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controller/Output/pjrcUSB/avr/usb_keyboard_serial.c
Jacob Alexander 15ec4ff71c Adding CLI and CDC Serial support for Teensy 2.0 and Teensy 2.0++
- Includes serial putchar and getchar cleanup (overall)
- Moved avr-capsense to DPH (renaming)
- Basic cleanup for including CLI on the avr architecture
2014-03-31 01:07:48 -07:00

1127 lines
33 KiB
C

/* USB Keyboard and CDC Serial Device for Teensy USB Development Board
* Copyright (c) 2009 PJRC.COM, LLC
* Modifications by Jacob Alexander (2011-2014)
*
* 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.
*/
// Local Includes
#include "usb_keyboard_serial.h"
// ----- Functions -----
// Set the avr into firmware reload mode
void usb_debug_reload()
{
cli();
// Disable watchdog, if enabled
// Disable all peripherals
UDCON = 1;
USBCON = (1 << FRZCLK); // Disable USB
UCSR1B = 0;
_delay_ms( 5 );
#if defined(__AVR_AT90USB162__) // Teensy 1.0
EIMSK = 0; PCICR = 0; SPCR = 0; ACSR = 0; EECR = 0;
TIMSK0 = 0; TIMSK1 = 0; UCSR1B = 0;
DDRB = 0; DDRC = 0; DDRD = 0;
PORTB = 0; PORTC = 0; PORTD = 0;
asm volatile("jmp 0x3E00");
#elif defined(__AVR_ATmega32U4__) // Teensy 2.0
EIMSK = 0; PCICR = 0; SPCR = 0; ACSR = 0; EECR = 0; ADCSRA = 0;
TIMSK0 = 0; TIMSK1 = 0; TIMSK3 = 0; TIMSK4 = 0; UCSR1B = 0; TWCR = 0;
DDRB = 0; DDRC = 0; DDRD = 0; DDRE = 0; DDRF = 0; TWCR = 0;
PORTB = 0; PORTC = 0; PORTD = 0; PORTE = 0; PORTF = 0;
asm volatile("jmp 0x7E00");
#elif defined(__AVR_AT90USB646__) // Teensy++ 1.0
EIMSK = 0; PCICR = 0; SPCR = 0; ACSR = 0; EECR = 0; ADCSRA = 0;
TIMSK0 = 0; TIMSK1 = 0; TIMSK2 = 0; TIMSK3 = 0; UCSR1B = 0; TWCR = 0;
DDRA = 0; DDRB = 0; DDRC = 0; DDRD = 0; DDRE = 0; DDRF = 0;
PORTA = 0; PORTB = 0; PORTC = 0; PORTD = 0; PORTE = 0; PORTF = 0;
asm volatile("jmp 0xFC00");
#elif defined(__AVR_AT90USB1286__) // Teensy++ 2.0
EIMSK = 0; PCICR = 0; SPCR = 0; ACSR = 0; EECR = 0; ADCSRA = 0;
TIMSK0 = 0; TIMSK1 = 0; TIMSK2 = 0; TIMSK3 = 0; UCSR1B = 0; TWCR = 0;
DDRA = 0; DDRB = 0; DDRC = 0; DDRD = 0; DDRE = 0; DDRF = 0;
PORTA = 0; PORTB = 0; PORTC = 0; PORTD = 0; PORTE = 0; PORTF = 0;
asm volatile("jmp 0x1FC00");
#endif
}
// WDT Setup for software reset the chip
void wdt_init(void)
{
MCUSR = 0;
wdt_disable();
}
/**************************************************************************
*
* Configurable Options
*
**************************************************************************/
// When you write data, it goes into a USB endpoint buffer, which
// is transmitted to the PC when it becomes full, or after a timeout
// with no more writes. Even if you write in exactly packet-size
// increments, this timeout is used to send a "zero length packet"
// that tells the PC no more data is expected and it should pass
// any buffered data to the application that may be waiting. If
// you want data sent immediately, call usb_serial_flush_output().
#define TRANSMIT_FLUSH_TIMEOUT 5 /* in milliseconds */
// If the PC is connected but not "listening", this is the length
// of time before usb_serial_getchar() returns with an error. This
// is roughly equivilant to a real UART simply transmitting the
// bits on a wire where nobody is listening, except you get an error
// code which you can ignore for serial-like discard of data, or
// use to know your data wasn't sent.
#define TRANSMIT_TIMEOUT 25 /* in milliseconds */
// USB devices are supposed to implment a halt feature, which is
// rarely (if ever) used. If you comment this line out, the halt
// code will be removed, saving 116 bytes of space (gcc 4.3.0).
// This is not strictly USB compliant, but works with all major
// operating systems.
#define SUPPORT_ENDPOINT_HALT
/**************************************************************************
*
* Descriptor Data
*
**************************************************************************/
// Descriptors are the data that your computer reads when it auto-detects
// this USB device (called "enumeration" in USB lingo). The most commonly
// changed items are editable at the top of this file. Changing things
// in here should only be done by those who've read chapter 9 of the USB
// spec and relevant portions of any USB class specifications!
static const uint8_t PROGMEM device_descriptor[] = {
18, // bLength
1, // bDescriptorType
0x00, 0x02, // bcdUSB
0, // bDeviceClass
0, // bDeviceSubClass
0, // bDeviceProtocol
ENDPOINT0_SIZE, // bMaxPacketSize0
LSB(VENDOR_ID), MSB(VENDOR_ID), // idVendor
LSB(PRODUCT_ID), MSB(PRODUCT_ID), // idProduct
0x00, 0x01, // bcdDevice
1, // iManufacturer
2, // iProduct
3, // iSerialNumber
1 // bNumConfigurations
};
// Keyboard Protocol 1, HID 1.11 spec, Appendix B, page 59-60
static const uint8_t PROGMEM keyboard_hid_report_desc[] = {
0x05, 0x01, // Usage Page (Generic Desktop),
0x09, 0x06, // Usage (Keyboard),
0xA1, 0x01, // Collection (Application),
0x75, 0x01, // Report Size (1),
0x95, 0x08, // Report Count (8),
0x05, 0x07, // Usage Page (Key Codes),
0x19, 0xE0, // Usage Minimum (224),
0x29, 0xE7, // Usage Maximum (231),
0x15, 0x00, // Logical Minimum (0),
0x25, 0x01, // Logical Maximum (1),
0x81, 0x02, // Input (Data, Variable, Absolute), ;Modifier byte
0x95, 0x08, // Report Count (8),
0x75, 0x01, // Report Size (1),
0x15, 0x00, // Logical Minimum (0),
0x25, 0x01, // Logical Maximum (1),
0x05, 0x0C, // Usage Page (Consumer),
0x09, 0xE9, // Usage (Volume Increment),
0x09, 0xEA, // Usage (Volume Decrement),
0x09, 0xE2, // Usage (Mute),
0x09, 0xCD, // Usage (Play/Pause),
0x09, 0xB5, // Usage (Scan Next Track),
0x09, 0xB6, // Usage (Scan Previous Track),
0x09, 0xB7, // Usage (Stop),
0x09, 0xB8, // Usage (Eject),
0x81, 0x02, // Input (Data, Variable, Absolute), ;Media keys
0x95, 0x05, // Report Count (5),
0x75, 0x01, // Report Size (1),
0x05, 0x08, // Usage Page (LEDs),
0x19, 0x01, // Usage Minimum (1),
0x29, 0x05, // Usage Maximum (5),
0x91, 0x02, // Output (Data, Variable, Absolute), ;LED report
0x95, 0x01, // Report Count (1),
0x75, 0x03, // Report Size (3),
0x91, 0x03, // Output (Constant), ;LED report padding
0x95, 0x06, // Report Count (6),
0x75, 0x08, // Report Size (8),
0x15, 0x00, // Logical Minimum (0),
0x25, 0x7F, // Logical Maximum(104),
0x05, 0x07, // Usage Page (Key Codes),
0x19, 0x00, // Usage Minimum (0),
0x29, 0x7F, // Usage Maximum (104),
0x81, 0x00, // Input (Data, Array), ;Normal keys
0xc0 // End Collection
};
// <Configuration> + <Keyboard HID> + <Serial CDC>
#define CONFIG1_DESC_SIZE (9 + 9+9+7 + 8+9+5+5+4+5+7+9+7+7)
#define KEYBOARD_HID_DESC_OFFSET (9 + 9)
#define SERIAL_CDC_DESC_OFFSET (9 + 9+9+7)
static const uint8_t PROGMEM config1_descriptor[CONFIG1_DESC_SIZE] = {
// --- Configuration ---
// - 9 bytes -
// configuration descriptor, USB spec 9.6.3, page 264-266, Table 9-10
9, // bLength;
2, // bDescriptorType;
LSB(CONFIG1_DESC_SIZE), // wTotalLength
MSB(CONFIG1_DESC_SIZE),
3, // bNumInterfaces
1, // bConfigurationValue
0, // iConfiguration
0xC0, // bmAttributes
50, // bMaxPower
// --- Keyboard HID ---
// - 9 bytes -
// interface descriptor, USB spec 9.6.5, page 267-269, Table 9-12
9, // bLength
4, // bDescriptorType
KEYBOARD_INTERFACE, // bInterfaceNumber
0, // bAlternateSetting
1, // bNumEndpoints
0x03, // bInterfaceClass (0x03 = HID)
0x01, // bInterfaceSubClass (0x01 = Boot)
0x01, // bInterfaceProtocol (0x01 = Keyboard)
0, // iInterface
// - 9 bytes -
// HID interface descriptor, HID 1.11 spec, section 6.2.1
9, // bLength
0x21, // bDescriptorType
0x11, 0x01, // bcdHID
0, // bCountryCode
1, // bNumDescriptors
0x22, // bDescriptorType
LSB(sizeof(keyboard_hid_report_desc)), // wDescriptorLength
MSB(sizeof(keyboard_hid_report_desc)),
// - 7 bytes -
// endpoint descriptor, USB spec 9.6.6, page 269-271, Table 9-13
7, // bLength
5, // bDescriptorType
KEYBOARD_ENDPOINT | 0x80, // bEndpointAddress
0x03, // bmAttributes (0x03=intr)
KEYBOARD_SIZE, 0, // wMaxPacketSize
KEYBOARD_INTERVAL, // bInterval
// --- Serial CDC ---
// - 8 bytes -
// interface association descriptor, USB ECN, Table 9-Z
8, // bLength
11, // bDescriptorType
CDC_STATUS_INTERFACE, // bFirstInterface
2, // bInterfaceCount
0x02, // bFunctionClass
0x02, // bFunctionSubClass
0x01, // bFunctionProtocol
4, // iFunction
// - 9 bytes -
// interface descriptor, USB spec 9.6.5, page 267-269, Table 9-12
9, // bLength
4, // bDescriptorType
CDC_STATUS_INTERFACE, // bInterfaceNumber
0, // bAlternateSetting
1, // bNumEndpoints
0x02, // bInterfaceClass
0x02, // bInterfaceSubClass
0x01, // bInterfaceProtocol
0, // iInterface
// - 5 bytes -
// CDC Header Functional Descriptor, CDC Spec 5.2.3.1, Table 26
5, // bFunctionLength
0x24, // bDescriptorType
0x00, // bDescriptorSubtype
0x10, 0x01, // bcdCDC
// - 5 bytes -
// Call Management Functional Descriptor, CDC Spec 5.2.3.2, Table 27
5, // bFunctionLength
0x24, // bDescriptorType
0x01, // bDescriptorSubtype
0x01, // bmCapabilities
1, // bDataInterface
// - 4 bytes -
// Abstract Control Management Functional Descriptor, CDC Spec 5.2.3.3, Table 28
4, // bFunctionLength
0x24, // bDescriptorType
0x02, // bDescriptorSubtype
0x06, // bmCapabilities
// - 5 bytes -
// Union Functional Descriptor, CDC Spec 5.2.3.8, Table 33
5, // bFunctionLength
0x24, // bDescriptorType
0x06, // bDescriptorSubtype
CDC_STATUS_INTERFACE, // bMasterInterface
CDC_DATA_INTERFACE, // bSlaveInterface0
// - 7 bytes -
// endpoint descriptor, USB spec 9.6.6, page 269-271, Table 9-13
7, // bLength
5, // bDescriptorType
CDC_ACM_ENDPOINT | 0x80, // bEndpointAddress
0x03, // bmAttributes (0x03=intr)
CDC_ACM_SIZE, 0, // wMaxPacketSize
64, // bInterval
// - 9 bytes -
// interface descriptor, USB spec 9.6.5, page 267-269, Table 9-12
9, // bLength
4, // bDescriptorType
CDC_DATA_INTERFACE, // bInterfaceNumber
0, // bAlternateSetting
2, // bNumEndpoints
0x0A, // bInterfaceClass
0x00, // bInterfaceSubClass
0x00, // bInterfaceProtocol
0, // iInterface
// - 7 bytes -
// endpoint descriptor, USB spec 9.6.6, page 269-271, Table 9-13
7, // bLength
5, // bDescriptorType
CDC_RX_ENDPOINT, // bEndpointAddress
0x02, // bmAttributes (0x02=bulk)
CDC_RX_SIZE, 0, // wMaxPacketSize
0, // bInterval
// - 7 bytes -
// endpoint descriptor, USB spec 9.6.6, page 269-271, Table 9-13
7, // bLength
5, // bDescriptorType
CDC_TX_ENDPOINT | 0x80, // bEndpointAddress
0x02, // bmAttributes (0x02=bulk)
CDC_TX_SIZE, 0, // wMaxPacketSize
0, // bInterval
};
// If you're desperate for a little extra code memory, these strings
// can be completely removed if iManufacturer, iProduct, iSerialNumber
// in the device desciptor are changed to zeros.
struct usb_string_descriptor_struct {
uint8_t bLength;
uint8_t bDescriptorType;
int16_t wString[];
};
static const struct usb_string_descriptor_struct PROGMEM string0 = {
4,
3,
{0x0409}
};
static const struct usb_string_descriptor_struct PROGMEM string1 = {
sizeof(STR_MANUFACTURER),
3,
STR_MANUFACTURER
};
static const struct usb_string_descriptor_struct PROGMEM string2 = {
sizeof(STR_PRODUCT),
3,
STR_PRODUCT
};
static const struct usb_string_descriptor_struct PROGMEM string3 = {
sizeof(STR_SERIAL),
3,
STR_SERIAL
};
// This table defines which descriptor data is sent for each specific
// request from the host (in wValue and wIndex).
static const struct descriptor_list_struct {
uint16_t wValue;
uint16_t wIndex;
const uint8_t *addr;
uint8_t length;
} PROGMEM descriptor_list[] = {
{0x0100, 0x0000, device_descriptor, sizeof(device_descriptor)},
{0x0200, 0x0000, config1_descriptor, sizeof(config1_descriptor)},
{0x2200, KEYBOARD_INTERFACE, keyboard_hid_report_desc, sizeof(keyboard_hid_report_desc)},
{0x2100, KEYBOARD_INTERFACE, config1_descriptor+KEYBOARD_HID_DESC_OFFSET, 9},
{0x0300, 0x0000, (const uint8_t *)&string0, 4},
{0x0301, 0x0409, (const uint8_t *)&string1, sizeof(STR_MANUFACTURER)},
{0x0302, 0x0409, (const uint8_t *)&string2, sizeof(STR_PRODUCT)},
{0x0303, 0x0409, (const uint8_t *)&string3, sizeof(STR_SERIAL)}
};
#define NUM_DESC_LIST (sizeof(descriptor_list)/sizeof(struct descriptor_list_struct))
/**************************************************************************
*
* Variables - these are the only non-stack RAM usage
*
**************************************************************************/
// zero when we are not configured, non-zero when enumerated
static volatile uint8_t usb_configuration=0;
// the time remaining before we transmit any partially full
// packet, or send a zero length packet.
static volatile uint8_t transmit_flush_timer=0;
static uint8_t transmit_previous_timeout=0;
// serial port settings (baud rate, control signals, etc) set
// by the PC. These are ignored, but kept in RAM.
static uint8_t cdc_line_coding[7]={0x00, 0xE1, 0x00, 0x00, 0x00, 0x00, 0x08};
static uint8_t cdc_line_rtsdtr=0;
/**************************************************************************
*
* Public Functions - these are the API intended for the user
*
**************************************************************************/
// initialize USB
void usb_init(void)
{
HW_CONFIG();
USB_FREEZE(); // enable USB
PLL_CONFIG(); // config PLL
while (!(PLLCSR & (1<<PLOCK))) ; // wait for PLL lock
USB_CONFIG(); // start USB clock
UDCON = 0; // enable attach resistor
usb_configuration = 0;
UDIEN = (1<<EORSTE)|(1<<SOFE);
sei();
// Disable watchdog timer after possible software reset
//wdt_init(); // XXX Not working...seems to be ok without this, not sure though
}
// return 0 if the USB is not configured, or the configuration
// number selected by the HOST
uint8_t usb_configured(void)
{
return usb_configuration;
}
// send the contents of USBKeys_Array and USBKeys_Modifiers
int8_t usb_keyboard_send(void)
{
uint8_t i, intr_state, timeout;
if (!usb_configuration) return -1;
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 -1;
// have we waited too long?
if (UDFNUML == timeout) return -1;
// get ready to try checking again
intr_state = SREG;
cli();
UENUM = KEYBOARD_ENDPOINT;
}
UEDATX = USBKeys_Modifiers;
UEDATX = 0;
for (i=0; i<6; i++) {
UEDATX = USBKeys_Array[i];
}
UEINTX = 0x3A;
USBKeys_Idle_Count = 0;
SREG = intr_state;
return 0;
}
// get the next character, or -1 if nothing received
int16_t usb_serial_getchar(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 -1;
}
UENUM = CDC_RX_ENDPOINT;
retry:
c = UEINTX;
if (!(c & (1<<RWAL))) {
// no data in buffer
if (c & (1<<RXOUTI)) {
UEINTX = 0x6B;
goto retry;
}
SREG = intr_state;
return -2;
}
// take one byte out of the buffer
c = UEDATX;
// if buffer completely used, release it
if (!(UEINTX & (1<<RWAL))) UEINTX = 0x6B;
SREG = intr_state;
return c;
}
// number of bytes available in the receive buffer
uint8_t usb_serial_available(void)
{
uint8_t n=0, i, intr_state;
intr_state = SREG;
cli();
if (usb_configuration) {
UENUM = CDC_RX_ENDPOINT;
n = UEBCLX;
if (!n) {
i = UEINTX;
if (i & (1<<RXOUTI) && !(i & (1<<RWAL))) UEINTX = 0x6B;
}
}
SREG = intr_state;
return n;
}
// discard any buffered input
void usb_serial_flush_input(void)
{
uint8_t intr_state;
if (usb_configuration) {
intr_state = SREG;
cli();
UENUM = CDC_RX_ENDPOINT;
while ((UEINTX & (1<<RWAL))) {
UEINTX = 0x6B;
}
SREG = intr_state;
}
}
// transmit a character. 0 returned on success, -1 on error
int8_t usb_serial_putchar(uint8_t c)
{
uint8_t timeout, intr_state;
// if we're not online (enumerated and configured), error
if (!usb_configuration) return -1;
// 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 = CDC_TX_ENDPOINT;
// if we gave up due to timeout before, don't wait again
if (transmit_previous_timeout) {
if (!(UEINTX & (1<<RWAL))) {
SREG = intr_state;
return -1;
}
transmit_previous_timeout = 0;
}
// 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) {
transmit_previous_timeout = 1;
return -1;
}
// has the USB gone offline?
if (!usb_configuration) return -1;
// get ready to try checking again
intr_state = SREG;
cli();
UENUM = CDC_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;
transmit_flush_timer = TRANSMIT_FLUSH_TIMEOUT;
SREG = intr_state;
return 0;
}
// transmit a character, but do not wait if the buffer is full,
// 0 returned on success, -1 on buffer full or error
int8_t usb_serial_putchar_nowait(uint8_t c)
{
uint8_t intr_state;
if (!usb_configuration) return -1;
intr_state = SREG;
cli();
UENUM = CDC_TX_ENDPOINT;
if (!(UEINTX & (1<<RWAL))) {
// buffer is full
SREG = intr_state;
return -2;
}
// actually write the byte into the FIFO
UEDATX = c;
// if this completed a packet, transmit it now!
if (!(UEINTX & (1<<RWAL))) UEINTX = 0x3A;
transmit_flush_timer = TRANSMIT_FLUSH_TIMEOUT;
SREG = intr_state;
return 0;
}
// transmit a buffer.
// 0 returned on success, -1 on error
// This function is optimized for speed! Each call takes approx 6.1 us overhead
// plus 0.25 us per byte. 12 Mbit/sec USB has 8.67 us per-packet overhead and
// takes 0.67 us per byte. If called with 64 byte packet-size blocks, this function
// can transmit at full USB speed using 43% CPU time. The maximum theoretical speed
// is 19 packets per USB frame, or 1216 kbytes/sec. However, bulk endpoints have the
// lowest priority, so any other USB devices will likely reduce the speed. Speed
// can also be limited by how quickly the PC-based software reads data, as the host
// controller in the PC will not allocate bandwitdh without a pending read request.
// (thanks to Victor Suarez for testing and feedback and initial code)
int8_t usb_serial_write(const char *buffer, uint16_t size)
{
uint8_t timeout, intr_state, write_size;
// if we're not online (enumerated and configured), error
if (!usb_configuration) return -1;
// 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 = CDC_TX_ENDPOINT;
// if we gave up due to timeout before, don't wait again
/*
if (transmit_previous_timeout) {
if (!(UEINTX & (1<<RWAL))) {
SREG = intr_state;
return -2;
}
transmit_previous_timeout = 0;
}
*/
// each iteration of this loop transmits a packet
while (size) {
// 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) {
transmit_previous_timeout = 1;
return -3;
}
// has the USB gone offline?
if (!usb_configuration) return -4;
// get ready to try checking again
intr_state = SREG;
cli();
UENUM = CDC_TX_ENDPOINT;
}
// compute how many bytes will fit into the next packet
write_size = CDC_TX_SIZE - UEBCLX;
if (write_size > size) write_size = size;
size -= write_size;
// write the packet
switch (write_size) {
#if (CDC_TX_SIZE == 64)
case 64: UEDATX = *buffer++;
case 63: UEDATX = *buffer++;
case 62: UEDATX = *buffer++;
case 61: UEDATX = *buffer++;
case 60: UEDATX = *buffer++;
case 59: UEDATX = *buffer++;
case 58: UEDATX = *buffer++;
case 57: UEDATX = *buffer++;
case 56: UEDATX = *buffer++;
case 55: UEDATX = *buffer++;
case 54: UEDATX = *buffer++;
case 53: UEDATX = *buffer++;
case 52: UEDATX = *buffer++;
case 51: UEDATX = *buffer++;
case 50: UEDATX = *buffer++;
case 49: UEDATX = *buffer++;
case 48: UEDATX = *buffer++;
case 47: UEDATX = *buffer++;
case 46: UEDATX = *buffer++;
case 45: UEDATX = *buffer++;
case 44: UEDATX = *buffer++;
case 43: UEDATX = *buffer++;
case 42: UEDATX = *buffer++;
case 41: UEDATX = *buffer++;
case 40: UEDATX = *buffer++;
case 39: UEDATX = *buffer++;
case 38: UEDATX = *buffer++;
case 37: UEDATX = *buffer++;
case 36: UEDATX = *buffer++;
case 35: UEDATX = *buffer++;
case 34: UEDATX = *buffer++;
case 33: UEDATX = *buffer++;
#endif
#if (CDC_TX_SIZE >= 32)
case 32: UEDATX = *buffer++;
case 31: UEDATX = *buffer++;
case 30: UEDATX = *buffer++;
case 29: UEDATX = *buffer++;
case 28: UEDATX = *buffer++;
case 27: UEDATX = *buffer++;
case 26: UEDATX = *buffer++;
case 25: UEDATX = *buffer++;
case 24: UEDATX = *buffer++;
case 23: UEDATX = *buffer++;
case 22: UEDATX = *buffer++;
case 21: UEDATX = *buffer++;
case 20: UEDATX = *buffer++;
case 19: UEDATX = *buffer++;
case 18: UEDATX = *buffer++;
case 17: UEDATX = *buffer++;
#endif
#if (CDC_TX_SIZE >= 16)
case 16: UEDATX = *buffer++;
case 15: UEDATX = *buffer++;
case 14: UEDATX = *buffer++;
case 13: UEDATX = *buffer++;
case 12: UEDATX = *buffer++;
case 11: UEDATX = *buffer++;
case 10: UEDATX = *buffer++;
case 9: UEDATX = *buffer++;
#endif
case 8: UEDATX = *buffer++;
case 7: UEDATX = *buffer++;
case 6: UEDATX = *buffer++;
case 5: UEDATX = *buffer++;
case 4: UEDATX = *buffer++;
case 3: UEDATX = *buffer++;
case 2: UEDATX = *buffer++;
default:
case 1: UEDATX = *buffer++;
case 0: break;
}
// if this completed a packet, transmit it now!
if (!(UEINTX & (1<<RWAL))) UEINTX = 0x3A;
transmit_flush_timer = TRANSMIT_FLUSH_TIMEOUT;
SREG = intr_state;
}
return 0;
}
// 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_flush_output(void)
{
uint8_t intr_state;
intr_state = SREG;
cli();
if (transmit_flush_timer) {
UENUM = CDC_TX_ENDPOINT;
UEINTX = 0x3A;
transmit_flush_timer = 0;
}
SREG = intr_state;
}
// functions to read the various async serial settings. These
// aren't actually used by USB at all (communication is always
// at full USB speed), but they are set by the host so we can
// set them properly if we're converting the USB to a real serial
// communication
uint32_t usb_serial_get_baud(void)
{
uint32_t *baud = (uint32_t*)cdc_line_coding;
return *baud;
}
uint8_t usb_serial_get_stopbits(void)
{
return cdc_line_coding[4];
}
uint8_t usb_serial_get_paritytype(void)
{
return cdc_line_coding[5];
}
uint8_t usb_serial_get_numbits(void)
{
return cdc_line_coding[6];
}
uint8_t usb_serial_get_control(void)
{
return cdc_line_rtsdtr;
}
// write the control signals, DCD, DSR, RI, etc
// There is no CTS signal. If software on the host has transmitted
// data to you but you haven't been calling the getchar function,
// it remains buffered (either here or on the host) and can not be
// lost because you weren't listening at the right time, like it
// would in real serial communication.
int8_t usb_serial_set_control(uint8_t signals)
{
uint8_t intr_state;
intr_state = SREG;
cli();
if (!usb_configuration) {
// we're not enumerated/configured
SREG = intr_state;
return -1;
}
UENUM = CDC_ACM_ENDPOINT;
if (!(UEINTX & (1<<RWAL))) {
// unable to write
// TODO; should this try to abort the previously
// buffered message??
SREG = intr_state;
return -1;
}
UEDATX = 0xA1;
UEDATX = 0x20;
UEDATX = 0;
UEDATX = 0;
UEDATX = 0; // 0 seems to work nicely. what if this is 1??
UEDATX = 0;
UEDATX = 1;
UEDATX = 0;
UEDATX = signals;
UEINTX = 0x3A;
SREG = intr_state;
return 0;
}
/**************************************************************************
*
* Private Functions - not intended for general user consumption....
*
**************************************************************************/
// USB Device Interrupt - handle all device-level events
// the transmit buffer flushing is triggered by the start of frame
//
ISR(USB_GEN_vect)
{
uint8_t intbits, t_cdc, i;
static uint8_t div4=0;
intbits = UDINT;
UDINT = 0;
if (intbits & (1<<EORSTI)) {
UENUM = 0;
UECONX = 1;
UECFG0X = EP_TYPE_CONTROL;
UECFG1X = EP_SIZE(ENDPOINT0_SIZE) | EP_SINGLE_BUFFER;
UEIENX = (1<<RXSTPE);
usb_configuration = 0;
cdc_line_rtsdtr = 0;
}
if ((intbits & (1<<SOFI)) && usb_configuration) {
t_cdc = transmit_flush_timer;
if (t_cdc) {
transmit_flush_timer = --t_cdc;
if (!t_cdc) {
UENUM = CDC_TX_ENDPOINT;
UEINTX = 0x3A;
}
}
if (USBKeys_Idle_Config && (++div4 & 3) == 0) {
UENUM = KEYBOARD_ENDPOINT;
if (UEINTX & (1<<RWAL)) {
USBKeys_Idle_Count++;
if (USBKeys_Idle_Count == USBKeys_Idle_Config) {
USBKeys_Idle_Count = 0;
UEDATX = USBKeys_Modifiers;
UEDATX = 0;
for (i=0; i<6; i++) {
UEDATX = USBKeys_Array[i];
}
UEINTX = 0x3A;
}
}
}
}
}
// Misc functions to wait for ready and send/receive packets
static inline void usb_wait_in_ready(void)
{
while (!(UEINTX & (1<<TXINI))) ;
}
static inline void usb_send_in(void)
{
UEINTX = ~(1<<TXINI);
}
static inline void usb_wait_receive_out(void)
{
while (!(UEINTX & (1<<RXOUTI))) ;
}
static inline void usb_ack_out(void)
{
UEINTX = ~(1<<RXOUTI);
}
// USB Endpoint Interrupt - endpoint 0 is handled here. The
// other endpoints are manipulated by the user-callable
// functions, and the start-of-frame interrupt.
//
ISR(USB_COM_vect)
{
uint8_t intbits;
const uint8_t *list;
const uint8_t *cfg;
uint8_t i, n, len, en;
uint8_t *p;
uint8_t bmRequestType;
uint8_t bRequest;
uint16_t wValue;
uint16_t wIndex;
uint16_t wLength;
uint16_t desc_val;
const uint8_t *desc_addr;
uint8_t desc_length;
UENUM = 0;
intbits = UEINTX;
if (intbits & (1<<RXSTPI)) {
bmRequestType = UEDATX;
bRequest = UEDATX;
wValue = UEDATX;
wValue |= (UEDATX << 8);
wIndex = UEDATX;
wIndex |= (UEDATX << 8);
wLength = UEDATX;
wLength |= (UEDATX << 8);
UEINTX = ~((1<<RXSTPI) | (1<<RXOUTI) | (1<<TXINI));
if (bRequest == GET_DESCRIPTOR) {
list = (const uint8_t *)descriptor_list;
for (i=0; ; i++) {
if (i >= NUM_DESC_LIST) {
UECONX = (1<<STALLRQ)|(1<<EPEN); //stall
return;
}
desc_val = pgm_read_word(list);
if (desc_val != wValue) {
list += sizeof(struct descriptor_list_struct);
continue;
}
list += 2;
desc_val = pgm_read_word(list);
if (desc_val != wIndex) {
list += sizeof(struct descriptor_list_struct)-2;
continue;
}
list += 2;
desc_addr = (const uint8_t *)pgm_read_word(list);
list += 2;
desc_length = pgm_read_byte(list);
break;
}
len = (wLength < 256) ? wLength : 255;
if (len > desc_length) len = desc_length;
do {
// wait for host ready for IN packet
do {
i = UEINTX;
} while (!(i & ((1<<TXINI)|(1<<RXOUTI))));
if (i & (1<<RXOUTI)) return; // abort
// send IN packet
n = len < ENDPOINT0_SIZE ? len : ENDPOINT0_SIZE;
for (i = n; i; i--) {
UEDATX = pgm_read_byte(desc_addr++);
}
len -= n;
usb_send_in();
} while (len || n == ENDPOINT0_SIZE);
return;
}
if (bRequest == SET_ADDRESS) {
usb_send_in();
usb_wait_in_ready();
UDADDR = wValue | (1<<ADDEN);
return;
}
if (bRequest == SET_CONFIGURATION && bmRequestType == 0) {
usb_configuration = wValue;
cdc_line_rtsdtr = 0;
transmit_flush_timer = 0;
usb_send_in();
cfg = endpoint_config_table;
for (i=1; i<6; i++) { // 4+1 of 7 endpoints are used // XXX Important to change if more endpoints are used
UENUM = i;
en = pgm_read_byte(cfg++);
UECONX = en;
if (en) {
UECFG0X = pgm_read_byte(cfg++);
UECFG1X = pgm_read_byte(cfg++);
}
}
UERST = 0x1E;
UERST = 0;
return;
}
if (bRequest == GET_CONFIGURATION && bmRequestType == 0x80) {
usb_wait_in_ready();
UEDATX = usb_configuration;
usb_send_in();
return;
}
if (bRequest == CDC_GET_LINE_CODING && bmRequestType == 0xA1) {
usb_wait_in_ready();
p = cdc_line_coding;
for (i=0; i<7; i++) {
UEDATX = *p++;
}
usb_send_in();
return;
}
if (bRequest == CDC_SET_LINE_CODING && bmRequestType == 0x21) {
usb_wait_receive_out();
p = cdc_line_coding;
for (i=0; i<7; i++) {
*p++ = UEDATX;
}
usb_ack_out();
usb_send_in();
return;
}
if (bRequest == CDC_SET_CONTROL_LINE_STATE && bmRequestType == 0x21) {
cdc_line_rtsdtr = wValue;
usb_wait_in_ready();
usb_send_in();
return;
}
if (bRequest == GET_STATUS) {
usb_wait_in_ready();
i = 0;
#ifdef SUPPORT_ENDPOINT_HALT
if (bmRequestType == 0x82) {
UENUM = wIndex;
if (UECONX & (1<<STALLRQ)) i = 1;
UENUM = 0;
}
#endif
UEDATX = i;
UEDATX = 0;
usb_send_in();
return;
}
#ifdef SUPPORT_ENDPOINT_HALT
if ((bRequest == CLEAR_FEATURE || bRequest == SET_FEATURE)
&& bmRequestType == 0x02 && wValue == 0) {
i = wIndex & 0x7F;
if (i >= 1 && i <= MAX_ENDPOINT) {
usb_send_in();
UENUM = i;
if (bRequest == SET_FEATURE) {
UECONX = (1<<STALLRQ)|(1<<EPEN);
} else {
UECONX = (1<<STALLRQC)|(1<<RSTDT)|(1<<EPEN);
UERST = (1 << i);
UERST = 0;
}
return;
}
}
#endif
if (wIndex == KEYBOARD_INTERFACE) {
if (bmRequestType == 0xA1) {
if (bRequest == HID_GET_REPORT) {
usb_wait_in_ready();
UEDATX = USBKeys_Modifiers;
UEDATX = 0;
for (i=0; i<6; i++) {
UEDATX = USBKeys_Array[i];
}
usb_send_in();
return;
}
if (bRequest == HID_GET_IDLE) {
usb_wait_in_ready();
UEDATX = USBKeys_Idle_Config;
usb_send_in();
return;
}
if (bRequest == HID_GET_PROTOCOL) {
usb_wait_in_ready();
UEDATX = USBKeys_Protocol;
usb_send_in();
return;
}
}
if (bmRequestType == 0x21) {
if (bRequest == HID_SET_REPORT) {
usb_wait_receive_out();
USBKeys_LEDs = UEDATX;
usb_ack_out();
usb_send_in();
return;
}
if (bRequest == HID_SET_IDLE) {
USBKeys_Idle_Config = (wValue >> 8);
USBKeys_Idle_Count = 0;
//usb_wait_in_ready();
usb_send_in();
return;
}
if (bRequest == HID_SET_PROTOCOL) {
USBKeys_Protocol = wValue;
//usb_wait_in_ready();
usb_send_in();
return;
}
}
}
}
UECONX = (1<<STALLRQ) | (1<<EPEN); // stall
}