {
			utf8_state = 0;
			write_unicode(unicode_wchar | c);
		} else if (utf8_state == 2) {
			unicode_wchar |= ((uint16_t)c << 6);
			utf8_state = 1;
		}
	} else if (c < 0xE0) {
		// begin 2 byte sequence, 0xC2 to 0xDF
		// or illegal 2 byte sequence, 0xC0 to 0xC1
		unicode_wchar = (uint16_t)(c & 0x1F) << 6;
		utf8_state = 1;
	} else if (c < 0xF0) {
		// begin 3 byte sequence, 0xE0 to 0xEF
		unicode_wchar = (uint16_t)(c & 0x0F) << 12;
		utf8_state = 2;
	} else {
		// begin 4 byte sequence (not supported), 0xF0 to 0xF4
		// or illegal, 0xF5 to 0xFF
		utf8_state = 255;
	}
#if ARDUINO >= 100
	return 1;
#endif
}


// Step #2: translate Unicode code point to keystroke sequence
//
KEYCODE_TYPE usb_keyboard_class::unicode_to_keycode(uint16_t cpoint)
{
	// Unicode code points beyond U+FFFF are not supported
	// technically this input should probably be called UCS-2
	if (cpoint < 32) {
		if (cpoint == 10) return KEY_ENTER & 0x3FFF;
		return 0;
	}
	if (cpoint < 128) {
		if (sizeof(KEYCODE_TYPE) == 1) {
			return pgm_read_byte(keycodes_ascii + (cpoint - 0x20));
		} else if (sizeof(KEYCODE_TYPE) == 2) {
			return pgm_read_word(keycodes_ascii + (cpoint - 0x20));
		}
		return 0;
	}
	#ifdef ISO_8859_1_A0
	if (cpoint <= 0xA0) return 0;
	if (cpoint < 0x100) {
		if (sizeof(KEYCODE_TYPE) == 1) {
			return pgm_read_byte(keycodes_iso_8859_1 + (cpoint - 0xA0));
		} else if (sizeof(KEYCODE_TYPE) == 2) {
			return pgm_read_word(keycodes_iso_8859_1 + (cpoint - 0xA0));
		}
		return 0;
	}
	#endif
	//#ifdef UNICODE_20AC
	//if (cpoint == 0x20AC) return UNICODE_20AC & 0x3FFF;
	//#endif
	#ifdef KEYCODE_EXTRA00
	if (cpoint == UNICODE_EXTRA00) return KEYCODE_EXTRA00 & 0x3FFF;
	#endif
	#ifdef KEYCODE_EXTRA01
	if (cpoint == UNICODE_EXTRA01) return KEYCODE_EXTRA01 & 0x3FFF;
	#endif
	#ifdef KEYCODE_EXTRA02
	if (cpoint == UNICODE_EXTRA02) return KEYCODE_EXTRA02 & 0x3FFF;
	#endif
	#ifdef KEYCODE_EXTRA03
	if (cpoint == UNICODE_EXTRA03) return KEYCODE_EXTRA03 & 0x3FFF;
	#endif
	#ifdef KEYCODE_EXTRA04
	if (cpoint == UNICODE_EXTRA04) return KEYCODE_EXTRA04 & 0x3FFF;
	#endif
	#ifdef KEYCODE_EXTRA05
	if (cpoint == UNICODE_EXTRA05) return KEYCODE_EXTRA05 & 0x3FFF;
	#endif
	#ifdef KEYCODE_EXTRA06
	if (cpoint == UNICODE_EXTRA06) return KEYCODE_EXTRA06 & 0x3FFF;
	#endif
	#ifdef KEYCODE_EXTRA07
	if (cpoint == UNICODE_EXTRA07) return KEYCODE_EXTRA07 & 0x3FFF;
	#endif
	#ifdef KEYCODE_EXTRA08
	if (cpoint == UNICODE_EXTRA08) return KEYCODE_EXTRA08 & 0x3FFF;
	#endif
	#ifdef KEYCODE_EXTRA09
	if (cpoint == UNICODE_EXTRA09) return KEYCODE_EXTRA09 & 0x3FFF;
	#endif
	return 0;
}

// Step #3: execute keystroke sequence
//
void usb_keyboard_class::write_keycode(KEYCODE_TYPE keycode)
{
	if (!keycode) return;
	#ifdef DEADKEYS_MASK
	KEYCODE_TYPE deadkeycode = deadkey_to_keycode(keycode);
	if (deadkeycode) write_key(deadkeycode);
	#endif
	write_key(keycode);
}

KEYCODE_TYPE usb_keyboard_class::deadkey_to_keycode(KEYCODE_TYPE keycode)
{
	#ifdef DEADKEYS_MASK
	keycode &= DEADKEYS_MASK;
	if (keycode == 0) return 0;
	#ifdef ACUTE_ACCENT_BITS
	if (keycode == ACUTE_ACCENT_BITS) return DEADKEY_ACUTE_ACCENT;
	#endif
	#ifdef CEDILLA_BITS
	if (keycode == CEDILLA_BITS) return DEADKEY_CEDILLA;
	#endif
	#ifdef CIRCUMFLEX_BITS
	if (keycode == CIRCUMFLEX_BITS) return DEADKEY_CIRCUMFLEX;
	#endif
	#ifdef DIAERESIS_BITS
	if (keycode == DIAERESIS_BITS) return DEADKEY_DIAERESIS;
	#endif
	#ifdef GRAVE_ACCENT_BITS
	if (keycode == GRAVE_ACCENT_BITS) return DEADKEY_GRAVE_ACCENT;
	#endif
	#ifdef TILDE_BITS
	if (keycode == TILDE_BITS) return DEADKEY_TILDE;
	#endif
	#ifdef RING_ABOVE_BITS
	if (keycode == RING_ABOVE_BITS) return DEADKEY_RING_ABOVE;
	#endif
	#endif // DEADKEYS_MASK
	return 0;
}

// Step #4: do each keystroke
//
void usb_keyboard_class::write_key(KEYCODE_TYPE keycode)
{
	keyboard_report_data[0] = keycode_to_modifier(keycode);
	keyboard_report_data[1] = 0;
	keyboard_report_data[2] = keycode_to_key(keycode);
	keyboard_report_data[3] = 0;
	keyboard_report_data[4] = 0;
	keyboard_report_data[5] = 0;
	keyboard_report_data[6] = 0;
	keyboard_report_data[7] = 0;
	send_now();
	keyboard_report_data[0] = 0;
	keyboard_report_data[2] = 0;
	send_now();
}

uint8_t usb_keyboard_class::keycode_to_modifier(KEYCODE_TYPE keycode)
{
	uint8_t modifier=0;

	#ifdef SHIFT_MASK
	if (keycode & SHIFT_MASK) modifier |= MODIFIERKEY_SHIFT;
	#endif
	#ifdef ALTGR_MASK
	if (keycode & ALTGR_MASK) modifier |= MODIFIERKEY_RIGHT_ALT;
	#endif
	#ifdef RCTRL_MASK
	if (keycode & RCTRL_MASK) modifier |= MODIFIERKEY_RIGHT_CTRL;
	#endif
	return modifier;
}

uint8_t usb_keyboard_class::keycode_to_key(KEYCODE_TYPE keycode)
{
	uint8_t key = keycode & 0x3F;
	#ifdef KEY_NON_US_100
	if (key == KEY_NON_US_100) key = 100;
	#endif
	return key;
}



void usb_keyboard_class::set_modifier(uint16_t c)
{
	keyboard_report_data[0] = (uint8_t)c;
}
void usb_keyboard_class::set_key1(uint8_t c)
{
	keyboard_report_data[2] = c;
}
void usb_keyboard_class::set_key2(uint8_t c)
{
	keyboard_report_data[3] = c;
}
void usb_keyboard_class::set_key3(uint8_t c)
{
	keyboard_report_data[4] = c;
}
void usb_keyboard_class::set_key4(uint8_t c)
{
	keyboard_report_data[5] = c;
}
void usb_keyboard_class::set_key5(uint8_t c)
{
	keyboard_report_data[6] = c;
}
void usb_keyboard_class::set_key6(uint8_t c)
{
	keyboard_report_data[7] = c;
}
void usb_keyboard_class::set_media(uint8_t c)
{
	keyboard_report_data[1] = c;
}


void usb_keyboard_class::send_now(void)
{
        uint8_t intr_state, timeout;

        if (!usb_configuration) return;
        intr_state = SREG;
        cli();
        UENUM = KEYBOARD_ENDPOINT;
        timeout = UDFNUML + 50;
        while (1) {
                // are we ready to transmit?
                if (UEINTX & (1<<RWAL)) break;
                SREG = intr_state;
                // has the USB gone offline?
                if (!usb_configuration) return;
                // have we waited too long?
                if (UDFNUML == timeout) return;
                // get ready to try checking again
                intr_state = SREG;
                cli();
                UENUM = KEYBOARD_ENDPOINT;
        }
        UEDATX = keyboard_report_data[0];
        UEDATX = keyboard_report_data[1];
        UEDATX = keyboard_report_data[2];
        UEDATX = keyboard_report_data[3];
        UEDATX = keyboard_report_data[4];
        UEDATX = keyboard_report_data[5];
        UEDATX = keyboard_report_data[6];
        UEDATX = keyboard_report_data[7];
        UEINTX = 0x3A;
        keyboard_idle_count = 0;
        SREG = intr_state;
}


void usb_keyboard_class::press(uint16_t n)
{
	uint8_t key, mod, msb, modrestore=0;

	msb = n >> 8;
	if (msb >= 0xC2 && msb <= 0xDF) {
		n = (n & 0x3F) | ((uint16_t)(msb & 0x1F) << 6);
	} else
	if (msb == 0x80) {
		presskey(0, n);
		return;
	} else
	if (msb == 0x40) {
		presskey(n, 0);
		return;
	}
	KEYCODE_TYPE keycode = unicode_to_keycode(n);
	if (!keycode) return;
	#ifdef DEADKEYS_MASK
	KEYCODE_TYPE deadkeycode = deadkey_to_keycode(keycode);
	if (deadkeycode) {
		modrestore = keyboard_report_data[0];
		if (modrestore) {
			keyboard_report_data[0] = 0;
			send_now();
		}
		// TODO: test if operating systems recognize
		// deadkey sequences when other keys are held
		mod = keycode_to_modifier(deadkeycode);
		key = keycode_to_key(deadkeycode);
		presskey(key, mod);
		releasekey(key, mod);
	}
	#endif
	mod = keycode_to_modifier(keycode);
	key = keycode_to_key(keycode);
	presskey(key, mod | modrestore);
}

void usb_keyboard_class::release(uint16_t n)
{
	uint8_t key, mod, msb;

	msb = n >> 8;
	if (msb >= 0xC2 && msb <= 0xDF) {
		n = (n & 0x3F) | ((uint16_t)(msb & 0x1F) << 6);
	} else
	if (msb == 0x80) {
		releasekey(0, n);
		return;
	} else
	if (msb == 0x40) {
		releasekey(n, 0);
		return;
	}
	KEYCODE_TYPE keycode = unicode_to_keycode(n);
	if (!keycode) return;
	mod = keycode_to_modifier(keycode);
	key = keycode_to_key(keycode);
	releasekey(key, mod);
}

void usb_keyboard_class::presskey(uint8_t key, uint8_t modifier)
{
	bool send_required = false;
	uint8_t i;

	if (modifier) {
		if ((keyboard_report_data[0] & modifier) != modifier) {
			keyboard_report_data[0] |= modifier;
			send_required = true;
		}
	}
	if (key) {
		for (i=2; i < 8; i++) {
			if (keyboard_report_data[i] == key) goto end;
		}
		for (i=2; i < 8; i++) {
			if (keyboard_report_data[i] == 0) {
				keyboard_report_data[i] = key;
				send_required = true;
				goto end;
			}
		}
	}
	end:
	if (send_required) send_now();
}

void usb_keyboard_class::releasekey(uint8_t key, uint8_t modifier)
{
	bool send_required = false;
	uint8_t i;

	if (modifier) {
		if ((keyboard_report_data[0] & modifier) != 0) {
			keyboard_report_data[0] &= ~modifier;
			send_required = true;
		}
	}
	if (key) {
		for (i=2; i < 8; i++) {
			if (keyboard_report_data[i] == key) {
				keyboard_report_data[i] = 0;
				send_required = true;
			}
		}
	}
	if (send_required) send_now();
}

void usb_keyboard_class::releaseAll(void)
{
	uint8_t i, anybits;

	anybits = keyboard_report_data[0];
	for (i=2; i < 8; i++) {
		anybits |= keyboard_report_data[i];
		keyboard_report_data[i] = 0;
	}
	if (!anybits) return;
	keyboard_report_data[0] = 0;
	send_now();
}







static volatile uint8_t prev_byte=0;

void usb_serial_class::begin(long speed)
{
	// make sure USB is initialized
	usb_init();
	uint16_t begin_wait = (uint16_t)millis();
	while (1) {
		// wait for the host to finish enumeration
		if (usb_configuration) {
			delay(250);  // a little time for host to load a driver
			return;
		}
		// or for suspend mode (powered without USB)
		if (usb_suspended) {
			uint16_t begin_suspend = (uint16_t)millis();
			while (usb_suspended) {
				// must remain suspended for a while, because
				// normal USB enumeration causes brief suspend
				// states, typically under 0.1 second
				if ((uint16_t)millis() - begin_suspend > 250) {
					return;
				}
			}
		}
		// ... or a timout (powered by a USB power adaptor that
		// wiggles the data lines to keep a USB device charging)
		if ((uint16_t)millis() - begin_wait > 2500) return;
	}
	prev_byte = 0;
}

void usb_serial_class::end()
{
	usb_shutdown();
	delay(25);
}


// number of bytes available in the receive buffer
int usb_serial_class::available()
{
	uint8_t c;

	c = prev_byte;	// assume 1 byte static volatile access is atomic
	if (c) return 1;
	c = readnext();
	if (c) {
		prev_byte = c;
		return 1;
	}
	return 0;
}

// get the next character, or -1 if nothing received
int usb_serial_class::read()
{
	uint8_t c;

	c = prev_byte;
	if (c) {
		prev_byte = 0;
		return c;
	}
	c = readnext();
	if (c) return c;
	return -1;
}

int usb_serial_class::peek()
{
	uint8_t c;

	c = prev_byte;
	if (c) return c;
	c = readnext();
	if (c) {
		prev_byte = c;
		return c;
	}
	return -1;
}

// get the next character, or 0 if nothing
uint8_t usb_serial_class::readnext(void)
{
	uint8_t c, intr_state;

	// interrupts are disabled so these functions can be
	// used from the main program or interrupt context,
	// even both in the same program!
	intr_state = SREG;
	cli();
	if (!usb_configuration) {
		SREG = intr_state;
		return 0;
	}
	UENUM = DEBUG_RX_ENDPOINT;
try_again:
	if (!(UEINTX & (1<<RWAL))) {
		// no packet in buffer
		SREG = intr_state;
		return 0;
	}
	// take one byte out of the buffer
	c = UEDATX;
	if (c == 0) {
		// if we see a zero, discard it and
		// discard the rest of this packet
		UEINTX = 0x6B;
		goto try_again;
	}
	// if this drained the buffer, release it
	if (!(UEINTX & (1<<RWAL))) UEINTX = 0x6B;
	SREG = intr_state;
	return c;
}

// discard any buffered input
void usb_serial_class::flush()
{
	uint8_t intr_state;

	if (usb_configuration) {
		intr_state = SREG;
		cli();
		UENUM = DEBUG_RX_ENDPOINT;
		while ((UEINTX & (1<<RWAL))) {
			UEINTX = 0x6B;
		}
		SREG = intr_state;
	}
	prev_byte = 0;
}

// transmit a character.
#if ARDUINO >= 100
size_t usb_serial_class::write(uint8_t c)
#else
void usb_serial_class::write(uint8_t c)
#endif
{
	//static uint8_t previous_timeout=0;
	uint8_t timeout, intr_state;

	// if we're not online (enumerated and configured), error
	if (!usb_configuration) goto error;
	// interrupts are disabled so these functions can be
	// used from the main program or interrupt context,
	// even both in the same program!
	intr_state = SREG;
	cli();
	UENUM = DEBUG_TX_ENDPOINT;
	// if we gave up due to timeout before, don't wait again
#if 0
	if (previous_timeout) {
		if (!(UEINTX & (1<<RWAL))) {
			SREG = intr_state;
			return;
		}
		previous_timeout = 0;
	}
#endif
	// wait for the FIFO to be ready to accept data
	timeout = UDFNUML + TRANSMIT_TIMEOUT;
	while (1) {
		// are we ready to transmit?
		if (UEINTX & (1<<RWAL)) break;
		SREG = intr_state;
		// have we waited too long?  This happens if the user
		// is not running an application that is listening
		if (UDFNUML == timeout) {
			//previous_timeout = 1;
			goto error;
		}
		// has the USB gone offline?
		if (!usb_configuration) goto error;
		// get ready to try checking again
		intr_state = SREG;
		cli();
		UENUM = DEBUG_TX_ENDPOINT;
	}
	// actually write the byte into the FIFO
	UEDATX = c;
	// if this completed a packet, transmit it now!
	if (!(UEINTX & (1<<RWAL))) {
		UEINTX = 0x3A;
		debug_flush_timer = 0;
	} else {
		debug_flush_timer = TRANSMIT_FLUSH_TIMEOUT;
	}
	SREG = intr_state;
#if ARDUINO >= 100
        return 1;
#endif
error:
#if ARDUINO >= 100
        setWriteError();
        return 0;
#else
	return;
#endif
}


// These are Teensy-specific extensions to the Serial object

// immediately transmit any buffered output.
// This doesn't actually transmit the data - that is impossible!
// USB devices only transmit when the host allows, so the best
// we can do is release the FIFO buffer for when the host wants it
void usb_serial_class::send_now(void)
{
	uint8_t intr_state;

	intr_state = SREG;
	cli();
	if (debug_flush_timer) {
		UENUM = DEBUG_TX_ENDPOINT;
		while ((UEINTX & (1<<RWAL))) {
			UEDATX = 0;
		}
		UEINTX = 0x3A;
		debug_flush_timer = 0;
	}
	SREG = intr_state;
}

uint32_t usb_serial_class::baud(void)
{
	return ((uint32_t)DEBUG_TX_SIZE * 10000 / DEBUG_TX_INTERVAL);
}

uint8_t usb_serial_class::stopbits(void)
{
	return 1;
}

uint8_t usb_serial_class::paritytype(void)
{
	return 0;
}

uint8_t usb_serial_class::numbits(void)
{
	return 8;
}

uint8_t usb_serial_class::dtr(void)
{
	return 1;
}

uint8_t usb_serial_class::rts(void)
{
	return 1;
}

usb_serial_class::operator bool()
{
	if (usb_configuration) return true;
	return false;
}


// Preinstantiate Objects //////////////////////////////////////////////////////

usb_serial_class	Serial = usb_serial_class();
usb_keyboard_class	Keyboard = usb_keyboard_class();
usb_disk_class		Disk = usb_disk_class();