// File callback to be used with vfs_add_file to return file contents
static uint32_t read_file_mbed_htm(uint32_t sector_offset, uint8_t* data, uint32_t num_sectors)
{
if (sector_offset != 0) {
return 0;
}
update_html_file(data, VFS_SECTOR_SIZE);
return strlen((const char *)data);
}
void usbd_msc_read_sect(uint32_t block, uint8_t *buf, uint32_t num_of_blocks)
{
virtual_media_t fs_read = {0,0};
uint32_t max_known_fs_entry_addr = 0;
uint32_t req_sector_offset = 0;
uint32_t req_addr = block * USBD_MSC_BlockSize;
uint8_t i = 0, real_data_present = 1;
// dont proceed if we're not ready
if (!USBD_MSC_MediaReady) {
return;
}
// indicate msc activity
main_blink_msd_led(0);
// A block is requested from the host. We dont have a flat file system image on disc
// rather just the required bits (mbr, fat, root dir, file data). The fs structure
// knows how these parts look without requiring them all to exist linearly in memory
while((fs[i].length != 0) && (fs_read.sect == 0)) {
// accumulate the length of the fs.sect(s) we have examined so far
max_known_fs_entry_addr += fs[i].length;
// determine if we have real system data or need to pad the transfer with 0
if (req_addr < max_known_fs_entry_addr) {
// we know this is where the data request is, store it for later transmission
fs_read.sect = fs[i].sect;
// sector can be larger than a block. Normalize the block number into the fs entry
req_sector_offset = fs[i].length - (max_known_fs_entry_addr - req_addr);
// determine if the inflated size is greater than the real size.
if(req_sector_offset >= sizeof(fs[i].sect)) {
real_data_present = 0;
}
}
i++;
}
// now send the data if a known sector and valid data in memory - otherwise send 0's
if (fs_read.sect != 0 && real_data_present == 1) {
memcpy(buf, &fs_read.sect[req_sector_offset], num_of_blocks * USBD_MSC_BlockSize);
}
else {
memset(buf, 0, num_of_blocks * USBD_MSC_BlockSize);
}
// Some files require runtime content. If one generate and overwrite the the read sequence
// buffer with the newer data (only works for files < 512 bytes and known location on fs)
if (block == (mbr.reserved_logical_sectors + (mbr.logical_sectors_per_fat*mbr.num_fats)
+ ((mbr.max_root_dir_entries*sizeof(FatDirectoryEntry_t)/mbr.bytes_per_sector)))) {
update_html_file(buf, (num_of_blocks * USBD_MSC_BlockSize));
}
}
__task void main_task(void) {
// State processing
uint16_t flags;
// LED
uint8_t dap_led_value = 1;
uint8_t cdc_led_value = 1;
uint8_t msd_led_value = 1;
// USB
uint32_t usb_state_count;
// thread running after usb connected started
uint8_t thread_started = 0;
// button state
char button_activated;
// string containing unique ID
uint8_t * id_str;
// Get a reference to this task
main_task_id = os_tsk_self();
// leds
gpio_init();
usbd_init();
swd_init();
// Turn on LED
gpio_set_dap_led(1);
gpio_set_cdc_led(1);
gpio_set_msd_led(1);
// Setup reset button
gpio_enable_button_flag(main_task_id, FLAGS_MAIN_RESET);
button_activated = 1;
// USB
usbd_connect(0);
usb_busy = USB_IDLE;
usb_busy_count = 0;
usb_state = USB_CONNECTING;
usb_state_count = USB_CONNECT_DELAY;
// Update HTML version information file
update_html_file();
// Start timer tasks
os_tsk_create_user(timer_task_30mS, TIMER_TASK_30_PRIORITY, (void *)stk_timer_30_task, TIMER_TASK_30_STACK);
// Target running
target_set_state(RESET_RUN_WITH_DEBUG);
// start semihost task
semihost_init();
semihost_enable();
while(1) {
os_evt_wait_or( FLAGS_MAIN_RESET // Put target in reset state
| FLAGS_MAIN_90MS // 90mS tick
| FLAGS_MAIN_30MS // 30mS tick
| FLAGS_MAIN_POWERDOWN // Power down interface
| FLAGS_MAIN_DISABLEDEBUG // Power down interface
| FLAGS_MAIN_USB_DISCONNECT, // Disable target debug
NO_TIMEOUT);
// Find out what event happened
flags = os_evt_get();
if (flags & FLAGS_MAIN_USB_DISCONNECT) {
usb_busy = USB_IDLE; // USB not busy
usb_state_count = 4;
usb_state = USB_DISCONNECT_CONNECT; // disconnect the usb
}
if (flags & FLAGS_MAIN_RESET) {
cdc_led_state = LED_OFF;
gpio_set_cdc_led(0);
//usbd_cdc_ser_flush();
if (send_uID) {
// set the target in reset to not receive char on the serial port
target_set_state(RESET_HOLD);
// send uid
id_str = get_uid_string();
USBD_CDC_ACM_DataSend(id_str, strlen((const char *)id_str));
send_uID = 0;
}
// Reset target
target_set_state(RESET_RUN);
cdc_led_state = LED_FLASH;
gpio_set_cdc_led(1);
button_activated = 0;
}
if (flags & FLAGS_MAIN_POWERDOWN) {
// Stop semihost task
semihost_disable();
// Disable debug
target_set_state(NO_DEBUG);
// Disconnect USB
usbd_connect(0);
// Turn off LED
gpio_set_dap_led(0);
gpio_set_cdc_led(0);
gpio_set_msd_led(0);
// TODO: put the interface chip in sleep mode
while (1) { }
}
if (flags & FLAGS_MAIN_DISABLEDEBUG) {
// Stop semihost task
semihost_disable();
// Disable debug
target_set_state(NO_DEBUG);
}
if (flags & FLAGS_MAIN_90MS) {
if (!button_activated) {
gpio_enable_button_flag(main_task_id, FLAGS_MAIN_RESET);
button_activated = 1;
}
// Update USB busy status
switch (usb_busy) {
case USB_ACTIVE:
if (DECZERO(usb_busy_count) == 0) {
usb_busy=USB_IDLE;
}
break;
case USB_IDLE:
default:
break;
}
// Update USB connect status
switch (usb_state) {
case USB_DISCONNECTING:
// Wait until USB is idle before disconnecting
if (usb_busy == USB_IDLE) {
usbd_connect(0);
usb_state = USB_DISCONNECTED;
}
break;
case USB_DISCONNECT_CONNECT:
// Wait until USB is idle before disconnecting
if ((usb_busy == USB_IDLE) && (DECZERO(usb_state_count) == 0)) {
usbd_connect(0);
usb_state = USB_CONNECTING;
// Update HTML file
update_html_file();
}
break;
case USB_CONNECTING:
// Wait before connecting
if (DECZERO(usb_state_count) == 0) {
usbd_connect(1);
usb_state = USB_CHECK_CONNECTED;
}
break;
case USB_CHECK_CONNECTED:
if(usbd_configured()) {
if (!thread_started) {
os_tsk_create_user(hid_process, DAP_TASK_PRIORITY, (void *)stk_dap_task, DAP_TASK_STACK);
serial_task_id = os_tsk_create_user(serial_process, SERIAL_TASK_PRIORITY, (void *)stk_serial_task, SERIAL_TASK_STACK);
thread_started = 1;
}
usb_state = USB_CONNECTED;
}
break;
case USB_CONNECTED:
case USB_DISCONNECTED:
default:
break;
}
}
// 30mS tick used for flashing LED when USB is busy
if (flags & FLAGS_MAIN_30MS) {
if (dap_led_usb_activity && ((dap_led_state == LED_FLASH) || (dap_led_state == LED_FLASH_PERMANENT))) {
// Flash DAP LED ONCE
if (dap_led_value) {
dap_led_value = 0;
} else {
dap_led_value = 1; // Turn on
if (dap_led_state == LED_FLASH) {
dap_led_usb_activity = 0;
}
}
// Update hardware
gpio_set_dap_led(dap_led_value);
}
if (msd_led_usb_activity && ((msd_led_state == LED_FLASH) || (msd_led_state == LED_FLASH_PERMANENT))) {
// Flash MSD LED ONCE
if (msd_led_value) {
msd_led_value = 0;
} else {
msd_led_value = 1; // Turn on
if (msd_led_state == LED_FLASH) {
msd_led_usb_activity = 0;
}
}
// Update hardware
gpio_set_msd_led(msd_led_value);
}
if (cdc_led_usb_activity && ((cdc_led_state == LED_FLASH) || (cdc_led_state == LED_FLASH_PERMANENT))) {
// Flash CDC LED ONCE
if (cdc_led_value) {
cdc_led_value = 0;
} else {
cdc_led_value = 1; // Turn on
if (cdc_led_state == LED_FLASH) {
cdc_led_usb_activity = 0;
}
}
// Update hardware
gpio_set_cdc_led(cdc_led_value);
}
}
}
}
__task void main_task(void) {
// State processing
uint16_t flags;
// LED
uint8_t dap_led_value = 1;
uint8_t cdc_led_value = 1;
uint8_t msd_led_value = 1;
// USB
uint32_t usb_state_count;
// thread running after usb connected started
uint8_t thread_started = 0;
// button state
char button_activated;
// string containing unique ID
uint8_t * id_str;
// Initialize our serial mailbox
os_mbx_init(&serial_mailbox, sizeof(serial_mailbox));
// Get a reference to this task
main_task_id = os_tsk_self();
// leds
gpio_init();
// Turn off LED
gpio_set_dap_led(1);
gpio_set_cdc_led(1);
gpio_set_msd_led(1);
#ifdef BOARD_UBLOX_C027
PORT_SWD_SETUP();
// wait until reset output to the target is pulled high
while (!PIN_nRESET_IN()) {
/* wait doing nothing */
}
os_dly_wait(4);
// if the reset input from button is low then enter isp programming mode
if (!(LPC_GPIO->B[19/*RESET_PIN*/ + (1/*RESET_PORT*/ << 5)] & 1)) {
enter_isp();
}
#endif
usbd_init();
swd_init();
// Setup reset button
gpio_enable_button_flag(main_task_id, FLAGS_MAIN_RESET);
button_activated = 1;
// USB
usbd_connect(0);
usb_busy = USB_IDLE;
usb_busy_count = 0;
usb_state = USB_CONNECTING;
usb_state_count = USB_CONNECT_DELAY;
// Update HTML version information file
update_html_file();
// Start timer tasks
os_tsk_create_user(timer_task_30mS, TIMER_TASK_30_PRIORITY, (void *)stk_timer_30_task, TIMER_TASK_30_STACK);
#ifndef BOARD_UBLOX_C027
// Target running
//target_set_state(RESET_RUN_WITH_DEBUG);
#endif
#ifdef BOARD_NRF51822AA
// Target running
target_set_state(RESET_RUN);
#endif
// start semihost task
semihost_init();
semihost_enable();
while(1) {
os_evt_wait_or( FLAGS_MAIN_RESET // Put target in reset state
| FLAGS_MAIN_90MS // 90mS tick
| FLAGS_MAIN_30MS // 30mS tick
| FLAGS_MAIN_POWERDOWN // Power down interface
| FLAGS_MAIN_DISABLEDEBUG // Power down interface
#ifdef USE_USB_EJECT_INSERT
| FLAGS_MAIN_USB_DISCONNECT // Disable target debug
| FLAGS_MAIN_USB_MEDIA_EJECT, // Eject file system
#else
| FLAGS_MAIN_USB_DISCONNECT, // Disable target debug
#endif
NO_TIMEOUT);
// Find out what event happened
flags = os_evt_get();
if (flags & FLAGS_MAIN_USB_DISCONNECT) {
usb_busy = USB_IDLE; // USB not busy
usb_state_count = 4;
usb_state = USB_DISCONNECT_CONNECT; // disconnect the usb
}
#ifdef USE_USB_EJECT_INSERT
if (flags & FLAGS_MAIN_USB_MEDIA_EJECT) {
EjectInsertMediaMode = EJECT_INSERT_WAIT_TO_EJECT;
EjectInsertMediaCounter = EJECT_INSERT_DELAY_500MS;
}
#endif
if (flags & FLAGS_MAIN_RESET) {
cdc_led_state = LED_OFF;
gpio_set_cdc_led(0);
//usbd_cdc_ser_flush();
if (send_uID) {
// set the target in reset to not receive char on the serial port
target_set_state(RESET_HOLD);
// send uid
id_str = get_uid_string();
USBD_CDC_ACM_DataSend(id_str, strlen((const char *)id_str));
send_uID = 0;
}
// Reset target
target_set_state(RESET_RUN);
cdc_led_state = LED_FLASH;
gpio_set_cdc_led(1);
button_activated = 0;
}
if (flags & FLAGS_MAIN_POWERDOWN) {
// Stop semihost task
semihost_disable();
// Disable debug
target_set_state(NO_DEBUG);
// Disconnect USB
usbd_connect(0);
// Turn off LED
gpio_set_dap_led(0);
gpio_set_cdc_led(0);
gpio_set_msd_led(0);
// TODO: put the interface chip in sleep mode
while (1) { }
}
if (flags & FLAGS_MAIN_DISABLEDEBUG) {
// Stop semihost task
semihost_disable();
// Disable debug
target_set_state(NO_DEBUG);
}
if (flags & FLAGS_MAIN_90MS) {
if (!button_activated) {
gpio_enable_button_flag(main_task_id, FLAGS_MAIN_RESET);
button_activated = 1;
}
#ifdef USE_USB_EJECT_INSERT
if (EjectInsertMediaMode == EJECT_INSERT_WAIT_TO_EJECT) {
if (--EjectInsertMediaCounter == 0) {
// Have waited ~0.5 second, time to eject media
EjectInsertMediaMode = EJECT_INSERT_WAIT_TO_INSERT;
EjectInsertMediaCounter = EJECT_INSERT_DELAY_500MS;
USBD_MSC_MediaReady = __FALSE;
}
}
if ((EjectInsertMediaMode == EJECT_INSERT_WAIT_TO_INSERT) && !USBD_MSC_MediaReadyEx) {
// The host computer have questioned the state and received
// the message that the media has been removed
if (--EjectInsertMediaCounter == 0) {
// Have waited ~0.5 seconds after ejecting, time to insert media
EjectInsertMediaMode = EJECT_INSERT_INACTIVE;
USBD_MSC_MediaReady = __TRUE;
}
}
#endif
// Update USB busy status
switch (usb_busy) {
case USB_ACTIVE:
if (DECZERO(usb_busy_count) == 0) {
usb_busy=USB_IDLE;
}
break;
case USB_IDLE:
default:
break;
}
// Update USB connect status
switch (usb_state) {
case USB_DISCONNECTING:
// Wait until USB is idle before disconnecting
if (usb_busy == USB_IDLE) {
usbd_connect(0);
usb_state = USB_DISCONNECTED;
}
break;
case USB_DISCONNECT_CONNECT:
// Wait until USB is idle before disconnecting
if ((usb_busy == USB_IDLE) && (DECZERO(usb_state_count) == 0)) {
usbd_connect(0);
usb_state = USB_CONNECTING;
// Update HTML file
update_html_file();
// Delay the connecting state before reconnecting to the host - improved usage with VMs
usb_state_count = 10; //(90ms * 10 = 900ms)
}
break;
case USB_CONNECTING:
// Wait before connecting
if (DECZERO(usb_state_count) == 0) {
usbd_connect(1);
usb_state = USB_CHECK_CONNECTED;
}
break;
case USB_CHECK_CONNECTED:
if(usbd_configured()) {
if (!thread_started) {
os_tsk_create_user(hid_process, DAP_TASK_PRIORITY, (void *)stk_dap_task, DAP_TASK_STACK);
serial_task_id = os_tsk_create_user(serial_process, SERIAL_TASK_PRIORITY, (void *)stk_serial_task, SERIAL_TASK_STACK);
thread_started = 1;
}
usb_state = USB_CONNECTED;
}
break;
case USB_CONNECTED:
case USB_DISCONNECTED:
default:
break;
}
}
// 30mS tick used for flashing LED when USB is busy
if (flags & FLAGS_MAIN_30MS) {
if (dap_led_usb_activity && ((dap_led_state == LED_FLASH) || (dap_led_state == LED_FLASH_PERMANENT))) {
// Flash DAP LED ONCE
if (dap_led_value) {
dap_led_value = 0;
} else {
dap_led_value = 1; // Turn on
if (dap_led_state == LED_FLASH) {
dap_led_usb_activity = 0;
}
}
// Update hardware
gpio_set_dap_led(dap_led_value);
}
if (msd_led_usb_activity && ((msd_led_state == LED_FLASH) || (msd_led_state == LED_FLASH_PERMANENT))) {
// Flash MSD LED ONCE
if (msd_led_value) {
msd_led_value = 0;
} else {
msd_led_value = 1; // Turn on
if (msd_led_state == LED_FLASH) {
msd_led_usb_activity = 0;
}
}
// Update hardware
gpio_set_msd_led(msd_led_value);
}
if (cdc_led_usb_activity && ((cdc_led_state == LED_FLASH) || (cdc_led_state == LED_FLASH_PERMANENT))) {
// Flash CDC LED ONCE
if (cdc_led_value) {
cdc_led_value = 0;
} else {
cdc_led_value = 1; // Turn on
if (cdc_led_state == LED_FLASH) {
cdc_led_usb_activity = 0;
}
}
// Update hardware
gpio_set_cdc_led(cdc_led_value);
}
}
}
}
