startup.s

周立功开发板SmartArm2200 I2C中断方式读写板上EEPROM CAT1025,在MDK Keil环境下完成。实现了完整的串口输入输出

;  Absolute addressing mode must be used.
;  Dummy Handlers are implemented as infinite loops which can be modified.

Vectors         LDR     PC, Reset_Addr         
                LDR     PC, Undef_Addr
                LDR     PC, SWI_Addr
                LDR     PC, PAbt_Addr
                LDR     PC, DAbt_Addr
                NOP                            ; Reserved Vector 
;               LDR     PC, IRQ_Addr
                LDR     PC, [PC, #-0x0FF0]     ; Vector from VicVectAddr
                LDR     PC, FIQ_Addr

Reset_Addr      DCD     Reset_Handler
Undef_Addr      DCD     Undef_Handler
SWI_Addr        DCD     SWI_Handler
PAbt_Addr       DCD     PAbt_Handler
DAbt_Addr       DCD     DAbt_Handler
                DCD     0                      ; Reserved Address 
IRQ_Addr        DCD     IRQ_Handler
FIQ_Addr        DCD     FIQ_Handler

Undef_Handler   B       Undef_Handler
SWI_Handler     B       SWI_Handler
PAbt_Handler    B       PAbt_Handler
DAbt_Handler    B       DAbt_Handler
IRQ_Handler     B       IRQ_Handler
FIQ_Handler     B       FIQ_Handler


; Reset Handler

                EXPORT  Reset_Handler
Reset_Handler   


; Setup External Memory Pins
                IF      :DEF:EXTERNAL_MODE
                LDR     R0, =PINSEL2
                LDR     R1, =PINSEL2_Val
                STR     R1, [R0]
                ENDIF


; Setup External Memory Controller
                IF      EMC_SETUP <> 0
                LDR     R0, =EMC_BASE

                IF      BCFG0_SETUP <> 0
                LDR     R1, =BCFG0_Val
                STR     R1, [R0, #BCFG0_OFS]
                ENDIF

                IF      BCFG1_SETUP <> 0
                LDR     R1, =BCFG1_Val
                STR     R1, [R0, #BCFG1_OFS]
                ENDIF

                IF      BCFG2_SETUP <> 0
                LDR     R1, =BCFG2_Val
                STR     R1, [R0, #BCFG2_OFS]
                ENDIF

                IF      BCFG3_SETUP <> 0
                LDR     R1, =BCFG3_Val
                STR     R1, [R0, #BCFG3_OFS]
                ENDIF

                ENDIF   ; EMC_SETUP


; Setup VPBDIV
                IF      VPBDIV_SETUP <> 0
                LDR     R0, =VPBDIV
                LDR     R1, =VPBDIV_Val
                STR     R1, [R0]
                ENDIF


; Setup PLL
                IF      PLL_SETUP <> 0
                LDR     R0, =PLL_BASE
                MOV     R1, #0xAA
                MOV     R2, #0x55

;  Configure and Enable PLL
                MOV     R3, #PLLCFG_Val
                STR     R3, [R0, #PLLCFG_OFS] 
                MOV     R3, #PLLCON_PLLE
                STR     R3, [R0, #PLLCON_OFS]
                STR     R1, [R0, #PLLFEED_OFS]
                STR     R2, [R0, #PLLFEED_OFS]

;  Wait until PLL Locked
PLL_Loop        LDR     R3, [R0, #PLLSTAT_OFS]
                ANDS    R3, R3, #PLLSTAT_PLOCK
                BEQ     PLL_Loop

;  Switch to PLL Clock
                MOV     R3, #(PLLCON_PLLE:OR:PLLCON_PLLC)
                STR     R3, [R0, #PLLCON_OFS]
                STR     R1, [R0, #PLLFEED_OFS]
                STR     R2, [R0, #PLLFEED_OFS]
                ENDIF   ; PLL_SETUP


; Setup MAM
                IF      MAM_SETUP <> 0
                LDR     R0, =MAM_BASE
                MOV     R1, #MAMTIM_Val
                STR     R1, [R0, #MAMTIM_OFS] 
                MOV     R1, #MAMCR_Val
                STR     R1, [R0, #MAMCR_OFS] 
                ENDIF   ; MAM_SETUP


; Memory Mapping (when Interrupt Vectors are in RAM)
MEMMAP          EQU     0xE01FC040      ; Memory Mapping Control
                IF      :DEF:REMAP
                LDR     R0, =MEMMAP
                IF      :DEF:EXTMEM_MODE
                MOV     R1, #3
                ELIF    :DEF:RAM_MODE
                MOV     R1, #2
                ELSE
                MOV     R1, #1
                ENDIF
                STR     R1, [R0]
                ENDIF

CODE_BASE0      EQU     0x00000000 
CODE_BASE1      EQU     0x80000000
CODE_BASE2      EQU     0x81000000 
MAP_START       EQU     0x40000000
MAP_END         EQU     0x40000040

                IF      :DEF:NO_COPY
                ;LDR     R2, =CODE_BASE2        ;for IDLE operation
                ELSE                            ;=>IF      :DEF:DB_IRAM
                IF      :DEF:REMAP               
                IF      :DEF:VIC_COPY0
                LDR     R2, =CODE_BASE1
                ELIF    :DEF:VIC_COPY1
                LDR     R2, =CODE_BASE2
                ELSE                             ;=>IF      :DEF:VIC_COPY0
                LDR     R2, =CODE_BASE0
                ENDIF
                
                LDR     R0, =MAP_START
                LDR     R1, =MAP_END                   
VIC_COPY        CMP     R0, R1                 
                LDRCC   R3, [R2], #4            ;read 4 bytes from r0 address,r0=r0+4
                STRCC   R3, [R0], #4            ;write 4 bytes to r4 address,r4=r4+4
                BCC     VIC_COPY                ;BCC - Branch if Carry Clear

                ENDIF                           ;=>IF      :DEF:REMAP
                ENDIF                           ;=>IF      :DEF:DB_IRAM 

; Initialise Interrupt System
;  ...

; Setup Stack for each mode

                LDR     R0, =Stack_Top

;  Enter Undefined Instruction Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_UND:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #UND_Stack_Size

;  Enter Abort Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_ABT:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #ABT_Stack_Size

;  Enter FIQ Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_FIQ:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #FIQ_Stack_Size

;  Enter IRQ Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_IRQ:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #IRQ_Stack_Size

;  Enter Supervisor Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_SVC:OR:I_Bit:OR:F_Bit
                MOV     SP, R0
                SUB     R0, R0, #SVC_Stack_Size

;  Enter User Mode and set its Stack Pointer
                MSR     CPSR_c, #Mode_USR
                MOV     SP, R0
                SUB     SL, SP, #USR_Stack_Size


; Enter the C code

                IMPORT  __main
                LDR     R0, =__main
                BX      R0


; User Initial Stack & Heap
                AREA    |.text|, CODE, READONLY

                IMPORT  __use_two_region_memory
                EXPORT  __user_initial_stackheap
__user_initial_stackheap

                LDR     R0, =  Heap_Mem
                LDR     R1, =(Stack_Mem + USR_Stack_Size)
                LDR     R2, = (Heap_Mem +      Heap_Size)
                LDR     R3, = Stack_Mem
                BX      LR


                END

;__user_initial_stackheap() returns the:
;    heap base in r0
;    stack base in r1, that is, the highest address in the stack region
;    heap limit in r2
;    stack limit in r3, that is, the lowest address in the stack region.
                                         
;If this function is re-implemented, it must:
;    use no more than 88 bytes of stack
;    not corrupt registers other than r12 (ip)
;    maintain eight-byte alignment of the heap.