/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #if !defined(lint) #include "assym.h" #endif /* * General assembly language routines. * It is the intent of this file to contain routines that are * specific to cpu architecture. */ /* * WARNING: If you add a fast trap handler which can be invoked by a * non-privileged user, you may have to use the FAST_TRAP_DONE macro * instead of "done" instruction to return back to the user mode. See * comments for the "fast_trap_done" entry point for more information. */ #define FAST_TRAP_DONE \ ba,a fast_trap_done /* * Override GET_NATIVE_TIME for the cpu module code. This is not * guaranteed to be exactly one instruction, be careful of using * the macro in delay slots. * * Do not use any instruction that modifies condition codes as the * caller may depend on these to remain unchanged across the macro. */ #define GET_NATIVE_TIME(out, scr1, scr2) \ rd STICK, out #define RD_TICKCMPR(out, scr) \ rd STICK_COMPARE, out #define WR_TICKCMPR(in,scr1,scr2,label) \ wr in, STICK_COMPARE #include #if defined(lint) #include #include #include #include #include #include #endif /* lint */ #include #include #include #include /* To get SYSBASE and PAGESIZE */ #include #include #include #include #include #include #include #include #if !defined(lint) #include "assym.h" #endif #define ICACHE_FLUSHSZ 0x20 #if defined(lint) /* * Softint generated when counter field of tick reg matches value field * of tick_cmpr reg */ /*ARGSUSED*/ void tickcmpr_set(uint64_t clock_cycles) {} #else /* lint */ ENTRY_NP(tickcmpr_set) ! get 64-bit clock_cycles interval mov %o0, %o2 mov 8, %o3 ! A reasonable initial step size 1: WR_TICKCMPR(%o2,%o4,%o5,__LINE__) ! Write to TICK_CMPR GET_NATIVE_TIME(%o0, %o4, %o5) ! Read %tick to confirm the sllx %o0, 1, %o0 ! value we wrote was in the future. srlx %o0, 1, %o0 cmp %o2, %o0 ! If the value we wrote was in the bg,pt %xcc, 2f ! future, then blow out of here. sllx %o3, 1, %o3 ! If not, then double our step size, ba,pt %xcc, 1b ! and take another lap. add %o0, %o3, %o2 ! 2: retl nop SET_SIZE(tickcmpr_set) #endif /* lint */ #if defined(lint) void tickcmpr_disable(void) {} #else ENTRY_NP(tickcmpr_disable) mov 1, %g1 sllx %g1, TICKINT_DIS_SHFT, %o0 WR_TICKCMPR(%o0,%o4,%o5,__LINE__) ! Write to TICK_CMPR retl nop SET_SIZE(tickcmpr_disable) #endif #if defined(lint) /* * tick_write_delta() increments %tick by the specified delta. This should * only be called after a CPR event to assure that gethrtime() continues to * increase monotonically. Obviously, writing %tick needs to de done very * carefully to avoid introducing unnecessary %tick skew across CPUs. For * this reason, we make sure we're i-cache hot before actually writing to * %tick. * * NOTE: No provision for this on sun4v right now. */ /*ARGSUSED*/ void tick_write_delta(uint64_t delta) {} #else /* lint */ .seg ".text" tick_write_delta_panic: .asciz "tick_write_delta: not supported" ENTRY_NP(tick_write_delta) sethi %hi(tick_write_delta_panic), %o1 save %sp, -SA(MINFRAME), %sp ! get a new window to preserve caller call panic or %i1, %lo(tick_write_delta_panic), %o0 /*NOTREACHED*/ retl nop #endif #if defined(lint) /* * return 1 if disabled */ int tickcmpr_disabled(void) { return (0); } #else /* lint */ ENTRY_NP(tickcmpr_disabled) RD_TICKCMPR(%g1, %o0) retl srlx %g1, TICKINT_DIS_SHFT, %o0 SET_SIZE(tickcmpr_disabled) #endif /* lint */ /* * Get current tick */ #if defined(lint) u_longlong_t gettick(void) { return (0); } #else /* lint */ ENTRY(gettick) GET_NATIVE_TIME(%o0, %o2, %o3) retl nop SET_SIZE(gettick) #endif /* lint */ /* * Return the counter portion of the tick register. */ #if defined(lint) uint64_t gettick_counter(void) { return(0); } #else /* lint */ ENTRY_NP(gettick_counter) rdpr %tick, %o0 sllx %o0, 1, %o0 retl srlx %o0, 1, %o0 ! shake off npt bit SET_SIZE(gettick_counter) #endif /* lint */ /* * Provide a C callable interface to the trap that reads the hi-res timer. * Returns 64-bit nanosecond timestamp in %o0 and %o1. */ #if defined(lint) hrtime_t gethrtime(void) { return ((hrtime_t)0); } hrtime_t gethrtime_unscaled(void) { return ((hrtime_t)0); } hrtime_t gethrtime_max(void) { return ((hrtime_t)0); } void scalehrtime(hrtime_t *hrt) { *hrt = 0; } void gethrestime(timespec_t *tp) { tp->tv_sec = 0; tp->tv_nsec = 0; } time_t gethrestime_sec(void) { return (0); } void gethrestime_lasttick(timespec_t *tp) { tp->tv_sec = 0; tp->tv_nsec = 0; } /*ARGSUSED*/ void hres_tick(void) { } void panic_hres_tick(void) { } #else /* lint */ ENTRY_NP(gethrtime) GET_HRTIME(%g1, %o0, %o1, %o2, %o3, %o4, %o5, %g2) ! %g1 = hrtime retl mov %g1, %o0 SET_SIZE(gethrtime) ENTRY_NP(gethrtime_unscaled) GET_NATIVE_TIME(%g1, %o2, %o3) ! %g1 = native time retl mov %g1, %o0 SET_SIZE(gethrtime_unscaled) ENTRY_NP(gethrtime_waitfree) ALTENTRY(dtrace_gethrtime) GET_NATIVE_TIME(%g1, %o2, %o3) ! %g1 = native time NATIVE_TIME_TO_NSEC(%g1, %o2, %o3) retl mov %g1, %o0 SET_SIZE(dtrace_gethrtime) SET_SIZE(gethrtime_waitfree) ENTRY(gethrtime_max) NATIVE_TIME_MAX(%g1) NATIVE_TIME_TO_NSEC(%g1, %o0, %o1) ! hrtime_t's are signed, max hrtime_t must be positive mov -1, %o2 brlz,a %g1, 1f srlx %o2, 1, %g1 1: retl mov %g1, %o0 SET_SIZE(gethrtime_max) ENTRY(scalehrtime) ldx [%o0], %o1 NATIVE_TIME_TO_NSEC(%o1, %o2, %o3) retl stx %o1, [%o0] SET_SIZE(scalehrtime) /* * Fast trap to return a timestamp, uses trap window, leaves traps * disabled. Returns a 64-bit nanosecond timestamp in %o0 and %o1. * * This is the handler for the ST_GETHRTIME trap. */ ENTRY_NP(get_timestamp) GET_HRTIME(%g1, %g2, %g3, %g4, %g5, %o0, %o1, %o2) ! %g1 = hrtime srlx %g1, 32, %o0 ! %o0 = hi32(%g1) srl %g1, 0, %o1 ! %o1 = lo32(%g1) FAST_TRAP_DONE SET_SIZE(get_timestamp) /* * Macro to convert GET_HRESTIME() bits into a timestamp. * * We use two separate macros so that the platform-dependent GET_HRESTIME() * can be as small as possible; CONV_HRESTIME() implements the generic part. */ #define CONV_HRESTIME(hrestsec, hrestnsec, adj, nslt, nano) \ brz,pt adj, 3f; /* no adjustments, it's easy */ \ add hrestnsec, nslt, hrestnsec; /* hrest.tv_nsec += nslt */ \ brlz,pn adj, 2f; /* if hrestime_adj negative */ \ srlx nslt, ADJ_SHIFT, nslt; /* delay: nslt >>= 4 */ \ subcc adj, nslt, %g0; /* hrestime_adj - nslt/16 */ \ movg %xcc, nslt, adj; /* adj by min(adj, nslt/16) */ \ ba 3f; /* go convert to sec/nsec */ \ add hrestnsec, adj, hrestnsec; /* delay: apply adjustment */ \ 2: addcc adj, nslt, %g0; /* hrestime_adj + nslt/16 */ \ bge,a,pt %xcc, 3f; /* is adj less negative? */ \ add hrestnsec, adj, hrestnsec; /* yes: hrest.nsec += adj */ \ sub hrestnsec, nslt, hrestnsec; /* no: hrest.nsec -= nslt/16 */ \ 3: cmp hrestnsec, nano; /* more than a billion? */ \ bl,pt %xcc, 4f; /* if not, we're done */ \ nop; /* delay: do nothing :( */ \ add hrestsec, 1, hrestsec; /* hrest.tv_sec++; */ \ sub hrestnsec, nano, hrestnsec; /* hrest.tv_nsec -= NANOSEC; */ \ ba,a 3b; /* check >= billion again */ \ 4: ENTRY_NP(gethrestime) GET_HRESTIME(%o1, %o2, %o3, %o4, %o5, %g1, %g2, %g3, %g4) CONV_HRESTIME(%o1, %o2, %o3, %o4, %o5) stn %o1, [%o0] retl stn %o2, [%o0 + CLONGSIZE] SET_SIZE(gethrestime) /* * Similar to gethrestime(), but gethrestime_sec() returns current hrestime * seconds. */ ENTRY_NP(gethrestime_sec) GET_HRESTIME(%o0, %o2, %o3, %o4, %o5, %g1, %g2, %g3, %g4) CONV_HRESTIME(%o0, %o2, %o3, %o4, %o5) retl ! %o0 current hrestime seconds nop SET_SIZE(gethrestime_sec) /* * Returns the hrestime on the last tick. This is simpler than gethrestime() * and gethrestime_sec(): no conversion is required. gethrestime_lasttick() * follows the same locking algorithm as GET_HRESTIME and GET_HRTIME, * outlined in detail in clock.h. (Unlike GET_HRESTIME/GET_HRTIME, we don't * rely on load dependencies to effect the membar #LoadLoad, instead declaring * it explicitly.) */ ENTRY_NP(gethrestime_lasttick) sethi %hi(hres_lock), %o1 0: lduw [%o1 + %lo(hres_lock)], %o2 ! Load lock value membar #LoadLoad ! Load of lock must complete andn %o2, 1, %o2 ! Mask off lowest bit ldn [%o1 + %lo(hrestime)], %g1 ! Seconds. add %o1, %lo(hrestime), %o4 ldn [%o4 + CLONGSIZE], %g2 ! Nanoseconds. membar #LoadLoad ! All loads must complete lduw [%o1 + %lo(hres_lock)], %o3 ! Reload lock value cmp %o3, %o2 ! If lock is locked or has bne 0b ! changed, retry. stn %g1, [%o0] ! Delay: store seconds retl stn %g2, [%o0 + CLONGSIZE] ! Delay: store nanoseconds SET_SIZE(gethrestime_lasttick) /* * Fast trap for gettimeofday(). Returns a timestruc_t in %o0 and %o1. * * This is the handler for the ST_GETHRESTIME trap. */ ENTRY_NP(get_hrestime) GET_HRESTIME(%o0, %o1, %g1, %g2, %g3, %g4, %g5, %o2, %o3) CONV_HRESTIME(%o0, %o1, %g1, %g2, %g3) FAST_TRAP_DONE SET_SIZE(get_hrestime) /* * Fast trap to return lwp virtual time, uses trap window, leaves traps * disabled. Returns a 64-bit number in %o0:%o1, which is the number * of nanoseconds consumed. * * This is the handler for the ST_GETHRVTIME trap. * * Register usage: * %o0, %o1 = return lwp virtual time * %o2 = CPU/thread * %o3 = lwp * %g1 = scratch * %g5 = scratch */ ENTRY_NP(get_virtime) GET_NATIVE_TIME(%g5, %g1, %g2) ! %g5 = native time in ticks CPU_ADDR(%g2, %g3) ! CPU struct ptr to %g2 ldn [%g2 + CPU_THREAD], %g2 ! thread pointer to %g2 ldn [%g2 + T_LWP], %g3 ! lwp pointer to %g3 /* * Subtract start time of current microstate from time * of day to get increment for lwp virtual time. */ ldx [%g3 + LWP_STATE_START], %g1 ! ms_state_start sub %g5, %g1, %g5 /* * Add current value of ms_acct[LMS_USER] */ ldx [%g3 + LWP_ACCT_USER], %g1 ! ms_acct[LMS_USER] add %g5, %g1, %g5 NATIVE_TIME_TO_NSEC(%g5, %g1, %o0) srl %g5, 0, %o1 ! %o1 = lo32(%g5) srlx %g5, 32, %o0 ! %o0 = hi32(%g5) FAST_TRAP_DONE SET_SIZE(get_virtime) .seg ".text" hrtime_base_panic: .asciz "hrtime_base stepping back" ENTRY_NP(hres_tick) save %sp, -SA(MINFRAME), %sp ! get a new window sethi %hi(hrestime), %l4 ldstub [%l4 + %lo(hres_lock + HRES_LOCK_OFFSET)], %l5 ! try locking 7: tst %l5 bz,pt %xcc, 8f ! if we got it, drive on ld [%l4 + %lo(nsec_scale)], %l5 ! delay: %l5 = scaling factor ldub [%l4 + %lo(hres_lock + HRES_LOCK_OFFSET)], %l5 9: tst %l5 bz,a,pn %xcc, 7b ldstub [%l4 + %lo(hres_lock + HRES_LOCK_OFFSET)], %l5 ba,pt %xcc, 9b ldub [%l4 + %lo(hres_lock + HRES_LOCK_OFFSET)], %l5 8: membar #StoreLoad|#StoreStore ! ! update hres_last_tick. %l5 has the scaling factor (nsec_scale). ! ldx [%l4 + %lo(hrtime_base)], %g1 ! load current hrtime_base GET_NATIVE_TIME(%l0, %l3, %l6) ! current native time stx %l0, [%l4 + %lo(hres_last_tick)]! prev = current ! convert native time to nsecs NATIVE_TIME_TO_NSEC_SCALE(%l0, %l5, %l2, NSEC_SHIFT) sub %l0, %g1, %i1 ! get accurate nsec delta ldx [%l4 + %lo(hrtime_base)], %l1 cmp %l1, %l0 bg,pn %xcc, 9f nop stx %l0, [%l4 + %lo(hrtime_base)] ! update hrtime_base ! ! apply adjustment, if any ! ldx [%l4 + %lo(hrestime_adj)], %l0 ! %l0 = hrestime_adj brz %l0, 2f ! hrestime_adj == 0 ? ! yes, skip adjustments clr %l5 ! delay: set adj to zero tst %l0 ! is hrestime_adj >= 0 ? bge,pt %xcc, 1f ! yes, go handle positive case srl %i1, ADJ_SHIFT, %l5 ! delay: %l5 = adj addcc %l0, %l5, %g0 ! hrestime_adj < -adj ? bl,pt %xcc, 2f ! yes, use current adj neg %l5 ! delay: %l5 = -adj ba,pt %xcc, 2f mov %l0, %l5 ! no, so set adj = hrestime_adj 1: subcc %l0, %l5, %g0 ! hrestime_adj < adj ? bl,a,pt %xcc, 2f ! yes, set adj = hrestime_adj mov %l0, %l5 ! delay: adj = hrestime_adj 2: ldx [%l4 + %lo(timedelta)], %l0 ! %l0 = timedelta sub %l0, %l5, %l0 ! timedelta -= adj stx %l0, [%l4 + %lo(timedelta)] ! store new timedelta stx %l0, [%l4 + %lo(hrestime_adj)] ! hrestime_adj = timedelta or %l4, %lo(hrestime), %l2 ldn [%l2], %i2 ! %i2:%i3 = hrestime sec:nsec ldn [%l2 + CLONGSIZE], %i3 add %i3, %l5, %i3 ! hrestime.nsec += adj add %i3, %i1, %i3 ! hrestime.nsec += nslt set NANOSEC, %l5 ! %l5 = NANOSEC cmp %i3, %l5 bl,pt %xcc, 5f ! if hrestime.tv_nsec < NANOSEC sethi %hi(one_sec), %i1 ! delay add %i2, 0x1, %i2 ! hrestime.tv_sec++ sub %i3, %l5, %i3 ! hrestime.tv_nsec - NANOSEC mov 0x1, %l5 st %l5, [%i1 + %lo(one_sec)] 5: stn %i2, [%l2] stn %i3, [%l2 + CLONGSIZE] ! store the new hrestime membar #StoreStore ld [%l4 + %lo(hres_lock)], %i1 inc %i1 ! release lock st %i1, [%l4 + %lo(hres_lock)] ! clear hres_lock ret restore 9: ! ! release hres_lock ! ld [%l4 + %lo(hres_lock)], %i1 inc %i1 st %i1, [%l4 + %lo(hres_lock)] sethi %hi(hrtime_base_panic), %o0 call panic or %o0, %lo(hrtime_base_panic), %o0 SET_SIZE(hres_tick) #endif /* lint */ #if !defined(lint) && !defined(__lint) .seg ".text" kstat_q_panic_msg: .asciz "kstat_q_exit: qlen == 0" ENTRY(kstat_q_panic) save %sp, -SA(MINFRAME), %sp sethi %hi(kstat_q_panic_msg), %o0 call panic or %o0, %lo(kstat_q_panic_msg), %o0 /*NOTREACHED*/ SET_SIZE(kstat_q_panic) #define BRZPN brz,pn #define BRZPT brz,pt #define KSTAT_Q_UPDATE(QOP, QBR, QZERO, QRETURN, QTYPE) \ ld [%o0 + QTYPE/**/CNT], %o1; /* %o1 = old qlen */ \ QOP %o1, 1, %o2; /* %o2 = new qlen */ \ QBR %o1, QZERO; /* done if qlen == 0 */ \ st %o2, [%o0 + QTYPE/**/CNT]; /* delay: save qlen */ \ ldx [%o0 + QTYPE/**/LASTUPDATE], %o3; \ ldx [%o0 + QTYPE/**/TIME], %o4; /* %o4 = old time */ \ ldx [%o0 + QTYPE/**/LENTIME], %o5; /* %o5 = old lentime */ \ sub %g1, %o3, %o2; /* %o2 = time delta */ \ mulx %o1, %o2, %o3; /* %o3 = cur lentime */ \ add %o4, %o2, %o4; /* %o4 = new time */ \ add %o5, %o3, %o5; /* %o5 = new lentime */ \ stx %o4, [%o0 + QTYPE/**/TIME]; /* save time */ \ stx %o5, [%o0 + QTYPE/**/LENTIME]; /* save lentime */ \ QRETURN; \ stx %g1, [%o0 + QTYPE/**/LASTUPDATE]; /* lastupdate = now */ .align 16 ENTRY(kstat_waitq_enter) GET_NATIVE_TIME(%g1, %g2, %g3) KSTAT_Q_UPDATE(add, BRZPT, 1f, 1:retl, KSTAT_IO_W) SET_SIZE(kstat_waitq_enter) .align 16 ENTRY(kstat_waitq_exit) GET_NATIVE_TIME(%g1, %g2, %g3) KSTAT_Q_UPDATE(sub, BRZPN, kstat_q_panic, retl, KSTAT_IO_W) SET_SIZE(kstat_waitq_exit) .align 16 ENTRY(kstat_runq_enter) GET_NATIVE_TIME(%g1, %g2, %g3) KSTAT_Q_UPDATE(add, BRZPT, 1f, 1:retl, KSTAT_IO_R) SET_SIZE(kstat_runq_enter) .align 16 ENTRY(kstat_runq_exit) GET_NATIVE_TIME(%g1, %g2, %g3) KSTAT_Q_UPDATE(sub, BRZPN, kstat_q_panic, retl, KSTAT_IO_R) SET_SIZE(kstat_runq_exit) .align 16 ENTRY(kstat_waitq_to_runq) GET_NATIVE_TIME(%g1, %g2, %g3) KSTAT_Q_UPDATE(sub, BRZPN, kstat_q_panic, 1:, KSTAT_IO_W) KSTAT_Q_UPDATE(add, BRZPT, 1f, 1:retl, KSTAT_IO_R) SET_SIZE(kstat_waitq_to_runq) .align 16 ENTRY(kstat_runq_back_to_waitq) GET_NATIVE_TIME(%g1, %g2, %g3) KSTAT_Q_UPDATE(sub, BRZPN, kstat_q_panic, 1:, KSTAT_IO_R) KSTAT_Q_UPDATE(add, BRZPT, 1f, 1:retl, KSTAT_IO_W) SET_SIZE(kstat_runq_back_to_waitq) #endif /* lint */ #ifdef lint int64_t timedelta; hrtime_t hres_last_tick; volatile timestruc_t hrestime; int64_t hrestime_adj; volatile int hres_lock; uint_t nsec_scale; hrtime_t hrtime_base; int traptrace_use_stick; #else /* * -- WARNING -- * * The following variables MUST be together on a 128-byte boundary. * In addition to the primary performance motivation (having them all * on the same cache line(s)), code here and in the GET*TIME() macros * assumes that they all have the same high 22 address bits (so * there's only one sethi). */ .seg ".data" .global timedelta, hres_last_tick, hrestime, hrestime_adj .global hres_lock, nsec_scale, hrtime_base, traptrace_use_stick .global nsec_shift, adj_shift /* XXX - above comment claims 128-bytes is necessary */ .align 64 timedelta: .word 0, 0 /* int64_t */ hres_last_tick: .word 0, 0 /* hrtime_t */ hrestime: .nword 0, 0 /* 2 longs */ hrestime_adj: .word 0, 0 /* int64_t */ hres_lock: .word 0 nsec_scale: .word 0 hrtime_base: .word 0, 0 traptrace_use_stick: .word 0 nsec_shift: .word NSEC_SHIFT adj_shift: .word ADJ_SHIFT #endif /* * drv_usecwait(clock_t n) [DDI/DKI - section 9F] * usec_delay(int n) [compatibility - should go one day] * Delay by spinning. * * delay for n microseconds. numbers <= 0 delay 1 usec * * With UltraSPARC-III the combination of supporting mixed-speed CPUs * and variable clock rate for power management requires that we * use %stick to implement this routine. */ #if defined(lint) /*ARGSUSED*/ void drv_usecwait(clock_t n) {} /*ARGSUSED*/ void usec_delay(int n) {} #else /* lint */ ENTRY(drv_usecwait) ALTENTRY(usec_delay) brlez,a,pn %o0, 0f mov 1, %o0 0: sethi %hi(sticks_per_usec), %o1 lduw [%o1 + %lo(sticks_per_usec)], %o1 mulx %o1, %o0, %o1 ! Scale usec to ticks inc %o1 ! We don't start on a tick edge GET_NATIVE_TIME(%o2, %o3, %o4) add %o1, %o2, %o1 1: cmp %o1, %o2 GET_NATIVE_TIME(%o2, %o3, %o4) bgeu,pt %xcc, 1b nop retl nop SET_SIZE(usec_delay) SET_SIZE(drv_usecwait) #endif /* lint */ #if defined(lint) /* ARGSUSED */ void pil14_interrupt(int level) {} #else /* * Level-14 interrupt prologue. */ ENTRY_NP(pil14_interrupt) CPU_ADDR(%g1, %g2) rdpr %pil, %g6 ! %g6 = interrupted PIL stn %g6, [%g1 + CPU_PROFILE_PIL] ! record interrupted PIL rdpr %tstate, %g6 rdpr %tpc, %g5 btst TSTATE_PRIV, %g6 ! trap from supervisor mode? bnz,a,pt %xcc, 1f stn %g5, [%g1 + CPU_PROFILE_PC] ! if so, record kernel PC stn %g5, [%g1 + CPU_PROFILE_UPC] ! if not, record user PC ba pil_interrupt_common ! must be large-disp branch stn %g0, [%g1 + CPU_PROFILE_PC] ! zero kernel PC 1: ba pil_interrupt_common ! must be large-disp branch stn %g0, [%g1 + CPU_PROFILE_UPC] ! zero user PC SET_SIZE(pil14_interrupt) ENTRY_NP(tick_rtt) ! ! Load TICK_COMPARE into %o5; if bit 63 is set, then TICK_COMPARE is ! disabled. If TICK_COMPARE is enabled, we know that we need to ! reenqueue the interrupt request structure. We'll then check TICKINT ! in SOFTINT; if it's set, then we know that we were in a TICK_COMPARE ! interrupt. In this case, TICK_COMPARE may have been rewritten ! recently; we'll compare %o5 to the current time to verify that it's ! in the future. ! ! Note that %o5 is live until after 1f. ! XXX - there is a subroutine call while %o5 is live! ! RD_TICKCMPR(%o5, %g1) srlx %o5, TICKINT_DIS_SHFT, %g1 brnz,pt %g1, 2f nop rdpr %pstate, %g5 andn %g5, PSTATE_IE, %g1 wrpr %g0, %g1, %pstate ! Disable vec interrupts sethi %hi(cbe_level14_inum), %o1 ldx [%o1 + %lo(cbe_level14_inum)], %o1 call intr_enqueue_req ! preserves %o5 and %g5 mov PIL_14, %o0 ! Check SOFTINT for TICKINT/STICKINT rd SOFTINT, %o4 set (TICK_INT_MASK | STICK_INT_MASK), %o0 andcc %o4, %o0, %g0 bz,a,pn %icc, 2f wrpr %g0, %g5, %pstate ! Enable vec interrupts ! clear TICKINT/STICKINT wr %o0, CLEAR_SOFTINT ! ! Now that we've cleared TICKINT, we can reread %tick and confirm ! that the value we programmed is still in the future. If it isn't, ! we need to reprogram TICK_COMPARE to fire as soon as possible. ! GET_NATIVE_TIME(%o0, %g1, %g2) ! %o0 = tick sllx %o0, 1, %o0 ! Clear the DIS bit srlx %o0, 1, %o0 cmp %o5, %o0 ! In the future? bg,a,pt %xcc, 2f ! Yes, drive on. wrpr %g0, %g5, %pstate ! delay: enable vec intr ! ! If we're here, then we have programmed TICK_COMPARE with a %tick ! which is in the past; we'll now load an initial step size, and loop ! until we've managed to program TICK_COMPARE to fire in the future. ! mov 8, %o4 ! 8 = arbitrary inital step 1: add %o0, %o4, %o5 ! Add the step WR_TICKCMPR(%o5,%g1,%g2,__LINE__) ! Write to TICK_CMPR GET_NATIVE_TIME(%o0, %g1, %g2) ! %o0 = tick sllx %o0, 1, %o0 ! Clear the DIS bit srlx %o0, 1, %o0 cmp %o5, %o0 ! In the future? bg,a,pt %xcc, 2f ! Yes, drive on. wrpr %g0, %g5, %pstate ! delay: enable vec intr ba 1b ! No, try again. sllx %o4, 1, %o4 ! delay: double step size 2: ba current_thread_complete nop SET_SIZE(tick_rtt) #endif /* lint */ #if defined(lint) /* * Prefetch a page_t for write or read, this assumes a linear * scan of sequential page_t's. */ /*ARGSUSED*/ void prefetch_page_w(void *pp) {} /*ARGSUSED*/ void prefetch_page_r(void *pp) {} #else /* lint */ /* XXXQ These should be inline templates, not functions */ ENTRY(prefetch_page_w) retl nop SET_SIZE(prefetch_page_w) ENTRY(prefetch_page_r) retl nop SET_SIZE(prefetch_page_r) #endif /* lint */ #if defined(lint) /* * Prefetch struct smap for write. */ /*ARGSUSED*/ void prefetch_smap_w(void *smp) {} #else /* lint */ /* XXXQ These should be inline templates, not functions */ ENTRY(prefetch_smap_w) retl nop SET_SIZE(prefetch_smap_w) #endif /* lint */ /* * Generic sun4v MMU and Cache operations. */ #if defined(lint) /*ARGSUSED*/ void vtag_flushpage(caddr_t vaddr, uint64_t sfmmup) {} /*ARGSUSED*/ void vtag_flushall(void) {} /*ARGSUSED*/ void vtag_unmap_perm_tl1(uint64_t vaddr, uint64_t ctxnum) {} /*ARGSUSED*/ void vtag_flushpage_tl1(uint64_t vaddr, uint64_t sfmmup) {} /*ARGSUSED*/ void vtag_flush_pgcnt_tl1(uint64_t vaddr, uint64_t sfmmup_pgcnt) {} /*ARGSUSED*/ void vtag_flushall_tl1(uint64_t dummy1, uint64_t dummy2) {} /*ARGSUSED*/ void vac_flushpage(pfn_t pfnum, int vcolor) {} /*ARGSUSED*/ void vac_flushpage_tl1(uint64_t pfnum, uint64_t vcolor) {} /*ARGSUSED*/ void flush_instr_mem(caddr_t vaddr, size_t len) {} #else /* lint */ ENTRY_NP(vtag_flushpage) /* * flush page from the tlb * * %o0 = vaddr * %o1 = sfmmup */ SFMMU_CPU_CNUM(%o1, %g1, %g2) /* %g1 = sfmmu cnum on this CPU */ mov %g1, %o1 mov MAP_ITLB | MAP_DTLB, %o2 ta MMU_UNMAP_ADDR brz,pt %o0, 1f nop ba panic_bad_hcall mov MMU_UNMAP_ADDR, %o1 1: retl nop SET_SIZE(vtag_flushpage) ENTRY_NP(vtag_flushall) mov %g0, %o0 ! XXX no cpu list yet mov %g0, %o1 ! XXX no cpu list yet mov MAP_ITLB | MAP_DTLB, %o2 mov MMU_DEMAP_ALL, %o5 ta FAST_TRAP brz,pt %o0, 1f nop ba panic_bad_hcall mov MMU_DEMAP_ALL, %o1 1: retl nop SET_SIZE(vtag_flushall) ENTRY_NP(vtag_unmap_perm_tl1) /* * x-trap to unmap perm map entry * %g1 = vaddr * %g2 = ctxnum (KCONTEXT only) */ mov %o0, %g3 mov %o1, %g4 mov %o2, %g5 mov %o5, %g6 mov %g1, %o0 mov %g2, %o1 mov MAP_ITLB | MAP_DTLB, %o2 mov UNMAP_PERM_ADDR, %o5 ta FAST_TRAP brz,pt %o0, 1f nop mov PTL1_BAD_HCALL, %g1 cmp %o0, H_ENOMAP move %xcc, PTL1_BAD_HCALL_UNMAP_PERM_ENOMAP, %g1 cmp %o0, H_EINVAL move %xcc, PTL1_BAD_HCALL_UNMAP_PERM_EINVAL, %g1 ba,a ptl1_panic 1: mov %g6, %o5 mov %g5, %o2 mov %g4, %o1 mov %g3, %o0 retry SET_SIZE(vtag_unmap_perm_tl1) ENTRY_NP(vtag_flushpage_tl1) /* * x-trap to flush page from tlb and tsb * * %g1 = vaddr, zero-extended on 32-bit kernel * %g2 = sfmmup * * assumes TSBE_TAG = 0 */ srln %g1, MMU_PAGESHIFT, %g1 slln %g1, MMU_PAGESHIFT, %g1 /* g1 = vaddr */ mov %o0, %g3 mov %o1, %g4 mov %o2, %g5 mov %g1, %o0 /* vaddr */ SFMMU_CPU_CNUM(%g2, %o1, %g6) /* %o1 = sfmmu cnum on this CPU */ mov MAP_ITLB | MAP_DTLB, %o2 ta MMU_UNMAP_ADDR brz,pt %o0, 1f nop ba ptl1_panic mov PTL1_BAD_HCALL, %g1 1: mov %g5, %o2 mov %g4, %o1 mov %g3, %o0 membar #Sync retry SET_SIZE(vtag_flushpage_tl1) ENTRY_NP(vtag_flush_pgcnt_tl1) /* * x-trap to flush pgcnt MMU_PAGESIZE pages from tlb * * %g1 = vaddr, zero-extended on 32-bit kernel * %g2 = , (pgcnt - 1) is pass'ed in via pgcnt6 bits. * * NOTE: this handler relies on the fact that no * interrupts or traps can occur during the loop * issuing the TLB_DEMAP operations. It is assumed * that interrupts are disabled and this code is * fetching from the kernel locked text address. * * assumes TSBE_TAG = 0 */ srln %g1, MMU_PAGESHIFT, %g1 slln %g1, MMU_PAGESHIFT, %g1 /* g1 = vaddr */ mov %o0, %g3 mov %o1, %g4 mov %o2, %g5 and %g2, SFMMU_PGCNT_MASK, %g7 /* g7 = pgcnt - 1 */ add %g7, 1, %g7 /* g7 = pgcnt */ andn %g2, SFMMU_PGCNT_MASK, %o0 /* %o0 = sfmmup */ SFMMU_CPU_CNUM(%o0, %g2, %g6) /* %g2 = sfmmu cnum on this CPU */ set MMU_PAGESIZE, %g6 /* g6 = pgsize */ 1: mov %g1, %o0 /* vaddr */ mov %g2, %o1 /* cnum */ mov MAP_ITLB | MAP_DTLB, %o2 ta MMU_UNMAP_ADDR brz,pt %o0, 2f nop ba ptl1_panic mov PTL1_BAD_HCALL, %g1 2: deccc %g7 /* decr pgcnt */ bnz,pt %icc,1b add %g1, %g6, %g1 /* go to nextpage */ mov %g5, %o2 mov %g4, %o1 mov %g3, %o0 membar #Sync retry SET_SIZE(vtag_flush_pgcnt_tl1) ! Not implemented on US1/US2 ENTRY_NP(vtag_flushall_tl1) mov %o0, %g3 mov %o1, %g4 mov %o2, %g5 mov %o3, %g6 ! XXXQ not used? mov %o5, %g7 mov %g0, %o0 ! XXX no cpu list yet mov %g0, %o1 ! XXX no cpu list yet mov MAP_ITLB | MAP_DTLB, %o2 mov MMU_DEMAP_ALL, %o5 ta FAST_TRAP brz,pt %o0, 1f nop ba ptl1_panic mov PTL1_BAD_HCALL, %g1 1: mov %g7, %o5 mov %g6, %o3 ! XXXQ not used? mov %g5, %o2 mov %g4, %o1 mov %g3, %o0 retry SET_SIZE(vtag_flushall_tl1) /* * flush_instr_mem: * Flush a portion of the I-$ starting at vaddr * %o0 vaddr * %o1 bytes to be flushed */ ENTRY(flush_instr_mem) membar #StoreStore ! Ensure the stores ! are globally visible 1: flush %o0 subcc %o1, ICACHE_FLUSHSZ, %o1 ! bytes = bytes-0x20 bgu,pt %ncc, 1b add %o0, ICACHE_FLUSHSZ, %o0 ! vaddr = vaddr+0x20 retl nop SET_SIZE(flush_instr_mem) #endif /* !lint */ #if !defined(CUSTOM_FPZERO) /* * fp_zero() - clear all fp data registers and the fsr */ #if defined(lint) || defined(__lint) void fp_zero(void) {} #else /* lint */ .global fp_zero_zero .align 8 fp_zero_zero: .xword 0 ENTRY_NP(fp_zero) sethi %hi(fp_zero_zero), %o0 ldx [%o0 + %lo(fp_zero_zero)], %fsr ldd [%o0 + %lo(fp_zero_zero)], %f0 fmovd %f0, %f2 fmovd %f0, %f4 fmovd %f0, %f6 fmovd %f0, %f8 fmovd %f0, %f10 fmovd %f0, %f12 fmovd %f0, %f14 fmovd %f0, %f16 fmovd %f0, %f18 fmovd %f0, %f20 fmovd %f0, %f22 fmovd %f0, %f24 fmovd %f0, %f26 fmovd %f0, %f28 fmovd %f0, %f30 fmovd %f0, %f32 fmovd %f0, %f34 fmovd %f0, %f36 fmovd %f0, %f38 fmovd %f0, %f40 fmovd %f0, %f42 fmovd %f0, %f44 fmovd %f0, %f46 fmovd %f0, %f48 fmovd %f0, %f50 fmovd %f0, %f52 fmovd %f0, %f54 fmovd %f0, %f56 fmovd %f0, %f58 fmovd %f0, %f60 retl fmovd %f0, %f62 SET_SIZE(fp_zero) #endif /* lint */ #endif /* CUSTOM_FPZERO */