Blame view

atmega16u2/custom/lufa-LUFA-170418/Bootloaders/MassStorage/BootloaderMassStorage.txt 11.4 KB
8a7dc1f5   adorian   Seance 4
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
  /** \file
   *
   *  This file contains special DoxyGen information for the generation of the main page and other special
   *  documentation pages. It is not a project source file.
   */
  
  /** \mainpage Mass Storage Class USB AVR Bootloader
   *
   *  \section Sec_Compat Demo Compatibility:
   *
   *  The following list indicates what microcontrollers are compatible with this demo.
   *
   *  \li Series 7 USB AVRs (AT90USBxxx7)
   *  \li Series 6 USB AVRs (AT90USBxxx6)
   *  \li Series 4 USB AVRs (ATMEGAxxU4) - <i>See \ref SSec_Aux_Space</i>
   *  \li ATMEGA32U2 - <i>See \ref SSec_Aux_Space</i>
   *
   *  \section Sec_Info USB Information:
   *
   *  The following table gives a rundown of the USB utilization of this demo.
   *
   *  <table>
   *   <tr>
   *    <td><b>USB Mode:</b></td>
   *    <td>Device</td>
   *   </tr>
   *   <tr>
   *    <td><b>USB Class:</b></td>
   *    <td>Mass Storage Device</td>
   *   </tr>
   *   <tr>
   *    <td><b>USB Subclass:</b></td>
   *    <td>Bulk-Only Transport</td>
   *   </tr>
   *   <tr>
   *    <td><b>Relevant Standards:</b></td>
   *    <td>USBIF Mass Storage Standard \n
   *        USB Bulk-Only Transport Standard \n
   *        SCSI Primary Commands Specification \n
   *        SCSI Block Commands Specification</td>
   *   </tr>
   *   <tr>
   *    <td><b>Supported USB Speeds:</b></td>
   *    <td>Full Speed Mode</td>
   *   </tr>
   *  </table>
   *
   *  \section Sec_Description Project Description:
   *
   *  This bootloader enumerates to the host as a Mass Storage device, capable of reading and writing a new binary
   *  firmware image file, to load firmware onto the AVR.
   *
   *  Out of the box this bootloader builds for the AT90USB1287 with an 8KB bootloader section size, and will fit
   *  into 6KB of bootloader space. If you wish to alter this size and/or change the AVR model, you will need to
   *  edit the MCU, FLASH_SIZE_KB and BOOT_SECTION_SIZE_KB values in the accompanying makefile.
   *
   *  When the bootloader is running, the board's LED(s) will flash at regular intervals to distinguish the
   *  bootloader from the normal user application.
   *
   *  \warning <b>THIS BOOTLOADER IS NOT SECURE.</b> Malicious entities can recover written data, even if the device
   *           lockbits are set.
   *
   *  \section Sec_Running Running the Bootloader
   *
   *  On the USB AVR8 devices, setting the \c HWBE device fuse will cause the bootloader to run if the \c HWB pin of
   *  the AVR is grounded when the device is reset.
   *
   *  The are two behaviours of this bootloader, depending on the device's fuses:
   *
   *  <b>If the device's BOOTRST fuse is set</b>, the bootloader will run any time the system is reset from
   *  the external reset pin, unless no valid user application has been loaded. To initiate the bootloader, the
   *  device's external reset pin should be grounded momentarily.
   *
   *  <b>If the device's BOOTRST fuse is not set</b>, the bootloader will run only if initiated via a software
   *  jump, or if the \c HWB pin was low during the last device reset (if the \c HWBE fuse is set).
   *
   *  For board specific exceptions to the above, see below.
   *
   *  \subsection SSec_XPLAIN Atmel Xplain Board
   *  Ground the USB AVR JTAG's \c TCK pin to ground when powering on the board to start the bootloader. This assumes the
   *  \c HWBE fuse is cleared and the \c BOOTRST fuse is set as the HWBE pin is not user accessible on this board.
   *
   *  \subsection SSec_Leonardo Arduino Leonardo Board
   *  Ground \c IO13 when powering the board to start the bootloader. This assumes the \c HWBE fuse is cleared and the
   *  \c BOOTRST fuse is set as the HWBE pin is not user accessible on this board.
   *
   *  \section Sec_Installation Driver Installation
   *
   *  This bootloader uses the Mass Storage drivers inbuilt into all modern operating systems, thus no additional
   *  drivers need to be supplied for correct operation.
   *
   *  \section Sec_HostApp Host Controller Application
   *
   *  This bootloader is compatible with all operating systems that support the FAT12 file system format. To reprogram the
   *  device, overwrite a file stored on the virtual FAT filesystem with a new binary (BIN format) image. Remember to safely
   *  remove your device from the host using the host OS's ejection APIs, to ensure all data is correctly flushed to the
   *  bootloader's virtual filesystem and not cached in the OS's file system driver.
   *
   *  The current device firmware can be read from the device by reading a file from the virtual FAT filesystem. Two files will
   *  be present:
   *    - <b>FLASH.BIN</b>, representing the AVR's internal flash memory
   *    - <b>EEPROM.BIN</b>, representing the AVR's internal EEPROM memory
   *
   *  To convert an existing Intel HEX (.HEX) program file to a binary (.BIN) file suitable for this bootloader, run:
   *    \code
   *		avr-objcopy -O binary -R .eeprom -R .fuse -R .lock -R .signature input.hex output.bin
   *    \endcode
   *  From a terminal, replacing <tt>input.hex</tt> and <tt>output.bin</tt> with the respective input and output filenames.
   *  AVR EEPROM data files in Intel HEX format (.EEP) uses a similar technique:
   *    \code
   *		avr-objcopy -O binary input.eep output.bin
   *    \endcode
   *
   *  \warning This bootloader is currently <b>incompatible with the Apple MacOS X OS Finder GUI</b>, due to the
   *           large amount of meta files this OS attempts to write to the disk along with the new binaries. On
   *           this platform, firmwares must be copied to the disk via the Terminal application only to prevent
   *           firmware corruption.
   *
   *  \section Sec_API User Application API
   *
   *  Several user application functions for FLASH and other special memory area manipulations are exposed by the bootloader,
   *  allowing the user application to call into the bootloader at runtime to read and write FLASH data.
   *
   *  By default, the bootloader API jump table is located 32 bytes from the end of the device's FLASH memory, and follows the
   *  following layout:
   *
   *  \code
   *  #define BOOTLOADER_API_TABLE_SIZE          32
   *  #define BOOTLOADER_API_TABLE_START         ((FLASHEND + 1UL) - BOOTLOADER_API_TABLE_SIZE)
   *  #define BOOTLOADER_API_CALL(Index)         (void*)((BOOTLOADER_API_TABLE_START + (Index * 2)) / 2)
   *
   *  void    (*BootloaderAPI_ErasePage)(uint32_t Address)               = BOOTLOADER_API_CALL(0);
   *  void    (*BootloaderAPI_WritePage)(uint32_t Address)               = BOOTLOADER_API_CALL(1);
   *  void    (*BootloaderAPI_FillWord)(uint32_t Address, uint16_t Word) = BOOTLOADER_API_CALL(2);
   *  uint8_t (*BootloaderAPI_ReadSignature)(uint16_t Address)           = BOOTLOADER_API_CALL(3);
   *  uint8_t (*BootloaderAPI_ReadFuse)(uint16_t Address)                = BOOTLOADER_API_CALL(4);
   *  uint8_t (*BootloaderAPI_ReadLock)(void)                            = BOOTLOADER_API_CALL(5);
   *  void    (*BootloaderAPI_WriteLock)(uint8_t LockBits)               = BOOTLOADER_API_CALL(6);
   *
   *  #define BOOTLOADER_MAGIC_SIGNATURE_START   (BOOTLOADER_API_TABLE_START + (BOOTLOADER_API_TABLE_SIZE - 2))
   *  #define BOOTLOADER_MAGIC_SIGNATURE         0xDCFB
   *
   *  #define BOOTLOADER_CLASS_SIGNATURE_START   (BOOTLOADER_API_TABLE_START + (BOOTLOADER_API_TABLE_SIZE - 4))
   *  #define BOOTLOADER_MASS_STORAGE_SIGNATURE  0xDF30
   *
   *  #define BOOTLOADER_ADDRESS_START           (BOOTLOADER_API_TABLE_START + (BOOTLOADER_API_TABLE_SIZE - 8))
   *  #define BOOTLOADER_ADDRESS_LENGTH          4
   *  \endcode
   *
   *  From the application the API support of the bootloader can be detected by reading the FLASH memory bytes located at address
   *  \c BOOTLOADER_MAGIC_SIGNATURE_START and comparing them to the value \c BOOTLOADER_MAGIC_SIGNATURE. The class of bootloader
   *  can be determined by reading the FLASH memory bytes located at address \c BOOTLOADER_CLASS_SIGNATURE_START and comparing them
   *  to the value \c BOOTLOADER_MASS_STORAGE_SIGNATURE. The start address of the bootloader can be retrieved by reading the bytes
   *  of FLASH memory starting from address \c BOOTLOADER_ADDRESS_START.
   *
   *  \subsection SSec_Aux_Space Auxiliary Bootloader Section
   *  To make the bootloader function on smaller devices (those with a physical bootloader section of smaller than 6KB) a second
   *  section of memory (called the <i>Auxiliary Bootloader Section</i>) is added before the start of the real bootloader section,
   *  and is filled with a portion of the bootloader code. This allows smaller devices to run the bootloader, at the cost of an
   *  additional portion of the device's FLASH (the bootloader section size in KB subtracted from the 6KB total size). A small
   *  trampoline is inserted at the start of the auxiliary section so that the bootloader will run normally in the case of a blank
   *  application section.
   *
   *  On devices supporting a 8KB bootloader section size, the AUX section is not created in the final binary.
   *
   *  \subsection SSec_API_MemLayout Device Memory Map
   *  The following illustration indicates the final memory map of the device when loaded with the bootloader.
   *
   *  \verbatim
   *  +----------------------------+ 0x0000
   *  |                            |
   *  |                            |
   *  |                            |
   *  |                            |
   *  |                            |
   *  |                            |
   *  |                            |
   *  |                            |
   *  |      User Application      |
   *  |                            |
   *  |                            |
   *  |                            |
   *  |                            |
   *  |                            |
   *  |                            |
   *  |                            |
   *  |                            |
   *  +----------------------------+ FLASHEND - BOOT_SECTION_SIZE - BOOT_AUX_SECTION_SIZE
   *  | Booloader Start Trampoline |
   *  | (Not User App. Accessible) |
   *  +----------------------------+ FLASHEND - BOOT_SECTION_SIZE - BOOT_AUX_SECTION_SIZE + 4
   *  |                            |
   *  |     Auxiliary Bootloader   |
   *  |  Space for Smaller Devices |
   *  | (Not User App. Accessible) |
   *  |                            |
   *  +----------------------------+ FLASHEND - BOOT_SECTION_SIZE
   *  |                            |
   *  |   Bootloader Application   |
   *  | (Not User App. Accessible) |
   *  |                            |
   *  +----------------------------+ FLASHEND - 96
   *  |   API Table Trampolines    |
   *  | (Not User App. Accessible) |
   *  +----------------------------+ FLASHEND - 32
   *  |    Bootloader API Table    |
   *  |   (User App. Accessible)   |
   *  +----------------------------+ FLASHEND - 8
   *  |   Bootloader ID Constants  |
   *  |   (User App. Accessible)   |
   *  +----------------------------+ FLASHEND
   *  \endverbatim
   *
   *  \section Sec_KnownIssues Known Issues:
   *
   *  \par In some cases, the application is not fully loaded into the device.
   *  Write-caching on some operating systems may interfere with the normal
   *  operation of the bootloader. Write caching should be disabled when using the
   *  Mass Storage bootloader, or the file system synced via an appropriate command
   *  (such as the OS's normal disk ejection command) before disconnecting the device.
   *
   *  \section Sec_Options Project Options
   *
   *  The following defines can be found in this demo, which can control the demo behaviour when defined, or changed in value.
   *
   *  <table>
   *   <tr>
   *    <th><b>Define Name:</b></th>
   *    <th><b>Location:</b></th>
   *    <th><b>Description:</b></th>
   *   </tr>
   *   <tr>
   *    <td>NO_APP_START_ON_EJECT</td>
   *    <td>AppConfig.h</td>
   *    <td>Define to disable automatic start of the loaded application when the virtual
   *        Mass Storage disk is ejected on the host.</td>
   *   </tr>
   *  </table>
   */