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|
/** @file
This library is only intended to be used by UEFI network stack modules.
It provides basic functions for the UEFI network stack.
Copyright (c) 2005 - 2011, Intel Corporation. All rights reserved.<BR>
This program and the accompanying materials
are licensed and made available under the terms and conditions of the BSD License
which accompanies this distribution. The full text of the license may be found at<BR>
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.
**/
#ifndef _NET_LIB_H_
#define _NET_LIB_H_
#include <Protocol/Ip6.h>
#include <Library/BaseLib.h>
#include <Library/BaseMemoryLib.h>
typedef UINT32 IP4_ADDR;
typedef UINT32 TCP_SEQNO;
typedef UINT16 TCP_PORTNO;
#define NET_ETHER_ADDR_LEN 6
#define NET_IFTYPE_ETHERNET 0x01
#define NET_VLAN_TAG_LEN 4
#define ETHER_TYPE_VLAN 0x8100
#define EFI_IP_PROTO_UDP 0x11
#define EFI_IP_PROTO_TCP 0x06
#define EFI_IP_PROTO_ICMP 0x01
#define IP4_PROTO_IGMP 0x02
#define IP6_ICMP 58
//
// The address classification
//
#define IP4_ADDR_CLASSA 1
#define IP4_ADDR_CLASSB 2
#define IP4_ADDR_CLASSC 3
#define IP4_ADDR_CLASSD 4
#define IP4_ADDR_CLASSE 5
#define IP4_MASK_NUM 33
#define IP6_PREFIX_NUM 129
#define IP6_HOP_BY_HOP 0
#define IP6_DESTINATION 60
#define IP6_ROUTING 43
#define IP6_FRAGMENT 44
#define IP6_AH 51
#define IP6_ESP 50
#define IP6_NO_NEXT_HEADER 59
#define IP_VERSION_4 4
#define IP_VERSION_6 6
#define IP6_PREFIX_LENGTH 64
#pragma pack(1)
//
// Ethernet head definition
//
typedef struct {
UINT8 DstMac [NET_ETHER_ADDR_LEN];
UINT8 SrcMac [NET_ETHER_ADDR_LEN];
UINT16 EtherType;
} ETHER_HEAD;
//
// 802.1Q VLAN Tag Control Information
//
typedef union {
struct {
UINT16 Vid : 12; // Unique VLAN identifier (0 to 4094)
UINT16 Cfi : 1; // Canonical Format Indicator
UINT16 Priority : 3; // 802.1Q priority level (0 to 7)
} Bits;
UINT16 Uint16;
} VLAN_TCI;
#define VLAN_TCI_CFI_CANONICAL_MAC 0
#define VLAN_TCI_CFI_NON_CANONICAL_MAC 1
//
// The EFI_IP4_HEADER is hard to use because the source and
// destination address are defined as EFI_IPv4_ADDRESS, which
// is a structure. Two structures can't be compared or masked
// directly. This is why there is an internal representation.
//
typedef struct {
UINT8 HeadLen : 4;
UINT8 Ver : 4;
UINT8 Tos;
UINT16 TotalLen;
UINT16 Id;
UINT16 Fragment;
UINT8 Ttl;
UINT8 Protocol;
UINT16 Checksum;
IP4_ADDR Src;
IP4_ADDR Dst;
} IP4_HEAD;
//
// ICMP head definition. Each ICMP message is categorized as either an error
// message or query message. Two message types have their own head format.
//
typedef struct {
UINT8 Type;
UINT8 Code;
UINT16 Checksum;
} IP4_ICMP_HEAD;
typedef struct {
IP4_ICMP_HEAD Head;
UINT32 Fourth; // 4th filed of the head, it depends on Type.
IP4_HEAD IpHead;
} IP4_ICMP_ERROR_HEAD;
typedef struct {
IP4_ICMP_HEAD Head;
UINT16 Id;
UINT16 Seq;
} IP4_ICMP_QUERY_HEAD;
typedef struct {
UINT8 Type;
UINT8 Code;
UINT16 Checksum;
} IP6_ICMP_HEAD;
typedef struct {
IP6_ICMP_HEAD Head;
UINT32 Fourth;
EFI_IP6_HEADER IpHead;
} IP6_ICMP_ERROR_HEAD;
typedef struct {
IP6_ICMP_HEAD Head;
UINT32 Fourth;
} IP6_ICMP_INFORMATION_HEAD;
//
// UDP header definition
//
typedef struct {
UINT16 SrcPort;
UINT16 DstPort;
UINT16 Length;
UINT16 Checksum;
} EFI_UDP_HEADER;
//
// TCP header definition
//
typedef struct {
TCP_PORTNO SrcPort;
TCP_PORTNO DstPort;
TCP_SEQNO Seq;
TCP_SEQNO Ack;
UINT8 Res : 4;
UINT8 HeadLen : 4;
UINT8 Flag;
UINT16 Wnd;
UINT16 Checksum;
UINT16 Urg;
} TCP_HEAD;
#pragma pack()
#define NET_MAC_EQUAL(pMac1, pMac2, Len) \
(CompareMem ((pMac1), (pMac2), Len) == 0)
#define NET_MAC_IS_MULTICAST(Mac, BMac, Len) \
(((*((UINT8 *) Mac) & 0x01) == 0x01) && (!NET_MAC_EQUAL (Mac, BMac, Len)))
#define NTOHL(x) SwapBytes32 (x)
#define HTONL(x) NTOHL(x)
#define NTOHS(x) SwapBytes16 (x)
#define HTONS(x) NTOHS(x)
#define NTOHLL(x) SwapBytes64 (x)
#define HTONLL(x) NTOHLL(x)
#define NTOHLLL(x) Ip6Swap128 (x)
#define HTONLLL(x) NTOHLLL(x)
//
// Test the IP's attribute, All the IPs are in host byte order.
//
#define IP4_IS_MULTICAST(Ip) (((Ip) & 0xF0000000) == 0xE0000000)
#define IP4_IS_LOCAL_BROADCAST(Ip) ((Ip) == 0xFFFFFFFF)
#define IP4_NET_EQUAL(Ip1, Ip2, NetMask) (((Ip1) & (NetMask)) == ((Ip2) & (NetMask)))
#define IP4_IS_VALID_NETMASK(Ip) (NetGetMaskLength (Ip) != IP4_MASK_NUM)
#define IP6_IS_MULTICAST(Ip6) (((Ip6)->Addr[0]) == 0xFF)
//
// Convert the EFI_IP4_ADDRESS to plain UINT32 IP4 address.
//
#define EFI_IP4(EfiIpAddr) (*(IP4_ADDR *) ((EfiIpAddr).Addr))
#define EFI_NTOHL(EfiIp) (NTOHL (EFI_IP4 ((EfiIp))))
#define EFI_IP4_EQUAL(Ip1, Ip2) (CompareMem ((Ip1), (Ip2), sizeof (EFI_IPv4_ADDRESS)) == 0)
#define EFI_IP6_EQUAL(Ip1, Ip2) (CompareMem ((Ip1), (Ip2), sizeof (EFI_IPv6_ADDRESS)) == 0)
#define IP4_COPY_ADDRESS(Dest, Src) (CopyMem ((Dest), (Src), sizeof (EFI_IPv4_ADDRESS)))
#define IP6_COPY_ADDRESS(Dest, Src) (CopyMem ((Dest), (Src), sizeof (EFI_IPv6_ADDRESS)))
#define IP6_COPY_LINK_ADDRESS(Mac1, Mac2) (CopyMem ((Mac1), (Mac2), sizeof (EFI_MAC_ADDRESS)))
//
// The debug level definition. This value is also used as the
// syslog's servity level. Don't change it.
//
#define NETDEBUG_LEVEL_TRACE 5
#define NETDEBUG_LEVEL_WARNING 4
#define NETDEBUG_LEVEL_ERROR 3
//
// Network debug message is sent out as syslog packet.
//
#define NET_SYSLOG_FACILITY 16 // Syslog local facility local use
#define NET_SYSLOG_PACKET_LEN 512
#define NET_SYSLOG_TX_TIMEOUT (500 * 1000 * 10) // 500ms
#define NET_DEBUG_MSG_LEN 470 // 512 - (ether+ip4+udp4 head length)
//
// The debug output expects the ASCII format string, Use %a to print ASCII
// string, and %s to print UNICODE string. PrintArg must be enclosed in ().
// For example: NET_DEBUG_TRACE ("Tcp", ("State transit to %a\n", Name));
//
#define NET_DEBUG_TRACE(Module, PrintArg) \
NetDebugOutput ( \
NETDEBUG_LEVEL_TRACE, \
Module, \
__FILE__, \
__LINE__, \
NetDebugASPrint PrintArg \
)
#define NET_DEBUG_WARNING(Module, PrintArg) \
NetDebugOutput ( \
NETDEBUG_LEVEL_WARNING, \
Module, \
__FILE__, \
__LINE__, \
NetDebugASPrint PrintArg \
)
#define NET_DEBUG_ERROR(Module, PrintArg) \
NetDebugOutput ( \
NETDEBUG_LEVEL_ERROR, \
Module, \
__FILE__, \
__LINE__, \
NetDebugASPrint PrintArg \
)
/**
Allocate a buffer, then format the message to it. This is a
help function for the NET_DEBUG_XXX macros. The PrintArg of
these macros treats the variable length print parameters as a
single parameter, and pass it to the NetDebugASPrint. For
example, NET_DEBUG_TRACE ("Tcp", ("State transit to %a\n", Name))
if extracted to:
NetDebugOutput (
NETDEBUG_LEVEL_TRACE,
"Tcp",
__FILE__,
__LINE__,
NetDebugASPrint ("State transit to %a\n", Name)
)
@param Format The ASCII format string.
@param ... The variable length parameter whose format is determined
by the Format string.
@return The buffer containing the formatted message,
or NULL if memory allocation failed.
**/
CHAR8 *
EFIAPI
NetDebugASPrint (
IN CHAR8 *Format,
...
);
/**
Builds an UDP4 syslog packet and send it using SNP.
This function will locate a instance of SNP then send the message through it.
Because it isn't open the SNP BY_DRIVER, apply caution when using it.
@param Level The servity level of the message.
@param Module The Moudle that generates the log.
@param File The file that contains the log.
@param Line The exact line that contains the log.
@param Message The user message to log.
@retval EFI_INVALID_PARAMETER Any input parameter is invalid.
@retval EFI_OUT_OF_RESOURCES Failed to allocate memory for the packet
@retval EFI_SUCCESS The log is discard because that it is more verbose
than the mNetDebugLevelMax. Or, it has been sent out.
**/
EFI_STATUS
EFIAPI
NetDebugOutput (
IN UINT32 Level,
IN UINT8 *Module,
IN UINT8 *File,
IN UINT32 Line,
IN UINT8 *Message
);
/**
Return the length of the mask.
Return the length of the mask. Valid values are 0 to 32.
If the mask is invalid, return the invalid length 33, which is IP4_MASK_NUM.
NetMask is in the host byte order.
@param[in] NetMask The netmask to get the length from.
@return The length of the netmask, or IP4_MASK_NUM (33) if the mask is invalid.
**/
INTN
EFIAPI
NetGetMaskLength (
IN IP4_ADDR NetMask
);
/**
Return the class of the IP address, such as class A, B, C.
Addr is in host byte order.
The address of class A starts with 0.
If the address belong to class A, return IP4_ADDR_CLASSA.
The address of class B starts with 10.
If the address belong to class B, return IP4_ADDR_CLASSB.
The address of class C starts with 110.
If the address belong to class C, return IP4_ADDR_CLASSC.
The address of class D starts with 1110.
If the address belong to class D, return IP4_ADDR_CLASSD.
The address of class E starts with 1111.
If the address belong to class E, return IP4_ADDR_CLASSE.
@param[in] Addr The address to get the class from.
@return IP address class, such as IP4_ADDR_CLASSA.
**/
INTN
EFIAPI
NetGetIpClass (
IN IP4_ADDR Addr
);
/**
Check whether the IP is a valid unicast address according to
the netmask. If NetMask is zero, use the IP address's class to get the default mask.
If Ip is 0, IP is not a valid unicast address.
Class D address is used for multicasting and class E address is reserved for future. If Ip
belongs to class D or class E, Ip is not a valid unicast address.
If all bits of the host address of Ip are 0 or 1, Ip is not a valid unicast address.
@param[in] Ip The IP to check against.
@param[in] NetMask The mask of the IP.
@return TRUE if Ip is a valid unicast address on the network, otherwise FALSE.
**/
BOOLEAN
EFIAPI
NetIp4IsUnicast (
IN IP4_ADDR Ip,
IN IP4_ADDR NetMask
);
/**
Check whether the incoming IPv6 address is a valid unicast address.
If the address is a multicast address has binary 0xFF at the start, it is not
a valid unicast address. If the address is unspecified ::, it is not a valid
unicast address to be assigned to any node. If the address is loopback address
::1, it is also not a valid unicast address to be assigned to any physical
interface.
@param[in] Ip6 The IPv6 address to check against.
@return TRUE if Ip6 is a valid unicast address on the network, otherwise FALSE.
**/
BOOLEAN
EFIAPI
NetIp6IsValidUnicast (
IN EFI_IPv6_ADDRESS *Ip6
);
/**
Check whether the incoming Ipv6 address is the unspecified address or not.
@param[in] Ip6 - Ip6 address, in network order.
@retval TRUE - Yes, incoming Ipv6 address is the unspecified address.
@retval FALSE - The incoming Ipv6 address is not the unspecified address
**/
BOOLEAN
EFIAPI
NetIp6IsUnspecifiedAddr (
IN EFI_IPv6_ADDRESS *Ip6
);
/**
Check whether the incoming Ipv6 address is a link-local address.
@param[in] Ip6 - Ip6 address, in network order.
@retval TRUE - The incoming Ipv6 address is a link-local address.
@retval FALSE - The incoming Ipv6 address is not a link-local address.
**/
BOOLEAN
EFIAPI
NetIp6IsLinkLocalAddr (
IN EFI_IPv6_ADDRESS *Ip6
);
/**
Check whether the Ipv6 address1 and address2 are on the connected network.
@param[in] Ip1 - Ip6 address1, in network order.
@param[in] Ip2 - Ip6 address2, in network order.
@param[in] PrefixLength - The prefix length of the checking net.
@retval TRUE - Yes, the Ipv6 address1 and address2 are connected.
@retval FALSE - No the Ipv6 address1 and address2 are not connected.
**/
BOOLEAN
EFIAPI
NetIp6IsNetEqual (
EFI_IPv6_ADDRESS *Ip1,
EFI_IPv6_ADDRESS *Ip2,
UINT8 PrefixLength
);
/**
Switches the endianess of an IPv6 address.
This function swaps the bytes in a 128-bit IPv6 address to switch the value
from little endian to big endian or vice versa. The byte swapped value is
returned.
@param Ip6 Points to an IPv6 address.
@return The byte swapped IPv6 address.
**/
EFI_IPv6_ADDRESS *
EFIAPI
Ip6Swap128 (
EFI_IPv6_ADDRESS *Ip6
);
extern IP4_ADDR gIp4AllMasks[IP4_MASK_NUM];
extern EFI_IPv4_ADDRESS mZeroIp4Addr;
#define NET_IS_DIGIT(Ch) (('0' <= (Ch)) && ((Ch) <= '9'))
#define NET_ROUNDUP(size, unit) (((size) + (unit) - 1) & (~((unit) - 1)))
#define NET_IS_LOWER_CASE_CHAR(Ch) (('a' <= (Ch)) && ((Ch) <= 'z'))
#define NET_IS_UPPER_CASE_CHAR(Ch) (('A' <= (Ch)) && ((Ch) <= 'Z'))
#define TICKS_PER_MS 10000U
#define TICKS_PER_SECOND 10000000U
#define NET_RANDOM(Seed) ((UINT32) ((UINT32) (Seed) * 1103515245UL + 12345) % 4294967295UL)
/**
Extract a UINT32 from a byte stream.
This function copies a UINT32 from a byte stream, and then converts it from Network
byte order to host byte order. Use this function to avoid alignment error.
@param[in] Buf The buffer to extract the UINT32.
@return The UINT32 extracted.
**/
UINT32
EFIAPI
NetGetUint32 (
IN UINT8 *Buf
);
/**
Puts a UINT32 into the byte stream in network byte order.
Converts a UINT32 from host byte order to network byte order, then copies it to the
byte stream.
@param[in, out] Buf The buffer in which to put the UINT32.
@param[in] Data The data to be converted and put into the byte stream.
**/
VOID
EFIAPI
NetPutUint32 (
IN OUT UINT8 *Buf,
IN UINT32 Data
);
/**
Initialize a random seed using current time.
Get current time first. Then initialize a random seed based on some basic
mathematical operations on the hour, day, minute, second, nanosecond and year
of the current time.
@return The random seed, initialized with current time.
**/
UINT32
EFIAPI
NetRandomInitSeed (
VOID
);
#define NET_LIST_USER_STRUCT(Entry, Type, Field) \
BASE_CR(Entry, Type, Field)
#define NET_LIST_USER_STRUCT_S(Entry, Type, Field, Sig) \
CR(Entry, Type, Field, Sig)
//
// Iterate through the double linked list. It is NOT delete safe
//
#define NET_LIST_FOR_EACH(Entry, ListHead) \
for(Entry = (ListHead)->ForwardLink; Entry != (ListHead); Entry = Entry->ForwardLink)
//
// Iterate through the double linked list. This is delete-safe.
// Don't touch NextEntry. Also, don't use this macro if list
// entries other than the Entry may be deleted when processing
// the current Entry.
//
#define NET_LIST_FOR_EACH_SAFE(Entry, NextEntry, ListHead) \
for(Entry = (ListHead)->ForwardLink, NextEntry = Entry->ForwardLink; \
Entry != (ListHead); \
Entry = NextEntry, NextEntry = Entry->ForwardLink \
)
//
// Make sure the list isn't empty before getting the first/last record.
//
#define NET_LIST_HEAD(ListHead, Type, Field) \
NET_LIST_USER_STRUCT((ListHead)->ForwardLink, Type, Field)
#define NET_LIST_TAIL(ListHead, Type, Field) \
NET_LIST_USER_STRUCT((ListHead)->BackLink, Type, Field)
/**
Remove the first node entry on the list, and return the removed node entry.
Removes the first node entry from a doubly linked list. It is up to the caller of
this function to release the memory used by the first node, if that is required. On
exit, the removed node is returned.
If Head is NULL, then ASSERT().
If Head was not initialized, then ASSERT().
If PcdMaximumLinkedListLength is not zero, and the number of nodes in the
linked list including the head node is greater than or equal to PcdMaximumLinkedListLength,
then ASSERT().
@param[in, out] Head The list header.
@return The first node entry that is removed from the list, NULL if the list is empty.
**/
LIST_ENTRY *
EFIAPI
NetListRemoveHead (
IN OUT LIST_ENTRY *Head
);
/**
Remove the last node entry on the list and return the removed node entry.
Removes the last node entry from a doubly linked list. It is up to the caller of
this function to release the memory used by the first node, if that is required. On
exit, the removed node is returned.
If Head is NULL, then ASSERT().
If Head was not initialized, then ASSERT().
If PcdMaximumLinkedListLength is not zero, and the number of nodes in the
linked list including the head node is greater than or equal to PcdMaximumLinkedListLength,
then ASSERT().
@param[in, out] Head The list head.
@return The last node entry that is removed from the list, NULL if the list is empty.
**/
LIST_ENTRY *
EFIAPI
NetListRemoveTail (
IN OUT LIST_ENTRY *Head
);
/**
Insert a new node entry after a designated node entry of a doubly linked list.
Inserts a new node entry designated by NewEntry after the node entry designated by PrevEntry
of the doubly linked list.
@param[in, out] PrevEntry The entry after which to insert.
@param[in, out] NewEntry The new entry to insert.
**/
VOID
EFIAPI
NetListInsertAfter (
IN OUT LIST_ENTRY *PrevEntry,
IN OUT LIST_ENTRY *NewEntry
);
/**
Insert a new node entry before a designated node entry of a doubly linked list.
Inserts a new node entry designated by NewEntry before the node entry designated by PostEntry
of the doubly linked list.
@param[in, out] PostEntry The entry to insert before.
@param[in, out] NewEntry The new entry to insert.
**/
VOID
EFIAPI
NetListInsertBefore (
IN OUT LIST_ENTRY *PostEntry,
IN OUT LIST_ENTRY *NewEntry
);
//
// Object container: EFI network stack spec defines various kinds of
// tokens. The drivers can share code to manage those objects.
//
typedef struct {
LIST_ENTRY Link;
VOID *Key;
VOID *Value;
} NET_MAP_ITEM;
typedef struct {
LIST_ENTRY Used;
LIST_ENTRY Recycled;
UINTN Count;
} NET_MAP;
#define NET_MAP_INCREAMENT 64
/**
Initialize the netmap. Netmap is a reposity to keep the <Key, Value> pairs.
Initialize the forward and backward links of two head nodes donated by Map->Used
and Map->Recycled of two doubly linked lists.
Initializes the count of the <Key, Value> pairs in the netmap to zero.
If Map is NULL, then ASSERT().
If the address of Map->Used is NULL, then ASSERT().
If the address of Map->Recycled is NULl, then ASSERT().
@param[in, out] Map The netmap to initialize.
**/
VOID
EFIAPI
NetMapInit (
IN OUT NET_MAP *Map
);
/**
To clean up the netmap, that is, release allocated memories.
Removes all nodes of the Used doubly linked list and frees memory of all related netmap items.
Removes all nodes of the Recycled doubly linked list and free memory of all related netmap items.
The number of the <Key, Value> pairs in the netmap is set to zero.
If Map is NULL, then ASSERT().
@param[in, out] Map The netmap to clean up.
**/
VOID
EFIAPI
NetMapClean (
IN OUT NET_MAP *Map
);
/**
Test whether the netmap is empty and return true if it is.
If the number of the <Key, Value> pairs in the netmap is zero, return TRUE.
If Map is NULL, then ASSERT().
@param[in] Map The net map to test.
@return TRUE if the netmap is empty, otherwise FALSE.
**/
BOOLEAN
EFIAPI
NetMapIsEmpty (
IN NET_MAP *Map
);
/**
Return the number of the <Key, Value> pairs in the netmap.
@param[in] Map The netmap to get the entry number.
@return The entry number in the netmap.
**/
UINTN
EFIAPI
NetMapGetCount (
IN NET_MAP *Map
);
/**
Allocate an item to save the <Key, Value> pair to the head of the netmap.
Allocate an item to save the <Key, Value> pair and add corresponding node entry
to the beginning of the Used doubly linked list. The number of the <Key, Value>
pairs in the netmap increase by 1.
If Map is NULL, then ASSERT().
@param[in, out] Map The netmap to insert into.
@param[in] Key The user's key.
@param[in] Value The user's value for the key.
@retval EFI_OUT_OF_RESOURCES Failed to allocate the memory for the item.
@retval EFI_SUCCESS The item is inserted to the head.
**/
EFI_STATUS
EFIAPI
NetMapInsertHead (
IN OUT NET_MAP *Map,
IN VOID *Key,
IN VOID *Value OPTIONAL
);
/**
Allocate an item to save the <Key, Value> pair to the tail of the netmap.
Allocate an item to save the <Key, Value> pair and add corresponding node entry
to the tail of the Used doubly linked list. The number of the <Key, Value>
pairs in the netmap increase by 1.
If Map is NULL, then ASSERT().
@param[in, out] Map The netmap to insert into.
@param[in] Key The user's key.
@param[in] Value The user's value for the key.
@retval EFI_OUT_OF_RESOURCES Failed to allocate the memory for the item.
@retval EFI_SUCCESS The item is inserted to the tail.
**/
EFI_STATUS
EFIAPI
NetMapInsertTail (
IN OUT NET_MAP *Map,
IN VOID *Key,
IN VOID *Value OPTIONAL
);
/**
Finds the key in the netmap and returns the point to the item containing the Key.
Iterate the Used doubly linked list of the netmap to get every item. Compare the key of every
item with the key to search. It returns the point to the item contains the Key if found.
If Map is NULL, then ASSERT().
@param[in] Map The netmap to search within.
@param[in] Key The key to search.
@return The point to the item contains the Key, or NULL if Key isn't in the map.
**/
NET_MAP_ITEM *
EFIAPI
NetMapFindKey (
IN NET_MAP *Map,
IN VOID *Key
);
/**
Remove the node entry of the item from the netmap and return the key of the removed item.
Remove the node entry of the item from the Used doubly linked list of the netmap.
The number of the <Key, Value> pairs in the netmap decrease by 1. Then add the node
entry of the item to the Recycled doubly linked list of the netmap. If Value is not NULL,
Value will point to the value of the item. It returns the key of the removed item.
If Map is NULL, then ASSERT().
If Item is NULL, then ASSERT().
if item in not in the netmap, then ASSERT().
@param[in, out] Map The netmap to remove the item from.
@param[in, out] Item The item to remove.
@param[out] Value The variable to receive the value if not NULL.
@return The key of the removed item.
**/
VOID *
EFIAPI
NetMapRemoveItem (
IN OUT NET_MAP *Map,
IN OUT NET_MAP_ITEM *Item,
OUT VOID **Value OPTIONAL
);
/**
Remove the first node entry on the netmap and return the key of the removed item.
Remove the first node entry from the Used doubly linked list of the netmap.
The number of the <Key, Value> pairs in the netmap decrease by 1. Then add the node
entry to the Recycled doubly linked list of the netmap. If parameter Value is not NULL,
parameter Value will point to the value of the item. It returns the key of the removed item.
If Map is NULL, then ASSERT().
If the Used doubly linked list is empty, then ASSERT().
@param[in, out] Map The netmap to remove the head from.
@param[out] Value The variable to receive the value if not NULL.
@return The key of the item removed.
**/
VOID *
EFIAPI
NetMapRemoveHead (
IN OUT NET_MAP *Map,
OUT VOID **Value OPTIONAL
);
/**
Remove the last node entry on the netmap and return the key of the removed item.
Remove the last node entry from the Used doubly linked list of the netmap.
The number of the <Key, Value> pairs in the netmap decrease by 1. Then add the node
entry to the Recycled doubly linked list of the netmap. If parameter Value is not NULL,
parameter Value will point to the value of the item. It returns the key of the removed item.
If Map is NULL, then ASSERT().
If the Used doubly linked list is empty, then ASSERT().
@param[in, out] Map The netmap to remove the tail from.
@param[out] Value The variable to receive the value if not NULL.
@return The key of the item removed.
**/
VOID *
EFIAPI
NetMapRemoveTail (
IN OUT NET_MAP *Map,
OUT VOID **Value OPTIONAL
);
typedef
EFI_STATUS
(EFIAPI *NET_MAP_CALLBACK) (
IN NET_MAP *Map,
IN NET_MAP_ITEM *Item,
IN VOID *Arg
);
/**
Iterate through the netmap and call CallBack for each item.
It will contiue the traverse if CallBack returns EFI_SUCCESS, otherwise, break
from the loop. It returns the CallBack's last return value. This function is
delete safe for the current item.
If Map is NULL, then ASSERT().
If CallBack is NULL, then ASSERT().
@param[in] Map The Map to iterate through.
@param[in] CallBack The callback function to call for each item.
@param[in] Arg The opaque parameter to the callback.
@retval EFI_SUCCESS There is no item in the netmap, or CallBack for each item
returns EFI_SUCCESS.
@retval Others It returns the CallBack's last return value.
**/
EFI_STATUS
EFIAPI
NetMapIterate (
IN NET_MAP *Map,
IN NET_MAP_CALLBACK CallBack,
IN VOID *Arg OPTIONAL
);
//
// Helper functions to implement driver binding and service binding protocols.
//
/**
Create a child of the service that is identified by ServiceBindingGuid.
Get the ServiceBinding Protocol first, then use it to create a child.
If ServiceBindingGuid is NULL, then ASSERT().
If ChildHandle is NULL, then ASSERT().
@param[in] Controller The controller which has the service installed.
@param[in] Image The image handle used to open service.
@param[in] ServiceBindingGuid The service's Guid.
@param[in, out] ChildHandle The handle to receive the created child.
@retval EFI_SUCCESS The child was successfully created.
@retval Others Failed to create the child.
**/
EFI_STATUS
EFIAPI
NetLibCreateServiceChild (
IN EFI_HANDLE Controller,
IN EFI_HANDLE Image,
IN EFI_GUID *ServiceBindingGuid,
IN OUT EFI_HANDLE *ChildHandle
);
/**
Destroy a child of the service that is identified by ServiceBindingGuid.
Get the ServiceBinding Protocol first, then use it to destroy a child.
If ServiceBindingGuid is NULL, then ASSERT().
@param[in] Controller The controller which has the service installed.
@param[in] Image The image handle used to open service.
@param[in] ServiceBindingGuid The service's Guid.
@param[in] ChildHandle The child to destroy.
@retval EFI_SUCCESS The child was destroyed.
@retval Others Failed to destroy the child.
**/
EFI_STATUS
EFIAPI
NetLibDestroyServiceChild (
IN EFI_HANDLE Controller,
IN EFI_HANDLE Image,
IN EFI_GUID *ServiceBindingGuid,
IN EFI_HANDLE ChildHandle
);
/**
Get handle with Simple Network Protocol installed on it.
There should be MNP Service Binding Protocol installed on the input ServiceHandle.
If Simple Network Protocol is already installed on the ServiceHandle, the
ServiceHandle will be returned. If SNP is not installed on the ServiceHandle,
try to find its parent handle with SNP installed.
@param[in] ServiceHandle The handle where network service binding protocols are
installed on.
@param[out] Snp The pointer to store the address of the SNP instance.
This is an optional parameter that may be NULL.
@return The SNP handle, or NULL if not found.
**/
EFI_HANDLE
EFIAPI
NetLibGetSnpHandle (
IN EFI_HANDLE ServiceHandle,
OUT EFI_SIMPLE_NETWORK_PROTOCOL **Snp OPTIONAL
);
/**
Retrieve VLAN ID of a VLAN device handle.
Search VLAN device path node in Device Path of specified ServiceHandle and
return its VLAN ID. If no VLAN device path node found, then this ServiceHandle
is not a VLAN device handle, and 0 will be returned.
@param[in] ServiceHandle The handle where network service binding protocols are
installed on.
@return VLAN ID of the device handle, or 0 if not a VLAN device.
**/
UINT16
EFIAPI
NetLibGetVlanId (
IN EFI_HANDLE ServiceHandle
);
/**
Find VLAN device handle with specified VLAN ID.
The VLAN child device handle is created by VLAN Config Protocol on ControllerHandle.
This function will append VLAN device path node to the parent device path,
and then use LocateDevicePath() to find the correct VLAN device handle.
@param[in] ControllerHandle The handle where network service binding protocols are
installed on.
@param[in] VlanId The configured VLAN ID for the VLAN device.
@return The VLAN device handle, or NULL if not found.
**/
EFI_HANDLE
EFIAPI
NetLibGetVlanHandle (
IN EFI_HANDLE ControllerHandle,
IN UINT16 VlanId
);
/**
Get MAC address associated with the network service handle.
There should be MNP Service Binding Protocol installed on the input ServiceHandle.
If SNP is installed on the ServiceHandle or its parent handle, MAC address will
be retrieved from SNP. If no SNP found, try to get SNP mode data use MNP.
@param[in] ServiceHandle The handle where network service binding protocols are
installed on.
@param[out] MacAddress The pointer to store the returned MAC address.
@param[out] AddressSize The length of returned MAC address.
@retval EFI_SUCCESS MAC address was returned successfully.
@retval Others Failed to get SNP mode data.
**/
EFI_STATUS
EFIAPI
NetLibGetMacAddress (
IN EFI_HANDLE ServiceHandle,
OUT EFI_MAC_ADDRESS *MacAddress,
OUT UINTN *AddressSize
);
/**
Convert MAC address of the NIC associated with specified Service Binding Handle
to a unicode string. Callers are responsible for freeing the string storage.
Locate simple network protocol associated with the Service Binding Handle and
get the mac address from SNP. Then convert the mac address into a unicode
string. It takes 2 unicode characters to represent a 1 byte binary buffer.
Plus one unicode character for the null-terminator.
@param[in] ServiceHandle The handle where network service binding protocol is
installed.
@param[in] ImageHandle The image handle used to act as the agent handle to
get the simple network protocol.
@param[out] MacString The pointer to store the address of the string
representation of the mac address.
@retval EFI_SUCCESS Converted the mac address a unicode string successfully.
@retval EFI_OUT_OF_RESOURCES There are not enough memory resources.
@retval Others Failed to open the simple network protocol.
**/
EFI_STATUS
EFIAPI
NetLibGetMacString (
IN EFI_HANDLE ServiceHandle,
IN EFI_HANDLE ImageHandle,
OUT CHAR16 **MacString
);
/**
Detect media status for specified network device.
The underlying UNDI driver may or may not support reporting media status from
GET_STATUS command (PXE_STATFLAGS_GET_STATUS_NO_MEDIA_SUPPORTED). This routine
will try to invoke Snp->GetStatus() to get the media status. If media is already
present, it returns directly. If media is not present, it will stop SNP and then
restart SNP to get the latest media status. This provides an opportunity to get
the correct media status for old UNDI driver, which doesn't support reporting
media status from GET_STATUS command.
Note: there are two limitations for the current algorithm:
1) For UNDI with this capability, when the cable is not attached, there will
be an redundant Stop/Start() process.
2) for UNDI without this capability, in case that network cable is attached when
Snp->Initialize() is invoked while network cable is unattached later,
NetLibDetectMedia() will report MediaPresent as TRUE, causing upper layer
apps to wait for timeout time.
@param[in] ServiceHandle The handle where network service binding protocols are
installed.
@param[out] MediaPresent The pointer to store the media status.
@retval EFI_SUCCESS Media detection success.
@retval EFI_INVALID_PARAMETER ServiceHandle is not a valid network device handle.
@retval EFI_UNSUPPORTED The network device does not support media detection.
@retval EFI_DEVICE_ERROR SNP is in an unknown state.
**/
EFI_STATUS
EFIAPI
NetLibDetectMedia (
IN EFI_HANDLE ServiceHandle,
OUT BOOLEAN *MediaPresent
);
/**
Create an IPv4 device path node.
The header type of IPv4 device path node is MESSAGING_DEVICE_PATH.
The header subtype of IPv4 device path node is MSG_IPv4_DP.
The length of the IPv4 device path node in bytes is 19.
Get other information from parameters to make up the whole IPv4 device path node.
@param[in, out] Node The pointer to the IPv4 device path node.
@param[in] Controller The controller handle.
@param[in] LocalIp The local IPv4 address.
@param[in] LocalPort The local port.
@param[in] RemoteIp The remote IPv4 address.
@param[in] RemotePort The remote port.
@param[in] Protocol The protocol type in the IP header.
@param[in] UseDefaultAddress Whether this instance is using default address or not.
**/
VOID
EFIAPI
NetLibCreateIPv4DPathNode (
IN OUT IPv4_DEVICE_PATH *Node,
IN EFI_HANDLE Controller,
IN IP4_ADDR LocalIp,
IN UINT16 LocalPort,
IN IP4_ADDR RemoteIp,
IN UINT16 RemotePort,
IN UINT16 Protocol,
IN BOOLEAN UseDefaultAddress
);
/**
Create an IPv6 device path node.
The header type of IPv6 device path node is MESSAGING_DEVICE_PATH.
The header subtype of IPv6 device path node is MSG_IPv6_DP.
The length of the IPv6 device path node in bytes is 43.
Get other information from parameters to make up the whole IPv6 device path node.
@param[in, out] Node The pointer to the IPv6 device path node.
@param[in] Controller The controller handle.
@param[in] LocalIp The local IPv6 address.
@param[in] LocalPort The local port.
@param[in] RemoteIp The remote IPv6 address.
@param[in] RemotePort The remote port.
@param[in] Protocol The protocol type in the IP header.
**/
VOID
EFIAPI
NetLibCreateIPv6DPathNode (
IN OUT IPv6_DEVICE_PATH *Node,
IN EFI_HANDLE Controller,
IN EFI_IPv6_ADDRESS *LocalIp,
IN UINT16 LocalPort,
IN EFI_IPv6_ADDRESS *RemoteIp,
IN UINT16 RemotePort,
IN UINT16 Protocol
);
/**
Find the UNDI/SNP handle from controller and protocol GUID.
For example, IP will open an MNP child to transmit/receive
packets. When MNP is stopped, IP should also be stopped. IP
needs to find its own private data that is related the IP's
service binding instance that is installed on the UNDI/SNP handle.
The controller is then either an MNP or an ARP child handle. Note that
IP opens these handles using BY_DRIVER. Use that infomation to get the
UNDI/SNP handle.
@param[in] Controller The protocol handle to check.
@param[in] ProtocolGuid The protocol that is related with the handle.
@return The UNDI/SNP handle or NULL for errors.
**/
EFI_HANDLE
EFIAPI
NetLibGetNicHandle (
IN EFI_HANDLE Controller,
IN EFI_GUID *ProtocolGuid
);
/**
This is the default unload handle for all the network drivers.
Disconnect the driver specified by ImageHandle from all the devices in the handle database.
Uninstall all the protocols installed in the driver entry point.
@param[in] ImageHandle The drivers' driver image.
@retval EFI_SUCCESS The image is unloaded.
@retval Others Failed to unload the image.
**/
EFI_STATUS
EFIAPI
NetLibDefaultUnload (
IN EFI_HANDLE ImageHandle
);
/**
Convert one Null-terminated ASCII string (decimal dotted) to EFI_IPv4_ADDRESS.
@param[in] String The pointer to the Ascii string.
@param[out] Ip4Address The pointer to the converted IPv4 address.
@retval EFI_SUCCESS Converted to an IPv4 address successfully.
@retval EFI_INVALID_PARAMETER The string is malformated, or Ip4Address is NULL.
**/
EFI_STATUS
EFIAPI
NetLibAsciiStrToIp4 (
IN CONST CHAR8 *String,
OUT EFI_IPv4_ADDRESS *Ip4Address
);
/**
Convert one Null-terminated ASCII string to EFI_IPv6_ADDRESS. The format of the
string is defined in RFC 4291 - Text Pepresentation of Addresses.
@param[in] String The pointer to the Ascii string.
@param[out] Ip6Address The pointer to the converted IPv6 address.
@retval EFI_SUCCESS Converted to an IPv6 address successfully.
@retval EFI_INVALID_PARAMETER The string is malformated, or Ip6Address is NULL.
**/
EFI_STATUS
EFIAPI
NetLibAsciiStrToIp6 (
IN CONST CHAR8 *String,
OUT EFI_IPv6_ADDRESS *Ip6Address
);
/**
Convert one Null-terminated Unicode string (decimal dotted) to EFI_IPv4_ADDRESS.
@param[in] String The pointer to the Ascii string.
@param[out] Ip4Address The pointer to the converted IPv4 address.
@retval EFI_SUCCESS Converted to an IPv4 address successfully.
@retval EFI_INVALID_PARAMETER The string is mal-formated or Ip4Address is NULL.
@retval EFI_OUT_OF_RESOURCES Failed to perform the operation due to lack of resources.
**/
EFI_STATUS
EFIAPI
NetLibStrToIp4 (
IN CONST CHAR16 *String,
OUT EFI_IPv4_ADDRESS *Ip4Address
);
/**
Convert one Null-terminated Unicode string to EFI_IPv6_ADDRESS. The format of
the string is defined in RFC 4291 - Text Pepresentation of Addresses.
@param[in] String The pointer to the Ascii string.
@param[out] Ip6Address The pointer to the converted IPv6 address.
@retval EFI_SUCCESS Converted to an IPv6 address successfully.
@retval EFI_INVALID_PARAMETER The string is malformated or Ip6Address is NULL.
@retval EFI_OUT_OF_RESOURCES Failed to perform the operation due to a lack of resources.
**/
EFI_STATUS
EFIAPI
NetLibStrToIp6 (
IN CONST CHAR16 *String,
OUT EFI_IPv6_ADDRESS *Ip6Address
);
/**
Convert one Null-terminated Unicode string to EFI_IPv6_ADDRESS and prefix length.
The format of the string is defined in RFC 4291 - Text Pepresentation of Addresses
Prefixes: ipv6-address/prefix-length.
@param[in] String The pointer to the Ascii string.
@param[out] Ip6Address The pointer to the converted IPv6 address.
@param[out] PrefixLength The pointer to the converted prefix length.
@retval EFI_SUCCESS Converted to an IPv6 address successfully.
@retval EFI_INVALID_PARAMETER The string is malformated, or Ip6Address is NULL.
@retval EFI_OUT_OF_RESOURCES Failed to perform the operation due to a lack of resources.
**/
EFI_STATUS
EFIAPI
NetLibStrToIp6andPrefix (
IN CONST CHAR16 *String,
OUT EFI_IPv6_ADDRESS *Ip6Address,
OUT UINT8 *PrefixLength
);
//
// Various signatures
//
#define NET_BUF_SIGNATURE SIGNATURE_32 ('n', 'b', 'u', 'f')
#define NET_VECTOR_SIGNATURE SIGNATURE_32 ('n', 'v', 'e', 'c')
#define NET_QUE_SIGNATURE SIGNATURE_32 ('n', 'b', 'q', 'u')
#define NET_PROTO_DATA 64 // Opaque buffer for protocols
#define NET_BUF_HEAD 1 // Trim or allocate space from head
#define NET_BUF_TAIL 0 // Trim or allocate space from tail
#define NET_VECTOR_OWN_FIRST 0x01 // We allocated the 1st block in the vector
#define NET_CHECK_SIGNATURE(PData, SIGNATURE) \
ASSERT (((PData) != NULL) && ((PData)->Signature == (SIGNATURE)))
//
// Single memory block in the vector.
//
typedef struct {
UINT32 Len; // The block's length
UINT8 *Bulk; // The block's Data
} NET_BLOCK;
typedef VOID (EFIAPI *NET_VECTOR_EXT_FREE) (VOID *Arg);
//
//NET_VECTOR contains several blocks to hold all packet's
//fragments and other house-keeping stuff for sharing. It
//doesn't specify the where actual packet fragment begins.
//
typedef struct {
UINT32 Signature;
INTN RefCnt; // Reference count to share NET_VECTOR.
NET_VECTOR_EXT_FREE Free; // external function to free NET_VECTOR
VOID *Arg; // opeque argument to Free
UINT32 Flag; // Flags, NET_VECTOR_OWN_FIRST
UINT32 Len; // Total length of the assocated BLOCKs
UINT32 BlockNum;
NET_BLOCK Block[1];
} NET_VECTOR;
//
//NET_BLOCK_OP operates on the NET_BLOCK. It specifies
//where the actual fragment begins and ends
//
typedef struct {
UINT8 *BlockHead; // Block's head, or the smallest valid Head
UINT8 *BlockTail; // Block's tail. BlockTail-BlockHead=block length
UINT8 *Head; // 1st byte of the data in the block
UINT8 *Tail; // Tail of the data in the block, Tail-Head=Size
UINT32 Size; // The size of the data
} NET_BLOCK_OP;
typedef union {
IP4_HEAD *Ip4;
EFI_IP6_HEADER *Ip6;
} NET_IP_HEAD;
//
//NET_BUF is the buffer manage structure used by the
//network stack. Every network packet may be fragmented. The Vector points to
//memory blocks used by each fragment, and BlockOp
//specifies where each fragment begins and ends.
//
//It also contains an opaque area for the protocol to store
//per-packet information. Protocol must be careful not
//to overwrite the members after that.
//
typedef struct {
UINT32 Signature;
INTN RefCnt;
LIST_ENTRY List; // The List this NET_BUF is on
NET_IP_HEAD Ip; // Network layer header, for fast access
TCP_HEAD *Tcp; // Transport layer header, for fast access
EFI_UDP_HEADER *Udp; // User Datagram Protocol header
UINT8 ProtoData [NET_PROTO_DATA]; //Protocol specific data
NET_VECTOR *Vector; // The vector containing the packet
UINT32 BlockOpNum; // Total number of BlockOp in the buffer
UINT32 TotalSize; // Total size of the actual packet
NET_BLOCK_OP BlockOp[1]; // Specify the position of actual packet
} NET_BUF;
//
//A queue of NET_BUFs. It is a thin extension of
//NET_BUF functions.
//
typedef struct {
UINT32 Signature;
INTN RefCnt;
LIST_ENTRY List; // The List this buffer queue is on
LIST_ENTRY BufList; // list of queued buffers
UINT32 BufSize; // total length of DATA in the buffers
UINT32 BufNum; // total number of buffers on the chain
} NET_BUF_QUEUE;
//
// Pseudo header for TCP and UDP checksum
//
#pragma pack(1)
typedef struct {
IP4_ADDR SrcIp;
IP4_ADDR DstIp;
UINT8 Reserved;
UINT8 Protocol;
UINT16 Len;
} NET_PSEUDO_HDR;
typedef struct {
EFI_IPv6_ADDRESS SrcIp;
EFI_IPv6_ADDRESS DstIp;
UINT32 Len;
UINT32 Reserved:24;
UINT32 NextHeader:8;
} NET_IP6_PSEUDO_HDR;
#pragma pack()
//
// The fragment entry table used in network interfaces. This is
// the same as NET_BLOCK now. Use two different to distinguish
// the two in case that NET_BLOCK be enhanced later.
//
typedef struct {
UINT32 Len;
UINT8 *Bulk;
} NET_FRAGMENT;
#define NET_GET_REF(PData) ((PData)->RefCnt++)
#define NET_PUT_REF(PData) ((PData)->RefCnt--)
#define NETBUF_FROM_PROTODATA(Info) BASE_CR((Info), NET_BUF, ProtoData)
#define NET_BUF_SHARED(Buf) \
(((Buf)->RefCnt > 1) || ((Buf)->Vector->RefCnt > 1))
#define NET_VECTOR_SIZE(BlockNum) \
(sizeof (NET_VECTOR) + ((BlockNum) - 1) * sizeof (NET_BLOCK))
#define NET_BUF_SIZE(BlockOpNum) \
(sizeof (NET_BUF) + ((BlockOpNum) - 1) * sizeof (NET_BLOCK_OP))
#define NET_HEADSPACE(BlockOp) \
(UINTN)((BlockOp)->Head - (BlockOp)->BlockHead)
#define NET_TAILSPACE(BlockOp) \
(UINTN)((BlockOp)->BlockTail - (BlockOp)->Tail)
/**
Allocate a single block NET_BUF. Upon allocation, all the
free space is in the tail room.
@param[in] Len The length of the block.
@return The pointer to the allocated NET_BUF, or NULL if the
allocation failed due to resource limitations.
**/
NET_BUF *
EFIAPI
NetbufAlloc (
IN UINT32 Len
);
/**
Free the net buffer and its associated NET_VECTOR.
Decrease the reference count of the net buffer by one. Free the associated net
vector and itself if the reference count of the net buffer is decreased to 0.
The net vector free operation decreases the reference count of the net
vector by one, and performs the resource free operation when the reference count
of the net vector is 0.
@param[in] Nbuf The pointer to the NET_BUF to be freed.
**/
VOID
EFIAPI
NetbufFree (
IN NET_BUF *Nbuf
);
/**
Get the index of NET_BLOCK_OP that contains the byte at Offset in the net
buffer.
For example, this function can be used to retrieve the IP header in the packet. It
also can be used to get the fragment that contains the byte used
mainly by the library implementation itself.
@param[in] Nbuf The pointer to the net buffer.
@param[in] Offset The offset of the byte.
@param[out] Index Index of the NET_BLOCK_OP that contains the byte at
Offset.
@return The pointer to the Offset'th byte of data in the net buffer, or NULL
if there is no such data in the net buffer.
**/
UINT8 *
EFIAPI
NetbufGetByte (
IN NET_BUF *Nbuf,
IN UINT32 Offset,
OUT UINT32 *Index OPTIONAL
);
/**
Create a copy of the net buffer that shares the associated net vector.
The reference count of the newly created net buffer is set to 1. The reference
count of the associated net vector is increased by one.
@param[in] Nbuf The pointer to the net buffer to be cloned.
@return The pointer to the cloned net buffer, or NULL if the
allocation failed due to resource limitations.
**/
NET_BUF *
EFIAPI
NetbufClone (
IN NET_BUF *Nbuf
);
/**
Create a duplicated copy of the net buffer with data copied and HeadSpace
bytes of head space reserved.
The duplicated net buffer will allocate its own memory to hold the data of the
source net buffer.
@param[in] Nbuf The pointer to the net buffer to be duplicated from.
@param[in, out] Duplicate The pointer to the net buffer to duplicate to. If
NULL, a new net buffer is allocated.
@param[in] HeadSpace The length of the head space to reserve.
@return The pointer to the duplicated net buffer, or NULL if
the allocation failed due to resource limitations.
**/
NET_BUF *
EFIAPI
NetbufDuplicate (
IN NET_BUF *Nbuf,
IN OUT NET_BUF *Duplicate OPTIONAL,
IN UINT32 HeadSpace
);
/**
Create a NET_BUF structure which contains Len byte data of Nbuf starting from
Offset.
A new NET_BUF structure will be created but the associated data in NET_VECTOR
is shared. This function exists to perform IP packet fragmentation.
@param[in] Nbuf The pointer to the net buffer to be extracted.
@param[in] Offset Starting point of the data to be included in the new
net buffer.
@param[in] Len The bytes of data to be included in the new net buffer.
@param[in] HeadSpace The bytes of the head space to reserve for the protocol header.
@return The pointer to the cloned net buffer, or NULL if the
allocation failed due to resource limitations.
**/
NET_BUF *
EFIAPI
NetbufGetFragment (
IN NET_BUF *Nbuf,
IN UINT32 Offset,
IN UINT32 Len,
IN UINT32 HeadSpace
);
/**
Reserve some space in the header room of the net buffer.
Upon allocation, all the space is in the tail room of the buffer. Call this
function to move space to the header room. This function is quite limited
in that it can only reserve space from the first block of an empty NET_BUF not
built from the external. However, it should be enough for the network stack.
@param[in, out] Nbuf The pointer to the net buffer.
@param[in] Len The length of buffer to be reserved from the header.
**/
VOID
EFIAPI
NetbufReserve (
IN OUT NET_BUF *Nbuf,
IN UINT32 Len
);
/**
Allocate Len bytes of space from the header or tail of the buffer.
@param[in, out] Nbuf The pointer to the net buffer.
@param[in] Len The length of the buffer to be allocated.
@param[in] FromHead The flag to indicate whether to reserve the data
from head (TRUE) or tail (FALSE).
@return The pointer to the first byte of the allocated buffer,
or NULL, if there is no sufficient space.
**/
UINT8*
EFIAPI
NetbufAllocSpace (
IN OUT NET_BUF *Nbuf,
IN UINT32 Len,
IN BOOLEAN FromHead
);
/**
Trim Len bytes from the header or the tail of the net buffer.
@param[in, out] Nbuf The pointer to the net buffer.
@param[in] Len The length of the data to be trimmed.
@param[in] FromHead The flag to indicate whether trim data is from the
head (TRUE) or the tail (FALSE).
@return The length of the actual trimmed data, which may be less
than Len if the TotalSize of Nbuf is less than Len.
**/
UINT32
EFIAPI
NetbufTrim (
IN OUT NET_BUF *Nbuf,
IN UINT32 Len,
IN BOOLEAN FromHead
);
/**
Copy Len bytes of data from the specific offset of the net buffer to the
destination memory.
The Len bytes of data may cross several fragments of the net buffer.
@param[in] Nbuf The pointer to the net buffer.
@param[in] Offset The sequence number of the first byte to copy.
@param[in] Len The length of the data to copy.
@param[in] Dest The destination of the data to copy to.
@return The length of the actual copied data, or 0 if the offset
specified exceeds the total size of net buffer.
**/
UINT32
EFIAPI
NetbufCopy (
IN NET_BUF *Nbuf,
IN UINT32 Offset,
IN UINT32 Len,
IN UINT8 *Dest
);
/**
Build a NET_BUF from external blocks.
A new NET_BUF structure will be created from external blocks. An additional block
of memory will be allocated to hold reserved HeadSpace bytes of header room
and existing HeadLen bytes of header, but the external blocks are shared by the
net buffer to avoid data copying.
@param[in] ExtFragment The pointer to the data block.
@param[in] ExtNum The number of the data blocks.
@param[in] HeadSpace The head space to be reserved.
@param[in] HeadLen The length of the protocol header. The function
pulls this amount of data into a linear block.
@param[in] ExtFree The pointer to the caller-provided free function.
@param[in] Arg The argument passed to ExtFree when ExtFree is
called.
@return The pointer to the net buffer built from the data blocks,
or NULL if the allocation failed due to resource
limit.
**/
NET_BUF *
EFIAPI
NetbufFromExt (
IN NET_FRAGMENT *ExtFragment,
IN UINT32 ExtNum,
IN UINT32 HeadSpace,
IN UINT32 HeadLen,
IN NET_VECTOR_EXT_FREE ExtFree,
IN VOID *Arg OPTIONAL
);
/**
Build a fragment table to contain the fragments in the net buffer. This is the
opposite operation of the NetbufFromExt.
@param[in] Nbuf Points to the net buffer.
@param[in, out] ExtFragment The pointer to the data block.
@param[in, out] ExtNum The number of the data blocks.
@retval EFI_BUFFER_TOO_SMALL The number of non-empty blocks is bigger than
ExtNum.
@retval EFI_SUCCESS The fragment table was built successfully.
**/
EFI_STATUS
EFIAPI
NetbufBuildExt (
IN NET_BUF *Nbuf,
IN OUT NET_FRAGMENT *ExtFragment,
IN OUT UINT32 *ExtNum
);
/**
Build a net buffer from a list of net buffers.
All the fragments will be collected from the list of NEW_BUF, and then a new
net buffer will be created through NetbufFromExt.
@param[in] BufList A List of the net buffer.
@param[in] HeadSpace The head space to be reserved.
@param[in] HeaderLen The length of the protocol header. The function
pulls this amount of data into a linear block.
@param[in] ExtFree The pointer to the caller provided free function.
@param[in] Arg The argument passed to ExtFree when ExtFree is called.
@return The pointer to the net buffer built from the list of net
buffers.
**/
NET_BUF *
EFIAPI
NetbufFromBufList (
IN LIST_ENTRY *BufList,
IN UINT32 HeadSpace,
IN UINT32 HeaderLen,
IN NET_VECTOR_EXT_FREE ExtFree,
IN VOID *Arg OPTIONAL
);
/**
Free a list of net buffers.
@param[in, out] Head The pointer to the head of linked net buffers.
**/
VOID
EFIAPI
NetbufFreeList (
IN OUT LIST_ENTRY *Head
);
/**
Initiate the net buffer queue.
@param[in, out] NbufQue The pointer to the net buffer queue to be initialized.
**/
VOID
EFIAPI
NetbufQueInit (
IN OUT NET_BUF_QUEUE *NbufQue
);
/**
Allocate and initialize a net buffer queue.
@return The pointer to the allocated net buffer queue, or NULL if the
allocation failed due to resource limit.
**/
NET_BUF_QUEUE *
EFIAPI
NetbufQueAlloc (
VOID
);
/**
Free a net buffer queue.
Decrease the reference count of the net buffer queue by one. The real resource
free operation isn't performed until the reference count of the net buffer
queue is decreased to 0.
@param[in] NbufQue The pointer to the net buffer queue to be freed.
**/
VOID
EFIAPI
NetbufQueFree (
IN NET_BUF_QUEUE *NbufQue
);
/**
Remove a net buffer from the head in the specific queue and return it.
@param[in, out] NbufQue The pointer to the net buffer queue.
@return The pointer to the net buffer removed from the specific queue,
or NULL if there is no net buffer in the specific queue.
**/
NET_BUF *
EFIAPI
NetbufQueRemove (
IN OUT NET_BUF_QUEUE *NbufQue
);
/**
Append a net buffer to the net buffer queue.
@param[in, out] NbufQue The pointer to the net buffer queue.
@param[in, out] Nbuf The pointer to the net buffer to be appended.
**/
VOID
EFIAPI
NetbufQueAppend (
IN OUT NET_BUF_QUEUE *NbufQue,
IN OUT NET_BUF *Nbuf
);
/**
Copy Len bytes of data from the net buffer queue at the specific offset to the
destination memory.
The copying operation is the same as NetbufCopy, but applies to the net buffer
queue instead of the net buffer.
@param[in] NbufQue The pointer to the net buffer queue.
@param[in] Offset The sequence number of the first byte to copy.
@param[in] Len The length of the data to copy.
@param[out] Dest The destination of the data to copy to.
@return The length of the actual copied data, or 0 if the offset
specified exceeds the total size of net buffer queue.
**/
UINT32
EFIAPI
NetbufQueCopy (
IN NET_BUF_QUEUE *NbufQue,
IN UINT32 Offset,
IN UINT32 Len,
OUT UINT8 *Dest
);
/**
Trim Len bytes of data from the buffer queue and free any net buffer
that is completely trimmed.
The trimming operation is the same as NetbufTrim but applies to the net buffer
queue instead of the net buffer.
@param[in, out] NbufQue The pointer to the net buffer queue.
@param[in] Len The length of the data to trim.
@return The actual length of the data trimmed.
**/
UINT32
EFIAPI
NetbufQueTrim (
IN OUT NET_BUF_QUEUE *NbufQue,
IN UINT32 Len
);
/**
Flush the net buffer queue.
@param[in, out] NbufQue The pointer to the queue to be flushed.
**/
VOID
EFIAPI
NetbufQueFlush (
IN OUT NET_BUF_QUEUE *NbufQue
);
/**
Compute the checksum for a bulk of data.
@param[in] Bulk The pointer to the data.
@param[in] Len The length of the data, in bytes.
@return The computed checksum.
**/
UINT16
EFIAPI
NetblockChecksum (
IN UINT8 *Bulk,
IN UINT32 Len
);
/**
Add two checksums.
@param[in] Checksum1 The first checksum to be added.
@param[in] Checksum2 The second checksum to be added.
@return The new checksum.
**/
UINT16
EFIAPI
NetAddChecksum (
IN UINT16 Checksum1,
IN UINT16 Checksum2
);
/**
Compute the checksum for a NET_BUF.
@param[in] Nbuf The pointer to the net buffer.
@return The computed checksum.
**/
UINT16
EFIAPI
NetbufChecksum (
IN NET_BUF *Nbuf
);
/**
Compute the checksum for TCP/UDP pseudo header.
Src and Dst are in network byte order, and Len is in host byte order.
@param[in] Src The source address of the packet.
@param[in] Dst The destination address of the packet.
@param[in] Proto The protocol type of the packet.
@param[in] Len The length of the packet.
@return The computed checksum.
**/
UINT16
EFIAPI
NetPseudoHeadChecksum (
IN IP4_ADDR Src,
IN IP4_ADDR Dst,
IN UINT8 Proto,
IN UINT16 Len
);
/**
Compute the checksum for the TCP6/UDP6 pseudo header.
Src and Dst are in network byte order, and Len is in host byte order.
@param[in] Src The source address of the packet.
@param[in] Dst The destination address of the packet.
@param[in] NextHeader The protocol type of the packet.
@param[in] Len The length of the packet.
@return The computed checksum.
**/
UINT16
EFIAPI
NetIp6PseudoHeadChecksum (
IN EFI_IPv6_ADDRESS *Src,
IN EFI_IPv6_ADDRESS *Dst,
IN UINT8 NextHeader,
IN UINT32 Len
);
/**
The function frees the net buffer which allocated by the IP protocol. It releases
only the net buffer and doesn't call the external free function.
This function should be called after finishing the process of mIpSec->ProcessExt()
for outbound traffic. The (EFI_IPSEC2_PROTOCOL)->ProcessExt() allocates a new
buffer for the ESP, so there needs a function to free the old net buffer.
@param[in] Nbuf The network buffer to be freed.
**/
VOID
NetIpSecNetbufFree (
NET_BUF *Nbuf
);
/**
This function obtains the system guid from the smbios table.
@param[out] SystemGuid The pointer of the returned system guid.
@retval EFI_SUCCESS Successfully obtained the system guid.
@retval EFI_NOT_FOUND Did not find the SMBIOS table.
**/
EFI_STATUS
EFIAPI
NetLibGetSystemGuid (
OUT EFI_GUID *SystemGuid
);
#endif
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