/* * Copyright (c) 2000-2004 Apple Computer, Inc. All rights reserved. * * @APPLE_LICENSE_HEADER_START@ * * This file contains Original Code and/or Modifications of Original Code * as defined in and that are subject to the Apple Public Source License * Version 2.0 (the 'License'). You may not use this file except in * compliance with the License. Please obtain a copy of the License at * http://www.opensource.apple.com/apsl/ and read it before using this * file. * * The Original Code and all software distributed under the License are * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES, * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT. * Please see the License for the specific language governing rights and * limitations under the License. * * @APPLE_LICENSE_HEADER_END@ */ /* * @OSF_COPYRIGHT@ */ #include #include #include #include #include #include #include #define FPVECDBG 0 .text /* * void machine_load_context(thread_t thread) * * Load the context for the first thread to run on a * cpu, and go. */ .align 5 .globl EXT(machine_load_context) LEXT(machine_load_context) mfsprg r6,1 ; Get the current activation lwz r6,ACT_PER_PROC(r6) ; Get the per_proc block lwz r0,PP_INTSTACK_TOP_SS(r6) stw r0,PP_ISTACKPTR(r6) mr r9,r3 /* Set up the current thread */ mtsprg 1,r9 li r0,0 /* Clear a register */ lwz r3,ACT_MACT_PCB(r9) /* Get the savearea used */ mfmsr r5 /* Since we are passing control, get our MSR values */ lwz r11,SAVprev+4(r3) /* Get the previous savearea */ lwz r1,saver1+4(r3) /* Load new stack pointer */ lwz r10,ACT_MACT_SPF(r9) /* Get the special flags */ stw r0,saver3+4(r3) /* Make sure we pass in a 0 for the continuation */ stw r0,FM_BACKPTR(r1) /* zero backptr */ stw r5,savesrr1+4(r3) /* Pass our MSR to the new guy */ stw r11,ACT_MACT_PCB(r9) /* Unstack our savearea */ oris r10,r10,hi16(OnProc) /* Set OnProc bit */ stw r0,ACT_PREEMPT_CNT(r9) /* Enable preemption */ stw r10,ACT_MACT_SPF(r9) /* Update the special flags */ stw r10,spcFlags(r6) /* Set per_proc copy of the special flags */ b EXT(exception_exit) /* Go for it */ /* thread_t Switch_context(thread_t old, * void (*cont)(void), * thread_t new) * * Switch from one thread to another. If a continuation is supplied, then * we do not need to save callee save registers. * */ /* void Call_continuation( void (*continuation)(void), void *param, wait_result_t wresult, vm_offset_t stack_ptr) */ .align 5 .globl EXT(Call_continuation) LEXT(Call_continuation) mtlr r3 /* continuation */ mr r3,r4 /* parameter */ mr r4,r5 /* wait result */ mr r1,r6 /* Load new stack pointer */ blrl /* Jump to the continuation */ mfsprg r3,1 b EXT(thread_terminate) /* * Get the old kernel stack, and store into the thread structure. * See if a continuation is supplied, and skip state save if so. * * Note that interrupts must be disabled before we get here (i.e., splsched) */ /* * Switch_context(old, continuation, new) * * Context switches are double jumps. We pass the following to the * context switch firmware call: * * R3 = switchee's savearea, virtual if continuation, low order physical for full switch * R4 = old thread * R5 = new SRR0 * R6 = new SRR1 * R7 = high order physical address of savearea for full switch * * savesrr0 is set to go to switch_in * savesrr1 is set to uninterruptible with translation on */ .align 5 .globl EXT(Switch_context) LEXT(Switch_context) lwz r12,ACT_PER_PROC(r3) ; Get the per_proc block #if DEBUG lwz r0,PP_ISTACKPTR(r12) ; (DEBUG/TRACE) make sure we are not mr. r0,r0 ; (DEBUG/TRACE) on the interrupt bne++ notonintstack ; (DEBUG/TRACE) stack BREAKPOINT_TRAP notonintstack: #endif lwz r8,ACT_MACT_PCB(r5) ; Get the PCB for the new guy lwz r9,umwSpace(r5) ; Get user memory window address space cmpwi cr1,r4,0 ; Remeber if there is a continuation - used waaaay down below lwz r0,CTHREAD_SELF+0(r5) ; Pick up the user assist "word" (actually a double) lwz r7,CTHREAD_SELF+4(r5) ; both halves lwz r11,ACT_MACT_BTE(r5) ; Get BlueBox Task Environment lwz r6,umwRelo(r5) ; Get user memory window relocation top stw r12,ACT_PER_PROC(r5) ; Set per_proc in new activation mtsprg 1,r5 lwz r2,umwRelo+4(r5) ; Get user memory window relocation bottom stw r0,UAW+0(r12) ; Save the assist word for the "ultra fast path" stw r7,UAW+4(r12) lwz r7,ACT_MACT_SPF(r5) ; Get the special flags sth r9,ppUMWmp+mpSpace(r12) ; Save the space stw r6,ppUMWmp+mpNestReloc(r12) ; Save top part of physical address stw r2,ppUMWmp+mpNestReloc+4(r12) ; Save bottom part of physical address stw r11,ppbbTaskEnv(r12) ; Save the bb task env lwz r2,traceMask(0) ; Get the enabled traces stw r7,spcFlags(r12) ; Set per_proc copy of the special flags lis r0,hi16(CutTrace) ; Trace FW call mr. r2,r2 ; Any tracing going on? lwz r11,SAVprev+4(r8) ; Get the previous of the switchee savearea ori r0,r0,lo16(CutTrace) ; Trace FW call beq++ cswNoTrc ; No trace today, dude... li r2,0x4400 ; Trace ID mr r6,r11 ; Trace prev savearea sc ; Cut trace entry of context switch cswNoTrc: lwz r2,curctx(r5) ; Grab our current context pointer lwz r10,FPUowner(r12) ; Grab the owner of the FPU lwz r9,VMXowner(r12) ; Grab the owner of the vector mfmsr r6 ; Get the MSR because the switched to thread should inherit it stw r11,ACT_MACT_PCB(r5) ; Dequeue the savearea we are switching to li r0,1 ; Get set to hold off quickfret rlwinm r6,r6,0,MSR_FP_BIT+1,MSR_FP_BIT-1 ; Turn off the FP cmplw r10,r2 ; Do we have the live float context? lwz r10,FPUlevel(r2) ; Get the live level mr r4,r3 ; Save our old thread to pass back cmplw cr5,r9,r2 ; Do we have the live vector context? rlwinm r6,r6,0,MSR_VEC_BIT+1,MSR_VEC_BIT-1 ; Turn off the vector stw r0,holdQFret(r12) ; Make sure we hold off releasing quickfret bne++ cswnofloat ; Float is not ours... cmplw r10,r11 ; Is the level the same? lhz r0,PP_CPU_NUMBER(r12) ; Get our CPU number lwz r5,FPUcpu(r2) ; Get the owning cpu bne++ cswnofloat ; Level not the same, this is not live... cmplw r5,r0 ; Still owned by this cpu? lwz r10,FPUsave(r2) ; Get the pointer to next saved context bne++ cswnofloat ; CPU claimed by someone else... mr. r10,r10 ; Is there a savearea here? ori r6,r6,lo16(MASK(MSR_FP)) ; Enable floating point beq-- cswnofloat ; No savearea to check... lwz r3,SAVlevel(r10) ; Get the level lwz r5,SAVprev+4(r10) ; Get the previous of this savearea cmplw r3,r11 ; Is it for the current level? bne++ cswnofloat ; Nope... stw r5,FPUsave(r2) ; Pop off this savearea rlwinm r3,r10,0,0,19 ; Move back to start of page lwz r5,quickfret(r12) ; Get the first in quickfret list (top) lwz r9,quickfret+4(r12) ; Get the first in quickfret list (bottom) lwz r7,SACvrswap(r3) ; Get the virtual to real conversion (top) lwz r3,SACvrswap+4(r3) ; Get the virtual to real conversion (bottom) stw r5,SAVprev(r10) ; Link the old in (top) stw r9,SAVprev+4(r10) ; Link the old in (bottom) xor r3,r10,r3 ; Convert to physical stw r7,quickfret(r12) ; Set the first in quickfret list (top) stw r3,quickfret+4(r12) ; Set the first in quickfret list (bottom) #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) mr r7,r2 ; (TEST/DEBUG) li r2,0x4401 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) lhz r0,PP_CPU_NUMBER(r12) ; (TEST/DEBUG) mr r2,r7 ; (TEST/DEBUG) #endif cswnofloat: bne++ cr5,cswnovect ; Vector is not ours... lwz r10,VMXlevel(r2) ; Get the live level cmplw r10,r11 ; Is the level the same? lhz r0,PP_CPU_NUMBER(r12) ; Get our CPU number lwz r5,VMXcpu(r2) ; Get the owning cpu bne++ cswnovect ; Level not the same, this is not live... cmplw r5,r0 ; Still owned by this cpu? lwz r10,VMXsave(r2) ; Get the level bne++ cswnovect ; CPU claimed by someone else... mr. r10,r10 ; Is there a savearea here? oris r6,r6,hi16(MASK(MSR_VEC)) ; Enable vector beq-- cswnovect ; No savearea to check... lwz r3,SAVlevel(r10) ; Get the level lwz r5,SAVprev+4(r10) ; Get the previous of this savearea cmplw r3,r11 ; Is it for the current level? bne++ cswnovect ; Nope... stw r5,VMXsave(r2) ; Pop off this savearea rlwinm r3,r10,0,0,19 ; Move back to start of page lwz r5,quickfret(r12) ; Get the first in quickfret list (top) lwz r9,quickfret+4(r12) ; Get the first in quickfret list (bottom) lwz r2,SACvrswap(r3) ; Get the virtual to real conversion (top) lwz r3,SACvrswap+4(r3) ; Get the virtual to real conversion (bottom) stw r5,SAVprev(r10) ; Link the old in (top) stw r9,SAVprev+4(r10) ; Link the old in (bottom) xor r3,r10,r3 ; Convert to physical stw r2,quickfret(r12) ; Set the first in quickfret list (top) stw r3,quickfret+4(r12) ; Set the first in quickfret list (bottom) #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x4501 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif cswnovect: li r0,0 ; Get set to release quickfret holdoff rlwinm r11,r8,0,0,19 ; Switch to savearea base lis r9,hi16(EXT(switch_in)) ; Get top of switch in routine lwz r5,savesrr0+4(r8) ; Set up the new SRR0 ; ; Note that the low-level code requires the R7 contain the high order half of the savearea's ; physical address. This is hack city, but it is the way it is. ; lwz r7,SACvrswap(r11) ; Get the high order V to R translation lwz r11,SACvrswap+4(r11) ; Get the low order V to R translation ori r9,r9,lo16(EXT(switch_in)) ; Bottom half of switch in stw r0,holdQFret(r12) ; Make sure we release quickfret holdoff stw r9,savesrr0+4(r8) ; Make us jump to the switch in routine lwz r9,SAVflags(r8) /* Get the flags */ lis r0,hi16(SwitchContextCall) /* Top part of switch context */ li r10,(MASK(MSR_ME)|MASK(MSR_DR)) /* Get the switcher's MSR */ ori r0,r0,lo16(SwitchContextCall) /* Bottom part of switch context */ stw r10,savesrr1+4(r8) /* Set up for switch in */ rlwinm r9,r9,0,15,13 /* Reset the syscall flag */ xor r3,r11,r8 /* Get the physical address of the new context save area */ stw r9,SAVflags(r8) /* Set the flags */ bne cr1,swtchtocont ; Switch to the continuation sc /* Switch to the new context */ /* We come back here in the new thread context * R4 was set to hold the old thread pointer, but switch_in will put it into * R3 where it belongs. */ blr /* Jump into the new thread */ ; ; This is where we go when a continuation is set. We are actually ; killing off the old context of the new guy so we need to pop off ; any float or vector states for the ditched level. ; ; Note that we do the same kind of thing a chkfac in hw_exceptions.s ; swtchtocont: stw r5,savesrr0+4(r8) ; Set the pc stw r6,savesrr1+4(r8) ; Set the next MSR to use stw r4,saver3+4(r8) ; Make sure we pass back the old thread mr r3,r8 ; Pass in the virtual address of savearea b EXT(exception_exit) ; Blocking on continuation, toss old context... /* * All switched to threads come here first to clean up the old thread. * We need to do the following contortions because we need to keep * the LR clean. And because we need to manipulate the savearea chain * with translation on. If we could, this should be done in lowmem_vectors * before translation is turned on. But we can't, dang it! * * switch_in() runs with DR on and IR off * * R3 = switcher's savearea (32-bit virtual) * saver4 = old thread in switcher's save * saver5 = new SRR0 in switcher's save * saver6 = new SRR1 in switcher's save */ .align 5 .globl EXT(switch_in) LEXT(switch_in) lwz r4,saver4+4(r3) ; Get the old thread lwz r5,saver5+4(r3) ; Get the srr0 value mfsprg r0,2 ; Get feature flags mr r9,r4 ; Get the switched from ACT lwz r6,saver6+4(r3) ; Get the srr1 value rlwinm. r0,r0,0,pf64Bitb,pf64Bitb ; Check for 64-bit lwz r10,ACT_MACT_PCB(r9) ; Get the top PCB on the old thread stw r3,ACT_MACT_PCB(r9) ; Put the new one on top stw r10,SAVprev+4(r3) ; Chain on the old one mr r3,r4 ; Pass back the old thread mtsrr0 r5 ; Set return point mtsrr1 r6 ; Set return MSR bne++ siSixtyFour ; Go do 64-bit... rfi ; Jam... siSixtyFour: rfid ; Jam... /* * void fpu_save(facility_context ctx) * * Note that there are some oddities here when we save a context we are using. * It is really not too cool to do this, but what the hey... Anyway, * we turn fpus and vecs off before we leave., The oddity is that if you use fpus after this, the * savearea containing the context just saved will go away. So, bottom line is * that don't use fpus until after you are done with the saved context. */ .align 5 .globl EXT(fpu_save) LEXT(fpu_save) lis r2,hi16(MASK(MSR_VEC)) ; Get the vector enable li r12,lo16(MASK(MSR_EE)) ; Get the EE bit ori r2,r2,lo16(MASK(MSR_FP)) ; Get FP mfmsr r0 ; Get the MSR andc r0,r0,r2 ; Clear FP, VEC andc r2,r0,r12 ; Clear EE ori r2,r2,MASK(MSR_FP) ; Enable the floating point feature for now also mtmsr r2 ; Set the MSR isync mfsprg r6,1 ; Get the current activation lwz r6,ACT_PER_PROC(r6) ; Get the per_proc block lwz r12,FPUowner(r6) ; Get the context ID for owner #if FPVECDBG mr r7,r0 ; (TEST/DEBUG) li r4,0 ; (TEST/DEBUG) mr r10,r3 ; (TEST/DEBUG) lis r0,hi16(CutTrace) ; (TEST/DEBUG) mr. r3,r12 ; (TEST/DEBUG) li r2,0x6F00 ; (TEST/DEBUG) li r5,0 ; (TEST/DEBUG) beq-- noowneryet ; (TEST/DEBUG) lwz r4,FPUlevel(r12) ; (TEST/DEBUG) lwz r5,FPUsave(r12) ; (TEST/DEBUG) noowneryet: oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) mr r0,r7 ; (TEST/DEBUG) mr r3,r10 ; (TEST/DEBUG) #endif mflr r2 ; Save the return address cmplw r3,r12 ; Is the specified context live? lhz r11,PP_CPU_NUMBER(r6) ; Get our CPU number lwz r9,FPUcpu(r3) ; Get the cpu that context was last on bne-- fsret ; Nobody owns the FPU, no save required... cmplw r9,r11 ; Was the context for this processor? la r5,FPUsync(r3) ; Point to the sync word bne-- fsret ; Facility not last used on this processor... ; ; It looks like we need to save this one. ; ; First, make sure that the live context block is not mucked with while ; we are trying to save it on out. Then we will give it the final check. ; lis r9,ha16(EXT(LockTimeOut)) ; Get the high part mftb r8 ; Get the time now lwz r9,lo16(EXT(LockTimeOut))(r9) ; Get the timeout value b fssync0a ; Jump to the lock... .align 5 fssync0: li r7,lgKillResv ; Get killing field stwcx. r7,0,r7 ; Kill reservation fssync0a: lwz r7,0(r5) ; Sniff the lock mftb r10 ; Is it time yet? cmplwi cr1,r7,0 ; Is it locked? sub r10,r10,r8 ; How long have we been spinning? cmplw r10,r9 ; Has it been too long? bgt-- fstimeout ; Way too long, panic... bne-- cr1,fssync0a ; Yea, still locked so sniff harder... fssync1: lwarx r7,0,r5 ; Get the sync word li r12,1 ; Get the lock mr. r7,r7 ; Is it unlocked? bne-- fssync0 stwcx. r12,0,r5 ; Store lock and test reservation bne-- fssync1 ; Try again if lost reservation... isync ; Toss speculation lwz r12,FPUowner(r6) ; Get the context ID for owner cmplw r3,r12 ; Check again if we own the FPU? bne-- fsretlk ; Go unlock and return since we no longer own context lwz r5,FPUcpu(r12) ; Get the cpu that context was last on lwz r7,FPUsave(r12) ; Get the current FPU savearea for the thread cmplw r5,r11 ; Is this for the same processor? lwz r9,FPUlevel(r12) ; Get our current level indicator bne-- fsretlk ; Not the same processor, skip any save... cmplwi r7,0 ; Have we ever saved this facility context? beq-- fsneedone ; Never saved it, so go do it... lwz r8,SAVlevel(r7) ; Get the level of this savearea cmplw r9,r8 ; Correct level? beq-- fsretlk ; The current level is already saved, bail out... fsneedone: bl EXT(save_get) ; Get a savearea for the context mfsprg r6,1 ; Get the current activation lwz r6,ACT_PER_PROC(r6) ; Get the per_proc block li r4,SAVfloat ; Get floating point tag lwz r12,FPUowner(r6) ; Get back our thread stb r4,SAVflags+2(r3) ; Mark this savearea as a float lwz r4,facAct(r12) ; Get the activation associated with live context lwz r8,FPUsave(r12) ; Get the current top floating point savearea stw r4,SAVact(r3) ; Indicate the right activation for this context lwz r9,FPUlevel(r12) ; Get our current level indicator again stw r3,FPUsave(r12) ; Set this as the most current floating point context stw r8,SAVprev+4(r3) ; And then chain this in front stw r9,SAVlevel(r3) ; Show level in savearea bl fp_store ; save all 32 FPRs in the save area at r3 mtlr r2 ; Restore return fsretlk: li r7,0 ; Get the unlock value eieio ; Make sure that these updates make it out stw r7,FPUsync(r12) ; Unlock it fsret: mtmsr r0 ; Put interrupts on if they were and floating point off isync blr fstimeout: mr r4,r5 ; Set the lock address mr r5,r7 ; Set the lock word data lis r3,hi16(fstimeout_str) ; Get the failed lck message ori r3,r3,lo16(fstimeout_str) ; Get the failed lck message bl EXT(panic) BREAKPOINT_TRAP ; We die here anyway .data fstimeout_str: STRINGD "fpu_save: timeout on sync lock (0x%08X), value = 0x%08X\n\000" .text /* * fpu_switch() * * Entered to handle the floating-point unavailable exception and * switch fpu context * * This code is run in virtual address mode on with interrupts off. * * Upon exit, the code returns to the users context with the floating * point facility turned on. * * ENTRY: VM switched ON * Interrupts OFF * State is saved in savearea pointed to by R4. * All other registers are free. * */ .align 5 .globl EXT(fpu_switch) LEXT(fpu_switch) #if DEBUG lis r3,hi16(EXT(fpu_trap_count)) ; Get address of FP trap counter ori r3,r3,lo16(EXT(fpu_trap_count)) ; Get address of FP trap counter lwz r1,0(r3) addi r1,r1,1 stw r1,0(r3) #endif /* DEBUG */ mfsprg r17,1 ; Get the current activation lwz r26,ACT_PER_PROC(r17) ; Get the per_proc block mfmsr r19 ; Get the current MSR mr r25,r4 ; Save the entry savearea lwz r22,FPUowner(r26) ; Get the thread that owns the FPU ori r19,r19,lo16(MASK(MSR_FP)) ; Enable the floating point feature mtmsr r19 ; Enable floating point instructions isync lwz r27,ACT_MACT_PCB(r17) ; Get the current level lwz r29,curctx(r17) ; Grab the current context anchor of the current thread ; R22 has the "old" context anchor ; R29 has the "new" context anchor #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x7F01 ; (TEST/DEBUG) mr r3,r22 ; (TEST/DEBUG) mr r5,r29 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif lhz r16,PP_CPU_NUMBER(r26) ; Get the current CPU number mr. r22,r22 ; See if there is any live FP status la r15,FPUsync(r22) ; Point to the sync word beq-- fsnosave ; No live context, so nothing to save... lwz r18,FPUcpu(r22) ; Get the last CPU we ran on cmplw cr2,r22,r29 ; Are both old and new the same context? lwz r30,FPUsave(r22) ; Get the top savearea cmplw r18,r16 ; Make sure we are on the right processor lwz r31,FPUlevel(r22) ; Get the context level cmplwi cr1,r30,0 ; Anything saved yet? bne-- fsnosave ; No, not on the same processor... ; ; Check to see if the live context has already been saved. ; Also check to see if all we are here just to re-enable the MSR ; and handle specially if so. ; cmplw r31,r27 ; See if the current and active levels are the same crand cr0_eq,cr2_eq,cr0_eq ; Remember if both the levels and contexts are the same beq-- fsthesame ; New and old are the same, just go enable... ; ; Note it turns out that on a G5, the following load has about a 50-50 chance of ; taking a segment exception in a system that is doing heavy file I/O. We ; make a dummy access right now in order to get that resolved before we take the lock. ; We do not use the data returned because it may change over the lock ; beq-- cr1,fswsync ; Nothing saved, skip the probe attempt... lwz r11,SAVlevel(r30) ; Touch the context in order to fault in the segment ; ; Make sure that the live context block is not mucked with while ; we are trying to save it on out ; fswsync: lis r11,ha16(EXT(LockTimeOut)) ; Get the high part mftb r3 ; Get the time now lwz r11,lo16(EXT(LockTimeOut))(r11) ; Get the timeout value b fswsync0a ; Jump to the lock... .align 5 fswsync0: li r19,lgKillResv ; Get killing field stwcx. r19,0,r19 ; Kill reservation fswsync0a: lwz r19,0(r15) ; Sniff the lock mftb r18 ; Is it time yet? cmplwi cr1,r19,0 ; Is it locked? sub r18,r18,r3 ; How long have we been spinning? cmplw r18,r11 ; Has it been too long? bgt-- fswtimeout ; Way too long, panic... bne-- cr1,fswsync0a ; Yea, still locked so sniff harder... fswsync1: lwarx r19,0,r15 ; Get the sync word li r0,1 ; Get the lock mr. r19,r19 ; Is it unlocked? bne-- fswsync0 stwcx. r0,0,r15 ; Store lock and test reservation bne-- fswsync1 ; Try again if lost reservation... isync ; Toss speculation ; ; Note that now that we have the lock, we need to check if anything changed. ; Also note that the possible changes are limited. The context owner can ; never change to a different thread or level although it can be invalidated. ; A new context can not be pushed on top of us, but it can be popped. The ; cpu indicator will always change if another processor mucked with any ; contexts. ; ; It should be very rare that any of the context stuff changes across the lock. ; lwz r0,FPUowner(r26) ; Get the thread that owns the FPU again lwz r11,FPUsave(r22) ; Get the top savearea again lwz r18,FPUcpu(r22) ; Get the last CPU we ran on again sub r0,r0,r22 ; Non-zero if we lost ownership, 0 if not xor r11,r11,r30 ; Non-zero if saved context changed, 0 if not xor r18,r18,r16 ; Non-zero if cpu changed, 0 if not cmplwi cr1,r30,0 ; Is anything saved? or r0,r0,r11 ; Zero only if both owner and context are unchanged or. r0,r0,r18 ; Zero only if nothing has changed li r3,0 ; Clear this bne-- fsnosavelk ; Something has changed, so this is not ours to save... beq-- cr1,fsmstsave ; There is no context saved yet... lwz r11,SAVlevel(r30) ; Get the level of top saved context cmplw r31,r11 ; Are live and saved the same? #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x7F02 ; (TEST/DEBUG) mr r3,r11 ; (TEST/DEBUG) mr r5,r31 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) li r3,0 ; (TEST/DEBUG) #endif beq++ fsnosavelk ; Same level, so already saved... fsmstsave: stw r3,FPUowner(r26) ; Kill the context now eieio ; Make sure everyone sees it bl EXT(save_get) ; Go get a savearea lwz r12,facAct(r22) ; Get the activation associated with the context stw r30,SAVprev+4(r3) ; Point us to the old context stw r31,SAVlevel(r3) ; Tag our level li r7,SAVfloat ; Get the floating point ID stw r12,SAVact(r3) ; Make sure we point to the right guy stb r7,SAVflags+2(r3) ; Set that we have a floating point save area stw r3,FPUsave(r22) ; Set this as the latest context savearea for the thread #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x7F03 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif bl fp_store ; store all 32 FPRs fsnosavelk: li r7,0 ; Get the unlock value eieio ; Make sure that these updates make it out stw r7,FPUsync(r22) ; Unlock it. ; ; The context is all saved now and the facility is free. ; ; Check if we need to fill the registers with junk, because this level has ; never used them before and some thieving bastard could hack the old values ; of some thread! Just imagine what would happen if they could! Why, nothing ; would be safe! My God! It is terrifying! ; ; Make sure that the live context block is not mucked with while ; we are trying to load it up ; fsnosave: la r15,FPUsync(r29) ; Point to the sync word lis r11,ha16(EXT(LockTimeOut)) ; Get the high part mftb r3 ; Get the time now lwz r11,lo16(EXT(LockTimeOut))(r11) ; Get the timeout value b fsnsync0a ; Jump to the lock... .align 5 fsnsync0: li r19,lgKillResv ; Get killing field stwcx. r19,0,r19 ; Kill reservation fsnsync0a: lwz r19,0(r15) ; Sniff the lock mftb r18 ; Is it time yet? cmplwi cr1,r19,0 ; Is it locked? sub r18,r18,r3 ; How long have we been spinning? cmplw r18,r11 ; Has it been too long? bgt-- fsntimeout ; Way too long, panic... bne-- cr1,fsnsync0a ; Yea, still locked so sniff harder... fsnsync1: lwarx r19,0,r15 ; Get the sync word li r0,1 ; Get the lock mr. r19,r19 ; Is it unlocked? bne-- fsnsync0 ; Unfortunately, it is locked... stwcx. r0,0,r15 ; Store lock and test reservation bne-- fsnsync1 ; Try again if lost reservation... isync ; Toss speculation lwz r15,ACT_MACT_PCB(r17) ; Get the current level of the "new" one lwz r19,FPUcpu(r29) ; Get the last CPU we ran on lwz r14,FPUsave(r29) ; Point to the top of the "new" context stack stw r16,FPUcpu(r29) ; Claim context for us eieio #if FPVECDBG lwz r13,FPUlevel(r29) ; (TEST/DEBUG) lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x7F04 ; (TEST/DEBUG) mr r1,r15 ; (TEST/DEBUG) mr r3,r14 ; (TEST/DEBUG) mr r5,r13 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif lis r18,hi16(EXT(PerProcTable)) ; Set base PerProcTable mulli r19,r19,ppeSize ; Find offset to the owner per_proc_entry ori r18,r18,lo16(EXT(PerProcTable)) ; Set base PerProcTable li r16,FPUowner ; Displacement to float owner add r19,r18,r19 ; Point to the owner per_proc_entry lwz r19,ppe_vaddr(r19) ; Point to the owner per_proc fsinvothr: lwarx r18,r16,r19 ; Get the owner sub r0,r18,r29 ; Subtract one from the other sub r11,r29,r18 ; Subtract the other from the one or r11,r11,r0 ; Combine them srawi r11,r11,31 ; Get a 0 if equal or -1 of not and r18,r18,r11 ; Make 0 if same, unchanged if not stwcx. r18,r16,r19 ; Try to invalidate it bne-- fsinvothr ; Try again if there was a collision... cmplwi cr1,r14,0 ; Do we possibly have some context to load? la r11,savefp0(r14) ; Point to first line to bring in stw r15,FPUlevel(r29) ; Set the "new" active level eieio stw r29,FPUowner(r26) ; Mark us as having the live context beq++ cr1,MakeSureThatNoTerroristsCanHurtUsByGod ; No "new" context to load... dcbt 0,r11 ; Touch line in lwz r0,SAVlevel(r14) ; Get the level of first facility savearea lwz r3,SAVprev+4(r14) ; Get the previous context cmplw r0,r15 ; Top level correct to load? li r7,0 ; Get the unlock value bne-- MakeSureThatNoTerroristsCanHurtUsByGod ; No, go initialize... stw r3,FPUsave(r29) ; Pop the context (we will toss the savearea later) #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x7F05 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif eieio ; Make sure that these updates make it out stw r7,FPUsync(r29) ; Unlock context now that the context save has been removed // Note this code is used both by 32- and 128-byte processors. This means six extra DCBTs // are executed on a 128-byte machine, but that is better than a mispredicted branch. la r11,savefp4(r14) ; Point to next line dcbt 0,r11 ; Touch line in lfd f0, savefp0(r14) lfd f1,savefp1(r14) lfd f2,savefp2(r14) la r11,savefp8(r14) ; Point to next line lfd f3,savefp3(r14) dcbt 0,r11 ; Touch line in lfd f4,savefp4(r14) lfd f5,savefp5(r14) lfd f6,savefp6(r14) la r11,savefp12(r14) ; Point to next line lfd f7,savefp7(r14) dcbt 0,r11 ; Touch line in lfd f8,savefp8(r14) lfd f9,savefp9(r14) lfd f10,savefp10(r14) la r11,savefp16(r14) ; Point to next line lfd f11,savefp11(r14) dcbt 0,r11 ; Touch line in lfd f12,savefp12(r14) lfd f13,savefp13(r14) lfd f14,savefp14(r14) la r11,savefp20(r14) ; Point to next line lfd f15,savefp15(r14) dcbt 0,r11 ; Touch line in lfd f16,savefp16(r14) lfd f17,savefp17(r14) lfd f18,savefp18(r14) la r11,savefp24(r14) ; Point to next line lfd f19,savefp19(r14) dcbt 0,r11 ; Touch line in lfd f20,savefp20(r14) lfd f21,savefp21(r14) la r11,savefp28(r14) ; Point to next line lfd f22,savefp22(r14) lfd f23,savefp23(r14) dcbt 0,r11 ; Touch line in lfd f24,savefp24(r14) lfd f25,savefp25(r14) lfd f26,savefp26(r14) lfd f27,savefp27(r14) lfd f28,savefp28(r14) lfd f29,savefp29(r14) lfd f30,savefp30(r14) lfd f31,savefp31(r14) mr r3,r14 ; Get the old savearea (we popped it before) bl EXT(save_ret) ; Toss it fsenable: lwz r8,savesrr1+4(r25) ; Get the msr of the interrupted guy ori r8,r8,MASK(MSR_FP) ; Enable the floating point feature lwz r10,ACT_MACT_SPF(r17) ; Get the act special flags lwz r11,spcFlags(r26) ; Get per_proc spec flags cause not in sync with act oris r10,r10,hi16(floatUsed|floatCng) ; Set that we used floating point oris r11,r11,hi16(floatUsed|floatCng) ; Set that we used floating point rlwinm. r0,r8,0,MSR_PR_BIT,MSR_PR_BIT ; See if we are doing this for user state stw r8,savesrr1+4(r25) ; Set the msr of the interrupted guy mr r3,r25 ; Pass the virtual addres of savearea beq- fsnuser ; We are not user state... stw r10,ACT_MACT_SPF(r17) ; Set the activation copy stw r11,spcFlags(r26) ; Set per_proc copy fsnuser: #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x7F07 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif b EXT(exception_exit) ; Exit to the fray... /* * Initialize the registers to some bogus value */ MakeSureThatNoTerroristsCanHurtUsByGod: #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x7F06 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif lis r5,hi16(EXT(FloatInit)) ; Get top secret floating point init value address li r7,0 ; Get the unlock value ori r5,r5,lo16(EXT(FloatInit)) ; Slam bottom eieio ; Make sure that these updates make it out stw r7,FPUsync(r29) ; Unlock it now that the context has been removed lfd f0,0(r5) ; Initialize FP0 fmr f1,f0 ; Do them all fmr f2,f0 fmr f3,f0 fmr f4,f0 fmr f5,f0 fmr f6,f0 fmr f7,f0 fmr f8,f0 fmr f9,f0 fmr f10,f0 fmr f11,f0 fmr f12,f0 fmr f13,f0 fmr f14,f0 fmr f15,f0 fmr f16,f0 fmr f17,f0 fmr f18,f0 fmr f19,f0 fmr f20,f0 fmr f21,f0 fmr f22,f0 fmr f23,f0 fmr f24,f0 fmr f25,f0 fmr f26,f0 fmr f27,f0 fmr f28,f0 fmr f29,f0 fmr f30,f0 fmr f31,f0 b fsenable ; Finish setting it all up... ; ; We get here when we are switching to the same context at the same level and the context ; is still live. Essentially, all we are doing is turning on the facility. It may have ; gotten turned off due to doing a context save for the current level or a context switch ; back to the live guy. ; .align 5 fsthesamel: li r7,0 ; Get the unlock value eieio ; Make sure that these updates make it out stw r7,FPUsync(r22) ; Unlock it. fsthesame: #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x7F0A ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif beq- cr1,fsenable ; Not saved yet, nothing to pop, go enable and exit... lwz r11,SAVlevel(r30) ; Get the level of top saved context lwz r14,SAVprev+4(r30) ; Get the previous savearea cmplw r11,r31 ; Are live and saved the same? bne++ fsenable ; Level not the same, nothing to pop, go enable and exit... mr r3,r30 ; Get the old savearea (we popped it before) stw r14,FPUsave(r22) ; Pop the savearea from the stack bl EXT(save_ret) ; Toss it b fsenable ; Go enable and exit... ; ; Note that we need to choke in this code rather than panic because there is no ; stack. ; fswtimeout: lis r0,hi16(Choke) ; Choke code ori r0,r0,lo16(Choke) ; and the rest li r3,failTimeout ; Timeout code sc ; System ABEND fsntimeout: lis r0,hi16(Choke) ; Choke code ori r0,r0,lo16(Choke) ; and the rest li r3,failTimeout ; Timeout code sc ; System ABEND vswtimeout0: lis r0,hi16(Choke) ; Choke code ori r0,r0,lo16(Choke) ; and the rest li r3,failTimeout ; Timeout code sc ; System ABEND vswtimeout1: lis r0,hi16(Choke) ; Choke code ori r0,r0,lo16(Choke) ; and the rest li r3,failTimeout ; Timeout code sc ; System ABEND ; ; This function invalidates any live floating point context for the passed in facility_context. ; This is intended to be called just before act_machine_sv_free tosses saveareas. ; .align 5 .globl EXT(toss_live_fpu) LEXT(toss_live_fpu) lis r0,hi16(MASK(MSR_VEC)) ; Get VEC mfmsr r9 ; Get the MSR ori r0,r0,lo16(MASK(MSR_FP)) ; Add in FP rlwinm. r8,r9,0,MSR_FP_BIT,MSR_FP_BIT ; Are floats on right now? andc r9,r9,r0 ; Force off VEC and FP ori r0,r0,lo16(MASK(MSR_EE)) ; Turn off EE andc r0,r9,r0 ; Turn off EE now mtmsr r0 ; No interruptions isync beq+ tlfnotours ; Floats off, can not be live here... mfsprg r8,1 ; Get the current activation lwz r8,ACT_PER_PROC(r8) ; Get the per_proc block ; ; Note that at this point, since floats are on, we are the owner ; of live state on this processor ; lwz r6,FPUowner(r8) ; Get the thread that owns the floats li r0,0 ; Clear this just in case we need it cmplw r6,r3 ; Are we tossing our own context? bne-- tlfnotours ; Nope... lfd f1,Zero(0) ; Make a 0 mtfsf 0xFF,f1 ; Clear it tlfnotours: lwz r11,FPUcpu(r3) ; Get the cpu on which we last loaded context lis r12,hi16(EXT(PerProcTable)) ; Set base PerProcTable mulli r11,r11,ppeSize ; Find offset to the owner per_proc_entry ori r12,r12,lo16(EXT(PerProcTable)) ; Set base PerProcTable li r10,FPUowner ; Displacement to float owner add r11,r12,r11 ; Point to the owner per_proc_entry lwz r11,ppe_vaddr(r11) ; Point to the owner per_proc tlfinvothr: lwarx r12,r10,r11 ; Get the owner sub r0,r12,r3 ; Subtract one from the other sub r8,r3,r12 ; Subtract the other from the one or r8,r8,r0 ; Combine them srawi r8,r8,31 ; Get a 0 if equal or -1 of not and r12,r12,r8 ; Make 0 if same, unchanged if not stwcx. r12,r10,r11 ; Try to invalidate it bne-- tlfinvothr ; Try again if there was a collision... mtmsr r9 ; Restore interruptions isync ; Could be turning off floats here blr ; Leave... /* * Altivec stuff is here. The techniques used are pretty identical to * the floating point. Except that we will honor the VRSAVE register * settings when loading and restoring registers. * * There are two indications of saved VRs: the VRSAVE register and the vrvalid * mask. VRSAVE is set by the vector user and represents the VRs that they * say that they are using. The vrvalid mask indicates which vector registers * are saved in the savearea. Whenever context is saved, it is saved according * to the VRSAVE register. It is loaded based on VRSAVE anded with * vrvalid (all other registers are splatted with 0s). This is done because we * don't want to load any registers we don't have a copy of, we want to set them * to zero instead. * * Note that there are some oddities here when we save a context we are using. * It is really not too cool to do this, but what the hey... Anyway, * we turn vectors and fpu off before we leave. * The oddity is that if you use vectors after this, the * savearea containing the context just saved will go away. So, bottom line is * that don't use vectors until after you are done with the saved context. * */ .align 5 .globl EXT(vec_save) LEXT(vec_save) lis r2,hi16(MASK(MSR_VEC)) ; Get VEC mfmsr r0 ; Get the MSR ori r2,r2,lo16(MASK(MSR_FP)) ; Add in FP andc r0,r0,r2 ; Force off VEC and FP ori r2,r2,lo16(MASK(MSR_EE)) ; Clear EE andc r2,r0,r2 ; Clear EE for now oris r2,r2,hi16(MASK(MSR_VEC)) ; Enable the vector facility for now also mtmsr r2 ; Set the MSR isync mfsprg r6,1 ; Get the current activation lwz r6,ACT_PER_PROC(r6) ; Get the per_proc block lwz r12,VMXowner(r6) ; Get the context ID for owner #if FPVECDBG mr r11,r6 ; (TEST/DEBUG) mr r7,r0 ; (TEST/DEBUG) li r4,0 ; (TEST/DEBUG) mr r10,r3 ; (TEST/DEBUG) lis r0,hi16(CutTrace) ; (TEST/DEBUG) mr. r3,r12 ; (TEST/DEBUG) li r2,0x5F00 ; (TEST/DEBUG) li r5,0 ; (TEST/DEBUG) lwz r6,liveVRS(r6) ; (TEST/DEBUG) beq-- noowneryeu ; (TEST/DEBUG) lwz r4,VMXlevel(r12) ; (TEST/DEBUG) lwz r5,VMXsave(r12) ; (TEST/DEBUG) noowneryeu: oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) mr r0,r7 ; (TEST/DEBUG) mr r3,r10 ; (TEST/DEBUG) mr r6,r11 ; (TEST/DEBUG) #endif mflr r2 ; Save the return address cmplw r3,r12 ; Is the specified context live? lhz r11,PP_CPU_NUMBER(r6) ; Get our CPU number bne-- vsret ; We do not own the vector, no save required... lwz r9,VMXcpu(r12) ; Get the cpu that context was last on cmplw r9,r11 ; Was the context for this processor? la r5,VMXsync(r3) ; Point to the sync word bne-- vsret ; Specified context is not live ; ; It looks like we need to save this one. Or possibly toss a saved one if ; the VRSAVE is 0. ; ; First, make sure that the live context block is not mucked with while ; we are trying to save it on out. Then we will give it the final check. ; lis r9,ha16(EXT(LockTimeOut)) ; Get the high part mftb r8 ; Get the time now lwz r9,lo16(EXT(LockTimeOut))(r9) ; Get the timeout value b vssync0a ; Jump to the lock... .align 5 vssync0: li r7,lgKillResv ; Get killing field stwcx. r7,0,r7 ; Kill reservation vssync0a: lwz r7,0(r5) ; Sniff the lock mftb r10 ; Is it time yet? cmplwi cr1,r7,0 ; Is it locked? sub r10,r10,r8 ; How long have we been spinning? cmplw r10,r9 ; Has it been too long? bgt-- vswtimeout0 ; Way too long, panic... bne-- cr1,vssync0a ; Yea, still locked so sniff harder... vssync1: lwarx r7,0,r5 ; Get the sync word li r12,1 ; Get the lock mr. r7,r7 ; Is it unlocked? bne-- vssync0 ; No, it is unlocked... stwcx. r12,0,r5 ; Store lock and test reservation bne-- vssync1 ; Try again if lost reservation... isync ; Toss speculation lwz r12,VMXowner(r6) ; Get the context ID for owner cmplw r3,r12 ; Check again if we own VMX? lwz r10,liveVRS(r6) ; Get the right VRSave register bne-- vsretlk ; Go unlock and return since we no longer own context lwz r5,VMXcpu(r12) ; Get the cpu that context was last on lwz r7,VMXsave(r12) ; Get the current vector savearea for the thread cmplwi cr1,r10,0 ; Is VRsave set to 0? cmplw r5,r11 ; Is this for the same processor? lwz r9,VMXlevel(r12) ; Get our current level indicator bne-- vsretlk ; Not the same processor, skip any save... cmplwi r7,0 ; Have we ever saved this facility context? beq-- vsneedone ; Never saved it, so we need an area... lwz r8,SAVlevel(r7) ; Get the level this savearea is for cmplw r9,r8 ; Correct level? bne-- vsneedone ; Different level, so we need to save... bne++ cr1,vsretlk ; VRsave is non-zero so we need to keep what is saved... lwz r4,SAVprev+4(r7) ; Pick up the previous area li r5,0 ; Assume we just dumped the last mr. r4,r4 ; Is there one? stw r4,VMXsave(r12) ; Dequeue this savearea beq-- vsnomore ; We do not have another... lwz r5,SAVlevel(r4) ; Get the level associated with save vsnomore: stw r5,VMXlevel(r12) ; Save the level li r7,0 ; Clear stw r7,VMXowner(r6) ; Show no live context here vsbackout: mr r4,r0 ; restore the saved MSR eieio stw r7,VMXsync(r12) ; Unlock the context b EXT(save_ret_wMSR) ; Toss the savearea and return from there... .align 5 vsneedone: beq-- cr1,vsclrlive ; VRSave is zero, go blow away the context... bl EXT(save_get) ; Get a savearea for the context mfsprg r6,1 ; Get the current activation lwz r6,ACT_PER_PROC(r6) ; Get the per_proc block li r4,SAVvector ; Get vector tag lwz r12,VMXowner(r6) ; Get back our context ID stb r4,SAVflags+2(r3) ; Mark this savearea as a vector mr. r12,r12 ; See if we were disowned while away. Very, very small chance of it... li r7,0 ; Clear beq-- vsbackout ; If disowned, just toss savearea... lwz r4,facAct(r12) ; Get the activation associated with live context lwz r8,VMXsave(r12) ; Get the current top vector savearea stw r4,SAVact(r3) ; Indicate the right activation for this context lwz r9,VMXlevel(r12) ; Get our current level indicator again stw r3,VMXsave(r12) ; Set this as the most current floating point context stw r8,SAVprev+4(r3) ; And then chain this in front stw r9,SAVlevel(r3) ; Set level in savearea mfcr r12 ; save CRs across call to vr_store lwz r10,liveVRS(r6) ; Get the right VRSave register bl vr_store ; store live VRs into savearea as required (uses r4-r11) mfsprg r6,1 ; Get the current activation mtcrf 255,r12 ; Restore the non-volatile CRs lwz r6,ACT_PER_PROC(r6) ; Get the per_proc block mtlr r2 ; Restore return address lwz r12,VMXowner(r6) ; Get back our context ID vsretlk: li r7,0 ; Get the unlock value eieio ; Make sure that these updates make it out stw r7,VMXsync(r12) ; Unlock it vsret: mtmsr r0 ; Put interrupts on if they were and vector off isync blr vsclrlive: li r7,0 ; Clear stw r7,VMXowner(r6) ; Show no live context here b vsretlk ; Go unlock and leave... /* * vec_switch() * * Entered to handle the vector unavailable exception and * switch vector context * * This code is run with virtual address mode on and interrupts off. * * Upon exit, the code returns to the users context with the vector * facility turned on. * * ENTRY: VM switched ON * Interrupts OFF * State is saved in savearea pointed to by R4. * All other registers are free. * */ .align 5 .globl EXT(vec_switch) LEXT(vec_switch) #if DEBUG lis r3,hi16(EXT(vec_trap_count)) ; Get address of vector trap counter ori r3,r3,lo16(EXT(vec_trap_count)) ; Get address of vector trap counter lwz r1,0(r3) addi r1,r1,1 stw r1,0(r3) #endif /* DEBUG */ mfsprg r17,1 ; Get the current activation lwz r26,ACT_PER_PROC(r17) ; Get the per_proc block mfmsr r19 ; Get the current MSR mr r25,r4 ; Save the entry savearea oris r19,r19,hi16(MASK(MSR_VEC)) ; Enable the vector feature lwz r22,VMXowner(r26) ; Get the thread that owns the vector mtmsr r19 ; Enable vector instructions isync lwz r27,ACT_MACT_PCB(r17) ; Get the current level lwz r29,curctx(r17) ; Grab the current context anchor of the current thread ; R22 has the "old" context anchor ; R29 has the "new" context anchor #if FPVECDBG lis r0,HIGH_ADDR(CutTrace) ; (TEST/DEBUG) li r2,0x5F01 ; (TEST/DEBUG) mr r3,r22 ; (TEST/DEBUG) mr r5,r29 ; (TEST/DEBUG) lwz r6,liveVRS(r26) ; (TEST/DEBUG) oris r0,r0,LOW_ADDR(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif lhz r16,PP_CPU_NUMBER(r26) ; Get the current CPU number mr. r22,r22 ; See if there is any live vector status la r15,VMXsync(r22) ; Point to the sync word beq-- vswnosave ; No live context, so nothing to save... lwz r18,VMXcpu(r22) ; Get the last CPU we ran on cmplw cr2,r22,r29 ; Are both old and new the same context? lwz r30,VMXsave(r22) ; Get the top savearea cmplwi cr1,r30,0 ; Anything saved yet? lwz r31,VMXlevel(r22) ; Get the context level cmplw r18,r16 ; Make sure we are on the right processor lwz r10,liveVRS(r26) ; Get the right VRSave register bne-- vswnosave ; No, not on the same processor... ; ; Check to see if the live context has already been saved. ; Also check to see if all we are here just to re-enable the MSR ; and handle specially if so. ; cmplw r31,r27 ; See if the current and active levels are the same crand cr0_eq,cr2_eq,cr0_eq ; Remember if both the levels and contexts are the same beq-- vswthesame ; New and old are the same, just go enable... ; ; Make sure that the live context block is not mucked with while ; we are trying to save it on out ; lis r11,ha16(EXT(LockTimeOut)) ; Get the high part mftb r3 ; Get the time now lwz r11,lo16(EXT(LockTimeOut))(r11) ; Get the timeout value b vswsync0a ; Jump to the lock... .align 5 vswsync0: li r19,lgKillResv ; Get killing field stwcx. r19,0,r19 ; Kill reservation vswsync0a: lwz r19,0(r15) ; Sniff the lock mftb r18 ; Is it time yet? cmplwi cr1,r19,0 ; Is it locked? sub r18,r18,r3 ; How long have we been spinning? cmplw r18,r11 ; Has it been too long? bgt-- vswtimeout0 ; Way too long, panic... bne-- cr1,vswsync0a ; Yea, still locked so sniff harder... vswsync1: lwarx r19,0,r15 ; Get the sync word li r0,1 ; Get the lock mr. r19,r19 ; Is it unlocked? bne-- vswsync0 stwcx. r0,0,r15 ; Store lock and test reservation bne-- vswsync1 ; Try again if lost reservation... isync ; Toss speculation ; ; Note that now that we have the lock, we need to check if anything changed. ; Also note that the possible changes are limited. The context owner can ; never change to a different thread or level although it can be invalidated. ; A new context can not be pushed on top of us, but it can be popped. The ; cpu indicator will always change if another processor mucked with any ; contexts. ; ; It should be very rare that any of the context stuff changes across the lock. ; lwz r0,VMXowner(r26) ; Get the thread that owns the vectors again lwz r11,VMXsave(r22) ; Get the top savearea again lwz r18,VMXcpu(r22) ; Get the last CPU we ran on again sub r0,r0,r22 ; Non-zero if we lost ownership, 0 if not xor r11,r11,r30 ; Non-zero if saved context changed, 0 if not xor r18,r18,r16 ; Non-zero if cpu changed, 0 if not cmplwi cr1,r30,0 ; Is anything saved? or r0,r0,r11 ; Zero only if both owner and context are unchanged or. r0,r0,r18 ; Zero only if nothing has changed cmplwi cr2,r10,0 ; Check VRSave to see if we really need to save anything... li r8,0 ; Clear bne-- vswnosavelk ; Something has changed, so this is not ours to save... beq-- cr1,vswmstsave ; There is no context saved yet... lwz r11,SAVlevel(r30) ; Get the level of top saved context cmplw r31,r11 ; Are live and saved the same? #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x5F02 ; (TEST/DEBUG) mr r3,r30 ; (TEST/DEBUG) mr r5,r31 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif beq++ vswnosavelk ; Same level, already saved... bne-- cr2,vswnosavelk ; Live context saved and VRSave not 0, no save and keep context... lwz r4,SAVprev+4(r30) ; Pick up the previous area li r5,0 ; Assume this is the only one (which should be the ususal case) mr. r4,r4 ; Was this the only one? stw r4,VMXsave(r22) ; Dequeue this savearea beq++ vswonlyone ; This was the only one... lwz r5,SAVlevel(r4) ; Get the level associated with previous save vswonlyone: stw r5,VMXlevel(r22) ; Save the level stw r8,VMXowner(r26) ; Clear owner mr r3,r30 ; Copy the savearea we are tossing bl EXT(save_ret) ; Toss the savearea b vswnosavelk ; Go load up the context... .align 5 vswmstsave: stw r8,VMXowner(r26) ; Clear owner beq-- cr2,vswnosavelk ; The VRSave was 0, so there is nothing to save... bl EXT(save_get) ; Go get a savearea lwz r12,facAct(r22) ; Get the activation associated with the context stw r3,VMXsave(r22) ; Set this as the latest context savearea for the thread stw r30,SAVprev+4(r3) ; Point us to the old context stw r31,SAVlevel(r3) ; Tag our level li r7,SAVvector ; Get the vector ID stw r12,SAVact(r3) ; Make sure we point to the right guy stb r7,SAVflags+2(r3) ; Set that we have a vector save area #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x5F03 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif lwz r10,liveVRS(r26) ; Get the right VRSave register bl vr_store ; store VRs into savearea according to vrsave (uses r4-r11) ; ; The context is all saved now and the facility is free. ; ; Check if we need to fill the registers with junk, because this level has ; never used them before and some thieving bastard could hack the old values ; of some thread! Just imagine what would happen if they could! Why, nothing ; would be safe! My God! It is terrifying! ; ; Also, along the way, thanks to Ian Ollmann, we generate the 0x7FFFDEAD (QNaNbarbarian) ; constant that we may need to fill unused vector registers. ; ; Make sure that the live context block is not mucked with while ; we are trying to load it up ; vswnosavelk: li r7,0 ; Get the unlock value eieio ; Make sure that these updates make it out stw r7,VMXsync(r22) ; Unlock the old context vswnosave: la r15,VMXsync(r29) ; Point to the sync word lis r11,ha16(EXT(LockTimeOut)) ; Get the high part mftb r3 ; Get the time now lwz r11,lo16(EXT(LockTimeOut))(r11) ; Get the timeout value b vswnsync0a ; Jump to the lock... .align 5 vswnsync0: li r19,lgKillResv ; Get killing field stwcx. r19,0,r19 ; Kill reservation vswnsync0a: lwz r19,0(r15) ; Sniff the lock mftb r18 ; Is it time yet? cmplwi cr1,r19,0 ; Is it locked? sub r18,r18,r3 ; How long have we been spinning? cmplw r18,r11 ; Has it been too long? bgt-- vswtimeout1 ; Way too long, panic... bne-- cr1,vswnsync0a ; Yea, still locked so sniff harder... vswnsync1: lwarx r19,0,r15 ; Get the sync word li r0,1 ; Get the lock mr. r19,r19 ; Is it unlocked? bne-- vswnsync0 ; Unfortunately, it is locked... stwcx. r0,0,r15 ; Store lock and test reservation bne-- vswnsync1 ; Try again if lost reservation... isync ; Toss speculation vspltisb v31,-10 ; Get 0xF6F6F6F6 lwz r15,ACT_MACT_PCB(r17) ; Get the current level of the "new" one vspltisb v30,5 ; Get 0x05050505 lwz r19,VMXcpu(r29) ; Get the last CPU we ran on vspltish v29,4 ; Get 0x00040004 lwz r14,VMXsave(r29) ; Point to the top of the "new" context stack vrlb v31,v31,v30 ; Get 0xDEDEDEDE stw r16,VMXcpu(r29) ; Claim context for us eieio #if FPVECDBG lwz r13,VMXlevel(r29) ; (TEST/DEBUG) lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x5F04 ; (TEST/DEBUG) mr r1,r15 ; (TEST/DEBUG) mr r3,r14 ; (TEST/DEBUG) mr r5,r13 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif lis r18,hi16(EXT(PerProcTable)) ; Set base PerProcTable vspltisb v28,-2 ; Get 0xFEFEFEFE mulli r19,r19,ppeSize ; Find offset to the owner per_proc_entry vsubuhm v31,v31,v29 ; Get 0xDEDADEDA ori r18,r18,lo16(EXT(PerProcTable)) ; Set base PerProcTable vpkpx v30,v28,v3 ; Get 0x7FFF7FFF li r16,VMXowner ; Displacement to vector owner add r19,r18,r19 ; Point to the owner per_proc_entry lwz r19,ppe_vaddr(r19) ; Point to the owner per_proc vrlb v31,v31,v29 ; Get 0xDEADDEAD vswinvothr: lwarx r18,r16,r19 ; Get the owner sub r0,r18,r29 ; Subtract one from the other sub r11,r29,r18 ; Subtract the other from the one or r11,r11,r0 ; Combine them srawi r11,r11,31 ; Get a 0 if equal or -1 of not and r18,r18,r11 ; Make 0 if same, unchanged if not stwcx. r18,r16,r19 ; Try to invalidate it bne-- vswinvothr ; Try again if there was a collision... cmplwi cr1,r14,0 ; Do we possibly have some context to load? vmrghh v31,v30,v31 ; Get 0x7FFFDEAD. V31 keeps this value until the bitter end stw r15,VMXlevel(r29) ; Set the "new" active level eieio stw r29,VMXowner(r26) ; Mark us as having the live context beq-- cr1,ProtectTheAmericanWay ; Nothing to restore, first time use... lwz r3,SAVprev+4(r14) ; Get the previous context lwz r0,SAVlevel(r14) ; Get the level of first facility savearea cmplw r0,r15 ; Top level correct to load? bne-- ProtectTheAmericanWay ; No, go initialize... stw r3,VMXsave(r29) ; Pop the context (we will toss the savearea later) #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x5F05 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif lwz r10,savevrvalid(r14) ; Get the valid VRs in the savearea lwz r22,savevrsave(r25) ; Get the most current VRSAVE and r10,r10,r22 ; Figure out just what registers need to be loaded mr r3,r14 ; r3 <- ptr to savearea with VRs bl vr_load ; load VRs from save area based on vrsave in r10 bl EXT(save_ret) ; Toss the save area after loading VRs vrenablelk: li r7,0 ; Get the unlock value eieio ; Make sure that these updates make it out stw r7,VMXsync(r29) ; Unlock the new context vrenable: lwz r8,savesrr1+4(r25) ; Get the msr of the interrupted guy oris r8,r8,hi16(MASK(MSR_VEC)) ; Enable the vector facility lwz r10,ACT_MACT_SPF(r17) ; Get the act special flags lwz r11,spcFlags(r26) ; Get per_proc spec flags cause not in sync with act oris r10,r10,hi16(vectorUsed|vectorCng) ; Set that we used vectors oris r11,r11,hi16(vectorUsed|vectorCng) ; Set that we used vectors rlwinm. r0,r8,0,MSR_PR_BIT,MSR_PR_BIT ; See if we are doing this for user state stw r8,savesrr1+4(r25) ; Set the msr of the interrupted guy mr r3,r25 ; Pass virtual address of the savearea beq- vrnuser ; We are not user state... stw r10,ACT_MACT_SPF(r17) ; Set the activation copy stw r11,spcFlags(r26) ; Set per_proc copy vrnuser: #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x5F07 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif b EXT(exception_exit) ; Exit to the fray... /* * Initialize the registers to some bogus value */ ProtectTheAmericanWay: #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x5F06 ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif vor v0,v31,v31 ; Copy into the next register vor v1,v31,v31 ; Copy into the next register vor v2,v31,v31 ; Copy into the next register vor v3,v31,v31 ; Copy into the next register vor v4,v31,v31 ; Copy into the next register vor v5,v31,v31 ; Copy into the next register vor v6,v31,v31 ; Copy into the next register vor v7,v31,v31 ; Copy into the next register vor v8,v31,v31 ; Copy into the next register vor v9,v31,v31 ; Copy into the next register vor v10,v31,v31 ; Copy into the next register vor v11,v31,v31 ; Copy into the next register vor v12,v31,v31 ; Copy into the next register vor v13,v31,v31 ; Copy into the next register vor v14,v31,v31 ; Copy into the next register vor v15,v31,v31 ; Copy into the next register vor v16,v31,v31 ; Copy into the next register vor v17,v31,v31 ; Copy into the next register vor v18,v31,v31 ; Copy into the next register vor v19,v31,v31 ; Copy into the next register vor v20,v31,v31 ; Copy into the next register vor v21,v31,v31 ; Copy into the next register vor v22,v31,v31 ; Copy into the next register vor v23,v31,v31 ; Copy into the next register vor v24,v31,v31 ; Copy into the next register vor v25,v31,v31 ; Copy into the next register vor v26,v31,v31 ; Copy into the next register vor v27,v31,v31 ; Copy into the next register vor v28,v31,v31 ; Copy into the next register vor v29,v31,v31 ; Copy into the next register vor v30,v31,v31 ; Copy into the next register b vrenablelk ; Finish setting it all up... ; ; We get here when we are switching to the same context at the same level and the context ; is still live. Essentially, all we are doing is turning on the faility. It may have ; gotten turned off due to doing a context save for the current level or a context switch ; back to the live guy. ; .align 5 vswthesame: #if FPVECDBG lis r0,hi16(CutTrace) ; (TEST/DEBUG) li r2,0x5F0A ; (TEST/DEBUG) oris r0,r0,lo16(CutTrace) ; (TEST/DEBUG) sc ; (TEST/DEBUG) #endif beq- cr1,vrenable ; Not saved yet, nothing to pop, go enable and exit... lwz r11,SAVlevel(r30) ; Get the level of top saved context lwz r14,SAVprev+4(r30) ; Get the previous savearea cmplw r11,r31 ; Are live and saved the same? bne+ vrenable ; Level not the same, nothing to pop, go enable and exit... mr r3,r30 ; Get the old savearea (we popped it before) stw r11,VMXsave(r22) ; Pop the vector stack bl EXT(save_ret) ; Toss it b vrenable ; Go enable and exit... ; ; This function invalidates any live vector context for the passed in facility_context. ; This is intended to be called just before act_machine_sv_free tosses saveareas. ; .align 5 .globl EXT(toss_live_vec) LEXT(toss_live_vec) lis r0,hi16(MASK(MSR_VEC)) ; Get VEC mfmsr r9 ; Get the MSR ori r0,r0,lo16(MASK(MSR_FP)) ; Add in FP rlwinm. r8,r9,0,MSR_VEC_BIT,MSR_VEC_BIT ; Are vectors on right now? andc r9,r9,r0 ; Force off VEC and FP ori r0,r0,lo16(MASK(MSR_EE)) ; Turn off EE andc r0,r9,r0 ; Turn off EE now mtmsr r0 ; No interruptions isync beq+ tlvnotours ; Vector off, can not be live here... mfsprg r8,1 ; Get the current activation lwz r8,ACT_PER_PROC(r8) ; Get the per_proc block ; ; Note that at this point, since vecs are on, we are the owner ; of live state on this processor ; lwz r6,VMXowner(r8) ; Get the thread that owns the vector li r0,0 ; Clear this just in case we need it cmplw r6,r3 ; Are we tossing our own context? bne- tlvnotours ; Nope... vspltish v1,1 ; Turn on the non-Java bit and saturate vspltisw v0,1 ; Turn on the saturate bit vxor v1,v1,v0 ; Turn off saturate mtspr vrsave,r0 ; Clear VRSAVE mtvscr v1 ; Set the non-java, no saturate status tlvnotours: lwz r11,VMXcpu(r3) ; Get the cpu on which we last loaded context lis r12,hi16(EXT(PerProcTable)) ; Set base PerProcTable mulli r11,r11,ppeSize ; Find offset to the owner per_proc_entry ori r12,r12,lo16(EXT(PerProcTable)) ; Set base PerProcTable li r10,VMXowner ; Displacement to vector owner add r11,r12,r11 ; Point to the owner per_proc_entry lwz r11,ppe_vaddr(r11) ; Point to the owner per_proc li r0,0 ; Set a 0 to invalidate context tlvinvothr: lwarx r12,r10,r11 ; Get the owner sub r0,r12,r3 ; Subtract one from the other sub r8,r3,r12 ; Subtract the other from the one or r8,r8,r0 ; Combine them srawi r8,r8,31 ; Get a 0 if equal or -1 of not and r12,r12,r8 ; Make 0 if same, unchanged if not stwcx. r12,r10,r11 ; Try to invalidate it bne-- tlvinvothr ; Try again if there was a collision... mtmsr r9 ; Restore interruptions isync ; Could be turning off vectors here blr ; Leave.... #if 0 ; ; This function invalidates any live vector context for the passed in facility_context ; if the level is current. It also tosses the corresponding savearea if there is one. ; This function is primarily used whenever we detect a VRSave that is all zeros. ; .align 5 .globl EXT(vec_trash) LEXT(vec_trash) lwz r12,facAct(r3) ; Get the activation lwz r11,VMXlevel(r3) ; Get the context level lwz r10,ACT_MACT_PCB(r12) ; Grab the current level for the thread lwz r9,VMXsave(r3) ; Get the savearea, if any cmplw r10,r11 ; Are we at the right level? cmplwi cr1,r9,0 ; Remember if there is a savearea bnelr+ ; No, we do nothing... lwz r11,VMXcpu(r3) ; Get the cpu on which we last loaded context lis r12,hi16(EXT(PerProcTable)) ; Set base PerProcTable mulli r11,r11,ppeSize ; Find offset to the owner per_proc_entry ori r12,r12,lo16(EXT(PerProcTable)) ; Set base PerProcTable li r10,VMXowner ; Displacement to vector owner add r11,r12,r11 ; Point to the owner per_proc_entry lwz r11,ppe_vaddr(r11) ; Point to the owner per_proc vtinvothr: lwarx r12,r10,r11 ; Get the owner sub r0,r12,r3 ; Subtract one from the other sub r8,r3,r12 ; Subtract the other from the one or r8,r8,r0 ; Combine them srawi r8,r8,31 ; Get a 0 if equal or -1 of not and r12,r12,r8 ; Make 0 if same, unchanged if not stwcx. r12,r10,r11 ; Try to invalidate it bne-- vtinvothr ; Try again if there was a collision... beqlr++ cr1 ; Leave if there is no savearea lwz r8,SAVlevel(r9) ; Get the level of the savearea cmplw r8,r11 ; Savearea for the current level? bnelr++ ; No, nothing to release... lwz r8,SAVprev+4(r9) ; Pick up the previous area mr. r8,r8 ; Is there a previous? beq-- vtnoprev ; Nope... lwz r7,SAVlevel(r8) ; Get the level associated with save vtnoprev: stw r8,VMXsave(r3) ; Dequeue this savearea stw r7,VMXlevel(r3) ; Pop the level mr r3,r9 ; Get the savearea to release b EXT(save_ret) ; Go and toss the save area (note, we will return from there)... #endif ; ; Just some test code to force vector and/or floating point in the kernel ; .align 5 .globl EXT(fctx_test) LEXT(fctx_test) mfsprg r3,1 ; Get the current thread mr. r3,r3 ; Are we actually up and running? beqlr- ; No... fmr f0,f0 ; Use floating point mftb r4 ; Get time base for a random number li r5,1 ; Get a potential vrsave to use andi. r4,r4,0x3F ; Get a number from 0 - 63 slw r5,r5,r4 ; Choose a register to save (should be 0 half the time) mtspr vrsave,r5 ; Set VRSave vor v0,v0,v0 ; Use vectors blr // ******************* // * f p _ s t o r e * // ******************* // // Store FPRs into a save area. Called by fpu_save and fpu_switch. // // When called: // floating pt is enabled // r3 = ptr to save area // // We destroy: // r11. fp_store: mfsprg r11,2 ; get feature flags mtcrf 0x02,r11 ; put cache line size bits in cr6 la r11,savefp0(r3) ; point to 1st line dcbz128 0,r11 ; establish 1st line no matter what linesize is bt-- pf32Byteb,fp_st32 ; skip if a 32-byte machine // Store the FPRs on a 128-byte machine. stfd f0,savefp0(r3) stfd f1,savefp1(r3) la r11,savefp16(r3) ; Point to the 2nd cache line stfd f2,savefp2(r3) stfd f3,savefp3(r3) dcbz128 0,r11 ; establish 2nd line stfd f4,savefp4(r3) stfd f5,savefp5(r3) stfd f6,savefp6(r3) stfd f7,savefp7(r3) stfd f8,savefp8(r3) stfd f9,savefp9(r3) stfd f10,savefp10(r3) stfd f11,savefp11(r3) stfd f12,savefp12(r3) stfd f13,savefp13(r3) stfd f14,savefp14(r3) stfd f15,savefp15(r3) stfd f16,savefp16(r3) stfd f17,savefp17(r3) stfd f18,savefp18(r3) stfd f19,savefp19(r3) stfd f20,savefp20(r3) stfd f21,savefp21(r3) stfd f22,savefp22(r3) stfd f23,savefp23(r3) stfd f24,savefp24(r3) stfd f25,savefp25(r3) stfd f26,savefp26(r3) stfd f27,savefp27(r3) stfd f28,savefp28(r3) stfd f29,savefp29(r3) stfd f30,savefp30(r3) stfd f31,savefp31(r3) blr // Store FPRs on a 32-byte machine. fp_st32: la r11,savefp4(r3) ; Point to the 2nd line stfd f0,savefp0(r3) dcbz 0,r11 ; Allocate cache stfd f1,savefp1(r3) stfd f2,savefp2(r3) la r11,savefp8(r3) ; Point to the 3rd line stfd f3,savefp3(r3) dcbz 0,r11 ; Allocate cache stfd f4,savefp4(r3) stfd f5,savefp5(r3) stfd f6,savefp6(r3) la r11,savefp12(r3) ; Point to the 4th line stfd f7,savefp7(r3) dcbz 0,r11 ; Allocate cache stfd f8,savefp8(r3) stfd f9,savefp9(r3) stfd f10,savefp10(r3) la r11,savefp16(r3) ; Point to the 5th line stfd f11,savefp11(r3) dcbz 0,r11 ; Allocate cache stfd f12,savefp12(r3) stfd f13,savefp13(r3) stfd f14,savefp14(r3) la r11,savefp20(r3) ; Point to the 6th line stfd f15,savefp15(r3) dcbz 0,r11 ; Allocate cache stfd f16,savefp16(r3) stfd f17,savefp17(r3) stfd f18,savefp18(r3) la r11,savefp24(r3) ; Point to the 7th line stfd f19,savefp19(r3) dcbz 0,r11 ; Allocate cache stfd f20,savefp20(r3) stfd f21,savefp21(r3) stfd f22,savefp22(r3) la r11,savefp28(r3) ; Point to the 8th line stfd f23,savefp23(r3) dcbz 0,r11 ; allocate it stfd f24,savefp24(r3) stfd f25,savefp25(r3) stfd f26,savefp26(r3) stfd f27,savefp27(r3) stfd f28,savefp28(r3) stfd f29,savefp29(r3) stfd f30,savefp30(r3) stfd f31,savefp31(r3) blr // ******************* // * v r _ s t o r e * // ******************* // // Store VRs into savearea, according to bits set in passed vrsave bitfield. This routine is used // both by vec_save and vec_switch. In order to minimize conditional branches and touching in // unnecessary cache blocks, we either save all or none of the VRs in a block. We have separate paths // for each cache block size. // // When called: // interrupts are off, vectors are enabled // r3 = ptr to save area // r10 = vrsave (not 0) // // We destroy: // r4 - r11, all CRs. vr_store: mfsprg r9,2 ; get feature flags stw r10,savevrvalid(r3) ; Save the validity information in savearea slwi r8,r10,1 ; Shift over 1 mtcrf 0x02,r9 ; put cache line size bits in cr6 where we can test or r8,r10,r8 ; r8 <- even bits show which pairs are in use bt-- pf32Byteb,vr_st32 ; skip if 32-byte cacheline processor ; Save vectors on a 128-byte linesize processor. We save all or none of the 8 registers in each of ; the four cache lines. This minimizes mispredicted branches yet handles cache lines optimally. slwi r7,r8,2 ; shift groups-of-2 over by 2 li r4,16 ; load offsets for X-form stores or r8,r7,r8 ; show if any in group of 4 are in use li r5,32 slwi r7,r8,4 ; shift groups-of-4 over by 4 li r6,48 or r11,r7,r8 ; show if any in group of 8 are in use li r7,64 mtcrf 0x80,r11 ; set CRs one at a time (faster) li r8,80 mtcrf 0x20,r11 li r9,96 mtcrf 0x08,r11 li r10,112 mtcrf 0x02,r11 bf 0,vr_st64b ; skip if none of vr0-vr7 are in use la r11,savevr0(r3) ; get address of this group of registers in save area dcbz128 0,r11 ; zero the line stvxl v0,0,r11 ; save 8 VRs in the line stvxl v1,r4,r11 stvxl v2,r5,r11 stvxl v3,r6,r11 stvxl v4,r7,r11 stvxl v5,r8,r11 stvxl v6,r9,r11 stvxl v7,r10,r11 vr_st64b: bf 8,vr_st64c ; skip if none of vr8-vr15 are in use la r11,savevr8(r3) ; get address of this group of registers in save area dcbz128 0,r11 ; zero the line stvxl v8,0,r11 ; save 8 VRs in the line stvxl v9,r4,r11 stvxl v10,r5,r11 stvxl v11,r6,r11 stvxl v12,r7,r11 stvxl v13,r8,r11 stvxl v14,r9,r11 stvxl v15,r10,r11 vr_st64c: bf 16,vr_st64d ; skip if none of vr16-vr23 are in use la r11,savevr16(r3) ; get address of this group of registers in save area dcbz128 0,r11 ; zero the line stvxl v16,0,r11 ; save 8 VRs in the line stvxl v17,r4,r11 stvxl v18,r5,r11 stvxl v19,r6,r11 stvxl v20,r7,r11 stvxl v21,r8,r11 stvxl v22,r9,r11 stvxl v23,r10,r11 vr_st64d: bflr 24 ; done if none of vr24-vr31 are in use la r11,savevr24(r3) ; get address of this group of registers in save area dcbz128 0,r11 ; zero the line stvxl v24,0,r11 ; save 8 VRs in the line stvxl v25,r4,r11 stvxl v26,r5,r11 stvxl v27,r6,r11 stvxl v28,r7,r11 stvxl v29,r8,r11 stvxl v30,r9,r11 stvxl v31,r10,r11 blr ; Save vectors on a 32-byte linesize processor. We save in 16 groups of 2: we either save both ; or neither in each group. This cuts down on conditional branches. ; r8 = bitmask with bit n set (for even n) if either of that pair of VRs is in use ; r3 = savearea vr_st32: mtcrf 0xFF,r8 ; set CR bits so we can branch on them li r4,16 ; load offset for X-form stores bf 0,vr_st32b ; skip if neither VR in this pair is in use la r11,savevr0(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v0,0,r11 ; save the two VRs in the line stvxl v1,r4,r11 vr_st32b: bf 2,vr_st32c ; skip if neither VR in this pair is in use la r11,savevr2(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v2,0,r11 ; save the two VRs in the line stvxl v3,r4,r11 vr_st32c: bf 4,vr_st32d ; skip if neither VR in this pair is in use la r11,savevr4(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v4,0,r11 ; save the two VRs in the line stvxl v5,r4,r11 vr_st32d: bf 6,vr_st32e ; skip if neither VR in this pair is in use la r11,savevr6(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v6,0,r11 ; save the two VRs in the line stvxl v7,r4,r11 vr_st32e: bf 8,vr_st32f ; skip if neither VR in this pair is in use la r11,savevr8(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v8,0,r11 ; save the two VRs in the line stvxl v9,r4,r11 vr_st32f: bf 10,vr_st32g ; skip if neither VR in this pair is in use la r11,savevr10(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v10,0,r11 ; save the two VRs in the line stvxl v11,r4,r11 vr_st32g: bf 12,vr_st32h ; skip if neither VR in this pair is in use la r11,savevr12(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v12,0,r11 ; save the two VRs in the line stvxl v13,r4,r11 vr_st32h: bf 14,vr_st32i ; skip if neither VR in this pair is in use la r11,savevr14(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v14,0,r11 ; save the two VRs in the line stvxl v15,r4,r11 vr_st32i: bf 16,vr_st32j ; skip if neither VR in this pair is in use la r11,savevr16(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v16,0,r11 ; save the two VRs in the line stvxl v17,r4,r11 vr_st32j: bf 18,vr_st32k ; skip if neither VR in this pair is in use la r11,savevr18(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v18,0,r11 ; save the two VRs in the line stvxl v19,r4,r11 vr_st32k: bf 20,vr_st32l ; skip if neither VR in this pair is in use la r11,savevr20(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v20,0,r11 ; save the two VRs in the line stvxl v21,r4,r11 vr_st32l: bf 22,vr_st32m ; skip if neither VR in this pair is in use la r11,savevr22(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v22,0,r11 ; save the two VRs in the line stvxl v23,r4,r11 vr_st32m: bf 24,vr_st32n ; skip if neither VR in this pair is in use la r11,savevr24(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v24,0,r11 ; save the two VRs in the line stvxl v25,r4,r11 vr_st32n: bf 26,vr_st32o ; skip if neither VR in this pair is in use la r11,savevr26(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v26,0,r11 ; save the two VRs in the line stvxl v27,r4,r11 vr_st32o: bf 28,vr_st32p ; skip if neither VR in this pair is in use la r11,savevr28(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v28,0,r11 ; save the two VRs in the line stvxl v29,r4,r11 vr_st32p: bflr 30 ; done if neither VR in this pair is in use la r11,savevr30(r3) ; get address of this group of registers in save area dcba 0,r11 ; establish the line wo reading it stvxl v30,0,r11 ; save the two VRs in the line stvxl v31,r4,r11 blr // ***************** // * v r _ l o a d * // ***************** // // Load live VRs from a savearea, according to bits set in a passed vector. This is the reverse // of "vr_store". Like it, we avoid touching unnecessary cache blocks and minimize conditional // branches by loading all VRs from a cache line, if we have to load any. If we don't load the VRs // in a cache line, we bug them. Note that this behavior is slightly different from earlier kernels, // which would bug all VRs that aren't live. // // When called: // interrupts are off, vectors are enabled // r3 = ptr to save area // r10 = vector of live regs to load (ie, savevrsave & savevrvalid, may be 0) // v31 = bugbug constant (0x7FFFDEAD7FFFDEAD7FFFDEAD7FFFDEAD) // // We destroy: // r4 - r11, all CRs. vr_load: mfsprg r9,2 ; get feature flags li r6,1 ; assuming 32-byte, get (#VRs)-1 in a cacheline mtcrf 0x02,r9 ; set cache line size bits in cr6 lis r7,0xC000 ; assuming 32-byte, set bits 0-1 bt-- pf32Byteb,vr_ld0 ; skip if 32-bit processor li r6,7 ; 128-byte machines have 8 VRs in a cacheline lis r7,0xFF00 ; so set bits 0-7 // Loop touching in cache blocks we will load from. // r3 = savearea ptr // r5 = we light bits for the VRs we will be loading // r6 = 1 if 32-byte, 7 if 128-byte // r7 = 0xC0000000 if 32-byte, 0xFF000000 if 128-byte // r10 = live VR bits // v31 = bugbug constant vr_ld0: li r5,0 ; initialize set of VRs to load la r11,savevr0(r3) ; get address of register file b vr_ld2 ; enter loop in middle .align 5 vr_ld1: ; loop over each cache line we will load dcbt r4,r11 ; start prefetch of the line andc r10,r10,r9 ; turn off the bits in this line or r5,r5,r9 ; we will load all these vr_ld2: ; initial entry pt cntlzw r4,r10 ; get offset to next live VR andc r4,r4,r6 ; cacheline align it srw. r9,r7,r4 ; position bits for VRs in that cache line slwi r4,r4,4 ; get byte offset within register file to that line bne vr_ld1 ; loop if more bits in r10 bf-- pf128Byteb,vr_ld32 ; skip if not 128-byte lines // Handle a processor with 128-byte cache lines. Four groups of 8 VRs. // r3 = savearea ptr // r5 = 1st bit in each cacheline is 1 iff any reg in that line must be loaded // r11 = addr(savevr0) // v31 = bugbug constant mtcrf 0x80,r5 ; set up bits for conditional branches li r4,16 ; load offsets for X-form stores li r6,48 mtcrf 0x20,r5 ; load CRs ona at a time, which is faster li r7,64 li r8,80 mtcrf 0x08,r5 li r9,96 li r10,112 mtcrf 0x02,r5 li r5,32 bt 0,vr_ld128a ; skip if this line must be loaded vor v0,v31,v31 ; no VR must be loaded, so bug them all vor v1,v31,v31 vor v2,v31,v31 vor v3,v31,v31 vor v4,v31,v31 vor v5,v31,v31 vor v6,v31,v31 vor v7,v31,v31 b vr_ld128b vr_ld128a: ; must load from this line lvxl v0,0,r11 lvxl v1,r4,r11 lvxl v2,r5,r11 lvxl v3,r6,r11 lvxl v4,r7,r11 lvxl v5,r8,r11 lvxl v6,r9,r11 lvxl v7,r10,r11 vr_ld128b: ; here to handle next cache line la r11,savevr8(r3) ; load offset to it bt 8,vr_ld128c ; skip if this line must be loaded vor v8,v31,v31 ; no VR must be loaded, so bug them all vor v9,v31,v31 vor v10,v31,v31 vor v11,v31,v31 vor v12,v31,v31 vor v13,v31,v31 vor v14,v31,v31 vor v15,v31,v31 b vr_ld128d vr_ld128c: ; must load from this line lvxl v8,0,r11 lvxl v9,r4,r11 lvxl v10,r5,r11 lvxl v11,r6,r11 lvxl v12,r7,r11 lvxl v13,r8,r11 lvxl v14,r9,r11 lvxl v15,r10,r11 vr_ld128d: ; here to handle next cache line la r11,savevr16(r3) ; load offset to it bt 16,vr_ld128e ; skip if this line must be loaded vor v16,v31,v31 ; no VR must be loaded, so bug them all vor v17,v31,v31 vor v18,v31,v31 vor v19,v31,v31 vor v20,v31,v31 vor v21,v31,v31 vor v22,v31,v31 vor v23,v31,v31 b vr_ld128f vr_ld128e: ; must load from this line lvxl v16,0,r11 lvxl v17,r4,r11 lvxl v18,r5,r11 lvxl v19,r6,r11 lvxl v20,r7,r11 lvxl v21,r8,r11 lvxl v22,r9,r11 lvxl v23,r10,r11 vr_ld128f: ; here to handle next cache line la r11,savevr24(r3) ; load offset to it bt 24,vr_ld128g ; skip if this line must be loaded vor v24,v31,v31 ; no VR must be loaded, so bug them all vor v25,v31,v31 vor v26,v31,v31 vor v27,v31,v31 vor v28,v31,v31 vor v29,v31,v31 vor v30,v31,v31 blr vr_ld128g: ; must load from this line lvxl v24,0,r11 lvxl v25,r4,r11 lvxl v26,r5,r11 lvxl v27,r6,r11 lvxl v28,r7,r11 lvxl v29,r8,r11 lvxl v30,r9,r11 lvxl v31,r10,r11 blr // Handle a processor with 32-byte cache lines. Sixteen groups of two VRs. // r5 = 1st bit in each cacheline is 1 iff any reg in that line must be loaded // r11 = addr(savevr0) vr_ld32: mtcrf 0xFF,r5 ; set up bits for conditional branches li r4,16 ; load offset for X-form stores bt 0,vr_ld32load0 ; skip if we must load this line vor v0,v31,v31 ; neither VR is live, so bug them both vor v1,v31,v31 b vr_ld32test2 vr_ld32load0: ; must load VRs in this line lvxl v0,0,r11 lvxl v1,r4,r11 vr_ld32test2: ; here to handle next cache line la r11,savevr2(r3) ; get offset to next cache line bt 2,vr_ld32load2 ; skip if we must load this line vor v2,v31,v31 ; neither VR is live, so bug them both vor v3,v31,v31 b vr_ld32test4 vr_ld32load2: ; must load VRs in this line lvxl v2,0,r11 lvxl v3,r4,r11 vr_ld32test4: ; here to handle next cache line la r11,savevr4(r3) ; get offset to next cache line bt 4,vr_ld32load4 ; skip if we must load this line vor v4,v31,v31 ; neither VR is live, so bug them both vor v5,v31,v31 b vr_ld32test6 vr_ld32load4: ; must load VRs in this line lvxl v4,0,r11 lvxl v5,r4,r11 vr_ld32test6: ; here to handle next cache line la r11,savevr6(r3) ; get offset to next cache line bt 6,vr_ld32load6 ; skip if we must load this line vor v6,v31,v31 ; neither VR is live, so bug them both vor v7,v31,v31 b vr_ld32test8 vr_ld32load6: ; must load VRs in this line lvxl v6,0,r11 lvxl v7,r4,r11 vr_ld32test8: ; here to handle next cache line la r11,savevr8(r3) ; get offset to next cache line bt 8,vr_ld32load8 ; skip if we must load this line vor v8,v31,v31 ; neither VR is live, so bug them both vor v9,v31,v31 b vr_ld32test10 vr_ld32load8: ; must load VRs in this line lvxl v8,0,r11 lvxl v9,r4,r11 vr_ld32test10: ; here to handle next cache line la r11,savevr10(r3) ; get offset to next cache line bt 10,vr_ld32load10 ; skip if we must load this line vor v10,v31,v31 ; neither VR is live, so bug them both vor v11,v31,v31 b vr_ld32test12 vr_ld32load10: ; must load VRs in this line lvxl v10,0,r11 lvxl v11,r4,r11 vr_ld32test12: ; here to handle next cache line la r11,savevr12(r3) ; get offset to next cache line bt 12,vr_ld32load12 ; skip if we must load this line vor v12,v31,v31 ; neither VR is live, so bug them both vor v13,v31,v31 b vr_ld32test14 vr_ld32load12: ; must load VRs in this line lvxl v12,0,r11 lvxl v13,r4,r11 vr_ld32test14: ; here to handle next cache line la r11,savevr14(r3) ; get offset to next cache line bt 14,vr_ld32load14 ; skip if we must load this line vor v14,v31,v31 ; neither VR is live, so bug them both vor v15,v31,v31 b vr_ld32test16 vr_ld32load14: ; must load VRs in this line lvxl v14,0,r11 lvxl v15,r4,r11 vr_ld32test16: ; here to handle next cache line la r11,savevr16(r3) ; get offset to next cache line bt 16,vr_ld32load16 ; skip if we must load this line vor v16,v31,v31 ; neither VR is live, so bug them both vor v17,v31,v31 b vr_ld32test18 vr_ld32load16: ; must load VRs in this line lvxl v16,0,r11 lvxl v17,r4,r11 vr_ld32test18: ; here to handle next cache line la r11,savevr18(r3) ; get offset to next cache line bt 18,vr_ld32load18 ; skip if we must load this line vor v18,v31,v31 ; neither VR is live, so bug them both vor v19,v31,v31 b vr_ld32test20 vr_ld32load18: ; must load VRs in this line lvxl v18,0,r11 lvxl v19,r4,r11 vr_ld32test20: ; here to handle next cache line la r11,savevr20(r3) ; get offset to next cache line bt 20,vr_ld32load20 ; skip if we must load this line vor v20,v31,v31 ; neither VR is live, so bug them both vor v21,v31,v31 b vr_ld32test22 vr_ld32load20: ; must load VRs in this line lvxl v20,0,r11 lvxl v21,r4,r11 vr_ld32test22: ; here to handle next cache line la r11,savevr22(r3) ; get offset to next cache line bt 22,vr_ld32load22 ; skip if we must load this line vor v22,v31,v31 ; neither VR is live, so bug them both vor v23,v31,v31 b vr_ld32test24 vr_ld32load22: ; must load VRs in this line lvxl v22,0,r11 lvxl v23,r4,r11 vr_ld32test24: ; here to handle next cache line la r11,savevr24(r3) ; get offset to next cache line bt 24,vr_ld32load24 ; skip if we must load this line vor v24,v31,v31 ; neither VR is live, so bug them both vor v25,v31,v31 b vr_ld32test26 vr_ld32load24: ; must load VRs in this line lvxl v24,0,r11 lvxl v25,r4,r11 vr_ld32test26: ; here to handle next cache line la r11,savevr26(r3) ; get offset to next cache line bt 26,vr_ld32load26 ; skip if we must load this line vor v26,v31,v31 ; neither VR is live, so bug them both vor v27,v31,v31 b vr_ld32test28 vr_ld32load26: ; must load VRs in this line lvxl v26,0,r11 lvxl v27,r4,r11 vr_ld32test28: ; here to handle next cache line la r11,savevr28(r3) ; get offset to next cache line bt 28,vr_ld32load28 ; skip if we must load this line vor v28,v31,v31 ; neither VR is live, so bug them both vor v29,v31,v31 b vr_ld32test30 vr_ld32load28: ; must load VRs in this line lvxl v28,0,r11 lvxl v29,r4,r11 vr_ld32test30: ; here to handle next cache line la r11,savevr30(r3) ; get offset to next cache line bt 30,vr_ld32load30 ; skip if we must load this line vor v30,v31,v31 ; neither VR is live, so bug them both blr vr_ld32load30: ; must load VRs in this line lvxl v30,0,r11 lvxl v31,r4,r11 blr