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diff --git a/arch/tile/include/hv/netio_intf.h b/arch/tile/include/hv/netio_intf.h
deleted file mode 100644
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--- a/arch/tile/include/hv/netio_intf.h
+++ /dev/null
@@ -1,2975 +0,0 @@
-/*
- * Copyright 2010 Tilera Corporation. All Rights Reserved.
- *
- * This program is free software; you can redistribute it and/or
- * modify it under the terms of the GNU General Public License
- * as published by the Free Software Foundation, version 2.
- *
- * This program is distributed in the hope that it will be useful, but
- * WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, GOOD TITLE or
- * NON INFRINGEMENT. See the GNU General Public License for
- * more details.
- */
-
-/**
- * NetIO interface structures and macros.
- */
-
-#ifndef __NETIO_INTF_H__
-#define __NETIO_INTF_H__
-
-#include <hv/netio_errors.h>
-
-#ifdef __KERNEL__
-#include <linux/types.h>
-#else
-#include <stdint.h>
-#endif
-
-#if !defined(__HV__) && !defined(__BOGUX__) && !defined(__KERNEL__)
-#include <assert.h>
-#define netio_assert assert /**< Enable assertions from macros */
-#else
-#define netio_assert(...) ((void)(0)) /**< Disable assertions from macros */
-#endif
-
-/*
- * If none of these symbols are defined, we're building libnetio in an
- * environment where we have pthreads, so we'll enable locking.
- */
-#if !defined(__HV__) && !defined(__BOGUX__) && !defined(__KERNEL__) && \
- !defined(__NEWLIB__)
-#define _NETIO_PTHREAD /**< Include a mutex in netio_queue_t below */
-
-/*
- * If NETIO_UNLOCKED is defined, we don't do use per-cpu locks on
- * per-packet NetIO operations. We still do pthread locking on things
- * like netio_input_register, though. This is used for building
- * libnetio_unlocked.
- */
-#ifndef NETIO_UNLOCKED
-
-/* Avoid PLT overhead by using our own inlined per-cpu lock. */
-#include <sched.h>
-typedef int _netio_percpu_mutex_t;
-
-static __inline int
-_netio_percpu_mutex_init(_netio_percpu_mutex_t* lock)
-{
- *lock = 0;
- return 0;
-}
-
-static __inline int
-_netio_percpu_mutex_lock(_netio_percpu_mutex_t* lock)
-{
- while (__builtin_expect(__insn_tns(lock), 0))
- sched_yield();
- return 0;
-}
-
-static __inline int
-_netio_percpu_mutex_unlock(_netio_percpu_mutex_t* lock)
-{
- *lock = 0;
- return 0;
-}
-
-#else /* NETIO_UNLOCKED */
-
-/* Don't do any locking for per-packet NetIO operations. */
-typedef int _netio_percpu_mutex_t;
-#define _netio_percpu_mutex_init(L)
-#define _netio_percpu_mutex_lock(L)
-#define _netio_percpu_mutex_unlock(L)
-
-#endif /* NETIO_UNLOCKED */
-#endif /* !__HV__, !__BOGUX, !__KERNEL__, !__NEWLIB__ */
-
-/** How many tiles can register for a given queue.
- * @ingroup setup */
-#define NETIO_MAX_TILES_PER_QUEUE 64
-
-
-/** Largest permissible queue identifier.
- * @ingroup setup */
-#define NETIO_MAX_QUEUE_ID 255
-
-
-#ifndef __DOXYGEN__
-
-/* Metadata packet checksum/ethertype flags. */
-
-/** The L4 checksum has not been calculated. */
-#define _NETIO_PKT_NO_L4_CSUM_SHIFT 0
-#define _NETIO_PKT_NO_L4_CSUM_RMASK 1
-#define _NETIO_PKT_NO_L4_CSUM_MASK \
- (_NETIO_PKT_NO_L4_CSUM_RMASK << _NETIO_PKT_NO_L4_CSUM_SHIFT)
-
-/** The L3 checksum has not been calculated. */
-#define _NETIO_PKT_NO_L3_CSUM_SHIFT 1
-#define _NETIO_PKT_NO_L3_CSUM_RMASK 1
-#define _NETIO_PKT_NO_L3_CSUM_MASK \
- (_NETIO_PKT_NO_L3_CSUM_RMASK << _NETIO_PKT_NO_L3_CSUM_SHIFT)
-
-/** The L3 checksum is incorrect (or perhaps has not been calculated). */
-#define _NETIO_PKT_BAD_L3_CSUM_SHIFT 2
-#define _NETIO_PKT_BAD_L3_CSUM_RMASK 1
-#define _NETIO_PKT_BAD_L3_CSUM_MASK \
- (_NETIO_PKT_BAD_L3_CSUM_RMASK << _NETIO_PKT_BAD_L3_CSUM_SHIFT)
-
-/** The Ethernet packet type is unrecognized. */
-#define _NETIO_PKT_TYPE_UNRECOGNIZED_SHIFT 3
-#define _NETIO_PKT_TYPE_UNRECOGNIZED_RMASK 1
-#define _NETIO_PKT_TYPE_UNRECOGNIZED_MASK \
- (_NETIO_PKT_TYPE_UNRECOGNIZED_RMASK << \
- _NETIO_PKT_TYPE_UNRECOGNIZED_SHIFT)
-
-/* Metadata packet type flags. */
-
-/** Where the packet type bits are; this field is the index into
- * _netio_pkt_info. */
-#define _NETIO_PKT_TYPE_SHIFT 4
-#define _NETIO_PKT_TYPE_RMASK 0x3F
-
-/** How many VLAN tags the packet has, and, if we have two, which one we
- * actually grouped on. A VLAN within a proprietary (Marvell or Broadcom)
- * tag is counted here. */
-#define _NETIO_PKT_VLAN_SHIFT 4
-#define _NETIO_PKT_VLAN_RMASK 0x3
-#define _NETIO_PKT_VLAN_MASK \
- (_NETIO_PKT_VLAN_RMASK << _NETIO_PKT_VLAN_SHIFT)
-#define _NETIO_PKT_VLAN_NONE 0 /* No VLAN tag. */
-#define _NETIO_PKT_VLAN_ONE 1 /* One VLAN tag. */
-#define _NETIO_PKT_VLAN_TWO_OUTER 2 /* Two VLAN tags, outer one used. */
-#define _NETIO_PKT_VLAN_TWO_INNER 3 /* Two VLAN tags, inner one used. */
-
-/** Which proprietary tags the packet has. */
-#define _NETIO_PKT_TAG_SHIFT 6
-#define _NETIO_PKT_TAG_RMASK 0x3
-#define _NETIO_PKT_TAG_MASK \
- (_NETIO_PKT_TAG_RMASK << _NETIO_PKT_TAG_SHIFT)
-#define _NETIO_PKT_TAG_NONE 0 /* No proprietary tags. */
-#define _NETIO_PKT_TAG_MRVL 1 /* Marvell HyperG.Stack tags. */
-#define _NETIO_PKT_TAG_MRVL_EXT 2 /* HyperG.Stack extended tags. */
-#define _NETIO_PKT_TAG_BRCM 3 /* Broadcom HiGig tags. */
-
-/** Whether a packet has an LLC + SNAP header. */
-#define _NETIO_PKT_SNAP_SHIFT 8
-#define _NETIO_PKT_SNAP_RMASK 0x1
-#define _NETIO_PKT_SNAP_MASK \
- (_NETIO_PKT_SNAP_RMASK << _NETIO_PKT_SNAP_SHIFT)
-
-/* NOTE: Bits 9 and 10 are unused. */
-
-/** Length of any custom data before the L2 header, in words. */
-#define _NETIO_PKT_CUSTOM_LEN_SHIFT 11
-#define _NETIO_PKT_CUSTOM_LEN_RMASK 0x1F
-#define _NETIO_PKT_CUSTOM_LEN_MASK \
- (_NETIO_PKT_CUSTOM_LEN_RMASK << _NETIO_PKT_CUSTOM_LEN_SHIFT)
-
-/** The L4 checksum is incorrect (or perhaps has not been calculated). */
-#define _NETIO_PKT_BAD_L4_CSUM_SHIFT 16
-#define _NETIO_PKT_BAD_L4_CSUM_RMASK 0x1
-#define _NETIO_PKT_BAD_L4_CSUM_MASK \
- (_NETIO_PKT_BAD_L4_CSUM_RMASK << _NETIO_PKT_BAD_L4_CSUM_SHIFT)
-
-/** Length of the L2 header, in words. */
-#define _NETIO_PKT_L2_LEN_SHIFT 17
-#define _NETIO_PKT_L2_LEN_RMASK 0x1F
-#define _NETIO_PKT_L2_LEN_MASK \
- (_NETIO_PKT_L2_LEN_RMASK << _NETIO_PKT_L2_LEN_SHIFT)
-
-
-/* Flags in minimal packet metadata. */
-
-/** We need an eDMA checksum on this packet. */
-#define _NETIO_PKT_NEED_EDMA_CSUM_SHIFT 0
-#define _NETIO_PKT_NEED_EDMA_CSUM_RMASK 1
-#define _NETIO_PKT_NEED_EDMA_CSUM_MASK \
- (_NETIO_PKT_NEED_EDMA_CSUM_RMASK << _NETIO_PKT_NEED_EDMA_CSUM_SHIFT)
-
-/* Data within the packet information table. */
-
-/* Note that, for efficiency, code which uses these fields assumes that none
- * of the shift values below are zero. See uses below for an explanation. */
-
-/** Offset within the L2 header of the innermost ethertype (in halfwords). */
-#define _NETIO_PKT_INFO_ETYPE_SHIFT 6
-#define _NETIO_PKT_INFO_ETYPE_RMASK 0x1F
-
-/** Offset within the L2 header of the VLAN tag (in halfwords). */
-#define _NETIO_PKT_INFO_VLAN_SHIFT 11
-#define _NETIO_PKT_INFO_VLAN_RMASK 0x1F
-
-#endif
-
-
-/** The size of a memory buffer representing a small packet.
- * @ingroup egress */
-#define SMALL_PACKET_SIZE 256
-
-/** The size of a memory buffer representing a large packet.
- * @ingroup egress */
-#define LARGE_PACKET_SIZE 2048
-
-/** The size of a memory buffer representing a jumbo packet.
- * @ingroup egress */
-#define JUMBO_PACKET_SIZE (12 * 1024)
-
-
-/* Common ethertypes.
- * @ingroup ingress */
-/** @{ */
-/** The ethertype of IPv4. */
-#define ETHERTYPE_IPv4 (0x0800)
-/** The ethertype of ARP. */
-#define ETHERTYPE_ARP (0x0806)
-/** The ethertype of VLANs. */
-#define ETHERTYPE_VLAN (0x8100)
-/** The ethertype of a Q-in-Q header. */
-#define ETHERTYPE_Q_IN_Q (0x9100)
-/** The ethertype of IPv6. */
-#define ETHERTYPE_IPv6 (0x86DD)
-/** The ethertype of MPLS. */
-#define ETHERTYPE_MPLS (0x8847)
-/** @} */
-
-
-/** The possible return values of NETIO_PKT_STATUS.
- * @ingroup ingress
- */
-typedef enum
-{
- /** No problems were detected with this packet. */
- NETIO_PKT_STATUS_OK,
- /** The packet is undersized; this is expected behavior if the packet's
- * ethertype is unrecognized, but otherwise the packet is likely corrupt. */
- NETIO_PKT_STATUS_UNDERSIZE,
- /** The packet is oversized and some trailing bytes have been discarded.
- This is expected behavior for short packets, since it's impossible to
- precisely determine the amount of padding which may have been added to
- them to make them meet the minimum Ethernet packet size. */
- NETIO_PKT_STATUS_OVERSIZE,
- /** The packet was judged to be corrupt by hardware (for instance, it had
- a bad CRC, or part of it was discarded due to lack of buffer space in
- the I/O shim) and should be discarded. */
- NETIO_PKT_STATUS_BAD
-} netio_pkt_status_t;
-
-
-/** Log2 of how many buckets we have. */
-#define NETIO_LOG2_NUM_BUCKETS (10)
-
-/** How many buckets we have.
- * @ingroup ingress */
-#define NETIO_NUM_BUCKETS (1 << NETIO_LOG2_NUM_BUCKETS)
-
-
-/**
- * @brief A group-to-bucket identifier.
- *
- * @ingroup setup
- *
- * This tells us what to do with a given group.
- */
-typedef union {
- /** The header broken down into bits. */
- struct {
- /** Whether we should balance on L4, if available */
- unsigned int __balance_on_l4:1;
- /** Whether we should balance on L3, if available */
- unsigned int __balance_on_l3:1;
- /** Whether we should balance on L2, if available */
- unsigned int __balance_on_l2:1;
- /** Reserved for future use */
- unsigned int __reserved:1;
- /** The base bucket to use to send traffic */
- unsigned int __bucket_base:NETIO_LOG2_NUM_BUCKETS;
- /** The mask to apply to the balancing value. This must be one less
- * than a power of two, e.g. 0x3 or 0xFF.
- */
- unsigned int __bucket_mask:NETIO_LOG2_NUM_BUCKETS;
- /** Pad to 32 bits */
- unsigned int __padding:(32 - 4 - 2 * NETIO_LOG2_NUM_BUCKETS);
- } bits;
- /** To send out the IDN. */
- unsigned int word;
-}
-netio_group_t;
-
-
-/**
- * @brief A VLAN-to-bucket identifier.
- *
- * @ingroup setup
- *
- * This tells us what to do with a given VLAN.
- */
-typedef netio_group_t netio_vlan_t;
-
-
-/**
- * A bucket-to-queue mapping.
- * @ingroup setup
- */
-typedef unsigned char netio_bucket_t;
-
-
-/**
- * A packet size can always fit in a netio_size_t.
- * @ingroup setup
- */
-typedef unsigned int netio_size_t;
-
-
-/**
- * @brief Ethernet standard (ingress) packet metadata.
- *
- * @ingroup ingress
- *
- * This is additional data associated with each packet.
- * This structure is opaque and accessed through the @ref ingress.
- *
- * Also, the buffer population operation currently assumes that standard
- * metadata is at least as large as minimal metadata, and will need to be
- * modified if that is no longer the case.
- */
-typedef struct
-{
-#ifdef __DOXYGEN__
- /** This structure is opaque. */
- unsigned char opaque[24];
-#else
- /** The overall ordinal of the packet */
- unsigned int __packet_ordinal;
- /** The ordinal of the packet within the group */
- unsigned int __group_ordinal;
- /** The best flow hash IPP could compute. */
- unsigned int __flow_hash;
- /** Flags pertaining to checksum calculation, packet type, etc. */
- unsigned int __flags;
- /** The first word of "user data". */
- unsigned int __user_data_0;
- /** The second word of "user data". */
- unsigned int __user_data_1;
-#endif
-}
-netio_pkt_metadata_t;
-
-
-/** To ensure that the L3 header is aligned mod 4, the L2 header should be
- * aligned mod 4 plus 2, since every supported L2 header is 4n + 2 bytes
- * long. The standard way to do this is to simply add 2 bytes of padding
- * before the L2 header.
- */
-#define NETIO_PACKET_PADDING 2
-
-
-
-/**
- * @brief Ethernet minimal (egress) packet metadata.
- *
- * @ingroup egress
- *
- * This structure represents information about packets which have
- * been processed by @ref netio_populate_buffer() or
- * @ref netio_populate_prepend_buffer(). This structure is opaque
- * and accessed through the @ref egress.
- *
- * @internal This structure is actually copied into the memory used by
- * standard metadata, which is assumed to be large enough.
- */
-typedef struct
-{
-#ifdef __DOXYGEN__
- /** This structure is opaque. */
- unsigned char opaque[14];
-#else
- /** The offset of the L2 header from the start of the packet data. */
- unsigned short l2_offset;
- /** The offset of the L3 header from the start of the packet data. */
- unsigned short l3_offset;
- /** Where to write the checksum. */
- unsigned char csum_location;
- /** Where to start checksumming from. */
- unsigned char csum_start;
- /** Flags pertaining to checksum calculation etc. */
- unsigned short flags;
- /** The L2 length of the packet. */
- unsigned short l2_length;
- /** The checksum with which to seed the checksum generator. */
- unsigned short csum_seed;
- /** How much to checksum. */
- unsigned short csum_length;
-#endif
-}
-netio_pkt_minimal_metadata_t;
-
-
-#ifndef __DOXYGEN__
-
-/**
- * @brief An I/O notification header.
- *
- * This is the first word of data received from an I/O shim in a notification
- * packet. It contains framing and status information.
- */
-typedef union
-{
- unsigned int word; /**< The whole word. */
- /** The various fields. */
- struct
- {
- unsigned int __channel:7; /**< Resource channel. */
- unsigned int __type:4; /**< Type. */
- unsigned int __ack:1; /**< Whether an acknowledgement is needed. */
- unsigned int __reserved:1; /**< Reserved. */
- unsigned int __protocol:1; /**< A protocol-specific word is added. */
- unsigned int __status:2; /**< Status of the transfer. */
- unsigned int __framing:2; /**< Framing of the transfer. */
- unsigned int __transfer_size:14; /**< Transfer size in bytes (total). */
- } bits;
-}
-__netio_pkt_notif_t;
-
-
-/**
- * Returns the base address of the packet.
- */
-#define _NETIO_PKT_HANDLE_BASE(p) \
- ((unsigned char*)((p).word & 0xFFFFFFC0))
-
-/**
- * Returns the base address of the packet.
- */
-#define _NETIO_PKT_BASE(p) \
- _NETIO_PKT_HANDLE_BASE(p->__packet)
-
-/**
- * @brief An I/O notification packet (second word)
- *
- * This is the second word of data received from an I/O shim in a notification
- * packet. This is the virtual address of the packet buffer, plus some flag
- * bits. (The virtual address of the packet is always 256-byte aligned so we
- * have room for 8 bits' worth of flags in the low 8 bits.)
- *
- * @internal
- * NOTE: The low two bits must contain "__queue", so the "packet size"
- * (SIZE_SMALL, SIZE_LARGE, or SIZE_JUMBO) can be determined quickly.
- *
- * If __addr or __offset are moved, _NETIO_PKT_BASE
- * (defined right below this) must be changed.
- */
-typedef union
-{
- unsigned int word; /**< The whole word. */
- /** The various fields. */
- struct
- {
- /** Which queue the packet will be returned to once it is sent back to
- the IPP. This is one of the SIZE_xxx values. */
- unsigned int __queue:2;
-
- /** The IPP handle of the sending IPP. */
- unsigned int __ipp_handle:2;
-
- /** Reserved for future use. */
- unsigned int __reserved:1;
-
- /** If 1, this packet has minimal (egress) metadata; otherwise, it
- has standard (ingress) metadata. */
- unsigned int __minimal:1;
-
- /** Offset of the metadata within the packet. This value is multiplied
- * by 64 and added to the base packet address to get the metadata
- * address. Note that this field is aligned within the word such that
- * you can easily extract the metadata address with a 26-bit mask. */
- unsigned int __offset:2;
-
- /** The top 24 bits of the packet's virtual address. */
- unsigned int __addr:24;
- } bits;
-}
-__netio_pkt_handle_t;
-
-#endif /* !__DOXYGEN__ */
-
-
-/**
- * @brief A handle for an I/O packet's storage.
- * @ingroup ingress
- *
- * netio_pkt_handle_t encodes the concept of a ::netio_pkt_t with its
- * packet metadata removed. It is a much smaller type that exists to
- * facilitate applications where the full ::netio_pkt_t type is too
- * large, such as those that cache enormous numbers of packets or wish
- * to transmit packet descriptors over the UDN.
- *
- * Because there is no metadata, most ::netio_pkt_t operations cannot be
- * performed on a netio_pkt_handle_t. It supports only
- * netio_free_handle() (to free the buffer) and
- * NETIO_PKT_CUSTOM_DATA_H() (to access a pointer to its contents).
- * The application must acquire any additional metadata it wants from the
- * original ::netio_pkt_t and record it separately.
- *
- * A netio_pkt_handle_t can be extracted from a ::netio_pkt_t by calling
- * NETIO_PKT_HANDLE(). An invalid handle (analogous to NULL) can be
- * created by assigning the value ::NETIO_PKT_HANDLE_NONE. A handle can
- * be tested for validity with NETIO_PKT_HANDLE_IS_VALID().
- */
-typedef struct
-{
- unsigned int word; /**< Opaque bits. */
-} netio_pkt_handle_t;
-
-/**
- * @brief A packet descriptor.
- *
- * @ingroup ingress
- * @ingroup egress
- *
- * This data structure represents a packet. The structure is manipulated
- * through the @ref ingress and the @ref egress.
- *
- * While the contents of a netio_pkt_t are opaque, the structure itself is
- * portable. This means that it may be shared between all tiles which have
- * done a netio_input_register() call for the interface on which the pkt_t
- * was initially received (via netio_get_packet()) or retrieved (via
- * netio_get_buffer()). The contents of a netio_pkt_t can be transmitted to
- * another tile via shared memory, or via a UDN message, or by other means.
- * The destination tile may then use the pkt_t as if it had originally been
- * received locally; it may read or write the packet's data, read its
- * metadata, free the packet, send the packet, transfer the netio_pkt_t to
- * yet another tile, and so forth.
- *
- * Once a netio_pkt_t has been transferred to a second tile, the first tile
- * should not reference the original copy; in particular, if more than one
- * tile frees or sends the same netio_pkt_t, the IPP's packet free lists will
- * become corrupted. Note also that each tile which reads or modifies
- * packet data must obey the memory coherency rules outlined in @ref input.
- */
-typedef struct
-{
-#ifdef __DOXYGEN__
- /** This structure is opaque. */
- unsigned char opaque[32];
-#else
- /** For an ingress packet (one with standard metadata), this is the
- * notification header we got from the I/O shim. For an egress packet
- * (one with minimal metadata), this word is zero if the packet has not
- * been populated, and nonzero if it has. */
- __netio_pkt_notif_t __notif_header;
-
- /** Virtual address of the packet buffer, plus state flags. */
- __netio_pkt_handle_t __packet;
-
- /** Metadata associated with the packet. */
- netio_pkt_metadata_t __metadata;
-#endif
-}
-netio_pkt_t;
-
-
-#ifndef __DOXYGEN__
-
-#define __NETIO_PKT_NOTIF_HEADER(pkt) ((pkt)->__notif_header)
-#define __NETIO_PKT_IPP_HANDLE(pkt) ((pkt)->__packet.bits.__ipp_handle)
-#define __NETIO_PKT_QUEUE(pkt) ((pkt)->__packet.bits.__queue)
-#define __NETIO_PKT_NOTIF_HEADER_M(mda, pkt) ((pkt)->__notif_header)
-#define __NETIO_PKT_IPP_HANDLE_M(mda, pkt) ((pkt)->__packet.bits.__ipp_handle)
-#define __NETIO_PKT_MINIMAL(pkt) ((pkt)->__packet.bits.__minimal)
-#define __NETIO_PKT_QUEUE_M(mda, pkt) ((pkt)->__packet.bits.__queue)
-#define __NETIO_PKT_FLAGS_M(mda, pkt) ((mda)->__flags)
-
-/* Packet information table, used by the attribute access functions below. */
-extern const uint16_t _netio_pkt_info[];
-
-#endif /* __DOXYGEN__ */
-
-
-#ifndef __DOXYGEN__
-/* These macros are deprecated and will disappear in a future MDE release. */
-#define NETIO_PKT_GOOD_CHECKSUM(pkt) \
- NETIO_PKT_L4_CSUM_CORRECT(pkt)
-#define NETIO_PKT_GOOD_CHECKSUM_M(mda, pkt) \
- NETIO_PKT_L4_CSUM_CORRECT_M(mda, pkt)
-#endif /* __DOXYGEN__ */
-
-
-/* Packet attribute access functions. */
-
-/** Return a pointer to the metadata for a packet.
- * @ingroup ingress
- *
- * Calling this function once and passing the result to other retrieval
- * functions with a "_M" suffix usually improves performance. This
- * function must be called on an 'ingress' packet (i.e. one retrieved
- * by @ref netio_get_packet(), on which @ref netio_populate_buffer() or
- * @ref netio_populate_prepend_buffer have not been called). Use of this
- * function on an 'egress' packet will cause an assertion failure.
- *
- * @param[in] pkt Packet on which to operate.
- * @return A pointer to the packet's standard metadata.
- */
-static __inline netio_pkt_metadata_t*
-NETIO_PKT_METADATA(netio_pkt_t* pkt)
-{
- netio_assert(!pkt->__packet.bits.__minimal);
- return &pkt->__metadata;
-}
-
-
-/** Return a pointer to the minimal metadata for a packet.
- * @ingroup egress
- *
- * Calling this function once and passing the result to other retrieval
- * functions with a "_MM" suffix usually improves performance. This
- * function must be called on an 'egress' packet (i.e. one on which
- * @ref netio_populate_buffer() or @ref netio_populate_prepend_buffer()
- * have been called, or one retrieved by @ref netio_get_buffer()). Use of
- * this function on an 'ingress' packet will cause an assertion failure.
- *
- * @param[in] pkt Packet on which to operate.
- * @return A pointer to the packet's standard metadata.
- */
-static __inline netio_pkt_minimal_metadata_t*
-NETIO_PKT_MINIMAL_METADATA(netio_pkt_t* pkt)
-{
- netio_assert(pkt->__packet.bits.__minimal);
- return (netio_pkt_minimal_metadata_t*) &pkt->__metadata;
-}
-
-
-/** Determine whether a packet has 'minimal' metadata.
- * @ingroup pktfuncs
- *
- * This function will return nonzero if the packet is an 'egress'
- * packet (i.e. one on which @ref netio_populate_buffer() or
- * @ref netio_populate_prepend_buffer() have been called, or one
- * retrieved by @ref netio_get_buffer()), and zero if the packet
- * is an 'ingress' packet (i.e. one retrieved by @ref netio_get_packet(),
- * which has not been converted into an 'egress' packet).
- *
- * @param[in] pkt Packet on which to operate.
- * @return Nonzero if the packet has minimal metadata.
- */
-static __inline unsigned int
-NETIO_PKT_IS_MINIMAL(netio_pkt_t* pkt)
-{
- return pkt->__packet.bits.__minimal;
-}
-
-
-/** Return a handle for a packet's storage.
- * @ingroup pktfuncs
- *
- * @param[in] pkt Packet on which to operate.
- * @return A handle for the packet's storage.
- */
-static __inline netio_pkt_handle_t
-NETIO_PKT_HANDLE(netio_pkt_t* pkt)
-{
- netio_pkt_handle_t h;
- h.word = pkt->__packet.word;
- return h;
-}
-
-
-/** A special reserved value indicating the absence of a packet handle.
- *
- * @ingroup pktfuncs
- */
-#define NETIO_PKT_HANDLE_NONE ((netio_pkt_handle_t) { 0 })
-
-
-/** Test whether a packet handle is valid.
- *
- * Applications may wish to use the reserved value NETIO_PKT_HANDLE_NONE
- * to indicate no packet at all. This function tests to see if a packet
- * handle is a real handle, not this special reserved value.
- *
- * @ingroup pktfuncs
- *
- * @param[in] handle Handle on which to operate.
- * @return One if the packet handle is valid, else zero.
- */
-static __inline unsigned int
-NETIO_PKT_HANDLE_IS_VALID(netio_pkt_handle_t handle)
-{
- return handle.word != 0;
-}
-
-
-
-/** Return a pointer to the start of the packet's custom header.
- * A custom header may or may not be present, depending upon the IPP; its
- * contents and alignment are also IPP-dependent. Currently, none of the
- * standard IPPs supplied by Tilera produce a custom header. If present,
- * the custom header precedes the L2 header in the packet buffer.
- * @ingroup ingress
- *
- * @param[in] handle Handle on which to operate.
- * @return A pointer to start of the packet.
- */
-static __inline unsigned char*
-NETIO_PKT_CUSTOM_DATA_H(netio_pkt_handle_t handle)
-{
- return _NETIO_PKT_HANDLE_BASE(handle) + NETIO_PACKET_PADDING;
-}
-
-
-/** Return the length of the packet's custom header.
- * A custom header may or may not be present, depending upon the IPP; its
- * contents and alignment are also IPP-dependent. Currently, none of the
- * standard IPPs supplied by Tilera produce a custom header. If present,
- * the custom header precedes the L2 header in the packet buffer.
- *
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return The length of the packet's custom header, in bytes.
- */
-static __inline netio_size_t
-NETIO_PKT_CUSTOM_HEADER_LENGTH_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- /*
- * Note that we effectively need to extract a quantity from the flags word
- * which is measured in words, and then turn it into bytes by shifting
- * it left by 2. We do this all at once by just shifting right two less
- * bits, and shifting the mask up two bits.
- */
- return ((mda->__flags >> (_NETIO_PKT_CUSTOM_LEN_SHIFT - 2)) &
- (_NETIO_PKT_CUSTOM_LEN_RMASK << 2));
-}
-
-
-/** Return the length of the packet, starting with the custom header.
- * A custom header may or may not be present, depending upon the IPP; its
- * contents and alignment are also IPP-dependent. Currently, none of the
- * standard IPPs supplied by Tilera produce a custom header. If present,
- * the custom header precedes the L2 header in the packet buffer.
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return The length of the packet, in bytes.
- */
-static __inline netio_size_t
-NETIO_PKT_CUSTOM_LENGTH_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return (__NETIO_PKT_NOTIF_HEADER(pkt).bits.__transfer_size -
- NETIO_PACKET_PADDING);
-}
-
-
-/** Return a pointer to the start of the packet's custom header.
- * A custom header may or may not be present, depending upon the IPP; its
- * contents and alignment are also IPP-dependent. Currently, none of the
- * standard IPPs supplied by Tilera produce a custom header. If present,
- * the custom header precedes the L2 header in the packet buffer.
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return A pointer to start of the packet.
- */
-static __inline unsigned char*
-NETIO_PKT_CUSTOM_DATA_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return NETIO_PKT_CUSTOM_DATA_H(NETIO_PKT_HANDLE(pkt));
-}
-
-
-/** Return the length of the packet's L2 (Ethernet plus VLAN or SNAP) header.
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return The length of the packet's L2 header, in bytes.
- */
-static __inline netio_size_t
-NETIO_PKT_L2_HEADER_LENGTH_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- /*
- * Note that we effectively need to extract a quantity from the flags word
- * which is measured in words, and then turn it into bytes by shifting
- * it left by 2. We do this all at once by just shifting right two less
- * bits, and shifting the mask up two bits. We then add two bytes.
- */
- return ((mda->__flags >> (_NETIO_PKT_L2_LEN_SHIFT - 2)) &
- (_NETIO_PKT_L2_LEN_RMASK << 2)) + 2;
-}
-
-
-/** Return the length of the packet, starting with the L2 (Ethernet) header.
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return The length of the packet, in bytes.
- */
-static __inline netio_size_t
-NETIO_PKT_L2_LENGTH_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return (NETIO_PKT_CUSTOM_LENGTH_M(mda, pkt) -
- NETIO_PKT_CUSTOM_HEADER_LENGTH_M(mda,pkt));
-}
-
-
-/** Return a pointer to the start of the packet's L2 (Ethernet) header.
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return A pointer to start of the packet.
- */
-static __inline unsigned char*
-NETIO_PKT_L2_DATA_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return (NETIO_PKT_CUSTOM_DATA_M(mda, pkt) +
- NETIO_PKT_CUSTOM_HEADER_LENGTH_M(mda, pkt));
-}
-
-
-/** Retrieve the length of the packet, starting with the L3 (generally,
- * the IP) header.
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return Length of the packet's L3 header and data, in bytes.
- */
-static __inline netio_size_t
-NETIO_PKT_L3_LENGTH_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return (NETIO_PKT_L2_LENGTH_M(mda, pkt) -
- NETIO_PKT_L2_HEADER_LENGTH_M(mda,pkt));
-}
-
-
-/** Return a pointer to the packet's L3 (generally, the IP) header.
- * @ingroup ingress
- *
- * Note that we guarantee word alignment of the L3 header.
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return A pointer to the packet's L3 header.
- */
-static __inline unsigned char*
-NETIO_PKT_L3_DATA_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return (NETIO_PKT_L2_DATA_M(mda, pkt) +
- NETIO_PKT_L2_HEADER_LENGTH_M(mda, pkt));
-}
-
-
-/** Return the ordinal of the packet.
- * @ingroup ingress
- *
- * Each packet is given an ordinal number when it is delivered by the IPP.
- * In the medium term, the ordinal is unique and monotonically increasing,
- * being incremented by 1 for each packet; the ordinal of the first packet
- * delivered after the IPP starts is zero. (Since the ordinal is of finite
- * size, given enough input packets, it will eventually wrap around to zero;
- * in the long term, therefore, ordinals are not unique.) The ordinals
- * handed out by different IPPs are not disjoint, so two packets from
- * different IPPs may have identical ordinals. Packets dropped by the
- * IPP or by the I/O shim are not assigned ordinals.
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return The packet's per-IPP packet ordinal.
- */
-static __inline unsigned int
-NETIO_PKT_ORDINAL_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return mda->__packet_ordinal;
-}
-
-
-/** Return the per-group ordinal of the packet.
- * @ingroup ingress
- *
- * Each packet is given a per-group ordinal number when it is
- * delivered by the IPP. By default, the group is the packet's VLAN,
- * although IPP can be recompiled to use different values. In
- * the medium term, the ordinal is unique and monotonically
- * increasing, being incremented by 1 for each packet; the ordinal of
- * the first packet distributed to a particular group is zero.
- * (Since the ordinal is of finite size, given enough input packets,
- * it will eventually wrap around to zero; in the long term,
- * therefore, ordinals are not unique.) The ordinals handed out by
- * different IPPs are not disjoint, so two packets from different IPPs
- * may have identical ordinals; similarly, packets distributed to
- * different groups may have identical ordinals. Packets dropped by
- * the IPP or by the I/O shim are not assigned ordinals.
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return The packet's per-IPP, per-group ordinal.
- */
-static __inline unsigned int
-NETIO_PKT_GROUP_ORDINAL_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return mda->__group_ordinal;
-}
-
-
-/** Return the VLAN ID assigned to the packet.
- * @ingroup ingress
- *
- * This value is usually contained within the packet header.
- *
- * This value will be zero if the packet does not have a VLAN tag, or if
- * this value was not extracted from the packet.
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return The packet's VLAN ID.
- */
-static __inline unsigned short
-NETIO_PKT_VLAN_ID_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- int vl = (mda->__flags >> _NETIO_PKT_VLAN_SHIFT) & _NETIO_PKT_VLAN_RMASK;
- unsigned short* pkt_p;
- int index;
- unsigned short val;
-
- if (vl == _NETIO_PKT_VLAN_NONE)
- return 0;
-
- pkt_p = (unsigned short*) NETIO_PKT_L2_DATA_M(mda, pkt);
- index = (mda->__flags >> _NETIO_PKT_TYPE_SHIFT) & _NETIO_PKT_TYPE_RMASK;
-
- val = pkt_p[(_netio_pkt_info[index] >> _NETIO_PKT_INFO_VLAN_SHIFT) &
- _NETIO_PKT_INFO_VLAN_RMASK];
-
-#ifdef __TILECC__
- return (__insn_bytex(val) >> 16) & 0xFFF;
-#else
- return (__builtin_bswap32(val) >> 16) & 0xFFF;
-#endif
-}
-
-
-/** Return the ethertype of the packet.
- * @ingroup ingress
- *
- * This value is usually contained within the packet header.
- *
- * This value is reliable if @ref NETIO_PKT_ETHERTYPE_RECOGNIZED_M()
- * returns true, and otherwise, may not be well defined.
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return The packet's ethertype.
- */
-static __inline unsigned short
-NETIO_PKT_ETHERTYPE_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- unsigned short* pkt_p = (unsigned short*) NETIO_PKT_L2_DATA_M(mda, pkt);
- int index = (mda->__flags >> _NETIO_PKT_TYPE_SHIFT) & _NETIO_PKT_TYPE_RMASK;
-
- unsigned short val =
- pkt_p[(_netio_pkt_info[index] >> _NETIO_PKT_INFO_ETYPE_SHIFT) &
- _NETIO_PKT_INFO_ETYPE_RMASK];
-
- return __builtin_bswap32(val) >> 16;
-}
-
-
-/** Return the flow hash computed on the packet.
- * @ingroup ingress
- *
- * For TCP and UDP packets, this hash is calculated by hashing together
- * the "5-tuple" values, specifically the source IP address, destination
- * IP address, protocol type, source port and destination port.
- * The hash value is intended to be helpful for millions of distinct
- * flows.
- *
- * For IPv4 or IPv6 packets which are neither TCP nor UDP, the flow hash is
- * derived by hashing together the source and destination IP addresses.
- *
- * For MPLS-encapsulated packets, the flow hash is derived by hashing
- * the first MPLS label.
- *
- * For all other packets the flow hash is computed from the source
- * and destination Ethernet addresses.
- *
- * The hash is symmetric, meaning it produces the same value if the
- * source and destination are swapped. The only exceptions are
- * tunneling protocols 0x04 (IP in IP Encapsulation), 0x29 (Simple
- * Internet Protocol), 0x2F (General Routing Encapsulation) and 0x32
- * (Encap Security Payload), which use only the destination address
- * since the source address is not meaningful.
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return The packet's 32-bit flow hash.
- */
-static __inline unsigned int
-NETIO_PKT_FLOW_HASH_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return mda->__flow_hash;
-}
-
-
-/** Return the first word of "user data" for the packet.
- *
- * The contents of the user data words depend on the IPP.
- *
- * When using the standard ipp1, ipp2, or ipp4 sub-drivers, the first
- * word of user data contains the least significant bits of the 64-bit
- * arrival cycle count (see @c get_cycle_count_low()).
- *
- * See the <em>System Programmer's Guide</em> for details.
- *
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return The packet's first word of "user data".
- */
-static __inline unsigned int
-NETIO_PKT_USER_DATA_0_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return mda->__user_data_0;
-}
-
-
-/** Return the second word of "user data" for the packet.
- *
- * The contents of the user data words depend on the IPP.
- *
- * When using the standard ipp1, ipp2, or ipp4 sub-drivers, the second
- * word of user data contains the most significant bits of the 64-bit
- * arrival cycle count (see @c get_cycle_count_high()).
- *
- * See the <em>System Programmer's Guide</em> for details.
- *
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return The packet's second word of "user data".
- */
-static __inline unsigned int
-NETIO_PKT_USER_DATA_1_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return mda->__user_data_1;
-}
-
-
-/** Determine whether the L4 (TCP/UDP) checksum was calculated.
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return Nonzero if the L4 checksum was calculated.
- */
-static __inline unsigned int
-NETIO_PKT_L4_CSUM_CALCULATED_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return !(mda->__flags & _NETIO_PKT_NO_L4_CSUM_MASK);
-}
-
-
-/** Determine whether the L4 (TCP/UDP) checksum was calculated and found to
- * be correct.
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return Nonzero if the checksum was calculated and is correct.
- */
-static __inline unsigned int
-NETIO_PKT_L4_CSUM_CORRECT_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return !(mda->__flags &
- (_NETIO_PKT_BAD_L4_CSUM_MASK | _NETIO_PKT_NO_L4_CSUM_MASK));
-}
-
-
-/** Determine whether the L3 (IP) checksum was calculated.
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return Nonzero if the L3 (IP) checksum was calculated.
-*/
-static __inline unsigned int
-NETIO_PKT_L3_CSUM_CALCULATED_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return !(mda->__flags & _NETIO_PKT_NO_L3_CSUM_MASK);
-}
-
-
-/** Determine whether the L3 (IP) checksum was calculated and found to be
- * correct.
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return Nonzero if the checksum was calculated and is correct.
- */
-static __inline unsigned int
-NETIO_PKT_L3_CSUM_CORRECT_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return !(mda->__flags &
- (_NETIO_PKT_BAD_L3_CSUM_MASK | _NETIO_PKT_NO_L3_CSUM_MASK));
-}
-
-
-/** Determine whether the ethertype was recognized and L3 packet data was
- * processed.
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return Nonzero if the ethertype was recognized and L3 packet data was
- * processed.
- */
-static __inline unsigned int
-NETIO_PKT_ETHERTYPE_RECOGNIZED_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return !(mda->__flags & _NETIO_PKT_TYPE_UNRECOGNIZED_MASK);
-}
-
-
-/** Retrieve the status of a packet and any errors that may have occurred
- * during ingress processing (length mismatches, CRC errors, etc.).
- * @ingroup ingress
- *
- * Note that packets for which @ref NETIO_PKT_ETHERTYPE_RECOGNIZED()
- * returns zero are always reported as underlength, as there is no a priori
- * means to determine their length. Normally, applications should use
- * @ref NETIO_PKT_BAD_M() instead of explicitly checking status with this
- * function.
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return The packet's status.
- */
-static __inline netio_pkt_status_t
-NETIO_PKT_STATUS_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return (netio_pkt_status_t) __NETIO_PKT_NOTIF_HEADER(pkt).bits.__status;
-}
-
-
-/** Report whether a packet is bad (i.e., was shorter than expected based on
- * its headers, or had a bad CRC).
- * @ingroup ingress
- *
- * Note that this function does not verify L3 or L4 checksums.
- *
- * @param[in] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- * @return Nonzero if the packet is bad and should be discarded.
- */
-static __inline unsigned int
-NETIO_PKT_BAD_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return ((NETIO_PKT_STATUS_M(mda, pkt) & 1) &&
- (NETIO_PKT_ETHERTYPE_RECOGNIZED_M(mda, pkt) ||
- NETIO_PKT_STATUS_M(mda, pkt) == NETIO_PKT_STATUS_BAD));
-}
-
-
-/** Return the length of the packet, starting with the L2 (Ethernet) header.
- * @ingroup egress
- *
- * @param[in] mmd Pointer to packet's minimal metadata.
- * @param[in] pkt Packet on which to operate.
- * @return The length of the packet, in bytes.
- */
-static __inline netio_size_t
-NETIO_PKT_L2_LENGTH_MM(netio_pkt_minimal_metadata_t* mmd, netio_pkt_t* pkt)
-{
- return mmd->l2_length;
-}
-
-
-/** Return the length of the L2 (Ethernet) header.
- * @ingroup egress
- *
- * @param[in] mmd Pointer to packet's minimal metadata.
- * @param[in] pkt Packet on which to operate.
- * @return The length of the packet's L2 header, in bytes.
- */
-static __inline netio_size_t
-NETIO_PKT_L2_HEADER_LENGTH_MM(netio_pkt_minimal_metadata_t* mmd,
- netio_pkt_t* pkt)
-{
- return mmd->l3_offset - mmd->l2_offset;
-}
-
-
-/** Return the length of the packet, starting with the L3 (IP) header.
- * @ingroup egress
- *
- * @param[in] mmd Pointer to packet's minimal metadata.
- * @param[in] pkt Packet on which to operate.
- * @return Length of the packet's L3 header and data, in bytes.
- */
-static __inline netio_size_t
-NETIO_PKT_L3_LENGTH_MM(netio_pkt_minimal_metadata_t* mmd, netio_pkt_t* pkt)
-{
- return (NETIO_PKT_L2_LENGTH_MM(mmd, pkt) -
- NETIO_PKT_L2_HEADER_LENGTH_MM(mmd, pkt));
-}
-
-
-/** Return a pointer to the packet's L3 (generally, the IP) header.
- * @ingroup egress
- *
- * Note that we guarantee word alignment of the L3 header.
- *
- * @param[in] mmd Pointer to packet's minimal metadata.
- * @param[in] pkt Packet on which to operate.
- * @return A pointer to the packet's L3 header.
- */
-static __inline unsigned char*
-NETIO_PKT_L3_DATA_MM(netio_pkt_minimal_metadata_t* mmd, netio_pkt_t* pkt)
-{
- return _NETIO_PKT_BASE(pkt) + mmd->l3_offset;
-}
-
-
-/** Return a pointer to the packet's L2 (Ethernet) header.
- * @ingroup egress
- *
- * @param[in] mmd Pointer to packet's minimal metadata.
- * @param[in] pkt Packet on which to operate.
- * @return A pointer to start of the packet.
- */
-static __inline unsigned char*
-NETIO_PKT_L2_DATA_MM(netio_pkt_minimal_metadata_t* mmd, netio_pkt_t* pkt)
-{
- return _NETIO_PKT_BASE(pkt) + mmd->l2_offset;
-}
-
-
-/** Retrieve the status of a packet and any errors that may have occurred
- * during ingress processing (length mismatches, CRC errors, etc.).
- * @ingroup ingress
- *
- * Note that packets for which @ref NETIO_PKT_ETHERTYPE_RECOGNIZED()
- * returns zero are always reported as underlength, as there is no a priori
- * means to determine their length. Normally, applications should use
- * @ref NETIO_PKT_BAD() instead of explicitly checking status with this
- * function.
- *
- * @param[in] pkt Packet on which to operate.
- * @return The packet's status.
- */
-static __inline netio_pkt_status_t
-NETIO_PKT_STATUS(netio_pkt_t* pkt)
-{
- netio_assert(!pkt->__packet.bits.__minimal);
-
- return (netio_pkt_status_t) __NETIO_PKT_NOTIF_HEADER(pkt).bits.__status;
-}
-
-
-/** Report whether a packet is bad (i.e., was shorter than expected based on
- * its headers, or had a bad CRC).
- * @ingroup ingress
- *
- * Note that this function does not verify L3 or L4 checksums.
- *
- * @param[in] pkt Packet on which to operate.
- * @return Nonzero if the packet is bad and should be discarded.
- */
-static __inline unsigned int
-NETIO_PKT_BAD(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_BAD_M(mda, pkt);
-}
-
-
-/** Return the length of the packet's custom header.
- * A custom header may or may not be present, depending upon the IPP; its
- * contents and alignment are also IPP-dependent. Currently, none of the
- * standard IPPs supplied by Tilera produce a custom header. If present,
- * the custom header precedes the L2 header in the packet buffer.
- * @ingroup pktfuncs
- *
- * @param[in] pkt Packet on which to operate.
- * @return The length of the packet's custom header, in bytes.
- */
-static __inline netio_size_t
-NETIO_PKT_CUSTOM_HEADER_LENGTH(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_CUSTOM_HEADER_LENGTH_M(mda, pkt);
-}
-
-
-/** Return the length of the packet, starting with the custom header.
- * A custom header may or may not be present, depending upon the IPP; its
- * contents and alignment are also IPP-dependent. Currently, none of the
- * standard IPPs supplied by Tilera produce a custom header. If present,
- * the custom header precedes the L2 header in the packet buffer.
- * @ingroup pktfuncs
- *
- * @param[in] pkt Packet on which to operate.
- * @return The length of the packet, in bytes.
- */
-static __inline netio_size_t
-NETIO_PKT_CUSTOM_LENGTH(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_CUSTOM_LENGTH_M(mda, pkt);
-}
-
-
-/** Return a pointer to the packet's custom header.
- * A custom header may or may not be present, depending upon the IPP; its
- * contents and alignment are also IPP-dependent. Currently, none of the
- * standard IPPs supplied by Tilera produce a custom header. If present,
- * the custom header precedes the L2 header in the packet buffer.
- * @ingroup pktfuncs
- *
- * @param[in] pkt Packet on which to operate.
- * @return A pointer to start of the packet.
- */
-static __inline unsigned char*
-NETIO_PKT_CUSTOM_DATA(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_CUSTOM_DATA_M(mda, pkt);
-}
-
-
-/** Return the length of the packet's L2 (Ethernet plus VLAN or SNAP) header.
- * @ingroup pktfuncs
- *
- * @param[in] pkt Packet on which to operate.
- * @return The length of the packet's L2 header, in bytes.
- */
-static __inline netio_size_t
-NETIO_PKT_L2_HEADER_LENGTH(netio_pkt_t* pkt)
-{
- if (NETIO_PKT_IS_MINIMAL(pkt))
- {
- netio_pkt_minimal_metadata_t* mmd = NETIO_PKT_MINIMAL_METADATA(pkt);
-
- return NETIO_PKT_L2_HEADER_LENGTH_MM(mmd, pkt);
- }
- else
- {
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_L2_HEADER_LENGTH_M(mda, pkt);
- }
-}
-
-
-/** Return the length of the packet, starting with the L2 (Ethernet) header.
- * @ingroup pktfuncs
- *
- * @param[in] pkt Packet on which to operate.
- * @return The length of the packet, in bytes.
- */
-static __inline netio_size_t
-NETIO_PKT_L2_LENGTH(netio_pkt_t* pkt)
-{
- if (NETIO_PKT_IS_MINIMAL(pkt))
- {
- netio_pkt_minimal_metadata_t* mmd = NETIO_PKT_MINIMAL_METADATA(pkt);
-
- return NETIO_PKT_L2_LENGTH_MM(mmd, pkt);
- }
- else
- {
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_L2_LENGTH_M(mda, pkt);
- }
-}
-
-
-/** Return a pointer to the packet's L2 (Ethernet) header.
- * @ingroup pktfuncs
- *
- * @param[in] pkt Packet on which to operate.
- * @return A pointer to start of the packet.
- */
-static __inline unsigned char*
-NETIO_PKT_L2_DATA(netio_pkt_t* pkt)
-{
- if (NETIO_PKT_IS_MINIMAL(pkt))
- {
- netio_pkt_minimal_metadata_t* mmd = NETIO_PKT_MINIMAL_METADATA(pkt);
-
- return NETIO_PKT_L2_DATA_MM(mmd, pkt);
- }
- else
- {
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_L2_DATA_M(mda, pkt);
- }
-}
-
-
-/** Retrieve the length of the packet, starting with the L3 (generally, the IP)
- * header.
- * @ingroup pktfuncs
- *
- * @param[in] pkt Packet on which to operate.
- * @return Length of the packet's L3 header and data, in bytes.
- */
-static __inline netio_size_t
-NETIO_PKT_L3_LENGTH(netio_pkt_t* pkt)
-{
- if (NETIO_PKT_IS_MINIMAL(pkt))
- {
- netio_pkt_minimal_metadata_t* mmd = NETIO_PKT_MINIMAL_METADATA(pkt);
-
- return NETIO_PKT_L3_LENGTH_MM(mmd, pkt);
- }
- else
- {
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_L3_LENGTH_M(mda, pkt);
- }
-}
-
-
-/** Return a pointer to the packet's L3 (generally, the IP) header.
- * @ingroup pktfuncs
- *
- * Note that we guarantee word alignment of the L3 header.
- *
- * @param[in] pkt Packet on which to operate.
- * @return A pointer to the packet's L3 header.
- */
-static __inline unsigned char*
-NETIO_PKT_L3_DATA(netio_pkt_t* pkt)
-{
- if (NETIO_PKT_IS_MINIMAL(pkt))
- {
- netio_pkt_minimal_metadata_t* mmd = NETIO_PKT_MINIMAL_METADATA(pkt);
-
- return NETIO_PKT_L3_DATA_MM(mmd, pkt);
- }
- else
- {
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_L3_DATA_M(mda, pkt);
- }
-}
-
-
-/** Return the ordinal of the packet.
- * @ingroup ingress
- *
- * Each packet is given an ordinal number when it is delivered by the IPP.
- * In the medium term, the ordinal is unique and monotonically increasing,
- * being incremented by 1 for each packet; the ordinal of the first packet
- * delivered after the IPP starts is zero. (Since the ordinal is of finite
- * size, given enough input packets, it will eventually wrap around to zero;
- * in the long term, therefore, ordinals are not unique.) The ordinals
- * handed out by different IPPs are not disjoint, so two packets from
- * different IPPs may have identical ordinals. Packets dropped by the
- * IPP or by the I/O shim are not assigned ordinals.
- *
- *
- * @param[in] pkt Packet on which to operate.
- * @return The packet's per-IPP packet ordinal.
- */
-static __inline unsigned int
-NETIO_PKT_ORDINAL(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_ORDINAL_M(mda, pkt);
-}
-
-
-/** Return the per-group ordinal of the packet.
- * @ingroup ingress
- *
- * Each packet is given a per-group ordinal number when it is
- * delivered by the IPP. By default, the group is the packet's VLAN,
- * although IPP can be recompiled to use different values. In
- * the medium term, the ordinal is unique and monotonically
- * increasing, being incremented by 1 for each packet; the ordinal of
- * the first packet distributed to a particular group is zero.
- * (Since the ordinal is of finite size, given enough input packets,
- * it will eventually wrap around to zero; in the long term,
- * therefore, ordinals are not unique.) The ordinals handed out by
- * different IPPs are not disjoint, so two packets from different IPPs
- * may have identical ordinals; similarly, packets distributed to
- * different groups may have identical ordinals. Packets dropped by
- * the IPP or by the I/O shim are not assigned ordinals.
- *
- * @param[in] pkt Packet on which to operate.
- * @return The packet's per-IPP, per-group ordinal.
- */
-static __inline unsigned int
-NETIO_PKT_GROUP_ORDINAL(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_GROUP_ORDINAL_M(mda, pkt);
-}
-
-
-/** Return the VLAN ID assigned to the packet.
- * @ingroup ingress
- *
- * This is usually also contained within the packet header. If the packet
- * does not have a VLAN tag, the VLAN ID returned by this function is zero.
- *
- * @param[in] pkt Packet on which to operate.
- * @return The packet's VLAN ID.
- */
-static __inline unsigned short
-NETIO_PKT_VLAN_ID(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_VLAN_ID_M(mda, pkt);
-}
-
-
-/** Return the ethertype of the packet.
- * @ingroup ingress
- *
- * This value is reliable if @ref NETIO_PKT_ETHERTYPE_RECOGNIZED()
- * returns true, and otherwise, may not be well defined.
- *
- * @param[in] pkt Packet on which to operate.
- * @return The packet's ethertype.
- */
-static __inline unsigned short
-NETIO_PKT_ETHERTYPE(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_ETHERTYPE_M(mda, pkt);
-}
-
-
-/** Return the flow hash computed on the packet.
- * @ingroup ingress
- *
- * For TCP and UDP packets, this hash is calculated by hashing together
- * the "5-tuple" values, specifically the source IP address, destination
- * IP address, protocol type, source port and destination port.
- * The hash value is intended to be helpful for millions of distinct
- * flows.
- *
- * For IPv4 or IPv6 packets which are neither TCP nor UDP, the flow hash is
- * derived by hashing together the source and destination IP addresses.
- *
- * For MPLS-encapsulated packets, the flow hash is derived by hashing
- * the first MPLS label.
- *
- * For all other packets the flow hash is computed from the source
- * and destination Ethernet addresses.
- *
- * The hash is symmetric, meaning it produces the same value if the
- * source and destination are swapped. The only exceptions are
- * tunneling protocols 0x04 (IP in IP Encapsulation), 0x29 (Simple
- * Internet Protocol), 0x2F (General Routing Encapsulation) and 0x32
- * (Encap Security Payload), which use only the destination address
- * since the source address is not meaningful.
- *
- * @param[in] pkt Packet on which to operate.
- * @return The packet's 32-bit flow hash.
- */
-static __inline unsigned int
-NETIO_PKT_FLOW_HASH(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_FLOW_HASH_M(mda, pkt);
-}
-
-
-/** Return the first word of "user data" for the packet.
- *
- * The contents of the user data words depend on the IPP.
- *
- * When using the standard ipp1, ipp2, or ipp4 sub-drivers, the first
- * word of user data contains the least significant bits of the 64-bit
- * arrival cycle count (see @c get_cycle_count_low()).
- *
- * See the <em>System Programmer's Guide</em> for details.
- *
- * @ingroup ingress
- *
- * @param[in] pkt Packet on which to operate.
- * @return The packet's first word of "user data".
- */
-static __inline unsigned int
-NETIO_PKT_USER_DATA_0(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_USER_DATA_0_M(mda, pkt);
-}
-
-
-/** Return the second word of "user data" for the packet.
- *
- * The contents of the user data words depend on the IPP.
- *
- * When using the standard ipp1, ipp2, or ipp4 sub-drivers, the second
- * word of user data contains the most significant bits of the 64-bit
- * arrival cycle count (see @c get_cycle_count_high()).
- *
- * See the <em>System Programmer's Guide</em> for details.
- *
- * @ingroup ingress
- *
- * @param[in] pkt Packet on which to operate.
- * @return The packet's second word of "user data".
- */
-static __inline unsigned int
-NETIO_PKT_USER_DATA_1(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_USER_DATA_1_M(mda, pkt);
-}
-
-
-/** Determine whether the L4 (TCP/UDP) checksum was calculated.
- * @ingroup ingress
- *
- * @param[in] pkt Packet on which to operate.
- * @return Nonzero if the L4 checksum was calculated.
- */
-static __inline unsigned int
-NETIO_PKT_L4_CSUM_CALCULATED(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_L4_CSUM_CALCULATED_M(mda, pkt);
-}
-
-
-/** Determine whether the L4 (TCP/UDP) checksum was calculated and found to
- * be correct.
- * @ingroup ingress
- *
- * @param[in] pkt Packet on which to operate.
- * @return Nonzero if the checksum was calculated and is correct.
- */
-static __inline unsigned int
-NETIO_PKT_L4_CSUM_CORRECT(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_L4_CSUM_CORRECT_M(mda, pkt);
-}
-
-
-/** Determine whether the L3 (IP) checksum was calculated.
- * @ingroup ingress
- *
- * @param[in] pkt Packet on which to operate.
- * @return Nonzero if the L3 (IP) checksum was calculated.
-*/
-static __inline unsigned int
-NETIO_PKT_L3_CSUM_CALCULATED(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_L3_CSUM_CALCULATED_M(mda, pkt);
-}
-
-
-/** Determine whether the L3 (IP) checksum was calculated and found to be
- * correct.
- * @ingroup ingress
- *
- * @param[in] pkt Packet on which to operate.
- * @return Nonzero if the checksum was calculated and is correct.
- */
-static __inline unsigned int
-NETIO_PKT_L3_CSUM_CORRECT(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_L3_CSUM_CORRECT_M(mda, pkt);
-}
-
-
-/** Determine whether the Ethertype was recognized and L3 packet data was
- * processed.
- * @ingroup ingress
- *
- * @param[in] pkt Packet on which to operate.
- * @return Nonzero if the Ethertype was recognized and L3 packet data was
- * processed.
- */
-static __inline unsigned int
-NETIO_PKT_ETHERTYPE_RECOGNIZED(netio_pkt_t* pkt)
-{
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_ETHERTYPE_RECOGNIZED_M(mda, pkt);
-}
-
-
-/** Set an egress packet's L2 length, using a metadata pointer to speed the
- * computation.
- * @ingroup egress
- *
- * @param[in,out] mmd Pointer to packet's minimal metadata.
- * @param[in] pkt Packet on which to operate.
- * @param[in] len Packet L2 length, in bytes.
- */
-static __inline void
-NETIO_PKT_SET_L2_LENGTH_MM(netio_pkt_minimal_metadata_t* mmd, netio_pkt_t* pkt,
- int len)
-{
- mmd->l2_length = len;
-}
-
-
-/** Set an egress packet's L2 length.
- * @ingroup egress
- *
- * @param[in,out] pkt Packet on which to operate.
- * @param[in] len Packet L2 length, in bytes.
- */
-static __inline void
-NETIO_PKT_SET_L2_LENGTH(netio_pkt_t* pkt, int len)
-{
- netio_pkt_minimal_metadata_t* mmd = NETIO_PKT_MINIMAL_METADATA(pkt);
-
- NETIO_PKT_SET_L2_LENGTH_MM(mmd, pkt, len);
-}
-
-
-/** Set an egress packet's L2 header length, using a metadata pointer to
- * speed the computation.
- * @ingroup egress
- *
- * It is not normally necessary to call this routine; only the L2 length,
- * not the header length, is needed to transmit a packet. It may be useful if
- * the egress packet will later be processed by code which expects to use
- * functions like @ref NETIO_PKT_L3_DATA() to get a pointer to the L3 payload.
- *
- * @param[in,out] mmd Pointer to packet's minimal metadata.
- * @param[in] pkt Packet on which to operate.
- * @param[in] len Packet L2 header length, in bytes.
- */
-static __inline void
-NETIO_PKT_SET_L2_HEADER_LENGTH_MM(netio_pkt_minimal_metadata_t* mmd,
- netio_pkt_t* pkt, int len)
-{
- mmd->l3_offset = mmd->l2_offset + len;
-}
-
-
-/** Set an egress packet's L2 header length.
- * @ingroup egress
- *
- * It is not normally necessary to call this routine; only the L2 length,
- * not the header length, is needed to transmit a packet. It may be useful if
- * the egress packet will later be processed by code which expects to use
- * functions like @ref NETIO_PKT_L3_DATA() to get a pointer to the L3 payload.
- *
- * @param[in,out] pkt Packet on which to operate.
- * @param[in] len Packet L2 header length, in bytes.
- */
-static __inline void
-NETIO_PKT_SET_L2_HEADER_LENGTH(netio_pkt_t* pkt, int len)
-{
- netio_pkt_minimal_metadata_t* mmd = NETIO_PKT_MINIMAL_METADATA(pkt);
-
- NETIO_PKT_SET_L2_HEADER_LENGTH_MM(mmd, pkt, len);
-}
-
-
-/** Set up an egress packet for hardware checksum computation, using a
- * metadata pointer to speed the operation.
- * @ingroup egress
- *
- * NetIO provides the ability to automatically calculate a standard
- * 16-bit Internet checksum on transmitted packets. The application
- * may specify the point in the packet where the checksum starts, the
- * number of bytes to be checksummed, and the two bytes in the packet
- * which will be replaced with the completed checksum. (If the range
- * of bytes to be checksummed includes the bytes to be replaced, the
- * initial values of those bytes will be included in the checksum.)
- *
- * For some protocols, the packet checksum covers data which is not present
- * in the packet, or is at least not contiguous to the main data payload.
- * For instance, the TCP checksum includes a "pseudo-header" which includes
- * the source and destination IP addresses of the packet. To accommodate
- * this, the checksum engine may be "seeded" with an initial value, which
- * the application would need to compute based on the specific protocol's
- * requirements. Note that the seed is given in host byte order (little-
- * endian), not network byte order (big-endian); code written to compute a
- * pseudo-header checksum in network byte order will need to byte-swap it
- * before use as the seed.
- *
- * Note that the checksum is computed as part of the transmission process,
- * so it will not be present in the packet upon completion of this routine.
- *
- * @param[in,out] mmd Pointer to packet's minimal metadata.
- * @param[in] pkt Packet on which to operate.
- * @param[in] start Offset within L2 packet of the first byte to include in
- * the checksum.
- * @param[in] length Number of bytes to include in the checksum.
- * the checksum.
- * @param[in] location Offset within L2 packet of the first of the two bytes
- * to be replaced with the calculated checksum.
- * @param[in] seed Initial value of the running checksum before any of the
- * packet data is added.
- */
-static __inline void
-NETIO_PKT_DO_EGRESS_CSUM_MM(netio_pkt_minimal_metadata_t* mmd,
- netio_pkt_t* pkt, int start, int length,
- int location, uint16_t seed)
-{
- mmd->csum_start = start;
- mmd->csum_length = length;
- mmd->csum_location = location;
- mmd->csum_seed = seed;
- mmd->flags |= _NETIO_PKT_NEED_EDMA_CSUM_MASK;
-}
-
-
-/** Set up an egress packet for hardware checksum computation.
- * @ingroup egress
- *
- * NetIO provides the ability to automatically calculate a standard
- * 16-bit Internet checksum on transmitted packets. The application
- * may specify the point in the packet where the checksum starts, the
- * number of bytes to be checksummed, and the two bytes in the packet
- * which will be replaced with the completed checksum. (If the range
- * of bytes to be checksummed includes the bytes to be replaced, the
- * initial values of those bytes will be included in the checksum.)
- *
- * For some protocols, the packet checksum covers data which is not present
- * in the packet, or is at least not contiguous to the main data payload.
- * For instance, the TCP checksum includes a "pseudo-header" which includes
- * the source and destination IP addresses of the packet. To accommodate
- * this, the checksum engine may be "seeded" with an initial value, which
- * the application would need to compute based on the specific protocol's
- * requirements. Note that the seed is given in host byte order (little-
- * endian), not network byte order (big-endian); code written to compute a
- * pseudo-header checksum in network byte order will need to byte-swap it
- * before use as the seed.
- *
- * Note that the checksum is computed as part of the transmission process,
- * so it will not be present in the packet upon completion of this routine.
- *
- * @param[in,out] pkt Packet on which to operate.
- * @param[in] start Offset within L2 packet of the first byte to include in
- * the checksum.
- * @param[in] length Number of bytes to include in the checksum.
- * the checksum.
- * @param[in] location Offset within L2 packet of the first of the two bytes
- * to be replaced with the calculated checksum.
- * @param[in] seed Initial value of the running checksum before any of the
- * packet data is added.
- */
-static __inline void
-NETIO_PKT_DO_EGRESS_CSUM(netio_pkt_t* pkt, int start, int length,
- int location, uint16_t seed)
-{
- netio_pkt_minimal_metadata_t* mmd = NETIO_PKT_MINIMAL_METADATA(pkt);
-
- NETIO_PKT_DO_EGRESS_CSUM_MM(mmd, pkt, start, length, location, seed);
-}
-
-
-/** Return the number of bytes which could be prepended to a packet, using a
- * metadata pointer to speed the operation.
- * See @ref netio_populate_prepend_buffer() to get a full description of
- * prepending.
- *
- * @param[in,out] mda Pointer to packet's standard metadata.
- * @param[in] pkt Packet on which to operate.
- */
-static __inline int
-NETIO_PKT_PREPEND_AVAIL_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
- return (pkt->__packet.bits.__offset << 6) +
- NETIO_PKT_CUSTOM_HEADER_LENGTH_M(mda, pkt);
-}
-
-
-/** Return the number of bytes which could be prepended to a packet, using a
- * metadata pointer to speed the operation.
- * See @ref netio_populate_prepend_buffer() to get a full description of
- * prepending.
- * @ingroup egress
- *
- * @param[in,out] mmd Pointer to packet's minimal metadata.
- * @param[in] pkt Packet on which to operate.
- */
-static __inline int
-NETIO_PKT_PREPEND_AVAIL_MM(netio_pkt_minimal_metadata_t* mmd, netio_pkt_t* pkt)
-{
- return (pkt->__packet.bits.__offset << 6) + mmd->l2_offset;
-}
-
-
-/** Return the number of bytes which could be prepended to a packet.
- * See @ref netio_populate_prepend_buffer() to get a full description of
- * prepending.
- * @ingroup egress
- *
- * @param[in] pkt Packet on which to operate.
- */
-static __inline int
-NETIO_PKT_PREPEND_AVAIL(netio_pkt_t* pkt)
-{
- if (NETIO_PKT_IS_MINIMAL(pkt))
- {
- netio_pkt_minimal_metadata_t* mmd = NETIO_PKT_MINIMAL_METADATA(pkt);
-
- return NETIO_PKT_PREPEND_AVAIL_MM(mmd, pkt);
- }
- else
- {
- netio_pkt_metadata_t* mda = NETIO_PKT_METADATA(pkt);
-
- return NETIO_PKT_PREPEND_AVAIL_M(mda, pkt);
- }
-}
-
-
-/** Flush a packet's minimal metadata from the cache, using a metadata pointer
- * to speed the operation.
- * @ingroup egress
- *
- * @param[in] mmd Pointer to packet's minimal metadata.
- * @param[in] pkt Packet on which to operate.
- */
-static __inline void
-NETIO_PKT_FLUSH_MINIMAL_METADATA_MM(netio_pkt_minimal_metadata_t* mmd,
- netio_pkt_t* pkt)
-{
-}
-
-
-/** Invalidate a packet's minimal metadata from the cache, using a metadata
- * pointer to speed the operation.
- * @ingroup egress
- *
- * @param[in] mmd Pointer to packet's minimal metadata.
- * @param[in] pkt Packet on which to operate.
- */
-static __inline void
-NETIO_PKT_INV_MINIMAL_METADATA_MM(netio_pkt_minimal_metadata_t* mmd,
- netio_pkt_t* pkt)
-{
-}
-
-
-/** Flush and then invalidate a packet's minimal metadata from the cache,
- * using a metadata pointer to speed the operation.
- * @ingroup egress
- *
- * @param[in] mmd Pointer to packet's minimal metadata.
- * @param[in] pkt Packet on which to operate.
- */
-static __inline void
-NETIO_PKT_FLUSH_INV_MINIMAL_METADATA_MM(netio_pkt_minimal_metadata_t* mmd,
- netio_pkt_t* pkt)
-{
-}
-
-
-/** Flush a packet's metadata from the cache, using a metadata pointer
- * to speed the operation.
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's minimal metadata.
- * @param[in] pkt Packet on which to operate.
- */
-static __inline void
-NETIO_PKT_FLUSH_METADATA_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
-}
-
-
-/** Invalidate a packet's metadata from the cache, using a metadata
- * pointer to speed the operation.
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's metadata.
- * @param[in] pkt Packet on which to operate.
- */
-static __inline void
-NETIO_PKT_INV_METADATA_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
-}
-
-
-/** Flush and then invalidate a packet's metadata from the cache,
- * using a metadata pointer to speed the operation.
- * @ingroup ingress
- *
- * @param[in] mda Pointer to packet's metadata.
- * @param[in] pkt Packet on which to operate.
- */
-static __inline void
-NETIO_PKT_FLUSH_INV_METADATA_M(netio_pkt_metadata_t* mda, netio_pkt_t* pkt)
-{
-}
-
-
-/** Flush a packet's minimal metadata from the cache.
- * @ingroup egress
- *
- * @param[in] pkt Packet on which to operate.
- */
-static __inline void
-NETIO_PKT_FLUSH_MINIMAL_METADATA(netio_pkt_t* pkt)
-{
-}
-
-
-/** Invalidate a packet's minimal metadata from the cache.
- * @ingroup egress
- *
- * @param[in] pkt Packet on which to operate.
- */
-static __inline void
-NETIO_PKT_INV_MINIMAL_METADATA(netio_pkt_t* pkt)
-{
-}
-
-
-/** Flush and then invalidate a packet's minimal metadata from the cache.
- * @ingroup egress
- *
- * @param[in] pkt Packet on which to operate.
- */
-static __inline void
-NETIO_PKT_FLUSH_INV_MINIMAL_METADATA(netio_pkt_t* pkt)
-{
-}
-
-
-/** Flush a packet's metadata from the cache.
- * @ingroup ingress
- *
- * @param[in] pkt Packet on which to operate.
- */
-static __inline void
-NETIO_PKT_FLUSH_METADATA(netio_pkt_t* pkt)
-{
-}
-
-
-/** Invalidate a packet's metadata from the cache.
- * @ingroup ingress
- *
- * @param[in] pkt Packet on which to operate.
- */
-static __inline void
-NETIO_PKT_INV_METADATA(netio_pkt_t* pkt)
-{
-}
-
-
-/** Flush and then invalidate a packet's metadata from the cache.
- * @ingroup ingress
- *
- * @param[in] pkt Packet on which to operate.
- */
-static __inline void
-NETIO_PKT_FLUSH_INV_METADATA(netio_pkt_t* pkt)
-{
-}
-
-/** Number of NUMA nodes we can distribute buffers to.
- * @ingroup setup */
-#define NETIO_NUM_NODE_WEIGHTS 16
-
-/**
- * @brief An object for specifying the characteristics of NetIO communication
- * endpoint.
- *
- * @ingroup setup
- *
- * The @ref netio_input_register() function uses this structure to define
- * how an application tile will communicate with an IPP.
- *
- *
- * Future updates to NetIO may add new members to this structure,
- * which can affect the success of the registration operation. Thus,
- * if dynamically initializing the structure, applications are urged to
- * zero it out first, for example:
- *
- * @code
- * netio_input_config_t config;
- * memset(&config, 0, sizeof (config));
- * config.flags = NETIO_RECV | NETIO_XMIT_CSUM | NETIO_TAG_NONE;
- * config.num_receive_packets = NETIO_MAX_RECEIVE_PKTS;
- * config.queue_id = 0;
- * .
- * .
- * .
- * @endcode
- *
- * since that guarantees that any unused structure members, including
- * members which did not exist when the application was first developed,
- * will not have unexpected values.
- *
- * If statically initializing the structure, we strongly recommend use of
- * C99-style named initializers, for example:
- *
- * @code
- * netio_input_config_t config = {
- * .flags = NETIO_RECV | NETIO_XMIT_CSUM | NETIO_TAG_NONE,
- * .num_receive_packets = NETIO_MAX_RECEIVE_PKTS,
- * .queue_id = 0,
- * },
- * @endcode
- *
- * instead of the old-style structure initialization:
- *
- * @code
- * // Bad example! Currently equivalent to the above, but don't do this.
- * netio_input_config_t config = {
- * NETIO_RECV | NETIO_XMIT_CSUM | NETIO_TAG_NONE, NETIO_MAX_RECEIVE_PKTS, 0
- * },
- * @endcode
- *
- * since the C99 style requires no changes to the code if elements of the
- * config structure are rearranged. (It also makes the initialization much
- * easier to understand.)
- *
- * Except for items which address a particular tile's transmit or receive
- * characteristics, such as the ::NETIO_RECV flag, applications are advised
- * to specify the same set of configuration data on all registrations.
- * This prevents differing results if multiple tiles happen to do their
- * registration operations in a different order on different invocations of
- * the application. This is particularly important for things like link
- * management flags, and buffer size and homing specifications.
- *
- * Unless the ::NETIO_FIXED_BUFFER_VA flag is specified in flags, the NetIO
- * buffer pool is automatically created and mapped into the application's
- * virtual address space at an address chosen by the operating system,
- * using the common memory (cmem) facility in the Tilera Multicore
- * Components library. The cmem facility allows multiple processes to gain
- * access to shared memory which is mapped into each process at an
- * identical virtual address. In order for this to work, the processes
- * must have a common ancestor, which must create the common memory using
- * tmc_cmem_init().
- *
- * In programs using the iLib process creation API, or in programs which use
- * only one process (which include programs using the pthreads library),
- * tmc_cmem_init() is called automatically. All other applications
- * must call it explicitly, before any child processes which might call
- * netio_input_register() are created.
- */
-typedef struct
-{
- /** Registration characteristics.
-
- This value determines several characteristics of the registration;
- flags for different types of behavior are ORed together to make the
- final flag value. Generally applications should specify exactly
- one flag from each of the following categories:
-
- - Whether the application will be receiving packets on this queue
- (::NETIO_RECV or ::NETIO_NO_RECV).
-
- - Whether the application will be transmitting packets on this queue,
- and if so, whether it will request egress checksum calculation
- (::NETIO_XMIT, ::NETIO_XMIT_CSUM, or ::NETIO_NO_XMIT). It is
- legal to call netio_get_buffer() without one of the XMIT flags,
- as long as ::NETIO_RECV is specified; in this case, the retrieved
- buffers must be passed to another tile for transmission.
-
- - Whether the application expects any vendor-specific tags in
- its packets' L2 headers (::NETIO_TAG_NONE, ::NETIO_TAG_BRCM,
- or ::NETIO_TAG_MRVL). This must match the configuration of the
- target IPP.
-
- To accommodate applications written to previous versions of the NetIO
- interface, none of the flags above are currently required; if omitted,
- NetIO behaves more or less as if ::NETIO_RECV | ::NETIO_XMIT_CSUM |
- ::NETIO_TAG_NONE were used. However, explicit specification of
- the relevant flags allows NetIO to do a better job of resource
- allocation, allows earlier detection of certain configuration errors,
- and may enable advanced features or higher performance in the future,
- so their use is strongly recommended.
-
- Note that specifying ::NETIO_NO_RECV along with ::NETIO_NO_XMIT
- is a special case, intended primarily for use by programs which
- retrieve network statistics or do link management operations.
- When these flags are both specified, the resulting queue may not
- be used with NetIO routines other than netio_get(), netio_set(),
- and netio_input_unregister(). See @ref link for more information
- on link management.
-
- Other flags are optional; their use is described below.
- */
- int flags;
-
- /** Interface name. This is a string which identifies the specific
- Ethernet controller hardware to be used. The format of the string
- is a device type and a device index, separated by a slash; so,
- the first 10 Gigabit Ethernet controller is named "xgbe/0", while
- the second 10/100/1000 Megabit Ethernet controller is named "gbe/1".
- */
- const char* interface;
-
- /** Receive packet queue size. This specifies the maximum number
- of ingress packets that can be received on this queue without
- being retrieved by @ref netio_get_packet(). If the IPP's distribution
- algorithm calls for a packet to be sent to this queue, and this
- number of packets are already pending there, the new packet
- will either be discarded, or sent to another tile registered
- for the same queue_id (see @ref drops). This value must
- be at least ::NETIO_MIN_RECEIVE_PKTS, can always be at least
- ::NETIO_MAX_RECEIVE_PKTS, and may be larger than that on certain
- interfaces.
- */
- int num_receive_packets;
-
- /** The queue ID being requested. Legal values for this range from 0
- to ::NETIO_MAX_QUEUE_ID, inclusive. ::NETIO_MAX_QUEUE_ID is always
- greater than or equal to the number of tiles; this allows one queue
- for each tile, plus at least one additional queue. Some applications
- may wish to use the additional queue as a destination for unwanted
- packets, since packets delivered to queues for which no tiles have
- registered are discarded.
- */
- unsigned int queue_id;
-
- /** Maximum number of small send buffers to be held in the local empty
- buffer cache. This specifies the size of the area which holds
- empty small egress buffers requested from the IPP but not yet
- retrieved via @ref netio_get_buffer(). This value must be greater
- than zero if the application will ever use @ref netio_get_buffer()
- to allocate empty small egress buffers; it may be no larger than
- ::NETIO_MAX_SEND_BUFFERS. See @ref epp for more details on empty
- buffer caching.
- */
- int num_send_buffers_small_total;
-
- /** Number of small send buffers to be preallocated at registration.
- If this value is nonzero, the specified number of empty small egress
- buffers will be requested from the IPP during the netio_input_register
- operation; this may speed the execution of @ref netio_get_buffer().
- This may be no larger than @ref num_send_buffers_small_total. See @ref
- epp for more details on empty buffer caching.
- */
- int num_send_buffers_small_prealloc;
-
- /** Maximum number of large send buffers to be held in the local empty
- buffer cache. This specifies the size of the area which holds empty
- large egress buffers requested from the IPP but not yet retrieved via
- @ref netio_get_buffer(). This value must be greater than zero if the
- application will ever use @ref netio_get_buffer() to allocate empty
- large egress buffers; it may be no larger than ::NETIO_MAX_SEND_BUFFERS.
- See @ref epp for more details on empty buffer caching.
- */
- int num_send_buffers_large_total;
-
- /** Number of large send buffers to be preallocated at registration.
- If this value is nonzero, the specified number of empty large egress
- buffers will be requested from the IPP during the netio_input_register
- operation; this may speed the execution of @ref netio_get_buffer().
- This may be no larger than @ref num_send_buffers_large_total. See @ref
- epp for more details on empty buffer caching.
- */
- int num_send_buffers_large_prealloc;
-
- /** Maximum number of jumbo send buffers to be held in the local empty
- buffer cache. This specifies the size of the area which holds empty
- jumbo egress buffers requested from the IPP but not yet retrieved via
- @ref netio_get_buffer(). This value must be greater than zero if the
- application will ever use @ref netio_get_buffer() to allocate empty
- jumbo egress buffers; it may be no larger than ::NETIO_MAX_SEND_BUFFERS.
- See @ref epp for more details on empty buffer caching.
- */
- int num_send_buffers_jumbo_total;
-
- /** Number of jumbo send buffers to be preallocated at registration.
- If this value is nonzero, the specified number of empty jumbo egress
- buffers will be requested from the IPP during the netio_input_register
- operation; this may speed the execution of @ref netio_get_buffer().
- This may be no larger than @ref num_send_buffers_jumbo_total. See @ref
- epp for more details on empty buffer caching.
- */
- int num_send_buffers_jumbo_prealloc;
-
- /** Total packet buffer size. This determines the total size, in bytes,
- of the NetIO buffer pool. Note that the maximum number of available
- buffers of each size is determined during hypervisor configuration
- (see the <em>System Programmer's Guide</em> for details); this just
- influences how much host memory is allocated for those buffers.
-
- The buffer pool is allocated from common memory, which will be
- automatically initialized if needed. If your buffer pool is larger
- than 240 MB, you might need to explicitly call @c tmc_cmem_init(),
- as described in the Application Libraries Reference Manual (UG227).
-
- Packet buffers are currently allocated in chunks of 16 MB; this
- value will be rounded up to the next larger multiple of 16 MB.
- If this value is zero, a default of 32 MB will be used; this was
- the value used by previous versions of NetIO. Note that taking this
- default also affects the placement of buffers on Linux NUMA nodes.
- See @ref buffer_node_weights for an explanation of buffer placement.
-
- In order to successfully allocate packet buffers, Linux must have
- available huge pages on the relevant Linux NUMA nodes. See the
- <em>System Programmer's Guide</em> for information on configuring
- huge page support in Linux.
- */
- uint64_t total_buffer_size;
-
- /** Buffer placement weighting factors.
-
- This array specifies the relative amount of buffering to place
- on each of the available Linux NUMA nodes. This array is
- indexed by the NUMA node, and the values in the array are
- proportional to the amount of buffer space to allocate on that
- node.
-
- If memory striping is enabled in the Hypervisor, then there is
- only one logical NUMA node (node 0). In that case, NetIO will by
- default ignore the suggested buffer node weights, and buffers
- will be striped across the physical memory controllers. See
- UG209 System Programmer's Guide for a description of the
- hypervisor option that controls memory striping.
-
- If memory striping is disabled, then there are up to four NUMA
- nodes, corresponding to the four DDRAM controllers in the TILE
- processor architecture. See UG100 Tile Processor Architecture
- Overview for a diagram showing the location of each of the DDRAM
- controllers relative to the tile array.
-
- For instance, if memory striping is disabled, the following
- configuration strucure:
-
- @code
- netio_input_config_t config = {
- .
- .
- .
- .total_buffer_size = 4 * 16 * 1024 * 1024;
- .buffer_node_weights = { 1, 0, 1, 0 },
- },
- @endcode
-
- would result in 32 MB of buffers being placed on controller 0, and
- 32 MB on controller 2. (Since buffers are allocated in units of
- 16 MB, some sets of weights will not be able to be matched exactly.)
-
- For the weights to be effective, @ref total_buffer_size must be
- nonzero. If @ref total_buffer_size is zero, causing the default
- 32 MB of buffer space to be used, then any specified weights will
- be ignored, and buffers will positioned as they were in previous
- versions of NetIO:
-
- - For xgbe/0 and gbe/0, 16 MB of buffers will be placed on controller 1,
- and the other 16 MB will be placed on controller 2.
-
- - For xgbe/1 and gbe/1, 16 MB of buffers will be placed on controller 2,
- and the other 16 MB will be placed on controller 3.
-
- If @ref total_buffer_size is nonzero, but all weights are zero,
- then all buffer space will be allocated on Linux NUMA node zero.
-
- By default, the specified buffer placement is treated as a hint;
- if sufficient free memory is not available on the specified
- controllers, the buffers will be allocated elsewhere. However,
- if the ::NETIO_STRICT_HOMING flag is specified in @ref flags, then a
- failure to allocate buffer space exactly as requested will cause the
- registration operation to fail with an error of ::NETIO_CANNOT_HOME.
-
- Note that maximal network performance cannot be achieved with
- only one memory controller.
- */
- uint8_t buffer_node_weights[NETIO_NUM_NODE_WEIGHTS];
-
- /** Fixed virtual address for packet buffers. Only valid when
- ::NETIO_FIXED_BUFFER_VA is specified in @ref flags; see the
- description of that flag for details.
- */
- void* fixed_buffer_va;
-
- /**
- Maximum number of outstanding send packet requests. This value is
- only relevant when an EPP is in use; it determines the number of
- slots in the EPP's outgoing packet queue which this tile is allowed
- to consume, and thus the number of packets which may be sent before
- the sending tile must wait for an acknowledgment from the EPP.
- Modifying this value is generally only helpful when using @ref
- netio_send_packet_vector(), where it can help improve performance by
- allowing a single vector send operation to process more packets.
- Typically it is not specified, and the default, which divides the
- outgoing packet slots evenly between all tiles on the chip, is used.
-
- If a registration asks for more outgoing packet queue slots than are
- available, ::NETIO_TOOMANY_XMIT will be returned. The total number
- of packet queue slots which are available for all tiles for each EPP
- is subject to change, but is currently ::NETIO_TOTAL_SENDS_OUTSTANDING.
-
-
- This value is ignored if ::NETIO_XMIT is not specified in flags.
- If you want to specify a large value here for a specific tile, you are
- advised to specify NETIO_NO_XMIT on other, non-transmitting tiles so
- that they do not consume a default number of packet slots. Any tile
- transmitting is required to have at least ::NETIO_MIN_SENDS_OUTSTANDING
- slots allocated to it; values less than that will be silently
- increased by the NetIO library.
- */
- int num_sends_outstanding;
-}
-netio_input_config_t;
-
-
-/** Registration flags; used in the @ref netio_input_config_t structure.
- * @addtogroup setup
- */
-/** @{ */
-
-/** Fail a registration request if we can't put packet buffers
- on the specified memory controllers. */
-#define NETIO_STRICT_HOMING 0x00000002
-
-/** This application expects no tags on its L2 headers. */
-#define NETIO_TAG_NONE 0x00000004
-
-/** This application expects Marvell extended tags on its L2 headers. */
-#define NETIO_TAG_MRVL 0x00000008
-
-/** This application expects Broadcom tags on its L2 headers. */
-#define NETIO_TAG_BRCM 0x00000010
-
-/** This registration may call routines which receive packets. */
-#define NETIO_RECV 0x00000020
-
-/** This registration may not call routines which receive packets. */
-#define NETIO_NO_RECV 0x00000040
-
-/** This registration may call routines which transmit packets. */
-#define NETIO_XMIT 0x00000080
-
-/** This registration may call routines which transmit packets with
- checksum acceleration. */
-#define NETIO_XMIT_CSUM 0x00000100
-
-/** This registration may not call routines which transmit packets. */
-#define NETIO_NO_XMIT 0x00000200
-
-/** This registration wants NetIO buffers mapped at an application-specified
- virtual address.
-
- NetIO buffers are by default created by the TMC common memory facility,
- which must be configured by a common ancestor of all processes sharing
- a network interface. When this flag is specified, NetIO buffers are
- instead mapped at an address chosen by the application (and specified
- in @ref netio_input_config_t::fixed_buffer_va). This allows multiple
- unrelated but cooperating processes to share a NetIO interface.
- All processes sharing the same interface must specify this flag,
- and all must specify the same fixed virtual address.
-
- @ref netio_input_config_t::fixed_buffer_va must be a
- multiple of 16 MB, and the packet buffers will occupy @ref
- netio_input_config_t::total_buffer_size bytes of virtual address
- space, beginning at that address. If any of those virtual addresses
- are currently occupied by other memory objects, like application or
- shared library code or data, @ref netio_input_register() will return
- ::NETIO_FAULT. While it is impossible to provide a fixed_buffer_va
- which will work for all applications, a good first guess might be to
- use 0xb0000000 minus @ref netio_input_config_t::total_buffer_size.
- If that fails, it might be helpful to consult the running application's
- virtual address description file (/proc/<em>pid</em>/maps) to see
- which regions of virtual address space are available.
- */
-#define NETIO_FIXED_BUFFER_VA 0x00000400
-
-/** This registration call will not complete unless the network link
- is up. The process will wait several seconds for this to happen (the
- precise interval is link-dependent), but if the link does not come up,
- ::NETIO_LINK_DOWN will be returned. This flag is the default if
- ::NETIO_NOREQUIRE_LINK_UP is not specified. Note that this flag by
- itself does not request that the link be brought up; that can be done
- with the ::NETIO_AUTO_LINK_UPDN or ::NETIO_AUTO_LINK_UP flags (the
- latter is the default if no NETIO_AUTO_LINK_xxx flags are specified),
- or by explicitly setting the link's desired state via netio_set().
- If the link is not brought up by one of those methods, and this flag
- is specified, the registration operation will return ::NETIO_LINK_DOWN.
- This flag is ignored if it is specified along with ::NETIO_NO_XMIT and
- ::NETIO_NO_RECV. See @ref link for more information on link
- management.
- */
-#define NETIO_REQUIRE_LINK_UP 0x00000800
-
-/** This registration call will complete even if the network link is not up.
- Whenever the link is not up, packets will not be sent or received:
- netio_get_packet() will return ::NETIO_NOPKT once all queued packets
- have been drained, and netio_send_packet() and similar routines will
- return NETIO_QUEUE_FULL once the outgoing packet queue in the EPP
- or the I/O shim is full. See @ref link for more information on link
- management.
- */
-#define NETIO_NOREQUIRE_LINK_UP 0x00001000
-
-#ifndef __DOXYGEN__
-/*
- * These are part of the implementation of the NETIO_AUTO_LINK_xxx flags,
- * but should not be used directly by applications, and are thus not
- * documented.
- */
-#define _NETIO_AUTO_UP 0x00002000
-#define _NETIO_AUTO_DN 0x00004000
-#define _NETIO_AUTO_PRESENT 0x00008000
-#endif
-
-/** Set the desired state of the link to up, allowing any speeds which are
- supported by the link hardware, as part of this registration operation.
- Do not take down the link automatically. This is the default if
- no other NETIO_AUTO_LINK_xxx flags are specified. This flag is ignored
- if it is specified along with ::NETIO_NO_XMIT and ::NETIO_NO_RECV.
- See @ref link for more information on link management.
- */
-#define NETIO_AUTO_LINK_UP (_NETIO_AUTO_PRESENT | _NETIO_AUTO_UP)
-
-/** Set the desired state of the link to up, allowing any speeds which are
- supported by the link hardware, as part of this registration operation.
- Set the desired state of the link to down the next time no tiles are
- registered for packet reception or transmission. This flag is ignored
- if it is specified along with ::NETIO_NO_XMIT and ::NETIO_NO_RECV.
- See @ref link for more information on link management.
- */
-#define NETIO_AUTO_LINK_UPDN (_NETIO_AUTO_PRESENT | _NETIO_AUTO_UP | \
- _NETIO_AUTO_DN)
-
-/** Set the desired state of the link to down the next time no tiles are
- registered for packet reception or transmission. This flag is ignored
- if it is specified along with ::NETIO_NO_XMIT and ::NETIO_NO_RECV.
- See @ref link for more information on link management.
- */
-#define NETIO_AUTO_LINK_DN (_NETIO_AUTO_PRESENT | _NETIO_AUTO_DN)
-
-/** Do not bring up the link automatically as part of this registration
- operation. Do not take down the link automatically. This flag
- is ignored if it is specified along with ::NETIO_NO_XMIT and
- ::NETIO_NO_RECV. See @ref link for more information on link management.
- */
-#define NETIO_AUTO_LINK_NONE _NETIO_AUTO_PRESENT
-
-
-/** Minimum number of receive packets. */
-#define NETIO_MIN_RECEIVE_PKTS 16
-
-/** Lower bound on the maximum number of receive packets; may be higher
- than this on some interfaces. */
-#define NETIO_MAX_RECEIVE_PKTS 128
-
-/** Maximum number of send buffers, per packet size. */
-#define NETIO_MAX_SEND_BUFFERS 16
-
-/** Number of EPP queue slots, and thus outstanding sends, per EPP. */
-#define NETIO_TOTAL_SENDS_OUTSTANDING 2015
-
-/** Minimum number of EPP queue slots, and thus outstanding sends, per
- * transmitting tile. */
-#define NETIO_MIN_SENDS_OUTSTANDING 16
-
-
-/**@}*/
-
-#ifndef __DOXYGEN__
-
-/**
- * An object for providing Ethernet packets to a process.
- */
-struct __netio_queue_impl_t;
-
-/**
- * An object for managing the user end of a NetIO queue.
- */
-struct __netio_queue_user_impl_t;
-
-#endif /* !__DOXYGEN__ */
-
-
-/** A netio_queue_t describes a NetIO communications endpoint.
- * @ingroup setup
- */
-typedef struct
-{
-#ifdef __DOXYGEN__
- uint8_t opaque[8]; /**< This is an opaque structure. */
-#else
- struct __netio_queue_impl_t* __system_part; /**< The system part. */
- struct __netio_queue_user_impl_t* __user_part; /**< The user part. */
-#ifdef _NETIO_PTHREAD
- _netio_percpu_mutex_t lock; /**< Queue lock. */
-#endif
-#endif
-}
-netio_queue_t;
-
-
-/**
- * @brief Packet send context.
- *
- * @ingroup egress
- *
- * Packet send context for use with netio_send_packet_prepare and _commit.
- */
-typedef struct
-{
-#ifdef __DOXYGEN__
- uint8_t opaque[44]; /**< This is an opaque structure. */
-#else
- uint8_t flags; /**< Defined below */
- uint8_t datalen; /**< Number of valid words pointed to by data. */
- uint32_t request[9]; /**< Request to be sent to the EPP or shim. Note
- that this is smaller than the 11-word maximum
- request size, since some constant values are
- not saved in the context. */
- uint32_t *data; /**< Data to be sent to the EPP or shim via IDN. */
-#endif
-}
-netio_send_pkt_context_t;
-
-
-#ifndef __DOXYGEN__
-#define SEND_PKT_CTX_USE_EPP 1 /**< We're sending to an EPP. */
-#define SEND_PKT_CTX_SEND_CSUM 2 /**< Request includes a checksum. */
-#endif
-
-/**
- * @brief Packet vector entry.
- *
- * @ingroup egress
- *
- * This data structure is used with netio_send_packet_vector() to send multiple
- * packets with one NetIO call. The structure should be initialized by
- * calling netio_pkt_vector_set(), rather than by setting the fields
- * directly.
- *
- * This structure is guaranteed to be a power of two in size, no
- * bigger than one L2 cache line, and to be aligned modulo its size.
- */
-typedef struct
-#ifndef __DOXYGEN__
-__attribute__((aligned(8)))
-#endif
-{
- /** Reserved for use by the user application. When initialized with
- * the netio_set_pkt_vector_entry() function, this field is guaranteed
- * to be visible to readers only after all other fields are already
- * visible. This way it can be used as a valid flag or generation
- * counter. */
- uint8_t user_data;
-
- /* Structure members below this point should not be accessed directly by
- * applications, as they may change in the future. */
-
- /** Low 8 bits of the packet address to send. The high bits are
- * acquired from the 'handle' field. */
- uint8_t buffer_address_low;
-
- /** Number of bytes to transmit. */
- uint16_t size;
-
- /** The raw handle from a netio_pkt_t. If this is NETIO_PKT_HANDLE_NONE,
- * this vector entry will be skipped and no packet will be transmitted. */
- netio_pkt_handle_t handle;
-}
-netio_pkt_vector_entry_t;
-
-
-/**
- * @brief Initialize fields in a packet vector entry.
- *
- * @ingroup egress
- *
- * @param[out] v Pointer to the vector entry to be initialized.
- * @param[in] pkt Packet to be transmitted when the vector entry is passed to
- * netio_send_packet_vector(). Note that the packet's attributes
- * (e.g., its L2 offset and length) are captured at the time this
- * routine is called; subsequent changes in those attributes will not
- * be reflected in the packet which is actually transmitted.
- * Changes in the packet's contents, however, will be so reflected.
- * If this is NULL, no packet will be transmitted.
- * @param[in] user_data User data to be set in the vector entry.
- * This function guarantees that the "user_data" field will become
- * visible to a reader only after all other fields have become visible.
- * This allows a structure in a ring buffer to be written and read
- * by a polling reader without any locks or other synchronization.
- */
-static __inline void
-netio_pkt_vector_set(volatile netio_pkt_vector_entry_t* v, netio_pkt_t* pkt,
- uint8_t user_data)
-{
- if (pkt)
- {
- if (NETIO_PKT_IS_MINIMAL(pkt))
- {
- netio_pkt_minimal_metadata_t* mmd =
- (netio_pkt_minimal_metadata_t*) &pkt->__metadata;
- v->buffer_address_low = (uintptr_t) NETIO_PKT_L2_DATA_MM(mmd, pkt) & 0xFF;
- v->size = NETIO_PKT_L2_LENGTH_MM(mmd, pkt);
- }
- else
- {
- netio_pkt_metadata_t* mda = &pkt->__metadata;
- v->buffer_address_low = (uintptr_t) NETIO_PKT_L2_DATA_M(mda, pkt) & 0xFF;
- v->size = NETIO_PKT_L2_LENGTH_M(mda, pkt);
- }
- v->handle.word = pkt->__packet.word;
- }
- else
- {
- v->handle.word = 0; /* Set handle to NETIO_PKT_HANDLE_NONE. */
- }
-
- __asm__("" : : : "memory");
-
- v->user_data = user_data;
-}
-
-
-/**
- * Flags and structures for @ref netio_get() and @ref netio_set().
- * @ingroup config
- */
-
-/** @{ */
-/** Parameter class; addr is a NETIO_PARAM_xxx value. */
-#define NETIO_PARAM 0
-/** Interface MAC address. This address is only valid with @ref netio_get().
- * The value is a 6-byte MAC address. Depending upon the overall system
- * design, a MAC address may or may not be available for each interface. */
-#define NETIO_PARAM_MAC 0
-
-/** Determine whether to suspend output on the receipt of pause frames.
- * If the value is nonzero, the I/O shim will suspend output when a pause
- * frame is received. If the value is zero, pause frames will be ignored. */
-#define NETIO_PARAM_PAUSE_IN 1
-
-/** Determine whether to send pause frames if the I/O shim packet FIFOs are
- * nearly full. If the value is zero, pause frames are not sent. If
- * the value is nonzero, it is the delay value which will be sent in any
- * pause frames which are output, in units of 512 bit times. */
-#define NETIO_PARAM_PAUSE_OUT 2
-
-/** Jumbo frame support. The value is a 4-byte integer. If the value is
- * nonzero, the MAC will accept frames of up to 10240 bytes. If the value
- * is zero, the MAC will only accept frames of up to 1544 bytes. */
-#define NETIO_PARAM_JUMBO 3
-
-/** I/O shim's overflow statistics register. The value is two 16-bit integers.
- * The first 16-bit value (or the low 16 bits, if the value is treated as a
- * 32-bit number) is the count of packets which were completely dropped and
- * not delivered by the shim. The second 16-bit value (or the high 16 bits,
- * if the value is treated as a 32-bit number) is the count of packets
- * which were truncated and thus only partially delivered by the shim. This
- * register is automatically reset to zero after it has been read.
- */
-#define NETIO_PARAM_OVERFLOW 4
-
-/** IPP statistics. This address is only valid with @ref netio_get(). The
- * value is a netio_stat_t structure. Unlike the I/O shim statistics, the
- * IPP statistics are not all reset to zero on read; see the description
- * of the netio_stat_t for details. */
-#define NETIO_PARAM_STAT 5
-
-/** Possible link state. The value is a combination of "NETIO_LINK_xxx"
- * flags. With @ref netio_get(), this will indicate which flags are
- * actually supported by the hardware.
- *
- * For historical reasons, specifying this value to netio_set() will have
- * the same behavior as using ::NETIO_PARAM_LINK_CONFIG, but this usage is
- * discouraged.
- */
-#define NETIO_PARAM_LINK_POSSIBLE_STATE 6
-
-/** Link configuration. The value is a combination of "NETIO_LINK_xxx" flags.
- * With @ref netio_set(), this will attempt to immediately bring up the
- * link using whichever of the requested flags are supported by the
- * hardware, or take down the link if the flags are zero; if this is
- * not possible, an error will be returned. Many programs will want
- * to use ::NETIO_PARAM_LINK_DESIRED_STATE instead.
- *
- * For historical reasons, specifying this value to netio_get() will
- * have the same behavior as using ::NETIO_PARAM_LINK_POSSIBLE_STATE,
- * but this usage is discouraged.
- */
-#define NETIO_PARAM_LINK_CONFIG NETIO_PARAM_LINK_POSSIBLE_STATE
-
-/** Current link state. This address is only valid with @ref netio_get().
- * The value is zero or more of the "NETIO_LINK_xxx" flags, ORed together.
- * If the link is down, the value ANDed with NETIO_LINK_SPEED will be
- * zero; if the link is up, the value ANDed with NETIO_LINK_SPEED will
- * result in exactly one of the NETIO_LINK_xxx values, indicating the
- * current speed. */
-#define NETIO_PARAM_LINK_CURRENT_STATE 7
-
-/** Variant symbol for current state, retained for compatibility with
- * pre-MDE-2.1 programs. */
-#define NETIO_PARAM_LINK_STATUS NETIO_PARAM_LINK_CURRENT_STATE
-
-/** Packet Coherence protocol. This address is only valid with @ref netio_get().
- * The value is nonzero if the interface is configured for cache-coherent DMA.
- */
-#define NETIO_PARAM_COHERENT 8
-
-/** Desired link state. The value is a conbination of "NETIO_LINK_xxx"
- * flags, which specify the desired state for the link. With @ref
- * netio_set(), this will, in the background, attempt to bring up the link
- * using whichever of the requested flags are reasonable, or take down the
- * link if the flags are zero. The actual link up or down operation may
- * happen after this call completes. If the link state changes in the
- * future, the system will continue to try to get back to the desired link
- * state; for instance, if the link is brought up successfully, and then
- * the network cable is disconnected, the link will go down. However, the
- * desired state of the link is still up, so if the cable is reconnected,
- * the link will be brought up again.
- *
- * With @ref netio_get(), this will indicate the desired state for the
- * link, as set with a previous netio_set() call, or implicitly by a
- * netio_input_register() or netio_input_unregister() operation. This may
- * not reflect the current state of the link; to get that, use
- * ::NETIO_PARAM_LINK_CURRENT_STATE. */
-#define NETIO_PARAM_LINK_DESIRED_STATE 9
-
-/** NetIO statistics structure. Retrieved using the ::NETIO_PARAM_STAT
- * address passed to @ref netio_get(). */
-typedef struct
-{
- /** Number of packets which have been received by the IPP and forwarded
- * to a tile's receive queue for processing. This value wraps at its
- * maximum, and is not cleared upon read. */
- uint32_t packets_received;
-
- /** Number of packets which have been dropped by the IPP, because they could
- * not be received, or could not be forwarded to a tile. The former happens
- * when the IPP does not have a free packet buffer of suitable size for an
- * incoming frame. The latter happens when all potential destination tiles
- * for a packet, as defined by the group, bucket, and queue configuration,
- * have full receive queues. This value wraps at its maximum, and is not
- * cleared upon read. */
- uint32_t packets_dropped;
-
- /*
- * Note: the #defines after each of the following four one-byte values
- * denote their location within the third word of the netio_stat_t. They
- * are intended for use only by the IPP implementation and are thus omitted
- * from the Doxygen output.
- */
-
- /** Number of packets dropped because no worker was able to accept a new
- * packet. This value saturates at its maximum, and is cleared upon
- * read. */
- uint8_t drops_no_worker;
-#ifndef __DOXYGEN__
-#define NETIO_STAT_DROPS_NO_WORKER 0
-#endif
-
- /** Number of packets dropped because no small buffers were available.
- * This value saturates at its maximum, and is cleared upon read. */
- uint8_t drops_no_smallbuf;
-#ifndef __DOXYGEN__
-#define NETIO_STAT_DROPS_NO_SMALLBUF 1
-#endif
-
- /** Number of packets dropped because no large buffers were available.
- * This value saturates at its maximum, and is cleared upon read. */
- uint8_t drops_no_largebuf;
-#ifndef __DOXYGEN__
-#define NETIO_STAT_DROPS_NO_LARGEBUF 2
-#endif
-
- /** Number of packets dropped because no jumbo buffers were available.
- * This value saturates at its maximum, and is cleared upon read. */
- uint8_t drops_no_jumbobuf;
-#ifndef __DOXYGEN__
-#define NETIO_STAT_DROPS_NO_JUMBOBUF 3
-#endif
-}
-netio_stat_t;
-
-
-/** Link can run, should run, or is running at 10 Mbps. */
-#define NETIO_LINK_10M 0x01
-
-/** Link can run, should run, or is running at 100 Mbps. */
-#define NETIO_LINK_100M 0x02
-
-/** Link can run, should run, or is running at 1 Gbps. */
-#define NETIO_LINK_1G 0x04
-
-/** Link can run, should run, or is running at 10 Gbps. */
-#define NETIO_LINK_10G 0x08
-
-/** Link should run at the highest speed supported by the link and by
- * the device connected to the link. Only usable as a value for
- * the link's desired state; never returned as a value for the current
- * or possible states. */
-#define NETIO_LINK_ANYSPEED 0x10
-
-/** All legal link speeds. */
-#define NETIO_LINK_SPEED (NETIO_LINK_10M | \
- NETIO_LINK_100M | \
- NETIO_LINK_1G | \
- NETIO_LINK_10G | \
- NETIO_LINK_ANYSPEED)
-
-
-/** MAC register class. Addr is a register offset within the MAC.
- * Registers within the XGbE and GbE MACs are documented in the Tile
- * Processor I/O Device Guide (UG104). MAC registers start at address
- * 0x4000, and do not include the MAC_INTERFACE registers. */
-#define NETIO_MAC 1
-
-/** MDIO register class (IEEE 802.3 clause 22 format). Addr is the "addr"
- * member of a netio_mdio_addr_t structure. */
-#define NETIO_MDIO 2
-
-/** MDIO register class (IEEE 802.3 clause 45 format). Addr is the "addr"
- * member of a netio_mdio_addr_t structure. */
-#define NETIO_MDIO_CLAUSE45 3
-
-/** NetIO MDIO address type. Retrieved or provided using the ::NETIO_MDIO
- * address passed to @ref netio_get() or @ref netio_set(). */
-typedef union
-{
- struct
- {
- unsigned int reg:16; /**< MDIO register offset. For clause 22 access,
- must be less than 32. */
- unsigned int phy:5; /**< Which MDIO PHY to access. */
- unsigned int dev:5; /**< Which MDIO device to access within that PHY.
- Applicable for clause 45 access only; ignored
- for clause 22 access. */
- }
- bits; /**< Container for bitfields. */
- uint64_t addr; /**< Value to pass to @ref netio_get() or
- * @ref netio_set(). */
-}
-netio_mdio_addr_t;
-
-/** @} */
-
-#endif /* __NETIO_INTF_H__ */