Operator-system/docs/interrupts-and-exceptions.md

## Interrupt and exception handling overview

The kernel's interrupt/exception handling is implemented in `idt.c` and a companion assembly file `isr.S` (not shown here). The design goals are:

- Preserve the firmware's existing hardware interrupt handlers where possible.
- Override CPU **exception vectors 0–31** with kernel stubs that route into a C dispatcher.
- Print detailed diagnostics for exceptions and halt on unrecoverable faults.

---

## IDT representation

The x86-64 Interrupt Descriptor Table (IDT) is represented as an array of packed 16-byte entries:

```22:37:/home/lochlan/Documents/Coding/c/os/idt.c
typedef struct {
    UINT16 offset_low;      /* bits  0-15 of handler address */
    UINT16 selector;        /* code segment selector         */
    UINT8  ist;             /* interrupt stack table index    */
    UINT8  type_attr;       /* type and attributes           */
    UINT16 offset_mid;      /* bits 16-31 of handler address */
    UINT32 offset_high;     /* bits 32-63 of handler address */
    UINT32 zero;            /* reserved, must be zero        */
} __attribute__((packed)) IdtEntry;

typedef struct {
    UINT16 limit;
    UINT64 base;
} __attribute__((packed)) IdtPtr;
```

Module state:

```42:47:/home/lochlan/Documents/Coding/c/os/idt.c
static IdtEntry  idt[IDT_SIZE];
static BootInfo *gBoot = NULL;

/* Defined in isr.S – one stub function per vector (0-255). */
extern void (*isr_stub_table[])(void);
```

Each element of `isr_stub_table` is a low-level assembly stub that:

- Saves CPU state into an `ISRFrame`.
- Calls the common C dispatcher `isr_handler`.
- Restores state and performs `iretq` (for IRQs) or loops into a halt (for fatal faults).

---

## Installing IDT entries

`idt_set_gate` encodes a handler function pointer into an IDT entry:

```53:67:/home/lochlan/Documents/Coding/c/os/idt.c
static void idt_set_gate(UINTN index, void (*handler)(void))
{
    UINT64 addr = (UINT64)(UINTN)handler;
    UINT16 selector = 0;

    __asm__ __volatile__("mov %%cs, %0" : "=r"(selector));

    idt[index].offset_low = (UINT16)(addr & 0xFFFF);
    idt[index].selector = selector;
    idt[index].ist = 0;
    idt[index].type_attr = IDT_TYPE_INTERRUPT;
    idt[index].offset_mid = (UINT16)((addr >> 16) & 0xFFFF);
    idt[index].offset_high = (UINT32)((addr >> 32) & 0xFFFFFFFF);
    idt[index].zero = 0;
}
```

`lidt` loads a new IDTR:

```69:73:/home/lochlan/Documents/Coding/c/os/idt.c
static void lidt(const IdtPtr *idtr)
{
    __asm__ __volatile__("lidt (%0)" :: "r"(idtr));
}
```

---

## Exception names

For better diagnostics, the kernel maps exception vectors to human-readable names:

```80:116:/home/lochlan/Documents/Coding/c/os/idt.c
static const CHAR16 *exception_name(UINTN vector)
{
    switch (vector) {
    case 0: return L"Divide Error";
    case 1: return L"Debug";
    ...
    case 14: return L"Page Fault";
    ...
    case 30: return L"Security";
    case 31: return L"Reserved";
    default: return L"Unknown";
    }
}
```

These strings are used by `isr_handler` when printing exception banners.

---

## PIC helpers and halting

The kernel provides minimal support for acknowledging legacy PIC interrupts and halting the CPU in fatal cases:

```124:136:/home/lochlan/Documents/Coding/c/os/idt.c
static inline void outb(UINT16 port, UINT8 value)
{
    __asm__ __volatile__("outb %0, %1" :: "a"(value), "Nd"(port));
}

static void pic_eoi(UINTN vector)
{
    if (vector >= 40) {
        outb(0xA0, 0x20);  /* EOI to slave PIC */
    }
    outb(0x20, 0x20);      /* EOI to master PIC */
}
```

`halt_forever` disables interrupts and executes `hlt` in an infinite loop:

```138:144:/home/lochlan/Documents/Coding/c/os/idt.c
static void halt_forever(void)
{
    for (;;) {
        __asm__ __volatile__("cli; hlt");
    }
}
```

---

## ISR dispatcher (`isr_handler`)

`isr_handler` is the central C function that receives control from all exception and interrupt stubs:

```150:177:/home/lochlan/Documents/Coding/c/os/idt.c
void isr_handler(ISRFrame *frame)
{
    UINT64 cr2 = 0;

    /* Hardware IRQs (vectors 32-47): send EOI and return */
    if (frame->vector >= 32 && frame->vector <= 47) {
        pic_eoi(frame->vector);
        return;
    }

    /* CPU exceptions (vectors 0-31): print diagnostics and halt */
    if (gBoot != NULL && gBoot->print != NULL) {
        gBoot->print(L"\n\rEXCEPTION: %d (%s)\n\r", frame->vector,
                     exception_name(frame->vector));
        gBoot->print(L"  Error Code: 0x%lx\n\r", frame->error_code);
        gBoot->print(L"  RIP: 0x%lx  CS: 0x%lx  RFLAGS: 0x%lx\n\r",
                     frame->rip, frame->cs, frame->rflags);
    }

    if (frame->vector == 14) {
        __asm__ __volatile__("mov %%cr2, %0" : "=r"(cr2));
        if (gBoot != NULL && gBoot->print != NULL) {
            gBoot->print(L"  CR2: 0x%lx\n\r", cr2);
        }
    }

    halt_forever();
}
```

The `ISRFrame` structure (defined in `idt.h`) contains the state saved by the assembly stubs, including:

- Exception/interrupt vector number.
- Error code (if applicable).
- `RIP`, `CS`, and `RFLAGS` at the time of the fault.

The handler's behaviour is:

- For **hardware IRQs** (vectors 32–47):
  - Send an **End Of Interrupt** (EOI) to the PIC.
  - Return to the interrupted context.
- For **CPU exceptions** (vectors 0–31):
  - Print a diagnostic header with the vector number and name.
  - Show error code and execution context (`RIP`, `CS`, `RFLAGS`).
  - For page faults (vector 14), read and print CR2 (faulting virtual address).
  - Halt the system via `halt_forever`.

This makes debugging faults significantly easier when running under QEMU or on real hardware.

---

## IDT initialisation (`idt_init`)

`idt_init` is called from `kmain` early during boot:

```183:214:/home/lochlan/Documents/Coding/c/os/idt.c
void idt_init(BootInfo *Boot)
{
    IdtPtr old_idtr;
    IdtPtr idtr;
    IdtEntry *old_idt = NULL;
    UINTN i = 0;

    gBoot = Boot;

    /* Read the firmware's existing IDT so we can preserve its entries */
    __asm__ __volatile__("sidt %0" : "=m"(old_idtr));
    old_idt = (IdtEntry *)(UINTN)old_idtr.base;

    /* Copy the entire existing IDT first (preserves firmware IRQ handlers) */
    for (i = 0; i < IDT_SIZE; i++) {
        if (old_idt != NULL && (i * sizeof(IdtEntry)) < (UINTN)(old_idtr.limit + 1)) {
            idt[i] = old_idt[i];
        } else {
            idt_set_gate(i, isr_stub_table[i]);
        }
    }

    /* Override only CPU exception vectors (0-31) with our handlers */
    for (i = 0; i < 32; i++) {
        idt_set_gate(i, isr_stub_table[i]);
    }

    idtr.limit = (UINT16)(sizeof(idt) - 1);
    idtr.base = (UINT64)(UINTN)idt;

    lidt(&idtr);
}
```

The process is:

1. **Capture firmware IDT**:
   - `sidt` reads the current IDTR into `old_idtr`.
   - `old_idt` is set to the base of the firmware's IDT.
2. **Copy firmware entries**:
   - For all indices `i` where the address lies within the firmware's IDT limit, copy the existing entry into the kernel's `idt` array.
   - For indices beyond the firmware's limit, install the kernel's own stub from `isr_stub_table`.
3. **Override CPU exceptions**:
   - For vectors 0–31, call `idt_set_gate` with the kernel's stubs, ensuring that exceptions are always handled by `isr_handler`.
4. **Activate new IDT**:
   - Populate `idtr` with the address and size of the kernel's `idt`.
   - Call `lidt` to load the new IDT.

This approach preserves any firmware-installed handlers for higher interrupt vectors (e.g., hardware IRQs or system-specific events), while guaranteeing full control over CPU exception handling.

---

## Interaction with the rest of the kernel

The IDT/ISR subsystem interacts with other parts of the kernel in the following ways:

- **BootInfo access**:
  - `id_tinit` stores `Boot` in `gBoot` so that `isr_handler` can safely use `Boot->print` for diagnostics.
- **Memory subsystem**:
  - `isr_handler` reads CR2 for page faults; combined with `paging_get_phys` from `memory.c`, this can be used to inspect paging state.
- **Tasks and scheduler**:
  - The current implementation is **non-preemptive**: context switches happen only through explicit calls to `task_yield`, not timer interrupts. Exceptions still interrupt tasks asynchronously, but there is no timer tick driving the scheduler.
- **User-level diagnostics**:
  - When an exception occurs, the on-screen diagnostics provide enough context to identify the type of fault and its location in the kernel, especially when used alongside a symbol-enabled build and external debugger.

Future extensions might include:

- Installing a periodic timer IRQ handler that calls `task_yield` to add preemptive scheduling.
- Extending `ISRFrame` and `isr_handler` with richer diagnostics or a kernel debugger stub.