os/boot/boot.68k

163 lines
6.9 KiB
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.equ SEC_BUF_START, 0x400
.equ PHDR_BUF_START, 0x600
.equ PHDR_BUF_SEC_SIZE, 5
.equ STORAGE_SEC, 0x0
.equ STORAGE_CNT, 0x4
.equ STORAGE_CMD, 0x8
.equ STORAGE_DMADR, 0xC
.global _start
_start:
move.w #0x4, d0 | Find a storage card
bsr.w find_first_card
| load the first PHDR_BUF_SEC_SIZE sectors of the ELF kernel binary off the disk
move.l #PHDR_BUF_START, a1 | Set the destination address to PHDR_BUF_START
move.l #0x2, d0 | Set the starting sector number to 2
move.l #PHDR_BUF_SEC_SIZE, d1 | Set the sector count
bsr.b read_sectors
move.l (PHDR_BUF_START + 0x1C), d0 | Load the offset of the program headers in the file
move.l #PHDR_BUF_START, a1 | Put the address of the program headers in a1
adda.w d0, a1
move.w (PHDR_BUF_START + 0x2C), d0 | Put the number of program headers - 1 in d0
subq.w #0x1, d0
phead_loop:
move.l (a1), d1 | If the type of the program header isn't 1 (LOAD), skip the header
cmpi.l #0x1, d1
bne.b next_seg
| Zero the destination memory
move.l (20, a1), d1 | Put the memory size - 1 in d1
subq.l #0x1, d1
move.l (8, a1), a2 | Put the starting memory address in a2
zero_loop:
move.b #0, (a2)+ | Zero a byte of the destination memory
dbra d1, zero_loop | Loop back if there is more to zero
| Load the segment data off disk
move.l (16, a1), d1 | Put the file size in d1
beq.b next_seg | If the file size is 0, skip the copy (ex, .bss section)
move.l a1,a6 | Save a1 in a6
move.l d0,d4 | Save d0 in d4
move.l (4, a1), d0 | Put the starting byte number in d0
addi.l #0x400, d0 | Add the 2 sector offset in the disk for the kernel file
move.l (8, a1), a1 | Put the destination memory address in a1
bsr.b read_bytes
move.l a6,a1 | Restore a1 from a6
move.l d4,d0 | Restore d0 from d4
next_seg:
lea (0x20, a1), a1 | Advance a1 to point to the next program header
dbra d0, phead_loop | If there are more program headers, loop back
move.l (PHDR_BUF_START + 0x18), a1 | Load the entry point of the program into a1
jmp (a1) | Jump to the entry point of the program
| Finds the first card with the type in d0.b, and returns it's IO base address in a0, or 0 if not found
| Clobbers d1
find_first_card:
move.l #0xff0000, a0 | a0 holds the address of the current card
ffc_loop:
lea (0x100, a0), a0 | Move to the next card
move.w (0xfe, a0), d1 | Load the type of the card into d1
beq.b ffc_done | If the type is 0 (empty slot), we have scanned all cards, so exit the loop
cmp.w d0, d1 | If the card is the type we want, return with the address in a0
beq.b ffc_done
bra.b ffc_loop | Loop back and check the next card
ffc_done:
rts
| Reads sectors from a storage card
| Card base in a0
| Destination in a1
| Start sector in d0.l
| Sector count in d1.l
read_sectors:
move.l d0, (STORAGE_SEC, a0) | Set the sector number
move.l d1, (STORAGE_CNT, a0) | Set the sector count
move.l a1, (STORAGE_DMADR, a0) | Set the destination address
move.w #0x1, (STORAGE_CMD, a0) | Issue a DMA read command
read_sectors_done:
rts
| Reads bytes off a storage card
| Card base in a0
| Destination in a1
| Start byte in d0.l
| Byte count in d1.l
read_bytes:
move.l d0, d6 | Save start byte in d6
move.l d1, d7 | Save byte count in d7
move.l a1, a6 | Save destination in a6
lsr.l #8, d0 | Divide start byte by 512 to compute starting sector
lsr.l #1, d0
move.l d0, d5 | Save the starting sector in d5
move.l #1, d1 | Read the starting sector into the sector buffer
move.l #SEC_BUF_START, a1
bsr.b read_sectors
move.l a6, a2 | Load the destination into a2
move.l d6, d0 | Load the start byte into d0
andi.l #0x1FF, d0 | Modulus start byte by 512 to compute sector data offset
move.l #0x1FF, d1 | Compute the number of bytes to transfer by subtracting the offset from 512
sub.l d0, d1
cmp d7, d1 | Compare the number of bytes to transfer with the byte count
ble.b count_ok | If it was less than the byte count, do not adjust the bytes to transfer
move.l d7, d1 | Otherwise, cap the transfer count to the total byte count
count_ok:
move.l d1, d6 | Save the number of bytes in d6
subi.l #1, d1 | Subtract 1 from the number of bytes to account for the extra loop done by dbra
start_sec_loop: | Transfer the required bytes from the start sector to the destination buffer
move.b (a1)+, (a2)+
dbra d1, start_sec_loop
move.l d5, d0 | Load the starting sector into d0
addi #1, d0 | Compute the start of the middle sectors by adding 1 to the starting sector
move.l d6, d2 | Load the number of bytes transferred into d2
move.l d7, d1 | Load the byte count into d1
sub.l d2, d1 | Compute the number of remaining bytes by subtracting the number of transferred bytes from the byte count
move.l d1, d6 | Save the number of remaining bytes in d6
lsr.l #8, d1 | Divide remaining bytes by 512 to compute the number of middle sectors
lsr.l #1, d1
move.l a2, a1 | Transfer the sector data to the end of the start sector bytes
bsr.b read_sectors | Read the middle sectors
move.l d1, d5 | Save the number of middle sectors in d5
lsl.l #8, d1 | Multiply the number of middle sectors by 512 to compute the number of bytes transferred
lsl.l #1, d1
adda.l d1, a2 | Add the number of bytes transferred to a2
add.l d5, d0 | Compute the end sector number by adding the start and count of the middle sectors
move.l #1, d1 | Set the number of sectors to read to 1
move.l #SEC_BUF_START, a1 | Set the read address of the sector to the sector buffer
bsr.b read_sectors | Read the end sector
move.l d6, d1 | Load the number of remaining bytes into d1
end_sec_loop: | Transfer the required bytes from the start sector to the destination buffer
move.b (a1)+, (a2)+
dbra d1, end_sec_loop
read_bytes_done:
rts
.if . != 512
.org 511
.byte 0
.endif
/* read_bytes theory: */
/* Start sector: Start byte / 512 */
/* Offset in start sector: Start byte % 512 */
/* Rem bytes: Byte count - (512 - Offset in start sector) */
/* Middle sectors start: start sector + 1 */
/* Middle sectors count: Rem bytes / 512 */
/* End sector: Middle sectors start + Middle sectors count */
/* End sector copy length: Rem bytes % 512 */
/* 0 1 2 3 4 5 6 7 8 9 A B C D E F * /
/* dddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddddd */
/* 0------------------------------------------------------------------------------------------S--------------------------------------------------------------------------------------E */
/* 91 bytes . 88 bytes */
/* Start sector: 91 / 16 = 5 */
/* Offset in start sector: 91 % 16 = 11 */
/* Rem bytes: 88 - (16 - 11) = 83 */
/* Middle sectors start: 5 + 1 = 6 */
/* Middle sectors count: 83 / 16 = 5 */
/* End sector: 6 + 5 = B */
/* End sector copy length: 83 % 16 = 3 */