/*++ Copyright (c) 1990 Microsoft Corporation Copyright (c) 1993 Digital Equipment Corporation Module Name: allproc.c Abstract: This module allocates and initializes kernel resources required to start a new processor, and passes a complete processor state structure to the HAL to obtain a new processor. Author: David N. Cutler 29-Apr-1993 Joe Notarangelo 30-Nov-1993 Environment: Kernel mode only. Revision History: --*/ #include "ki.h" #ifdef ALLOC_PRAGMA #pragma alloc_text(INIT, KeStartAllProcessors) #pragma alloc_text(INIT, KiAllProcessorsStarted) #endif #if defined(KE_MULTINODE) PHALNUMAQUERYNODEAFFINITY KiQueryNodeAffinity; // // Statically preallocate enough KNODE structures to allow MM // to allocate pages by node during system initialization. As // processors are brought online, real KNODE structures are // allocated in the appropriate memory for the node. // // This statically allocated set will be deallocated once the // system is initialized. // #ifdef ALLOC_DATA_PRAGMA #pragma data_seg("INITDATA") #endif KNODE KiNodeInit[MAXIMUM_CCNUMA_NODES]; #endif // // Define macro to round up to 64-byte boundary and define block sizes. // #define ROUND_UP(x) ((sizeof(x) + 64) & (~64)) #define BLOCK1_SIZE ((3 * KERNEL_STACK_SIZE) + PAGE_SIZE) #define BLOCK2_SIZE (ROUND_UP(KPRCB) + ROUND_UP(KNODE) + ROUND_UP(ETHREAD) + 64) // // Macros to compute whether an address is physically addressable. // #if defined(_AXP64_) #define IS_KSEG_ADDRESS(v) \ (((v) >= KSEG43_BASE) && \ ((v) < KSEG43_LIMIT) && \ (KSEG_PFN(v) < ((KSEG2_BASE - KSEG0_BASE) >> PAGE_SHIFT))) #define KSEG_PFN(v) ((ULONG)(((v) - KSEG43_BASE) >> PAGE_SHIFT)) #define KSEG0_ADDRESS(v) (KSEG0_BASE | ((v) - KSEG43_BASE)) #else #define IS_KSEG_ADDRESS(v) (((v) >= KSEG0_BASE) && ((v) < KSEG2_BASE)) #define KSEG_PFN(v) ((ULONG)(((v) - KSEG0_BASE) >> PAGE_SHIFT)) #define KSEG0_ADDRESS(v) (v) #endif // // Define forward referenced prototypes. // VOID KiStartProcessor ( IN PLOADER_PARAMETER_BLOCK Loaderblock ); VOID KeStartAllProcessors( VOID ) /*++ Routine Description: This function is called during phase 1 initialization on the master boot processor to start all of the other registered processors. Arguments: None. Return Value: None. --*/ { #if !defined(NT_UP) ULONG_PTR MemoryBlock1; ULONG_PTR MemoryBlock2; ULONG Number; ULONG PcrPage; PKPRCB Prcb; KPROCESSOR_STATE ProcessorState; struct _RESTART_BLOCK *RestartBlock; BOOLEAN Started; LOGICAL SpecialPoolState; UCHAR NodeNumber = 0; #if defined(KE_MULTINODE) KAFFINITY NewProcessorAffinity; PKNODE Node; NTSTATUS Status; // // If this is a NUMA system, find out the number of nodes and the // processors which belong to each node. // if (KeNumberNodes > 1) { for (NodeNumber = 0; NodeNumber < KeNumberNodes; NodeNumber++) { Node = KeNodeBlock[NodeNumber]; // // Ask HAL which processors belong to this node and // what Node Color to use for page coloring. // Status = KiQueryNodeAffinity(NodeNumber, &Node->ProcessorMask); if (!NT_SUCCESS(Status)) { DbgPrint( "KE/HAL: NUMA Hal failed to return info for Node %i.\n", NodeNumber); DbgPrint("KE/HAL: Reverting to non NUMA configuration.\n"); ASSERT(NT_SUCCESS(Status)); KeNumberNodes = 1; } else { // // In the unlikely event that processor 0 is not // on node 0, now would be the perfect time to // fix it. // if (Node->ProcessorMask & 1) { KeGetCurrentPrcb()->ParentNode = Node; } } } } #endif // // If the registered number of processors is greater than the maximum // number of processors supported, then only allow the maximum number // of supported processors. // if (KeRegisteredProcessors > MAXIMUM_PROCESSORS) { KeRegisteredProcessors = MAXIMUM_PROCESSORS; } // // Initialize the processor state that will be used to start each of // processors. Each processor starts in the system initialization code // with address of the loader parameter block as an argument. // RtlZeroMemory(&ProcessorState, sizeof(KPROCESSOR_STATE)); ProcessorState.ContextFrame.IntA0 = (ULONGLONG)(LONG_PTR)KeLoaderBlock; ProcessorState.ContextFrame.Fir = (ULONGLONG)(LONG_PTR)KiStartProcessor; Number = 1; while (Number < KeRegisteredProcessors) { #if defined(KE_MULTINODE) NewProcessorAffinity = 1 << Number; for (NodeNumber = 0; NodeNumber < KeNumberNodes; NodeNumber++) { Node = KeNodeBlock[NodeNumber]; if (Node->ProcessorMask & NewProcessorAffinity) { break; } } if (NodeNumber == KeNumberNodes) { // // This should only happen when we're about to ask // for one processor more than is in the system. We // could bail here but we have always depended on // the HAL to tell us we're done. Set up as if // on Node 0 so MM and friends won't be referencing // uninitialized structures. // NodeNumber = 0; Node = KeNodeBlock[0]; } #endif // // Allocate a DPC stack, an idle thread kernel stack, a panic // stack, a PCR page, a processor block, and an executive thread // object. If the allocation fails or the allocation cannot be // made from unmapped nonpaged pool, then stop starting processors. // // Disable any special pooling that the user may have set in the // registry as the next couple of allocations must come from KSEG0. // SpecialPoolState = MmSetSpecialPool(FALSE); MemoryBlock1 = (ULONG_PTR)ExAllocatePool(NonPagedPool, BLOCK1_SIZE); if (IS_KSEG_ADDRESS(MemoryBlock1) == FALSE) { MmSetSpecialPool(SpecialPoolState); if ((PVOID)MemoryBlock1 != NULL) { ExFreePool((PVOID)MemoryBlock1); } break; } MemoryBlock2 = (ULONG_PTR)ExAllocatePool(NonPagedPool, BLOCK2_SIZE); if (IS_KSEG_ADDRESS(MemoryBlock2) == FALSE) { MmSetSpecialPool(SpecialPoolState); ExFreePool((PVOID)MemoryBlock1); if ((PVOID)MemoryBlock2 != NULL) { ExFreePool((PVOID)MemoryBlock2); } break; } MmSetSpecialPool(SpecialPoolState); // // Zero both blocks of allocated memory. // RtlZeroMemory((PVOID)MemoryBlock1, BLOCK1_SIZE); RtlZeroMemory((PVOID)MemoryBlock2, BLOCK2_SIZE); // // Set address of interrupt stack in loader parameter block. // KeLoaderBlock->u.Alpha.PanicStack = KSEG0_ADDRESS(MemoryBlock1 + (1 * KERNEL_STACK_SIZE)); // // Set address of idle thread kernel stack in loader parameter block. // KeLoaderBlock->KernelStack = KSEG0_ADDRESS(MemoryBlock1 + (2 * KERNEL_STACK_SIZE)); ProcessorState.ContextFrame.IntSp = (ULONGLONG)(LONG_PTR)KeLoaderBlock->KernelStack; // // Set address of panic stack in loader parameter block. // KeLoaderBlock->u.Alpha.DpcStack = KSEG0_ADDRESS(MemoryBlock1 + (3 * KERNEL_STACK_SIZE)); // // Set the page frame of the PCR page in the loader parameter block. // PcrPage = KSEG_PFN(MemoryBlock1 + (3 * KERNEL_STACK_SIZE)); KeLoaderBlock->u.Alpha.PcrPage = PcrPage; // // Set the address of the processor block and executive thread in the // loader parameter block. // KeLoaderBlock->Prcb = KSEG0_ADDRESS((MemoryBlock2 + 63) & ~63); KeLoaderBlock->Thread = KeLoaderBlock->Prcb + ROUND_UP(KPRCB) + ROUND_UP(KNODE); #if defined(KE_MULTINODE) // // If this is the first processor on this node, use the // space allocated for KNODE as the KNODE. // if (KeNodeBlock[NodeNumber] == &KiNodeInit[NodeNumber]) { Node = (PKNODE)(KeLoaderBlock->Prcb + ROUND_UP(KPRCB)); *Node = KiNodeInit[NodeNumber]; KeNodeBlock[NodeNumber] = Node; } ((PKPRCB)KeLoaderBlock->Prcb)->ParentNode = Node; #else ((PKPRCB)KeLoaderBlock->Prcb)->ParentNode = KeNodeBlock[0]; #endif // // Attempt to start the next processor. If attempt is successful, // then wait for the processor to get initialized. Otherwise, // deallocate the processor resources and terminate the loop. // Started = HalStartNextProcessor(KeLoaderBlock, &ProcessorState); if (Started == FALSE) { ExFreePool((PVOID)MemoryBlock1); ExFreePool((PVOID)MemoryBlock2); break; } else { // // Wait until boot is finished on the target processor before // starting the next processor. Booting is considered to be // finished when a processor completes its initialization and // drops into the idle loop. // Prcb = (PKPRCB)(KeLoaderBlock->Prcb); RestartBlock = Prcb->RestartBlock; while (RestartBlock->BootStatus.BootFinished == 0) { KiMb(); } } Number += 1; } // // // All processors have been stated. // KiAllProcessorsStarted(); #endif // // Reset and synchronize the performance counters of all processors, by // applying a null adjustment to the interrupt time // KiAdjustInterruptTime(0); return; } #if !defined(NT_UP) VOID KiAllProcessorsStarted( VOID ) /*++ Routine Description: This routine is called once all processors in the system have been started. Arguments: None. Return Value: None. --*/ { ULONG i; #if defined(KE_MULTINODE) // // Make sure there are no references to the temporary nodes // used during initialization. // for (i = 0; i < KeNumberNodes; i++) { if (KeNodeBlock[i] == &KiNodeInit[i]) { // // No processor started on this node so no new node // structure has been allocated. This is possible // if the node contains only memory or IO busses. At // this time we need to allocate a permanent node // structure for the node. // KeNodeBlock[i] = ExAllocatePoolWithTag(NonPagedPool, sizeof(KNODE), ' eK'); if (KeNodeBlock[i]) { *KeNodeBlock[i] = KiNodeInit[i]; } } } for (i = KeNumberNodes; i < MAXIMUM_CCNUMA_NODES; i++) { KeNodeBlock[i] = NULL; } #endif if (KeNumberNodes == 1) { // // For Non NUMA machines, Node 0 gets all processors. // KeNodeBlock[0]->ProcessorMask = KeActiveProcessors; } } #endif