struct hid_device_info HID_API_EXPORT *hid_enumerate(unsigned short vendor_id, unsigned short product_id)
{
struct hid_device_info *root = NULL; // return object
struct hid_device_info *cur_dev = NULL;
CFIndex num_devices;
int i;
setlocale(LC_ALL,"");
/* Set up the HID Manager if it hasn't been done */
hid_init();
/* Get a list of the Devices */
CFSetRef device_set = IOHIDManagerCopyDevices(hid_mgr);
/* Convert the list into a C array so we can iterate easily. */
num_devices = CFSetGetCount(device_set);
IOHIDDeviceRef *device_array = calloc(num_devices, sizeof(IOHIDDeviceRef));
CFSetGetValues(device_set, (const void **) device_array);
/* Iterate over each device, making an entry for it. */
for (i = 0; i < num_devices; i++) {
unsigned short dev_vid;
unsigned short dev_pid;
#define BUF_LEN 256
wchar_t buf[BUF_LEN];
char cbuf[BUF_LEN];
IOHIDDeviceRef dev = device_array[i];
if (!dev) {
continue;
}
dev_vid = get_vendor_id(dev);
dev_pid = get_product_id(dev);
/* Check the VID/PID against the arguments */
if ((vendor_id == 0x0 && product_id == 0x0) ||
(vendor_id == dev_vid && product_id == dev_pid)) {
struct hid_device_info *tmp;
size_t len;
/* VID/PID match. Create the record. */
tmp = malloc(sizeof(struct hid_device_info));
if (cur_dev) {
cur_dev->next = tmp;
}
else {
root = tmp;
}
cur_dev = tmp;
// Get the Usage Page and Usage for this device.
cur_dev->usage_page = get_int_property(dev, CFSTR(kIOHIDPrimaryUsagePageKey));
cur_dev->usage = get_int_property(dev, CFSTR(kIOHIDPrimaryUsageKey));
/* Fill out the record */
cur_dev->next = NULL;
len = make_path(dev, cbuf, sizeof(cbuf));
cur_dev->path = strdup(cbuf);
/* Serial Number */
get_serial_number(dev, buf, BUF_LEN);
cur_dev->serial_number = dup_wcs(buf);
/* Manufacturer and Product strings */
get_manufacturer_string(dev, buf, BUF_LEN);
cur_dev->manufacturer_string = dup_wcs(buf);
get_product_string(dev, buf, BUF_LEN);
cur_dev->product_string = dup_wcs(buf);
/* VID/PID */
cur_dev->vendor_id = dev_vid;
cur_dev->product_id = dev_pid;
/* Release Number */
cur_dev->release_number = get_int_property(dev, CFSTR(kIOHIDVersionNumberKey));
/* Interface Number (Unsupported on Mac)*/
cur_dev->interface_number = -1;
}
}
free(device_array);
CFRelease(device_set);
return root;
}
/* "serialno": The device serial number. */
static EFI_STATUS publish_serialno(void)
{
char *serial = get_serial_number();
return fastboot_publish("serialno", serial ? serial : "N/A");
}
int HID_API_EXPORT_CALL hid_get_serial_number_string(hid_device *dev, wchar_t *string, size_t maxlen)
{
return get_serial_number(dev->device_handle, string, maxlen);
}
/*
* generate_and_store_mac_addr()
*
* This routine is called when, upon program initialization, we discover
* that there is no valid network settings (including MAC address) programmed
* into flash memory at the last flash sector. If it is not safe to use the
* contents of this last sector of flash, the user is prompted to
* enter the serial number at the console. A MAC address is then
* generated using 0xFF followed by the last 2 bytes of the serial number
* appended to Altera's Vendor ID, an assigned MAC address range with the first
* 3 bytes of 00:07:ED. For example, if the Nios Development Board serial
* number is 040800017, the corresponding ethernet number generated will be
* 00:07:ED:FF:8F:11.
*
* It should be noted that this number, while unique, will likely differ from
* the also unique (but now lost forever) MAC address programmed into the
* development board on the production line.
*
* As we are erasing the entire flash sector, we'll re-program it with not
* only the MAC address, but static IP, subnet, gateway, and "Use DHCP"
* sections. These fail-safe static settings are compatible with previous
* Nios Ethernet designs, and allow the "factory-safe" design to behave
* as expected if the last flash sector is erased.
*/
error_t generate_and_store_mac_addr()
{
error_t error = -1;
alt_u32 ser_num = 0;
char flash_content[32];
alt_flash_fd* flash_handle;
printf("Can't read the MAC address from your board (this probably means\n");
printf("that your flash was erased). We will assign you a MAC address and\n");
printf("static network settings\n\n");
ser_num = get_serial_number();
if (ser_num)
{
/* This says the image is safe */
flash_content[0] = 0xfe;
flash_content[1] = 0x5a;
flash_content[2] = 0x0;
flash_content[3] = 0x0;
/* This is the Altera Vendor ID */
flash_content[4] = 0x0;
flash_content[5] = 0x7;
flash_content[6] = 0xed;
/* Reserverd Board identifier for erase boards */
flash_content[7] = 0xFF;
flash_content[8] = (ser_num & 0xff00) >> 8;
flash_content[9] = ser_num & 0xff;
/* Then comes a 16-bit "flags" field */
flash_content[10] = 0xFF;
flash_content[11] = 0xFF;
/* Then comes the static IP address */
flash_content[12] = IPADDR0;
flash_content[13] = IPADDR1;
flash_content[14] = IPADDR2;
flash_content[15] = IPADDR3;
/* Then comes the static nameserver address */
flash_content[16] = 0xFF;
flash_content[17] = 0xFF;
flash_content[18] = 0xFF;
flash_content[19] = 0xFF;
/* Then comes the static subnet mask */
flash_content[20] = MSKADDR0;
flash_content[21] = MSKADDR1;
flash_content[22] = MSKADDR2;
flash_content[23] = MSKADDR3;
/* Then comes the static gateway address */
flash_content[24] = GWADDR0;
flash_content[25] = GWADDR1;
flash_content[26] = GWADDR2;
flash_content[27] = GWADDR3;
/* And finally whether to use DHCP - set all bits to be safe */
flash_content[28] = 0xFF;
flash_content[29] = 0xFF;
flash_content[30] = 0xFF;
flash_content[31] = 0xFF;
#if 0
/* Write the MAC address to flash */
flash_handle = alt_flash_open_dev(EXT_FLASH_NAME);
if (flash_handle)
{
alt_write_flash(flash_handle,
last_flash_sector_offset,
flash_content,
32);
alt_flash_close_dev(flash_handle);
error = 0;
}
#endif
}
return error;
}
