cstartup_ice.s

ARM入门的好帮手.包含了从简单到相对较复杂的程序.

DataAbortHandler
                b           DataAbortHandler

;------------------------------------------------------------------------------
;- EBI Initialization Data
;-------------------------
;- The EBI values depend to target choice , Clock, and memories access time.
;- Yous must be define these values in include file
;- The EBI User Interface Image which is copied by the boot.
;- The EBI_CSR_x are defined in the target and hardware depend.
;- That's hardware! Details in the Electrical Datasheet of the AT91 device.
;- EBI Base Address is added at the end for commodity in copy code.
;- ICE note :For ICE debug no need to set the EBI value these values already set
;- by the boot function.
;------------------------------------------------------------------------------
InitTableEBI
            DCD         EBI_CSR_0
            DCD         EBI_CSR_1
            DCD         EBI_CSR_2
            DCD         EBI_CSR_3
            DCD         EBI_CSR_4
            DCD         EBI_CSR_5
            DCD         EBI_CSR_6
            DCD         EBI_CSR_7
            DCD         0x00000001  ; REMAP command
            DCD         0x00000006  ; 6 memory regions, standard read
PtEBIBase
            DCD         EBI_BASE    ; EBI Base Address

;------------------------------------------------------------------------------
;- The reset handler before Remap
;--------------------------------
;- From here, the code is executed from SRAM address
;------------------------------------------------------------------------------
InitReset

;------------------------------------------------------------------------------
;- Speed up the Boot sequence
;----------------------------
;- After reset, the number os wait states on chip select 0 is 8. All AT91
;- Evaluation Boards fits fast flash memories, so that the number of wait
;- states can be optimized to fast up the boot sequence.
;- ICE note :For ICE debug no need to set the EBI value these values already set
;- by the boot function.
;------------------------------------------------------------------------------
;- Load System EBI Base address and CSR0 Init Value
                ldr     r0, PtEBIBase
                ldr     r1, [pc,#-(8+.-InitTableEBI)] ; values (relative)

;- Speed up code execution by disabling wait state on Chip Select 0
                str     r1, [r0]

;------------------------------------------------------------------------------
;- low level init
;----------------
; Call __low_level_init to perform initialization before initializing
; AIC and calling main.
;----------------------------------------------------------------------

                bl      __low_level_init

;------------------------------------------------------------------------------
;- Reset the Interrupt Controller
;--------------------------------
;- Normally, the code is executed only if a reset has been actually performed.
;- So, the AIC initialization resumes at setting up the default vectors.
;------------------------------------------------------------------------------
;- Load the AIC Base Address and the default handler addresses
                 add     r0, pc,AicData-8-.  ; @ where to read values (relative)

                ldmia   r0, {r1-r4}

;- Setup the Spurious Vector
                str     r4, [r1, #AIC_SPU]      ; r4 = spurious handler


;- ICE note : For ICE debug
;- Perform 8 End Of Interrupt Command to make sure AIC will not lock out nIRQ
                mov         r0, #8
LoopAic0
                str         r1, [r1, #AIC_EOICR]    ; any value written
                subs        r0, r0, #1
                bhi         LoopAic0

;- Set up the default interrupt handler vectors
                str     r2, [r1, #AIC_SVR]      ; SVR[0] for FIQ
                add     r1, r1, #AIC_SVR
                mov     r0, #31                 ; counter
LoopAic1
                str     r3, [r1, r0, LSL #2]    ; SVRs for IRQs
                subs    r0, r0, #1              ; do not save FIQ
                bhi     LoopAic1

                b       EndInitAic

;- Default Interrupt Handlers
AicData
                DCD     AIC_BASE                ; AIC Base Address
;------------------------------------------------------------------------------
;- Default Interrupt Handler
;---------------------------
;- These function are defined in the AT91 library. If you want to change this
;- you can redifine these function in your appication code
;------------------------------------------------------------------------------

                IMPORT  at91_default_fiq_handler
                IMPORT  at91_default_irq_handler
                IMPORT  at91_spurious_handler
PtDefaultHandler
                DCD     at91_default_fiq_handler
                DCD     at91_default_irq_handler
                DCD     at91_spurious_handler
EndInitAic

;------------------------------------------------------------------------------
;- Setup Exception Vectors in Internal RAM before Remap
;------------------------------------------------------
;- That's important to perform this operation before Remap in order to guarantee
;- that the core has valid vectors at any time during the remap operation.
;- Note: There are only 5 offsets as the vectoring is used.
;- ICE note : In this code only the start address value is changed if you use
;- without Semihosting.
;-  Before Remap the internal RAM it's 0x300000
;-  After  Remap the internal RAM it's 0x000000
;-      Remap it's already executed it's no possible to write to 0x300000.
;------------------------------------------------------------------------------
;- Copy the ARM exception vectors

; The RAM_BASE = 0 it's specific for ICE
                mov     r8,#RAM_BASE            ; @ of the hard vector after remap  in internal RAM 0x0

                sub     r9, pc,8+.-VectorTable  ; @ where to read values (relative)
                ldmia   r9!, {r0-r7}            ; read 8 vectors

                stmia   r8!, {r0-r7}            ; store them
                ldmia   r9!, {r0-r4}            ; read 5 absolute handler addresses
                stmia   r8!, {r0-r4}            ; store them

;------------------------------------------------------------------------------
;- Initialise the Memory Controller
;----------------------------------
;- That's principaly the Remap Command. Actually, all the External Bus
;- Interface is configured with some instructions and the User Interface Image
;- as described above. The jump "mov pc, r12" could be unread as it is after
;- located after the Remap but actually it is thanks to the Arm core pipeline.
;- The IniTableEBI addressing must be relative .
;- The PtInitRemap must be absolute as the processor jumps at this address
;- immediatly after the Remap is performed.
;- Note also that the EBI base address is loaded in r11 by the "ldmia".
;- ICE note :For ICE debug these values already set by the boot function and the
;- Remap it's already executed it's no need to set still.
;------------------------------------------------------------------------------
;- Copy the Image of the Memory Controller
                sub     r10, pc,#(8+.-InitTableEBI) ; get the address of the chip select register image
                ldr     r12, PtInitRemap        ; get the real jump address ( after remap )

;- Copy Chip Select Register Image to Memory Controller and command remap
                ldmia   r10!, {r0-r9,r11}       ; load the complete image and the EBI base
                stmia   r11!, {r0-r9}           ; store the complete image with the remap command

;- Jump to ROM at its new address
                mov     pc, r12                 ; jump and break the pipeline

PtInitRemap
                DCD     InitRemap               ; address where to jump after REMAP

;------------------------------------------------------------------------------
;- The Reset Handler after Remap
;-------------------------------
;- From here, the code is continous execute from its link address.
;------------------------------------------------------------------------------
InitRemap

;------------------------------------------------------------------------------
;- Stack Sizes Definition
;------------------------
;- Interrupt Stack requires 3 words x 8 priority level x 4 bytes when using
;- the vectoring. This assume that the IRQ_ENTRY/IRQ_EXIT macro are used.
;- The Interrupt Stack must be adjusted depending on the interrupt handlers.
;- Fast Interrupt is the same than Interrupt without priority level.
;- Other stacks are defined by default to save one word each.
;- The System stack size is not defined and is limited by the free internal
;- SRAM.
;- User stack size is not defined and is limited by the free external SRAM.
;------------------------------------------------------------------------------

IRQ_STACK_SIZE      EQU     (3*8*4)     ; 3 words per interrupt priority level
FIQ_STACK_SIZE      EQU     (3*4)       ; 3 words
ABT_STACK_SIZE      EQU     (1*4)       ; 1 word
UND_STACK_SIZE      EQU     (1*4)       ; 1 word

;------------------------------------------------------------------------------
;- Top of Stack Definition
;-------------------------
;- Fast Interrupt, Interrupt, Abort, Undefined and Supervisor Stack are located
;- at the top of internal memory in order to speed the exception handling
;- context saving and restoring.
;- User (Application, C) Stack is located at the top of the external memory.
;------------------------------------------------------------------------------

TOP_EXCEPTION_STACK     EQU     RAM_LIMIT           ; Defined in part
TOP_APPLICATION_STACK   EQU     EXT_SRAM_LIMIT      ; Defined in Target

;------------------------------------------------------------------------------
;- Setup the stack for each mode
;-------------------------------
                ldr     r0, =TOP_EXCEPTION_STACK

;- Set up Fast Interrupt Mode and set FIQ Mode Stack
                msr     CPSR_c, #ARM_MODE_FIQ | I_BIT | F_BIT
                mov     r13, r0                     ; Init stack FIQ
                sub     r0, r0, #FIQ_STACK_SIZE

;- Set up Interrupt Mode and set IRQ Mode Stack
                msr     CPSR_c, #ARM_MODE_IRQ | I_BIT | F_BIT
                mov     r13, r0                     ; Init stack IRQ
                sub     r0, r0, #IRQ_STACK_SIZE

;- Set up Abort Mode and set Abort Mode Stack
                msr     CPSR_c, #ARM_MODE_ABORT | I_BIT | F_BIT
                mov     r13, r0                     ; Init stack Abort
                sub     r0, r0, #ABT_STACK_SIZE

;- Set up Undefined Instruction Mode and set Undef Mode Stack
                msr     CPSR_c, #ARM_MODE_UNDEF | I_BIT | F_BIT
                mov     r13, r0                     ; Init stack Undef
                sub     r0, r0, #UND_STACK_SIZE

;- Set up Supervisor Mode and set Supervisor Mode Stack
                msr     CPSR_c, #ARM_MODE_SVC | I_BIT | F_BIT
                mov     r13, r0                     ; Init stack Sup
                sub     r0, r0, #UND_STACK_SIZE

;------------------------------------------------------------------------------
;- Setup Application Operating Mode and Enable the interrupts
;------------------------------------------------------------
;- System Mode is selected first and the stack is setup. This allows to prevent
;- any interrupt occurence while the User is not initialized. System Mode is
;- used as the interrupt enabling would be avoided from User Mode (CPSR cannot
;- be written while the core is in User Mode).
;------------------------------------------------------------------------------
                msr     CPSR_c, #ARM_MODE_USER      ; set User mode
	
                b          _start
;----------------------------------------------------------------------
; Call __low_level_init to perform initialization before initializing
; AIC and calling main.
; Enable all peripherial clock
; The peripheral clocks are automatically enabled after a reset.
;----------------------------------------------------------------------
__low_level_init:
                mvn         r0,#0               ; R0<- 0xFFFFFFFF
                ldr         r1,=PS_BASE         ; Get Power saving configuartion
                str         r0,[r1, #PS_PCER]   ; Enable all peripherial clock
                mov         pc,r14              ; Return

            END