/*++ BUILD Version: 0000 // Increment this if a change has global effects Copyright (c) 1998 Microsoft Corporation Module Name: handle.c Abstract: Handle table library. Handles are generated as follows : handle = Base value + (Table entry index << 4) + (Handle usage instance & 0xf) A free list is kept in the handle table header, with the oldest free entry being at the head of the list & the youngest at the tail. The low four bits of the handle values are used for a usage instance count, which gets incremented every time a handle is freed (to prevent immediate re-use of the same handle value). Author: Dan Knudson (DanKn) 15-Sep-1998 Revision History: --*/ #include "windows.h" #include "assert.h" #include "tlnklist.h" #include "tapihndl.h" #define TABLE_DELTA 64 BOOL GrowTable( PHANDLETABLEHEADER Header ) /*++ Returns: Index of next free table entry if success, -1 if error --*/ { DWORD numEntries = Header->NumEntries, i, numAdditionalEntries; PHANDLETABLEENTRY newTable; // First, we need to compute how many entries we can still alloc. // To do this, we need to now how many entries can the table accommodate, // so that the largest handle value will not exceed MAXDWORD. We get // this by reversing the algorithm used to compute handle values based // on the table entry's index. numAdditionalEntries = (MAXDWORD - Header->HandleBase) >> 4; // This is the maximum number of entries in the table, // so that handle values do not overflow DWORDs. numAdditionalEntries -= numEntries; // This is how many entries we can still alloc; if (0 == numAdditionalEntries) { // The table is already as big as it can be... return FALSE; } if (numAdditionalEntries > TABLE_DELTA) { numAdditionalEntries = TABLE_DELTA; // We only grow the handle table in TABLE_DELTA or } // or smaller increments. if (!(newTable = HeapAlloc( Header->Heap, 0, (numEntries + numAdditionalEntries) * sizeof (*newTable) ))) { return FALSE; } CopyMemory( newTable, Header->Table, numEntries * sizeof(*newTable) ); for (i = numEntries; i < numEntries + TABLE_DELTA; i++) { // // Init this entry. Note that we set "Instance = i" to stagger // the handle values, because we know tapisrv queues events & // completion msgs to a specific SPEVentHandlerThread based on // handle values. // PHANDLETABLEENTRY entry = newTable + i; InsertHeadList (&Header->FreeList, &entry->ListEntry); entry->Handle = 0; entry->Instance = i; } if (Header->Table) { HeapFree (Header->Heap, 0, Header->Table); } Header->Table = newTable; Header->NumEntries += TABLE_DELTA; return TRUE; } HANDLE CreateHandleTable( HANDLE Heap, FREECONTEXTCALLBACK FreeContextCallback, DWORD MinHandleValue, DWORD MaxHandleValue /* Right now, MaxHandleValue is not used. If we find that we need to use it however, store it in the table header and replace MAXDWORD with it in the code at the beginning of GrowTable */ ) /*++ --*/ { PHANDLETABLEHEADER header; if (!(header = HeapAlloc (Heap, HEAP_ZERO_MEMORY, sizeof (*header)))) { return NULL; } header->Heap = Heap; header->HandleBase = MinHandleValue; header->FreeContextCallback = FreeContextCallback; InitializeListHead (&header->FreeList); InitializeCriticalSectionAndSpinCount (&header->Lock, 0x80001000); if (!GrowTable (header)) { DeleteCriticalSection (&header->Lock); HeapFree (Heap, 0, header); return NULL; } return ((HANDLE) header); } VOID DeleteHandleTable( HANDLE HandleTable ) /*++ --*/ { PHANDLETABLEHEADER header = (PHANDLETABLEHEADER) HandleTable; HeapFree (header->Heap, 0, header->Table); DeleteCriticalSection (&header->Lock); HeapFree (header->Heap, 0, header); } // // Distinct calls of NewObject in the same handle table always return distinct handles. // All NewObject calls in tapisrv use the same handle table, so the handles are known to be distinct, // even between different types of objects (i.e. HCALL vs. HLINE) // This will need to remain true if the NewObject() implementation changes in the future, // as various TAPI operations use this assumption. // DWORD NewObject( HANDLE HandleTable, LPVOID Context, LPVOID Context2 ) /*++ --*/ { DWORD handle; PHANDLETABLEENTRY entry; PHANDLETABLEHEADER header = (PHANDLETABLEHEADER) HandleTable; if (header && Context) { EnterCriticalSection (&header->Lock); if (IsListEmpty (&header->FreeList)) { if (!GrowTable (header)) { LeaveCriticalSection (&header->Lock); return 0; } } entry = (PHANDLETABLEENTRY) RemoveHeadList (&header->FreeList); entry->Context.C = Context; entry->Context.C2 = Context2; entry->Handle = header->HandleBase + (((DWORD)(entry - header->Table)) << 4) + // (entry_index << 4) is guraranteed // to fit in a DWORD (see comments at the // start of GrowTable). (entry->Instance & 0xf); entry->ReferenceCount = 1; handle = entry->Handle; LeaveCriticalSection (&header->Lock); } else { handle = 0; } return handle; } LPVOID ReferenceObject( HANDLE HandleTable, DWORD Handle, DWORD Key ) /*++ --*/ { LPVOID context = 0; DWORD index; PHANDLETABLEENTRY entry; PHANDLETABLEHEADER header = (PHANDLETABLEHEADER) HandleTable; if (header && Handle >= header->HandleBase) { index = (Handle - header->HandleBase) >> 4; if (index < header->NumEntries) { EnterCriticalSection (&header->Lock); entry = header->Table + index; if (entry->Handle == Handle && entry->ReferenceCount != 0) { context = entry->Context.C; if (Key) { try { if (*((LPDWORD) context) == Key) { entry->ReferenceCount++; } else { context = 0; } } except (EXCEPTION_EXECUTE_HANDLER) { context = 0; } } else { entry->ReferenceCount++; } } LeaveCriticalSection (&header->Lock); } } return context; } LPVOID ReferenceObjectEx( HANDLE HandleTable, DWORD Handle, DWORD Key, LPVOID *Context2 ) /*++ --*/ { LPVOID context = 0; DWORD index; PHANDLETABLEENTRY entry; PHANDLETABLEHEADER header = (PHANDLETABLEHEADER) HandleTable; if (header && Handle >= header->HandleBase) { index = (Handle - header->HandleBase) >> 4; if (index < header->NumEntries) { EnterCriticalSection (&header->Lock); entry = header->Table + index; if (entry->Handle == Handle && entry->ReferenceCount != 0) { context = entry->Context.C; *Context2 = entry->Context.C2; if (Key) { try { if (*((LPDWORD) context) == Key) { entry->ReferenceCount++; } else { context = 0; } } except (EXCEPTION_EXECUTE_HANDLER) { context = 0; } } else { entry->ReferenceCount++; } } LeaveCriticalSection (&header->Lock); } } return context; } VOID DereferenceObject( HANDLE HandleTable, DWORD Handle, DWORD DereferenceCount ) /*++ --*/ { LPVOID context, context2; DWORD index; PHANDLETABLEENTRY entry; PHANDLETABLEHEADER header = (PHANDLETABLEHEADER) HandleTable; if (header && Handle >= header->HandleBase) { index = (Handle - header->HandleBase) >> 4; if (index < header->NumEntries) { EnterCriticalSection (&header->Lock); entry = header->Table + index; if (entry->Handle == Handle && entry->ReferenceCount != 0) { assert (DereferenceCount >= entry->ReferenceCount); entry->ReferenceCount -= DereferenceCount; if (entry->ReferenceCount == 0) { entry->Instance = entry->Handle + 1; entry->Handle = 0; context = entry->Context.C; context2 = entry->Context.C2; InsertTailList (&header->FreeList, &entry->ListEntry); LeaveCriticalSection (&header->Lock); (*header->FreeContextCallback)(context, context2); return; } } else { // assert } LeaveCriticalSection (&header->Lock); } else { // assert } } } void ReleaseAllHandles( HANDLE HandleTable, PVOID Context2 ) { DWORD index; LPVOID context, context2; PHANDLETABLEENTRY entry; PHANDLETABLEHEADER header = (PHANDLETABLEHEADER) HandleTable; if (header && NULL != Context2) { EnterCriticalSection (&header->Lock); for (index = 0, entry = header->Table; index < header->NumEntries; index++, entry++) { if (0 != entry->Handle && entry->Context.C2 == Context2) { entry->Instance = entry->Handle + 1; entry->Handle = 0; context = entry->Context.C; context2 = entry->Context.C2; InsertTailList (&header->FreeList, &entry->ListEntry); (*header->FreeContextCallback)(context, context2); } } LeaveCriticalSection (&header->Lock); } }