/* cpu_asm.c ===> cpu_asm.S or cpu_asm.s
*
* This file contains the basic algorithms for all assembly code used
* in an specific CPU port of RTEMS. These algorithms must be implemented
* in assembly language
*
* NOTE: This is supposed to be a .S or .s file NOT a C file.
*
* COPYRIGHT (c) 1989-2008.
* On-Line Applications Research Corporation (OAR).
*
* The license and distribution terms for this file may be
* found in the file LICENSE in this distribution or at
* http://www.rtems.com/license/LICENSE.
*
* $Id$
*/
/*
* This is supposed to be an assembly file. This means that system.h
* and cpu.h should not be included in a "real" cpu_asm file. An
* implementation in assembly should include "cpu_asm.h>
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include <avr/io.h>
#include <avr/sfr_defs.h>
#include <rtems/asm.h>
#define jmpb_hi r25
#define jmpb_lo r24
#define val_hi r23
#define val_lo r22
#define ret_lo r24
#define ret_hi r25
PUBLIC( setjmp )
SYM( setjmp ):
X_movw XL, jmpb_lo
/*;save call-saved registers and frame pointer*/
.irp .L_regno, 2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,28,29
st X+, r\.L_regno
.endr
/*;get return address*/
pop ZH
pop ZL
/*save stack pointer (after popping)*/
in ret_lo, AVR_STACK_POINTER_LO_ADDR
st X+, ret_lo
#ifdef _HAVE_AVR_STACK_POINTER_HI
in ret_lo, AVR_STACK_POINTER_HI_ADDR
st X+, ret_lo
#else
in ret_lo, __zero_reg__
st X+, ret_lo
#endif
/*save status reg (I flag)*/
in ret_lo, AVR_STATUS_ADDR
st X+, ret_lo
/*save return addr*/
st X+, ZL
st X+, ZH
/*return zero*/
clr ret_hi
clr ret_lo
ijmp
.size _U(setjmp),.-_U(setjmp)
.global _U(longjmp)
.type _U(longjmp), @function
_U(longjmp):
X_movw XL, jmpb_lo
/*return value*/
X_movw ret_lo, val_lo
/*if zero, change to 1*/
cpi ret_lo, 1
cpc ret_hi, __zero_reg__
adc ret_lo, __zero_reg__
/*restore call-saved registers and frame pointer*/
.irp .L_regno, 2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,28,29
ld r\.L_regno, X+
.endr
/*; restore stack pointer (SP value before the setjmp() call) and SREG*/
ld ZL, X+
ld ZH, X+
ld __tmp_reg__, X+
#if defined (__AVR_XMEGA__) && __AVR_XMEGA__
/* A write to SPL will automatically disable interrupts for up to 4
instructions or until the next I/O memory write. */
out AVR_STATUS_ADDR, __tmp_reg__
out AVR_STACK_POINTER_LO_ADDR, ZL
out AVR_STACK_POINTER_HI_ADDR, ZH
#else
# ifdef _HAVE_AVR_STACK_POINTER_HI
/* interrupts disabled for shortest possible time (3 cycles) */
cli
out AVR_STACK_POINTER_HI_ADDR, ZH
# endif
/* Restore status register (including the interrupt enable flag).
Interrupts are re-enabled only after the next instruction. */
out AVR_STATUS_ADDR, __tmp_reg__
out AVR_STACK_POINTER_LO_ADDR, ZL
#endif
; get return address and jump
ld ZL, X+
ld ZH, X+
#if defined(__AVR_3_BYTE_PC__) && __AVR_3_BYTE_PC__
ld __tmp_reg__, X+
.L_jmp3:
push ZL
push ZH
push __tmp_reg__
ret
#else
ijmp
#endif
.size _U(longjmp), . - _U(longjmp)
/*
* _CPU_Context_save_fp_context
*
* This routine is responsible for saving the FP context
* at *fp_context_ptr. If the point to load the FP context
* from is changed then the pointer is modified by this routine.
*
* Sometimes a macro implementation of this is in cpu.h which dereferences
* the ** and a similarly named routine in this file is passed something
* like a (Context_Control_fp *). The general rule on making this decision
* is to avoid writing assembly language.
*
* NO_CPU Specific Information:
*
* XXX document implementation including references if appropriate
void _CPU_Context_save_fp(
Context_Control_fp **fp_context_ptr
)
{
}
*/
PUBLIC(_CPU_Context_save_fp)
SYM(_CPU_Context_save_fp):
ret
/*
* _CPU_Context_restore_fp_context
*
* This routine is responsible for restoring the FP context
* at *fp_context_ptr. If the point to load the FP context
* from is changed then the pointer is modified by this routine.
*
* Sometimes a macro implementation of this is in cpu.h which dereferences
* the ** and a similarly named routine in this file is passed something
* like a (Context_Control_fp *). The general rule on making this decision
* is to avoid writing assembly language.
*
* NO_CPU Specific Information:
*
* XXX document implementation including references if appropriate
void _CPU_Context_restore_fp(
Context_Control_fp **fp_context_ptr
)
{
}
*/
PUBLIC(_CPU_Context_restore_fp)
SYM(_CPU_Context_restore_fp):
ret
/* _CPU_Context_switch
*
* This routine performs a normal non-FP context switch.
*
* NO_CPU Specific Information:
*
* XXX document implementation including references if appropriate
void _CPU_Context_switch(
Context_Control *run,
Context_Control *heir
);
*/
PUBLIC(_CPU_Context_switch)
SYM(_CPU_Context_switch):
mov r26, r24 /*r26,r27 is X*/
mov r27, r25
mov r24, r22
mov r25, r23
/*save registers*/
#if 1
/*if this section is removed there is a problem.*/
/*debug section start*/
pop r22
pop r23
push r22
push r23
/*debug section end*/
#endif
push r2
push r3
push r4
push r5
push r6
push r7
push r8
push r9
push r10
push r11
push r12
push r13
push r14
push r15
push r16
push r17
push r28
push r29
/*load sreg*/
lds r23,0x5f /*load sreg*/
/*disable interrupts*/
cli
/*load stack pointer*/
lds r22,0x5d /*spl*/
lds r21,0x5e /*sph*/
/*save sreg and sp to context struct*/
/*save low then high byte --- verify this delete when verified*/
st X+, r22
st X+, r21
st X, r23
PUBLIC(_CPU_Context_restore)
SYM(_CPU_Context_restore):
mov r26,r24 /* R26/27 are X */
mov r27,r25
/*restore stack pointer*/
ld r25, X+
ld r24, X+
sts 0x5E,r24 /*sph*/
sts 0x5D ,r25 /*spl*/
/*restore registers from stack*/
pop r29
pop r28
pop r17
pop r16
pop r15
pop r14
pop r13
pop r12
pop r11
pop r10
pop r9
pop r8
pop r7
pop r6
pop r5
pop r4
pop r3
pop r2
/*restore sreg*/
ld r25, X
sts 0x5f,r25 /*sreg*/
pop r30
pop r31
IJMP
ret
/*PAGE
*
* _CPU_Context_Initialize
*
* This kernel routine initializes the basic non-FP context area associated
* with each thread.
*
* Input parameters:
* the_context - pointer to the context area
* stack_base - address of memory for the SPARC
* size - size in bytes of the stack area
* new_level - interrupt level for this context area
* entry_point - the starting execution point for this this context
* is_fp - TRUE if this context is associated with an FP thread
*
* the_context is in r25,r24
* entry point is in r13,r12
* stack base is in r23, r22
* size is in r21, r20, r19,r18
* newleve is in r14,r15, r16, 17
*
*
* Output parameters: NONE
*/
PUBLIC(_CPU_Context_Initialize)
SYM(_CPU_Context_Initialize):
//save caller saved regs
PUSH R10
PUSH R11
PUSH R12
PUSH R13
PUSH R14
PUSH R15
PUSH R16
PUSH R17
PUSH R28
PUSH R29
//calculate new stack pointer
ADD R22, R18
ADC R23, R19
MOV R26, R22
MOV R27, R23
//Initialize stack with entry point
ST -X, R13
ST -X, R12
//store new stack pointer in context control
SBIW R26, 0X13 /*subtract 33 to account for registers*/
MOV R28, R24
MOV R29, R25
STD Y+1, R27 //save stack pointer high to context control
ST Y, R26 //save stack pointer low to context control
//set interrupt level in new context
LDI R18, 0 //set sreg in new context to zero
STD Y+2, R18 //interrupts not enabled
MOV R18, R14
CPI R18, 0
BRNE NEW_LEVEL_ZERO
LDI R18, 0X80 //set sreg in new context to 0x80
STD Y+2, R18 //interupts enabled
NEW_LEVEL_ZERO:
//restore caller saved regs
POP R29
POP R28
POP R17
POP R16
POP R15
POP R14
POP R13
POP R12
POP R11
POP R10
RET
/* void __ISR_Handler()
*
* This routine provides the RTEMS interrupt management.
*
* NO_CPU Specific Information:
*
* XXX document implementation including references if appropriate
void _ISR_Handler(void)
{
*/
/*
* This discussion ignores a lot of the ugly details in a real
* implementation such as saving enough registers/state to be
* able to do something real. Keep in mind that the goal is
* to invoke a user's ISR handler which is written in C and
* uses a certain set of registers.
*
* Also note that the exact order is to a large extent flexible.
* Hardware will dictate a sequence for a certain subset of
* _ISR_Handler while requirements for setting
*/
/*
* At entry to "common" _ISR_Handler, the vector number must be
* available. On some CPUs the hardware puts either the vector
* number or the offset into the vector table for this ISR in a
* known place. If the hardware does not give us this information,
* then the assembly portion of RTEMS for this port will contain
* a set of distinct interrupt entry points which somehow place
* the vector number in a known place (which is safe if another
* interrupt nests this one) and branches to _ISR_Handler.
*
* save some or all context on stack
* may need to save some special interrupt information for exit
*
* #if ( CPU_HAS_SOFTWARE_INTERRUPT_STACK == TRUE )
* if ( _ISR_Nest_level == 0 )
* switch to software interrupt stack
* #endif
*
* _ISR_Nest_level++;
*
* _Thread_Dispatch_disable_level++;
*
* (*_ISR_Vector_table[ vector ])( vector );
*
* _Thread_Dispatch_disable_level--;
*
* --_ISR_Nest_level;
*
* if ( _ISR_Nest_level )
* goto the label "exit interrupt (simple case)"
*
* if ( _Thread_Dispatch_disable_level )
* _ISR_Signals_to_thread_executing = FALSE;
* goto the label "exit interrupt (simple case)"
*
* if ( _Context_Switch_necessary || _ISR_Signals_to_thread_executing ) {
* _ISR_Signals_to_thread_executing = FALSE;
* call _Thread_Dispatch() or prepare to return to _ISR_Dispatch
* prepare to get out of interrupt
* return from interrupt (maybe to _ISR_Dispatch)
*
* LABEL "exit interrupt (simple case):
* #if ( CPU_HAS_SOFTWARE_INTERRUPT_STACK == TRUE )
* if outermost interrupt
* restore stack
* #endif
* prepare to get out of interrupt
* return from interrupt
*/
/*} */
PUBLIC(_ISR_Handler)
SYM(_ISR_Handler):
ret