;=========================================
; NAME: 2440INIT.S
; DESC: C start up codes
; Configure memory, ISR ,stacks
;Initialize C-variables
; HISTORY:
; 2002.02.25:kwtark: ver 0.0
; 2002.03.20:purnnamu: Add some functions for testing STOP,Sleep mode
; 2003.03.14:DonGo: Modified for 2440.
;=========================================
GET option.inc
GET memcfg.inc
GET 2440addr.inc
BIT_SELFREFRESH EQU(1<<22) ; bit[22]=1,others=0
;Pre-defined constants 体系的作业形式设定
USERMODE EQU 0x10
FIQMODE EQU 0x11
IRQMODE EQU 0x12
SVCMODE EQU 0x13
ABORTMODE EQU 0x17
UNDEFMODE EQU 0x1b
MODEMASK EQU 0x1f
NOINT EQU 0xc0
;The location of stacks 体系的仓库空间设定
UserStackEQU(_STACK_BASEADDRESS-0x3800);0x33ff4800 ~
SVCStackEQU(_STACK_BASEADDRESS-0x2800);0x33ff5800 ~
UndefStackEQU(_STACK_BASEADDRESS-0x2400);0x33ff5c00 ~
AbortStackEQU(_STACK_BASEADDRESS-0x2000);0x33ff6000 ~
IRQStackEQU(_STACK_BASEADDRESS-0x1000);0x33ff7000 ~
FIQStackEQU(_STACK_BASEADDRESS-0x0);0x33ff8000 ~
;arm处理器有两种作业状况 1.arm:32位 这种作业状况下履行字对准的arm指令 2.Thumb:16位 这种作业状况履行半字对准的Thumb指令
;因为处理器分为16位 32位两种作业状况 程序的编译器也是分16位和32两种编译办法 所以下面的程序用于依据处理器作业状况确认编译器编译办法
;code16伪指令指示汇编编译器后边的指令为16位的thumb指令
;code32伪指令指示汇编编译器后边的指令为32位的arm指令
;这段是为了一致现在的处理器作业状况和软件编译办法(16位编译环境运用tasm.exe编译)
;[ if,| else ,]endif
;Check if tasm.exe(armasm -16…@ADS1.0) is used.
GBLL THUMBCODE ;界说一个全局变量
[ {CONFIG} = 16 ;设置THUMBCODE 为 true表明告知体系当时想用thumb,但实践发动时不可,只能发动后再跳
THUMBCODE SETL {TRUE}
CODE32 ;发动时强制运用32位编译形式
|
THUMBCODE SETL {FALSE} ;假如体系要求是ARM指令,则直接设置THUMBCODE 为 false 阐明当时的是32位编译形式
]
MACRO ;宏界说
MOV_PC_LR
[ THUMBCODE
bx lr
|
movpc,lr
]
MEND
MACRO
MOVEQ_PC_LR
[ THUMBCODE
bxeq lr
|
moveq pc,lr
]
MEND
;留意下面这段程序是个宏界说
;下面包含的HandlerXXX HANDLER HandleXXX将都被下面这段程序打开
;这段程序用于把中止服务程序的首地址装载到pc中,有人称之为“加载程序”。
;本初始化程序界说了一个数据区(在文件最终),32个字空间,寄存相应中止服务程序的首地址。每个字
;空间都有一个标号,以Handle***命名。
;在向量中止形式下运用“加载程序”来履行中止服务程序。
;这儿就有必要讲一下向量中止形式和非向量中止形式的概念
;向量中止形式是当cpu读取坐落0x18处的IRQ中止指令的时分,体系主动读取对应于该中止源确认地址上的;
;指令替代0x18处的指令,经过跳转指令体系就直接跳转到对应地址
;函数中 节省了中止处理时刻提高了中止处理速度标 例如 ADC中止的向量地址为0xC0,则在0xC0处放如下
;代码:ldr PC,=HandlerADC 当ADC中止发生的时分体系会
;主动跳转到HandlerADC函数中
;非向量中止形式处理办法是一种传统的中止处理办法,当体系发生中止的时分,体系将interrupt
;pending寄存器中对应标志方位位 然后跳转到坐落0x18处的一致中止
;函数中 该函数经过读取interrupt pending寄存器中对应标志位 来判别中止源 并依据优先级联系再跳到
;对应中止源的处理代码中
MACRO
$HandlerLabel HANDLER $HandleLabel
$HandlerLabel
subsp,sp,#4;decrement sp(to store jump address)
stmfdsp!,{r0};PUSH the work register to stack(lr doest push because it return to original address)
ldr r0,=$HandleLabel;load the address of HandleXXX to r0
ldr r0,[r0] ;load the contents(service routine start address) of HandleXXX
str r0,[sp,#4] ;store the contents(ISR) of HandleXXX to stack
ldmfd sp!,{r0,pc} ;POP the work register and pc(jump to ISR)
MEND ;将$HandleLabel地址空间中的数据给PC,中止服务程序的进口
IMPORT |Image
Limit| ; End of ROM code (=start of ROM data)
IMPORT |Image
Base| ; Base of RAM to initialise
IMPORT |Image
Base| ; Base and limit of area
IMPORT |Image
Limit| ; to zero initialise
IMPORTMain
AREA Init,CODE,READONLY
ENTRY
;板子上电和复位后,程序开端从坐落0x0处开端履行,硬件刚刚上电复位后 程序从这儿开端履行跳转到标为ResetHandler处履行
;1)The code, which converts to Big-endian, should be in little endian code.
;2)The following little endian code will be compiled in Big-Endian mode.
; The code byte order should be changed as the memory bus width.
;3)The pseudo instruction,DCD cant be used here because the linker generates error.
;条件编译,在编译成机器码前就设定好
ASSERT:DEF:ENDIAN_CHANGE ;判别ENDIAN_CHANGE是否已界说
[ ENDIAN_CHANGE ;假如现已界说了ENDIAN_CHANGE,则判别,这儿是FALSE
ASSERT :DEF:ENTRY_BUS_WIDTH ;判别ENTRY_BUS_WIDTH是否已界说
[ ENTRY_BUS_WIDTH=32 ;假如现已界说了ENTRY_BUS_WIDTH,则判别是不是为32
bChangeBigEndian ;DCD 0xea000007
]
;在bigendian中,地址为A的字单元包含字节单元A,A+1,A+2,A+3,字节单元由高位到低位为A,A+1,A+2,A+3
;地址为A的字单元包含半字单元A,A+2,半字单元由高位到低位为A,A+2
[ ENTRY_BUS_WIDTH=16
andeqr14,r7,r0,lsl #20 ;DCD 0x0007ea00也是b ChangeBigEndian指令,仅仅因为总线不一样而取机器码的次序不一样,
;先取低位->高位 上述指令是经过机器码装换而来的
]
[ ENTRY_BUS_WIDTH=8
streqr0,[r0,-r10,ror #1] ;DCD 0x070000ea也是b ChangeBigEndian指令,仅仅
;因为总线不一样而取机器码的次序不一样
]
|
bResetHandler;here is the first instrument 0x00这是第一条履行的指令
;主要内容为:关看门狗定时器,关中止,初始化 PLL 和时钟,初始化存储器体系。
]
bHandlerUndef;handler for Undefined mode
bHandlerSWI;handler for SWI interrupt
bHandlerPabort;handler for PAbort
bHandlerDabort;handler for DAbort
b.;reserved
bHandlerIRQ;handler for IRQ interrupt
bHandlerFIQ;handler for FIQ interrupt
;@0x20
bEnterPWDN; Must be @0x20.
;经过设置CP15的C1的位7,设置存储格局为Bigendian,三种总线办法
ChangeBigEndian
;@0x24
[ ENTRY_BUS_WIDTH=32
DCD0xee110f10;0xee110f10 => mrc p15,0,r0,c1,c0,0
DCD0xe3800080;0xe3800080 => orr r0,r0,#0x80; //Big-endian
DCD0xee010f10;0xee010f10 => mcr p15,0,r0,c1,c0,0
;对存储器操控寄存器操作,指定内存形式为Big-endian
;因为刚开端CPU都是依照32位总线的指令格局运转的,假如选用其他的话,CPU辨认不了,有必要转化
;但当体系初始化好今后,则CPU能主动辨认
]
[ ENTRY_BUS_WIDTH=16
DCD 0x0f10ee11
DCD 0x0080e380
DCD 0x0f10ee01
;因为选用Big-endian形式,选用16位总线时,物理地址的高位和数据的位置对应
;所以指令的机器码也相应的凹凸对调
]
[ ENTRY_BUS_WIDTH=8
DCD 0x100f11ee
DCD 0x800080e3
DCD 0x100f01ee
]
DCD 0xffffffff ;swinv 0xffffff is similar with NOP and run well in both endian mode.
DCD 0xffffffff
DCD 0xffffffff
DCD 0xffffffff
DCD 0xffffffff
b ResetHandler
;Function for entering power down mode
; 1. SDRAM should be in self-refresh mode.
; 2. All interrupt should be maksked for SDRAM/DRAM self-refresh.
; 3. LCD controller should be disabled for SDRAM/DRAM self-refresh.
; 4. The I-cache may have to be turned on.
; 5. The location of the following code may have not to be changed.
;void EnterPWDN(int CLKCON);
EnterPWDN
mov r2,r0;r2=rCLKCON 保存原始数据 0x4c00000c 使能各模块的时钟输入
tst r0,#0x8;SLEEP mode? 测验bit[3] SLEEP mode? 1=>sleep
bne ENTER_SLEEP ;C=0,即TST成果非0,bit[3]=1
;进入PWDN后假如不是sleep则进入stop
;进入Stop mode
ENTER_STOP
ldr r0,=REFRESH
ldr r3,[r0];r3=rREFRESH
mov r1, r3
orr r1, r1, #BIT_SELFREFRESH
str r1, [r0];Enable SDRAM self-refresh
mov r1,#16;wait until self-refresh is issued. may not be needed.
0subs r1,r1,#1
bne %B0
ldr r0,=CLKCON;enter STOP mode.
str r2,[r0]
mov r1,#32
0subs r1,r1,#1;1) wait until the STOP mode is in effect.
bne %B0;2) Or wait here until the CPU&Peripherals will be turned-off
; Entering SLEEP mode, only the reset by wake-up is available.
ldr r0,=REFRESH ;exit from SDRAM self refresh mode.
str r3,[r0]
MOV_PC_LR
ENTER_SLEEP
;NOTE.
;1) rGSTATUS3 should have the return address after wake-up from SLEEP mode.
ldr r0,=REFRESH
ldr r1,[r0];r1=rREFRESH
orr r1, r1, #BIT_SELFREFRESH
str r1, [r0];Enable SDRAM self-refresh
mov r1,#16;Wait until self-refresh is issued,which may not be needed.
0subs r1,r1,#1
bne %B0
ldrr1,=MISCCR
ldrr0,[r1]
orrr0,r0,#(7<<17) ;Set SCLK0=0, SCLK1=0, SCKE=0.
strr0,[r1]
ldr r0,=CLKCON; Enter sleep mode
str r2,[r0]
b .;CPU will die here.
;进入Sleep Mode,1)设置SDRAM为self-refresh
; 2)设置MISCCR bit[17] 1:sclk0=sclk 0:sclk0=0
;bit[18] 1:sclk1=sclk 0:sclk1=0
;bit[19] 1:Self refresh retain enable
;0:Self refresh retain disable
;When 1, After wake-up from sleep, The self-refresh will be retained.
WAKEUP_SLEEP
;Release SCLKn after wake-up from the SLEEP mode.
ldrr1,=MISCCR
ldrr0,[r1]
bicr0,r0,#(7<<17) ;SCLK0:0->SCLK, SCLK1:0->SCLK, SCKE:0->=SCKE.
strr0,[r1]
;设置MISCCR
;Set memory control registers
ldrr0,=SMRDATA
ldrr1,=BWSCON;BWSCON Address;总线宽度和等候操控寄存器
addr2, r0, #52;End address of SMRDATA
0
ldrr3, [r0], #4 ;数据处理后R0自加4,[R0]->R3,R0+4->R0
strr3, [r1], #4
cmpr2, r0
bne%B0
;设置一切的memory control register,他的初始地址为BWSCON,初始化
;数据在以SMRDATA为开端的存储区
mov r1,#256
0subs r1,r1,#1;1) wait until the SelfRefresh is released.
bne %B0
ldr r1,=GSTATUS3 ;GSTATUS3 has the start address just after SLEEP wake-up
ldr r0,[r1]
mov pc,r0
;跳出Sleep Mode,进入Sleep状况前的PC
;异常中止宏调用
LTORG
HandlerFIQ HANDLER HandleFIQ
HandlerIRQ HANDLER HandleIRQ
HandlerUndef HANDLER HandleUndef
HandlerSWI HANDLER HandleSWI
HandlerDabort HANDLER HandleDabort
HandlerPabort HANDLER HandlePabort
IsrIRQ
subsp,sp,#4 ;reserved for PC
stmfdsp!,{r8-r9}
ldrr9,=INTOFFSET ;地址为0x4a000014的空间存着中止的偏移
ldrr9,[r9]
ldrr8,=HandleEINT0
addr8,r8,r9,lsl #2
ldrr8,[r8]
strr8,[sp,#8]
ldmfdsp!,{r8-r9,pc}
;外部中止号判别,经过中止服务程序进口地址存储器的地址偏移确认
;PC=[HandleEINT0+[INTOFFSET]]
;=======
; ENTRY
;=======
;扳子上电和复位后 程序开端从坐落0x0履行b ResetHandler 程序从跳转到这儿履行
;板子上电复位后 履行几个过程这儿经过标号在注释中加1,2,3….标明 标号表明履行次序
ResetHandler
;1.制止看门狗 屏蔽一切中止
;WTCON界说在2440addr.inc里边,WTCON EQU 0x53000000
;把WTCON地址放到R0里,然后在设置r1为0,最终把r1中的0值
;拷贝到r0所指向的地址里边,即禁用watch dog
ldrr0,=WTCON ;watch dog disable
ldrr1,=0x0
strr1,[r0]
;底子同上,INTMSK 0x4A000008 R/W Interrupt mask control
ldrr0,=INTMSK
ldrr1,=0xffffffff ;all interrupt disable封闭一切中止
strr1,[r0]
;底子同上,INTMSK 0X4A00001C R/W SubInterrupt mask control
ldrr0,=INTSUBMSK
ldrr1,=0x3ff;all sub interrupt disable封闭一切子中止(这个寄存器有11位)
strr1,[r0]
;因为条件为FALSE,这段底子就不会履行
[ {FALSE}
; rGPFDAT = (rGPFDAT & ~(0xf<<4)) | ((~data & 0xf)<<4);
; Led_Display
ldrr0,=GPFCON
ldrr1,=0x5500
strr1,[r0]
ldrr0,=GPFDAT
ldrr1,=0x10
strr1,[r0]
]
;2.依据作业频率设置pll
;这儿介绍一下计算公式
;Fpllo=(m*Fin)/(p*2^s)
;m=MDIV+8,p=PDIV+2,s=SDIV
;The proper range of P and M: 1<=P<=62, 1<=M<=248
;Fpllo有必要大于20Mhz小于66Mhz
;Fpllo*2^s有必要小于170Mhz
;如下面的PLLCON设定中的M_DIV P_DIV S_DIV是取自option.h中
;#elif (MCLK==40000000)
;#define PLL_M (0x48)
;#define PLL_P (0x3)
;#define PLL_S (0x2)
;所以m=MDIV+8=80,p=PDIV+2=5,s=SDIV=2
;硬件运用晶振为10Mhz,即Fin=10Mhz
;Fpllo=80*10/5*2^2=40Mhz
;设置PLL的重置推迟
;因为在更改了主时钟操控器(MPLL)之后,新的频率需求必定时刻往后才干安稳
;所以需求等候一段时刻,而这个等候的时刻便是运用LOCKTIME(地址为0x4c000000)寄存器来设置的
;LOCKTIME[15:00] MPLL lock time count value for FCLK, HCLK, and PCLK
;LOCKTIME[32:16] UPLL lock time count value for UCLK.
;FCLK用于CPU核
;HCLK用于AHB总线的设备(比方SDRAM)
;PCLK用于APB总线的设备(比方UART)
;UPLL为USB的操控时钟,依据USB标准,好像是48MHz
;ARM920T内核运用FCLK
;内存操控器,LCD操控器等运用HCLK;
; 看门狗、串口等运用PCLK
