| ;================================================================== |
| ; Copyright ARM Ltd 2005. All rights reserved. |
| ; |
| ; Cortex-A8 Dhrystone example - Startup Code |
| ;================================================================== |
| |
| PRESERVE8 |
| AREA CORTEXA8, CODE, READONLY |
| |
| ENTRY |
| |
| ; Standard definitions of mode bits and interrupt (I & F) flags in PSRs |
| |
| Mode_USR EQU 0x10 |
| Mode_FIQ EQU 0x11 |
| Mode_IRQ EQU 0x12 |
| Mode_SVC EQU 0x13 |
| Mode_ABT EQU 0x17 |
| Mode_UNDEF EQU 0x1B |
| Mode_SYS EQU 0x1F |
| |
| I_Bit EQU 0x80 ; when I bit is set, IRQ is disabled |
| F_Bit EQU 0x40 ; when F bit is set, FIQ is disabled |
| |
| ;================================================================== |
| ; Disable Cortex-A8 MMU if enabled |
| ;================================================================== |
| |
| EXPORT Start |
| |
| Start |
| |
| MRC p15, 0, r0, c1, c0, 0 ; Read CP15 Control Register into r0 |
| TST r0, #0x1 ; Is the MMU enabled? |
| BICNE r0, r0, #0x1 ; Clear bit 0 |
| MCRNE p15, 0, r0, c1, c0, 0 ; Write value back |
| |
| ;================================================================== |
| ; Initialise Supervisor Mode Stack |
| ; Note stack must be 8 byte aligned. |
| ;================================================================== |
| |
| IMPORT ||Image$$STACK$$ZI$$Limit|| ; Linker symbol from scatter file |
| LDR SP, =||Image$$STACK$$ZI$$Limit|| |
| |
| ;================================================================== |
| ; TLB maintenance, Invalidate Data and Instruction TLB's |
| ;================================================================== |
| |
| MOV r0,#0 |
| MCR p15, 0, r0, c8, c7, 0 ; Cortex-A8 I-TLB and D-TLB invalidation |
| |
| ;================================================================== |
| ; Cache Invalidation code for Cortex-A8 |
| ;================================================================== |
| |
| ; Invalidate L1 Instruction Cache |
| |
| MRC p15, 1, r0, c0, c0, 1 ; Read CLIDR |
| TST r0, #0x3 ; Harvard Cache? |
| MOV r0, #0 |
| MCRNE p15, 0, r0, c7, c5, 0 ; Invalidate Instruction Cache |
| |
| ; Invalidate Data/Unified Caches |
| |
| MRC p15, 1, r0, c0, c0, 1 ; Read CLIDR |
| ANDS r3, r0, #&7000000 |
| MOV r3, r3, LSR #23 ; Total cache levels << 1 |
| BEQ Finished |
| |
| MOV r10, #0 ; R10 holds current cache level << 1 |
| Loop1 ADD r2, r10, r10, LSR #1 ; R2 holds cache "Set" position |
| MOV r1, r0, LSR r2 ; Bottom 3 bits are the Cache-type for this level |
| AND r1, R1, #7 ; Get those 3 bits alone |
| CMP r1, #2 |
| BLT Skip ; No cache or only instruction cache at this level |
| |
| MCR p15, 2, r10, c0, c0, 0 ; Write the Cache Size selection register |
| MOV r1, #0 |
| MCR p15, 0, r1, c7, c5, 4 ; PrefetchFlush to sync the change to the CacheSizeID reg |
| MRC p15, 1, r1, c0, c0, 0 ; Reads current Cache Size ID register |
| AND r2, r1, #&7 ; Extract the line length field |
| ADD r2, r2, #4 ; Add 4 for the line length offset (log2 16 bytes) |
| LDR r4, =0x3FF |
| ANDS r4, r4, r1, LSR #3 ; R4 is the max number on the way size (right aligned) |
| CLZ r5, r4 ; R5 is the bit position of the way size increment |
| LDR r7, =0x00007FFF |
| ANDS r7, r7, r1, LSR #13 ; R7 is the max number of the index size (right aligned) |
| |
| Loop2 MOV r9, r4 ; R9 working copy of the max way size (right aligned) |
| |
| Loop3 ORR r11, r10, r9, LSL r5 ; Factor in the Way number and cache number into R11 |
| ORR r11, r11, r7, LSL r2 ; Factor in the Set number |
| MCR p15, 0, r11, c7, c14, 2 ; Clean and Invalidate by set/way |
| SUBS r9, r9, #1 ; Decrement the Way number |
| BGE Loop3 |
| SUBS r7, r7, #1 ; Decrement the Set number |
| BGE Loop2 |
| Skip ADD r10, r10, #2 ; increment the cache number |
| CMP r3, r10 |
| BGT Loop1 |
| |
| Finished |
| |
| |
| ;=================================================================== |
| ; Cortex-A8 MMU Configuration |
| ; Set translation table base |
| ;=================================================================== |
| |
| |
| IMPORT ||Image$$TTB$$ZI$$Base|| ; from scatter file.; |
| |
| ; Cortex-A8 supports two translation tables |
| ; Configure translation table base (TTB) control register cp15,c2 |
| ; to a value of all zeros, indicates we are using TTB register 0. |
| |
| MOV r0,#0x0 |
| MCR p15, 0, r0, c2, c0, 2 |
| |
| ; write the address of our page table base to TTB register 0.; |
| ; We are setting to outer-noncachable [4:3] is zero |
| |
| LDR r0,=||Image$$TTB$$ZI$$Base|| |
| MCR p15, 0, r0, c2, c0, 0 |
| |
| |
| ;=================================================================== |
| ; Cortex-A8 PAGE TABLE generation, using standard Arch v6 tables |
| ; |
| ; AP[11:10] - Access Permissions = b11, Read/Write Access |
| ; Domain[8:5] - Domain = b1111, Domain 15 |
| ; Type[1:0] - Descriptor Type = b10, 1Mb descriptors |
| ; |
| ; TEX C B |
| ; 000 0 0 Strongly Ordered |
| ; 001 1 1 Outer and inner write back, write allocate Normal |
| ;=================================================================== |
| |
| LDR r1,=0xfff ; loop counter |
| LDR r2,=2_00000000000000000000110111100010 |
| |
| ; r0 contains the address of the translation table base |
| ; r1 is loop counter |
| ; r2 is level1 descriptor (bits 19:0) |
| |
| ; use loop counter to create 4096 individual table entries |
| ; this writes from address 0x7FFC down to 0x4000 in word steps (4bytes). |
| |
| init_ttb_1 |
| |
| ORR r3, r2, r1, LSL#20 ; r3 now contains full level1 descriptor to write |
| STR r3, [r0, r1, LSL#2] ; str table entry at TTB base + loopcount*4 |
| SUBS r1, r1, #1 ; decrement loop counter |
| BPL init_ttb_1 |
| |
| ; In this example we will change the cacheable attribute in the first descriptor. |
| ; Virtual memory from 0 to 1MB will be cacheable (write back mode). |
| ; TEX[14:12]=001 and CB[3:2]= 11, Outer and inner write back, write allocate. |
| |
| ORR r3,r3,#2_0000000001100 ; Set CB bits |
| ORR r3,r3,#2_1000000000000 ; Set TEX bits |
| STR r3,[r0] |
| |
| ADD r2, r3, #0x100000 ; alter r3 to have correct base address for second descriptor (flat mapping) |
| STR r2, [r0, #4] ; store the new descriptor at r0 + 4 (overwrite second section descriptor) |
| |
| ADD r2, r3, #0x200000 ; alter r3 to have correct base address for 3 descriptor (flat mapping) |
| STR r2, [r0, #8] ; store the new descriptor at r0 + 4 (overwrite second section descriptor) |
| |
| ADD r2, r3, #0x300000 ; alter r3 to have correct base address for 4 descriptor (flat mapping) |
| STR r2, [r0, #0xc] ; store the new descriptor at r0 + 4 (overwrite second section descriptor) |
| |
| ADD r2, r3, #0x400000 ; alter r3 to have correct base address for 5 descriptor (flat mapping) |
| STR r2, [r0, #0x10] ; store the new descriptor at r0 + 4 (overwrite second section descriptor) |
| |
| ADD r2, r3, #0x500000 ; alter r3 to have correct base address for 6 descriptor (flat mapping) |
| STR r2, [r0, #0x14] ; store the new descriptor at r0 + 4 (overwrite second section descriptor) |
| |
| ADD r2, r3, #0x600000 ; alter r3 to have correct base address for 7 descriptor (flat mapping) |
| STR r2, [r0, #0x18] ; store the new descriptor at r0 + 4 (overwrite second section descriptor) |
| |
| ADD r2, r3, #0x700000 ; alter r3 to have correct base address for 8 descriptor (flat mapping) |
| STR r2, [r0, #0x1c] ; store the new descriptor at r0 + 4 (overwrite second section descriptor) |
| |
| ADD r2, r3, #0x800000 ; alter r3 to have correct base address for 9 descriptor (flat mapping) |
| STR r2, [r0, #0x20] ; store the new descriptor at r0 + 4 (overwrite second section descriptor) |
| |
| ADD r2, r3, #0x900000 ; alter r3 to have correct base address for 10 descriptor (flat mapping) |
| STR r2, [r0, #0x24] ; store the new descriptor at r0 + 4 (overwrite second section descriptor) |
| |
| ADD r2, r3, #0xa00000 ; alter r3 to have correct base address for 11 descriptor (flat mapping) |
| STR r2, [r0, #0x28] ; store the new descriptor at r0 + 4 (overwrite second section descriptor) |
| |
| ADD r2, r3, #0xb00000 ; alter r3 to have correct base address for 12 descriptor (flat mapping) |
| STR r2, [r0, #0x2c] ; store the new descriptor at r0 + 4 (overwrite second section descriptor) |
| |
| ADD r2, r3, #0xc00000 ; alter r3 to have correct base address for 13 descriptor (flat mapping) |
| STR r2, [r0, #0x30] ; store the new descriptor at r0 + 4 (overwrite second section descriptor) |
| |
| ;=================================================================== |
| ; Setup domain control register - Enable all domains to client mode |
| ;=================================================================== |
| |
| MRC p15, 0, r0, c3, c0, 0 ; Read Domain Access Control Register |
| LDR r0, =0x55555555 ; Initialize every domain entry to b01 (client) |
| MCR p15, 0, r0, c3, c0, 0 ; Write Domain Access Control Register |
| |
| ;=================================================================== |
| ; Setup L2 Cache - L2 Cache Auxiliary Control |
| ;=================================================================== |
| |
| MOV r0, #0 |
| ;MCR p15, 1, r0, c9, c0, 2 ; Write L2 Auxilary Control Register |
| |
| ;================================================================== |
| ; Enable access to NEON/VFP by enabling access to Coprocessors 10 and 11. |
| ; Enables Full Access i.e. in both priv and non priv modes |
| ;================================================================== |
| |
| MRC p15, 0, r0, c1, c0, 2 ; read CP access register |
| ORR r0, r0, #(0x3 <<20) ; enable access CP 10 |
| ORR r0, r0, #(0x3 <<22) ; enable access CP 11 |
| MCR p15, 0, r0, c1, c0, 2 ; write CP access register back |
| |
| ;================================================================== |
| ; Switch on the VFP and Neon Hardware |
| ;================================================================= |
| |
| MOV r0, #0 ; Set up a register |
| ORR r0, r0, #(0x1 << 30) |
| FMXR FPEXC, r0 ; Write FPEXC register, EN bit set. |
| |
| ;=================================================================== |
| ; Enable MMU and Branch to __main |
| ;=================================================================== |
| |
| IMPORT __main ; before MMU enabled import label to __main |
| LDR r12,=__main ; save this in register for possible long jump |
| |
| |
| MRC p15, 0, r0, c1, c0, 0 ; read CP15 register 1 into r0 |
| ORR r0, r0, #0x1 ; enable MMU before scatter loading |
| MCR p15, 0, r0, c1, c0, 0 ; write CP15 register 1 |
| |
| |
| ; Now the MMU is enabled, virtual to physical address translations will occur. |
| ; This will affect the next instruction fetches. |
| ; |
| ; The two instructions currently in the ARM pipeline will have been fetched |
| ; before the MMU was enabled. This property is useful because the next two |
| ; instructions are safe even if new instruction fetches fail. If this routine |
| ; was mapped out of the new virtual memory map, the branch to __main would |
| ; still succeed. |
| |
| BX r12 ; branch to __main C library entry point |
| |
| END ; mark the end of this file |
| |