// Copyright (c) .NET Foundation and contributors. All rights reserved. Licensed under the Microsoft Reciprocal License. See LICENSE.TXT file in the project root for full license information. #include "precomp.h" // Exit macros #define ApupExitOnLastError(x, s, ...) ExitOnLastErrorSource(DUTIL_SOURCE_APUPUTIL, x, s, __VA_ARGS__) #define ApupExitOnLastErrorDebugTrace(x, s, ...) ExitOnLastErrorDebugTraceSource(DUTIL_SOURCE_APUPUTIL, x, s, __VA_ARGS__) #define ApupExitWithLastError(x, s, ...) ExitWithLastErrorSource(DUTIL_SOURCE_APUPUTIL, x, s, __VA_ARGS__) #define ApupExitOnFailure(x, s, ...) ExitOnFailureSource(DUTIL_SOURCE_APUPUTIL, x, s, __VA_ARGS__) #define ApupExitOnRootFailure(x, s, ...) ExitOnRootFailureSource(DUTIL_SOURCE_APUPUTIL, x, s, __VA_ARGS__) #define ApupExitOnFailureDebugTrace(x, s, ...) ExitOnFailureDebugTraceSource(DUTIL_SOURCE_APUPUTIL, x, s, __VA_ARGS__) #define ApupExitOnNull(p, x, e, s, ...) ExitOnNullSource(DUTIL_SOURCE_APUPUTIL, p, x, e, s, __VA_ARGS__) #define ApupExitOnNullWithLastError(p, x, s, ...) ExitOnNullWithLastErrorSource(DUTIL_SOURCE_APUPUTIL, p, x, s, __VA_ARGS__) #define ApupExitOnNullDebugTrace(p, x, e, s, ...) ExitOnNullDebugTraceSource(DUTIL_SOURCE_APUPUTIL, p, x, e, s, __VA_ARGS__) #define ApupExitOnInvalidHandleWithLastError(p, x, s, ...) ExitOnInvalidHandleWithLastErrorSource(DUTIL_SOURCE_APUPUTIL, p, x, s, __VA_ARGS__) #define ApupExitOnWin32Error(e, x, s, ...) ExitOnWin32ErrorSource(DUTIL_SOURCE_APUPUTIL, e, x, s, __VA_ARGS__) #define ApupExitOnGdipFailure(g, x, s, ...) ExitOnGdipFailureSource(DUTIL_SOURCE_APUPUTIL, g, x, s, __VA_ARGS__) // prototypes static HRESULT ProcessEntry( __in ATOM_ENTRY* pAtomEntry, __in LPCWSTR wzDefaultAppId, __inout APPLICATION_UPDATE_ENTRY* pApupEntry ); static HRESULT ParseEnclosure( __in ATOM_LINK* pLink, __in APPLICATION_UPDATE_ENCLOSURE* pEnclosure ); static __callback int __cdecl CompareEntries( void* pvContext, const void* pvLeft, const void* pvRight ); static HRESULT FilterEntries( __in APPLICATION_UPDATE_ENTRY* rgEntries, __in DWORD cEntries, __in VERUTIL_VERSION* pCurrentVersion, __inout APPLICATION_UPDATE_ENTRY** prgFilteredEntries, __inout DWORD* pcFilteredEntries ); static HRESULT CopyEntry( __in const APPLICATION_UPDATE_ENTRY* pSrc, __in APPLICATION_UPDATE_ENTRY* pDest ); static HRESULT CopyEnclosure( __in const APPLICATION_UPDATE_ENCLOSURE* pSrc, __in APPLICATION_UPDATE_ENCLOSURE* pDest ); static void FreeEntry( __in APPLICATION_UPDATE_ENTRY* pApupEntry ); static void FreeEnclosure( __in APPLICATION_UPDATE_ENCLOSURE* pEnclosure ); // // ApupCalculateChainFromAtom - returns the chain of application updates found in an ATOM feed. // extern "C" HRESULT DAPI ApupAllocChainFromAtom( __in ATOM_FEED* pFeed, __out APPLICATION_UPDATE_CHAIN** ppChain ) { HRESULT hr = S_OK; APPLICATION_UPDATE_CHAIN* pChain = NULL; pChain = static_cast(MemAlloc(sizeof(APPLICATION_UPDATE_CHAIN), TRUE)); // First search the ATOM feed's custom elements to try and find the default application identity. for (ATOM_UNKNOWN_ELEMENT* pElement = pFeed->pUnknownElements; pElement; pElement = pElement->pNext) { if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, pElement->wzNamespace, -1, APPLICATION_SYNDICATION_NAMESPACE, -1)) { if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, pElement->wzElement, -1, L"application", -1)) { hr = StrAllocString(&pChain->wzDefaultApplicationId, pElement->wzValue, 0); ApupExitOnFailure(hr, "Failed to allocate default application id."); for (ATOM_UNKNOWN_ATTRIBUTE* pAttribute = pElement->pAttributes; pAttribute; pAttribute = pAttribute->pNext) { if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, pAttribute->wzAttribute, -1, L"type", -1)) { hr = StrAllocString(&pChain->wzDefaultApplicationType, pAttribute->wzValue, 0); ApupExitOnFailure(hr, "Failed to allocate default application type."); } } } } } // Assume there will be as many application updates entries as their are feed entries. if (pFeed->cEntries) { pChain->rgEntries = static_cast(MemAlloc(sizeof(APPLICATION_UPDATE_ENTRY) * pFeed->cEntries, TRUE)); ApupExitOnNull(pChain->rgEntries, hr, E_OUTOFMEMORY, "Failed to allocate memory for update entries."); // Process each entry, building up the chain. for (DWORD i = 0; i < pFeed->cEntries; ++i) { hr = ProcessEntry(pFeed->rgEntries + i, pChain->wzDefaultApplicationId, pChain->rgEntries + pChain->cEntries); ApupExitOnFailure(hr, "Failed to process ATOM entry."); if (S_FALSE != hr) { ++pChain->cEntries; } } // Sort the chain by descending version and ascending total size. qsort_s(pChain->rgEntries, pChain->cEntries, sizeof(APPLICATION_UPDATE_ENTRY), CompareEntries, NULL); } // Trim the unused entries from the end, if any of the entries failed to parse or validate if (pChain->cEntries != pFeed->cEntries) { if (pChain->cEntries > 0) { pChain->rgEntries = static_cast(MemReAlloc(pChain->rgEntries, sizeof(APPLICATION_UPDATE_ENTRY) * pChain->cEntries, FALSE)); ApupExitOnNull(pChain->rgEntries, hr, E_OUTOFMEMORY, "Failed to reallocate memory for update entries."); } else { ReleaseNullMem(pChain->rgEntries); } } *ppChain = pChain; pChain = NULL; LExit: ReleaseApupChain(pChain); return hr; } // // ApupFilterChain - remove the unneeded update elements from the chain. // HRESULT DAPI ApupFilterChain( __in APPLICATION_UPDATE_CHAIN* pChain, __in VERUTIL_VERSION* pVersion, __out APPLICATION_UPDATE_CHAIN** ppFilteredChain ) { HRESULT hr = S_OK; APPLICATION_UPDATE_CHAIN* pNewChain = NULL; APPLICATION_UPDATE_ENTRY* prgEntries = NULL; DWORD cEntries = NULL; pNewChain = static_cast(MemAlloc(sizeof(APPLICATION_UPDATE_CHAIN), TRUE)); ApupExitOnNull(pNewChain, hr, E_OUTOFMEMORY, "Failed to allocate filtered chain."); hr = FilterEntries(pChain->rgEntries, pChain->cEntries, pVersion, &prgEntries, &cEntries); ApupExitOnFailure(hr, "Failed to filter entries by version."); if (pChain->wzDefaultApplicationId) { hr = StrAllocString(&pNewChain->wzDefaultApplicationId, pChain->wzDefaultApplicationId, 0); ApupExitOnFailure(hr, "Failed to copy default application id."); } if (pChain->wzDefaultApplicationType) { hr = StrAllocString(&pNewChain->wzDefaultApplicationType, pChain->wzDefaultApplicationType, 0); ApupExitOnFailure(hr, "Failed to copy default application type."); } pNewChain->rgEntries = prgEntries; pNewChain->cEntries = cEntries; *ppFilteredChain = pNewChain; pNewChain = NULL; LExit: ReleaseApupChain(pNewChain); return hr; } // // ApupFreeChain - frees a previously allocated application update chain. // extern "C" void DAPI ApupFreeChain( __in APPLICATION_UPDATE_CHAIN* pChain ) { if (pChain) { for (DWORD i = 0; i < pChain->cEntries; ++i) { FreeEntry(pChain->rgEntries + i); } ReleaseMem(pChain->rgEntries); ReleaseStr(pChain->wzDefaultApplicationType); ReleaseStr(pChain->wzDefaultApplicationId); ReleaseMem(pChain); } } static HRESULT ProcessEntry( __in ATOM_ENTRY* pAtomEntry, __in LPCWSTR wzDefaultAppId, __inout APPLICATION_UPDATE_ENTRY* pApupEntry ) { HRESULT hr = S_OK; int nCompareResult = 0; // First search the ATOM entry's custom elements to try and find the application update information. for (ATOM_UNKNOWN_ELEMENT* pElement = pAtomEntry->pUnknownElements; pElement; pElement = pElement->pNext) { if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, pElement->wzNamespace, -1, APPLICATION_SYNDICATION_NAMESPACE, -1)) { if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, pElement->wzElement, -1, L"application", -1)) { hr = StrAllocString(&pApupEntry->wzApplicationId, pElement->wzValue, 0); ApupExitOnFailure(hr, "Failed to allocate application identity."); for (ATOM_UNKNOWN_ATTRIBUTE* pAttribute = pElement->pAttributes; pAttribute; pAttribute = pAttribute->pNext) { if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, pAttribute->wzAttribute, -1, L"type", -1)) { hr = StrAllocString(&pApupEntry->wzApplicationType, pAttribute->wzValue, 0); ApupExitOnFailure(hr, "Failed to allocate application type."); } } } else if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, pElement->wzElement, -1, L"upgrade", -1)) { hr = StrAllocString(&pApupEntry->wzUpgradeId, pElement->wzValue, 0); ApupExitOnFailure(hr, "Failed to allocate upgrade id."); for (ATOM_UNKNOWN_ATTRIBUTE* pAttribute = pElement->pAttributes; pAttribute; pAttribute = pAttribute->pNext) { if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, pAttribute->wzAttribute, -1, L"version", -1)) { hr = VerParseVersion(pAttribute->wzValue, 0, FALSE, &pApupEntry->pUpgradeVersion); ApupExitOnFailure(hr, "Failed to parse upgrade version string '%ls' from ATOM entry.", pAttribute->wzValue); } else if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, pAttribute->wzAttribute, -1, L"exclusive", -1)) { if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, pAttribute->wzValue, -1, L"true", -1)) { pApupEntry->fUpgradeExclusive = TRUE; } } } } else if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, pElement->wzElement, -1, L"version", -1)) { hr = VerParseVersion(pElement->wzValue, 0, FALSE, &pApupEntry->pVersion); ApupExitOnFailure(hr, "Failed to parse version string '%ls' from ATOM entry.", pElement->wzValue); } } } // If there is no application identity or no version, skip the whole thing. if ((!pApupEntry->wzApplicationId && !wzDefaultAppId) || !pApupEntry->pVersion) { ExitFunction1(hr = S_FALSE); // skip this update since it has no application id or version. } if (pApupEntry->pUpgradeVersion) { hr = VerCompareParsedVersions(pApupEntry->pUpgradeVersion, pApupEntry->pVersion, &nCompareResult); ApupExitOnFailure(hr, "Failed to compare version to upgrade version."); if (nCompareResult >= 0) { hr = HRESULT_FROM_WIN32(ERROR_INVALID_DATA); ApupExitOnRootFailure(hr, "Upgrade version is greater than or equal to application version."); } } if (pAtomEntry->wzTitle) { hr = StrAllocString(&pApupEntry->wzTitle, pAtomEntry->wzTitle, 0); ApupExitOnFailure(hr, "Failed to allocate application title."); } if (pAtomEntry->wzSummary) { hr = StrAllocString(&pApupEntry->wzSummary, pAtomEntry->wzSummary, 0); ApupExitOnFailure(hr, "Failed to allocate application summary."); } if (pAtomEntry->pContent) { if (pAtomEntry->pContent->wzType) { hr = StrAllocString(&pApupEntry->wzContentType, pAtomEntry->pContent->wzType, 0); ApupExitOnFailure(hr, "Failed to allocate content type."); } if (pAtomEntry->pContent->wzValue) { hr = StrAllocString(&pApupEntry->wzContent, pAtomEntry->pContent->wzValue, 0); ApupExitOnFailure(hr, "Failed to allocate content."); } } // Now process the enclosures. Assume every link in the ATOM entry is an enclosure. pApupEntry->rgEnclosures = static_cast(MemAlloc(sizeof(APPLICATION_UPDATE_ENCLOSURE) * pAtomEntry->cLinks, TRUE)); ApupExitOnNull(pApupEntry->rgEnclosures, hr, E_OUTOFMEMORY, "Failed to allocate enclosures for application update entry."); for (DWORD i = 0; i < pAtomEntry->cLinks; ++i) { ATOM_LINK* pLink = pAtomEntry->rgLinks + i; if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, pLink->wzRel, -1, L"enclosure", -1)) { hr = ParseEnclosure(pLink, pApupEntry->rgEnclosures + pApupEntry->cEnclosures); ApupExitOnFailure(hr, "Failed to parse enclosure."); pApupEntry->dw64TotalSize += pApupEntry->rgEnclosures[pApupEntry->cEnclosures].dw64Size; // total up the size of the enclosures ++pApupEntry->cEnclosures; } } LExit: if (S_OK != hr) // if anything went wrong, free the entry. { FreeEntry(pApupEntry); memset(pApupEntry, 0, sizeof(APPLICATION_UPDATE_ENTRY)); } return hr; } static HRESULT ParseEnclosure( __in ATOM_LINK* pLink, __in APPLICATION_UPDATE_ENCLOSURE* pEnclosure ) { HRESULT hr = S_OK; DWORD dwDigestLength = 0; DWORD dwDigestStringLength = 0; size_t cchDigestString = 0; // First search the ATOM link's custom elements to try and find the application update enclosure information. for (ATOM_UNKNOWN_ELEMENT* pElement = pLink->pUnknownElements; pElement; pElement = pElement->pNext) { if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, pElement->wzNamespace, -1, APPLICATION_SYNDICATION_NAMESPACE, -1)) { if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, L"digest", -1, pElement->wzElement, -1)) { // Find the digest[@algorithm] which is required. Everything else is ignored. for (ATOM_UNKNOWN_ATTRIBUTE* pAttribute = pElement->pAttributes; pAttribute; pAttribute = pAttribute->pNext) { dwDigestLength = 0; if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, L"algorithm", -1, pAttribute->wzAttribute, -1)) { if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, NORM_IGNORECASE, L"md5", -1, pAttribute->wzValue, -1)) { pEnclosure->digestAlgorithm = APUP_HASH_ALGORITHM_MD5; dwDigestLength = MD5_HASH_LEN; } else if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, NORM_IGNORECASE, L"sha1", -1, pAttribute->wzValue, -1)) { pEnclosure->digestAlgorithm = APUP_HASH_ALGORITHM_SHA1; dwDigestLength = SHA1_HASH_LEN; } else if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, NORM_IGNORECASE, L"sha256", -1, pAttribute->wzValue, -1)) { pEnclosure->digestAlgorithm = APUP_HASH_ALGORITHM_SHA256; dwDigestLength = SHA256_HASH_LEN; } else if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, NORM_IGNORECASE, L"sha512", -1, pAttribute->wzValue, -1)) { pEnclosure->digestAlgorithm = APUP_HASH_ALGORITHM_SHA512; dwDigestLength = SHA512_HASH_LEN; } break; } } if (dwDigestLength) { dwDigestStringLength = 2 * dwDigestLength; hr = ::StringCchLengthW(pElement->wzValue, STRSAFE_MAX_CCH, &cchDigestString); ApupExitOnFailure(hr, "Failed to get string length of digest value."); if (dwDigestStringLength != cchDigestString) { hr = HRESULT_FROM_WIN32(ERROR_INVALID_DATA); ApupExitOnRootFailure(hr, "Invalid digest length (%Iu) for digest algorithm (%u).", cchDigestString, dwDigestStringLength); } pEnclosure->cbDigest = sizeof(BYTE) * dwDigestLength; pEnclosure->rgbDigest = static_cast(MemAlloc(pEnclosure->cbDigest, TRUE)); ApupExitOnNull(pEnclosure->rgbDigest, hr, E_OUTOFMEMORY, "Failed to allocate memory for digest."); hr = StrHexDecode(pElement->wzValue, pEnclosure->rgbDigest, pEnclosure->cbDigest); ApupExitOnFailure(hr, "Failed to decode digest value."); } else { hr = HRESULT_FROM_WIN32(ERROR_INVALID_DATA); ApupExitOnRootFailure(hr, "Unknown algorithm type for digest."); } break; } else if (CSTR_EQUAL == ::CompareStringW(LOCALE_INVARIANT, 0, L"name", -1, pElement->wzElement, -1)) { hr = StrAllocString(&pEnclosure->wzLocalName, pElement->wzValue, 0); ApupExitOnFailure(hr, "Failed to copy local name."); } } } pEnclosure->dw64Size = pLink->dw64Length; hr = StrAllocString(&pEnclosure->wzUrl, pLink->wzUrl, 0); ApupExitOnFailure(hr, "Failed to allocate enclosure URL."); pEnclosure->fInstaller = FALSE; pEnclosure->wzLocalName = NULL; LExit: return hr; } static __callback int __cdecl CompareEntries( void* /*pvContext*/, const void* pvLeft, const void* pvRight ) { int ret = 0; const APPLICATION_UPDATE_ENTRY* pEntryLeft = static_cast(pvLeft); const APPLICATION_UPDATE_ENTRY* pEntryRight = static_cast(pvRight); VerCompareParsedVersions(pEntryLeft->pVersion, pEntryRight->pVersion, &ret); if (0 == ret) { VerCompareParsedVersions(pEntryLeft->pUpgradeVersion, pEntryRight->pUpgradeVersion, &ret); if (0 == ret) { ret = (pEntryLeft->dw64TotalSize < pEntryRight->dw64TotalSize) ? -1 : (pEntryLeft->dw64TotalSize > pEntryRight->dw64TotalSize) ? 1 : 0; } } // Sort descending. ret = -ret; return ret; } static HRESULT FilterEntries( __in APPLICATION_UPDATE_ENTRY* rgEntries, __in DWORD cEntries, __in VERUTIL_VERSION* pCurrentVersion, __inout APPLICATION_UPDATE_ENTRY** prgFilteredEntries, __inout DWORD* pcFilteredEntries ) { HRESULT hr = S_OK; int nCompareResult = 0; size_t cbAllocSize = 0; const APPLICATION_UPDATE_ENTRY* pRequired = NULL;; LPVOID pv = NULL; if (cEntries) { for (DWORD i = 0; i < cEntries; ++i) { const APPLICATION_UPDATE_ENTRY* pEntry = rgEntries + i; hr = VerCompareParsedVersions(pCurrentVersion, pEntry->pVersion, &nCompareResult); ApupExitOnFailure(hr, "Failed to compare versions."); if (nCompareResult >= 0) { continue; } hr = VerCompareParsedVersions(pCurrentVersion, pEntry->pUpgradeVersion, &nCompareResult); ApupExitOnFailure(hr, "Failed to compare upgrade versions."); if (nCompareResult > 0 || (!pEntry->fUpgradeExclusive && nCompareResult == 0)) { pRequired = pEntry; break; } } if (pRequired) { DWORD cNewFilteredEntries = *pcFilteredEntries + 1; hr = ::SizeTMult(sizeof(APPLICATION_UPDATE_ENTRY), cNewFilteredEntries, &cbAllocSize); ApupExitOnFailure(hr, "Overflow while calculating alloc size for more entries - number of entries: %u", cNewFilteredEntries); if (*prgFilteredEntries) { pv = MemReAlloc(*prgFilteredEntries, cbAllocSize, FALSE); ApupExitOnNull(pv, hr, E_OUTOFMEMORY, "Failed to reallocate memory for more entries."); } else { pv = MemAlloc(cbAllocSize, TRUE); ApupExitOnNull(pv, hr, E_OUTOFMEMORY, "Failed to allocate memory for entries."); } *pcFilteredEntries = cNewFilteredEntries; *prgFilteredEntries = static_cast(pv); pv = NULL; hr = CopyEntry(pRequired, *prgFilteredEntries + *pcFilteredEntries - 1); ApupExitOnFailure(hr, "Failed to deep copy entry."); hr = VerCompareParsedVersions(pRequired->pVersion, rgEntries[0].pVersion, &nCompareResult); ApupExitOnFailure(hr, "Failed to compare required version."); if (nCompareResult < 0) { FilterEntries(rgEntries, cEntries, pRequired->pVersion, prgFilteredEntries, pcFilteredEntries); } } } LExit: ReleaseMem(pv); return hr; } static HRESULT CopyEntry( __in const APPLICATION_UPDATE_ENTRY* pSrc, __in APPLICATION_UPDATE_ENTRY* pDest ) { HRESULT hr = S_OK; size_t cbAllocSize = 0; memset(pDest, 0, sizeof(APPLICATION_UPDATE_ENTRY)); if (pSrc->wzApplicationId) { hr = StrAllocString(&pDest->wzApplicationId, pSrc->wzApplicationId, 0); ApupExitOnFailure(hr, "Failed to copy application id."); } if (pSrc->wzApplicationType) { hr = StrAllocString(&pDest->wzApplicationType, pSrc->wzApplicationType, 0); ApupExitOnFailure(hr, "Failed to copy application type."); } if (pSrc->wzUpgradeId) { hr = StrAllocString(&pDest->wzUpgradeId, pSrc->wzUpgradeId, 0); ApupExitOnFailure(hr, "Failed to copy upgrade id."); } if (pSrc->wzTitle) { hr = StrAllocString(&pDest->wzTitle, pSrc->wzTitle, 0); ApupExitOnFailure(hr, "Failed to copy title."); } if (pSrc->wzSummary) { hr = StrAllocString(&pDest->wzSummary, pSrc->wzSummary, 0); ApupExitOnFailure(hr, "Failed to copy summary."); } if (pSrc->wzContentType) { hr = StrAllocString(&pDest->wzContentType, pSrc->wzContentType, 0); ApupExitOnFailure(hr, "Failed to copy content type."); } if (pSrc->wzContent) { hr = StrAllocString(&pDest->wzContent, pSrc->wzContent, 0); ApupExitOnFailure(hr, "Failed to copy content."); } pDest->dw64TotalSize = pSrc->dw64TotalSize; hr = VerCopyVersion(pSrc->pUpgradeVersion, &pDest->pUpgradeVersion); ApupExitOnFailure(hr, "Failed to copy upgrade version."); hr = VerCopyVersion(pSrc->pVersion, &pDest->pVersion); ApupExitOnFailure(hr, "Failed to copy version."); pDest->fUpgradeExclusive = pSrc->fUpgradeExclusive; hr = ::SizeTMult(sizeof(APPLICATION_UPDATE_ENCLOSURE), pSrc->cEnclosures, &cbAllocSize); ApupExitOnRootFailure(hr, "Overflow while calculating memory allocation size"); pDest->rgEnclosures = static_cast(MemAlloc(cbAllocSize, TRUE)); ApupExitOnNull(pDest->rgEnclosures, hr, E_OUTOFMEMORY, "Failed to allocate copy of enclosures."); pDest->cEnclosures = pSrc->cEnclosures; for (DWORD i = 0; i < pDest->cEnclosures; ++i) { hr = CopyEnclosure(pSrc->rgEnclosures + i, pDest->rgEnclosures + i); ApupExitOnFailure(hr, "Failed to copy enclosure."); } LExit: if (FAILED(hr)) { FreeEntry(pDest); } return hr; } static HRESULT CopyEnclosure( __in const APPLICATION_UPDATE_ENCLOSURE* pSrc, __in APPLICATION_UPDATE_ENCLOSURE* pDest ) { HRESULT hr = S_OK; memset(pDest, 0, sizeof(APPLICATION_UPDATE_ENCLOSURE)); if (pSrc->wzUrl) { hr = StrAllocString(&pDest->wzUrl, pSrc->wzUrl, 0); ApupExitOnFailure(hr, "Failed copy url."); } if (pSrc->wzLocalName) { hr = StrAllocString(&pDest->wzLocalName, pSrc->wzLocalName, 0); ApupExitOnFailure(hr, "Failed copy url."); } pDest->rgbDigest = static_cast(MemAlloc(sizeof(BYTE) * pSrc->cbDigest, FALSE)); ApupExitOnNull(pDest->rgbDigest, hr, E_OUTOFMEMORY, "Failed to allocate memory for copy of digest."); pDest->cbDigest = pSrc->cbDigest; memcpy_s(pDest->rgbDigest, sizeof(BYTE) * pDest->cbDigest, pSrc->rgbDigest, sizeof(BYTE) * pSrc->cbDigest); pDest->digestAlgorithm = pSrc->digestAlgorithm; pDest->dw64Size = pSrc->dw64Size; pDest->fInstaller = pSrc->fInstaller; LExit: if (FAILED(hr)) { FreeEnclosure(pDest); } return hr; } static void FreeEntry( __in APPLICATION_UPDATE_ENTRY* pEntry ) { if (pEntry) { for (DWORD i = 0; i < pEntry->cEnclosures; ++i) { FreeEnclosure(pEntry->rgEnclosures + i); } ReleaseStr(pEntry->wzUpgradeId); ReleaseStr(pEntry->wzApplicationType); ReleaseStr(pEntry->wzApplicationId); ReleaseStr(pEntry->wzTitle); ReleaseStr(pEntry->wzSummary); ReleaseStr(pEntry->wzContentType); ReleaseStr(pEntry->wzContent); ReleaseVerutilVersion(pEntry->pVersion); ReleaseVerutilVersion(pEntry->pUpgradeVersion); } } static void FreeEnclosure( __in APPLICATION_UPDATE_ENCLOSURE* pEnclosure ) { if (pEnclosure) { ReleaseMem(pEnclosure->rgbDigest); ReleaseStr(pEnclosure->wzLocalName); ReleaseStr(pEnclosure->wzUrl); } }