/* * Copyright (c) 2000-2005 Apple Computer, Inc. All rights reserved. * * @APPLE_OSREFERENCE_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. The rights granted to you under the License * may not be used to create, or enable the creation or redistribution of, * unlawful or unlicensed copies of an Apple operating system, or to * circumvent, violate, or enable the circumvention or violation of, any * terms of an Apple operating system software license agreement. * * 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_OSREFERENCE_LICENSE_HEADER_END@ */ #include #include #include #include #include /* * This file contains implementations for the Virtual Machine Monitor * facility. */ #define vmmMapDone 31 #define vmmDoing64 30 /* * int vmm_dispatch(savearea, act); * vmm_dispatch is a PPC only system call. It is used with a selector (first * parameter) to determine what function to enter. This is treated as an extension * of hw_exceptions. * * Inputs: * R4 = current activation * R16 = current thread * R30 = current savearea */ .align 5 ; Line up on cache line .globl EXT(vmm_dispatch_table) LEXT(vmm_dispatch_table) /* Don't change the order of these routines in the table. It's */ /* OK to add new routines, but they must be added at the bottom. */ .long EXT(vmm_get_version_sel) ; Get the version of the VMM interface .long 0 ; Not valid in Fam .long EXT(vmm_get_features_sel) ; Get the features of the VMM interface .long 0 ; Not valid in Fam .long EXT(vmm_init_context_sel) ; Initializes a new VMM context .long 0 ; Not valid in Fam .long EXT(vmm_tear_down_context) ; Tears down a previously-allocated VMM context .long 0 ; Not valid in Fam .long EXT(vmm_tear_down_all) ; Tears down all VMMs .long 0 ; Not valid in Fam .long EXT(vmm_map_page32) ; Maps a page from the main address space into the VM space - supports 32-bit .long 1 ; Valid in Fam .long EXT(vmm_get_page_mapping32) ; Returns client va associated with VM va - supports 32-bit .long 1 ; Valid in Fam .long EXT(vmm_unmap_page32) ; Unmaps a page from the VM space - supports 32-bit .long 1 ; Valid in Fam .long EXT(vmm_unmap_all_pages) ; Unmaps all pages from the VM space .long 1 ; Valid in Fam .long EXT(vmm_get_page_dirty_flag32) ; Gets the change bit for a page and optionally clears it - supports 32-bit .long 1 ; Valid in Fam .long EXT(vmm_get_float_state) ; Gets current floating point state .long 0 ; not valid in Fam .long EXT(vmm_get_vector_state) ; Gets current vector state .long 0 ; Not valid in Fam .long EXT(vmm_set_timer) ; Sets a timer value .long 1 ; Valid in Fam .long EXT(vmm_get_timer) ; Gets a timer value .long 1 ; Valid in Fam .long EXT(switchIntoVM) ; Switches to the VM context .long 1 ; Valid in Fam .long EXT(vmm_protect_page32) ; Sets protection values for a page - supports 32-bit .long 1 ; Valid in Fam .long EXT(vmm_map_execute32) ; Maps a page an launches VM - supports 32-bit .long 1 ; Not valid in Fam .long EXT(vmm_protect_execute32) ; Sets protection values for a page and launches VM - supports 32-bit .long 1 ; Valid in Fam .long EXT(vmm_map_list32) ; Maps a list of pages - supports 32-bit .long 1 ; Valid in Fam .long EXT(vmm_unmap_list32) ; Unmaps a list of pages - supports 32-bit .long 1 ; Valid in Fam .long EXT(vmm_fam_reserved) ; exit from Fam to host .long 1 ; Valid in Fam .long EXT(vmm_fam_reserved) ; resume guest from Fam .long 1 ; Valid in Fam .long EXT(vmm_fam_reserved) ; get guest register from Fam .long 1 ; Valid in Fam .long EXT(vmm_fam_reserved) ; Set guest register from Fam .long 1 ; Valid in Fam .long EXT(vmm_activate_XA) ; Activate extended architecture features for a VM .long 0 ; Not valid in Fam .long EXT(vmm_deactivate_XA) ; Deactivate extended architecture features for a VM .long 0 ; Not valid in Fam .long EXT(vmm_get_XA) ; Get extended architecture features from a VM .long 1 ; Valid in Fam .long EXT(vmm_map_page) ; Map a host to guest address space - supports 64-bit .long 1 ; Valid in Fam .long EXT(vmm_get_page_mapping) ; Get host address of a guest page - supports 64-bit .long 1 ; Valid in Fam .long EXT(vmm_unmap_page) ; Unmap a guest page - supports 64-bit .long 1 ; Valid in Fam .long EXT(vmm_get_page_dirty_flag) ; Check if guest page modified - supports 64-bit .long 1 ; Valid in Fam .long EXT(vmm_protect_page) ; Sets protection values for a page - supports 64-bit .long 1 ; Valid in Fam .long EXT(vmm_map_execute) ; Map guest page and launch - supports 64-bit .long 1 ; Valid in Fam .long EXT(vmm_protect_execute) ; Set prot attributes and launch - supports 64-bit .long 1 ; Valid in Fam .long EXT(vmm_map_list64) ; Map a list of pages into guest address spaces - supports 64-bit .long 1 ; Valid in Fam .long EXT(vmm_unmap_list64) ; Unmap a list of pages from guest address spaces - supports 64-bit .long 1 ; Valid in Fam .long EXT(vmm_max_addr) ; Returns the maximum virtual address .long 1 ; Valid in Fam #if 0 .long EXT(vmm_set_guest_memory) ; Set guest memory extent .long 0 ; Not valid in FAM .long EXT(vmm_purge_local) ; Purge all local guest mappings */ .long 1 ; Valid in FAM #endif .set vmm_count,(.-EXT(vmm_dispatch_table))/8 ; Get the top number .align 5 .globl EXT(vmm_dispatch) LEXT(vmm_dispatch) lwz r11,saver3+4(r30) ; Get the selector mr r3,r4 ; All of our functions want the activation as the first parm lis r10,hi16(EXT(vmm_dispatch_table)) ; Get top half of table cmplwi r11,kVmmExecuteVM ; Should we switch to the VM now? cmplwi cr1,r11,vmm_count ; See if we have a valid selector ori r10,r10,lo16(EXT(vmm_dispatch_table)) ; Get low half of table lwz r4,saver4+4(r30) ; Get 1st parameter after selector beq+ EXT(switchIntoVM) ; Yes, go switch to it.... rlwinm r11,r11,3,0,28 ; Index into table bge- cr1,vmmBogus ; It is a bogus entry add r12,r10,r11 ; Get the vmm dispatch syscall entry mfsprg r10,1 ; Get the current activation lwz r10,ACT_PER_PROC(r10) ; Get the per_proc block lwz r13,0(r12) ; Get address of routine lwz r12,4(r12) ; Get validity flag lwz r5,spcFlags(r10) ; Get per_proc special flags cmpwi cr1,r12,0 ; Check Fam valid rlwinm. r5,r5,0,FamVMmodebit,FamVMmodebit ; Test FamVMmodebit crand cr0_eq,cr1_eq,cr0_gt ; In Fam and Invalid syscall beq vmmBogus ; Intercept to host lwz r5,saver5+4(r30) ; Get 2nd parameter after selector - note that some of these parameters may actually be long longs lwz r6,saver6+4(r30) ; Get 3rd parameter after selector mtlr r13 ; Set the routine address lwz r7,saver7+4(r30) ; Get 4th parameter after selector lwz r8,saver8+4(r30) ; Get 5th parameter after selector lwz r9,saver9+4(r30) ; Get 6th parameter after selector ; ; NOTE: some of the above parameters are actually long longs. We have glue code that transforms ; all needed parameters and/or adds 32-/64-bit flavors to the needed functions. ; blrl ; Call function vmmRetPt: li r0,0 ; Clear this out stw r0,saver3(r30) ; Make sure top of RC is clear stw r3,saver3+4(r30) ; Pass back the return code stw r0,saver4(r30) ; Make sure bottom of RC is clear (just in case) stw r4,saver4+4(r30) ; Pass back the bottom return code (just in case) li r3,1 ; Set normal return with check for AST b EXT(ppcscret) ; Go back to handler... vmmBogus: mfsprg r3,1 ; Get the current activation lwz r10,ACT_PER_PROC(r3) ; Get the per_proc block lwz r5,spcFlags(r10) ; Get per_proc special flags rlwinm. r5,r5,0,FamVMmodebit,FamVMmodebit ; Test FamVMmodebit bne vmmexitcall ; Do it to it li r3,0 ; Bogus selector, treat like a bogus system call b EXT(ppcscret) ; Go back to handler... .align 5 .globl EXT(vmm_get_version_sel) LEXT(vmm_get_version_sel) ; Selector based version of get version lis r3,hi16(EXT(vmm_get_version)) ori r3,r3,lo16(EXT(vmm_get_version)) b selcomm .align 5 .globl EXT(vmm_get_features_sel) LEXT(vmm_get_features_sel) ; Selector based version of get features lis r3,hi16(EXT(vmm_get_features)) ori r3,r3,lo16(EXT(vmm_get_features)) b selcomm .align 5 .globl EXT(vmm_init_context_sel) LEXT(vmm_init_context_sel) ; Selector based version of init context lwz r4,saver4+4(r30) ; Get the passed in version lwz r5,saver5+4(r30) ; Get the passed in comm area lis r3,hi16(EXT(vmm_init_context)) stw r4,saver3+4(r30) ; Cheat and move this parameter over ori r3,r3,lo16(EXT(vmm_init_context)) stw r5,saver4+4(r30) ; Cheat and move this parameter over selcomm: mtlr r3 ; Set the real routine address mr r3,r30 ; Pass in the savearea blrl ; Call the function b EXT(ppcscret) ; Go back to handler... .align 5 .globl EXT(vmm_map_page32) LEXT(vmm_map_page32) mr r9,r7 ; Move prot to correct parm mr r8,r6 ; Move guest address to low half of long long li r7,0 ; Clear high half of guest address mr r6,r5 ; Move host address to low half of long long li r5,0 ; Clear high half of host address b EXT(vmm_map_page) ; Transition to real function... .align 5 .globl EXT(vmm_get_page_mapping32) LEXT(vmm_get_page_mapping32) mr r6,r5 ; Move guest address to low half of long long li r5,0 ; Clear high half of guest address bl EXT(vmm_get_page_mapping) ; Transition to real function... mr r3,r4 ; Convert addr64_t to vm_offset_t, dropping top half b vmmRetPt ; Join normal return... .align 5 .globl EXT(vmm_unmap_page32) LEXT(vmm_unmap_page32) mr r6,r5 ; Move guest address to low half of long long li r5,0 ; Clear high half of guest address b EXT(vmm_unmap_page) ; Transition to real function... .align 5 .globl EXT(vmm_get_page_dirty_flag32) LEXT(vmm_get_page_dirty_flag32) mr r7,r6 ; Move reset flag mr r6,r5 ; Move guest address to low half of long long li r5,0 ; Clear high half of guest address b EXT(vmm_get_page_dirty_flag) ; Transition to real function... .align 5 .globl EXT(vmm_protect_page32) LEXT(vmm_protect_page32) mr r7,r6 ; Move protection bits mr r6,r5 ; Move guest address to low half of long long li r5,0 ; Clear high half of guest address b EXT(vmm_protect_page) ; Transition to real function... .align 5 .globl EXT(vmm_map_execute32) LEXT(vmm_map_execute32) mr r9,r7 ; Move prot to correct parm mr r8,r6 ; Move guest address to low half of long long li r7,0 ; Clear high half of guest address mr r6,r5 ; Move host address to low half of long long li r5,0 ; Clear high half of host address b EXT(vmm_map_execute) ; Transition to real function... .align 5 .globl EXT(vmm_protect_execute32) LEXT(vmm_protect_execute32) mr r7,r6 ; Move protection bits mr r6,r5 ; Move guest address to low half of long long li r5,0 ; Clear high half of guest address b EXT(vmm_protect_execute) ; Transition to real function... .align 5 .globl EXT(vmm_map_list32) LEXT(vmm_map_list32) li r6,0 ; Set 32-bit flavor b EXT(vmm_map_list) ; Go to common routine... .align 5 .globl EXT(vmm_map_list64) LEXT(vmm_map_list64) li r6,1 ; Set 64-bit flavor b EXT(vmm_map_list) ; Go to common routine... .align 5 .globl EXT(vmm_map_list32) LEXT(vmm_unmap_list32) li r6,0 ; Set 32-bit flavor b EXT(vmm_unmap_list) ; Go to common routine... .align 5 .globl EXT(vmm_map_list64) LEXT(vmm_unmap_list64) li r6,1 ; Set 64-bit flavor b EXT(vmm_unmap_list) ; Go to common routine... /* * Here is where we transition to the virtual machine. * * We will swap the register context in the savearea with that which is saved in our shared * context area. We will validity check a bit and clear any nasty bits in the MSR and force * the manditory ones on. * * Then we will setup the new address space to run with, and anything else that is normally part * of a context switch. * * The vmm_execute_vm entry point is for the fused vmm_map_execute and vmm_protect_execute * calls. This is called, but never returned from. We always go directly back to the * user from here. * * */ .align 5 .globl EXT(vmm_execute_vm) LEXT(vmm_execute_vm) lwz r30,ACT_MACT_PCB(r3) ; Restore the savearea pointer because it could be trash here b EXT(switchIntoVM) ; Join common... .align 5 .globl EXT(switchIntoVM) LEXT(switchIntoVM) mfsprg r10,1 ; Get the current activation lwz r10,ACT_PER_PROC(r10) ; Get the per_proc block rlwinm r31,r4,24,24,31 ; Get the address space rlwinm r4,r4,0,24,31 ; Isolate the context id lwz r28,vmmControl(r3) ; Pick up the control table address subi r4,r4,1 ; Switch to zero offset rlwinm. r2,r28,0,0,30 ; Is there a context there? (Note: we will ignore bit 31 so that we ; do not try this while we are transitioning off to on cmplwi cr1,r4,kVmmMaxContexts ; Is the index valid? beq- vmmBogus ; Not started, treat like a bogus system call subic. r31,r31,1 ; Make address space 0 based and test if we use default mulli r2,r4,vmmCEntrySize ; Get displacement from index bge- cr1,swvmmBogus ; Index is bogus... add r2,r2,r28 ; Point to the entry bge-- swvmmDAdsp ; There was an explicit address space request mr r31,r4 ; Default the address space to the context ID swvmmDAdsp: la r2,vmmc(r2) ; Get the offset to the context array lwz r8,vmmGFlags(r28) ; Get the general flags lwz r4,vmmFlags(r2) ; Get the flags for the selected entry crset vmmMapDone ; Assume we will be mapping something lwz r5,vmmContextKern(r2) ; Get the context area address rlwinm. r26,r4,0,vmmInUseb,vmmInUseb ; See if the slot is in use cmplwi cr1,r31,kVmmMaxContexts ; See if we have a valid address space ID rlwinm r8,r8,0,24,31 ; Clean up address space beq-- swvmmBogus ; This context is no good... la r26,vmmAdsp(r28) ; Point to the pmaps sub r8,r8,r31 ; Get diff between launching address space - 1 and last mapped into (should be 1 if the same) rlwinm r31,r31,2,0,29 ; Index to the pmap cmplwi r8,1 ; See if we have the same address space bge-- cr1,swvmmBogAdsp ; Address space is no good... lwzx r31,r26,r31 ; Get the requested address space pmap li r0,0 ; Get a 0 in case we need to trash redrive lwz r15,spcFlags(r10) ; Get per_proc special flags beq swvmmAdspOk ; Do not invalidate address space if we are launching the same crclr vmmMapDone ; Clear map done flag stb r0,vmmGFlags+3(r28) ; Clear the last mapped address space ID so we will not redrive later ; ; Here we check for any immediate intercepts. So far, the only ; two of these are a timer pop and and external stop. We will not dispatch if ; either is true. They need to either reset the timer (i.e. set timer ; to 0) or to set a future time, or if it is external stop, set the vmmXStopRst flag. ; swvmmAdspOk: rlwinm. r0,r15,0,FamVMmodebit,FamVMmodebit ; Test FamVMmodebit stw r31,vmmPmap(r2) ; Save the last dispatched address space bne vmmFamGuestResume lwz r6,vmmCntrl(r5) ; Get the control field rlwinm. r7,r6,0,vmmXStartb,vmmXStartb ; Clear all but start bit beq+ swvmChkStop ; Do not reset stop andc r6,r6,r7 ; Clear it li r8,vmmFlags ; Point to the flags stw r6,vmmCntrl(r5) ; Set the control field swvmtryx: lwarx r4,r8,r2 ; Pick up the flags rlwinm r4,r4,0,vmmXStopb+1,vmmXStopb-1 ; Clear the stop bit stwcx. r4,r8,r2 ; Save the updated field bne- swvmtryx ; Try again... swvmChkStop: rlwinm. r26,r4,0,vmmXStopb,vmmXStopb ; Is this VM stopped? bne-- swvmSetStop ; Yes... rlwinm. r26,r4,0,vmmTimerPopb,vmmTimerPopb ; Did the timer go pop? cmplwi cr1,r31,0 ; Is there actually an address space defined? bne-- svvmTimerPop ; Yes... ; ; Special note: we need to intercept any attempt to launch a guest into a non-existent address space. ; We will just go emulate an ISI if there is not one. ; beq-- cr1,swvmEmulateISI ; We are trying to launch into an undefined address space. This is not so good... ; ; Here is where we actually swap into the VM (alternate) context. ; We will bulk do a wholesale swap of the registers in the context area (the VMs) ; with the ones in the savearea (our main code). During the copy, we will fix up the ; MSR, forcing on a few bits and turning off a few others. Then we will deal with the ; PMAP and other per_proc stuff. Finally, we will exit back through the main exception ; handler to deal with unstacking saveareas and ASTs, etc. ; swvmDoSwitch: ; ; First, we save the volatile registers we care about. Remember, all register ; handling here is pretty funky anyway, so we just pick the ones that are ok. ; mr r26,r3 ; Save the activation pointer la r11,vmmFacCtx(r2) ; Point to the virtual machine facility context mr r27,r2 ; Save the context entry stw r11,deferctx(r3) ; Start using the virtual machine facility context when we exit lwz r11,ACT_MACT_SPF(r26) ; Get the special flags mr r3,r31 ; Get the pointer to the PMAP oris r15,r11,hi16(runningVM) ; ; Show that we are swapped to the VM right now bl EXT(hw_set_user_space_dis) ; Swap the address spaces lwz r17,vmmFlags(r27) ; Get the status flags lwz r20,vmmContextKern(r27) ; Get the state page kernel addr lwz r21,vmmCntrl(r20) ; Get vmmCntrl rlwinm. r22,r21,0,vmmFamEnab,vmmFamEnab ; Is vmmFamEnab set? lwz r22,vmmXAFlgs(r27) ; Get the eXtended Architecture flags stw r22,VMMXAFlgs(r10) ; Store vmmXAFlgs in per_proc VMMXAFlgs beq swvmNoFam ; No Fam intercept rlwinm. r22,r22,0,0,0 ; Are we doing a 64-bit virtual machine? rlwimi r15,r21,32+vmmFamSetb-FamVMmodebit,FamVMmodebit,FamVMmodebit ; Set FamVMmode bit rlwinm r21,r21,0,vmmFamSetb+1,vmmFamSetb-1 ; Clear FamSet bit bne swvmXfamintercpt lwz r22,famintercepts(r20) ; Load intercept bit field b swvmfamintercptres swvmXfamintercpt: lwz r22,faminterceptsX(r20) ; Load intercept bit field swvmfamintercptres: stw r21,vmmCntrl(r20) ; Update vmmCntrl lwz r19,vmmContextPhys(r27) ; Get vmmFAMarea address stw r22,vmmFAMintercept(r27) ; Get vmmFAMintercept stw r22,FAMintercept(r10) ; Store vmmFAMintercept in per_proc FAMintercept stw r19,VMMareaPhys(r10) ; Store VMMareaPhys oris r15,r15,hi16(FamVMena) ; Set FamVMenabit swvmNoFam: stw r27,vmmCEntry(r26) ; Remember what context we are running bf++ vmmMapDone,swvmNoMap ; We have not mapped anything or it was not for this address space ; ; This little bit of hoopala here (triggered by vmmMapDone) is ; a performance enhancement. This will change the returning savearea ; to look like we had a DSI rather than a system call. Then, setting ; the redrive bit, the exception handler will redrive the exception as ; a DSI, entering the last mapped address into the hash table. This keeps ; double faults from happening. Note that there is only a gain if the VM ; takes a fault, then the emulator resolves it only, and then begins ; the VM execution again. It seems like this should be the normal case. ; ; Note that we need to revisit this when we move the virtual machines to the task because ; then it will be possible for more than one thread to access this stuff at the same time. ; lwz r3,SAVflags(r30) ; Pick up the savearea flags lwz r2,vmmLastMap(r28) ; Get the last mapped address lwz r14,vmmLastMap+4(r28) ; Get the last mapped address low half li r20,T_DATA_ACCESS ; Change to DSI fault oris r3,r3,hi16(SAVredrive) ; Set exception redrive stw r2,savedar(r30) ; Set the DAR to the last thing we mapped stw r14,savedar+4(r30) ; Set the DAR to the last thing we mapped stw r3,SAVflags(r30) ; Turn on the redrive request lis r2,hi16(MASK(DSISR_HASH)) ; Set PTE/DBAT miss li r0,0 ; Clear stw r20,saveexception(r30) ; Say we need to emulate a DSI stw r2,savedsisr(r30) ; Pretend we have a PTE miss stb r0,vmmGFlags+3(r28) ; Show that the redrive has been taken care of swvmNoMap: lwz r20,vmmContextKern(r27) ; Get the comm area rlwimi r15,r17,32-(floatCngbit-vmmFloatCngdb),floatCngbit,vectorCngbit ; Shift and insert changed bits lwz r20,vmmCntrl(r20) ; Get the control flags rlwimi r17,r11,8,24,31 ; Save the old spf flags rlwimi r15,r20,32+vmmKeyb-userProtKeybit,userProtKeybit,userProtKeybit ; Set the protection key stw r15,spcFlags(r10) ; Set per_proc copy of the special flags stw r15,ACT_MACT_SPF(r26) ; Get the special flags stw r17,vmmFlags(r27) ; Set the status flags bl swapCtxt ; First, swap the general register state lwz r17,vmmContextKern(r27) ; Get the comm area back la r25,vmmFacCtx(r27) ; Point to the facility context lwz r15,vmmCntrl(r17) ; Get the control flags again mfsprg r29,1 ; Get the current activation lwz r29,ACT_PER_PROC(r29) ; Get the per_proc block ; ; Check if there is new floating point context to load ; rlwinm. r0,r15,0,vmmFloatLoadb,vmmFloatLoadb ; Are there new floating point values? lhz r29,PP_CPU_NUMBER(r29) ; Get our cpu number li r14,vmmppcFPRs ; Get displacement to the new values andc r15,r15,r0 ; Clear the bit beq+ swvmNoNewFloats ; Nope, good... lwz r19,FPUcpu(r25) ; Get the last CPU we ran on stw r29,FPUcpu(r25) ; Claim the context for ourselves eieio ; Make sure this stays in order 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 swvminvfpu: lwarx r18,r16,r19 ; Get the owner sub r0,r18,r25 ; Subtract one from the other sub r3,r25,r18 ; Subtract the other from the one or r3,r3,r0 ; Combine them srawi r3,r3,31 ; Get a 0 if equal or -1 of not and r18,r18,r3 ; Make 0 if same, unchanged if not stwcx. r18,r16,r19 ; Try to invalidate it bne-- swvminvfpu ; Try again if there was a collision... lwz r3,FPUsave(r25) ; Get the FPU savearea dcbt r14,r17 ; Touch in first line of new stuff mr. r3,r3 ; Is there one? bne+ swvmGotFloat ; Yes... bl EXT(save_get) ; Get a savearea li r7,SAVfloat ; Get floating point flag stw r26,SAVact(r3) ; Save our activation li r0,0 ; Get a zero stb r7,SAVflags+2(r3) ; Set that this is floating point stw r0,SAVprev+4(r3) ; Clear the back chain stw r0,SAVlevel(r3) ; We are always at level 0 (user state) stw r3,FPUsave(r25) ; Chain us to context swvmGotFloat: la r4,savefp0(r3) ; Point to the destination mr r21,r3 ; Save the save area la r3,vmmppcFPRs(r17) ; Point to the source li r5,32*8 ; Get the size (32 FPRs at 8 bytes each) bl EXT(bcopy) ; Copy the new values lwz r11,ACT_MACT_SPF(r26) ; Get the special flags stw r15,vmmCntrl(r17) ; Save the control flags sans vmmFloatLoad rlwinm r11,r11,0,floatCngbit+1,floatCngbit-1 ; Clear the changed bit here lwz r14,vmmStat(r17) ; Get the status flags mfsprg r10,1 ; Get the current activation lwz r10,ACT_PER_PROC(r10) ; Get the per_proc block stw r11,ACT_MACT_SPF(r26) ; Get the special flags rlwinm r14,r14,0,vmmFloatCngdb+1,vmmFloatCngdb-1 ; Clear the changed flag stw r11,spcFlags(r10) ; Set per_proc copy of the special flags stw r14,vmmStat(r17) ; Set the status flags sans vmmFloatCngd ; ; Check if there is new vector context to load ; swvmNoNewFloats: rlwinm. r0,r15,0,vmmVectLoadb,vmmVectLoadb ; Are there new vector values? li r14,vmmppcVRs ; Get displacement to the new values andc r15,r15,r0 ; Clear the bit beq+ swvmNoNewVects ; Nope, good... lwz r19,VMXcpu(r25) ; Get the last CPU we ran on stw r29,VMXcpu(r25) ; Claim the context for ourselves eieio ; Make sure this stays in order 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,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 swvminvvec: lwarx r18,r16,r19 ; Get the owner sub r0,r18,r25 ; Subtract one from the other sub r3,r25,r18 ; Subtract the other from the one or r3,r3,r0 ; Combine them srawi r3,r3,31 ; Get a 0 if equal or -1 of not and r18,r18,r3 ; Make 0 if same, unchanged if not stwcx. r18,r16,r19 ; Try to invalidate it bne-- swvminvfpu ; Try again if there was a collision... swvminvved: lwz r3,VMXsave(r25) ; Get the vector savearea dcbt r14,r17 ; Touch in first line of new stuff mr. r3,r3 ; Is there one? bne+ swvmGotVect ; Yes... bl EXT(save_get) ; Get a savearea li r7,SAVvector ; Get the vector type flag stw r26,SAVact(r3) ; Save our activation li r0,0 ; Get a zero stb r7,SAVflags+2(r3) ; Set that this is vector stw r0,SAVprev+4(r3) ; Clear the back chain stw r0,SAVlevel(r3) ; We are always at level 0 (user state) stw r3,VMXsave(r25) ; Chain us to context swvmGotVect: mr r21,r3 ; Save the pointer to the savearea la r4,savevr0(r3) ; Point to the destination la r3,vmmppcVRs(r17) ; Point to the source li r5,32*16 ; Get the size (32 vectors at 16 bytes each) bl EXT(bcopy) ; Copy the new values lwz r8,savevrsave(r30) ; Get the current VRSave lwz r11,ACT_MACT_SPF(r26) ; Get the special flags stw r15,vmmCntrl(r17) ; Save the control flags sans vmmVectLoad rlwinm r11,r11,0,vectorCngbit+1,vectorCngbit-1 ; Clear the changed bit here stw r8,savevrvalid(r21) ; Set the current VRSave as valid saved lwz r14,vmmStat(r17) ; Get the status flags mfsprg r10,1 ; Get the current activation lwz r10,ACT_PER_PROC(r10) ; Get the per_proc block stw r11,ACT_MACT_SPF(r26) ; Get the special flags rlwinm r14,r14,0,vmmVectCngdb+1,vmmVectCngdb-1 ; Clear the changed flag stw r11,spcFlags(r10) ; Set per_proc copy of the special flags stw r14,vmmStat(r17) ; Set the status flags sans vmmVectCngd swvmNoNewVects: li r3,1 ; Show normal exit with check for AST mr r16,r26 ; Restore the thread pointer b EXT(ppcscret) ; Go back to handler... .align 5 swvmmBogus: li r2,kVmmBogusContext ; Set bogus index return li r0,0 ; Clear li r3,1 ; Set normal return with check for AST stw r0,saver3(r30) ; Clear upper half stw r2,saver3+4(r30) ; Pass back the return code b EXT(ppcscret) ; Go back to handler... swvmmBogAdsp: li r2,kVmmInvalidAdSpace ; Set bogus address space return li r0,0 ; Clear li r3,1 ; Set normal return with check for AST stw r0,saver3(r30) ; Clear upper half stw r2,saver3+4(r30) ; Pass back the return code b EXT(ppcscret) ; Go back to handler... swvmSetStop: li r2,kVmmStopped ; Set stopped return li r0,0 ; Clear li r3,1 ; Set normal return with check for AST stw r0,saver3(r30) ; Clear upper half stw r2,saver3+4(r30) ; Pass back the return code stw r2,return_code(r5) ; Save the exit code b EXT(ppcscret) ; Go back to handler... svvmTimerPop: li r2,kVmmReturnNull ; Set null return li r0,0 ; Clear li r3,1 ; Set normal return with check for AST stw r0,saver3(r30) ; Clear upper half stw r2,saver3+4(r30) ; Pass back the return code stw r2,return_code(r5) ; Save the exit code b EXT(ppcscret) ; Go back to handler... swvmEmulateISI: mfsprg r10,2 ; Get feature flags lwz r11,vmmXAFlgs(r28) ; Get the eXtended Architecture flags mtcrf 0x02,r10 ; Move pf64Bit to its normal place in CR6 rlwinm. r11,r11,0,0,0 ; Are we doing a 64-bit virtual machine? li r2,kVmmReturnInstrPageFault ; Set ISI crnot vmmDoing64,cr0_eq ; Remember if this is a 64-bit VM li r0,0 ; Clear li r3,1 ; Set normal return with check for AST stw r0,saver3(r30) ; Clear upper half stw r2,saver3+4(r30) ; Pass back the return code stw r2,return_code(r5) ; Save the exit code lis r7,hi16(MASK(DSISR_HASH)) ; Pretend like we got a PTE miss bt vmmDoing64,vmISI64 ; Go do this for a 64-bit VM... lwz r10,vmmppcpc(r5) ; Get the PC as failing address stw r10,return_params+0(r5) ; Save PC as first return parm stw r7,return_params+4(r5) ; Save the pseudo-DSISR as second return parm b EXT(ppcscret) ; Go back to handler... vmISI64: ld r10,vmmppcXpc(r5) ; Get the PC as failing address std r10,return_paramsX+0(r5) ; Save PC as first return parm std r7,return_paramsX+8(r5) ; Save the pseudo-DSISR as second return parm b EXT(ppcscret) ; Go back to handler... ; ; These syscalls are invalid, FAM syscall fast path ; .align 5 .globl EXT(vmm_fam_reserved) LEXT(vmm_fam_reserved) li r3,0 ; Force exception b EXT(ppcscret) ; Go back to handler... ; ; Here is where we exit from vmm mode. We do this on any kind of exception. ; Interruptions (decrementer, external, etc.) are another story though. ; These we just pass through. We also switch back explicity when requested. ; This will happen in response to a timer pop and some kinds of ASTs. ; ; Inputs: ; R3 = activation ; R4 = savearea ; .align 5 .globl EXT(vmm_exit) LEXT(vmm_exit) vmmexitcall: lwz r2,vmmCEntry(r3) ; Get the context that is active lwz r12,ACT_VMMAP(r3) ; Get the VM_MAP for this guy lwz r11,ACT_MACT_SPF(r3) ; Get the special flags lwz r19,vmmFlags(r2) ; Get the status flags mr r16,r3 ; R16 is safe to use for the activation address rlwimi r19,r11,floatCngbit-vmmFloatCngdb,vmmFloatCngdb,vmmVectCngdb ; Shift and insert changed bits li r0,0 ; Get a zero rlwimi r11,r19,vmmSpfSaveb,floatCngbit,vectorCngbit ; Restore the saved part of the spf lwz r3,VMMAP_PMAP(r12) ; Get the pmap for the activation rlwinm r11,r11,0,runningVMbit+1,runningVMbit-1 ; Clear the "in VM" flag stw r0,vmmCEntry(r16) ; Clear pointer to active context stw r19,vmmFlags(r2) ; Set the status flags rlwinm r11,r11,0,userProtKeybit+1,userProtKeybit-1 ; Set back to normal protection key mfsprg r10,1 ; Get the current activation lwz r10,ACT_PER_PROC(r10) ; Get the per_proc block rlwinm r11,r11,0,FamVMenabit+1,FamVMenabit-1 ; Clear FamVMEnable lwz r18,spcFlags(r10) ; Get per_proc copy of the special flags lwz r5,vmmContextKern(r2) ; Get the state page kernel addr rlwinm r11,r11,0,FamVMmodebit+1,FamVMmodebit-1 ; Clear FamVMMode lwz r6,vmmCntrl(r5) ; Get the control field rlwimi r19,r18,FamVMmodebit-vmmFAMmodeb,vmmFAMmodeb,vmmFAMmodeb ; Shift and insert changed bits rlwimi r6,r18,FamVMmodebit-vmmFamSetb,vmmFamSetb,vmmFamSetb ; Shift and insert changed bits rlwimi r6,r18,userProtKeybit-vmmKeyb,vmmKeyb,vmmKeyb ; Shift and insert changed bits stw r11,ACT_MACT_SPF(r16) ; Get the special flags stw r6,vmmCntrl(r5) ; Store the control field stw r11,spcFlags(r10) ; Set per_proc copy of the special flags mr r26,r16 ; Save the activation pointer mr r27,r2 ; Save the context entry bl EXT(hw_set_user_space_dis) ; Swap the address spaces back to the emulator la r5,facctx(r16) ; Point to the main facility context mr r2,r27 ; Restore stw r5,deferctx(r16) ; Start using the main facility context on the way out lwz r5,vmmContextKern(r27) ; Get the context area address mr r3,r16 ; Restore activation address stw r19,vmmStat(r5) ; Save the changed and popped flags bl swapCtxt ; Exchange the VM context for the emulator one stw r8,saver3+4(r30) ; Set the return code as the return value also b EXT(retFromVM) ; Go back to handler... ; ; Here is where we force exit from vmm mode. We do this when as ; part of termination and is used to insure that we are not executing ; in an alternate context. Because this is called from C we need to save ; all non-volatile registers. ; ; Inputs: ; R3 = activation ; R4 = user savearea ; Interruptions disabled ; .align 5 .globl EXT(vmm_force_exit) LEXT(vmm_force_exit) stwu r1,-(FM_ALIGN(20*4)+FM_SIZE)(r1) ; Get enough space for the registers mflr r0 ; Save the return stmw r13,FM_ARG0(r1) ; Save all non-volatile registers stw r0,(FM_ALIGN(20*4)+FM_SIZE+FM_LR_SAVE)(r1) ; Save the return lwz r2,vmmCEntry(r3) ; Get the context that is active lwz r11,ACT_MACT_SPF(r3) ; Get the special flags lwz r19,vmmFlags(r2) ; Get the status flags lwz r12,ACT_VMMAP(r3) ; Get the VM_MAP for this guy rlwimi r19,r11,floatCngbit-vmmFloatCngdb,vmmFloatCngdb,vmmVectCngdb ; Shift and insert changed bits mr r26,r3 ; Save the activation pointer rlwimi r11,r19,vmmSpfSaveb,floatCngbit,vectorCngbit ; Restore the saved part of the spf li r0,0 ; Get a zero rlwinm r9,r11,0,runningVMbit+1,runningVMbit-1 ; Clear the "in VM" flag cmplw r9,r11 ; Check if we were in a vm lwz r3,VMMAP_PMAP(r12) ; Get the pmap for the activation beq- vfeNotRun ; We were not in a vm.... rlwinm r9,r9,0,userProtKeybit+1,userProtKeybit-1 ; Set back to normal protection key stw r0,vmmCEntry(r26) ; Clear pointer to active context mfsprg r10,1 ; Get the current activation lwz r10,ACT_PER_PROC(r10) ; Get the per_proc block lwz r18,spcFlags(r10) ; Get per_proc copy of the special flags rlwinm r9,r9,0,FamVMenabit+1,FamVMenabit-1 ; Clear Fam Enable rlwinm r9,r9,0,FamVMmodebit+1,FamVMmodebit-1 ; Clear Fam Enable lwz r5,vmmContextKern(r2) ; Get the context area address lwz r6,vmmCntrl(r5) ; Get the control field rlwimi r19,r18,FamVMmodebit-vmmFAMmodeb,vmmFAMmodeb,vmmFAMmodeb ; Shift and insert changed bits rlwimi r6,r18,FamVMmodebit-vmmFamSetb,vmmFamSetb,vmmFamSetb ; Shift and insert changed bits rlwimi r6,r18,userProtKeybit-vmmKeyb,vmmKeyb,vmmKeyb ; Shift and insert changed bits stw r6,vmmCntrl(r5) ; Store the control field stw r9,ACT_MACT_SPF(r26) ; Get the special flags stw r9,spcFlags(r10) ; Set per_proc copy of the special flags mr r27,r2 ; Save the context entry mr r30,r4 ; Save the savearea bl EXT(hw_set_user_space_dis) ; Swap the address spaces back to the emulator la r7,facctx(r26) ; Point to the main facility context lwz r5,vmmContextKern(r27) ; Get the context area address stw r19,vmmStat(r5) ; Save the changed and popped flags stw r7,deferctx(r26) ; Tell context launcher to switch facility context bl swapCtxt ; Exchange the VM context for the emulator one lwz r8,saveexception(r30) ; Pick up the exception code lwz r7,SAVflags(r30) ; Pick up the savearea flags lis r9,hi16(SAVredrive) ; Get exception redrive bit rlwinm r8,r8,30,24,31 ; Convert exception to return code andc r7,r7,r9 ; Make sure redrive is off because we are intercepting stw r8,saver3+4(r30) ; Set the return code as the return value also stw r7,SAVflags(r30) ; Set the savearea flags vfeNotRun: lmw r13,FM_ARG0(r1) ; Restore all non-volatile registers lwz r1,0(r1) ; Pop the stack lwz r0,FM_LR_SAVE(r1) ; Get the return address mtlr r0 ; Set return blr ; ; Note: we will not do any DCBTs to the savearea. It was just stored to a few cycles ago and should ; still be in the cache. ; ; NOTE NOTE: R16 is important to save!!!! ; .align 5 swapCtxt: mfsprg r10,2 ; Get feature flags la r6,vmmppcpc(r5) ; Point to the first line mtcrf 0x02,r10 ; Move pf64Bit to its normal place in CR6 lwz r14,saveexception(r30) ; Get the exception code dcbt 0,r6 ; Touch in the first line of the context area bt++ pf64Bitb,swap64 ; Go do this swap on a 64-bit machine... lwz r7,savesrr0+4(r30) ; Start moving context lwz r8,savesrr1+4(r30) lwz r9,saver0+4(r30) cmplwi cr1,r14,T_SYSTEM_CALL ; Are we switching because of a system call? lwz r10,saver1+4(r30) lwz r11,saver2+4(r30) lwz r12,saver3+4(r30) lwz r13,saver4+4(r30) la r6,vmmppcr6(r5) ; Point to second line lwz r14,saver5+4(r30) dcbt 0,r6 ; Touch second line of context area lwz r15,vmmppcpc(r5) ; First line of context lis r22,hi16(MSR_IMPORT_BITS) ; Get the MSR bits that are controllable by user lwz r23,vmmppcmsr(r5) ori r22,r22,lo16(MSR_IMPORT_BITS) ; Get the rest of the MSR bits that are controllable by user lwz r17,vmmppcr0(r5) lwz r18,vmmppcr1(r5) and r23,r23,r22 ; Keep only the controllable bits lwz r19,vmmppcr2(r5) oris r23,r23,hi16(MSR_EXPORT_MASK_SET) ; Force on the required bits lwz r20,vmmppcr3(r5) ori r23,r23,lo16(MSR_EXPORT_MASK_SET) ; Force on the other required bits lwz r21,vmmppcr4(r5) lwz r22,vmmppcr5(r5) dcbt 0,r6 ; Touch third line of context area stw r7,vmmppcpc(r5) ; Save emulator context into the context area stw r8,vmmppcmsr(r5) stw r9,vmmppcr0(r5) stw r10,vmmppcr1(r5) stw r11,vmmppcr2(r5) stw r12,vmmppcr3(r5) stw r13,vmmppcr4(r5) stw r14,vmmppcr5(r5) ; ; Save the first 3 parameters if we are an SC (we will take care of the last later) ; bne+ cr1,swapnotsc ; Skip next if not an SC exception... stw r12,return_params+0(r5) ; Save the first return stw r13,return_params+4(r5) ; Save the second return stw r14,return_params+8(r5) ; Save the third return swapnotsc: li r6,0 ; Clear this out stw r6,savesrr0(r30) ; Insure that high order is clear stw r15,savesrr0+4(r30) ; Save vm context into the savearea stw r6,savesrr1(r30) ; Insure that high order is clear stw r23,savesrr1+4(r30) stw r17,saver0+4(r30) stw r18,saver1+4(r30) stw r19,saver2+4(r30) stw r20,saver3+4(r30) stw r21,saver4+4(r30) la r6,vmmppcr14(r5) ; Point to fourth line stw r22,saver5+4(r30) dcbt 0,r6 ; Touch fourth line ; Swap 8 registers lwz r7,saver6+4(r30) ; Read savearea lwz r8,saver7+4(r30) lwz r9,saver8+4(r30) lwz r10,saver9+4(r30) lwz r11,saver10+4(r30) lwz r12,saver11+4(r30) lwz r13,saver12+4(r30) lwz r14,saver13+4(r30) lwz r15,vmmppcr6(r5) ; Read vm context lwz r24,vmmppcr7(r5) lwz r17,vmmppcr8(r5) lwz r18,vmmppcr9(r5) lwz r19,vmmppcr10(r5) lwz r20,vmmppcr11(r5) lwz r21,vmmppcr12(r5) lwz r22,vmmppcr13(r5) stw r7,vmmppcr6(r5) ; Write context stw r8,vmmppcr7(r5) stw r9,vmmppcr8(r5) stw r10,vmmppcr9(r5) stw r11,vmmppcr10(r5) stw r12,vmmppcr11(r5) stw r13,vmmppcr12(r5) la r6,vmmppcr22(r5) ; Point to fifth line stw r14,vmmppcr13(r5) dcbt 0,r6 ; Touch fifth line stw r15,saver6+4(r30) ; Write vm context stw r24,saver7+4(r30) stw r17,saver8+4(r30) stw r18,saver9+4(r30) stw r19,saver10+4(r30) stw r20,saver11+4(r30) stw r21,saver12+4(r30) stw r22,saver13+4(r30) ; Swap 8 registers lwz r7,saver14+4(r30) ; Read savearea lwz r8,saver15+4(r30) lwz r9,saver16+4(r30) lwz r10,saver17+4(r30) lwz r11,saver18+4(r30) lwz r12,saver19+4(r30) lwz r13,saver20+4(r30) lwz r14,saver21+4(r30) lwz r15,vmmppcr14(r5) ; Read vm context lwz r24,vmmppcr15(r5) lwz r17,vmmppcr16(r5) lwz r18,vmmppcr17(r5) lwz r19,vmmppcr18(r5) lwz r20,vmmppcr19(r5) lwz r21,vmmppcr20(r5) lwz r22,vmmppcr21(r5) stw r7,vmmppcr14(r5) ; Write context stw r8,vmmppcr15(r5) stw r9,vmmppcr16(r5) stw r10,vmmppcr17(r5) stw r11,vmmppcr18(r5) stw r12,vmmppcr19(r5) stw r13,vmmppcr20(r5) la r6,vmmppcr30(r5) ; Point to sixth line stw r14,vmmppcr21(r5) dcbt 0,r6 ; Touch sixth line stw r15,saver14+4(r30) ; Write vm context stw r24,saver15+4(r30) stw r17,saver16+4(r30) stw r18,saver17+4(r30) stw r19,saver18+4(r30) stw r20,saver19+4(r30) stw r21,saver20+4(r30) stw r22,saver21+4(r30) ; Swap 8 registers lwz r7,saver22+4(r30) ; Read savearea lwz r8,saver23+4(r30) lwz r9,saver24+4(r30) lwz r10,saver25+4(r30) lwz r11,saver26+4(r30) lwz r12,saver27+4(r30) lwz r13,saver28+4(r30) lwz r14,saver29+4(r30) lwz r15,vmmppcr22(r5) ; Read vm context lwz r24,vmmppcr23(r5) lwz r17,vmmppcr24(r5) lwz r18,vmmppcr25(r5) lwz r19,vmmppcr26(r5) lwz r20,vmmppcr27(r5) lwz r21,vmmppcr28(r5) lwz r22,vmmppcr29(r5) stw r7,vmmppcr22(r5) ; Write context stw r8,vmmppcr23(r5) stw r9,vmmppcr24(r5) stw r10,vmmppcr25(r5) stw r11,vmmppcr26(r5) stw r12,vmmppcr27(r5) stw r13,vmmppcr28(r5) la r6,vmmppcvscr(r5) ; Point to seventh line stw r14,vmmppcr29(r5) dcbt 0,r6 ; Touch seventh line stw r15,saver22+4(r30) ; Write vm context stw r24,saver23+4(r30) stw r17,saver24+4(r30) stw r18,saver25+4(r30) stw r19,saver26+4(r30) stw r20,saver27+4(r30) stw r21,saver28+4(r30) stw r22,saver29+4(r30) ; Swap 8 registers lwz r7,saver30+4(r30) ; Read savearea lwz r8,saver31+4(r30) lwz r9,savecr(r30) lwz r10,savexer+4(r30) lwz r11,savelr+4(r30) lwz r12,savectr+4(r30) lwz r14,savevrsave(r30) lwz r15,vmmppcr30(r5) ; Read vm context lwz r24,vmmppcr31(r5) lwz r17,vmmppccr(r5) lwz r18,vmmppcxer(r5) lwz r19,vmmppclr(r5) lwz r20,vmmppcctr(r5) lwz r22,vmmppcvrsave(r5) stw r7,vmmppcr30(r5) ; Write context stw r8,vmmppcr31(r5) stw r9,vmmppccr(r5) stw r10,vmmppcxer(r5) stw r11,vmmppclr(r5) stw r12,vmmppcctr(r5) stw r14,vmmppcvrsave(r5) stw r15,saver30+4(r30) ; Write vm context stw r24,saver31+4(r30) stw r17,savecr(r30) stw r18,savexer+4(r30) stw r19,savelr+4(r30) stw r20,savectr+4(r30) stw r22,savevrsave(r30) ; Swap 8 registers lwz r7,savevscr+0(r30) ; Read savearea lwz r8,savevscr+4(r30) lwz r9,savevscr+8(r30) lwz r10,savevscr+12(r30) lwz r11,savefpscrpad(r30) lwz r12,savefpscr(r30) lwz r15,vmmppcvscr+0(r5) ; Read vm context lwz r24,vmmppcvscr+4(r5) lwz r17,vmmppcvscr+8(r5) lwz r18,vmmppcvscr+12(r5) lwz r19,vmmppcfpscrpad(r5) lwz r20,vmmppcfpscr(r5) stw r7,vmmppcvscr+0(r5) ; Write context stw r8,vmmppcvscr+4(r5) stw r9,vmmppcvscr+8(r5) stw r10,vmmppcvscr+12(r5) stw r11,vmmppcfpscrpad(r5) stw r12,vmmppcfpscr(r5) stw r15,savevscr+0(r30) ; Write vm context stw r24,savevscr+4(r30) stw r17,savevscr+8(r30) stw r18,savevscr+12(r30) stw r19,savefpscrpad(r30) stw r20,savefpscr(r30) ; ; Cobble up the exception return code and save any specific return values ; lwz r7,saveexception(r30) ; Pick up the exception code rlwinm r8,r7,30,24,31 ; Convert exception to return code cmplwi r7,T_DATA_ACCESS ; Was this a DSI? stw r8,return_code(r5) ; Save the exit code cmplwi cr1,r7,T_INSTRUCTION_ACCESS ; Exiting because of an ISI? beq+ swapDSI ; Yeah... cmplwi r7,T_ALIGNMENT ; Alignment exception? beq+ cr1,swapISI ; We had an ISI... cmplwi cr1,r7,T_SYSTEM_CALL ; Exiting because of an system call? beq+ swapDSI ; An alignment exception looks like a DSI... beq+ cr1,swapSC ; We had a system call... blr ; Return... ; ; Set exit returns for a DSI or alignment exception ; swapDSI: lwz r10,savedar+4(r30) ; Get the DAR lwz r7,savedsisr(r30) ; and the DSISR stw r10,return_params+0(r5) ; Save DAR as first return parm stw r7,return_params+4(r5) ; Save DSISR as second return parm blr ; Return... ; ; Set exit returns for a ISI ; swapISI: lwz r7,vmmppcmsr(r5) ; Get the SRR1 value lwz r10,vmmppcpc(r5) ; Get the PC as failing address rlwinm r7,r7,0,1,4 ; Save the bits that match the DSISR stw r10,return_params+0(r5) ; Save PC as first return parm stw r7,return_params+4(r5) ; Save the pseudo-DSISR as second return parm blr ; Return... ; ; Set exit returns for a system call (note: we did the first 3 earlier) ; Do we really need to pass parameters back here???? ; swapSC: lwz r10,vmmppcr6(r5) ; Get the fourth paramter stw r10,return_params+12(r5) ; Save it blr ; Return... ; ; Here is the swap for 64-bit machines ; swap64: lwz r22,vmmXAFlgs(r27) ; Get the eXtended Architecture flags ld r7,savesrr0(r30) ; Start moving context ld r8,savesrr1(r30) ld r9,saver0(r30) cmplwi cr1,r14,T_SYSTEM_CALL ; Are we switching because of a system call? ld r10,saver1(r30) ld r11,saver2(r30) rlwinm. r22,r22,0,0,0 ; Are we doing a 64-bit virtual machine? ld r12,saver3(r30) crnot vmmDoing64,cr0_eq ; Remember if this is a 64-bit VM ld r13,saver4(r30) la r6,vmmppcr6(r5) ; Point to second line ld r14,saver5(r30) dcbt 0,r6 ; Touch second line of context area bt vmmDoing64,sw64x1 ; Skip to 64-bit stuff lwz r15,vmmppcpc(r5) ; First line of context lis r22,hi16(MSR_IMPORT_BITS) ; Get the MSR bits that are controllable by user lwz r23,vmmppcmsr(r5) ori r22,r22,lo16(MSR_IMPORT_BITS) ; Get the rest of the MSR bits that are controllable by user lwz r17,vmmppcr0(r5) lwz r18,vmmppcr1(r5) and r23,r23,r22 ; Keep only the controllable bits lwz r19,vmmppcr2(r5) oris r23,r23,hi16(MSR_EXPORT_MASK_SET) ; Force on the required bits lwz r20,vmmppcr3(r5) ori r23,r23,lo16(MSR_EXPORT_MASK_SET) ; Force on the other required bits lwz r21,vmmppcr4(r5) lwz r22,vmmppcr5(r5) dcbt 0,r6 ; Touch third line of context area stw r7,vmmppcpc(r5) ; Save emulator context into the context area stw r8,vmmppcmsr(r5) stw r9,vmmppcr0(r5) stw r10,vmmppcr1(r5) stw r11,vmmppcr2(r5) stw r12,vmmppcr3(r5) stw r13,vmmppcr4(r5) stw r14,vmmppcr5(r5) ; ; Save the first 3 parameters if we are an SC (we will take care of the last later) ; bne+ cr1,sw64x1done ; Skip next if not an SC exception... stw r12,return_params+0(r5) ; Save the first return stw r13,return_params+4(r5) ; Save the second return stw r14,return_params+8(r5) ; Save the third return b sw64x1done ; We are done with this section... sw64x1: ld r15,vmmppcXpc(r5) ; First line of context li r0,1 ; Get a 1 to turn on 64-bit lis r22,hi16(MSR_IMPORT_BITS) ; Get the MSR bits that are controllable by user (we will also allow 64-bit here) sldi r0,r0,63 ; Get 64-bit bit ld r23,vmmppcXmsr(r5) ori r22,r22,lo16(MSR_IMPORT_BITS) ; Get the rest of the MSR bits that are controllable by user ld r17,vmmppcXr0(r5) or r22,r22,r0 ; Add the 64-bit bit ld r18,vmmppcXr1(r5) and r23,r23,r22 ; Keep only the controllable bits ld r19,vmmppcXr2(r5) oris r23,r23,hi16(MSR_EXPORT_MASK_SET) ; Force on the required bits ld r20,vmmppcXr3(r5) ori r23,r23,lo16(MSR_EXPORT_MASK_SET) ; Force on the other required bits ld r21,vmmppcXr4(r5) ld r22,vmmppcXr5(r5) dcbt 0,r6 ; Touch third line of context area std r7,vmmppcXpc(r5) ; Save emulator context into the context area std r8,vmmppcXmsr(r5) std r9,vmmppcXr0(r5) std r10,vmmppcXr1(r5) std r11,vmmppcXr2(r5) std r12,vmmppcXr3(r5) std r13,vmmppcXr4(r5) std r14,vmmppcXr5(r5) ; ; Save the first 3 parameters if we are an SC (we will take care of the last later) ; bne+ cr1,sw64x1done ; Skip next if not an SC exception... std r12,return_paramsX+0(r5) ; Save the first return std r13,return_paramsX+8(r5) ; Save the second return std r14,return_paramsX+16(r5) ; Save the third return sw64x1done: std r15,savesrr0(r30) ; Save vm context into the savearea std r23,savesrr1(r30) std r17,saver0(r30) std r18,saver1(r30) std r19,saver2(r30) std r20,saver3(r30) std r21,saver4(r30) la r6,vmmppcr14(r5) ; Point to fourth line std r22,saver5(r30) dcbt 0,r6 ; Touch fourth line ; Swap 8 registers ld r7,saver6(r30) ; Read savearea ld r8,saver7(r30) ld r9,saver8(r30) ld r10,saver9(r30) ld r11,saver10(r30) ld r12,saver11(r30) ld r13,saver12(r30) ld r14,saver13(r30) bt vmmDoing64,sw64x2 ; Skip to 64-bit stuff lwz r15,vmmppcr6(r5) ; Read vm context lwz r24,vmmppcr7(r5) lwz r17,vmmppcr8(r5) lwz r18,vmmppcr9(r5) lwz r19,vmmppcr10(r5) lwz r20,vmmppcr11(r5) lwz r21,vmmppcr12(r5) lwz r22,vmmppcr13(r5) stw r7,vmmppcr6(r5) ; Write context stw r8,vmmppcr7(r5) stw r9,vmmppcr8(r5) stw r10,vmmppcr9(r5) stw r11,vmmppcr10(r5) stw r12,vmmppcr11(r5) stw r13,vmmppcr12(r5) la r6,vmmppcr22(r5) ; Point to fifth line stw r14,vmmppcr13(r5) dcbt 0,r6 ; Touch fifth line b sw64x2done ; We are done with this section... sw64x2: ld r15,vmmppcXr6(r5) ; Read vm context ld r24,vmmppcXr7(r5) ld r17,vmmppcXr8(r5) ld r18,vmmppcXr9(r5) ld r19,vmmppcXr10(r5) ld r20,vmmppcXr11(r5) ld r21,vmmppcXr12(r5) ld r22,vmmppcXr13(r5) std r7,vmmppcXr6(r5) ; Write context std r8,vmmppcXr7(r5) std r9,vmmppcXr8(r5) std r10,vmmppcXr9(r5) std r11,vmmppcXr10(r5) std r12,vmmppcXr11(r5) std r13,vmmppcXr12(r5) la r6,vmmppcXr22(r5) ; Point to fifth line std r14,vmmppcXr13(r5) dcbt 0,r6 ; Touch fifth line sw64x2done: std r15,saver6(r30) ; Write vm context std r24,saver7(r30) std r17,saver8(r30) std r18,saver9(r30) std r19,saver10(r30) std r20,saver11(r30) std r21,saver12(r30) std r22,saver13(r30) ; Swap 8 registers ld r7,saver14(r30) ; Read savearea ld r8,saver15(r30) ld r9,saver16(r30) ld r10,saver17(r30) ld r11,saver18(r30) ld r12,saver19(r30) ld r13,saver20(r30) ld r14,saver21(r30) bt vmmDoing64,sw64x3 ; Skip to 64-bit stuff lwz r15,vmmppcr14(r5) ; Read vm context lwz r24,vmmppcr15(r5) lwz r17,vmmppcr16(r5) lwz r18,vmmppcr17(r5) lwz r19,vmmppcr18(r5) lwz r20,vmmppcr19(r5) lwz r21,vmmppcr20(r5) lwz r22,vmmppcr21(r5) stw r7,vmmppcr14(r5) ; Write context stw r8,vmmppcr15(r5) stw r9,vmmppcr16(r5) stw r10,vmmppcr17(r5) stw r11,vmmppcr18(r5) stw r12,vmmppcr19(r5) stw r13,vmmppcr20(r5) la r6,vmmppcr30(r5) ; Point to sixth line stw r14,vmmppcr21(r5) dcbt 0,r6 ; Touch sixth line b sw64x3done ; Done with this section... sw64x3: ld r15,vmmppcXr14(r5) ; Read vm context ld r24,vmmppcXr15(r5) ld r17,vmmppcXr16(r5) ld r18,vmmppcXr17(r5) ld r19,vmmppcXr18(r5) ld r20,vmmppcXr19(r5) ld r21,vmmppcXr20(r5) ld r22,vmmppcXr21(r5) std r7,vmmppcXr14(r5) ; Write context std r8,vmmppcXr15(r5) std r9,vmmppcXr16(r5) std r10,vmmppcXr17(r5) std r11,vmmppcXr18(r5) std r12,vmmppcXr19(r5) std r13,vmmppcXr20(r5) la r6,vmmppcXr30(r5) ; Point to sixth line std r14,vmmppcXr21(r5) dcbt 0,r6 ; Touch sixth line sw64x3done: std r15,saver14(r30) ; Write vm context std r24,saver15(r30) std r17,saver16(r30) std r18,saver17(r30) std r19,saver18(r30) std r20,saver19(r30) std r21,saver20(r30) std r22,saver21(r30) ; Swap 8 registers ld r7,saver22(r30) ; Read savearea ld r8,saver23(r30) ld r9,saver24(r30) ld r10,saver25(r30) ld r11,saver26(r30) ld r12,saver27(r30) ld r13,saver28(r30) ld r14,saver29(r30) bt vmmDoing64,sw64x4 ; Skip to 64-bit stuff lwz r15,vmmppcr22(r5) ; Read vm context lwz r24,vmmppcr23(r5) lwz r17,vmmppcr24(r5) lwz r18,vmmppcr25(r5) lwz r19,vmmppcr26(r5) lwz r20,vmmppcr27(r5) lwz r21,vmmppcr28(r5) lwz r22,vmmppcr29(r5) stw r7,vmmppcr22(r5) ; Write context stw r8,vmmppcr23(r5) stw r9,vmmppcr24(r5) stw r10,vmmppcr25(r5) stw r11,vmmppcr26(r5) stw r12,vmmppcr27(r5) stw r13,vmmppcr28(r5) la r6,vmmppcvscr(r5) ; Point to seventh line stw r14,vmmppcr29(r5) dcbt 0,r6 ; Touch seventh line b sw64x4done ; Done with this section... sw64x4: ld r15,vmmppcXr22(r5) ; Read vm context ld r24,vmmppcXr23(r5) ld r17,vmmppcXr24(r5) ld r18,vmmppcXr25(r5) ld r19,vmmppcXr26(r5) ld r20,vmmppcXr27(r5) ld r21,vmmppcXr28(r5) ld r22,vmmppcXr29(r5) std r7,vmmppcXr22(r5) ; Write context std r8,vmmppcXr23(r5) std r9,vmmppcXr24(r5) std r10,vmmppcXr25(r5) std r11,vmmppcXr26(r5) std r12,vmmppcXr27(r5) std r13,vmmppcXr28(r5) la r6,vmmppcvscr(r5) ; Point to seventh line std r14,vmmppcXr29(r5) dcbt 0,r6 ; Touch seventh line sw64x4done: std r15,saver22(r30) ; Write vm context std r24,saver23(r30) std r17,saver24(r30) std r18,saver25(r30) std r19,saver26(r30) std r20,saver27(r30) std r21,saver28(r30) std r22,saver29(r30) ; Swap 8 registers ld r7,saver30(r30) ; Read savearea ld r8,saver31(r30) lwz r9,savecr(r30) ld r10,savexer(r30) ld r11,savelr(r30) ld r12,savectr(r30) lwz r14,savevrsave(r30) bt vmmDoing64,sw64x5 ; Skip to 64-bit stuff lwz r15,vmmppcr30(r5) ; Read vm context lwz r24,vmmppcr31(r5) lwz r17,vmmppccr(r5) lwz r18,vmmppcxer(r5) lwz r19,vmmppclr(r5) lwz r20,vmmppcctr(r5) lwz r22,vmmppcvrsave(r5) stw r7,vmmppcr30(r5) ; Write context stw r8,vmmppcr31(r5) stw r9,vmmppccr(r5) stw r10,vmmppcxer(r5) stw r11,vmmppclr(r5) stw r12,vmmppcctr(r5) stw r14,vmmppcvrsave(r5) b sw64x5done ; Done here... sw64x5: ld r15,vmmppcXr30(r5) ; Read vm context ld r24,vmmppcXr31(r5) lwz r17,vmmppcXcr(r5) ld r18,vmmppcXxer(r5) ld r19,vmmppcXlr(r5) ld r20,vmmppcXctr(r5) lwz r22,vmmppcXvrsave(r5) std r7,vmmppcXr30(r5) ; Write context std r8,vmmppcXr31(r5) stw r9,vmmppcXcr(r5) std r10,vmmppcXxer(r5) std r11,vmmppcXlr(r5) std r12,vmmppcXctr(r5) stw r14,vmmppcXvrsave(r5) sw64x5done: std r15,saver30(r30) ; Write vm context std r24,saver31(r30) stw r17,savecr(r30) std r18,savexer(r30) std r19,savelr(r30) std r20,savectr(r30) stw r22,savevrsave(r30) ; Swap 8 registers lwz r7,savevscr+0(r30) ; Read savearea lwz r8,savevscr+4(r30) lwz r9,savevscr+8(r30) lwz r10,savevscr+12(r30) lwz r11,savefpscrpad(r30) lwz r12,savefpscr(r30) lwz r15,vmmppcvscr+0(r5) ; Read vm context lwz r24,vmmppcvscr+4(r5) lwz r17,vmmppcvscr+8(r5) lwz r18,vmmppcvscr+12(r5) lwz r19,vmmppcfpscrpad(r5) lwz r20,vmmppcfpscr(r5) stw r7,vmmppcvscr+0(r5) ; Write context stw r8,vmmppcvscr+4(r5) stw r9,vmmppcvscr+8(r5) stw r10,vmmppcvscr+12(r5) stw r11,vmmppcfpscrpad(r5) stw r12,vmmppcfpscr(r5) stw r15,savevscr+0(r30) ; Write vm context stw r24,savevscr+4(r30) stw r17,savevscr+8(r30) stw r18,savevscr+12(r30) stw r19,savefpscrpad(r30) stw r20,savefpscr(r30) ; ; Cobble up the exception return code and save any specific return values ; lwz r7,saveexception(r30) ; Pick up the exception code rlwinm r8,r7,30,24,31 ; Convert exception to return code cmplwi r7,T_DATA_ACCESS ; Was this a DSI? stw r8,return_code(r5) ; Save the exit code cmplwi cr1,r7,T_INSTRUCTION_ACCESS ; Exiting because of an ISI? beq+ swapDSI64 ; Yeah... cmplwi r7,T_ALIGNMENT ; Alignment exception? beq+ cr1,swapISI64 ; We had an ISI... cmplwi cr1,r7,T_SYSTEM_CALL ; Exiting because of an system call? beq+ swapDSI64 ; An alignment exception looks like a DSI... beq+ cr1,swapSC64 ; We had a system call... blr ; Return... ; ; Set exit returns for a DSI or alignment exception ; swapDSI64: ld r10,savedar(r30) ; Get the DAR lwz r7,savedsisr(r30) ; and the DSISR bt vmmDoing64,sw64DSI ; Skip to 64-bit stuff... stw r10,return_params+0(r5) ; Save DAR as first return parm stw r7,return_params+4(r5) ; Save DSISR as second return parm blr ; Return... sw64DSI: std r10,return_paramsX+0(r5) ; Save DAR as first return parm std r7,return_paramsX+8(r5) ; Save DSISR as second return parm (note that this is expanded to 64 bits) blr ; Return... ; ; Set exit returns for a ISI ; swapISI64: bt vmmDoing64,sw64ISI ; Skip to 64-bit stuff... lwz r7,vmmppcmsr(r5) ; Get the SRR1 value lwz r10,vmmppcpc(r5) ; Get the PC as failing address rlwinm r7,r7,0,1,4 ; Save the bits that match the DSISR stw r10,return_params+0(r5) ; Save PC as first return parm stw r7,return_params+4(r5) ; Save the pseudo-DSISR as second return parm blr ; Return... sw64ISI: ld r7,vmmppcXmsr(r5) ; Get the SRR1 value ld r10,vmmppcXpc(r5) ; Get the PC as failing address rlwinm r7,r7,0,1,4 ; Save the bits that match the DSISR std r10,return_paramsX+0(r5) ; Save PC as first return parm std r7,return_paramsX+8(r5) ; Save the pseudo-DSISR as second return parm blr ; Return... ; ; Set exit returns for a system call (note: we did the first 3 earlier) ; Do we really need to pass parameters back here???? ; swapSC64: bt vmmDoing64,sw64SC ; Skip to 64-bit stuff... lwz r10,vmmppcr6(r5) ; Get the fourth paramter stw r10,return_params+12(r5) ; Save it blr ; Return... sw64SC: ld r10,vmmppcXr6(r5) ; Get the fourth paramter std r10,return_paramsX+24(r5) ; Save it blr ; Return... ; ; vmmFamGuestResume: ; Restore Guest context from Fam mode. ; vmmFamGuestResume: mfsprg r10,1 ; Get the current activation lwz r10,ACT_PER_PROC(r10) ; Get the per_proc block lwz r27,vmmCEntry(r3) ; Get the context that is active lwz r4,VMMXAFlgs(r10) ; Get the eXtended Architecture flags rlwinm. r4,r4,0,0,0 ; Are we doing a 64-bit virtual machine? lwz r15,spcFlags(r10) ; Get per_proc special flags mr r26,r3 ; Save the activation pointer lwz r20,vmmContextKern(r27) ; Get the comm area rlwinm r15,r15,0,FamVMmodebit+1,FamVMmodebit-1 ; Clear FamVMmodebit stw r15,spcFlags(r10) ; Update the special flags bne fgrX lwz r7,famguestpc(r20) ; Load famguest ctx pc bf++ vmmMapDone,fgrNoMap ; No mapping done for this space. lwz r3,SAVflags(r30) ; Pick up the savearea flags lwz r2,vmmLastMap(r28) ; Get the last mapped address lwz r6,vmmLastMap+4(r28) ; Get the last mapped address li r4,T_DATA_ACCESS ; Change to DSI fault oris r3,r3,hi16(SAVredrive) ; Set exception redrive stw r2,savedar(r30) ; Set the DAR to the last thing we mapped stw r6,savedar+4(r30) ; Set the DAR to the last thing we mapped stw r3,SAVflags(r30) ; Turn on the redrive request lis r2,hi16(MASK(DSISR_HASH)) ; Set PTE/DBAT miss stw r4,saveexception(r30) ; Say we need to emulate a DSI li r0,0 ; Clear stw r2,savedsisr(r30) ; Pretend we have a PTE miss stb r0,vmmGFlags+3(r28) ; Show that the redrive has been taken care of fgrNoMap: lwz r4,savesrr1+4(r30) ; Get the saved MSR value stw r7,savesrr0+4(r30) ; Set savearea pc lwz r5,famguestmsr(r20) ; Load famguest ctx msr lis r6,hi16(MSR_IMPORT_BITS) ; Get the MSR bits that are controllable by user ori r6,r6,lo16(MSR_IMPORT_BITS) ; Get the rest of the MSR bits that are controllable by user and r5,r5,r6 ; Keep only the controllable bits oris r5,r5,hi16(MSR_EXPORT_MASK_SET) ; Force on the required bits ori r5,r5,lo16(MSR_EXPORT_MASK_SET) ; Force on the other required bits rlwimi r5,r4,0,MSR_FP_BIT,MSR_FP_BIT ; Propagate guest FP rlwimi r5,r4,0,MSR_VEC_BIT,MSR_VEC_BIT ; Propagate guest Vector stw r5,savesrr1+4(r30) ; Set savearea srr1 lwz r4,famguestr0(r20) ; Load famguest ctx r0 lwz r5,famguestr1(r20) ; Load famguest ctx r1 lwz r6,famguestr2(r20) ; Load famguest ctx r2 lwz r7,famguestr3(r20) ; Load famguest ctx r3 stw r4,saver0+4(r30) ; Set savearea r0 stw r5,saver1+4(r30) ; Set savearea r1 stw r6,saver2+4(r30) ; Set savearea r2 stw r7,saver3+4(r30) ; Set savearea r3 lwz r4,famguestr4(r20) ; Load famguest ctx r4 lwz r5,famguestr5(r20) ; Load famguest ctx r5 lwz r6,famguestr6(r20) ; Load famguest ctx r6 lwz r7,famguestr7(r20) ; Load famguest ctx r7 stw r4,saver4+4(r30) ; Set savearea r4 stw r5,saver5+4(r30) ; Set savearea r5 stw r6,saver6+4(r30) ; Set savearea r6 stw r7,saver7+4(r30) ; Set savearea r7 b fgrret fgrX: ld r7,famguestXpc(r20) ; Load famguest ctx pc bf++ vmmMapDone,fgrXNoMap ; No mapping done for this space. lwz r3,SAVflags(r30) ; Pick up the savearea flags ld r2,vmmLastMap(r28) ; Get the last mapped address li r4,T_DATA_ACCESS ; Change to DSI fault oris r3,r3,hi16(SAVredrive) ; Set exception redrive std r2,savedar(r30) ; Set the DAR to the last thing we mapped stw r3,SAVflags(r30) ; Turn on the redrive request lis r2,hi16(MASK(DSISR_HASH)) ; Set PTE/DBAT miss stw r4,saveexception(r30) ; Say we need to emulate a DSI li r0,0 ; Clear stw r2,savedsisr(r30) ; Pretend we have a PTE miss stb r0,vmmGFlags+3(r28) ; Show that the redrive has been taken care of fgrXNoMap: ld r4,savesrr1(r30) ; Get the saved MSR value std r7,savesrr0(r30) ; Set savearea pc ld r5,famguestXmsr(r20) ; Load famguest ctx msr lis r6,hi16(MSR_IMPORT_BITS) ; Get the MSR bits that are controllable by user ori r6,r6,lo16(MSR_IMPORT_BITS) ; Get the rest of the MSR bits that are controllable by user and r5,r5,r6 ; Keep only the controllable bits oris r5,r5,hi16(MSR_EXPORT_MASK_SET) ; Force on the required bits ori r5,r5,lo16(MSR_EXPORT_MASK_SET) ; Force on the other required bits rlwimi r5,r4,0,MSR_FP_BIT,MSR_FP_BIT ; Propagate guest FP rlwimi r5,r4,0,MSR_VEC_BIT,MSR_VEC_BIT ; Propagate guest Vector std r5,savesrr1(r30) ; Set savearea srr1 ld r4,famguestXr0(r20) ; Load famguest ctx r0 ld r5,famguestXr1(r20) ; Load famguest ctx r1 ld r6,famguestXr2(r20) ; Load famguest ctx r2 ld r7,famguestXr3(r20) ; Load famguest ctx r3 std r4,saver0(r30) ; Set savearea r0 std r5,saver1(r30) ; Set savearea r1 std r6,saver2(r30) ; Set savearea r2 std r7,saver3(r30) ; Set savearea r3 ld r4,famguestXr4(r20) ; Load famguest ctx r4 ld r5,famguestXr5(r20) ; Load famguest ctx r5 ld r6,famguestXr6(r20) ; Load famguest ctx r6 ld r7,famguestXr7(r20) ; Load famguest ctx r7 std r4,saver4(r30) ; Set savearea r4 std r5,saver5(r30) ; Set savearea r5 std r6,saver6(r30) ; Set savearea r6 std r7,saver7(r30) ; Set savearea r7 fgrret: li r3,1 ; Show normal exit with check for AST mr r16,r26 ; Restore the thread pointer b EXT(ppcscret) ; Go back to handler... ; ; FAM Intercept exception handler ; .align 5 .globl EXT(vmm_fam_exc) LEXT(vmm_fam_exc) lwz r4,VMMXAFlgs(r2) ; Get the eXtended Architecture flags lwz r1,pfAvailable(r2) ; Get the CPU features flags rlwinm. r4,r4,0,0,0 ; Are we doing a 64-bit virtual machine? bne fexcX lwz r4,saver4+4(r13) ; Load savearea r4 cmplwi r11,T_ALIGNMENT ; Alignment exception? lwz r3,VMMareaPhys(r2) ; Load phys state page addr mtcrf 0x02,r1 ; Move pf64Bit to its normal place in CR6 cmplwi cr1,r11,T_PROGRAM ; Exiting because of an PRG? bt++ pf64Bitb,fexcVMareaPhys64 ; Go do this on a 64-bit machine... slwi r3,r3,12 ; Change ppnum to physical address b fexcVMareaPhysres fexcVMareaPhys64: mtxer r5 ; Restore xer lwz r5,saver5+4(r13) ; Load savearea r5 lwz r6,saver6+4(r13) ; Load savearea r6 sldi r3,r3,12 ; Change ppnum to physical address fexcVMareaPhysres: stw r4,famguestr4(r3) ; Save r4 in famguest ctx stw r5,famguestr5(r3) ; Save r5 in famguest ctx stw r6,famguestr6(r3) ; Save r6 in famguest ctx stw r7,famguestr7(r3) ; Save r7 in famguest ctx lwz r4,saver0+4(r13) ; Load savearea r0 lwz r5,saver1+4(r13) ; Load savearea r1 lwz r6,saver2+4(r13) ; Load savearea r2 lwz r7,saver3+4(r13) ; Load savearea r3 stw r4,famguestr0(r3) ; Save r0 in famguest ctx stw r5,famguestr1(r3) ; Save r1 in famguest ctx stw r6,famguestr2(r3) ; Save r2 in famguest ctx stw r7,famguestr3(r3) ; Save r3 in famguest ctx lwz r4,spcFlags(r2) ; Load per_proc spcFlags oris r4,r4,hi16(FamVMmode) ; Set FAM mode stw r4,spcFlags(r2) ; Update per_proc spcFlags mfsrr0 r2 ; Get the interrupt srr0 mfsrr1 r4 ; Get the interrupt srr1 stw r2,famguestpc(r3) ; Save srr0 in famguest ctx stw r4,famguestmsr(r3) ; Save srr1 in famguest ctx li r6,lo16(MASK(MSR_FE0)|MASK(MSR_SE)|MASK(MSR_BE)|MASK(MSR_FE1)) andc r6,r4,r6 ; Clear SE BE FE0 FE1 mtsrr1 r6 ; Set srr1 mr r6,r3 ; Set r6 with phys state page addr rlwinm r7,r11,30,24,31 ; Convert exception to return code beq+ cr1,fexcPRG ; We had a program exception... bne+ fexcret ; We had an Alignment... mfdar r3 ; Load dar mfdsisr r4 ; Load dsisr stw r3,famparam+0x4(r6) ; Set famparam 1 with dar stw r4,famparam+0x8(r6) ; Set famparam 2 with dsir b fexcret ; fexcPRG: stw r4,famparam+0x4(r6) ; Set famparam 1 with srr1 mr r3,r4 ; Set r3 with dsisr lwz r4,famguestr4(r6) ; Load r4 from famguest context fexcret: lwz r5,famguestr5(r6) ; Load r5 from famguest context lwz r13,famhandler(r6) ; Load user address to resume stw r2,famparam(r6) ; Set famparam 0 with srr0 stw r7,famdispcode(r6) ; Save the exit code lwz r1,famrefcon(r6) ; load refcon bt++ pf64Bitb,fexcrfi64 ; Go do this on a 64-bit machine... mtcr r0 ; Restore cr mtsrr0 r13 ; Load srr0 mr r0,r7 ; Set dispatch code lwz r7,famguestr7(r6) ; Load r7 from famguest context lwz r6,famguestr6(r6) ; Load r6 from famguest context mfsprg r13,2 ; Restore r13 mfsprg r11,3 ; Restore r11 rfi fexcrfi64: mtcr r0 ; Restore cr mtsrr0 r13 ; Load srr0 mr r0,r7 ; Set dispatch code lwz r7,famguestr7(r6) ; Load r7 from famguest context lwz r6,famguestr6(r6) ; Load r6 from famguest context mfsprg r13,2 ; Restore r13 mfsprg r11,3 ; Restore r11 rfid fexcX: mtxer r5 ; Restore xer ld r4,saver4(r13) ; Load savearea r4 ld r5,saver5(r13) ; Load savearea r5 ld r6,saver6(r13) ; Load savearea r6 cmplwi r11,T_ALIGNMENT ; Alignment exception? lwz r3,VMMareaPhys(r2) ; Load phys state page addr mtcrf 0x02,r1 ; Move pf64Bit to its normal place in CR6 cmplwi cr1,r11,T_PROGRAM ; Exiting because of an PRG? sldi r3,r3,12 ; Change ppnum to physical address std r4,famguestXr4(r3) ; Save r4 in famguest ctx std r5,famguestXr5(r3) ; Save r5 in famguest ctx std r6,famguestXr6(r3) ; Save r6 in famguest ctx std r7,famguestXr7(r3) ; Save r7 in famguest ctx ld r4,saver0(r13) ; Load savearea r0 ld r5,saver1(r13) ; Load savearea r1 ld r6,saver2(r13) ; Load savearea r2 ld r7,saver3(r13) ; Load savearea r3 std r4,famguestXr0(r3) ; Save r0 in famguest ctx std r5,famguestXr1(r3) ; Save r1 in famguest ctx std r6,famguestXr2(r3) ; Save r2 in famguest ctx std r7,famguestXr3(r3) ; Save r3 in famguest ctx lwz r4,spcFlags(r2) ; Load per_proc spcFlags oris r4,r4,hi16(FamVMmode) ; Set FAM mode stw r4,spcFlags(r2) ; Update per_proc spcFlags mfsrr0 r2 ; Get the interrupt srr0 mfsrr1 r4 ; Get the interrupt srr1 std r2,famguestXpc(r3) ; Save srr0 in famguest ctx std r4,famguestXmsr(r3) ; Save srr1 in famguest ctx li r6,lo16(MASK(MSR_FE0)|MASK(MSR_SE)|MASK(MSR_BE)|MASK(MSR_FE1)) andc r6,r4,r6 ; Clear SE BE FE0 FE1 mtsrr1 r6 ; Set srr1 mr r6,r3 ; Set r6 with phys state page addr rlwinm r7,r11,30,24,31 ; Convert exception to return code beq+ cr1,fexcXPRG ; We had a program exception... bne+ fexcXret ; We had an Alignment... mfdar r3 ; Load dar mfdsisr r4 ; Load dsisr std r3,famparamX+0x8(r6) ; Set famparam 1 with dar std r4,famparamX+0x10(r6) ; Set famparam 2 with dsir b fexcXret fexcXPRG: std r4,famparamX+0x8(r6) ; Set famparam 1 with srr1 mr r3,r4 ; Set r3 with dsisr ld r4,famguestXr4(r6) ; Load r4 from famguest context fexcXret: ld r5,famguestXr5(r6) ; Load r5 from famguest context ld r13,famhandlerX(r6) ; Load user address to resume std r2,famparamX(r6) ; Set famparam 0 with srr0 std r7,famdispcodeX(r6) ; Save the exit code ld r1,famrefconX(r6) ; load refcon mtcr r0 ; Restore cr mtsrr0 r13 ; Load srr0 mr r0,r7 ; Set dispatch code ld r7,famguestXr7(r6) ; Load r7 from famguest context ld r6,famguestXr6(r6) ; Load r6 from famguest context mfsprg r13,2 ; Restore r13 mfsprg r11,3 ; Restore r11 rfid ; ; FAM Intercept DSI ISI fault handler ; .align 5 .globl EXT(vmm_fam_pf) LEXT(vmm_fam_pf) lwz r4,VMMXAFlgs(r2) ; Get the eXtended Architecture flags lwz r3,VMMareaPhys(r2) ; Load phys state page addr rlwinm. r4,r4,0,0,0 ; Are we doing a 64-bit virtual machine? bne fpfX lwz r4,saver0+4(r13) ; Load savearea r0 lwz r5,saver1+4(r13) ; Load savearea r1 lwz r6,saver2+4(r13) ; Load savearea r2 lwz r7,saver3+4(r13) ; Load savearea r3 bt++ pf64Bitb,fpfVMareaPhys64 ; Go do this on a 64-bit machine... slwi r3,r3,12 ; Change ppnum to physical address b fpfVMareaPhysret fpfVMareaPhys64: sldi r3,r3,12 ; Change ppnum to physical address fpfVMareaPhysret: stw r4,famguestr0(r3) ; Save r0 in famguest stw r5,famguestr1(r3) ; Save r1 in famguest stw r6,famguestr2(r3) ; Save r2 in famguest stw r7,famguestr3(r3) ; Save r3 in famguest lwz r4,saver4+4(r13) ; Load savearea r0 lwz r5,saver5+4(r13) ; Load savearea r1 lwz r6,saver6+4(r13) ; Load savearea r2 lwz r7,saver7+4(r13) ; Load savearea r3 stw r4,famguestr4(r3) ; Save r4 in famguest lwz r4,spcFlags(r2) ; Load spcFlags stw r5,famguestr5(r3) ; Save r5 in famguest lwz r5,savesrr0+4(r13) ; Get the interrupt srr0 stw r6,famguestr6(r3) ; Save r6 in famguest lwz r6,savesrr1+4(r13) ; Load srr1 oris r4,r4,hi16(FamVMmode) ; Set FAM mode stw r7,famguestr7(r3) ; Save r7 in famguest stw r4,spcFlags(r2) ; Update spcFlags lwz r1,famrefcon(r3) ; Load refcon lwz r2,famhandler(r3) ; Load famhandler to resume stw r5,famguestpc(r3) ; Save srr0 stw r5,saver2+4(r13) ; Store srr0 in savearea r2 stw r5,famparam(r3) ; Store srr0 in fam param 0 stw r6,famguestmsr(r3) ; Save srr1 in famguestmsr cmplwi cr1,r11,T_INSTRUCTION_ACCESS ; Was this a ISI? rlwinm r7,r11,30,24,31 ; Convert exception to return code beq+ cr1,fpfISI ; We had an ISI... ; fpfDSI lwz r6,savedar+4(r13) ; Load dar from savearea lwz r4,savedsisr(r13) ; Load dsisr from savearea stw r6,famparam+0x4(r3) ; Store dar in fam param 1 stw r6,saver3+4(r13) ; Store dar in savearea r3 stw r4,famparam+0x8(r3) ; Store dsisr in fam param 2 stw r4,saver4+4(r13) ; Store dsisr in savearea r4 b fpfret fpfISI: rlwinm r6,r6,0,1,4 ; Save the bits that match the DSISR stw r6,famparam+0x4(r3) ; Store srr1 in fam param 1 stw r6,saver3+4(r13) ; Store srr1 in savearea r3 fpfret: stw r7,saver0+4(r13) ; Set dispatch code stw r7,famdispcode(r3) ; Set dispatch code stw r1,saver1+4(r13) ; Store refcon in savearea r1 stw r2,savesrr0+4(r13) ; Store famhandler in srr0 blr fpfX: ld r4,saver0(r13) ; Load savearea r0 ld r5,saver1(r13) ; Load savearea r1 ld r6,saver2(r13) ; Load savearea r2 ld r7,saver3(r13) ; Load savearea r3 sldi r3,r3,12 ; Change ppnum to physical address std r4,famguestXr0(r3) ; Save r0 in famguest std r5,famguestXr1(r3) ; Save r1 in famguest std r6,famguestXr2(r3) ; Save r2 in famguest std r7,famguestXr3(r3) ; Save r3 in famguest ld r4,saver4(r13) ; Load savearea r0 ld r5,saver5(r13) ; Load savearea r1 ld r6,saver6(r13) ; Load savearea r2 ld r7,saver7(r13) ; Load savearea r3 std r4,famguestXr4(r3) ; Save r4 in famguest lwz r4,spcFlags(r2) ; Load spcFlags std r5,famguestXr5(r3) ; Save r5 in famguest ld r5,savesrr0(r13) ; Get the interrupt srr0 std r6,famguestXr6(r3) ; Save r6 in famguest ld r6,savesrr1(r13) ; Load srr1 oris r4,r4,hi16(FamVMmode) ; Set FAM mode std r7,famguestXr7(r3) ; Save r7 in famguest stw r4,spcFlags(r2) ; Update spcFlags ld r1,famrefconX(r3) ; Load refcon ld r2,famhandlerX(r3) ; Load famhandler to resume std r5,famguestXpc(r3) ; Save srr0 std r5,saver2(r13) ; Store srr0 in savearea r2 std r5,famparamX(r3) ; Store srr0 in fam param 0 std r6,famguestXmsr(r3) ; Save srr1 in famguestmsr cmplwi cr1,r11,T_INSTRUCTION_ACCESS ; Was this a ISI? rlwinm r7,r11,30,24,31 ; Convert exception to return code beq+ cr1,fpfXISI ; We had an ISI... ; fpfXDSI ld r6,savedar(r13) ; Load dar from savearea lwz r4,savedsisr(r13) ; Load dsisr from savearea std r6,famparamX+0x8(r3) ; Store dar in fam param 1 std r6,saver3(r13) ; Store dar in savearea r3 std r4,famparamX+0x10(r3) ; Store dsisr in fam param 2 std r4,saver4(r13) ; Store dsisr in savearea r4 b fpfXret fpfXISI: rlwinm r6,r6,0,1,4 ; Save the bits that match the DSISR std r6,famparamX+0x8(r3) ; Store srr1 in fam param 1 std r6,saver3(r13) ; Store srr1 in savearea r3 fpfXret: std r7,saver0(r13) ; Set dispatch code std r7,famdispcodeX(r3) ; Set dispatch code std r1,saver1(r13) ; Store refcon in savearea r1 std r2,savesrr0(r13) ; Store famhandler in srr0 blr /* * Ultra Fast Path FAM syscalls * * The UFT FAMs are those from kvmmResumeGuest to kvmmSetGuestRegister, inclusive. * We get here directly from the syscall vector, with interrupts and translation off, * 64-bit mode on if supported, and all registers live except: * * r13 = holds caller's cr * sprg2 = holds caller's r13 * sprg3 = holds caller's r11 * cr2 = set on (r3==kvmmSetGuestRegister) * cr5 = set on (r3==kvmmResumeGuest) */ .align 5 .globl EXT(vmm_ufp) LEXT(vmm_ufp) mfsprg r3,0 ; Get the per_proc area mr r11,r13 ; Move saved cr to r11 lwz r13,VMMXAFlgs(r3) ; Get the eXtended Architecture flags rlwinm. r13,r13,0,0,0 ; Are we doing a 64-bit virtual machine? lwz r13,pfAvailable(r3) ; Get feature flags mtcrf 0x02,r13 ; Put pf64Bitb etc in cr6 lwz r13,VMMareaPhys(r3) ; Load fast assist area bt++ pf64Bitb,ufpVMareaPhys64 ; Go do this on a 64-bit machine... slwi r13,r13,12 ; Change ppnum to physical address b ufpVMareaPhysret ufpVMareaPhys64: sldi r13,r13,12 ; Change ppnum to physical address ufpVMareaPhysret: bne ufpX ; go handle a 64-bit virtual machine bt cr5_eq,ufpResumeGuest ; if kvmmResumeGuest, branch to ResumeGuest cmplwi cr5,r4,7 ; First argument in range? (ie, 0-7) bgt cr5,ufpVMret ; Return if not in the range slwi r4,r4,2 ; multiply index by 4 la r3,famguestr0(r13) ; Load the base address bt cr2_eq,ufpSetGuestReg ; Set/get selector ; ufpGetGuestReg lwzx r3,r4,r3 ; Load the guest register b ufpVMret ; Return ufpSetGuestReg: stwx r5,r4,r3 ; Update the guest register li r3,0 ; Set return value b ufpVMret ; Return ufpResumeGuest: lwz r7,spcFlags(r3) ; Pick up the special flags mtsrr0 r4 ; Set srr0 rlwinm. r6,r6,0,vmmKeyb,vmmKeyb ; Check vmmKeyb in maskCntrl rlwinm r7,r7,0,FamVMmodebit+1,FamVMmodebit-1 ; Clear FamVMmodebit stw r7,spcFlags(r3) ; Update the special flags mfsrr1 r6 ; Get the current MSR value lwz r4,famguestmsr(r13) ; Load guest srr1 lis r1,hi16(MSR_IMPORT_BITS) ; Get the MSR bits that are controllable by user ori r1,r1,lo16(MSR_IMPORT_BITS) ; Get the rest of the MSR bits that are controllable by user and r4,r4,r1 ; Keep only the controllable bits oris r4,r4,hi16(MSR_EXPORT_MASK_SET) ; Force on the required bits ori r4,r4,lo16(MSR_EXPORT_MASK_SET) ; Force on the other required bits rlwimi r4,r6,0,MSR_FP_BIT,MSR_FP_BIT ; Propagate guest FP rlwimi r4,r6,0,MSR_VEC_BIT,MSR_VEC_BIT ; Propagate guest Vector beq ufpnokey ; Branch if not key switch mr r2,r7 ; Save r7 rlwimi r7,r5,32+vmmKeyb-userProtKeybit,userProtKeybit,userProtKeybit ; Set the protection key cmpw cr0,r7,r2 ; Is userProtKeybit changed? beq ufpnokey ; No, go to ResumeGuest_nokey mr r5,r3 ; Get the per_proc area stw r7,spcFlags(r3) ; Update the special flags bt++ pf64Bitb,ufpsave64 ; Go do this on a 64-bit machine... lwz r3,next_savearea+4(r5) ; Get the exception save area stw r8,saver8+4(r3) ; Save r8 stw r9,saver9+4(r3) ; Save r9 stw r10,saver10+4(r3) ; Save r10 stw r11,saver11+4(r3) ; Save r11 stw r12,saver12+4(r3) ; Save r12 stw r13,saver13+4(r3) ; Save r12 stw r14,saver14+4(r3) ; Save r14 stw r15,saver15+4(r3) ; Save r15 stw r16,saver16+4(r3) ; Save r16 stw r17,saver17+4(r3) ; Save r17 stw r18,saver18+4(r3) ; Save r18 stw r19,saver19+4(r3) ; Save r19 stw r20,saver20+4(r3) ; Save r20 stw r21,saver21+4(r3) ; Save r21 stw r22,saver22+4(r3) ; Save r22 stw r23,saver23+4(r3) ; Save r23 stw r24,saver24+4(r3) ; Save r24 stw r25,saver25+4(r3) ; Save r25 stw r26,saver26+4(r3) ; Save r26 stw r27,saver27+4(r3) ; Save r27 stw r28,saver28+4(r3) ; Save r28 stw r29,saver29+4(r3) ; Save r29 stw r30,saver30+4(r3) ; Save r30 stw r31,saver31+4(r3) ; Save r31 b ufpsaveres ; Continue ufpsave64: ld r3,next_savearea(r5) ; Get the exception save area std r8,saver8(r3) ; Save r8 std r9,saver9(r3) ; Save r9 std r10,saver10(r3) ; Save r10 std r11,saver11(r3) ; Save r11 std r12,saver12(r3) ; Save r12 std r13,saver13(r3) ; Save r12 std r14,saver14(r3) ; Save r14 std r15,saver15(r3) ; Save r15 std r16,saver16(r3) ; Save r16 std r17,saver17(r3) ; Save r17 std r18,saver18(r3) ; Save r18 std r19,saver19(r3) ; Save r19 std r20,saver20(r3) ; Save r20 std r21,saver21(r3) ; Save r21 std r22,saver22(r3) ; Save r22 std r23,saver23(r3) ; Save r23 std r24,saver24(r3) ; Save r24 std r25,saver25(r3) ; Save r25 std r26,saver26(r3) ; Save r26 std r27,saver27(r3) ; Save r27 std r28,saver28(r3) ; Save r28 std r29,saver29(r3) ; Save r29 mfxer r2 ; Get xer std r30,saver30(r3) ; Save r30 std r31,saver31(r3) ; Save r31 std r2,savexer(r3) ; Save xer ufpsaveres: mflr r20 ; Get lr li r2,1 ; Set to 1 stw r7,spcFlags(r5) ; Update the special flags mr r13,r3 ; Set current savearea mr r21,r4 ; Save r4 sth r2,ppInvSeg(r5) ; Force a reload of the SRs mr r29,r5 ; Get the per_proc area mr r3,r4 ; Set MSR value we going to bl EXT(switchSegs) ; Go handle the segment registers/STB mr r3,r13 ; Set current savearea mr r4,r21 ; Restore r4 mtlr r20 ; Set lr bt++ pf64Bitb,ufprestore64 ; Go do this on a 64-bit machine... lwz r8,saver8+4(r3) ; Load r8 lwz r9,saver9+4(r3) ; Load r9 lwz r10,saver10+4(r3) ; Load r10 lwz r11,saver11+4(r3) ; Load r11 lwz r12,saver12+4(r3) ; Load r12 lwz r13,saver13+4(r3) ; Load r12 lwz r14,saver14+4(r3) ; Load r14 lwz r15,saver15+4(r3) ; Load r15 lwz r16,saver16+4(r3) ; Load r16 lwz r17,saver17+4(r3) ; Load r17 lwz r18,saver18+4(r3) ; Load r18 lwz r19,saver19+4(r3) ; Load r19 lwz r20,saver20+4(r3) ; Load r20 lwz r21,saver21+4(r3) ; Load r21 lwz r22,saver22+4(r3) ; Load r22 lwz r23,saver23+4(r3) ; Load r23 lwz r24,saver24+4(r3) ; Load r24 lwz r25,saver25+4(r3) ; Load r25 lwz r26,saver26+4(r3) ; Load r26 lwz r27,saver27+4(r3) ; Load r27 lwz r28,saver28+4(r3) ; Load r28 lwz r29,saver29+4(r3) ; Load r29 lwz r30,saver30+4(r3) ; Load r30 lwz r31,saver31+4(r3) ; Load r31 b ufpnokey ; Continue ufprestore64: ld r2,savexer(r3) ; Load xer ld r8,saver8(r3) ; Load r8 ld r9,saver9(r3) ; Load r9 ld r10,saver10(r3) ; Load r10 mtxer r2 ; Restore xer ld r11,saver11(r3) ; Load r11 ld r12,saver12(r3) ; Load r12 ld r13,saver13(r3) ; Load r12 ld r14,saver14(r3) ; Load r14 ld r15,saver15(r3) ; Load r15 ld r16,saver16(r3) ; Load r16 ld r17,saver17(r3) ; Load r17 ld r18,saver18(r3) ; Load r18 ld r19,saver19(r3) ; Load r19 ld r20,saver20(r3) ; Load r20 ld r21,saver21(r3) ; Load r21 ld r22,saver22(r3) ; Load r22 ld r23,saver23(r3) ; Load r23 ld r24,saver24(r3) ; Load r24 ld r25,saver25(r3) ; Load r25 ld r26,saver26(r3) ; Load r26 ld r27,saver27(r3) ; Load r27 ld r28,saver28(r3) ; Load r28 ld r29,saver29(r3) ; Load r29 ld r30,saver30(r3) ; Load r30 ld r31,saver31(r3) ; Load r31 ufpnokey: mfsprg r3,0 ; Get the per_proc area mtsrr1 r4 ; Set srr1 lwz r0,famguestr0(r13) ; Load r0 lwz r1,famguestr1(r13) ; Load r1 lwz r2,famguestr2(r13) ; Load r2 lwz r3,famguestr3(r13) ; Load r3 lwz r4,famguestr4(r13) ; Load r4 lwz r5,famguestr5(r13) ; Load r5 lwz r6,famguestr6(r13) ; Load r6 lwz r7,famguestr7(r13) ; Load r7 ufpVMret: mfsprg r13,2 ; Restore R13 bt++ pf64Bitb,ufpVMrfi64 ; Go do this on a 64-bit machine... mtcrf 0xFF,r11 ; Restore CR mfsprg r11,3 ; Restore R11 rfi ; All done, go back... ufpVMrfi64: mtcrf 0xFF,r11 ; Restore CR mfsprg r11,3 ; Restore R11 rfid ufpX: ; here if virtual machine is 64-bit bt cr5_eq,ufpXResumeGuest ; if kvmmResumeGuest, branch to ResumeGuest cmplwi cr5,r4,7 ; Is first arg in range 0-7? bgt cr5,ufpXVMret ; Return if not in the range slwi r4,r4,3 ; multiply index by 8 la r3,famguestXr0(r13) ; Load the base address bt cr2_eq,ufpXSetGuestReg ; Set/get selector ; ufpXGetGuestReg ldx r3,r4,r3 ; Load the guest register b ufpXVMret ; Return ufpXSetGuestReg: stdx r5,r4,r3 ; Update the guest register li r3,0 ; Set return value b ufpXVMret ; Return ufpXResumeGuest: lwz r7,spcFlags(r3) ; Pick up the special flags mtsrr0 r4 ; Set srr0 rlwinm. r6,r6,0,vmmKeyb,vmmKeyb ; Check vmmKeyb in maskCntrl rlwinm r7,r7,0,FamVMmodebit+1,FamVMmodebit-1 ; Clear FamVMmodebit stw r7,spcFlags(r3) ; Update the special flags mfsrr1 r6 ; Get the current MSR value ld r4,famguestXmsr(r13) ; Load guest srr1 lis r1,hi16(MSR_IMPORT_BITS) ; Get the MSR bits that are controllable by user ori r1,r1,lo16(MSR_IMPORT_BITS) ; Get the rest of the MSR bits that are controllable by user and r4,r4,r1 ; Keep only the controllable bits oris r4,r4,hi16(MSR_EXPORT_MASK_SET) ; Force on the required bits ori r4,r4,lo16(MSR_EXPORT_MASK_SET) ; Force on the other required bits rlwimi r4,r6,0,MSR_FP_BIT,MSR_FP_BIT ; Propagate guest FP rlwimi r4,r6,0,MSR_VEC_BIT,MSR_VEC_BIT ; Propagate guest Vector beq ufpXnokey ; Branch if not key switch mr r2,r7 ; Save r7 rlwimi r7,r5,32+vmmKeyb-userProtKeybit,userProtKeybit,userProtKeybit ; Set the protection key cmpw cr0,r7,r2 ; Is userProtKeybit changed? beq ufpXnokey ; No, go to ResumeGuest_nokey mr r5,r3 ; Get the per_proc area stw r7,spcFlags(r3) ; Update the special flags ld r3,next_savearea(r5) ; Get the exception save area std r8,saver8(r3) ; Save r8 std r9,saver9(r3) ; Save r9 std r10,saver10(r3) ; Save r10 std r11,saver11(r3) ; Save r11 std r12,saver12(r3) ; Save r12 std r13,saver13(r3) ; Save r12 std r14,saver14(r3) ; Save r14 std r15,saver15(r3) ; Save r15 std r16,saver16(r3) ; Save r16 std r17,saver17(r3) ; Save r17 std r18,saver18(r3) ; Save r18 std r19,saver19(r3) ; Save r19 std r20,saver20(r3) ; Save r20 std r21,saver21(r3) ; Save r21 std r22,saver22(r3) ; Save r22 std r23,saver23(r3) ; Save r23 std r24,saver24(r3) ; Save r24 std r25,saver25(r3) ; Save r25 std r26,saver26(r3) ; Save r26 std r27,saver27(r3) ; Save r27 std r28,saver28(r3) ; Save r28 std r29,saver29(r3) ; Save r29 mfxer r2 ; Get xer std r30,saver30(r3) ; Save r30 std r31,saver31(r3) ; Save r31 std r2,savexer(r3) ; Save xer mflr r20 ; Get lr li r2,1 ; Set to 1 stw r7,spcFlags(r5) ; Update the special flags mr r13,r3 ; Set current savearea mr r21,r4 ; Save r4 sth r2,ppInvSeg(r5) ; Force a reload of the SRs mr r29,r5 ; Get the per_proc area mr r3,r4 ; Set MSR value we going to bl EXT(switchSegs) ; Go handle the segment registers/STB mr r3,r13 ; Set current savearea mr r4,r21 ; Restore r4 mtlr r20 ; Set lr ld r2,savexer(r3) ; Load xer ld r8,saver8(r3) ; Load r8 ld r9,saver9(r3) ; Load r9 ld r10,saver10(r3) ; Load r10 mtxer r2 ; Restore xer ld r11,saver11(r3) ; Load r11 ld r12,saver12(r3) ; Load r12 ld r13,saver13(r3) ; Load r12 ld r14,saver14(r3) ; Load r14 ld r15,saver15(r3) ; Load r15 ld r16,saver16(r3) ; Load r16 ld r17,saver17(r3) ; Load r17 ld r18,saver18(r3) ; Load r18 ld r19,saver19(r3) ; Load r19 ld r20,saver20(r3) ; Load r20 ld r21,saver21(r3) ; Load r21 ld r22,saver22(r3) ; Load r22 ld r23,saver23(r3) ; Load r23 ld r24,saver24(r3) ; Load r24 ld r25,saver25(r3) ; Load r25 ld r26,saver26(r3) ; Load r26 ld r27,saver27(r3) ; Load r27 ld r28,saver28(r3) ; Load r28 ld r29,saver29(r3) ; Load r29 ld r30,saver30(r3) ; Load r30 ld r31,saver31(r3) ; Load r31 ufpXnokey: mtsrr1 r4 ; Set srr1 ld r0,famguestXr0(r13) ; Load r0 ld r1,famguestXr1(r13) ; Load r1 ld r2,famguestXr2(r13) ; Load r2 ld r3,famguestXr3(r13) ; Load r3 ld r4,famguestXr4(r13) ; Load r4 ld r5,famguestXr5(r13) ; Load r5 ld r6,famguestXr6(r13) ; Load r6 ld r7,famguestXr7(r13) ; Load r7 ufpXVMret: mfsprg r13,2 ; Restore R13 mtcrf 0xFF,r11 ; Restore CR mfsprg r11,3 ; Restore R11 rfid