Leaked source code of windows server 2003
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#include "pch.h"
#pragma hdrstop
#include "modset.h"
#include "modtree.h"
#include "ncstl.h"
struct GMBCONTEXT
{
// The tree to reference for generating the set.
//
IN const CModuleTree* pTree;
// The module to start with when generating the set.
//
IN const CModule* pSourceMod;
// INS_FLAGS to use when adding DepChain to the set.
//
IN DWORD dwFlags;
// The module list set to generate based on pSourceMod.
//
IN OUT CModuleListSet* pSet;
// The result of the operation.
//
OUT HRESULT hr;
// This module list is built up via recursion. It is
// temporary. It represents a depenedency chain sourced
// at pSourceMod. It is added to the set when the depth
// of the chain (or a circular reference) is detected.
//
CModuleList DepChain;
};
VOID
GetModuleBindings (
IN const CModule* pMod,
IN OUT GMBCONTEXT* pCtx)
{
BOOL fFoundOne = FALSE;
const CModuleTreeEntry* pScan;
Assert (pCtx);
Assert (pCtx->pSourceMod);
Assert (pCtx->pSet);
Assert (pCtx->pTree);
// Append this module to te end of the context's working
// dependency chain.
//
pCtx->hr = pCtx->DepChain.HrInsertModule (pMod,
INS_ASSERT_IF_DUP | INS_APPEND);
if (S_OK != pCtx->hr)
{
return;
}
// For all rows in the tree where the module is the one passed in...
//
for (pScan = pCtx->pTree->PFindFirstEntryWithModule (pMod);
(pScan != pCtx->pTree->end()) && (pScan->m_pModule == pMod);
pScan++)
{
fFoundOne = TRUE;
// Detect circular import chains.
//
if (pCtx->DepChain.FLinearFindModuleByPointer (pScan->m_pImportModule))
{
pCtx->DepChain.m_fCircular = TRUE;
continue;
}
GetModuleBindings (pScan->m_pImportModule, pCtx);
if (S_OK != pCtx->hr)
{
return;
}
}
// If we didnt find any rows with pMod as a module, it means we
// hit the depth of the dependency chain. Time to add it to the set
// unless this is the original module we were asked to find the
// set for.
//
if (!fFoundOne && (pMod != pCtx->pSourceMod))
{
CHAR pszBuf [4096];
ULONG cch = celems(pszBuf);
pCtx->DepChain.FDumpToString (pszBuf, &cch);
strcat(pszBuf, "\n");
printf(pszBuf);
pCtx->hr = pCtx->pSet->HrAddModuleList (&pCtx->DepChain,
INS_APPEND | pCtx->dwFlags);
}
const CModule* pRemoved;
pRemoved = pCtx->DepChain.RemoveLastModule();
// This should be the component we appened above.
//
Assert (pRemoved == pMod);
}
CModuleTree::~CModuleTree ()
{
FreeCollectionAndItem (Modules);
}
HRESULT
CModuleTree::HrAddEntry (
IN CModule* pMod,
IN CModule* pImport,
IN DWORD dwFlags)
{
HRESULT hr;
iterator InsertPosition = NULL;
CModuleTreeEntry* pEntry;
Assert (pMod);
Assert (pImport);
if (size() == capacity())
{
//fprintf(stderr, "growing module tree buffer\n");
__try
{
reserve (size() + 16384);
}
__except(EXCEPTION_EXECUTE_HANDLER)
{
return E_OUTOFMEMORY;
}
}
hr = S_OK;
//pEntry = PFindFirstEntryAfterModuleGroup (pMod);
pEntry = PBinarySearchEntryByModule (pMod, &InsertPosition);
if (pEntry != end())
{
Assert (pEntry);
CModuleTreeEntry* pScan;
// Found an entry with a matching module. Need to scan backwards
// in the module group looking for a duplicate. If not found,
// Scan to the end looking for a duplicate and if we reach the
// end of the group, we can insert this entry there.
//
pScan = pEntry;
while (pScan != begin())
{
pScan--;
if (pScan->m_pModule != pMod)
{
// Left the group without finding a dupliate.
//
break;
}
if (pScan->m_pImportModule == pImport)
{
// Don't insert duplicate entries.
//
return S_OK;
}
}
Assert (pMod == pEntry->m_pModule);
while (pEntry != end() && pEntry->m_pModule == pMod)
{
// Don't insert duplicate entries.
//
if (pEntry->m_pImportModule == pImport)
{
return S_OK;
}
pEntry++;
}
// Looks like we'll be inserting it.
//
InsertPosition = pEntry;
}
else
{
// InsertPosition is the correct insertion point.
//
Assert (InsertPosition);
}
__try
{
CModuleTreeEntry Entry;
Entry.m_pModule = pMod;
Entry.m_pImportModule = pImport;
Entry.m_dwFlags = dwFlags;
Assert (InsertPosition);
insert (InsertPosition, Entry);
Assert (S_OK == hr);
DbgVerifySorted();
}
__except(EXCEPTION_EXECUTE_HANDLER)
{
hr = E_OUTOFMEMORY;
}
return hr;
}
HRESULT
CModuleTree::HrGetModuleBindings (
IN const CModule* pMod,
IN DWORD dwFlags /* GMB_FLAGS */,
OUT CModuleListSet* pSet) const
{
GMBCONTEXT Ctx;
Assert (pMod);
Assert (dwFlags);
Assert (pSet);
// Initialize the output parameter.
//
if (!(dwFlags & GMBF_ADD_TO_MLSET))
{
pSet->clear();
}
// Initialize members of the context structure for recursion.
//
ZeroMemory (&Ctx, sizeof(Ctx));
Ctx.pTree = this;
Ctx.pSourceMod = pMod;
Ctx.dwFlags = (dwFlags & GMBF_ADD_TO_MLSET)
? INS_IGNORE_IF_DUP
: INS_ASSERT_IF_DUP;
Ctx.pSet = pSet;
GetModuleBindings (pMod, &Ctx);
return Ctx.hr;
}
CModuleTreeEntry*
CModuleTree::PBinarySearchEntryByModule (
IN const CModule* pMod,
OUT CModuleTreeEntry** pInsertPosition OPTIONAL) const
{
Assert (pMod);
// Find the module using a binary search.
//
if (size())
{
LONG Lo;
LONG Hi;
LONG Mid;
INT Result;
const CModuleTreeEntry* pScan;
PCSTR pszFileName = pMod->m_pszFileName;
Lo = 0;
Hi = size() - 1;
while (Hi >= Lo)
{
Mid = (Lo + Hi) / 2;
Assert ((UINT)Mid < size());
pScan = (begin() + Mid);
Result = strcmp (pszFileName, pScan->m_pModule->m_pszFileName);
if (Result < 0)
{
Hi = Mid - 1;
}
else if (Result > 0)
{
Lo = Mid + 1;
}
else
{
Assert (pMod == pScan->m_pModule);
return const_cast<CModuleTreeEntry*>(pScan);
}
}
// If we make it to here, the module was not found.
//
if (pInsertPosition)
{
CModule* pGroupMod;
const CModuleTreeEntry* pPrev;
// Seek to the beginning of this group. We need to insert
// before the entire group, not just the one item we last found.
//
pScan = begin() + Lo;
if (pScan != begin())
{
pGroupMod = pScan->m_pModule;
do
{
pPrev = pScan - 1;
if (pPrev->m_pModule == pGroupMod)
{
pScan = pPrev;
}
else
{
break;
}
} while (pPrev != begin());
}
*pInsertPosition = const_cast<CModuleTreeEntry*>(pScan);
Assert (*pInsertPosition >= begin());
Assert (*pInsertPosition <= end());
}
}
else if (pInsertPosition)
{
// Empty collection. Insert position is at the beginning.
//
*pInsertPosition = const_cast<CModuleTreeEntry*>(begin());
}
return const_cast<CModuleTreeEntry*>(end());
}
CModuleTreeEntry*
CModuleTree::PFindFirstEntryWithModule (
IN const CModule* pMod) const
{
CModuleTreeEntry* pEntry;
Assert (pMod);
pEntry = PBinarySearchEntryByModule (pMod, NULL);
if (pEntry != end())
{
Assert (pEntry);
if (pEntry != begin())
{
CModuleTreeEntry* pPrev;
Assert (pMod == pEntry->m_pModule);
while (1)
{
pPrev = pEntry - 1;
if (pPrev->m_pModule == pMod)
{
pEntry = pPrev;
}
else
{
break;
}
if (pPrev == begin())
{
break;
}
}
}
}
return pEntry;
}
CModuleTreeEntry*
CModuleTree::PFindFirstEntryAfterModuleGroup (
IN const CModule* pMod) const
{
CModuleTreeEntry* pEntry;
Assert (pMod);
pEntry = PBinarySearchEntryByModule (pMod, NULL);
if (pEntry != end())
{
Assert (pEntry);
Assert (pMod == pEntry->m_pModule);
while (pEntry != end() && pEntry->m_pModule == pMod)
{
pEntry++;
}
}
return pEntry;
}
CModuleTreeEntry*
CModuleTree::PBinarySearchEntry (
IN const CModule* pMod,
IN const CModule* pImport,
OUT CModuleTreeEntry** pInsertPosition OPTIONAL) const
{
CModuleTreeEntry* pEntry;
Assert (this);
Assert (pMod);
Assert (pImport);
pEntry = PBinarySearchEntryByModule (pMod, pInsertPosition);
if (pEntry != end())
{
Assert (pEntry);
const CModuleTreeEntry* pScan;
// Found an entry with a matching module. Need to scan backwards
// in the module group looking for a match. If not found,
// Scan to the end looking for a match and if we reach the
// end of the group, that will be the insert position (if specified).
//
pScan = pEntry;
while (pScan != begin())
{
pScan--;
if (pScan->m_pModule != pMod)
{
// Left the group without finding a dupliate.
//
break;
}
if (pScan->m_pImportModule == pImport)
{
Assert (pScan->m_pModule == pMod);
return const_cast<CModuleTreeEntry*>(pScan);
}
}
pScan = pEntry;
Assert (pMod == pScan->m_pModule);
while (pScan != end() && pScan->m_pModule == pMod)
{
if (pScan->m_pImportModule == pImport)
{
Assert (pScan->m_pModule == pMod);
return const_cast<CModuleTreeEntry*>(pScan);
}
pScan++;
}
if (pInsertPosition)
{
*pInsertPosition = const_cast<CModuleTreeEntry*>(pScan);
}
// No match.
pEntry = const_cast<CModuleTreeEntry*>(end());
}
return pEntry;
}
#if DBG
VOID
CModuleTree::DbgVerifySorted ()
{
CModuleTreeEntry* pScan;
CModuleTreeEntry* pPrev = NULL;
if (size() > 1)
{
for (pPrev = begin(), pScan = begin() + 1; pScan != end(); pScan++)
{
Assert (strcmp(pPrev->m_pModule->m_pszFileName,
pScan->m_pModule->m_pszFileName) <= 0);
pPrev = pScan;
}
}
}
#endif