Lesson 18

2024-10-27 20:34:19 +00:00 · 2015-02-03 19:12:51 +01:00 · 2015-02-03 19:12:51 +01:00 · 418bb11305
commit 418bb11305
parent 69a7c1c2a6
17 changed files with 412 additions and 16 deletions
--- a/14-checkpoint/boot/32bit_print.asm
+++ b/14-checkpoint/boot/32bit_print.asm
@ -1 +0,0 @@
 ../../08-32bit-print/32bit-print.asm
--- a/14-checkpoint/boot/32bit_print.asm
+++ b/14-checkpoint/boot/32bit_print.asm
@ -0,0 +1,26 @@
 [bits 32] ; using 32-bit protected mode
 ; this is how constants are defined
 VIDEO_MEMORY equ 0xb8000
 WHITE_OB_BLACK equ 0x0f ; the color byte for each character
 print_string_pm:
    pusha
    mov edx, VIDEO_MEMORY
 print_string_pm_loop:
    mov al, [ebx] ; [ebx] is the address of our character
    mov ah, WHITE_OB_BLACK
    cmp al, 0 ; check if end of string
    je print_string_pm_done
    mov [edx], ax ; store character + attribute in video memory
    add ebx, 1 ; next char
    add edx, 2 ; next video memory position
    jmp print_string_pm_loop
 print_string_pm_done:
    popa
    ret
--- a/14-checkpoint/boot/disk.asm
+++ b/14-checkpoint/boot/disk.asm
@ -1 +0,0 @@
 ../../07-bootsector-disk/boot_sect_disk.asm
--- a/14-checkpoint/boot/disk.asm
+++ b/14-checkpoint/boot/disk.asm
@ -0,0 +1,46 @@
 ; load 'dh' sectors from drive 'dl' into ES:BX
 disk_load:
    pusha
    ; reading from disk requires setting specific values in all registers
    ; so we will overwrite our input parameters from 'dx'. Let's save it
    ; to the stack for later use.
    push dx
    mov ah, 0x02 ; ah <- int 0x13 function. 0x02 = 'read'
    mov al, dh   ; al <- number of sectors to read (0x01 .. 0x80)
    mov cl, 0x02 ; cl <- sector (0x01 .. 0x11)
                 ; 0x01 is our boot sector, 0x02 is the first 'available' sector
    mov ch, 0x00 ; ch <- cylinder (0x0 .. 0x3FF, upper 2 bits in 'cl')
    ; dl <- drive number. Our caller sets it as a parameter and gets it from BIOS
    ; (0 = floppy, 1 = floppy2, 0x80 = hdd, 0x81 = hdd2)
    mov dh, 0x00 ; dh <- head number (0x0 .. 0xF)
    ; [es:bx] <- pointer to buffer where the data will be stored
    ; caller sets it up for us, and it is actually the standard location for int 13h
    int 0x13      ; BIOS interrupt
    jc disk_error ; if error (stored in the carry bit)
    pop dx
    cmp al, dh    ; BIOS also sets 'al' to the # of sectors read. Compare it.
    jne sectors_error
    popa
    ret
 disk_error:
    mov bx, DISK_ERROR
    call print
    call print_nl
    mov dh, ah ; ah = error code, dl = disk drive that dropped the error
    call print_hex ; check out the code at http://stanislavs.org/helppc/int_13-1.html
    jmp disk_loop
 sectors_error:
    mov bx, SECTORS_ERROR
    call print
 disk_loop:
    jmp $
 DISK_ERROR: db "Disk read error", 0
 SECTORS_ERROR: db "Incorrect number of sectors read", 0
--- a/14-checkpoint/boot/gdt.asm
+++ b/14-checkpoint/boot/gdt.asm
@ -1 +0,0 @@
 ../../09-32bit-gdt/32bit-gdt.asm
--- a/14-checkpoint/boot/gdt.asm
+++ b/14-checkpoint/boot/gdt.asm
@ -0,0 +1,35 @@
 gdt_start: ; don't remove the labels, they're needed to compute sizes and jumps
    ; the GDT starts with a null 8-byte
    dd 0x0 ; 4 byte
    dd 0x0 ; 4 byte
 ; GDT for code segment. base = 0x00000000, length = 0xfffff
 ; for flags, refer to os-dev.pdf document, page 36
 gdt_code: 
    dw 0xffff    ; segment length, bits 0-15
    dw 0x0       ; segment base, bits 0-15
    db 0x0       ; segment base, bits 16-23
    db 10011010b ; flags (8 bits)
    db 11001111b ; flags (4 bits) + segment length, bits 16-19
    db 0x0       ; segment base, bits 24-31
 ; GDT for data segment. base and length identical to code segment
 ; some flags changed, again, refer to os-dev.pdf
 gdt_data:
    dw 0xffff
    dw 0x0
    db 0x0
    db 10010010b
    db 11001111b
    db 0x0
 gdt_end:
 ; GDT descriptor
 gdt_descriptor:
    dw gdt_end - gdt_start - 1 ; size (16 bit), always one less of its true size
    dd gdt_start ; address (32 bit)
 ; define some constants for later use
 CODE_SEG equ gdt_code - gdt_start
 DATA_SEG equ gdt_data - gdt_start
--- a/14-checkpoint/boot/kernel_entry.asm
+++ b/14-checkpoint/boot/kernel_entry.asm
@ -1 +0,0 @@
 ../../13-kernel-barebones/kernel_entry.asm
--- a/14-checkpoint/boot/kernel_entry.asm
+++ b/14-checkpoint/boot/kernel_entry.asm
@ -0,0 +1,4 @@
 [bits 32]
 [extern main] ; Define calling point. Must have same name as kernel.c 'main' function
 call main ; Calls the C function. The linker will know where it is placed in memory
 jmp $
--- a/14-checkpoint/boot/print.asm
+++ b/14-checkpoint/boot/print.asm
@ -1 +0,0 @@
 ../../05-bootsector-functions-strings/boot_sect_print.asm
--- a/14-checkpoint/boot/print.asm
+++ b/14-checkpoint/boot/print.asm
@ -0,0 +1,37 @@
 print:
    pusha
 ; keep this in mind:
 ; while (string[i] != 0) { print string[i]; i++ }
 ; the comparison for string end (null byte)
 start:
    mov al, [bx] ; 'bx' is the base address for the string
    cmp al, 0 
    je done
    ; the part where we print with the BIOS help
    mov ah, 0x0e
    int 0x10 ; 'al' already contains the char
    ; increment pointer and do next loop
    add bx, 1
    jmp start
 done:
    popa
    ret
 print_nl:
    pusha
    mov ah, 0x0e
    mov al, 0x0a ; newline char
    int 0x10
    mov al, 0x0d ; carriage return
    int 0x10
    popa
    ret
--- a/14-checkpoint/boot/print_hex.asm
+++ b/14-checkpoint/boot/print_hex.asm
@ -1 +0,0 @@
 ../../05-bootsector-functions-strings/boot_sect_print_hex.asm
--- a/14-checkpoint/boot/print_hex.asm
+++ b/14-checkpoint/boot/print_hex.asm
@ -0,0 +1,46 @@
 ; receiving the data in 'dx'
 ; For the examples we'll assume that we're called with dx=0x1234
 print_hex:
    pusha
    mov cx, 0 ; our index variable
 ; Strategy: get the last char of 'dx', then convert to ASCII
 ; Numeric ASCII values: '0' (ASCII 0x30) to '9' (0x39), so just add 0x30 to byte N.
 ; For alphabetic characters A-F: 'A' (ASCII 0x41) to 'F' (0x46) we'll add 0x40
 ; Then, move the ASCII byte to the correct position on the resulting string
 hex_loop:
    cmp cx, 4 ; loop 4 times
    je end
    ; 1. convert last char of 'dx' to ascii
    mov ax, dx ; we will use 'ax' as our working register
    and ax, 0x000f ; 0x1234 -> 0x0004 by masking first three to zeros
    add al, 0x30 ; add 0x30 to N to convert it to ASCII "N"
    cmp al, 0x39 ; if > 9, add extra 8 to represent 'A' to 'F'
    jle step2
    add al, 7 ; 'A' is ASCII 65 instead of 58, so 65-58=7
 step2:
    ; 2. get the correct position of the string to place our ASCII char
    ; bx <- base address + string length - index of char
    mov bx, HEX_OUT + 5 ; base + length
    sub bx, cx  ; our index variable
    mov [bx], al ; copy the ASCII char on 'al' to the position pointed by 'bx'
    ror dx, 4 ; 0x1234 -> 0x4123 -> 0x3412 -> 0x2341 -> 0x1234
    ; increment index and loop
    add cx, 1
    jmp hex_loop
 end:
    ; prepare the parameter and call the function
    ; remember that print receives parameters in 'bx'
    mov bx, HEX_OUT
    call print
    popa
    ret
 HEX_OUT:
    db '0x0000',0 ; reserve memory for our new string
--- a/14-checkpoint/boot/switch_pm.asm
+++ b/14-checkpoint/boot/switch_pm.asm
@ -1 +0,0 @@
 ../../10-32bit-enter/32bit-switch.asm
--- a/14-checkpoint/boot/switch_pm.asm
+++ b/14-checkpoint/boot/switch_pm.asm
@ -0,0 +1,22 @@
 [bits 16]
 switch_to_pm:
    cli ; 1. disable interrupts
    lgdt [gdt_descriptor] ; 2. load the GDT descriptor
    mov eax, cr0
    or eax, 0x1 ; 3. set 32-bit mode bit in cr0
    mov cr0, eax
    jmp CODE_SEG:init_pm ; 4. far jump by using a different segment
 [bits 32]
 init_pm: ; we are now using 32-bit instructions
    mov ax, DATA_SEG ; 5. update the segment registers
    mov ds, ax
    mov ss, ax
    mov es, ax
    mov fs, ax
    mov gs, ax
    mov ebp, 0x90000 ; 6. update the stack right at the top of the free space
    mov esp, ebp
    call BEGIN_PM ; 7. Call a well-known label with useful code
--- a/15-video-ports/Makefile
+++ b/15-video-ports/Makefile
@ -1 +0,0 @@
 ../14-checkpoint/Makefile
--- a/15-video-ports/Makefile
+++ b/15-video-ports/Makefile
@ -0,0 +1,46 @@
 C_SOURCES = $(wildcard kernel/*.c drivers/*.c)
 HEADERS = $(wildcard kernel/*.h drivers/*.h)
 # Nice syntax for file extension replacement
 OBJ = ${C_SOURCES:.c=.o}
 # Change this if your cross-compiler is somewhere else
 CC = /usr/local/i386elfgcc/bin/i386-elf-gcc
 GDB = /usr/local/i386elfgcc/bin/i386-elf-gdb
 # -g: Use debugging symbols in gcc
 CFLAGS = -g
 # First rule is run by default
 os-image.bin: boot/bootsect.bin kernel.bin
 	cat $^ > os-image.bin
 # '--oformat binary' deletes all symbols as a collateral, so we don't need
 # to 'strip' them manually on this case
 kernel.bin: boot/kernel_entry.o ${OBJ}
 	i386-elf-ld -o $@ -Ttext 0x1000 $^ --oformat binary
 # Used for debugging purposes
 kernel.elf: boot/kernel_entry.o ${OBJ}
 	i386-elf-ld -o $@ -Ttext 0x1000 $^ 
 run: os-image.bin
 	qemu-system-i386 -fda os-image.bin
 # Open the connection to qemu and load our kernel-object file with symbols
 debug: os-image.bin kernel.elf
 	qemu-system-i386 -s -fda os-image.bin &
 	${GDB} -ex "target remote localhost:1234" -ex "symbol-file kernel.elf"
 # Generic rules for wildcards
 # To make an object, always compile from its .c
 %.o: %.c ${HEADERS}
 	${CC} ${CFLAGS} -ffreestanding -c $< -o $@
 %.o: %.asm
 	nasm $< -f elf -o $@
 %.bin: %.asm
 	nasm $< -f bin -o $@
 clean:
 	rm -rf *.bin *.dis *.o os-image.bin *.elf
 	rm -rf kernel/*.o boot/*.bin drivers/*.o boot/*.o
--- a/15-video-ports/boot
+++ b/15-video-ports/boot
@ -1 +0,0 @@
 ../14-checkpoint/boot
--- a/16-video-driver/Makefile
+++ b/16-video-driver/Makefile
@ -1 +0,0 @@
 ../14-checkpoint/Makefile
--- a/16-video-driver/Makefile
+++ b/16-video-driver/Makefile
@ -0,0 +1,46 @@
 C_SOURCES = $(wildcard kernel/*.c drivers/*.c)
 HEADERS = $(wildcard kernel/*.h drivers/*.h)
 # Nice syntax for file extension replacement
 OBJ = ${C_SOURCES:.c=.o}
 # Change this if your cross-compiler is somewhere else
 CC = /usr/local/i386elfgcc/bin/i386-elf-gcc
 GDB = /usr/local/i386elfgcc/bin/i386-elf-gdb
 # -g: Use debugging symbols in gcc
 CFLAGS = -g
 # First rule is run by default
 os-image.bin: boot/bootsect.bin kernel.bin
 	cat $^ > os-image.bin
 # '--oformat binary' deletes all symbols as a collateral, so we don't need
 # to 'strip' them manually on this case
 kernel.bin: boot/kernel_entry.o ${OBJ}
 	i386-elf-ld -o $@ -Ttext 0x1000 $^ --oformat binary
 # Used for debugging purposes
 kernel.elf: boot/kernel_entry.o ${OBJ}
 	i386-elf-ld -o $@ -Ttext 0x1000 $^ 
 run: os-image.bin
 	qemu-system-i386 -fda os-image.bin
 # Open the connection to qemu and load our kernel-object file with symbols
 debug: os-image.bin kernel.elf
 	qemu-system-i386 -s -fda os-image.bin &
 	${GDB} -ex "target remote localhost:1234" -ex "symbol-file kernel.elf"
 # Generic rules for wildcards
 # To make an object, always compile from its .c
 %.o: %.c ${HEADERS}
 	${CC} ${CFLAGS} -ffreestanding -c $< -o $@
 %.o: %.asm
 	nasm $< -f elf -o $@
 %.bin: %.asm
 	nasm $< -f bin -o $@
 clean:
 	rm -rf *.bin *.dis *.o os-image.bin *.elf
 	rm -rf kernel/*.o boot/*.bin drivers/*.o boot/*.o
--- a/16-video-driver/boot
+++ b/16-video-driver/boot
@ -1 +0,0 @@
 ../14-checkpoint/boot
--- a/17-video-scroll/Makefile
+++ b/17-video-scroll/Makefile
@ -1 +0,0 @@
 ../14-checkpoint/Makefile
--- a/17-video-scroll/Makefile
+++ b/17-video-scroll/Makefile
@ -0,0 +1,46 @@
 C_SOURCES = $(wildcard kernel/*.c drivers/*.c)
 HEADERS = $(wildcard kernel/*.h drivers/*.h)
 # Nice syntax for file extension replacement
 OBJ = ${C_SOURCES:.c=.o}
 # Change this if your cross-compiler is somewhere else
 CC = /usr/local/i386elfgcc/bin/i386-elf-gcc
 GDB = /usr/local/i386elfgcc/bin/i386-elf-gdb
 # -g: Use debugging symbols in gcc
 CFLAGS = -g
 # First rule is run by default
 os-image.bin: boot/bootsect.bin kernel.bin
 	cat $^ > os-image.bin
 # '--oformat binary' deletes all symbols as a collateral, so we don't need
 # to 'strip' them manually on this case
 kernel.bin: boot/kernel_entry.o ${OBJ}
 	i386-elf-ld -o $@ -Ttext 0x1000 $^ --oformat binary
 # Used for debugging purposes
 kernel.elf: boot/kernel_entry.o ${OBJ}
 	i386-elf-ld -o $@ -Ttext 0x1000 $^ 
 run: os-image.bin
 	qemu-system-i386 -fda os-image.bin
 # Open the connection to qemu and load our kernel-object file with symbols
 debug: os-image.bin kernel.elf
 	qemu-system-i386 -s -fda os-image.bin &
 	${GDB} -ex "target remote localhost:1234" -ex "symbol-file kernel.elf"
 # Generic rules for wildcards
 # To make an object, always compile from its .c
 %.o: %.c ${HEADERS}
 	${CC} ${CFLAGS} -ffreestanding -c $< -o $@
 %.o: %.asm
 	nasm $< -f elf -o $@
 %.bin: %.asm
 	nasm $< -f bin -o $@
 clean:
 	rm -rf *.bin *.dis *.o os-image.bin *.elf
 	rm -rf kernel/*.o boot/*.bin drivers/*.o boot/*.o
--- a/17-video-scroll/boot
+++ b/17-video-scroll/boot
@ -1 +0,0 @@
 ../14-checkpoint/boot/
--- a/17-video-scroll/drivers/ports.c
+++ b/17-video-scroll/drivers/ports.c
@ -1 +0,0 @@
 ../../16-video-driver/drivers/ports.c
--- a/17-video-scroll/drivers/ports.c
+++ b/17-video-scroll/drivers/ports.c
@ -0,0 +1,35 @@
 /**
 * Read a byte from the specified port
 */
 unsigned char port_byte_in (unsigned short port) {
    unsigned char result;
    /* Inline assembler syntax
     * !! Notice how the source and destination registers are switched from NASM !!
     *
     * '"=a" (result)'; set '=' the C variable '(result)' to the value of register e'a'x
     * '"d" (port)': map the C variable '(port)' into e'd'x register
     *
     * Inputs and outputs are separated by colons
     */
    __asm__("in %%dx, %%al" : "=a" (result) : "d" (port));
    return result;
 }
 void port_byte_out (unsigned short port, unsigned char data) {
    /* Notice how here both registers are mapped to C variables and
     * nothing is returned, thus, no equals '=' in the asm syntax 
     * However we see a comma since there are two variables in the input area
     * and none in the 'return' area
     */
    __asm__("out %%al, %%dx" : : "a" (data), "d" (port));
 }
 unsigned short port_word_in (unsigned short port) {
    unsigned short result;
    __asm__("in %%dx, %%ax" : "=a" (result) : "d" (port));
    return result;
 }
 void port_word_out (unsigned short port, unsigned short data) {
    __asm__("out %%ax, %%dx" : : "a" (data), "d" (port));
 }
--- a/17-video-scroll/drivers/ports.h
+++ b/17-video-scroll/drivers/ports.h
@ -1 +0,0 @@
 ../../16-video-driver/drivers/ports.h
--- a/17-video-scroll/drivers/ports.h
+++ b/17-video-scroll/drivers/ports.h
@ -0,0 +1,4 @@
 unsigned char port_byte_in (unsigned short port);
 void port_byte_out (unsigned short port, unsigned char data);
 unsigned short port_word_in (unsigned short port);
 void port_word_out (unsigned short port, unsigned short data);
--- a/17-video-scroll/drivers/screen.h
+++ b/17-video-scroll/drivers/screen.h
@ -1 +0,0 @@
 ../../16-video-driver/drivers/screen.h
--- a/17-video-scroll/drivers/screen.h
+++ b/17-video-scroll/drivers/screen.h
@ -0,0 +1,14 @@
 #define VIDEO_ADDRESS 0xb8000
 #define MAX_ROWS 25
 #define MAX_COLS 80
 #define WHITE_ON_BLACK 0x0f
 #define RED_ON_WHITE 0xf4
 /* Screen i/o ports */
 #define REG_SCREEN_CTRL 0x3d4
 #define REG_SCREEN_DATA 0x3d5
 /* Public kernel API */
 void clear_screen();
 void kprint_at(char *message, int col, int row);
 void kprint(char *message);
--- a/18-interrupts/kernel/util.h
+++ b/18-interrupts/kernel/util.h
@ -1,5 +1,10 @@
 #ifndef UTIL_H
 #define UTIL_H
 #include "../cpu/types.h"
 void memory_copy(char *source, char *dest, int nbytes);
 void memory_set(u8 *dest, u8 val, u32 len);
 void int_to_ascii(int n, char str[]);
 #endif
		`@ -1 +0,0 @@`
			`../../05-bootsector-functions-strings/boot_sect_print.asm`