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// #========================================================================
// #
// # vectors.S
// #
// # ARM exception vectors
// #
// #========================================================================
//####ECOSGPLCOPYRIGHTBEGIN####
// -------------------------------------------
// This file is part of eCos, the Embedded Configurable Operating System.
// Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc.
//
// eCos is free software; you can redistribute it and/or modify it under
// the terms of the GNU General Public License as published by the Free
// Software Foundation; either version 2 or (at your option) any later version.
//
// eCos is distributed in the hope that it will be useful, but WITHOUT ANY
// WARRANTY; without even the implied warranty of MERCHANTABILITY or
// FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
// for more details.
//
// You should have received a copy of the GNU General Public License along
// with eCos; if not, write to the Free Software Foundation, Inc.,
// 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA.
//
// As a special exception, if other files instantiate templates or use macros
// or inline functions from this file, or you compile this file and link it
// with other works to produce a work based on this file, this file does not
// by itself cause the resulting work to be covered by the GNU General Public
// License. However the source code for this file must still be made available
// in accordance with section (3) of the GNU General Public License.
//
// This exception does not invalidate any other reasons why a work based on
// this file might be covered by the GNU General Public License.
//
// Alternative licenses for eCos may be arranged by contacting Red Hat, Inc.
// at http://sources.redhat.com/ecos/ecos-license/
// -------------------------------------------
//####ECOSGPLCOPYRIGHTEND####
// #========================================================================
// ######DESCRIPTIONBEGIN####
// #
// # Author(s): nickg, gthomas
// # Contributors: nickg, gthomas
// # Date: 1999-02-20
// # Purpose: ARM exception vectors
// # Description: This file defines the code placed into the exception
// # vectors. It also contains the first level default VSRs
// # that save and restore state for both exceptions and
// # interrupts.
// #
// #####DESCRIPTIONEND####
// #
// #========================================================================
#include <pkgconf/hal.h>
#include <pkgconf/hal_arm.h>
#ifdef CYGPKG_KERNEL // no CDL yet
#include <pkgconf/kernel.h>
#else
# undef CYGFUN_HAL_COMMON_KERNEL_SUPPORT
# undef CYGIMP_HAL_COMMON_INTERRUPTS_USE_INTERRUPT_STACK
#endif
#include <cyg/hal/hal_platform_setup.h>
#ifdef CYGDBG_HAL_DEBUG_GDB_INCLUDE_STUBS
// The CDL should enforce this
#undef CYGHWR_HAL_ARM_DUMP_EXCEPTIONS
#endif
#include "arm.inc"
#ifdef __thumb__
// Switch to thumb mode
#define THUMB_MODE(_r_, _l_) \
ldr _r_,=_l_ ## f+1 ;\
bx _r_ ;\
.pool ;\
.code 16 ;\
.thumb_func ;\
_l_:
// Switch to ARM mode
#define ARM_MODE(_r_, _l_) \
ldr _r_,=_l_ ## f ;\
bx _r_ ;\
.pool ;\
.code 32 ;\
_l_:
// Function definition, start executing body in ARM mode
#define FUNC_START_ARM(_name_, _r_) \
.code 16 ;\
.thumb_func ;\
.globl _name_ ;\
_name_: ;\
ldr _r_,=_name_ ## _ARM ;\
bx _r_ ;\
.code 32 ;\
_name_ ## _ARM:
#else
// Switch to thumb mode
#define THUMB_MODE(_r_, _l_)
// Switch to ARM mode
#define ARM_MODE(_r_, _l_)
// Function definition, start executing body in ARM mode
#define FUNC_START_ARM(_name_, _r_) \
.globl _name_; \
_name_:
#endif
#define PTR(name) \
.##name: .word name
// CYGHWR_HAL_ROM_VADDR is used when compiling for a different location
// from the base of ROM. hal_platform_setup.h might define it. For
// example, if flash is from 0x50000000 upwards (as on SA11x0), and we are
// to execute at 0x50040000, then we want the reset vector to point to
// 0x0004pqrs - the unmapped ROM address of the code - rather than
// 0x0000pqrs, which is the offset into our flash block.
//
// But usually it's not defined, so the behaviour is the obvious.
#ifndef UNMAPPED
#ifdef CYGHWR_HAL_ARM_HAS_MMU
# ifndef CYGHWR_HAL_ROM_VADDR
# define CYGHWR_HAL_ROM_VADDR __exception_handlers
# endif
# define UNMAPPED(x) ((x)-CYGHWR_HAL_ROM_VADDR)
#else
# define UNMAPPED(x) (x)
#endif
#endif
#define UNMAPPED_PTR(name) \
.##name: .word UNMAPPED(name)
// .file "vectors.S"
// CYGHWR_LED_MACRO can be defined in hal_platform_setup.h. It's free to
// use r0+r1. Argument is in "\x" - cannot use macro arguments since the
// macro may contain #-chars and use of arguments cause these to be
// interpreted as CPP stringify operators.
// See example in PID hal_platform_setup.h.
#ifndef CYGHWR_LED_MACRO
#define CYGHWR_LED_MACRO
#endif
.macro LED x
CYGHWR_LED_MACRO
.endm
//==========================================================================
// Hardware exception vectors.
// This entire section will be copied to location 0x0000 at startup time.
//
.code 32
.section ".vectors","ax"
// This macro allows platforms to add their own code at the very start of
// the image. This may be required in some circumstances where eCos ROM
// based code does not run immediately upon reset and/or when some sort of
// special header is required at the start of the image.
#ifdef PLATFORM_PREAMBLE
PLATFORM_PREAMBLE
#endif
.global __exception_handlers
__exception_handlers:
#ifdef CYGSEM_HAL_ROM_RESET_USES_JUMP
// Assumption: ROM code has these vectors at the hardware reset address.
// A simple jump removes any address-space dependencies [i.e. safer]
b reset_vector // 0x00
#else
ldr pc,.reset_vector // 0x00
#endif
ldr pc,.undefined_instruction // 0x04
ldr pc,.software_interrupt // 0x08 start && software int
ldr pc,.abort_prefetch // 0x0C
ldr pc,.abort_data // 0x10
.word 0 // unused
ldr pc,.IRQ // 0x18
ldr pc,.FIQ // 0x1C
// The layout of these pointers should match the vector table above since
// they are copied in pairs.
.global vectors
vectors:
UNMAPPED_PTR(reset_vector) // 0x20
PTR(undefined_instruction) // 0x24
PTR(software_interrupt) // 0x28
PTR(abort_prefetch) // 0x2C
PTR(abort_data) // 0x30
.word 0 // 0x34
PTR(IRQ) // 0x38
PTR(FIQ) // 0x3c
#ifdef CYGSEM_HAL_ARM_PID_ANGEL_BOOT
PTR(start) // This is copied to 0x28 for bootup // 0x40
#endif
// location 0x40 is used for storing DRAM size if known
// for some platforms.
//
// "Vectors" - fixed location data items
// This section contains any data which might be shared between
// an eCos application and any other environment, e.g. the debug
// ROM.
//
.section ".fixed_vectors"
// Interrupt/exception VSR pointers
.globl hal_vsr_table
hal_vsr_table:
.rept 8
.long 0
.endr
.globl hal_dram_size
hal_dram_size:
.long 0
// what, if anything, hal_dram_type means is up to the platform
.globl hal_dram_type
hal_dram_type:
.long 0
.balign 16
#ifdef CYGSEM_HAL_VIRTUAL_VECTOR_SUPPORT
// Vectors used to communicate between eCos and ROM environments
.globl hal_virtual_vector_table
hal_virtual_vector_table:
.rept CYGNUM_CALL_IF_TABLE_SIZE
.long 0
.endr
#endif
#ifdef CYGHWR_HAL_ARM_ICE_THREAD_SUPPORT
.balign 16 // Should be at 0x50
ice_thread_vector:
.long 0 // Must be 'MICE'
.long 0 // Pointer to thread support vector
.long 0 // eCos executing flag
.long 0 // Must be 'GDB '
#endif // CYGHWR_HAL_ARM_ICE_THREAD_SUPPORT
.balign 32
// Other vectors - this may include "fixed" locations
#ifdef PLATFORM_VECTORS
PLATFORM_VECTORS
#endif
.text
// Startup code which will get the machine into supervisor mode
.global reset_vector
.type reset_vector,function
reset_vector:
PLATFORM_SETUP1 // Early stage platform initialization
// which can set DRAM size at 0x40
// see <cyg/hal/hal_platform_setup.h>
// Come here to reset board
warm_reset:
#if defined(CYG_HAL_STARTUP_RAM) && \
!defined(CYGDBG_HAL_DEBUG_GDB_INCLUDE_STUBS)
mrs r7,cpsr // move back to IRQ mode
and r7,r7,#CPSR_MODE_BITS
cmp r7,#CPSR_SUPERVISOR_MODE
beq start
#endif
// We cannot access any LED registers until after PLATFORM_SETUP1
LED 7
mov r0,#0 // move vectors
ldr r1,=__exception_handlers
#ifndef CYGDBG_HAL_DEBUG_GDB_INCLUDE_STUBS
// Wait with this if stubs are included (see further down).
ldr r2,[r1,#0x04] // undefined instruction
str r2,[r0,#0x04]
ldr r2,[r1,#0x24]
str r2,[r0,#0x24]
#endif
ldr r2,[r1,#0x08] // software interrupt
str r2,[r0,#0x08]
#ifdef CYGHWR_HAL_ARM_ICE_THREAD_SUPPORT
ldr r2,=ice_thread_vector
sub r2,r2,r1 // compute fixed (low memory) address
ldr r3,=0x4D494345 // 'MICE'
str r3,[r2],#4
ldr r3,=hal_arm_ice_thread_handler
str r3,[r2],#4
mov r3,#1
str r3,[r2],#4
ldr r3,=0x47444220 // 'GDB '
str r3,[r2],#4
#endif // CYGHWR_HAL_ARM_ICE_THREAD_SUPPORT
#if defined(CYGSEM_HAL_ARM_PID_ANGEL_BOOT)
// Ugly hack to get into supervisor mode
ldr r2,[r1,#0x40]
str r2,[r0,#0x28]
LED 6
swi // switch to supervisor mode
#endif
// =========================================================================
// Real startup code. We jump here from the reset vector to set up the world.
.globl start
start:
LED 5
#if defined(CYG_HAL_STARTUP_RAM) && \
!defined(CYGDBG_HAL_DEBUG_GDB_INCLUDE_STUBS)
// If we get restarted, hang here to avoid corrupting memory
ldr r0,.init_flag
ldr r1,[r0]
1: cmp r1,#0
bne 1b
ldr r1,init_done
str r1,[r0]
#endif
// Reset software interrupt pointer
mov r0,#0 // move vectors
ldr r1,.__exception_handlers
#if defined(CYG_HAL_STARTUP_RAM) && \
!defined(CYGDBG_HAL_DEBUG_GDB_INCLUDE_STUBS)
cmp r7,#CPSR_SUPERVISOR_MODE
beq 10f
#endif
ldr r2,[r1,#0x28] // software interrupt
str r2,[r0,#0x28]
10:
ldr r2,[r1,#0x18] // IRQ
str r2,[r0,#0x18]
ldr r2,[r1,#0x38]
str r2,[r0,#0x38]
ldr r2,[r1,#0x1C] // FIQ
str r2,[r0,#0x1C]
ldr r2,[r1,#0x3C]
str r2,[r0,#0x3C]
ldr r2,[r1,#0x0C] // abort (prefetch)
str r2,[r0,#0x0C]
ldr r2,[r1,#0x2C]
str r2,[r0,#0x2C]
ldr r2,[r1,#0x10] // abort (data)
str r2,[r0,#0x10]
ldr r2,[r1,#0x30]
str r2,[r0,#0x30]
LED 4
#if defined(CYG_HAL_STARTUP_ROM) || defined(CYG_HAL_STARTUP_ROMRAM)
// Set up reset vector
mov r0,#0
ldr r1,.__exception_handlers
ldr r2,[r1,#0x00] // reset vector intstruction
str r2,[r0,#0x00]
ldr r2,=warm_reset
str r2,[r0,#0x20]
// Relocate [copy] data from ROM to RAM
ldr r3,.__rom_data_start
ldr r4,.__ram_data_start
ldr r5,.__ram_data_end
cmp r4,r5 // jump if no data to move
beq 2f
sub r3,r3,#4 // loop adjustments
sub r4,r4,#4
1: ldr r0,[r3,#4]! // copy info
str r0,[r4,#4]!
cmp r4,r5
bne 1b
2:
#endif
// initialize interrupt/exception environments
ldr sp,.__startup_stack
mov r0,#(CPSR_IRQ_DISABLE|CPSR_FIQ_DISABLE|CPSR_IRQ_MODE)
msr cpsr,r0
ldr sp,.__exception_stack
mov r0,#(CPSR_IRQ_DISABLE|CPSR_FIQ_DISABLE|CPSR_UNDEF_MODE)
msr cpsr,r0
ldr sp,.__exception_stack
// initialize CPSR (machine state register)
mov r0,#(CPSR_IRQ_DISABLE|CPSR_FIQ_DISABLE|CPSR_SUPERVISOR_MODE)
msr cpsr,r0
// Note: some functions in LIBGCC1 will cause a "restore from SPSR"!!
msr spsr,r0
// initialize stack
#ifdef CYGIMP_HAL_COMMON_INTERRUPTS_USE_INTERRUPT_STACK
// use interrupt stack for system initialization since it's bigger
// than the "startup" stack in this configuration
ldr sp,.__interrupt_stack
#else
ldr sp,.__startup_stack
#endif
// clear BSS
ldr r1,.__bss_start
ldr r2,.__bss_end
mov r0,#0
cmp r1,r2
beq 2f
1: str r0,[r1],#4
cmp r1,r2
bls 1b
2:
// Run kernel + application in THUMB mode
THUMB_MODE(r1,10)
LED 3
// Call platform specific hardware initialization
bl hal_hardware_init
#ifdef CYGDBG_HAL_DEBUG_GDB_INCLUDE_STUBS
bl initialize_stub
// Now that stub is initialized, change vector. It is possible
// to single-step through most of the init code, except the below.
// Put a breakpoint at the call to cyg_hal_invoke_constructors to
// pass over this bit (s-s depends on internal state in the stub).
#endif
#if defined(CYGDBG_HAL_DEBUG_GDB_INCLUDE_STUBS) || \
defined(CYGIMP_HAL_PROCESS_ALL_EXCEPTIONS)
mov r0,#0 // move vectors
ldr r1,=__exception_handlers
ldr r2,[r1,#0x04] // undefined instruction
str r2,[r0,#0x04]
ldr r2,[r1,#0x24]
str r2,[r0,#0x24]
#endif
#if defined(CYGDBG_HAL_DEBUG_GDB_CTRLC_SUPPORT) \
|| defined(CYGDBG_HAL_DEBUG_GDB_BREAK_SUPPORT)
.extern hal_ctrlc_isr_init
bl hal_ctrlc_isr_init
#endif
LED 2
// Run through static constructors
bl cyg_hal_invoke_constructors
LED 1
// This starts up the eCos kernel
#ifdef CYGIMP_HAL_COMMON_INTERRUPTS_USE_INTERRUPT_STACK
ldr r1,=__startup_stack
mov sp,r1
#endif
bl cyg_start
_start_hang:
b _start_hang
.code 32
.global reset_platform
.type reset_platform,function
reset_platform:
#ifdef CYGSEM_HAL_ROM_MONITOR
// initialize CPSR (machine state register)
mov r0,#(CPSR_IRQ_DISABLE|CPSR_FIQ_DISABLE|CPSR_SUPERVISOR_MODE)
msr cpsr,r0
b warm_reset
#else
mov r0,#0
mov pc,r0 // Jump to reset vector
#endif
init_done:
.long 0xDEADB00B
//
// Exception handlers
// Assumption: get here from a non-user context [mode]
//
.code 32
undefined_instruction:
ldr sp,.__undef_exception_stack // get good stack
stmfd sp!,{r0-r5} // save some supervisor regs
mrs r1,spsr
tst r1,#CPSR_THUMB_ENABLE
subeq r0,lr,#4 // PC at time of interrupt (ARM)
subne r0,lr,#2 // PC at time of interrupt (thumb)
mov r2,#CYGNUM_HAL_EXCEPTION_ILLEGAL_INSTRUCTION
mov r3,sp
b call_exception_handler
.code 32
software_interrupt:
stmfd sp!,{r8}
ldr r8,.__undef_exception_stack // get good stack
stmfd r8!,{r0-r5} // save some supervisor regs
mov r3,r8
ldmfd sp!,{r8}
mrs r1,spsr
tst r1,#CPSR_THUMB_ENABLE
subeq r0,lr,#4 // PC at time of SWI (ARM)
subne r0,lr,#2 // PC at time of SWI (thumb)
mov r2,#CYGNUM_HAL_EXCEPTION_INTERRUPT
b call_exception_handler
.code 32
abort_prefetch:
ldr sp,.__undef_exception_stack // get good stack
stmfd sp!,{r0-r5} // save some supervisor regs
sub r0,lr,#4 // PC at time of interrupt
mrs r1,spsr
mov r2,#CYGNUM_HAL_EXCEPTION_CODE_ACCESS
mov r3,sp
b call_exception_handler
.code 32
abort_data:
ldr sp,.__undef_exception_stack // get good stack
stmfd sp!,{r0-r5} // save some supervisor regs
sub r0,lr,#4 // PC at time of interrupt
mrs r1,spsr
mov r2,#CYGNUM_HAL_EXCEPTION_DATA_ACCESS
mov r3,sp
b call_exception_handler
//
// Dispatch an exception handler.
.code 32
call_exception_handler:
//
// On Entry:
//
// r4,r5 = scratch
// r3 = pointer to temp save area
// r2 = vector number
// r1 = exception psr
// r0 = exception pc
//
// [r3+20]: exception r5
// [r3+16]: exception r4
// [r3+12]: exception r3
// [r3+8] : exception r2
// [r3+4] : exception r1
// [r3] : exception r0
mrs r4,cpsr // switch to Supervisor Mode
bic r4,r4,#CPSR_MODE_BITS
orr r4,r4,#CPSR_SUPERVISOR_MODE
msr cpsr,r4
mov r5,sp // save original svc sp
mov r4,lr // and original svc lr
#ifdef CYGDBG_HAL_DEBUG_GDB_INCLUDE_STUBS
// Make sure we use the GDB stack.
ldr sp,.__GDB_stack
cmp r5,sp // already on GDB stack?
bhi 10f
ldr r4,.__GDB_stack_base
cmp r5,r4
movhi sp,r5
10:
#endif
//
// r5 holds original svc sp, current sp is stack to use
// r4 holds original svc lr, which must also be preserved
//
stmfd sp!,{r0-r2,r4,r5} // push svc_sp, svc_lr, vector, psr, pc
// switch to pre-exception mode to get banked regs
mov r0,sp // r0 survives mode switch
mrs r2,cpsr // Save current psr for return
orr r1,r1,#CPSR_IRQ_DISABLE|CPSR_FIQ_DISABLE
bic r1,r1,#CPSR_THUMB_ENABLE
msr cpsr,r1
stmfd r0!,{r8-r12,sp,lr}
msr cpsr,r2 // back to svc mode
mov sp,r0 // update stack pointer
// now save pre-exception r0-r7 on current stack
ldmfd r3,{r0-r5}
stmfd sp!,{r0-r7}
// SP needs fixing if exception occured in SVC mode.
// The original SVC LR is still in place so that
// does not need to be fixed here.
ldr r1,[sp,#armreg_cpsr]
and r1,r1,#CPSR_MODE_BITS
cmp r1,#CPSR_SUPERVISOR_MODE
ldreq r1,[sp,#armreg_svcsp]
streq r1,[sp,#armreg_sp]
#ifdef CYGHWR_HAL_ARM_DUMP_EXCEPTIONS
mov r0,sp
ldr r1,.__dump_procs
ldr r2,[sp,#armreg_vector]
mov lr,pc
ldr pc,[r1,r2,lsl #2]
#endif
// call exception handler
mov r0,sp
THUMB_MODE(r9,10)
bl exception_handler
#ifdef CYGHWR_HAL_ARM_DUMP_EXCEPTIONS
mov r0,sp
bl cyg_hal_report_exception_handler_returned
#endif
ARM_MODE(r1,10)
//
// Return from exception
//
return_from_exception:
ldr r0,[sp,#armreg_cpsr]
msr spsr,r0
// return to supervisor mode is simple
and r1,r0,#CPSR_MODE_BITS
cmp r1,#CPSR_SUPERVISOR_MODE
ldmeqfd sp,{r0-r14,pc}^
//
// return to other non-user modes is a little trickier
//
// switch to pre-exception mode and restore r8-r14
add r2,sp,#armreg_r8
mrs r1,cpsr
orr r0,r0,#CPSR_IRQ_DISABLE|CPSR_FIQ_DISABLE
bic r0,r0,#CPSR_THUMB_ENABLE
msr cpsr,r0
ldmfd r2,{r8-r14}
msr cpsr, r1 // back to svc mode
// move sp,lr and pc for final load
ldr r0,[sp,#armreg_svcsp]
str r0,[sp,#armreg_r8]
ldr r0,[sp,#armreg_svclr]
str r0,[sp,#armreg_r9]
ldr r0,[sp,#armreg_pc]
str r0,[sp,#armreg_r10]
// restore r0-r7,sp,lr and return from exception
ldmfd sp,{r0-r7,sp,lr,pc}^
#ifdef CYGHWR_HAL_ARM_DUMP_EXCEPTIONS
__dump_procs:
.word 0 // placeholder for reset
.word cyg_hal_report_undefined_instruction
.word cyg_hal_report_software_interrupt
.word cyg_hal_report_abort_prefetch
.word cyg_hal_report_abort_data
.word 0 // reserved
#endif
// Handle device interrupts
// This is slightly more complicated than the other exception handlers because
// it needs to interface with the kernel (if present).
.code 32
FIQ:
// We can get here from any non-user mode.
mrs r8,spsr // CPSR at time of interrupt
and r9,r8,#CPSR_MODE_BITS // isolate pre-interrupt mode
cmp r9,#CPSR_IRQ_MODE
bne 1f
// If FIQ interrupted IRQ mode, just return with FIQ disabled.
// The common interrupt handling takes care of the rest.
orr r8,r8,#CPSR_FIQ_DISABLE
msr spsr,r8
subs pc,lr,#4
1:
// If FIQ interrupted other non-user mode, switch to IRQ mode and
// fall through to IRQ handler.
ldr sp,.__exception_stack // get good stack to save lr and spsr
stmdb sp,{r8,lr}
mov r8,#CPSR_IRQ_MODE|CPSR_FIQ_DISABLE|CPSR_IRQ_DISABLE
msr cpsr,r8 // switch to IRQ mode
ldr sp,.__exception_stack // get regs saved in FIQ mode
ldmdb sp,{sp,lr}
msr spsr,sp
// now it looks like we got an IRQ instead of an FIQ except that
// FIQ is disabled so we don't recurse.
IRQ:
// Note: I use this exception stack while saving the context because
// the current SP does not seem to be always valid in this CPU mode.
ldr sp,.__exception_stack // get good stack
stmfd sp!,{r0-r5} // save some supervisor regs
sub r0,lr,#4 // PC at time of interrupt
mrs r1,spsr
mov r2,#CYGNUM_HAL_VECTOR_IRQ
mov r3,sp
handle_IRQ_or_FIQ:
mrs r4,cpsr // switch to Supervisor Mode
bic r4,r4,#CPSR_MODE_BITS
orr r4,r4,#CPSR_SUPERVISOR_MODE
msr cpsr,r4
mov r5,sp // save original svc sp
mov r4,lr // save original svc lr
stmfd sp!,{r0-r2,r4,r5} // push svc_sp, svc_lr, vector, psr, pc
// switch to pre-exception mode to get banked regs
mov r0,sp // r0 survives mode switch
mrs r2,cpsr // Save current psr for return
orr r1,r1,#CPSR_IRQ_DISABLE|CPSR_FIQ_DISABLE
bic r1,r1,#CPSR_THUMB_ENABLE
msr cpsr,r1
stmfd r0!,{r8-r12,sp,lr}
msr cpsr,r2 // back to svc mode
mov sp,r0 // update stack pointer
// now save pre-exception r0-r7 on current stack
ldmfd r3,{r0-r5}
stmfd sp!,{r0-r7}
// sp needs fixing if exception occured in SVC mode.
ldr r1,[sp,#armreg_cpsr]
and r1,r1,#CPSR_MODE_BITS
cmp r1,#CPSR_SUPERVISOR_MODE
ldreq r1,[sp,#armreg_svcsp]
streq r1,[sp,#armreg_sp]
mov v6,sp // Save pointer to register frame
// mov r0,sp
// bl _show_frame_in
#ifdef CYGIMP_HAL_COMMON_INTERRUPTS_USE_INTERRUPT_STACK
// Switch to interrupt stack
ldr r2,.irq_level // current number of nested interrupts
ldr r0,[r2]
add r1,r0,#1
str r1,[r2] // if was zero, switch stacks
cmp r0,#0
moveq r1,sp // save old stack pointer
ldreq sp,.__interrupt_stack
stmeqfd sp!,{r1}
10:
#endif
// The entire CPU state is now stashed on the stack,
// increment the scheduler lock and handle the interrupt
#ifdef CYGFUN_HAL_COMMON_KERNEL_SUPPORT
.extern cyg_scheduler_sched_lock
ldr r3,.cyg_scheduler_sched_lock
ldr r4,[r3]
add r4,r4,#1
str r4,[r3]
#endif
THUMB_MODE(r3,10)
mov r0,v6
bl hal_IRQ_handler // determine interrupt source
mov v1,r0 // returned vector #
#if defined(CYGPKG_KERNEL_INSTRUMENT) && \
defined(CYGDBG_KERNEL_INSTRUMENT_INTR)
ldr r0,=RAISE_INTR // arg0 = type = INTR,RAISE
mov r1,v1 // arg1 = vector
mov r2,#0 // arg2 = 0
bl cyg_instrument // call instrument function
#endif
ARM_MODE(r0,10)
mov r0,v1 // vector #
#if defined(CYGDBG_HAL_DEBUG_GDB_CTRLC_SUPPORT) \
|| defined(CYGDBG_HAL_DEBUG_GDB_BREAK_SUPPORT)
// If we are supporting Ctrl-C interrupts from GDB, we must squirrel
// away a pointer to the save interrupt state here so that we can
// plant a breakpoint at some later time.
.extern hal_saved_interrupt_state
ldr r2,=hal_saved_interrupt_state
str v6,[r2]
#endif
cmp r0,#CYGNUM_HAL_INTERRUPT_NONE // spurious interrupt
bne 10f
#ifndef CYGIMP_HAL_COMMON_INTERRUPTS_IGNORE_SPURIOUS
mov r0,v6 // register frame
bl hal_spurious_IRQ
#endif // CYGIMP_HAL_COMMON_INTERRUPTS_IGNORE_SPURIOUS
b spurious_IRQ
10: ldr r1,.hal_interrupt_data
ldr r1,[r1,v1,lsl #2] // handler data
ldr r2,.hal_interrupt_handlers
ldr v3,[r2,v1,lsl #2] // handler (indexed by vector #)
mov r2,v6 // register frame (this is necessary
// for the ISR too, for ^C detection)
#ifdef __thumb__
ldr lr,=10f
bx v3 // invoke handler (thumb mode)
.pool
.code 16
.thumb_func
IRQ_10T:
10: ldr r2,=15f
bx r2 // switch back to ARM mode
.pool
.code 32
15:
IRQ_15A:
#else
mov lr,pc // invoke handler (call indirect
mov pc,v3 // thru v3)
#endif
spurious_IRQ:
#ifdef CYGIMP_HAL_COMMON_INTERRUPTS_USE_INTERRUPT_STACK
// If we are returning from the last nested interrupt, move back
// to the thread stack. interrupt_end() must be called on the
// thread stack since it potentially causes a context switch.
ldr r2,.irq_level
ldr r3,[r2]
subs r1,r3,#1
str r1,[r2]
ldreq sp,[sp] // This should be the saved stack pointer
#endif
#ifdef CYGFUN_HAL_COMMON_KERNEL_SUPPORT
// The return value from the handler (in r0) will indicate whether a
// DSR is to be posted. Pass this together with a pointer to the
// interrupt object we have just used to the interrupt tidy up routine.
// don't run this for spurious interrupts!
cmp v1,#CYGNUM_HAL_INTERRUPT_NONE
beq 17f
ldr r1,.hal_interrupt_objects
ldr r1,[r1,v1,lsl #2]
mov r2,v6 // register frame
THUMB_MODE(r3,10)
bl interrupt_end // post any bottom layer handler
// threads and call scheduler
ARM_MODE(r1,10)
17:
#endif
// mov r0,sp
// bl show_frame_out
// return from IRQ is same as return from exception
b return_from_exception
#ifdef CYGIMP_HAL_COMMON_INTERRUPTS_USE_INTERRUPT_STACK
// Execute pending DSRs the interrupt stack
// Note: this can only be called from code running on a thread stack
FUNC_START_ARM(hal_interrupt_stack_call_pending_DSRs, r1)
stmfd sp!,{r4,r5,lr}
// Disable interrupts
mrs r4,cpsr // disable IRQ's
orr r2,r4,#CPSR_IRQ_DISABLE|CPSR_FIQ_DISABLE
bic r5,r4,#CPSR_IRQ_DISABLE|CPSR_FIQ_DISABLE
msr cpsr,r2
// Switch to interrupt stack
mov r3,sp // save old stack pointer
ldr sp,.__interrupt_stack
stmfd sp!,{r3} // stored at top of interrupt stack
ldr r2,.irq_level // current number of nested interrupts
ldr r3,[r2]
add r3,r3,#1 // bump nesting level
str r3,[r2]
msr cpsr,r5 // enable interrupts
THUMB_MODE(r1,20)
bl cyg_interrupt_call_pending_DSRs
ARM_MODE(r1,22)
// Disable interrupts
mrs r1,cpsr // disable IRQ's
orr r2,r1,#CPSR_IRQ_DISABLE|CPSR_FIQ_DISABLE
msr cpsr,r2
// Move back to the thread stack.
ldr r2,.irq_level
ldr r3,[r2]
sub r3,r3,#1 // decrement nesting level
str r3,[r2]
ldr sp,[sp] // This should be the saved stack pointer
msr cpsr,r4 // restore interrupts to original state
#ifdef __thumb__
ldmfd sp!,{r4,r5,lr} // return
bx lr
#else
ldmfd sp!,{r4,r5,pc} // return
#endif // __thumb__
#endif // CYGIMP_HAL_COMMON_INTERRUPTS_USE_INTERRUPT_STACK
// Thumb-only support functions
#ifdef __thumb__
FUNC_START_ARM(hal_disable_interrupts, r1)
mrs r0,cpsr // current state
orr r1,r0,#0xC0 // mask both FIQ and IRQ
msr cpsr,r1
bx lr // exit, _old_ in r0
FUNC_START_ARM(hal_enable_interrupts, r1)
mrs r0,cpsr // current state
bic r1,r0,#0xC0 // mask both FIQ and IRQ
msr cpsr,r1
bx lr // exit
FUNC_START_ARM(hal_restore_interrupts, r1)
mrs r1,cpsr // current state
bic r1,r1,#0xC0 // mask out FIQ/IRQ bits
and r0,r0,#0xC0 // keep only FIQ/IRQ
orr r1,r1,r0 // mask both FIQ and IRQ
msr cpsr,r1
bx lr // exit
FUNC_START_ARM(hal_query_interrupts, r1)
mrs r0,cpsr // current state
bx lr // exit, state in r0
#endif // __thumb__
// Dummy/support functions
.global __gccmain
.global _psr
.global _sp
#ifdef __thumb__
.code 16
.thumb_func
__gccmain:
bx lr
.code 16
.thumb_func
_psr:
ARM_MODE(r1,10)
mrs r0,cpsr
bx lr
.code 16
.thumb_func
_sp:
mov r0,sp
bx lr
#else
__gccmain:
mov pc,lr
_psr:
mrs r0,cpsr
mov pc,lr
_sp:
mov r0,sp
mov pc,lr
#endif
//
// Pointers to various objects.
//
#ifdef CYGDBG_HAL_DEBUG_GDB_INCLUDE_STUBS
PTR(__GDB_stack_base)
PTR(__GDB_stack)
#endif
PTR(__startup_stack)
PTR(__exception_stack)
PTR(__undef_exception_stack)
PTR(__bss_start)
PTR(__bss_end)
PTR(_end)
PTR(__rom_data_start)
PTR(__ram_data_start)
PTR(__ram_data_end)
PTR(hal_interrupt_handlers)
PTR(hal_interrupt_data)
PTR(hal_interrupt_objects)
PTR(__exception_handlers)
PTR(init_flag)
#ifdef CYGFUN_HAL_COMMON_KERNEL_SUPPORT
PTR(cyg_scheduler_sched_lock)
#endif
#ifdef CYGIMP_HAL_COMMON_INTERRUPTS_USE_INTERRUPT_STACK
PTR(irq_level)
PTR(__interrupt_stack)
#endif
#ifdef CYGHWR_HAL_ARM_DUMP_EXCEPTIONS
PTR(__dump_procs)
#endif
//
// Identification - useful to find out when a system was configured
_eCos_id:
.asciz "eCos : " __DATE__
// -------------------------------------------------------------------------
// Interrupt vector tables.
// These tables contain the isr, data and object pointers used to deliver
// interrupts to user code.
// Despite appearances, their sizes are not #defines, but .equ symbols
// generated by magic without proper dependencies in arm.inc
// Recompiling will not DTRT without manual intervention.
.data
init_flag:
.balign 4
.long 0
.extern hal_default_isr
.globl hal_interrupt_handlers
hal_interrupt_handlers:
.rept CYGNUM_HAL_ISR_COUNT
.long hal_default_isr
.endr
.globl hal_interrupt_data
hal_interrupt_data:
.rept CYGNUM_HAL_ISR_COUNT
.long 0
.endr
.globl hal_interrupt_objects
hal_interrupt_objects:
.rept CYGNUM_HAL_ISR_COUNT
.long 0
.endr
// -------------------------------------------------------------------------
// Temporary interrupt stack
.section ".bss"
// Small stacks, only used for saving information between CPU modes
__exception_stack_base:
.rept 32
.long 0
.endr
__exception_stack:
.rept 32
.long 0
.endr
__undef_exception_stack:
// Runtime stack used during all interrupt processing
#ifndef CYGNUM_HAL_COMMON_INTERRUPTS_STACK_SIZE
#define CYGNUM_HAL_COMMON_INTERRUPTS_STACK_SIZE 4096
#endif
#ifdef CYGIMP_HAL_COMMON_INTERRUPTS_USE_INTERRUPT_STACK
.balign 16
.global cyg_interrupt_stack_base
cyg_interrupt_stack_base:
__interrupt_stack_base:
.rept CYGNUM_HAL_COMMON_INTERRUPTS_STACK_SIZE
.byte 0
.endr
.balign 16
.global cyg_interrupt_stack
cyg_interrupt_stack:
__interrupt_stack:
irq_level:
.long 0
#endif
#ifdef CYGDBG_HAL_DEBUG_GDB_INCLUDE_STUBS
.balign 16
__GDB_stack_base:
.rept CYGNUM_HAL_COMMON_INTERRUPTS_STACK_SIZE // rather than 1k
.byte 0
.endr
__GDB_stack:
#endif
.balign 16
__startup_stack_base:
#ifdef CYGIMP_HAL_COMMON_INTERRUPTS_USE_INTERRUPT_STACK
.rept 512
#else
.rept CYGNUM_HAL_COMMON_INTERRUPTS_STACK_SIZE
#endif
.byte 0
.endr
.balign 16
__startup_stack:
#ifdef PLATFORM_EXTRAS
#include PLATFORM_EXTRAS
#endif
// --------------------------------------------------------------------------
// end of vectors.S