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[/] [or1k/] [trunk/] [linux/] [linux-2.4/] [arch/] [ppc64/] [kernel/] [mf.c] - Rev 1275
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/* * mf.c * Copyright (C) 2001 Troy D. Armstrong IBM Corporation * * This modules exists as an interface between a Linux secondary partition * running on an iSeries and the primary partition's Virtual Service * Processor (VSP) object. The VSP has final authority over powering on/off * all partitions in the iSeries. It also provides miscellaneous low-level * machine facility type operations. * * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include <asm/iSeries/mf.h> #include <linux/types.h> #include <linux/errno.h> #include <linux/kernel.h> #include <linux/init.h> #include <linux/mm.h> #include <asm/iSeries/HvLpConfig.h> #include <linux/slab.h> #include <linux/delay.h> #include <asm/nvram.h> #include <asm/time.h> #include <asm/iSeries/ItSpCommArea.h> #include <asm/iSeries/mf_proc.h> #include <asm/iSeries/iSeries_proc.h> #include <asm/uaccess.h> #include <linux/pci.h> extern struct pci_dev * iSeries_vio_dev; /* * This is the structure layout for the Machine Facilities LPAR event * flows. */ struct VspCmdData; struct CeMsgData; union SafeCast { u64 ptrAsU64; void *ptr; }; typedef void (*CeMsgCompleteHandler)( void *token, struct CeMsgData *vspCmdRsp ); struct CeMsgCompleteData { CeMsgCompleteHandler xHdlr; void *xToken; }; struct VspRspData { struct semaphore *xSemaphore; struct VspCmdData *xResponse; }; struct IoMFLpEvent { struct HvLpEvent xHvLpEvent; u16 xSubtypeRc; u16 xRsvd1; u32 xRsvd2; union { struct AllocData { u16 xSize; u16 xType; u32 xCount; u16 xRsvd3; u8 xRsvd4; HvLpIndex xTargetLp; } xAllocData; struct CeMsgData { u8 xCEMsg[12]; char xReserved[4]; struct CeMsgCompleteData *xToken; } xCEMsgData; struct VspCmdData { union SafeCast xTokenUnion; u16 xCmd; HvLpIndex xLpIndex; u8 xRc; u32 xReserved1; union VspCmdSubData { struct { u64 xState; } xGetStateOut; struct { u64 xIplType; } xGetIplTypeOut, xFunction02SelectIplTypeIn; struct { u64 xIplMode; } xGetIplModeOut, xFunction02SelectIplModeIn; struct { u64 xPage[4]; } xGetSrcHistoryIn; struct { u64 xFlag; } xGetAutoIplWhenPrimaryIplsOut, xSetAutoIplWhenPrimaryIplsIn, xWhiteButtonPowerOffIn, xFunction08FastPowerOffIn, xIsSpcnRackPowerIncompleteOut; struct { u64 xToken; u64 xAddressType; u64 xSide; u32 xTransferLength; u32 xOffset; } xSetKernelImageIn, xGetKernelImageIn, xSetKernelCmdLineIn, xGetKernelCmdLineIn; struct { u32 xTransferLength; } xGetKernelImageOut,xGetKernelCmdLineOut; u8 xReserved2[80]; } xSubData; } xVspCmd; } xUnion; }; /* * All outgoing event traffic is kept on a FIFO queue. The first * pointer points to the one that is outstanding, and all new * requests get stuck on the end. Also, we keep a certain number of * preallocated stack elements so that we can operate very early in * the boot up sequence (before kmalloc is ready). */ struct StackElement { struct StackElement * next; struct IoMFLpEvent event; MFCompleteHandler hdlr; char dmaData[72]; unsigned dmaDataLength; unsigned remoteAddress; }; static spinlock_t spinlock; static struct StackElement * head = NULL; static struct StackElement * tail = NULL; static struct StackElement * avail = NULL; static struct StackElement prealloc[16]; /* * Put a stack element onto the available queue, so it can get reused. * Attention! You must have the spinlock before calling! */ void free( struct StackElement * element ) { if ( element != NULL ) { element->next = avail; avail = element; } } /* * Enqueue the outbound event onto the stack. If the queue was * empty to begin with, we must also issue it via the Hypervisor * interface. There is a section of code below that will touch * the first stack pointer without the protection of the spinlock. * This is OK, because we know that nobody else will be modifying * the first pointer when we do this. */ static int signalEvent( struct StackElement * newElement ) { int rc = 0; unsigned long flags; int go = 1; struct StackElement * element; HvLpEvent_Rc hvRc; /* enqueue the event */ if ( newElement != NULL ) { spin_lock_irqsave( &spinlock, flags ); if ( head == NULL ) head = newElement; else { go = 0; tail->next = newElement; } newElement->next = NULL; tail = newElement; spin_unlock_irqrestore( &spinlock, flags ); } /* send the event */ while ( go ) { go = 0; /* any DMA data to send beforehand? */ if ( head->dmaDataLength > 0 ) HvCallEvent_dmaToSp( head->dmaData, head->remoteAddress, head->dmaDataLength, HvLpDma_Direction_LocalToRemote ); hvRc = HvCallEvent_signalLpEvent(&head->event.xHvLpEvent); if ( hvRc != HvLpEvent_Rc_Good ) { printk( KERN_ERR "mf.c: HvCallEvent_signalLpEvent() failed with %d\n", (int)hvRc ); spin_lock_irqsave( &spinlock, flags ); element = head; head = head->next; if ( head != NULL ) go = 1; spin_unlock_irqrestore( &spinlock, flags ); if ( element == newElement ) rc = -EIO; else { if ( element->hdlr != NULL ) { union SafeCast mySafeCast; mySafeCast.ptrAsU64 = element->event.xHvLpEvent.xCorrelationToken; (*element->hdlr)( mySafeCast.ptr, -EIO ); } } spin_lock_irqsave( &spinlock, flags ); free( element ); spin_unlock_irqrestore( &spinlock, flags ); } } return rc; } /* * Allocate a new StackElement structure, and initialize it. */ static struct StackElement * newStackElement( void ) { struct StackElement * newElement = NULL; HvLpIndex primaryLp = HvLpConfig_getPrimaryLpIndex(); unsigned long flags; if ( newElement == NULL ) { spin_lock_irqsave( &spinlock, flags ); if ( avail != NULL ) { newElement = avail; avail = avail->next; } spin_unlock_irqrestore( &spinlock, flags ); } if ( newElement == NULL ) newElement = kmalloc(sizeof(struct StackElement),GFP_ATOMIC); if ( newElement == NULL ) { printk( KERN_ERR "mf.c: unable to kmalloc %ld bytes\n", sizeof(struct StackElement) ); return NULL; } memset( newElement, 0, sizeof(struct StackElement) ); newElement->event.xHvLpEvent.xFlags.xValid = 1; newElement->event.xHvLpEvent.xFlags.xAckType = HvLpEvent_AckType_ImmediateAck; newElement->event.xHvLpEvent.xFlags.xAckInd = HvLpEvent_AckInd_DoAck; newElement->event.xHvLpEvent.xFlags.xFunction = HvLpEvent_Function_Int; newElement->event.xHvLpEvent.xType = HvLpEvent_Type_MachineFac; newElement->event.xHvLpEvent.xSourceLp = HvLpConfig_getLpIndex(); newElement->event.xHvLpEvent.xTargetLp = primaryLp; newElement->event.xHvLpEvent.xSizeMinus1 = sizeof(newElement->event)-1; newElement->event.xHvLpEvent.xRc = HvLpEvent_Rc_Good; newElement->event.xHvLpEvent.xSourceInstanceId = HvCallEvent_getSourceLpInstanceId(primaryLp,HvLpEvent_Type_MachineFac); newElement->event.xHvLpEvent.xTargetInstanceId = HvCallEvent_getTargetLpInstanceId(primaryLp,HvLpEvent_Type_MachineFac); return newElement; } static int signalVspInstruction( struct VspCmdData *vspCmd ) { struct StackElement * newElement = newStackElement(); int rc = 0; struct VspRspData response; DECLARE_MUTEX_LOCKED(Semaphore); response.xSemaphore = &Semaphore; response.xResponse = vspCmd; if ( newElement == NULL ) rc = -ENOMEM; else { newElement->event.xHvLpEvent.xSubtype = 6; newElement->event.xHvLpEvent.x.xSubtypeData = ('M'<<24)+('F'<<16)+('V'<<8)+('I'<<0); newElement->event.xUnion.xVspCmd.xTokenUnion.ptr = &response; newElement->event.xUnion.xVspCmd.xCmd = vspCmd->xCmd; newElement->event.xUnion.xVspCmd.xLpIndex = HvLpConfig_getLpIndex(); newElement->event.xUnion.xVspCmd.xRc = 0xFF; newElement->event.xUnion.xVspCmd.xReserved1 = 0; memcpy(&(newElement->event.xUnion.xVspCmd.xSubData),&(vspCmd->xSubData), sizeof(vspCmd->xSubData)); mb(); rc = signalEvent(newElement); } if (rc == 0) { down(&Semaphore); } return rc; } /* * Send a 12-byte CE message to the primary partition VSP object */ static int signalCEMsg( char * ceMsg, void * token ) { struct StackElement * newElement = newStackElement(); int rc = 0; if ( newElement == NULL ) rc = -ENOMEM; else { newElement->event.xHvLpEvent.xSubtype = 0; newElement->event.xHvLpEvent.x.xSubtypeData = ('M'<<24)+('F'<<16)+('C'<<8)+('E'<<0); memcpy( newElement->event.xUnion.xCEMsgData.xCEMsg, ceMsg, 12 ); newElement->event.xUnion.xCEMsgData.xToken = token; rc = signalEvent(newElement); } return rc; } /* * Send a 12-byte CE message and DMA data to the primary partition VSP object */ static int dmaAndSignalCEMsg( char * ceMsg, void * token, void * dmaData, unsigned dmaDataLength, unsigned remoteAddress ) { struct StackElement * newElement = newStackElement(); int rc = 0; if ( newElement == NULL ) rc = -ENOMEM; else { newElement->event.xHvLpEvent.xSubtype = 0; newElement->event.xHvLpEvent.x.xSubtypeData = ('M'<<24)+('F'<<16)+('C'<<8)+('E'<<0); memcpy( newElement->event.xUnion.xCEMsgData.xCEMsg, ceMsg, 12 ); newElement->event.xUnion.xCEMsgData.xToken = token; memcpy( newElement->dmaData, dmaData, dmaDataLength ); newElement->dmaDataLength = dmaDataLength; newElement->remoteAddress = remoteAddress; rc = signalEvent(newElement); } return rc; } /* * Initiate a nice (hopefully) shutdown of Linux. We simply are * going to try and send the init process a SIGINT signal. If * this fails (why?), we'll simply force it off in a not-so-nice * manner. */ static int shutdown( void ) { extern int cad_pid; /* from kernel/sys.c */ int rc = kill_proc(cad_pid,SIGINT,1); if ( rc ) { printk( KERN_ALERT "mf.c: SIGINT to init failed (%d), hard shutdown commencing\n", rc ); mf_powerOff(); } else printk( KERN_INFO "mf.c: init has been successfully notified to proceed with shutdown\n" ); return rc; } /* * The primary partition VSP object is sending us a new * event flow. Handle it... */ static void intReceived( struct IoMFLpEvent * event ) { int freeIt = 0; struct StackElement * two = NULL; /* ack the interrupt */ event->xHvLpEvent.xRc = HvLpEvent_Rc_Good; HvCallEvent_ackLpEvent( &event->xHvLpEvent ); /* process interrupt */ switch( event->xHvLpEvent.xSubtype ) { case 0: /* CE message */ switch( event->xUnion.xCEMsgData.xCEMsg[3] ) { case 0x5B: /* power control notification */ if ( (event->xUnion.xCEMsgData.xCEMsg[5]&0x20) != 0 ) { printk( KERN_INFO "mf.c: Commencing partition shutdown\n" ); if ( shutdown() == 0 ) signalCEMsg( "\x00\x00\x00\xDB\x00\x00\x00\x00\x00\x00\x00\x00", NULL ); } break; case 0xC0: /* get time */ { if ( (head != NULL) && ( head->event.xUnion.xCEMsgData.xCEMsg[3] == 0x40 ) ) { freeIt = 1; if ( head->event.xUnion.xCEMsgData.xToken != 0 ) { CeMsgCompleteHandler xHdlr = head->event.xUnion.xCEMsgData.xToken->xHdlr; void * token = head->event.xUnion.xCEMsgData.xToken->xToken; if (xHdlr != NULL) (*xHdlr)( token, &(event->xUnion.xCEMsgData) ); } } } break; } /* remove from queue */ if ( freeIt == 1 ) { unsigned long flags; spin_lock_irqsave( &spinlock, flags ); if ( head != NULL ) { struct StackElement *oldHead = head; head = head->next; two = head; free( oldHead ); } spin_unlock_irqrestore( &spinlock, flags ); } /* send next waiting event */ if ( two != NULL ) signalEvent( NULL ); break; case 1: /* IT sys shutdown */ printk( KERN_INFO "mf.c: Commencing system shutdown\n" ); shutdown(); break; } } /* * The primary partition VSP object is acknowledging the receipt * of a flow we sent to them. If there are other flows queued * up, we must send another one now... */ static void ackReceived( struct IoMFLpEvent * event ) { unsigned long flags; struct StackElement * two = NULL; unsigned long freeIt = 0; /* handle current event */ if ( head != NULL ) { switch( event->xHvLpEvent.xSubtype ) { case 0: /* CE msg */ if ( event->xUnion.xCEMsgData.xCEMsg[3] == 0x40 ) { if ( event->xUnion.xCEMsgData.xCEMsg[2] != 0 ) { freeIt = 1; if ( head->event.xUnion.xCEMsgData.xToken != 0 ) { CeMsgCompleteHandler xHdlr = head->event.xUnion.xCEMsgData.xToken->xHdlr; void * token = head->event.xUnion.xCEMsgData.xToken->xToken; if (xHdlr != NULL) (*xHdlr)( token, &(event->xUnion.xCEMsgData) ); } } } else { freeIt = 1; } break; case 4: /* allocate */ case 5: /* deallocate */ if ( head->hdlr != NULL ) { union SafeCast mySafeCast; mySafeCast.ptrAsU64 = event->xHvLpEvent.xCorrelationToken; (*head->hdlr)( mySafeCast.ptr, event->xUnion.xAllocData.xCount ); } freeIt = 1; break; case 6: { struct VspRspData *rsp = (struct VspRspData *)event->xUnion.xVspCmd.xTokenUnion.ptr; if (rsp != NULL) { if (rsp->xResponse != NULL) memcpy(rsp->xResponse, &(event->xUnion.xVspCmd), sizeof(event->xUnion.xVspCmd)); if (rsp->xSemaphore != NULL) up(rsp->xSemaphore); } else { printk( KERN_ERR "mf.c: no rsp\n"); } freeIt = 1; } break; } } else printk( KERN_ERR "mf.c: stack empty for receiving ack\n" ); /* remove from queue */ spin_lock_irqsave( &spinlock, flags ); if (( head != NULL ) && ( freeIt == 1 )) { struct StackElement *oldHead = head; head = head->next; two = head; free( oldHead ); } spin_unlock_irqrestore( &spinlock, flags ); /* send next waiting event */ if ( two != NULL ) signalEvent( NULL ); } /* * This is the generic event handler we are registering with * the Hypervisor. Ensure the flows are for us, and then * parse it enough to know if it is an interrupt or an * acknowledge. */ static void hvHandler( struct HvLpEvent * event, struct pt_regs * regs ) { if ( (event != NULL) && (event->xType == HvLpEvent_Type_MachineFac) ) { switch( event->xFlags.xFunction ) { case HvLpEvent_Function_Ack: ackReceived( (struct IoMFLpEvent *)event ); break; case HvLpEvent_Function_Int: intReceived( (struct IoMFLpEvent *)event ); break; default: printk( KERN_ERR "mf.c: non ack/int event received\n" ); break; } } else printk( KERN_ERR "mf.c: alien event received\n" ); } /* * Global kernel interface to allocate and seed events into the * Hypervisor. */ void mf_allocateLpEvents( HvLpIndex targetLp, HvLpEvent_Type type, unsigned size, unsigned count, MFCompleteHandler hdlr, void * userToken ) { struct StackElement * newElement = newStackElement(); int rc = 0; if ( newElement == NULL ) rc = -ENOMEM; else { union SafeCast mine; mine.ptr = userToken; newElement->event.xHvLpEvent.xSubtype = 4; newElement->event.xHvLpEvent.xCorrelationToken = mine.ptrAsU64; newElement->event.xHvLpEvent.x.xSubtypeData = ('M'<<24)+('F'<<16)+('M'<<8)+('A'<<0); newElement->event.xUnion.xAllocData.xTargetLp = targetLp; newElement->event.xUnion.xAllocData.xType = type; newElement->event.xUnion.xAllocData.xSize = size; newElement->event.xUnion.xAllocData.xCount = count; newElement->hdlr = hdlr; rc = signalEvent(newElement); } if ( (rc != 0) && (hdlr != NULL) ) (*hdlr)( userToken, rc ); } /* * Global kernel interface to unseed and deallocate events already in * Hypervisor. */ void mf_deallocateLpEvents( HvLpIndex targetLp, HvLpEvent_Type type, unsigned count, MFCompleteHandler hdlr, void * userToken ) { struct StackElement * newElement = newStackElement(); int rc = 0; if ( newElement == NULL ) rc = -ENOMEM; else { union SafeCast mine; mine.ptr = userToken; newElement->event.xHvLpEvent.xSubtype = 5; newElement->event.xHvLpEvent.xCorrelationToken = mine.ptrAsU64; newElement->event.xHvLpEvent.x.xSubtypeData = ('M'<<24)+('F'<<16)+('M'<<8)+('D'<<0); newElement->event.xUnion.xAllocData.xTargetLp = targetLp; newElement->event.xUnion.xAllocData.xType = type; newElement->event.xUnion.xAllocData.xCount = count; newElement->hdlr = hdlr; rc = signalEvent(newElement); } if ( (rc != 0) && (hdlr != NULL) ) (*hdlr)( userToken, rc ); } /* * Global kernel interface to tell the VSP object in the primary * partition to power this partition off. */ void mf_powerOff( void ) { printk( KERN_INFO "mf.c: Down it goes...\n" ); signalCEMsg( "\x00\x00\x00\x4D\x00\x00\x00\x00\x00\x00\x00\x00", NULL ); for (;;); } /* * Global kernel interface to tell the VSP object in the primary * partition to reboot this partition. */ void mf_reboot( void ) { printk( KERN_INFO "mf.c: Preparing to bounce...\n" ); signalCEMsg( "\x00\x00\x00\x4E\x00\x00\x00\x00\x00\x00\x00\x00", NULL ); for (;;); } /* * Display a single word SRC onto the VSP control panel. */ void mf_displaySrc( u32 word ) { u8 ce[12]; memcpy( ce, "\x00\x00\x00\x4A\x00\x00\x00\x01\x00\x00\x00\x00", 12 ); ce[8] = word>>24; ce[9] = word>>16; ce[10] = word>>8; ce[11] = word; signalCEMsg( ce, NULL ); } /* * Display a single word SRC of the form "PROGXXXX" on the VSP control panel. */ void mf_displayProgress( u16 value ) { u8 ce[12]; u8 src[72]; memcpy( ce, "\x00\x00\x04\x4A\x00\x00\x00\x48\x00\x00\x00\x00", 12 ); memcpy( src, "\x01\x00\x00\x01" "\x00\x00\x00\x00" "\x00\x00\x00\x00" "\x00\x00\x00\x00" "\x00\x00\x00\x00" "\x00\x00\x00\x00" "\x00\x00\x00\x00" "\x00\x00\x00\x00" "\x00\x00\x00\x00" "\x00\x00\x00\x00" "PROGxxxx" " ", 72 ); src[6] = value>>8; src[7] = value&255; src[44] = "0123456789ABCDEF"[(value>>12)&15]; src[45] = "0123456789ABCDEF"[(value>>8)&15]; src[46] = "0123456789ABCDEF"[(value>>4)&15]; src[47] = "0123456789ABCDEF"[value&15]; dmaAndSignalCEMsg( ce, NULL, src, sizeof(src), 9*64*1024 ); } /* * Clear the VSP control panel. Used to "erase" an SRC that was * previously displayed. */ void mf_clearSrc( void ) { signalCEMsg( "\x00\x00\x00\x4B\x00\x00\x00\x00\x00\x00\x00\x00", NULL ); } /* * Initialization code here. */ void mf_init( void ) { int i; /* initialize */ spin_lock_init( &spinlock ); for ( i = 0; i < sizeof(prealloc)/sizeof(*prealloc); ++i ) free( &prealloc[i] ); HvLpEvent_registerHandler( HvLpEvent_Type_MachineFac, &hvHandler ); /* virtual continue ack */ signalCEMsg( "\x00\x00\x00\x57\x00\x00\x00\x00\x00\x00\x00\x00", NULL ); /* initialization complete */ printk( KERN_NOTICE "mf.c: iSeries Linux LPAR Machine Facilities initialized\n" ); iSeries_proc_callback(&mf_proc_init); } void mf_setSide(char side) { int rc = 0; u64 newSide = 0; struct VspCmdData myVspCmd; memset(&myVspCmd, 0, sizeof(myVspCmd)); if (side == 'A') newSide = 0; else if (side == 'B') newSide = 1; else if (side == 'C') newSide = 2; else newSide = 3; myVspCmd.xSubData.xFunction02SelectIplTypeIn.xIplType = newSide; myVspCmd.xCmd = 10; rc = signalVspInstruction(&myVspCmd); } char mf_getSide(void) { char returnValue = ' '; int rc = 0; struct VspCmdData myVspCmd; memset(&myVspCmd, 0, sizeof(myVspCmd)); myVspCmd.xCmd = 2; myVspCmd.xSubData.xFunction02SelectIplTypeIn.xIplType = 0; mb(); rc = signalVspInstruction(&myVspCmd); if (rc != 0) { return returnValue; } else { if (myVspCmd.xRc == 0) { if (myVspCmd.xSubData.xGetIplTypeOut.xIplType == 0) returnValue = 'A'; else if (myVspCmd.xSubData.xGetIplTypeOut.xIplType == 1) returnValue = 'B'; else if (myVspCmd.xSubData.xGetIplTypeOut.xIplType == 2) returnValue = 'C'; else returnValue = 'D'; } } return returnValue; } void mf_getSrcHistory(char *buffer, int size) { /* struct IplTypeReturnStuff returnStuff; struct StackElement * newElement = newStackElement(); int rc = 0; char *pages[4]; pages[0] = kmalloc(4096, GFP_ATOMIC); pages[1] = kmalloc(4096, GFP_ATOMIC); pages[2] = kmalloc(4096, GFP_ATOMIC); pages[3] = kmalloc(4096, GFP_ATOMIC); if (( newElement == NULL ) || (pages[0] == NULL) || (pages[1] == NULL) || (pages[2] == NULL) || (pages[3] == NULL)) rc = -ENOMEM; else { returnStuff.xType = 0; returnStuff.xRc = 0; returnStuff.xDone = 0; newElement->event.xHvLpEvent.xSubtype = 6; newElement->event.xHvLpEvent.x.xSubtypeData = ('M'<<24)+('F'<<16)+('V'<<8)+('I'<<0); newElement->event.xUnion.xVspCmd.xEvent = &returnStuff; newElement->event.xUnion.xVspCmd.xCmd = 4; newElement->event.xUnion.xVspCmd.xLpIndex = HvLpConfig_getLpIndex(); newElement->event.xUnion.xVspCmd.xRc = 0xFF; newElement->event.xUnion.xVspCmd.xReserved1 = 0; newElement->event.xUnion.xVspCmd.xSubData.xGetSrcHistoryIn.xPage[0] = (0x8000000000000000ULL | virt_to_absolute((unsigned long)pages[0])); newElement->event.xUnion.xVspCmd.xSubData.xGetSrcHistoryIn.xPage[1] = (0x8000000000000000ULL | virt_to_absolute((unsigned long)pages[1])); newElement->event.xUnion.xVspCmd.xSubData.xGetSrcHistoryIn.xPage[2] = (0x8000000000000000ULL | virt_to_absolute((unsigned long)pages[2])); newElement->event.xUnion.xVspCmd.xSubData.xGetSrcHistoryIn.xPage[3] = (0x8000000000000000ULL | virt_to_absolute((unsigned long)pages[3])); mb(); rc = signalEvent(newElement); } if (rc != 0) { return; } else { while (returnStuff.xDone != 1) { udelay(10); } if (returnStuff.xRc == 0) { memcpy(buffer, pages[0], size); } } kfree(pages[0]); kfree(pages[1]); kfree(pages[2]); kfree(pages[3]);*/ } void mf_setCmdLine(const char *cmdline, int size, u64 side) { struct VspCmdData myVspCmd; int rc = 0; dma_addr_t dma_addr = 0; char *page = pci_alloc_consistent(iSeries_vio_dev, size, &dma_addr); if (page == NULL) { printk(KERN_ERR "mf.c: couldn't allocate memory to set command line\n"); return; } copy_from_user(page, cmdline, size); memset(&myVspCmd, 0, sizeof(myVspCmd)); myVspCmd.xCmd = 31; myVspCmd.xSubData.xSetKernelCmdLineIn.xToken = dma_addr; myVspCmd.xSubData.xSetKernelCmdLineIn.xAddressType = HvLpDma_AddressType_TceIndex; myVspCmd.xSubData.xSetKernelCmdLineIn.xSide = side; myVspCmd.xSubData.xSetKernelCmdLineIn.xTransferLength = size; mb(); rc = signalVspInstruction(&myVspCmd); pci_free_consistent(iSeries_vio_dev, size, page, dma_addr); } int mf_getCmdLine(char *cmdline, int *size, u64 side) { struct VspCmdData myVspCmd; int rc = 0; int len = *size; dma_addr_t dma_addr = pci_map_single(iSeries_vio_dev, cmdline, *size, PCI_DMA_FROMDEVICE); memset(cmdline, 0, *size); memset(&myVspCmd, 0, sizeof(myVspCmd)); myVspCmd.xCmd = 33; myVspCmd.xSubData.xGetKernelCmdLineIn.xToken = dma_addr; myVspCmd.xSubData.xGetKernelCmdLineIn.xAddressType = HvLpDma_AddressType_TceIndex; myVspCmd.xSubData.xGetKernelCmdLineIn.xSide = side; myVspCmd.xSubData.xGetKernelCmdLineIn.xTransferLength = *size; mb(); rc = signalVspInstruction(&myVspCmd); if ( ! rc ) { if (myVspCmd.xRc == 0) { len = myVspCmd.xSubData.xGetKernelCmdLineOut.xTransferLength; } /* else { memcpy(cmdline, "Bad cmdline", 11); } */ } pci_unmap_single(iSeries_vio_dev, dma_addr, *size, PCI_DMA_FROMDEVICE); return len; } int mf_setVmlinuxChunk(const char *buffer, int size, int offset, u64 side) { struct VspCmdData myVspCmd; int rc = 0; dma_addr_t dma_addr = 0; char *page = pci_alloc_consistent(iSeries_vio_dev, size, &dma_addr); if (page == NULL) { printk(KERN_ERR "mf.c: couldn't allocate memory to set vmlinux chunk\n"); return -ENOMEM; } copy_from_user(page, buffer, size); memset(&myVspCmd, 0, sizeof(myVspCmd)); myVspCmd.xCmd = 30; myVspCmd.xSubData.xGetKernelImageIn.xToken = dma_addr; myVspCmd.xSubData.xGetKernelImageIn.xAddressType = HvLpDma_AddressType_TceIndex; myVspCmd.xSubData.xGetKernelImageIn.xSide = side; myVspCmd.xSubData.xGetKernelImageIn.xOffset = offset; myVspCmd.xSubData.xGetKernelImageIn.xTransferLength = size; mb(); rc = signalVspInstruction(&myVspCmd); if (rc == 0) { if (myVspCmd.xRc == 0) { rc = 0; } else { rc = -ENOMEM; } } pci_free_consistent(iSeries_vio_dev, size, page, dma_addr); return rc; } int mf_getVmlinuxChunk(char *buffer, int *size, int offset, u64 side) { struct VspCmdData myVspCmd; int rc = 0; int len = *size; dma_addr_t dma_addr = pci_map_single(iSeries_vio_dev, buffer, *size, PCI_DMA_FROMDEVICE); memset(buffer, 0, len); memset(&myVspCmd, 0, sizeof(myVspCmd)); myVspCmd.xCmd = 32; myVspCmd.xSubData.xGetKernelImageIn.xToken = dma_addr; myVspCmd.xSubData.xGetKernelImageIn.xAddressType = HvLpDma_AddressType_TceIndex; myVspCmd.xSubData.xGetKernelImageIn.xSide = side; myVspCmd.xSubData.xGetKernelImageIn.xOffset = offset; myVspCmd.xSubData.xGetKernelImageIn.xTransferLength = len; mb(); rc = signalVspInstruction(&myVspCmd); if (rc == 0) { if (myVspCmd.xRc == 0) { *size = myVspCmd.xSubData.xGetKernelImageOut.xTransferLength; } else { rc = -ENOMEM; } } pci_unmap_single(iSeries_vio_dev, dma_addr, len, PCI_DMA_FROMDEVICE); return rc; } int mf_setRtcTime(unsigned long time) { struct rtc_time tm; to_tm(time, &tm); return mf_setRtc( &tm ); } struct RtcTimeData { struct semaphore *xSemaphore; struct CeMsgData xCeMsg; int xRc; }; void getRtcTimeComplete(void * token, struct CeMsgData *ceMsg) { struct RtcTimeData *rtc = (struct RtcTimeData *)token; memcpy(&(rtc->xCeMsg), ceMsg, sizeof(rtc->xCeMsg)); rtc->xRc = 0; up(rtc->xSemaphore); } static unsigned long lastsec = 1; int mf_getRtcTime(unsigned long *time) { /* unsigned long usec, tsec; */ u32 dataWord1 = *((u32 *)(&xSpCommArea.xBcdTimeAtIplStart)); u32 dataWord2 = *(((u32 *)&(xSpCommArea.xBcdTimeAtIplStart)) + 1); int year = 1970; int year1 = ( dataWord1 >> 24 ) & 0x000000FF; int year2 = ( dataWord1 >> 16 ) & 0x000000FF; int sec = ( dataWord1 >> 8 ) & 0x000000FF; int min = dataWord1 & 0x000000FF; int hour = ( dataWord2 >> 24 ) & 0x000000FF; int day = ( dataWord2 >> 8 ) & 0x000000FF; int mon = dataWord2 & 0x000000FF; BCD_TO_BIN(sec); BCD_TO_BIN(min); BCD_TO_BIN(hour); BCD_TO_BIN(day); BCD_TO_BIN(mon); BCD_TO_BIN(year1); BCD_TO_BIN(year2); year = year1 * 100 + year2; *time = mktime(year, mon, day, hour, min, sec); *time += ( jiffies / HZ ); /* Now THIS is a nasty hack! * It ensures that the first two calls to mf_getRtcTime get different * answers. That way the loop in init_time (time.c) will not think * the clock is stuck. */ if ( lastsec ) { *time -= lastsec; --lastsec; } return 0; } int mf_getRtc( struct rtc_time * tm ) { struct CeMsgCompleteData ceComplete; struct RtcTimeData rtcData; int rc = 0; DECLARE_MUTEX_LOCKED(Semaphore); memset(&ceComplete, 0, sizeof(ceComplete)); memset(&rtcData, 0, sizeof(rtcData)); rtcData.xSemaphore = &Semaphore; ceComplete.xHdlr = &getRtcTimeComplete; ceComplete.xToken = (void *)&rtcData; rc = signalCEMsg( "\x00\x00\x00\x40\x00\x00\x00\x00\x00\x00\x00\x00", &ceComplete ); if ( rc == 0 ) { down(&Semaphore); if ( rtcData.xRc == 0) { if ( ( rtcData.xCeMsg.xCEMsg[2] == 0xa9 ) || ( rtcData.xCeMsg.xCEMsg[2] == 0xaf ) ) { /* TOD clock is not set */ tm->tm_sec = 1; tm->tm_min = 1; tm->tm_hour = 1; tm->tm_mday = 10; tm->tm_mon = 8; tm->tm_year = 71; mf_setRtc( tm ); } { u32 dataWord1 = *((u32 *)(rtcData.xCeMsg.xCEMsg+4)); u32 dataWord2 = *((u32 *)(rtcData.xCeMsg.xCEMsg+8)); u8 year = (dataWord1 >> 16 ) & 0x000000FF; u8 sec = ( dataWord1 >> 8 ) & 0x000000FF; u8 min = dataWord1 & 0x000000FF; u8 hour = ( dataWord2 >> 24 ) & 0x000000FF; u8 day = ( dataWord2 >> 8 ) & 0x000000FF; u8 mon = dataWord2 & 0x000000FF; BCD_TO_BIN(sec); BCD_TO_BIN(min); BCD_TO_BIN(hour); BCD_TO_BIN(day); BCD_TO_BIN(mon); BCD_TO_BIN(year); if ( year <= 69 ) year += 100; tm->tm_sec = sec; tm->tm_min = min; tm->tm_hour = hour; tm->tm_mday = day; tm->tm_mon = mon; tm->tm_year = year; } } else { rc = rtcData.xRc; tm->tm_sec = 0; tm->tm_min = 0; tm->tm_hour = 0; tm->tm_mday = 15; tm->tm_mon = 5; tm->tm_year = 52; } tm->tm_wday = 0; tm->tm_yday = 0; tm->tm_isdst = 0; } return rc; } int mf_setRtc(struct rtc_time * tm) { char ceTime[12] = "\x00\x00\x00\x41\x00\x00\x00\x00\x00\x00\x00\x00"; int rc = 0; u8 day, mon, hour, min, sec, y1, y2; unsigned year; year = 1900 + tm->tm_year; y1 = year / 100; y2 = year % 100; sec = tm->tm_sec; min = tm->tm_min; hour = tm->tm_hour; day = tm->tm_mday; mon = tm->tm_mon + 1; BIN_TO_BCD(sec); BIN_TO_BCD(min); BIN_TO_BCD(hour); BIN_TO_BCD(mon); BIN_TO_BCD(day); BIN_TO_BCD(y1); BIN_TO_BCD(y2); ceTime[4] = y1; ceTime[5] = y2; ceTime[6] = sec; ceTime[7] = min; ceTime[8] = hour; ceTime[10] = day; ceTime[11] = mon; rc = signalCEMsg( ceTime, NULL ); return rc; }
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