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compiles now, new import architecture

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This commit is contained in:
Jack Halford 2019-08-22 21:59:23 +02:00
parent 888b51282d
commit bdc3b2939b
18 changed files with 113 additions and 300 deletions
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1
build.zig
View file

@ -7,7 +7,6 @@ pub fn build(b: *Builder) void {
kernel.addPackagePath("x86", "src/arch/x86/index.zig"); kernel.addPackagePath("x86", "src/arch/x86/index.zig");
kernel.setOutputDir("build"); kernel.setOutputDir("build");
// kernel.addAssemblyFile("src/arch/x86/_start.s");
kernel.addAssemblyFile("src/arch/x86/gdt.s"); kernel.addAssemblyFile("src/arch/x86/gdt.s");
kernel.addAssemblyFile("src/arch/x86/isr.s"); kernel.addAssemblyFile("src/arch/x86/isr.s");
kernel.addAssemblyFile("src/arch/x86/paging.s"); kernel.addAssemblyFile("src/arch/x86/paging.s");

2
qemu.sh
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@ -12,8 +12,8 @@ start() {
-m 1337M \ -m 1337M \
-curses \ -curses \
-append "Hello" \ -append "Hello" \
-drive file=disk.img,if=virtio\
-kernel ${KERNEL} -kernel ${KERNEL}
# -drive file=disk.img,if=virtio\
# -no-reboot \ # -no-reboot \
# -device virtio-net,netdev=network0 -netdev tap,id=network0,ifname=tap0,script=no,downscript=no \ # -device virtio-net,netdev=network0 -netdev tap,id=network0,ifname=tap0,script=no,downscript=no \
# build/kernel.iso # build/kernel.iso

16
src/arch/x86/_start.s
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@ -1,16 +0,0 @@
.global __start
.type __start, @function
// Entry point. It puts the machine into a consistent state,
// starts the kernel and then waits forever.
__start:
mov $0x80000, %esp // Setup the stack.
push %ebx // Pass multiboot info structure.
push %eax // Pass multiboot magic code.
call kmain // Call the kernel.
// Halt the CPU.
cli
hlt

21
src/arch/x86/idt.zig
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@ -1,18 +1,19 @@
// https://wiki.osdev.org/IDT // https://wiki.osdev.org/IDT
usingnamespace @import("kernel"); // usingnamespace @import("kernel");
usingnamespace @import("x86"); // usingnamespace @import("x86");
usingnamespace @import("index.zig");
// Types of gates. // Types of gates.
pub const INTERRUPT_GATE = 0x8E; pub const INTERRUPT_GATE = 0x8E;
pub const SYSCALL_GATE = 0xEE; pub const SYSCALL_GATE = 0xEE;
// Interrupt Descriptor Table. // Interrupt Descriptor Table.
var idt: [256]IDTEntry = undefined; var idt_table: [256]IDTEntry = undefined;
// IDT descriptor register pointing at the IDT. // IDT descriptor register pointing at the IDT.
const idtr = IDTRegister{ const idtr = IDTRegister{
.limit = u16(@sizeOf(@typeOf(idt))), .limit = u16(@sizeOf(@typeOf(idt_table))),
.base = &idt, .base = &idt_table,
}; };
// Structure representing an entry in the IDT. // Structure representing an entry in the IDT.
@ -40,11 +41,11 @@ const IDTRegister = packed struct {
pub fn setGate(n: u8, flags: u8, offset: extern fn () void) void { pub fn setGate(n: u8, flags: u8, offset: extern fn () void) void {
const intOffset = @ptrToInt(offset); const intOffset = @ptrToInt(offset);
idt[n].offset_low = @truncate(u16, intOffset); idt_table[n].offset_low = @truncate(u16, intOffset);
idt[n].offset_high = @truncate(u16, intOffset >> 16); idt_table[n].offset_high = @truncate(u16, intOffset >> 16);
idt[n].flags = flags; idt_table[n].flags = flags;
idt[n].zero = 0; idt_table[n].zero = 0;
idt[n].selector = gdt.KERNEL_CODE; idt_table[n].selector = gdt.KERNEL_CODE;
} }
// Initialize the Interrupt Descriptor Table. // Initialize the Interrupt Descriptor Table.

22
src/arch/x86/index.zig
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@ -1,9 +1,15 @@
usingnamespace @import("lib/io.zig"); pub usingnamespace @import("../../vga.zig");
usingnamespace @import("lib/instructions.zig"); pub const multiboot = @import("../../multiboot.zig");
usingnamespace @import("main.zig");
const memory = @import("memory.zig"); pub usingnamespace @import("lib/io.zig");
const paging = @import("paging.zig"); pub usingnamespace @import("lib/instructions.zig");
const idt = @import("idt.zig"); pub usingnamespace @import("main.zig");
const gdt = @import("gdt.zig");
const interrupt = @import("interrupt.zig"); pub const memory = @import("memory.zig");
pub const paging = @import("paging.zig");
pub const idt = @import("idt.zig");
pub const isr = @import("isr.zig");
pub const gdt = @import("gdt.zig");
pub const interrupt = @import("interrupt.zig");
pub const assert = @import("std").debug.assert;

61
src/arch/x86/interrupt.zig
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@ -1,6 +1,6 @@
usingnamespace @import("kernel"); usingnamespace @import("index.zig");
const x86 = @import("x86"); // const x86 = @import("index.zig");
const isr = @import("isr.zig"); // const isr = @import("isr.zig");
// PIC ports. // PIC ports.
const PIC1_CMD = 0x20; const PIC1_CMD = 0x20;
@ -32,16 +32,17 @@ var handlers = [_]fn () void{unhandled} ** 48;
fn unhandled() noreturn { fn unhandled() noreturn {
const n = isr.context.interrupt_n; const n = isr.context.interrupt_n;
print("unhandled interrupt number {d}", n);
if (n < IRQ_0) { if (n < IRQ_0) {
println("unhandled exception number {d}", n); println(" (exception)");
} else { } else {
println("unhandled IRQ number {d} (intr {d})", n - IRQ_0, n); println(" (IRQ number {d})", n - IRQ_0);
} }
x86.hang(); hang();
} }
inline fn picwait() void { inline fn picwait() void {
x86.outb(WAIT_PORT, 0); outb(WAIT_PORT, 0);
} }
//// ////
@ -81,8 +82,8 @@ export fn interruptDispatch() void {
// If no user thread is ready to run, halt here and wait for interrupts. // If no user thread is ready to run, halt here and wait for interrupts.
// if (scheduler.current() == null) { // if (scheduler.current() == null) {
// x86.sti(); // sti();
// x86.hlt(); // hlt();
// } // }
} }
@ -92,8 +93,8 @@ inline fn spuriousIRQ(irq: u8) bool {
// TODO: handle spurious IRQ15. // TODO: handle spurious IRQ15.
// Read the value of the In-Service Register. // Read the value of the In-Service Register.
x86.outb(PIC1_CMD, ISR_READ); outb(PIC1_CMD, ISR_READ);
const in_service = x86.inb(PIC1_CMD); const in_service = inb(PIC1_CMD);
// Verify whether IRQ7 is set in the ISR. // Verify whether IRQ7 is set in the ISR.
return (in_service & (1 << 7)) == 0; return (in_service & (1 << 7)) == 0;
@ -103,11 +104,11 @@ inline fn startOfInterrupt(irq: u8) void {
// mask the irq and then ACK // mask the irq and then ACK
if (irq >= 8) { if (irq >= 8) {
maskIRQ(irq, true); maskIRQ(irq, true);
x86.outb(PIC1_CMD, ACK); outb(PIC1_CMD, ACK);
x86.outb(PIC2_CMD, ACK); outb(PIC2_CMD, ACK);
} else { } else {
maskIRQ(irq, true); maskIRQ(irq, true);
x86.outb(PIC1_CMD, ACK); outb(PIC1_CMD, ACK);
} }
} }
@ -115,10 +116,10 @@ inline fn endOfInterrupt(irq: u8) void {
// unmask the irq and then ACK // unmask the irq and then ACK
if (irq >= 8) { if (irq >= 8) {
maskIRQ(irq, false); maskIRQ(irq, false);
x86.outb(PIC2_CMD, ACK); outb(PIC2_CMD, ACK);
} else { } else {
maskIRQ(irq, false); maskIRQ(irq, false);
x86.outb(PIC1_CMD, ACK); outb(PIC1_CMD, ACK);
} }
} }
@ -133,33 +134,33 @@ pub fn registerIRQ(irq: u8, handler: fn () void) void {
fn remapPIC() void { fn remapPIC() void {
// ICW1: start initialization sequence. // ICW1: start initialization sequence.
x86.outb(PIC1_CMD, ICW1_INIT | ICW1_ICW4); outb(PIC1_CMD, ICW1_INIT | ICW1_ICW4);
picwait(); picwait();
x86.outb(PIC2_CMD, ICW1_INIT | ICW1_ICW4); outb(PIC2_CMD, ICW1_INIT | ICW1_ICW4);
picwait(); picwait();
// ICW2: Interrupt Vector offsets of IRQs. // ICW2: Interrupt Vector offsets of IRQs.
x86.outb(PIC1_DATA, IRQ_0); // IRQ 0..7 -> Interrupt 32..39 outb(PIC1_DATA, IRQ_0); // IRQ 0..7 -> Interrupt 32..39
picwait(); picwait();
x86.outb(PIC2_DATA, IRQ_0 + 8); // IRQ 8..15 -> Interrupt 40..47 outb(PIC2_DATA, IRQ_0 + 8); // IRQ 8..15 -> Interrupt 40..47
picwait(); picwait();
// ICW3: IRQ line 2 to connect master to slave PIC. // ICW3: IRQ line 2 to connect master to slave PIC.
x86.outb(PIC1_DATA, 1 << 2); outb(PIC1_DATA, 1 << 2);
picwait(); picwait();
x86.outb(PIC2_DATA, 2); outb(PIC2_DATA, 2);
picwait(); picwait();
// ICW4: 80x86 mode. // ICW4: 80x86 mode.
x86.outb(PIC1_DATA, ICW4_8086); outb(PIC1_DATA, ICW4_8086);
picwait(); picwait();
x86.outb(PIC2_DATA, ICW4_8086); outb(PIC2_DATA, ICW4_8086);
picwait(); picwait();
// Mask all IRQs. // Mask all IRQs.
x86.outb(PIC1_DATA, 0xFF); outb(PIC1_DATA, 0xFF);
picwait(); picwait();
x86.outb(PIC2_DATA, 0xFF); outb(PIC2_DATA, 0xFF);
picwait(); picwait();
} }
@ -167,16 +168,16 @@ pub fn maskIRQ(irq: u8, mask: bool) void {
if (irq > 15) return; if (irq > 15) return;
// Figure out if master or slave PIC owns the IRQ. // Figure out if master or slave PIC owns the IRQ.
const port = if (irq < 8) u16(PIC1_DATA) else u16(PIC2_DATA); const port = if (irq < 8) u16(PIC1_DATA) else u16(PIC2_DATA);
const old = x86.inb(port); // Retrieve the current mask. const old = inb(port); // Retrieve the current mask.
// Mask or unmask the interrupt. // Mask or unmask the interrupt.
const shift = @intCast(u3, irq % 8); const shift = @intCast(u3, irq % 8);
if (mask) { if (mask) {
x86.outb(port, old | (u8(1) << shift)); outb(port, old | (u8(1) << shift));
} else { } else {
x86.outb(port, old & ~(u8(1) << shift)); outb(port, old & ~(u8(1) << shift));
} }
const new = x86.inb(port); // Retrieve the current mask. const new = inb(port); // Retrieve the current mask.
} }
//// ////

2
src/arch/x86/isr.zig
View file

@ -1,4 +1,4 @@
usingnamespace @import("x86"); usingnamespace @import("index.zig");
// Interrupt Service Routines defined externally in assembly. // Interrupt Service Routines defined externally in assembly.
extern fn isr0() void; extern fn isr0() void;

9
src/arch/x86/main.zig
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@ -1,13 +1,14 @@
usingnamespace @import("kernel"); // usingnamespace @import("kernel");
usingnamespace @import("x86"); usingnamespace @import("index.zig");
// const multiboot = @import("../../multiboot.zig");
/// x86 specific intialization /// x86 specific intialization
pub fn x86_main(info: *const MultibootInfo) void { pub fn x86_main(info: *const multiboot.MultibootInfo) void {
gdt.initialize(); gdt.initialize();
idt.initialize(); idt.initialize();
memory.initialize(info); memory.initialize(info);
paging.initialize(); paging.initialize();
// enable interrupts // enable interrupts
x86.sti(); sti();
} }

12
src/arch/x86/memory.zig
View file

@ -1,4 +1,4 @@
usingnamespace @import("kernel"); usingnamespace @import("index.zig");
var stack: [*]usize = undefined; // Stack of free physical page. var stack: [*]usize = undefined; // Stack of free physical page.
var stack_index: usize = 0; // Index into the stack. var stack_index: usize = 0; // Index into the stack.
@ -51,10 +51,10 @@ pub fn free(address: usize) void {
// Arguments: // Arguments:
// info: Information structure from bootloader. // info: Information structure from bootloader.
// //
pub fn initialize(info: *const MultibootInfo) void { pub fn initialize(info: *const multiboot.MultibootInfo) void {
// Ensure the bootloader has given us the memory map. // Ensure the bootloader has given us the memory map.
assert((info.flags & MULTIBOOT_INFO_MEMORY) != 0); assert((info.flags & multiboot.MULTIBOOT_INFO_MEMORY) != 0);
assert((info.flags & MULTIBOOT_INFO_MEM_MAP) != 0); assert((info.flags & multiboot.MULTIBOOT_INFO_MEM_MAP) != 0);
// Place the stack of free pages after the last Multiboot module. // Place the stack of free pages after the last Multiboot module.
stack = @intToPtr([*]usize, 0x200000); stack = @intToPtr([*]usize, 0x200000);
@ -65,7 +65,7 @@ pub fn initialize(info: *const MultibootInfo) void {
var map: usize = info.mmap_addr; var map: usize = info.mmap_addr;
while (map < info.mmap_addr + info.mmap_length) { while (map < info.mmap_addr + info.mmap_length) {
var entry = @intToPtr(*MultibootMMapEntry, map); var entry = @intToPtr(*multiboot.MultibootMMapEntry, map);
// Calculate the start and end of this memory area. // Calculate the start and end of this memory area.
var start = @truncate(usize, entry.addr); var start = @truncate(usize, entry.addr);
@ -74,7 +74,7 @@ pub fn initialize(info: *const MultibootInfo) void {
start = if (start >= stack_end) start else stack_end; start = if (start >= stack_end) start else stack_end;
// Flag all the pages in this memory area as free. // Flag all the pages in this memory area as free.
if (entry.type == MULTIBOOT_MEMORY_AVAILABLE) while (start < end) : (start += PAGE_SIZE) if (entry.type == multiboot.MULTIBOOT_MEMORY_AVAILABLE) while (start < end) : (start += PAGE_SIZE)
free(start); free(start);
// Go to the next entry in the memory map. // Go to the next entry in the memory map.

4
src/arch/x86/paging.zig
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@ -1,5 +1,5 @@
usingnamespace @import("kernel"); usingnamespace @import("index.zig");
usingnamespace @import("x86"); // usingnamespace @import("x86");
extern fn setupPaging(phys_pd: usize) void; extern fn setupPaging(phys_pd: usize) void;

4
src/console.zig
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@ -1,4 +1,4 @@
usingnamespace @import("kernel"); usingnamespace @import("index.zig");
var command: [10]u8 = undefined; var command: [10]u8 = undefined;
var command_len: usize = 0; var command_len: usize = 0;
@ -30,6 +30,6 @@ pub fn keypress(char: u8) void {
} }
pub fn initialize() void { pub fn initialize() void {
@import("x86").interrupt.registerIRQ(1, ps2.keyboard_handler); x86.interrupt.registerIRQ(1, ps2.keyboard_handler);
print("> "); print("> ");
} }

9
src/index.zig
View file

@ -1,8 +1,9 @@
pub const assert = @import("std").debug.assert;
pub const std = @import("std");
pub usingnamespace @import("vga.zig"); pub usingnamespace @import("vga.zig");
pub const main = @import("main.zig");
pub const multiboot = @import("multiboot.zig"); pub const multiboot = @import("multiboot.zig");
pub const console = @import("console.zig"); pub const console = @import("console.zig");
pub const pci = @import("pci.zig"); pub const pci = @import("pci/pci.zig");
pub const ps2 = @import("ps2.zig"); pub const ps2 = @import("ps2.zig");
pub const x86 = @import("arch/x86/index.zig");
pub const assert = @import("std").debug.assert;

32
src/main.zig
View file

@ -1,29 +1,43 @@
usingnamespace @import("kernel"); usingnamespace @import("kernel");
// const x86 = @import("x86");
const x86 = @import("x86"); // Place the header at the very beginning of the binary.
export const multiboot_header align(4) linksection(".multiboot") = multiboot: {
const MAGIC = u32(0x1BADB002); // multiboot magic
const ALIGN = u32(1 << 0); // Align loaded modules at 4k
const MEMINFO = u32(1 << 1); // Receive a memory map from the bootloader.
const ADDR = u32(1 << 16); // Load specific addr
const FLAGS = ALIGN | MEMINFO; // Combine the flags.
break :multiboot multiboot.MultibootHeader{
.magic = MAGIC,
.flags = FLAGS,
.checksum = ~(MAGIC +% FLAGS) +% 1,
};
};
export var stack_bytes: [16 * 1024]u8 align(16) linksection(".bss") = undefined; export var stack_bytes: [16 * 1024]u8 align(16) linksection(".bss") = undefined;
const stack_bytes_slice = stack_bytes[0..]; const stack_bytes_slice = stack_bytes[0..];
// linker.ld entrypoint // linker.ld entrypoint
export nakedcc fn _start() noreturn { export nakedcc fn __start() noreturn {
// ebx -> multiboot info
const info: u32 = asm volatile (""
: [result] "={ebx}" (-> u32)
);
// eax -> multiboot magic // eax -> multiboot magic
const magic: u32 = asm volatile ("" const magic: u32 = asm volatile (""
: [result] "={eax}" (-> u32) : [result] "={eax}" (-> u32)
); );
// ebx -> multiboot info
const info: u32 = asm volatile (""
: [result] "={ebx}" (-> u32)
);
@newStackCall(stack_bytes_slice, kmain, magic, @intToPtr(*const multiboot.MultibootInfo, info)); @newStackCall(stack_bytes_slice, kmain, magic, @intToPtr(*const multiboot.MultibootInfo, info));
while (true) {} // @newStackCall(stack_bytes_slice, kmain);
} }
// arch independant initialization // arch independant initialization
fn kmain(magic: u32, info: *const multiboot.MultibootInfo) noreturn { fn kmain(magic: u32, info: *const multiboot.MultibootInfo) noreturn {
assert(magic == multiboot.MULTIBOOT_BOOTLOADER_MAGIC);
clear(); clear();
println("--- {x} ---", magic);
// assert(magic == multiboot.MULTIBOOT_BOOTLOADER_MAGIC);
println("--- x86 initialization ---"); println("--- x86 initialization ---");
x86.x86_main(info); x86.x86_main(info);
println("--- core initialization ---"); println("--- core initialization ---");

17
src/multiboot.zig
View file

@ -124,7 +124,7 @@ pub const MultibootModule = packed struct {
}; };
// Multiboot structure to be read by the bootloader. // Multiboot structure to be read by the bootloader.
const MultibootHeader = packed struct { pub const MultibootHeader = packed struct {
magic: u32, // Must be equal to header magic number. magic: u32, // Must be equal to header magic number.
flags: u32, // Feature flags. flags: u32, // Feature flags.
checksum: u32, // Above fields plus this one must equal 0 mod 2^32. checksum: u32, // Above fields plus this one must equal 0 mod 2^32.
@ -136,18 +136,3 @@ const MultibootHeader = packed struct {
entry_addr: u32 = 0, entry_addr: u32 = 0,
}; };
// NOTE: this structure is incomplete. // NOTE: this structure is incomplete.
// Place the header at the very beginning of the binary.
export const multiboot_header align(4) linksection(".multiboot") = multiboot: {
const MAGIC = u32(0x1BADB002); // multiboot magic
const ALIGN = u32(1 << 0); // Align loaded modules at 4k
const MEMINFO = u32(1 << 1); // Receive a memory map from the bootloader.
const ADDR = u32(1 << 16); // Load specific addr
const FLAGS = ALIGN | MEMINFO; // Combine the flags.
break :multiboot MultibootHeader{
.magic = MAGIC,
.flags = FLAGS,
.checksum = ~(MAGIC +% FLAGS) +% 1,
};
};

157
src/pci.zig
View file

@ -1,157 +0,0 @@
usingnamespace @import("kernel");
const arch = @import("x86");
const std = @import("std");
const virtio = @import("virtio.zig");
const PCI_CONFIG_ADDRESS = 0xCF8;
const PCI_CONFIG_DATA = 0xCFC;
// https://wiki.osdev.org/Pci
pub const PciAddress = packed struct {
offset: u8,
function: u3,
slot: u5,
bus: u8,
reserved: u7,
enable: u1,
};
pub const PciDevice = struct {
bus: u8,
slot: u5,
function: u3,
vendor: u16 = undefined,
pub fn init(bus: u8, slot: u5, function: u3) ?PciDevice {
var dev = PciDevice{ .bus = bus, .slot = slot, .function = function };
dev.vendor = dev.vendor();
if (dev.vendor == 0xffff) return null;
return dev;
}
pub fn address(self: PciDevice, offset: u8) u32 {
var addr = PciAddress{
.enable = 1,
.reserved = 0,
.bus = self.bus,
.slot = self.slot,
.function = self.function,
.offset = offset,
};
return @bitCast(u32, addr);
}
pub fn format(self: PciDevice) void {
print("{}:{}.{}", self.bus, self.slot, self.function);
print(" {x},{x:2}", self.class(), self.subclass());
print(" 0x{x},0x{x}", self.vendor, self.device());
if (self.driver()) |d|
print(" {}", d.name);
println("");
}
pub fn driver(self: PciDevice) ?Driver {
var i: usize = 0;
while (i < Drivers.len) : (i += 1) {
var drv = Drivers[i];
if (self.class() != drv.class or self.subclass() != drv.subclass)
continue;
if (drv.vendor) |v| if (self.vendor != v)
continue;
if (drv.subsystem) |ss| if (self.subsystem() != ss)
continue;
return drv;
}
return null;
}
// 0 1 2 3
// 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | vendor ID | device ID |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | command | status |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | revision ID | prog IF | subclass | class |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// |cache line size| latency timer | header type | bist |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
pub fn vendor(self: PciDevice) u16 {
return self.config_read(u16, 0x0);
}
pub fn device(self: PciDevice) u16 {
return self.config_read(u16, 0x2);
}
pub fn subclass(self: PciDevice) u8 {
return self.config_read(u8, 0xa);
}
pub fn class(self: PciDevice) u8 {
return self.config_read(u8, 0xb);
}
pub fn header_type(self: PciDevice) u8 {
return self.config_read(u8, 0xe);
}
// only for header_type == 0
pub fn subsystem(self: PciDevice) u16 {
return self.config_read(u8, 0x2e);
}
pub inline fn config_read(self: PciDevice, comptime size: type, comptime offset: u8) size {
// ask for access before reading config
arch.outl(PCI_CONFIG_ADDRESS, self.address(offset));
switch (size) {
// read the correct size
u8 => return arch.inb(PCI_CONFIG_DATA),
u16 => return arch.inw(PCI_CONFIG_DATA),
u32 => return arch.inl(PCI_CONFIG_DATA),
else => @compileError("pci config space only supports reading u8, u16, u32."),
}
}
};
const Driver = struct {
name: [*]u8,
class: u8,
subclass: u8,
vendor: ?u16 = null,
subsystem: ?u16 = null,
init: fn (PciDevice) void,
};
const name = "virtio-blk";
pub var Drivers: [1]Driver = [_]Driver{Driver{ .name = &name, .class = 0x1, .subclass = 0x0, .vendor = 0x1af4, .subsystem = 0x2, .init = virtio.init }};
// TODO: factor 2 functions when anonymous fn is released
pub fn scan() void {
var slot: u5 = 0;
// 0..31
while (slot <= std.math.maxInt(u5)) : (slot += 1) {
if (PciDevice.init(0, slot, 0)) |dev| {
var function: u3 = 0;
// 0..7
while (function <= std.math.maxInt(u3)) : (function += 1) {
if (PciDevice.init(0, slot, function)) |vf| {
if (vf.driver()) |d| d.init(vf);
}
}
}
}
}
pub fn lspci() void {
var slot: u5 = 0;
println("b:s.f c,s v d drv");
// 0..31
while (slot <= std.math.maxInt(u5)) : (slot += 1) {
if (PciDevice.init(0, slot, 0)) |dev| {
var function: u3 = 0;
// 0..7
while (function <= std.math.maxInt(u3)) : (function += 1) {
if (PciDevice.init(0, slot, function)) |vf| {
vf.format();
}
}
}
}
}

4
src/ps2.zig
View file

@ -1,5 +1,5 @@
usingnamespace @import("kernel"); usingnamespace @import("index.zig");
const x86 = @import("x86"); // const x86 = @import("x86");
const PS2_DATA = 0x60; const PS2_DATA = 0x60;
const PS2_STATUS = 0x64; const PS2_STATUS = 0x64;

18
src/vga.zig
View file

@ -1,4 +1,4 @@
const arch = @import("x86"); const x86 = @import("arch/x86/index.zig");
const std = @import("std"); const std = @import("std");
// Screen size. // Screen size.
@ -156,10 +156,10 @@ const VGA = struct {
// Use the software cursor as the source of truth. // Use the software cursor as the source of truth.
// //
pub fn updateCursor(self: *const VGA) void { pub fn updateCursor(self: *const VGA) void {
arch.outb(0x3D4, 0x0F); x86.outb(0x3D4, 0x0F);
arch.outb(0x3D5, @truncate(u8, self.cursor)); x86.outb(0x3D5, @truncate(u8, self.cursor));
arch.outb(0x3D4, 0x0E); x86.outb(0x3D4, 0x0E);
arch.outb(0x3D5, @truncate(u8, self.cursor >> 8)); x86.outb(0x3D5, @truncate(u8, self.cursor >> 8));
} }
//// ////
@ -169,11 +169,11 @@ const VGA = struct {
pub fn fetchCursor(self: *VGA) void { pub fn fetchCursor(self: *VGA) void {
var cursor: usize = 0; var cursor: usize = 0;
arch.outb(0x3D4, 0x0E); x86.outb(0x3D4, 0x0E);
cursor |= usize(arch.inb(0x3D5)) << 8; cursor |= usize(x86.inb(0x3D5)) << 8;
arch.outb(0x3D4, 0x0F); x86.outb(0x3D4, 0x0F);
cursor |= arch.inb(0x3D5); cursor |= x86.inb(0x3D5);
self.cursor = cursor; self.cursor = cursor;
} }

22
src/virtio.zig
View file

@ -1,22 +0,0 @@
usingnamespace @import("kernel");
pub fn init(pci: PciDevice) void {
println("-- virtio-block init --");
pci.format();
assert(pci.header_type() == 0x0); // mass storage device
assert(pci.subsystem() == 0x2); // virtio-block
const intr_line = pci.config_read(u8, 0x3c);
const intr_pin = pci.config_read(u8, 0x3d);
const min_grant = pci.config_read(u8, 0x3e);
const max_lat = pci.config_read(u8, 0x3f);
println("{x} {} {} {}", intr_line, intr_pin, min_grant, max_lat);
println("dev features =0x{x}", pci.config_read(u32, 0x10));
println("guest features=0x{x}", pci.config_read(u32, 0x14));
println("queue addr =0x{x}", pci.config_read(u32, 0x18));
println("queue size =0x{x}", pci.config_read(u16, 0x1c));
println("queue select =0x{x}", pci.config_read(u16, 0x1e));
println("queue notify =0x{x}", pci.config_read(u16, 0x20));
println("device status =0x{x}", pci.config_read(u8, 0x22));
println("isr status =0x{x}", pci.config_read(u8, 0x23));
}