/* $Id: DevLsiLogicSCSI.cpp 99775 2023-05-12 12:21:58Z vboxsync $ */ /** @file * DevLsiLogicSCSI - LsiLogic LSI53c1030 SCSI controller. */ /* * 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_DEV_LSILOGICSCSI #include #include #include #include #include #include #include #include #include #include #include #include #ifdef IN_RING3 # include # include # include # include # include #endif #include "DevLsiLogicSCSI.h" #include "VBoxSCSI.h" #include "VBoxDD.h" /********************************************************************************************************************************* * Defined Constants And Macros * *********************************************************************************************************************************/ /** The current saved state version. */ #define LSILOGIC_SAVED_STATE_VERSION 6 /** The saved state version used by VirtualBox before removal of the * VBoxSCSI BIOS interface. */ #define LSILOGIC_SAVED_STATE_VERSION_PRE_VBOXSCSI_REMOVAL 5 /** The saved state version used by VirtualBox before the diagnostic * memory access was implemented. */ #define LSILOGIC_SAVED_STATE_VERSION_PRE_DIAG_MEM 4 /** The saved state version used by VirtualBox before the doorbell status flag * was changed from bool to a 32bit enum. */ #define LSILOGIC_SAVED_STATE_VERSION_BOOL_DOORBELL 3 /** The saved state version used by VirtualBox before SAS support was added. */ #define LSILOGIC_SAVED_STATE_VERSION_PRE_SAS 2 /** The saved state version used by VirtualBox 3.0 and earlier. It does not * include the device config part. */ #define LSILOGIC_SAVED_STATE_VERSION_VBOX_30 1 /** Maximum number of entries in the release log. */ #define MAX_REL_LOG_ERRORS 1024 #define LSILOGIC_RTGCPHYS_FROM_U32(Hi, Lo) ( (RTGCPHYS)RT_MAKE_U64(Lo, Hi) ) /** Upper number a buffer is freed if it was too big before. */ #define LSILOGIC_MAX_ALLOC_TOO_MUCH 20 /** Maximum size of the memory regions (prevents teh guest from DOSing the host by * allocating loadds of memory). */ #define LSILOGIC_MEMORY_REGIONS_MAX _1M /********************************************************************************************************************************* * Structures and Typedefs * *********************************************************************************************************************************/ /** Pointer to the shared instance data for the LsiLogic emulation. */ typedef struct LSILOGICSCSI *PLSILOGICSCSI; #ifdef IN_RING3 /** * Memory buffer callback. * * @param pDevIns The device instance. * @param GCPhys The guest physical address of the memory buffer. * @param pSgBuf The pointer to the host R3 S/G buffer. * @param cbCopy How many bytes to copy between the two buffers. * @param pcbSkip Initially contains the amount of bytes to skip * starting from the guest physical address before * accessing the S/G buffer and start copying data. * On return this contains the remaining amount if * cbCopy < *pcbSkip or 0 otherwise. */ typedef DECLCALLBACKTYPE(void, FNLSILOGICR3MEMCOPYCALLBACK,(PPDMDEVINS pDevIns, RTGCPHYS GCPhys, PRTSGBUF pSgBuf, size_t cbCopy, size_t *pcbSkip)); /** Pointer to a memory copy buffer callback. */ typedef FNLSILOGICR3MEMCOPYCALLBACK *PFNLSILOGICR3MEMCOPYCALLBACK; #endif /** * Reply data. */ typedef struct LSILOGICSCSIREPLY { /** Lower 32 bits of the reply address in memory. */ uint32_t u32HostMFALowAddress; /** Full address of the reply in guest memory. */ RTGCPHYS GCPhysReplyAddress; /** Size of the reply. */ uint32_t cbReply; /** Different views to the reply depending on the request type. */ MptReplyUnion Reply; } LSILOGICSCSIREPLY; /** Pointer to reply data. */ typedef LSILOGICSCSIREPLY *PLSILOGICSCSIREPLY; /** * Memory region of the IOC. */ typedef struct LSILOGICMEMREGN { /** List node. */ RTLISTNODE NodeList; /** 32bit address the region starts to describe. */ uint32_t u32AddrStart; /** 32bit address the region ends (inclusive). */ uint32_t u32AddrEnd; /** Data for this region - variable. */ uint32_t au32Data[1]; } LSILOGICMEMREGN; /** Pointer to a memory region. */ typedef LSILOGICMEMREGN *PLSILOGICMEMREGN; /** * State of a device attached to the buslogic host adapter. * * @implements PDMIBASE * @implements PDMISCSIPORT * @implements PDMILEDPORTS */ typedef struct LSILOGICDEVICE { /** Pointer to the owning lsilogic device instance - R3 pointer */ PPDMDEVINSR3 pDevIns; /** LUN of the device. */ uint32_t iLUN; /** Number of outstanding tasks on the port. */ volatile uint32_t cOutstandingRequests; /** Our base interface. */ PDMIBASE IBase; /** Media port interface. */ PDMIMEDIAPORT IMediaPort; /** Extended media port interface. */ PDMIMEDIAEXPORT IMediaExPort; /** Led interface. */ PDMILEDPORTS ILed; /** Pointer to the attached driver's base interface. */ R3PTRTYPE(PPDMIBASE) pDrvBase; /** Pointer to the attached driver's media interface. */ R3PTRTYPE(PPDMIMEDIA) pDrvMedia; /** Pointer to the attached driver's extended media interface. */ R3PTRTYPE(PPDMIMEDIAEX) pDrvMediaEx; /** The status LED state for this device. */ PDMLED Led; /** Device name. */ char szName[16]; } LSILOGICDEVICE; /** Pointer to a device state. */ typedef LSILOGICDEVICE *PLSILOGICDEVICE; /** Pointer to a task state. */ typedef struct LSILOGICREQ *PLSILOGICREQ; /** * Shared instance data for the LsiLogic emulation. */ typedef struct LSILOGICSCSI { /** The state the controller is currently in. */ LSILOGICSTATE enmState; /** Who needs to init the driver to get into operational state. */ LSILOGICWHOINIT enmWhoInit; /** Flag whether we are in doorbell function. */ LSILOGICDOORBELLSTATE enmDoorbellState; /** Flag whether diagnostic access is enabled. */ bool fDiagnosticEnabled; /** Flag whether a notification was send to R3. */ bool fNotificationSent; /** Flag whether the guest enabled event notification from the IOC. */ bool fEventNotificationEnabled; /** Flag whether the diagnostic address and RW registers are enabled. */ bool fDiagRegsEnabled; /** Number of device states allocated. */ uint32_t cDeviceStates; uint32_t u32Padding1; /** Interrupt mask. */ volatile uint32_t uInterruptMask; /** Interrupt status register. */ volatile uint32_t uInterruptStatus; /** Buffer for messages which are passed through the doorbell using the * handshake method. */ uint32_t aMessage[sizeof(MptConfigurationRequest)]; /** @todo r=bird: Looks like 4 times the required size? Please explain in comment if this correct... */ /** Actual position in the buffer. */ uint32_t iMessage; /** Size of the message which is given in the doorbell message in dwords. */ uint32_t cMessage; /** Reply buffer. * @note 60 bytes */ MptReplyUnion ReplyBuffer; /** Next entry to read. */ uint32_t uNextReplyEntryRead; /** Size of the reply in the buffer in 16bit words. */ uint32_t cReplySize; /** The fault code of the I/O controller if we are in the fault state. */ uint16_t u16IOCFaultCode; uint16_t u16Padding2; /** Upper 32 bits of the message frame address to locate requests in guest memory. */ uint32_t u32HostMFAHighAddr; /** Upper 32 bits of the sense buffer address. */ uint32_t u32SenseBufferHighAddr; /** Maximum number of devices the driver reported he can handle. */ uint8_t cMaxDevices; /** Maximum number of buses the driver reported he can handle. */ uint8_t cMaxBuses; /** Current size of reply message frames in the guest. */ uint16_t cbReplyFrame; /** Next key to write in the sequence to get access * to diagnostic memory. */ uint32_t iDiagnosticAccess; /** Number entries configured for the reply queue. */ uint32_t cReplyQueueEntries; /** Number entries configured for the outstanding request queue. */ uint32_t cRequestQueueEntries; /** Critical section protecting the reply post queue. */ PDMCRITSECT ReplyPostQueueCritSect; /** Critical section protecting the reply free queue. */ PDMCRITSECT ReplyFreeQueueCritSect; /** Critical section protecting the request queue against * concurrent access from the guest. */ PDMCRITSECT RequestQueueCritSect; /** Critical section protecting the reply free queue against * concurrent write access from the guest. */ PDMCRITSECT ReplyFreeQueueWriteCritSect; /** The reply free qeueue (only the first cReplyQueueEntries are used). */ uint32_t volatile aReplyFreeQueue[LSILOGICSCSI_REPLY_QUEUE_DEPTH_MAX]; /** The reply post qeueue (only the first cReplyQueueEntries are used). */ uint32_t volatile aReplyPostQueue[LSILOGICSCSI_REPLY_QUEUE_DEPTH_MAX]; /** The request qeueue (only the first cRequestQueueEntries are used). */ uint32_t volatile aRequestQueue[LSILOGICSCSI_REQUEST_QUEUE_DEPTH_MAX]; /** Next free entry in the reply queue the guest can write a address to. */ volatile uint32_t uReplyFreeQueueNextEntryFreeWrite; /** Next valid entry the controller can read a valid address for reply frames from. */ volatile uint32_t uReplyFreeQueueNextAddressRead; /** Next free entry in the reply queue the guest can write a address to. */ volatile uint32_t uReplyPostQueueNextEntryFreeWrite; /** Next valid entry the controller can read a valid address for reply frames from. */ volatile uint32_t uReplyPostQueueNextAddressRead; /** Next free entry the guest can write a address to a request frame to. */ volatile uint32_t uRequestQueueNextEntryFreeWrite; /** Next valid entry the controller can read a valid address for request frames from. */ volatile uint32_t uRequestQueueNextAddressRead; /** Indicates that PDMDevHlpAsyncNotificationCompleted should be called when * a port is entering the idle state. */ bool volatile fSignalIdle; /** Flag whether the worker thread is sleeping. */ volatile bool fWrkThreadSleeping; bool afPadding3[2]; /** Current address to read from or write to in the diagnostic memory region. */ uint32_t u32DiagMemAddr; /** Emulated controller type */ LSILOGICCTRLTYPE enmCtrlType; /** Handle counter */ uint16_t u16NextHandle; /** Number of ports this controller has. */ uint8_t cPorts; uint8_t afPadding4; /** The event semaphore the processing thread waits on. */ SUPSEMEVENT hEvtProcess; /** PCI Region \#0: I/O ports register access. */ IOMIOPORTHANDLE hIoPortsReg; /** PCI Region \#1: MMIO register access. */ IOMMMIOHANDLE hMmioReg; /** PCI Region \#2: MMIO diag. */ IOMMMIOHANDLE hMmioDiag; /** ISA Ports for the BIOS (when booting is configured). */ IOMIOPORTHANDLE hIoPortsBios; } LSILOGICSCSI; AssertCompileMemberAlignment(LSILOGICSCSI, ReplyPostQueueCritSect, 8); /** * Ring-3 instance data for the LsiLogic emulation. */ typedef struct LSILOGICSCSIR3 { /** States for attached devices. */ R3PTRTYPE(PLSILOGICDEVICE) paDeviceStates; /** Status LUN: The base interface. */ PDMIBASE IBase; /** Status LUN: Leds interface. */ PDMILEDPORTS ILeds; /** Status LUN: Partner of ILeds. */ R3PTRTYPE(PPDMILEDCONNECTORS) pLedsConnector; /** Status LUN: Media Notifys. */ R3PTRTYPE(PPDMIMEDIANOTIFY) pMediaNotify; /** Pointer to the configuration page area. */ R3PTRTYPE(PMptConfigurationPagesSupported) pConfigurationPages; /** Current size of the memory regions. */ uint32_t cbMemRegns; uint32_t u32Padding3; /** Critical section protecting the memory regions. */ RTCRITSECT CritSectMemRegns; /** List of memory regions - PLSILOGICMEMREGN. */ RTLISTANCHORR3 ListMemRegns; /** Worker thread. */ R3PTRTYPE(PPDMTHREAD) pThreadWrk; /** The device instace - only for getting bearings in interface methods. */ PPDMDEVINSR3 pDevIns; } LSILOGICSCSIR3; /** Pointer to the ring-3 instance data for the LsiLogic emulation. */ typedef LSILOGICSCSIR3 *PLSILOGICSCSIR3; /** * Ring-0 instance data for the LsiLogic emulation. */ typedef struct LSILOGICSCSIR0 { uint64_t u64Unused; } LSILOGICSCSIR0; /** Pointer to the ring-0 instance data for the LsiLogic emulation. */ typedef LSILOGICSCSIR0 *PLSILOGICSCSIR0; /** * Raw-mode instance data for the LsiLogic emulation. */ typedef struct LSILOGICSCSIRC { uint64_t u64Unused; } LSILOGICSCSIRC; /** Pointer to the raw-mode instance data for the LsiLogic emulation. */ typedef LSILOGICSCSIRC *PLSILOGICSCSIRC; /** The current context instance data for the LsiLogic emulation. */ typedef CTX_SUFF(LSILOGICSCSI) LSILOGICSCSICC; /** Pointer to the current context instance data for the LsiLogic emulation. */ typedef CTX_SUFF(PLSILOGICSCSI) PLSILOGICSCSICC; /** * Task state object which holds all necessary data while * processing the request from the guest. */ typedef struct LSILOGICREQ { /** I/O request handle. */ PDMMEDIAEXIOREQ hIoReq; /** Next in the redo list. */ PLSILOGICREQ pRedoNext; /** Target device. */ PLSILOGICDEVICE pTargetDevice; /** The message request from the guest. */ MptRequestUnion GuestRequest; /** Address of the message request frame in guests memory. * Used to read the S/G entries in the second step. */ RTGCPHYS GCPhysMessageFrameAddr; /** Physical start address of the S/G list. */ RTGCPHYS GCPhysSgStart; /** Chain offset */ uint32_t cChainOffset; /** Pointer to the sense buffer. */ uint8_t abSenseBuffer[18]; /** SCSI status code. */ uint8_t u8ScsiSts; } LSILOGICREQ; #ifndef VBOX_DEVICE_STRUCT_TESTCASE /********************************************************************************************************************************* * Internal Functions * *********************************************************************************************************************************/ RT_C_DECLS_BEGIN #ifdef IN_RING3 static void lsilogicR3InitializeConfigurationPages(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis, PLSILOGICSCSICC pThisCC); static void lsilogicR3ConfigurationPagesFree(PLSILOGICSCSI pThis, PLSILOGICSCSICC pThisCC); static int lsilogicR3ProcessConfigurationRequest(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis, PLSILOGICSCSICC pThisCC, PMptConfigurationRequest pConfigurationReq, PMptConfigurationReply pReply); #endif RT_C_DECLS_END /********************************************************************************************************************************* * Global Variables * *********************************************************************************************************************************/ /** Key sequence the guest has to write to enable access * to diagnostic memory. */ static const uint8_t g_lsilogicDiagnosticAccess[] = {0x04, 0x0b, 0x02, 0x07, 0x0d}; /** * Updates the status of the interrupt pin of the device. * * @param pDevIns The device instance. * @param pThis Pointer to the shared LsiLogic device state. */ static void lsilogicUpdateInterrupt(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis) { uint32_t uIntSts; LogFlowFunc(("Updating interrupts\n")); /* Mask out doorbell status so that it does not affect interrupt updating. */ uIntSts = (ASMAtomicReadU32(&pThis->uInterruptStatus) & ~LSILOGIC_REG_HOST_INTR_STATUS_DOORBELL_STS); /* Check maskable interrupts. */ uIntSts &= ~(ASMAtomicReadU32(&pThis->uInterruptMask) & ~LSILOGIC_REG_HOST_INTR_MASK_IRQ_ROUTING); if (uIntSts) { LogFlowFunc(("Setting interrupt\n")); PDMDevHlpPCISetIrq(pDevIns, 0, 1); } else { LogFlowFunc(("Clearing interrupt\n")); PDMDevHlpPCISetIrq(pDevIns, 0, 0); } } /** * Sets a given interrupt status bit in the status register and * updates the interrupt status. * * @param pDevIns The device instance. * @param pThis Pointer to the shared LsiLogic device state. * @param uStatus The status bit to set. */ DECLINLINE(void) lsilogicSetInterrupt(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis, uint32_t uStatus) { ASMAtomicOrU32(&pThis->uInterruptStatus, uStatus); lsilogicUpdateInterrupt(pDevIns, pThis); } /** * Clears a given interrupt status bit in the status register and * updates the interrupt status. * * @param pDevIns The device instance. * @param pThis Pointer to the shared LsiLogic device state. * @param uStatus The status bit to set. */ DECLINLINE(void) lsilogicClearInterrupt(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis, uint32_t uStatus) { ASMAtomicAndU32(&pThis->uInterruptStatus, ~uStatus); lsilogicUpdateInterrupt(pDevIns, pThis); } #ifdef IN_RING3 /** * Sets the I/O controller into fault state and sets the fault code. * * @param pThis Pointer to the shared LsiLogic device state. * @param uIOCFaultCode Fault code to set. */ DECLINLINE(void) lsilogicSetIOCFaultCode(PLSILOGICSCSI pThis, uint16_t uIOCFaultCode) { if (pThis->enmState != LSILOGICSTATE_FAULT) { LogFunc(("Setting I/O controller into FAULT state: uIOCFaultCode=%u\n", uIOCFaultCode)); pThis->enmState = LSILOGICSTATE_FAULT; pThis->u16IOCFaultCode = uIOCFaultCode; } else LogFunc(("We are already in FAULT state\n")); } #endif /* IN_RING3 */ /** * Returns the number of frames in the reply free queue. * * @returns Number of frames in the reply free queue. * @param pThis Pointer to the shared LsiLogic device state. */ DECLINLINE(uint32_t) lsilogicReplyFreeQueueGetFrameCount(PLSILOGICSCSI pThis) { uint32_t cReplyFrames = 0; if (pThis->uReplyFreeQueueNextAddressRead <= pThis->uReplyFreeQueueNextEntryFreeWrite) cReplyFrames = pThis->uReplyFreeQueueNextEntryFreeWrite - pThis->uReplyFreeQueueNextAddressRead; else cReplyFrames = pThis->cReplyQueueEntries - pThis->uReplyFreeQueueNextAddressRead + pThis->uReplyFreeQueueNextEntryFreeWrite; return cReplyFrames; } #ifdef IN_RING3 /** * Returns the number of free entries in the reply post queue. * * @returns Number of frames in the reply free queue. * @param pThis Pointer to the shared LsiLogic device state. */ DECLINLINE(uint32_t) lsilogicReplyPostQueueGetFrameCount(PLSILOGICSCSI pThis) { uint32_t cReplyFrames = 0; if (pThis->uReplyPostQueueNextAddressRead <= pThis->uReplyPostQueueNextEntryFreeWrite) cReplyFrames = pThis->cReplyQueueEntries - pThis->uReplyPostQueueNextEntryFreeWrite + pThis->uReplyPostQueueNextAddressRead; else cReplyFrames = pThis->uReplyPostQueueNextEntryFreeWrite - pThis->uReplyPostQueueNextAddressRead; return cReplyFrames; } /** * Performs a hard reset on the controller. * * @returns VBox status code. * @param pDevIns The device instance. * @param pThis Pointer to the shared LsiLogic device state. * @param pThisCC Pointer to the ring-3 LsiLogic device state. */ static int lsilogicR3HardReset(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis, PLSILOGICSCSICC pThisCC) { pThis->enmState = LSILOGICSTATE_RESET; pThis->enmDoorbellState = LSILOGICDOORBELLSTATE_NOT_IN_USE; /* The interrupts are masked out. */ pThis->uInterruptMask |= LSILOGIC_REG_HOST_INTR_MASK_DOORBELL | LSILOGIC_REG_HOST_INTR_MASK_REPLY; /* Reset interrupt states. */ pThis->uInterruptStatus = 0; lsilogicUpdateInterrupt(pDevIns, pThis); /* Reset the queues. */ pThis->uReplyFreeQueueNextEntryFreeWrite = 0; pThis->uReplyFreeQueueNextAddressRead = 0; pThis->uReplyPostQueueNextEntryFreeWrite = 0; pThis->uReplyPostQueueNextAddressRead = 0; pThis->uRequestQueueNextEntryFreeWrite = 0; pThis->uRequestQueueNextAddressRead = 0; /* Disable diagnostic access. */ pThis->iDiagnosticAccess = 0; pThis->fDiagnosticEnabled = false; pThis->fDiagRegsEnabled = false; /* Set default values. */ pThis->cMaxDevices = pThis->cDeviceStates; pThis->cMaxBuses = 1; pThis->cbReplyFrame = 128; /** @todo Figure out where it is needed. */ pThis->u16NextHandle = 1; pThis->u32DiagMemAddr = 0; lsilogicR3InitializeConfigurationPages(pDevIns, pThis, pThisCC); /* Mark that we finished performing the reset. */ pThis->enmState = LSILOGICSTATE_READY; return VINF_SUCCESS; } /** * Allocates the configuration pages based on the device. * * @returns VBox status code. * @param pThis Pointer to the shared LsiLogic device state. * @param pThisCC Pointer to the ring-3 LsiLogic device state. */ static int lsilogicR3ConfigurationPagesAlloc(PLSILOGICSCSI pThis, PLSILOGICSCSICC pThisCC) { pThisCC->pConfigurationPages = (PMptConfigurationPagesSupported)RTMemAllocZ(sizeof(MptConfigurationPagesSupported)); if (!pThisCC->pConfigurationPages) return VERR_NO_MEMORY; if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) { PMptConfigurationPagesSas pPages = &pThisCC->pConfigurationPages->u.SasPages; pPages->cbManufacturingPage7 = LSILOGICSCSI_MANUFACTURING7_GET_SIZE(pThis->cPorts); PMptConfigurationPageManufacturing7 pManufacturingPage7 = (PMptConfigurationPageManufacturing7)RTMemAllocZ(pPages->cbManufacturingPage7); AssertPtrReturn(pManufacturingPage7, VERR_NO_MEMORY); pPages->pManufacturingPage7 = pManufacturingPage7; /* SAS I/O unit page 0 - Port specific information. */ pPages->cbSASIOUnitPage0 = LSILOGICSCSI_SASIOUNIT0_GET_SIZE(pThis->cPorts); PMptConfigurationPageSASIOUnit0 pSASPage0 = (PMptConfigurationPageSASIOUnit0)RTMemAllocZ(pPages->cbSASIOUnitPage0); AssertPtrReturn(pSASPage0, VERR_NO_MEMORY); pPages->pSASIOUnitPage0 = pSASPage0; /* SAS I/O unit page 1 - Port specific settings. */ pPages->cbSASIOUnitPage1 = LSILOGICSCSI_SASIOUNIT1_GET_SIZE(pThis->cPorts); PMptConfigurationPageSASIOUnit1 pSASPage1 = (PMptConfigurationPageSASIOUnit1)RTMemAllocZ(pPages->cbSASIOUnitPage1); AssertPtrReturn(pSASPage1, VERR_NO_MEMORY); pPages->pSASIOUnitPage1 = pSASPage1; pPages->cPHYs = pThis->cPorts; pPages->paPHYs = (PMptPHY)RTMemAllocZ(pPages->cPHYs * sizeof(MptPHY)); AssertPtrReturn(pPages->paPHYs, VERR_NO_MEMORY); /* Initialize the PHY configuration */ for (unsigned i = 0; i < pThis->cPorts; i++) { /* Settings for present devices. */ if (pThisCC->paDeviceStates[i].pDrvBase) { PMptSASDevice pSASDevice = (PMptSASDevice)RTMemAllocZ(sizeof(MptSASDevice)); AssertPtrReturn(pSASDevice, VERR_NO_MEMORY); /* Link into device list. */ if (!pPages->cDevices) { pPages->pSASDeviceHead = pSASDevice; pPages->pSASDeviceTail = pSASDevice; pPages->cDevices = 1; } else { pSASDevice->pPrev = pPages->pSASDeviceTail; pPages->pSASDeviceTail->pNext = pSASDevice; pPages->pSASDeviceTail = pSASDevice; pPages->cDevices++; } } } } return VINF_SUCCESS; } /** * Frees the configuration pages if allocated. * * @param pThis Pointer to the shared LsiLogic device state. * @param pThisCC Pointer to the ring-3 LsiLogic device state. */ static void lsilogicR3ConfigurationPagesFree(PLSILOGICSCSI pThis, PLSILOGICSCSICC pThisCC) { if (pThisCC->pConfigurationPages) { /* Destroy device list if we emulate a SAS controller. */ if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) { PMptConfigurationPagesSas pSasPages = &pThisCC->pConfigurationPages->u.SasPages; PMptSASDevice pSASDeviceCurr = pSasPages->pSASDeviceHead; while (pSASDeviceCurr) { PMptSASDevice pFree = pSASDeviceCurr; pSASDeviceCurr = pSASDeviceCurr->pNext; RTMemFree(pFree); } if (pSasPages->paPHYs) RTMemFree(pSasPages->paPHYs); if (pSasPages->pManufacturingPage7) RTMemFree(pSasPages->pManufacturingPage7); if (pSasPages->pSASIOUnitPage0) RTMemFree(pSasPages->pSASIOUnitPage0); if (pSasPages->pSASIOUnitPage1) RTMemFree(pSasPages->pSASIOUnitPage1); pSasPages->pSASDeviceHead = NULL; pSasPages->paPHYs = NULL; pSasPages->pManufacturingPage7 = NULL; pSasPages->pSASIOUnitPage0 = NULL; pSasPages->pSASIOUnitPage1 = NULL; } RTMemFree(pThisCC->pConfigurationPages); pThisCC->pConfigurationPages = NULL; } } /** * Finishes a context reply. * * @param pDevIns The device instance. * @param pThis Pointer to the shared LsiLogic device state. * @param u32MessageContext The message context ID to post. */ static void lsilogicR3FinishContextReply(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis, uint32_t u32MessageContext) { LogFlowFunc(("pThis=%#p u32MessageContext=%#x\n", pThis, u32MessageContext)); AssertMsg(pThis->enmDoorbellState == LSILOGICDOORBELLSTATE_NOT_IN_USE, ("We are in a doorbell function\n")); /* Write message context ID into reply post queue. */ int rc = PDMDevHlpCritSectEnter(pDevIns, &pThis->ReplyPostQueueCritSect, VINF_SUCCESS); PDM_CRITSECT_RELEASE_ASSERT_RC_DEV(pDevIns, &pThis->ReplyPostQueueCritSect, rc); /* Check for a entry in the queue. */ if (!lsilogicReplyPostQueueGetFrameCount(pThis)) { /* Set error code. */ lsilogicSetIOCFaultCode(pThis, LSILOGIC_IOCSTATUS_INSUFFICIENT_RESOURCES); PDMDevHlpCritSectLeave(pDevIns, &pThis->ReplyPostQueueCritSect); return; } /* We have a context reply. */ ASMAtomicWriteU32(&pThis->aReplyPostQueue[pThis->uReplyPostQueueNextEntryFreeWrite], u32MessageContext); ASMAtomicIncU32(&pThis->uReplyPostQueueNextEntryFreeWrite); pThis->uReplyPostQueueNextEntryFreeWrite %= pThis->cReplyQueueEntries; /* Set interrupt. */ lsilogicSetInterrupt(pDevIns, pThis, LSILOGIC_REG_HOST_INTR_STATUS_REPLY_INTR); PDMDevHlpCritSectLeave(pDevIns, &pThis->ReplyPostQueueCritSect); } /** * Takes necessary steps to finish a reply frame. * * @param pDevIns The device instance. * @param pThis Pointer to the shared LsiLogic device state. * @param pReply Pointer to the reply message. * @param fForceReplyFifo Flag whether the use of the reply post fifo is forced. */ static void lsilogicFinishAddressReply(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis, PMptReplyUnion pReply, bool fForceReplyFifo) { /* * If we are in a doorbell function we set the reply size now and * set the system doorbell status interrupt to notify the guest that * we are ready to send the reply. */ if (pThis->enmDoorbellState != LSILOGICDOORBELLSTATE_NOT_IN_USE && !fForceReplyFifo) { /* Set size of the reply in 16bit words. The size in the reply is in 32bit dwords. */ pThis->cReplySize = pReply->Header.u8MessageLength * 2; Log(("%s: cReplySize=%u\n", __FUNCTION__, pThis->cReplySize)); pThis->uNextReplyEntryRead = 0; lsilogicSetInterrupt(pDevIns, pThis, LSILOGIC_REG_HOST_INTR_STATUS_SYSTEM_DOORBELL); } else { /* * The reply queues are only used if the request was fetched from the request queue. * Requests from the request queue are always transferred to R3. So it is not possible * that this case happens in R0 or GC. */ # ifdef IN_RING3 /* Grab a free reply message from the queue. */ int rc = PDMDevHlpCritSectEnter(pDevIns, &pThis->ReplyFreeQueueCritSect, VINF_SUCCESS); PDM_CRITSECT_RELEASE_ASSERT_RC_DEV(pDevIns, &pThis->ReplyFreeQueueCritSect, rc); /* Check for a free reply frame. */ if (!lsilogicReplyFreeQueueGetFrameCount(pThis)) { /* Set error code. */ lsilogicSetIOCFaultCode(pThis, LSILOGIC_IOCSTATUS_INSUFFICIENT_RESOURCES); PDMDevHlpCritSectLeave(pDevIns, &pThis->ReplyFreeQueueCritSect); return; } uint32_t u32ReplyFrameAddressLow = pThis->aReplyFreeQueue[pThis->uReplyFreeQueueNextAddressRead]; pThis->uReplyFreeQueueNextAddressRead++; pThis->uReplyFreeQueueNextAddressRead %= pThis->cReplyQueueEntries; PDMDevHlpCritSectLeave(pDevIns, &pThis->ReplyFreeQueueCritSect); /* Build 64bit physical address. */ RTGCPHYS GCPhysReplyMessage = LSILOGIC_RTGCPHYS_FROM_U32(pThis->u32HostMFAHighAddr, u32ReplyFrameAddressLow); size_t cbReplyCopied = (pThis->cbReplyFrame < sizeof(MptReplyUnion)) ? pThis->cbReplyFrame : sizeof(MptReplyUnion); /* Write reply to guest memory. */ PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysReplyMessage, pReply, cbReplyCopied); /* Write low 32bits of reply frame into post reply queue. */ rc = PDMDevHlpCritSectEnter(pDevIns, &pThis->ReplyPostQueueCritSect, VINF_SUCCESS); PDM_CRITSECT_RELEASE_ASSERT_RC_DEV(pDevIns, &pThis->ReplyPostQueueCritSect, rc); /* Check for a entry in the queue. */ if (!lsilogicReplyPostQueueGetFrameCount(pThis)) { /* Set error code. */ lsilogicSetIOCFaultCode(pThis, LSILOGIC_IOCSTATUS_INSUFFICIENT_RESOURCES); PDMDevHlpCritSectLeave(pDevIns, &pThis->ReplyPostQueueCritSect); return; } /* We have a address reply. Set the 31th bit to indicate that. */ ASMAtomicWriteU32(&pThis->aReplyPostQueue[pThis->uReplyPostQueueNextEntryFreeWrite], RT_BIT(31) | (u32ReplyFrameAddressLow >> 1)); ASMAtomicIncU32(&pThis->uReplyPostQueueNextEntryFreeWrite); pThis->uReplyPostQueueNextEntryFreeWrite %= pThis->cReplyQueueEntries; if (fForceReplyFifo) { pThis->enmDoorbellState = LSILOGICDOORBELLSTATE_NOT_IN_USE; lsilogicSetInterrupt(pDevIns, pThis, LSILOGIC_REG_HOST_INTR_STATUS_SYSTEM_DOORBELL); } /* Set interrupt. */ lsilogicSetInterrupt(pDevIns, pThis, LSILOGIC_REG_HOST_INTR_STATUS_REPLY_INTR); PDMDevHlpCritSectLeave(pDevIns, &pThis->ReplyPostQueueCritSect); # else AssertMsgFailed(("This is not allowed to happen.\n")); # endif } } /** * Tries to find a memory region which covers the given address. * * @returns Pointer to memory region or NULL if not found. * @param pThisCC Pointer to the ring-3 LsiLogic device state. * @param u32Addr The 32bit address to search for. */ static PLSILOGICMEMREGN lsilogicR3MemRegionFindByAddr(PLSILOGICSCSICC pThisCC, uint32_t u32Addr) { PLSILOGICMEMREGN pRegion = NULL; PLSILOGICMEMREGN pIt; RTListForEach(&pThisCC->ListMemRegns, pIt, LSILOGICMEMREGN, NodeList) { if ( u32Addr >= pIt->u32AddrStart && u32Addr <= pIt->u32AddrEnd) { pRegion = pIt; break; } } return pRegion; } /** * Frees all allocated memory regions. * * @param pThisCC Pointer to the ring-3 LsiLogic device state. */ static void lsilogicR3MemRegionsFree(PLSILOGICSCSICC pThisCC) { PLSILOGICMEMREGN pItNext; PLSILOGICMEMREGN pIt; RTListForEachSafe(&pThisCC->ListMemRegns, pIt, pItNext, LSILOGICMEMREGN, NodeList) { RTListNodeRemove(&pIt->NodeList); RTMemFree(pIt); } pThisCC->cbMemRegns = 0; } /** * Inserts a given memory region into the list. * * @param pThisCC Pointer to the ring-3 LsiLogic device state. * @param pRegion The region to insert. */ static void lsilogicR3MemRegionInsert(PLSILOGICSCSICC pThisCC, PLSILOGICMEMREGN pRegion) { bool fInserted = false; /* Insert at the right position. */ PLSILOGICMEMREGN pIt; RTListForEach(&pThisCC->ListMemRegns, pIt, LSILOGICMEMREGN, NodeList) { if (pRegion->u32AddrEnd < pIt->u32AddrStart) { RTListNodeInsertBefore(&pIt->NodeList, &pRegion->NodeList); fInserted = true; break; } } if (!fInserted) RTListAppend(&pThisCC->ListMemRegns, &pRegion->NodeList); } /** * Count number of memory regions. * * @returns Number of memory regions. * @param pThisCC Pointer to the ring-3 LsiLogic device state. */ static uint32_t lsilogicR3MemRegionsCount(PLSILOGICSCSICC pThisCC) { uint32_t cRegions = 0; PLSILOGICMEMREGN pIt; RTListForEach(&pThisCC->ListMemRegns, pIt, LSILOGICMEMREGN, NodeList) { cRegions++; } return cRegions; } /** * Handles a write to the diagnostic data register. * * @param pThis Pointer to the shared LsiLogic device state. * @param pThisCC Pointer to the ring-3 LsiLogic device state. * @param u32Data Data to write. */ static void lsilogicR3DiagRegDataWrite(PLSILOGICSCSI pThis, PLSILOGICSCSICC pThisCC, uint32_t u32Data) { RTCritSectEnter(&pThisCC->CritSectMemRegns); PLSILOGICMEMREGN pRegion = lsilogicR3MemRegionFindByAddr(pThisCC, pThis->u32DiagMemAddr); if (pRegion) { uint32_t offRegion = pThis->u32DiagMemAddr - pRegion->u32AddrStart; AssertMsg( offRegion % 4 == 0 && pThis->u32DiagMemAddr <= pRegion->u32AddrEnd, ("Region offset not on a word boundary or crosses memory region\n")); offRegion /= 4; pRegion->au32Data[offRegion] = u32Data; } else { pRegion = NULL; /* Create new region, first check whether we can extend another region. */ PLSILOGICMEMREGN pIt; RTListForEach(&pThisCC->ListMemRegns, pIt, LSILOGICMEMREGN, NodeList) { if (pThis->u32DiagMemAddr == pIt->u32AddrEnd + sizeof(uint32_t)) { pRegion = pIt; break; } } if (pRegion) { /* Reallocate. */ RTListNodeRemove(&pRegion->NodeList); uint32_t cRegionSizeOld = (pRegion->u32AddrEnd - pRegion->u32AddrStart) / 4 + 1; uint32_t cRegionSizeNew = cRegionSizeOld + 512; if (pThisCC->cbMemRegns + 512 * sizeof(uint32_t) < LSILOGIC_MEMORY_REGIONS_MAX) { PLSILOGICMEMREGN pRegionNew; pRegionNew = (PLSILOGICMEMREGN)RTMemRealloc(pRegion, RT_UOFFSETOF_DYN(LSILOGICMEMREGN, au32Data[cRegionSizeNew])); if (pRegionNew) { pRegion = pRegionNew; memset(&pRegion->au32Data[cRegionSizeOld], 0, 512 * sizeof(uint32_t)); pRegion->au32Data[cRegionSizeOld] = u32Data; pRegion->u32AddrEnd = pRegion->u32AddrStart + (cRegionSizeNew - 1) * sizeof(uint32_t); pThisCC->cbMemRegns += 512 * sizeof(uint32_t); } /* else: Silently fail, there is nothing we can do here and the guest might work nevertheless. */ lsilogicR3MemRegionInsert(pThisCC, pRegion); } } else { if (pThisCC->cbMemRegns + 512 * sizeof(uint32_t) < LSILOGIC_MEMORY_REGIONS_MAX) { /* Create completely new. */ pRegion = (PLSILOGICMEMREGN)RTMemAllocZ(RT_OFFSETOF(LSILOGICMEMREGN, au32Data[512])); if (pRegion) { pRegion->u32AddrStart = pThis->u32DiagMemAddr; pRegion->u32AddrEnd = pRegion->u32AddrStart + (512 - 1) * sizeof(uint32_t); pRegion->au32Data[0] = u32Data; pThisCC->cbMemRegns += 512 * sizeof(uint32_t); lsilogicR3MemRegionInsert(pThisCC, pRegion); } /* else: Silently fail, there is nothing we can do here and the guest might work nevertheless. */ } } } /* Memory access is always 32bit big. */ pThis->u32DiagMemAddr += sizeof(uint32_t); RTCritSectLeave(&pThisCC->CritSectMemRegns); } /** * Handles a read from the diagnostic data register. * * @param pThis Pointer to the shared LsiLogic device state. * @param pThisCC Pointer to the ring-3 LsiLogic device state. * @param pu32Data Where to store the data. */ static void lsilogicR3DiagRegDataRead(PLSILOGICSCSI pThis, PLSILOGICSCSICC pThisCC, uint32_t *pu32Data) { RTCritSectEnter(&pThisCC->CritSectMemRegns); PLSILOGICMEMREGN pRegion = lsilogicR3MemRegionFindByAddr(pThisCC, pThis->u32DiagMemAddr); if (pRegion) { uint32_t offRegion = pThis->u32DiagMemAddr - pRegion->u32AddrStart; AssertMsg( offRegion % 4 == 0 && pThis->u32DiagMemAddr <= pRegion->u32AddrEnd, ("Region offset not on a word boundary or crosses memory region\n")); offRegion /= 4; *pu32Data = pRegion->au32Data[offRegion]; } else /* No region, default value 0. */ *pu32Data = 0; /* Memory access is always 32bit big. */ pThis->u32DiagMemAddr += sizeof(uint32_t); RTCritSectLeave(&pThisCC->CritSectMemRegns); } /** * Handles a write to the diagnostic memory address register. * * @param pThis Pointer to the shared LsiLogic device state. * @param u32Addr Address to write. */ static void lsilogicR3DiagRegAddressWrite(PLSILOGICSCSI pThis, uint32_t u32Addr) { pThis->u32DiagMemAddr = u32Addr & ~UINT32_C(0x3); /* 32bit alignment. */ } /** * Handles a read from the diagnostic memory address register. * * @param pThis Pointer to the shared LsiLogic device state. * @param pu32Addr Where to store the current address. */ static void lsilogicR3DiagRegAddressRead(PLSILOGICSCSI pThis, uint32_t *pu32Addr) { *pu32Addr = pThis->u32DiagMemAddr; } /** * Processes a given Request from the guest * * @returns VBox status code. * @param pDevIns The device instance. * @param pThis Pointer to the shared LsiLogic device state. * @param pThisCC Pointer to the ring-3 LsiLogic device state. * @param pMessageHdr Pointer to the message header of the request. * @param pReply Pointer to the reply. */ static int lsilogicR3ProcessMessageRequest(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis, PLSILOGICSCSICC pThisCC, PMptMessageHdr pMessageHdr, PMptReplyUnion pReply) { int rc = VINF_SUCCESS; bool fForceReplyPostFifo = false; # ifdef LOG_ENABLED if (pMessageHdr->u8Function < RT_ELEMENTS(g_apszMPTFunctionNames)) Log(("Message request function: %s\n", g_apszMPTFunctionNames[pMessageHdr->u8Function])); else Log(("Message request function: \n")); # endif memset(pReply, 0, sizeof(MptReplyUnion)); switch (pMessageHdr->u8Function) { case MPT_MESSAGE_HDR_FUNCTION_SCSI_TASK_MGMT: { PMptSCSITaskManagementRequest pTaskMgmtReq = (PMptSCSITaskManagementRequest)pMessageHdr; LogFlow(("u8TaskType=%u\n", pTaskMgmtReq->u8TaskType)); LogFlow(("u32TaskMessageContext=%#x\n", pTaskMgmtReq->u32TaskMessageContext)); pReply->SCSITaskManagement.u8MessageLength = 6; /* 6 32bit dwords. */ pReply->SCSITaskManagement.u8TaskType = pTaskMgmtReq->u8TaskType; pReply->SCSITaskManagement.u32TerminationCount = 0; fForceReplyPostFifo = true; break; } case MPT_MESSAGE_HDR_FUNCTION_IOC_INIT: { /* * This request sets the I/O controller to the * operational state. */ PMptIOCInitRequest pIOCInitReq = (PMptIOCInitRequest)pMessageHdr; /* Update configuration values. */ pThis->enmWhoInit = (LSILOGICWHOINIT)pIOCInitReq->u8WhoInit; pThis->cbReplyFrame = pIOCInitReq->u16ReplyFrameSize; pThis->cMaxBuses = pIOCInitReq->u8MaxBuses; pThis->cMaxDevices = pIOCInitReq->u8MaxDevices; pThis->u32HostMFAHighAddr = pIOCInitReq->u32HostMfaHighAddr; pThis->u32SenseBufferHighAddr = pIOCInitReq->u32SenseBufferHighAddr; if (pThis->enmState == LSILOGICSTATE_READY) { pThis->enmState = LSILOGICSTATE_OPERATIONAL; } /* Return reply. */ pReply->IOCInit.u8MessageLength = 5; pReply->IOCInit.u8WhoInit = pThis->enmWhoInit; pReply->IOCInit.u8MaxDevices = pThis->cMaxDevices; pReply->IOCInit.u8MaxBuses = pThis->cMaxBuses; break; } case MPT_MESSAGE_HDR_FUNCTION_IOC_FACTS: { pReply->IOCFacts.u8MessageLength = 15; /* 15 32bit dwords. */ if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI) { pReply->IOCFacts.u16MessageVersion = 0x0102; /* Version from the specification. */ pReply->IOCFacts.u8NumberOfPorts = pThis->cPorts; } else if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) { pReply->IOCFacts.u16MessageVersion = 0x0105; /* Version from the specification. */ pReply->IOCFacts.u8NumberOfPorts = pThis->cPorts; } else AssertMsgFailed(("Invalid controller type %d\n", pThis->enmCtrlType)); pReply->IOCFacts.u8IOCNumber = 0; /* PCI function number. */ pReply->IOCFacts.u16IOCExceptions = 0; pReply->IOCFacts.u8MaxChainDepth = LSILOGICSCSI_MAXIMUM_CHAIN_DEPTH; pReply->IOCFacts.u8WhoInit = pThis->enmWhoInit; pReply->IOCFacts.u8BlockSize = 12; /* Block size in 32bit dwords. This is the largest request we can get (SCSI I/O). */ pReply->IOCFacts.u8Flags = 0; /* Bit 0 is set if the guest must upload the FW prior to using the controller. Obviously not needed here. */ pReply->IOCFacts.u16ReplyQueueDepth = pThis->cReplyQueueEntries - 1; /* One entry is always free. */ pReply->IOCFacts.u16RequestFrameSize = 128; /** @todo Figure out where it is needed. */ pReply->IOCFacts.u32CurrentHostMFAHighAddr = pThis->u32HostMFAHighAddr; pReply->IOCFacts.u16GlobalCredits = pThis->cRequestQueueEntries - 1; /* One entry is always free. */ pReply->IOCFacts.u8EventState = 0; /* Event notifications not enabled. */ pReply->IOCFacts.u32CurrentSenseBufferHighAddr = pThis->u32SenseBufferHighAddr; pReply->IOCFacts.u16CurReplyFrameSize = pThis->cbReplyFrame; pReply->IOCFacts.u8MaxDevices = pThis->cMaxDevices; pReply->IOCFacts.u8MaxBuses = pThis->cMaxBuses; pReply->IOCFacts.u16ProductID = 0xcafe; /* Our own product ID :) */ pReply->IOCFacts.u32FwImageSize = 0; /* No image needed. */ pReply->IOCFacts.u32FWVersion = 0; /* Check for a valid firmware image in the IOC memory which was downloaded by the guest earlier and use that. */ RTCritSectEnter(&pThisCC->CritSectMemRegns); PLSILOGICMEMREGN pRegion = lsilogicR3MemRegionFindByAddr(pThisCC, LSILOGIC_FWIMGHDR_LOAD_ADDRESS); if (pRegion) { uint32_t offImgHdr = (LSILOGIC_FWIMGHDR_LOAD_ADDRESS - pRegion->u32AddrStart); if (pRegion->u32AddrEnd - offImgHdr + 1 >= sizeof(FwImageHdr)) /* End address is inclusive. */ { PFwImageHdr pFwImgHdr = (PFwImageHdr)&pRegion->au32Data[offImgHdr / 4]; /* Check for the signature. */ /** @todo Checksum validation. */ if ( pFwImgHdr->u32Signature1 == LSILOGIC_FWIMGHDR_SIGNATURE1 && pFwImgHdr->u32Signature2 == LSILOGIC_FWIMGHDR_SIGNATURE2 && pFwImgHdr->u32Signature3 == LSILOGIC_FWIMGHDR_SIGNATURE3) { LogFlowFunc(("IOC Facts: Found valid firmware image header in memory, using version (%#x), size (%d) and product ID (%#x) from there\n", pFwImgHdr->u32FwVersion, pFwImgHdr->u32ImageSize, pFwImgHdr->u16ProductId)); pReply->IOCFacts.u16ProductID = pFwImgHdr->u16ProductId; pReply->IOCFacts.u32FwImageSize = pFwImgHdr->u32ImageSize; pReply->IOCFacts.u32FWVersion = pFwImgHdr->u32FwVersion; } } } RTCritSectLeave(&pThisCC->CritSectMemRegns); break; } case MPT_MESSAGE_HDR_FUNCTION_PORT_FACTS: { PMptPortFactsRequest pPortFactsReq = (PMptPortFactsRequest)pMessageHdr; pReply->PortFacts.u8MessageLength = 10; pReply->PortFacts.u8PortNumber = pPortFactsReq->u8PortNumber; if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI) { /* This controller only supports one bus with bus number 0. */ if (pPortFactsReq->u8PortNumber >= pThis->cPorts) { pReply->PortFacts.u8PortType = 0; /* Not existant. */ } else { pReply->PortFacts.u8PortType = 0x01; /* SCSI Port. */ pReply->PortFacts.u16MaxDevices = LSILOGICSCSI_PCI_SPI_DEVICES_PER_BUS_MAX; pReply->PortFacts.u16ProtocolFlags = RT_BIT(3) | RT_BIT(0); /* SCSI initiator and LUN supported. */ pReply->PortFacts.u16PortSCSIID = 7; /* Default */ pReply->PortFacts.u16MaxPersistentIDs = 0; pReply->PortFacts.u16MaxPostedCmdBuffers = 0; /* Only applies for target mode which we dont support. */ pReply->PortFacts.u16MaxLANBuckets = 0; /* Only for the LAN controller. */ } } else if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) { if (pPortFactsReq->u8PortNumber >= pThis->cPorts) { pReply->PortFacts.u8PortType = 0; /* Not existant. */ } else { pReply->PortFacts.u8PortType = 0x30; /* SAS Port. */ pReply->PortFacts.u16MaxDevices = pThis->cPorts; pReply->PortFacts.u16ProtocolFlags = RT_BIT(3) | RT_BIT(0); /* SCSI initiator and LUN supported. */ pReply->PortFacts.u16PortSCSIID = pThis->cPorts; pReply->PortFacts.u16MaxPersistentIDs = 0; pReply->PortFacts.u16MaxPostedCmdBuffers = 0; /* Only applies for target mode which we dont support. */ pReply->PortFacts.u16MaxLANBuckets = 0; /* Only for the LAN controller. */ } } else AssertMsgFailed(("Invalid controller type %d\n", pThis->enmCtrlType)); break; } case MPT_MESSAGE_HDR_FUNCTION_PORT_ENABLE: { /* * The port enable request notifies the IOC to make the port available and perform * appropriate discovery on the associated link. */ PMptPortEnableRequest pPortEnableReq = (PMptPortEnableRequest)pMessageHdr; pReply->PortEnable.u8MessageLength = 5; pReply->PortEnable.u8PortNumber = pPortEnableReq->u8PortNumber; break; } case MPT_MESSAGE_HDR_FUNCTION_EVENT_NOTIFICATION: { PMptEventNotificationRequest pEventNotificationReq = (PMptEventNotificationRequest)pMessageHdr; if (pEventNotificationReq->u8Switch) pThis->fEventNotificationEnabled = true; else pThis->fEventNotificationEnabled = false; pReply->EventNotification.u16EventDataLength = 1; /* 1 32bit D-Word. */ pReply->EventNotification.u8MessageLength = 8; pReply->EventNotification.u8MessageFlags = (1 << 7); pReply->EventNotification.u8AckRequired = 0; pReply->EventNotification.u32Event = MPT_EVENT_EVENT_CHANGE; pReply->EventNotification.u32EventContext = 0; pReply->EventNotification.u32EventData = pThis->fEventNotificationEnabled ? 1 : 0; break; } case MPT_MESSAGE_HDR_FUNCTION_EVENT_ACK: { AssertMsgFailed(("todo")); break; } case MPT_MESSAGE_HDR_FUNCTION_CONFIG: { PMptConfigurationRequest pConfigurationReq = (PMptConfigurationRequest)pMessageHdr; rc = lsilogicR3ProcessConfigurationRequest(pDevIns, pThis, pThisCC, pConfigurationReq, &pReply->Configuration); AssertRC(rc); break; } case MPT_MESSAGE_HDR_FUNCTION_FW_UPLOAD: { PMptFWUploadRequest pFWUploadReq = (PMptFWUploadRequest)pMessageHdr; pReply->FWUpload.u8ImageType = pFWUploadReq->u8ImageType; pReply->FWUpload.u8MessageLength = 6; pReply->FWUpload.u32ActualImageSize = 0; break; } case MPT_MESSAGE_HDR_FUNCTION_FW_DOWNLOAD: { //PMptFWDownloadRequest pFWDownloadReq = (PMptFWDownloadRequest)pMessageHdr; pReply->FWDownload.u8MessageLength = 5; LogFlowFunc(("FW Download request issued\n")); break; } case MPT_MESSAGE_HDR_FUNCTION_SCSI_IO_REQUEST: /* Should be handled already. */ default: AssertMsgFailed(("Invalid request function %#x\n", pMessageHdr->u8Function)); } /* Copy common bits from request message frame to reply. */ pReply->Header.u8Function = pMessageHdr->u8Function; pReply->Header.u32MessageContext = pMessageHdr->u32MessageContext; lsilogicFinishAddressReply(pDevIns, pThis, pReply, fForceReplyPostFifo); return rc; } #endif /* IN_RING3 */ /** * Writes a value to a register at a given offset. * * @returns Strict VBox status code. * @param pDevIns The devie instance. * @param pThis Pointer to the shared LsiLogic device state. * @param offReg Offset of the register to write. * @param u32 The value being written. */ static VBOXSTRICTRC lsilogicRegisterWrite(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis, uint32_t offReg, uint32_t u32) { LogFlowFunc(("pThis=%#p offReg=%#x u32=%#x\n", pThis, offReg, u32)); switch (offReg) { case LSILOGIC_REG_REPLY_QUEUE: { int rc = PDMDevHlpCritSectEnter(pDevIns, &pThis->ReplyFreeQueueWriteCritSect, VINF_IOM_R3_MMIO_WRITE); if (rc != VINF_SUCCESS) return rc; /* Add the entry to the reply free queue. */ ASMAtomicWriteU32(&pThis->aReplyFreeQueue[pThis->uReplyFreeQueueNextEntryFreeWrite], u32); pThis->uReplyFreeQueueNextEntryFreeWrite++; pThis->uReplyFreeQueueNextEntryFreeWrite %= pThis->cReplyQueueEntries; PDMDevHlpCritSectLeave(pDevIns, &pThis->ReplyFreeQueueWriteCritSect); break; } case LSILOGIC_REG_REQUEST_QUEUE: { int rc = PDMDevHlpCritSectEnter(pDevIns, &pThis->RequestQueueCritSect, VINF_IOM_R3_MMIO_WRITE); if (rc != VINF_SUCCESS) return rc; uint32_t uNextWrite = ASMAtomicReadU32(&pThis->uRequestQueueNextEntryFreeWrite); ASMAtomicWriteU32(&pThis->aRequestQueue[uNextWrite], u32); /* * Don't update the value in place. It can happen that we get preempted * after the increment but before the modulo. * Another EMT will read the wrong value when processing the queues * and hang in an endless loop creating thousands of requests. */ uNextWrite++; uNextWrite %= pThis->cRequestQueueEntries; ASMAtomicWriteU32(&pThis->uRequestQueueNextEntryFreeWrite, uNextWrite); PDMDevHlpCritSectLeave(pDevIns, &pThis->RequestQueueCritSect); /* Send notification to R3 if there is not one sent already. Do this * only if the worker thread is not sleeping or might go sleeping. */ if (!ASMAtomicXchgBool(&pThis->fNotificationSent, true)) { if (ASMAtomicReadBool(&pThis->fWrkThreadSleeping)) { LogFlowFunc(("Signal event semaphore\n")); rc = PDMDevHlpSUPSemEventSignal(pDevIns, pThis->hEvtProcess); AssertRC(rc); } } break; } case LSILOGIC_REG_DOORBELL: { /* * When the guest writes to this register a real device would set the * doorbell status bit in the interrupt status register to indicate that the IOP * has still to process the message. * The guest needs to wait with posting new messages here until the bit is cleared. * Because the guest is not continuing execution while we are here we can skip this. */ if (pThis->enmDoorbellState == LSILOGICDOORBELLSTATE_NOT_IN_USE) { uint32_t uFunction = LSILOGIC_REG_DOORBELL_GET_FUNCTION(u32); switch (uFunction) { case LSILOGIC_DOORBELL_FUNCTION_IO_UNIT_RESET: case LSILOGIC_DOORBELL_FUNCTION_IOC_MSG_UNIT_RESET: { /* * The I/O unit reset does much more on real hardware like * reloading the firmware, nothing we need to do here, * so this is like the IOC message unit reset. */ pThis->enmState = LSILOGICSTATE_RESET; /* Reset interrupt status. */ pThis->uInterruptStatus = 0; lsilogicUpdateInterrupt(pDevIns, pThis); /* Reset the queues. */ pThis->uReplyFreeQueueNextEntryFreeWrite = 0; pThis->uReplyFreeQueueNextAddressRead = 0; pThis->uReplyPostQueueNextEntryFreeWrite = 0; pThis->uReplyPostQueueNextAddressRead = 0; pThis->uRequestQueueNextEntryFreeWrite = 0; pThis->uRequestQueueNextAddressRead = 0; /* Only the IOC message unit reset transisionts to the ready state. */ if (uFunction == LSILOGIC_DOORBELL_FUNCTION_IOC_MSG_UNIT_RESET) pThis->enmState = LSILOGICSTATE_READY; break; } case LSILOGIC_DOORBELL_FUNCTION_HANDSHAKE: { pThis->cMessage = LSILOGIC_REG_DOORBELL_GET_SIZE(u32); pThis->iMessage = 0; /* This is not supposed to happen and the result is undefined, just stay in the current state. */ AssertMsgReturn(pThis->cMessage <= RT_ELEMENTS(pThis->aMessage), ("Message doesn't fit into the buffer, cMessage=%u", pThis->cMessage), VINF_SUCCESS); pThis->enmDoorbellState = LSILOGICDOORBELLSTATE_FN_HANDSHAKE; /* Update the interrupt status to notify the guest that a doorbell function was started. */ lsilogicSetInterrupt(pDevIns, pThis, LSILOGIC_REG_HOST_INTR_STATUS_SYSTEM_DOORBELL); break; } case LSILOGIC_DOORBELL_FUNCTION_REPLY_FRAME_REMOVAL: { pThis->enmDoorbellState = LSILOGICDOORBELLSTATE_RFR_FRAME_COUNT_LOW; /* Update the interrupt status to notify the guest that a doorbell function was started. */ lsilogicSetInterrupt(pDevIns, pThis, LSILOGIC_REG_HOST_INTR_STATUS_SYSTEM_DOORBELL); break; } default: AssertMsgFailed(("Unknown function %u to perform\n", uFunction)); } } else if (pThis->enmDoorbellState == LSILOGICDOORBELLSTATE_FN_HANDSHAKE) { /* * We are already performing a doorbell function. * Get the remaining parameters, ignore any excess writes. */ AssertMsgReturn(pThis->iMessage < pThis->cMessage, ("Guest is trying to write more than was indicated in the handshake\n"), VINF_SUCCESS); /* * If the last byte of the message is written, force a switch to R3 because some requests might force * a reply through the FIFO which cannot be handled in GC or R0. */ #ifndef IN_RING3 if (pThis->iMessage == pThis->cMessage - 1) return VINF_IOM_R3_MMIO_WRITE; #endif pThis->aMessage[pThis->iMessage++] = u32; #ifdef IN_RING3 if (pThis->iMessage == pThis->cMessage) { int rc = lsilogicR3ProcessMessageRequest(pDevIns, pThis, PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC), (PMptMessageHdr)pThis->aMessage, &pThis->ReplyBuffer); AssertRC(rc); } #endif } break; } case LSILOGIC_REG_HOST_INTR_STATUS: { /* * Clear the bits the guest wants except the system doorbell interrupt and the IO controller * status bit. * The former bit is always cleared no matter what the guest writes to the register and * the latter one is read only. */ ASMAtomicAndU32(&pThis->uInterruptStatus, ~LSILOGIC_REG_HOST_INTR_STATUS_SYSTEM_DOORBELL); /* * Check if there is still a doorbell function in progress. Set the * system doorbell interrupt bit again if it is. * We do not use lsilogicSetInterrupt here because the interrupt status * is updated afterwards anyway. */ if ( (pThis->enmDoorbellState == LSILOGICDOORBELLSTATE_FN_HANDSHAKE) && (pThis->cMessage == pThis->iMessage)) { if (pThis->uNextReplyEntryRead == pThis->cReplySize) { /* Reply finished. Reset doorbell in progress status. */ Log(("%s: Doorbell function finished\n", __FUNCTION__)); pThis->enmDoorbellState = LSILOGICDOORBELLSTATE_NOT_IN_USE; } ASMAtomicOrU32(&pThis->uInterruptStatus, LSILOGIC_REG_HOST_INTR_STATUS_SYSTEM_DOORBELL); } else if ( pThis->enmDoorbellState != LSILOGICDOORBELLSTATE_NOT_IN_USE && pThis->enmDoorbellState != LSILOGICDOORBELLSTATE_FN_HANDSHAKE) { /* Reply frame removal, check whether the reply free queue is empty. */ if ( pThis->uReplyFreeQueueNextAddressRead == pThis->uReplyFreeQueueNextEntryFreeWrite && pThis->enmDoorbellState == LSILOGICDOORBELLSTATE_RFR_NEXT_FRAME_LOW) pThis->enmDoorbellState = LSILOGICDOORBELLSTATE_NOT_IN_USE; ASMAtomicOrU32(&pThis->uInterruptStatus, LSILOGIC_REG_HOST_INTR_STATUS_SYSTEM_DOORBELL); } lsilogicUpdateInterrupt(pDevIns, pThis); break; } case LSILOGIC_REG_HOST_INTR_MASK: { ASMAtomicWriteU32(&pThis->uInterruptMask, u32 & LSILOGIC_REG_HOST_INTR_MASK_W_MASK); lsilogicUpdateInterrupt(pDevIns, pThis); break; } case LSILOGIC_REG_WRITE_SEQUENCE: { if (pThis->fDiagnosticEnabled) { /* Any value will cause a reset and disabling access. */ pThis->fDiagnosticEnabled = false; pThis->iDiagnosticAccess = 0; pThis->fDiagRegsEnabled = false; } else if ((u32 & 0xf) == g_lsilogicDiagnosticAccess[pThis->iDiagnosticAccess]) { pThis->iDiagnosticAccess++; if (pThis->iDiagnosticAccess == RT_ELEMENTS(g_lsilogicDiagnosticAccess)) { /* * Key sequence successfully written. Enable access to diagnostic * memory and register. */ pThis->fDiagnosticEnabled = true; } } else { /* Wrong value written - reset to beginning. */ pThis->iDiagnosticAccess = 0; } break; } case LSILOGIC_REG_HOST_DIAGNOSTIC: { if (pThis->fDiagnosticEnabled) { #ifndef IN_RING3 return VINF_IOM_R3_MMIO_WRITE; #else if (u32 & LSILOGIC_REG_HOST_DIAGNOSTIC_RESET_ADAPTER) lsilogicR3HardReset(pDevIns, pThis, PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC)); else if (u32 & LSILOGIC_REG_HOST_DIAGNOSTIC_DIAG_RW_ENABLE) pThis->fDiagRegsEnabled = true; #endif } break; } case LSILOGIC_REG_DIAG_RW_DATA: { if (pThis->fDiagRegsEnabled) { #ifndef IN_RING3 return VINF_IOM_R3_MMIO_WRITE; #else lsilogicR3DiagRegDataWrite(pThis, PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC), u32); #endif } break; } case LSILOGIC_REG_DIAG_RW_ADDRESS: { if (pThis->fDiagRegsEnabled) { #ifndef IN_RING3 return VINF_IOM_R3_MMIO_WRITE; #else lsilogicR3DiagRegAddressWrite(pThis, u32); #endif } break; } default: /* Ignore. */ { break; } } return VINF_SUCCESS; } /** * Reads the content of a register at a given offset. * * @returns VBox status code. * @param pDevIns The device instance. * @param pThis Pointer to the shared LsiLogic device state. * @param offReg Offset of the register to read. * @param pu32 Where to store the content of the register. */ static VBOXSTRICTRC lsilogicRegisterRead(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis, uint32_t offReg, uint32_t *pu32) { int rc = VINF_SUCCESS; uint32_t u32 = 0; Assert(!(offReg & 3)); /* Align to a 4 byte offset. */ switch (offReg) { case LSILOGIC_REG_REPLY_QUEUE: { rc = PDMDevHlpCritSectEnter(pDevIns, &pThis->ReplyPostQueueCritSect, VINF_IOM_R3_MMIO_READ); if (rc != VINF_SUCCESS) break; uint32_t idxReplyPostQueueWrite = ASMAtomicUoReadU32(&pThis->uReplyPostQueueNextEntryFreeWrite); uint32_t idxReplyPostQueueRead = ASMAtomicUoReadU32(&pThis->uReplyPostQueueNextAddressRead); if (idxReplyPostQueueWrite != idxReplyPostQueueRead) { u32 = pThis->aReplyPostQueue[idxReplyPostQueueRead]; idxReplyPostQueueRead++; idxReplyPostQueueRead %= pThis->cReplyQueueEntries; ASMAtomicWriteU32(&pThis->uReplyPostQueueNextAddressRead, idxReplyPostQueueRead); } else { /* The reply post queue is empty. Reset interrupt. */ u32 = UINT32_C(0xffffffff); lsilogicClearInterrupt(pDevIns, pThis, LSILOGIC_REG_HOST_INTR_STATUS_REPLY_INTR); } PDMDevHlpCritSectLeave(pDevIns, &pThis->ReplyPostQueueCritSect); Log(("%s: Returning address %#x\n", __FUNCTION__, u32)); break; } case LSILOGIC_REG_DOORBELL: { u32 = LSILOGIC_REG_DOORBELL_SET_STATE(pThis->enmState); u32 |= LSILOGIC_REG_DOORBELL_SET_USED(pThis->enmDoorbellState); u32 |= LSILOGIC_REG_DOORBELL_SET_WHOINIT(pThis->enmWhoInit); /* * If there is a doorbell function in progress we pass the return value * instead of the status code. We transfer 16bit of the reply * during one read. */ switch (pThis->enmDoorbellState) { case LSILOGICDOORBELLSTATE_NOT_IN_USE: /* We return the status code of the I/O controller. */ u32 |= pThis->u16IOCFaultCode; break; case LSILOGICDOORBELLSTATE_FN_HANDSHAKE: /* Return next 16bit value. */ if (pThis->uNextReplyEntryRead < pThis->cReplySize) u32 |= pThis->ReplyBuffer.au16Reply[pThis->uNextReplyEntryRead++]; lsilogicSetInterrupt(pDevIns, pThis, LSILOGIC_REG_HOST_INTR_STATUS_SYSTEM_DOORBELL); break; case LSILOGICDOORBELLSTATE_RFR_FRAME_COUNT_LOW: { uint32_t cReplyFrames = lsilogicReplyFreeQueueGetFrameCount(pThis); u32 |= cReplyFrames & UINT32_C(0xffff); pThis->enmDoorbellState = LSILOGICDOORBELLSTATE_RFR_FRAME_COUNT_HIGH; lsilogicSetInterrupt(pDevIns, pThis, LSILOGIC_REG_HOST_INTR_STATUS_SYSTEM_DOORBELL); break; } case LSILOGICDOORBELLSTATE_RFR_FRAME_COUNT_HIGH: { uint32_t cReplyFrames = lsilogicReplyFreeQueueGetFrameCount(pThis); u32 |= cReplyFrames >> 16; pThis->enmDoorbellState = LSILOGICDOORBELLSTATE_RFR_NEXT_FRAME_LOW; lsilogicSetInterrupt(pDevIns, pThis, LSILOGIC_REG_HOST_INTR_STATUS_SYSTEM_DOORBELL); break; } case LSILOGICDOORBELLSTATE_RFR_NEXT_FRAME_LOW: if (pThis->uReplyFreeQueueNextEntryFreeWrite != pThis->uReplyFreeQueueNextAddressRead) { u32 |= pThis->aReplyFreeQueue[pThis->uReplyFreeQueueNextAddressRead] & UINT32_C(0xffff); pThis->enmDoorbellState = LSILOGICDOORBELLSTATE_RFR_NEXT_FRAME_HIGH; lsilogicSetInterrupt(pDevIns, pThis, LSILOGIC_REG_HOST_INTR_STATUS_SYSTEM_DOORBELL); } break; case LSILOGICDOORBELLSTATE_RFR_NEXT_FRAME_HIGH: u32 |= pThis->aReplyFreeQueue[pThis->uReplyFreeQueueNextAddressRead] >> 16; pThis->uReplyFreeQueueNextAddressRead++; pThis->uReplyFreeQueueNextAddressRead %= pThis->cReplyQueueEntries; pThis->enmDoorbellState = LSILOGICDOORBELLSTATE_RFR_NEXT_FRAME_LOW; lsilogicSetInterrupt(pDevIns, pThis, LSILOGIC_REG_HOST_INTR_STATUS_SYSTEM_DOORBELL); break; default: AssertMsgFailed(("Invalid doorbell state %d\n", pThis->enmDoorbellState)); } break; } case LSILOGIC_REG_HOST_INTR_STATUS: { u32 = ASMAtomicReadU32(&pThis->uInterruptStatus); break; } case LSILOGIC_REG_HOST_INTR_MASK: { u32 = ASMAtomicReadU32(&pThis->uInterruptMask); break; } case LSILOGIC_REG_HOST_DIAGNOSTIC: { if (pThis->fDiagnosticEnabled) u32 |= LSILOGIC_REG_HOST_DIAGNOSTIC_DRWE; if (pThis->fDiagRegsEnabled) u32 |= LSILOGIC_REG_HOST_DIAGNOSTIC_DIAG_RW_ENABLE; break; } case LSILOGIC_REG_DIAG_RW_DATA: { if (pThis->fDiagRegsEnabled) { #ifndef IN_RING3 return VINF_IOM_R3_MMIO_READ; #else lsilogicR3DiagRegDataRead(pThis, PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC), &u32); #endif } } RT_FALL_THRU(); case LSILOGIC_REG_DIAG_RW_ADDRESS: { if (pThis->fDiagRegsEnabled) { #ifndef IN_RING3 return VINF_IOM_R3_MMIO_READ; #else lsilogicR3DiagRegAddressRead(pThis, &u32); #endif } } RT_FALL_THRU(); case LSILOGIC_REG_TEST_BASE_ADDRESS: /* The spec doesn't say anything about these registers, so we just ignore them */ default: /* Ignore. */ { /** @todo LSILOGIC_REG_DIAG_* should return all F's when accessed by MMIO. We * return 0. Likely to apply to undefined offsets as well. */ break; } } *pu32 = u32; LogFlowFunc(("pThis=%#p offReg=%#x u32=%#x\n", pThis, offReg, u32)); return rc; } /** * @callback_method_impl{FNIOMIOPORTNEWOUT} */ static DECLCALLBACK(VBOXSTRICTRC) lsilogicIOPortWrite(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT offPort, uint32_t u32, unsigned cb) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); VBOXSTRICTRC rcStrict; RT_NOREF2(pvUser, cb); if (!(offPort & 3)) { rcStrict = lsilogicRegisterWrite(pDevIns, pThis, offPort, u32); if (rcStrict == VINF_IOM_R3_MMIO_WRITE) rcStrict = VINF_IOM_R3_IOPORT_WRITE; } else { Log(("lsilogicIOPortWrite: Ignoring misaligned write - offPort=%#x u32=%#x cb=%#x\n", offPort, u32, cb)); rcStrict = VINF_SUCCESS; } return rcStrict; } /** * @callback_method_impl{FNIOMIOPORTNEWIN} */ static DECLCALLBACK(VBOXSTRICTRC) lsilogicIOPortRead(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT offPort, uint32_t *pu32, unsigned cb) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); RT_NOREF_PV(pvUser); RT_NOREF_PV(cb); VBOXSTRICTRC rcStrict = lsilogicRegisterRead(pDevIns, pThis, offPort & ~(uint32_t)3, pu32); if (rcStrict == VINF_IOM_R3_MMIO_READ) rcStrict = VINF_IOM_R3_IOPORT_READ; return rcStrict; } /** * @callback_method_impl{FNIOMMMIONEWWRITE} */ static DECLCALLBACK(VBOXSTRICTRC) lsilogicMMIOWrite(PPDMDEVINS pDevIns, void *pvUser, RTGCPHYS off, void const *pv, unsigned cb) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); uint32_t u32; RT_NOREF_PV(pvUser); /* See comments in lsilogicR3Construct regarding size and alignment. */ if (cb == 4) u32 = *(uint32_t const *)pv; else { if (cb > 4) u32 = *(uint32_t const *)pv; else if (cb >= 2) u32 = *(uint16_t const *)pv; else u32 = *(uint8_t const *)pv; Log(("lsilogicMMIOWrite: Non-DWORD write access - off=%#RGp u32=%#x cb=%#x\n", off, u32, cb)); } VBOXSTRICTRC rcStrict; if (!(off & 3)) rcStrict = lsilogicRegisterWrite(pDevIns, pThis, (uint32_t)off, u32); else { Log(("lsilogicMMIOWrite: Ignoring misaligned write - off=%#RGp u32=%#x cb=%#x\n", off, u32, cb)); rcStrict = VINF_SUCCESS; } return rcStrict; } /** * @callback_method_impl{FNIOMMMIONEWREAD} */ static DECLCALLBACK(VBOXSTRICTRC) lsilogicMMIORead(PPDMDEVINS pDevIns, void *pvUser, RTGCPHYS off, void *pv, unsigned cb) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); Assert(!(off & 3)); Assert(cb == 4); /* If any of these trigger you've changed the registration flags or IOM is busted. */ RT_NOREF2(pvUser, cb); return lsilogicRegisterRead(pDevIns, pThis, off, (uint32_t *)pv); } /** * @callback_method_impl{FNIOMMMIONEWWRITE} */ static DECLCALLBACK(VBOXSTRICTRC) lsilogicDiagnosticWrite(PPDMDEVINS pDevIns, void *pvUser, RTGCPHYS off, void const *pv, unsigned cb) { RT_NOREF(pDevIns, pvUser, off, pv, cb); LogFlowFunc(("pThis=%#p GCPhysAddr=%RGp pv=%#p{%.*Rhxs} cb=%u\n", PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI), off, pv, cb, pv, cb)); return VINF_SUCCESS; } /** * @callback_method_impl{FNIOMMMIONEWREAD} */ static DECLCALLBACK(VBOXSTRICTRC) lsilogicDiagnosticRead(PPDMDEVINS pDevIns, void *pvUser, RTGCPHYS off, void *pv, unsigned cb) { RT_NOREF(pDevIns, pvUser, off, pv, cb); LogFlowFunc(("pThis=%#p off=%RGp pv=%#p{%.*Rhxs} cb=%u\n", PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI), off, pv, cb, pv, cb)); return VINF_SUCCESS; } #ifdef IN_RING3 # ifdef LOG_ENABLED /** * Dump an SG entry. * * @param pSGEntry Pointer to the SG entry to dump */ static void lsilogicDumpSGEntry(PMptSGEntryUnion pSGEntry) { if (LogIsEnabled()) { switch (pSGEntry->Simple32.u2ElementType) { case MPTSGENTRYTYPE_SIMPLE: { Log(("%s: Dumping info for SIMPLE SG entry:\n", __FUNCTION__)); Log(("%s: u24Length=%u\n", __FUNCTION__, pSGEntry->Simple32.u24Length)); Log(("%s: fEndOfList=%d\n", __FUNCTION__, pSGEntry->Simple32.fEndOfList)); Log(("%s: f64BitAddress=%d\n", __FUNCTION__, pSGEntry->Simple32.f64BitAddress)); Log(("%s: fBufferContainsData=%d\n", __FUNCTION__, pSGEntry->Simple32.fBufferContainsData)); Log(("%s: fLocalAddress=%d\n", __FUNCTION__, pSGEntry->Simple32.fLocalAddress)); Log(("%s: fEndOfBuffer=%d\n", __FUNCTION__, pSGEntry->Simple32.fEndOfBuffer)); Log(("%s: fLastElement=%d\n", __FUNCTION__, pSGEntry->Simple32.fLastElement)); Log(("%s: u32DataBufferAddressLow=%u\n", __FUNCTION__, pSGEntry->Simple32.u32DataBufferAddressLow)); if (pSGEntry->Simple32.f64BitAddress) { Log(("%s: u32DataBufferAddressHigh=%u\n", __FUNCTION__, pSGEntry->Simple64.u32DataBufferAddressHigh)); Log(("%s: GCDataBufferAddress=%RGp\n", __FUNCTION__, ((uint64_t)pSGEntry->Simple64.u32DataBufferAddressHigh << 32) | pSGEntry->Simple64.u32DataBufferAddressLow)); } else Log(("%s: GCDataBufferAddress=%RGp\n", __FUNCTION__, pSGEntry->Simple32.u32DataBufferAddressLow)); break; } case MPTSGENTRYTYPE_CHAIN: { Log(("%s: Dumping info for CHAIN SG entry:\n", __FUNCTION__)); Log(("%s: u16Length=%u\n", __FUNCTION__, pSGEntry->Chain.u16Length)); Log(("%s: u8NExtChainOffset=%d\n", __FUNCTION__, pSGEntry->Chain.u8NextChainOffset)); Log(("%s: f64BitAddress=%d\n", __FUNCTION__, pSGEntry->Chain.f64BitAddress)); Log(("%s: fLocalAddress=%d\n", __FUNCTION__, pSGEntry->Chain.fLocalAddress)); Log(("%s: u32SegmentAddressLow=%u\n", __FUNCTION__, pSGEntry->Chain.u32SegmentAddressLow)); Log(("%s: u32SegmentAddressHigh=%u\n", __FUNCTION__, pSGEntry->Chain.u32SegmentAddressHigh)); if (pSGEntry->Chain.f64BitAddress) Log(("%s: GCSegmentAddress=%RGp\n", __FUNCTION__, ((uint64_t)pSGEntry->Chain.u32SegmentAddressHigh << 32) | pSGEntry->Chain.u32SegmentAddressLow)); else Log(("%s: GCSegmentAddress=%RGp\n", __FUNCTION__, pSGEntry->Chain.u32SegmentAddressLow)); break; } } } } # endif /* LOG_ENABLED */ /** * Copy from guest to host memory worker. * * @copydoc FNLSILOGICR3MEMCOPYCALLBACK */ static DECLCALLBACK(void) lsilogicR3CopyBufferFromGuestWorker(PPDMDEVINS pDevIns, RTGCPHYS GCPhys, PRTSGBUF pSgBuf, size_t cbCopy, size_t *pcbSkip) { size_t cbSkipped = RT_MIN(cbCopy, *pcbSkip); cbCopy -= cbSkipped; GCPhys += cbSkipped; *pcbSkip -= cbSkipped; while (cbCopy) { size_t cbSeg = cbCopy; void *pvSeg = RTSgBufGetNextSegment(pSgBuf, &cbSeg); AssertPtr(pvSeg); PDMDevHlpPCIPhysReadUser(pDevIns, GCPhys, pvSeg, cbSeg); GCPhys += cbSeg; cbCopy -= cbSeg; } } /** * Copy from host to guest memory worker. * * @copydoc FNLSILOGICR3MEMCOPYCALLBACK */ static DECLCALLBACK(void) lsilogicR3CopyBufferToGuestWorker(PPDMDEVINS pDevIns, RTGCPHYS GCPhys, PRTSGBUF pSgBuf, size_t cbCopy, size_t *pcbSkip) { size_t cbSkipped = RT_MIN(cbCopy, *pcbSkip); cbCopy -= cbSkipped; GCPhys += cbSkipped; *pcbSkip -= cbSkipped; while (cbCopy) { size_t cbSeg = cbCopy; void *pvSeg = RTSgBufGetNextSegment(pSgBuf, &cbSeg); AssertPtr(pvSeg); PDMDevHlpPCIPhysWriteUser(pDevIns, GCPhys, pvSeg, cbSeg); GCPhys += cbSeg; cbCopy -= cbSeg; } } /** * Walks the guest S/G buffer calling the given copy worker for every buffer. * * @returns The amout of bytes actually copied. * @param pDevIns The device instance. * @param pLsiReq LSI request state. * @param pfnCopyWorker The copy method to apply for each guest buffer. * @param pSgBuf The host S/G buffer. * @param cbSkip How many bytes to skip in advance before starting to * copy. * @param cbCopy How many bytes to copy. */ static size_t lsilogicSgBufWalker(PPDMDEVINS pDevIns, PLSILOGICREQ pLsiReq, PFNLSILOGICR3MEMCOPYCALLBACK pfnCopyWorker, PRTSGBUF pSgBuf, size_t cbSkip, size_t cbCopy) { bool fEndOfList = false; RTGCPHYS GCPhysSgEntryNext = pLsiReq->GCPhysSgStart; RTGCPHYS GCPhysSegmentStart = pLsiReq->GCPhysSgStart; uint32_t cChainOffsetNext = pLsiReq->cChainOffset; size_t cbCopied = 0; /* * Add the amount to skip to the host buffer size to avoid a * few conditionals later on. */ cbCopy += cbSkip; /* Go through the list until we reach the end. */ while ( !fEndOfList && cbCopy) { bool fEndOfSegment = false; while ( !fEndOfSegment && cbCopy) { MptSGEntryUnion SGEntry; Log(("%s: Reading SG entry from %RGp\n", __FUNCTION__, GCPhysSgEntryNext)); /* Read the entry. */ PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysSgEntryNext, &SGEntry, sizeof(MptSGEntryUnion)); # ifdef LOG_ENABLED lsilogicDumpSGEntry(&SGEntry); # endif AssertMsg(SGEntry.Simple32.u2ElementType == MPTSGENTRYTYPE_SIMPLE, ("Invalid SG entry type\n")); /* Check if this is a zero element and abort. */ if ( !SGEntry.Simple32.u24Length && SGEntry.Simple32.fEndOfList && SGEntry.Simple32.fEndOfBuffer) return cbCopied - RT_MIN(cbSkip, cbCopied); size_t cbCopyThis = RT_MIN(SGEntry.Simple32.u24Length, cbCopy); RTGCPHYS GCPhysAddrDataBuffer = SGEntry.Simple32.u32DataBufferAddressLow; if (SGEntry.Simple32.f64BitAddress) { GCPhysAddrDataBuffer |= ((uint64_t)SGEntry.Simple64.u32DataBufferAddressHigh) << 32; GCPhysSgEntryNext += sizeof(MptSGEntrySimple64); } else GCPhysSgEntryNext += sizeof(MptSGEntrySimple32); pfnCopyWorker(pDevIns, GCPhysAddrDataBuffer, pSgBuf, cbCopyThis, &cbSkip); cbCopy -= cbCopyThis; cbCopied += cbCopyThis; /* Check if we reached the end of the list. */ if (SGEntry.Simple32.fEndOfList) { /* We finished. */ fEndOfSegment = true; fEndOfList = true; } else if (SGEntry.Simple32.fLastElement) fEndOfSegment = true; } /* while (!fEndOfSegment) */ /* Get next chain element. */ if (cChainOffsetNext) { MptSGEntryChain SGEntryChain; PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysSegmentStart + cChainOffsetNext, &SGEntryChain, sizeof(MptSGEntryChain)); AssertMsg(SGEntryChain.u2ElementType == MPTSGENTRYTYPE_CHAIN, ("Invalid SG entry type\n")); /* Set the next address now. */ GCPhysSgEntryNext = SGEntryChain.u32SegmentAddressLow; if (SGEntryChain.f64BitAddress) GCPhysSgEntryNext |= ((uint64_t)SGEntryChain.u32SegmentAddressHigh) << 32; GCPhysSegmentStart = GCPhysSgEntryNext; cChainOffsetNext = SGEntryChain.u8NextChainOffset * sizeof(uint32_t); } } /* while (!fEndOfList) */ return cbCopied - RT_MIN(cbSkip, cbCopied); } /** * Copies a data buffer into the S/G buffer set up by the guest. * * @returns Amount of bytes copied to the guest. * @param pDevIns The device instance. * @param pReq Request structure. * @param pSgBuf The S/G buffer to copy from. * @param cbSkip How many bytes to skip in advance before starting to copy. * @param cbCopy How many bytes to copy. */ static size_t lsilogicR3CopySgBufToGuest(PPDMDEVINS pDevIns, PLSILOGICREQ pReq, PRTSGBUF pSgBuf, size_t cbSkip, size_t cbCopy) { return lsilogicSgBufWalker(pDevIns, pReq, lsilogicR3CopyBufferToGuestWorker, pSgBuf, cbSkip, cbCopy); } /** * Copies the guest S/G buffer into a host data buffer. * * @returns Amount of bytes copied from the guest. * @param pDevIns The device instance. * @param pReq Request structure. * @param pSgBuf The S/G buffer to copy into. * @param cbSkip How many bytes to skip in advance before starting to copy. * @param cbCopy How many bytes to copy. */ static size_t lsilogicR3CopySgBufFromGuest(PPDMDEVINS pDevIns, PLSILOGICREQ pReq, PRTSGBUF pSgBuf, size_t cbSkip, size_t cbCopy) { return lsilogicSgBufWalker(pDevIns, pReq, lsilogicR3CopyBufferFromGuestWorker, pSgBuf, cbSkip, cbCopy); } #if 0 /* unused */ /** * Copy a simple memory buffer to the guest memory buffer. * * @returns Amount of bytes copied to the guest. * @param pThis The LsiLogic controller device instance. * @param pReq Request structure. * @param pvSrc The buffer to copy from. * @param cbSrc How many bytes to copy. * @param cbSkip How many bytes to skip initially. */ static size_t lsilogicR3CopyBufferToGuest(PLSILOGICSCSI pThis, PLSILOGICREQ pReq, const void *pvSrc, size_t cbSrc, size_t cbSkip) { RTSGSEG Seg; RTSGBUF SgBuf; Seg.pvSeg = (void *)pvSrc; Seg.cbSeg = cbSrc; RTSgBufInit(&SgBuf, &Seg, 1); return lsilogicR3CopySgBufToGuest(pThis, pReq, &SgBuf, cbSkip, cbSrc); } /** * Copy a guest memry buffe into simple host memory buffer. * * @returns Amount of bytes copied to the guest. * @param pThis The LsiLogic controller device instance. * @param pReq Request structure. * @param pvSrc The buffer to copy from. * @param cbSrc How many bytes to copy. * @param cbSkip How many bytes to skip initially. */ static size_t lsilogicR3CopyBufferFromGuest(PLSILOGICSCSI pThis, PLSILOGICREQ pReq, void *pvDst, size_t cbDst, size_t cbSkip) { RTSGSEG Seg; RTSGBUF SgBuf; Seg.pvSeg = (void *)pvDst; Seg.cbSeg = cbDst; RTSgBufInit(&SgBuf, &Seg, 1); return lsilogicR3CopySgBufFromGuest(pThis, pReq, &SgBuf, cbSkip, cbDst); } #endif # ifdef LOG_ENABLED static void lsilogicR3DumpSCSIIORequest(PMptSCSIIORequest pSCSIIORequest) { if (LogIsEnabled()) { Log(("%s: u8TargetID=%d\n", __FUNCTION__, pSCSIIORequest->u8TargetID)); Log(("%s: u8Bus=%d\n", __FUNCTION__, pSCSIIORequest->u8Bus)); Log(("%s: u8ChainOffset=%d\n", __FUNCTION__, pSCSIIORequest->u8ChainOffset)); Log(("%s: u8Function=%d\n", __FUNCTION__, pSCSIIORequest->u8Function)); Log(("%s: u8CDBLength=%d\n", __FUNCTION__, pSCSIIORequest->u8CDBLength)); Log(("%s: u8SenseBufferLength=%d\n", __FUNCTION__, pSCSIIORequest->u8SenseBufferLength)); Log(("%s: u8MessageFlags=%d\n", __FUNCTION__, pSCSIIORequest->u8MessageFlags)); Log(("%s: u32MessageContext=%#x\n", __FUNCTION__, pSCSIIORequest->u32MessageContext)); for (unsigned i = 0; i < RT_ELEMENTS(pSCSIIORequest->au8LUN); i++) Log(("%s: u8LUN[%d]=%d\n", __FUNCTION__, i, pSCSIIORequest->au8LUN[i])); Log(("%s: u32Control=%#x\n", __FUNCTION__, pSCSIIORequest->u32Control)); for (unsigned i = 0; i < RT_ELEMENTS(pSCSIIORequest->au8CDB); i++) Log(("%s: u8CDB[%d]=%d\n", __FUNCTION__, i, pSCSIIORequest->au8CDB[i])); Log(("%s: u32DataLength=%#x\n", __FUNCTION__, pSCSIIORequest->u32DataLength)); Log(("%s: u32SenseBufferLowAddress=%#x\n", __FUNCTION__, pSCSIIORequest->u32SenseBufferLowAddress)); } } # endif /** * Handles the completion of th given request. * * @param pDevIns The device instance. * @param pThis Pointer to the shared LsiLogic device state. * @param pReq The request to complete. * @param rcReq Status code of the request. */ static void lsilogicR3ReqComplete(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis, PLSILOGICREQ pReq, int rcReq) { PLSILOGICDEVICE pTgtDev = pReq->pTargetDevice; RTGCPHYS GCPhysAddrSenseBuffer; GCPhysAddrSenseBuffer = pReq->GuestRequest.SCSIIO.u32SenseBufferLowAddress; GCPhysAddrSenseBuffer |= ((uint64_t)pThis->u32SenseBufferHighAddr << 32); /* Copy the sense buffer over. */ if (pReq->GuestRequest.SCSIIO.u8SenseBufferLength > 0) PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysAddrSenseBuffer, pReq->abSenseBuffer, RT_UNLIKELY( pReq->GuestRequest.SCSIIO.u8SenseBufferLength < sizeof(pReq->abSenseBuffer)) ? pReq->GuestRequest.SCSIIO.u8SenseBufferLength : sizeof(pReq->abSenseBuffer)); if (RT_SUCCESS(rcReq) && RT_LIKELY(pReq->u8ScsiSts == SCSI_STATUS_OK)) { uint32_t u32MsgCtx = pReq->GuestRequest.SCSIIO.u32MessageContext; /* Free the request before posting completion. */ pTgtDev->pDrvMediaEx->pfnIoReqFree(pTgtDev->pDrvMediaEx, pReq->hIoReq); lsilogicR3FinishContextReply(pDevIns, pThis, u32MsgCtx); } else { MptReplyUnion IOCReply; RT_ZERO(IOCReply); /* The SCSI target encountered an error during processing post a reply. */ IOCReply.SCSIIOError.u8TargetID = pReq->GuestRequest.SCSIIO.u8TargetID; IOCReply.SCSIIOError.u8Bus = pReq->GuestRequest.SCSIIO.u8Bus; IOCReply.SCSIIOError.u8MessageLength = 8; IOCReply.SCSIIOError.u8Function = pReq->GuestRequest.SCSIIO.u8Function; IOCReply.SCSIIOError.u8CDBLength = pReq->GuestRequest.SCSIIO.u8CDBLength; IOCReply.SCSIIOError.u8SenseBufferLength = pReq->GuestRequest.SCSIIO.u8SenseBufferLength; IOCReply.SCSIIOError.u8MessageFlags = pReq->GuestRequest.SCSIIO.u8MessageFlags; IOCReply.SCSIIOError.u32MessageContext = pReq->GuestRequest.SCSIIO.u32MessageContext; IOCReply.SCSIIOError.u8SCSIStatus = pReq->u8ScsiSts; IOCReply.SCSIIOError.u8SCSIState = MPT_SCSI_IO_ERROR_SCSI_STATE_AUTOSENSE_VALID; IOCReply.SCSIIOError.u16IOCStatus = 0; IOCReply.SCSIIOError.u32IOCLogInfo = 0; IOCReply.SCSIIOError.u32TransferCount = 0; IOCReply.SCSIIOError.u32SenseCount = sizeof(pReq->abSenseBuffer); IOCReply.SCSIIOError.u32ResponseInfo = 0; /* Free the request before posting completion. */ pTgtDev->pDrvMediaEx->pfnIoReqFree(pTgtDev->pDrvMediaEx, pReq->hIoReq); lsilogicFinishAddressReply(pDevIns, pThis, &IOCReply, false); } ASMAtomicDecU32(&pTgtDev->cOutstandingRequests); if (pTgtDev->cOutstandingRequests == 0 && pThis->fSignalIdle) PDMDevHlpAsyncNotificationCompleted(pDevIns); } /** * Processes a SCSI I/O request by setting up the request * and sending it to the underlying SCSI driver. * Steps needed to complete request are done in the * callback called by the driver below upon completion of * the request. * * @returns VBox status code. * @param pDevIns The device instance. * @param pThis Pointer to the shared LsiLogic device state. * @param pThisCC Pointer to the ring-3 LsiLogic device state. * @param GCPhysMessageFrameAddr Guest physical address where the request is located. * @param pGuestReq The request read fro th guest memory. */ static int lsilogicR3ProcessSCSIIORequest(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis, PLSILOGICSCSICC pThisCC, RTGCPHYS GCPhysMessageFrameAddr, PMptRequestUnion pGuestReq) { MptReplyUnion IOCReply; int rc = VINF_SUCCESS; # ifdef LOG_ENABLED lsilogicR3DumpSCSIIORequest(&pGuestReq->SCSIIO); # endif if (RT_LIKELY( (pGuestReq->SCSIIO.u8TargetID < pThis->cDeviceStates) && (pGuestReq->SCSIIO.u8Bus == 0))) { PLSILOGICDEVICE pTgtDev = &pThisCC->paDeviceStates[pGuestReq->SCSIIO.u8TargetID]; if (pTgtDev->pDrvBase) { /* Allocate and prepare a new request. */ PDMMEDIAEXIOREQ hIoReq; PLSILOGICREQ pLsiReq = NULL; rc = pTgtDev->pDrvMediaEx->pfnIoReqAlloc(pTgtDev->pDrvMediaEx, &hIoReq, (void **)&pLsiReq, pGuestReq->SCSIIO.u32MessageContext, PDMIMEDIAEX_F_SUSPEND_ON_RECOVERABLE_ERR); if (RT_SUCCESS(rc)) { pLsiReq->hIoReq = hIoReq; pLsiReq->pTargetDevice = pTgtDev; pLsiReq->GCPhysMessageFrameAddr = GCPhysMessageFrameAddr; pLsiReq->GCPhysSgStart = GCPhysMessageFrameAddr + sizeof(MptSCSIIORequest); pLsiReq->cChainOffset = pGuestReq->SCSIIO.u8ChainOffset; if (pLsiReq->cChainOffset) pLsiReq->cChainOffset = pLsiReq->cChainOffset * sizeof(uint32_t) - sizeof(MptSCSIIORequest); memcpy(&pLsiReq->GuestRequest, pGuestReq, sizeof(MptRequestUnion)); RT_BZERO(&pLsiReq->abSenseBuffer[0], sizeof(pLsiReq->abSenseBuffer)); PDMMEDIAEXIOREQSCSITXDIR enmXferDir = PDMMEDIAEXIOREQSCSITXDIR_UNKNOWN; uint8_t uDataDirection = MPT_SCSIIO_REQUEST_CONTROL_TXDIR_GET(pLsiReq->GuestRequest.SCSIIO.u32Control); /* * Keep the direction to unknown if there is a mismatch between the data length * and the transfer direction bit. * The Solaris 9 driver is buggy and sets it to none for INQUIRY requests. */ if ( uDataDirection == MPT_SCSIIO_REQUEST_CONTROL_TXDIR_NONE && pLsiReq->GuestRequest.SCSIIO.u32DataLength == 0) enmXferDir = PDMMEDIAEXIOREQSCSITXDIR_NONE; else if (uDataDirection == MPT_SCSIIO_REQUEST_CONTROL_TXDIR_WRITE) enmXferDir = PDMMEDIAEXIOREQSCSITXDIR_TO_DEVICE; else if (uDataDirection == MPT_SCSIIO_REQUEST_CONTROL_TXDIR_READ) enmXferDir = PDMMEDIAEXIOREQSCSITXDIR_FROM_DEVICE; ASMAtomicIncU32(&pTgtDev->cOutstandingRequests); rc = pTgtDev->pDrvMediaEx->pfnIoReqSendScsiCmd(pTgtDev->pDrvMediaEx, pLsiReq->hIoReq, pLsiReq->GuestRequest.SCSIIO.au8LUN[1], &pLsiReq->GuestRequest.SCSIIO.au8CDB[0], pLsiReq->GuestRequest.SCSIIO.u8CDBLength, enmXferDir, NULL, pLsiReq->GuestRequest.SCSIIO.u32DataLength, &pLsiReq->abSenseBuffer[0], sizeof(pLsiReq->abSenseBuffer), NULL, &pLsiReq->u8ScsiSts, 30 * RT_MS_1SEC); if (rc != VINF_PDM_MEDIAEX_IOREQ_IN_PROGRESS) lsilogicR3ReqComplete(pDevIns, pThis, pLsiReq, rc); return VINF_SUCCESS; } else IOCReply.SCSIIOError.u16IOCStatus = MPT_SCSI_IO_ERROR_IOCSTATUS_DEVICE_NOT_THERE; } else { /* Device is not present report SCSI selection timeout. */ IOCReply.SCSIIOError.u16IOCStatus = MPT_SCSI_IO_ERROR_IOCSTATUS_DEVICE_NOT_THERE; } } else { /* Report out of bounds target ID or bus. */ if (pGuestReq->SCSIIO.u8Bus != 0) IOCReply.SCSIIOError.u16IOCStatus = MPT_SCSI_IO_ERROR_IOCSTATUS_INVALID_BUS; else IOCReply.SCSIIOError.u16IOCStatus = MPT_SCSI_IO_ERROR_IOCSTATUS_INVALID_TARGETID; } static int g_cLogged = 0; if (g_cLogged++ < MAX_REL_LOG_ERRORS) { LogRel(("LsiLogic#%d: %d/%d (Bus/Target) doesn't exist\n", pDevIns->iInstance, pGuestReq->SCSIIO.u8TargetID, pGuestReq->SCSIIO.u8Bus)); /* Log the CDB too */ LogRel(("LsiLogic#%d: Guest issued CDB {%#x", pDevIns->iInstance, pGuestReq->SCSIIO.au8CDB[0])); for (unsigned i = 1; i < pGuestReq->SCSIIO.u8CDBLength; i++) LogRel((", %#x", pGuestReq->SCSIIO.au8CDB[i])); LogRel(("}\n")); } /* The rest is equal to both errors. */ IOCReply.SCSIIOError.u8TargetID = pGuestReq->SCSIIO.u8TargetID; IOCReply.SCSIIOError.u8Bus = pGuestReq->SCSIIO.u8Bus; IOCReply.SCSIIOError.u8MessageLength = sizeof(MptSCSIIOErrorReply) / 4; IOCReply.SCSIIOError.u8Function = pGuestReq->SCSIIO.u8Function; IOCReply.SCSIIOError.u8CDBLength = pGuestReq->SCSIIO.u8CDBLength; IOCReply.SCSIIOError.u8SenseBufferLength = pGuestReq->SCSIIO.u8SenseBufferLength; IOCReply.SCSIIOError.u8Reserved = 0; IOCReply.SCSIIOError.u8MessageFlags = 0; IOCReply.SCSIIOError.u32MessageContext = pGuestReq->SCSIIO.u32MessageContext; IOCReply.SCSIIOError.u8SCSIStatus = SCSI_STATUS_OK; IOCReply.SCSIIOError.u8SCSIState = MPT_SCSI_IO_ERROR_SCSI_STATE_TERMINATED; IOCReply.SCSIIOError.u32IOCLogInfo = 0; IOCReply.SCSIIOError.u32TransferCount = 0; IOCReply.SCSIIOError.u32SenseCount = 0; IOCReply.SCSIIOError.u32ResponseInfo = 0; lsilogicFinishAddressReply(pDevIns, pThis, &IOCReply, false); return rc; } /** * @interface_method_impl{PDMIMEDIAPORT,pfnQueryDeviceLocation} */ static DECLCALLBACK(int) lsilogicR3QueryDeviceLocation(PPDMIMEDIAPORT pInterface, const char **ppcszController, uint32_t *piInstance, uint32_t *piLUN) { PLSILOGICDEVICE pTgtDev = RT_FROM_MEMBER(pInterface, LSILOGICDEVICE, IMediaPort); PPDMDEVINS pDevIns = pTgtDev->pDevIns; AssertPtrReturn(ppcszController, VERR_INVALID_POINTER); AssertPtrReturn(piInstance, VERR_INVALID_POINTER); AssertPtrReturn(piLUN, VERR_INVALID_POINTER); *ppcszController = pDevIns->pReg->szName; *piInstance = pDevIns->iInstance; *piLUN = pTgtDev->iLUN; return VINF_SUCCESS; } /** * @interface_method_impl{PDMIMEDIAEXPORT,pfnIoReqCopyFromBuf} */ static DECLCALLBACK(int) lsilogicR3IoReqCopyFromBuf(PPDMIMEDIAEXPORT pInterface, PDMMEDIAEXIOREQ hIoReq, void *pvIoReqAlloc, uint32_t offDst, PRTSGBUF pSgBuf, size_t cbCopy) { RT_NOREF1(hIoReq); PLSILOGICDEVICE pTgtDev = RT_FROM_MEMBER(pInterface, LSILOGICDEVICE, IMediaExPort); PPDMDEVINS pDevIns = pTgtDev->pDevIns; PLSILOGICREQ pReq = (PLSILOGICREQ)pvIoReqAlloc; size_t cbCopied = lsilogicR3CopySgBufToGuest(pDevIns, pReq, pSgBuf, offDst, cbCopy); return cbCopied == cbCopy ? VINF_SUCCESS : VERR_PDM_MEDIAEX_IOBUF_OVERFLOW; } /** * @interface_method_impl{PDMIMEDIAEXPORT,pfnIoReqCopyToBuf} */ static DECLCALLBACK(int) lsilogicR3IoReqCopyToBuf(PPDMIMEDIAEXPORT pInterface, PDMMEDIAEXIOREQ hIoReq, void *pvIoReqAlloc, uint32_t offSrc, PRTSGBUF pSgBuf, size_t cbCopy) { RT_NOREF1(hIoReq); PLSILOGICDEVICE pTgtDev = RT_FROM_MEMBER(pInterface, LSILOGICDEVICE, IMediaExPort); PPDMDEVINS pDevIns = pTgtDev->pDevIns; PLSILOGICREQ pReq = (PLSILOGICREQ)pvIoReqAlloc; size_t cbCopied = lsilogicR3CopySgBufFromGuest(pDevIns, pReq, pSgBuf, offSrc, cbCopy); return cbCopied == cbCopy ? VINF_SUCCESS : VERR_PDM_MEDIAEX_IOBUF_UNDERRUN; } /** * @interface_method_impl{PDMIMEDIAEXPORT,pfnIoReqCompleteNotify} */ static DECLCALLBACK(int) lsilogicR3IoReqCompleteNotify(PPDMIMEDIAEXPORT pInterface, PDMMEDIAEXIOREQ hIoReq, void *pvIoReqAlloc, int rcReq) { RT_NOREF(hIoReq); PLSILOGICDEVICE pTgtDev = RT_FROM_MEMBER(pInterface, LSILOGICDEVICE, IMediaExPort); PPDMDEVINS pDevIns = pTgtDev->pDevIns; PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); lsilogicR3ReqComplete(pDevIns, pThis, (PLSILOGICREQ)pvIoReqAlloc, rcReq); return VINF_SUCCESS; } /** * @interface_method_impl{PDMIMEDIAEXPORT,pfnIoReqStateChanged} */ static DECLCALLBACK(void) lsilogicR3IoReqStateChanged(PPDMIMEDIAEXPORT pInterface, PDMMEDIAEXIOREQ hIoReq, void *pvIoReqAlloc, PDMMEDIAEXIOREQSTATE enmState) { RT_NOREF3(hIoReq, pvIoReqAlloc, enmState); PLSILOGICDEVICE pTgtDev = RT_FROM_MEMBER(pInterface, LSILOGICDEVICE, IMediaExPort); switch (enmState) { case PDMMEDIAEXIOREQSTATE_SUSPENDED: { /* Make sure the request is not accounted for so the VM can suspend successfully. */ PPDMDEVINS pDevIns = pTgtDev->pDevIns; PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); uint32_t cTasksActive = ASMAtomicDecU32(&pTgtDev->cOutstandingRequests); if (!cTasksActive && pThis->fSignalIdle) PDMDevHlpAsyncNotificationCompleted(pDevIns); break; } case PDMMEDIAEXIOREQSTATE_ACTIVE: /* Make sure the request is accounted for so the VM suspends only when the request is complete. */ ASMAtomicIncU32(&pTgtDev->cOutstandingRequests); break; default: AssertMsgFailed(("Invalid request state given %u\n", enmState)); } } /** * @interface_method_impl{PDMIMEDIAEXPORT,pfnMediumEjected} */ static DECLCALLBACK(void) lsilogicR3MediumEjected(PPDMIMEDIAEXPORT pInterface) { PLSILOGICDEVICE pTgtDev = RT_FROM_MEMBER(pInterface, LSILOGICDEVICE, IMediaExPort); PPDMDEVINS pDevIns = pTgtDev->pDevIns; PLSILOGICSCSICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC); if (pThisCC->pMediaNotify) { int rc = PDMDevHlpVMReqCallNoWait(pDevIns, VMCPUID_ANY, (PFNRT)pThisCC->pMediaNotify->pfnEjected, 2, pThisCC->pMediaNotify, pTgtDev->iLUN); AssertRC(rc); } } /** * Return the configuration page header and data * which matches the given page type and number. * * @returns VINF_SUCCESS if successful * VERR_NOT_FOUND if the requested page could be found. * @param pThis Pointer to the shared LsiLogic device state. data. * @param pPages The pages supported by the controller. * @param u8PageNumber Number of the page to get. * @param ppPageHeader Where to store the pointer to the page header. * @param ppbPageData Where to store the pointer to the page data. * @param pcbPage Where to store the size of the page data in bytes on success. */ static int lsilogicR3ConfigurationIOUnitPageGetFromNumber(PLSILOGICSCSI pThis, PMptConfigurationPagesSupported pPages, uint8_t u8PageNumber, PMptConfigurationPageHeader *ppPageHeader, uint8_t **ppbPageData, size_t *pcbPage) { RT_NOREF(pThis); int rc = VINF_SUCCESS; AssertPtr(ppPageHeader); Assert(ppbPageData); switch (u8PageNumber) { case 0: *ppPageHeader = &pPages->IOUnitPage0.u.fields.Header; *ppbPageData = pPages->IOUnitPage0.u.abPageData; *pcbPage = sizeof(pPages->IOUnitPage0); break; case 1: *ppPageHeader = &pPages->IOUnitPage1.u.fields.Header; *ppbPageData = pPages->IOUnitPage1.u.abPageData; *pcbPage = sizeof(pPages->IOUnitPage1); break; case 2: *ppPageHeader = &pPages->IOUnitPage2.u.fields.Header; *ppbPageData = pPages->IOUnitPage2.u.abPageData; *pcbPage = sizeof(pPages->IOUnitPage2); break; case 3: *ppPageHeader = &pPages->IOUnitPage3.u.fields.Header; *ppbPageData = pPages->IOUnitPage3.u.abPageData; *pcbPage = sizeof(pPages->IOUnitPage3); break; case 4: *ppPageHeader = &pPages->IOUnitPage4.u.fields.Header; *ppbPageData = pPages->IOUnitPage4.u.abPageData; *pcbPage = sizeof(pPages->IOUnitPage4); break; default: rc = VERR_NOT_FOUND; } return rc; } /** * Return the configuration page header and data * which matches the given page type and number. * * @returns VINF_SUCCESS if successful * VERR_NOT_FOUND if the requested page could be found. * @param pThis Pointer to the shared LsiLogic device state. data. * @param pPages The pages supported by the controller. * @param u8PageNumber Number of the page to get. * @param ppPageHeader Where to store the pointer to the page header. * @param ppbPageData Where to store the pointer to the page data. * @param pcbPage Where to store the size of the page data in bytes on success. */ static int lsilogicR3ConfigurationIOCPageGetFromNumber(PLSILOGICSCSI pThis, PMptConfigurationPagesSupported pPages, uint8_t u8PageNumber, PMptConfigurationPageHeader *ppPageHeader, uint8_t **ppbPageData, size_t *pcbPage) { RT_NOREF(pThis); int rc = VINF_SUCCESS; AssertPtr(ppPageHeader); Assert(ppbPageData); switch (u8PageNumber) { case 0: *ppPageHeader = &pPages->IOCPage0.u.fields.Header; *ppbPageData = pPages->IOCPage0.u.abPageData; *pcbPage = sizeof(pPages->IOCPage0); break; case 1: *ppPageHeader = &pPages->IOCPage1.u.fields.Header; *ppbPageData = pPages->IOCPage1.u.abPageData; *pcbPage = sizeof(pPages->IOCPage1); break; case 2: *ppPageHeader = &pPages->IOCPage2.u.fields.Header; *ppbPageData = pPages->IOCPage2.u.abPageData; *pcbPage = sizeof(pPages->IOCPage2); break; case 3: *ppPageHeader = &pPages->IOCPage3.u.fields.Header; *ppbPageData = pPages->IOCPage3.u.abPageData; *pcbPage = sizeof(pPages->IOCPage3); break; case 4: *ppPageHeader = &pPages->IOCPage4.u.fields.Header; *ppbPageData = pPages->IOCPage4.u.abPageData; *pcbPage = sizeof(pPages->IOCPage4); break; case 6: *ppPageHeader = &pPages->IOCPage6.u.fields.Header; *ppbPageData = pPages->IOCPage6.u.abPageData; *pcbPage = sizeof(pPages->IOCPage6); break; default: rc = VERR_NOT_FOUND; } return rc; } /** * Return the configuration page header and data * which matches the given page type and number. * * @returns VINF_SUCCESS if successful * VERR_NOT_FOUND if the requested page could be found. * @param pThis Pointer to the shared LsiLogic device state. data. * @param pPages The pages supported by the controller. * @param u8PageNumber Number of the page to get. * @param ppPageHeader Where to store the pointer to the page header. * @param ppbPageData Where to store the pointer to the page data. * @param pcbPage Where to store the size of the page data in bytes on success. */ static int lsilogicR3ConfigurationManufacturingPageGetFromNumber(PLSILOGICSCSI pThis, PMptConfigurationPagesSupported pPages, uint8_t u8PageNumber, PMptConfigurationPageHeader *ppPageHeader, uint8_t **ppbPageData, size_t *pcbPage) { int rc = VINF_SUCCESS; AssertPtr(ppPageHeader); Assert(ppbPageData); switch (u8PageNumber) { case 0: *ppPageHeader = &pPages->ManufacturingPage0.u.fields.Header; *ppbPageData = pPages->ManufacturingPage0.u.abPageData; *pcbPage = sizeof(pPages->ManufacturingPage0); break; case 1: *ppPageHeader = &pPages->ManufacturingPage1.u.fields.Header; *ppbPageData = pPages->ManufacturingPage1.u.abPageData; *pcbPage = sizeof(pPages->ManufacturingPage1); break; case 2: *ppPageHeader = &pPages->ManufacturingPage2.u.fields.Header; *ppbPageData = pPages->ManufacturingPage2.u.abPageData; *pcbPage = sizeof(pPages->ManufacturingPage2); break; case 3: *ppPageHeader = &pPages->ManufacturingPage3.u.fields.Header; *ppbPageData = pPages->ManufacturingPage3.u.abPageData; *pcbPage = sizeof(pPages->ManufacturingPage3); break; case 4: *ppPageHeader = &pPages->ManufacturingPage4.u.fields.Header; *ppbPageData = pPages->ManufacturingPage4.u.abPageData; *pcbPage = sizeof(pPages->ManufacturingPage4); break; case 5: *ppPageHeader = &pPages->ManufacturingPage5.u.fields.Header; *ppbPageData = pPages->ManufacturingPage5.u.abPageData; *pcbPage = sizeof(pPages->ManufacturingPage5); break; case 6: *ppPageHeader = &pPages->ManufacturingPage6.u.fields.Header; *ppbPageData = pPages->ManufacturingPage6.u.abPageData; *pcbPage = sizeof(pPages->ManufacturingPage6); break; case 7: if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) { *ppPageHeader = &pPages->u.SasPages.pManufacturingPage7->u.fields.Header; *ppbPageData = pPages->u.SasPages.pManufacturingPage7->u.abPageData; *pcbPage = pPages->u.SasPages.cbManufacturingPage7; } else rc = VERR_NOT_FOUND; break; case 8: *ppPageHeader = &pPages->ManufacturingPage8.u.fields.Header; *ppbPageData = pPages->ManufacturingPage8.u.abPageData; *pcbPage = sizeof(pPages->ManufacturingPage8); break; case 9: *ppPageHeader = &pPages->ManufacturingPage9.u.fields.Header; *ppbPageData = pPages->ManufacturingPage9.u.abPageData; *pcbPage = sizeof(pPages->ManufacturingPage9); break; case 10: *ppPageHeader = &pPages->ManufacturingPage10.u.fields.Header; *ppbPageData = pPages->ManufacturingPage10.u.abPageData; *pcbPage = sizeof(pPages->ManufacturingPage10); break; default: rc = VERR_NOT_FOUND; } return rc; } /** * Return the configuration page header and data * which matches the given page type and number. * * @returns VINF_SUCCESS if successful * VERR_NOT_FOUND if the requested page could be found. * @param pThis Pointer to the shared LsiLogic device state. data. * @param pPages The pages supported by the controller. * @param u8PageNumber Number of the page to get. * @param ppPageHeader Where to store the pointer to the page header. * @param ppbPageData Where to store the pointer to the page data. * @param pcbPage Where to store the size of the page data in bytes on success. */ static int lsilogicR3ConfigurationBiosPageGetFromNumber(PLSILOGICSCSI pThis, PMptConfigurationPagesSupported pPages, uint8_t u8PageNumber, PMptConfigurationPageHeader *ppPageHeader, uint8_t **ppbPageData, size_t *pcbPage) { RT_NOREF(pThis); int rc = VINF_SUCCESS; AssertPtr(ppPageHeader); Assert(ppbPageData); switch (u8PageNumber) { case 1: *ppPageHeader = &pPages->BIOSPage1.u.fields.Header; *ppbPageData = pPages->BIOSPage1.u.abPageData; *pcbPage = sizeof(pPages->BIOSPage1); break; case 2: *ppPageHeader = &pPages->BIOSPage2.u.fields.Header; *ppbPageData = pPages->BIOSPage2.u.abPageData; *pcbPage = sizeof(pPages->BIOSPage2); break; case 4: *ppPageHeader = &pPages->BIOSPage4.u.fields.Header; *ppbPageData = pPages->BIOSPage4.u.abPageData; *pcbPage = sizeof(pPages->BIOSPage4); break; default: rc = VERR_NOT_FOUND; } return rc; } /** * Return the configuration page header and data * which matches the given page type and number. * * @returns VINF_SUCCESS if successful * VERR_NOT_FOUND if the requested page could be found. * @param pThis Pointer to the shared LsiLogic device state. data. * @param pPages The pages supported by the controller. * @param u8Port The port to retrieve the page for. * @param u8PageNumber Number of the page to get. * @param ppPageHeader Where to store the pointer to the page header. * @param ppbPageData Where to store the pointer to the page data. * @param pcbPage Where to store the size of the page data in bytes on success. */ static int lsilogicR3ConfigurationSCSISPIPortPageGetFromNumber(PLSILOGICSCSI pThis, PMptConfigurationPagesSupported pPages, uint8_t u8Port, uint8_t u8PageNumber, PMptConfigurationPageHeader *ppPageHeader, uint8_t **ppbPageData, size_t *pcbPage) { RT_NOREF(pThis); int rc = VINF_SUCCESS; AssertPtr(ppPageHeader); Assert(ppbPageData); if (u8Port >= RT_ELEMENTS(pPages->u.SpiPages.aPortPages)) return VERR_NOT_FOUND; switch (u8PageNumber) { case 0: *ppPageHeader = &pPages->u.SpiPages.aPortPages[u8Port].SCSISPIPortPage0.u.fields.Header; *ppbPageData = pPages->u.SpiPages.aPortPages[u8Port].SCSISPIPortPage0.u.abPageData; *pcbPage = sizeof(pPages->u.SpiPages.aPortPages[u8Port].SCSISPIPortPage0); break; case 1: *ppPageHeader = &pPages->u.SpiPages.aPortPages[u8Port].SCSISPIPortPage1.u.fields.Header; *ppbPageData = pPages->u.SpiPages.aPortPages[u8Port].SCSISPIPortPage1.u.abPageData; *pcbPage = sizeof(pPages->u.SpiPages.aPortPages[u8Port].SCSISPIPortPage1); break; case 2: *ppPageHeader = &pPages->u.SpiPages.aPortPages[u8Port].SCSISPIPortPage2.u.fields.Header; *ppbPageData = pPages->u.SpiPages.aPortPages[u8Port].SCSISPIPortPage2.u.abPageData; *pcbPage = sizeof(pPages->u.SpiPages.aPortPages[u8Port].SCSISPIPortPage2); break; default: rc = VERR_NOT_FOUND; } return rc; } /** * Return the configuration page header and data * which matches the given page type and number. * * @returns VINF_SUCCESS if successful * VERR_NOT_FOUND if the requested page could be found. * @param pThis Pointer to the shared LsiLogic device state. data. * @param pPages The pages supported by the controller. * @param u8Bus The bus the device is on the page should be returned. * @param u8TargetID The target ID of the device to return the page for. * @param u8PageNumber Number of the page to get. * @param ppPageHeader Where to store the pointer to the page header. * @param ppbPageData Where to store the pointer to the page data. * @param pcbPage Where to store the size of the page data in bytes on success. */ static int lsilogicR3ConfigurationSCSISPIDevicePageGetFromNumber(PLSILOGICSCSI pThis, PMptConfigurationPagesSupported pPages, uint8_t u8Bus, uint8_t u8TargetID, uint8_t u8PageNumber, PMptConfigurationPageHeader *ppPageHeader, uint8_t **ppbPageData, size_t *pcbPage) { RT_NOREF(pThis); int rc = VINF_SUCCESS; AssertPtr(ppPageHeader); Assert(ppbPageData); if (u8Bus >= RT_ELEMENTS(pPages->u.SpiPages.aBuses)) return VERR_NOT_FOUND; if (u8TargetID >= RT_ELEMENTS(pPages->u.SpiPages.aBuses[u8Bus].aDevicePages)) return VERR_NOT_FOUND; switch (u8PageNumber) { case 0: *ppPageHeader = &pPages->u.SpiPages.aBuses[u8Bus].aDevicePages[u8TargetID].SCSISPIDevicePage0.u.fields.Header; *ppbPageData = pPages->u.SpiPages.aBuses[u8Bus].aDevicePages[u8TargetID].SCSISPIDevicePage0.u.abPageData; *pcbPage = sizeof(pPages->u.SpiPages.aBuses[u8Bus].aDevicePages[u8TargetID].SCSISPIDevicePage0); break; case 1: *ppPageHeader = &pPages->u.SpiPages.aBuses[u8Bus].aDevicePages[u8TargetID].SCSISPIDevicePage1.u.fields.Header; *ppbPageData = pPages->u.SpiPages.aBuses[u8Bus].aDevicePages[u8TargetID].SCSISPIDevicePage1.u.abPageData; *pcbPage = sizeof(pPages->u.SpiPages.aBuses[u8Bus].aDevicePages[u8TargetID].SCSISPIDevicePage1); break; case 2: *ppPageHeader = &pPages->u.SpiPages.aBuses[u8Bus].aDevicePages[u8TargetID].SCSISPIDevicePage2.u.fields.Header; *ppbPageData = pPages->u.SpiPages.aBuses[u8Bus].aDevicePages[u8TargetID].SCSISPIDevicePage2.u.abPageData; *pcbPage = sizeof(pPages->u.SpiPages.aBuses[u8Bus].aDevicePages[u8TargetID].SCSISPIDevicePage2); break; case 3: *ppPageHeader = &pPages->u.SpiPages.aBuses[u8Bus].aDevicePages[u8TargetID].SCSISPIDevicePage3.u.fields.Header; *ppbPageData = pPages->u.SpiPages.aBuses[u8Bus].aDevicePages[u8TargetID].SCSISPIDevicePage3.u.abPageData; *pcbPage = sizeof(pPages->u.SpiPages.aBuses[u8Bus].aDevicePages[u8TargetID].SCSISPIDevicePage3); break; default: rc = VERR_NOT_FOUND; } return rc; } static int lsilogicR3ConfigurationSASIOUnitPageGetFromNumber(PMptConfigurationPagesSupported pPages, uint8_t u8PageNumber, PMptExtendedConfigurationPageHeader *ppPageHeader, uint8_t **ppbPageData, size_t *pcbPage) { int rc = VINF_SUCCESS; switch (u8PageNumber) { case 0: *ppPageHeader = &pPages->u.SasPages.pSASIOUnitPage0->u.fields.ExtHeader; *ppbPageData = pPages->u.SasPages.pSASIOUnitPage0->u.abPageData; *pcbPage = pPages->u.SasPages.cbSASIOUnitPage0; break; case 1: *ppPageHeader = &pPages->u.SasPages.pSASIOUnitPage1->u.fields.ExtHeader; *ppbPageData = pPages->u.SasPages.pSASIOUnitPage1->u.abPageData; *pcbPage = pPages->u.SasPages.cbSASIOUnitPage1; break; case 2: *ppPageHeader = &pPages->u.SasPages.SASIOUnitPage2.u.fields.ExtHeader; *ppbPageData = pPages->u.SasPages.SASIOUnitPage2.u.abPageData; *pcbPage = sizeof(pPages->u.SasPages.SASIOUnitPage2); break; case 3: *ppPageHeader = &pPages->u.SasPages.SASIOUnitPage3.u.fields.ExtHeader; *ppbPageData = pPages->u.SasPages.SASIOUnitPage3.u.abPageData; *pcbPage = sizeof(pPages->u.SasPages.SASIOUnitPage3); break; default: rc = VERR_NOT_FOUND; } return rc; } static int lsilogicR3ConfigurationSASPHYPageGetFromNumber(PMptConfigurationPagesSupported pPages, uint8_t u8PageNumber, MptConfigurationPageAddress PageAddress, PMptExtendedConfigurationPageHeader *ppPageHeader, uint8_t **ppbPageData, size_t *pcbPage) { int rc = VINF_SUCCESS; uint8_t uAddressForm = MPT_CONFIGURATION_PAGE_ADDRESS_GET_SAS_FORM(PageAddress); PMptConfigurationPagesSas pPagesSas = &pPages->u.SasPages; PMptPHY pPHYPages = NULL; Log(("Address form %d\n", uAddressForm)); if (uAddressForm == 0) /* PHY number */ { uint8_t u8PhyNumber = PageAddress.SASPHY.Form0.u8PhyNumber; Log(("PHY number %d\n", u8PhyNumber)); if (u8PhyNumber >= pPagesSas->cPHYs) return VERR_NOT_FOUND; pPHYPages = &pPagesSas->paPHYs[u8PhyNumber]; } else if (uAddressForm == 1) /* Index form */ { uint16_t u16Index = PageAddress.SASPHY.Form1.u16Index; Log(("PHY index %d\n", u16Index)); if (u16Index >= pPagesSas->cPHYs) return VERR_NOT_FOUND; pPHYPages = &pPagesSas->paPHYs[u16Index]; } else rc = VERR_NOT_FOUND; /* Correct? */ if (pPHYPages) { switch (u8PageNumber) { case 0: *ppPageHeader = &pPHYPages->SASPHYPage0.u.fields.ExtHeader; *ppbPageData = pPHYPages->SASPHYPage0.u.abPageData; *pcbPage = sizeof(pPHYPages->SASPHYPage0); break; case 1: *ppPageHeader = &pPHYPages->SASPHYPage1.u.fields.ExtHeader; *ppbPageData = pPHYPages->SASPHYPage1.u.abPageData; *pcbPage = sizeof(pPHYPages->SASPHYPage1); break; default: rc = VERR_NOT_FOUND; } } else rc = VERR_NOT_FOUND; return rc; } static int lsilogicR3ConfigurationSASDevicePageGetFromNumber(PMptConfigurationPagesSupported pPages, uint8_t u8PageNumber, MptConfigurationPageAddress PageAddress, PMptExtendedConfigurationPageHeader *ppPageHeader, uint8_t **ppbPageData, size_t *pcbPage) { int rc = VINF_SUCCESS; uint8_t uAddressForm = MPT_CONFIGURATION_PAGE_ADDRESS_GET_SAS_FORM(PageAddress); PMptConfigurationPagesSas pPagesSas = &pPages->u.SasPages; PMptSASDevice pSASDevice = NULL; Log(("Address form %d\n", uAddressForm)); if (uAddressForm == 0) { uint16_t u16Handle = PageAddress.SASDevice.Form0And2.u16Handle; Log(("Get next handle %#x\n", u16Handle)); pSASDevice = pPagesSas->pSASDeviceHead; /* Get the first device? */ if (u16Handle != 0xffff) { /* No, search for the right one. */ while ( pSASDevice && pSASDevice->SASDevicePage0.u.fields.u16DevHandle != u16Handle) pSASDevice = pSASDevice->pNext; if (pSASDevice) pSASDevice = pSASDevice->pNext; } } else if (uAddressForm == 1) { uint8_t u8TargetID = PageAddress.SASDevice.Form1.u8TargetID; uint8_t u8Bus = PageAddress.SASDevice.Form1.u8Bus; Log(("u8TargetID=%d u8Bus=%d\n", u8TargetID, u8Bus)); pSASDevice = pPagesSas->pSASDeviceHead; while ( pSASDevice && ( pSASDevice->SASDevicePage0.u.fields.u8TargetID != u8TargetID || pSASDevice->SASDevicePage0.u.fields.u8Bus != u8Bus)) pSASDevice = pSASDevice->pNext; } else if (uAddressForm == 2) { uint16_t u16Handle = PageAddress.SASDevice.Form0And2.u16Handle; Log(("Handle %#x\n", u16Handle)); pSASDevice = pPagesSas->pSASDeviceHead; while ( pSASDevice && pSASDevice->SASDevicePage0.u.fields.u16DevHandle != u16Handle) pSASDevice = pSASDevice->pNext; } if (pSASDevice) { switch (u8PageNumber) { case 0: *ppPageHeader = &pSASDevice->SASDevicePage0.u.fields.ExtHeader; *ppbPageData = pSASDevice->SASDevicePage0.u.abPageData; *pcbPage = sizeof(pSASDevice->SASDevicePage0); break; case 1: *ppPageHeader = &pSASDevice->SASDevicePage1.u.fields.ExtHeader; *ppbPageData = pSASDevice->SASDevicePage1.u.abPageData; *pcbPage = sizeof(pSASDevice->SASDevicePage1); break; case 2: *ppPageHeader = &pSASDevice->SASDevicePage2.u.fields.ExtHeader; *ppbPageData = pSASDevice->SASDevicePage2.u.abPageData; *pcbPage = sizeof(pSASDevice->SASDevicePage2); break; default: rc = VERR_NOT_FOUND; } } else rc = VERR_NOT_FOUND; return rc; } /** * Returns the extended configuration page header and data. * @returns VINF_SUCCESS if successful * VERR_NOT_FOUND if the requested page could be found. * @param pThisCC Pointer to the ring-3 LsiLogic device state. * @param pConfigurationReq The configuration request. * @param ppPageHeader Where to return the pointer to the page header on success. * @param ppbPageData Where to store the pointer to the page data. * @param pcbPage Where to store the size of the page in bytes. */ static int lsilogicR3ConfigurationPageGetExtended(PLSILOGICSCSICC pThisCC, PMptConfigurationRequest pConfigurationReq, PMptExtendedConfigurationPageHeader *ppPageHeader, uint8_t **ppbPageData, size_t *pcbPage) { int rc = VINF_SUCCESS; Log(("Extended page requested:\n")); Log(("u8ExtPageType=%#x\n", pConfigurationReq->u8ExtPageType)); Log(("u8ExtPageLength=%d\n", pConfigurationReq->u16ExtPageLength)); switch (pConfigurationReq->u8ExtPageType) { case MPT_CONFIGURATION_PAGE_TYPE_EXTENDED_SASIOUNIT: { rc = lsilogicR3ConfigurationSASIOUnitPageGetFromNumber(pThisCC->pConfigurationPages, pConfigurationReq->u8PageNumber, ppPageHeader, ppbPageData, pcbPage); break; } case MPT_CONFIGURATION_PAGE_TYPE_EXTENDED_SASPHYS: { rc = lsilogicR3ConfigurationSASPHYPageGetFromNumber(pThisCC->pConfigurationPages, pConfigurationReq->u8PageNumber, pConfigurationReq->PageAddress, ppPageHeader, ppbPageData, pcbPage); break; } case MPT_CONFIGURATION_PAGE_TYPE_EXTENDED_SASDEVICE: { rc = lsilogicR3ConfigurationSASDevicePageGetFromNumber(pThisCC->pConfigurationPages, pConfigurationReq->u8PageNumber, pConfigurationReq->PageAddress, ppPageHeader, ppbPageData, pcbPage); break; } case MPT_CONFIGURATION_PAGE_TYPE_EXTENDED_SASEXPANDER: /* No expanders supported */ case MPT_CONFIGURATION_PAGE_TYPE_EXTENDED_ENCLOSURE: /* No enclosures supported */ default: rc = VERR_NOT_FOUND; } return rc; } /** * Processes a Configuration request. * * @returns VBox status code. * @param pDevIns The device instance. * @param pThis Pointer to the shared LsiLogic device state. * @param pThisCC Pointer to the ring-3 LsiLogic device state. * @param pConfigurationReq Pointer to the request structure. * @param pReply Pointer to the reply message frame */ static int lsilogicR3ProcessConfigurationRequest(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis, PLSILOGICSCSICC pThisCC, PMptConfigurationRequest pConfigurationReq, PMptConfigurationReply pReply) { int rc = VINF_SUCCESS; uint8_t *pbPageData = NULL; PMptConfigurationPageHeader pPageHeader = NULL; PMptExtendedConfigurationPageHeader pExtPageHeader = NULL; uint8_t u8PageType; uint8_t u8PageAttribute; size_t cbPage = 0; LogFlowFunc(("pThis=%#p\n", pThis)); u8PageType = MPT_CONFIGURATION_PAGE_TYPE_GET(pConfigurationReq->u8PageType); u8PageAttribute = MPT_CONFIGURATION_PAGE_ATTRIBUTE_GET(pConfigurationReq->u8PageType); Log(("GuestRequest:\n")); Log(("u8Action=%#x\n", pConfigurationReq->u8Action)); Log(("u8PageType=%#x\n", u8PageType)); Log(("u8PageNumber=%d\n", pConfigurationReq->u8PageNumber)); Log(("u8PageLength=%d\n", pConfigurationReq->u8PageLength)); Log(("u8PageVersion=%d\n", pConfigurationReq->u8PageVersion)); /* Copy common bits from the request into the reply. */ pReply->u8MessageLength = 6; /* 6 32bit D-Words. */ pReply->u8Action = pConfigurationReq->u8Action; pReply->u8Function = pConfigurationReq->u8Function; pReply->u32MessageContext = pConfigurationReq->u32MessageContext; switch (u8PageType) { case MPT_CONFIGURATION_PAGE_TYPE_IO_UNIT: { /* Get the page data. */ rc = lsilogicR3ConfigurationIOUnitPageGetFromNumber(pThis, pThisCC->pConfigurationPages, pConfigurationReq->u8PageNumber, &pPageHeader, &pbPageData, &cbPage); break; } case MPT_CONFIGURATION_PAGE_TYPE_IOC: { /* Get the page data. */ rc = lsilogicR3ConfigurationIOCPageGetFromNumber(pThis, pThisCC->pConfigurationPages, pConfigurationReq->u8PageNumber, &pPageHeader, &pbPageData, &cbPage); break; } case MPT_CONFIGURATION_PAGE_TYPE_MANUFACTURING: { /* Get the page data. */ rc = lsilogicR3ConfigurationManufacturingPageGetFromNumber(pThis, pThisCC->pConfigurationPages, pConfigurationReq->u8PageNumber, &pPageHeader, &pbPageData, &cbPage); break; } case MPT_CONFIGURATION_PAGE_TYPE_SCSI_SPI_PORT: { /* Get the page data. */ rc = lsilogicR3ConfigurationSCSISPIPortPageGetFromNumber(pThis, pThisCC->pConfigurationPages, pConfigurationReq->PageAddress.MPIPortNumber.u8PortNumber, pConfigurationReq->u8PageNumber, &pPageHeader, &pbPageData, &cbPage); break; } case MPT_CONFIGURATION_PAGE_TYPE_SCSI_SPI_DEVICE: { /* Get the page data. */ rc = lsilogicR3ConfigurationSCSISPIDevicePageGetFromNumber(pThis, pThisCC->pConfigurationPages, pConfigurationReq->PageAddress.BusAndTargetId.u8Bus, pConfigurationReq->PageAddress.BusAndTargetId.u8TargetID, pConfigurationReq->u8PageNumber, &pPageHeader, &pbPageData, &cbPage); break; } case MPT_CONFIGURATION_PAGE_TYPE_BIOS: { rc = lsilogicR3ConfigurationBiosPageGetFromNumber(pThis, pThisCC->pConfigurationPages, pConfigurationReq->u8PageNumber, &pPageHeader, &pbPageData, &cbPage); break; } case MPT_CONFIGURATION_PAGE_TYPE_EXTENDED: { if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) { rc = lsilogicR3ConfigurationPageGetExtended(pThisCC, pConfigurationReq, &pExtPageHeader, &pbPageData, &cbPage); } else rc = VERR_NOT_FOUND; break; } default: rc = VERR_NOT_FOUND; } if (rc == VERR_NOT_FOUND) { Log(("Page not found\n")); pReply->u8PageType = pConfigurationReq->u8PageType; pReply->u8PageNumber = pConfigurationReq->u8PageNumber; pReply->u8PageLength = pConfigurationReq->u8PageLength; pReply->u8PageVersion = pConfigurationReq->u8PageVersion; pReply->u16IOCStatus = MPT_IOCSTATUS_CONFIG_INVALID_PAGE; return VINF_SUCCESS; } if (u8PageType == MPT_CONFIGURATION_PAGE_TYPE_EXTENDED) { pReply->u8PageType = pExtPageHeader->u8PageType; pReply->u8PageNumber = pExtPageHeader->u8PageNumber; pReply->u8PageVersion = pExtPageHeader->u8PageVersion; pReply->u8ExtPageType = pExtPageHeader->u8ExtPageType; pReply->u16ExtPageLength = pExtPageHeader->u16ExtPageLength; for (int i = 0; i < pExtPageHeader->u16ExtPageLength; i++) LogFlowFunc(("PageData[%d]=%#x\n", i, ((uint32_t *)pbPageData)[i])); } else { pReply->u8PageType = pPageHeader->u8PageType; pReply->u8PageNumber = pPageHeader->u8PageNumber; pReply->u8PageLength = pPageHeader->u8PageLength; pReply->u8PageVersion = pPageHeader->u8PageVersion; for (int i = 0; i < pReply->u8PageLength; i++) LogFlowFunc(("PageData[%d]=%#x\n", i, ((uint32_t *)pbPageData)[i])); } /* * Don't use the scatter gather handling code as the configuration request always have only one * simple element. */ switch (pConfigurationReq->u8Action) { case MPT_CONFIGURATION_REQUEST_ACTION_DEFAULT: /* Nothing to do. We are always using the defaults. */ case MPT_CONFIGURATION_REQUEST_ACTION_HEADER: { /* Already copied above nothing to do. */ break; } case MPT_CONFIGURATION_REQUEST_ACTION_READ_NVRAM: case MPT_CONFIGURATION_REQUEST_ACTION_READ_CURRENT: case MPT_CONFIGURATION_REQUEST_ACTION_READ_DEFAULT: { uint32_t cbBuffer = pConfigurationReq->SimpleSGElement.u24Length; if (cbBuffer != 0) { RTGCPHYS GCPhysAddrPageBuffer = pConfigurationReq->SimpleSGElement.u32DataBufferAddressLow; if (pConfigurationReq->SimpleSGElement.f64BitAddress) GCPhysAddrPageBuffer |= (uint64_t)pConfigurationReq->SimpleSGElement.u32DataBufferAddressHigh << 32; PDMDevHlpPCIPhysWriteMeta(pDevIns, GCPhysAddrPageBuffer, pbPageData, RT_MIN(cbBuffer, cbPage)); } break; } case MPT_CONFIGURATION_REQUEST_ACTION_WRITE_CURRENT: case MPT_CONFIGURATION_REQUEST_ACTION_WRITE_NVRAM: { uint32_t cbBuffer = pConfigurationReq->SimpleSGElement.u24Length; if (cbBuffer != 0) { RTGCPHYS GCPhysAddrPageBuffer = pConfigurationReq->SimpleSGElement.u32DataBufferAddressLow; if (pConfigurationReq->SimpleSGElement.f64BitAddress) GCPhysAddrPageBuffer |= (uint64_t)pConfigurationReq->SimpleSGElement.u32DataBufferAddressHigh << 32; LogFlow(("cbBuffer=%u cbPage=%u\n", cbBuffer, cbPage)); PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysAddrPageBuffer, pbPageData, RT_MIN(cbBuffer, cbPage)); } break; } default: AssertMsgFailed(("todo\n")); } return VINF_SUCCESS; } /** * Initializes the configuration pages for the SPI SCSI controller. * * @param pThis Pointer to the shared LsiLogic device state. * @param pThisCC Pointer to the ring-3 LsiLogic device state. */ static void lsilogicR3InitializeConfigurationPagesSpi(PLSILOGICSCSI pThis, PLSILOGICSCSICC pThisCC) { PMptConfigurationPagesSpi pPages = &pThisCC->pConfigurationPages->u.SpiPages; AssertMsg(pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI, ("Controller is not the SPI SCSI one\n")); LogFlowFunc(("pThis=%#p\n", pThis)); RT_NOREF(pThis); /* Clear everything first. */ memset(pPages, 0, sizeof(MptConfigurationPagesSpi)); for (unsigned i = 0; i < RT_ELEMENTS(pPages->aPortPages); i++) { /* SCSI-SPI port page 0. */ pPages->aPortPages[i].SCSISPIPortPage0.u.fields.Header.u8PageType = MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY | MPT_CONFIGURATION_PAGE_TYPE_SCSI_SPI_PORT; pPages->aPortPages[i].SCSISPIPortPage0.u.fields.Header.u8PageNumber = 0; pPages->aPortPages[i].SCSISPIPortPage0.u.fields.Header.u8PageLength = sizeof(MptConfigurationPageSCSISPIPort0) / 4; pPages->aPortPages[i].SCSISPIPortPage0.u.fields.fInformationUnitTransfersCapable = true; pPages->aPortPages[i].SCSISPIPortPage0.u.fields.fDTCapable = true; pPages->aPortPages[i].SCSISPIPortPage0.u.fields.fQASCapable = true; pPages->aPortPages[i].SCSISPIPortPage0.u.fields.u8MinimumSynchronousTransferPeriod = 0; pPages->aPortPages[i].SCSISPIPortPage0.u.fields.u8MaximumSynchronousOffset = 0xff; pPages->aPortPages[i].SCSISPIPortPage0.u.fields.fWide = true; pPages->aPortPages[i].SCSISPIPortPage0.u.fields.fAIPCapable = true; pPages->aPortPages[i].SCSISPIPortPage0.u.fields.u2SignalingType = 0x3; /* Single Ended. */ /* SCSI-SPI port page 1. */ pPages->aPortPages[i].SCSISPIPortPage1.u.fields.Header.u8PageType = MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE | MPT_CONFIGURATION_PAGE_TYPE_SCSI_SPI_PORT; pPages->aPortPages[i].SCSISPIPortPage1.u.fields.Header.u8PageNumber = 1; pPages->aPortPages[i].SCSISPIPortPage1.u.fields.Header.u8PageLength = sizeof(MptConfigurationPageSCSISPIPort1) / 4; pPages->aPortPages[i].SCSISPIPortPage1.u.fields.u8SCSIID = 7; pPages->aPortPages[i].SCSISPIPortPage1.u.fields.u16PortResponseIDsBitmask = (1 << 7); pPages->aPortPages[i].SCSISPIPortPage1.u.fields.u32OnBusTimerValue = 0; /* SCSI-SPI port page 2. */ pPages->aPortPages[i].SCSISPIPortPage2.u.fields.Header.u8PageType = MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE | MPT_CONFIGURATION_PAGE_TYPE_SCSI_SPI_PORT; pPages->aPortPages[i].SCSISPIPortPage2.u.fields.Header.u8PageNumber = 2; pPages->aPortPages[i].SCSISPIPortPage2.u.fields.Header.u8PageLength = sizeof(MptConfigurationPageSCSISPIPort2) / 4; pPages->aPortPages[i].SCSISPIPortPage2.u.fields.u4HostSCSIID = 7; pPages->aPortPages[i].SCSISPIPortPage2.u.fields.u2InitializeHBA = 0x3; pPages->aPortPages[i].SCSISPIPortPage2.u.fields.fTerminationDisabled = true; for (unsigned iDevice = 0; iDevice < RT_ELEMENTS(pPages->aPortPages[i].SCSISPIPortPage2.u.fields.aDeviceSettings); iDevice++) { pPages->aPortPages[i].SCSISPIPortPage2.u.fields.aDeviceSettings[iDevice].fBootChoice = true; } /* Everything else 0 for now. */ } for (unsigned uBusCurr = 0; uBusCurr < RT_ELEMENTS(pPages->aBuses); uBusCurr++) { for (unsigned uDeviceCurr = 0; uDeviceCurr < RT_ELEMENTS(pPages->aBuses[uBusCurr].aDevicePages); uDeviceCurr++) { /* SCSI-SPI device page 0. */ pPages->aBuses[uBusCurr].aDevicePages[uDeviceCurr].SCSISPIDevicePage0.u.fields.Header.u8PageType = MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY | MPT_CONFIGURATION_PAGE_TYPE_SCSI_SPI_DEVICE; pPages->aBuses[uBusCurr].aDevicePages[uDeviceCurr].SCSISPIDevicePage0.u.fields.Header.u8PageNumber = 0; pPages->aBuses[uBusCurr].aDevicePages[uDeviceCurr].SCSISPIDevicePage0.u.fields.Header.u8PageLength = sizeof(MptConfigurationPageSCSISPIDevice0) / 4; /* Everything else 0 for now. */ /* SCSI-SPI device page 1. */ pPages->aBuses[uBusCurr].aDevicePages[uDeviceCurr].SCSISPIDevicePage1.u.fields.Header.u8PageType = MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE | MPT_CONFIGURATION_PAGE_TYPE_SCSI_SPI_DEVICE; pPages->aBuses[uBusCurr].aDevicePages[uDeviceCurr].SCSISPIDevicePage1.u.fields.Header.u8PageNumber = 1; pPages->aBuses[uBusCurr].aDevicePages[uDeviceCurr].SCSISPIDevicePage1.u.fields.Header.u8PageLength = sizeof(MptConfigurationPageSCSISPIDevice1) / 4; /* Everything else 0 for now. */ /* SCSI-SPI device page 2. */ pPages->aBuses[uBusCurr].aDevicePages[uDeviceCurr].SCSISPIDevicePage2.u.fields.Header.u8PageType = MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE | MPT_CONFIGURATION_PAGE_TYPE_SCSI_SPI_DEVICE; pPages->aBuses[uBusCurr].aDevicePages[uDeviceCurr].SCSISPIDevicePage2.u.fields.Header.u8PageNumber = 2; pPages->aBuses[uBusCurr].aDevicePages[uDeviceCurr].SCSISPIDevicePage2.u.fields.Header.u8PageLength = sizeof(MptConfigurationPageSCSISPIDevice2) / 4; /* Everything else 0 for now. */ pPages->aBuses[uBusCurr].aDevicePages[uDeviceCurr].SCSISPIDevicePage3.u.fields.Header.u8PageType = MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY | MPT_CONFIGURATION_PAGE_TYPE_SCSI_SPI_DEVICE; pPages->aBuses[uBusCurr].aDevicePages[uDeviceCurr].SCSISPIDevicePage3.u.fields.Header.u8PageNumber = 3; pPages->aBuses[uBusCurr].aDevicePages[uDeviceCurr].SCSISPIDevicePage3.u.fields.Header.u8PageLength = sizeof(MptConfigurationPageSCSISPIDevice3) / 4; /* Everything else 0 for now. */ } } } /** * Generates a handle. * * @returns the handle. * @param pThis Pointer to the shared LsiLogic device state. */ DECLINLINE(uint16_t) lsilogicGetHandle(PLSILOGICSCSI pThis) { uint16_t u16Handle = pThis->u16NextHandle++; return u16Handle; } /** * Generates a SAS address (WWID) * * @param pSASAddress Pointer to an unitialised SAS address. * @param iId iId which will go into the address. * * @todo Generate better SAS addresses. (Request a block from SUN probably) */ DECLINLINE(void) lsilogicSASAddressGenerate(PSASADDRESS pSASAddress, unsigned iId) { pSASAddress->u8Address[0] = (0x5 << 5); pSASAddress->u8Address[1] = 0x01; pSASAddress->u8Address[2] = 0x02; pSASAddress->u8Address[3] = 0x03; pSASAddress->u8Address[4] = 0x04; pSASAddress->u8Address[5] = 0x05; pSASAddress->u8Address[6] = 0x06; pSASAddress->u8Address[7] = iId; } /** * Initializes the configuration pages for the SAS SCSI controller. * * @param pThis Pointer to the shared LsiLogic device state. * @param pThisCC Pointer to the ring-3 LsiLogic device state. */ static void lsilogicR3InitializeConfigurationPagesSas(PLSILOGICSCSI pThis, PLSILOGICSCSICC pThisCC) { PMptConfigurationPagesSas pPages = &pThisCC->pConfigurationPages->u.SasPages; AssertMsg(pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS, ("Controller is not the SAS SCSI one\n")); LogFlowFunc(("pThis=%#p\n", pThis)); /* Manufacturing Page 7 - Connector settings. */ PMptConfigurationPageManufacturing7 pManufacturingPage7 = pPages->pManufacturingPage7; AssertPtr(pManufacturingPage7); MPT_CONFIG_PAGE_HEADER_INIT_MANUFACTURING(pManufacturingPage7, 0, 7, MPT_CONFIGURATION_PAGE_ATTRIBUTE_PERSISTENT_READONLY); /* Set size manually. */ if (pPages->cbManufacturingPage7 / 4 > 255) pManufacturingPage7->u.fields.Header.u8PageLength = 255; else pManufacturingPage7->u.fields.Header.u8PageLength = pPages->cbManufacturingPage7 / 4; pManufacturingPage7->u.fields.u8NumPhys = pThis->cPorts; /* SAS I/O unit page 0 - Port specific information. */ PMptConfigurationPageSASIOUnit0 pSASPage0 = pPages->pSASIOUnitPage0; AssertPtr(pSASPage0); MPT_CONFIG_EXTENDED_PAGE_HEADER_INIT(pSASPage0, pPages->cbSASIOUnitPage0, 0, MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY, MPT_CONFIGURATION_PAGE_TYPE_EXTENDED_SASIOUNIT); pSASPage0->u.fields.u8NumPhys = pThis->cPorts; pPages->pSASIOUnitPage0 = pSASPage0; /* SAS I/O unit page 1 - Port specific settings. */ PMptConfigurationPageSASIOUnit1 pSASPage1 = pPages->pSASIOUnitPage1; AssertPtr(pSASPage1); MPT_CONFIG_EXTENDED_PAGE_HEADER_INIT(pSASPage1, pPages->cbSASIOUnitPage1, 1, MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE, MPT_CONFIGURATION_PAGE_TYPE_EXTENDED_SASIOUNIT); pSASPage1->u.fields.u8NumPhys = pSASPage0->u.fields.u8NumPhys; pSASPage1->u.fields.u16ControlFlags = 0; pSASPage1->u.fields.u16AdditionalControlFlags = 0; /* SAS I/O unit page 2 - Port specific information. */ pPages->SASIOUnitPage2.u.fields.ExtHeader.u8PageType = MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY | MPT_CONFIGURATION_PAGE_TYPE_EXTENDED; pPages->SASIOUnitPage2.u.fields.ExtHeader.u8PageNumber = 2; pPages->SASIOUnitPage2.u.fields.ExtHeader.u8ExtPageType = MPT_CONFIGURATION_PAGE_TYPE_EXTENDED_SASIOUNIT; pPages->SASIOUnitPage2.u.fields.ExtHeader.u16ExtPageLength = sizeof(MptConfigurationPageSASIOUnit2) / 4; /* SAS I/O unit page 3 - Port specific information. */ pPages->SASIOUnitPage3.u.fields.ExtHeader.u8PageType = MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY | MPT_CONFIGURATION_PAGE_TYPE_EXTENDED; pPages->SASIOUnitPage3.u.fields.ExtHeader.u8PageNumber = 3; pPages->SASIOUnitPage3.u.fields.ExtHeader.u8ExtPageType = MPT_CONFIGURATION_PAGE_TYPE_EXTENDED_SASIOUNIT; pPages->SASIOUnitPage3.u.fields.ExtHeader.u16ExtPageLength = sizeof(MptConfigurationPageSASIOUnit3) / 4; Assert(pPages->cPHYs == pThis->cPorts); AssertPtr(pPages->paPHYs); /* Initialize the PHY configuration */ PMptSASDevice pSASDevice = pPages->pSASDeviceHead; for (unsigned i = 0; i < pThis->cPorts; i++) { PMptPHY pPHYPages = &pPages->paPHYs[i]; uint16_t u16ControllerHandle = lsilogicGetHandle(pThis); pManufacturingPage7->u.fields.aPHY[i].u8Location = LSILOGICSCSI_MANUFACTURING7_LOCATION_AUTO; pSASPage0->u.fields.aPHY[i].u8Port = i; pSASPage0->u.fields.aPHY[i].u8PortFlags = 0; pSASPage0->u.fields.aPHY[i].u8PhyFlags = 0; pSASPage0->u.fields.aPHY[i].u8NegotiatedLinkRate = LSILOGICSCSI_SASIOUNIT0_NEGOTIATED_RATE_FAILED; pSASPage0->u.fields.aPHY[i].u32ControllerPhyDeviceInfo = LSILOGICSCSI_SASIOUNIT0_DEVICE_TYPE_SET(LSILOGICSCSI_SASIOUNIT0_DEVICE_TYPE_NO); pSASPage0->u.fields.aPHY[i].u16ControllerDevHandle = u16ControllerHandle; pSASPage0->u.fields.aPHY[i].u16AttachedDevHandle = 0; /* No device attached. */ pSASPage0->u.fields.aPHY[i].u32DiscoveryStatus = 0; /* No errors */ pSASPage1->u.fields.aPHY[i].u8Port = i; pSASPage1->u.fields.aPHY[i].u8PortFlags = 0; pSASPage1->u.fields.aPHY[i].u8PhyFlags = 0; pSASPage1->u.fields.aPHY[i].u8MaxMinLinkRate = LSILOGICSCSI_SASIOUNIT1_LINK_RATE_MIN_SET(LSILOGICSCSI_SASIOUNIT1_LINK_RATE_15GB) | LSILOGICSCSI_SASIOUNIT1_LINK_RATE_MAX_SET(LSILOGICSCSI_SASIOUNIT1_LINK_RATE_30GB); pSASPage1->u.fields.aPHY[i].u32ControllerPhyDeviceInfo = LSILOGICSCSI_SASIOUNIT0_DEVICE_TYPE_SET(LSILOGICSCSI_SASIOUNIT0_DEVICE_TYPE_NO); /* SAS PHY page 0. */ pPHYPages->SASPHYPage0.u.fields.ExtHeader.u8PageType = MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY | MPT_CONFIGURATION_PAGE_TYPE_EXTENDED; pPHYPages->SASPHYPage0.u.fields.ExtHeader.u8PageNumber = 0; pPHYPages->SASPHYPage0.u.fields.ExtHeader.u8ExtPageType = MPT_CONFIGURATION_PAGE_TYPE_EXTENDED_SASPHYS; pPHYPages->SASPHYPage0.u.fields.ExtHeader.u16ExtPageLength = sizeof(MptConfigurationPageSASPHY0) / 4; pPHYPages->SASPHYPage0.u.fields.u8AttachedPhyIdentifier = i; pPHYPages->SASPHYPage0.u.fields.u32AttachedDeviceInfo = LSILOGICSCSI_SASPHY0_DEV_INFO_DEVICE_TYPE_SET(LSILOGICSCSI_SASPHY0_DEV_INFO_DEVICE_TYPE_NO); pPHYPages->SASPHYPage0.u.fields.u8ProgrammedLinkRate = LSILOGICSCSI_SASIOUNIT1_LINK_RATE_MIN_SET(LSILOGICSCSI_SASIOUNIT1_LINK_RATE_15GB) | LSILOGICSCSI_SASIOUNIT1_LINK_RATE_MAX_SET(LSILOGICSCSI_SASIOUNIT1_LINK_RATE_30GB); pPHYPages->SASPHYPage0.u.fields.u8HwLinkRate = LSILOGICSCSI_SASIOUNIT1_LINK_RATE_MIN_SET(LSILOGICSCSI_SASIOUNIT1_LINK_RATE_15GB) | LSILOGICSCSI_SASIOUNIT1_LINK_RATE_MAX_SET(LSILOGICSCSI_SASIOUNIT1_LINK_RATE_30GB); /* SAS PHY page 1. */ pPHYPages->SASPHYPage1.u.fields.ExtHeader.u8PageType = MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY | MPT_CONFIGURATION_PAGE_TYPE_EXTENDED; pPHYPages->SASPHYPage1.u.fields.ExtHeader.u8PageNumber = 1; pPHYPages->SASPHYPage1.u.fields.ExtHeader.u8ExtPageType = MPT_CONFIGURATION_PAGE_TYPE_EXTENDED_SASPHYS; pPHYPages->SASPHYPage1.u.fields.ExtHeader.u16ExtPageLength = sizeof(MptConfigurationPageSASPHY1) / 4; /* Settings for present devices. */ if (pThisCC->paDeviceStates[i].pDrvBase) { uint16_t u16DeviceHandle = lsilogicGetHandle(pThis); SASADDRESS SASAddress; AssertPtr(pSASDevice); memset(&SASAddress, 0, sizeof(SASADDRESS)); lsilogicSASAddressGenerate(&SASAddress, i); pSASPage0->u.fields.aPHY[i].u8NegotiatedLinkRate = LSILOGICSCSI_SASIOUNIT0_NEGOTIATED_RATE_SET(LSILOGICSCSI_SASIOUNIT0_NEGOTIATED_RATE_30GB); pSASPage0->u.fields.aPHY[i].u32ControllerPhyDeviceInfo = LSILOGICSCSI_SASIOUNIT0_DEVICE_TYPE_SET(LSILOGICSCSI_SASIOUNIT0_DEVICE_TYPE_END) | LSILOGICSCSI_SASIOUNIT0_DEVICE_SSP_TARGET; pSASPage0->u.fields.aPHY[i].u16AttachedDevHandle = u16DeviceHandle; pSASPage1->u.fields.aPHY[i].u32ControllerPhyDeviceInfo = LSILOGICSCSI_SASIOUNIT0_DEVICE_TYPE_SET(LSILOGICSCSI_SASIOUNIT0_DEVICE_TYPE_END) | LSILOGICSCSI_SASIOUNIT0_DEVICE_SSP_TARGET; pSASPage0->u.fields.aPHY[i].u16ControllerDevHandle = u16DeviceHandle; pPHYPages->SASPHYPage0.u.fields.u32AttachedDeviceInfo = LSILOGICSCSI_SASPHY0_DEV_INFO_DEVICE_TYPE_SET(LSILOGICSCSI_SASPHY0_DEV_INFO_DEVICE_TYPE_END); pPHYPages->SASPHYPage0.u.fields.SASAddress = SASAddress; pPHYPages->SASPHYPage0.u.fields.u16OwnerDevHandle = u16DeviceHandle; pPHYPages->SASPHYPage0.u.fields.u16AttachedDevHandle = u16DeviceHandle; /* SAS device page 0. */ pSASDevice->SASDevicePage0.u.fields.ExtHeader.u8PageType = MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY | MPT_CONFIGURATION_PAGE_TYPE_EXTENDED; pSASDevice->SASDevicePage0.u.fields.ExtHeader.u8PageNumber = 0; pSASDevice->SASDevicePage0.u.fields.ExtHeader.u8ExtPageType = MPT_CONFIGURATION_PAGE_TYPE_EXTENDED_SASDEVICE; pSASDevice->SASDevicePage0.u.fields.ExtHeader.u16ExtPageLength = sizeof(MptConfigurationPageSASDevice0) / 4; pSASDevice->SASDevicePage0.u.fields.SASAddress = SASAddress; pSASDevice->SASDevicePage0.u.fields.u16ParentDevHandle = u16ControllerHandle; pSASDevice->SASDevicePage0.u.fields.u8PhyNum = i; pSASDevice->SASDevicePage0.u.fields.u8AccessStatus = LSILOGICSCSI_SASDEVICE0_STATUS_NO_ERRORS; pSASDevice->SASDevicePage0.u.fields.u16DevHandle = u16DeviceHandle; pSASDevice->SASDevicePage0.u.fields.u8TargetID = i; pSASDevice->SASDevicePage0.u.fields.u8Bus = 0; pSASDevice->SASDevicePage0.u.fields.u32DeviceInfo = LSILOGICSCSI_SASPHY0_DEV_INFO_DEVICE_TYPE_SET(LSILOGICSCSI_SASPHY0_DEV_INFO_DEVICE_TYPE_END) | LSILOGICSCSI_SASIOUNIT0_DEVICE_SSP_TARGET; pSASDevice->SASDevicePage0.u.fields.u16Flags = LSILOGICSCSI_SASDEVICE0_FLAGS_DEVICE_PRESENT | LSILOGICSCSI_SASDEVICE0_FLAGS_DEVICE_MAPPED_TO_BUS_AND_TARGET_ID | LSILOGICSCSI_SASDEVICE0_FLAGS_DEVICE_MAPPING_PERSISTENT; pSASDevice->SASDevicePage0.u.fields.u8PhysicalPort = i; /* SAS device page 1. */ pSASDevice->SASDevicePage1.u.fields.ExtHeader.u8PageType = MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY | MPT_CONFIGURATION_PAGE_TYPE_EXTENDED; pSASDevice->SASDevicePage1.u.fields.ExtHeader.u8PageNumber = 1; pSASDevice->SASDevicePage1.u.fields.ExtHeader.u8ExtPageType = MPT_CONFIGURATION_PAGE_TYPE_EXTENDED_SASDEVICE; pSASDevice->SASDevicePage1.u.fields.ExtHeader.u16ExtPageLength = sizeof(MptConfigurationPageSASDevice1) / 4; pSASDevice->SASDevicePage1.u.fields.SASAddress = SASAddress; pSASDevice->SASDevicePage1.u.fields.u16DevHandle = u16DeviceHandle; pSASDevice->SASDevicePage1.u.fields.u8TargetID = i; pSASDevice->SASDevicePage1.u.fields.u8Bus = 0; /* SAS device page 2. */ pSASDevice->SASDevicePage2.u.fields.ExtHeader.u8PageType = MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY | MPT_CONFIGURATION_PAGE_TYPE_EXTENDED; pSASDevice->SASDevicePage2.u.fields.ExtHeader.u8PageNumber = 2; pSASDevice->SASDevicePage2.u.fields.ExtHeader.u8ExtPageType = MPT_CONFIGURATION_PAGE_TYPE_EXTENDED_SASDEVICE; pSASDevice->SASDevicePage2.u.fields.ExtHeader.u16ExtPageLength = sizeof(MptConfigurationPageSASDevice2) / 4; pSASDevice->SASDevicePage2.u.fields.SASAddress = SASAddress; pSASDevice = pSASDevice->pNext; } } } /** * Initializes the configuration pages. * * @param pDevIns The device instance. * @param pThis Pointer to the shared LsiLogic device state. * @param pThisCC Pointer to the ring-3 LsiLogic device state. */ static void lsilogicR3InitializeConfigurationPages(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis, PLSILOGICSCSICC pThisCC) { /* Initialize the common pages. */ LogFlowFunc(("pThis=%#p\n", pThis)); AssertPtrReturnVoid(pThisCC->pConfigurationPages); PMptConfigurationPagesSupported pPages = pThisCC->pConfigurationPages; /* Manufacturing Page 0. */ MPT_CONFIG_PAGE_HEADER_INIT_MANUFACTURING(&pPages->ManufacturingPage0, MptConfigurationPageManufacturing0, 0, MPT_CONFIGURATION_PAGE_ATTRIBUTE_PERSISTENT_READONLY); strncpy((char *)pPages->ManufacturingPage0.u.fields.abChipName, "VBox MPT Fusion", 16); strncpy((char *)pPages->ManufacturingPage0.u.fields.abChipRevision, "1.0", 8); strncpy((char *)pPages->ManufacturingPage0.u.fields.abBoardName, "VBox MPT Fusion", 16); strncpy((char *)pPages->ManufacturingPage0.u.fields.abBoardAssembly, "SUN", 8); memcpy(pPages->ManufacturingPage0.u.fields.abBoardTracerNumber, "CAFECAFECAFECAFE", 16); /* Manufacturing Page 1 - I don't know what this contains so we leave it 0 for now. */ MPT_CONFIG_PAGE_HEADER_INIT_MANUFACTURING(&pPages->ManufacturingPage1, MptConfigurationPageManufacturing1, 1, MPT_CONFIGURATION_PAGE_ATTRIBUTE_PERSISTENT_READONLY); /* Manufacturing Page 2. */ MPT_CONFIG_PAGE_HEADER_INIT_MANUFACTURING(&pPages->ManufacturingPage2, MptConfigurationPageManufacturing2, 2, MPT_CONFIGURATION_PAGE_ATTRIBUTE_PERSISTENT_READONLY); if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI) { pPages->ManufacturingPage2.u.fields.u16PCIDeviceID = LSILOGICSCSI_PCI_SPI_DEVICE_ID; pPages->ManufacturingPage2.u.fields.u8PCIRevisionID = LSILOGICSCSI_PCI_SPI_REVISION_ID; } else if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) { pPages->ManufacturingPage2.u.fields.u16PCIDeviceID = LSILOGICSCSI_PCI_SAS_DEVICE_ID; pPages->ManufacturingPage2.u.fields.u8PCIRevisionID = LSILOGICSCSI_PCI_SAS_REVISION_ID; } /* Manufacturing Page 3. */ MPT_CONFIG_PAGE_HEADER_INIT_MANUFACTURING(&pPages->ManufacturingPage3, MptConfigurationPageManufacturing3, 3, MPT_CONFIGURATION_PAGE_ATTRIBUTE_PERSISTENT_READONLY); if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI) { pPages->ManufacturingPage3.u.fields.u16PCIDeviceID = LSILOGICSCSI_PCI_SPI_DEVICE_ID; pPages->ManufacturingPage3.u.fields.u8PCIRevisionID = LSILOGICSCSI_PCI_SPI_REVISION_ID; } else if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) { pPages->ManufacturingPage3.u.fields.u16PCIDeviceID = LSILOGICSCSI_PCI_SAS_DEVICE_ID; pPages->ManufacturingPage3.u.fields.u8PCIRevisionID = LSILOGICSCSI_PCI_SAS_REVISION_ID; } /* Manufacturing Page 4 - I don't know what this contains so we leave it 0 for now. */ MPT_CONFIG_PAGE_HEADER_INIT_MANUFACTURING(&pPages->ManufacturingPage4, MptConfigurationPageManufacturing4, 4, MPT_CONFIGURATION_PAGE_ATTRIBUTE_PERSISTENT_READONLY); /* Manufacturing Page 5 - WWID settings. */ MPT_CONFIG_PAGE_HEADER_INIT_MANUFACTURING(&pPages->ManufacturingPage5, MptConfigurationPageManufacturing5, 5, MPT_CONFIGURATION_PAGE_ATTRIBUTE_PERSISTENT_READONLY); /* Manufacturing Page 6 - Product specific settings. */ MPT_CONFIG_PAGE_HEADER_INIT_MANUFACTURING(&pPages->ManufacturingPage6, MptConfigurationPageManufacturing6, 6, MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE); /* Manufacturing Page 8 - Product specific settings. */ MPT_CONFIG_PAGE_HEADER_INIT_MANUFACTURING(&pPages->ManufacturingPage8, MptConfigurationPageManufacturing8, 8, MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE); /* Manufacturing Page 9 - Product specific settings. */ MPT_CONFIG_PAGE_HEADER_INIT_MANUFACTURING(&pPages->ManufacturingPage9, MptConfigurationPageManufacturing9, 9, MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE); /* Manufacturing Page 10 - Product specific settings. */ MPT_CONFIG_PAGE_HEADER_INIT_MANUFACTURING(&pPages->ManufacturingPage10, MptConfigurationPageManufacturing10, 10, MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE); /* I/O Unit page 0. */ MPT_CONFIG_PAGE_HEADER_INIT_IO_UNIT(&pPages->IOUnitPage0, MptConfigurationPageIOUnit0, 0, MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY); pPages->IOUnitPage0.u.fields.u64UniqueIdentifier = 0xcafe; /* I/O Unit page 1. */ MPT_CONFIG_PAGE_HEADER_INIT_IO_UNIT(&pPages->IOUnitPage1, MptConfigurationPageIOUnit1, 1, MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY); pPages->IOUnitPage1.u.fields.fSingleFunction = true; pPages->IOUnitPage1.u.fields.fAllPathsMapped = false; pPages->IOUnitPage1.u.fields.fIntegratedRAIDDisabled = true; pPages->IOUnitPage1.u.fields.f32BitAccessForced = false; /* I/O Unit page 2. */ MPT_CONFIG_PAGE_HEADER_INIT_IO_UNIT(&pPages->IOUnitPage2, MptConfigurationPageIOUnit2, 2, MPT_CONFIGURATION_PAGE_ATTRIBUTE_PERSISTENT); pPages->IOUnitPage2.u.fields.fPauseOnError = false; pPages->IOUnitPage2.u.fields.fVerboseModeEnabled = false; pPages->IOUnitPage2.u.fields.fDisableColorVideo = false; pPages->IOUnitPage2.u.fields.fNotHookInt40h = false; pPages->IOUnitPage2.u.fields.u32BIOSVersion = 0xcafecafe; pPages->IOUnitPage2.u.fields.aAdapterOrder[0].fAdapterEnabled = true; pPages->IOUnitPage2.u.fields.aAdapterOrder[0].fAdapterEmbedded = true; pPages->IOUnitPage2.u.fields.aAdapterOrder[0].u8PCIBusNumber = 0; pPages->IOUnitPage2.u.fields.aAdapterOrder[0].u8PCIDevFn = pDevIns->apPciDevs[0]->uDevFn; /* I/O Unit page 3. */ MPT_CONFIG_PAGE_HEADER_INIT_IO_UNIT(&pPages->IOUnitPage3, MptConfigurationPageIOUnit3, 3, MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE); pPages->IOUnitPage3.u.fields.u8GPIOCount = 0; /* I/O Unit page 4. */ MPT_CONFIG_PAGE_HEADER_INIT_IO_UNIT(&pPages->IOUnitPage4, MptConfigurationPageIOUnit4, 4, MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE); /* IOC page 0. */ MPT_CONFIG_PAGE_HEADER_INIT_IOC(&pPages->IOCPage0, MptConfigurationPageIOC0, 0, MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY); pPages->IOCPage0.u.fields.u32TotalNVStore = 0; pPages->IOCPage0.u.fields.u32FreeNVStore = 0; if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI) { pPages->IOCPage0.u.fields.u16VendorId = LSILOGICSCSI_PCI_VENDOR_ID; pPages->IOCPage0.u.fields.u16DeviceId = LSILOGICSCSI_PCI_SPI_DEVICE_ID; pPages->IOCPage0.u.fields.u8RevisionId = LSILOGICSCSI_PCI_SPI_REVISION_ID; pPages->IOCPage0.u.fields.u32ClassCode = LSILOGICSCSI_PCI_SPI_CLASS_CODE; pPages->IOCPage0.u.fields.u16SubsystemVendorId = LSILOGICSCSI_PCI_SPI_SUBSYSTEM_VENDOR_ID; pPages->IOCPage0.u.fields.u16SubsystemId = LSILOGICSCSI_PCI_SPI_SUBSYSTEM_ID; } else if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) { pPages->IOCPage0.u.fields.u16VendorId = LSILOGICSCSI_PCI_VENDOR_ID; pPages->IOCPage0.u.fields.u16DeviceId = LSILOGICSCSI_PCI_SAS_DEVICE_ID; pPages->IOCPage0.u.fields.u8RevisionId = LSILOGICSCSI_PCI_SAS_REVISION_ID; pPages->IOCPage0.u.fields.u32ClassCode = LSILOGICSCSI_PCI_SAS_CLASS_CODE; pPages->IOCPage0.u.fields.u16SubsystemVendorId = LSILOGICSCSI_PCI_SAS_SUBSYSTEM_VENDOR_ID; pPages->IOCPage0.u.fields.u16SubsystemId = LSILOGICSCSI_PCI_SAS_SUBSYSTEM_ID; } /* IOC page 1. */ MPT_CONFIG_PAGE_HEADER_INIT_IOC(&pPages->IOCPage1, MptConfigurationPageIOC1, 1, MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE); pPages->IOCPage1.u.fields.fReplyCoalescingEnabled = false; pPages->IOCPage1.u.fields.u32CoalescingTimeout = 0; pPages->IOCPage1.u.fields.u8CoalescingDepth = 0; /* IOC page 2. */ MPT_CONFIG_PAGE_HEADER_INIT_IOC(&pPages->IOCPage2, MptConfigurationPageIOC2, 2, MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY); /* Everything else here is 0. */ /* IOC page 3. */ MPT_CONFIG_PAGE_HEADER_INIT_IOC(&pPages->IOCPage3, MptConfigurationPageIOC3, 3, MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY); /* Everything else here is 0. */ /* IOC page 4. */ MPT_CONFIG_PAGE_HEADER_INIT_IOC(&pPages->IOCPage4, MptConfigurationPageIOC4, 4, MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY); /* Everything else here is 0. */ /* IOC page 6. */ MPT_CONFIG_PAGE_HEADER_INIT_IOC(&pPages->IOCPage6, MptConfigurationPageIOC6, 6, MPT_CONFIGURATION_PAGE_ATTRIBUTE_READONLY); /* Everything else here is 0. */ /* BIOS page 1. */ MPT_CONFIG_PAGE_HEADER_INIT_BIOS(&pPages->BIOSPage1, MptConfigurationPageBIOS1, 1, MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE); /* BIOS page 2. */ MPT_CONFIG_PAGE_HEADER_INIT_BIOS(&pPages->BIOSPage2, MptConfigurationPageBIOS2, 2, MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE); /* BIOS page 4. */ MPT_CONFIG_PAGE_HEADER_INIT_BIOS(&pPages->BIOSPage4, MptConfigurationPageBIOS4, 4, MPT_CONFIGURATION_PAGE_ATTRIBUTE_CHANGEABLE); if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI) lsilogicR3InitializeConfigurationPagesSpi(pThis, pThisCC); else if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) lsilogicR3InitializeConfigurationPagesSas(pThis, pThisCC); else AssertMsgFailed(("Invalid controller type %d\n", pThis->enmCtrlType)); } /** * Sets the emulated controller type from a given string. * * @returns VBox status code. * * @param pThis Pointer to the shared LsiLogic device state. * @param pcszCtrlType The string to use. */ static int lsilogicR3GetCtrlTypeFromString(PLSILOGICSCSI pThis, const char *pcszCtrlType) { int rc = VERR_INVALID_PARAMETER; if (!RTStrCmp(pcszCtrlType, LSILOGICSCSI_PCI_SPI_CTRLNAME)) { pThis->enmCtrlType = LSILOGICCTRLTYPE_SCSI_SPI; rc = VINF_SUCCESS; } else if (!RTStrCmp(pcszCtrlType, LSILOGICSCSI_PCI_SAS_CTRLNAME)) { pThis->enmCtrlType = LSILOGICCTRLTYPE_SCSI_SAS; rc = VINF_SUCCESS; } return rc; } /** * @callback_method_impl{PFNDBGFHANDLERDEV} */ static DECLCALLBACK(void) lsilogicR3Info(PPDMDEVINS pDevIns, PCDBGFINFOHLP pHlp, const char *pszArgs) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); PLSILOGICSCSICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC); /* * Parse args. */ bool const fVerbose = pszArgs && strstr(pszArgs, "verbose") != NULL; /* * Show info. */ pHlp->pfnPrintf(pHlp, "%s#%d: port=%04x mmio=%RGp max-devices=%u GC=%RTbool R0=%RTbool\n", pDevIns->pReg->szName, pDevIns->iInstance, PDMDevHlpIoPortGetMappingAddress(pDevIns, pThis->hIoPortsReg), PDMDevHlpMmioGetMappingAddress(pDevIns, pThis->hMmioReg), pThis->cDeviceStates, pDevIns->fRCEnabled, pDevIns->fR0Enabled); /* * Show general state. */ pHlp->pfnPrintf(pHlp, "enmState=%u\n", pThis->enmState); pHlp->pfnPrintf(pHlp, "enmWhoInit=%u\n", pThis->enmWhoInit); pHlp->pfnPrintf(pHlp, "enmDoorbellState=%d\n", pThis->enmDoorbellState); pHlp->pfnPrintf(pHlp, "fDiagnosticEnabled=%RTbool\n", pThis->fDiagnosticEnabled); pHlp->pfnPrintf(pHlp, "fNotificationSent=%RTbool\n", pThis->fNotificationSent); pHlp->pfnPrintf(pHlp, "fEventNotificationEnabled=%RTbool\n", pThis->fEventNotificationEnabled); pHlp->pfnPrintf(pHlp, "uInterruptMask=%#x\n", pThis->uInterruptMask); pHlp->pfnPrintf(pHlp, "uInterruptStatus=%#x\n", pThis->uInterruptStatus); pHlp->pfnPrintf(pHlp, "u16IOCFaultCode=%#06x\n", pThis->u16IOCFaultCode); pHlp->pfnPrintf(pHlp, "u32HostMFAHighAddr=%#x\n", pThis->u32HostMFAHighAddr); pHlp->pfnPrintf(pHlp, "u32SenseBufferHighAddr=%#x\n", pThis->u32SenseBufferHighAddr); pHlp->pfnPrintf(pHlp, "cMaxDevices=%u\n", pThis->cMaxDevices); pHlp->pfnPrintf(pHlp, "cMaxBuses=%u\n", pThis->cMaxBuses); pHlp->pfnPrintf(pHlp, "cbReplyFrame=%u\n", pThis->cbReplyFrame); pHlp->pfnPrintf(pHlp, "cReplyQueueEntries=%u\n", pThis->cReplyQueueEntries); pHlp->pfnPrintf(pHlp, "cRequestQueueEntries=%u\n", pThis->cRequestQueueEntries); pHlp->pfnPrintf(pHlp, "cPorts=%u\n", pThis->cPorts); /* * Show queue status. */ pHlp->pfnPrintf(pHlp, "uReplyFreeQueueNextEntryFreeWrite=%u\n", pThis->uReplyFreeQueueNextEntryFreeWrite); pHlp->pfnPrintf(pHlp, "uReplyFreeQueueNextAddressRead=%u\n", pThis->uReplyFreeQueueNextAddressRead); pHlp->pfnPrintf(pHlp, "uReplyPostQueueNextEntryFreeWrite=%u\n", pThis->uReplyPostQueueNextEntryFreeWrite); pHlp->pfnPrintf(pHlp, "uReplyPostQueueNextAddressRead=%u\n", pThis->uReplyPostQueueNextAddressRead); pHlp->pfnPrintf(pHlp, "uRequestQueueNextEntryFreeWrite=%u\n", pThis->uRequestQueueNextEntryFreeWrite); pHlp->pfnPrintf(pHlp, "uRequestQueueNextAddressRead=%u\n", pThis->uRequestQueueNextAddressRead); /* * Show queue content if verbose */ if (fVerbose) { for (unsigned i = 0; i < pThis->cReplyQueueEntries; i++) pHlp->pfnPrintf(pHlp, "RFQ[%u]=%#x\n", i, pThis->aReplyFreeQueue[i]); pHlp->pfnPrintf(pHlp, "\n"); for (unsigned i = 0; i < pThis->cReplyQueueEntries; i++) pHlp->pfnPrintf(pHlp, "RPQ[%u]=%#x\n", i, pThis->aReplyPostQueue[i]); pHlp->pfnPrintf(pHlp, "\n"); for (unsigned i = 0; i < pThis->cRequestQueueEntries; i++) pHlp->pfnPrintf(pHlp, "ReqQ[%u]=%#x\n", i, pThis->aRequestQueue[i]); } /* * Print the device status. */ for (unsigned i = 0; i < pThis->cDeviceStates; i++) { PLSILOGICDEVICE pDevice = &pThisCC->paDeviceStates[i]; pHlp->pfnPrintf(pHlp, "\n"); pHlp->pfnPrintf(pHlp, "Device[%u]: device-attached=%RTbool cOutstandingRequests=%u\n", i, pDevice->pDrvBase != NULL, pDevice->cOutstandingRequests); } } /** * @callback_method_impl{FNPDMTHREADDEV} */ static DECLCALLBACK(int) lsilogicR3Worker(PPDMDEVINS pDevIns, PPDMTHREAD pThread) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); PLSILOGICSCSICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC); int rc = VINF_SUCCESS; if (pThread->enmState == PDMTHREADSTATE_INITIALIZING) return VINF_SUCCESS; while (pThread->enmState == PDMTHREADSTATE_RUNNING) { ASMAtomicWriteBool(&pThis->fWrkThreadSleeping, true); bool fNotificationSent = ASMAtomicXchgBool(&pThis->fNotificationSent, false); if (!fNotificationSent) { Assert(ASMAtomicReadBool(&pThis->fWrkThreadSleeping)); rc = PDMDevHlpSUPSemEventWaitNoResume(pDevIns, pThis->hEvtProcess, RT_INDEFINITE_WAIT); AssertLogRelMsgReturn(RT_SUCCESS(rc) || rc == VERR_INTERRUPTED, ("%Rrc\n", rc), rc); if (RT_UNLIKELY(pThread->enmState != PDMTHREADSTATE_RUNNING)) break; LogFlowFunc(("Woken up with rc=%Rrc\n", rc)); ASMAtomicWriteBool(&pThis->fNotificationSent, false); } ASMAtomicWriteBool(&pThis->fWrkThreadSleeping, false); /* Only process request which arrived before we received the notification. */ uint32_t uRequestQueueNextEntryWrite = ASMAtomicReadU32(&pThis->uRequestQueueNextEntryFreeWrite); /* Go through the messages now and process them. */ while ( RT_LIKELY(pThis->enmState == LSILOGICSTATE_OPERATIONAL) && (pThis->uRequestQueueNextAddressRead != uRequestQueueNextEntryWrite)) { MptRequestUnion GuestRequest; uint32_t u32RequestMessageFrameDesc = pThis->aRequestQueue[pThis->uRequestQueueNextAddressRead]; RTGCPHYS GCPhysMessageFrameAddr = LSILOGIC_RTGCPHYS_FROM_U32(pThis->u32HostMFAHighAddr, (u32RequestMessageFrameDesc & ~0x07)); /* Read the message header from the guest first. */ PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysMessageFrameAddr, &GuestRequest, sizeof(MptMessageHdr)); /* Determine the size of the request. */ uint32_t cbRequest = 0; switch (GuestRequest.Header.u8Function) { case MPT_MESSAGE_HDR_FUNCTION_SCSI_IO_REQUEST: cbRequest = sizeof(MptSCSIIORequest); break; case MPT_MESSAGE_HDR_FUNCTION_SCSI_TASK_MGMT: cbRequest = sizeof(MptSCSITaskManagementRequest); break; case MPT_MESSAGE_HDR_FUNCTION_IOC_INIT: cbRequest = sizeof(MptIOCInitRequest); break; case MPT_MESSAGE_HDR_FUNCTION_IOC_FACTS: cbRequest = sizeof(MptIOCFactsRequest); break; case MPT_MESSAGE_HDR_FUNCTION_CONFIG: cbRequest = sizeof(MptConfigurationRequest); break; case MPT_MESSAGE_HDR_FUNCTION_PORT_FACTS: cbRequest = sizeof(MptPortFactsRequest); break; case MPT_MESSAGE_HDR_FUNCTION_PORT_ENABLE: cbRequest = sizeof(MptPortEnableRequest); break; case MPT_MESSAGE_HDR_FUNCTION_EVENT_NOTIFICATION: cbRequest = sizeof(MptEventNotificationRequest); break; case MPT_MESSAGE_HDR_FUNCTION_EVENT_ACK: AssertMsgFailed(("todo\n")); //cbRequest = sizeof(MptEventAckRequest); break; case MPT_MESSAGE_HDR_FUNCTION_FW_DOWNLOAD: cbRequest = sizeof(MptFWDownloadRequest); break; case MPT_MESSAGE_HDR_FUNCTION_FW_UPLOAD: cbRequest = sizeof(MptFWUploadRequest); break; default: AssertMsgFailed(("Unknown function issued %u\n", GuestRequest.Header.u8Function)); lsilogicSetIOCFaultCode(pThis, LSILOGIC_IOCSTATUS_INVALID_FUNCTION); } if (cbRequest != 0) { /* Read the complete message frame from guest memory now. */ PDMDevHlpPCIPhysReadMeta(pDevIns, GCPhysMessageFrameAddr, &GuestRequest, cbRequest); /* Handle SCSI I/O requests now. */ if (GuestRequest.Header.u8Function == MPT_MESSAGE_HDR_FUNCTION_SCSI_IO_REQUEST) { rc = lsilogicR3ProcessSCSIIORequest(pDevIns, pThis, pThisCC, GCPhysMessageFrameAddr, &GuestRequest); AssertRC(rc); } else { MptReplyUnion Reply; rc = lsilogicR3ProcessMessageRequest(pDevIns, pThis, pThisCC, &GuestRequest.Header, &Reply); AssertRC(rc); } pThis->uRequestQueueNextAddressRead++; pThis->uRequestQueueNextAddressRead %= pThis->cRequestQueueEntries; } } /* While request frames available. */ } /* While running */ return VINF_SUCCESS; } /** * @callback_method_impl{FNPDMTHREADWAKEUPDEV} */ static DECLCALLBACK(int) lsilogicR3WorkerWakeUp(PPDMDEVINS pDevIns, PPDMTHREAD pThread) { RT_NOREF(pThread); PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); return PDMDevHlpSUPSemEventSignal(pDevIns, pThis->hEvtProcess); } /** * Kicks the controller to process pending tasks after the VM was resumed * or loaded from a saved state. * * @param pDevIns The device instance. * @param pThis Pointer to the shared LsiLogic device state. */ static void lsilogicR3Kick(PPDMDEVINS pDevIns, PLSILOGICSCSI pThis) { if (pThis->fNotificationSent) { /* Notify the worker thread that there are pending requests. */ LogFlowFunc(("Signal event semaphore\n")); int rc = PDMDevHlpSUPSemEventSignal(pDevIns, pThis->hEvtProcess); AssertRC(rc); } } /* * Saved state. */ /** * @callback_method_impl{FNSSMDEVLIVEEXEC} */ static DECLCALLBACK(int) lsilogicR3LiveExec(PPDMDEVINS pDevIns, PSSMHANDLE pSSM, uint32_t uPass) { RT_NOREF(uPass); PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); PLSILOGICSCSICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC); PCPDMDEVHLPR3 pHlp = pDevIns->pHlpR3; pHlp->pfnSSMPutU32(pSSM, pThis->enmCtrlType); pHlp->pfnSSMPutU32(pSSM, pThis->cDeviceStates); pHlp->pfnSSMPutU32(pSSM, pThis->cPorts); /* Save the device config. */ for (unsigned i = 0; i < pThis->cDeviceStates; i++) pHlp->pfnSSMPutBool(pSSM, pThisCC->paDeviceStates[i].pDrvBase != NULL); return VINF_SSM_DONT_CALL_AGAIN; } /** * @callback_method_impl{FNSSMDEVSAVEEXEC} */ static DECLCALLBACK(int) lsilogicR3SaveExec(PPDMDEVINS pDevIns, PSSMHANDLE pSSM) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); PLSILOGICSCSICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC); PCPDMDEVHLPR3 pHlp = pDevIns->pHlpR3; /* Every device first. */ lsilogicR3LiveExec(pDevIns, pSSM, SSM_PASS_FINAL); for (unsigned i = 0; i < pThis->cDeviceStates; i++) { PLSILOGICDEVICE pDevice = &pThisCC->paDeviceStates[i]; AssertMsg(!pDevice->cOutstandingRequests, ("There are still outstanding requests on this device\n")); pHlp->pfnSSMPutU32(pSSM, pDevice->cOutstandingRequests); /* Query all suspended requests and store them in the request queue. */ if (pDevice->pDrvMediaEx) { uint32_t cReqsRedo = pDevice->pDrvMediaEx->pfnIoReqGetSuspendedCount(pDevice->pDrvMediaEx); if (cReqsRedo) { PDMMEDIAEXIOREQ hIoReq; PLSILOGICREQ pReq; int rc = pDevice->pDrvMediaEx->pfnIoReqQuerySuspendedStart(pDevice->pDrvMediaEx, &hIoReq, (void **)&pReq); AssertRCBreak(rc); for (;;) { /* Write only the lower 32bit part of the address. */ ASMAtomicWriteU32(&pThis->aRequestQueue[pThis->uRequestQueueNextEntryFreeWrite], pReq->GCPhysMessageFrameAddr & UINT32_C(0xffffffff)); pThis->uRequestQueueNextEntryFreeWrite++; pThis->uRequestQueueNextEntryFreeWrite %= pThis->cRequestQueueEntries; cReqsRedo--; if (!cReqsRedo) break; rc = pDevice->pDrvMediaEx->pfnIoReqQuerySuspendedNext(pDevice->pDrvMediaEx, hIoReq, &hIoReq, (void **)&pReq); AssertRCBreak(rc); } } } } /* Now the main device state. */ pHlp->pfnSSMPutU32(pSSM, pThis->enmState); pHlp->pfnSSMPutU32(pSSM, pThis->enmWhoInit); pHlp->pfnSSMPutU32(pSSM, pThis->enmDoorbellState); pHlp->pfnSSMPutBool(pSSM, pThis->fDiagnosticEnabled); pHlp->pfnSSMPutBool(pSSM, pThis->fNotificationSent); pHlp->pfnSSMPutBool(pSSM, pThis->fEventNotificationEnabled); pHlp->pfnSSMPutU32(pSSM, pThis->uInterruptMask); pHlp->pfnSSMPutU32(pSSM, pThis->uInterruptStatus); for (unsigned i = 0; i < RT_ELEMENTS(pThis->aMessage); i++) pHlp->pfnSSMPutU32(pSSM, pThis->aMessage[i]); pHlp->pfnSSMPutU32(pSSM, pThis->iMessage); pHlp->pfnSSMPutU32(pSSM, pThis->cMessage); pHlp->pfnSSMPutMem(pSSM, &pThis->ReplyBuffer, sizeof(pThis->ReplyBuffer)); pHlp->pfnSSMPutU32(pSSM, pThis->uNextReplyEntryRead); pHlp->pfnSSMPutU32(pSSM, pThis->cReplySize); pHlp->pfnSSMPutU16(pSSM, pThis->u16IOCFaultCode); pHlp->pfnSSMPutU32(pSSM, pThis->u32HostMFAHighAddr); pHlp->pfnSSMPutU32(pSSM, pThis->u32SenseBufferHighAddr); pHlp->pfnSSMPutU8(pSSM, pThis->cMaxDevices); pHlp->pfnSSMPutU8(pSSM, pThis->cMaxBuses); pHlp->pfnSSMPutU16(pSSM, pThis->cbReplyFrame); pHlp->pfnSSMPutU32(pSSM, pThis->iDiagnosticAccess); pHlp->pfnSSMPutU32(pSSM, pThis->cReplyQueueEntries); pHlp->pfnSSMPutU32(pSSM, pThis->cRequestQueueEntries); pHlp->pfnSSMPutU32(pSSM, pThis->uReplyFreeQueueNextEntryFreeWrite); pHlp->pfnSSMPutU32(pSSM, pThis->uReplyFreeQueueNextAddressRead); pHlp->pfnSSMPutU32(pSSM, pThis->uReplyPostQueueNextEntryFreeWrite); pHlp->pfnSSMPutU32(pSSM, pThis->uReplyPostQueueNextAddressRead); pHlp->pfnSSMPutU32(pSSM, pThis->uRequestQueueNextEntryFreeWrite); pHlp->pfnSSMPutU32(pSSM, pThis->uRequestQueueNextAddressRead); for (unsigned i = 0; i < pThis->cReplyQueueEntries; i++) pHlp->pfnSSMPutU32(pSSM, pThis->aReplyFreeQueue[i]); for (unsigned i = 0; i < pThis->cReplyQueueEntries; i++) pHlp->pfnSSMPutU32(pSSM, pThis->aReplyPostQueue[i]); for (unsigned i = 0; i < pThis->cRequestQueueEntries; i++) pHlp->pfnSSMPutU32(pSSM, pThis->aRequestQueue[i]); pHlp->pfnSSMPutU16(pSSM, pThis->u16NextHandle); /* Save diagnostic memory register and data regions. */ pHlp->pfnSSMPutU32(pSSM, pThis->u32DiagMemAddr); pHlp->pfnSSMPutU32(pSSM, lsilogicR3MemRegionsCount(pThisCC)); PLSILOGICMEMREGN pIt; RTListForEach(&pThisCC->ListMemRegns, pIt, LSILOGICMEMREGN, NodeList) { pHlp->pfnSSMPutU32(pSSM, pIt->u32AddrStart); pHlp->pfnSSMPutU32(pSSM, pIt->u32AddrEnd); pHlp->pfnSSMPutMem(pSSM, &pIt->au32Data[0], (pIt->u32AddrEnd - pIt->u32AddrStart + 1) * sizeof(uint32_t)); } PMptConfigurationPagesSupported pPages = pThisCC->pConfigurationPages; pHlp->pfnSSMPutMem(pSSM, &pPages->ManufacturingPage0, sizeof(MptConfigurationPageManufacturing0)); pHlp->pfnSSMPutMem(pSSM, &pPages->ManufacturingPage1, sizeof(MptConfigurationPageManufacturing1)); pHlp->pfnSSMPutMem(pSSM, &pPages->ManufacturingPage2, sizeof(MptConfigurationPageManufacturing2)); pHlp->pfnSSMPutMem(pSSM, &pPages->ManufacturingPage3, sizeof(MptConfigurationPageManufacturing3)); pHlp->pfnSSMPutMem(pSSM, &pPages->ManufacturingPage4, sizeof(MptConfigurationPageManufacturing4)); pHlp->pfnSSMPutMem(pSSM, &pPages->ManufacturingPage5, sizeof(MptConfigurationPageManufacturing5)); pHlp->pfnSSMPutMem(pSSM, &pPages->ManufacturingPage6, sizeof(MptConfigurationPageManufacturing6)); pHlp->pfnSSMPutMem(pSSM, &pPages->ManufacturingPage8, sizeof(MptConfigurationPageManufacturing8)); pHlp->pfnSSMPutMem(pSSM, &pPages->ManufacturingPage9, sizeof(MptConfigurationPageManufacturing9)); pHlp->pfnSSMPutMem(pSSM, &pPages->ManufacturingPage10, sizeof(MptConfigurationPageManufacturing10)); pHlp->pfnSSMPutMem(pSSM, &pPages->IOUnitPage0, sizeof(MptConfigurationPageIOUnit0)); pHlp->pfnSSMPutMem(pSSM, &pPages->IOUnitPage1, sizeof(MptConfigurationPageIOUnit1)); pHlp->pfnSSMPutMem(pSSM, &pPages->IOUnitPage2, sizeof(MptConfigurationPageIOUnit2)); pHlp->pfnSSMPutMem(pSSM, &pPages->IOUnitPage3, sizeof(MptConfigurationPageIOUnit3)); pHlp->pfnSSMPutMem(pSSM, &pPages->IOUnitPage4, sizeof(MptConfigurationPageIOUnit4)); pHlp->pfnSSMPutMem(pSSM, &pPages->IOCPage0, sizeof(MptConfigurationPageIOC0)); pHlp->pfnSSMPutMem(pSSM, &pPages->IOCPage1, sizeof(MptConfigurationPageIOC1)); pHlp->pfnSSMPutMem(pSSM, &pPages->IOCPage2, sizeof(MptConfigurationPageIOC2)); pHlp->pfnSSMPutMem(pSSM, &pPages->IOCPage3, sizeof(MptConfigurationPageIOC3)); pHlp->pfnSSMPutMem(pSSM, &pPages->IOCPage4, sizeof(MptConfigurationPageIOC4)); pHlp->pfnSSMPutMem(pSSM, &pPages->IOCPage6, sizeof(MptConfigurationPageIOC6)); pHlp->pfnSSMPutMem(pSSM, &pPages->BIOSPage1, sizeof(MptConfigurationPageBIOS1)); pHlp->pfnSSMPutMem(pSSM, &pPages->BIOSPage2, sizeof(MptConfigurationPageBIOS2)); pHlp->pfnSSMPutMem(pSSM, &pPages->BIOSPage4, sizeof(MptConfigurationPageBIOS4)); /* Device dependent pages */ if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI) { PMptConfigurationPagesSpi pSpiPages = &pPages->u.SpiPages; pHlp->pfnSSMPutMem(pSSM, &pSpiPages->aPortPages[0].SCSISPIPortPage0, sizeof(MptConfigurationPageSCSISPIPort0)); pHlp->pfnSSMPutMem(pSSM, &pSpiPages->aPortPages[0].SCSISPIPortPage1, sizeof(MptConfigurationPageSCSISPIPort1)); pHlp->pfnSSMPutMem(pSSM, &pSpiPages->aPortPages[0].SCSISPIPortPage2, sizeof(MptConfigurationPageSCSISPIPort2)); for (unsigned i = 0; i < RT_ELEMENTS(pSpiPages->aBuses[0].aDevicePages); i++) { pHlp->pfnSSMPutMem(pSSM, &pSpiPages->aBuses[0].aDevicePages[i].SCSISPIDevicePage0, sizeof(MptConfigurationPageSCSISPIDevice0)); pHlp->pfnSSMPutMem(pSSM, &pSpiPages->aBuses[0].aDevicePages[i].SCSISPIDevicePage1, sizeof(MptConfigurationPageSCSISPIDevice1)); pHlp->pfnSSMPutMem(pSSM, &pSpiPages->aBuses[0].aDevicePages[i].SCSISPIDevicePage2, sizeof(MptConfigurationPageSCSISPIDevice2)); pHlp->pfnSSMPutMem(pSSM, &pSpiPages->aBuses[0].aDevicePages[i].SCSISPIDevicePage3, sizeof(MptConfigurationPageSCSISPIDevice3)); } } else if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) { PMptConfigurationPagesSas pSasPages = &pPages->u.SasPages; pHlp->pfnSSMPutU32(pSSM, pSasPages->cbManufacturingPage7); pHlp->pfnSSMPutU32(pSSM, pSasPages->cbSASIOUnitPage0); pHlp->pfnSSMPutU32(pSSM, pSasPages->cbSASIOUnitPage1); pHlp->pfnSSMPutMem(pSSM, pSasPages->pManufacturingPage7, pSasPages->cbManufacturingPage7); pHlp->pfnSSMPutMem(pSSM, pSasPages->pSASIOUnitPage0, pSasPages->cbSASIOUnitPage0); pHlp->pfnSSMPutMem(pSSM, pSasPages->pSASIOUnitPage1, pSasPages->cbSASIOUnitPage1); pHlp->pfnSSMPutMem(pSSM, &pSasPages->SASIOUnitPage2, sizeof(MptConfigurationPageSASIOUnit2)); pHlp->pfnSSMPutMem(pSSM, &pSasPages->SASIOUnitPage3, sizeof(MptConfigurationPageSASIOUnit3)); pHlp->pfnSSMPutU32(pSSM, pSasPages->cPHYs); for (unsigned i = 0; i < pSasPages->cPHYs; i++) { pHlp->pfnSSMPutMem(pSSM, &pSasPages->paPHYs[i].SASPHYPage0, sizeof(MptConfigurationPageSASPHY0)); pHlp->pfnSSMPutMem(pSSM, &pSasPages->paPHYs[i].SASPHYPage1, sizeof(MptConfigurationPageSASPHY1)); } /* The number of devices first. */ pHlp->pfnSSMPutU32(pSSM, pSasPages->cDevices); for (PMptSASDevice pCurr = pSasPages->pSASDeviceHead; pCurr; pCurr = pCurr->pNext) { pHlp->pfnSSMPutMem(pSSM, &pCurr->SASDevicePage0, sizeof(MptConfigurationPageSASDevice0)); pHlp->pfnSSMPutMem(pSSM, &pCurr->SASDevicePage1, sizeof(MptConfigurationPageSASDevice1)); pHlp->pfnSSMPutMem(pSSM, &pCurr->SASDevicePage2, sizeof(MptConfigurationPageSASDevice2)); } } else AssertMsgFailed(("Invalid controller type %d\n", pThis->enmCtrlType)); return pHlp->pfnSSMPutU32(pSSM, UINT32_MAX); } /** * @callback_method_impl{FNSSMDEVLOADDONE} */ static DECLCALLBACK(int) lsilogicR3LoadDone(PPDMDEVINS pDevIns, PSSMHANDLE pSSM) { RT_NOREF(pSSM); PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); lsilogicR3Kick(pDevIns, pThis); return VINF_SUCCESS; } /** * @callback_method_impl{FNSSMDEVLOADEXEC} */ static DECLCALLBACK(int) lsilogicR3LoadExec(PPDMDEVINS pDevIns, PSSMHANDLE pSSM, uint32_t uVersion, uint32_t uPass) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); PLSILOGICSCSICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC); PCPDMDEVHLPR3 pHlp = pDevIns->pHlpR3; int rc; if ( uVersion > LSILOGIC_SAVED_STATE_VERSION || uVersion < LSILOGIC_SAVED_STATE_VERSION_VBOX_30) return VERR_SSM_UNSUPPORTED_DATA_UNIT_VERSION; /* device config */ if (uVersion > LSILOGIC_SAVED_STATE_VERSION_PRE_SAS) { LSILOGICCTRLTYPE enmCtrlType; uint32_t cDeviceStates, cPorts; PDMDEVHLP_SSM_GET_ENUM32_RET(pHlp, pSSM, enmCtrlType, LSILOGICCTRLTYPE); pHlp->pfnSSMGetU32(pSSM, &cDeviceStates); rc = pHlp->pfnSSMGetU32(pSSM, &cPorts); AssertRCReturn(rc, rc); if (enmCtrlType != pThis->enmCtrlType) return pHlp->pfnSSMSetCfgError(pSSM, RT_SRC_POS, N_("Target config mismatch (Controller type): config=%d state=%d"), pThis->enmCtrlType, enmCtrlType); if (cDeviceStates != pThis->cDeviceStates) return pHlp->pfnSSMSetCfgError(pSSM, RT_SRC_POS, N_("Target config mismatch (Device states): config=%u state=%u"), pThis->cDeviceStates, cDeviceStates); if (cPorts != pThis->cPorts) return pHlp->pfnSSMSetCfgError(pSSM, RT_SRC_POS, N_("Target config mismatch (Ports): config=%u state=%u"), pThis->cPorts, cPorts); } if (uVersion > LSILOGIC_SAVED_STATE_VERSION_VBOX_30) { for (unsigned i = 0; i < pThis->cDeviceStates; i++) { bool fPresent; rc = pHlp->pfnSSMGetBool(pSSM, &fPresent); AssertRCReturn(rc, rc); if (fPresent != (pThisCC->paDeviceStates[i].pDrvBase != NULL)) return pHlp->pfnSSMSetCfgError(pSSM, RT_SRC_POS, N_("Target %u config mismatch: config=%RTbool state=%RTbool"), i, pThisCC->paDeviceStates[i].pDrvBase != NULL, fPresent); } } if (uPass != SSM_PASS_FINAL) return VINF_SUCCESS; /* Every device first. */ for (unsigned i = 0; i < pThis->cDeviceStates; i++) { PLSILOGICDEVICE pDevice = &pThisCC->paDeviceStates[i]; AssertMsg(!pDevice->cOutstandingRequests, ("There are still outstanding requests on this device\n")); pHlp->pfnSSMGetU32V(pSSM, &pDevice->cOutstandingRequests); } /* Now the main device state. */ PDMDEVHLP_SSM_GET_ENUM32_RET(pHlp, pSSM, pThis->enmState, LSILOGICSTATE); PDMDEVHLP_SSM_GET_ENUM32_RET(pHlp, pSSM, pThis->enmWhoInit, LSILOGICWHOINIT); if (uVersion <= LSILOGIC_SAVED_STATE_VERSION_BOOL_DOORBELL) { /* * The doorbell status flag distinguishes only between * doorbell not in use or a Function handshake is currently in progress. */ bool fDoorbellInProgress = false; rc = pHlp->pfnSSMGetBool(pSSM, &fDoorbellInProgress); AssertRCReturn(rc, rc); if (fDoorbellInProgress) pThis->enmDoorbellState = LSILOGICDOORBELLSTATE_FN_HANDSHAKE; else pThis->enmDoorbellState = LSILOGICDOORBELLSTATE_NOT_IN_USE; } else PDMDEVHLP_SSM_GET_ENUM32_RET(pHlp, pSSM, pThis->enmDoorbellState, LSILOGICDOORBELLSTATE); pHlp->pfnSSMGetBool(pSSM, &pThis->fDiagnosticEnabled); pHlp->pfnSSMGetBool(pSSM, &pThis->fNotificationSent); pHlp->pfnSSMGetBool(pSSM, &pThis->fEventNotificationEnabled); pHlp->pfnSSMGetU32V(pSSM, &pThis->uInterruptMask); pHlp->pfnSSMGetU32V(pSSM, &pThis->uInterruptStatus); for (unsigned i = 0; i < RT_ELEMENTS(pThis->aMessage); i++) pHlp->pfnSSMGetU32(pSSM, &pThis->aMessage[i]); pHlp->pfnSSMGetU32(pSSM, &pThis->iMessage); pHlp->pfnSSMGetU32(pSSM, &pThis->cMessage); pHlp->pfnSSMGetMem(pSSM, &pThis->ReplyBuffer, sizeof(pThis->ReplyBuffer)); pHlp->pfnSSMGetU32(pSSM, &pThis->uNextReplyEntryRead); pHlp->pfnSSMGetU32(pSSM, &pThis->cReplySize); pHlp->pfnSSMGetU16(pSSM, &pThis->u16IOCFaultCode); pHlp->pfnSSMGetU32(pSSM, &pThis->u32HostMFAHighAddr); pHlp->pfnSSMGetU32(pSSM, &pThis->u32SenseBufferHighAddr); pHlp->pfnSSMGetU8(pSSM, &pThis->cMaxDevices); pHlp->pfnSSMGetU8(pSSM, &pThis->cMaxBuses); pHlp->pfnSSMGetU16(pSSM, &pThis->cbReplyFrame); pHlp->pfnSSMGetU32(pSSM, &pThis->iDiagnosticAccess); uint32_t cReplyQueueEntries, cRequestQueueEntries; pHlp->pfnSSMGetU32(pSSM, &cReplyQueueEntries); rc = pHlp->pfnSSMGetU32(pSSM, &cRequestQueueEntries); AssertRCReturn(rc, rc); if ( cReplyQueueEntries != pThis->cReplyQueueEntries || cRequestQueueEntries != pThis->cRequestQueueEntries) { LogRel(("Changing queue sizes: cReplyQueueEntries=%u cRequestQueuEntries=%u\n", cReplyQueueEntries, cRequestQueueEntries)); if ( cReplyQueueEntries > RT_ELEMENTS(pThis->aReplyFreeQueue) || cReplyQueueEntries < LSILOGICSCSI_REQUEST_QUEUE_DEPTH_MIN || cRequestQueueEntries > RT_ELEMENTS(pThis->aRequestQueue) || cRequestQueueEntries < LSILOGICSCSI_REPLY_QUEUE_DEPTH_MIN) return pHlp->pfnSSMSetCfgError(pSSM, RT_SRC_POS, N_("Out of bounds: cReplyQueueEntries=%u cRequestQueueEntries=%u"), cReplyQueueEntries, cRequestQueueEntries); pThis->cReplyQueueEntries = cReplyQueueEntries; pThis->cRequestQueueEntries = cRequestQueueEntries; } pHlp->pfnSSMGetU32V(pSSM, &pThis->uReplyFreeQueueNextEntryFreeWrite); pHlp->pfnSSMGetU32V(pSSM, &pThis->uReplyFreeQueueNextAddressRead); pHlp->pfnSSMGetU32V(pSSM, &pThis->uReplyPostQueueNextEntryFreeWrite); pHlp->pfnSSMGetU32V(pSSM, &pThis->uReplyPostQueueNextAddressRead); pHlp->pfnSSMGetU32V(pSSM, &pThis->uRequestQueueNextEntryFreeWrite); pHlp->pfnSSMGetU32V(pSSM, &pThis->uRequestQueueNextAddressRead); PMptConfigurationPagesSupported pPages = pThisCC->pConfigurationPages; if (uVersion <= LSILOGIC_SAVED_STATE_VERSION_PRE_SAS) { PMptConfigurationPagesSpi pSpiPages = &pPages->u.SpiPages; MptConfigurationPagesSupported_SSM_V2 ConfigPagesV2; if (pThis->enmCtrlType != LSILOGICCTRLTYPE_SCSI_SPI) return pHlp->pfnSSMSetCfgError(pSSM, RT_SRC_POS, N_("Config mismatch: Expected SPI SCSI controller")); pHlp->pfnSSMGetMem(pSSM, &ConfigPagesV2, sizeof(MptConfigurationPagesSupported_SSM_V2)); pPages->ManufacturingPage0 = ConfigPagesV2.ManufacturingPage0; pPages->ManufacturingPage1 = ConfigPagesV2.ManufacturingPage1; pPages->ManufacturingPage2 = ConfigPagesV2.ManufacturingPage2; pPages->ManufacturingPage3 = ConfigPagesV2.ManufacturingPage3; pPages->ManufacturingPage4 = ConfigPagesV2.ManufacturingPage4; pPages->IOUnitPage0 = ConfigPagesV2.IOUnitPage0; pPages->IOUnitPage1 = ConfigPagesV2.IOUnitPage1; pPages->IOUnitPage2 = ConfigPagesV2.IOUnitPage2; pPages->IOUnitPage3 = ConfigPagesV2.IOUnitPage3; pPages->IOCPage0 = ConfigPagesV2.IOCPage0; pPages->IOCPage1 = ConfigPagesV2.IOCPage1; pPages->IOCPage2 = ConfigPagesV2.IOCPage2; pPages->IOCPage3 = ConfigPagesV2.IOCPage3; pPages->IOCPage4 = ConfigPagesV2.IOCPage4; pPages->IOCPage6 = ConfigPagesV2.IOCPage6; pSpiPages->aPortPages[0].SCSISPIPortPage0 = ConfigPagesV2.aPortPages[0].SCSISPIPortPage0; pSpiPages->aPortPages[0].SCSISPIPortPage1 = ConfigPagesV2.aPortPages[0].SCSISPIPortPage1; pSpiPages->aPortPages[0].SCSISPIPortPage2 = ConfigPagesV2.aPortPages[0].SCSISPIPortPage2; for (unsigned i = 0; i < RT_ELEMENTS(pPages->u.SpiPages.aBuses[0].aDevicePages); i++) { pSpiPages->aBuses[0].aDevicePages[i].SCSISPIDevicePage0 = ConfigPagesV2.aBuses[0].aDevicePages[i].SCSISPIDevicePage0; pSpiPages->aBuses[0].aDevicePages[i].SCSISPIDevicePage1 = ConfigPagesV2.aBuses[0].aDevicePages[i].SCSISPIDevicePage1; pSpiPages->aBuses[0].aDevicePages[i].SCSISPIDevicePage2 = ConfigPagesV2.aBuses[0].aDevicePages[i].SCSISPIDevicePage2; pSpiPages->aBuses[0].aDevicePages[i].SCSISPIDevicePage3 = ConfigPagesV2.aBuses[0].aDevicePages[i].SCSISPIDevicePage3; } } else { /* Queue content */ for (unsigned i = 0; i < pThis->cReplyQueueEntries; i++) pHlp->pfnSSMGetU32V(pSSM, &pThis->aReplyFreeQueue[i]); for (unsigned i = 0; i < pThis->cReplyQueueEntries; i++) pHlp->pfnSSMGetU32V(pSSM, &pThis->aReplyPostQueue[i]); for (unsigned i = 0; i < pThis->cRequestQueueEntries; i++) pHlp->pfnSSMGetU32V(pSSM, &pThis->aRequestQueue[i]); pHlp->pfnSSMGetU16(pSSM, &pThis->u16NextHandle); if (uVersion > LSILOGIC_SAVED_STATE_VERSION_PRE_DIAG_MEM) { /* Save diagnostic memory register and data regions. */ pHlp->pfnSSMGetU32(pSSM, &pThis->u32DiagMemAddr); uint32_t cMemRegions = 0; rc = pHlp->pfnSSMGetU32(pSSM, &cMemRegions); AssertLogRelRCReturn(rc, rc); while (cMemRegions) { uint32_t u32AddrStart = 0; pHlp->pfnSSMGetU32(pSSM, &u32AddrStart); uint32_t u32AddrEnd = 0; rc = pHlp->pfnSSMGetU32(pSSM, &u32AddrEnd); AssertLogRelRCReturn(rc, rc); uint32_t cRegion = u32AddrEnd - u32AddrStart + 1; PLSILOGICMEMREGN pRegion = (PLSILOGICMEMREGN)RTMemAllocZ(RT_UOFFSETOF_DYN(LSILOGICMEMREGN, au32Data[cRegion])); if (pRegion) { pRegion->u32AddrStart = u32AddrStart; pRegion->u32AddrEnd = u32AddrEnd; pHlp->pfnSSMGetMem(pSSM, &pRegion->au32Data[0], cRegion * sizeof(uint32_t)); lsilogicR3MemRegionInsert(pThisCC, pRegion); pThisCC->cbMemRegns += cRegion * sizeof(uint32_t); } else { /* Leave a log message but continue. */ LogRel(("LsiLogic: Out of memory while restoring the state, might not work as expected\n")); pHlp->pfnSSMSkip(pSSM, cRegion * sizeof(uint32_t)); } cMemRegions--; } } /* Configuration pages */ pHlp->pfnSSMGetMem(pSSM, &pPages->ManufacturingPage0, sizeof(MptConfigurationPageManufacturing0)); pHlp->pfnSSMGetMem(pSSM, &pPages->ManufacturingPage1, sizeof(MptConfigurationPageManufacturing1)); pHlp->pfnSSMGetMem(pSSM, &pPages->ManufacturingPage2, sizeof(MptConfigurationPageManufacturing2)); pHlp->pfnSSMGetMem(pSSM, &pPages->ManufacturingPage3, sizeof(MptConfigurationPageManufacturing3)); pHlp->pfnSSMGetMem(pSSM, &pPages->ManufacturingPage4, sizeof(MptConfigurationPageManufacturing4)); pHlp->pfnSSMGetMem(pSSM, &pPages->ManufacturingPage5, sizeof(MptConfigurationPageManufacturing5)); pHlp->pfnSSMGetMem(pSSM, &pPages->ManufacturingPage6, sizeof(MptConfigurationPageManufacturing6)); pHlp->pfnSSMGetMem(pSSM, &pPages->ManufacturingPage8, sizeof(MptConfigurationPageManufacturing8)); pHlp->pfnSSMGetMem(pSSM, &pPages->ManufacturingPage9, sizeof(MptConfigurationPageManufacturing9)); pHlp->pfnSSMGetMem(pSSM, &pPages->ManufacturingPage10, sizeof(MptConfigurationPageManufacturing10)); pHlp->pfnSSMGetMem(pSSM, &pPages->IOUnitPage0, sizeof(MptConfigurationPageIOUnit0)); pHlp->pfnSSMGetMem(pSSM, &pPages->IOUnitPage1, sizeof(MptConfigurationPageIOUnit1)); pHlp->pfnSSMGetMem(pSSM, &pPages->IOUnitPage2, sizeof(MptConfigurationPageIOUnit2)); pHlp->pfnSSMGetMem(pSSM, &pPages->IOUnitPage3, sizeof(MptConfigurationPageIOUnit3)); pHlp->pfnSSMGetMem(pSSM, &pPages->IOUnitPage4, sizeof(MptConfigurationPageIOUnit4)); pHlp->pfnSSMGetMem(pSSM, &pPages->IOCPage0, sizeof(MptConfigurationPageIOC0)); pHlp->pfnSSMGetMem(pSSM, &pPages->IOCPage1, sizeof(MptConfigurationPageIOC1)); pHlp->pfnSSMGetMem(pSSM, &pPages->IOCPage2, sizeof(MptConfigurationPageIOC2)); pHlp->pfnSSMGetMem(pSSM, &pPages->IOCPage3, sizeof(MptConfigurationPageIOC3)); pHlp->pfnSSMGetMem(pSSM, &pPages->IOCPage4, sizeof(MptConfigurationPageIOC4)); pHlp->pfnSSMGetMem(pSSM, &pPages->IOCPage6, sizeof(MptConfigurationPageIOC6)); pHlp->pfnSSMGetMem(pSSM, &pPages->BIOSPage1, sizeof(MptConfigurationPageBIOS1)); pHlp->pfnSSMGetMem(pSSM, &pPages->BIOSPage2, sizeof(MptConfigurationPageBIOS2)); pHlp->pfnSSMGetMem(pSSM, &pPages->BIOSPage4, sizeof(MptConfigurationPageBIOS4)); /* Device dependent pages */ if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI) { PMptConfigurationPagesSpi pSpiPages = &pPages->u.SpiPages; pHlp->pfnSSMGetMem(pSSM, &pSpiPages->aPortPages[0].SCSISPIPortPage0, sizeof(MptConfigurationPageSCSISPIPort0)); pHlp->pfnSSMGetMem(pSSM, &pSpiPages->aPortPages[0].SCSISPIPortPage1, sizeof(MptConfigurationPageSCSISPIPort1)); pHlp->pfnSSMGetMem(pSSM, &pSpiPages->aPortPages[0].SCSISPIPortPage2, sizeof(MptConfigurationPageSCSISPIPort2)); for (unsigned i = 0; i < RT_ELEMENTS(pSpiPages->aBuses[0].aDevicePages); i++) { pHlp->pfnSSMGetMem(pSSM, &pSpiPages->aBuses[0].aDevicePages[i].SCSISPIDevicePage0, sizeof(MptConfigurationPageSCSISPIDevice0)); pHlp->pfnSSMGetMem(pSSM, &pSpiPages->aBuses[0].aDevicePages[i].SCSISPIDevicePage1, sizeof(MptConfigurationPageSCSISPIDevice1)); pHlp->pfnSSMGetMem(pSSM, &pSpiPages->aBuses[0].aDevicePages[i].SCSISPIDevicePage2, sizeof(MptConfigurationPageSCSISPIDevice2)); pHlp->pfnSSMGetMem(pSSM, &pSpiPages->aBuses[0].aDevicePages[i].SCSISPIDevicePage3, sizeof(MptConfigurationPageSCSISPIDevice3)); } } else if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) { uint32_t cbPage0, cbPage1, cPHYs, cbManufacturingPage7; PMptConfigurationPagesSas pSasPages = &pPages->u.SasPages; pHlp->pfnSSMGetU32(pSSM, &cbManufacturingPage7); pHlp->pfnSSMGetU32(pSSM, &cbPage0); rc = pHlp->pfnSSMGetU32(pSSM, &cbPage1); AssertRCReturn(rc, rc); if ( (cbPage0 != pSasPages->cbSASIOUnitPage0) || (cbPage1 != pSasPages->cbSASIOUnitPage1) || (cbManufacturingPage7 != pSasPages->cbManufacturingPage7)) return VERR_SSM_LOAD_CONFIG_MISMATCH; AssertPtr(pSasPages->pManufacturingPage7); AssertPtr(pSasPages->pSASIOUnitPage0); AssertPtr(pSasPages->pSASIOUnitPage1); pHlp->pfnSSMGetMem(pSSM, pSasPages->pManufacturingPage7, pSasPages->cbManufacturingPage7); pHlp->pfnSSMGetMem(pSSM, pSasPages->pSASIOUnitPage0, pSasPages->cbSASIOUnitPage0); pHlp->pfnSSMGetMem(pSSM, pSasPages->pSASIOUnitPage1, pSasPages->cbSASIOUnitPage1); pHlp->pfnSSMGetMem(pSSM, &pSasPages->SASIOUnitPage2, sizeof(MptConfigurationPageSASIOUnit2)); pHlp->pfnSSMGetMem(pSSM, &pSasPages->SASIOUnitPage3, sizeof(MptConfigurationPageSASIOUnit3)); rc = pHlp->pfnSSMGetU32(pSSM, &cPHYs); AssertRCReturn(rc, rc); if (cPHYs != pSasPages->cPHYs) return VERR_SSM_LOAD_CONFIG_MISMATCH; AssertPtr(pSasPages->paPHYs); for (unsigned i = 0; i < pSasPages->cPHYs; i++) { pHlp->pfnSSMGetMem(pSSM, &pSasPages->paPHYs[i].SASPHYPage0, sizeof(MptConfigurationPageSASPHY0)); pHlp->pfnSSMGetMem(pSSM, &pSasPages->paPHYs[i].SASPHYPage1, sizeof(MptConfigurationPageSASPHY1)); } /* The number of devices first. */ rc = pHlp->pfnSSMGetU32(pSSM, &pSasPages->cDevices); AssertRCReturn(rc, rc); PMptSASDevice pCurr = pSasPages->pSASDeviceHead; for (unsigned i = 0; i < pSasPages->cDevices; i++) { AssertReturn(pCurr, VERR_SSM_LOAD_CONFIG_MISMATCH); pHlp->pfnSSMGetMem(pSSM, &pCurr->SASDevicePage0, sizeof(MptConfigurationPageSASDevice0)); pHlp->pfnSSMGetMem(pSSM, &pCurr->SASDevicePage1, sizeof(MptConfigurationPageSASDevice1)); rc = pHlp->pfnSSMGetMem(pSSM, &pCurr->SASDevicePage2, sizeof(MptConfigurationPageSASDevice2)); AssertRCReturn(rc, rc); pCurr = pCurr->pNext; } Assert(!pCurr); } else AssertMsgFailed(("Invalid controller type %d\n", pThis->enmCtrlType)); } if (uVersion <= LSILOGIC_SAVED_STATE_VERSION_PRE_VBOXSCSI_REMOVAL) vboxscsiR3LoadExecLegacy(pHlp, pSSM); uint32_t u32; rc = pHlp->pfnSSMGetU32(pSSM, &u32); if (RT_FAILURE(rc)) return rc; AssertMsgReturn(u32 == UINT32_MAX, ("%#x\n", u32), VERR_SSM_DATA_UNIT_FORMAT_CHANGED); return VINF_SUCCESS; } /* * The device level IBASE and LED interfaces. */ /** * @interface_method_impl{PDMILEDPORTS,pfnQueryStatusLed, For a SCSI device.} * * @remarks Called by the scsi driver, proxying the main calls. */ static DECLCALLBACK(int) lsilogicR3DeviceQueryStatusLed(PPDMILEDPORTS pInterface, unsigned iLUN, PPDMLED *ppLed) { PLSILOGICDEVICE pDevice = RT_FROM_MEMBER(pInterface, LSILOGICDEVICE, ILed); if (iLUN == 0) { *ppLed = &pDevice->Led; Assert((*ppLed)->u32Magic == PDMLED_MAGIC); return VINF_SUCCESS; } return VERR_PDM_LUN_NOT_FOUND; } /** * @interface_method_impl{PDMIBASE,pfnQueryInterface} */ static DECLCALLBACK(void *) lsilogicR3DeviceQueryInterface(PPDMIBASE pInterface, const char *pszIID) { PLSILOGICDEVICE pDevice = RT_FROM_MEMBER(pInterface, LSILOGICDEVICE, IBase); PDMIBASE_RETURN_INTERFACE(pszIID, PDMIBASE, &pDevice->IBase); PDMIBASE_RETURN_INTERFACE(pszIID, PDMIMEDIAPORT, &pDevice->IMediaPort); PDMIBASE_RETURN_INTERFACE(pszIID, PDMIMEDIAEXPORT, &pDevice->IMediaExPort); PDMIBASE_RETURN_INTERFACE(pszIID, PDMILEDPORTS, &pDevice->ILed); return NULL; } /* * The controller level IBASE and LED interfaces. */ /** * Gets the pointer to the status LED of a unit. * * @returns VBox status code. * @param pInterface Pointer to the interface structure containing the called function pointer. * @param iLUN The unit which status LED we desire. * @param ppLed Where to store the LED pointer. */ static DECLCALLBACK(int) lsilogicR3StatusQueryStatusLed(PPDMILEDPORTS pInterface, unsigned iLUN, PPDMLED *ppLed) { PLSILOGICSCSICC pThisCC = RT_FROM_MEMBER(pInterface, LSILOGICSCSICC, ILeds); PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pThisCC->pDevIns, PLSILOGICSCSI); if (iLUN < pThis->cDeviceStates) { *ppLed = &pThisCC->paDeviceStates[iLUN].Led; Assert((*ppLed)->u32Magic == PDMLED_MAGIC); return VINF_SUCCESS; } return VERR_PDM_LUN_NOT_FOUND; } /** * @interface_method_impl{PDMIBASE,pfnQueryInterface} */ static DECLCALLBACK(void *) lsilogicR3StatusQueryInterface(PPDMIBASE pInterface, const char *pszIID) { PLSILOGICSCSICC pThisCC = RT_FROM_MEMBER(pInterface, LSILOGICSCSICC, IBase); PDMIBASE_RETURN_INTERFACE(pszIID, PDMIBASE, &pThisCC->IBase); PDMIBASE_RETURN_INTERFACE(pszIID, PDMILEDPORTS, &pThisCC->ILeds); return NULL; } /* * The PDM device interface and some helpers. */ /** * Checks if all asynchronous I/O is finished. * * Used by lsilogicR3Reset, lsilogicR3Suspend and lsilogicR3PowerOff. * * @returns true if quiesced, false if busy. * @param pDevIns The device instance. */ static bool lsilogicR3AllAsyncIOIsFinished(PPDMDEVINS pDevIns) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); PLSILOGICSCSICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC); for (uint32_t i = 0; i < pThis->cDeviceStates; i++) { PLSILOGICDEVICE pThisDevice = &pThisCC->paDeviceStates[i]; if (pThisDevice->pDrvBase) { if (pThisDevice->cOutstandingRequests != 0) return false; } } return true; } /** * @callback_method_impl{FNPDMDEVASYNCNOTIFY, * Callback employed by lsilogicR3Suspend and lsilogicR3PowerOff.} */ static DECLCALLBACK(bool) lsilogicR3IsAsyncSuspendOrPowerOffDone(PPDMDEVINS pDevIns) { if (!lsilogicR3AllAsyncIOIsFinished(pDevIns)) return false; PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); ASMAtomicWriteBool(&pThis->fSignalIdle, false); return true; } /** * Common worker for ahciR3Suspend and ahciR3PowerOff. */ static void lsilogicR3SuspendOrPowerOff(PPDMDEVINS pDevIns) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); PLSILOGICSCSICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC); ASMAtomicWriteBool(&pThis->fSignalIdle, true); if (!lsilogicR3AllAsyncIOIsFinished(pDevIns)) PDMDevHlpSetAsyncNotification(pDevIns, lsilogicR3IsAsyncSuspendOrPowerOffDone); else { ASMAtomicWriteBool(&pThis->fSignalIdle, false); AssertMsg(!pThis->fNotificationSent, ("The PDM Queue should be empty at this point\n")); } for (uint32_t i = 0; i < pThis->cDeviceStates; i++) { PLSILOGICDEVICE pThisDevice = &pThisCC->paDeviceStates[i]; if (pThisDevice->pDrvMediaEx) pThisDevice->pDrvMediaEx->pfnNotifySuspend(pThisDevice->pDrvMediaEx); } } /** * @interface_method_impl{PDMDEVREG,pfnSuspend} */ static DECLCALLBACK(void) lsilogicR3Suspend(PPDMDEVINS pDevIns) { Log(("lsilogicR3Suspend\n")); lsilogicR3SuspendOrPowerOff(pDevIns); } /** * @interface_method_impl{PDMDEVREG,pfnResume} */ static DECLCALLBACK(void) lsilogicR3Resume(PPDMDEVINS pDevIns) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); Log(("lsilogicR3Resume\n")); lsilogicR3Kick(pDevIns, pThis); } /** * @interface_method_impl{PDMDEVREG,pfnDetach} * * One harddisk at one port has been unplugged. * The VM is suspended at this point. */ static DECLCALLBACK(void) lsilogicR3Detach(PPDMDEVINS pDevIns, unsigned iLUN, uint32_t fFlags) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); PLSILOGICSCSICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC); Log(("%s: iLUN=%#x\n", __FUNCTION__, iLUN)); RT_NOREF(fFlags); AssertMsg(fFlags & PDM_TACH_FLAGS_NOT_HOT_PLUG, ("LsiLogic: Device does not support hotplugging\n")); if (iLUN >= pThis->cDeviceStates) return; /* * Zero some important members. */ PLSILOGICDEVICE pDevice = &pThisCC->paDeviceStates[iLUN]; pDevice->pDrvBase = NULL; pDevice->pDrvMedia = NULL; pDevice->pDrvMediaEx = NULL; } /** * @interface_method_impl{PDMDEVREG,pfnAttach} */ static DECLCALLBACK(int) lsilogicR3Attach(PPDMDEVINS pDevIns, unsigned iLUN, uint32_t fFlags) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); PLSILOGICSCSICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC); PLSILOGICDEVICE pDevice = &pThisCC->paDeviceStates[iLUN]; int rc; if (iLUN >= pThis->cDeviceStates) return VERR_PDM_LUN_NOT_FOUND; AssertMsgReturn(fFlags & PDM_TACH_FLAGS_NOT_HOT_PLUG, ("LsiLogic: Device does not support hotplugging\n"), VERR_INVALID_PARAMETER); /* the usual paranoia */ AssertRelease(!pDevice->pDrvBase); AssertRelease(!pDevice->pDrvMedia); AssertRelease(!pDevice->pDrvMediaEx); Assert(pDevice->iLUN == iLUN); /* * Try attach the block device and get the interfaces, * required as well as optional. */ rc = PDMDevHlpDriverAttach(pDevIns, pDevice->iLUN, &pDevice->IBase, &pDevice->pDrvBase, NULL); if (RT_SUCCESS(rc)) { /* Query the media interface. */ pDevice->pDrvMedia = PDMIBASE_QUERY_INTERFACE(pDevice->pDrvBase, PDMIMEDIA); AssertMsgReturn(RT_VALID_PTR(pDevice->pDrvMedia), ("LsiLogic configuration error: LUN#%d misses the basic media interface!\n", pDevice->iLUN), VERR_PDM_MISSING_INTERFACE); /* Get the extended media interface. */ pDevice->pDrvMediaEx = PDMIBASE_QUERY_INTERFACE(pDevice->pDrvBase, PDMIMEDIAEX); AssertMsgReturn(RT_VALID_PTR(pDevice->pDrvMediaEx), ("LsiLogic configuration error: LUN#%d misses the extended media interface!\n", pDevice->iLUN), VERR_PDM_MISSING_INTERFACE); rc = pDevice->pDrvMediaEx->pfnIoReqAllocSizeSet(pDevice->pDrvMediaEx, sizeof(LSILOGICREQ)); AssertMsgRCReturn(rc, ("LsiLogic configuration error: LUN#%u: Failed to set I/O request size!", pDevice->iLUN), rc); } else AssertMsgFailed(("Failed to attach LUN#%d. rc=%Rrc\n", pDevice->iLUN, rc)); if (RT_FAILURE(rc)) { pDevice->pDrvBase = NULL; pDevice->pDrvMedia = NULL; pDevice->pDrvMediaEx = NULL; } return rc; } /** * Common reset worker. * * @param pDevIns The device instance data. */ static void lsilogicR3ResetCommon(PPDMDEVINS pDevIns) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); PLSILOGICSCSICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC); int rc; rc = lsilogicR3HardReset(pDevIns, pThis, pThisCC); AssertRC(rc); } /** * @callback_method_impl{FNPDMDEVASYNCNOTIFY, * Callback employed by lsilogicR3Reset.} */ static DECLCALLBACK(bool) lsilogicR3IsAsyncResetDone(PPDMDEVINS pDevIns) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); if (!lsilogicR3AllAsyncIOIsFinished(pDevIns)) return false; ASMAtomicWriteBool(&pThis->fSignalIdle, false); lsilogicR3ResetCommon(pDevIns); return true; } /** * @interface_method_impl{PDMDEVREG,pfnReset} */ static DECLCALLBACK(void) lsilogicR3Reset(PPDMDEVINS pDevIns) { PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); ASMAtomicWriteBool(&pThis->fSignalIdle, true); if (!lsilogicR3AllAsyncIOIsFinished(pDevIns)) PDMDevHlpSetAsyncNotification(pDevIns, lsilogicR3IsAsyncResetDone); else { ASMAtomicWriteBool(&pThis->fSignalIdle, false); lsilogicR3ResetCommon(pDevIns); } } /** * @interface_method_impl{PDMDEVREG,pfnPowerOff} */ static DECLCALLBACK(void) lsilogicR3PowerOff(PPDMDEVINS pDevIns) { Log(("lsilogicR3PowerOff\n")); lsilogicR3SuspendOrPowerOff(pDevIns); } /** * @interface_method_impl{PDMDEVREG,pfnDestruct} */ static DECLCALLBACK(int) lsilogicR3Destruct(PPDMDEVINS pDevIns) { PDMDEV_CHECK_VERSIONS_RETURN_QUIET(pDevIns); PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); PLSILOGICSCSICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC); PDMDevHlpCritSectDelete(pDevIns, &pThis->ReplyFreeQueueCritSect); PDMDevHlpCritSectDelete(pDevIns, &pThis->ReplyPostQueueCritSect); PDMDevHlpCritSectDelete(pDevIns, &pThis->RequestQueueCritSect); PDMDevHlpCritSectDelete(pDevIns, &pThis->ReplyFreeQueueWriteCritSect); if (RTCritSectIsInitialized(&pThisCC->CritSectMemRegns)) RTCritSectDelete(&pThisCC->CritSectMemRegns); RTMemFree(pThisCC->paDeviceStates); pThisCC->paDeviceStates = NULL; if (pThis->hEvtProcess != NIL_SUPSEMEVENT) { PDMDevHlpSUPSemEventClose(pDevIns, pThis->hEvtProcess); pThis->hEvtProcess = NIL_SUPSEMEVENT; } lsilogicR3ConfigurationPagesFree(pThis, pThisCC); lsilogicR3MemRegionsFree(pThisCC); return VINF_SUCCESS; } /** * @interface_method_impl{PDMDEVREG,pfnConstruct} */ static DECLCALLBACK(int) lsilogicR3Construct(PPDMDEVINS pDevIns, int iInstance, PCFGMNODE pCfg) { PDMDEV_CHECK_VERSIONS_RETURN(pDevIns); PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); PLSILOGICSCSICC pThisCC = PDMDEVINS_2_DATA_CC(pDevIns, PLSILOGICSCSICC); PCPDMDEVHLPR3 pHlp = pDevIns->pHlpR3; int rc = VINF_SUCCESS; /* * Initialize enought of the state to make the destructure not trip up. */ pThis->hEvtProcess = NIL_SUPSEMEVENT; RTListInit(&pThisCC->ListMemRegns); pThis->hMmioReg = NIL_IOMMMIOHANDLE; pThis->hMmioDiag = NIL_IOMMMIOHANDLE; pThis->hIoPortsReg = NIL_IOMIOPORTHANDLE; pThis->hIoPortsBios = NIL_IOMIOPORTHANDLE; pThisCC->pDevIns = pDevIns; pThisCC->IBase.pfnQueryInterface = lsilogicR3StatusQueryInterface; pThisCC->ILeds.pfnQueryStatusLed = lsilogicR3StatusQueryStatusLed; /* * Validate and read configuration. */ PDMDEV_VALIDATE_CONFIG_RETURN(pDevIns, "ReplyQueueDepth|" "RequestQueueDepth|" "ControllerType|" "NumPorts|" "Bootable", /* Keep it for legacy configs, even though it doesn't do anything anymore, see @bugref{4841}. */ ""); rc = pHlp->pfnCFGMQueryU32Def(pCfg, "ReplyQueueDepth", &pThis->cReplyQueueEntries, LSILOGICSCSI_REPLY_QUEUE_DEPTH_DEFAULT); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("LsiLogic configuration error: failed to read ReplyQueue as integer")); if ( pThis->cReplyQueueEntries < LSILOGICSCSI_REPLY_QUEUE_DEPTH_MIN || pThis->cReplyQueueEntries > LSILOGICSCSI_REPLY_QUEUE_DEPTH_MAX - 1 /* see +1 later in the function */) return PDMDevHlpVMSetError(pDevIns, VERR_OUT_OF_RANGE, RT_SRC_POS, N_("LsiLogic configuration error: 'ReplyQueueDepth' = %u is out of ranage (%u..%u)"), pThis->cReplyQueueEntries, LSILOGICSCSI_REPLY_QUEUE_DEPTH_MIN, LSILOGICSCSI_REPLY_QUEUE_DEPTH_MAX - 1); Log(("%s: ReplyQueueDepth=%u\n", __FUNCTION__, pThis->cReplyQueueEntries)); rc = pHlp->pfnCFGMQueryU32Def(pCfg, "RequestQueueDepth", &pThis->cRequestQueueEntries, LSILOGICSCSI_REQUEST_QUEUE_DEPTH_DEFAULT); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("LsiLogic configuration error: failed to read RequestQueue as integer")); if ( pThis->cRequestQueueEntries < LSILOGICSCSI_REQUEST_QUEUE_DEPTH_MIN || pThis->cRequestQueueEntries > LSILOGICSCSI_REQUEST_QUEUE_DEPTH_MAX - 1 /* see +1 later in the function */) return PDMDevHlpVMSetError(pDevIns, VERR_OUT_OF_RANGE, RT_SRC_POS, N_("LsiLogic configuration error: 'RequestQueue' = %u is out of ranage (%u..%u)"), pThis->cRequestQueueEntries, LSILOGICSCSI_REQUEST_QUEUE_DEPTH_MIN, LSILOGICSCSI_REQUEST_QUEUE_DEPTH_MIN - 1); Log(("%s: RequestQueueDepth=%u\n", __FUNCTION__, pThis->cRequestQueueEntries)); char szCtrlType[64]; rc = pHlp->pfnCFGMQueryStringDef(pCfg, "ControllerType", szCtrlType, sizeof(szCtrlType), LSILOGICSCSI_PCI_SPI_CTRLNAME); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("LsiLogic configuration error: failed to read ControllerType as string")); Log(("%s: ControllerType=%s\n", __FUNCTION__, szCtrlType)); rc = lsilogicR3GetCtrlTypeFromString(pThis, szCtrlType); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("LsiLogic configuration error: failed to determine controller type from string")); char szDevTag[20]; RTStrPrintf(szDevTag, sizeof(szDevTag), "LSILOGIC%s-%u", pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI ? "SPI" : "SAS", iInstance); rc = pHlp->pfnCFGMQueryU8(pCfg, "NumPorts", &pThis->cPorts); if (rc == VERR_CFGM_VALUE_NOT_FOUND) { if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI) pThis->cPorts = LSILOGICSCSI_PCI_SPI_PORTS_MAX; else if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) pThis->cPorts = LSILOGICSCSI_PCI_SAS_PORTS_DEFAULT; else AssertMsgFailed(("Invalid controller type: %d\n", pThis->enmCtrlType)); } else if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("LsiLogic configuration error: failed to read NumPorts as integer")); /* Init static parts. */ PPDMPCIDEV pPciDev = pDevIns->apPciDevs[0]; PDMPCIDEV_ASSERT_VALID(pDevIns, pPciDev); PDMPciDevSetVendorId(pPciDev, LSILOGICSCSI_PCI_VENDOR_ID); /* LsiLogic */ if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI) { PDMPciDevSetDeviceId(pPciDev, LSILOGICSCSI_PCI_SPI_DEVICE_ID); /* LSI53C1030 */ PDMPciDevSetSubSystemVendorId(pPciDev, LSILOGICSCSI_PCI_SPI_SUBSYSTEM_VENDOR_ID); PDMPciDevSetSubSystemId(pPciDev, LSILOGICSCSI_PCI_SPI_SUBSYSTEM_ID); } else if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) { PDMPciDevSetDeviceId(pPciDev, LSILOGICSCSI_PCI_SAS_DEVICE_ID); /* SAS1068 */ PDMPciDevSetSubSystemVendorId(pPciDev, LSILOGICSCSI_PCI_SAS_SUBSYSTEM_VENDOR_ID); PDMPciDevSetSubSystemId(pPciDev, LSILOGICSCSI_PCI_SAS_SUBSYSTEM_ID); } else AssertMsgFailed(("Invalid controller type: %d\n", pThis->enmCtrlType)); PDMPciDevSetClassProg(pPciDev, 0x00); /* SCSI */ PDMPciDevSetClassSub(pPciDev, 0x00); /* SCSI */ PDMPciDevSetClassBase(pPciDev, 0x01); /* Mass storage */ PDMPciDevSetInterruptPin(pPciDev, 0x01); /* Interrupt pin A */ # ifdef VBOX_WITH_MSI_DEVICES PDMPciDevSetStatus(pPciDev, VBOX_PCI_STATUS_CAP_LIST); PDMPciDevSetCapabilityList(pPciDev, 0x80); # endif /* * Create critical sections protecting the reply post and free queues. */ rc = PDMDevHlpCritSectInit(pDevIns, &pThis->ReplyFreeQueueCritSect, RT_SRC_POS, "%sRFQ", szDevTag); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("LsiLogic: cannot create critical section for reply free queue")); rc = PDMDevHlpCritSectInit(pDevIns, &pThis->ReplyPostQueueCritSect, RT_SRC_POS, "%sRPQ", szDevTag); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("LsiLogic: cannot create critical section for reply post queue")); rc = PDMDevHlpCritSectInit(pDevIns, &pThis->RequestQueueCritSect, RT_SRC_POS, "%sRQ", szDevTag); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("LsiLogic: cannot create critical section for request queue")); rc = PDMDevHlpCritSectInit(pDevIns, &pThis->ReplyFreeQueueWriteCritSect, RT_SRC_POS, "%sRFQW", szDevTag); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("LsiLogic: cannot create critical section for reply free queue write access")); /* * Critical section protecting the memory regions. */ rc = RTCritSectInit(&pThisCC->CritSectMemRegns); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("LsiLogic: Failed to initialize critical section protecting the memory regions")); /* * Register the PCI device, it's I/O regions. */ rc = PDMDevHlpPCIRegister(pDevIns, pPciDev); if (RT_FAILURE(rc)) return rc; # ifdef VBOX_WITH_MSI_DEVICES PDMMSIREG MsiReg; RT_ZERO(MsiReg); /* use this code for MSI-X support */ # if 0 MsiReg.cMsixVectors = 1; MsiReg.iMsixCapOffset = 0x80; MsiReg.iMsixNextOffset = 0x00; MsiReg.iMsixBar = 3; Assert(pDevIns->pReg->cMaxMsixVectors >= MsiReg.cMsixVectors); /* fix device registration when enabling this */ # else MsiReg.cMsiVectors = 1; MsiReg.iMsiCapOffset = 0x80; MsiReg.iMsiNextOffset = 0x00; # endif rc = PDMDevHlpPCIRegisterMsi(pDevIns, &MsiReg); if (RT_FAILURE (rc)) { /* That's OK, we can work without MSI */ PDMPciDevSetCapabilityList(pPciDev, 0x0); } # endif /* Region #0: I/O ports. */ rc = PDMDevHlpPCIIORegionCreateIo(pDevIns, 0 /*iPciRegion*/, LSILOGIC_PCI_SPACE_IO_SIZE, lsilogicIOPortWrite, lsilogicIOPortRead, NULL /*pvUser*/, pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI ? "LsiLogic" : "LsiLogicSas", NULL /*paExtDesc*/, &pThis->hIoPortsReg); AssertRCReturn(rc, rc); /* Region #1: MMIO. * * Non-4-byte read access to LSILOGIC_REG_REPLY_QUEUE may cause real strange behavior * because the data is part of a physical guest address. But some drivers use 1-byte * access to scan for SCSI controllers. So, we simplify our code by telling IOM to * read DWORDs. * * Regarding writes, we couldn't find anything specific in the specs about what should * happen. So far we've ignored unaligned writes and assumed the missing bytes of * byte and word access to be zero. We suspect that IOMMMIO_FLAGS_WRITE_ONLY_DWORD * or IOMMMIO_FLAGS_WRITE_DWORD_ZEROED would be the most appropriate here, but since we * don't have real hw to test one, the old behavior is kept exactly like it used to be. */ /** @todo Check out unaligned writes and non-dword writes on real LsiLogic * hardware. */ rc = PDMDevHlpPCIIORegionCreateMmio(pDevIns, 1 /*iPciRegion*/, LSILOGIC_PCI_SPACE_MEM_SIZE, PCI_ADDRESS_SPACE_MEM, lsilogicMMIOWrite, lsilogicMMIORead, NULL /*pvUser*/, IOMMMIO_FLAGS_READ_DWORD | IOMMMIO_FLAGS_WRITE_PASSTHRU, pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI ? "LsiLogic" : "LsiLogicSas", &pThis->hMmioReg); AssertRCReturn(rc, rc); /* Region #2: MMIO - Diag. */ rc = PDMDevHlpPCIIORegionCreateMmio(pDevIns, 2 /*iPciRegion*/, LSILOGIC_PCI_SPACE_MEM_SIZE, PCI_ADDRESS_SPACE_MEM, lsilogicDiagnosticWrite, lsilogicDiagnosticRead, NULL /*pvUser*/, IOMMMIO_FLAGS_READ_PASSTHRU | IOMMMIO_FLAGS_WRITE_PASSTHRU, pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI ? "LsiLogicDiag" : "LsiLogicSasDiag", &pThis->hMmioDiag); AssertRCReturn(rc, rc); /* * We need one entry free in the queue. */ pThis->cReplyQueueEntries++; AssertLogRelReturn(pThis->cReplyQueueEntries <= RT_ELEMENTS(pThis->aReplyFreeQueue), VERR_INTERNAL_ERROR_3); AssertLogRelReturn(pThis->cReplyQueueEntries <= RT_ELEMENTS(pThis->aReplyPostQueue), VERR_INTERNAL_ERROR_3); pThis->cRequestQueueEntries++; AssertLogRelReturn(pThis->cRequestQueueEntries <= RT_ELEMENTS(pThis->aRequestQueue), VERR_INTERNAL_ERROR_3); /* * Device states. */ if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI) pThis->cDeviceStates = pThis->cPorts * LSILOGICSCSI_PCI_SPI_DEVICES_PER_BUS_MAX; else if (pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SAS) pThis->cDeviceStates = pThis->cPorts * LSILOGICSCSI_PCI_SAS_DEVICES_PER_PORT_MAX; else AssertLogRelMsgFailedReturn(("Invalid controller type: %d\n", pThis->enmCtrlType), VERR_INTERNAL_ERROR_4); /* * Create event semaphore and worker thread. */ rc = PDMDevHlpThreadCreate(pDevIns, &pThisCC->pThreadWrk, pThis, lsilogicR3Worker, lsilogicR3WorkerWakeUp, 0, RTTHREADTYPE_IO, szDevTag); if (RT_FAILURE(rc)) return PDMDevHlpVMSetError(pDevIns, rc, RT_SRC_POS, N_("LsiLogic: Failed to create worker thread %s"), szDevTag); rc = PDMDevHlpSUPSemEventCreate(pDevIns, &pThis->hEvtProcess); if (RT_FAILURE(rc)) return PDMDevHlpVMSetError(pDevIns, rc, RT_SRC_POS, N_("LsiLogic: Failed to create SUP event semaphore")); /* * Allocate device states. */ pThisCC->paDeviceStates = (PLSILOGICDEVICE)RTMemAllocZ(sizeof(LSILOGICDEVICE) * pThis->cDeviceStates); if (!pThisCC->paDeviceStates) return PDMDEV_SET_ERROR(pDevIns, rc, N_("Failed to allocate memory for device states")); for (unsigned i = 0; i < pThis->cDeviceStates; i++) { PLSILOGICDEVICE pDevice = &pThisCC->paDeviceStates[i]; /* Initialize static parts of the device. */ pDevice->iLUN = i; pDevice->pDevIns = pDevIns; pDevice->Led.u32Magic = PDMLED_MAGIC; pDevice->IBase.pfnQueryInterface = lsilogicR3DeviceQueryInterface; pDevice->IMediaPort.pfnQueryDeviceLocation = lsilogicR3QueryDeviceLocation; pDevice->IMediaExPort.pfnIoReqCompleteNotify = lsilogicR3IoReqCompleteNotify; pDevice->IMediaExPort.pfnIoReqCopyFromBuf = lsilogicR3IoReqCopyFromBuf; pDevice->IMediaExPort.pfnIoReqCopyToBuf = lsilogicR3IoReqCopyToBuf; pDevice->IMediaExPort.pfnIoReqQueryBuf = NULL; pDevice->IMediaExPort.pfnIoReqQueryDiscardRanges = NULL; pDevice->IMediaExPort.pfnIoReqStateChanged = lsilogicR3IoReqStateChanged; pDevice->IMediaExPort.pfnMediumEjected = lsilogicR3MediumEjected; pDevice->ILed.pfnQueryStatusLed = lsilogicR3DeviceQueryStatusLed; RTStrPrintf(pDevice->szName, sizeof(pDevice->szName), "Device%u", i); /* Attach SCSI driver. */ rc = PDMDevHlpDriverAttach(pDevIns, pDevice->iLUN, &pDevice->IBase, &pDevice->pDrvBase, pDevice->szName); if (RT_SUCCESS(rc)) { /* Query the media interface. */ pDevice->pDrvMedia = PDMIBASE_QUERY_INTERFACE(pDevice->pDrvBase, PDMIMEDIA); AssertMsgReturn(RT_VALID_PTR(pDevice->pDrvMedia), ("LsiLogic configuration error: LUN#%d misses the basic media interface!\n", pDevice->iLUN), VERR_PDM_MISSING_INTERFACE); /* Get the extended media interface. */ pDevice->pDrvMediaEx = PDMIBASE_QUERY_INTERFACE(pDevice->pDrvBase, PDMIMEDIAEX); AssertMsgReturn(RT_VALID_PTR(pDevice->pDrvMediaEx), ("LsiLogic configuration error: LUN#%d misses the extended media interface!\n", pDevice->iLUN), VERR_PDM_MISSING_INTERFACE); rc = pDevice->pDrvMediaEx->pfnIoReqAllocSizeSet(pDevice->pDrvMediaEx, sizeof(LSILOGICREQ)); if (RT_FAILURE(rc)) return PDMDevHlpVMSetError(pDevIns, rc, RT_SRC_POS, N_("LsiLogic configuration error: LUN#%u: Failed to set I/O request size!"), pDevice->iLUN); } else if (rc == VERR_PDM_NO_ATTACHED_DRIVER) { pDevice->pDrvBase = NULL; rc = VINF_SUCCESS; Log(("LsiLogic: no driver attached to device %s\n", pDevice->szName)); } else { AssertLogRelMsgFailed(("LsiLogic: Failed to attach %s\n", pDevice->szName)); return rc; } } /* * Attach status driver (optional). */ PPDMIBASE pBase; rc = PDMDevHlpDriverAttach(pDevIns, PDM_STATUS_LUN, &pThisCC->IBase, &pBase, "Status Port"); if (RT_SUCCESS(rc)) { pThisCC->pLedsConnector = PDMIBASE_QUERY_INTERFACE(pBase, PDMILEDCONNECTORS); pThisCC->pMediaNotify = PDMIBASE_QUERY_INTERFACE(pBase, PDMIMEDIANOTIFY); } else AssertMsgReturn(rc == VERR_PDM_NO_ATTACHED_DRIVER, ("Failed to attach to status driver. rc=%Rrc\n", rc), PDMDEV_SET_ERROR(pDevIns, rc, N_("LsiLogic cannot attach to status driver"))); /* Register save state handlers. */ rc = PDMDevHlpSSMRegisterEx(pDevIns, LSILOGIC_SAVED_STATE_VERSION, sizeof(*pThis), NULL, NULL, lsilogicR3LiveExec, NULL, NULL, lsilogicR3SaveExec, NULL, NULL, lsilogicR3LoadExec, lsilogicR3LoadDone); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("LsiLogic cannot register save state handlers")); pThis->enmWhoInit = LSILOGICWHOINIT_SYSTEM_BIOS; /* * Register the info item. */ char szTmp[128]; RTStrPrintf(szTmp, sizeof(szTmp), "%s%u", pDevIns->pReg->szName, pDevIns->iInstance); PDMDevHlpDBGFInfoRegister(pDevIns, szTmp, pThis->enmCtrlType == LSILOGICCTRLTYPE_SCSI_SPI ? "LsiLogic SPI info." : "LsiLogic SAS info.", lsilogicR3Info); /* Allocate configuration pages. */ rc = lsilogicR3ConfigurationPagesAlloc(pThis, pThisCC); if (RT_FAILURE(rc)) PDMDEV_SET_ERROR(pDevIns, rc, N_("LsiLogic: Failed to allocate memory for configuration pages")); /* Perform hard reset. */ rc = lsilogicR3HardReset(pDevIns, pThis, pThisCC); AssertRC(rc); return rc; } #else /* !IN_RING3 */ /** * @callback_method_impl{PDMDEVREGR0,pfnConstruct} */ static DECLCALLBACK(int) lsilogicRZConstruct(PPDMDEVINS pDevIns) { PDMDEV_CHECK_VERSIONS_RETURN(pDevIns); PLSILOGICSCSI pThis = PDMDEVINS_2_DATA(pDevIns, PLSILOGICSCSI); /* Setup callbacks for this context: */ int rc = PDMDevHlpIoPortSetUpContext(pDevIns, pThis->hIoPortsReg, lsilogicIOPortWrite, lsilogicIOPortRead, NULL /*pvUser*/); AssertRCReturn(rc, rc); rc = PDMDevHlpMmioSetUpContext(pDevIns, pThis->hMmioReg, lsilogicMMIOWrite, lsilogicMMIORead, NULL /*pvUser*/); AssertRCReturn(rc, rc); rc = PDMDevHlpMmioSetUpContext(pDevIns, pThis->hMmioDiag, lsilogicDiagnosticWrite, lsilogicDiagnosticRead, NULL /*pvUser*/); AssertRCReturn(rc, rc); return VINF_SUCCESS; } #endif /* !IN_RING3 */ /** * The device registration structure - SPI SCSI controller. */ const PDMDEVREG g_DeviceLsiLogicSCSI = { /* .u32Version = */ PDM_DEVREG_VERSION, /* .uReserved0 = */ 0, /* .szName = */ "lsilogicscsi", /* .fFlags = */ PDM_DEVREG_FLAGS_DEFAULT_BITS | PDM_DEVREG_FLAGS_RZ | PDM_DEVREG_FLAGS_NEW_STYLE | PDM_DEVREG_FLAGS_FIRST_SUSPEND_NOTIFICATION | PDM_DEVREG_FLAGS_FIRST_POWEROFF_NOTIFICATION, /* .fClass = */ PDM_DEVREG_CLASS_STORAGE, /* .cMaxInstances = */ ~0U, /* .uSharedVersion = */ 42, /* .cbInstanceShared = */ sizeof(LSILOGICSCSI), /* .cbInstanceCC = */ sizeof(LSILOGICSCSICC), /* .cbInstanceRC = */ sizeof(LSILOGICSCSIRC), /* .cMaxPciDevices = */ 1, /* .cMaxMsixVectors = */ 0, /* .pszDescription = */ "LSI Logic 53c1030 SCSI controller.\n", #if defined(IN_RING3) /* .pszRCMod = */ "VBoxDDRC.rc", /* .pszR0Mod = */ "VBoxDDR0.r0", /* .pfnConstruct = */ lsilogicR3Construct, /* .pfnDestruct = */ lsilogicR3Destruct, /* .pfnRelocate = */ NULL, /* .pfnMemSetup = */ NULL, /* .pfnPowerOn = */ NULL, /* .pfnReset = */ lsilogicR3Reset, /* .pfnSuspend = */ lsilogicR3Suspend, /* .pfnResume = */ lsilogicR3Resume, /* .pfnAttach = */ lsilogicR3Attach, /* .pfnDetach = */ lsilogicR3Detach, /* .pfnQueryInterface = */ NULL, /* .pfnInitComplete = */ NULL, /* .pfnPowerOff = */ lsilogicR3PowerOff, /* .pfnSoftReset = */ NULL, /* .pfnReserved0 = */ NULL, /* .pfnReserved1 = */ NULL, /* .pfnReserved2 = */ NULL, /* .pfnReserved3 = */ NULL, /* .pfnReserved4 = */ NULL, /* .pfnReserved5 = */ NULL, /* .pfnReserved6 = */ NULL, /* .pfnReserved7 = */ NULL, #elif defined(IN_RING0) /* .pfnEarlyConstruct = */ NULL, /* .pfnConstruct = */ lsilogicRZConstruct, /* .pfnDestruct = */ NULL, /* .pfnFinalDestruct = */ NULL, /* .pfnRequest = */ NULL, /* .pfnReserved0 = */ NULL, /* .pfnReserved1 = */ NULL, /* .pfnReserved2 = */ NULL, /* .pfnReserved3 = */ NULL, /* .pfnReserved4 = */ NULL, /* .pfnReserved5 = */ NULL, /* .pfnReserved6 = */ NULL, /* .pfnReserved7 = */ NULL, #elif defined(IN_RC) /* .pfnConstruct = */ lsilogicRZConstruct, /* .pfnReserved0 = */ NULL, /* .pfnReserved1 = */ NULL, /* .pfnReserved2 = */ NULL, /* .pfnReserved3 = */ NULL, /* .pfnReserved4 = */ NULL, /* .pfnReserved5 = */ NULL, /* .pfnReserved6 = */ NULL, /* .pfnReserved7 = */ NULL, #else # error "Not in IN_RING3, IN_RING0 or IN_RC!" #endif /* .u32VersionEnd = */ PDM_DEVREG_VERSION }; /** * The device registration structure - SAS controller. */ const PDMDEVREG g_DeviceLsiLogicSAS = { /* .u32Version = */ PDM_DEVREG_VERSION, /* .uReserved0 = */ 0, /* .szName = */ "lsilogicsas", /* .fFlags = */ PDM_DEVREG_FLAGS_DEFAULT_BITS | PDM_DEVREG_FLAGS_RZ | PDM_DEVREG_FLAGS_NEW_STYLE | PDM_DEVREG_FLAGS_FIRST_SUSPEND_NOTIFICATION | PDM_DEVREG_FLAGS_FIRST_POWEROFF_NOTIFICATION | PDM_DEVREG_FLAGS_FIRST_RESET_NOTIFICATION, /* .fClass = */ PDM_DEVREG_CLASS_STORAGE, /* .cMaxInstances = */ ~0U, /* .uSharedVersion = */ 42, /* .cbInstanceShared = */ sizeof(LSILOGICSCSI), /* .cbInstanceCC = */ sizeof(LSILOGICSCSICC), /* .cbInstanceRC = */ sizeof(LSILOGICSCSIRC), /* .cMaxPciDevices = */ 1, /* .cMaxMsixVectors = */ 0, /* .pszDescription = */ "LSI Logic SAS1068 controller.\n", #if defined(IN_RING3) /* .pszRCMod = */ "VBoxDDRC.rc", /* .pszR0Mod = */ "VBoxDDR0.r0", /* .pfnConstruct = */ lsilogicR3Construct, /* .pfnDestruct = */ lsilogicR3Destruct, /* .pfnRelocate = */ NULL, /* .pfnMemSetup = */ NULL, /* .pfnPowerOn = */ NULL, /* .pfnReset = */ lsilogicR3Reset, /* .pfnSuspend = */ lsilogicR3Suspend, /* .pfnResume = */ lsilogicR3Resume, /* .pfnAttach = */ lsilogicR3Attach, /* .pfnDetach = */ lsilogicR3Detach, /* .pfnQueryInterface = */ NULL, /* .pfnInitComplete = */ NULL, /* .pfnPowerOff = */ lsilogicR3PowerOff, /* .pfnSoftReset = */ NULL, /* .pfnReserved0 = */ NULL, /* .pfnReserved1 = */ NULL, /* .pfnReserved2 = */ NULL, /* .pfnReserved3 = */ NULL, /* .pfnReserved4 = */ NULL, /* .pfnReserved5 = */ NULL, /* .pfnReserved6 = */ NULL, /* .pfnReserved7 = */ NULL, #elif defined(IN_RING0) /* .pfnEarlyConstruct = */ NULL, /* .pfnConstruct = */ lsilogicRZConstruct, /* .pfnDestruct = */ NULL, /* .pfnFinalDestruct = */ NULL, /* .pfnRequest = */ NULL, /* .pfnReserved0 = */ NULL, /* .pfnReserved1 = */ NULL, /* .pfnReserved2 = */ NULL, /* .pfnReserved3 = */ NULL, /* .pfnReserved4 = */ NULL, /* .pfnReserved5 = */ NULL, /* .pfnReserved6 = */ NULL, /* .pfnReserved7 = */ NULL, #elif defined(IN_RC) /* .pfnConstruct = */ lsilogicRZConstruct, /* .pfnReserved0 = */ NULL, /* .pfnReserved1 = */ NULL, /* .pfnReserved2 = */ NULL, /* .pfnReserved3 = */ NULL, /* .pfnReserved4 = */ NULL, /* .pfnReserved5 = */ NULL, /* .pfnReserved6 = */ NULL, /* .pfnReserved7 = */ NULL, #else # error "Not in IN_RING3, IN_RING0 or IN_RC!" #endif /* .u32VersionEnd = */ PDM_DEVREG_VERSION }; #endif /* !VBOX_DEVICE_STRUCT_TESTCASE */