/* Created: September 2012 (c) 2012 by ihsan Kehribar Changes for Micronucleus protocol version V2.x (c) 2014 T. Bo"scke 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. */ /***************************************************************/ /* See the micronucleus_lib.h for the function descriptions/comments */ /***************************************************************/ #include "micronucleus_lib.h" #include "littleWire_util.h" micronucleus* micronucleus_connect(int fast_mode) { micronucleus *nucleus = NULL; struct usb_bus *busses; // intialise usb and find micronucleus device usb_init(); usb_find_busses(); usb_find_devices(); busses = usb_get_busses(); struct usb_bus *bus; for (bus = busses; bus; bus = bus->next) { struct usb_device *dev; for (dev = bus->devices; dev; dev = dev->next) { /* Check if this device is a micronucleus */ if (dev->descriptor.idVendor == MICRONUCLEUS_VENDOR_ID && dev->descriptor.idProduct == MICRONUCLEUS_PRODUCT_ID) { nucleus = malloc(sizeof(micronucleus)); nucleus->version.major = (dev->descriptor.bcdDevice >> 8) & 0xFF; nucleus->version.minor = dev->descriptor.bcdDevice & 0xFF; if (nucleus->version.major > MICRONUCLEUS_MAX_MAJOR_VERSION) { fprintf(stderr, "Warning: device with unknown new version of Micronucleus detected.\n" "This tool doesn't know how to upload to this new device. Updates may be available.\n" "Device reports version as: %d.%d\n", nucleus->version.major, nucleus->version.minor); return NULL; } nucleus->device = usb_open(dev); if (nucleus->version.major>=2) { // Version 2.x // get nucleus info unsigned char buffer[6]; int res = usb_control_msg(nucleus->device, USB_ENDPOINT_IN| USB_TYPE_VENDOR | USB_RECIP_DEVICE, 0, 0, 0, (char *)buffer, 6, MICRONUCLEUS_USB_TIMEOUT); // Device descriptor was found, but talking to it was not succesful. This can happen when the device is being reset. if (res<0) return NULL; assert(res >= 6); nucleus->flash_size = (buffer[0]<<8) + buffer[1]; nucleus->page_size = buffer[2]; nucleus->pages = (nucleus->flash_size / nucleus->page_size); if (nucleus->pages * nucleus->page_size < nucleus->flash_size) nucleus->pages += 1; nucleus->bootloader_start = nucleus->pages*nucleus->page_size; if ((nucleus->version.major>=2)&&(!fast_mode)) { // firmware v2 reports more aggressive write times. Add 2ms if fast mode is not used. nucleus->write_sleep = (buffer[3] & 127) + 2; } else { nucleus->write_sleep = (buffer[3] & 127); } // if bit 7 of write sleep time is set, divide the erase time by four to // accomodate to the 4*page erase of the ATtiny841/441 if (buffer[3]&128) { nucleus->erase_sleep = nucleus->write_sleep * nucleus->pages / 4; } else { nucleus->erase_sleep = nucleus->write_sleep * nucleus->pages; } nucleus->signature1 = buffer[4]; nucleus->signature2 = buffer[5]; } else { // Version 1.x // get nucleus info unsigned char buffer[4]; int res = usb_control_msg(nucleus->device, USB_ENDPOINT_IN| USB_TYPE_VENDOR | USB_RECIP_DEVICE, 0, 0, 0, (char *)buffer, 4, MICRONUCLEUS_USB_TIMEOUT); // Device descriptor was found, but talking to it was not succesful. This can happen when the device is being reset. if (res<0) return NULL; assert(res >= 4); nucleus->flash_size = (buffer[0]<<8) + buffer[1]; nucleus->page_size = buffer[2]; nucleus->pages = (nucleus->flash_size / nucleus->page_size); if (nucleus->pages * nucleus->page_size < nucleus->flash_size) nucleus->pages += 1; nucleus->bootloader_start = nucleus->pages*nucleus->page_size; nucleus->write_sleep = (buffer[3] & 127); nucleus->erase_sleep = nucleus->write_sleep * nucleus->pages; nucleus->signature1 = 0; nucleus->signature2 = 0; } } } } return nucleus; } int micronucleus_eraseFlash(micronucleus* deviceHandle, micronucleus_callback progress) { int res; res = usb_control_msg(deviceHandle->device, USB_ENDPOINT_OUT| USB_TYPE_VENDOR | USB_RECIP_DEVICE, 2, 0, 0, NULL, 0, MICRONUCLEUS_USB_TIMEOUT); // give microcontroller enough time to erase all writable pages and come back online float i = 0; while (i < 1.0) { // update progress callback if one was supplied if (progress) progress(i); delay(((float) deviceHandle->erase_sleep) / 100.0f); i += 0.01; } /* Under Linux, the erase process is often aborted with errors such as: usbfs: USBDEVFS_CONTROL failed cmd micronucleus rqt 192 rq 2 len 0 ret -84 This seems to be because the erase is taking long enough that the device is disconnecting and reconnecting. Under Windows, micronucleus can see this and automatically reconnects prior to uploading the program. To get the the same functionality, we must flag this state (the "-84" error result) by converting the return to -2 for the upper layer. On Mac OS a common error is -34 = epipe, but adding it to this list causes: Assertion failed: (res >= 4), function micronucleus_connect, file library/micronucleus_lib.c, line 63. */ if (res == -5 || res == -34 || res == -84) { if (res == -34) { usb_close(deviceHandle->device); deviceHandle->device = NULL; } return 1; // recoverable errors } else { return res; } } int micronucleus_writeFlash(micronucleus* deviceHandle, unsigned int program_size, unsigned char* program, micronucleus_callback prog) { unsigned char page_length = deviceHandle->page_size; unsigned char page_buffer[page_length]; unsigned int address; // overall flash memory address unsigned int page_address; // address within this page when copying buffer unsigned int res; unsigned int pagecontainsdata; unsigned int userReset; for (address = 0; address < deviceHandle->flash_size; address += deviceHandle->page_size) { // work around a bug in older bootloader versions if (deviceHandle->version.major == 1 && deviceHandle->version.minor <= 2 && address / deviceHandle->page_size == deviceHandle->pages - 1) { page_length = deviceHandle->flash_size % deviceHandle->page_size; } pagecontainsdata=0; // copy in bytes from user program for (page_address = 0; page_address < page_length; page_address += 1) { if (address + page_address > program_size) { page_buffer[page_address] = 0xFF; // pad out remainder with unprogrammed bytes } else { pagecontainsdata=1; // page contains data and needs to be written page_buffer[page_address] = program[address + page_address]; // load from user program } } // Reset vector patching is done in the host tool in micronucleus >=2 if (deviceHandle->version.major >=2) { if ( address == 0 ) { // save user reset vector (bootloader will patch with its vector) unsigned int word0,word1; word0 = page_buffer [1] * 0x100 + page_buffer [0]; word1 = page_buffer [3] * 0x100 + page_buffer [2]; if (word0==0x940c) { // long jump userReset = word1; } else if ((word0&0xf000)==0xc000) { // rjmp userReset = (word0 & 0x0fff) - 0 + 1; } else { fprintf(stderr, "The reset vector of the user program does not contain a branch instruction,\n" "therefore the bootloader can not be inserted. Please rearrage your code.\n" ); return -1; } // Patch in jmp to bootloader. if (deviceHandle->bootloader_start > 0x2000) { // jmp unsigned data = 0x940c; page_buffer [ 0 ] = data >> 0 & 0xff; page_buffer [ 1 ] = data >> 8 & 0xff; page_buffer [ 2 ] = deviceHandle->bootloader_start >> 0 & 0xff; page_buffer [ 3 ] = deviceHandle->bootloader_start >> 8 & 0xff; } else { // rjmp unsigned data = 0xc000 | ((deviceHandle->bootloader_start/2 - 1) & 0x0fff); page_buffer [ 0 ] = data >> 0 & 0xff; page_buffer [ 1 ] = data >> 8 & 0xff; } } if ( address >= deviceHandle->bootloader_start - deviceHandle->page_size ) { // move user reset vector to end of last page // The reset vector is always the last vector in the tinyvectortable unsigned int user_reset_addr = (deviceHandle->pages*deviceHandle->page_size) - 4; if (user_reset_addr > 0x2000) { // jmp unsigned data = 0x940c; page_buffer [user_reset_addr - address + 0] = data >> 0 & 0xff; page_buffer [user_reset_addr - address + 1] = data >> 8 & 0xff; page_buffer [user_reset_addr - address + 2] = userReset >> 0 & 0xff; page_buffer [user_reset_addr - address + 3] = userReset >> 8 & 0xff; } else { // rjmp unsigned data = 0xc000 | ((userReset - user_reset_addr/2 - 1) & 0x0fff); page_buffer [user_reset_addr - address + 0] = data >> 0 & 0xff; page_buffer [user_reset_addr - address + 1] = data >> 8 & 0xff; } } } // always write last page so bootloader can insert the tiny vector table if ( address >= deviceHandle->bootloader_start - deviceHandle->page_size ) pagecontainsdata = 1; // ask microcontroller to write this page's data if (pagecontainsdata) { if (deviceHandle->version.major == 1) { // Firmware rev.1 transfers a page as a single block // ask microcontroller to write this page's data res = usb_control_msg(deviceHandle->device, USB_ENDPOINT_OUT| USB_TYPE_VENDOR | USB_RECIP_DEVICE, 1, page_length, address, page_buffer, page_length, MICRONUCLEUS_USB_TIMEOUT); } else if (deviceHandle->version.major >= 2) { // Firmware rev.2 uses individual set up packets to transfer data res = usb_control_msg(deviceHandle->device, USB_ENDPOINT_OUT| USB_TYPE_VENDOR | USB_RECIP_DEVICE, 1, page_length, address, NULL, 0, MICRONUCLEUS_USB_TIMEOUT); if (res) return -1; int i; for (i=0; i< page_length; i+=4) { int w1,w2; w1=(page_buffer[i+1]<<8)+(page_buffer[i+0]<<0); w2=(page_buffer[i+3]<<8)+(page_buffer[i+2]<<0); res = usb_control_msg(deviceHandle->device, USB_ENDPOINT_OUT| USB_TYPE_VENDOR | USB_RECIP_DEVICE, 3, w1, w2, NULL, 0, MICRONUCLEUS_USB_TIMEOUT); if (res) return -1; } } /* res = usb_control_msg(deviceHandle->device, USB_ENDPOINT_OUT| USB_TYPE_VENDOR | USB_RECIP_DEVICE, 1, page_length, address, (char*)page_buffer, page_length, MICRONUCLEUS_USB_TIMEOUT); if (res != page_length) return -1; */ // give microcontroller enough time to write this page and come back online delay(deviceHandle->write_sleep); } // call progress update callback if that's a thing if (prog) prog(((float) address) / ((float) deviceHandle->flash_size)); } // call progress update callback with completion status if (prog) prog(1.0); return 0; } int micronucleus_startApp(micronucleus* deviceHandle) { int res; res = usb_control_msg(deviceHandle->device, USB_ENDPOINT_OUT| USB_TYPE_VENDOR | USB_RECIP_DEVICE, 4, 0, 0, NULL, 0, MICRONUCLEUS_USB_TIMEOUT); if(res!=0) return -1; else return 0; }