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Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of Marvell nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. *******************************************************************************/ /******************************************************************************* * mvNfpSec.c - Marvell Network Fast Processing with IPSec(Routing only) * * DESCRIPTION: * * Supported Features: * - OS independent. * *******************************************************************************/ /* includes */ #include "mvOs.h" #include "mvDebug.h" #include "eth/nfp/mvNfp.h" #include "eth/mvEth.h" #include "eth/nfp/mvNfpSec.h" #include "cesa/mvCesa.h" /* IPSec SA & SPD DBs */ MV_NFP_SEC_SPD_RULE* spdInDb; MV_NFP_SEC_SPD_RULE* spdOutDb; MV_NFP_SEC_SA_ENTRY* saInDb; MV_NFP_SEC_SA_ENTRY* saOutDb; static MV_CESA_MBUF cesaMbufArray[MV_NFP_SEC_Q_SIZE]; static MV_CESA_COMMAND cesaCmdArray[MV_NFP_SEC_Q_SIZE]; static MV_NFP_SEC_CESA_PRIV cesaPrivArray[MV_NFP_SEC_Q_SIZE + MV_NFP_SEC_REQ_Q_SIZE]; static int cesaCmdIndx = 0; static int cesaPrivIndx = 0; static MV_U32 spdInRuleCount; static MV_U32 spdOutRuleCount; static MV_U32 saInEntryCount; static MV_U32 saOutEntryCount; static MV_U32 secDbSize; extern int cesaReqResources; MV_STATUS mvNfpSecInit(MV_U32 dbSize) { if(dbSize == 0) return MV_BAD_PARAM; spdInDb = (struct _mv_nfp_sec_spd_rule*)mvOsMalloc(dbSize * (sizeof(struct _mv_nfp_sec_spd_rule))); spdOutDb = (struct _mv_nfp_sec_spd_rule*)mvOsMalloc(dbSize * (sizeof(struct _mv_nfp_sec_spd_rule))); saInDb = (struct _mv_nfp_sec_sa_entry*)mvOsMalloc(dbSize * (sizeof(struct _mv_nfp_sec_sa_entry))); saOutDb = (struct _mv_nfp_sec_sa_entry*)mvOsMalloc(dbSize * (sizeof(struct _mv_nfp_sec_sa_entry))); if((spdInDb == NULL) || (spdOutDb== NULL) || (saInDb == NULL) || (saOutDb == NULL)) { mvOsPrintf("NFP-IPSec Rules DB: Not Enough Memory\n"); return MV_NO_RESOURCE; } secDbSize = dbSize; spdInRuleCount = spdOutRuleCount = saInEntryCount = saOutEntryCount = 0; memset(spdInDb, 0, (dbSize * sizeof(struct _mv_nfp_sec_spd_rule))); memset(spdOutDb, 0, (dbSize * sizeof(struct _mv_nfp_sec_spd_rule))); memset(saInDb, 0, (dbSize * sizeof(struct _mv_nfp_sec_sa_entry))); memset(saOutDb, 0, (dbSize * sizeof(struct _mv_nfp_sec_sa_entry))); return MV_OK; } MV_STATUS mvNfpSecDbClear(MV_VOID) { MV_U32 i; MV_NFP_SEC_SPD_RULE *pCurrSpdInRule, *pCurrSpdOutRule; MV_NFP_SEC_SA_ENTRY *pCurrSAInEntery, *pCurrSAOutEntery; if((spdInDb == NULL) && (spdOutDb == NULL) && (saInDb == NULL) && (saOutDb == NULL)) return MV_NOT_INITIALIZED; /* assume all 4 DBs are initialized */ for(i = 0; i < secDbSize; i++) { pCurrSpdInRule = (spdInDb + i); pCurrSpdOutRule = (spdOutDb + i); pCurrSAInEntery = (saInDb + i); pCurrSAOutEntery = (saOutDb + i); mvOsFree(pCurrSpdInRule); mvOsFree(pCurrSpdOutRule); mvOsFree(pCurrSAInEntery); mvOsFree(pCurrSAOutEntery); } spdInDb = spdOutDb = NULL; saInDb = saOutDb = NULL; return MV_OK; } static INLINE MV_VOID mvNfpSecClearRange(MV_U8* addr, MV_U32 size) { MV_U32 i; MV_U8 *align; align = (MV_U8*)((MV_U32)addr & ~0x1f); for(i = 0; align <= (addr+size); align += CPU_D_CACHE_LINE_SIZE) mvOsCacheLineFlushInv(NULL, align); } static INLINE MV_VOID mvNfpSecInvRange(MV_U8* addr, MV_U32 size) { MV_U32 i; MV_U8 *align; align = (MV_U8*)((MV_U32)addr & ~0x1f); for(i = 0; align <= (addr+size); align += CPU_D_CACHE_LINE_SIZE) mvOsCacheLineInv(NULL, align); } /****************************************************/ /* warning: need to replace DB list with hash table */ /****************************************************/ MV_NFP_SEC_SPD_RULE* mvNfpSecSPDRuleSet(MV_NFP_SEC_SPD_RULE* pSpdRule, MV_NFP_SEC_RULE_DB_DIR inOut) { MV_NFP_SEC_SPD_RULE* pCurrSpdRule; MV_U32 currRuleIndex = 0, spdRuleCount; pCurrSpdRule = (inOut ? spdOutDb : spdInDb); spdRuleCount = (inOut ? spdOutRuleCount : spdInRuleCount); if(spdRuleCount >= secDbSize) return NULL; /* search if rule already exists */ while(currRuleIndex < spdRuleCount) { if((pCurrSpdRule->sIp == pSpdRule->sIp) && (pCurrSpdRule->dIp == pSpdRule->dIp) #ifdef MV_NFP_SEC_5TUPLE_KEY_SUPPORT && (pCurrSpdRule->proto == pSpdRule->proto) && (pCurrSpdRule->srcPort == pSpdRule->srcPort) && (pCurrSpdRule->dstPort == pSpdRule->dstPort) #endif ) { /* rule exists - return */ return pCurrSpdRule; } currRuleIndex++; pCurrSpdRule++; } pCurrSpdRule = (inOut ? (spdOutDb+spdRuleCount) : (spdInDb+spdRuleCount));; memcpy(pCurrSpdRule, pSpdRule, sizeof(struct _mv_nfp_sec_spd_rule)); inOut ? spdOutRuleCount++ : spdInRuleCount++ ; return pCurrSpdRule; } MV_NFP_SEC_SA_ENTRY* mvNfpSecSAEntrySet(MV_NFP_SEC_SA_ENTRY* pSAEntry, MV_NFP_SEC_RULE_DB_DIR inOut) { MV_NFP_SEC_SA_ENTRY* pCurrSAEntery; MV_U32 currEntryIndex = 0, saEntryCount; pCurrSAEntery = (inOut ? saOutDb : saInDb); saEntryCount = (inOut ? saOutEntryCount : saInEntryCount); if(saEntryCount >= secDbSize) return NULL; /* search if rule already exists */ while(currEntryIndex < saEntryCount) { if(pCurrSAEntery->spi == pSAEntry->spi) { /* rule exists - return */ return pCurrSAEntery; } currEntryIndex++; pCurrSAEntery++; } pCurrSAEntery = (inOut ? (saOutDb+saEntryCount) : (saInDb+saEntryCount)); memcpy(pCurrSAEntery, pSAEntry, sizeof(struct _mv_nfp_sec_sa_entry)); inOut ? saOutEntryCount++ : saInEntryCount++ ; return pCurrSAEntery; } MV_STATUS mvNfpSecOutCheck(MV_PKT_INFO *pPktInfo) { if(pPktInfo->pFrags->dataSize > MV_NFP_SEC_MAX_PACKET) return MV_OUT_OF_RANGE; return MV_OK; } INLINE MV_STATUS mvNfpSecInCheck(MV_PKT_INFO *pPktInfo, MV_NFP_SEC_SA_ENTRY* pSAEntry) { /* TBD - sequence number */ return MV_OK; } MV_NFP_SEC_SPD_RULE* mvNfpSecSPDRuleFind(MV_U32 dstIp, MV_U32 srcIp, MV_U8 proto, MV_U16 dport, MV_U16 sport, MV_NFP_SEC_RULE_DB_DIR inOut) { MV_NFP_SEC_SPD_RULE* pCurrSpdRule; MV_U32 currRuleIndex = 0, spdRuleCount; pCurrSpdRule = (inOut ? spdOutDb : spdInDb); spdRuleCount = (inOut ? spdOutRuleCount : spdInRuleCount); /* SPD DB is empty */ if(!spdRuleCount) return NULL; /* scan IN/OUT SPD database for matching rule */ while(currRuleIndex < spdRuleCount) { if((pCurrSpdRule->sIp == srcIp) && (pCurrSpdRule->dIp == dstIp) #ifdef MV_NFP_SEC_5TUPLE_KEY_SUPPORT && (pCurrSpdRule->proto == proto) (pCurrSpdRule->srcPort == sport) && (pCurrSpdRule->dstPort == dport) #endif ) { /* rule found - return */ return pCurrSpdRule; } currRuleIndex++; pCurrSpdRule++; } return NULL; } INLINE MV_VOID mvNfpSecBuildMac(MV_PKT_INFO *pPktInfo, MV_NFP_SEC_SA_ENTRY* pSAEntry) { MV_802_3_HEADER *pMacHdr; pMacHdr = (MV_802_3_HEADER*)((MV_U8 *)(pPktInfo->pFrags[0].bufVirtPtr)); memcpy(pMacHdr, &pSAEntry->tunnelHdr.dstMac, 12); pMacHdr->typeOrLen = 0x08; /* stands for IP protocol code 16bit swapped */ return; } INLINE MV_VOID mvNfpSecBuildIPTunnel(MV_PKT_INFO *pPktInfo, MV_NFP_SEC_SA_ENTRY* pSAEntry) { MV_IP_HEADER *pIpHdr, *pIntIpHdr; MV_U16 newIpTotalLength; newIpTotalLength = pPktInfo->pFrags[0].dataSize - sizeof(MV_802_3_HEADER); pIpHdr = (MV_IP_HEADER*)(pPktInfo->pFrags[0].bufVirtPtr + sizeof(MV_802_3_HEADER)); pIntIpHdr = (MV_IP_HEADER*)((MV_U8*)(pIpHdr) + sizeof(MV_IP_HEADER) + sizeof(MV_ESP_HEADER) + pSAEntry->ivSize); /* TBD - review below settings in RFC */ pIpHdr->version = 0x45; pIpHdr->tos = 0; pIpHdr->checksum = 0; pIpHdr->totalLength = MV_16BIT_BE(newIpTotalLength); pIpHdr->identifier = 0; pIpHdr->fragmentCtrl = 0; pIpHdr->ttl = pIntIpHdr->ttl -1 ; pIpHdr->protocol = MV_IP_PROTO_ESP; pIpHdr->srcIP = pSAEntry->tunnelHdr.sIp; pIpHdr->dstIP = pSAEntry->tunnelHdr.dIp; pPktInfo->status = ETH_TX_IP_NO_FRAG | ETH_TX_GENERATE_IP_CHKSUM_MASK | (0x5 << ETH_TX_IP_HEADER_LEN_OFFSET); return; } /* Append sequence number and spi, save some space for IV */ INLINE MV_VOID mvNfpSecBuildEspHdr(MV_PKT_INFO *pPktInfo, MV_NFP_SEC_SA_ENTRY* pSAEntry) { MV_ESP_HEADER *pEspHdr; pEspHdr = (MV_ESP_HEADER*)(pPktInfo->pFrags[0].bufVirtPtr + sizeof(MV_802_3_HEADER) + sizeof(MV_IP_HEADER)); pEspHdr->spi = pSAEntry->spi; pSAEntry->seqNum = (pSAEntry->seqNum++); pEspHdr->seqNum = MV_32BIT_BE(pSAEntry->seqNum); } MV_STATUS mvNfpSecEspProcess(MV_PKT_INFO *pPktInfo, MV_NFP_SEC_SA_ENTRY* pSAEntry) { MV_CESA_COMMAND *pCesaCmd; MV_CESA_MBUF *pCesaMbuf; MV_NFP_SEC_CESA_PRIV *pCesaPriv; MV_STATUS status; MV_IP_HEADER *pIpHdr; MV_BUF_INFO *pBuf; pCesaCmd = &cesaCmdArray[cesaCmdIndx]; pCesaMbuf = &cesaMbufArray[cesaCmdIndx]; cesaCmdIndx++; cesaCmdIndx %= MV_NFP_SEC_Q_SIZE; pCesaPriv = &cesaPrivArray[cesaPrivIndx++]; cesaPrivIndx = cesaPrivIndx%(MV_NFP_SEC_Q_SIZE + MV_NFP_SEC_REQ_Q_SIZE); pCesaPriv->pPktInfo = pPktInfo; pCesaPriv->pSaEntry = pSAEntry; pCesaPriv->pCesaCmd = pCesaCmd; /* * Fix, encrypt/decrypt the IP payload only, --BK 20091027 */ pBuf = pPktInfo->pFrags; pIpHdr = (MV_IP_HEADER*)(pBuf->bufVirtPtr + sizeof(MV_802_3_HEADER)); pBuf->dataSize = MV_16BIT_BE(pIpHdr->totalLength) + sizeof(MV_802_3_HEADER); pBuf->bufVirtPtr += MV_NFP_SEC_ESP_OFFSET; pBuf->bufPhysAddr += MV_NFP_SEC_ESP_OFFSET; pBuf->dataSize -= MV_NFP_SEC_ESP_OFFSET; pBuf->bufAddrShift -= MV_NFP_SEC_ESP_OFFSET; pCesaMbuf->pFrags = pPktInfo->pFrags; pCesaMbuf->numFrags = 1; pCesaMbuf->mbufSize = pBuf->dataSize; pCesaCmd->pReqPrv = (MV_VOID*)pCesaPriv; pCesaCmd->sessionId = pSAEntry->sid; pCesaCmd->pSrc = pCesaMbuf; pCesaCmd->pDst = pCesaMbuf; pCesaCmd->skipFlush = MV_TRUE; /* Assume ESP */ pCesaCmd->cryptoOffset = sizeof(MV_ESP_HEADER) + pSAEntry->ivSize; pCesaCmd->cryptoLength = pBuf->dataSize - (sizeof(MV_ESP_HEADER) + pSAEntry->ivSize + pSAEntry->digestSize); pCesaCmd->ivFromUser = 0; /* relevant for encode only */ pCesaCmd->ivOffset = sizeof(MV_ESP_HEADER); pCesaCmd->macOffset = 0; pCesaCmd->macLength = pBuf->dataSize - pSAEntry->digestSize; pCesaCmd->digestOffset = pBuf->dataSize - pSAEntry->digestSize ; /* save original digest in case of decrypt+auth */ if(pSAEntry->secOp == MV_NFP_SEC_DECRYPT) { memcpy(pCesaPriv->orgDigest,(pBuf->bufVirtPtr + pCesaCmd->digestOffset), pSAEntry->digestSize); mvNfpSecInvRange((pBuf->bufVirtPtr + pCesaCmd->digestOffset), pSAEntry->digestSize); } pSAEntry->stats.bytes += pBuf->dataSize; if (pSAEntry->secOp == MV_NFP_SEC_DECRYPT) pSAEntry->stats.decrypt++; else pSAEntry->stats.encrypt++; disable_irq(CESA_IRQ); status = mvCesaAction(pCesaCmd); enable_irq(CESA_IRQ); if(status != MV_OK) { pSAEntry->stats.rejected++; mvOsPrintf("%s: mvCesaAction failed %d\n", __FUNCTION__, status); } return status; } MV_STATUS mvNfpSecOutgoing(MV_PKT_INFO *pPktInfo, MV_NFP_SEC_SA_ENTRY* pSAEntry) { MV_U8* pTmp; MV_U32 cryptoSize, encBlockMod, dSize; MV_BUF_INFO* pBuf = pPktInfo->pFrags; /* CESA Q is full drop. */ if (cesaReqResources <= 1) { pSAEntry->stats.rejected++; return MV_NO_RESOURCE; } /* encrypt payload */ cryptoSize = pBuf->dataSize - sizeof(MV_802_3_HEADER) - ETH_MV_HEADER_SIZE; /* ignore Marvell header */ pBuf->dataSize -= ETH_MV_HEADER_SIZE; pBuf->bufVirtPtr += ETH_MV_HEADER_SIZE; pBuf->bufPhysAddr += ETH_MV_HEADER_SIZE; pBuf->bufAddrShift -= ETH_MV_HEADER_SIZE; /* Align buffer address to beginning of new packet - TBD handle VLAN tag, LLC */ dSize = pSAEntry->ivSize + sizeof(MV_ESP_HEADER) + sizeof(MV_IP_HEADER); pBuf->bufVirtPtr -= dSize; pBuf->bufPhysAddr -= dSize; pBuf->dataSize += dSize; pBuf->bufAddrShift += dSize; encBlockMod = (cryptoSize % MV_NFP_SEC_ENC_BLOCK_SIZE); /* leave space for padLen + Protocol */ if(encBlockMod > 14 ) { encBlockMod = MV_NFP_SEC_ENC_BLOCK_SIZE - encBlockMod; encBlockMod += MV_NFP_SEC_ENC_BLOCK_SIZE; } else encBlockMod = MV_NFP_SEC_ENC_BLOCK_SIZE - encBlockMod; /* expected frame size */ dSize = pBuf->dataSize + encBlockMod + pSAEntry->digestSize; #ifdef CONFIG_MV_ETH_NFP_PPP /* keep enough room for PPPoE header */ if (ETH_FP_IFINDEX_MAX != mvFpPppPhyIf(pSAEntry->tunnelHdr.outIfIndex)) dSize += ETH_FP_PPPOE_HDR; #endif if (dSize > ETH_FP_MTU - ETH_MV_HEADER_SIZE) goto rollback; pBuf->dataSize += encBlockMod; pTmp = pBuf->bufVirtPtr + pBuf->dataSize; memset(pTmp - encBlockMod, 0, encBlockMod - 2); *((MV_U8*)(pTmp-2)) = (MV_U8)(encBlockMod-2); *((MV_U8*)(pTmp-1)) = (MV_U8)4; mvNfpSecClearRange(pTmp - encBlockMod, encBlockMod); pBuf->dataSize += pSAEntry->digestSize; mvNfpSecBuildEspHdr(pPktInfo, pSAEntry); mvNfpSecBuildIPTunnel(pPktInfo, pSAEntry); mvNfpSecBuildMac(pPktInfo, pSAEntry); /* flush & invalidate new MAC, IP, & ESP headers + old ip*/ dSize = pBuf->bufAddrShift + sizeof(MV_IP_HEADER) + sizeof(MV_802_3_HEADER); mvNfpSecClearRange(pBuf->bufVirtPtr, dSize); return mvNfpSecEspProcess(pPktInfo, pSAEntry); rollback: /* slow path */ pBuf->bufPhysAddr += pBuf->bufAddrShift; pBuf->bufVirtPtr += pBuf->bufAddrShift; pBuf->dataSize -= pBuf->bufAddrShift; pBuf->bufAddrShift = 0; pSAEntry->stats.rejected++; return MV_OUT_OF_RANGE; } MV_STATUS mvNfpSecIncoming(MV_PKT_INFO *pPktInfo, MV_NFP_SEC_SA_ENTRY* pSAEntry) { MV_BUF_INFO* pBuf = pPktInfo->pFrags; MV_U32 invSize; /* CESA Q is full drop. */ if(cesaReqResources <= 1) { pSAEntry->stats.rejected++; return MV_NO_RESOURCE; } /* TBD - duplicate invalidatation */ if(MV_OK != mvNfpSecInCheck(pPktInfo, pSAEntry)) { pSAEntry->stats.rejected++; return MV_ERROR; } /* ignore Marvell header */ pBuf->dataSize -= ETH_MV_HEADER_SIZE; pBuf->bufVirtPtr += ETH_MV_HEADER_SIZE; pBuf->bufPhysAddr += ETH_MV_HEADER_SIZE; pBuf->bufAddrShift -= ETH_MV_HEADER_SIZE; /* update buffer address shift value */ /* tracked by bufAddrShift, --BK 091022 */ /* pBuf->bufAddrShift -= (pSAEntry->ivSize + sizeof(MV_ESP_HEADER) + sizeof(MV_IP_HEADER));*/ /* invalidate MAC, IP & ESP headers */ invSize = sizeof(MV_802_3_HEADER) + sizeof(MV_IP_HEADER) + sizeof(MV_ESP_HEADER); mvNfpSecInvRange(pBuf->bufVirtPtr, invSize); return mvNfpSecEspProcess(pPktInfo, pSAEntry); } MV_NFP_SEC_SA_ENTRY* mvNfpSecSARuleFind(MV_U32 spiPkt) { MV_NFP_SEC_SA_ENTRY* pCurrSAEntery = saInDb; MV_U32 currEntryIndex = 0; while(currEntryIndex < saInEntryCount) { if(pCurrSAEntery->spi == spiPkt) return pCurrSAEntery; currEntryIndex++; pCurrSAEntery++; } return NULL; } MV_VOID mvNfpSecSaPrint(MV_NFP_SEC_SA_ENTRY *pSAEntry) { mvDebugPrintIpAddr(MV_32BIT_BE(pSAEntry->tunnelHdr.sIp)); mvOsPrintf("->"); mvDebugPrintIpAddr(MV_32BIT_BE(pSAEntry->tunnelHdr.dIp)); mvOsPrintf(" out_if=%d da=", pSAEntry->tunnelHdr.outIfIndex); mvDebugPrintMacAddr(pSAEntry->tunnelHdr.dstMac); mvOsPrintf(" spi=0x%x", MV_32BIT_BE(pSAEntry->spi)); if (pSAEntry) mvOsPrintf("\tstats: encrypt:%d decrypt:%d reject:%d drop:%d bytes:%d", pSAEntry->stats.encrypt, pSAEntry->stats.decrypt, pSAEntry->stats.rejected, pSAEntry->stats.dropped, pSAEntry->stats.bytes); mvOsPrintf("\n"); } MV_VOID mvNfpSecDbPrint(MV_VOID) { MV_U32 i; mvOsPrintf("NFP IPSec:\n"); for(i = 0; i < spdInRuleCount; i++) { mvOsPrintf("inbound[%d] ", i); mvDebugPrintIpAddr(MV_32BIT_BE(spdInDb[i].sIp)); mvOsPrintf("->"); mvDebugPrintIpAddr(MV_32BIT_BE(spdInDb[i].dIp)); mvOsPrintf(" "); mvNfpSecSaPrint(spdInDb[i].pSAEntry); } for(i = 0; i < spdOutRuleCount; i++) { mvOsPrintf("outbound[%d] ", i); mvDebugPrintIpAddr(MV_32BIT_BE(spdOutDb[i].sIp)); mvOsPrintf("->"); mvDebugPrintIpAddr(MV_32BIT_BE(spdOutDb[i].dIp)); mvOsPrintf(" "); mvNfpSecSaPrint(spdOutDb[i].pSAEntry); } }