/* $Id: iokit.cpp $ */ /** @file * Main - Darwin IOKit Routines. * * Because IOKit makes use of COM like interfaces, it does not mix very * well with COM/XPCOM and must therefore be isolated from it using a * simpler C interface. */ /* * Copyright (C) 2006-2023 Oracle and/or its affiliates. * * This file is part of VirtualBox base platform packages, as * available from https://www.virtualbox.org. * * 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, in version 3 of the * License. * * 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, see . * * SPDX-License-Identifier: GPL-3.0-only */ /********************************************************************************************************************************* * Header Files * *********************************************************************************************************************************/ #define LOG_GROUP LOG_GROUP_MAIN #ifdef STANDALONE_TESTCASE # define VBOX_WITH_USB #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef VBOX_WITH_USB # include # include #endif #include #include #include #include #include #include #include #include #include #include #ifdef STANDALONE_TESTCASE # include # include #endif #include "iokit.h" /* A small hack... */ #ifdef STANDALONE_TESTCASE # define DarwinFreeUSBDeviceFromIOKit(a) do { } while (0) #endif /********************************************************************************************************************************* * Defined Constants And Macros * *********************************************************************************************************************************/ /** An attempt at catching reference leaks. */ #define MY_CHECK_CREFS(cRefs) do { AssertMsg(cRefs < 25, ("%ld\n", cRefs)); NOREF(cRefs); } while (0) /** Contains the pid of the current client. If 0, the kernel is the current client. */ #define VBOXUSB_CLIENT_KEY "VBoxUSB-Client" /** Contains the pid of the filter owner (i.e. the VBoxSVC pid). */ #define VBOXUSB_OWNER_KEY "VBoxUSB-Owner" /** The VBoxUSBDevice class name. */ #define VBOXUSBDEVICE_CLASS_NAME "org_virtualbox_VBoxUSBDevice" /** Define the constant for the IOUSBHostDevice class name added in El Capitan. */ #ifndef kIOUSBHostDeviceClassName # define kIOUSBHostDeviceClassName "IOUSBHostDevice" #endif /** The major darwin version indicating OS X El Captian, used to take care of the USB changes. */ #define VBOX_OSX_EL_CAPTIAN_VER 15 /********************************************************************************************************************************* * Global Variables * *********************************************************************************************************************************/ /** The IO Master Port. */ static mach_port_t g_MasterPort = MACH_PORT_NULL; /** Major darwin version as returned by uname -r. */ static uint32_t g_uMajorDarwin = 0; /** * Lazily opens the master port. * * @returns true if the port is open, false on failure (very unlikely). */ static bool darwinOpenMasterPort(void) { if (!g_MasterPort) { kern_return_t krc = IOMasterPort(MACH_PORT_NULL, &g_MasterPort); AssertReturn(krc == KERN_SUCCESS, false); /* Get the darwin version we are running on. */ char szVersion[64]; int vrc = RTSystemQueryOSInfo(RTSYSOSINFO_RELEASE, &szVersion[0], sizeof(szVersion)); if (RT_SUCCESS(vrc)) { vrc = RTStrToUInt32Ex(&szVersion[0], NULL, 10, &g_uMajorDarwin); AssertLogRelMsg(vrc == VINF_SUCCESS || vrc == VWRN_TRAILING_CHARS, ("Failed to convert the major part of the version string '%s' into an integer: %Rrc\n", szVersion, vrc)); } else AssertLogRelMsgFailed(("Failed to query the OS release version with %Rrc\n", vrc)); } return true; } /** * Checks whether the value exists. * * @returns true / false accordingly. * @param DictRef The dictionary. * @param KeyStrRef The key name. */ static bool darwinDictIsPresent(CFDictionaryRef DictRef, CFStringRef KeyStrRef) { return !!CFDictionaryGetValue(DictRef, KeyStrRef); } /** * Gets a boolean value. * * @returns Success indicator (true/false). * @param DictRef The dictionary. * @param KeyStrRef The key name. * @param pf Where to store the key value. */ static bool darwinDictGetBool(CFDictionaryRef DictRef, CFStringRef KeyStrRef, bool *pf) { CFTypeRef BoolRef = CFDictionaryGetValue(DictRef, KeyStrRef); if ( BoolRef && CFGetTypeID(BoolRef) == CFBooleanGetTypeID()) { *pf = CFBooleanGetValue((CFBooleanRef)BoolRef); return true; } *pf = false; return false; } /** * Gets an unsigned 8-bit integer value. * * @returns Success indicator (true/false). * @param DictRef The dictionary. * @param KeyStrRef The key name. * @param pu8 Where to store the key value. */ static bool darwinDictGetU8(CFDictionaryRef DictRef, CFStringRef KeyStrRef, uint8_t *pu8) { CFTypeRef ValRef = CFDictionaryGetValue(DictRef, KeyStrRef); if (ValRef) { if (CFNumberGetValue((CFNumberRef)ValRef, kCFNumberSInt8Type, pu8)) return true; } *pu8 = 0; return false; } /** * Gets an unsigned 16-bit integer value. * * @returns Success indicator (true/false). * @param DictRef The dictionary. * @param KeyStrRef The key name. * @param pu16 Where to store the key value. */ static bool darwinDictGetU16(CFDictionaryRef DictRef, CFStringRef KeyStrRef, uint16_t *pu16) { CFTypeRef ValRef = CFDictionaryGetValue(DictRef, KeyStrRef); if (ValRef) { if (CFNumberGetValue((CFNumberRef)ValRef, kCFNumberSInt16Type, pu16)) return true; } *pu16 = 0; return false; } /** * Gets an unsigned 32-bit integer value. * * @returns Success indicator (true/false). * @param DictRef The dictionary. * @param KeyStrRef The key name. * @param pu32 Where to store the key value. */ static bool darwinDictGetU32(CFDictionaryRef DictRef, CFStringRef KeyStrRef, uint32_t *pu32) { CFTypeRef ValRef = CFDictionaryGetValue(DictRef, KeyStrRef); if (ValRef) { if (CFNumberGetValue((CFNumberRef)ValRef, kCFNumberSInt32Type, pu32)) return true; } *pu32 = 0; return false; } /** * Gets an unsigned 64-bit integer value. * * @returns Success indicator (true/false). * @param DictRef The dictionary. * @param KeyStrRef The key name. * @param pu64 Where to store the key value. */ static bool darwinDictGetU64(CFDictionaryRef DictRef, CFStringRef KeyStrRef, uint64_t *pu64) { CFTypeRef ValRef = CFDictionaryGetValue(DictRef, KeyStrRef); if (ValRef) { if (CFNumberGetValue((CFNumberRef)ValRef, kCFNumberSInt64Type, pu64)) return true; } *pu64 = 0; return false; } /** * Gets a RTPROCESS value. * * @returns Success indicator (true/false). * @param DictRef The dictionary. * @param KeyStrRef The key name. * @param pProcess Where to store the key value. */ static bool darwinDictGetProcess(CFMutableDictionaryRef DictRef, CFStringRef KeyStrRef, PRTPROCESS pProcess) { switch (sizeof(*pProcess)) { case sizeof(uint16_t): return darwinDictGetU16(DictRef, KeyStrRef, (uint16_t *)pProcess); case sizeof(uint32_t): return darwinDictGetU32(DictRef, KeyStrRef, (uint32_t *)pProcess); case sizeof(uint64_t): return darwinDictGetU64(DictRef, KeyStrRef, (uint64_t *)pProcess); default: AssertMsgFailedReturn(("%d\n", sizeof(*pProcess)), false); } } /** * Gets string value, converted to UTF-8 and put in user buffer. * * @returns Success indicator (true/false). * @param DictRef The dictionary. * @param KeyStrRef The key name. * @param psz The string buffer. On failure this will be an empty string (""). * @param cch The size of the buffer. */ static bool darwinDictGetString(CFDictionaryRef DictRef, CFStringRef KeyStrRef, char *psz, size_t cch) { CFTypeRef ValRef = CFDictionaryGetValue(DictRef, KeyStrRef); if (ValRef) { if (CFStringGetCString((CFStringRef)ValRef, psz, (CFIndex)cch, kCFStringEncodingUTF8)) return true; } Assert(cch > 0); *psz = '\0'; return false; } /** * Gets string value, converted to UTF-8 and put in a IPRT string buffer. * * @returns Success indicator (true/false). * @param DictRef The dictionary. * @param KeyStrRef The key name. * @param ppsz Where to store the key value. Free with RTStrFree. Set to NULL on failure. */ static bool darwinDictDupString(CFDictionaryRef DictRef, CFStringRef KeyStrRef, char **ppsz) { char szBuf[512]; if (darwinDictGetString(DictRef, KeyStrRef, szBuf, sizeof(szBuf))) { USBLibPurgeEncoding(szBuf); *ppsz = RTStrDup(szBuf); if (*ppsz) return true; } *ppsz = NULL; return false; } /** * Gets a byte string (data) of a specific size. * * @returns Success indicator (true/false). * @param DictRef The dictionary. * @param KeyStrRef The key name. * @param pvBuf The buffer to store the bytes in. * @param cbBuf The size of the buffer. This must exactly match the data size. */ static bool darwinDictGetData(CFDictionaryRef DictRef, CFStringRef KeyStrRef, void *pvBuf, size_t cbBuf) { CFTypeRef ValRef = CFDictionaryGetValue(DictRef, KeyStrRef); if (ValRef) { CFIndex cbActual = CFDataGetLength((CFDataRef)ValRef); if (cbActual >= 0 && cbBuf == (size_t)cbActual) { CFDataGetBytes((CFDataRef)ValRef, CFRangeMake(0, (CFIndex)cbBuf), (uint8_t *)pvBuf); return true; } } memset(pvBuf, '\0', cbBuf); return false; } #if 1 && !defined(STANDALONE_TESTCASE) /* dumping disabled */ # define DARWIN_IOKIT_LOG(a) Log(a) # define DARWIN_IOKIT_LOG_FLUSH() do {} while (0) # define DARWIN_IOKIT_DUMP_OBJ(o) do {} while (0) #else # if defined(STANDALONE_TESTCASE) # include # define DARWIN_IOKIT_LOG(a) RTPrintf a # define DARWIN_IOKIT_LOG_FLUSH() RTStrmFlush(g_pStdOut) # else # define DARWIN_IOKIT_LOG(a) RTLogPrintf a # define DARWIN_IOKIT_LOG_FLUSH() RTLogFlush(NULL) # endif # define DARWIN_IOKIT_DUMP_OBJ(o) darwinDumpObj(o) /** * Callback for dumping a dictionary key. * * @param pvKey The key name. * @param pvValue The key value * @param pvUser The recursion depth. */ static void darwinDumpDictCallback(const void *pvKey, const void *pvValue, void *pvUser) { /* display the key name. */ char *pszKey = (char *)RTMemTmpAlloc(1024); if (!CFStringGetCString((CFStringRef)pvKey, pszKey, 1024, kCFStringEncodingUTF8)) strcpy(pszKey, "CFStringGetCString failure"); DARWIN_IOKIT_LOG(("%+*s%s", (int)(uintptr_t)pvUser, "", pszKey)); RTMemTmpFree(pszKey); /* display the value type */ CFTypeID Type = CFGetTypeID(pvValue); DARWIN_IOKIT_LOG((" [%d-", Type)); /* display the value */ if (Type == CFDictionaryGetTypeID()) { DARWIN_IOKIT_LOG(("dictionary] =\n" "%-*s{\n", (int)(uintptr_t)pvUser, "")); CFDictionaryApplyFunction((CFDictionaryRef)pvValue, darwinDumpDictCallback, (void *)((uintptr_t)pvUser + 4)); DARWIN_IOKIT_LOG(("%-*s}\n", (int)(uintptr_t)pvUser, "")); } else if (Type == CFBooleanGetTypeID()) DARWIN_IOKIT_LOG(("bool] = %s\n", CFBooleanGetValue((CFBooleanRef)pvValue) ? "true" : "false")); else if (Type == CFNumberGetTypeID()) { union { SInt8 s8; SInt16 s16; SInt32 s32; SInt64 s64; Float32 rf32; Float64 rd64; char ch; short s; int i; long l; long long ll; float rf; double rd; CFIndex iCF; } u; RT_ZERO(u); CFNumberType NumType = CFNumberGetType((CFNumberRef)pvValue); if (CFNumberGetValue((CFNumberRef)pvValue, NumType, &u)) { switch (CFNumberGetType((CFNumberRef)pvValue)) { case kCFNumberSInt8Type: DARWIN_IOKIT_LOG(("SInt8] = %RI8 (%#RX8)\n", NumType, u.s8, u.s8)); break; case kCFNumberSInt16Type: DARWIN_IOKIT_LOG(("SInt16] = %RI16 (%#RX16)\n", NumType, u.s16, u.s16)); break; case kCFNumberSInt32Type: DARWIN_IOKIT_LOG(("SInt32] = %RI32 (%#RX32)\n", NumType, u.s32, u.s32)); break; case kCFNumberSInt64Type: DARWIN_IOKIT_LOG(("SInt64] = %RI64 (%#RX64)\n", NumType, u.s64, u.s64)); break; case kCFNumberFloat32Type: DARWIN_IOKIT_LOG(("float32] = %#lx\n", NumType, u.l)); break; case kCFNumberFloat64Type: DARWIN_IOKIT_LOG(("float64] = %#llx\n", NumType, u.ll)); break; case kCFNumberFloatType: DARWIN_IOKIT_LOG(("float] = %#lx\n", NumType, u.l)); break; case kCFNumberDoubleType: DARWIN_IOKIT_LOG(("double] = %#llx\n", NumType, u.ll)); break; case kCFNumberCharType: DARWIN_IOKIT_LOG(("char] = %hhd (%hhx)\n", NumType, u.ch, u.ch)); break; case kCFNumberShortType: DARWIN_IOKIT_LOG(("short] = %hd (%hx)\n", NumType, u.s, u.s)); break; case kCFNumberIntType: DARWIN_IOKIT_LOG(("int] = %d (%#x)\n", NumType, u.i, u.i)); break; case kCFNumberLongType: DARWIN_IOKIT_LOG(("long] = %ld (%#lx)\n", NumType, u.l, u.l)); break; case kCFNumberLongLongType: DARWIN_IOKIT_LOG(("long long] = %lld (%#llx)\n", NumType, u.ll, u.ll)); break; case kCFNumberCFIndexType: DARWIN_IOKIT_LOG(("CFIndex] = %lld (%#llx)\n", NumType, (long long)u.iCF, (long long)u.iCF)); break; break; default: DARWIN_IOKIT_LOG(("%d?] = %lld (%llx)\n", NumType, u.ll, u.ll)); break; } } else DARWIN_IOKIT_LOG(("number] = CFNumberGetValue failed\n")); } else if (Type == CFBooleanGetTypeID()) DARWIN_IOKIT_LOG(("boolean] = %RTbool\n", CFBooleanGetValue((CFBooleanRef)pvValue))); else if (Type == CFStringGetTypeID()) { DARWIN_IOKIT_LOG(("string] = ")); char *pszValue = (char *)RTMemTmpAlloc(16*_1K); if (!CFStringGetCString((CFStringRef)pvValue, pszValue, 16*_1K, kCFStringEncodingUTF8)) strcpy(pszValue, "CFStringGetCString failure"); DARWIN_IOKIT_LOG(("\"%s\"\n", pszValue)); RTMemTmpFree(pszValue); } else if (Type == CFDataGetTypeID()) { CFIndex cb = CFDataGetLength((CFDataRef)pvValue); DARWIN_IOKIT_LOG(("%zu bytes] =", (size_t)cb)); void *pvData = RTMemTmpAlloc(cb + 8); CFDataGetBytes((CFDataRef)pvValue, CFRangeMake(0, cb), (uint8_t *)pvData); if (!cb) DARWIN_IOKIT_LOG((" \n")); else if (cb <= 32) DARWIN_IOKIT_LOG((" %.*Rhxs\n", cb, pvData)); else DARWIN_IOKIT_LOG(("\n%.*Rhxd\n", cb, pvData)); RTMemTmpFree(pvData); } else DARWIN_IOKIT_LOG(("??] = %p\n", pvValue)); } /** * Dumps a dictionary to the log. * * @param DictRef The dictionary to dump. */ static void darwinDumpDict(CFDictionaryRef DictRef, unsigned cIndents) { CFDictionaryApplyFunction(DictRef, darwinDumpDictCallback, (void *)(uintptr_t)cIndents); DARWIN_IOKIT_LOG_FLUSH(); } /** * Dumps an I/O kit registry object and all it children. * @param Object The object to dump. * @param cIndents The number of indents to use. */ static void darwinDumpObjInt(io_object_t Object, unsigned cIndents) { static io_string_t s_szPath; kern_return_t krc = IORegistryEntryGetPath(Object, kIOServicePlane, s_szPath); if (krc != KERN_SUCCESS) strcpy(s_szPath, "IORegistryEntryGetPath failed"); DARWIN_IOKIT_LOG(("Dumping %p - %s:\n", (const void *)Object, s_szPath)); CFMutableDictionaryRef PropsRef = 0; krc = IORegistryEntryCreateCFProperties(Object, &PropsRef, kCFAllocatorDefault, kNilOptions); if (krc == KERN_SUCCESS) { darwinDumpDict(PropsRef, cIndents + 4); CFRelease(PropsRef); } /* * Children. */ io_iterator_t Children; krc = IORegistryEntryGetChildIterator(Object, kIOServicePlane, &Children); if (krc == KERN_SUCCESS) { io_object_t Child; while ((Child = IOIteratorNext(Children)) != IO_OBJECT_NULL) { darwinDumpObjInt(Child, cIndents + 4); IOObjectRelease(Child); } IOObjectRelease(Children); } else DARWIN_IOKIT_LOG(("IORegistryEntryGetChildIterator -> %#x\n", krc)); } /** * Dumps an I/O kit registry object and all it children. * @param Object The object to dump. */ static void darwinDumpObj(io_object_t Object) { darwinDumpObjInt(Object, 0); } #endif /* helpers for dumping registry dictionaries */ #ifdef VBOX_WITH_USB /** * Notification data created by DarwinSubscribeUSBNotifications, used by * the callbacks and finally freed by DarwinUnsubscribeUSBNotifications. */ typedef struct DARWINUSBNOTIFY { /** The notification port. * It's shared between the notification callbacks. */ IONotificationPortRef NotifyPort; /** The run loop source for NotifyPort. */ CFRunLoopSourceRef NotifyRLSrc; /** The attach notification iterator. */ io_iterator_t AttachIterator; /** The 2nd attach notification iterator. */ io_iterator_t AttachIterator2; /** The detach notification iterator. */ io_iterator_t DetachIterator; } DARWINUSBNOTIFY, *PDARWINUSBNOTIFY; /** * Run thru an iterator. * * The docs says this is necessary to start getting notifications, * so this function is called in the callbacks and right after * registering the notification. * * @param pIterator The iterator reference. */ static void darwinDrainIterator(io_iterator_t pIterator) { io_object_t Object; while ((Object = IOIteratorNext(pIterator)) != IO_OBJECT_NULL) { DARWIN_IOKIT_DUMP_OBJ(Object); IOObjectRelease(Object); } } /** * Callback for the 1st attach notification. * * @param pvNotify Our data. * @param NotifyIterator The notification iterator. */ static void darwinUSBAttachNotification1(void *pvNotify, io_iterator_t NotifyIterator) { DARWIN_IOKIT_LOG(("USB Attach Notification1\n")); NOREF(pvNotify); //PDARWINUSBNOTIFY pNotify = (PDARWINUSBNOTIFY)pvNotify; darwinDrainIterator(NotifyIterator); } /** * Callback for the 2nd attach notification. * * @param pvNotify Our data. * @param NotifyIterator The notification iterator. */ static void darwinUSBAttachNotification2(void *pvNotify, io_iterator_t NotifyIterator) { DARWIN_IOKIT_LOG(("USB Attach Notification2\n")); NOREF(pvNotify); //PDARWINUSBNOTIFY pNotify = (PDARWINUSBNOTIFY)pvNotify; darwinDrainIterator(NotifyIterator); } /** * Callback for the detach notifications. * * @param pvNotify Our data. * @param NotifyIterator The notification iterator. */ static void darwinUSBDetachNotification(void *pvNotify, io_iterator_t NotifyIterator) { DARWIN_IOKIT_LOG(("USB Detach Notification\n")); NOREF(pvNotify); //PDARWINUSBNOTIFY pNotify = (PDARWINUSBNOTIFY)pvNotify; darwinDrainIterator(NotifyIterator); } /** * Subscribes the run loop to USB notification events relevant to * device attach/detach. * * The source mode for these events is defined as VBOX_IOKIT_MODE_STRING * so that the caller can listen to events from this mode only and * re-evalutate the list of attached devices whenever an event arrives. * * @returns opaque for passing to the unsubscribe function. If NULL * something unexpectedly failed during subscription. */ void *DarwinSubscribeUSBNotifications(void) { AssertReturn(darwinOpenMasterPort(), NULL); PDARWINUSBNOTIFY pNotify = (PDARWINUSBNOTIFY)RTMemAllocZ(sizeof(*pNotify)); AssertReturn(pNotify, NULL); /* * Create the notification port, bake it into a runloop source which we * then add to our run loop. */ pNotify->NotifyPort = IONotificationPortCreate(g_MasterPort); Assert(pNotify->NotifyPort); if (pNotify->NotifyPort) { pNotify->NotifyRLSrc = IONotificationPortGetRunLoopSource(pNotify->NotifyPort); Assert(pNotify->NotifyRLSrc); if (pNotify->NotifyRLSrc) { CFRunLoopRef RunLoopRef = CFRunLoopGetCurrent(); CFRetain(RunLoopRef); /* Workaround for crash when cleaning up the TLS / runloop((sub)mode). See @bugref{2807}. */ CFRunLoopAddSource(RunLoopRef, pNotify->NotifyRLSrc, CFSTR(VBOX_IOKIT_MODE_STRING)); /* * Create the notification callbacks. */ kern_return_t krc = IOServiceAddMatchingNotification(pNotify->NotifyPort, kIOPublishNotification, IOServiceMatching(kIOUSBDeviceClassName), darwinUSBAttachNotification1, pNotify, &pNotify->AttachIterator); if (krc == KERN_SUCCESS) { darwinDrainIterator(pNotify->AttachIterator); krc = IOServiceAddMatchingNotification(pNotify->NotifyPort, kIOMatchedNotification, IOServiceMatching(kIOUSBDeviceClassName), darwinUSBAttachNotification2, pNotify, &pNotify->AttachIterator2); if (krc == KERN_SUCCESS) { darwinDrainIterator(pNotify->AttachIterator2); krc = IOServiceAddMatchingNotification(pNotify->NotifyPort, kIOTerminatedNotification, IOServiceMatching(kIOUSBDeviceClassName), darwinUSBDetachNotification, pNotify, &pNotify->DetachIterator); if (krc == KERN_SUCCESS) { darwinDrainIterator(pNotify->DetachIterator); return pNotify; } IOObjectRelease(pNotify->AttachIterator2); } IOObjectRelease(pNotify->AttachIterator); } CFRunLoopRemoveSource(RunLoopRef, pNotify->NotifyRLSrc, CFSTR(VBOX_IOKIT_MODE_STRING)); } IONotificationPortDestroy(pNotify->NotifyPort); } RTMemFree(pNotify); return NULL; } /** * Unsubscribe the run loop from USB notification subscribed to * by DarwinSubscribeUSBNotifications. * * @param pvOpaque The return value from DarwinSubscribeUSBNotifications. */ void DarwinUnsubscribeUSBNotifications(void *pvOpaque) { PDARWINUSBNOTIFY pNotify = (PDARWINUSBNOTIFY)pvOpaque; if (!pNotify) return; IOObjectRelease(pNotify->AttachIterator); pNotify->AttachIterator = IO_OBJECT_NULL; IOObjectRelease(pNotify->AttachIterator2); pNotify->AttachIterator2 = IO_OBJECT_NULL; IOObjectRelease(pNotify->DetachIterator); pNotify->DetachIterator = IO_OBJECT_NULL; CFRunLoopRemoveSource(CFRunLoopGetCurrent(), pNotify->NotifyRLSrc, CFSTR(VBOX_IOKIT_MODE_STRING)); IONotificationPortDestroy(pNotify->NotifyPort); pNotify->NotifyRLSrc = NULL; pNotify->NotifyPort = NULL; RTMemFree(pNotify); } /** * Descends recursively into a IORegistry tree locating the first object of a given class. * * The search is performed depth first. * * @returns Object reference if found, NULL if not. * @param Object The current tree root. * @param pszClass The name of the class we're looking for. * @param pszNameBuf A scratch buffer for query the class name in to avoid * wasting 128 bytes on an io_name_t object for every recursion. */ static io_object_t darwinFindObjectByClass(io_object_t Object, const char *pszClass, io_name_t pszNameBuf) { io_iterator_t Children; kern_return_t krc = IORegistryEntryGetChildIterator(Object, kIOServicePlane, &Children); if (krc != KERN_SUCCESS) return IO_OBJECT_NULL; io_object_t Child; while ((Child = IOIteratorNext(Children)) != IO_OBJECT_NULL) { krc = IOObjectGetClass(Child, pszNameBuf); if ( krc == KERN_SUCCESS && !strcmp(pszNameBuf, pszClass)) break; io_object_t GrandChild = darwinFindObjectByClass(Child, pszClass, pszNameBuf); IOObjectRelease(Child); if (GrandChild) { Child = GrandChild; break; } } IOObjectRelease(Children); return Child; } /** * Descends recursively into IOUSBMassStorageClass tree to check whether * the MSD is mounted or not. * * The current heuristic is to look for the IOMedia class. * * @returns true if mounted, false if not. * @param MSDObj The IOUSBMassStorageClass object. * @param pszNameBuf A scratch buffer for query the class name in to avoid * wasting 128 bytes on an io_name_t object for every recursion. */ static bool darwinIsMassStorageInterfaceInUse(io_object_t MSDObj, io_name_t pszNameBuf) { io_object_t MediaObj = darwinFindObjectByClass(MSDObj, kIOMediaClass, pszNameBuf); if (MediaObj) { CFMutableDictionaryRef pProperties; kern_return_t krc; bool fInUse = true; krc = IORegistryEntryCreateCFProperties(MediaObj, &pProperties, kCFAllocatorDefault, kNilOptions); if (krc == KERN_SUCCESS) { CFBooleanRef pBoolValue = (CFBooleanRef)CFDictionaryGetValue(pProperties, CFSTR(kIOMediaOpenKey)); if (pBoolValue) fInUse = CFBooleanGetValue(pBoolValue); CFRelease(pProperties); } /* more checks? */ IOObjectRelease(MediaObj); return fInUse; } return false; } /** * Finds the matching IOUSBHostDevice registry entry for the given legacy USB device interface (IOUSBDevice). * * @returns kern_return_t error code. * @param USBDeviceLegacy The legacy device I/O Kit object. * @param pUSBDevice Where to store the IOUSBHostDevice object on success. */ static kern_return_t darwinGetUSBHostDeviceFromLegacyDevice(io_object_t USBDeviceLegacy, io_object_t *pUSBDevice) { kern_return_t krc = KERN_SUCCESS; uint64_t uIoRegEntryId = 0; *pUSBDevice = 0; /* Get the registry entry ID to match against. */ krc = IORegistryEntryGetRegistryEntryID(USBDeviceLegacy, &uIoRegEntryId); if (krc != KERN_SUCCESS) return krc; /* * Create a matching dictionary for searching for USB Devices in the IOKit. */ CFMutableDictionaryRef RefMatchingDict = IOServiceMatching(kIOUSBHostDeviceClassName); AssertReturn(RefMatchingDict, KERN_FAILURE); /* * Perform the search and get a collection of USB Device back. */ io_iterator_t USBDevices = IO_OBJECT_NULL; IOReturn irc = IOServiceGetMatchingServices(g_MasterPort, RefMatchingDict, &USBDevices); AssertMsgReturn(irc == kIOReturnSuccess, ("irc=%d\n", irc), KERN_FAILURE); RefMatchingDict = NULL; /* the reference is consumed by IOServiceGetMatchingServices. */ /* * Walk the devices and check for the matching alternate registry entry ID. */ io_object_t USBDevice; while ((USBDevice = IOIteratorNext(USBDevices)) != IO_OBJECT_NULL) { DARWIN_IOKIT_DUMP_OBJ(USBDevice); CFMutableDictionaryRef PropsRef = 0; krc = IORegistryEntryCreateCFProperties(USBDevice, &PropsRef, kCFAllocatorDefault, kNilOptions); if (krc == KERN_SUCCESS) { uint64_t uAltRegId = 0; if ( darwinDictGetU64(PropsRef, CFSTR("AppleUSBAlternateServiceRegistryID"), &uAltRegId) && uAltRegId == uIoRegEntryId) { *pUSBDevice = USBDevice; CFRelease(PropsRef); break; } CFRelease(PropsRef); } IOObjectRelease(USBDevice); } IOObjectRelease(USBDevices); return krc; } static bool darwinUSBDeviceIsGrabbedDetermineState(PUSBDEVICE pCur, io_object_t USBDevice) { /* * Iterate the interfaces (among the children of the IOUSBDevice object). */ io_iterator_t Interfaces; kern_return_t krc = IORegistryEntryGetChildIterator(USBDevice, kIOServicePlane, &Interfaces); if (krc != KERN_SUCCESS) return false; bool fHaveOwner = false; RTPROCESS Owner = NIL_RTPROCESS; bool fHaveClient = false; RTPROCESS Client = NIL_RTPROCESS; io_object_t Interface; while ((Interface = IOIteratorNext(Interfaces)) != IO_OBJECT_NULL) { io_name_t szName; krc = IOObjectGetClass(Interface, szName); if ( krc == KERN_SUCCESS && !strcmp(szName, VBOXUSBDEVICE_CLASS_NAME)) { CFMutableDictionaryRef PropsRef = 0; krc = IORegistryEntryCreateCFProperties(Interface, &PropsRef, kCFAllocatorDefault, kNilOptions); if (krc == KERN_SUCCESS) { fHaveOwner = darwinDictGetProcess(PropsRef, CFSTR(VBOXUSB_OWNER_KEY), &Owner); fHaveClient = darwinDictGetProcess(PropsRef, CFSTR(VBOXUSB_CLIENT_KEY), &Client); CFRelease(PropsRef); } } IOObjectRelease(Interface); } IOObjectRelease(Interfaces); /* * Calc the status. */ if (fHaveOwner) { if (Owner == RTProcSelf()) pCur->enmState = !fHaveClient || Client == NIL_RTPROCESS || !Client ? USBDEVICESTATE_HELD_BY_PROXY : USBDEVICESTATE_USED_BY_GUEST; else pCur->enmState = USBDEVICESTATE_USED_BY_HOST; } return fHaveOwner; } /** * Worker for determining the USB device state for devices which are not captured by the VBoxUSB driver * Works for both, IOUSBDevice (legacy on release >= El Capitan) and IOUSBHostDevice (available on >= El Capitan). * * @param pCur The USB device data. * @param USBDevice I/O Kit USB device object (either IOUSBDevice or IOUSBHostDevice). */ static void darwinDetermineUSBDeviceStateWorker(PUSBDEVICE pCur, io_object_t USBDevice) { /* * Iterate the interfaces (among the children of the IOUSBDevice object). */ io_iterator_t Interfaces; kern_return_t krc = IORegistryEntryGetChildIterator(USBDevice, kIOServicePlane, &Interfaces); if (krc != KERN_SUCCESS) return; bool fUserClientOnly = true; bool fConfigured = false; bool fInUse = false; bool fSeizable = true; io_object_t Interface; while ((Interface = IOIteratorNext(Interfaces)) != IO_OBJECT_NULL) { io_name_t szName; krc = IOObjectGetClass(Interface, szName); if ( krc == KERN_SUCCESS && ( !strcmp(szName, "IOUSBInterface") || !strcmp(szName, "IOUSBHostInterface"))) { fConfigured = true; /* * Iterate the interface children looking for stuff other than * IOUSBUserClientInit objects. */ io_iterator_t Children1; krc = IORegistryEntryGetChildIterator(Interface, kIOServicePlane, &Children1); if (krc == KERN_SUCCESS) { io_object_t Child1; while ((Child1 = IOIteratorNext(Children1)) != IO_OBJECT_NULL) { krc = IOObjectGetClass(Child1, szName); if ( krc == KERN_SUCCESS && strcmp(szName, "IOUSBUserClientInit")) { fUserClientOnly = false; if ( !strcmp(szName, "IOUSBMassStorageClass") || !strcmp(szName, "IOUSBMassStorageInterfaceNub")) { /* Only permit capturing MSDs that aren't mounted, at least until the GUI starts poping up warnings about data loss and such when capturing a busy device. */ fSeizable = false; fInUse |= darwinIsMassStorageInterfaceInUse(Child1, szName); } else if (!strcmp(szName, "IOUSBHIDDriver") || !strcmp(szName, "AppleHIDMouse") /** @todo more? */) { /* For now, just assume that all HID devices are inaccessible because of the greedy HID service. */ fSeizable = false; fInUse = true; } else fInUse = true; } IOObjectRelease(Child1); } IOObjectRelease(Children1); } } IOObjectRelease(Interface); } IOObjectRelease(Interfaces); /* * Calc the status. */ if (!fInUse) pCur->enmState = USBDEVICESTATE_UNUSED; else pCur->enmState = fSeizable ? USBDEVICESTATE_USED_BY_HOST_CAPTURABLE : USBDEVICESTATE_USED_BY_HOST; } /** * Worker function for DarwinGetUSBDevices() that tries to figure out * what state the device is in and set enmState. * * This is mostly a matter of distinguishing between devices that nobody * uses, devices that can be seized and devices that cannot be grabbed. * * @param pCur The USB device data. * @param USBDevice The USB device object. * @param PropsRef The USB device properties. */ static void darwinDeterminUSBDeviceState(PUSBDEVICE pCur, io_object_t USBDevice, CFMutableDictionaryRef /* PropsRef */) { if (!darwinUSBDeviceIsGrabbedDetermineState(pCur, USBDevice)) { /* * The USB stack was completely reworked on El Capitan and the IOUSBDevice and IOUSBInterface * are deprecated and don't return the information required for the additional checks below. * We also can't directly make use of the new classes (IOUSBHostDevice and IOUSBHostInterface) * because VBoxUSB only exposes the legacy interfaces. Trying to use the new classes results in errors * because the I/O Kit USB library wants to use the new interfaces. The result is us losing the device * form the list when VBoxUSB has attached to the USB device. * * To make the checks below work we have to get hold of the IOUSBHostDevice and IOUSBHostInterface * instances for the current device. Fortunately the IOUSBHostDevice instance contains a * "AppleUSBAlternateServiceRegistryID" which points to the legacy class instance for the same device. * So just iterate over the list of IOUSBHostDevice instances and check whether the * AppleUSBAlternateServiceRegistryID property matches with the legacy instance. * * The upside is that we can keep VBoxUSB untouched and still compatible with older OS X releases. */ if (g_uMajorDarwin >= VBOX_OSX_EL_CAPTIAN_VER) { io_object_t IOUSBDeviceNew = IO_OBJECT_NULL; kern_return_t krc = darwinGetUSBHostDeviceFromLegacyDevice(USBDevice, &IOUSBDeviceNew); if ( krc == KERN_SUCCESS && IOUSBDeviceNew != IO_OBJECT_NULL) { darwinDetermineUSBDeviceStateWorker(pCur, IOUSBDeviceNew); IOObjectRelease(IOUSBDeviceNew); } } else darwinDetermineUSBDeviceStateWorker(pCur, USBDevice); } } /** * Enumerate the USB devices returning a FIFO of them. * * @returns Pointer to the head. * USBProxyService::freeDevice is expected to free each of the list elements. */ PUSBDEVICE DarwinGetUSBDevices(void) { AssertReturn(darwinOpenMasterPort(), NULL); //DARWIN_IOKIT_LOG(("DarwinGetUSBDevices\n")); /* * Create a matching dictionary for searching for USB Devices in the IOKit. */ CFMutableDictionaryRef RefMatchingDict = IOServiceMatching(kIOUSBDeviceClassName); AssertReturn(RefMatchingDict, NULL); /* * Perform the search and get a collection of USB Device back. */ io_iterator_t USBDevices = IO_OBJECT_NULL; IOReturn irc = IOServiceGetMatchingServices(g_MasterPort, RefMatchingDict, &USBDevices); AssertMsgReturn(irc == kIOReturnSuccess, ("irc=%d\n", irc), NULL); RefMatchingDict = NULL; /* the reference is consumed by IOServiceGetMatchingServices. */ /* * Enumerate the USB Devices. */ PUSBDEVICE pHead = NULL; PUSBDEVICE pTail = NULL; unsigned i = 0; io_object_t USBDevice; while ((USBDevice = IOIteratorNext(USBDevices)) != IO_OBJECT_NULL) { DARWIN_IOKIT_DUMP_OBJ(USBDevice); /* * Query the device properties from the registry. * * We could alternatively use the device and such, but that will be * slower and we would have to resort to the registry for the three * string anyway. */ CFMutableDictionaryRef PropsRef = 0; kern_return_t krc = IORegistryEntryCreateCFProperties(USBDevice, &PropsRef, kCFAllocatorDefault, kNilOptions); if (krc == KERN_SUCCESS) { bool fOk = false; PUSBDEVICE pCur = (PUSBDEVICE)RTMemAllocZ(sizeof(*pCur)); do /* loop for breaking out of on failure. */ { AssertBreak(pCur); /* * Mandatory */ pCur->bcdUSB = 0; /* we've no idea. */ pCur->enmState = USBDEVICESTATE_USED_BY_HOST_CAPTURABLE; /* just a default, we'll try harder in a bit. */ /* Skip hubs. On 10.11 beta 3, the root hub simulations does not have a USBDeviceClass property, so simply ignore failures to retrieve it. */ if (!darwinDictGetU8(PropsRef, CFSTR(kUSBDeviceClass), &pCur->bDeviceClass)) { #ifdef VBOX_STRICT char szTmp[80]; Assert( darwinDictGetString(PropsRef, CFSTR("IOClassNameOverride"), szTmp, sizeof(szTmp)) && strcmp(szTmp, "IOUSBRootHubDevice") == 0); #endif break; } if (pCur->bDeviceClass == 0x09 /* hub, find a define! */) break; AssertBreak(darwinDictGetU8(PropsRef, CFSTR(kUSBDeviceSubClass), &pCur->bDeviceSubClass)); AssertBreak(darwinDictGetU8(PropsRef, CFSTR(kUSBDeviceProtocol), &pCur->bDeviceProtocol)); AssertBreak(darwinDictGetU16(PropsRef, CFSTR(kUSBVendorID), &pCur->idVendor)); AssertBreak(darwinDictGetU16(PropsRef, CFSTR(kUSBProductID), &pCur->idProduct)); AssertBreak(darwinDictGetU16(PropsRef, CFSTR(kUSBDeviceReleaseNumber), &pCur->bcdDevice)); uint32_t u32LocationId; AssertBreak(darwinDictGetU32(PropsRef, CFSTR(kUSBDevicePropertyLocationID), &u32LocationId)); uint64_t u64SessionId; AssertBreak(darwinDictGetU64(PropsRef, CFSTR("sessionID"), &u64SessionId)); char szAddress[64]; RTStrPrintf(szAddress, sizeof(szAddress), "p=0x%04RX16;v=0x%04RX16;s=0x%016RX64;l=0x%08RX32", pCur->idProduct, pCur->idVendor, u64SessionId, u32LocationId); pCur->pszAddress = RTStrDup(szAddress); AssertBreak(pCur->pszAddress); pCur->bBus = u32LocationId >> 24; darwinDictGetU8(PropsRef, CFSTR("PortNum"), &pCur->bPort); /* Not present in 10.11 beta 3, so ignore failure. (Is set to zero.) */ uint8_t bSpeed; AssertBreak(darwinDictGetU8(PropsRef, CFSTR(kUSBDevicePropertySpeed), &bSpeed)); Assert(bSpeed <= 4); pCur->enmSpeed = bSpeed == 4 ? USBDEVICESPEED_SUPER : bSpeed == 3 ? USBDEVICESPEED_SUPER : bSpeed == 2 ? USBDEVICESPEED_HIGH : bSpeed == 1 ? USBDEVICESPEED_FULL : bSpeed == 0 ? USBDEVICESPEED_LOW : USBDEVICESPEED_UNKNOWN; /* * Optional. * There are some nameless device in the iMac, apply names to them. */ darwinDictDupString(PropsRef, CFSTR("USB Vendor Name"), (char **)&pCur->pszManufacturer); if ( !pCur->pszManufacturer && pCur->idVendor == kIOUSBVendorIDAppleComputer) pCur->pszManufacturer = RTStrDup("Apple Computer, Inc."); darwinDictDupString(PropsRef, CFSTR("USB Product Name"), (char **)&pCur->pszProduct); if ( !pCur->pszProduct && pCur->bDeviceClass == 224 /* Wireless */ && pCur->bDeviceSubClass == 1 /* Radio Frequency */ && pCur->bDeviceProtocol == 1 /* Bluetooth */) pCur->pszProduct = RTStrDup("Bluetooth"); darwinDictDupString(PropsRef, CFSTR("USB Serial Number"), (char **)&pCur->pszSerialNumber); pCur->pszBackend = RTStrDup("host"); AssertBreak(pCur->pszBackend); #if 0 /* leave the remainder as zero for now. */ /* * Create a plugin interface for the service and query its USB Device interface. */ SInt32 Score = 0; IOCFPlugInInterface **ppPlugInInterface = NULL; irc = IOCreatePlugInInterfaceForService(USBDevice, kIOUSBDeviceUserClientTypeID, kIOCFPlugInInterfaceID, &ppPlugInInterface, &Score); if (irc == kIOReturnSuccess) { IOUSBDeviceInterface245 **ppUSBDevI = NULL; HRESULT hrc = (*ppPlugInInterface)->QueryInterface(ppPlugInInterface, CFUUIDGetUUIDBytes(kIOUSBDeviceInterfaceID245), (LPVOID *)&ppUSBDevI); irc = IODestroyPlugInInterface(ppPlugInInterface); Assert(irc == kIOReturnSuccess); ppPlugInInterface = NULL; if (hrc == S_OK) { /** @todo enumerate configurations and interfaces if we actually need them. */ //IOReturn (*GetNumberOfConfigurations)(void *self, UInt8 *numConfig); //IOReturn (*GetConfigurationDescriptorPtr)(void *self, UInt8 configIndex, IOUSBConfigurationDescriptorPtr *desc); //IOReturn (*CreateInterfaceIterator)(void *self, IOUSBFindInterfaceRequest *req, io_iterator_t *iter); } long cReft = (*ppUSBDeviceInterface)->Release(ppUSBDeviceInterface); MY_CHECK_CREFS(cRefs); } #endif /* * Try determine the state. */ darwinDeterminUSBDeviceState(pCur, USBDevice, PropsRef); /* * We're good. Link the device. */ pCur->pPrev = pTail; if (pTail) pTail = pTail->pNext = pCur; else pTail = pHead = pCur; fOk = true; } while (0); /* cleanup on failure / skipped device. */ if (!fOk && pCur) DarwinFreeUSBDeviceFromIOKit(pCur); CFRelease(PropsRef); } else AssertMsgFailed(("krc=%#x\n", krc)); IOObjectRelease(USBDevice); i++; } IOObjectRelease(USBDevices); //DARWIN_IOKIT_LOG_FLUSH(); /* * Some post processing. There are a couple of things we have to * make 100% sure about, and that is that the (Apple) keyboard * and mouse most likely to be in use by the user aren't available * for capturing. If there is no Apple mouse or keyboard we'll * take the first one from another vendor. */ /* As it turns out, the HID service will take all keyboards and mice and we're not currently able to seize them. */ PUSBDEVICE pMouse = NULL; PUSBDEVICE pKeyboard = NULL; for (PUSBDEVICE pCur = pHead; pCur; pCur = pCur->pNext) if (pCur->idVendor == kIOUSBVendorIDAppleComputer) { /* * This test is a bit rough, should check device class/protocol but * we don't have interface info yet so that might be a bit tricky. */ if ( ( !pKeyboard || pKeyboard->idVendor != kIOUSBVendorIDAppleComputer) && pCur->pszProduct && strstr(pCur->pszProduct, " Keyboard")) pKeyboard = pCur; else if ( ( !pMouse || pMouse->idVendor != kIOUSBVendorIDAppleComputer) && pCur->pszProduct && strstr(pCur->pszProduct, " Mouse") ) pMouse = pCur; } else if (!pKeyboard || !pMouse) { if ( pCur->bDeviceClass == 3 /* HID */ && pCur->bDeviceProtocol == 1 /* Keyboard */) pKeyboard = pCur; else if ( pCur->bDeviceClass == 3 /* HID */ && pCur->bDeviceProtocol == 2 /* Mouse */) pMouse = pCur; /** @todo examin interfaces */ } if (pKeyboard) pKeyboard->enmState = USBDEVICESTATE_USED_BY_HOST; if (pMouse) pMouse->enmState = USBDEVICESTATE_USED_BY_HOST; return pHead; } #endif /* VBOX_WITH_USB */ /** * Enumerate the CD, DVD and BlueRay drives returning a FIFO of device name strings. * * @returns Pointer to the head. * The caller is responsible for calling RTMemFree() on each of the nodes. */ PDARWINDVD DarwinGetDVDDrives(void) { AssertReturn(darwinOpenMasterPort(), NULL); /* * Create a matching dictionary for searching for CD, DVD and BlueRay services in the IOKit. * * The idea is to find all the devices which are of class IOCDBlockStorageDevice. * CD devices are represented by IOCDBlockStorageDevice class itself, while DVD and BlueRay ones * have it as a parent class. */ CFMutableDictionaryRef RefMatchingDict = IOServiceMatching("IOCDBlockStorageDevice"); AssertReturn(RefMatchingDict, NULL); /* * Perform the search and get a collection of DVD services. */ io_iterator_t DVDServices = IO_OBJECT_NULL; IOReturn irc = IOServiceGetMatchingServices(g_MasterPort, RefMatchingDict, &DVDServices); AssertMsgReturn(irc == kIOReturnSuccess, ("irc=%d\n", irc), NULL); RefMatchingDict = NULL; /* the reference is consumed by IOServiceGetMatchingServices. */ /* * Enumerate the matching services. * (This enumeration must be identical to the one performed in DrvHostBase.cpp.) */ PDARWINDVD pHead = NULL; PDARWINDVD pTail = NULL; unsigned i = 0; io_object_t DVDService; while ((DVDService = IOIteratorNext(DVDServices)) != IO_OBJECT_NULL) { DARWIN_IOKIT_DUMP_OBJ(DVDService); /* * Get the properties we use to identify the DVD drive. * * While there is a (weird 12 byte) GUID, it isn't persistent * across boots. So, we have to use a combination of the * vendor name and product name properties with an optional * sequence number for identification. */ CFMutableDictionaryRef PropsRef = 0; kern_return_t krc = IORegistryEntryCreateCFProperties(DVDService, &PropsRef, kCFAllocatorDefault, kNilOptions); if (krc == KERN_SUCCESS) { /* Get the Device Characteristics dictionary. */ CFDictionaryRef DevCharRef = (CFDictionaryRef)CFDictionaryGetValue(PropsRef, CFSTR(kIOPropertyDeviceCharacteristicsKey)); if (DevCharRef) { /* The vendor name. */ char szVendor[128]; char *pszVendor = &szVendor[0]; CFTypeRef ValueRef = CFDictionaryGetValue(DevCharRef, CFSTR(kIOPropertyVendorNameKey)); if ( ValueRef && CFGetTypeID(ValueRef) == CFStringGetTypeID() && CFStringGetCString((CFStringRef)ValueRef, szVendor, sizeof(szVendor), kCFStringEncodingUTF8)) pszVendor = RTStrStrip(szVendor); else *pszVendor = '\0'; /* The product name. */ char szProduct[128]; char *pszProduct = &szProduct[0]; ValueRef = CFDictionaryGetValue(DevCharRef, CFSTR(kIOPropertyProductNameKey)); if ( ValueRef && CFGetTypeID(ValueRef) == CFStringGetTypeID() && CFStringGetCString((CFStringRef)ValueRef, szProduct, sizeof(szProduct), kCFStringEncodingUTF8)) pszProduct = RTStrStrip(szProduct); else *pszProduct = '\0'; /* Construct the name and check for duplicates. */ char szName[256 + 32]; if (*pszVendor || *pszProduct) { if (*pszVendor && *pszProduct) RTStrPrintf(szName, sizeof(szName), "%s %s", pszVendor, pszProduct); else strcpy(szName, *pszVendor ? pszVendor : pszProduct); for (PDARWINDVD pCur = pHead; pCur; pCur = pCur->pNext) { if (!strcmp(szName, pCur->szName)) { if (*pszVendor && *pszProduct) RTStrPrintf(szName, sizeof(szName), "%s %s (#%u)", pszVendor, pszProduct, i); else RTStrPrintf(szName, sizeof(szName), "%s (#%u)", *pszVendor ? pszVendor : pszProduct, i); break; } } } else RTStrPrintf(szName, sizeof(szName), "(#%u)", i); /* Create the device. */ size_t cbName = strlen(szName) + 1; PDARWINDVD pNew = (PDARWINDVD)RTMemAlloc(RT_UOFFSETOF_DYN(DARWINDVD, szName[cbName])); if (pNew) { pNew->pNext = NULL; memcpy(pNew->szName, szName, cbName); if (pTail) pTail = pTail->pNext = pNew; else pTail = pHead = pNew; } } CFRelease(PropsRef); } else AssertMsgFailed(("krc=%#x\n", krc)); IOObjectRelease(DVDService); i++; } IOObjectRelease(DVDServices); return pHead; } /** * Enumerate the fixed drives (HDDs, SSD, ++) returning a FIFO of device paths * strings and model strings separated by ':'. * * @returns Pointer to the head. * The caller is responsible for calling RTMemFree() on each of the nodes. */ PDARWINFIXEDDRIVE DarwinGetFixedDrives(void) { AssertReturn(darwinOpenMasterPort(), NULL); /* * Create a matching dictionary for searching drives in the IOKit. * * The idea is to find all the IOMedia objects with "Whole"="True" which identify the disks but * not partitions. */ CFMutableDictionaryRef RefMatchingDict = IOServiceMatching("IOMedia"); AssertReturn(RefMatchingDict, NULL); CFDictionaryAddValue(RefMatchingDict, CFSTR(kIOMediaWholeKey), kCFBooleanTrue); /* * Perform the search and get a collection of IOMedia objects. */ io_iterator_t MediaServices = IO_OBJECT_NULL; IOReturn irc = IOServiceGetMatchingServices(g_MasterPort, RefMatchingDict, &MediaServices); AssertMsgReturn(irc == kIOReturnSuccess, ("irc=%d\n", irc), NULL); RefMatchingDict = NULL; /* the reference is consumed by IOServiceGetMatchingServices. */ /* * Enumerate the matching services. * (This enumeration must be identical to the one performed in DrvHostBase.cpp.) */ PDARWINFIXEDDRIVE pHead = NULL; PDARWINFIXEDDRIVE pTail = NULL; unsigned i = 0; io_object_t MediaService; while ((MediaService = IOIteratorNext(MediaServices)) != IO_OBJECT_NULL) { DARWIN_IOKIT_DUMP_OBJ(MediaService); /* * Find the IOMedia parents having the IOBlockStorageDevice type and check they have "device-type" = "Generic". * If the IOMedia object hasn't IOBlockStorageDevices with such device-type in parents the one is not general * disk but either CDROM-like device or some another device which has no interest for the function. */ /* * Just avoid parents enumeration if the IOMedia is IOCDMedia, i.e. CDROM-like disk */ if (IOObjectConformsTo(MediaService, kIOCDMediaClass)) { IOObjectRelease(MediaService); continue; } bool fIsGenericStorage = false; io_registry_entry_t ChildEntry = MediaService; io_registry_entry_t ParentEntry = IO_OBJECT_NULL; kern_return_t krc = KERN_SUCCESS; while ( !fIsGenericStorage && (krc = IORegistryEntryGetParentEntry(ChildEntry, kIOServicePlane, &ParentEntry)) == KERN_SUCCESS) { if (!IOObjectIsEqualTo(ChildEntry, MediaService)) IOObjectRelease(ChildEntry); DARWIN_IOKIT_DUMP_OBJ(ParentEntry); if (IOObjectConformsTo(ParentEntry, kIOBlockStorageDeviceClass)) { CFTypeRef DeviceTypeValueRef = IORegistryEntryCreateCFProperty(ParentEntry, CFSTR("device-type"), kCFAllocatorDefault, 0); if ( DeviceTypeValueRef && CFGetTypeID(DeviceTypeValueRef) == CFStringGetTypeID() && CFStringCompare((CFStringRef)DeviceTypeValueRef, CFSTR("Generic"), kCFCompareCaseInsensitive) == kCFCompareEqualTo) fIsGenericStorage = true; if (DeviceTypeValueRef != NULL) CFRelease(DeviceTypeValueRef); } ChildEntry = ParentEntry; } if (ChildEntry != IO_OBJECT_NULL && !IOObjectIsEqualTo(ChildEntry, MediaService)) IOObjectRelease(ChildEntry); if (!fIsGenericStorage) { IOObjectRelease(MediaService); continue; } CFTypeRef DeviceName; DeviceName = IORegistryEntryCreateCFProperty(MediaService, CFSTR(kIOBSDNameKey), kCFAllocatorDefault,0); if (DeviceName) { char szDeviceFilePath[MAXPATHLEN]; strcpy(szDeviceFilePath, _PATH_DEV); size_t cchPathSize = strlen(szDeviceFilePath); if (CFStringGetCString((CFStringRef)DeviceName, &szDeviceFilePath[cchPathSize], (CFIndex)(sizeof(szDeviceFilePath) - cchPathSize), kCFStringEncodingUTF8)) { PDARWINFIXEDDRIVE pDuplicate = pHead; while (pDuplicate && strcmp(szDeviceFilePath, pDuplicate->szName) != 0) pDuplicate = pDuplicate->pNext; if (pDuplicate == NULL) { /* Get model for the IOMedia object. * * Due to vendor and product property names are different and * depend on interface and device type, the best way to get a drive * model is get IORegistry name for the IOMedia object. Usually, * it takes " Media" form. Noticed, * such naming are used by only IOMedia objects having * "Whole" = True and "BSDName" properties set. */ io_name_t szEntryName = { 0 }; if ((krc = IORegistryEntryGetName(MediaService, szEntryName)) == KERN_SUCCESS) { /* remove " Media" from the end of the name */ char *pszMedia = strrchr(szEntryName, ' '); if ( pszMedia != NULL && (uintptr_t)pszMedia < (uintptr_t)&szEntryName[sizeof(szEntryName)] && strcmp(pszMedia, " Media") == 0) { *pszMedia = '\0'; RTStrPurgeEncoding(szEntryName); } } /* Create the device path and model name in form "/device/path:model". */ cchPathSize = strlen(szDeviceFilePath); size_t const cchModelSize = strlen(szEntryName); size_t const cbExtra = cchPathSize + 1 + cchModelSize + !!cchModelSize; PDARWINFIXEDDRIVE pNew = (PDARWINFIXEDDRIVE)RTMemAlloc(RT_UOFFSETOF_DYN(DARWINFIXEDDRIVE, szName[cbExtra])); if (pNew) { pNew->pNext = NULL; memcpy(pNew->szName, szDeviceFilePath, cchPathSize + 1); pNew->pszModel = NULL; if (cchModelSize) pNew->pszModel = (const char *)memcpy(&pNew->szName[cchPathSize + 1], szEntryName, cchModelSize + 1); if (pTail) pTail = pTail->pNext = pNew; else pTail = pHead = pNew; } } } CFRelease(DeviceName); } IOObjectRelease(MediaService); i++; } IOObjectRelease(MediaServices); return pHead; } /** * Enumerate the ethernet capable network devices returning a FIFO of them. * * @returns Pointer to the head. */ PDARWINETHERNIC DarwinGetEthernetControllers(void) { AssertReturn(darwinOpenMasterPort(), NULL); /* * Create a matching dictionary for searching for ethernet controller * services in the IOKit. * * For some really stupid reason I don't get all the controllers if I look for * objects that are instances of IOEthernetController or its descendants (only * get the AirPort on my mac pro). But fortunately using IOEthernetInterface * seems to work. Weird s**t! */ //CFMutableDictionaryRef RefMatchingDict = IOServiceMatching("IOEthernetController"); - this doesn't work :-( CFMutableDictionaryRef RefMatchingDict = IOServiceMatching("IOEthernetInterface"); AssertReturn(RefMatchingDict, NULL); /* * Perform the search and get a collection of ethernet controller services. */ io_iterator_t EtherIfServices = IO_OBJECT_NULL; IOReturn irc = IOServiceGetMatchingServices(g_MasterPort, RefMatchingDict, &EtherIfServices); AssertMsgReturn(irc == kIOReturnSuccess, ("irc=%d\n", irc), NULL); RefMatchingDict = NULL; /* the reference is consumed by IOServiceGetMatchingServices. */ /* * Get a copy of the current network interfaces from the system configuration service. * We'll use this for looking up the proper interface names. */ CFArrayRef IfsRef = SCNetworkInterfaceCopyAll(); CFIndex cIfs = IfsRef ? CFArrayGetCount(IfsRef) : 0; /* * Get the current preferences and make a copy of the network services so we * can look up the right interface names. The IfsRef is just for fallback. */ CFArrayRef ServicesRef = NULL; CFIndex cServices = 0; SCPreferencesRef PrefsRef = SCPreferencesCreate(kCFAllocatorDefault, CFSTR("org.virtualbox.VBoxSVC"), NULL); if (PrefsRef) { SCNetworkSetRef SetRef = SCNetworkSetCopyCurrent(PrefsRef); CFRelease(PrefsRef); if (SetRef) { ServicesRef = SCNetworkSetCopyServices(SetRef); CFRelease(SetRef); cServices = ServicesRef ? CFArrayGetCount(ServicesRef) : 0; } } /* * Enumerate the ethernet controller services. */ PDARWINETHERNIC pHead = NULL; PDARWINETHERNIC pTail = NULL; io_object_t EtherIfService; while ((EtherIfService = IOIteratorNext(EtherIfServices)) != IO_OBJECT_NULL) { /* * Dig up the parent, meaning the IOEthernetController. */ io_object_t EtherNICService; kern_return_t krc = IORegistryEntryGetParentEntry(EtherIfService, kIOServicePlane, &EtherNICService); /*krc = IORegistryEntryGetChildEntry(EtherNICService, kIOServicePlane, &EtherIfService); */ if (krc == KERN_SUCCESS) { DARWIN_IOKIT_DUMP_OBJ(EtherNICService); /* * Get the properties we use to identify and name the Ethernet NIC. * We need the both the IOEthernetController and it's IONetworkInterface child. */ CFMutableDictionaryRef PropsRef = 0; krc = IORegistryEntryCreateCFProperties(EtherNICService, &PropsRef, kCFAllocatorDefault, kNilOptions); if (krc == KERN_SUCCESS) { CFMutableDictionaryRef IfPropsRef = 0; krc = IORegistryEntryCreateCFProperties(EtherIfService, &IfPropsRef, kCFAllocatorDefault, kNilOptions); if (krc == KERN_SUCCESS) { /* * Gather the required data. * We'll create a UUID from the MAC address and the BSD name. */ char szTmp[256]; do { /* Check if airport (a bit heuristical - it's com.apple.driver.AirPortBrcm43xx here). */ darwinDictGetString(PropsRef, CFSTR("CFBundleIdentifier"), szTmp, sizeof(szTmp)); bool fWireless; bool fAirPort = fWireless = strstr(szTmp, ".AirPort") != NULL; /* Check if it's USB. */ darwinDictGetString(PropsRef, CFSTR("IOProviderClass"), szTmp, sizeof(szTmp)); bool fUSB = strstr(szTmp, "USB") != NULL; /* Is it builtin? */ bool fBuiltin; darwinDictGetBool(IfPropsRef, CFSTR("IOBuiltin"), &fBuiltin); /* Is it the primary interface */ bool fPrimaryIf; darwinDictGetBool(IfPropsRef, CFSTR("IOPrimaryInterface"), &fPrimaryIf); /* Get the MAC address. */ RTMAC Mac; AssertBreak(darwinDictGetData(PropsRef, CFSTR("IOMACAddress"), &Mac, sizeof(Mac))); /* The BSD Name from the interface dictionary. No assert here as the belkin USB-C gadget does not always end up with a BSD name, typically requiring replugging. */ char szBSDName[RT_SIZEOFMEMB(DARWINETHERNIC, szBSDName)]; if (RT_UNLIKELY(!darwinDictGetString(IfPropsRef, CFSTR("BSD Name"), szBSDName, sizeof(szBSDName)))) { LogRelMax(32, ("DarwinGetEthernetControllers: Warning! Failed to get 'BSD Name'; provider class %s\n", szTmp)); break; } /* Check if it's really wireless. */ if ( darwinDictIsPresent(IfPropsRef, CFSTR("IO80211CountryCode")) || darwinDictIsPresent(IfPropsRef, CFSTR("IO80211DriverVersion")) || darwinDictIsPresent(IfPropsRef, CFSTR("IO80211HardwareVersion")) || darwinDictIsPresent(IfPropsRef, CFSTR("IO80211Locale"))) fWireless = true; else fAirPort = fWireless = false; /** @todo IOPacketFilters / IONetworkFilterGroup? */ /* * Create the interface name. * * Note! The ConsoleImpl2.cpp code ASSUMES things about the name. It is also * stored in the VM config files. (really bright idea) */ strcpy(szTmp, szBSDName); char *psz = strchr(szTmp, '\0'); *psz++ = ':'; *psz++ = ' '; size_t cchLeft = sizeof(szTmp) - (size_t)(psz - &szTmp[0]) - (sizeof(" (Wireless)") - 1); bool fFound = false; CFIndex i; /* look it up among the current services */ for (i = 0; i < cServices; i++) { SCNetworkServiceRef ServiceRef = (SCNetworkServiceRef)CFArrayGetValueAtIndex(ServicesRef, i); SCNetworkInterfaceRef IfRef = SCNetworkServiceGetInterface(ServiceRef); if (IfRef) { CFStringRef BSDNameRef = SCNetworkInterfaceGetBSDName(IfRef); if ( BSDNameRef && CFStringGetCString(BSDNameRef, psz, (CFIndex)cchLeft, kCFStringEncodingUTF8) && !strcmp(psz, szBSDName)) { CFStringRef ServiceNameRef = SCNetworkServiceGetName(ServiceRef); if ( ServiceNameRef && CFStringGetCString(ServiceNameRef, psz, (CFIndex)cchLeft, kCFStringEncodingUTF8)) { fFound = true; break; } } } } /* Look it up in the interface list. */ if (!fFound) for (i = 0; i < cIfs; i++) { SCNetworkInterfaceRef IfRef = (SCNetworkInterfaceRef)CFArrayGetValueAtIndex(IfsRef, i); CFStringRef BSDNameRef = SCNetworkInterfaceGetBSDName(IfRef); if ( BSDNameRef && CFStringGetCString(BSDNameRef, psz, (CFIndex)cchLeft, kCFStringEncodingUTF8) && !strcmp(psz, szBSDName)) { CFStringRef DisplayNameRef = SCNetworkInterfaceGetLocalizedDisplayName(IfRef); if ( DisplayNameRef && CFStringGetCString(DisplayNameRef, psz, (CFIndex)cchLeft, kCFStringEncodingUTF8)) { fFound = true; break; } } } /* Generate a half plausible name if we for some silly reason didn't find the interface. */ if (!fFound) RTStrPrintf(szTmp, sizeof(szTmp), "%s: %s%s(?)", szBSDName, fUSB ? "USB " : "", fWireless ? fAirPort ? "AirPort " : "Wireless" : "Ethernet"); /* If we did find it and it's wireless but without "AirPort" or "Wireless", fix it */ else if ( fWireless && !strstr(psz, "AirPort") && !strstr(psz, "Wireless")) strcat(szTmp, fAirPort ? " (AirPort)" : " (Wireless)"); /* * Create the list entry. */ DARWIN_IOKIT_LOG(("Found: if=%s mac=%.6Rhxs fWireless=%RTbool fAirPort=%RTbool fBuiltin=%RTbool fPrimaryIf=%RTbool fUSB=%RTbool\n", szBSDName, &Mac, fWireless, fAirPort, fBuiltin, fPrimaryIf, fUSB)); size_t cchName = strlen(szTmp); PDARWINETHERNIC pNew = (PDARWINETHERNIC)RTMemAlloc(RT_UOFFSETOF_DYN(DARWINETHERNIC, szName[cchName + 1])); if (pNew) { strncpy(pNew->szBSDName, szBSDName, sizeof(pNew->szBSDName)); /* the '\0' padding is intentional! */ RTUuidClear(&pNew->Uuid); memcpy(&pNew->Uuid, pNew->szBSDName, RT_MIN(sizeof(pNew->szBSDName), sizeof(pNew->Uuid))); pNew->Uuid.Gen.u8ClockSeqHiAndReserved = (pNew->Uuid.Gen.u8ClockSeqHiAndReserved & 0x3f) | 0x80; pNew->Uuid.Gen.u16TimeHiAndVersion = (pNew->Uuid.Gen.u16TimeHiAndVersion & 0x0fff) | 0x4000; pNew->Uuid.Gen.au8Node[0] = Mac.au8[0]; pNew->Uuid.Gen.au8Node[1] = Mac.au8[1]; pNew->Uuid.Gen.au8Node[2] = Mac.au8[2]; pNew->Uuid.Gen.au8Node[3] = Mac.au8[3]; pNew->Uuid.Gen.au8Node[4] = Mac.au8[4]; pNew->Uuid.Gen.au8Node[5] = Mac.au8[5]; pNew->Mac = Mac; pNew->fWireless = fWireless; pNew->fAirPort = fAirPort; pNew->fBuiltin = fBuiltin; pNew->fUSB = fUSB; pNew->fPrimaryIf = fPrimaryIf; memcpy(pNew->szName, szTmp, cchName + 1); /* * Link it into the list, keep the list sorted by fPrimaryIf and the BSD name. */ if (pTail) { PDARWINETHERNIC pPrev = pTail; if (strcmp(pNew->szBSDName, pPrev->szBSDName) < 0) { pPrev = NULL; for (PDARWINETHERNIC pCur = pHead; pCur; pPrev = pCur, pCur = pCur->pNext) if ( (int)pNew->fPrimaryIf - (int)pCur->fPrimaryIf > 0 || ( (int)pNew->fPrimaryIf - (int)pCur->fPrimaryIf == 0 && strcmp(pNew->szBSDName, pCur->szBSDName) >= 0)) break; } if (pPrev) { /* tail or in list. */ pNew->pNext = pPrev->pNext; pPrev->pNext = pNew; if (pPrev == pTail) pTail = pNew; } else { /* head */ pNew->pNext = pHead; pHead = pNew; } } else { /* empty list */ pNew->pNext = NULL; pTail = pHead = pNew; } } } while (0); CFRelease(IfPropsRef); } CFRelease(PropsRef); } IOObjectRelease(EtherNICService); } else AssertMsgFailed(("krc=%#x\n", krc)); IOObjectRelease(EtherIfService); } IOObjectRelease(EtherIfServices); if (ServicesRef) CFRelease(ServicesRef); if (IfsRef) CFRelease(IfsRef); return pHead; } #ifdef STANDALONE_TESTCASE /** * This file can optionally be compiled into a testcase, this is the main function. * To build: * g++ -I ../../../../include -D IN_RING3 iokit.cpp ../../../../out/darwin.x86/debug/lib/RuntimeR3.a ../../../../out/darwin.x86/debug/lib/SUPR3.a ../../../../out/darwin.x86/debug/lib/RuntimeR3.a ../../../../out/darwin.x86/debug/lib/VBox-kStuff.a ../../../../out/darwin.x86/debug/lib/RuntimeR3.a -framework CoreFoundation -framework IOKit -framework SystemConfiguration -liconv -D STANDALONE_TESTCASE -o iokit -g && ./iokit */ int main(int argc, char **argv) { RTR3InitExe(argc, &argv, 0); if (1) { /* * Network preferences. */ RTPrintf("Preferences: Network Services\n"); SCPreferencesRef PrefsRef = SCPreferencesCreate(kCFAllocatorDefault, CFSTR("org.virtualbox.VBoxSVC"), NULL); if (PrefsRef) { CFDictionaryRef NetworkServiceRef = (CFDictionaryRef)SCPreferencesGetValue(PrefsRef, kSCPrefNetworkServices); darwinDumpDict(NetworkServiceRef, 4); CFRelease(PrefsRef); } } if (1) { /* * Network services interfaces in the current config. */ RTPrintf("Preferences: Network Service Interfaces\n"); SCPreferencesRef PrefsRef = SCPreferencesCreate(kCFAllocatorDefault, CFSTR("org.virtualbox.VBoxSVC"), NULL); if (PrefsRef) { SCNetworkSetRef SetRef = SCNetworkSetCopyCurrent(PrefsRef); if (SetRef) { CFArrayRef ServicesRef = SCNetworkSetCopyServices(SetRef); CFIndex cServices = CFArrayGetCount(ServicesRef); for (CFIndex i = 0; i < cServices; i++) { SCNetworkServiceRef ServiceRef = (SCNetworkServiceRef)CFArrayGetValueAtIndex(ServicesRef, i); char szServiceName[128] = {0}; CFStringGetCString(SCNetworkServiceGetName(ServiceRef), szServiceName, sizeof(szServiceName), kCFStringEncodingUTF8); SCNetworkInterfaceRef IfRef = SCNetworkServiceGetInterface(ServiceRef); char szBSDName[16] = {0}; if (SCNetworkInterfaceGetBSDName(IfRef)) CFStringGetCString(SCNetworkInterfaceGetBSDName(IfRef), szBSDName, sizeof(szBSDName), kCFStringEncodingUTF8); char szDisplayName[128] = {0}; if (SCNetworkInterfaceGetLocalizedDisplayName(IfRef)) CFStringGetCString(SCNetworkInterfaceGetLocalizedDisplayName(IfRef), szDisplayName, sizeof(szDisplayName), kCFStringEncodingUTF8); RTPrintf(" #%u ServiceName=\"%s\" IfBSDName=\"%s\" IfDisplayName=\"%s\"\n", i, szServiceName, szBSDName, szDisplayName); } CFRelease(ServicesRef); CFRelease(SetRef); } CFRelease(PrefsRef); } } if (1) { /* * Network interfaces. */ RTPrintf("Preferences: Network Interfaces\n"); CFArrayRef IfsRef = SCNetworkInterfaceCopyAll(); if (IfsRef) { CFIndex cIfs = CFArrayGetCount(IfsRef); for (CFIndex i = 0; i < cIfs; i++) { SCNetworkInterfaceRef IfRef = (SCNetworkInterfaceRef)CFArrayGetValueAtIndex(IfsRef, i); char szBSDName[16] = {0}; if (SCNetworkInterfaceGetBSDName(IfRef)) CFStringGetCString(SCNetworkInterfaceGetBSDName(IfRef), szBSDName, sizeof(szBSDName), kCFStringEncodingUTF8); char szDisplayName[128] = {0}; if (SCNetworkInterfaceGetLocalizedDisplayName(IfRef)) CFStringGetCString(SCNetworkInterfaceGetLocalizedDisplayName(IfRef), szDisplayName, sizeof(szDisplayName), kCFStringEncodingUTF8); RTPrintf(" #%u BSDName=\"%s\" DisplayName=\"%s\"\n", i, szBSDName, szDisplayName); } CFRelease(IfsRef); } } if (1) { /* * Get and display the ethernet controllers. */ RTPrintf("Ethernet controllers:\n"); PDARWINETHERNIC pEtherNICs = DarwinGetEthernetControllers(); for (PDARWINETHERNIC pCur = pEtherNICs; pCur; pCur = pCur->pNext) { RTPrintf("%s\n", pCur->szName); RTPrintf(" szBSDName=%s\n", pCur->szBSDName); RTPrintf(" UUID=%RTuuid\n", &pCur->Uuid); RTPrintf(" Mac=%.6Rhxs\n", &pCur->Mac); RTPrintf(" fWireless=%RTbool\n", pCur->fWireless); RTPrintf(" fAirPort=%RTbool\n", pCur->fAirPort); RTPrintf(" fBuiltin=%RTbool\n", pCur->fBuiltin); RTPrintf(" fUSB=%RTbool\n", pCur->fUSB); RTPrintf(" fPrimaryIf=%RTbool\n", pCur->fPrimaryIf); } } return 0; } #endif