/* $Id: ISCSI.cpp 40229 2012-02-23 12:22:21Z vboxsync $ */ /** @file * iSCSI initiator driver, VD backend. */ /* * Copyright (C) 2006-2011 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. */ /******************************************************************************* * Header Files * *******************************************************************************/ #define LOG_GROUP LOG_GROUP_VD_ISCSI #include #include #include #include #include #include #include #include #include #include #include #include #include #include /******************************************************************************* * Defined Constants And Macros * *******************************************************************************/ /** The maximum number of release log entries per image. */ #define MAX_LOG_REL_ERRORS 1024 /** Default port number to use for iSCSI. */ #define ISCSI_DEFAULT_PORT 3260 /** Converts a number in the range of 0 - 15 into the corresponding hex char. */ #define NUM_2_HEX(b) ('0' + (b) + (((b) > 9) ? 39 : 0)) /** Converts a hex char into the corresponding number in the range 0-15. */ #define HEX_2_NUM(c) (((c) <= '9') ? ((c) - '0') : (((c - 'A' + 10) & 0xf))) /* Converts a base64 char into the corresponding number in the range 0-63. */ #define B64_2_NUM(c) ((c >= 'A' && c <= 'Z') ? (c - 'A') : (c >= 'a' && c <= 'z') ? (c - 'a' + 26) : (c >= '0' && c <= '9') ? (c - '0' + 52) : (c == '+') ? 62 : (c == '/') ? 63 : -1) /** Minimum CHAP_MD5 challenge length in bytes. */ #define CHAP_MD5_CHALLENGE_MIN 16 /** Maximum CHAP_MD5 challenge length in bytes. */ #define CHAP_MD5_CHALLENGE_MAX 24 /** * SCSI peripheral device type. */ typedef enum SCSIDEVTYPE { /** direct-access device. */ SCSI_DEVTYPE_DISK = 0, /** sequential-access device. */ SCSI_DEVTYPE_TAPE, /** printer device. */ SCSI_DEVTYPE_PRINTER, /** processor device. */ SCSI_DEVTYPE_PROCESSOR, /** write-once device. */ SCSI_DEVTYPE_WORM, /** CD/DVD device. */ SCSI_DEVTYPE_CDROM, /** scanner device. */ SCSI_DEVTYPE_SCANNER, /** optical memory device. */ SCSI_DEVTYPE_OPTICAL, /** medium changer. */ SCSI_DEVTYPE_CHANGER, /** communications device. */ SCSI_DEVTYPE_COMMUNICATION, /** storage array controller device. */ SCSI_DEVTYPE_RAIDCTL = 0x0c, /** enclosure services device. */ SCSI_DEVTYPE_ENCLOSURE, /** simplified direct-access device. */ SCSI_DEVTYPE_SIMPLEDISK, /** optical card reader/writer device. */ SCSI_DEVTYPE_OCRW, /** bridge controller device. */ SCSI_DEVTYPE_BRIDGE, /** object-based storage device. */ SCSI_DEVTYPE_OSD } SCSIDEVTYPE; /** Mask for extracting the SCSI device type out of the first byte of the INQUIRY response. */ #define SCSI_DEVTYPE_MASK 0x1f /** Mask to extract the CmdQue bit out of the seventh byte of the INQUIRY response. */ #define SCSI_INQUIRY_CMDQUE_MASK 0x02 /** Maximum PDU payload size we can handle in one piece. Greater or equal than * s_iscsiConfigDefaultWriteSplit. */ #define ISCSI_DATA_LENGTH_MAX _256K /** Maximum PDU size we can handle in one piece. */ #define ISCSI_RECV_PDU_BUFFER_SIZE (ISCSI_DATA_LENGTH_MAX + ISCSI_BHS_SIZE) /** Version of the iSCSI standard which this initiator driver can handle. */ #define ISCSI_MY_VERSION 0 /** Length of ISCSI basic header segment. */ #define ISCSI_BHS_SIZE 48 /** Reserved task tag value. */ #define ISCSI_TASK_TAG_RSVD 0xffffffff /** * iSCSI opcodes. */ typedef enum ISCSIOPCODE { /** NOP-Out. */ ISCSIOP_NOP_OUT = 0x00000000, /** SCSI command. */ ISCSIOP_SCSI_CMD = 0x01000000, /** SCSI task management request. */ ISCSIOP_SCSI_TASKMGMT_REQ = 0x02000000, /** Login request. */ ISCSIOP_LOGIN_REQ = 0x03000000, /** Text request. */ ISCSIOP_TEXT_REQ = 0x04000000, /** SCSI Data-Out. */ ISCSIOP_SCSI_DATA_OUT = 0x05000000, /** Logout request. */ ISCSIOP_LOGOUT_REQ = 0x06000000, /** SNACK request. */ ISCSIOP_SNACK_REQ = 0x10000000, /** NOP-In. */ ISCSIOP_NOP_IN = 0x20000000, /** SCSI response. */ ISCSIOP_SCSI_RES = 0x21000000, /** SCSI Task Management response. */ ISCSIOP_SCSI_TASKMGMT_RES = 0x22000000, /** Login response. */ ISCSIOP_LOGIN_RES = 0x23000000, /** Text response. */ ISCSIOP_TEXT_RES = 0x24000000, /** SCSI Data-In. */ ISCSIOP_SCSI_DATA_IN = 0x25000000, /** Logout response. */ ISCSIOP_LOGOUT_RES = 0x26000000, /** Ready To Transfer (R2T). */ ISCSIOP_R2T = 0x31000000, /** Asynchronous message. */ ISCSIOP_ASYN_MSG = 0x32000000, /** Reject. */ ISCSIOP_REJECT = 0x3f000000 } ISCSIOPCODE; /** Mask for extracting the iSCSI opcode out of the first header word. */ #define ISCSIOP_MASK 0x3f000000 /** ISCSI BHS word 0: Request should be processed immediately. */ #define ISCSI_IMMEDIATE_DELIVERY_BIT 0x40000000 /** ISCSI BHS word 0: This is the final PDU for this request/response. */ #define ISCSI_FINAL_BIT 0x00800000 /** ISCSI BHS word 0: Mask for extracting the CSG. */ #define ISCSI_CSG_MASK 0x000c0000 /** ISCSI BHS word 0: Shift offset for extracting the CSG. */ #define ISCSI_CSG_SHIFT 18 /** ISCSI BHS word 0: Mask for extracting the NSG. */ #define ISCSI_NSG_MASK 0x00030000 /** ISCSI BHS word 0: Shift offset for extracting the NSG. */ #define ISCSI_NSG_SHIFT 16 /** ISCSI BHS word 0: task attribute untagged */ #define ISCSI_TASK_ATTR_UNTAGGED 0x00000000 /** ISCSI BHS word 0: task attribute simple */ #define ISCSI_TASK_ATTR_SIMPLE 0x00010000 /** ISCSI BHS word 0: task attribute ordered */ #define ISCSI_TASK_ATTR_ORDERED 0x00020000 /** ISCSI BHS word 0: task attribute head of queue */ #define ISCSI_TASK_ATTR_HOQ 0x00030000 /** ISCSI BHS word 0: task attribute ACA */ #define ISCSI_TASK_ATTR_ACA 0x00040000 /** ISCSI BHS word 0: transit to next login phase. */ #define ISCSI_TRANSIT_BIT 0x00800000 /** ISCSI BHS word 0: continue with login negotiation. */ #define ISCSI_CONTINUE_BIT 0x00400000 /** ISCSI BHS word 0: residual underflow. */ #define ISCSI_RESIDUAL_UNFL_BIT 0x00020000 /** ISCSI BHS word 0: residual overflow. */ #define ISCSI_RESIDUAL_OVFL_BIT 0x00040000 /** ISCSI BHS word 0: Bidirectional read residual underflow. */ #define ISCSI_BI_READ_RESIDUAL_UNFL_BIT 0x00080000 /** ISCSI BHS word 0: Bidirectional read residual overflow. */ #define ISCSI_BI_READ_RESIDUAL_OVFL_BIT 0x00100000 /** ISCSI BHS word 0: SCSI response mask. */ #define ISCSI_SCSI_RESPONSE_MASK 0x0000ff00 /** ISCSI BHS word 0: SCSI status mask. */ #define ISCSI_SCSI_STATUS_MASK 0x000000ff /** ISCSI BHS word 0: response includes status. */ #define ISCSI_STATUS_BIT 0x00010000 /** Maximum number of scatter/gather segments needed to send a PDU. */ #define ISCSI_SG_SEGMENTS_MAX 4 /** Number of entries in the command table. */ #define ISCSI_CMD_WAITING_ENTRIES 32 /** * iSCSI login status class. */ typedef enum ISCSILOGINSTATUSCLASS { /** Success. */ ISCSI_LOGIN_STATUS_CLASS_SUCCESS = 0, /** Redirection. */ ISCSI_LOGIN_STATUS_CLASS_REDIRECTION, /** Initiator error. */ ISCSI_LOGIN_STATUS_CLASS_INITIATOR_ERROR, /** Target error. */ ISCSI_LOGIN_STATUS_CLASS_TARGET_ERROR } ISCSILOGINSTATUSCLASS; /** * iSCSI connection state. */ typedef enum ISCSISTATE { /** Not having a connection/session at all. */ ISCSISTATE_FREE, /** Currently trying to login. */ ISCSISTATE_IN_LOGIN, /** Normal operation, corresponds roughly to the Full Feature Phase. */ ISCSISTATE_NORMAL, /** Currently trying to logout. */ ISCSISTATE_IN_LOGOUT } ISCSISTATE; /** * iSCSI PDU send flags (and maybe more in the future). */ typedef enum ISCSIPDUFLAGS { /** No special flags */ ISCSIPDU_DEFAULT = 0, /** Do not attempt to re-attach to the target if the connection is lost */ ISCSIPDU_NO_REATTACH = RT_BIT(1) } ISCSIPDUFLAGS; /******************************************************************************* * Structures and Typedefs * *******************************************************************************/ /** * iSCSI login negotiation parameter */ typedef struct ISCSIPARAMETER { /** Name of the parameter. */ const char *pszParamName; /** Value of the parameter. */ const char *pszParamValue; /** Length of the binary parameter. 0=zero-terminated string. */ size_t cbParamValue; } ISCSIPARAMETER; /** * iSCSI Response PDU buffer (scatter). */ typedef struct ISCSIRES { /** Length of PDU segment. */ size_t cbSeg; /** Pointer to PDU segment. */ void *pvSeg; } ISCSIRES; /** Pointer to an iSCSI Response PDU buffer. */ typedef ISCSIRES *PISCSIRES; /** Pointer to a const iSCSI Response PDU buffer. */ typedef ISCSIRES const *PCISCSIRES; /** * iSCSI Request PDU buffer (gather). */ typedef struct ISCSIREQ { /** Length of PDU segment in bytes. */ size_t cbSeg; /** Pointer to PDU segment. */ const void *pcvSeg; } ISCSIREQ; /** Pointer to an iSCSI Request PDU buffer. */ typedef ISCSIREQ *PISCSIREQ; /** Pointer to a const iSCSI Request PDU buffer. */ typedef ISCSIREQ const *PCISCSIREQ; /** * SCSI transfer directions. */ typedef enum SCSIXFER { SCSIXFER_NONE = 0, SCSIXFER_TO_TARGET, SCSIXFER_FROM_TARGET, SCSIXFER_TO_FROM_TARGET } SCSIXFER, *PSCSIXFER; /** Forward declaration. */ typedef struct ISCSIIMAGE *PISCSIIMAGE; /** * SCSI request structure. */ typedef struct SCSIREQ { /** Transfer direction. */ SCSIXFER enmXfer; /** Length of command block. */ size_t cbCDB; /** Length of Initiator2Target data buffer. */ size_t cbI2TData; /** Length of Target2Initiator data buffer. */ size_t cbT2IData; /** Length of sense buffer * This contains the number of sense bytes received upon completion. */ size_t cbSense; /** Completion status of the command. */ uint8_t status; /** Pointer to command block. */ void *pvCDB; /** Pointer to sense buffer. */ void *pvSense; /** Pointer to the Initiator2Target S/G list. */ PRTSGSEG paI2TSegs; /** Number of entries in the I2T S/G list. */ unsigned cI2TSegs; /** Pointer to the Target2Initiator S/G list. */ PRTSGSEG paT2ISegs; /** Number of entries in the T2I S/G list. */ unsigned cT2ISegs; /** S/G buffer for the target to initiator bits. */ RTSGBUF SgBufT2I; } SCSIREQ, *PSCSIREQ; /** * Async request structure holding all necessary data for * request processing. */ typedef struct SCSIREQASYNC { /** I/O context associated with this request. */ PVDIOCTX pIoCtx; /** Pointer to the SCSI request structure. */ PSCSIREQ pScsiReq; /** The CDB. */ uint8_t abCDB[16]; /** The sense buffer. */ uint8_t abSense[96]; /** Status code to return if we got sense data. */ int rcSense; /** Number of retries if the command completes with sense * data before we return with an error. */ unsigned cSenseRetries; /** The number of entries in the I2T S/G list. */ unsigned cI2TSegs; /** The number of entries in the T2I S/G list. */ unsigned cT2ISegs; /** The S/G list - variable in size. * This array holds both the I2T and T2I segments. * The I2T segments are first and the T2I are second. */ RTSGSEG aSegs[1]; } SCSIREQASYNC, *PSCSIREQASYNC; typedef enum ISCSICMDTYPE { /** Process a SCSI request. */ ISCSICMDTYPE_REQ = 0, /** Call a function in the I/O thread. */ ISCSICMDTYPE_EXEC, /** Usual 32bit hack. */ ISCSICMDTYPE_32BIT_HACK = 0x7fffffff } ISCSICMDTYPE; /** The command completion function. */ typedef DECLCALLBACK(void) FNISCSICMDCOMPLETED(PISCSIIMAGE pImage, int rcReq, void *pvUser); /** Pointer to a command completion function. */ typedef FNISCSICMDCOMPLETED *PFNISCSICMDCOMPLETED; /** The command execution function. */ typedef DECLCALLBACK(int) FNISCSIEXEC(void *pvUser); /** Pointer to a command execution function. */ typedef FNISCSIEXEC *PFNISCSIEXEC; /** * Structure used to complete a synchronous request. */ typedef struct ISCSICMDSYNC { /** Event semaphore to wakeup the waiting thread. */ RTSEMEVENT EventSem; /** Status code of the command. */ int rcCmd; } ISCSICMDSYNC, *PISCSICMDSYNC; /** * iSCSI command. * Used to forward requests to the I/O thread * if existing. */ typedef struct ISCSICMD { /** Next one in the list. */ struct ISCSICMD *pNext; /** Assigned ITT. */ uint32_t Itt; /** Completion callback. */ PFNISCSICMDCOMPLETED pfnComplete; /** Opaque user data. */ void *pvUser; /** Command to execute. */ ISCSICMDTYPE enmCmdType; /** Command type dependent data. */ union { /** Process a SCSI request. */ struct { /** The SCSI request to process. */ PSCSIREQ pScsiReq; } ScsiReq; /** Call a function in the I/O thread. */ struct { /** The method to execute. */ PFNISCSIEXEC pfnExec; /** User data. */ void *pvUser; } Exec; } CmdType; } ISCSICMD, *PISCSICMD; /** * Send iSCSI PDU. * Contains all necessary data to send a PDU. */ typedef struct ISCSIPDUTX { /** Pointer to the next PDu to send. */ struct ISCSIPDUTX *pNext; /** The BHS. */ uint32_t aBHS[12]; /** Assigned CmdSN for this PDU. */ uint32_t CmdSN; /** The S/G buffer used for sending. */ RTSGBUF SgBuf; /** Number of bytes to send until the PDU completed. */ size_t cbSgLeft; /** The iSCSI command this PDU belongs to. */ PISCSICMD pIScsiCmd; /** Number of segments in the request segments array. */ unsigned cISCSIReq; /** The request segments - variable in size. */ RTSGSEG aISCSIReq[1]; } ISCSIPDUTX, *PISCSIPDUTX; /** * Block driver instance data. */ typedef struct ISCSIIMAGE { /** Pointer to the filename (location). Not really used. */ const char *pszFilename; /** Pointer to the initiator name. */ char *pszInitiatorName; /** Pointer to the target name. */ char *pszTargetName; /** Pointer to the target address. */ char *pszTargetAddress; /** Pointer to the user name for authenticating the Initiator. */ char *pszInitiatorUsername; /** Pointer to the secret for authenticating the Initiator. */ uint8_t *pbInitiatorSecret; /** Length of the secret for authenticating the Initiator. */ size_t cbInitiatorSecret; /** Pointer to the user name for authenticating the Target. */ char *pszTargetUsername; /** Pointer to the secret for authenticating the Initiator. */ uint8_t *pbTargetSecret; /** Length of the secret for authenticating the Initiator. */ size_t cbTargetSecret; /** Limit for iSCSI writes, essentially limiting the amount of data * written in a single write. This is negotiated with the target, so * the actual size might be smaller. */ uint32_t cbWriteSplit; /** Initiator session identifier. */ uint64_t ISID; /** SCSI Logical Unit Number. */ uint64_t LUN; /** Pointer to the per-disk VD interface list. */ PVDINTERFACE pVDIfsDisk; /** Pointer to the per-image VD interface list. */ PVDINTERFACE pVDIfsImage; /** Error interface. */ PVDINTERFACEERROR pIfError; /** Config interface. */ PVDINTERFACECONFIG pIfConfig; /** I/O interface. */ PVDINTERFACEIOINT pIfIo; /** TCP network stack interface. */ PVDINTERFACETCPNET pIfNet; /** Image open flags. */ unsigned uOpenFlags; /** Number of re-login retries when a connection fails. */ uint32_t cISCSIRetries; /** Sector size on volume. */ uint32_t cbSector; /** Size of volume in sectors. */ uint64_t cVolume; /** Total volume size in bytes. Easier than multiplying the above values all the time. */ uint64_t cbSize; /** Negotiated maximum data length when sending to target. */ uint32_t cbSendDataLength; /** Negotiated maximum data length when receiving from target. */ uint32_t cbRecvDataLength; /** Current state of the connection/session. */ ISCSISTATE state; /** Flag whether the first Login Response PDU has been seen. */ bool FirstRecvPDU; /** Initiator Task Tag of the last iSCSI request PDU. */ uint32_t ITT; /** Sequence number of the last command. */ uint32_t CmdSN; /** Sequence number of the next command expected by the target. */ uint32_t ExpCmdSN; /** Maximum sequence number accepted by the target (determines size of window). */ uint32_t MaxCmdSN; /** Expected sequence number of next status. */ uint32_t ExpStatSN; /** Currently active request. */ PISCSIREQ paCurrReq; /** Segment number of currently active request. */ uint32_t cnCurrReq; /** Pointer to receive PDU buffer. (Freed by RT) */ void *pvRecvPDUBuf; /** Length of receive PDU buffer. */ size_t cbRecvPDUBuf; /** Mutex protecting against concurrent use from several threads. */ RTSEMMUTEX Mutex; /** Pointer to the target hostname. */ char *pszHostname; /** Port to use on the target host. */ uint32_t uPort; /** Socket handle of the TCP connection. */ VDSOCKET Socket; /** Timeout for read operations on the TCP connection (in milliseconds). */ uint32_t uReadTimeout; /** Flag whether to automatically generate the initiator name. */ bool fAutomaticInitiatorName; /** Flag whether to use the host IP stack or DevINIP. */ bool fHostIP; /** Head of request queue */ PISCSICMD pScsiReqQueue; /** Mutex protecting the request queue from concurrent access. */ RTSEMMUTEX MutexReqQueue; /** I/O thread. */ RTTHREAD hThreadIo; /** Flag whether the thread should be still running. */ volatile bool fRunning; /* Flag whether the target supports command queuing. */ bool fCmdQueuingSupported; /** Flag whether extended select is supported. */ bool fExtendedSelectSupported; /** Padding used for aligning the PDUs. */ uint8_t aPadding[4]; /** Socket events to poll for. */ uint32_t fPollEvents; /** Number of bytes to read to complete the current PDU. */ size_t cbRecvPDUResidual; /** Current position in the PDU buffer. */ uint8_t *pbRecvPDUBufCur; /** Flag whether we are currently reading the BHS. */ bool fRecvPDUBHS; /** List of PDUs waiting to get transmitted. */ PISCSIPDUTX pIScsiPDUTxHead; /** Tail of PDUs waiting to get transmitted. */ PISCSIPDUTX pIScsiPDUTxTail; /** PDU we are currently transmitting. */ PISCSIPDUTX pIScsiPDUTxCur; /** Number of commands waiting for an answer from the target. * Used for timeout handling for poll. */ unsigned cCmdsWaiting; /** Table of commands waiting for a response from the target. */ PISCSICMD aCmdsWaiting[ISCSI_CMD_WAITING_ENTRIES]; /** Release log counter. */ unsigned cLogRelErrors; } ISCSIIMAGE; /******************************************************************************* * Static Variables * *******************************************************************************/ /** Default initiator basename. */ static const char *s_iscsiDefaultInitiatorBasename = "iqn.2009-08.com.sun.virtualbox.initiator"; /** Default LUN. */ static const char *s_iscsiConfigDefaultLUN = "0"; /** Default timeout, 10 seconds. */ static const char *s_iscsiConfigDefaultTimeout = "10000"; /** Default write split value, less or equal to ISCSI_DATA_LENGTH_MAX. */ static const char *s_iscsiConfigDefaultWriteSplit = "262144"; /** Default host IP stack. */ static const char *s_iscsiConfigDefaultHostIPStack = "1"; /** Description of all accepted config parameters. */ static const VDCONFIGINFO s_iscsiConfigInfo[] = { { "TargetName", NULL, VDCFGVALUETYPE_STRING, VD_CFGKEY_MANDATORY }, /* LUN is defined of string type to handle the "enc" prefix. */ { "LUN", s_iscsiConfigDefaultLUN, VDCFGVALUETYPE_STRING, VD_CFGKEY_MANDATORY }, { "TargetAddress", NULL, VDCFGVALUETYPE_STRING, VD_CFGKEY_MANDATORY }, { "InitiatorName", NULL, VDCFGVALUETYPE_STRING, 0 }, { "InitiatorUsername", NULL, VDCFGVALUETYPE_STRING, 0 }, { "InitiatorSecret", NULL, VDCFGVALUETYPE_BYTES, 0 }, { "TargetUsername", NULL, VDCFGVALUETYPE_STRING, VD_CFGKEY_EXPERT }, { "TargetSecret", NULL, VDCFGVALUETYPE_BYTES, VD_CFGKEY_EXPERT }, { "WriteSplit", s_iscsiConfigDefaultWriteSplit, VDCFGVALUETYPE_INTEGER, VD_CFGKEY_EXPERT }, { "Timeout", s_iscsiConfigDefaultTimeout, VDCFGVALUETYPE_INTEGER, VD_CFGKEY_EXPERT }, { "HostIPStack", s_iscsiConfigDefaultHostIPStack, VDCFGVALUETYPE_INTEGER, VD_CFGKEY_EXPERT }, { NULL, NULL, VDCFGVALUETYPE_INTEGER, 0 } }; /******************************************************************************* * Internal Functions * *******************************************************************************/ /* iSCSI low-level functions (only to be used from the iSCSI high-level functions). */ static uint32_t iscsiNewITT(PISCSIIMAGE pImage); static int iscsiSendPDU(PISCSIIMAGE pImage, PISCSIREQ paReq, uint32_t cnReq, uint32_t uFlags); static int iscsiRecvPDU(PISCSIIMAGE pImage, uint32_t itt, PISCSIRES paRes, uint32_t cnRes); static int iscsiRecvPDUAsync(PISCSIIMAGE pImage); static int iscsiSendPDUAsync(PISCSIIMAGE pImage); static int iscsiValidatePDU(PISCSIRES paRes, uint32_t cnRes); static int iscsiRecvPDUProcess(PISCSIIMAGE pImage, PISCSIRES paRes, uint32_t cnRes); static int iscsiPDUTxPrepare(PISCSIIMAGE pImage, PISCSICMD pIScsiCmd); static int iscsiRecvPDUUpdateRequest(PISCSIIMAGE pImage, PISCSIRES paRes, uint32_t cnRes); static void iscsiCmdComplete(PISCSIIMAGE pImage, PISCSICMD pIScsiCmd, int rcCmd); static int iscsiTextAddKeyValue(uint8_t *pbBuf, size_t cbBuf, size_t *pcbBufCurr, const char *pcszKey, const char *pcszValue, size_t cbValue); static int iscsiTextGetKeyValue(const uint8_t *pbBuf, size_t cbBuf, const char *pcszKey, const char **ppcszValue); static int iscsiStrToBinary(const char *pcszValue, uint8_t *pbValue, size_t *pcbValue); static int iscsiUpdateParameters(PISCSIIMAGE pImage, const uint8_t *pbBuf, size_t cbBuf); /* Serial number arithmetic comparison. */ static bool serial_number_less(uint32_t sn1, uint32_t sn2); static bool serial_number_greater(uint32_t sn1, uint32_t sn2); /* CHAP-MD5 functions. */ #ifdef IMPLEMENT_TARGET_AUTH static void chap_md5_generate_challenge(uint8_t *pbChallenge, size_t *pcbChallenge); #endif static void chap_md5_compute_response(uint8_t *pbResponse, uint8_t id, const uint8_t *pbChallenge, size_t cbChallenge, const uint8_t *pbSecret, size_t cbSecret); /** * Internal: release log wrapper limiting the number of entries. */ DECLINLINE(void) iscsiLogRel(PISCSIIMAGE pImage, const char *pcszFormat, ...) { if (pImage->cLogRelErrors++ < MAX_LOG_REL_ERRORS) { va_list va; va_start(va, pcszFormat); LogRel(("%N\n", pcszFormat, &va)); va_end(va); } } DECLINLINE(bool) iscsiIsClientConnected(PISCSIIMAGE pImage) { return pImage->Socket != NIL_VDSOCKET && pImage->pIfNet->pfnIsClientConnected(pImage->Socket); } /** * Calculates the hash for the given ITT used * to look up the command in the table. */ DECLINLINE(uint32_t) iscsiIttHash(uint32_t Itt) { return Itt % ISCSI_CMD_WAITING_ENTRIES; } static PISCSICMD iscsiCmdGetFromItt(PISCSIIMAGE pImage, uint32_t Itt) { PISCSICMD pIScsiCmd = NULL; pIScsiCmd = pImage->aCmdsWaiting[iscsiIttHash(Itt)]; while ( pIScsiCmd && pIScsiCmd->Itt != Itt) pIScsiCmd = pIScsiCmd->pNext; return pIScsiCmd; } static void iscsiCmdInsert(PISCSIIMAGE pImage, PISCSICMD pIScsiCmd) { PISCSICMD pIScsiCmdOld; uint32_t idx = iscsiIttHash(pIScsiCmd->Itt); Assert(!pIScsiCmd->pNext); pIScsiCmdOld = pImage->aCmdsWaiting[idx]; pIScsiCmd->pNext = pIScsiCmdOld; pImage->aCmdsWaiting[idx] = pIScsiCmd; pImage->cCmdsWaiting++; } static PISCSICMD iscsiCmdRemove(PISCSIIMAGE pImage, uint32_t Itt) { PISCSICMD pIScsiCmd = NULL; PISCSICMD pIScsiCmdPrev = NULL; uint32_t idx = iscsiIttHash(Itt); pIScsiCmd = pImage->aCmdsWaiting[idx]; while ( pIScsiCmd && pIScsiCmd->Itt != Itt) { pIScsiCmdPrev = pIScsiCmd; pIScsiCmd = pIScsiCmd->pNext; } if (pIScsiCmd) { if (pIScsiCmdPrev) { Assert(!pIScsiCmd->pNext || VALID_PTR(pIScsiCmd->pNext)); pIScsiCmdPrev->pNext = pIScsiCmd->pNext; } else { pImage->aCmdsWaiting[idx] = pIScsiCmd->pNext; Assert(!pImage->aCmdsWaiting[idx] || VALID_PTR(pImage->aCmdsWaiting[idx])); } pImage->cCmdsWaiting--; } return pIScsiCmd; } /** * Removes all commands from the table and returns the * list head * * @returns Pointer to the head of teh command list. * @param pImage iSCSI connection to use. */ static PISCSICMD iscsiCmdRemoveAll(PISCSIIMAGE pImage) { PISCSICMD pIScsiCmdHead = NULL; for (unsigned idx = 0; idx < RT_ELEMENTS(pImage->aCmdsWaiting); idx++) { PISCSICMD pHead; PISCSICMD pTail; pHead = pImage->aCmdsWaiting[idx]; pImage->aCmdsWaiting[idx] = NULL; if (pHead) { /* Get the tail. */ pTail = pHead; while (pTail->pNext) pTail = pTail->pNext; /* Concatenate. */ pTail->pNext = pIScsiCmdHead; pIScsiCmdHead = pHead; } } pImage->cCmdsWaiting = 0; return pIScsiCmdHead; } static int iscsiTransportConnect(PISCSIIMAGE pImage) { int rc; if (!pImage->pszHostname) return VERR_NET_DEST_ADDRESS_REQUIRED; rc = pImage->pIfNet->pfnClientConnect(pImage->Socket, pImage->pszHostname, pImage->uPort); if (RT_FAILURE(rc)) { if ( rc == VERR_NET_CONNECTION_REFUSED || rc == VERR_NET_CONNECTION_RESET || rc == VERR_NET_UNREACHABLE || rc == VERR_NET_HOST_UNREACHABLE || rc == VERR_NET_CONNECTION_TIMED_OUT) { /* Standardize return value for no connection. */ rc = VERR_NET_CONNECTION_REFUSED; } return rc; } /* Disable Nagle algorithm, we want things to be sent immediately. */ pImage->pIfNet->pfnSetSendCoalescing(pImage->Socket, false); /* Make initiator name and ISID unique on this host. */ RTNETADDR LocalAddr; rc = pImage->pIfNet->pfnGetLocalAddress(pImage->Socket, &LocalAddr); if (RT_FAILURE(rc)) return rc; if ( LocalAddr.uPort == RTNETADDR_PORT_NA || LocalAddr.uPort > 65535) return VERR_NET_ADDRESS_FAMILY_NOT_SUPPORTED; pImage->ISID &= ~65535ULL; pImage->ISID |= LocalAddr.uPort; /* Eliminate the port so that it isn't included below. */ LocalAddr.uPort = RTNETADDR_PORT_NA; if (pImage->fAutomaticInitiatorName) { if (pImage->pszInitiatorName) RTStrFree(pImage->pszInitiatorName); RTStrAPrintf(&pImage->pszInitiatorName, "%s:01:%RTnaddr", s_iscsiDefaultInitiatorBasename, &LocalAddr); if (!pImage->pszInitiatorName) return VERR_NO_MEMORY; } LogRel(("iSCSI: connect from initiator %s with source port %u\n", pImage->pszInitiatorName, pImage->ISID & 65535)); return VINF_SUCCESS; } static int iscsiTransportClose(PISCSIIMAGE pImage) { int rc; LogFlowFunc(("(%s:%d)\n", pImage->pszHostname, pImage->uPort)); if (iscsiIsClientConnected(pImage)) { LogRel(("iSCSI: disconnect from initiator %s with source port %u\n", pImage->pszInitiatorName, pImage->ISID & 65535)); rc = pImage->pIfNet->pfnClientClose(pImage->Socket); } else rc = VINF_SUCCESS; LogFlowFunc(("returns %Rrc\n", rc)); return rc; } static int iscsiTransportRead(PISCSIIMAGE pImage, PISCSIRES paResponse, unsigned int cnResponse) { int rc = VINF_SUCCESS; unsigned int i = 0; size_t cbToRead, cbActuallyRead, residual, cbSegActual = 0, cbAHSLength, cbDataLength; char *pDst; LogFlowFunc(("cnResponse=%d (%s:%d)\n", cnResponse, pImage->pszHostname, pImage->uPort)); if (!iscsiIsClientConnected(pImage)) { /* Reconnecting makes no sense in this case, as there will be nothing * to receive. We would just run into a timeout. */ rc = VERR_BROKEN_PIPE; } if (RT_SUCCESS(rc) && paResponse[0].cbSeg >= ISCSI_BHS_SIZE) { cbToRead = 0; residual = ISCSI_BHS_SIZE; /* Do not read more than the BHS length before the true PDU length is known. */ cbSegActual = residual; pDst = (char *)paResponse[i].pvSeg; uint64_t u64Timeout = RTTimeMilliTS() + pImage->uReadTimeout; do { int64_t cMilliesRemaining = u64Timeout - RTTimeMilliTS(); if (cMilliesRemaining <= 0) { rc = VERR_TIMEOUT; break; } Assert(cMilliesRemaining < 1000000); rc = pImage->pIfNet->pfnSelectOne(pImage->Socket, cMilliesRemaining); if (RT_FAILURE(rc)) break; rc = pImage->pIfNet->pfnRead(pImage->Socket, pDst, residual, &cbActuallyRead); if (RT_FAILURE(rc)) break; if (cbActuallyRead == 0) { /* The other end has closed the connection. */ iscsiTransportClose(pImage); pImage->state = ISCSISTATE_FREE; rc = VERR_NET_CONNECTION_RESET; break; } if (cbToRead == 0) { /* Currently reading the BHS. */ residual -= cbActuallyRead; pDst += cbActuallyRead; if (residual <= 40) { /* Enough data read to figure out the actual PDU size. */ uint32_t word1 = RT_N2H_U32(((uint32_t *)(paResponse[0].pvSeg))[1]); cbAHSLength = (word1 & 0xff000000) >> 24; cbAHSLength = ((cbAHSLength - 1) | 3) + 1; /* Add padding. */ cbDataLength = word1 & 0x00ffffff; cbDataLength = ((cbDataLength - 1) | 3) + 1; /* Add padding. */ cbToRead = residual + cbAHSLength + cbDataLength; residual += paResponse[0].cbSeg - ISCSI_BHS_SIZE; if (residual > cbToRead) residual = cbToRead; cbSegActual = ISCSI_BHS_SIZE + cbAHSLength + cbDataLength; /* Check whether we are already done with this PDU (no payload). */ if (cbToRead == 0) break; } } else { cbToRead -= cbActuallyRead; if (cbToRead == 0) break; pDst += cbActuallyRead; residual -= cbActuallyRead; } if (residual == 0) { i++; if (i >= cnResponse) { /* No space left in receive buffers. */ rc = VERR_BUFFER_OVERFLOW; break; } pDst = (char *)paResponse[i].pvSeg; residual = paResponse[i].cbSeg; if (residual > cbToRead) residual = cbToRead; cbSegActual = residual; } LogFlowFunc(("cbToRead=%u residual=%u cbSegActual=%u cbActuallRead=%u\n", cbToRead, residual, cbSegActual, cbActuallyRead)); } while (true); } else { if (RT_SUCCESS(rc)) rc = VERR_BUFFER_OVERFLOW; } if (RT_SUCCESS(rc)) { paResponse[i].cbSeg = cbSegActual; for (i++; i < cnResponse; i++) paResponse[i].cbSeg = 0; } if (RT_UNLIKELY( RT_FAILURE(rc) && ( rc == VERR_NET_CONNECTION_RESET || rc == VERR_NET_CONNECTION_ABORTED || rc == VERR_NET_CONNECTION_RESET_BY_PEER || rc == VERR_NET_CONNECTION_REFUSED || rc == VERR_BROKEN_PIPE))) { /* Standardize return value for broken connection. */ rc = VERR_BROKEN_PIPE; } LogFlowFunc(("returns %Rrc\n", rc)); return rc; } static int iscsiTransportWrite(PISCSIIMAGE pImage, PISCSIREQ paRequest, unsigned int cnRequest) { int rc = VINF_SUCCESS; uint32_t pad = 0; unsigned int i; LogFlowFunc(("cnRequest=%d (%s:%d)\n", cnRequest, pImage->pszHostname, pImage->uPort)); if (!iscsiIsClientConnected(pImage)) { /* Attempt to reconnect if the connection was previously broken. */ rc = iscsiTransportConnect(pImage); } if (RT_SUCCESS(rc)) { /* Construct scatter/gather buffer for entire request, worst case * needs twice as many entries to allow for padding. */ unsigned cBuf = 0; for (i = 0; i < cnRequest; i++) { cBuf++; if (paRequest[i].cbSeg & 3) cBuf++; } Assert(cBuf < ISCSI_SG_SEGMENTS_MAX); RTSGBUF buf; RTSGSEG aSeg[ISCSI_SG_SEGMENTS_MAX]; static char aPad[4] = { 0, 0, 0, 0 }; RTSgBufInit(&buf, &aSeg[0], cBuf); unsigned iBuf = 0; for (i = 0; i < cnRequest; i++) { /* Actual data chunk. */ aSeg[iBuf].pvSeg = (void *)paRequest[i].pcvSeg; aSeg[iBuf].cbSeg = paRequest[i].cbSeg; iBuf++; /* Insert proper padding before the next chunk. */ if (paRequest[i].cbSeg & 3) { aSeg[iBuf].pvSeg = &aPad[0]; aSeg[iBuf].cbSeg = 4 - (paRequest[i].cbSeg & 3); iBuf++; } } /* Send out the request, the socket is set to send data immediately, * avoiding unnecessary delays. */ rc = pImage->pIfNet->pfnSgWrite(pImage->Socket, &buf); } if (RT_UNLIKELY( RT_FAILURE(rc) && ( rc == VERR_NET_CONNECTION_RESET || rc == VERR_NET_CONNECTION_ABORTED || rc == VERR_NET_CONNECTION_RESET_BY_PEER || rc == VERR_NET_CONNECTION_REFUSED || rc == VERR_BROKEN_PIPE))) { /* Standardize return value for broken connection. */ rc = VERR_BROKEN_PIPE; } LogFlowFunc(("returns %Rrc\n", rc)); return rc; } static int iscsiTransportOpen(PISCSIIMAGE pImage) { int rc = VINF_SUCCESS; size_t cbHostname = 0; /* shut up gcc */ const char *pcszPort = NULL; /* shut up gcc */ char *pszPortEnd; uint16_t uPort; /* Clean up previous connection data. */ iscsiTransportClose(pImage); if (pImage->pszHostname) { RTMemFree(pImage->pszHostname); pImage->pszHostname = NULL; pImage->uPort = 0; } /* Locate the port number via the colon separating the hostname from the port. */ if (*pImage->pszTargetAddress) { if (*pImage->pszTargetAddress != '[') { /* Normal hostname or IPv4 dotted decimal. */ pcszPort = strchr(pImage->pszTargetAddress, ':'); if (pcszPort != NULL) { cbHostname = pcszPort - pImage->pszTargetAddress; pcszPort++; } else cbHostname = strlen(pImage->pszTargetAddress); } else { /* IPv6 literal address. Contains colons, so skip to closing square bracket. */ pcszPort = strchr(pImage->pszTargetAddress, ']'); if (pcszPort != NULL) { pcszPort++; cbHostname = pcszPort - pImage->pszTargetAddress; if (*pcszPort == '\0') pcszPort = NULL; else if (*pcszPort != ':') rc = VERR_PARSE_ERROR; else pcszPort++; } else rc = VERR_PARSE_ERROR; } } else rc = VERR_PARSE_ERROR; /* Now split address into hostname and port. */ if (RT_SUCCESS(rc)) { pImage->pszHostname = (char *)RTMemAlloc(cbHostname + 1); if (!pImage->pszHostname) rc = VERR_NO_MEMORY; else { memcpy(pImage->pszHostname, pImage->pszTargetAddress, cbHostname); pImage->pszHostname[cbHostname] = '\0'; if (pcszPort != NULL) { rc = RTStrToUInt16Ex(pcszPort, &pszPortEnd, 0, &uPort); /* Note that RT_SUCCESS() macro to check the rc value is not strict enough in this case. */ if (rc == VINF_SUCCESS && *pszPortEnd == '\0' && uPort != 0) { pImage->uPort = uPort; } else { rc = VERR_PARSE_ERROR; } } else pImage->uPort = ISCSI_DEFAULT_PORT; } } if (RT_SUCCESS(rc)) { if (!iscsiIsClientConnected(pImage)) rc = iscsiTransportConnect(pImage); } else { if (pImage->pszHostname) { RTMemFree(pImage->pszHostname); pImage->pszHostname = NULL; } pImage->uPort = 0; } LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** * Attach to an iSCSI target. Performs all operations necessary to enter * Full Feature Phase. * * @returns VBox status. * @param pImage The iSCSI connection state to be used. */ static int iscsiAttach(void *pvUser) { int rc; uint32_t itt; uint32_t csg, nsg, substate; uint64_t isid_tsih; uint8_t bBuf[4096]; /* Should be large enough even for large authentication values. */ size_t cbBuf; bool transit; uint8_t pbChallenge[1024]; /* RFC3720 specifies this as maximum. */ size_t cbChallenge = 0; /* shut up gcc */ uint8_t bChapIdx; uint8_t aResponse[RTMD5HASHSIZE]; uint32_t cnISCSIReq; ISCSIREQ aISCSIReq[4]; uint32_t aReqBHS[12]; uint32_t cnISCSIRes; ISCSIRES aISCSIRes[2]; uint32_t aResBHS[12]; char *pszNext; PISCSIIMAGE pImage = (PISCSIIMAGE)pvUser; bool fParameterNeg = true;; pImage->cbRecvDataLength = ISCSI_DATA_LENGTH_MAX; pImage->cbSendDataLength = RT_MIN(ISCSI_DATA_LENGTH_MAX, pImage->cbWriteSplit); char szMaxDataLength[16]; RTStrPrintf(szMaxDataLength, sizeof(szMaxDataLength), "%u", ISCSI_DATA_LENGTH_MAX); ISCSIPARAMETER aParameterNeg[] = { { "HeaderDigest", "None", 0 }, { "DataDigest", "None", 0 }, { "MaxConnections", "1", 0 }, { "InitialR2T", "No", 0 }, { "ImmediateData", "Yes", 0 }, { "MaxRecvDataSegmentLength", szMaxDataLength, 0 }, { "MaxBurstLength", szMaxDataLength, 0 }, { "FirstBurstLength", szMaxDataLength, 0 }, { "DefaultTime2Wait", "0", 0 }, { "DefaultTime2Retain", "60", 0 }, { "DataPDUInOrder", "Yes", 0 }, { "DataSequenceInOrder", "Yes", 0 }, { "ErrorRecoveryLevel", "0", 0 }, { "MaxOutstandingR2T", "1", 0 } }; LogFlowFunc(("entering\n")); Assert(pImage->state == ISCSISTATE_FREE); RTSemMutexRequest(pImage->Mutex, RT_INDEFINITE_WAIT); /* Make 100% sure the connection isn't reused for a new login. */ iscsiTransportClose(pImage); restart: if (!iscsiIsClientConnected(pImage)) { rc = iscsiTransportOpen(pImage); if (RT_FAILURE(rc)) goto out; } pImage->state = ISCSISTATE_IN_LOGIN; pImage->ITT = 1; pImage->FirstRecvPDU = true; pImage->CmdSN = 1; pImage->ExpCmdSN = 0; pImage->MaxCmdSN = 1; pImage->ExpStatSN = 0; /* * Send login request to target. */ itt = iscsiNewITT(pImage); csg = 0; nsg = 0; substate = 0; isid_tsih = pImage->ISID << 16; /* TSIH field currently always 0 */ do { transit = false; cbBuf = 0; /* Handle all cases with a single switch statement. */ switch (csg << 8 | substate) { case 0x0000: /* security negotiation, step 0: propose authentication. */ rc = iscsiTextAddKeyValue(bBuf, sizeof(bBuf), &cbBuf, "SessionType", "Normal", 0); if (RT_FAILURE(rc)) goto out; rc = iscsiTextAddKeyValue(bBuf, sizeof(bBuf), &cbBuf, "InitiatorName", pImage->pszInitiatorName, 0); if (RT_FAILURE(rc)) goto out; rc = iscsiTextAddKeyValue(bBuf, sizeof(bBuf), &cbBuf, "TargetName", pImage->pszTargetName, 0); if (RT_FAILURE(rc)) goto out; if (pImage->pszInitiatorUsername == NULL) { /* No authentication. Immediately switch to next phase. */ rc = iscsiTextAddKeyValue(bBuf, sizeof(bBuf), &cbBuf, "AuthMethod", "None", 0); if (RT_FAILURE(rc)) goto out; nsg = 1; transit = true; } else { rc = iscsiTextAddKeyValue(bBuf, sizeof(bBuf), &cbBuf, "AuthMethod", "CHAP,None", 0); if (RT_FAILURE(rc)) goto out; } break; case 0x0001: /* security negotiation, step 1: propose CHAP_MD5 variant. */ rc = iscsiTextAddKeyValue(bBuf, sizeof(bBuf), &cbBuf, "CHAP_A", "5", 0); if (RT_FAILURE(rc)) goto out; break; case 0x0002: /* security negotiation, step 2: send authentication info. */ rc = iscsiTextAddKeyValue(bBuf, sizeof(bBuf), &cbBuf, "CHAP_N", pImage->pszInitiatorUsername, 0); if (RT_FAILURE(rc)) goto out; chap_md5_compute_response(aResponse, bChapIdx, pbChallenge, cbChallenge, pImage->pbInitiatorSecret, pImage->cbInitiatorSecret); rc = iscsiTextAddKeyValue(bBuf, sizeof(bBuf), &cbBuf, "CHAP_R", (const char *)aResponse, RTMD5HASHSIZE); if (RT_FAILURE(rc)) goto out; nsg = 1; transit = true; break; case 0x0100: /* login operational negotiation, step 0: set parameters. */ if (fParameterNeg) { for (unsigned i = 0; i < RT_ELEMENTS(aParameterNeg); i++) { rc = iscsiTextAddKeyValue(bBuf, sizeof(bBuf), &cbBuf, aParameterNeg[i].pszParamName, aParameterNeg[i].pszParamValue, aParameterNeg[i].cbParamValue); if (RT_FAILURE(rc)) goto out; } fParameterNeg = false; } nsg = 3; transit = true; break; case 0x0300: /* full feature phase. */ default: /* Should never come here. */ AssertMsgFailed(("send: Undefined login state %d substate %d\n", csg, substate)); break; } aReqBHS[0] = RT_H2N_U32( ISCSI_IMMEDIATE_DELIVERY_BIT | (csg << ISCSI_CSG_SHIFT) | (transit ? (nsg << ISCSI_NSG_SHIFT | ISCSI_TRANSIT_BIT) : 0) | ISCSI_MY_VERSION /* Minimum version. */ | (ISCSI_MY_VERSION << 8) /* Maximum version. */ | ISCSIOP_LOGIN_REQ); /* C=0 */ aReqBHS[1] = RT_H2N_U32((uint32_t)cbBuf); /* TotalAHSLength=0 */ aReqBHS[2] = RT_H2N_U32(isid_tsih >> 32); aReqBHS[3] = RT_H2N_U32(isid_tsih & 0xffffffff); aReqBHS[4] = itt; aReqBHS[5] = RT_H2N_U32(1 << 16); /* CID=1,reserved */ aReqBHS[6] = RT_H2N_U32(pImage->CmdSN); aReqBHS[7] = RT_H2N_U32(pImage->ExpStatSN); aReqBHS[8] = 0; /* reserved */ aReqBHS[9] = 0; /* reserved */ aReqBHS[10] = 0; /* reserved */ aReqBHS[11] = 0; /* reserved */ cnISCSIReq = 0; aISCSIReq[cnISCSIReq].pcvSeg = aReqBHS; aISCSIReq[cnISCSIReq].cbSeg = sizeof(aReqBHS); cnISCSIReq++; aISCSIReq[cnISCSIReq].pcvSeg = bBuf; aISCSIReq[cnISCSIReq].cbSeg = cbBuf; cnISCSIReq++; rc = iscsiSendPDU(pImage, aISCSIReq, cnISCSIReq, ISCSIPDU_NO_REATTACH); if (RT_SUCCESS(rc)) { ISCSIOPCODE cmd; ISCSILOGINSTATUSCLASS loginStatusClass; cnISCSIRes = 0; aISCSIRes[cnISCSIRes].pvSeg = aResBHS; aISCSIRes[cnISCSIRes].cbSeg = sizeof(aResBHS); cnISCSIRes++; aISCSIRes[cnISCSIRes].pvSeg = bBuf; aISCSIRes[cnISCSIRes].cbSeg = sizeof(bBuf); cnISCSIRes++; rc = iscsiRecvPDU(pImage, itt, aISCSIRes, cnISCSIRes); if (RT_FAILURE(rc)) break; /** @todo collect partial login responses with Continue bit set. */ Assert(aISCSIRes[0].pvSeg == aResBHS); Assert(aISCSIRes[0].cbSeg >= ISCSI_BHS_SIZE); Assert((RT_N2H_U32(aResBHS[0]) & ISCSI_CONTINUE_BIT) == 0); cmd = (ISCSIOPCODE)(RT_N2H_U32(aResBHS[0]) & ISCSIOP_MASK); if (cmd == ISCSIOP_LOGIN_RES) { if ((RT_N2H_U32(aResBHS[0]) & 0xff) != ISCSI_MY_VERSION) { iscsiTransportClose(pImage); rc = VERR_PARSE_ERROR; break; /* Give up immediately, as a RFC violation in version fields is very serious. */ } loginStatusClass = (ISCSILOGINSTATUSCLASS)(RT_N2H_U32(aResBHS[9]) >> 24); switch (loginStatusClass) { case ISCSI_LOGIN_STATUS_CLASS_SUCCESS: uint32_t targetCSG; uint32_t targetNSG; bool targetTransit; if (pImage->FirstRecvPDU) { pImage->FirstRecvPDU = false; pImage->ExpStatSN = RT_N2H_U32(aResBHS[6]) + 1; } targetCSG = (RT_N2H_U32(aResBHS[0]) & ISCSI_CSG_MASK) >> ISCSI_CSG_SHIFT; targetNSG = (RT_N2H_U32(aResBHS[0]) & ISCSI_NSG_MASK) >> ISCSI_NSG_SHIFT; targetTransit = !!(RT_N2H_U32(aResBHS[0]) & ISCSI_TRANSIT_BIT); /* Handle all cases with a single switch statement. */ switch (csg << 8 | substate) { case 0x0000: /* security negotiation, step 0: receive final authentication. */ rc = iscsiUpdateParameters(pImage, bBuf, aISCSIRes[1].cbSeg); if (RT_FAILURE(rc)) break; const char *pcszAuthMethod; rc = iscsiTextGetKeyValue(bBuf, aISCSIRes[1].cbSeg, "AuthMethod", &pcszAuthMethod); if (RT_FAILURE(rc)) { rc = VERR_PARSE_ERROR; break; } if (strcmp(pcszAuthMethod, "None") == 0) { /* Authentication offered, but none required. Skip to operational parameters. */ csg = 1; nsg = 1; transit = true; substate = 0; break; } else if (strcmp(pcszAuthMethod, "CHAP") == 0 && targetNSG == 0 && !targetTransit) { /* CHAP authentication required, continue with next substate. */ substate++; break; } /* Unknown auth method or login response PDU headers incorrect. */ rc = VERR_PARSE_ERROR; break; case 0x0001: /* security negotiation, step 1: receive final CHAP variant and challenge. */ rc = iscsiUpdateParameters(pImage, bBuf, aISCSIRes[1].cbSeg); if (RT_FAILURE(rc)) break; const char *pcszChapAuthMethod; const char *pcszChapIdxTarget; const char *pcszChapChallengeStr; rc = iscsiTextGetKeyValue(bBuf, aISCSIRes[1].cbSeg, "CHAP_A", &pcszChapAuthMethod); if (RT_FAILURE(rc)) { rc = VERR_PARSE_ERROR; break; } if (strcmp(pcszChapAuthMethod, "5") != 0) { rc = VERR_PARSE_ERROR; break; } rc = iscsiTextGetKeyValue(bBuf, aISCSIRes[1].cbSeg, "CHAP_I", &pcszChapIdxTarget); if (RT_FAILURE(rc)) { rc = VERR_PARSE_ERROR; break; } rc = RTStrToUInt8Ex(pcszChapIdxTarget, &pszNext, 0, &bChapIdx); if ((rc > VINF_SUCCESS) || *pszNext != '\0') { rc = VERR_PARSE_ERROR; break; } rc = iscsiTextGetKeyValue(bBuf, aISCSIRes[1].cbSeg, "CHAP_C", &pcszChapChallengeStr); if (RT_FAILURE(rc)) { rc = VERR_PARSE_ERROR; break; } cbChallenge = sizeof(pbChallenge); rc = iscsiStrToBinary(pcszChapChallengeStr, pbChallenge, &cbChallenge); if (RT_FAILURE(rc)) break; substate++; transit = true; break; case 0x0002: /* security negotiation, step 2: check authentication success. */ rc = iscsiUpdateParameters(pImage, bBuf, aISCSIRes[1].cbSeg); if (RT_FAILURE(rc)) break; if (targetCSG == 0 && targetNSG == 1 && targetTransit) { /* Target wants to continue in login operational state, authentication success. */ csg = 1; nsg = 3; substate = 0; break; } rc = VERR_PARSE_ERROR; break; case 0x0100: /* login operational negotiation, step 0: check results. */ rc = iscsiUpdateParameters(pImage, bBuf, aISCSIRes[1].cbSeg); if (RT_FAILURE(rc)) break; if (targetCSG == 1 && targetNSG == 3 && targetTransit) { /* Target wants to continue in full feature phase, login finished. */ csg = 3; nsg = 3; substate = 0; break; } else if (targetCSG == 1 && targetNSG == 1 && !targetTransit) { /* Target wants to negotiate certain parameters and * stay in login operational negotiation. */ csg = 1; nsg = 3; substate = 0; } rc = VERR_PARSE_ERROR; break; case 0x0300: /* full feature phase. */ default: AssertMsgFailed(("recv: Undefined login state %d substate %d\n", csg, substate)); rc = VERR_PARSE_ERROR; break; } break; case ISCSI_LOGIN_STATUS_CLASS_REDIRECTION: const char *pcszTargetRedir; /* Target has moved to some other location, as indicated in the TargetAddress key. */ rc = iscsiTextGetKeyValue(bBuf, aISCSIRes[1].cbSeg, "TargetAddress", &pcszTargetRedir); if (RT_FAILURE(rc)) { rc = VERR_PARSE_ERROR; break; } if (pImage->pszTargetAddress) RTMemFree(pImage->pszTargetAddress); { size_t cb = strlen(pcszTargetRedir) + 1; pImage->pszTargetAddress = (char *)RTMemAlloc(cb); if (!pImage->pszTargetAddress) { rc = VERR_NO_MEMORY; break; } memcpy(pImage->pszTargetAddress, pcszTargetRedir, cb); } rc = iscsiTransportOpen(pImage); goto restart; case ISCSI_LOGIN_STATUS_CLASS_INITIATOR_ERROR: iscsiTransportClose(pImage); rc = VERR_IO_GEN_FAILURE; goto out; case ISCSI_LOGIN_STATUS_CLASS_TARGET_ERROR: iscsiTransportClose(pImage); rc = VINF_EOF; break; default: rc = VERR_PARSE_ERROR; } if (csg == 3) { /* * Finished login, continuing with Full Feature Phase. */ rc = VINF_SUCCESS; break; } } else { AssertMsgFailed(("%s: ignoring unexpected PDU with first word = %#08x\n", __FUNCTION__, RT_N2H_U32(aResBHS[0]))); } } else break; } while (true); out: if (RT_FAILURE(rc)) { /* * Close connection to target. */ iscsiTransportClose(pImage); pImage->state = ISCSISTATE_FREE; } else pImage->state = ISCSISTATE_NORMAL; RTSemMutexRelease(pImage->Mutex); LogFlowFunc(("returning %Rrc\n", rc)); LogRel(("iSCSI: login to target %s %s\n", pImage->pszTargetName, RT_SUCCESS(rc) ? "successful" : "failed")); return rc; } /** * Detach from an iSCSI target. * * @returns VBox status. * @param pImage The iSCSI connection state to be used. */ static int iscsiDetach(void *pvUser) { int rc; uint32_t itt; uint32_t cnISCSIReq = 0; ISCSIREQ aISCSIReq[4]; uint32_t aReqBHS[12]; PISCSIIMAGE pImage = (PISCSIIMAGE)pvUser; LogFlowFunc(("entering\n")); RTSemMutexRequest(pImage->Mutex, RT_INDEFINITE_WAIT); if (pImage->state != ISCSISTATE_FREE && pImage->state != ISCSISTATE_IN_LOGOUT) { pImage->state = ISCSISTATE_IN_LOGOUT; /* * Send logout request to target. */ itt = iscsiNewITT(pImage); aReqBHS[0] = RT_H2N_U32(ISCSI_FINAL_BIT | ISCSIOP_LOGOUT_REQ); /* I=0,F=1,Reason=close session */ aReqBHS[1] = RT_H2N_U32(0); /* TotalAHSLength=0,DataSementLength=0 */ aReqBHS[2] = 0; /* reserved */ aReqBHS[3] = 0; /* reserved */ aReqBHS[4] = itt; aReqBHS[5] = 0; /* reserved */ aReqBHS[6] = RT_H2N_U32(pImage->CmdSN); aReqBHS[7] = RT_H2N_U32(pImage->ExpStatSN); aReqBHS[8] = 0; /* reserved */ aReqBHS[9] = 0; /* reserved */ aReqBHS[10] = 0; /* reserved */ aReqBHS[11] = 0; /* reserved */ pImage->CmdSN++; aISCSIReq[cnISCSIReq].pcvSeg = aReqBHS; aISCSIReq[cnISCSIReq].cbSeg = sizeof(aReqBHS); cnISCSIReq++; rc = iscsiSendPDU(pImage, aISCSIReq, cnISCSIReq, ISCSIPDU_NO_REATTACH); if (RT_SUCCESS(rc)) { /* * Read logout response from target. */ ISCSIRES aISCSIRes; uint32_t aResBHS[12]; aISCSIRes.pvSeg = aResBHS; aISCSIRes.cbSeg = sizeof(aResBHS); rc = iscsiRecvPDU(pImage, itt, &aISCSIRes, 1); if (RT_SUCCESS(rc)) { if (RT_N2H_U32(aResBHS[0]) != (ISCSI_FINAL_BIT | ISCSIOP_LOGOUT_RES)) AssertMsgFailed(("iSCSI Logout response invalid\n")); } else AssertMsgFailed(("iSCSI Logout response error, rc=%Rrc\n", rc)); } else AssertMsgFailed(("Could not send iSCSI Logout request, rc=%Rrc\n", rc)); } if (pImage->state != ISCSISTATE_FREE) { /* * Close connection to target. */ rc = iscsiTransportClose(pImage); if (RT_FAILURE(rc)) AssertMsgFailed(("Could not close connection to target, rc=%Rrc\n", rc)); } pImage->state = ISCSISTATE_FREE; RTSemMutexRelease(pImage->Mutex); LogFlowFunc(("leaving\n")); LogRel(("iSCSI: logout to target %s\n", pImage->pszTargetName)); return VINF_SUCCESS; } /** * Perform a command on an iSCSI target. Target must be already in * Full Feature Phase. * * @returns VBOX status. * @param pImage The iSCSI connection state to be used. * @param pRequest Command descriptor. Contains all information about * the command, its transfer directions and pointers * to the buffer(s) used for transferring data and * status information. */ static int iscsiCommand(PISCSIIMAGE pImage, PSCSIREQ pRequest) { int rc; uint32_t itt; uint32_t cbData; uint32_t cnISCSIReq = 0; ISCSIREQ aISCSIReq[4]; uint32_t aReqBHS[12]; uint32_t *pDst = NULL; size_t cbBufLength; uint32_t aStatus[256]; /**< Plenty of buffer for status information. */ uint32_t ExpDataSN = 0; bool final = false; LogFlowFunc(("entering, CmdSN=%d\n", pImage->CmdSN)); Assert(pRequest->enmXfer != SCSIXFER_TO_FROM_TARGET); /**< @todo not yet supported, would require AHS. */ Assert(pRequest->cbI2TData <= 0xffffff); /* larger transfers would require R2T support. */ Assert(pRequest->cbCDB <= 16); /* would cause buffer overrun below. */ /* If not in normal state, then the transport connection was dropped. Try * to reestablish by logging in, the target might be responsive again. */ if (pImage->state == ISCSISTATE_FREE) rc = iscsiAttach(pImage); /* If still not in normal state, then the underlying transport connection * cannot be established. Get out before bad things happen (and make * sure the caller suspends the VM again). */ if (pImage->state != ISCSISTATE_NORMAL) { rc = VERR_NET_CONNECTION_REFUSED; goto out; } /* * Send SCSI command to target with all I2T data included. */ cbData = 0; if (pRequest->enmXfer == SCSIXFER_FROM_TARGET) cbData = (uint32_t)pRequest->cbT2IData; else cbData = (uint32_t)pRequest->cbI2TData; RTSemMutexRequest(pImage->Mutex, RT_INDEFINITE_WAIT); itt = iscsiNewITT(pImage); memset(aReqBHS, 0, sizeof(aReqBHS)); aReqBHS[0] = RT_H2N_U32( ISCSI_FINAL_BIT | ISCSI_TASK_ATTR_SIMPLE | ISCSIOP_SCSI_CMD | (pRequest->enmXfer << 21)); /* I=0,F=1,Attr=Simple */ aReqBHS[1] = RT_H2N_U32(0x00000000 | ((uint32_t)pRequest->cbI2TData & 0xffffff)); /* TotalAHSLength=0 */ aReqBHS[2] = RT_H2N_U32(pImage->LUN >> 32); aReqBHS[3] = RT_H2N_U32(pImage->LUN & 0xffffffff); aReqBHS[4] = itt; aReqBHS[5] = RT_H2N_U32(cbData); aReqBHS[6] = RT_H2N_U32(pImage->CmdSN); aReqBHS[7] = RT_H2N_U32(pImage->ExpStatSN); memcpy(aReqBHS + 8, pRequest->pvCDB, pRequest->cbCDB); pImage->CmdSN++; aISCSIReq[cnISCSIReq].pcvSeg = aReqBHS; aISCSIReq[cnISCSIReq].cbSeg = sizeof(aReqBHS); cnISCSIReq++; if ( pRequest->enmXfer == SCSIXFER_TO_TARGET || pRequest->enmXfer == SCSIXFER_TO_FROM_TARGET) { Assert(pRequest->cI2TSegs == 1); aISCSIReq[cnISCSIReq].pcvSeg = pRequest->paI2TSegs[0].pvSeg; aISCSIReq[cnISCSIReq].cbSeg = pRequest->paI2TSegs[0].cbSeg; /* Padding done by transport. */ cnISCSIReq++; } rc = iscsiSendPDU(pImage, aISCSIReq, cnISCSIReq, ISCSIPDU_DEFAULT); if (RT_FAILURE(rc)) goto out_release; /* Place SCSI request in queue. */ pImage->paCurrReq = aISCSIReq; pImage->cnCurrReq = cnISCSIReq; /* * Read SCSI response/data in PDUs from target. */ if ( pRequest->enmXfer == SCSIXFER_FROM_TARGET || pRequest->enmXfer == SCSIXFER_TO_FROM_TARGET) { Assert(pRequest->cT2ISegs == 1); pDst = (uint32_t *)pRequest->paT2ISegs[0].pvSeg; cbBufLength = pRequest->paT2ISegs[0].cbSeg; } else cbBufLength = 0; do { uint32_t cnISCSIRes = 0; ISCSIRES aISCSIRes[4]; uint32_t aResBHS[12]; aISCSIRes[cnISCSIRes].pvSeg = aResBHS; aISCSIRes[cnISCSIRes].cbSeg = sizeof(aResBHS); cnISCSIRes++; if (cbBufLength != 0 && ( pRequest->enmXfer == SCSIXFER_FROM_TARGET || pRequest->enmXfer == SCSIXFER_TO_FROM_TARGET)) { aISCSIRes[cnISCSIRes].pvSeg = pDst; aISCSIRes[cnISCSIRes].cbSeg = cbBufLength; cnISCSIRes++; } /* Always reserve space for the status - it's impossible to tell * beforehand whether this will be the final PDU or not. */ aISCSIRes[cnISCSIRes].pvSeg = aStatus; aISCSIRes[cnISCSIRes].cbSeg = sizeof(aStatus); cnISCSIRes++; rc = iscsiRecvPDU(pImage, itt, aISCSIRes, cnISCSIRes); if (RT_FAILURE(rc)) break; final = !!(RT_N2H_U32(aResBHS[0]) & ISCSI_FINAL_BIT); ISCSIOPCODE cmd = (ISCSIOPCODE)(RT_N2H_U32(aResBHS[0]) & ISCSIOP_MASK); if (cmd == ISCSIOP_SCSI_RES) { /* This is the final PDU which delivers the status (and may be omitted if * the last Data-In PDU included successful completion status). Note * that ExpStatSN has been bumped already in iscsiRecvPDU. */ if (!final || ((RT_N2H_U32(aResBHS[0]) & 0x0000ff00) != 0) || (RT_N2H_U32(aResBHS[6]) != pImage->ExpStatSN - 1)) { /* SCSI Response in the wrong place or with a (target) failure. */ rc = VERR_PARSE_ERROR; break; } /* The following is a bit tricky, as in error situations we may * get the status only instead of the result data plus optional * status. Thus the status may have ended up partially in the * data area. */ pRequest->status = RT_N2H_U32(aResBHS[0]) & 0x000000ff; cbData = RT_N2H_U32(aResBHS[1]) & 0x00ffffff; if (cbData >= 2) { uint32_t cbStat = RT_N2H_U32(((uint32_t *)aISCSIRes[1].pvSeg)[0]) >> 16; if (cbStat + 2 > cbData) { rc = VERR_BUFFER_OVERFLOW; break; } /* Truncate sense data if it doesn't fit into the buffer. */ pRequest->cbSense = RT_MIN(cbStat, pRequest->cbSense); memcpy(pRequest->pvSense, ((const char *)aISCSIRes[1].pvSeg) + 2, RT_MIN(aISCSIRes[1].cbSeg - 2, pRequest->cbSense)); if ( cnISCSIRes > 2 && aISCSIRes[2].cbSeg && (ssize_t)pRequest->cbSense - aISCSIRes[1].cbSeg + 2 > 0) { memcpy((char *)pRequest->pvSense + aISCSIRes[1].cbSeg - 2, aISCSIRes[2].pvSeg, pRequest->cbSense - aISCSIRes[1].cbSeg + 2); } } else if (cbData == 1) { rc = VERR_PARSE_ERROR; break; } else pRequest->cbSense = 0; break; } else if (cmd == ISCSIOP_SCSI_DATA_IN) { /* A Data-In PDU carries some data that needs to be added to the received * data in response to the command. There may be both partial and complete * Data-In PDUs, so collect data until the status is included or the status * is sent in a separate SCSI Result frame (see above). */ if (final && aISCSIRes[2].cbSeg != 0) { /* The received PDU is partially stored in the buffer for status. * Must not happen under normal circumstances and is a target error. */ rc = VERR_BUFFER_OVERFLOW; break; } uint32_t len = RT_N2H_U32(aResBHS[1]) & 0x00ffffff; pDst = (uint32_t *)((char *)pDst + len); cbBufLength -= len; ExpDataSN++; if (final && (RT_N2H_U32(aResBHS[0]) & ISCSI_STATUS_BIT) != 0) { pRequest->status = RT_N2H_U32(aResBHS[0]) & 0x000000ff; pRequest->cbSense = 0; break; } } else { rc = VERR_PARSE_ERROR; break; } } while (true); /* Remove SCSI request from queue. */ pImage->paCurrReq = NULL; pImage->cnCurrReq = 0; out_release: if (rc == VERR_TIMEOUT) { /* Drop connection in case the target plays dead. Much better than * delaying the next requests until the timed out command actually * finishes. Also keep in mind that command shouldn't take longer than * about 30-40 seconds, or the guest will lose its patience. */ iscsiTransportClose(pImage); pImage->state = ISCSISTATE_FREE; rc = VERR_BROKEN_PIPE; } RTSemMutexRelease(pImage->Mutex); out: LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** * Generate a new Initiator Task Tag. * * @returns Initiator Task Tag. * @param pImage The iSCSI connection state to be used. */ static uint32_t iscsiNewITT(PISCSIIMAGE pImage) { uint32_t next_itt; next_itt = pImage->ITT++; if (pImage->ITT == ISCSI_TASK_TAG_RSVD) pImage->ITT = 0; return RT_H2N_U32(next_itt); } /** * Send an iSCSI request. The request can consist of several segments, which * are padded to 4 byte boundaries and concatenated. * * @returns VBOX status * @param pImage The iSCSI connection state to be used. * @param paReq Pointer to array of iSCSI request sections. * @param cnReq Number of valid iSCSI request sections in the array. * @param uFlags Flags controlling the exact send semantics. */ static int iscsiSendPDU(PISCSIIMAGE pImage, PISCSIREQ paReq, uint32_t cnReq, uint32_t uFlags) { int rc = VINF_SUCCESS; /** @todo return VERR_VD_ISCSI_INVALID_STATE in the appropriate situations, * needs cleaning up of timeout/disconnect handling a bit, as otherwise * too many incorrect errors are signalled. */ Assert(cnReq >= 1); Assert(paReq[0].cbSeg >= ISCSI_BHS_SIZE); for (uint32_t i = 0; i < pImage->cISCSIRetries; i++) { rc = iscsiTransportWrite(pImage, paReq, cnReq); if (RT_SUCCESS(rc)) break; if ( (uFlags & ISCSIPDU_NO_REATTACH) || (rc != VERR_BROKEN_PIPE && rc != VERR_NET_CONNECTION_REFUSED)) break; /* No point in reestablishing the connection for a logout */ if (pImage->state == ISCSISTATE_IN_LOGOUT) break; RTThreadSleep(500); if (pImage->state != ISCSISTATE_IN_LOGIN) { /* Attempt to re-login when a connection fails, but only when not * currently logging in. */ rc = iscsiAttach(pImage); if (RT_FAILURE(rc)) break; } } return rc; } /** * Wait for an iSCSI response with a matching Initiator Target Tag. The response is * split into several segments, as requested by the caller-provided buffer specification. * Remember that the response can be split into several PDUs by the sender, so make * sure that all parts are collected and processed appropriately by the caller. * * @returns VBOX status * @param pImage The iSCSI connection state to be used. * @param paRes Pointer to array of iSCSI response sections. * @param cnRes Number of valid iSCSI response sections in the array. */ static int iscsiRecvPDU(PISCSIIMAGE pImage, uint32_t itt, PISCSIRES paRes, uint32_t cnRes) { int rc = VINF_SUCCESS; ISCSIRES aResBuf; for (uint32_t i = 0; i < pImage->cISCSIRetries; i++) { aResBuf.pvSeg = pImage->pvRecvPDUBuf; aResBuf.cbSeg = pImage->cbRecvPDUBuf; rc = iscsiTransportRead(pImage, &aResBuf, 1); if (RT_FAILURE(rc)) { if (rc == VERR_BROKEN_PIPE || rc == VERR_NET_CONNECTION_REFUSED) { /* No point in reestablishing the connection for a logout */ if (pImage->state == ISCSISTATE_IN_LOGOUT) break; /* Connection broken while waiting for a response - wait a while and * try to restart by re-sending the original request (if any). * This also handles the connection reestablishment (login etc.). */ RTThreadSleep(500); if (pImage->state != ISCSISTATE_IN_LOGIN) { /* Attempt to re-login when a connection fails, but only when not * currently logging in. */ rc = iscsiAttach(pImage); if (RT_FAILURE(rc)) break; } if (pImage->paCurrReq != NULL) { rc = iscsiSendPDU(pImage, pImage->paCurrReq, pImage->cnCurrReq, ISCSIPDU_DEFAULT); if (RT_FAILURE(rc)) break; } } else { /* Signal other errors (VERR_BUFFER_OVERFLOW etc.) to the caller. */ break; } } else { ISCSIOPCODE cmd; const uint32_t *pcvResSeg = (const uint32_t *)aResBuf.pvSeg; /* Check whether the received PDU is valid, and update the internal state of * the iSCSI connection/session. */ rc = iscsiValidatePDU(&aResBuf, 1); if (RT_FAILURE(rc)) continue; cmd = (ISCSIOPCODE)(RT_N2H_U32(pcvResSeg[0]) & ISCSIOP_MASK); switch (cmd) { case ISCSIOP_SCSI_RES: case ISCSIOP_SCSI_TASKMGMT_RES: case ISCSIOP_SCSI_DATA_IN: case ISCSIOP_R2T: case ISCSIOP_ASYN_MSG: case ISCSIOP_TEXT_RES: case ISCSIOP_LOGIN_RES: case ISCSIOP_LOGOUT_RES: case ISCSIOP_REJECT: case ISCSIOP_NOP_IN: if (serial_number_less(pImage->MaxCmdSN, RT_N2H_U32(pcvResSeg[8]))) pImage->MaxCmdSN = RT_N2H_U32(pcvResSeg[8]); if (serial_number_less(pImage->ExpCmdSN, RT_N2H_U32(pcvResSeg[7]))) pImage->ExpCmdSN = RT_N2H_U32(pcvResSeg[7]); break; default: rc = VERR_PARSE_ERROR; } if (RT_FAILURE(rc)) continue; if ( !pImage->FirstRecvPDU && (cmd != ISCSIOP_SCSI_DATA_IN || (RT_N2H_U32(pcvResSeg[0]) & ISCSI_STATUS_BIT)) && ( cmd != ISCSIOP_LOGIN_RES || (ISCSILOGINSTATUSCLASS)((RT_N2H_U32(pcvResSeg[9]) >> 24) == ISCSI_LOGIN_STATUS_CLASS_SUCCESS))) { if (pImage->ExpStatSN == RT_N2H_U32(pcvResSeg[6])) { /* StatSN counter is not advanced on R2T and on a target SN update NOP-In. */ if ( (cmd != ISCSIOP_R2T) && ((cmd != ISCSIOP_NOP_IN) || (RT_N2H_U32(pcvResSeg[4]) != ISCSI_TASK_TAG_RSVD))) pImage->ExpStatSN++; } else { rc = VERR_PARSE_ERROR; continue; } } /* Finally check whether the received PDU matches what the caller wants. */ if ( itt == pcvResSeg[4] && itt != ISCSI_TASK_TAG_RSVD) { /* Copy received PDU (one segment) to caller-provided buffers. */ uint32_t j; size_t cbSeg; const uint8_t *pSrc; pSrc = (const uint8_t *)aResBuf.pvSeg; cbSeg = aResBuf.cbSeg; for (j = 0; j < cnRes; j++) { if (cbSeg > paRes[j].cbSeg) { memcpy(paRes[j].pvSeg, pSrc, paRes[j].cbSeg); pSrc += paRes[j].cbSeg; cbSeg -= paRes[j].cbSeg; } else { memcpy(paRes[j].pvSeg, pSrc, cbSeg); paRes[j].cbSeg = cbSeg; cbSeg = 0; break; } } if (cbSeg != 0) { rc = VERR_BUFFER_OVERFLOW; break; } for (j++; j < cnRes; j++) paRes[j].cbSeg = 0; break; } else if ( cmd == ISCSIOP_NOP_IN && RT_N2H_U32(pcvResSeg[5]) != ISCSI_TASK_TAG_RSVD) { uint32_t cnISCSIReq; ISCSIREQ aISCSIReq[4]; uint32_t aReqBHS[12]; aReqBHS[0] = RT_H2N_U32(ISCSI_IMMEDIATE_DELIVERY_BIT | ISCSI_FINAL_BIT | ISCSIOP_NOP_OUT); aReqBHS[1] = RT_H2N_U32(0); /* TotalAHSLength=0,DataSementLength=0 */ aReqBHS[2] = pcvResSeg[2]; /* copy LUN from NOP-In */ aReqBHS[3] = pcvResSeg[3]; /* copy LUN from NOP-In */ aReqBHS[4] = RT_H2N_U32(ISCSI_TASK_TAG_RSVD); /* ITT, reply */ aReqBHS[5] = pcvResSeg[5]; /* copy TTT from NOP-In */ aReqBHS[6] = RT_H2N_U32(pImage->CmdSN); aReqBHS[7] = RT_H2N_U32(pImage->ExpStatSN); aReqBHS[8] = 0; /* reserved */ aReqBHS[9] = 0; /* reserved */ aReqBHS[10] = 0; /* reserved */ aReqBHS[11] = 0; /* reserved */ cnISCSIReq = 0; aISCSIReq[cnISCSIReq].pcvSeg = aReqBHS; aISCSIReq[cnISCSIReq].cbSeg = sizeof(aReqBHS); cnISCSIReq++; iscsiSendPDU(pImage, aISCSIReq, cnISCSIReq, ISCSIPDU_NO_REATTACH); /* Break if the caller wanted to process the NOP-in only. */ if (itt == ISCSI_TASK_TAG_RSVD) break; } } } LogFlowFunc(("returns rc=%Rrc\n")); return rc; } /** * Reset the PDU buffer * * @param pImage The iSCSI connection state to be used. */ static void iscsiRecvPDUReset(PISCSIIMAGE pImage) { pImage->cbRecvPDUResidual = ISCSI_BHS_SIZE; pImage->fRecvPDUBHS = true; pImage->pbRecvPDUBufCur = (uint8_t *)pImage->pvRecvPDUBuf; } static void iscsiPDUTxAdd(PISCSIIMAGE pImage, PISCSIPDUTX pIScsiPDUTx, bool fFront) { if (!fFront) { /* Insert PDU at the tail of the list. */ if (!pImage->pIScsiPDUTxHead) pImage->pIScsiPDUTxHead = pIScsiPDUTx; else pImage->pIScsiPDUTxTail->pNext = pIScsiPDUTx; pImage->pIScsiPDUTxTail = pIScsiPDUTx; } else { /* Insert PDU at the beginning of the list. */ pIScsiPDUTx->pNext = pImage->pIScsiPDUTxHead; pImage->pIScsiPDUTxHead = pIScsiPDUTx; if (!pImage->pIScsiPDUTxTail) pImage->pIScsiPDUTxTail = pIScsiPDUTx; } } /** * Receives a PDU in a non blocking way. * * @returns VBOX status code. * @param pImage The iSCSI connection state to be used. */ static int iscsiRecvPDUAsync(PISCSIIMAGE pImage) { size_t cbActuallyRead = 0; int rc = VINF_SUCCESS; LogFlowFunc(("pImage=%#p\n", pImage)); /* Check if we are in the middle of a PDU receive. */ if (pImage->cbRecvPDUResidual == 0) { /* * We are receiving a new PDU, don't read more than the BHS initially * until we know the real size of the PDU. */ iscsiRecvPDUReset(pImage); LogFlow(("Receiving new PDU\n")); } rc = pImage->pIfNet->pfnReadNB(pImage->Socket, pImage->pbRecvPDUBufCur, pImage->cbRecvPDUResidual, &cbActuallyRead); if (RT_SUCCESS(rc) && cbActuallyRead == 0) rc = VERR_BROKEN_PIPE; if (RT_SUCCESS(rc)) { LogFlow(("Received %zu bytes\n", cbActuallyRead)); pImage->cbRecvPDUResidual -= cbActuallyRead; pImage->pbRecvPDUBufCur += cbActuallyRead; /* Check if we received everything we wanted. */ if ( !pImage->cbRecvPDUResidual && pImage->fRecvPDUBHS) { size_t cbAHSLength, cbDataLength; /* If we were reading the BHS first get the actual PDU size now. */ uint32_t word1 = RT_N2H_U32(((uint32_t *)(pImage->pvRecvPDUBuf))[1]); cbAHSLength = (word1 & 0xff000000) >> 24; cbAHSLength = ((cbAHSLength - 1) | 3) + 1; /* Add padding. */ cbDataLength = word1 & 0x00ffffff; cbDataLength = ((cbDataLength - 1) | 3) + 1; /* Add padding. */ pImage->cbRecvPDUResidual = cbAHSLength + cbDataLength; pImage->fRecvPDUBHS = false; /* Start receiving the rest of the PDU. */ } if (!pImage->cbRecvPDUResidual) { /* We received the complete PDU with or without any payload now. */ LogFlow(("Received complete PDU\n")); ISCSIRES aResBuf; aResBuf.pvSeg = pImage->pvRecvPDUBuf; aResBuf.cbSeg = pImage->cbRecvPDUBuf; rc = iscsiRecvPDUProcess(pImage, &aResBuf, 1); } } else LogFlowFunc(("Reading from the socket returned with rc=%Rrc\n", rc)); return rc; } static int iscsiSendPDUAsync(PISCSIIMAGE pImage) { size_t cbSent = 0; int rc = VINF_SUCCESS; LogFlowFunc(("pImage=%#p\n", pImage)); do { /* * If there is no PDU active, get the first one from the list. * Check that we are allowed to transfer the PDU by comparing the * command sequence number and the maximum sequence number allowed by the target. */ if (!pImage->pIScsiPDUTxCur) { if ( !pImage->pIScsiPDUTxHead || serial_number_greater(pImage->pIScsiPDUTxHead->CmdSN, pImage->MaxCmdSN)) break; pImage->pIScsiPDUTxCur = pImage->pIScsiPDUTxHead; pImage->pIScsiPDUTxHead = pImage->pIScsiPDUTxCur->pNext; if (!pImage->pIScsiPDUTxHead) pImage->pIScsiPDUTxTail = NULL; } /* Send as much as we can. */ rc = pImage->pIfNet->pfnSgWriteNB(pImage->Socket, &pImage->pIScsiPDUTxCur->SgBuf, &cbSent); LogFlow(("SgWriteNB returned rc=%Rrc cbSent=%zu\n", rc, cbSent)); if (RT_SUCCESS(rc)) { LogFlow(("Sent %zu bytes for PDU %#p\n", cbSent, pImage->pIScsiPDUTxCur)); pImage->pIScsiPDUTxCur->cbSgLeft -= cbSent; RTSgBufAdvance(&pImage->pIScsiPDUTxCur->SgBuf, cbSent); if (!pImage->pIScsiPDUTxCur->cbSgLeft) { /* PDU completed, free it and place the command on the waiting for response list. */ if (pImage->pIScsiPDUTxCur->pIScsiCmd) { LogFlow(("Sent complete PDU, placing on waiting list\n")); iscsiCmdInsert(pImage, pImage->pIScsiPDUTxCur->pIScsiCmd); } RTMemFree(pImage->pIScsiPDUTxCur); pImage->pIScsiPDUTxCur = NULL; } } } while ( RT_SUCCESS(rc) && !pImage->pIScsiPDUTxCur); if (rc == VERR_TRY_AGAIN) rc = VINF_SUCCESS; /* Add the write poll flag if we still have something to send, clear it otherwise. */ if (pImage->pIScsiPDUTxCur) pImage->fPollEvents |= VD_INTERFACETCPNET_EVT_WRITE; else pImage->fPollEvents &= ~VD_INTERFACETCPNET_EVT_WRITE; LogFlowFunc(("rc=%Rrc pIScsiPDUTxCur=%#p\n", rc, pImage->pIScsiPDUTxCur)); return rc; } /** * Process a received PDU. * * @return VBOX status code. * @param pImage The iSCSI connection state to be used. * @param paRes Pointer to the array of iSCSI response sections. * @param cnRes Number of valid iSCSI response sections in the array. */ static int iscsiRecvPDUProcess(PISCSIIMAGE pImage, PISCSIRES paRes, uint32_t cnRes) { int rc = VINF_SUCCESS; LogFlowFunc(("pImage=%#p paRes=%#p cnRes=%u\n", pImage, paRes, cnRes)); /* Validate the PDU first. */ rc = iscsiValidatePDU(paRes, cnRes); if (RT_SUCCESS(rc)) { ISCSIOPCODE cmd; const uint32_t *pcvResSeg = (const uint32_t *)paRes[0].pvSeg; Assert(paRes[0].cbSeg > 9 * sizeof(uint32_t)); do { cmd = (ISCSIOPCODE)(RT_N2H_U32(pcvResSeg[0]) & ISCSIOP_MASK); switch (cmd) { case ISCSIOP_SCSI_RES: case ISCSIOP_SCSI_TASKMGMT_RES: case ISCSIOP_SCSI_DATA_IN: case ISCSIOP_R2T: case ISCSIOP_ASYN_MSG: case ISCSIOP_TEXT_RES: case ISCSIOP_LOGIN_RES: case ISCSIOP_LOGOUT_RES: case ISCSIOP_REJECT: case ISCSIOP_NOP_IN: if (serial_number_less(pImage->MaxCmdSN, RT_N2H_U32(pcvResSeg[8]))) pImage->MaxCmdSN = RT_N2H_U32(pcvResSeg[8]); if (serial_number_less(pImage->ExpCmdSN, RT_N2H_U32(pcvResSeg[7]))) pImage->ExpCmdSN = RT_N2H_U32(pcvResSeg[7]); break; default: rc = VERR_PARSE_ERROR; } if (RT_FAILURE(rc)) break; if ( !pImage->FirstRecvPDU && (cmd != ISCSIOP_SCSI_DATA_IN || (RT_N2H_U32(pcvResSeg[0]) & ISCSI_STATUS_BIT))) { if (pImage->ExpStatSN == RT_N2H_U32(pcvResSeg[6])) { /* StatSN counter is not advanced on R2T and on a target SN update NOP-In. */ if ( (cmd != ISCSIOP_R2T) && ((cmd != ISCSIOP_NOP_IN) || (RT_N2H_U32(pcvResSeg[4]) != ISCSI_TASK_TAG_RSVD))) pImage->ExpStatSN++; } else { rc = VERR_PARSE_ERROR; break; } } if (pcvResSeg[4] != ISCSI_TASK_TAG_RSVD) { /* * This is a response from the target for a request from the initiator. * Get the request and update its state. */ rc = iscsiRecvPDUUpdateRequest(pImage, paRes, cnRes); /* Try to send more PDUs now that we updated the MaxCmdSN field */ if ( RT_SUCCESS(rc) && !pImage->pIScsiPDUTxCur) rc = iscsiSendPDUAsync(pImage); } else { /* This is a target initiated request (we handle only NOP-In request at the moment). */ if ( cmd == ISCSIOP_NOP_IN && RT_N2H_U32(pcvResSeg[5]) != ISCSI_TASK_TAG_RSVD) { PISCSIPDUTX pIScsiPDUTx; uint32_t cnISCSIReq; uint32_t *paReqBHS; LogFlowFunc(("Sending NOP-Out\n")); /* Allocate a new PDU initialize it and put onto the waiting list. */ pIScsiPDUTx = (PISCSIPDUTX)RTMemAllocZ(sizeof(ISCSIPDUTX)); if (!pIScsiPDUTx) { rc = VERR_NO_MEMORY; break; } paReqBHS = &pIScsiPDUTx->aBHS[0]; paReqBHS[0] = RT_H2N_U32(ISCSI_IMMEDIATE_DELIVERY_BIT | ISCSI_FINAL_BIT | ISCSIOP_NOP_OUT); paReqBHS[1] = RT_H2N_U32(0); /* TotalAHSLength=0,DataSementLength=0 */ paReqBHS[2] = pcvResSeg[2]; /* copy LUN from NOP-In */ paReqBHS[3] = pcvResSeg[3]; /* copy LUN from NOP-In */ paReqBHS[4] = RT_H2N_U32(ISCSI_TASK_TAG_RSVD); /* ITT, reply */ paReqBHS[5] = pcvResSeg[5]; /* copy TTT from NOP-In */ paReqBHS[6] = RT_H2N_U32(pImage->CmdSN); paReqBHS[7] = RT_H2N_U32(pImage->ExpStatSN); paReqBHS[8] = 0; /* reserved */ paReqBHS[9] = 0; /* reserved */ paReqBHS[10] = 0; /* reserved */ paReqBHS[11] = 0; /* reserved */ cnISCSIReq = 0; pIScsiPDUTx->aISCSIReq[cnISCSIReq].pvSeg = paReqBHS; pIScsiPDUTx->aISCSIReq[cnISCSIReq].cbSeg = sizeof(pIScsiPDUTx->aBHS); cnISCSIReq++; pIScsiPDUTx->cbSgLeft = sizeof(pIScsiPDUTx->aBHS); RTSgBufInit(&pIScsiPDUTx->SgBuf, pIScsiPDUTx->aISCSIReq, cnISCSIReq); /* * Link the PDU to the list. * Insert at the front of the list to send the response as soon as possible * to avoid frequent reconnects for a slow connection when there are many PDUs * waiting. */ iscsiPDUTxAdd(pImage, pIScsiPDUTx, true /* fFront */); /* Start transfer of a PDU if there is no one active at the moment. */ if (!pImage->pIScsiPDUTxCur) rc = iscsiSendPDUAsync(pImage); } } } while (0); } return rc; } /** * Check the static (not dependent on the connection/session state) validity of an iSCSI response PDU. * * @returns VBOX status * @param paRes Pointer to array of iSCSI response sections. * @param cnRes Number of valid iSCSI response sections in the array. */ static int iscsiValidatePDU(PISCSIRES paRes, uint32_t cnRes) { const uint32_t *pcrgResBHS; uint32_t hw0; Assert(cnRes >= 1); Assert(paRes[0].cbSeg >= ISCSI_BHS_SIZE); LogFlowFunc(("paRes=%#p cnRes=%u\n", paRes, cnRes)); pcrgResBHS = (const uint32_t *)(paRes[0].pvSeg); hw0 = RT_N2H_U32(pcrgResBHS[0]); switch (hw0 & ISCSIOP_MASK) { case ISCSIOP_NOP_IN: /* NOP-In responses must not be split into several PDUs nor it may contain * ping data for target-initiated pings nor may both task tags be valid task tags. */ if ( (hw0 & ISCSI_FINAL_BIT) == 0 || ( RT_N2H_U32(pcrgResBHS[4]) == ISCSI_TASK_TAG_RSVD && RT_N2H_U32(pcrgResBHS[1]) != 0) || ( RT_N2H_U32(pcrgResBHS[4]) != ISCSI_TASK_TAG_RSVD && RT_N2H_U32(pcrgResBHS[5]) != ISCSI_TASK_TAG_RSVD)) return VERR_PARSE_ERROR; break; case ISCSIOP_SCSI_RES: /* SCSI responses must not be split into several PDUs nor must the residual * bits be contradicting each other nor may the residual bits be set for PDUs * containing anything else but a completed command response. Underflow * is no reason for declaring a PDU as invalid, as the target may choose * to return less data than we assume to get. */ if ( (hw0 & ISCSI_FINAL_BIT) == 0 || ((hw0 & ISCSI_BI_READ_RESIDUAL_OVFL_BIT) && (hw0 & ISCSI_BI_READ_RESIDUAL_UNFL_BIT)) || ((hw0 & ISCSI_RESIDUAL_OVFL_BIT) && (hw0 & ISCSI_RESIDUAL_UNFL_BIT)) || ( ((hw0 & ISCSI_SCSI_RESPONSE_MASK) == 0) && ((hw0 & ISCSI_SCSI_STATUS_MASK) == SCSI_STATUS_OK) && (hw0 & ( ISCSI_BI_READ_RESIDUAL_OVFL_BIT | ISCSI_BI_READ_RESIDUAL_UNFL_BIT | ISCSI_RESIDUAL_OVFL_BIT)))) return VERR_PARSE_ERROR; break; case ISCSIOP_LOGIN_RES: /* Login responses must not contain contradicting transit and continue bits. */ if ((hw0 & ISCSI_CONTINUE_BIT) && ((hw0 & ISCSI_TRANSIT_BIT) != 0)) return VERR_PARSE_ERROR; break; case ISCSIOP_TEXT_RES: /* Text responses must not contain contradicting final and continue bits nor * may the final bit be set for PDUs containing a target transfer tag other than * the reserved transfer tag (and vice versa). */ if ( (((hw0 & ISCSI_CONTINUE_BIT) && (hw0 & ISCSI_FINAL_BIT) != 0)) || (((hw0 & ISCSI_FINAL_BIT) && (RT_N2H_U32(pcrgResBHS[5]) != ISCSI_TASK_TAG_RSVD))) || (((hw0 & ISCSI_FINAL_BIT) == 0) && (RT_N2H_U32(pcrgResBHS[5]) == ISCSI_TASK_TAG_RSVD))) return VERR_PARSE_ERROR; break; case ISCSIOP_SCSI_DATA_IN: /* SCSI Data-in responses must not contain contradicting residual bits when * status bit is set. */ if ((hw0 & ISCSI_STATUS_BIT) && (hw0 & ISCSI_RESIDUAL_OVFL_BIT) && (hw0 & ISCSI_RESIDUAL_UNFL_BIT)) return VERR_PARSE_ERROR; break; case ISCSIOP_LOGOUT_RES: /* Logout responses must not have the final bit unset and may not contain any * data or additional header segments. */ if ( ((hw0 & ISCSI_FINAL_BIT) == 0) || (RT_N2H_U32(pcrgResBHS[1]) != 0)) return VERR_PARSE_ERROR; break; case ISCSIOP_ASYN_MSG: /* Asynchronous Messages must not have the final bit unset and may not contain * an initiator task tag. */ if ( ((hw0 & ISCSI_FINAL_BIT) == 0) || (RT_N2H_U32(pcrgResBHS[4]) != ISCSI_TASK_TAG_RSVD)) return VERR_PARSE_ERROR; break; case ISCSIOP_SCSI_TASKMGMT_RES: case ISCSIOP_R2T: case ISCSIOP_REJECT: default: /* Do some logging, ignore PDU. */ LogFlowFunc(("ignore unhandled PDU, first word %#08x\n", RT_N2H_U32(pcrgResBHS[0]))); return VERR_PARSE_ERROR; } /* A target must not send PDUs with MaxCmdSN less than ExpCmdSN-1. */ if (serial_number_less(RT_N2H_U32(pcrgResBHS[8]), RT_N2H_U32(pcrgResBHS[7])-1)) return VERR_PARSE_ERROR; return VINF_SUCCESS; } /** * Prepares a PDU to transfer for the given command and adds it to the list. */ static int iscsiPDUTxPrepare(PISCSIIMAGE pImage, PISCSICMD pIScsiCmd) { int rc = VINF_SUCCESS; uint32_t *paReqBHS; size_t cbData = 0; size_t cbSegs = 0; PSCSIREQ pScsiReq; PISCSIPDUTX pIScsiPDU = NULL; LogFlowFunc(("pImage=%#p pIScsiCmd=%#p\n", pImage, pIScsiCmd)); Assert(pIScsiCmd->enmCmdType == ISCSICMDTYPE_REQ); pIScsiCmd->Itt = iscsiNewITT(pImage); pScsiReq = pIScsiCmd->CmdType.ScsiReq.pScsiReq; if (pScsiReq->cT2ISegs) RTSgBufInit(&pScsiReq->SgBufT2I, pScsiReq->paT2ISegs, pScsiReq->cT2ISegs); /* * Allocate twice as much entries as required for padding (worst case). * The additional segment is for the BHS. */ size_t cI2TSegs = 2*(pScsiReq->cI2TSegs + 1); pIScsiPDU = (PISCSIPDUTX)RTMemAllocZ(RT_OFFSETOF(ISCSIPDUTX, aISCSIReq[cI2TSegs])); if (!pIScsiPDU) return VERR_NO_MEMORY; pIScsiPDU->pIScsiCmd = pIScsiCmd; if (pScsiReq->enmXfer == SCSIXFER_FROM_TARGET) cbData = (uint32_t)pScsiReq->cbT2IData; else cbData = (uint32_t)pScsiReq->cbI2TData; paReqBHS = pIScsiPDU->aBHS; /* Setup the BHS. */ paReqBHS[0] = RT_H2N_U32( ISCSI_FINAL_BIT | ISCSI_TASK_ATTR_SIMPLE | ISCSIOP_SCSI_CMD | (pScsiReq->enmXfer << 21)); /* I=0,F=1,Attr=Simple */ paReqBHS[1] = RT_H2N_U32(0x00000000 | ((uint32_t)pScsiReq->cbI2TData & 0xffffff)); /* TotalAHSLength=0 */ paReqBHS[2] = RT_H2N_U32(pImage->LUN >> 32); paReqBHS[3] = RT_H2N_U32(pImage->LUN & 0xffffffff); paReqBHS[4] = pIScsiCmd->Itt; paReqBHS[5] = RT_H2N_U32(cbData); paReqBHS[6] = RT_H2N_U32(pImage->CmdSN); paReqBHS[7] = RT_H2N_U32(pImage->ExpStatSN); memcpy(paReqBHS + 8, pScsiReq->pvCDB, pScsiReq->cbCDB); pIScsiPDU->CmdSN = pImage->CmdSN; pImage->CmdSN++; /* Setup the S/G buffers. */ uint32_t cnISCSIReq = 0; pIScsiPDU->aISCSIReq[cnISCSIReq].cbSeg = sizeof(pIScsiPDU->aBHS); pIScsiPDU->aISCSIReq[cnISCSIReq].pvSeg = pIScsiPDU->aBHS; cnISCSIReq++; cbSegs = sizeof(pIScsiPDU->aBHS); /* Padding is not necessary for the BHS. */ if (pScsiReq->cbI2TData) { for (unsigned cSeg = 0; cSeg < pScsiReq->cI2TSegs; cSeg++) { Assert(cnISCSIReq < cI2TSegs); pIScsiPDU->aISCSIReq[cnISCSIReq].cbSeg = pScsiReq->paI2TSegs[cSeg].cbSeg; pIScsiPDU->aISCSIReq[cnISCSIReq].pvSeg = pScsiReq->paI2TSegs[cSeg].pvSeg; cbSegs += pScsiReq->paI2TSegs[cSeg].cbSeg; cnISCSIReq++; /* Add padding if necessary. */ if (pScsiReq->paI2TSegs[cSeg].cbSeg & 3) { Assert(cnISCSIReq < cI2TSegs); pIScsiPDU->aISCSIReq[cnISCSIReq].pvSeg = &pImage->aPadding[0]; pIScsiPDU->aISCSIReq[cnISCSIReq].cbSeg = 4 - (pScsiReq->paI2TSegs[cSeg].cbSeg & 3); cbSegs += pIScsiPDU->aISCSIReq[cnISCSIReq].cbSeg; cnISCSIReq++; } } } pIScsiPDU->cISCSIReq = cnISCSIReq; pIScsiPDU->cbSgLeft = cbSegs; RTSgBufInit(&pIScsiPDU->SgBuf, pIScsiPDU->aISCSIReq, cnISCSIReq); /* Link the PDU to the list. */ iscsiPDUTxAdd(pImage, pIScsiPDU, false /* fFront */); /* Start transfer of a PDU if there is no one active at the moment. */ if (!pImage->pIScsiPDUTxCur) rc = iscsiSendPDUAsync(pImage); return rc; } /** * Updates the state of a request from the PDU we received. * * @return VBox status code. * @param pImage iSCSI connection state to use. * @param paRes Pointer to array of iSCSI response sections. * @param cnRes Number of valid iSCSI response sections in the array. */ static int iscsiRecvPDUUpdateRequest(PISCSIIMAGE pImage, PISCSIRES paRes, uint32_t cnRes) { int rc = VINF_SUCCESS; PISCSICMD pIScsiCmd; uint32_t *paResBHS; LogFlowFunc(("pImage=%#p paRes=%#p cnRes=%u\n", pImage, paRes, cnRes)); Assert(cnRes == 1); Assert(paRes[0].cbSeg >= ISCSI_BHS_SIZE); paResBHS = (uint32_t *)paRes[0].pvSeg; pIScsiCmd = iscsiCmdGetFromItt(pImage, paResBHS[4]); if (pIScsiCmd) { bool final = false; PSCSIREQ pScsiReq; LogFlow(("Found SCSI command %#p for Itt=%#u\n", pIScsiCmd, paResBHS[4])); Assert(pIScsiCmd->enmCmdType == ISCSICMDTYPE_REQ); pScsiReq = pIScsiCmd->CmdType.ScsiReq.pScsiReq; final = !!(RT_N2H_U32(paResBHS[0]) & ISCSI_FINAL_BIT); ISCSIOPCODE cmd = (ISCSIOPCODE)(RT_N2H_U32(paResBHS[0]) & ISCSIOP_MASK); if (cmd == ISCSIOP_SCSI_RES) { /* This is the final PDU which delivers the status (and may be omitted if * the last Data-In PDU included successful completion status). Note * that ExpStatSN has been bumped already in iscsiRecvPDU. */ if (!final || ((RT_N2H_U32(paResBHS[0]) & 0x0000ff00) != 0) || (RT_N2H_U32(paResBHS[6]) != pImage->ExpStatSN - 1)) { /* SCSI Response in the wrong place or with a (target) failure. */ LogFlow(("Wrong ExpStatSN value in PDU\n")); rc = VERR_PARSE_ERROR; } else { pScsiReq->status = RT_N2H_U32(paResBHS[0]) & 0x000000ff; size_t cbData = RT_N2H_U32(paResBHS[1]) & 0x00ffffff; void *pvSense = (uint8_t *)paRes[0].pvSeg + ISCSI_BHS_SIZE; if (cbData >= 2) { uint32_t cbStat = RT_N2H_U32(((uint32_t *)pvSense)[0]) >> 16; if (cbStat + 2 > cbData) { rc = VERR_BUFFER_OVERFLOW; } else { /* Truncate sense data if it doesn't fit into the buffer. */ pScsiReq->cbSense = RT_MIN(cbStat, pScsiReq->cbSense); memcpy(pScsiReq->pvSense, (uint8_t *)pvSense + 2, RT_MIN(paRes[0].cbSeg - ISCSI_BHS_SIZE - 2, pScsiReq->cbSense)); } } else if (cbData == 1) rc = VERR_PARSE_ERROR; else pScsiReq->cbSense = 0; } iscsiCmdComplete(pImage, pIScsiCmd, rc); } else if (cmd == ISCSIOP_SCSI_DATA_IN) { /* A Data-In PDU carries some data that needs to be added to the received * data in response to the command. There may be both partial and complete * Data-In PDUs, so collect data until the status is included or the status * is sent in a separate SCSI Result frame (see above). */ size_t cbData = RT_N2H_U32(paResBHS[1]) & 0x00ffffff; void *pvData = (uint8_t *)paRes[0].pvSeg + ISCSI_BHS_SIZE; if (final && cbData > pScsiReq->cbT2IData) { /* The received PDU is bigger than what we requested. * Must not happen under normal circumstances and is a target error. */ rc = VERR_BUFFER_OVERFLOW; } else { /* Copy data from the received PDU into the T2I segments. */ size_t cbCopied = RTSgBufCopyFromBuf(&pScsiReq->SgBufT2I, pvData, cbData); Assert(cbCopied == cbData); if (final && (RT_N2H_U32(paResBHS[0]) & ISCSI_STATUS_BIT) != 0) { pScsiReq->status = RT_N2H_U32(paResBHS[0]) & 0x000000ff; pScsiReq->cbSense = 0; iscsiCmdComplete(pImage, pIScsiCmd, VINF_SUCCESS); } } } else rc = VERR_PARSE_ERROR; } /* Log any errors here but ignore the PDU. */ if (RT_FAILURE(rc)) { LogRel(("iSCSI: Received malformed PDU from target %s (rc=%Rrc), ignoring\n", pImage->pszTargetName, rc)); rc = VINF_SUCCESS; } return rc; } /** * Appends a key-value pair to the buffer. Normal ASCII strings (cbValue == 0) and large binary values * of a given length (cbValue > 0) are directly supported. Other value types must be converted to ASCII * by the caller. Strings must be in UTF-8 encoding. * * @returns VBOX status * @param pbBuf Pointer to the key-value buffer. * @param cbBuf Length of the key-value buffer. * @param pcbBufCurr Currently used portion of the key-value buffer. * @param pszKey Pointer to a string containing the key. * @param pszValue Pointer to either a string containing the value or to a large binary value. * @param cbValue Length of the binary value if applicable. */ static int iscsiTextAddKeyValue(uint8_t *pbBuf, size_t cbBuf, size_t *pcbBufCurr, const char *pcszKey, const char *pcszValue, size_t cbValue) { size_t cbBufTmp = *pcbBufCurr; size_t cbKey = strlen(pcszKey); size_t cbValueEnc; uint8_t *pbCurr; if (cbValue == 0) cbValueEnc = strlen(pcszValue); else cbValueEnc = cbValue * 2 + 2; /* 2 hex bytes per byte, 2 bytes prefix */ if (cbBuf < cbBufTmp + cbKey + 1 + cbValueEnc + 1) { /* Buffer would overflow, signal error. */ return VERR_BUFFER_OVERFLOW; } /* * Append a key=value pair (zero terminated string) to the end of the buffer. */ pbCurr = pbBuf + cbBufTmp; memcpy(pbCurr, pcszKey, cbKey); pbCurr += cbKey; *pbCurr++ = '='; if (cbValue == 0) { memcpy(pbCurr, pcszValue, cbValueEnc); pbCurr += cbValueEnc; } else { *pbCurr++ = '0'; *pbCurr++ = 'x'; for (uint32_t i = 0; i < cbValue; i++) { uint8_t b; b = pcszValue[i]; *pbCurr++ = NUM_2_HEX(b >> 4); *pbCurr++ = NUM_2_HEX(b & 0xf); } } *pbCurr = '\0'; *pcbBufCurr = cbBufTmp + cbKey + 1 + cbValueEnc + 1; return VINF_SUCCESS; } /** * Retrieve the value for a given key from the key=value buffer. * * @returns VBOX status. * @param pbBuf Buffer containing key=value pairs. * @param cbBuf Length of buffer with key=value pairs. * @param pszKey Pointer to key for which to retrieve the value. * @param ppszValue Pointer to value string pointer. */ static int iscsiTextGetKeyValue(const uint8_t *pbBuf, size_t cbBuf, const char *pcszKey, const char **ppcszValue) { size_t cbKey = strlen(pcszKey); while (cbBuf != 0) { size_t cbKeyValNull = strlen((const char *)pbBuf) + 1; if (strncmp(pcszKey, (const char *)pbBuf, cbKey) == 0 && pbBuf[cbKey] == '=') { *ppcszValue = (const char *)(pbBuf + cbKey + 1); return VINF_SUCCESS; } pbBuf += cbKeyValNull; cbBuf -= cbKeyValNull; } return VERR_INVALID_NAME; } /** * Convert a long-binary value from a value string to the binary representation. * * @returns VBOX status * @param pszValue Pointer to a string containing the textual value representation. * @param pbValue Pointer to the value buffer for the binary value. * @param pcbValue In: length of value buffer, out: actual length of binary value. */ static int iscsiStrToBinary(const char *pcszValue, uint8_t *pbValue, size_t *pcbValue) { size_t cbValue = *pcbValue; char c1, c2, c3, c4; Assert(cbValue >= 1); if (strlen(pcszValue) < 3) return VERR_PARSE_ERROR; if (*pcszValue++ != '0') return VERR_PARSE_ERROR; switch (*pcszValue++) { case 'x': case 'X': if (strlen(pcszValue) & 1) { c1 = *pcszValue++; *pbValue++ = HEX_2_NUM(c1); cbValue--; } while (*pcszValue != '\0') { if (cbValue == 0) return VERR_BUFFER_OVERFLOW; c1 = *pcszValue++; if ((c1 < '0' || c1 > '9') && (c1 < 'a' || c1 > 'f') && (c1 < 'A' || c1 > 'F')) return VERR_PARSE_ERROR; c2 = *pcszValue++; if ((c2 < '0' || c2 > '9') && (c2 < 'a' || c2 > 'f') && (c2 < 'A' || c2 > 'F')) return VERR_PARSE_ERROR; *pbValue++ = (HEX_2_NUM(c1) << 4) | HEX_2_NUM(c2); cbValue--; } *pcbValue -= cbValue; break; case 'b': case 'B': if ((strlen(pcszValue) & 3) != 0) return VERR_PARSE_ERROR; while (*pcszValue != '\0') { uint32_t temp; if (cbValue == 0) return VERR_BUFFER_OVERFLOW; c1 = *pcszValue++; if ((c1 < 'A' || c1 > 'Z') && (c1 < 'a' || c1 >'z') && (c1 < '0' || c1 > '9') && (c1 != '+') && (c1 != '/')) return VERR_PARSE_ERROR; c2 = *pcszValue++; if ((c2 < 'A' || c2 > 'Z') && (c2 < 'a' || c2 >'z') && (c2 < '0' || c2 > '9') && (c2 != '+') && (c2 != '/')) return VERR_PARSE_ERROR; c3 = *pcszValue++; if ((c3 < 'A' || c3 > 'Z') && (c3 < 'a' || c3 >'z') && (c3 < '0' || c3 > '9') && (c3 != '+') && (c3 != '/') && (c3 != '=')) return VERR_PARSE_ERROR; c4 = *pcszValue++; if ( (c3 == '=' && c4 != '=') || ((c4 < 'A' || c4 > 'Z') && (c4 < 'a' || c4 >'z') && (c4 < '0' || c4 > '9') && (c4 != '+') && (c4 != '/') && (c4 != '='))) return VERR_PARSE_ERROR; temp = (B64_2_NUM(c1) << 18) | (B64_2_NUM(c2) << 12); if (c3 == '=') { if (*pcszValue != '\0') return VERR_PARSE_ERROR; *pbValue++ = temp >> 16; cbValue--; } else { temp |= B64_2_NUM(c3) << 6; if (c4 == '=') { if (*pcszValue != '\0') return VERR_PARSE_ERROR; if (cbValue < 2) return VERR_BUFFER_OVERFLOW; *pbValue++ = temp >> 16; *pbValue++ = (temp >> 8) & 0xff; cbValue -= 2; } else { temp |= B64_2_NUM(c4); if (cbValue < 3) return VERR_BUFFER_OVERFLOW; *pbValue++ = temp >> 16; *pbValue++ = (temp >> 8) & 0xff; *pbValue++ = temp & 0xff; cbValue -= 3; } } } *pcbValue -= cbValue; break; default: return VERR_PARSE_ERROR; } return VINF_SUCCESS; } /** * Retrieve the relevant parameter values and update the initiator state. * * @returns VBOX status. * @param pImage Current iSCSI initiator state. * @param pbBuf Buffer containing key=value pairs. * @param cbBuf Length of buffer with key=value pairs. */ static int iscsiUpdateParameters(PISCSIIMAGE pImage, const uint8_t *pbBuf, size_t cbBuf) { int rc; const char *pcszMaxRecvDataSegmentLength = NULL; const char *pcszMaxBurstLength = NULL; const char *pcszFirstBurstLength = NULL; rc = iscsiTextGetKeyValue(pbBuf, cbBuf, "MaxRecvDataSegmentLength", &pcszMaxRecvDataSegmentLength); if (rc == VERR_INVALID_NAME) rc = VINF_SUCCESS; if (RT_FAILURE(rc)) return VERR_PARSE_ERROR; rc = iscsiTextGetKeyValue(pbBuf, cbBuf, "MaxBurstLength", &pcszMaxBurstLength); if (rc == VERR_INVALID_NAME) rc = VINF_SUCCESS; if (RT_FAILURE(rc)) return VERR_PARSE_ERROR; rc = iscsiTextGetKeyValue(pbBuf, cbBuf, "FirstBurstLength", &pcszFirstBurstLength); if (rc == VERR_INVALID_NAME) rc = VINF_SUCCESS; if (RT_FAILURE(rc)) return VERR_PARSE_ERROR; if (pcszMaxRecvDataSegmentLength) { uint32_t cb = pImage->cbSendDataLength; rc = RTStrToUInt32Full(pcszMaxRecvDataSegmentLength, 0, &cb); AssertRC(rc); pImage->cbSendDataLength = RT_MIN(pImage->cbSendDataLength, cb); } if (pcszMaxBurstLength) { uint32_t cb = pImage->cbSendDataLength; rc = RTStrToUInt32Full(pcszMaxBurstLength, 0, &cb); AssertRC(rc); pImage->cbSendDataLength = RT_MIN(pImage->cbSendDataLength, cb); } if (pcszFirstBurstLength) { uint32_t cb = pImage->cbSendDataLength; rc = RTStrToUInt32Full(pcszFirstBurstLength, 0, &cb); AssertRC(rc); pImage->cbSendDataLength = RT_MIN(pImage->cbSendDataLength, cb); } return VINF_SUCCESS; } static bool serial_number_less(uint32_t s1, uint32_t s2) { return (s1 < s2 && s2 - s1 < 0x80000000) || (s1 > s2 && s1 - s2 > 0x80000000); } static bool serial_number_greater(uint32_t s1, uint32_t s2) { return (s1 < s2 && s2 - s1 > 0x80000000) || (s1 > s2 && s1 - s2 < 0x80000000); } #ifdef IMPLEMENT_TARGET_AUTH static void chap_md5_generate_challenge(uint8_t *pbChallenge, size_t *pcbChallenge) { uint8_t cbChallenge; cbChallenge = RTrand_U8(CHAP_MD5_CHALLENGE_MIN, CHAP_MD5_CHALLENGE_MAX); RTrand_bytes(pbChallenge, cbChallenge); *pcbChallenge = cbChallenge; } #endif static void chap_md5_compute_response(uint8_t *pbResponse, uint8_t id, const uint8_t *pbChallenge, size_t cbChallenge, const uint8_t *pbSecret, size_t cbSecret) { RTMD5CONTEXT ctx; uint8_t bId; bId = id; RTMd5Init(&ctx); RTMd5Update(&ctx, &bId, 1); RTMd5Update(&ctx, pbSecret, cbSecret); RTMd5Update(&ctx, pbChallenge, cbChallenge); RTMd5Final(pbResponse, &ctx); } /** * Internal. - Wrapper around the extended select callback of the net interface. */ DECLINLINE(int) iscsiIoThreadWait(PISCSIIMAGE pImage, RTMSINTERVAL cMillies, uint32_t fEvents, uint32_t *pfEvents) { return pImage->pIfNet->pfnSelectOneEx(pImage->Socket, fEvents, pfEvents, cMillies); } /** * Internal. - Pokes a thread waiting for I/O. */ DECLINLINE(int) iscsiIoThreadPoke(PISCSIIMAGE pImage) { return pImage->pIfNet->pfnPoke(pImage->Socket); } /** * Internal. - Get the next request from the queue. */ DECLINLINE(PISCSICMD) iscsiCmdGet(PISCSIIMAGE pImage) { int rc; PISCSICMD pIScsiCmd = NULL; rc = RTSemMutexRequest(pImage->MutexReqQueue, RT_INDEFINITE_WAIT); AssertRC(rc); pIScsiCmd = pImage->pScsiReqQueue; if (pIScsiCmd) { pImage->pScsiReqQueue = pIScsiCmd->pNext; pIScsiCmd->pNext = NULL; } rc = RTSemMutexRelease(pImage->MutexReqQueue); AssertRC(rc); return pIScsiCmd; } /** * Internal. - Adds the given command to the queue. */ DECLINLINE(int) iscsiCmdPut(PISCSIIMAGE pImage, PISCSICMD pIScsiCmd) { int rc = RTSemMutexRequest(pImage->MutexReqQueue, RT_INDEFINITE_WAIT); AssertRC(rc); pIScsiCmd->pNext = pImage->pScsiReqQueue; pImage->pScsiReqQueue = pIScsiCmd; rc = RTSemMutexRelease(pImage->MutexReqQueue); AssertRC(rc); iscsiIoThreadPoke(pImage); return rc; } /** * Internal. - Completes the request with the appropriate action. * Synchronous requests are completed with waking up the thread * and asynchronous ones by continuing the associated I/O context. */ static void iscsiCmdComplete(PISCSIIMAGE pImage, PISCSICMD pIScsiCmd, int rcCmd) { LogFlowFunc(("pImage=%#p pIScsiCmd=%#p rcCmd=%Rrc\n", pImage, pIScsiCmd, rcCmd)); /* Remove from the table first. */ iscsiCmdRemove(pImage, pIScsiCmd->Itt); /* Call completion callback. */ pIScsiCmd->pfnComplete(pImage, rcCmd, pIScsiCmd->pvUser); /* Free command structure. */ #ifdef DEBUG memset(pIScsiCmd, 0xff, sizeof(ISCSICMD)); #endif RTMemFree(pIScsiCmd); } /** * Reattaches the to the target after an error aborting * pending commands and resending them. * * @param pImage iSCSI connection state. */ static void iscsiReattach(PISCSIIMAGE pImage) { int rc = VINF_SUCCESS; PISCSICMD pIScsiCmdHead = NULL; PISCSICMD pIScsiCmd = NULL; PISCSICMD pIScsiCmdCur = NULL; PISCSIPDUTX pIScsiPDUTx = NULL; /* Close connection. */ iscsiTransportClose(pImage); pImage->state = ISCSISTATE_FREE; /* Reset PDU we are receiving. */ iscsiRecvPDUReset(pImage); /* * Abort all PDUs we are about to transmit, * the command need a new Itt if the relogin is successful. */ while (pImage->pIScsiPDUTxHead) { pIScsiPDUTx = pImage->pIScsiPDUTxHead; pImage->pIScsiPDUTxHead = pIScsiPDUTx->pNext; pIScsiCmd = pIScsiPDUTx->pIScsiCmd; if (pIScsiCmd) { /* Place on command list. */ pIScsiCmd->pNext = pIScsiCmdHead; pIScsiCmdHead = pIScsiCmd; } RTMemFree(pIScsiPDUTx); } /* Clear the tail pointer (safety precaution). */ pImage->pIScsiPDUTxTail = NULL; /* Clear the current PDU too. */ if (pImage->pIScsiPDUTxCur) { pIScsiPDUTx = pImage->pIScsiPDUTxCur; pImage->pIScsiPDUTxCur = NULL; pIScsiCmd = pIScsiPDUTx->pIScsiCmd; if (pIScsiCmd) { pIScsiCmd->pNext = pIScsiCmdHead; pIScsiCmdHead = pIScsiCmd; } RTMemFree(pIScsiPDUTx); } /* * Get all commands which are waiting for a response * They need to be resend too after a successful reconnect. */ pIScsiCmd = iscsiCmdRemoveAll(pImage); if (pIScsiCmd) { pIScsiCmdCur = pIScsiCmd; while (pIScsiCmdCur->pNext) pIScsiCmdCur = pIScsiCmdCur->pNext; /* * Place them in front of the list because they are the oldest requests * and need to be processed first to minimize the risk to time out. */ pIScsiCmdCur->pNext = pIScsiCmdHead; pIScsiCmdHead = pIScsiCmd; } /* Try to attach. */ rc = iscsiAttach(pImage); if (RT_SUCCESS(rc)) { /* Phew, we have a connection again. * Prepare new PDUs for the aborted commands. */ while (pIScsiCmdHead) { pIScsiCmd = pIScsiCmdHead; pIScsiCmdHead = pIScsiCmdHead->pNext; pIScsiCmd->pNext = NULL; rc = iscsiPDUTxPrepare(pImage, pIScsiCmd); AssertRC(rc); } } else { /* * Still no luck, complete commands with error so the caller * has a chance to inform the user and maybe resend the command. */ while (pIScsiCmdHead) { pIScsiCmd = pIScsiCmdHead; pIScsiCmdHead = pIScsiCmdHead->pNext; iscsiCmdComplete(pImage, pIScsiCmd, VERR_BROKEN_PIPE); } } } /** * Internal. Main iSCSI I/O worker. */ static DECLCALLBACK(int) iscsiIoThreadWorker(RTTHREAD ThreadSelf, void *pvUser) { PISCSIIMAGE pImage = (PISCSIIMAGE)pvUser; /* Initialize the initial event mask. */ pImage->fPollEvents = VD_INTERFACETCPNET_EVT_READ | VD_INTERFACETCPNET_EVT_ERROR; while (pImage->fRunning) { uint32_t fEvents; int rc; fEvents = 0; /* Wait for work or for data from the target. */ RTMSINTERVAL msWait; if (pImage->cCmdsWaiting) { pImage->fPollEvents &= ~VD_INTERFACETCPNET_HINT_INTERRUPT; msWait = pImage->uReadTimeout; } else { pImage->fPollEvents |= VD_INTERFACETCPNET_HINT_INTERRUPT; msWait = RT_INDEFINITE_WAIT; } LogFlow(("Waiting for events fPollEvents=%#x\n", pImage->fPollEvents)); rc = iscsiIoThreadWait(pImage, msWait, pImage->fPollEvents, &fEvents); if (rc == VERR_INTERRUPTED) { /* Check the queue. */ PISCSICMD pIScsiCmd = iscsiCmdGet(pImage); while (pIScsiCmd) { switch (pIScsiCmd->enmCmdType) { case ISCSICMDTYPE_REQ: { /* If there is no connection complete the command with an error. */ if (RT_LIKELY(iscsiIsClientConnected(pImage))) { rc = iscsiPDUTxPrepare(pImage, pIScsiCmd); AssertRC(rc); } else iscsiCmdComplete(pImage, pIScsiCmd, VERR_NET_CONNECTION_REFUSED); break; } case ISCSICMDTYPE_EXEC: { rc = pIScsiCmd->CmdType.Exec.pfnExec(pIScsiCmd->CmdType.Exec.pvUser); iscsiCmdComplete(pImage, pIScsiCmd, rc); break; } default: AssertMsgFailed(("Invalid command type %d\n", pIScsiCmd->enmCmdType)); } pIScsiCmd = iscsiCmdGet(pImage); } } else if (rc == VERR_TIMEOUT && pImage->cCmdsWaiting) { /* * We are waiting for a response from the target but * it didn't answered yet. * We assume the connection is broken and try to reconnect. */ LogFlow(("Timed out while waiting for an answer from the target, reconnecting\n")); iscsiReattach(pImage); } else if (RT_SUCCESS(rc) || rc == VERR_TIMEOUT) { Assert(pImage->state == ISCSISTATE_NORMAL); LogFlow(("Got socket events %#x\n", fEvents)); if (fEvents & VD_INTERFACETCPNET_EVT_READ) { /* Continue or start a new PDU receive task */ LogFlow(("There is data on the socket\n")); rc = iscsiRecvPDUAsync(pImage); if (rc == VERR_BROKEN_PIPE) iscsiReattach(pImage); else if (RT_FAILURE(rc)) iscsiLogRel(pImage, "iSCSI: Handling incoming request failed %Rrc\n", rc); } if (fEvents & VD_INTERFACETCPNET_EVT_WRITE) { LogFlow(("The socket is writable\n")); rc = iscsiSendPDUAsync(pImage); if (RT_FAILURE(rc)) { /* * Something unexpected happened, log the error and try to reset everything * by reattaching to the target. */ iscsiLogRel(pImage, "iSCSI: Sending PDU failed %Rrc\n", rc); iscsiReattach(pImage); } } if (fEvents & VD_INTERFACETCPNET_EVT_ERROR) { LogFlow(("An error ocurred\n")); iscsiReattach(pImage); } } else iscsiLogRel(pImage, "iSCSI: Waiting for I/O failed rc=%Rrc\n", rc); } return VINF_SUCCESS; } /** * Internal. - Enqueues a request asynchronously. */ static int iscsiCommandAsync(PISCSIIMAGE pImage, PSCSIREQ pScsiReq, PFNISCSICMDCOMPLETED pfnComplete, void *pvUser) { int rc; if (pImage->fExtendedSelectSupported) { PISCSICMD pIScsiCmd = (PISCSICMD)RTMemAllocZ(sizeof(ISCSICMD)); if (!pIScsiCmd) return VERR_NO_MEMORY; /* Init the command structure. */ pIScsiCmd->pNext = NULL; pIScsiCmd->enmCmdType = ISCSICMDTYPE_REQ; pIScsiCmd->pfnComplete = pfnComplete; pIScsiCmd->pvUser = pvUser; pIScsiCmd->CmdType.ScsiReq.pScsiReq = pScsiReq; rc = iscsiCmdPut(pImage, pIScsiCmd); if (RT_FAILURE(rc)) RTMemFree(pIScsiCmd); } else rc = VERR_NOT_SUPPORTED; return rc; } static void iscsiCommandCompleteSync(PISCSIIMAGE pImage, int rcReq, void *pvUser) { PISCSICMDSYNC pIScsiCmdSync = (PISCSICMDSYNC)pvUser; pIScsiCmdSync->rcCmd = rcReq; int rc = RTSemEventSignal(pIScsiCmdSync->EventSem); AssertRC(rc); } /** * Internal. - Enqueues a request in a synchronous fashion * i.e. returns when the request completed. */ static int iscsiCommandSync(PISCSIIMAGE pImage, PSCSIREQ pScsiReq, bool fRetry, int rcSense) { int rc; if (pImage->fExtendedSelectSupported) { ISCSICMDSYNC IScsiCmdSync; /* Create event semaphore. */ rc = RTSemEventCreate(&IScsiCmdSync.EventSem); if (RT_FAILURE(rc)) return rc; if (fRetry) { for (unsigned i = 0; i < 10; i++) { rc = iscsiCommandAsync(pImage, pScsiReq, iscsiCommandCompleteSync, &IScsiCmdSync); if (RT_FAILURE(rc)) break; rc = RTSemEventWait(IScsiCmdSync.EventSem, RT_INDEFINITE_WAIT); AssertRC(rc); rc = IScsiCmdSync.rcCmd; if ( (RT_SUCCESS(rc) && !pScsiReq->cbSense) || RT_FAILURE(rc)) break; rc = rcSense; } } else { rc = iscsiCommandAsync(pImage, pScsiReq, iscsiCommandCompleteSync, &IScsiCmdSync); if (RT_SUCCESS(rc)) { rc = RTSemEventWait(IScsiCmdSync.EventSem, RT_INDEFINITE_WAIT); AssertRC(rc); rc = IScsiCmdSync.rcCmd; if (RT_FAILURE(rc) || pScsiReq->cbSense > 0) rc = rcSense; } } RTSemEventDestroy(IScsiCmdSync.EventSem); } else { if (fRetry) { for (unsigned i = 0; i < 10; i++) { rc = iscsiCommand(pImage, pScsiReq); if ( (RT_SUCCESS(rc) && !pScsiReq->cbSense) || RT_FAILURE(rc)) break; rc = rcSense; } } else { rc = iscsiCommand(pImage, pScsiReq); if (RT_SUCCESS(rc) && pScsiReq->cbSense > 0) rc = rcSense; } } return rc; } /** * Internal. - Executes a given function in a synchronous fashion * on the I/O thread if available. */ static int iscsiExecSync(PISCSIIMAGE pImage, PFNISCSIEXEC pfnExec, void *pvUser) { int rc; if (pImage->fExtendedSelectSupported) { ISCSICMDSYNC IScsiCmdSync; PISCSICMD pIScsiCmd = (PISCSICMD)RTMemAllocZ(sizeof(ISCSICMD)); if (!pIScsiCmd) return VERR_NO_MEMORY; /* Create event semaphore. */ rc = RTSemEventCreate(&IScsiCmdSync.EventSem); if (RT_FAILURE(rc)) { RTMemFree(pIScsiCmd); return rc; } /* Init the command structure. */ pIScsiCmd->pNext = NULL; pIScsiCmd->enmCmdType = ISCSICMDTYPE_EXEC; pIScsiCmd->pfnComplete = iscsiCommandCompleteSync; pIScsiCmd->pvUser = &IScsiCmdSync; pIScsiCmd->CmdType.Exec.pfnExec = pfnExec; pIScsiCmd->CmdType.Exec.pvUser = pvUser; rc = iscsiCmdPut(pImage, pIScsiCmd); if (RT_FAILURE(rc)) RTMemFree(pIScsiCmd); else { rc = RTSemEventWait(IScsiCmdSync.EventSem, RT_INDEFINITE_WAIT); AssertRC(rc); rc = IScsiCmdSync.rcCmd; } RTSemEventDestroy(IScsiCmdSync.EventSem); } else { /* No I/O thread, execute in the current thread. */ rc = pfnExec(pvUser); } return rc; } static void iscsiCommandAsyncComplete(PISCSIIMAGE pImage, int rcReq, void *pvUser) { bool fComplete = true; size_t cbTransfered = 0; PSCSIREQASYNC pReqAsync = (PSCSIREQASYNC)pvUser; PSCSIREQ pScsiReq = pReqAsync->pScsiReq; if ( RT_SUCCESS(rcReq) && pScsiReq->cbSense > 0) { /* Try again if possible. */ if (pReqAsync->cSenseRetries > 0) { pReqAsync->cSenseRetries--; pScsiReq->cbSense = sizeof(pReqAsync->abSense); int rc = iscsiCommandAsync(pImage, pScsiReq, iscsiCommandAsyncComplete, pReqAsync); if (RT_SUCCESS(rc)) fComplete = false; else rcReq = pReqAsync->rcSense; } else rcReq = pReqAsync->rcSense; } if (fComplete) { if (pScsiReq->enmXfer == SCSIXFER_FROM_TARGET) cbTransfered = pScsiReq->cbT2IData; else if (pScsiReq->enmXfer == SCSIXFER_TO_TARGET) cbTransfered = pScsiReq->cbI2TData; else AssertMsg(pScsiReq->enmXfer == SCSIXFER_NONE, ("To/From transfers are not supported yet\n")); /* Continue I/O context. */ pImage->pIfIo->pfnIoCtxCompleted(pImage->pIfIo->Core.pvUser, pReqAsync->pIoCtx, rcReq, cbTransfered); RTMemFree(pScsiReq); RTMemFree(pReqAsync); } } /** * Internal. Free all allocated space for representing an image, and optionally * delete the image from disk. */ static int iscsiFreeImage(PISCSIIMAGE pImage, bool fDelete) { int rc = VINF_SUCCESS; Assert(!fDelete); /* This MUST be false, the flag isn't supported. */ /* Freeing a never allocated image (e.g. because the open failed) is * not signalled as an error. After all nothing bad happens. */ if (pImage) { if (pImage->Mutex != NIL_RTSEMMUTEX) { /* Detaching only makes sense when the mutex is there. Otherwise the * failure happened long before we could attach to the target. */ iscsiExecSync(pImage, iscsiDetach, pImage); RTSemMutexDestroy(pImage->Mutex); pImage->Mutex = NIL_RTSEMMUTEX; } if (pImage->hThreadIo != NIL_RTTHREAD) { ASMAtomicXchgBool(&pImage->fRunning, false); rc = iscsiIoThreadPoke(pImage); AssertRC(rc); /* Wait for the thread to terminate. */ rc = RTThreadWait(pImage->hThreadIo, RT_INDEFINITE_WAIT, NULL); AssertRC(rc); } /* Destroy the socket. */ if (pImage->Socket != NIL_VDSOCKET) { pImage->pIfNet->pfnSocketDestroy(pImage->Socket); } if (pImage->MutexReqQueue != NIL_RTSEMMUTEX) { RTSemMutexDestroy(pImage->MutexReqQueue); pImage->MutexReqQueue = NIL_RTSEMMUTEX; } if (pImage->pszTargetName) { RTMemFree(pImage->pszTargetName); pImage->pszTargetName = NULL; } if (pImage->pszInitiatorName) { if (pImage->fAutomaticInitiatorName) RTStrFree(pImage->pszInitiatorName); else RTMemFree(pImage->pszInitiatorName); pImage->pszInitiatorName = NULL; } if (pImage->pszInitiatorUsername) { RTMemFree(pImage->pszInitiatorUsername); pImage->pszInitiatorUsername = NULL; } if (pImage->pbInitiatorSecret) { RTMemFree(pImage->pbInitiatorSecret); pImage->pbInitiatorSecret = NULL; } if (pImage->pszTargetUsername) { RTMemFree(pImage->pszTargetUsername); pImage->pszTargetUsername = NULL; } if (pImage->pbTargetSecret) { RTMemFree(pImage->pbTargetSecret); pImage->pbTargetSecret = NULL; } if (pImage->pvRecvPDUBuf) { RTMemFree(pImage->pvRecvPDUBuf); pImage->pvRecvPDUBuf = NULL; } pImage->cbRecvPDUResidual = 0; } LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** * Internal: Open an image, constructing all necessary data structures. */ static int iscsiOpenImage(PISCSIIMAGE pImage, unsigned uOpenFlags) { int rc; char *pszLUN = NULL, *pszLUNInitial = NULL; bool fLunEncoded = false; uint32_t uWriteSplitDef = 0; uint32_t uTimeoutDef = 0; uint64_t uHostIPTmp = 0; bool fHostIPDef = 0; rc = RTStrToUInt32Full(s_iscsiConfigDefaultWriteSplit, 0, &uWriteSplitDef); AssertRC(rc); rc = RTStrToUInt32Full(s_iscsiConfigDefaultTimeout, 0, &uTimeoutDef); AssertRC(rc); rc = RTStrToUInt64Full(s_iscsiConfigDefaultHostIPStack, 0, &uHostIPTmp); AssertRC(rc); fHostIPDef = !!uHostIPTmp; pImage->uOpenFlags = uOpenFlags; /* Get error signalling interface. */ pImage->pIfError = VDIfErrorGet(pImage->pVDIfsDisk); /* Get TCP network stack interface. */ pImage->pIfNet = VDIfTcpNetGet(pImage->pVDIfsImage); if (!pImage->pIfNet) { rc = vdIfError(pImage->pIfError, VERR_VD_ISCSI_UNKNOWN_INTERFACE, RT_SRC_POS, N_("iSCSI: TCP network stack interface missing")); goto out; } /* Get configuration interface. */ pImage->pIfConfig = VDIfConfigGet(pImage->pVDIfsImage); if (!pImage->pIfConfig) { rc = vdIfError(pImage->pIfError, VERR_VD_ISCSI_UNKNOWN_INTERFACE, RT_SRC_POS, N_("iSCSI: configuration interface missing")); goto out; } /* Get I/O interface. */ pImage->pIfIo = VDIfIoIntGet(pImage->pVDIfsImage); if (!pImage->pIfIo) { rc = vdIfError(pImage->pIfError, VERR_VD_ISCSI_UNKNOWN_INTERFACE, RT_SRC_POS, N_("iSCSI: I/O interface missing")); goto out; } /* This ISID will be adjusted later to make it unique on this host. */ pImage->ISID = 0x800000000000ULL | 0x001234560000ULL; pImage->cISCSIRetries = 10; pImage->state = ISCSISTATE_FREE; pImage->pvRecvPDUBuf = RTMemAlloc(ISCSI_RECV_PDU_BUFFER_SIZE); pImage->cbRecvPDUBuf = ISCSI_RECV_PDU_BUFFER_SIZE; if (pImage->pvRecvPDUBuf == NULL) { rc = VERR_NO_MEMORY; goto out; } pImage->Mutex = NIL_RTSEMMUTEX; pImage->MutexReqQueue = NIL_RTSEMMUTEX; rc = RTSemMutexCreate(&pImage->Mutex); if (RT_FAILURE(rc)) goto out; rc = RTSemMutexCreate(&pImage->MutexReqQueue); if (RT_FAILURE(rc)) goto out; /* Validate configuration, detect unknown keys. */ if (!VDCFGAreKeysValid(pImage->pIfConfig, "TargetName\0InitiatorName\0LUN\0TargetAddress\0InitiatorUsername\0InitiatorSecret\0TargetUsername\0TargetSecret\0WriteSplit\0Timeout\0HostIPStack\0")) { rc = vdIfError(pImage->pIfError, VERR_VD_ISCSI_UNKNOWN_CFG_VALUES, RT_SRC_POS, N_("iSCSI: configuration error: unknown configuration keys present")); goto out; } /* Query the iSCSI upper level configuration. */ rc = VDCFGQueryStringAlloc(pImage->pIfConfig, "TargetName", &pImage->pszTargetName); if (RT_FAILURE(rc)) { rc = vdIfError(pImage->pIfError, rc, RT_SRC_POS, N_("iSCSI: configuration error: failed to read TargetName as string")); goto out; } rc = VDCFGQueryStringAlloc(pImage->pIfConfig, "InitiatorName", &pImage->pszInitiatorName); if (rc == VERR_CFGM_VALUE_NOT_FOUND || rc == VERR_CFGM_NO_PARENT) { pImage->fAutomaticInitiatorName = true; rc = VINF_SUCCESS; } if (RT_FAILURE(rc)) { rc = vdIfError(pImage->pIfError, rc, RT_SRC_POS, N_("iSCSI: configuration error: failed to read InitiatorName as string")); goto out; } rc = VDCFGQueryStringAllocDef(pImage->pIfConfig, "LUN", &pszLUN, s_iscsiConfigDefaultLUN); if (RT_FAILURE(rc)) { rc = vdIfError(pImage->pIfError, rc, RT_SRC_POS, N_("iSCSI: configuration error: failed to read LUN as string")); goto out; } pszLUNInitial = pszLUN; if (!strncmp(pszLUN, "enc", 3)) { fLunEncoded = true; pszLUN += 3; } rc = RTStrToUInt64Full(pszLUN, 0, &pImage->LUN); if (RT_FAILURE(rc)) { rc = vdIfError(pImage->pIfError, rc, RT_SRC_POS, N_("iSCSI: configuration error: failed to convert LUN to integer")); goto out; } if (!fLunEncoded) { if (pImage->LUN <= 255) { pImage->LUN = pImage->LUN << 48; /* uses peripheral device addressing method */ } else if (pImage->LUN <= 16383) { pImage->LUN = (pImage->LUN << 48) | RT_BIT_64(62); /* uses flat space addressing method */ } else { rc = VERR_OUT_OF_RANGE; rc = vdIfError(pImage->pIfError, rc, RT_SRC_POS, N_("iSCSI: configuration error: LUN number out of range (0-16383)")); goto out; } } rc = VDCFGQueryStringAlloc(pImage->pIfConfig, "TargetAddress", &pImage->pszTargetAddress); if (RT_FAILURE(rc)) { rc = vdIfError(pImage->pIfError, rc, RT_SRC_POS, N_("iSCSI: configuration error: failed to read TargetAddress as string")); goto out; } pImage->pszInitiatorUsername = NULL; rc = VDCFGQueryStringAlloc(pImage->pIfConfig, "InitiatorUsername", &pImage->pszInitiatorUsername); if (rc == VERR_CFGM_VALUE_NOT_FOUND || rc == VERR_CFGM_NO_PARENT) rc = VINF_SUCCESS; if (RT_FAILURE(rc)) { rc = vdIfError(pImage->pIfError, rc, RT_SRC_POS, N_("iSCSI: configuration error: failed to read InitiatorUsername as string")); goto out; } pImage->pbInitiatorSecret = NULL; pImage->cbInitiatorSecret = 0; rc = VDCFGQueryBytesAlloc(pImage->pIfConfig, "InitiatorSecret", (void **)&pImage->pbInitiatorSecret, &pImage->cbInitiatorSecret); if (rc == VERR_CFGM_VALUE_NOT_FOUND || rc == VERR_CFGM_NO_PARENT) rc = VINF_SUCCESS; if (RT_FAILURE(rc)) { rc = vdIfError(pImage->pIfError, rc, RT_SRC_POS, N_("iSCSI: configuration error: failed to read InitiatorSecret as byte string")); goto out; } pImage->pszTargetUsername = NULL; rc = VDCFGQueryStringAlloc(pImage->pIfConfig, "TargetUsername", &pImage->pszTargetUsername); if (rc == VERR_CFGM_VALUE_NOT_FOUND || rc == VERR_CFGM_NO_PARENT) rc = VINF_SUCCESS; if (RT_FAILURE(rc)) { rc = vdIfError(pImage->pIfError, rc, RT_SRC_POS, N_("iSCSI: configuration error: failed to read TargetUsername as string")); goto out; } pImage->pbTargetSecret = NULL; pImage->cbTargetSecret = 0; rc = VDCFGQueryBytesAlloc(pImage->pIfConfig, "TargetSecret", (void **)&pImage->pbTargetSecret, &pImage->cbTargetSecret); if (rc == VERR_CFGM_VALUE_NOT_FOUND || rc == VERR_CFGM_NO_PARENT) rc = VINF_SUCCESS; if (RT_FAILURE(rc)) { rc = vdIfError(pImage->pIfError, rc, RT_SRC_POS, N_("iSCSI: configuration error: failed to read TargetSecret as byte string")); goto out; } rc = VDCFGQueryU32Def(pImage->pIfConfig, "WriteSplit", &pImage->cbWriteSplit, uWriteSplitDef); if (RT_FAILURE(rc)) { rc = vdIfError(pImage->pIfError, rc, RT_SRC_POS, N_("iSCSI: configuration error: failed to read WriteSplit as U32")); goto out; } pImage->pszHostname = NULL; pImage->uPort = 0; pImage->Socket = NIL_VDSOCKET; /* Query the iSCSI lower level configuration. */ rc = VDCFGQueryU32Def(pImage->pIfConfig, "Timeout", &pImage->uReadTimeout, uTimeoutDef); if (RT_FAILURE(rc)) { rc = vdIfError(pImage->pIfError, rc, RT_SRC_POS, N_("iSCSI: configuration error: failed to read Timeout as U32")); goto out; } rc = VDCFGQueryBoolDef(pImage->pIfConfig, "HostIPStack", &pImage->fHostIP, fHostIPDef); if (RT_FAILURE(rc)) { rc = vdIfError(pImage->pIfError, rc, RT_SRC_POS, N_("iSCSI: configuration error: failed to read HostIPStack as boolean")); goto out; } /* Don't actually establish iSCSI transport connection if this is just an * open to query the image information and the host IP stack isn't used. * Even trying is rather useless, as in this context the InTnet IP stack * isn't present. Returning dummies is the best possible result anyway. */ if ((uOpenFlags & VD_OPEN_FLAGS_INFO) && !pImage->fHostIP) { LogFunc(("Not opening the transport connection as IntNet IP stack is not available. Will return dummies\n")); goto out; } memset(pImage->aCmdsWaiting, 0, sizeof(pImage->aCmdsWaiting)); pImage->cbRecvPDUResidual = 0; /* Create the socket structure. */ rc = pImage->pIfNet->pfnSocketCreate(VD_INTERFACETCPNET_CONNECT_EXTENDED_SELECT, &pImage->Socket); if (RT_SUCCESS(rc)) { pImage->fExtendedSelectSupported = true; pImage->fRunning = true; rc = RTThreadCreate(&pImage->hThreadIo, iscsiIoThreadWorker, pImage, 0, RTTHREADTYPE_IO, RTTHREADFLAGS_WAITABLE, "iSCSI-Io"); if (RT_FAILURE(rc)) { LogFunc(("Creating iSCSI I/O thread failed rc=%Rrc\n", rc)); goto out; } } else if (rc == VERR_NOT_SUPPORTED) { /* Async I/O is not supported without extended select. */ if ((uOpenFlags & VD_OPEN_FLAGS_ASYNC_IO)) { LogFunc(("Extended select is not supported by the interface but async I/O is requested -> %Rrc\n", rc)); goto out; } else { pImage->fExtendedSelectSupported = false; rc = pImage->pIfNet->pfnSocketCreate(0, &pImage->Socket); if (RT_FAILURE(rc)) { LogFunc(("Creating socket failed -> %Rrc\n", rc)); goto out; } } } else { LogFunc(("Creating socket failed -> %Rrc\n", rc)); goto out; } /* * Attach to the iSCSI target. This implicitly establishes the iSCSI * transport connection. */ rc = iscsiExecSync(pImage, iscsiAttach, pImage); if (RT_FAILURE(rc)) { LogRel(("iSCSI: could not open target %s, rc=%Rrc\n", pImage->pszTargetName, rc)); goto out; } LogFlowFunc(("target '%s' opened successfully\n", pImage->pszTargetName)); SCSIREQ sr; RTSGSEG DataSeg; uint8_t sense[96]; uint8_t data8[8]; uint8_t data12[12]; /* * Inquire available LUNs - purely dummy request. */ uint8_t CDB_rlun[12]; uint8_t rlundata[16]; CDB_rlun[0] = SCSI_REPORT_LUNS; CDB_rlun[1] = 0; /* reserved */ CDB_rlun[2] = 0; /* reserved */ CDB_rlun[3] = 0; /* reserved */ CDB_rlun[4] = 0; /* reserved */ CDB_rlun[5] = 0; /* reserved */ CDB_rlun[6] = sizeof(rlundata) >> 24; CDB_rlun[7] = (sizeof(rlundata) >> 16) & 0xff; CDB_rlun[8] = (sizeof(rlundata) >> 8) & 0xff; CDB_rlun[9] = sizeof(rlundata) & 0xff; CDB_rlun[10] = 0; /* reserved */ CDB_rlun[11] = 0; /* control */ DataSeg.pvSeg = rlundata; DataSeg.cbSeg = sizeof(rlundata); sr.enmXfer = SCSIXFER_FROM_TARGET; sr.cbCDB = sizeof(CDB_rlun); sr.pvCDB = CDB_rlun; sr.cbI2TData = 0; sr.paI2TSegs = NULL; sr.cI2TSegs = 0; sr.cbT2IData = DataSeg.cbSeg; sr.paT2ISegs = &DataSeg; sr.cT2ISegs = 1; sr.cbSense = sizeof(sense); sr.pvSense = sense; rc = iscsiCommandSync(pImage, &sr, false, VERR_INVALID_STATE); if (RT_FAILURE(rc)) { LogRel(("iSCSI: Could not get LUN info for target %s, rc=%Rrc\n", pImage->pszTargetName, rc)); return rc; } /* * Inquire device characteristics - no tapes, scanners etc., please. */ uint8_t CDB_inq[6]; CDB_inq[0] = SCSI_INQUIRY; CDB_inq[1] = 0; /* reserved */ CDB_inq[2] = 0; /* reserved */ CDB_inq[3] = 0; /* reserved */ CDB_inq[4] = sizeof(data8); CDB_inq[5] = 0; /* control */ DataSeg.pvSeg = data8; DataSeg.cbSeg = sizeof(data8); sr.enmXfer = SCSIXFER_FROM_TARGET; sr.cbCDB = sizeof(CDB_inq); sr.pvCDB = CDB_inq; sr.cbI2TData = 0; sr.paI2TSegs = NULL; sr.cI2TSegs = 0; sr.cbT2IData = DataSeg.cbSeg; sr.paT2ISegs = &DataSeg; sr.cT2ISegs = 1; sr.cbSense = sizeof(sense); sr.pvSense = sense; rc = iscsiCommandSync(pImage, &sr, true /* fRetry */, VERR_INVALID_STATE); if (RT_SUCCESS(rc)) { uint8_t devType = (sr.cbT2IData > 0) ? data8[0] & SCSI_DEVTYPE_MASK : 255; if (devType != SCSI_DEVTYPE_DISK) { rc = vdIfError(pImage->pIfError, VERR_VD_ISCSI_INVALID_TYPE, RT_SRC_POS, N_("iSCSI: target address %s, target name %s, SCSI LUN %lld reports device type=%u"), pImage->pszTargetAddress, pImage->pszTargetName, pImage->LUN, devType); LogRel(("iSCSI: Unsupported SCSI peripheral device type %d for target %s\n", devType & SCSI_DEVTYPE_MASK, pImage->pszTargetName)); goto out; } uint8_t uCmdQueue = (sr.cbT2IData >= 8) ? data8[7] & SCSI_INQUIRY_CMDQUE_MASK : 0; if (uCmdQueue > 0) pImage->fCmdQueuingSupported = true; else if (uOpenFlags & VD_OPEN_FLAGS_ASYNC_IO) { rc = VERR_NOT_SUPPORTED; goto out; } LogRel(("iSCSI: target address %s, target name %s, %s command queuing\n", pImage->pszTargetAddress, pImage->pszTargetName, pImage->fCmdQueuingSupported ? "supports" : "doesn't support")); } else { LogRel(("iSCSI: Could not get INQUIRY info for target %s, rc=%Rrc\n", pImage->pszTargetName, rc)); goto out; } /* * Query write disable bit in the device specific parameter entry in the * mode parameter header. Refuse read/write opening of read only disks. */ uint8_t CDB_ms[6]; uint8_t data4[4]; CDB_ms[0] = SCSI_MODE_SENSE_6; CDB_ms[1] = 0; /* dbd=0/reserved */ CDB_ms[2] = 0x3f; /* pc=0/page code=0x3f, ask for all pages */ CDB_ms[3] = 0; /* subpage code=0, return everything in page_0 format */ CDB_ms[4] = sizeof(data4); /* allocation length=4 */ CDB_ms[5] = 0; /* control */ DataSeg.pvSeg = data4; DataSeg.cbSeg = sizeof(data4); sr.enmXfer = SCSIXFER_FROM_TARGET; sr.cbCDB = sizeof(CDB_ms); sr.pvCDB = CDB_ms; sr.cbI2TData = 0; sr.paI2TSegs = NULL; sr.cI2TSegs = 0; sr.cbT2IData = DataSeg.cbSeg; sr.paT2ISegs = &DataSeg; sr.cT2ISegs = 1; sr.cbSense = sizeof(sense); sr.pvSense = sense; rc = iscsiCommandSync(pImage, &sr, true /* fRetry */, VERR_INVALID_STATE); if (RT_SUCCESS(rc)) { if (!(uOpenFlags & VD_OPEN_FLAGS_READONLY) && data4[2] & 0x80) { rc = VERR_VD_IMAGE_READ_ONLY; goto out; } } else { LogRel(("iSCSI: Could not get MODE SENSE info for target %s, rc=%Rrc\n", pImage->pszTargetName, rc)); goto out; } /* * Determine sector size and capacity of the volume immediately. */ uint8_t CDB_cap[16]; RT_ZERO(data12); RT_ZERO(CDB_cap); CDB_cap[0] = SCSI_SERVICE_ACTION_IN_16; CDB_cap[1] = SCSI_SVC_ACTION_IN_READ_CAPACITY_16; /* subcommand */ CDB_cap[10+3] = sizeof(data12); /* allocation length (dword) */ DataSeg.pvSeg = data12; DataSeg.cbSeg = sizeof(data12); sr.enmXfer = SCSIXFER_FROM_TARGET; sr.cbCDB = sizeof(CDB_cap); sr.pvCDB = CDB_cap; sr.cbI2TData = 0; sr.paI2TSegs = NULL; sr.cI2TSegs = 0; sr.cbT2IData = DataSeg.cbSeg; sr.paT2ISegs = &DataSeg; sr.cT2ISegs = 1; sr.cbSense = sizeof(sense); sr.pvSense = sense; rc = iscsiCommandSync(pImage, &sr, false /* fRetry */, VINF_SUCCESS); if ( RT_SUCCESS(rc) && sr.status == SCSI_STATUS_OK) { pImage->cVolume = RT_BE2H_U64(*(uint64_t *)&data12[0]); pImage->cVolume++; pImage->cbSector = RT_BE2H_U32(*(uint32_t *)&data12[8]); pImage->cbSize = pImage->cVolume * pImage->cbSector; if (pImage->cVolume == 0 || pImage->cbSector != 512 || pImage->cbSize < pImage->cVolume) { rc = vdIfError(pImage->pIfError, VERR_VD_ISCSI_INVALID_TYPE, RT_SRC_POS, N_("iSCSI: target address %s, target name %s, SCSI LUN %lld reports media sector count=%llu sector size=%u"), pImage->pszTargetAddress, pImage->pszTargetName, pImage->LUN, pImage->cVolume, pImage->cbSector); } } else { uint8_t CDB_capfb[10]; RT_ZERO(data8); CDB_capfb[0] = SCSI_READ_CAPACITY; CDB_capfb[1] = 0; /* reserved */ CDB_capfb[2] = 0; /* reserved */ CDB_capfb[3] = 0; /* reserved */ CDB_capfb[4] = 0; /* reserved */ CDB_capfb[5] = 0; /* reserved */ CDB_capfb[6] = 0; /* reserved */ CDB_capfb[7] = 0; /* reserved */ CDB_capfb[8] = 0; /* reserved */ CDB_capfb[9] = 0; /* control */ DataSeg.pvSeg = data8; DataSeg.cbSeg = sizeof(data8); sr.enmXfer = SCSIXFER_FROM_TARGET; sr.cbCDB = sizeof(CDB_capfb); sr.pvCDB = CDB_capfb; sr.cbI2TData = 0; sr.paI2TSegs = NULL; sr.cI2TSegs = 0; sr.cbT2IData = DataSeg.cbSeg; sr.paT2ISegs = &DataSeg; sr.cT2ISegs = 1; sr.cbSense = sizeof(sense); sr.pvSense = sense; rc = iscsiCommandSync(pImage, &sr, false /* fRetry */, VINF_SUCCESS); if (RT_SUCCESS(rc)) { pImage->cVolume = (data8[0] << 24) | (data8[1] << 16) | (data8[2] << 8) | data8[3]; pImage->cVolume++; pImage->cbSector = (data8[4] << 24) | (data8[5] << 16) | (data8[6] << 8) | data8[7]; pImage->cbSize = pImage->cVolume * pImage->cbSector; if (pImage->cVolume == 0 || pImage->cbSector != 512) { rc = vdIfError(pImage->pIfError, VERR_VD_ISCSI_INVALID_TYPE, RT_SRC_POS, N_("iSCSI: fallback capacity detectio for target address %s, target name %s, SCSI LUN %lld reports media sector count=%llu sector size=%u"), pImage->pszTargetAddress, pImage->pszTargetName, pImage->LUN, pImage->cVolume, pImage->cbSector); } } else { LogRel(("iSCSI: Could not determine capacity of target %s, rc=%Rrc\n", pImage->pszTargetName, rc)); goto out; } } /* * Check the read and write cache bits. * Try to enable the cache if it is disabled. * * We already checked that this is a block access device. No need * to do it again. */ uint8_t aCachingModePage[32]; uint8_t aCDBModeSense6[6]; memset(aCachingModePage, '\0', sizeof(aCachingModePage)); aCDBModeSense6[0] = SCSI_MODE_SENSE_6; aCDBModeSense6[1] = 0; aCDBModeSense6[2] = (0x00 << 6) | (0x08 & 0x3f); /* Current values and caching mode page */ aCDBModeSense6[3] = 0; /* Sub page code. */ aCDBModeSense6[4] = sizeof(aCachingModePage) & 0xff; aCDBModeSense6[5] = 0; DataSeg.pvSeg = aCachingModePage; DataSeg.cbSeg = sizeof(aCachingModePage); sr.enmXfer = SCSIXFER_FROM_TARGET; sr.cbCDB = sizeof(aCDBModeSense6); sr.pvCDB = aCDBModeSense6; sr.cbI2TData = 0; sr.paI2TSegs = NULL; sr.cI2TSegs = 0; sr.cbT2IData = DataSeg.cbSeg; sr.paT2ISegs = &DataSeg; sr.cT2ISegs = 1; sr.cbSense = sizeof(sense); sr.pvSense = sense; rc = iscsiCommandSync(pImage, &sr, false /* fRetry */, VINF_SUCCESS); if ( RT_SUCCESS(rc) && (sr.status == SCSI_STATUS_OK) && (aCachingModePage[0] >= 15) && (aCachingModePage[4 + aCachingModePage[3]] & 0x3f) == 0x08 && (aCachingModePage[4 + aCachingModePage[3] + 1] > 3)) { uint32_t Offset = 4 + aCachingModePage[3]; /* * Check if the read and/or the write cache is disabled. * The write cache is disabled if bit 2 (WCE) is zero and * the read cache is disabled if bit 0 (RCD) is set. */ if (!ASMBitTest(&aCachingModePage[Offset + 2], 2) || ASMBitTest(&aCachingModePage[Offset + 2], 0)) { /* * Write Cache Enable (WCE) bit is zero or the Read Cache Disable (RCD) is one * So one of the caches is disabled. Enable both caches. * The rest is unchanged. */ ASMBitSet(&aCachingModePage[Offset + 2], 2); ASMBitClear(&aCachingModePage[Offset + 2], 0); uint8_t aCDBCaching[6]; aCDBCaching[0] = SCSI_MODE_SELECT_6; aCDBCaching[1] = 0; /* Don't write the page into NV RAM. */ aCDBCaching[2] = 0; aCDBCaching[3] = 0; aCDBCaching[4] = sizeof(aCachingModePage) & 0xff; aCDBCaching[5] = 0; DataSeg.pvSeg = aCachingModePage; DataSeg.cbSeg = sizeof(aCachingModePage); sr.enmXfer = SCSIXFER_TO_TARGET; sr.cbCDB = sizeof(aCDBCaching); sr.pvCDB = aCDBCaching; sr.cbI2TData = DataSeg.cbSeg; sr.paI2TSegs = &DataSeg; sr.cI2TSegs = 1; sr.cbT2IData = 0; sr.paT2ISegs = NULL; sr.cT2ISegs = 0; sr.cbSense = sizeof(sense); sr.pvSense = sense; sr.status = 0; rc = iscsiCommandSync(pImage, &sr, false /* fRetry */, VINF_SUCCESS); if ( RT_SUCCESS(rc) && (sr.status == SCSI_STATUS_OK)) { LogRel(("iSCSI: Enabled read and write cache of target %s\n", pImage->pszTargetName)); } else { /* Log failures but continue. */ LogRel(("iSCSI: Could not enable read and write cache of target %s, rc=%Rrc status=%#x\n", pImage->pszTargetName, rc, sr.status)); LogRel(("iSCSI: Sense:\n%.*Rhxd\n", sr.cbSense, sense)); rc = VINF_SUCCESS; } } } else { /* Log errors but continue. */ LogRel(("iSCSI: Could not check write cache of target %s, rc=%Rrc, got mode page %#x\n", pImage->pszTargetName, rc,aCachingModePage[0] & 0x3f)); LogRel(("iSCSI: Sense:\n%.*Rhxd\n", sr.cbSense, sense)); rc = VINF_SUCCESS; } out: if (RT_FAILURE(rc)) iscsiFreeImage(pImage, false); return rc; } /** @copydoc VBOXHDDBACKEND::pfnCheckIfValid */ static int iscsiCheckIfValid(const char *pszFilename, PVDINTERFACE pVDIfsDisk, PVDINTERFACE pVDIfsImage, VDTYPE *penmType) { LogFlowFunc(("pszFilename=\"%s\"\n", pszFilename)); /* iSCSI images can't be checked for validity this way, as the filename * just can't supply enough configuration information. */ int rc = VERR_VD_ISCSI_INVALID_HEADER; LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnOpen */ static int iscsiOpen(const char *pszFilename, unsigned uOpenFlags, PVDINTERFACE pVDIfsDisk, PVDINTERFACE pVDIfsImage, VDTYPE enmType, void **ppBackendData) { LogFlowFunc(("pszFilename=\"%s\" uOpenFlags=%#x pVDIfsDisk=%#p pVDIfsImage=%#p ppBackendData=%#p\n", pszFilename, uOpenFlags, pVDIfsDisk, pVDIfsImage, ppBackendData)); int rc; PISCSIIMAGE pImage; /* Check open flags. All valid flags are supported. */ if (uOpenFlags & ~VD_OPEN_FLAGS_MASK) { rc = VERR_INVALID_PARAMETER; goto out; } /* Check remaining arguments. */ if ( !VALID_PTR(pszFilename) || !*pszFilename || strchr(pszFilename, '"')) { rc = VERR_INVALID_PARAMETER; goto out; } pImage = (PISCSIIMAGE)RTMemAllocZ(sizeof(ISCSIIMAGE)); if (!pImage) { rc = VERR_NO_MEMORY; goto out; } pImage->pszFilename = pszFilename; pImage->pszInitiatorName = NULL; pImage->pszTargetName = NULL; pImage->pszTargetAddress = NULL; pImage->pszInitiatorUsername = NULL; pImage->pbInitiatorSecret = NULL; pImage->pszTargetUsername = NULL; pImage->pbTargetSecret = NULL; pImage->paCurrReq = NULL; pImage->pvRecvPDUBuf = NULL; pImage->pszHostname = NULL; pImage->pVDIfsDisk = pVDIfsDisk; pImage->pVDIfsImage = pVDIfsImage; pImage->cLogRelErrors = 0; rc = iscsiOpenImage(pImage, uOpenFlags); if (RT_SUCCESS(rc)) { LogFlowFunc(("target %s cVolume %d, cbSector %d\n", pImage->pszTargetName, pImage->cVolume, pImage->cbSector)); LogRel(("iSCSI: target address %s, target name %s, SCSI LUN %lld\n", pImage->pszTargetAddress, pImage->pszTargetName, pImage->LUN)); *ppBackendData = pImage; } else RTMemFree(pImage); out: LogFlowFunc(("returns %Rrc (pBackendData=%#p)\n", rc, *ppBackendData)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnCreate */ static int iscsiCreate(const char *pszFilename, uint64_t cbSize, unsigned uImageFlags, const char *pszComment, PCVDGEOMETRY pPCHSGeometry, PCVDGEOMETRY pLCHSGeometry, PCRTUUID pUuid, unsigned uOpenFlags, unsigned uPercentStart, unsigned uPercentSpan, PVDINTERFACE pVDIfsDisk, PVDINTERFACE pVDIfsImage, PVDINTERFACE pVDIfsOperation, void **ppBackendData) { LogFlowFunc(("pszFilename=\"%s\" cbSize=%llu uImageFlags=%#x pszComment=\"%s\" pPCHSGeometry=%#p pLCHSGeometry=%#p Uuid=%RTuuid uOpenFlags=%#x uPercentStart=%u uPercentSpan=%u pVDIfsDisk=%#p pVDIfsImage=%#p pVDIfsOperation=%#p ppBackendData=%#p", pszFilename, cbSize, uImageFlags, pszComment, pPCHSGeometry, pLCHSGeometry, pUuid, uOpenFlags, uPercentStart, uPercentSpan, pVDIfsDisk, pVDIfsImage, pVDIfsOperation, ppBackendData)); int rc = VERR_NOT_SUPPORTED; LogFlowFunc(("returns %Rrc (pBackendData=%#p)\n", rc, *ppBackendData)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnClose */ static int iscsiClose(void *pBackendData, bool fDelete) { LogFlowFunc(("pBackendData=%#p fDelete=%d\n", pBackendData, fDelete)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; Assert(!fDelete); /* This flag is unsupported. */ rc = iscsiFreeImage(pImage, fDelete); RTMemFree(pImage); LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnRead */ static int iscsiRead(void *pBackendData, uint64_t uOffset, void *pvBuf, size_t cbToRead, size_t *pcbActuallyRead) { /** @todo reinstate logging of the target everywhere - dropped temporarily */ LogFlowFunc(("pBackendData=%#p uOffset=%llu pvBuf=%#p cbToRead=%zu pcbActuallyRead=%#p\n", pBackendData, uOffset, pvBuf, cbToRead, pcbActuallyRead)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; uint64_t lba; uint16_t tls; int rc; Assert(pImage); Assert(uOffset % 512 == 0); Assert(cbToRead % 512 == 0); Assert(pImage->cbSector); AssertPtr(pvBuf); if ( uOffset + cbToRead > pImage->cbSize || cbToRead == 0) { rc = VERR_INVALID_PARAMETER; goto out; } /* * Clip read size to a value which is supported by the target. */ cbToRead = RT_MIN(cbToRead, pImage->cbRecvDataLength); lba = uOffset / pImage->cbSector; tls = (uint16_t)(cbToRead / pImage->cbSector); SCSIREQ sr; RTSGSEG T2ISeg; size_t cbCDB; uint8_t abCDB[16]; uint8_t sense[96]; if (pImage->cVolume < _4G) { cbCDB = 10; abCDB[0] = SCSI_READ_10; abCDB[1] = 0; /* reserved */ abCDB[2] = (lba >> 24) & 0xff; abCDB[3] = (lba >> 16) & 0xff; abCDB[4] = (lba >> 8) & 0xff; abCDB[5] = lba & 0xff; abCDB[6] = 0; /* reserved */ abCDB[7] = (tls >> 8) & 0xff; abCDB[8] = tls & 0xff; abCDB[9] = 0; /* control */ } else { cbCDB = 16; abCDB[0] = SCSI_READ_16; abCDB[1] = 0; /* reserved */ abCDB[2] = (lba >> 56) & 0xff; abCDB[3] = (lba >> 48) & 0xff; abCDB[4] = (lba >> 40) & 0xff; abCDB[5] = (lba >> 32) & 0xff; abCDB[6] = (lba >> 24) & 0xff; abCDB[7] = (lba >> 16) & 0xff; abCDB[8] = (lba >> 8) & 0xff; abCDB[9] = lba & 0xff; abCDB[10] = 0; /* tls unused */ abCDB[11] = 0; /* tls unused */ abCDB[12] = (tls >> 8) & 0xff; abCDB[13] = tls & 0xff; abCDB[14] = 0; /* reserved */ abCDB[15] = 0; /* reserved */ } T2ISeg.pvSeg = pvBuf; T2ISeg.cbSeg = cbToRead; sr.enmXfer = SCSIXFER_FROM_TARGET; sr.cbCDB = cbCDB; sr.pvCDB = abCDB; sr.cbI2TData = 0; sr.paI2TSegs = NULL; sr.cI2TSegs = 0; sr.cbT2IData = cbToRead; sr.paT2ISegs = &T2ISeg; sr.cT2ISegs = 1; sr.cbSense = sizeof(sense); sr.pvSense = sense; rc = iscsiCommandSync(pImage, &sr, true, VERR_READ_ERROR); if (RT_FAILURE(rc)) { LogFlow(("iscsiCommandSync(%s, %#llx) -> %Rrc\n", pImage->pszTargetName, uOffset, rc)); *pcbActuallyRead = 0; } else *pcbActuallyRead = sr.cbT2IData; out: LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnWrite */ static int iscsiWrite(void *pBackendData, uint64_t uOffset, const void *pvBuf, size_t cbToWrite, size_t *pcbWriteProcess, size_t *pcbPreRead, size_t *pcbPostRead, unsigned fWrite) { LogFlowFunc(("pBackendData=%#p uOffset=%llu pvBuf=%#p cbToWrite=%zu pcbWriteProcess=%#p pcbPreRead=%#p pcbPostRead=%#p\n", pBackendData, uOffset, pvBuf, cbToWrite, pcbWriteProcess, pcbPreRead, pcbPostRead)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; uint64_t lba; uint16_t tls; int rc; Assert(pImage); Assert(uOffset % 512 == 0); Assert(cbToWrite % 512 == 0); Assert(pImage->cbSector); Assert(pvBuf); if (pImage->uOpenFlags & VD_OPEN_FLAGS_READONLY) { rc = VERR_VD_IMAGE_READ_ONLY; goto out; } *pcbPreRead = 0; *pcbPostRead = 0; /* * Clip write size to a value which is supported by the target. */ cbToWrite = RT_MIN(cbToWrite, pImage->cbSendDataLength); lba = uOffset / pImage->cbSector; tls = (uint16_t)(cbToWrite / pImage->cbSector); SCSIREQ sr; RTSGSEG I2TSeg; size_t cbCDB; uint8_t abCDB[16]; uint8_t sense[96]; if (pImage->cVolume < _4G) { cbCDB = 10; abCDB[0] = SCSI_WRITE_10; abCDB[1] = 0; /* reserved */ abCDB[2] = (lba >> 24) & 0xff; abCDB[3] = (lba >> 16) & 0xff; abCDB[4] = (lba >> 8) & 0xff; abCDB[5] = lba & 0xff; abCDB[6] = 0; /* reserved */ abCDB[7] = (tls >> 8) & 0xff; abCDB[8] = tls & 0xff; abCDB[9] = 0; /* control */ } else { cbCDB = 16; abCDB[0] = SCSI_WRITE_16; abCDB[1] = 0; /* reserved */ abCDB[2] = (lba >> 56) & 0xff; abCDB[3] = (lba >> 48) & 0xff; abCDB[4] = (lba >> 40) & 0xff; abCDB[5] = (lba >> 32) & 0xff; abCDB[6] = (lba >> 24) & 0xff; abCDB[7] = (lba >> 16) & 0xff; abCDB[8] = (lba >> 8) & 0xff; abCDB[9] = lba & 0xff; abCDB[10] = 0; /* tls unused */ abCDB[11] = 0; /* tls unused */ abCDB[12] = (tls >> 8) & 0xff; abCDB[13] = tls & 0xff; abCDB[14] = 0; /* reserved */ abCDB[15] = 0; /* reserved */ } I2TSeg.pvSeg = (void *)pvBuf; I2TSeg.cbSeg = cbToWrite; sr.enmXfer = SCSIXFER_TO_TARGET; sr.cbCDB = cbCDB; sr.pvCDB = abCDB; sr.cbI2TData = cbToWrite; sr.paI2TSegs = &I2TSeg; sr.cI2TSegs = 1; sr.cbT2IData = 0; sr.paT2ISegs = NULL; sr.cT2ISegs = 0; sr.cbSense = sizeof(sense); sr.pvSense = sense; rc = iscsiCommandSync(pImage, &sr, true, VERR_WRITE_ERROR); if (RT_FAILURE(rc)) { LogFlow(("iscsiCommandSync(%s, %#llx) -> %Rrc\n", pImage->pszTargetName, uOffset, rc)); *pcbWriteProcess = 0; } else *pcbWriteProcess = cbToWrite; out: LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnFlush */ static int iscsiFlush(void *pBackendData) { LogFlowFunc(("pBackendData=%#p\n", pBackendData)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; Assert(pImage); SCSIREQ sr; uint8_t abCDB[10]; uint8_t sense[96]; abCDB[0] = SCSI_SYNCHRONIZE_CACHE; abCDB[1] = 0; /* reserved */ abCDB[2] = 0; /* LBA 0 */ abCDB[3] = 0; /* LBA 0 */ abCDB[4] = 0; /* LBA 0 */ abCDB[5] = 0; /* LBA 0 */ abCDB[6] = 0; /* reserved */ abCDB[7] = 0; /* transfer everything to disk */ abCDB[8] = 0; /* transfer everything to disk */ abCDB[9] = 0; /* control */ sr.enmXfer = SCSIXFER_NONE; sr.cbCDB = sizeof(abCDB); sr.pvCDB = abCDB; sr.cbI2TData = 0; sr.paI2TSegs = NULL; sr.cI2TSegs = 0; sr.cbT2IData = 0; sr.paT2ISegs = NULL; sr.cT2ISegs = 0; sr.cbSense = sizeof(sense); sr.pvSense = sense; rc = iscsiCommandSync(pImage, &sr, false, VINF_SUCCESS); if (RT_FAILURE(rc)) AssertMsgFailed(("iscsiCommand(%s) -> %Rrc\n", pImage->pszTargetName, rc)); LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnGetVersion */ static unsigned iscsiGetVersion(void *pBackendData) { LogFlowFunc(("pBackendData=%#p\n", pBackendData)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; Assert(pImage); NOREF(pImage); return 0; } /** @copydoc VBOXHDDBACKEND::pfnGetSize */ static uint64_t iscsiGetSize(void *pBackendData) { LogFlowFunc(("pBackendData=%#p\n", pBackendData)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; Assert(pImage); if (pImage) return pImage->cbSize; else return 0; } /** @copydoc VBOXHDDBACKEND::pfnGetFileSize */ static uint64_t iscsiGetFileSize(void *pBackendData) { LogFlowFunc(("pBackendData=%#p\n", pBackendData)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; Assert(pImage); NOREF(pImage); if (pImage) return pImage->cbSize; else return 0; } /** @copydoc VBOXHDDBACKEND::pfnGetPCHSGeometry */ static int iscsiGetPCHSGeometry(void *pBackendData, PVDGEOMETRY pPCHSGeometry) { LogFlowFunc(("pBackendData=%#p pPCHSGeometry=%#p\n", pBackendData, pPCHSGeometry)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; Assert(pImage); if (pImage) rc = VERR_VD_GEOMETRY_NOT_SET; else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc (PCHS=%u/%u/%u)\n", rc, pPCHSGeometry->cCylinders, pPCHSGeometry->cHeads, pPCHSGeometry->cSectors)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnSetPCHSGeometry */ static int iscsiSetPCHSGeometry(void *pBackendData, PCVDGEOMETRY pPCHSGeometry) { LogFlowFunc(("pBackendData=%#p pPCHSGeometry=%#p PCHS=%u/%u/%u\n", pBackendData, pPCHSGeometry, pPCHSGeometry->cCylinders, pPCHSGeometry->cHeads, pPCHSGeometry->cSectors)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; Assert(pImage); if (pImage) { if (pImage->uOpenFlags & VD_OPEN_FLAGS_READONLY) { rc = VERR_VD_IMAGE_READ_ONLY; goto out; } rc = VERR_VD_GEOMETRY_NOT_SET; } else rc = VERR_VD_NOT_OPENED; out: LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnGetLCHSGeometry */ static int iscsiGetLCHSGeometry(void *pBackendData, PVDGEOMETRY pLCHSGeometry) { LogFlowFunc(("pBackendData=%#p pLCHSGeometry=%#p\n", pBackendData, pLCHSGeometry)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; Assert(pImage); if (pImage) rc = VERR_VD_GEOMETRY_NOT_SET; else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc (LCHS=%u/%u/%u)\n", rc, pLCHSGeometry->cCylinders, pLCHSGeometry->cHeads, pLCHSGeometry->cSectors)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnSetLCHSGeometry */ static int iscsiSetLCHSGeometry(void *pBackendData, PCVDGEOMETRY pLCHSGeometry) { LogFlowFunc(("pBackendData=%#p pLCHSGeometry=%#p LCHS=%u/%u/%u\n", pBackendData, pLCHSGeometry, pLCHSGeometry->cCylinders, pLCHSGeometry->cHeads, pLCHSGeometry->cSectors)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; Assert(pImage); if (pImage) { if (pImage->uOpenFlags & VD_OPEN_FLAGS_READONLY) { rc = VERR_VD_IMAGE_READ_ONLY; goto out; } rc = VERR_VD_GEOMETRY_NOT_SET; } else rc = VERR_VD_NOT_OPENED; out: LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnGetImageFlags */ static unsigned iscsiGetImageFlags(void *pBackendData) { LogFlowFunc(("pBackendData=%#p\n", pBackendData)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; unsigned uImageFlags; Assert(pImage); NOREF(pImage); uImageFlags = VD_IMAGE_FLAGS_FIXED; LogFlowFunc(("returns %#x\n", uImageFlags)); return uImageFlags; } /** @copydoc VBOXHDDBACKEND::pfnGetOpenFlags */ static unsigned iscsiGetOpenFlags(void *pBackendData) { LogFlowFunc(("pBackendData=%#p\n", pBackendData)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; unsigned uOpenFlags; Assert(pImage); if (pImage) uOpenFlags = pImage->uOpenFlags; else uOpenFlags = 0; LogFlowFunc(("returns %#x\n", uOpenFlags)); return uOpenFlags; } /** @copydoc VBOXHDDBACKEND::pfnSetOpenFlags */ static int iscsiSetOpenFlags(void *pBackendData, unsigned uOpenFlags) { LogFlowFunc(("pBackendData=%#p\n uOpenFlags=%#x", pBackendData, uOpenFlags)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; /* Image must be opened and the new flags must be valid. */ if (!pImage || (uOpenFlags & ~(VD_OPEN_FLAGS_READONLY | VD_OPEN_FLAGS_INFO | VD_OPEN_FLAGS_ASYNC_IO | VD_OPEN_FLAGS_SHAREABLE | VD_OPEN_FLAGS_SEQUENTIAL))) { rc = VERR_INVALID_PARAMETER; goto out; } /* Implement this operation via reopening the image if we actually need * to do something. A read/write -> readonly transition doesn't need a * reopen. In the other direction we don't have the necessary information * as the "disk is readonly" flag is thrown away. Can be optimized too, * but it's not worth the effort at the moment. */ if ( !(uOpenFlags & VD_OPEN_FLAGS_READONLY) && (pImage->uOpenFlags & VD_OPEN_FLAGS_READONLY)) { iscsiFreeImage(pImage, false); rc = iscsiOpenImage(pImage, uOpenFlags); } else { pImage->uOpenFlags = uOpenFlags; rc = VINF_SUCCESS; } out: LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnGetComment */ static int iscsiGetComment(void *pBackendData, char *pszComment, size_t cbComment) { LogFlowFunc(("pBackendData=%#p pszComment=%#p cbComment=%zu\n", pBackendData, pszComment, cbComment)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; Assert(pImage); if (pImage) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc comment='%s'\n", rc, pszComment)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnSetComment */ static int iscsiSetComment(void *pBackendData, const char *pszComment) { LogFlowFunc(("pBackendData=%#p pszComment=\"%s\"\n", pBackendData, pszComment)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; Assert(pImage); if (pImage) { if (!(pImage->uOpenFlags & VD_OPEN_FLAGS_READONLY)) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_IMAGE_READ_ONLY; } else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnGetUuid */ static int iscsiGetUuid(void *pBackendData, PRTUUID pUuid) { LogFlowFunc(("pBackendData=%#p pUuid=%#p\n", pBackendData, pUuid)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; Assert(pImage); if (pImage) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc (%RTuuid)\n", rc, pUuid)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnSetUuid */ static int iscsiSetUuid(void *pBackendData, PCRTUUID pUuid) { LogFlowFunc(("pBackendData=%#p Uuid=%RTuuid\n", pBackendData, pUuid)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; LogFlowFunc(("%RTuuid\n", pUuid)); Assert(pImage); if (pImage) { if (!(pImage->uOpenFlags & VD_OPEN_FLAGS_READONLY)) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_IMAGE_READ_ONLY; } else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnGetModificationUuid */ static int iscsiGetModificationUuid(void *pBackendData, PRTUUID pUuid) { LogFlowFunc(("pBackendData=%#p pUuid=%#p\n", pBackendData, pUuid)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; Assert(pImage); if (pImage) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc (%RTuuid)\n", rc, pUuid)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnSetModificationUuid */ static int iscsiSetModificationUuid(void *pBackendData, PCRTUUID pUuid) { LogFlowFunc(("pBackendData=%#p Uuid=%RTuuid\n", pBackendData, pUuid)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; LogFlowFunc(("%RTuuid\n", pUuid)); Assert(pImage); if (pImage) { if (!(pImage->uOpenFlags & VD_OPEN_FLAGS_READONLY)) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_IMAGE_READ_ONLY; } else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnGetParentUuid */ static int iscsiGetParentUuid(void *pBackendData, PRTUUID pUuid) { LogFlowFunc(("pBackendData=%#p pUuid=%#p\n", pBackendData, pUuid)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; Assert(pImage); if (pImage) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc (%RTuuid)\n", rc, pUuid)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnSetParentUuid */ static int iscsiSetParentUuid(void *pBackendData, PCRTUUID pUuid) { LogFlowFunc(("pBackendData=%#p Uuid=%RTuuid\n", pBackendData, pUuid)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; LogFlowFunc(("%RTuuid\n", pUuid)); Assert(pImage); if (pImage) { if (!(pImage->uOpenFlags & VD_OPEN_FLAGS_READONLY)) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_IMAGE_READ_ONLY; } else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnGetParentModificationUuid */ static int iscsiGetParentModificationUuid(void *pBackendData, PRTUUID pUuid) { LogFlowFunc(("pBackendData=%#p pUuid=%#p\n", pBackendData, pUuid)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; Assert(pImage); if (pImage) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc (%RTuuid)\n", rc, pUuid)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnSetParentModificationUuid */ static int iscsiSetParentModificationUuid(void *pBackendData, PCRTUUID pUuid) { LogFlowFunc(("pBackendData=%#p Uuid=%RTuuid\n", pBackendData, pUuid)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc; LogFlowFunc(("%RTuuid\n", pUuid)); Assert(pImage); if (pImage) { if (!(pImage->uOpenFlags & VD_OPEN_FLAGS_READONLY)) rc = VERR_NOT_SUPPORTED; else rc = VERR_VD_IMAGE_READ_ONLY; } else rc = VERR_VD_NOT_OPENED; LogFlowFunc(("returns %Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnDump */ static void iscsiDump(void *pBackendData) { PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; Assert(pImage); if (pImage) { /** @todo put something useful here */ vdIfErrorMessage(pImage->pIfError, "Header: cVolume=%u\n", pImage->cVolume); } } /** @copydoc VBOXHDDBACKEND::pfnAsyncRead */ static int iscsiAsyncRead(void *pBackendData, uint64_t uOffset, size_t cbToRead, PVDIOCTX pIoCtx, size_t *pcbActuallyRead) { LogFlowFunc(("pBackendData=%p uOffset=%#llx pIoCtx=%#p cbToRead=%u pcbActuallyRead=%p\n", pBackendData, uOffset, pIoCtx, cbToRead, pcbActuallyRead)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc = VINF_SUCCESS; if (uOffset + cbToRead > pImage->cbSize) return VERR_INVALID_PARAMETER; /* * Clip read size to a value which is supported by the target. */ cbToRead = RT_MIN(cbToRead, pImage->cbRecvDataLength); unsigned cT2ISegs = 0; size_t cbSegs = 0; /* Get the number of segments. */ cbSegs = pImage->pIfIo->pfnIoCtxSegArrayCreate(pImage->pIfIo->Core.pvUser, pIoCtx, NULL, &cT2ISegs, cbToRead); Assert(cbSegs == cbToRead); PSCSIREQASYNC pReqAsync = (PSCSIREQASYNC)RTMemAllocZ(RT_OFFSETOF(SCSIREQASYNC, aSegs[cT2ISegs])); if (RT_LIKELY(pReqAsync)) { PSCSIREQ pReq = (PSCSIREQ)RTMemAllocZ(sizeof(SCSIREQ)); if (pReq) { uint64_t lba; uint16_t tls; uint8_t *pbCDB = &pReqAsync->abCDB[0]; size_t cbCDB; lba = uOffset / pImage->cbSector; tls = (uint16_t)(cbToRead / pImage->cbSector); cbSegs = pImage->pIfIo->pfnIoCtxSegArrayCreate(pImage->pIfIo->Core.pvUser, pIoCtx, &pReqAsync->aSegs[0], &cT2ISegs, cbToRead); Assert(cbSegs == cbToRead); pReqAsync->cT2ISegs = cT2ISegs; pReqAsync->pIoCtx = pIoCtx; pReqAsync->pScsiReq = pReq; pReqAsync->cSenseRetries = 10; pReqAsync->rcSense = VERR_READ_ERROR; if (pImage->cVolume < _4G) { cbCDB = 10; pbCDB[0] = SCSI_READ_10; pbCDB[1] = 0; /* reserved */ pbCDB[2] = (lba >> 24) & 0xff; pbCDB[3] = (lba >> 16) & 0xff; pbCDB[4] = (lba >> 8) & 0xff; pbCDB[5] = lba & 0xff; pbCDB[6] = 0; /* reserved */ pbCDB[7] = (tls >> 8) & 0xff; pbCDB[8] = tls & 0xff; pbCDB[9] = 0; /* control */ } else { cbCDB = 16; pbCDB[0] = SCSI_READ_16; pbCDB[1] = 0; /* reserved */ pbCDB[2] = (lba >> 56) & 0xff; pbCDB[3] = (lba >> 48) & 0xff; pbCDB[4] = (lba >> 40) & 0xff; pbCDB[5] = (lba >> 32) & 0xff; pbCDB[6] = (lba >> 24) & 0xff; pbCDB[7] = (lba >> 16) & 0xff; pbCDB[8] = (lba >> 8) & 0xff; pbCDB[9] = lba & 0xff; pbCDB[10] = 0; /* tls unused */ pbCDB[11] = 0; /* tls unused */ pbCDB[12] = (tls >> 8) & 0xff; pbCDB[13] = tls & 0xff; pbCDB[14] = 0; /* reserved */ pbCDB[15] = 0; /* reserved */ } pReq->enmXfer = SCSIXFER_FROM_TARGET; pReq->cbCDB = cbCDB; pReq->pvCDB = pReqAsync->abCDB; pReq->cbI2TData = 0; pReq->paI2TSegs = NULL; pReq->cI2TSegs = 0; pReq->cbT2IData = cbToRead; pReq->paT2ISegs = &pReqAsync->aSegs[pReqAsync->cI2TSegs]; pReq->cT2ISegs = pReqAsync->cT2ISegs; pReq->cbSense = sizeof(pReqAsync->abSense); pReq->pvSense = pReqAsync->abSense; rc = iscsiCommandAsync(pImage, pReq, iscsiCommandAsyncComplete, pReqAsync); if (RT_FAILURE(rc)) AssertMsgFailed(("iscsiCommand(%s, %#llx) -> %Rrc\n", pImage->pszTargetName, uOffset, rc)); else { *pcbActuallyRead = cbToRead; return VERR_VD_IOCTX_HALT; /* Halt the I/O context until further notification from the I/O thread. */ } RTMemFree(pReq); } else rc = VERR_NO_MEMORY; RTMemFree(pReqAsync); } else rc = VERR_NO_MEMORY; LogFlowFunc(("returns rc=%Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnAsyncWrite */ static int iscsiAsyncWrite(void *pBackendData, uint64_t uOffset, size_t cbToWrite, PVDIOCTX pIoCtx, size_t *pcbWriteProcess, size_t *pcbPreRead, size_t *pcbPostRead, unsigned fWrite) { LogFlowFunc(("pBackendData=%p uOffset=%llu pIoCtx=%#p cbToWrite=%u pcbWriteProcess=%p pcbPreRead=%p pcbPostRead=%p fWrite=%u\n", pBackendData, uOffset, pIoCtx, cbToWrite, pcbWriteProcess, pcbPreRead, pcbPostRead, fWrite)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc = VINF_SUCCESS; AssertPtr(pImage); Assert(uOffset % 512 == 0); Assert(cbToWrite % 512 == 0); if (uOffset + cbToWrite > pImage->cbSize) return VERR_INVALID_PARAMETER; /* * Clip read size to a value which is supported by the target. */ cbToWrite = RT_MIN(cbToWrite, pImage->cbSendDataLength); unsigned cI2TSegs = 0; size_t cbSegs = 0; /* Get the number of segments. */ cbSegs = pImage->pIfIo->pfnIoCtxSegArrayCreate(pImage->pIfIo->Core.pvUser, pIoCtx, NULL, &cI2TSegs, cbToWrite); Assert(cbSegs == cbToWrite); PSCSIREQASYNC pReqAsync = (PSCSIREQASYNC)RTMemAllocZ(RT_OFFSETOF(SCSIREQASYNC, aSegs[cI2TSegs])); if (RT_LIKELY(pReqAsync)) { PSCSIREQ pReq = (PSCSIREQ)RTMemAllocZ(sizeof(SCSIREQ)); if (pReq) { uint64_t lba; uint16_t tls; uint8_t *pbCDB = &pReqAsync->abCDB[0]; size_t cbCDB; lba = uOffset / pImage->cbSector; tls = (uint16_t)(cbToWrite / pImage->cbSector); cbSegs = pImage->pIfIo->pfnIoCtxSegArrayCreate(pImage->pIfIo->Core.pvUser, pIoCtx, &pReqAsync->aSegs[0], &cI2TSegs, cbToWrite); Assert(cbSegs == cbToWrite); pReqAsync->cI2TSegs = cI2TSegs; pReqAsync->pIoCtx = pIoCtx; pReqAsync->pScsiReq = pReq; pReqAsync->cSenseRetries = 10; pReqAsync->rcSense = VERR_WRITE_ERROR; if (pImage->cVolume < _4G) { cbCDB = 10; pbCDB[0] = SCSI_WRITE_10; pbCDB[1] = 0; /* reserved */ pbCDB[2] = (lba >> 24) & 0xff; pbCDB[3] = (lba >> 16) & 0xff; pbCDB[4] = (lba >> 8) & 0xff; pbCDB[5] = lba & 0xff; pbCDB[6] = 0; /* reserved */ pbCDB[7] = (tls >> 8) & 0xff; pbCDB[8] = tls & 0xff; pbCDB[9] = 0; /* control */ } else { cbCDB = 16; pbCDB[0] = SCSI_WRITE_16; pbCDB[1] = 0; /* reserved */ pbCDB[2] = (lba >> 56) & 0xff; pbCDB[3] = (lba >> 48) & 0xff; pbCDB[4] = (lba >> 40) & 0xff; pbCDB[5] = (lba >> 32) & 0xff; pbCDB[6] = (lba >> 24) & 0xff; pbCDB[7] = (lba >> 16) & 0xff; pbCDB[8] = (lba >> 8) & 0xff; pbCDB[9] = lba & 0xff; pbCDB[10] = 0; /* tls unused */ pbCDB[11] = 0; /* tls unused */ pbCDB[12] = (tls >> 8) & 0xff; pbCDB[13] = tls & 0xff; pbCDB[14] = 0; /* reserved */ pbCDB[15] = 0; /* reserved */ } pReq->enmXfer = SCSIXFER_TO_TARGET; pReq->cbCDB = cbCDB; pReq->pvCDB = pReqAsync->abCDB; pReq->cbI2TData = cbToWrite; pReq->paI2TSegs = &pReqAsync->aSegs[0]; pReq->cI2TSegs = pReqAsync->cI2TSegs; pReq->cbT2IData = 0; pReq->paT2ISegs = NULL; pReq->cT2ISegs = 0; pReq->cbSense = sizeof(pReqAsync->abSense); pReq->pvSense = pReqAsync->abSense; rc = iscsiCommandAsync(pImage, pReq, iscsiCommandAsyncComplete, pReqAsync); if (RT_FAILURE(rc)) AssertMsgFailed(("iscsiCommand(%s, %#llx) -> %Rrc\n", pImage->pszTargetName, uOffset, rc)); else { *pcbWriteProcess = cbToWrite; return VERR_VD_IOCTX_HALT; /* Halt the I/O context until further notification from the I/O thread. */ } RTMemFree(pReq); } else rc = VERR_NO_MEMORY; RTMemFree(pReqAsync); } else rc = VERR_NO_MEMORY; LogFlowFunc(("returns rc=%Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnAsyncFlush */ static int iscsiAsyncFlush(void *pBackendData, PVDIOCTX pIoCtx) { LogFlowFunc(("pBackendData=%p pIoCtx=%#p\n", pBackendData, pIoCtx)); PISCSIIMAGE pImage = (PISCSIIMAGE)pBackendData; int rc = VINF_SUCCESS; PSCSIREQASYNC pReqAsync = (PSCSIREQASYNC)RTMemAllocZ(sizeof(SCSIREQASYNC)); if (RT_LIKELY(pReqAsync)) { PSCSIREQ pReq = (PSCSIREQ)RTMemAllocZ(sizeof(SCSIREQ)); if (pReq) { uint8_t *pbCDB = &pReqAsync->abCDB[0]; pReqAsync->pIoCtx = pIoCtx; pReqAsync->pScsiReq = pReq; pReqAsync->cSenseRetries = 0; pReqAsync->rcSense = VINF_SUCCESS; pbCDB[0] = SCSI_SYNCHRONIZE_CACHE; pbCDB[1] = 0; /* reserved */ pbCDB[2] = 0; /* reserved */ pbCDB[3] = 0; /* reserved */ pbCDB[4] = 0; /* reserved */ pbCDB[5] = 0; /* reserved */ pbCDB[6] = 0; /* reserved */ pbCDB[7] = 0; /* reserved */ pbCDB[8] = 0; /* reserved */ pbCDB[9] = 0; /* control */ pReq->enmXfer = SCSIXFER_NONE; pReq->cbCDB = 10; pReq->pvCDB = pReqAsync->abCDB; pReq->cbI2TData = 0; pReq->paI2TSegs = NULL; pReq->cI2TSegs = 0; pReq->cbT2IData = 0; pReq->paT2ISegs = NULL; pReq->cT2ISegs = 0; pReq->cbSense = sizeof(pReqAsync->abSense); pReq->pvSense = pReqAsync->abSense; rc = iscsiCommandAsync(pImage, pReq, iscsiCommandAsyncComplete, pReqAsync); if (RT_FAILURE(rc)) AssertMsgFailed(("iscsiCommand(%s) -> %Rrc\n", pImage->pszTargetName, rc)); else return VERR_VD_IOCTX_HALT; /* Halt the I/O context until further notification from the I/O thread. */ RTMemFree(pReq); } else rc = VERR_NO_MEMORY; RTMemFree(pReqAsync); } else rc = VERR_NO_MEMORY; LogFlowFunc(("returns rc=%Rrc\n", rc)); return rc; } /** @copydoc VBOXHDDBACKEND::pfnComposeLocation */ static int iscsiComposeLocation(PVDINTERFACE pConfig, char **pszLocation) { char *pszTarget = NULL; char *pszLUN = NULL; char *pszAddress = NULL; int rc = VDCFGQueryStringAlloc(VDIfConfigGet(pConfig), "TargetName", &pszTarget); if (RT_SUCCESS(rc)) { rc = VDCFGQueryStringAlloc(VDIfConfigGet(pConfig), "LUN", &pszLUN); if (RT_SUCCESS(rc)) { rc = VDCFGQueryStringAlloc(VDIfConfigGet(pConfig), "TargetAddress", &pszAddress); if (RT_SUCCESS(rc)) { if (RTStrAPrintf(pszLocation, "iscsi://%s/%s/%s", pszAddress, pszTarget, pszLUN) < 0) rc = VERR_NO_MEMORY; } } } RTMemFree(pszTarget); RTMemFree(pszLUN); RTMemFree(pszAddress); return rc; } /** @copydoc VBOXHDDBACKEND::pfnComposeName */ static int iscsiComposeName(PVDINTERFACE pConfig, char **pszName) { char *pszTarget = NULL; char *pszLUN = NULL; char *pszAddress = NULL; int rc = VDCFGQueryStringAlloc(VDIfConfigGet(pConfig), "TargetName", &pszTarget); if (RT_SUCCESS(rc)) { rc = VDCFGQueryStringAlloc(VDIfConfigGet(pConfig), "LUN", &pszLUN); if (RT_SUCCESS(rc)) { rc = VDCFGQueryStringAlloc(VDIfConfigGet(pConfig), "TargetAddress", &pszAddress); if (RT_SUCCESS(rc)) { /** @todo think about a nicer looking location scheme for iSCSI */ if (RTStrAPrintf(pszName, "%s/%s/%s", pszAddress, pszTarget, pszLUN) < 0) rc = VERR_NO_MEMORY; } } } RTMemFree(pszTarget); RTMemFree(pszLUN); RTMemFree(pszAddress); return rc; } VBOXHDDBACKEND g_ISCSIBackend = { /* pszBackendName */ "iSCSI", /* cbSize */ sizeof(VBOXHDDBACKEND), /* uBackendCaps */ VD_CAP_CONFIG | VD_CAP_TCPNET | VD_CAP_ASYNC, /* papszFileExtensions */ NULL, /* paConfigInfo */ s_iscsiConfigInfo, /* hPlugin */ NIL_RTLDRMOD, /* pfnCheckIfValid */ iscsiCheckIfValid, /* pfnOpen */ iscsiOpen, /* pfnCreate */ iscsiCreate, /* pfnRename */ NULL, /* pfnClose */ iscsiClose, /* pfnRead */ iscsiRead, /* pfnWrite */ iscsiWrite, /* pfnFlush */ iscsiFlush, /* pfnGetVersion */ iscsiGetVersion, /* pfnGetSize */ iscsiGetSize, /* pfnGetFileSize */ iscsiGetFileSize, /* pfnGetPCHSGeometry */ iscsiGetPCHSGeometry, /* pfnSetPCHSGeometry */ iscsiSetPCHSGeometry, /* pfnGetLCHSGeometry */ iscsiGetLCHSGeometry, /* pfnSetLCHSGeometry */ iscsiSetLCHSGeometry, /* pfnGetImageFlags */ iscsiGetImageFlags, /* pfnGetOpenFlags */ iscsiGetOpenFlags, /* pfnSetOpenFlags */ iscsiSetOpenFlags, /* pfnGetComment */ iscsiGetComment, /* pfnSetComment */ iscsiSetComment, /* pfnGetUuid */ iscsiGetUuid, /* pfnSetUuid */ iscsiSetUuid, /* pfnGetModificationUuid */ iscsiGetModificationUuid, /* pfnSetModificationUuid */ iscsiSetModificationUuid, /* pfnGetParentUuid */ iscsiGetParentUuid, /* pfnSetParentUuid */ iscsiSetParentUuid, /* pfnGetParentModificationUuid */ iscsiGetParentModificationUuid, /* pfnSetParentModificationUuid */ iscsiSetParentModificationUuid, /* pfnDump */ iscsiDump, /* pfnGetTimeStamp */ NULL, /* pfnGetParentTimeStamp */ NULL, /* pfnSetParentTimeStamp */ NULL, /* pfnGetParentFilename */ NULL, /* pfnSetParentFilename */ NULL, /* pfnAsyncRead */ iscsiAsyncRead, /* pfnAsyncWrite */ iscsiAsyncWrite, /* pfnAsyncFlush */ iscsiAsyncFlush, /* pfnComposeLocation */ iscsiComposeLocation, /* pfnComposeName */ iscsiComposeName, /* pfnCompact */ NULL, /* pfnResize */ NULL, /* pfnDiscard */ NULL, /* pfnAsyncDiscard */ NULL, /* pfnRepair */ NULL };