adding files as they are from deesix on my IRC via pastebin

2024-11-22 06:06:52 -08:00 · 2024-09-13 13:18:45 -07:00 · 2024-09-13 13:18:45 -07:00 · 82e910ca86
commit 82e910ca86
parent f4f71fd3c2
3 changed files with 540 additions and 21 deletions
--- a/boot.asm
+++ b/boot.asm
@ -11,7 +11,7 @@ boot:
 	mov [disk],dl
 	mov ah, 0x2    ;read sectors
-	mov al, 6      ;sectors to read
+	mov al, 64     ;sectors to read
 	mov ch, 0      ;cylinder idx
 	mov dh, 0      ;head idx
 	mov cl, 2      ;sector idx
@ -30,22 +30,37 @@ boot:
 	mov gs, ax
 	mov ss, ax
 	jmp CODE_SEG:boot2
 ; access(8)
 ;    P:present(1) DPL:descriptor_privilege_level(2)
 ;    S:descriptor_type(1) E:executable(1) DC:direction/conforming(1)
 ;    RW:readable/writable(1) A:accessed(1)
 ; flags(4)
 ;    G:granularity(1) DB:size(1) L:long_mode_code(1) Reserved(1)
 gdt_start:
-	dq 0x0
+	dq 0x0000000000000000 ; null descriptor
 gdt_code:
-	dw 0xFFFF
+	dw 0xFFFF    ; limit_0_15(16)
-	dw 0x0
+	dw 0x0000    ; base_0_15(16)
-	db 0x0
+	db 0x00      ; base_16_23(8)
-	db 10011010b
+	db 10011010b ; P(1)=1=present DPL(2)=00=ring0 S(1)=1=non_system E(1)=1=code
-	db 11001111b
+	             ; DC(1)=0=same_ring RW(1)=1=readable A(1)=0=not_accessed
-	db 0x0
+	db 11001111b ; G(1)=1=page, DB(1)=1=32b, L(1)=0=non_64b Reserved(1)=0=_
 	             ; limit_16_19(4)=1111
 	db 0x00      ; base_24_31(8)
 gdt_data:
-	dw 0xFFFF
+	dw 0xFFFF    ; limit_0_15(16)
-	dw 0x0
+	dw 0x0000    ; base_0_15(16)
-	db 0x0
+	db 0x00      ; base_16_23(8)
-	db 10010010b
+	db 10010010b ; P(1)=1=present DPL(2)=00=ring0 S(1)=1=non_system E(1)=0=data
-	db 11001111b
+	             ; DC(1)=0=grows_up RW(1)=1=rw A(1)=0=not_accessed
-	db 0x0
+	db 11001111b ; G(1)=1=page DB(1)=1=32b_sp L(1)=0=_ Reserved(1)=0=_
 	             ; limit_16_19(4)=1111
 	db 0x00      ; base_24_31(8)
 gdt_end:
 gdt_pointer:
 	dw gdt_end - gdt_start
--- a/do.sh
+++ b/do.sh
@ -0,0 +1,29 @@
 #!/bin/sh
 set -e
 # TODO: Check the compiler does x86
 if [ "$1" = "build" ]; then
    shift
    printf "Assembling bootloader...\n"
    nasm -f elf32 boot.asm -o boot.o
    printf "Compiling...\n"
    gcc \
        -save-temps \
        -std=c99 -m32 \
        -fno-pic \
        -mgeneral-regs-only \
        -ffreestanding -nostdlib \
        -Wall -Wextra -Wpedantic \
        kernel.c boot.o \
        -o kernel.bin \
        -T linker.ld
 fi
 if [ "$1" = "boot" ]; then
    printf "Booting...\n\n"
    MACHINE="-machine pc -cpu 486"
    qemu-system-i386 $MACHINE -net none -serial stdio -drive file=kernel.bin,index=0,if=floppy,format=raw
 fi
--- a/kernel.c
+++ b/kernel.c
@ -1,13 +1,488 @@
 #include <stdbool.h>
 #include <stddef.h>
 #include <stdint.h>
 bool terminate = false;
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 static inline void outb(uint16_t port, uint8_t val)
 {
    __asm__ volatile ("outb %b0, %w1" : : "a"(val), "Nd"(port) : "memory");
 }
 static inline uint8_t inb(uint16_t port)
 {
    uint8_t ret;
    __asm__ volatile ("inb %w1, %b0" : "=a"(ret) : "Nd"(port) : "memory");
    return ret;
 }
 static inline void io_wait(void)
 {
    outb(0x80, 0);
 }
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 #define PORT 0x3f8          // COM1
 void init_serial(void)
 {
    // Enable "data available" interrupt.
    outb(PORT + 1, 0x01);
 }
 // Use only when there _is_ something to read.
 char read_serial()
 {
    return inb(PORT);
 }
 int is_transmit_empty()
 {
    return inb(PORT + 5) & 0x20;
 }
 void write_serial(char a)
 {
    while (is_transmit_empty() == 0);
    outb(PORT, a);
 }
 #undef PORT
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 /*
 * Convert numbers to hexadecimal chars.
 */
 char nibble_to_hex(int n)
 {
    if   (n>=0 && n<10) return (n+48);
    else if (n>=10 && n<16) return (n+55+32);
    else return '?';
 }
 void int_to_hex(char *hex, uint64_t a, size_t size)
 {
    int i = 0;
    int divisor = size << 3;
    while (divisor != 0) {
        divisor -= 4;
        hex[i] = nibble_to_hex((a >> divisor) & 0xF);
        i += 1;
    }
 }
 void u8_to_hex (char *s, uint8_t  a) { int_to_hex(s, a, 1); }
 void u16_to_hex(char *s, uint16_t a) { int_to_hex(s, a, 2); }
 void u32_to_hex(char *s, uint32_t a) { int_to_hex(s, a, 4); }
 void u64_to_hex(char *s, uint64_t a) { int_to_hex(s, a, 8); }
 /*
 * Logging functions.
 */
 // Use serial for log output.
 #define PUTCHAR write_serial
 // Sends buffer of a given size to the log.
 void klog(char *buff, int size)
 {
    for (int i=0; i<size; ++i) PUTCHAR(buff[i]);
 }
 // Like klog but also sends a newline character.
 void klogl(char *buff, int size)
 {
    klog(buff, size); PUTCHAR('\n');
 }
 // Sends a NUL-terminated string to the log (not including the NUL).
 void klogs(const char *str)
 {
    while(*str) PUTCHAR(*str++);
 }
 #undef PUTCHAR
 // Functions that send integers to the log, in hex (without 0x prefix).
 #define B hexbuff
 #define D char B[16] = {0}
 void klog_u8 (uint8_t  a) { D; u8_to_hex (B, a); klog(B, 2) ; }
 void klog_u16(uint16_t a) { D; u16_to_hex(B, a); klog(B, 4) ; }
 void klog_u32(uint32_t a) { D; u32_to_hex(B, a); klog(B, 8) ; }
 void klog_u64(uint64_t a) { D; u64_to_hex(B, a); klog(B, 16); }
 // These send a newline character too.
 void klogl_u8 (uint8_t  a) { D; u8_to_hex (B, a); klogl(B, 2) ; }
 void klogl_u16(uint16_t a) { D; u16_to_hex(B, a); klogl(B, 4) ; }
 void klogl_u32(uint32_t a) { D; u32_to_hex(B, a); klogl(B, 8) ; }
 void klogl_u64(uint64_t a) { D; u64_to_hex(B, a); klogl(B, 16); }
 #undef D
 #undef B
 void demo_klog_functions(void)
 {
    klogs("\nCheck; one, two, one, two.\n");
    klogl_u8(0x01);
    klogl_u16(0x2345);
    klogl_u32(0x6789abcd);
    klogl_u64(0xef0123456789abcd);
    klog_u8(0x01);
    klog_u16(0x2345);
    klog_u32(0x6789abcd);
    klog_u64(0xef0123456789abcd);
    klogs("\n0123456789abcdef0123456789abcd\n");
 }
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 #define PIC1            0x20     /* IO base address for master PIC */
 #define PIC2            0xA0     /* IO base address for slave PIC */
 #define PIC1_COMMAND    PIC1
 #define PIC1_DATA       (PIC1+1)
 #define PIC2_COMMAND    PIC2
 #define PIC2_DATA       (PIC2+1)
 #define ICW1_ICW4       0x01     /* Indicates that ICW4 will be present */
 #define ICW1_INIT       0x10     /* Initialization - required! */
 #define ICW4_8086       0x01     /* 8086/88 (MCS-80/85) mode */
 void pic_remap(int offset)
 {
    uint8_t a1, a2;
    // save masks
    a1 = inb(PIC1_DATA); a2 = inb(PIC2_DATA);
    // starts the initialization sequence (in cascade mode)
    outb(PIC1_COMMAND, ICW1_INIT | ICW1_ICW4); io_wait();
    outb(PIC2_COMMAND, ICW1_INIT | ICW1_ICW4); io_wait();
    // ICW2: Master PIC vector offset
    outb(PIC1_DATA, offset); io_wait();
    // ICW2: Slave PIC vector offset
    outb(PIC2_DATA, offset+8); io_wait();
    // ICW3: tell Master PIC that there is a slave PIC at IRQ2 (0000 0100)
    outb(PIC1_DATA, 4); io_wait();
    // ICW3: tell Slave PIC its cascade identity (0000 0010)
    outb(PIC2_DATA, 2); io_wait();
    // ICW4: have the PICs use 8086 mode (and not 8080 mode)
    outb(PIC1_DATA, ICW4_8086); io_wait();
    outb(PIC2_DATA, ICW4_8086); io_wait();
    // restore saved masks.
    outb(PIC1_DATA, a1); outb(PIC2_DATA, a2);
 }
 void pic_end_of_irq(int irq)
 {
    if (irq >= 8) outb(PIC2_COMMAND, 0x20);
    outb(PIC1_COMMAND, 0x20);
 }
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 struct gdt_descriptor
 {
    uint16_t limit;
    uint32_t base;
 } __attribute__((packed));
 void sgdt(struct gdt_descriptor *gdtd)
 {
    __asm__ volatile ("sgdt %0" : : "m"(*gdtd) : "memory");
 }
 void klog_info_about_gdt(void)
 {
    struct gdt_descriptor gdtd;
    sgdt(&gdtd);
    klogs("**\n GDT info:\n");
    klogl_u32(gdtd.base);
    klogl_u16(gdtd.limit);
    // For each (8 bytes long) entry in the table...
    for (uint32_t b = gdtd.base; b < gdtd.base + gdtd.limit; b += 8) {
        // ... log each byte, in hex.
        for (uint32_t i = b; i < b + 8; ++i) {
            klog_u8(*(uint8_t*)i);
        }
        klogs("\n");
    }
 }
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 struct idt_gate_descriptor
 {
    uint16_t offset_1;        // offset bits 0..15
    uint16_t selector;        // a code segment selector in GDT or LDT
    uint8_t  zero;            // unused, set to 0
    uint8_t  type_attributes; // gate type, dpl, and p fields
    uint16_t offset_2;        // offset bits 16..31
 } __attribute__((packed));
 #define PIC_REMAP_OFFSET 0x20
 // The IDT begins with gates for the exceptions; we remap the PIC to start at
 // some point after them. For the PIC IRQs that's 16 gates more. If we define
 // our software interrupts... we'll have to make room.
 #define IDT_NUM_GATES (PIC_REMAP_OFFSET + 16)
 __attribute__((aligned(0x10)))
 struct idt_gate_descriptor idt[IDT_NUM_GATES] = {0};
 static inline void lidt(void)
 {
    struct {
        uint16_t limit;
        void     *base;
    } __attribute__((packed)) src = { IDT_NUM_GATES * 8 - 1, idt };
    __asm__ ("lidt %0" : : "m"(src) );
 }
 struct interrupt_frame; // Not defined yet, but we need a pointer to it.
 #define GATE_F          void (*f)(struct interrupt_frame *)
 #define GATE_WITH_ERR_F void (*f)(struct interrupt_frame *, uint32_t)
 #define FOR_INTR        0x8e /* Present, DPL 0, 32b interrupt gate */
 #define FOR_TRAP        0x8f /* Present, DPL 0, 32b trap gate */
 struct idt_gate_descriptor gate(uint8_t type_attributes, uint32_t f)
 {
    return (struct idt_gate_descriptor){
        .type_attributes = type_attributes,
        .selector = 0x0008, // Our code segment in GDT, ring0 requested.
        .offset_1 = (uint16_t)(f & 0xffff),
        .offset_2 = (uint16_t)((f>>16) & 0xffff),
        .zero = 0x00
    };
 }
 void klog_idt_gate_update(int n)
 {
    klogs(" "); klog_u8(n);
 }
 void set_irq_handler(size_t irq, GATE_F)
 {
    idt[irq + PIC_REMAP_OFFSET] = gate(FOR_INTR, (uint32_t)f);
    klog_idt_gate_update(irq);
 }
 void set_exception_with_err_handler(size_t number, GATE_WITH_ERR_F)
 {
    idt[number] = gate(FOR_TRAP, (uint32_t)f);
    klog_idt_gate_update(number);
 }
 void set_exception_handler(size_t number, GATE_F)
 {
    idt[number] = gate(FOR_TRAP, (uint32_t)f);
    klog_idt_gate_update(number);
 }
 #undef FOR_TRAP
 #undef FOR_INTR
 #undef GATE_WITH_ERR_F
 #undef GATE_F
 void pic_clear_irq(uint8_t irq)
 {
    uint16_t port;
    uint8_t value;
    if(irq < 8) {
        port = PIC1_DATA;
    } else {
        port = PIC2_DATA; irq -= 8;
    }
    value = inb(port) & ~(1 << irq);
    outb(port, value);
 }
 void pic_mask_all_irqs(void)
 {
    outb(PIC1_DATA, 0xff); outb(PIC2_DATA, 0xff);
 }
 static inline void sti(void)
 {
    __asm__ volatile ("sti");
 }
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 void panic(void)
 {
    klogs("Panic: halt.");
    __asm__ volatile ("cli; hlt;");
 }
 __attribute__((interrupt))
 void exception_with_err_handler(struct interrupt_frame *frame, uint32_t error_code)
 {
    (void)frame;
    klogs("\n(generic handler) Exception with err "); klogl_u32(error_code);
    panic();
 }
 __attribute__((interrupt))
 void exception_handler(struct interrupt_frame *frame)
 {
    (void)frame;
    klogs("\n(generic handler) Exception\n");
    panic();
 }
 __attribute__((interrupt))
 void exception_de(struct interrupt_frame *frame)
 {
    (void)frame;
    klogs("\nException: Divide Error.\n");
    panic();
 }
 __attribute__((interrupt))
 void exception_gp(struct interrupt_frame *frame, uint32_t error_code)
 {
    (void)frame;
    klogs("\nException: General Protection; error code "); klogl_u32(error_code);
    panic();
 }
 __attribute__((interrupt))
 void irq1_handler(struct interrupt_frame *frame)
 {
    (void)frame;
    uint8_t k = inb(0x60);
    klogs("Key: "); klogl_u8(k);
    if (k ==  /* q */ 0x90) terminate = true;
    pic_end_of_irq(1);
 }
 __attribute__((interrupt))
 void irq4_handler(struct interrupt_frame *frame)
 {
    (void)frame;
    uint8_t c = read_serial();
    write_serial(c); // Echo.
    // Testing stuff when receiving some chars.
    if (c == 'q') terminate = true;
    if (c == '0')
        __asm__ volatile ("mov $0, %bl; div %bl"); // Division by zero.
    if (c == 'f')
        __asm__ volatile ("int $13;");             // General Protection fault.
    pic_end_of_irq(4);
 }
 void init_interrupts(void)
 {
    klogs("**\n  Init interrupts\n");
    klogs("Preparing PIC.\n");
    pic_mask_all_irqs();
    pic_remap(PIC_REMAP_OFFSET);
    klogs("Init exceptions.\n");
 #define A(n) set_exception_handler(n, &exception_handler)
 #define B(n) set_exception_with_err_handler(n, &exception_with_err_handler)
    set_exception_handler(0, &exception_de);
    A(1); A(2); A(3); A(4); A(5); A(6); A(7); B(8); A(9);
    B(10); B(11); B(12);
    set_exception_with_err_handler(13, &exception_gp);
    B(14); A(15); A(16); B(17); A(18); A(19);
    A(20); B(21); A(28); B(29); B(30);
 #undef B
 #undef A
    klogs("\nInit IRQs.\n");
    // Assign handlers to hardware interrupts.
    // Use the IRQ number here (the offset is applied elsewhere).
    set_irq_handler(1, &irq1_handler);  // Keyboard.
    set_irq_handler(4, &irq4_handler);  // Serial.
    klogs("\n");
    // Make our IDT the active one.
    lidt();
    // Unmask hardware interrupts that we're ready to handle.
    pic_clear_irq(1);
    pic_clear_irq(4);
    // Start accepting IRQs (that is... from the PIC).
    sti();
 }
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 //////////////////////////////////////////////////////////////////////
 void kmain(void)
 {
-    const uint16_t color = 0x0F00;
+    init_serial();
-    const char *hello = "Hello C world!";
+    klogs("Hello from kmain!\n");
-    volatile uint16_t *vga = (volatile uint16_t *)0xb8000;
+    demo_klog_functions();
-    for (int i = 0; i < 16; ++i)
+    init_interrupts();
-    {
+
    const uint16_t color = 0x7e00;
    volatile uint16_t *vga = (volatile uint16_t *)0xb8000;
    const char *hello = "Hello! Please, see serial output.";
    for (int i = 0; hello[i] != 0; ++i) {
        vga[i + 80] = color | (uint16_t)hello[i];
    }
    klog_info_about_gdt();
    klogs("\n\n**\n  Ready!\n");
    klogs(
      "(accepting input from keyboard)\n"
      " type q to return from kmain\n"
      " key info sent to serial\n"
      "(accepting input from serial, with echo)\n"
      " send q to return from kmain\n"
      " send f to invoke GPF\n"
      " send 0 to trigger divide by zero\n"
    );
    while (!terminate) {
        __asm__ volatile ("hlt");
    }
    klogs("\nkmain returning now... o/\n");
 }