/** @file Functions implementation related with DHCPv4 for HTTP boot driver. Copyright (c) 2015, Intel Corporation. All rights reserved.
This program and the accompanying materials are licensed and made available under the terms and conditions of the BSD License that accompanies this distribution. The full text of the license may be found at http://opensource.org/licenses/bsd-license.php. THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. **/ #include "HttpBootDxe.h" // // This is a map from the interested DHCP4 option tags' index to the tag value. // UINT8 mInterestedDhcp4Tags[HTTP_BOOT_DHCP4_TAG_INDEX_MAX] = { HTTP_BOOT_DHCP4_TAG_BOOTFILE_LEN, HTTP_BOOT_DHCP4_TAG_OVERLOAD, HTTP_BOOT_DHCP4_TAG_MSG_TYPE, HTTP_BOOT_DHCP4_TAG_SERVER_ID, HTTP_BOOT_DHCP4_TAG_CLASS_ID, HTTP_BOOT_DHCP4_TAG_BOOTFILE, HTTP_BOOT_DHCP4_TAG_DNS_SERVER }; // // There are 4 times retries with the value of 4, 8, 16 and 32, refers to UEFI 2.5 spec. // UINT32 mHttpDhcpTimeout[4] = {4, 8, 16, 32}; /** Build the options buffer for the DHCPv4 request packet. @param[in] Private Pointer to HTTP boot driver private data. @param[out] OptList Pointer to the option pointer array. @param[in] Buffer Pointer to the buffer to contain the option list. @return Index The count of the built-in options. **/ UINT32 HttpBootBuildDhcp4Options ( IN HTTP_BOOT_PRIVATE_DATA *Private, OUT EFI_DHCP4_PACKET_OPTION **OptList, IN UINT8 *Buffer ) { HTTP_BOOT_DHCP4_OPTION_ENTRY OptEnt; UINT16 Value; UINT32 Index; Index = 0; OptList[0] = (EFI_DHCP4_PACKET_OPTION *) Buffer; // // Append parameter request list option. // OptList[Index]->OpCode = HTTP_BOOT_DHCP4_TAG_PARA_LIST; OptList[Index]->Length = 27; OptEnt.Para = (HTTP_BOOT_DHCP4_OPTION_PARA *) OptList[Index]->Data; OptEnt.Para->ParaList[0] = HTTP_BOOT_DHCP4_TAG_NETMASK; OptEnt.Para->ParaList[1] = HTTP_BOOT_DHCP4_TAG_TIME_OFFSET; OptEnt.Para->ParaList[2] = HTTP_BOOT_DHCP4_TAG_ROUTER; OptEnt.Para->ParaList[3] = HTTP_BOOT_DHCP4_TAG_TIME_SERVER; OptEnt.Para->ParaList[4] = HTTP_BOOT_DHCP4_TAG_NAME_SERVER; OptEnt.Para->ParaList[5] = HTTP_BOOT_DHCP4_TAG_DNS_SERVER; OptEnt.Para->ParaList[6] = HTTP_BOOT_DHCP4_TAG_HOSTNAME; OptEnt.Para->ParaList[7] = HTTP_BOOT_DHCP4_TAG_BOOTFILE_LEN; OptEnt.Para->ParaList[8] = HTTP_BOOT_DHCP4_TAG_DOMAINNAME; OptEnt.Para->ParaList[9] = HTTP_BOOT_DHCP4_TAG_ROOTPATH; OptEnt.Para->ParaList[10] = HTTP_BOOT_DHCP4_TAG_EXTEND_PATH; OptEnt.Para->ParaList[11] = HTTP_BOOT_DHCP4_TAG_EMTU; OptEnt.Para->ParaList[12] = HTTP_BOOT_DHCP4_TAG_TTL; OptEnt.Para->ParaList[13] = HTTP_BOOT_DHCP4_TAG_BROADCAST; OptEnt.Para->ParaList[14] = HTTP_BOOT_DHCP4_TAG_NIS_DOMAIN; OptEnt.Para->ParaList[15] = HTTP_BOOT_DHCP4_TAG_NIS_SERVER; OptEnt.Para->ParaList[16] = HTTP_BOOT_DHCP4_TAG_NTP_SERVER; OptEnt.Para->ParaList[17] = HTTP_BOOT_DHCP4_TAG_VENDOR; OptEnt.Para->ParaList[18] = HTTP_BOOT_DHCP4_TAG_REQUEST_IP; OptEnt.Para->ParaList[19] = HTTP_BOOT_DHCP4_TAG_LEASE; OptEnt.Para->ParaList[20] = HTTP_BOOT_DHCP4_TAG_SERVER_ID; OptEnt.Para->ParaList[21] = HTTP_BOOT_DHCP4_TAG_T1; OptEnt.Para->ParaList[22] = HTTP_BOOT_DHCP4_TAG_T2; OptEnt.Para->ParaList[23] = HTTP_BOOT_DHCP4_TAG_CLASS_ID; OptEnt.Para->ParaList[25] = HTTP_BOOT_DHCP4_TAG_BOOTFILE; OptEnt.Para->ParaList[26] = HTTP_BOOT_DHCP4_TAG_UUID; Index++; OptList[Index] = GET_NEXT_DHCP_OPTION (OptList[Index - 1]); // // Append UUID/Guid-based client identifier option // OptList[Index]->OpCode = HTTP_BOOT_DHCP4_TAG_UUID; OptList[Index]->Length = (UINT8) sizeof (HTTP_BOOT_DHCP4_OPTION_UUID); OptEnt.Uuid = (HTTP_BOOT_DHCP4_OPTION_UUID *) OptList[Index]->Data; OptEnt.Uuid->Type = 0; if (EFI_ERROR (NetLibGetSystemGuid ((EFI_GUID *) OptEnt.Uuid->Guid))) { // // Zero the Guid to indicate NOT programable if failed to get system Guid. // ZeroMem (OptEnt.Uuid->Guid, sizeof (EFI_GUID)); } Index++; OptList[Index] = GET_NEXT_DHCP_OPTION (OptList[Index - 1]); // // Append client network device interface option // OptList[Index]->OpCode = HTTP_BOOT_DHCP4_TAG_UNDI; OptList[Index]->Length = (UINT8) sizeof (HTTP_BOOT_DHCP4_OPTION_UNDI); OptEnt.Undi = (HTTP_BOOT_DHCP4_OPTION_UNDI *) OptList[Index]->Data; if (Private->Nii != NULL) { OptEnt.Undi->Type = Private->Nii->Type; OptEnt.Undi->MajorVer = Private->Nii->MajorVer; OptEnt.Undi->MinorVer = Private->Nii->MinorVer; } else { OptEnt.Undi->Type = DEFAULT_UNDI_TYPE; OptEnt.Undi->MajorVer = DEFAULT_UNDI_MAJOR; OptEnt.Undi->MinorVer = DEFAULT_UNDI_MINOR; } Index++; OptList[Index] = GET_NEXT_DHCP_OPTION (OptList[Index - 1]); // // Append client system architecture option // OptList[Index]->OpCode = HTTP_BOOT_DHCP4_TAG_ARCH; OptList[Index]->Length = (UINT8) sizeof (HTTP_BOOT_DHCP4_OPTION_ARCH); OptEnt.Arch = (HTTP_BOOT_DHCP4_OPTION_ARCH *) OptList[Index]->Data; Value = HTONS (EFI_HTTP_BOOT_CLIENT_SYSTEM_ARCHITECTURE); CopyMem (&OptEnt.Arch->Type, &Value, sizeof (UINT16)); Index++; OptList[Index] = GET_NEXT_DHCP_OPTION (OptList[Index - 1]); // // Append vendor class identify option // OptList[Index]->OpCode = HTTP_BOOT_DHCP4_TAG_CLASS_ID; OptList[Index]->Length = (UINT8) sizeof (HTTP_BOOT_DHCP4_OPTION_CLID); OptEnt.Clid = (HTTP_BOOT_DHCP4_OPTION_CLID *) OptList[Index]->Data; CopyMem ( OptEnt.Clid, DEFAULT_CLASS_ID_DATA, sizeof (HTTP_BOOT_DHCP4_OPTION_CLID) ); HttpBootUintnToAscDecWithFormat ( EFI_HTTP_BOOT_CLIENT_SYSTEM_ARCHITECTURE, OptEnt.Clid->ArchitectureType, sizeof (OptEnt.Clid->ArchitectureType) ); if (Private->Nii != NULL) { CopyMem (OptEnt.Clid->InterfaceName, Private->Nii->StringId, sizeof (OptEnt.Clid->InterfaceName)); HttpBootUintnToAscDecWithFormat (Private->Nii->MajorVer, OptEnt.Clid->UndiMajor, sizeof (OptEnt.Clid->UndiMajor)); HttpBootUintnToAscDecWithFormat (Private->Nii->MinorVer, OptEnt.Clid->UndiMinor, sizeof (OptEnt.Clid->UndiMinor)); } Index++; return Index; } /** Parse a certain dhcp4 option by OptTag in Buffer, and return with start pointer. @param[in] Buffer Pointer to the option buffer. @param[in] Length Length of the option buffer. @param[in] OptTag Tag of the required option. @retval NULL Failed to find the required option. @retval Others The position of the required option. **/ EFI_DHCP4_PACKET_OPTION * HttpBootParseDhcp4Options ( IN UINT8 *Buffer, IN UINT32 Length, IN UINT8 OptTag ) { EFI_DHCP4_PACKET_OPTION *Option; UINT32 Offset; Option = (EFI_DHCP4_PACKET_OPTION *) Buffer; Offset = 0; while (Offset < Length && Option->OpCode != HTTP_BOOT_DHCP4_TAG_EOP) { if (Option->OpCode == OptTag) { // // Found the required option. // return Option; } // // Skip the current option to the next. // if (Option->OpCode == HTTP_BOOT_DHCP4_TAG_PAD) { Offset++; } else { Offset += Option->Length + 2; } Option = (EFI_DHCP4_PACKET_OPTION *) (Buffer + Offset); } return NULL; } /** Cache the DHCPv4 packet. @param[in] Dst Pointer to the cache buffer for DHCPv4 packet. @param[in] Src Pointer to the DHCPv4 packet to be cached. **/ VOID HttpBootCacheDhcp4Packet ( IN EFI_DHCP4_PACKET *Dst, IN EFI_DHCP4_PACKET *Src ) { ASSERT (Dst->Size >= Src->Length); CopyMem (&Dst->Dhcp4, &Src->Dhcp4, Src->Length); Dst->Length = Src->Length; } /** Parse the cached DHCPv4 packet, including all the options. @param[in] Cache4 Pointer to cached DHCPv4 packet. @retval EFI_SUCCESS Parsed the DHCPv4 packet successfully. @retval EFI_DEVICE_ERROR Failed to parse an invalid packet. **/ EFI_STATUS HttpBootParseDhcp4Packet ( IN HTTP_BOOT_DHCP4_PACKET_CACHE *Cache4 ) { EFI_DHCP4_PACKET *Offer; EFI_DHCP4_PACKET_OPTION **Options; UINTN Index; EFI_DHCP4_PACKET_OPTION *Option; BOOLEAN IsProxyOffer; BOOLEAN IsHttpOffer; BOOLEAN IsDnsOffer; BOOLEAN IpExpressedUri; UINT8 *Ptr8; EFI_STATUS Status; HTTP_BOOT_OFFER_TYPE OfferType; EFI_IPv4_ADDRESS IpAddr; IsDnsOffer = FALSE; IpExpressedUri = FALSE; IsProxyOffer = FALSE; IsHttpOffer = FALSE; ZeroMem (Cache4->OptList, sizeof (Cache4->OptList)); Offer = &Cache4->Packet.Offer; Options = Cache4->OptList; // // Parse DHCPv4 options in this offer, and store the pointers. // First, try to parse DHCPv4 options from the DHCP optional parameters field. // for (Index = 0; Index < HTTP_BOOT_DHCP4_TAG_INDEX_MAX; Index++) { Options[Index] = HttpBootParseDhcp4Options ( Offer->Dhcp4.Option, GET_OPTION_BUFFER_LEN (Offer), mInterestedDhcp4Tags[Index] ); } // // Second, Check if bootfilename and serverhostname is overloaded to carry DHCP options refers to rfc-2132. // If yes, try to parse options from the BootFileName field, then ServerName field. // Option = Options[HTTP_BOOT_DHCP4_TAG_INDEX_OVERLOAD]; if (Option != NULL) { if ((Option->Data[0] & HTTP_BOOT_DHCP4_OVERLOAD_FILE) != 0) { for (Index = 0; Index < HTTP_BOOT_DHCP4_TAG_INDEX_MAX; Index++) { if (Options[Index] == NULL) { Options[Index] = HttpBootParseDhcp4Options ( (UINT8 *) Offer->Dhcp4.Header.BootFileName, sizeof (Offer->Dhcp4.Header.BootFileName), mInterestedDhcp4Tags[Index] ); } } } if ((Option->Data[0] & HTTP_BOOT_DHCP4_OVERLOAD_SERVER_NAME) != 0) { for (Index = 0; Index < HTTP_BOOT_DHCP4_TAG_INDEX_MAX; Index++) { if (Options[Index] == NULL) { Options[Index] = HttpBootParseDhcp4Options ( (UINT8 *) Offer->Dhcp4.Header.ServerName, sizeof (Offer->Dhcp4.Header.ServerName), mInterestedDhcp4Tags[Index] ); } } } } // // The offer with "yiaddr" is a proxy offer. // if (Offer->Dhcp4.Header.YourAddr.Addr[0] == 0) { IsProxyOffer = TRUE; } // // The offer with "HTTPClient" is a Http offer. // Option = Options[HTTP_BOOT_DHCP4_TAG_INDEX_CLASS_ID]; if ((Option != NULL) && (Option->Length >= 9) && (CompareMem (Option->Data, DEFAULT_CLASS_ID_DATA, 9) == 0)) { IsHttpOffer = TRUE; } // // The offer with Domain Server is a DNS offer. // Option = Options[HTTP_BOOT_DHCP4_TAG_INDEX_DNS_SERVER]; if (Option != NULL) { IsDnsOffer = TRUE; } // // Parse boot file name: // Boot URI information is provided thru 'file' field in DHCP Header or option 67. // According to RFC 2132, boot file name should be read from DHCP option 67 (bootfile name) if present. // Otherwise, read from boot file field in DHCP header. // if (Options[HTTP_BOOT_DHCP4_TAG_INDEX_BOOTFILE] != NULL) { // // RFC 2132, Section 9.5 does not strictly state Bootfile name (option 67) is null // terminated string. So force to append null terminated character at the end of string. // Ptr8 = (UINT8*)&Options[HTTP_BOOT_DHCP4_TAG_INDEX_BOOTFILE]->Data[0]; Ptr8 += Options[HTTP_BOOT_DHCP4_TAG_INDEX_BOOTFILE]->Length; if (*(Ptr8 - 1) != '\0') { *Ptr8 = '\0'; } } else if (Offer->Dhcp4.Header.BootFileName[0] != 0) { // // If the bootfile is not present and bootfilename is present in DHCPv4 packet, just parse it. // Do not count dhcp option header here, or else will destroy the serverhostname. // Options[HTTP_BOOT_DHCP4_TAG_INDEX_BOOTFILE] = (EFI_DHCP4_PACKET_OPTION *) (&Offer->Dhcp4.Header.BootFileName[0] - OFFSET_OF (EFI_DHCP4_PACKET_OPTION, Data[0])); } // // Http offer must have a boot URI. // if (IsHttpOffer && Options[HTTP_BOOT_DHCP4_TAG_INDEX_BOOTFILE] == NULL) { return EFI_DEVICE_ERROR; } // // Try to retrieve the IP of HTTP server from URI. // if (IsHttpOffer) { Status = HttpParseUrl ( (CHAR8*) Options[HTTP_BOOT_DHCP4_TAG_INDEX_BOOTFILE]->Data, (UINT32) AsciiStrLen ((CHAR8*) Options[HTTP_BOOT_DHCP4_TAG_INDEX_BOOTFILE]->Data), FALSE, &Cache4->UriParser ); if (EFI_ERROR (Status)) { return EFI_DEVICE_ERROR; } Status = HttpUrlGetIp4 ( (CHAR8*) Options[HTTP_BOOT_DHCP4_TAG_INDEX_BOOTFILE]->Data, Cache4->UriParser, &IpAddr ); IpExpressedUri = !EFI_ERROR (Status); } // // Determine offer type of the DHCPv4 packet. // if (IsHttpOffer) { if (IpExpressedUri) { OfferType = IsProxyOffer ? HttpOfferTypeProxyIpUri : HttpOfferTypeDhcpIpUri; } else { if (!IsProxyOffer) { OfferType = IsDnsOffer ? HttpOfferTypeDhcpNameUriDns : HttpOfferTypeDhcpNameUri; } else { OfferType = HttpOfferTypeProxyNameUri; } } } else { if (!IsProxyOffer) { OfferType = IsDnsOffer ? HttpOfferTypeDhcpDns : HttpOfferTypeDhcpOnly; } else { return EFI_DEVICE_ERROR; } } Cache4->OfferType = OfferType; return EFI_SUCCESS; } /** Cache all the received DHCPv4 offers, and set OfferIndex and OfferCount. @param[in] Private Pointer to HTTP boot driver private data. @param[in] RcvdOffer Pointer to the received offer packet. **/ VOID HttpBootCacheDhcp4Offer ( IN HTTP_BOOT_PRIVATE_DATA *Private, IN EFI_DHCP4_PACKET *RcvdOffer ) { HTTP_BOOT_DHCP4_PACKET_CACHE *Cache4; EFI_DHCP4_PACKET *Offer; HTTP_BOOT_OFFER_TYPE OfferType; ASSERT (Private->OfferNum < HTTP_BOOT_OFFER_MAX_NUM); Cache4 = &Private->OfferBuffer[Private->OfferNum].Dhcp4; Offer = &Cache4->Packet.Offer; // // Cache the content of DHCPv4 packet firstly. // HttpBootCacheDhcp4Packet (Offer, RcvdOffer); // // Validate the DHCPv4 packet, and parse the options and offer type. // if (EFI_ERROR (HttpBootParseDhcp4Packet (Cache4))) { return; } // // Determine whether cache the current offer by type, and record OfferIndex and OfferCount. // OfferType = Cache4->OfferType; ASSERT (OfferType < HttpOfferTypeMax); ASSERT (Private->OfferCount[OfferType] < HTTP_BOOT_OFFER_MAX_NUM); Private->OfferIndex[OfferType][Private->OfferCount[OfferType]] = Private->OfferNum; Private->OfferCount[OfferType]++; Private->OfferNum++; } /** Select an DHCPv4 or DHCP6 offer, and record SelectIndex and SelectProxyType. @param[in] Private Pointer to HTTP boot driver private data. **/ VOID HttpBootSelectDhcpOffer ( IN HTTP_BOOT_PRIVATE_DATA *Private ) { Private->SelectIndex = 0; Private->SelectProxyType = HttpOfferTypeMax; // // Priority1: HttpOfferTypeDhcpIpUri // Priority2: HttpOfferTypeDhcpNameUriDns // Priority3: HttpOfferTypeDhcpOnly + HttpOfferTypeProxyIpUri // Priority4: HttpOfferTypeDhcpDns + HttpOfferTypeProxyIpUri // Priority5: HttpOfferTypeDhcpDns + HttpOfferTypeProxyNameUri // Priority6: HttpOfferTypeDhcpDns + HttpOfferTypeDhcpNameUri // if (Private->OfferCount[HttpOfferTypeDhcpIpUri] > 0) { Private->SelectIndex = Private->OfferIndex[HttpOfferTypeDhcpIpUri][0] + 1; } else if (Private->OfferCount[HttpOfferTypeDhcpNameUriDns] > 0) { Private->SelectIndex = Private->OfferIndex[HttpOfferTypeDhcpNameUriDns][0] + 1; } else if (Private->OfferCount[HttpOfferTypeDhcpOnly] > 0 && Private->OfferCount[HttpOfferTypeProxyIpUri] > 0) { Private->SelectIndex = Private->OfferIndex[HttpOfferTypeDhcpOnly][0] + 1; Private->SelectProxyType = HttpOfferTypeProxyIpUri; } else if (Private->OfferCount[HttpOfferTypeDhcpDns] > 0 && Private->OfferCount[HttpOfferTypeProxyIpUri] > 0) { Private->SelectIndex = Private->OfferIndex[HttpOfferTypeDhcpDns][0] + 1; Private->SelectProxyType = HttpOfferTypeProxyIpUri; } else if (Private->OfferCount[HttpOfferTypeDhcpDns] > 0 && Private->OfferCount[HttpOfferTypeProxyNameUri] > 0) { Private->SelectIndex = Private->OfferIndex[HttpOfferTypeDhcpDns][0] + 1; Private->SelectProxyType = HttpOfferTypeProxyNameUri; } else if (Private->OfferCount[HttpOfferTypeDhcpDns] > 0 && Private->OfferCount[HttpOfferTypeDhcpNameUri] > 0) { Private->SelectIndex = Private->OfferIndex[HttpOfferTypeDhcpDns][0] + 1; Private->SelectProxyType = HttpOfferTypeDhcpNameUri; } } /** EFI_DHCP4_CALLBACK is provided by the consumer of the EFI DHCPv4 Protocol driver to intercept events that occurred in the configuration process. @param[in] This Pointer to the EFI DHCPv4 Protocol. @param[in] Context Pointer to the context set by EFI_DHCP4_PROTOCOL.Configure(). @param[in] CurrentState The current operational state of the EFI DHCPv4 Protocol driver. @param[in] Dhcp4Event The event that occurs in the current state, which usually means a state transition. @param[in] Packet The DHCPv4 packet that is going to be sent or already received. @param[out] NewPacket The packet that is used to replace the above Packet. @retval EFI_SUCCESS Tells the EFI DHCPv4 Protocol driver to continue the DHCP process. @retval EFI_NOT_READY Only used in the Dhcp4Selecting state. The EFI DHCPv4 Protocol driver will continue to wait for more DHCPOFFER packets until the retry timeout expires. @retval EFI_ABORTED Tells the EFI DHCPv4 Protocol driver to abort the current process and return to the Dhcp4Init or Dhcp4InitReboot state. **/ EFI_STATUS EFIAPI HttpBootDhcp4CallBack ( IN EFI_DHCP4_PROTOCOL *This, IN VOID *Context, IN EFI_DHCP4_STATE CurrentState, IN EFI_DHCP4_EVENT Dhcp4Event, IN EFI_DHCP4_PACKET *Packet OPTIONAL, OUT EFI_DHCP4_PACKET **NewPacket OPTIONAL ) { HTTP_BOOT_PRIVATE_DATA *Private; EFI_DHCP4_PACKET_OPTION *MaxMsgSize; UINT16 Value; EFI_STATUS Status; if ((Dhcp4Event != Dhcp4RcvdOffer) && (Dhcp4Event != Dhcp4SelectOffer)) { return EFI_SUCCESS; } Private = (HTTP_BOOT_PRIVATE_DATA *) Context; // // Override the Maximum DHCP Message Size. // MaxMsgSize = HttpBootParseDhcp4Options ( Packet->Dhcp4.Option, GET_OPTION_BUFFER_LEN (Packet), HTTP_BOOT_DHCP4_TAG_MAXMSG ); if (MaxMsgSize != NULL) { Value = HTONS (HTTP_BOOT_DHCP4_PACKET_MAX_SIZE); CopyMem (MaxMsgSize->Data, &Value, sizeof (Value)); } Status = EFI_SUCCESS; switch (Dhcp4Event) { case Dhcp4RcvdOffer: Status = EFI_NOT_READY; if (Private->OfferNum < HTTP_BOOT_OFFER_MAX_NUM) { // // Cache the DHCPv4 offers to OfferBuffer[] for select later, and record // the OfferIndex and OfferCount. // HttpBootCacheDhcp4Offer (Private, Packet); } break; case Dhcp4SelectOffer: // // Select offer according to the priority in UEFI spec, and record the SelectIndex // and SelectProxyType. // HttpBootSelectDhcpOffer (Private); if (Private->SelectIndex == 0) { Status = EFI_ABORTED; } else { *NewPacket = &Private->OfferBuffer[Private->SelectIndex - 1].Dhcp4.Packet.Offer; } break; default: break; } return Status; } /** This function will register the IPv4 gateway address to the network device. @param[in] Private The pointer to HTTP_BOOT_PRIVATE_DATA. @retval EFI_SUCCESS The new IP configuration has been configured successfully. @retval Others Failed to configure the address. **/ EFI_STATUS HttpBootRegisterIp4Gateway ( IN HTTP_BOOT_PRIVATE_DATA *Private ) { EFI_STATUS Status; EFI_IP4_CONFIG2_PROTOCOL *Ip4Config2; ASSERT (!Private->UsingIpv6); Ip4Config2 = Private->Ip4Config2; // // Configure the gateway if valid. // if (!EFI_IP4_EQUAL (&Private->GatewayIp, &mZeroIp4Addr)) { Status = Ip4Config2->SetData ( Ip4Config2, Ip4Config2DataTypeGateway, sizeof (EFI_IPv4_ADDRESS), &Private->GatewayIp ); if (EFI_ERROR (Status)) { return Status; } } return EFI_SUCCESS; } /** This function will register the default DNS addresses to the network device. @param[in] Private The pointer to HTTP_BOOT_PRIVATE_DATA. @param[in] DataLength Size of the buffer pointed to by DnsServerData in bytes. @param[in] DnsServerData Point a list of DNS server address in an array of EFI_IPv4_ADDRESS instances. @retval EFI_SUCCESS The DNS configuration has been configured successfully. @retval Others Failed to configure the address. **/ EFI_STATUS HttpBootRegisterIp4Dns ( IN HTTP_BOOT_PRIVATE_DATA *Private, IN UINTN DataLength, IN VOID *DnsServerData ) { EFI_IP4_CONFIG2_PROTOCOL *Ip4Config2; ASSERT (!Private->UsingIpv6); Ip4Config2 = Private->Ip4Config2; return Ip4Config2->SetData ( Ip4Config2, Ip4Config2DataTypeDnsServer, DataLength, DnsServerData ); } /** This function will switch the IP4 configuration policy to Static. @param[in] Private Pointer to HTTP boot driver private data. @retval EFI_SUCCESS The policy is already configured to static. @retval Others Other error as indicated.. **/ EFI_STATUS HttpBootSetIp4Policy ( IN HTTP_BOOT_PRIVATE_DATA *Private ) { EFI_IP4_CONFIG2_POLICY Policy; EFI_STATUS Status; EFI_IP4_CONFIG2_PROTOCOL *Ip4Config2; UINTN DataSize; Ip4Config2 = Private->Ip4Config2; DataSize = sizeof (EFI_IP4_CONFIG2_POLICY); Status = Ip4Config2->GetData ( Ip4Config2, Ip4Config2DataTypePolicy, &DataSize, &Policy ); if (EFI_ERROR (Status)) { return Status; } if (Policy != Ip4Config2PolicyStatic) { Policy = Ip4Config2PolicyStatic; Status= Ip4Config2->SetData ( Ip4Config2, Ip4Config2DataTypePolicy, sizeof (EFI_IP4_CONFIG2_POLICY), &Policy ); if (EFI_ERROR (Status)) { return Status; } } return EFI_SUCCESS; } /** Start the D.O.R.A DHCPv4 process to acquire the IPv4 address and other Http boot information. @param[in] Private Pointer to HTTP boot driver private data. @retval EFI_SUCCESS The D.O.R.A process successfully finished. @retval Others Failed to finish the D.O.R.A process. **/ EFI_STATUS HttpBootDhcp4Dora ( IN HTTP_BOOT_PRIVATE_DATA *Private ) { EFI_DHCP4_PROTOCOL *Dhcp4; UINT32 OptCount; EFI_DHCP4_PACKET_OPTION *OptList[HTTP_BOOT_DHCP4_OPTION_MAX_NUM]; UINT8 Buffer[HTTP_BOOT_DHCP4_OPTION_MAX_SIZE]; EFI_DHCP4_CONFIG_DATA Config; EFI_STATUS Status; EFI_DHCP4_MODE_DATA Mode; Dhcp4 = Private->Dhcp4; ASSERT (Dhcp4 != NULL); Status = HttpBootSetIp4Policy (Private); if (EFI_ERROR (Status)) { return Status; } // // Build option list for the request packet. // OptCount = HttpBootBuildDhcp4Options (Private, OptList, Buffer); ASSERT (OptCount > 0); ZeroMem (&Config, sizeof(Config)); Config.OptionCount = OptCount; Config.OptionList = OptList; Config.Dhcp4Callback = HttpBootDhcp4CallBack; Config.CallbackContext = Private; Config.DiscoverTryCount = HTTP_BOOT_DHCP_RETRIES; Config.DiscoverTimeout = mHttpDhcpTimeout; // // Configure the DHCPv4 instance for HTTP boot. // Status = Dhcp4->Configure (Dhcp4, &Config); if (EFI_ERROR (Status)) { goto ON_EXIT; } // // Initialize the record fields for DHCPv4 offer in private data. // Private->OfferNum = 0; ZeroMem (Private->OfferCount, sizeof (Private->OfferCount)); ZeroMem (Private->OfferIndex, sizeof (Private->OfferIndex)); // // Start DHCPv4 D.O.R.A. process to acquire IPv4 address. // Status = Dhcp4->Start (Dhcp4, NULL); if (EFI_ERROR (Status)) { goto ON_EXIT; } // // Get the acquired IPv4 address and store them. // Status = Dhcp4->GetModeData (Dhcp4, &Mode); if (EFI_ERROR (Status)) { goto ON_EXIT; } ASSERT (Mode.State == Dhcp4Bound); CopyMem (&Private->StationIp, &Mode.ClientAddress, sizeof (EFI_IPv4_ADDRESS)); CopyMem (&Private->SubnetMask, &Mode.SubnetMask, sizeof (EFI_IPv4_ADDRESS)); CopyMem (&Private->GatewayIp, &Mode.RouterAddress, sizeof (EFI_IPv4_ADDRESS)); Status = HttpBootRegisterIp4Gateway (Private); if (EFI_ERROR (Status)) { goto ON_EXIT; } AsciiPrint ("\n Station IP address is "); HttpBootShowIp4Addr (&Private->StationIp.v4); AsciiPrint ("\n"); ON_EXIT: if (EFI_ERROR (Status)) { Dhcp4->Stop (Dhcp4); Dhcp4->Configure (Dhcp4, NULL); } else { ZeroMem (&Config, sizeof (EFI_DHCP4_CONFIG_DATA)); Dhcp4->Configure (Dhcp4, &Config); } return Status; }