blob: 6931a148279c4a84c77e1ca18222485172f34bdd [file] [log] [blame]
/** @file
Functions implementation related with DHCPv4 for HTTP boot driver.
Copyright (c) 2015 - 2018, Intel Corporation. All rights reserved.<BR>
SPDX-License-Identifier: BSD-2-Clause-Patent
**/
#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] = {
DHCP4_TAG_BOOTFILE_LEN,
DHCP4_TAG_OVERLOAD,
DHCP4_TAG_MSG_TYPE,
DHCP4_TAG_SERVER_ID,
DHCP4_TAG_VENDOR_CLASS_ID,
DHCP4_TAG_BOOTFILE,
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 = DHCP4_TAG_PARA_LIST;
OptList[Index]->Length = 27;
OptEnt.Para = (HTTP_BOOT_DHCP4_OPTION_PARA *)OptList[Index]->Data;
OptEnt.Para->ParaList[0] = DHCP4_TAG_NETMASK;
OptEnt.Para->ParaList[1] = DHCP4_TAG_TIME_OFFSET;
OptEnt.Para->ParaList[2] = DHCP4_TAG_ROUTER;
OptEnt.Para->ParaList[3] = DHCP4_TAG_TIME_SERVER;
OptEnt.Para->ParaList[4] = DHCP4_TAG_NAME_SERVER;
OptEnt.Para->ParaList[5] = DHCP4_TAG_DNS_SERVER;
OptEnt.Para->ParaList[6] = DHCP4_TAG_HOSTNAME;
OptEnt.Para->ParaList[7] = DHCP4_TAG_BOOTFILE_LEN;
OptEnt.Para->ParaList[8] = DHCP4_TAG_DOMAINNAME;
OptEnt.Para->ParaList[9] = DHCP4_TAG_ROOTPATH;
OptEnt.Para->ParaList[10] = DHCP4_TAG_EXTEND_PATH;
OptEnt.Para->ParaList[11] = DHCP4_TAG_EMTU;
OptEnt.Para->ParaList[12] = DHCP4_TAG_TTL;
OptEnt.Para->ParaList[13] = DHCP4_TAG_BROADCAST;
OptEnt.Para->ParaList[14] = DHCP4_TAG_NIS_DOMAIN;
OptEnt.Para->ParaList[15] = DHCP4_TAG_NIS_SERVER;
OptEnt.Para->ParaList[16] = DHCP4_TAG_NTP_SERVER;
OptEnt.Para->ParaList[17] = DHCP4_TAG_VENDOR;
OptEnt.Para->ParaList[18] = DHCP4_TAG_REQUEST_IP;
OptEnt.Para->ParaList[19] = DHCP4_TAG_LEASE;
OptEnt.Para->ParaList[20] = DHCP4_TAG_SERVER_ID;
OptEnt.Para->ParaList[21] = DHCP4_TAG_T1;
OptEnt.Para->ParaList[22] = DHCP4_TAG_T2;
OptEnt.Para->ParaList[23] = DHCP4_TAG_VENDOR_CLASS_ID;
OptEnt.Para->ParaList[25] = DHCP4_TAG_BOOTFILE;
OptEnt.Para->ParaList[26] = DHCP4_TAG_UUID;
Index++;
OptList[Index] = GET_NEXT_DHCP_OPTION (OptList[Index - 1]);
//
// Append UUID/Guid-based client identifier option
//
OptList[Index]->OpCode = 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 programmable 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 = 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 = 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 = DHCP4_TAG_VENDOR_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 != DHCP4_TAG_EOP) {
if (Option->OpCode == OptTag) {
//
// Found the required option.
//
return Option;
}
//
// Skip the current option to the next.
//
if (Option->OpCode == 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.
@retval EFI_SUCCESS Packet is copied.
@retval EFI_BUFFER_TOO_SMALL Cache buffer is not big enough to hold the packet.
**/
EFI_STATUS
HttpBootCacheDhcp4Packet (
IN EFI_DHCP4_PACKET *Dst,
IN EFI_DHCP4_PACKET *Src
)
{
if (Dst->Size < Src->Length) {
return EFI_BUFFER_TOO_SMALL;
}
CopyMem (&Dst->Dhcp4, &Src->Dhcp4, Src->Length);
Dst->Length = Src->Length;
return EFI_SUCCESS;
}
/**
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;
BOOLEAN FileFieldOverloaded;
IsDnsOffer = FALSE;
IpExpressedUri = FALSE;
IsProxyOffer = FALSE;
IsHttpOffer = FALSE;
FileFieldOverloaded = 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) {
FileFieldOverloaded = TRUE;
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 >= 10) &&
(CompareMem (Option->Data, DEFAULT_CLASS_ID_DATA, 10) == 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 (!FileFieldOverloaded && (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) {
if (IsProxyOffer) {
OfferType = HttpOfferTypeProxyIpUri;
} else {
OfferType = IsDnsOffer ? HttpOfferTypeDhcpIpUriDns : HttpOfferTypeDhcpIpUri;
}
} else {
if (!IsProxyOffer) {
OfferType = IsDnsOffer ? HttpOfferTypeDhcpNameUriDns : HttpOfferTypeDhcpNameUri;
} else {
OfferType = HttpOfferTypeProxyNameUri;
}
}
} else {
if (!IsProxyOffer) {
OfferType = IsDnsOffer ? HttpOfferTypeDhcpDns : HttpOfferTypeDhcpOnly;
} else {
if (Cache4->UriParser != NULL) {
FreePool (Cache4->UriParser);
}
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.
@retval EFI_SUCCESS Cache and parse the packet successfully.
@retval Others Operation failed.
**/
EFI_STATUS
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;
EFI_STATUS Status;
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.
//
Status = HttpBootCacheDhcp4Packet (Offer, RcvdOffer);
if (EFI_ERROR (Status)) {
return Status;
}
//
// Validate the DHCPv4 packet, and parse the options and offer type.
//
if (EFI_ERROR (HttpBootParseDhcp4Packet (Cache4))) {
return EFI_ABORTED;
}
//
// 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++;
return EFI_SUCCESS;
}
/**
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;
if (Private->FilePathUri != NULL) {
//
// We are in home environment, the URI is already specified.
// Just need to choose a DHCP offer.
// The offer with DNS server address takes priority here.
//
if (Private->OfferCount[HttpOfferTypeDhcpDns] > 0) {
Private->SelectIndex = Private->OfferIndex[HttpOfferTypeDhcpDns][0] + 1;
} else if (Private->OfferCount[HttpOfferTypeDhcpIpUriDns] > 0) {
Private->SelectIndex = Private->OfferIndex[HttpOfferTypeDhcpIpUriDns][0] + 1;
} else if (Private->OfferCount[HttpOfferTypeDhcpNameUriDns] > 0) {
Private->SelectIndex = Private->OfferIndex[HttpOfferTypeDhcpNameUriDns][0] + 1;
} else if (Private->OfferCount[HttpOfferTypeDhcpOnly] > 0) {
Private->SelectIndex = Private->OfferIndex[HttpOfferTypeDhcpOnly][0] + 1;
} else if (Private->OfferCount[HttpOfferTypeDhcpIpUri] > 0) {
Private->SelectIndex = Private->OfferIndex[HttpOfferTypeDhcpIpUri][0] + 1;
}
} else {
//
// We are in corporate environment.
//
// Priority1: HttpOfferTypeDhcpIpUri or HttpOfferTypeDhcpIpUriDns
// 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[HttpOfferTypeDhcpIpUriDns] > 0) {
Private->SelectIndex = Private->OfferIndex[HttpOfferTypeDhcpIpUriDns][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;
BOOLEAN Received;
if ((Dhcp4Event != Dhcp4SendDiscover) &&
(Dhcp4Event != Dhcp4RcvdOffer) &&
(Dhcp4Event != Dhcp4SendRequest) &&
(Dhcp4Event != Dhcp4RcvdAck) &&
(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),
DHCP4_TAG_MAXMSG
);
if (MaxMsgSize != NULL) {
Value = HTONS (HTTP_BOOT_DHCP4_PACKET_MAX_SIZE);
CopyMem (MaxMsgSize->Data, &Value, sizeof (Value));
}
//
// Callback to user if any packets sent or received.
//
if ((Private->HttpBootCallback != NULL) && (Dhcp4Event != Dhcp4SelectOffer)) {
Received = (BOOLEAN)(Dhcp4Event == Dhcp4RcvdOffer || Dhcp4Event == Dhcp4RcvdAck);
Status = Private->HttpBootCallback->Callback (
Private->HttpBootCallback,
HttpBootDhcp4,
Received,
Packet->Length,
&Packet->Dhcp4
);
if (EFI_ERROR (Status)) {
return EFI_ABORTED;
}
}
Status = EFI_SUCCESS;
switch (Dhcp4Event) {
case Dhcp4RcvdOffer:
Status = EFI_NOT_READY;
if (Packet->Length > HTTP_BOOT_DHCP4_PACKET_MAX_SIZE) {
//
// Ignore the incoming packets which exceed the maximum length.
//
break;
}
if (Private->OfferNum < HTTP_BOOT_OFFER_MAX_NUM) {
//
// Cache the DHCPv4 offers to OfferBuffer[] for select later, and record
// the OfferIndex and OfferCount.
// If error happens, just ignore this packet and continue to wait more offer.
//
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;
}