/* $Id: VBoxNetFlt.c $ */ /** @file * VBoxNetFlt - Network Filter Driver (Host), Common Code. */ /* * Copyright (C) 2008-2022 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 . * * The contents of this file may alternatively be used under the terms * of the Common Development and Distribution License Version 1.0 * (CDDL), a copy of it is provided in the "COPYING.CDDL" file included * in the VirtualBox distribution, in which case the provisions of the * CDDL are applicable instead of those of the GPL. * * You may elect to license modified versions of this file under the * terms and conditions of either the GPL or the CDDL or both. * * SPDX-License-Identifier: GPL-3.0-only OR CDDL-1.0 */ /** @page pg_netflt VBoxNetFlt - Network Interface Filter * * This is a kernel module that attaches to a real interface on the host and * filters and injects packets. * * In the big picture we're one of the three trunk interface on the internal * network, the one named "NIC Filter Driver": @image html Networking_Overview.gif * * * @section sec_netflt_locking Locking and Potential Races * * The main challenge here is to make sure the netfilter and internal network * instances won't be destroyed while someone is calling into them. * * The main calls into or out of of the filter driver are: * - Send. * - Async send completion (not implemented yet) * - Release by the internal network. * - Receive. * - Disappearance of the host networking interface. * - Reappearance of the host networking interface. * * The latter two calls are can be caused by driver unloading/loading or the * device being physical unplugged (e.g. a USB network device). Actually, the * unload scenario must fervently be prevent as it will cause panics because the * internal network will assume the trunk is around until it releases it. * @todo Need to figure which host allow unloading and block/fix it. * * Currently the netfilter instance lives until the internal network releases * it. So, it is the internal networks responsibility to make sure there are no * active calls when it releases the trunk and destroys the network. The * netfilter assists in this by providing INTNETTRUNKIFPORT::pfnSetState and * INTNETTRUNKIFPORT::pfnWaitForIdle. The trunk state is used to enable/disable * promiscuous mode on the hardware NIC (or similar activation) as well * indicating that disconnect is imminent and no further calls shall be made * into the internal network. After changing the state to disconnecting and * prior to invoking INTNETTRUNKIFPORT::pfnDisconnectAndRelease, the internal * network will use INTNETTRUNKIFPORT::pfnWaitForIdle to wait for any still * active calls to complete. * * The netfilter employs a busy counter and an internal state in addition to the * public trunk state. All these variables are protected using a spinlock. * * * @section sec_netflt_msc Locking / Sequence Diagrams - OBSOLETE * * !OBSOLETE! - THIS WAS THE OLD APPROACH! * * This secion contains a few sequence diagrams describing the problematic * transitions of a host interface filter instance. * * The thing that makes it all a bit problematic is that multiple events may * happen at the same time, and that we have to be very careful to avoid * deadlocks caused by mixing our locks with the ones in the host kernel. The * main events are receive, send, async send completion, disappearance of the * host networking interface and its reappearance. The latter two events are * can be caused by driver unloading/loading or the device being physical * unplugged (e.g. a USB network device). * * The strategy for dealing with these issues are: * - Use a simple state machine. * - Require the user (IntNet) to serialize all its calls to us, * while at the same time not owning any lock used by any of the * the callbacks we might call on receive and async send completion. * - Make sure we're 100% idle before disconnecting, and have a * disconnected status on both sides to fend off async calls. * - Protect the host specific interface handle and the state variables * using a spinlock. * * * @subsection subsec_netflt_msc_dis_rel Disconnect from the network and release - OBSOLETE * * @msc * VM, IntNet, NetFlt, Kernel, Wire; * * VM->IntNet [label="pkt0", linecolor="green", textcolor="green"]; * IntNet=>IntNet [label="Lock Network", linecolor="green", textcolor="green" ]; * IntNet=>IntNet [label="Route packet -> wire", linecolor="green", textcolor="green" ]; * IntNet=>IntNet [label="Unlock Network", linecolor="green", textcolor="green" ]; * IntNet=>NetFlt [label="pkt0 to wire", linecolor="green", textcolor="green" ]; * NetFlt=>Kernel [label="pkt0 to wire", linecolor="green", textcolor="green"]; * Kernel->Wire [label="pkt0 to wire", linecolor="green", textcolor="green"]; * * --- [label="Suspending the trunk interface"]; * IntNet=>IntNet [label="Lock Network"]; * * Wire->Kernel [label="pkt1 - racing us", linecolor="red", textcolor="red"]; * Kernel=>>NetFlt [label="pkt1 - racing us", linecolor="red", textcolor="red"]; * NetFlt=>>IntNet [label="pkt1 recv - blocks", linecolor="red", textcolor="red"]; * * IntNet=>IntNet [label="Mark Trunk Suspended"]; * IntNet=>IntNet [label="Unlock Network"]; * * IntNet=>NetFlt [label="pfnSetActive(false)"]; * NetFlt=>NetFlt [label="Mark inactive (atomic)"]; * IntNet<NetFlt [label="pfnWaitForIdle(forever)"]; * * IntNet=>>NetFlt [label="pkt1 to host", linecolor="red", textcolor="red"]; * NetFlt=>>Kernel [label="pkt1 to host", linecolor="red", textcolor="red"]; * * Kernel<-Wire [label="pkt0 on wire", linecolor="green", textcolor="green"]; * NetFlt<>NetFlt [label="pfnSGRelease", linecolor="green", textcolor="green"]; * NetFlt<-NetFlt [label="idle", linecolor="green", textcolor="green"]; * * IntNet<Kernel [label="pkt2", linecolor="red", textcolor="red"]; * Kernel=>>NetFlt [label="pkt2", linecolor="red", textcolor="red"]; * NetFlt=>>Kernel [label="pkt2 to host", linecolor="red", textcolor="red"]; * * VM->IntNet [label="pkt3", linecolor="green", textcolor="green"]; * IntNet=>IntNet [label="Lock Network", linecolor="green", textcolor="green" ]; * IntNet=>IntNet [label="Route packet -> drop", linecolor="green", textcolor="green" ]; * IntNet=>IntNet [label="Unlock Network", linecolor="green", textcolor="green" ]; * * --- [label="The trunk interface is idle now, disconnect it"]; * IntNet=>IntNet [label="Lock Network"]; * IntNet=>IntNet [label="Unlink Trunk"]; * IntNet=>IntNet [label="Unlock Network"]; * IntNet=>NetFlt [label="pfnDisconnectAndRelease"]; * NetFlt=>Kernel [label="iflt_detach"]; * NetFlt<<=Kernel [label="iff_detached"]; * NetFlt>>Kernel [label="iff_detached"]; * NetFlt<NetFlt [label="Release"]; * IntNet<IntNet [label="pkt0", linecolor="green", textcolor="green"]; * IntNet=>IntNet [label="Lock Network", linecolor="green", textcolor="green" ]; * IntNet=>IntNet [label="Route packet -> wire", linecolor="green", textcolor="green" ]; * IntNet=>IntNet [label="Unlock Network", linecolor="green", textcolor="green" ]; * IntNet=>NetFlt [label="pkt0 to wire", linecolor="green", textcolor="green" ]; * NetFlt=>Kernel [label="ifnet_reference w/ spinlock", linecolor="green", textcolor="green" ]; * NetFlt<Kernel [label="pkt0 to wire (blocks)", linecolor="green", textcolor="green" ]; * * --- [label="The host interface is being disconnected"]; * Kernel->NetFlt [label="iff_detached"]; * NetFlt=>Kernel [label="ifnet_release w/ spinlock"]; * NetFlt<NetFlt [label="fDisconnectedFromHost=true"]; * NetFlt>>Kernel [label="iff_detached"]; * * NetFlt<NetFlt [label="Acquire spinlock", linecolor="green", textcolor="green"]; * NetFlt=>Kernel [label="ifnet_release", linecolor="green", textcolor="green"]; * NetFlt<NetFlt [label="pIf=NULL", linecolor="green", textcolor="green"]; * NetFlt=>NetFlt [label="Release spinlock", linecolor="green", textcolor="green"]; * IntNet<=NetFlt [label="pfnSGRelease", linecolor="green", textcolor="green"]; * IntNet>>NetFlt [label="pfnSGRelease", linecolor="green", textcolor="green"]; * IntNet<IntNet [label="pkt0"]; * IntNet=>IntNet [label="Lock Network"]; * IntNet=>IntNet [label="Route packet -> wire"]; * IntNet=>IntNet [label="Unlock Network"]; * IntNet=>NetFlt [label="pkt0 to wire"]; * NetFlt=>NetFlt [label="Read pIf(==NULL) w/ spinlock"]; * IntNet<IntNet [label="pkt1"]; * IntNet=>IntNet [label="Lock Network"]; * IntNet=>IntNet [label="Route packet -> wire"]; * IntNet=>IntNet [label="Unlock Network"]; * IntNet=>NetFlt [label="pkt1 to wire"]; * NetFlt=>NetFlt [label="Read pIf(==NULL) w/ spinlock"]; * NetFlt=>NetFlt [label="fRediscoveryPending=true w/ spinlock"]; * NetFlt=>Kernel [label="ifnet_find_by_name"]; * NetFlt<IntNet [label="pkt2", linecolor="red", textcolor="red"]; * IntNet=>IntNet [label="Lock Network", linecolor="red", textcolor="red"]; * IntNet=>IntNet [label="Route packet -> wire", linecolor="red", textcolor="red"]; * IntNet=>IntNet [label="Unlock Network", linecolor="red", textcolor="red"]; * IntNet=>NetFlt [label="pkt2 to wire", linecolor="red", textcolor="red"]; * NetFlt=>NetFlt [label="!pIf || fRediscoveryPending (w/ spinlock)", linecolor="red", textcolor="red"]; * IntNet<Kernel [label="iflt_attach"]; * NetFlt<NetFlt [label="Acquire spinlock"]; * NetFlt=>NetFlt [label="Set pIf and update flags"]; * NetFlt=>NetFlt [label="Release spinlock"]; * * NetFlt=>Kernel [label="pkt1 to wire"]; * Kernel->Wire [label="pkt1 to wire"]; * NetFlt< #include #include #include #include #include #include #include #include #include #include /********************************************************************************************************************************* * Defined Constants And Macros * *********************************************************************************************************************************/ #define IFPORT_2_VBOXNETFLTINS(pIfPort) \ ( (PVBOXNETFLTINS)((uint8_t *)(pIfPort) - RT_UOFFSETOF(VBOXNETFLTINS, MyPort)) ) AssertCompileMemberSize(VBOXNETFLTINS, enmState, sizeof(uint32_t)); /** * Sets the enmState member atomically. * * Used for all updates. * * @param pThis The instance. * @param enmNewState The new value. */ DECLINLINE(void) vboxNetFltSetState(PVBOXNETFLTINS pThis, VBOXNETFTLINSSTATE enmNewState) { ASMAtomicWriteU32((uint32_t volatile *)&pThis->enmState, enmNewState); } /** * Gets the enmState member atomically. * * Used for all reads. * * @returns The enmState value. * @param pThis The instance. */ DECLINLINE(VBOXNETFTLINSSTATE) vboxNetFltGetState(PVBOXNETFLTINS pThis) { return (VBOXNETFTLINSSTATE)ASMAtomicUoReadU32((uint32_t volatile *)&pThis->enmState); } /** * Finds a instance by its name, the caller does the locking. * * @returns Pointer to the instance by the given name. NULL if not found. * @param pGlobals The globals. * @param pszName The name of the instance. */ static PVBOXNETFLTINS vboxNetFltFindInstanceLocked(PVBOXNETFLTGLOBALS pGlobals, const char *pszName) { PVBOXNETFLTINS pCur; for (pCur = pGlobals->pInstanceHead; pCur; pCur = pCur->pNext) if (!strcmp(pszName, pCur->szName)) return pCur; return NULL; } /** * Finds a instance by its name, will request the mutex. * * No reference to the instance is retained, we're assuming the caller to * already have one but just for some reason doesn't have the pointer to it. * * @returns Pointer to the instance by the given name. NULL if not found. * @param pGlobals The globals. * @param pszName The name of the instance. */ DECLHIDDEN(PVBOXNETFLTINS) vboxNetFltFindInstance(PVBOXNETFLTGLOBALS pGlobals, const char *pszName) { PVBOXNETFLTINS pRet; int rc = RTSemFastMutexRequest(pGlobals->hFastMtx); AssertRCReturn(rc, NULL); pRet = vboxNetFltFindInstanceLocked(pGlobals, pszName); rc = RTSemFastMutexRelease(pGlobals->hFastMtx); AssertRC(rc); return pRet; } /** * Unlinks an instance from the chain. * * @param pGlobals The globals. * @param pToUnlink The instance to unlink. */ static void vboxNetFltUnlinkLocked(PVBOXNETFLTGLOBALS pGlobals, PVBOXNETFLTINS pToUnlink) { if (pGlobals->pInstanceHead == pToUnlink) pGlobals->pInstanceHead = pToUnlink->pNext; else { PVBOXNETFLTINS pCur; for (pCur = pGlobals->pInstanceHead; pCur; pCur = pCur->pNext) if (pCur->pNext == pToUnlink) { pCur->pNext = pToUnlink->pNext; break; } Assert(pCur); } pToUnlink->pNext = NULL; } /** * Performs interface rediscovery if it was disconnected from the host. * * @returns true if successfully rediscovered and connected, false if not. * @param pThis The instance. */ static bool vboxNetFltMaybeRediscovered(PVBOXNETFLTINS pThis) { uint64_t Now; bool fRediscovered; bool fDoIt; /* * Don't do rediscovery if we're called with preemption disabled. * * Note! This may cause trouble if we're always called with preemption * disabled and vboxNetFltOsMaybeRediscovered actually does some real * work. For the time being though, only Darwin and FreeBSD depends * on these call outs and neither supports sending with preemption * disabled. */ if (!RTThreadPreemptIsEnabled(NIL_RTTHREAD)) return false; /* * Rediscovered already? Time to try again? */ Now = RTTimeNanoTS(); RTSpinlockAcquire(pThis->hSpinlock); fRediscovered = !ASMAtomicUoReadBool(&pThis->fDisconnectedFromHost); fDoIt = !fRediscovered && !ASMAtomicUoReadBool(&pThis->fRediscoveryPending) && Now - ASMAtomicUoReadU64(&pThis->NanoTSLastRediscovery) > UINT64_C(5000000000); /* 5 sec */ if (fDoIt) ASMAtomicWriteBool(&pThis->fRediscoveryPending, true); RTSpinlockRelease(pThis->hSpinlock); /* * Call the OS specific code to do the job. * Update the state when the call returns, that is everything except for * the fDisconnectedFromHost flag which the OS specific code shall set. */ if (fDoIt) { fRediscovered = vboxNetFltOsMaybeRediscovered(pThis); Assert(!fRediscovered || !ASMAtomicUoReadBool(&pThis->fDisconnectedFromHost)); ASMAtomicUoWriteU64(&pThis->NanoTSLastRediscovery, RTTimeNanoTS()); ASMAtomicWriteBool(&pThis->fRediscoveryPending, false); if (fRediscovered) /** @todo this isn't 100% serialized. */ vboxNetFltPortOsSetActive(pThis, pThis->enmTrunkState == INTNETTRUNKIFSTATE_ACTIVE); } return fRediscovered; } /** * @copydoc INTNETTRUNKIFPORT::pfnXmit */ static DECLCALLBACK(int) vboxNetFltPortXmit(PINTNETTRUNKIFPORT pIfPort, void *pvIfData, PINTNETSG pSG, uint32_t fDst) { PVBOXNETFLTINS pThis = IFPORT_2_VBOXNETFLTINS(pIfPort); int rc = VINF_SUCCESS; /* * Input validation. */ AssertPtr(pThis); AssertPtr(pSG); Assert(pThis->MyPort.u32Version == INTNETTRUNKIFPORT_VERSION); AssertReturn(vboxNetFltGetState(pThis) == kVBoxNetFltInsState_Connected, VERR_INVALID_STATE); /* * Do a busy retain and then make sure we're connected to the interface * before invoking the OS specific code. */ if (RT_LIKELY(vboxNetFltTryRetainBusyActive(pThis))) { if ( !ASMAtomicUoReadBool(&pThis->fDisconnectedFromHost) || vboxNetFltMaybeRediscovered(pThis)) rc = vboxNetFltPortOsXmit(pThis, pvIfData, pSG, fDst); vboxNetFltRelease(pThis, true /* fBusy */); } return rc; } /** * @copydoc INTNETTRUNKIFPORT::pfnWaitForIdle */ static DECLCALLBACK(int) vboxNetFltPortWaitForIdle(PINTNETTRUNKIFPORT pIfPort, uint32_t cMillies) { PVBOXNETFLTINS pThis = IFPORT_2_VBOXNETFLTINS(pIfPort); int rc; /* * Input validation. */ AssertPtr(pThis); Assert(pThis->MyPort.u32Version == INTNETTRUNKIFPORT_VERSION); AssertReturn(vboxNetFltGetState(pThis) == kVBoxNetFltInsState_Connected, VERR_INVALID_STATE); AssertReturn(pThis->enmTrunkState == INTNETTRUNKIFSTATE_DISCONNECTING, VERR_INVALID_STATE); /* * Go to sleep on the semaphore after checking the busy count. */ vboxNetFltRetain(pThis, false /* fBusy */); rc = VINF_SUCCESS; while (pThis->cBusy && RT_SUCCESS(rc)) rc = RTSemEventWait(pThis->hEventIdle, cMillies); /** @todo make interruptible? */ vboxNetFltRelease(pThis, false /* fBusy */); return rc; } /** * @copydoc INTNETTRUNKIFPORT::pfnSetState */ static DECLCALLBACK(INTNETTRUNKIFSTATE) vboxNetFltPortSetState(PINTNETTRUNKIFPORT pIfPort, INTNETTRUNKIFSTATE enmState) { PVBOXNETFLTINS pThis = IFPORT_2_VBOXNETFLTINS(pIfPort); INTNETTRUNKIFSTATE enmOldTrunkState; /* * Input validation. */ AssertPtr(pThis); AssertPtr(pThis->pGlobals); Assert(pThis->MyPort.u32Version == INTNETTRUNKIFPORT_VERSION); AssertReturn(vboxNetFltGetState(pThis) == kVBoxNetFltInsState_Connected, INTNETTRUNKIFSTATE_INVALID); AssertReturn(enmState > INTNETTRUNKIFSTATE_INVALID && enmState < INTNETTRUNKIFSTATE_END, INTNETTRUNKIFSTATE_INVALID); /* * Take the lock and change the state. */ RTSpinlockAcquire(pThis->hSpinlock); enmOldTrunkState = pThis->enmTrunkState; if (enmOldTrunkState != enmState) ASMAtomicWriteU32((uint32_t volatile *)&pThis->enmTrunkState, enmState); RTSpinlockRelease(pThis->hSpinlock); /* * If the state change indicates that the trunk has become active or * inactive, call the OS specific part so they can work the promiscuous * settings and such. * Note! The caller makes sure there are no concurrent pfnSetState calls. */ if ((enmOldTrunkState == INTNETTRUNKIFSTATE_ACTIVE) != (enmState == INTNETTRUNKIFSTATE_ACTIVE)) vboxNetFltPortOsSetActive(pThis, (enmState == INTNETTRUNKIFSTATE_ACTIVE)); return enmOldTrunkState; } /** * @copydoc INTNETTRUNKIFPORT::pfnNotifyMacAddress */ static DECLCALLBACK(void) vboxNetFltPortNotifyMacAddress(PINTNETTRUNKIFPORT pIfPort, void *pvIfData, PCRTMAC pMac) { PVBOXNETFLTINS pThis = IFPORT_2_VBOXNETFLTINS(pIfPort); /* * Input validation. */ AssertPtr(pThis); Assert(pThis->MyPort.u32Version == INTNETTRUNKIFPORT_VERSION); vboxNetFltRetain(pThis, false /* fBusy */); vboxNetFltPortOsNotifyMacAddress(pThis, pvIfData, pMac); vboxNetFltRelease(pThis, false /* fBusy */); } /** * @copydoc INTNETTRUNKIFPORT::pfnConnectInterface */ static DECLCALLBACK(int) vboxNetFltPortConnectInterface(PINTNETTRUNKIFPORT pIfPort, void *pvIf, void **ppvIfData) { PVBOXNETFLTINS pThis = IFPORT_2_VBOXNETFLTINS(pIfPort); int rc; /* * Input validation. */ AssertPtr(pThis); Assert(pThis->MyPort.u32Version == INTNETTRUNKIFPORT_VERSION); vboxNetFltRetain(pThis, false /* fBusy */); rc = vboxNetFltPortOsConnectInterface(pThis, pvIf, ppvIfData); vboxNetFltRelease(pThis, false /* fBusy */); return rc; } /** * @copydoc INTNETTRUNKIFPORT::pfnDisconnectInterface */ static DECLCALLBACK(void) vboxNetFltPortDisconnectInterface(PINTNETTRUNKIFPORT pIfPort, void *pvIfData) { PVBOXNETFLTINS pThis = IFPORT_2_VBOXNETFLTINS(pIfPort); int rc; /* * Input validation. */ AssertPtr(pThis); Assert(pThis->MyPort.u32Version == INTNETTRUNKIFPORT_VERSION); vboxNetFltRetain(pThis, false /* fBusy */); rc = vboxNetFltPortOsDisconnectInterface(pThis, pvIfData); vboxNetFltRelease(pThis, false /* fBusy */); AssertRC(rc); /** @todo fix vboxNetFltPortOsDisconnectInterface. */ } /** * @copydoc INTNETTRUNKIFPORT::pfnDisconnectAndRelease */ static DECLCALLBACK(void) vboxNetFltPortDisconnectAndRelease(PINTNETTRUNKIFPORT pIfPort) { PVBOXNETFLTINS pThis = IFPORT_2_VBOXNETFLTINS(pIfPort); /* * Serious paranoia. */ AssertPtr(pThis); Assert(pThis->MyPort.u32Version == INTNETTRUNKIFPORT_VERSION); Assert(pThis->MyPort.u32VersionEnd == INTNETTRUNKIFPORT_VERSION); AssertPtr(pThis->pGlobals); Assert(pThis->hEventIdle != NIL_RTSEMEVENT); Assert(pThis->hSpinlock != NIL_RTSPINLOCK); Assert(pThis->szName[0]); Assert(vboxNetFltGetState(pThis) == kVBoxNetFltInsState_Connected); Assert(pThis->enmTrunkState == INTNETTRUNKIFSTATE_DISCONNECTING); Assert(!pThis->fRediscoveryPending); Assert(!pThis->cBusy); /* * Disconnect and release it. */ RTSpinlockAcquire(pThis->hSpinlock); vboxNetFltSetState(pThis, kVBoxNetFltInsState_Disconnecting); RTSpinlockRelease(pThis->hSpinlock); vboxNetFltOsDisconnectIt(pThis); pThis->pSwitchPort = NULL; #ifdef VBOXNETFLT_STATIC_CONFIG RTSpinlockAcquire(pThis->hSpinlock); vboxNetFltSetState(pThis, kVBoxNetFltInsState_Unconnected); RTSpinlockRelease(pThis->hSpinlock); #endif vboxNetFltRelease(pThis, false /* fBusy */); } /** * Destroy a device that has been disconnected from the switch. * * @returns true if the instance is destroyed, false otherwise. * @param pThis The instance to be destroyed. This is * no longer valid when this function returns. */ static bool vboxNetFltDestroyInstance(PVBOXNETFLTINS pThis) { PVBOXNETFLTGLOBALS pGlobals = pThis->pGlobals; uint32_t cRefs = ASMAtomicUoReadU32((uint32_t volatile *)&pThis->cRefs); int rc; LogFlow(("vboxNetFltDestroyInstance: pThis=%p (%s)\n", pThis, pThis->szName)); /* * Validate the state. */ #ifdef VBOXNETFLT_STATIC_CONFIG Assert( vboxNetFltGetState(pThis) == kVBoxNetFltInsState_Disconnecting || vboxNetFltGetState(pThis) == kVBoxNetFltInsState_Unconnected); #else Assert(vboxNetFltGetState(pThis) == kVBoxNetFltInsState_Disconnecting); #endif Assert(pThis->enmTrunkState == INTNETTRUNKIFSTATE_DISCONNECTING); Assert(!pThis->fRediscoveryPending); Assert(!pThis->cRefs); Assert(!pThis->cBusy); Assert(!pThis->pSwitchPort); /* * Make sure the state is 'disconnecting' / 'destroying' and let the OS * specific code do its part of the cleanup outside the mutex. */ rc = RTSemFastMutexRequest(pGlobals->hFastMtx); AssertRC(rc); vboxNetFltSetState(pThis, kVBoxNetFltInsState_Disconnecting); RTSemFastMutexRelease(pGlobals->hFastMtx); vboxNetFltOsDeleteInstance(pThis); /* * Unlink the instance and free up its resources. */ rc = RTSemFastMutexRequest(pGlobals->hFastMtx); AssertRC(rc); vboxNetFltSetState(pThis, kVBoxNetFltInsState_Destroyed); vboxNetFltUnlinkLocked(pGlobals, pThis); RTSemFastMutexRelease(pGlobals->hFastMtx); RTSemEventDestroy(pThis->hEventIdle); pThis->hEventIdle = NIL_RTSEMEVENT; RTSpinlockDestroy(pThis->hSpinlock); pThis->hSpinlock = NIL_RTSPINLOCK; RTMemFree(pThis); NOREF(cRefs); return true; } /** * Releases a reference to the specified instance. * * This method will destroy the instance when the count reaches 0. * It will also take care of decrementing the counter and idle wakeup. * * @param pThis The instance. * @param fBusy Whether the busy counter should be decremented too. */ DECLHIDDEN(void) vboxNetFltRelease(PVBOXNETFLTINS pThis, bool fBusy) { uint32_t cRefs; /* * Paranoid Android. */ AssertPtr(pThis); Assert(pThis->MyPort.u32Version == INTNETTRUNKIFPORT_VERSION); Assert(pThis->MyPort.u32VersionEnd == INTNETTRUNKIFPORT_VERSION); Assert( vboxNetFltGetState(pThis) > kVBoxNetFltInsState_Invalid && vboxNetFltGetState(pThis) < kVBoxNetFltInsState_Destroyed); AssertPtr(pThis->pGlobals); Assert(pThis->hEventIdle != NIL_RTSEMEVENT); Assert(pThis->hSpinlock != NIL_RTSPINLOCK); Assert(pThis->szName[0]); /* * Work the busy counter. */ if (fBusy) { cRefs = ASMAtomicDecU32(&pThis->cBusy); if (!cRefs) { int rc = RTSemEventSignal(pThis->hEventIdle); AssertRC(rc); } else Assert(cRefs < UINT32_MAX / 2); } /* * The object reference counting. */ cRefs = ASMAtomicDecU32(&pThis->cRefs); if (!cRefs) vboxNetFltDestroyInstance(pThis); else Assert(cRefs < UINT32_MAX / 2); } /** * @copydoc INTNETTRUNKIFPORT::pfnRelease */ static DECLCALLBACK(void) vboxNetFltPortRelease(PINTNETTRUNKIFPORT pIfPort) { PVBOXNETFLTINS pThis = IFPORT_2_VBOXNETFLTINS(pIfPort); vboxNetFltRelease(pThis, false /* fBusy */); } /** * @callback_method_impl{FNINTNETTRUNKIFPORTRELEASEBUSY} */ DECL_HIDDEN_CALLBACK(void) vboxNetFltPortReleaseBusy(PINTNETTRUNKIFPORT pIfPort) { PVBOXNETFLTINS pThis = IFPORT_2_VBOXNETFLTINS(pIfPort); vboxNetFltRelease(pThis, true /*fBusy*/); } /** * Retains a reference to the specified instance and a busy reference too. * * @param pThis The instance. * @param fBusy Whether the busy counter should be incremented as well. */ DECLHIDDEN(void) vboxNetFltRetain(PVBOXNETFLTINS pThis, bool fBusy) { uint32_t cRefs; /* * Paranoid Android. */ AssertPtr(pThis); Assert(pThis->MyPort.u32Version == INTNETTRUNKIFPORT_VERSION); Assert(pThis->MyPort.u32VersionEnd == INTNETTRUNKIFPORT_VERSION); Assert( vboxNetFltGetState(pThis) > kVBoxNetFltInsState_Invalid && vboxNetFltGetState(pThis) < kVBoxNetFltInsState_Destroyed); AssertPtr(pThis->pGlobals); Assert(pThis->hEventIdle != NIL_RTSEMEVENT); Assert(pThis->hSpinlock != NIL_RTSPINLOCK); Assert(pThis->szName[0]); /* * Retain the object. */ cRefs = ASMAtomicIncU32(&pThis->cRefs); Assert(cRefs > 1 && cRefs < UINT32_MAX / 2); /* * Work the busy counter. */ if (fBusy) { cRefs = ASMAtomicIncU32(&pThis->cBusy); Assert(cRefs > 0 && cRefs < UINT32_MAX / 2); } NOREF(cRefs); } /** * Tries to retain the device as busy if the trunk is active. * * This is used before calling pfnRecv or pfnPreRecv. * * @returns true if we succeeded in retaining a busy reference to the active * device. false if we failed. * @param pThis The instance. */ DECLHIDDEN(bool) vboxNetFltTryRetainBusyActive(PVBOXNETFLTINS pThis) { uint32_t cRefs; bool fRc; /* * Paranoid Android. */ AssertPtr(pThis); Assert(pThis->MyPort.u32Version == INTNETTRUNKIFPORT_VERSION); Assert(pThis->MyPort.u32VersionEnd == INTNETTRUNKIFPORT_VERSION); Assert( vboxNetFltGetState(pThis) > kVBoxNetFltInsState_Invalid && vboxNetFltGetState(pThis) < kVBoxNetFltInsState_Destroyed); AssertPtr(pThis->pGlobals); Assert(pThis->hEventIdle != NIL_RTSEMEVENT); Assert(pThis->hSpinlock != NIL_RTSPINLOCK); Assert(pThis->szName[0]); /* * Do the retaining and checking behind the spinlock. */ RTSpinlockAcquire(pThis->hSpinlock); fRc = pThis->enmTrunkState == INTNETTRUNKIFSTATE_ACTIVE; if (fRc) { cRefs = ASMAtomicIncU32(&pThis->cRefs); AssertMsg(cRefs > 1 && cRefs < UINT32_MAX / 2, ("%d\n", cRefs)); NOREF(cRefs); cRefs = ASMAtomicIncU32(&pThis->cBusy); AssertMsg(cRefs >= 1 && cRefs < UINT32_MAX / 2, ("%d\n", cRefs)); NOREF(cRefs); } RTSpinlockRelease(pThis->hSpinlock); return fRc; } /** * Tries to retain the device as busy if the trunk is not disconnecting. * * This is used before reporting stuff to the internal network. * * @returns true if we succeeded in retaining a busy reference to the active * device. false if we failed. * @param pThis The instance. */ DECLHIDDEN(bool) vboxNetFltTryRetainBusyNotDisconnected(PVBOXNETFLTINS pThis) { uint32_t cRefs; bool fRc; /* * Paranoid Android. */ AssertPtr(pThis); Assert(pThis->MyPort.u32Version == INTNETTRUNKIFPORT_VERSION); Assert(pThis->MyPort.u32VersionEnd == INTNETTRUNKIFPORT_VERSION); Assert( vboxNetFltGetState(pThis) > kVBoxNetFltInsState_Invalid && vboxNetFltGetState(pThis) < kVBoxNetFltInsState_Destroyed); AssertPtr(pThis->pGlobals); Assert(pThis->hEventIdle != NIL_RTSEMEVENT); Assert(pThis->hSpinlock != NIL_RTSPINLOCK); Assert(pThis->szName[0]); /* * Do the retaining and checking behind the spinlock. */ RTSpinlockAcquire(pThis->hSpinlock); fRc = pThis->enmTrunkState == INTNETTRUNKIFSTATE_ACTIVE || pThis->enmTrunkState == INTNETTRUNKIFSTATE_INACTIVE; if (fRc) { cRefs = ASMAtomicIncU32(&pThis->cRefs); AssertMsg(cRefs > 1 && cRefs < UINT32_MAX / 2, ("%d\n", cRefs)); NOREF(cRefs); cRefs = ASMAtomicIncU32(&pThis->cBusy); AssertMsg(cRefs >= 1 && cRefs < UINT32_MAX / 2, ("%d\n", cRefs)); NOREF(cRefs); } RTSpinlockRelease(pThis->hSpinlock); return fRc; } /** * @copydoc INTNETTRUNKIFPORT::pfnRetain */ static DECLCALLBACK(void) vboxNetFltPortRetain(PINTNETTRUNKIFPORT pIfPort) { PVBOXNETFLTINS pThis = IFPORT_2_VBOXNETFLTINS(pIfPort); vboxNetFltRetain(pThis, false /* fBusy */); } /** * Connects the instance to the specified switch port. * * Called while owning the lock. We're ASSUMING that the internal * networking code is already owning an recursive mutex, so, there * will be no deadlocks when vboxNetFltOsConnectIt calls back into * it for setting preferences. * * @returns VBox status code. * @param pThis The instance. * @param pSwitchPort The port on the internal network 'switch'. * @param ppIfPort Where to return our port interface. */ static int vboxNetFltConnectIt(PVBOXNETFLTINS pThis, PINTNETTRUNKSWPORT pSwitchPort, PINTNETTRUNKIFPORT *ppIfPort) { int rc; /* * Validate state. */ Assert(!pThis->fRediscoveryPending); Assert(!pThis->cBusy); #ifdef VBOXNETFLT_STATIC_CONFIG Assert(vboxNetFltGetState(pThis) == kVBoxNetFltInsState_Unconnected); #else Assert(vboxNetFltGetState(pThis) == kVBoxNetFltInsState_Initializing); #endif Assert(pThis->enmTrunkState == INTNETTRUNKIFSTATE_INACTIVE); /* * Do the job. * Note that we're calling the os stuff while owning the semaphore here. */ pThis->pSwitchPort = pSwitchPort; rc = vboxNetFltOsConnectIt(pThis); if (RT_SUCCESS(rc)) { vboxNetFltSetState(pThis, kVBoxNetFltInsState_Connected); *ppIfPort = &pThis->MyPort; } else pThis->pSwitchPort = NULL; Assert(pThis->enmTrunkState == INTNETTRUNKIFSTATE_INACTIVE); return rc; } /** * Creates a new instance. * * The new instance will be in the suspended state in a dynamic config and in * the inactive in a static one. * * Called without owning the lock, but will request is several times. * * @returns VBox status code. * @param pGlobals The globals. * @param pszName The instance name. * @param pSwitchPort The port on the switch that we're connected with (dynamic only). * @param fNoPromisc Do not attempt going into promiscuous mode. * @param pvContext Context argument for vboxNetFltOsInitInstance. * @param ppIfPort Where to store the pointer to our port interface (dynamic only). */ static int vboxNetFltNewInstance(PVBOXNETFLTGLOBALS pGlobals, const char *pszName, PINTNETTRUNKSWPORT pSwitchPort, bool fNoPromisc, void *pvContext, PINTNETTRUNKIFPORT *ppIfPort) { /* * Allocate and initialize a new instance before requesting the mutex. * Note! That in a static config we'll initialize the trunk state to * disconnecting and flip it in vboxNetFltFactoryCreateAndConnect * later on. This better reflext the state and it works better with * assertions in the destruction path. */ int rc; size_t const cchName = strlen(pszName); PVBOXNETFLTINS pNew = (PVBOXNETFLTINS)RTMemAllocZVar(RT_UOFFSETOF_DYN(VBOXNETFLTINS, szName[cchName + 1])); if (!pNew) return VERR_INTNET_FLT_IF_FAILED; AssertMsg(((uintptr_t)pNew & 7) == 0, ("%p LB %#x\n", pNew, RT_UOFFSETOF_DYN(VBOXNETFLTINS, szName[cchName + 1]))); pNew->pNext = NULL; pNew->MyPort.u32Version = INTNETTRUNKIFPORT_VERSION; pNew->MyPort.pfnRetain = vboxNetFltPortRetain; pNew->MyPort.pfnRelease = vboxNetFltPortRelease; pNew->MyPort.pfnDisconnectAndRelease= vboxNetFltPortDisconnectAndRelease; pNew->MyPort.pfnSetState = vboxNetFltPortSetState; pNew->MyPort.pfnWaitForIdle = vboxNetFltPortWaitForIdle; pNew->MyPort.pfnXmit = vboxNetFltPortXmit; pNew->MyPort.pfnNotifyMacAddress = vboxNetFltPortNotifyMacAddress; pNew->MyPort.pfnConnectInterface = vboxNetFltPortConnectInterface; pNew->MyPort.pfnDisconnectInterface = vboxNetFltPortDisconnectInterface; pNew->MyPort.u32VersionEnd = INTNETTRUNKIFPORT_VERSION; pNew->pSwitchPort = pSwitchPort; pNew->pGlobals = pGlobals; pNew->hSpinlock = NIL_RTSPINLOCK; pNew->enmState = kVBoxNetFltInsState_Initializing; #ifdef VBOXNETFLT_STATIC_CONFIG pNew->enmTrunkState = INTNETTRUNKIFSTATE_DISCONNECTING; #else pNew->enmTrunkState = INTNETTRUNKIFSTATE_INACTIVE; #endif pNew->fDisconnectedFromHost = false; pNew->fRediscoveryPending = false; pNew->fDisablePromiscuous = fNoPromisc; pNew->NanoTSLastRediscovery = INT64_MAX; pNew->cRefs = 1; pNew->cBusy = 0; pNew->hEventIdle = NIL_RTSEMEVENT; memcpy(pNew->szName, pszName, cchName + 1); rc = RTSpinlockCreate(&pNew->hSpinlock, RTSPINLOCK_FLAGS_INTERRUPT_SAFE, "VBoxNetFltNewInstance"); if (RT_SUCCESS(rc)) { rc = RTSemEventCreate(&pNew->hEventIdle); if (RT_SUCCESS(rc)) { rc = vboxNetFltOsPreInitInstance(pNew); if (RT_SUCCESS(rc)) { /* * Insert the instance into the chain, checking for * duplicates first of course (race). */ rc = RTSemFastMutexRequest(pGlobals->hFastMtx); if (RT_SUCCESS(rc)) { if (!vboxNetFltFindInstanceLocked(pGlobals, pszName)) { pNew->pNext = pGlobals->pInstanceHead; pGlobals->pInstanceHead = pNew; RTSemFastMutexRelease(pGlobals->hFastMtx); /* * Call the OS specific initialization code. */ rc = vboxNetFltOsInitInstance(pNew, pvContext); RTSemFastMutexRequest(pGlobals->hFastMtx); if (RT_SUCCESS(rc)) { #ifdef VBOXNETFLT_STATIC_CONFIG /* * Static instances are unconnected at birth. */ Assert(!pSwitchPort); pNew->enmState = kVBoxNetFltInsState_Unconnected; RTSemFastMutexRelease(pGlobals->hFastMtx); *ppIfPort = &pNew->MyPort; return rc; #else /* !VBOXNETFLT_STATIC_CONFIG */ /* * Connect it as well, the OS specific bits has to be done outside * the lock as they may call back to into intnet. */ rc = vboxNetFltConnectIt(pNew, pSwitchPort, ppIfPort); if (RT_SUCCESS(rc)) { RTSemFastMutexRelease(pGlobals->hFastMtx); Assert(*ppIfPort == &pNew->MyPort); return rc; } /* Bail out (failed). */ vboxNetFltOsDeleteInstance(pNew); #endif /* !VBOXNETFLT_STATIC_CONFIG */ } vboxNetFltUnlinkLocked(pGlobals, pNew); } else rc = VERR_INTNET_FLT_IF_BUSY; RTSemFastMutexRelease(pGlobals->hFastMtx); } } RTSemEventDestroy(pNew->hEventIdle); } RTSpinlockDestroy(pNew->hSpinlock); } RTMemFree(pNew); return rc; } #ifdef VBOXNETFLT_STATIC_CONFIG /** * Searches for the NetFlt instance by its name and creates the new one if not found. * * @returns VBox status code. * @retval VINF_SUCCESS and *ppInstance if a new instance was created. * @retval VINF_ALREADY_INITIALIZED and *ppInstance if an instance already exists. * * @param pGlobal Pointer to the globals. * @param pszName The instance name. * @param ppInstance Where to return the instance pointer on success. * @param pvContext Context which needs to be passed along to vboxNetFltOsInitInstance. */ DECLHIDDEN(int) vboxNetFltSearchCreateInstance(PVBOXNETFLTGLOBALS pGlobals, const char *pszName, PVBOXNETFLTINS *ppInstance, void *pvContext) { PINTNETTRUNKIFPORT pIfPort; PVBOXNETFLTINS pCur; VBOXNETFTLINSSTATE enmState; int rc; *ppInstance = NULL; rc = RTSemFastMutexRequest(pGlobals->hFastMtx); AssertRCReturn(rc, rc); /* * Look for an existing instance in the list. * * There might be an existing one in the list if the driver was unbound * while it was connected to an internal network. We're running into * a destruction race that is a bit similar to the one in * vboxNetFltFactoryCreateAndConnect, only the roles are reversed * and we're not in a position to back down. Instead of backing down * we'll delay a bit giving the other thread time to complete the * destructor. */ pCur = vboxNetFltFindInstanceLocked(pGlobals, pszName); while (pCur) { uint32_t cRefs = ASMAtomicIncU32(&pCur->cRefs); if (cRefs > 1) { enmState = vboxNetFltGetState(pCur); switch (enmState) { case kVBoxNetFltInsState_Unconnected: case kVBoxNetFltInsState_Connected: case kVBoxNetFltInsState_Disconnecting: if (pCur->fDisconnectedFromHost) { /* Wait for it to exit the transitional disconnecting state. It might otherwise be running the risk of upsetting the OS specific code... */ /** @todo This reconnect stuff should be serialized correctly for static * devices. Shouldn't it? In the dynamic case we're using the INTNET * outbound thunk lock, but that doesn't quite cut it here, or does * it? We could either transition to initializing or make a callback * while owning the mutex here... */ if (enmState == kVBoxNetFltInsState_Disconnecting) { do { RTSemFastMutexRelease(pGlobals->hFastMtx); RTThreadSleep(2); /* (2ms) */ RTSemFastMutexRequest(pGlobals->hFastMtx); enmState = vboxNetFltGetState(pCur); } while (enmState == kVBoxNetFltInsState_Disconnecting); AssertMsg(enmState == kVBoxNetFltInsState_Unconnected, ("%d\n", enmState)); Assert(pCur->fDisconnectedFromHost); } RTSemFastMutexRelease(pGlobals->hFastMtx); *ppInstance = pCur; return VINF_ALREADY_INITIALIZED; } /* fall thru */ default: { bool fDfH = pCur->fDisconnectedFromHost; RTSemFastMutexRelease(pGlobals->hFastMtx); vboxNetFltRelease(pCur, false /* fBusy */); LogRel(("VBoxNetFlt: Huh? An instance of '%s' already exists! [pCur=%p cRefs=%d fDfH=%RTbool enmState=%d]\n", pszName, pCur, cRefs - 1, fDfH, enmState)); *ppInstance = NULL; return VERR_INTNET_FLT_IF_BUSY; } } } /* Zero references, it's being destroyed. Delay a bit so the destructor can finish its work and try again. (vboxNetFltNewInstance will fail with duplicate name if we don't.) */ # ifdef RT_STRICT Assert(cRefs == 1); enmState = vboxNetFltGetState(pCur); AssertMsg( enmState == kVBoxNetFltInsState_Unconnected || enmState == kVBoxNetFltInsState_Disconnecting || enmState == kVBoxNetFltInsState_Destroyed, ("%d\n", enmState)); # endif ASMAtomicDecU32(&pCur->cRefs); RTSemFastMutexRelease(pGlobals->hFastMtx); RTThreadSleep(2); /* (2ms) */ rc = RTSemFastMutexRequest(pGlobals->hFastMtx); AssertRCReturn(rc, rc); /* try again */ pCur = vboxNetFltFindInstanceLocked(pGlobals, pszName); } RTSemFastMutexRelease(pGlobals->hFastMtx); /* * Try create a new instance. * (fNoPromisc is overridden in the vboxNetFltFactoryCreateAndConnect path, so pass true here.) */ rc = vboxNetFltNewInstance(pGlobals, pszName, NULL, true /* fNoPromisc */, pvContext, &pIfPort); if (RT_SUCCESS(rc)) *ppInstance = IFPORT_2_VBOXNETFLTINS(pIfPort); else *ppInstance = NULL; return rc; } #endif /* VBOXNETFLT_STATIC_CONFIG */ /** * @copydoc INTNETTRUNKFACTORY::pfnCreateAndConnect */ static DECLCALLBACK(int) vboxNetFltFactoryCreateAndConnect(PINTNETTRUNKFACTORY pIfFactory, const char *pszName, PINTNETTRUNKSWPORT pSwitchPort, uint32_t fFlags, PINTNETTRUNKIFPORT *ppIfPort) { PVBOXNETFLTGLOBALS pGlobals = (PVBOXNETFLTGLOBALS)((uint8_t *)pIfFactory - RT_UOFFSETOF(VBOXNETFLTGLOBALS, TrunkFactory)); PVBOXNETFLTINS pCur; int rc; LogFlow(("vboxNetFltFactoryCreateAndConnect: pszName=%p:{%s} fFlags=%#x\n", pszName, pszName, fFlags)); Assert(pGlobals->cFactoryRefs > 0); AssertMsgReturn(!(fFlags & ~(INTNETTRUNKFACTORY_FLAG_NO_PROMISC)), ("%#x\n", fFlags), VERR_INVALID_PARAMETER); /* * Static: Find instance, check if busy, connect if not. * Dynamic: Check for duplicate / busy interface instance. */ rc = RTSemFastMutexRequest(pGlobals->hFastMtx); AssertRCReturn(rc, rc); //#if defined(VBOXNETADP) && defined(RT_OS_WINDOWS) // /* temporary hack to pick up the first adapter */ // pCur = pGlobals->pInstanceHead; /** @todo Don't for get to remove this temporary hack... :-) */ //#else pCur = vboxNetFltFindInstanceLocked(pGlobals, pszName); //#endif if (pCur) { #ifdef VBOXNETFLT_STATIC_CONFIG /* Try grab a reference. If the count had already reached zero we're racing the destructor code and must back down. */ uint32_t cRefs = ASMAtomicIncU32(&pCur->cRefs); if (cRefs > 1) { if (vboxNetFltGetState(pCur) == kVBoxNetFltInsState_Unconnected) { pCur->enmTrunkState = INTNETTRUNKIFSTATE_INACTIVE; /** @todo protect me? */ pCur->fDisablePromiscuous = !!(fFlags & INTNETTRUNKFACTORY_FLAG_NO_PROMISC); rc = vboxNetFltConnectIt(pCur, pSwitchPort, ppIfPort); if (RT_SUCCESS(rc)) pCur = NULL; /* Don't release it, reference given to the caller. */ else pCur->enmTrunkState = INTNETTRUNKIFSTATE_DISCONNECTING; } else rc = VERR_INTNET_FLT_IF_BUSY; } else { Assert(cRefs == 1); ASMAtomicDecU32(&pCur->cRefs); pCur = NULL; /* nothing to release */ rc = VERR_INTNET_FLT_IF_NOT_FOUND; } RTSemFastMutexRelease(pGlobals->hFastMtx); if (pCur) vboxNetFltRelease(pCur, false /* fBusy */); #else rc = VERR_INTNET_FLT_IF_BUSY; RTSemFastMutexRelease(pGlobals->hFastMtx); #endif LogFlow(("vboxNetFltFactoryCreateAndConnect: returns %Rrc\n", rc)); return rc; } RTSemFastMutexRelease(pGlobals->hFastMtx); #ifdef VBOXNETFLT_STATIC_CONFIG rc = VERR_INTNET_FLT_IF_NOT_FOUND; #else /* * Dynamically create a new instance. */ rc = vboxNetFltNewInstance(pGlobals, pszName, pSwitchPort, !!(fFlags & INTNETTRUNKFACTORY_FLAG_NO_PROMISC), NULL, ppIfPort); #endif LogFlow(("vboxNetFltFactoryCreateAndConnect: returns %Rrc\n", rc)); return rc; } /** * @copydoc INTNETTRUNKFACTORY::pfnRelease */ static DECLCALLBACK(void) vboxNetFltFactoryRelease(PINTNETTRUNKFACTORY pIfFactory) { PVBOXNETFLTGLOBALS pGlobals = (PVBOXNETFLTGLOBALS)((uint8_t *)pIfFactory - RT_UOFFSETOF(VBOXNETFLTGLOBALS, TrunkFactory)); int32_t cRefs = ASMAtomicDecS32(&pGlobals->cFactoryRefs); Assert(cRefs >= 0); NOREF(cRefs); LogFlow(("vboxNetFltFactoryRelease: cRefs=%d (new)\n", cRefs)); } /** * Implements the SUPDRV component factor interface query method. * * @returns Pointer to an interface. NULL if not supported. * * @param pSupDrvFactory Pointer to the component factory registration structure. * @param pSession The session - unused. * @param pszInterfaceUuid The factory interface id. */ static DECLCALLBACK(void *) vboxNetFltQueryFactoryInterface(PCSUPDRVFACTORY pSupDrvFactory, PSUPDRVSESSION pSession, const char *pszInterfaceUuid) { PVBOXNETFLTGLOBALS pGlobals = (PVBOXNETFLTGLOBALS)((uint8_t *)pSupDrvFactory - RT_UOFFSETOF(VBOXNETFLTGLOBALS, SupDrvFactory)); /* * Convert the UUID strings and compare them. */ RTUUID UuidReq; int rc = RTUuidFromStr(&UuidReq, pszInterfaceUuid); if (RT_SUCCESS(rc)) { if (!RTUuidCompareStr(&UuidReq, INTNETTRUNKFACTORY_UUID_STR)) { ASMAtomicIncS32(&pGlobals->cFactoryRefs); return &pGlobals->TrunkFactory; } #ifdef LOG_ENABLED /* log legacy queries */ /* else if (!RTUuidCompareStr(&UuidReq, INTNETTRUNKFACTORY_V1_UUID_STR)) Log(("VBoxNetFlt: V1 factory query\n")); */ else Log(("VBoxNetFlt: unknown factory interface query (%s)\n", pszInterfaceUuid)); #endif } else Log(("VBoxNetFlt: rc=%Rrc, uuid=%s\n", rc, pszInterfaceUuid)); RT_NOREF1(pSession); return NULL; } /** * Checks whether the VBoxNetFlt wossname can be unloaded. * * This will return false if someone is currently using the module. * * @returns true if it's relatively safe to unload it, otherwise false. * @param pGlobals Pointer to the globals. */ DECLHIDDEN(bool) vboxNetFltCanUnload(PVBOXNETFLTGLOBALS pGlobals) { int rc = RTSemFastMutexRequest(pGlobals->hFastMtx); bool fRc = !pGlobals->pInstanceHead && pGlobals->cFactoryRefs <= 0; RTSemFastMutexRelease(pGlobals->hFastMtx); AssertRC(rc); return fRc; } /** * Try to close the IDC connection to SUPDRV if established. * * @returns VBox status code. * @retval VINF_SUCCESS on success. * @retval VERR_WRONG_ORDER if we're busy. * * @param pGlobals Pointer to the globals. * * @sa vboxNetFltTryDeleteIdcAndGlobals() */ DECLHIDDEN(int) vboxNetFltTryDeleteIdc(PVBOXNETFLTGLOBALS pGlobals) { int rc; Assert(pGlobals->hFastMtx != NIL_RTSEMFASTMUTEX); /* * Check before trying to deregister the factory. */ if (!vboxNetFltCanUnload(pGlobals)) return VERR_WRONG_ORDER; if (!pGlobals->fIDCOpen) rc = VINF_SUCCESS; else { /* * Disconnect from SUPDRV and check that nobody raced us, * reconnect if that should happen. */ rc = SUPR0IdcComponentDeregisterFactory(&pGlobals->SupDrvIDC, &pGlobals->SupDrvFactory); AssertRC(rc); if (!vboxNetFltCanUnload(pGlobals)) { rc = SUPR0IdcComponentRegisterFactory(&pGlobals->SupDrvIDC, &pGlobals->SupDrvFactory); AssertRC(rc); return VERR_WRONG_ORDER; } SUPR0IdcClose(&pGlobals->SupDrvIDC); pGlobals->fIDCOpen = false; } return rc; } /** * Establishes the IDC connection to SUPDRV and registers our component factory. * * @returns VBox status code. * @param pGlobals Pointer to the globals. * @sa vboxNetFltInitGlobalsAndIdc(). */ DECLHIDDEN(int) vboxNetFltInitIdc(PVBOXNETFLTGLOBALS pGlobals) { int rc; Assert(!pGlobals->fIDCOpen); /* * Establish a connection to SUPDRV and register our component factory. */ rc = SUPR0IdcOpen(&pGlobals->SupDrvIDC, 0 /* iReqVersion = default */, 0 /* iMinVersion = default */, NULL, NULL, NULL); if (RT_SUCCESS(rc)) { rc = SUPR0IdcComponentRegisterFactory(&pGlobals->SupDrvIDC, &pGlobals->SupDrvFactory); if (RT_SUCCESS(rc)) { pGlobals->fIDCOpen = true; Log(("VBoxNetFlt: pSession=%p\n", SUPR0IdcGetSession(&pGlobals->SupDrvIDC))); return rc; } /* bail out. */ LogRel(("VBoxNetFlt: Failed to register component factory, rc=%Rrc\n", rc)); SUPR0IdcClose(&pGlobals->SupDrvIDC); } return rc; } /** * Deletes the globals. * * This must be called after the IDC connection has been closed, * see vboxNetFltTryDeleteIdc(). * * @param pGlobals Pointer to the globals. * @sa vboxNetFltTryDeleteIdcAndGlobals() */ DECLHIDDEN(void) vboxNetFltDeleteGlobals(PVBOXNETFLTGLOBALS pGlobals) { Assert(!pGlobals->fIDCOpen); /* * Release resources. */ RTSemFastMutexDestroy(pGlobals->hFastMtx); pGlobals->hFastMtx = NIL_RTSEMFASTMUTEX; } /** * Initializes the globals. * * @returns VBox status code. * @param pGlobals Pointer to the globals. * @sa vboxNetFltInitGlobalsAndIdc(). */ DECLHIDDEN(int) vboxNetFltInitGlobals(PVBOXNETFLTGLOBALS pGlobals) { /* * Initialize the common portions of the structure. */ int rc = RTSemFastMutexCreate(&pGlobals->hFastMtx); if (RT_SUCCESS(rc)) { pGlobals->pInstanceHead = NULL; pGlobals->TrunkFactory.pfnRelease = vboxNetFltFactoryRelease; pGlobals->TrunkFactory.pfnCreateAndConnect = vboxNetFltFactoryCreateAndConnect; #if defined(RT_OS_WINDOWS) && defined(VBOXNETADP) memcpy(pGlobals->SupDrvFactory.szName, "VBoxNetAdp", sizeof("VBoxNetAdp")); #else memcpy(pGlobals->SupDrvFactory.szName, "VBoxNetFlt", sizeof("VBoxNetFlt")); #endif pGlobals->SupDrvFactory.pfnQueryFactoryInterface = vboxNetFltQueryFactoryInterface; pGlobals->fIDCOpen = false; return rc; } return rc; } /** * Called by the native part when the OS wants the driver to unload. * * @returns VINF_SUCCESS on success, VERR_WRONG_ORDER if we're busy. * * @param pGlobals Pointer to the globals. */ DECLHIDDEN(int) vboxNetFltTryDeleteIdcAndGlobals(PVBOXNETFLTGLOBALS pGlobals) { int rc = vboxNetFltTryDeleteIdc(pGlobals); if (RT_SUCCESS(rc)) vboxNetFltDeleteGlobals(pGlobals); return rc; } /** * Called by the native driver/kext module initialization routine. * * It will initialize the common parts of the globals, assuming the caller * has already taken care of the OS specific bits, and establish the IDC * connection to SUPDRV. * * @returns VBox status code. * @param pGlobals Pointer to the globals. */ DECLHIDDEN(int) vboxNetFltInitGlobalsAndIdc(PVBOXNETFLTGLOBALS pGlobals) { /* * Initialize the common portions of the structure. */ int rc = vboxNetFltInitGlobals(pGlobals); if (RT_SUCCESS(rc)) { rc = vboxNetFltInitIdc(pGlobals); if (RT_SUCCESS(rc)) return rc; /* bail out. */ vboxNetFltDeleteGlobals(pGlobals); } return rc; }