Provided by: avr-libc_2.0.0+Atmel3.7.0-1_all bug

NAME

       avr_sfr - <avr/sfr_defs.h>: Special function registers

SYNOPSIS

   Modules
       Additional notes from <avr/sfr_defs.h>

   Bit manipulation
       #define _BV(bit)   (1 << (bit))
       #define _VECTOR(N)   __vector_ ## N

   IO register bit manipulation
       #define bit_is_set(sfr,  bit)   (_SFR_BYTE(sfr) & _BV(bit))
       #define bit_is_clear(sfr,  bit)   (!(_SFR_BYTE(sfr) & _BV(bit)))
       #define loop_until_bit_is_set(sfr,  bit)   do { } while (bit_is_clear(sfr, bit))
       #define loop_until_bit_is_clear(sfr,  bit)   do { } while (bit_is_set(sfr, bit))

Detailed Description

       When working with microcontrollers, many tasks usually consist of controlling internal
       peripherals, or external peripherals that are connected to the device. The entire IO
       address space is made available as memory-mapped IO, i.e. it can be accessed using all the
       MCU instructions that are applicable to normal data memory. For most AVR devices, the IO
       register space is mapped into the data memory address space with an offset of 0x20 since
       the bottom of this space is reserved for direct access to the MCU registers. (Actual SRAM
       is available only behind the IO register area, starting at some specific address depending
       on the device.)

       For example the user can access memory-mapped IO registers as if they were globally
       defined variables like this:

       PORTA = 0x33;
       unsigned char foo = PINA;

       The compiler will choose the correct instruction sequence to generate based on the address
       of the register being accessed.

       The advantage of using the memory-mapped registers in C programs is that it makes the
       programs more portable to other C compilers for the AVR platform.

       Note that special care must be taken when accessing some of the 16-bit timer IO registers
       where access from both the main program and within an interrupt context can happen. See
       Why do some 16-bit timer registers sometimes get trashed?.

       Porting programs that use the deprecated sbi/cbi macros

       Access to the AVR single bit set and clear instructions are provided via the standard C
       bit manipulation commands. The sbi and cbi macros are no longer directly supported. sbi
       (sfr,bit) can be replaced by sfr |= _BV(bit) .

       i.e.: sbi(PORTB, PB1); is now PORTB |= _BV(PB1);

       This actually is more flexible than having sbi directly, as the optimizer will use a
       hardware sbi if appropriate, or a read/or/write operation if not appropriate. You do not
       need to keep track of which registers sbi/cbi will operate on.

       Likewise, cbi (sfr,bit) is now sfr &= ~(_BV(bit));

Macro Definition Documentation

   #define _BV(bit)   (1 << (bit))
       #include <avr/io.h>

       Converts a bit number into a byte value.

       Note
           The bit shift is performed by the compiler which then inserts the result into the
           code. Thus, there is no run-time overhead when using _BV().

   #define bit_is_clear(sfr, bit)   (!(_SFR_BYTE(sfr) & _BV(bit)))
       #include <avr/io.h>

       Test whether bit bit in IO register sfr is clear. This will return non-zero if the bit is
       clear, and a 0 if the bit is set.

   #define bit_is_set(sfr, bit)   (_SFR_BYTE(sfr) & _BV(bit))
       #include <avr/io.h>

       Test whether bit bit in IO register sfr is set. This will return a 0 if the bit is clear,
       and non-zero if the bit is set.

   #define loop_until_bit_is_clear(sfr, bit)   do { } while (bit_is_set(sfr, bit))
       #include <avr/io.h>

       Wait until bit bit in IO register sfr is clear.

   #define loop_until_bit_is_set(sfr, bit)   do { } while (bit_is_clear(sfr, bit))
       #include <avr/io.h>

       Wait until bit bit in IO register sfr is set.

Author

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