Michael Petch

I have to do some other things now. Good luck!

Good idea.

The keyboard was the only one you had registered a handler for.

Yes, basically for any interrupt you don't have registered it will display "unhandled". You can change that all you want. The keyboard should work and print characters to the console.

I hang out mostly on OSDev, Stackoverflow, and Reddit helping people with their projects.

But I haven't made any of my small OS projects as a hobby available.

I have developed custom OSes for a client in the embedded space.

Since the early 2000s

Decades

I have the stubs calling interrupt_handler directly removing an extra layer to the interrupt processing. The interrupt number is now passed into interrupt handler as part of the interrupt_frame structure.

OKay, I have submitted a pull request. You can take a look at all the changes. But the big ones are that the stubs are generated using macros to reduce the copy and pasting. I have created an appropriate interrupt_frame structure that passes all the registers in. The stubs now push the segment selectors and set DS=ES=FS=GS to the kernel data selector (this will come in hnady when you use usermode).

I am looking at it now. I am doing some cleanup. The order you push things on the stack is a bit of a problem and you may have noticed the assembly code is a lot of copy and paste that can be reduced by using some macros. Give me about half an hour to come up with something a bit cleaner based on what you have.

I can check in in a little while. Just busy doing something at the moment

As well you push rsp . That should be mov rdi, rsp because in the System V ABI calling convention the first parameter is passed to a function in RDI. This differs from the 32-bit C calling convention which passes all parameters on the stack. More on the 64-bit calling convention is here: wiki.osdev.org/System_V_ABI#x86-64 . Before calling the C functions in the stubs you should also issue a CLD instruction before the call. This is a requirement of the x86-64 ABI as well.

Your interrupt stubs still need some cleanup. You need to save (before the call to a C function) and restore (after the call) all the registers. You are pushing an extra 0 in all the ISRs. You need to push an extra 0 when there is no error code. isr8_stub should not be pushing the extra 0 because the CPU puts an error code on the stack automatically. You can see this table to see which exceptions push an error code automatically: wiki.osdev.org/Exceptions

In idt.c you need to change all the entries to point to the assembly stubs. As an example from: idt_set_gate(32, (uint64_t)isr32, 0x08, 0x8E); to idt_set_gate(32, (uint64_t)isr32_stub, 0x08, 0x8E); . This code would have to be modified to send an EOI in the handlers to properly get future interrupts.

I really can't tell without seeing all the code changes you have made. Can you make your Github available again? I noticed you made it unavailable after we dealt with your last question.

The interrupt attribute does have limitations and I generally don't recommend it. It is documented here: gcc.gnu.org/onlinedocs/gcc/… . I prefer to write the ISR stubs in assembler.

You need to create ISR handlers that return with IRETQ. Most people create the stubs in assembly that set up the stack frame, call a C function with a pointer to the stack frame and then do an IRETQ. The other alternative to get things going is to mark your isr handler functions (like isr32, isr33 etc) with the __attribute__((interrupt)) . This will cause an iretq to be used to return rather than a ret.

The problem isn't in the code you are showing. The log at least tells you that you got a timer interrupt nd then nothing else. It just so happens I saw the problem during the last question you asked but it wasn't related to your first problem. The issue is that interrupt handlers need to end with iretq to return from interrupt. You are using C functions for ISR handlers and those return with a ret. The result of using ret is that your function doesn't properly restore things like the RFLAGS including the Interrupt Flag. IF stays off after the ret and you get no more interrupts.

Use the one at pastebin and not the one I pasted in the chat. There were a couple of mistakes in it that have been fixed here: pastebin.com/LBC3EMgt

The formatting on here was removed. You can find a better formatted version here: pastebin.com/raw/8GKCtBge

That linker script will always place .text and .data and .rodata sections in build/obj/boot.o first

And then replace -Ttext=0x7c00 in the linker options with -Tlink.ld

The problem is that you need to make sure that the boot.o object is listed first (in OBJ_FILES) otherwise the first time you add executable code to a C file it will be placed in the system.elf file first before anything else including your bootloader code which pushes everything further in the file including the boot signature.

It appears OI may have mistakenly deleted that comment though

I hinted you were going to have that problem in a comment I made.

Well it aligned on a 4k boundary. If it is the pg_dir address in the objdump then it is fine. If CR3 is not equal to pg_dir then there is a problem

It would probably be a good idea before int $0x13 in boot_load that you do mov $00, %dh to ensure the cylinder number is initialized (0 in your case). You initialize all other values except that one.

If you ever have an unexpected problem opening a disk image with BOCHS check the directory with the disk image and remove all the files ending with .lock .

It looks like the disk image (system.img) isn't big enough (minimum geometry) to be seen understood as a hard disk by QEMU or BOCHS. In the Makefile Just before dd if=$(BIN_DIR)/$(OS_BIN) of=$(BIN_DIR)/$(OS_IMG) conv=notrunc add this line dd if=/dev/zero of=$(BIN_DIR)/$(OS_IMG) bs=512 count=20160 . system.img will be about 9-10MiB in size with geometry of 20 cylinders, 16 heads and 63 sectors. Then make sure in debug-qemu that you use system.img and not system.bin so use @qemu-system-i386 -s -S -drive file=$(BIN_DIR)/$(OS_IMG),index=0,media=disk,format=raw

I ran both those and they worked. You can ignore the SMM interrupts at the start. Your code gets to the infinite loop without crashing now. It works in QEMU and BOCHS. If the SMM stuff is just confusing you then you can use -d int -M smm=off instead of -d int

The -d int you can remove if you wish. With that option though it will show all the exceptions and interrupts as they occurred which can be useful for debugging.

I see you removed the jmp . and replaced it with j_: hlt jmp j_ . The problem is that you needed to place that loop before the gdt_desc: otherwise you try to execute gdt_desc as code which will lead to garbage being executed and possibly crash.

Okay first thing I noticed was that the system.elf/system.bin didn't match the boot.S file in using .code16 and .code32. I had to do a make clean make all and the code looked correct except that somewhere along the line you removed the jmp . (infinite loop) that was just before gdt_desc: in boot.S . Without the infinite loop it will crash trying to exxceute garbage in memory.

I will forewarn you - the order that your object files (.o files) appear to the linker will matter if you start adding executable code (not just data) in your .c files. If boot.o isn't listed first when linking then it is possible .text (code) from other files may appear first and that will cause things to fail.

I ran it in BOCHs and QEMU. In both cases it worked. It went into an infinite loop and both were in protected mode with a proper GDT and paging was enabled (The first 4MiB were identity mapped). If you wish archive your system.elf and system.bin files and email them to me at [email protected] or create a github repo with all your code and Makefiles etc.

I made the change I suggested with the exact code here in thee question and it worked. I recommend ensuring that you are using the code you provided in the question as a starting point. I don't know if you've made other changes to the code you are using locally.

The start of your boot.S is being assembled as 32-bit code (the default when assembling with GCC using -m32), however you want the first part to be assembled as 16-bit code. Before _start: add the line .code16 to assemble as 16-bit code. Then on the line before protected_mode_start: add the line .code32 to tell the assembler to encode instructions as 32-bit code from that point on. I'd recommend using BOCHS to debug the early stage and bootloader.

"when I stepped through your code with GDB/QEMU the switch_task seemed to throw an exception after your code called switch_asm executed somewhere unexpected in memory." should have said "when I stepped through your code with GDB/QEMU the switch_task seemed to throw an exception after going somewhere in memory that wasn't expected - as in it jumped to the wrong memory address"

I don't have time to look at this just this minute, as I have to go out for a few hours but when I stepped through your code with GDB/QEMU the switch_task seemed to throw an exception after your code called switch_asm executed somewhere unexpected in memory. As I was heading out I noticed for some reason your code is now just throwing a page fault exception. Not sure if that was because of the debug info added. I'll have to look later.

If you don't have at least NASM 2.16.01 I highly recommend downloading the latest stable source and building it as it has a problem with debug output that was recently fixed. I suspect though that you received a second timer interrupt and the switch_task failed trying to switch the second time. THe script in the last comment also runs QEMU with the -d int option and redirects output to dbg.log . That log can help as it will tell you what exceptions and interrupts occurred before failure.

That would be a different problem of course. As I said I haven't actually looked at all how your code interacts. An observation though is that your switch_task seems to be based on something that was part of some co-operative multitasking code. I'd actually recommend compiling with debug output (gcc's -g option and nasm's -g option) and use QEMU and GDB remote debugging facility to debug. A script that launches QEMU and GDB can be found here: pastebin.com/TYtXGHgC .

You can call it before switch_task but I haven't investigated fully whether your code as written has potential other issues.

It's only called once for the reason given earlier. Once your code schedules and switches to the first task it sits in an infinite loop printing a and it never reaches the EOI code that acknowledges you processed IRQ0 (timer). Without acknowledging with an EOI you will not get another timer interrupt (or any external interrupt in the case of IRQ0 not being acknowledged). This is the case even if you have interrupts enabled (IF=1)

Your code (in the zip file) does send EOIs but the problem is more fundamental. You receive a timer interrupt, timer_handler gets called in interrupt context and the scheduler ends up starting fn which prints a in an infinite loop. While fn will have interrupts enabled because you set eflags with IF=1 when the task starts, you won't get another timer interrupt (or any interrupt for that matter) until an EOI is sent to the PICs. Because of this once fn goes into the infinite loop no fiuther timer interrupts will occur and thus the scheduler will never have a chance to switch tasks.

Do you send an EOI to acknowledge to the PIC that you've processed the interrupt? An EOI for IRQ0 through IRQ 0x07 (inclusive) which includes IRQ0 - is done by sending a 0x20 to the Master PIC at port 0x20. Do that before you IRET. We don't know what your schedule function looks like and how it all fits together. A minimal reproducible example would be useful.

"stack registers" should have been "stack variables"

I assume you found out that in your interrupt handlers (the assembly code) that you were popping the values off incorrectly. You have to pop things off in reverse order of how it was pushed.