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Usually, all but the first could probably be done easily using the inline assembler facility of the compiler.
Although avr-libc is primarily targeted to support programming AVR microcontrollers using the C (and C++) language, there's limited support for direct assembler usage as well. The benefits of it are:
avr-gcc
) that in turn will call the assembler and linker as required.This approach has the following advantages:
avr-gcc
, regardless of the actual source language used.crt
XXX.o
) and linker script.
Note that the invokation of the C preprocessor will be automatic when the filename provided for the assembler file ends in .S (the capital letter "s"). This would even apply to operating systems that use case-insensitive filesystems since the actual decision is made based on the case of the filename suffix given on the command-line, not based on the actual filename from the file system.
Alternatively, the language can explicitly be specified using the -x assembler-with-cpp
option.
#include <avr/io.h> ; Note [1] work = 16 ; Note [2] tmp = 17 inttmp = 19 intsav = 0 SQUARE = PD6 ; Note [3] ; Note [4]: tmconst= 10700000 / 200000 ; 100 kHz => 200000 edges/s fuzz= 8 ; # clocks in ISR until TCNT0 is set .section .text .global main ; Note [5] main: rcall ioinit 1: rjmp 1b ; Note [6] .global TIMER0_OVF_vect ; Note [7] TIMER0_OVF_vect: ldi inttmp, 256 - tmconst + fuzz out _SFR_IO_ADDR(TCNT0), inttmp ; Note [8] in intsav, _SFR_IO_ADDR(SREG) ; Note [9] sbic _SFR_IO_ADDR(PORTD), SQUARE rjmp 1f sbi _SFR_IO_ADDR(PORTD), SQUARE rjmp 2f 1: cbi _SFR_IO_ADDR(PORTD), SQUARE 2: out _SFR_IO_ADDR(SREG), intsav reti ioinit: sbi _SFR_IO_ADDR(DDRD), SQUARE ldi work, _BV(TOIE0) out _SFR_IO_ADDR(TIMSK), work ldi work, _BV(CS00) ; tmr0: CK/1 out _SFR_IO_ADDR(TCCR0), work ldi work, 256 - tmconst out _SFR_IO_ADDR(TCNT0), work sei ret .global __vector_default ; Note [10] __vector_default: reti .end
#define work 16
int
by default in order to calculate constant integer expressions. TCCNT0
register, we therefore have to account for the number of clock cycles required for interrupt acknowledge and for the instructions to reload TCCNT0
(4 clock cycles for interrupt acknowledge, 2 cycles for the jump from the interrupt vector, 2 cycles for the 2 instructions that reload TCCNT0
). This is what the constant fuzz
is for.
.global. main
is the application entry point that will be jumped to from the ininitalization routine in crts1200.o
.
sleep
instruction (using idle mode) could be used as well, but probably would not conserve much energy anyway since the interrupt service is executed quite frequently.
.global in order to be acceptable for this purpose. This will only work if <avr/io.h>
has been included. Note that the assembler or linker have no chance to check the correct spelling of an interrupt function, so it should be double-checked. (When analyzing the resulting object file using avr-objdump
or avr-nm
, a name like __vector_N
should appear, with N being a small integer number.)
_SFR_IO_ADDR
. (The AT90S1200 does not have RAM thus the memory-mapped approach to access the IO registers is not available. It would be slower than using in
/ out
instructions anyway.) TCCNT0
is time-critical, it is even performed before saving SREG
. Obviously, this requires that the instructions involved would not change any of the flag bits in SREG
.SREG
. (Note that this serves as an example here only since actually, all the following instructions would not modify SREG
either, but that's not commonly the case.)
__vector_default
. This must be
.global, and obviously, should end in a reti
instruction. (By default, a jump to location 0 would be implied instead.)
As gas comes from a Unix origin, its pseudo-op and overall assembler syntax is slightly different than the one being used by other assemblers. Numeric constants follow the C notation (prefix 0x
for hexadecimal constants), expressions use a C-like syntax.
Some common pseudo-ops include:
.byte allocates single byte constants
.ascii allocates a non-terminated string of characters
.asciz allocates a \0-terminated string of characters (C string)
.data switches to the .data section (initialized RAM variables)
.text switches to the .text section (code and ROM constants)
.set declares a symbol as a constant expression (identical to
.equ)
.global (or
.globl) declares a public symbol that is visible to the linker (e. g. function entry point, global variable)
.extern declares a symbol to be externally defined; this is effectively a comment only, as gas treats all undefined symbols it encounters as globally undefined anyway
Note that .org is available in gas as well, but is a fairly pointless pseudo-op in an assembler environment that uses relocatable object files, as it is the linker that determines the final position of some object in ROM or RAM.
Along with the architecture-independent standard operators, there are some AVR-specific operators available which are unfortunately not yet described in the official documentation. The most notable operators are:
lo8
Takes the least significant 8 bits of a 16-bit integer
hi8
Takes the most significant 8 bits of a 16-bit integer
pm
Takes a program-memory (ROM) address, and converts it into a RAM address. This implies a division by 2 as the AVR handles ROM addresses as 16-bit words (e.g. in an IJMP
or ICALL
instruction), and can also handle relocatable symbols on the right-hand side.Example:
ldi r24, lo8(pm(somefunc)) ldi r25, hi8(pm(somefunc)) call something
This passes the address of function somefunc
as the first parameter to function something
.