/* * linux/kernel/sys_call.S * * Copyright (C) 1991, 1992 Linus Torvalds */ /* * sys_call.S contains the system-call and fault low-level handling routines. * This also contains the timer-interrupt handler, as well as all interrupts * and faults that can result in a task-switch. * * NOTE: This code handles signal-recognition, which happens every time * after a timer-interrupt and after each system call. * * Stack layout in 'ret_from_system_call': * ptrace needs to have all regs on the stack. * if the order here is changed, it needs to be * updated in fork.c:copy_process, signal.c:do_signal, * ptrace.c and ptrace.h * * 0(%esp) - %ebx * 4(%esp) - %ecx * 8(%esp) - %edx * C(%esp) - %esi * 10(%esp) - %edi * 14(%esp) - %ebp * 18(%esp) - %eax * 1C(%esp) - %ds * 20(%esp) - %es * 24(%esp) - %fs * 28(%esp) - %gs * 2C(%esp) - orig_eax * 30(%esp) - %eip * 34(%esp) - %cs * 38(%esp) - %eflags * 3C(%esp) - %oldesp * 40(%esp) - %oldss */ EBX = 0x00 ECX = 0x04 EDX = 0x08 ESI = 0x0C EDI = 0x10 EBP = 0x14 EAX = 0x18 DS = 0x1C ES = 0x20 FS = 0x24 GS = 0x28 ORIG_EAX = 0x2C EIP = 0x30 CS = 0x34 EFLAGS = 0x38 OLDESP = 0x3C OLDSS = 0x40 /* * these are offsets into the task-struct. */ state = 0 counter = 4 priority = 8 signal = 12 sigaction = 16 # MUST be 16 (=len of sigaction) blocked = (33*16) /* * offsets within sigaction */ sa_handler = 0 sa_mask = 4 sa_flags = 8 sa_restorer = 12 ENOSYS = 38 /* * Ok, I get parallel printer interrupts while using the floppy for some * strange reason. Urgel. Now I just ignore them. */ .globl _system_call,_sys_execve .globl _device_not_available, _coprocessor_error .globl _divide_error,_debug,_nmi,_int3,_overflow,_bounds,_invalid_op .globl _double_fault,_coprocessor_segment_overrun .globl _invalid_TSS,_segment_not_present,_stack_segment .globl _general_protection,_reserved .globl _alignment_check,_page_fault .globl ret_from_sys_call #define SAVE_ALL \ cld; \ push %gs; \ push %fs; \ push %es; \ push %ds; \ pushl %eax; \ pushl %ebp; \ pushl %edi; \ pushl %esi; \ pushl %edx; \ pushl %ecx; \ pushl %ebx; \ movl $0x10,%edx; \ mov %dx,%ds; \ mov %dx,%es; \ movl $0x17,%edx; \ mov %dx,%fs .align 2 reschedule: pushl $ret_from_sys_call jmp _schedule .align 2 _system_call: pushl %eax # save orig_eax SAVE_ALL movl $-ENOSYS,EAX(%esp) cmpl _NR_syscalls,%eax jae ret_from_sys_call call _sys_call_table(,%eax,4) movl %eax,EAX(%esp) # save the return value ret_from_sys_call: cmpw $0x0f,CS(%esp) # was old code segment supervisor ? jne 2f cmpw $0x17,OLDSS(%esp) # was stack segment = 0x17 ? jne 2f 1: cmpl $0,_need_resched jne reschedule movl _current,%eax cmpl $0,state(%eax) # state jne reschedule cmpl $0,counter(%eax) # counter je reschedule movl $1,_need_resched cmpl _task,%eax # task[0] cannot have signals je 2f movl $0,_need_resched movl signal(%eax),%ebx movl blocked(%eax),%ecx notl %ecx andl %ebx,%ecx bsfl %ecx,%ecx je 2f btrl %ecx,%ebx movl %ebx,signal(%eax) movl %esp,%ebx pushl %ebx incl %ecx pushl %ecx call _do_signal popl %ecx popl %ebx testl %eax, %eax jne 1b # see if we need to switch tasks, or do more signals 2: popl %ebx popl %ecx popl %edx popl %esi popl %edi popl %ebp popl %eax pop %ds pop %es pop %fs pop %gs addl $4,%esp # skip the orig_eax iret .align 2 _sys_execve: lea (EIP+4)(%esp),%eax # don't forget about the return address. pushl %eax call _do_execve addl $4,%esp ret _divide_error: pushl $0 # no error code pushl $_do_divide_error error_code: push %fs push %es push %ds pushl %eax pushl %ebp pushl %edi pushl %esi pushl %edx pushl %ecx pushl %ebx cld movl $-1, %eax xchgl %eax, ORIG_EAX(%esp) # orig_eax (get the error code. ) xorl %ebx,%ebx # zero ebx mov %gs,%bx # get the lower order bits of gs xchgl %ebx, GS(%esp) # get the address and save gs. pushl %eax # push the error code lea 52(%esp),%edx pushl %edx movl $0x10,%edx mov %dx,%ds mov %dx,%es movl $0x17,%edx mov %dx,%fs call *%ebx addl $8,%esp jmp ret_from_sys_call .align 2 _coprocessor_error: pushl $0 pushl $_do_coprocessor_error jmp error_code .align 2 _device_not_available: pushl $-1 # mark this as an int SAVE_ALL pushl $ret_from_sys_call clts # clear TS so that we can use math movl %cr0,%eax testl $0x4,%eax # EM (math emulation bit) je _math_state_restore pushl $0 # temporary storage for ORIG_EIP call _math_emulate addl $4,%esp ret _debug: pushl $0 pushl $_do_debug jmp error_code _nmi: pushl $0 pushl $_do_nmi jmp error_code _int3: pushl $0 pushl $_do_int3 jmp error_code _overflow: pushl $0 pushl $_do_overflow jmp error_code _bounds: pushl $0 pushl $_do_bounds jmp error_code _invalid_op: pushl $0 pushl $_do_invalid_op jmp error_code _coprocessor_segment_overrun: pushl $0 pushl $_do_coprocessor_segment_overrun jmp error_code _reserved: pushl $0 pushl $_do_reserved jmp error_code _double_fault: pushl $_do_double_fault jmp error_code _invalid_TSS: pushl $_do_invalid_TSS jmp error_code _segment_not_present: pushl $_do_segment_not_present jmp error_code _stack_segment: pushl $_do_stack_segment jmp error_code _general_protection: pushl $_do_general_protection jmp error_code _alignment_check: pushl $_do_alignment_check jmp error_code _page_fault: pushl $_do_page_fault jmp error_code