/* Copyright (c) 2007, Atmel Corporation All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the copyright holders nor the names of contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /* $Id$ */ /* avr/fuse.h - Fuse API */ #ifndef _AVR_FUSE_H_ #define _AVR_FUSE_H_ 1 /* This file must be explicitly included by . */ #if !defined(_AVR_IO_H_) #error "You must #include and not by itself." #endif /** \file */ /** \defgroup avr_fuse : Fuse Support \par Introduction The Fuse API allows a user to specify the fuse settings for the specific AVR device they are compiling for. These fuse settings will be placed in a special section in the ELF output file, after linking. Programming tools can take advantage of the fuse information embedded in the ELF file, by extracting this information and determining if the fuses need to be programmed before programming the Flash and EEPROM memories. This also allows a single ELF file to contain all the information needed to program an AVR. To use the Fuse API, include the header file, which in turn automatically includes the individual I/O header file and the file. These other two files provides everything necessary to set the AVR fuses. \par Fuse API Each I/O header file must define the FUSE_MEMORY_SIZE macro which is defined to the number of fuse bytes that exist in the AVR device. A new type, __fuse_t, is defined as a structure. The number of fields in this structure are determined by the number of fuse bytes in the FUSE_MEMORY_SIZE macro. If FUSE_MEMORY_SIZE == 1, there is only a single field: byte, of type unsigned char. If FUSE_MEMORY_SIZE == 2, there are two fields: low, and high, of type unsigned char. If FUSE_MEMORY_SIZE == 3, there are three fields: low, high, and extended, of type unsigned char. If FUSE_MEMORY_SIZE > 3, there is a single field: byte, which is an array of unsigned char with the size of the array being FUSE_MEMORY_SIZE. A convenience macro, FUSEMEM, is defined as a GCC attribute for a custom-named section of ".fuse". A convenience macro, FUSES, is defined that declares a variable, __fuse, of type __fuse_t with the attribute defined by FUSEMEM. This variable allows the end user to easily set the fuse data. \note If a device-specific I/O header file has previously defined FUSEMEM, then FUSEMEM is not redefined. If a device-specific I/O header file has previously defined FUSES, then FUSES is not redefined. Each AVR device I/O header file has a set of defined macros which specify the actual fuse bits available on that device. The AVR fuses have inverted values, logical 1 for an unprogrammed (disabled) bit and logical 0 for a programmed (enabled) bit. The defined macros for each individual fuse bit represent this in their definition by a bit-wise inversion of a mask. For example, the FUSE_EESAVE fuse in the ATmega128 is defined as: \code #define FUSE_EESAVE ~_BV(3) \endcode \note The _BV macro creates a bit mask from a bit number. It is then inverted to represent logical values for a fuse memory byte. To combine the fuse bits macros together to represent a whole fuse byte, use the bitwise AND operator, like so: \code (FUSE_BOOTSZ0 & FUSE_BOOTSZ1 & FUSE_EESAVE & FUSE_SPIEN & FUSE_JTAGEN) \endcode Each device I/O header file also defines macros that provide default values for each fuse byte that is available. LFUSE_DEFAULT is defined for a Low Fuse byte. HFUSE_DEFAULT is defined for a High Fuse byte. EFUSE_DEFAULT is defined for an Extended Fuse byte. If FUSE_MEMORY_SIZE > 3, then the I/O header file defines macros that provide default values for each fuse byte like so: FUSE0_DEFAULT FUSE1_DEFAULT FUSE2_DEFAULT FUSE3_DEFAULT FUSE4_DEFAULT .... \par API Usage Example Putting all of this together is easy. Using C99's designated initializers: \code #include FUSES = { .low = LFUSE_DEFAULT, .high = (FUSE_BOOTSZ0 & FUSE_BOOTSZ1 & FUSE_EESAVE & FUSE_SPIEN & FUSE_JTAGEN), .extended = EFUSE_DEFAULT, }; int main(void) { return 0; } \endcode Or, using the variable directly instead of the FUSES macro, \code #include __fuse_t __fuse __attribute__((section (".fuse"))) = { .low = LFUSE_DEFAULT, .high = (FUSE_BOOTSZ0 & FUSE_BOOTSZ1 & FUSE_EESAVE & FUSE_SPIEN & FUSE_JTAGEN), .extended = EFUSE_DEFAULT, }; int main(void) { return 0; } \endcode If you are compiling in C++, you cannot use the designated intializers so you must do: \code #include FUSES = { LFUSE_DEFAULT, // .low (FUSE_BOOTSZ0 & FUSE_BOOTSZ1 & FUSE_EESAVE & FUSE_SPIEN & FUSE_JTAGEN), // .high EFUSE_DEFAULT, // .extended }; int main(void) { return 0; } \endcode However there are a number of caveats that you need to be aware of to use this API properly. Be sure to include to get all of the definitions for the API. The FUSES macro defines a global variable to store the fuse data. This variable is assigned to its own linker section. Assign the desired fuse values immediately in the variable initialization. The .fuse section in the ELF file will get its values from the initial variable assignment ONLY. This means that you can NOT assign values to this variable in functions and the new values will not be put into the ELF .fuse section. The global variable is declared in the FUSES macro has two leading underscores, which means that it is reserved for the "implementation", meaning the library, so it will not conflict with a user-named variable. You must initialize ALL fields in the __fuse_t structure. This is because the fuse bits in all bytes default to a logical 1, meaning unprogrammed. Normal uninitialized data defaults to all locgial zeros. So it is vital that all fuse bytes are initialized, even with default data. If they are not, then the fuse bits may not programmed to the desired settings. Be sure to have the -mmcu=device flag in your compile command line and your linker command line to have the correct device selected and to have the correct I/O header file included when you include . You can print out the contents of the .fuse section in the ELF file by using this command line: \code avr-objdump -s -j .fuse \endcode The section contents shows the address on the left, then the data going from lower address to a higher address, left to right. */ #ifndef __ASSEMBLER__ #ifndef FUSEMEM #define FUSEMEM __attribute__((section (".fuse"))) #endif #if FUSE_MEMORY_SIZE > 3 typedef struct { unsigned char byte[FUSE_MEMORY_SIZE]; } __fuse_t; #elif FUSE_MEMORY_SIZE == 3 typedef struct { unsigned char low; unsigned char high; unsigned char extended; } __fuse_t; #elif FUSE_MEMORY_SIZE == 2 typedef struct { unsigned char low; unsigned char high; } __fuse_t; #elif FUSE_MEMORY_SIZE == 1 typedef struct { unsigned char byte; } __fuse_t; #endif #ifndef FUSES #define FUSES __fuse_t __fuse FUSEMEM #endif #endif /* !__ASSEMBLER__ */ #endif /* _AVR_FUSE_H_ */