/* * arch/alpha/kernel/entry.S * * Kernel entry-points. */ #include #include #include #include #include .text .set noat /* Stack offsets. */ #define SP_OFF 184 #define SWITCH_STACK_SIZE 320 /* * This defines the normal kernel pt-regs layout. * * regs 9-15 preserved by C code * regs 16-18 saved by PAL-code * regs 29-30 saved and set up by PAL-code * JRP - Save regs 16-18 in a special area of the stack, so that * the palcode-provided values are available to the signal handler. */ #define SAVE_ALL \ subq $sp, SP_OFF, $sp; \ stq $0, 0($sp); \ stq $1, 8($sp); \ stq $2, 16($sp); \ stq $3, 24($sp); \ stq $4, 32($sp); \ stq $28, 144($sp); \ lda $2, alpha_mv; \ stq $5, 40($sp); \ stq $6, 48($sp); \ stq $7, 56($sp); \ stq $8, 64($sp); \ stq $19, 72($sp); \ stq $20, 80($sp); \ stq $21, 88($sp); \ ldq $2, HAE_CACHE($2); \ stq $22, 96($sp); \ stq $23, 104($sp); \ stq $24, 112($sp); \ stq $25, 120($sp); \ stq $26, 128($sp); \ stq $27, 136($sp); \ stq $2, 152($sp); \ stq $16, 160($sp); \ stq $17, 168($sp); \ stq $18, 176($sp) #define RESTORE_ALL \ lda $19, alpha_mv; \ ldq $0, 0($sp); \ ldq $1, 8($sp); \ ldq $2, 16($sp); \ ldq $3, 24($sp); \ ldq $21, 152($sp); \ ldq $20, HAE_CACHE($19); \ ldq $4, 32($sp); \ ldq $5, 40($sp); \ ldq $6, 48($sp); \ ldq $7, 56($sp); \ subq $20, $21, $20; \ ldq $8, 64($sp); \ beq $20, 99f; \ ldq $20, HAE_REG($19); \ stq $21, HAE_CACHE($19); \ stq $21, 0($20); \ ldq $0, 0($sp); \ ldq $1, 8($sp); \ 99:; \ ldq $19, 72($sp); \ ldq $20, 80($sp); \ ldq $21, 88($sp); \ ldq $22, 96($sp); \ ldq $23, 104($sp); \ ldq $24, 112($sp); \ ldq $25, 120($sp); \ ldq $26, 128($sp); \ ldq $27, 136($sp); \ ldq $28, 144($sp); \ addq $sp, SP_OFF, $sp /* * Non-syscall kernel entry points. */ .align 4 .globl entInt .ent entInt entInt: SAVE_ALL lda $8, 0x3fff lda $26, ret_from_sys_call bic $sp, $8, $8 mov $sp, $19 jsr $31, do_entInt .end entInt .align 4 .globl entArith .ent entArith entArith: SAVE_ALL lda $8, 0x3fff lda $26, ret_from_sys_call bic $sp, $8, $8 mov $sp, $18 jsr $31, do_entArith .end entArith .align 4 .globl entMM .ent entMM entMM: SAVE_ALL /* save $9 - $15 so the inline exception code can manipulate them. */ subq $sp, 56, $sp stq $9, 0($sp) stq $10, 8($sp) stq $11, 16($sp) stq $12, 24($sp) stq $13, 32($sp) stq $14, 40($sp) stq $15, 48($sp) addq $sp, 56, $19 /* handle the fault */ lda $8, 0x3fff bic $sp, $8, $8 jsr $26, do_page_fault /* reload the registers after the exception code played. */ ldq $9, 0($sp) ldq $10, 8($sp) ldq $11, 16($sp) ldq $12, 24($sp) ldq $13, 32($sp) ldq $14, 40($sp) ldq $15, 48($sp) addq $sp, 56, $sp /* finish up the syscall as normal. */ br ret_from_sys_call .end entMM .align 4 .globl entIF .ent entIF entIF: SAVE_ALL lda $8, 0x3fff lda $26, ret_from_sys_call bic $sp, $8, $8 mov $sp, $17 jsr $31, do_entIF .end entIF .align 4 .globl entUna .ent entUna entUna: lda $sp, -256($sp) stq $0, 0($sp) ldq $0, 256($sp) /* get PS */ stq $1, 8($sp) stq $2, 16($sp) stq $3, 24($sp) and $0, 8, $0 /* user mode? */ stq $4, 32($sp) bne $0, entUnaUser /* yup -> do user-level unaligned fault */ stq $5, 40($sp) stq $6, 48($sp) stq $7, 56($sp) stq $8, 64($sp) stq $9, 72($sp) stq $10, 80($sp) stq $11, 88($sp) stq $12, 96($sp) stq $13, 104($sp) stq $14, 112($sp) stq $15, 120($sp) /* 16-18 PAL-saved */ stq $19, 152($sp) stq $20, 160($sp) stq $21, 168($sp) stq $22, 176($sp) stq $23, 184($sp) stq $24, 192($sp) stq $25, 200($sp) stq $26, 208($sp) stq $27, 216($sp) stq $28, 224($sp) mov $sp, $19 stq $gp, 232($sp) lda $8, 0x3fff stq $31, 248($sp) bic $sp, $8, $8 jsr $26, do_entUna ldq $0, 0($sp) ldq $1, 8($sp) ldq $2, 16($sp) ldq $3, 24($sp) ldq $4, 32($sp) ldq $5, 40($sp) ldq $6, 48($sp) ldq $7, 56($sp) ldq $8, 64($sp) ldq $9, 72($sp) ldq $10, 80($sp) ldq $11, 88($sp) ldq $12, 96($sp) ldq $13, 104($sp) ldq $14, 112($sp) ldq $15, 120($sp) /* 16-18 PAL-saved */ ldq $19, 152($sp) ldq $20, 160($sp) ldq $21, 168($sp) ldq $22, 176($sp) ldq $23, 184($sp) ldq $24, 192($sp) ldq $25, 200($sp) ldq $26, 208($sp) ldq $27, 216($sp) ldq $28, 224($sp) ldq $gp, 232($sp) lda $sp, 256($sp) call_pal PAL_rti .end entUna .align 4 .ent entUnaUser entUnaUser: ldq $0, 0($sp) /* restore original $0 */ lda $sp, 256($sp) /* pop entUna's stack frame */ SAVE_ALL /* setup normal kernel stack */ lda $sp, -56($sp) stq $9, 0($sp) stq $10, 8($sp) stq $11, 16($sp) stq $12, 24($sp) stq $13, 32($sp) stq $14, 40($sp) stq $15, 48($sp) lda $8, 0x3fff addq $sp, 56, $19 bic $sp, $8, $8 jsr $26, do_entUnaUser ldq $9, 0($sp) ldq $10, 8($sp) ldq $11, 16($sp) ldq $12, 24($sp) ldq $13, 32($sp) ldq $14, 40($sp) ldq $15, 48($sp) lda $sp, 56($sp) br ret_from_sys_call .end entUnaUser .align 4 .globl entDbg .ent entDbg entDbg: SAVE_ALL lda $8, 0x3fff lda $26, ret_from_sys_call bic $sp, $8, $8 mov $sp, $16 jsr $31, do_entDbg .end entDbg /* * The system call entry point is special. Most importantly, it looks * like a function call to userspace as far as clobbered registers. We * do preserve the argument registers (for syscall restarts) and $26 * (for leaf syscall functions). * * So much for theory. We don't take advantage of this yet. * * Note that a0-a2 are not saved by PALcode as with the other entry points. */ .align 4 .globl entSys .globl ret_from_sys_call .ent entSys entSys: SAVE_ALL lda $8, 0x3fff bic $sp, $8, $8 lda $4, NR_SYSCALLS($31) stq $16, SP_OFF+24($sp) lda $5, sys_call_table lda $27, sys_ni_syscall cmpult $0, $4, $4 ldl $3, TI_FLAGS($8) stq $17, SP_OFF+32($sp) s8addq $0, $5, $5 stq $18, SP_OFF+40($sp) blbs $3, strace beq $4, 1f ldq $27, 0($5) 1: jsr $26, ($27), alpha_ni_syscall ldgp $gp, 0($26) blt $0, $syscall_error /* the call failed */ stq $0, 0($sp) stq $31, 72($sp) /* a3=0 => no error */ .align 4 ret_from_sys_call: cmovne $26, 0, $19 /* $19 = 0 => non-restartable */ ldq $0, SP_OFF($sp) and $0, 8, $0 beq $0, restore_all ret_from_reschedule: /* Make sure need_resched and sigpending don't change between sampling and the rti. */ lda $16, 7 call_pal PAL_swpipl ldl $5, TI_FLAGS($8) and $5, _TIF_WORK_MASK, $2 bne $5, work_pending restore_all: RESTORE_ALL call_pal PAL_rti .align 3 $syscall_error: /* * Some system calls (e.g., ptrace) can return arbitrary * values which might normally be mistaken as error numbers. * Those functions must zero $0 (v0) directly in the stack * frame to indicate that a negative return value wasn't an * error number.. */ ldq $19, 0($sp) /* old syscall nr (zero if success) */ beq $19, $ret_success ldq $20, 72($sp) /* .. and this a3 */ subq $31, $0, $0 /* with error in v0 */ addq $31, 1, $1 /* set a3 for errno return */ stq $0, 0($sp) mov $31, $26 /* tell "ret_from_sys_call" we can restart */ stq $1, 72($sp) /* a3 for return */ br ret_from_sys_call $ret_success: stq $0, 0($sp) stq $31, 72($sp) /* a3=0 => no error */ br ret_from_sys_call .end entSys /* * Do all cleanup when returning from all interrupts and system calls. * * Arguments: * $5: TI_FLAGS. * $8: current. * $19: The old syscall number, or zero if this is not a return * from a syscall that errored and is possibly restartable. * $20: Error indication. */ .align 4 .ent work_pending work_pending: and $5, _TIF_NEED_RESCHED, $2 beq $2, $work_notifysig $work_resched: subq $sp, 16, $sp stq $19, 0($sp) /* save syscall nr */ stq $20, 8($sp) /* and error indication (a3) */ jsr $26, schedule ldq $19, 0($sp) ldq $20, 8($sp) addq $sp, 16, $sp /* Make sure need_resched and sigpending don't change between sampling and the rti. */ lda $16, 7 call_pal PAL_swpipl ldl $5, TI_FLAGS($8) and $5, _TIF_WORK_MASK, $2 beq $2, restore_all and $5, _TIF_NEED_RESCHED, $2 bne $2, $work_resched $work_notifysig: mov $sp, $16 br $1, do_switch_stack mov $sp, $17 mov $5, $18 jsr $26, do_notify_resume bsr $1, undo_switch_stack br restore_all .end work_pending /* * PTRACE syscall handler */ .align 4 .ent strace strace: /* set up signal stack, call syscall_trace */ bsr $1, do_switch_stack jsr $26, syscall_trace bsr $1, undo_switch_stack /* get the system call number and the arguments back.. */ ldq $0, 0($sp) ldq $16, SP_OFF+24($sp) ldq $17, SP_OFF+32($sp) ldq $18, SP_OFF+40($sp) ldq $19, 72($sp) ldq $20, 80($sp) ldq $21, 88($sp) /* get the system call pointer.. */ lda $1, NR_SYSCALLS($31) lda $2, sys_call_table lda $27, alpha_ni_syscall cmpult $0, $1, $1 s8addq $0, $2, $2 beq $1, 1f ldq $27, 0($2) 1: jsr $26, ($27), sys_gettimeofday ldgp $gp, 0($26) /* check return.. */ blt $0, $strace_error /* the call failed */ stq $31, 72($sp) /* a3=0 => no error */ $strace_success: stq $0, 0($sp) /* save return value */ bsr $1, do_switch_stack jsr $26, syscall_trace bsr $1, undo_switch_stack br $31, ret_from_sys_call .align 3 $strace_error: ldq $19, 0($sp) /* old syscall nr (zero if success) */ beq $19, $strace_success ldq $20, 72($sp) /* .. and this a3 */ subq $31, $0, $0 /* with error in v0 */ addq $31, 1, $1 /* set a3 for errno return */ stq $0, 0($sp) stq $1, 72($sp) /* a3 for return */ bsr $1, do_switch_stack mov $19, $9 /* save old syscall number */ mov $20, $10 /* save old a3 */ jsr $26, syscall_trace mov $9, $19 mov $10, $20 bsr $1, undo_switch_stack mov $31, $26 /* tell "ret_from_sys_call" we can restart */ br ret_from_sys_call .end strace /* * Save and restore the switch stack -- aka the balance of the user context. */ .align 4 .ent do_switch_stack do_switch_stack: lda $sp, -SWITCH_STACK_SIZE($sp) stq $9, 0($sp) stq $10, 8($sp) stq $11, 16($sp) stq $12, 24($sp) stq $13, 32($sp) stq $14, 40($sp) stq $15, 48($sp) stq $26, 56($sp) stt $f0, 64($sp) stt $f1, 72($sp) stt $f2, 80($sp) stt $f3, 88($sp) stt $f4, 96($sp) stt $f5, 104($sp) stt $f6, 112($sp) stt $f7, 120($sp) stt $f8, 128($sp) stt $f9, 136($sp) stt $f10, 144($sp) stt $f11, 152($sp) stt $f12, 160($sp) stt $f13, 168($sp) stt $f14, 176($sp) stt $f15, 184($sp) stt $f16, 192($sp) stt $f17, 200($sp) stt $f18, 208($sp) stt $f19, 216($sp) stt $f20, 224($sp) stt $f21, 232($sp) stt $f22, 240($sp) stt $f23, 248($sp) stt $f24, 256($sp) stt $f25, 264($sp) stt $f26, 272($sp) stt $f27, 280($sp) mf_fpcr $f0 # get fpcr stt $f28, 288($sp) stt $f29, 296($sp) stt $f30, 304($sp) stt $f0, 312($sp) # save fpcr in slot of $f31 ldt $f0, 64($sp) # dont let "do_switch_stack" change fp state. ret $31, ($1), 1 .end do_switch_stack .align 4 .ent undo_switch_stack undo_switch_stack: ldq $9, 0($sp) ldq $10, 8($sp) ldq $11, 16($sp) ldq $12, 24($sp) ldq $13, 32($sp) ldq $14, 40($sp) ldq $15, 48($sp) ldq $26, 56($sp) ldt $f30, 312($sp) # get saved fpcr ldt $f0, 64($sp) ldt $f1, 72($sp) ldt $f2, 80($sp) ldt $f3, 88($sp) mt_fpcr $f30 # install saved fpcr ldt $f4, 96($sp) ldt $f5, 104($sp) ldt $f6, 112($sp) ldt $f7, 120($sp) ldt $f8, 128($sp) ldt $f9, 136($sp) ldt $f10, 144($sp) ldt $f11, 152($sp) ldt $f12, 160($sp) ldt $f13, 168($sp) ldt $f14, 176($sp) ldt $f15, 184($sp) ldt $f16, 192($sp) ldt $f17, 200($sp) ldt $f18, 208($sp) ldt $f19, 216($sp) ldt $f20, 224($sp) ldt $f21, 232($sp) ldt $f22, 240($sp) ldt $f23, 248($sp) ldt $f24, 256($sp) ldt $f25, 264($sp) ldt $f26, 272($sp) ldt $f27, 280($sp) ldt $f28, 288($sp) ldt $f29, 296($sp) ldt $f30, 304($sp) lda $sp, SWITCH_STACK_SIZE($sp) ret $31, ($1), 1 .end undo_switch_stack /* * The meat of the context switch code. */ .align 4 .globl alpha_switch_to .ent alpha_switch_to alpha_switch_to: .prologue 0 bsr $1, do_switch_stack call_pal PAL_swpctx lda $8, 0x3fff bsr $1, undo_switch_stack bic $sp, $8, $8 mov $17, $0 ret .end alpha_switch_to /* * New processes begin life here. */ .globl ret_from_fork .align 4 .ent ret_from_fork ret_from_fork: lda $26, ret_from_sys_call mov $17, $16 jmp $31, schedule_tail .end ret_from_fork /* * kernel_thread(fn, arg, clone_flags) */ .align 4 .globl kernel_thread .ent kernel_thread kernel_thread: /* We can be called from a module. */ ldgp $gp, 0($27) .prologue 1 subq $sp, SP_OFF+6*8, $sp br $1, 2f /* load start address */ /* We've now "returned" from a fake system call. */ unop blt $0, 1f /* error? */ ldi $1, 0x3fff beq $20, 1f /* parent or child? */ bic $sp, $1, $8 /* in child. */ jsr $26, ($27) ldgp $gp, 0($26) mov $0, $16 mov $31, $26 jmp $31, sys_exit 1: ret /* in parent. */ .align 4 2: /* Fake a system call stack frame, as we can't do system calls from kernel space. Note that we store FN and ARG as they need to be set up in the child for the call. Also store $8 and $26 for use in the parent. */ stq $31, SP_OFF($sp) /* ps */ stq $1, SP_OFF+8($sp) /* pc */ stq $gp, SP_OFF+16($sp) /* gp */ stq $16, 136($sp) /* $27; FN for child */ stq $17, SP_OFF+24($sp) /* $16; ARG for child */ stq $8, 64($sp) /* $8 */ stq $26, 128($sp) /* $26 */ /* Avoid the HAE being gratuitously wrong, to avoid restoring it. */ ldq $2, alpha_mv+HAE_CACHE stq $2, 152($sp) /* HAE */ /* Shuffle FLAGS to the front; add CLONE_VM. */ ldi $1, CLONE_VM|CLONE_UNTRACED or $18, $1, $16 bsr $26, sys_clone /* We don't actually care for a3 success widgetry in the kernel. Not for positive errno values. */ stq $0, 0($sp) /* $0 */ br restore_all .end kernel_thread /* * kernel_execve(path, argv, envp) */ .align 4 .globl kernel_execve .ent kernel_execve kernel_execve: /* We can be called from a module. */ ldgp $gp, 0($27) lda $sp, -(32+SIZEOF_PT_REGS+8)($sp) .frame $sp, 32+SIZEOF_PT_REGS+8, $26, 0 stq $26, 0($sp) stq $16, 8($sp) stq $17, 16($sp) stq $18, 24($sp) .prologue 1 lda $16, 32($sp) lda $17, 0 lda $18, SIZEOF_PT_REGS bsr $26, memset !samegp /* Avoid the HAE being gratuitously wrong, which would cause us to do the whole turn off interrupts thing and restore it. */ ldq $2, alpha_mv+HAE_CACHE stq $2, 152+32($sp) ldq $16, 8($sp) ldq $17, 16($sp) ldq $18, 24($sp) lda $19, 32($sp) bsr $26, do_execve !samegp ldq $26, 0($sp) bne $0, 1f /* error! */ /* Move the temporary pt_regs struct from its current location to the top of the kernel stack frame. See copy_thread for details for a normal process. */ lda $16, 0x4000 - SIZEOF_PT_REGS($8) lda $17, 32($sp) lda $18, SIZEOF_PT_REGS bsr $26, memmove !samegp /* Take that over as our new stack frame and visit userland! */ lda $sp, 0x4000 - SIZEOF_PT_REGS($8) br $31, ret_from_sys_call 1: lda $sp, 32+SIZEOF_PT_REGS+8($sp) ret .end kernel_execve /* * Special system calls. Most of these are special in that they either * have to play switch_stack games or in some way use the pt_regs struct. */ .align 4 .globl sys_fork .ent sys_fork sys_fork: .prologue 0 mov $sp, $21 bsr $1, do_switch_stack bis $31, SIGCHLD, $16 mov $31, $17 mov $31, $18 mov $31, $19 mov $31, $20 jsr $26, alpha_clone bsr $1, undo_switch_stack ret .end sys_fork .align 4 .globl sys_clone .ent sys_clone sys_clone: .prologue 0 mov $sp, $21 bsr $1, do_switch_stack /* $16, $17, $18, $19, $20 come from the user. */ jsr $26, alpha_clone bsr $1, undo_switch_stack ret .end sys_clone .align 4 .globl sys_vfork .ent sys_vfork sys_vfork: .prologue 0 mov $sp, $16 bsr $1, do_switch_stack jsr $26, alpha_vfork bsr $1, undo_switch_stack ret .end sys_vfork .align 4 .globl sys_sigreturn .ent sys_sigreturn sys_sigreturn: .prologue 0 mov $sp, $17 lda $18, -SWITCH_STACK_SIZE($sp) lda $sp, -SWITCH_STACK_SIZE($sp) jsr $26, do_sigreturn br $1, undo_switch_stack br ret_from_sys_call .end sys_sigreturn .align 4 .globl sys_rt_sigreturn .ent sys_rt_sigreturn sys_rt_sigreturn: .prologue 0 mov $sp, $17 lda $18, -SWITCH_STACK_SIZE($sp) lda $sp, -SWITCH_STACK_SIZE($sp) jsr $26, do_rt_sigreturn br $1, undo_switch_stack br ret_from_sys_call .end sys_rt_sigreturn .align 4 .globl sys_sigsuspend .ent sys_sigsuspend sys_sigsuspend: .prologue 0 mov $sp, $17 br $1, do_switch_stack mov $sp, $18 subq $sp, 16, $sp stq $26, 0($sp) jsr $26, do_sigsuspend ldq $26, 0($sp) lda $sp, SWITCH_STACK_SIZE+16($sp) ret .end sys_sigsuspend .align 4 .globl sys_rt_sigsuspend .ent sys_rt_sigsuspend sys_rt_sigsuspend: .prologue 0 mov $sp, $18 br $1, do_switch_stack mov $sp, $19 subq $sp, 16, $sp stq $26, 0($sp) jsr $26, do_rt_sigsuspend ldq $26, 0($sp) lda $sp, SWITCH_STACK_SIZE+16($sp) ret .end sys_rt_sigsuspend .align 4 .globl sys_sethae .ent sys_sethae sys_sethae: .prologue 0 stq $16, 152($sp) ret .end sys_sethae .align 4 .globl osf_getpriority .ent osf_getpriority osf_getpriority: lda $sp, -16($sp) stq $26, 0($sp) .prologue 0 jsr $26, sys_getpriority ldq $26, 0($sp) blt $0, 1f /* Return value is the unbiased priority, i.e. 20 - prio. This does result in negative return values, so signal no error by writing into the R0 slot. */ lda $1, 20 stq $31, 16($sp) subl $1, $0, $0 unop 1: lda $sp, 16($sp) ret .end osf_getpriority .align 4 .globl sys_getxuid .ent sys_getxuid sys_getxuid: .prologue 0 ldq $2, TI_TASK($8) ldl $0, TASK_UID($2) ldl $1, TASK_EUID($2) stq $1, 80($sp) ret .end sys_getxuid .align 4 .globl sys_getxgid .ent sys_getxgid sys_getxgid: .prologue 0 ldq $2, TI_TASK($8) ldl $0, TASK_GID($2) ldl $1, TASK_EGID($2) stq $1, 80($sp) ret .end sys_getxgid .align 4 .globl sys_getxpid .ent sys_getxpid sys_getxpid: .prologue 0 ldq $2, TI_TASK($8) /* See linux/kernel/timer.c sys_getppid for discussion about this loop. */ ldq $3, TASK_GROUP_LEADER($2) ldq $4, TASK_REAL_PARENT($3) ldl $0, TASK_TGID($2) 1: ldl $1, TASK_TGID($4) #ifdef CONFIG_SMP mov $4, $5 mb ldq $3, TASK_GROUP_LEADER($2) ldq $4, TASK_REAL_PARENT($3) cmpeq $4, $5, $5 beq $5, 1b #endif stq $1, 80($sp) ret .end sys_getxpid .align 4 .globl sys_alpha_pipe .ent sys_alpha_pipe sys_alpha_pipe: lda $sp, -16($sp) stq $26, 0($sp) .prologue 0 lda $16, 8($sp) jsr $26, do_pipe ldq $26, 0($sp) bne $0, 1f /* The return values are in $0 and $20. */ ldl $1, 12($sp) ldl $0, 8($sp) stq $1, 80+16($sp) 1: lda $sp, 16($sp) ret .end sys_alpha_pipe .align 4 .globl sys_execve .ent sys_execve sys_execve: .prologue 0 mov $sp, $19 jmp $31, do_sys_execve .end sys_execve .align 4 .globl osf_sigprocmask .ent osf_sigprocmask osf_sigprocmask: .prologue 0 mov $sp, $18 jmp $31, do_osf_sigprocmask .end osf_sigprocmask .align 4 .globl alpha_ni_syscall .ent alpha_ni_syscall alpha_ni_syscall: .prologue 0 /* Special because it also implements overflow handling via syscall number 0. And if you recall, zero is a special trigger for "not an error". Store large non-zero there. */ lda $0, -ENOSYS unop stq $0, 0($sp) ret .end alpha_ni_syscall