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# Copyright (c) 2018 Cisco and/or its affiliates.
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at:
#
#     http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.

*** Settings ***
| Resource | resources/libraries/robot/performance/performance_setup.robot
| ...
| Force Tags | 3_NODE_SINGLE_LINK_TOPO | PERFTEST | HW_ENV | MRR
| ... | NIC_Intel-X710 | ETH | L2BDMACLRN | SCALE | L2BDBASE | FIB_1M
| ...
| Suite Setup | Set up 3-node performance topology with DUT's NIC model
| ... | L2 | Intel-X710
| Suite Teardown | Tear down 3-node performance topology
| ...
| Test Setup | Set up performance test
| ...
| Test Teardown | Tear down performance mrr test
| ...
| Documentation | *Raw results for L2BD test cases*
| ...
| ... | *[Top] Network Topologies:* TG-DUT1-DUT2-TG 3-node circular topology\
| ... | with single links between nodes.
| ... | *[Enc] Packet Encapsulations:* Eth-IPv4 for L2 switching of IPv4.
| ... | *[Cfg] DUT configuration:* DUT1 and DUT2 are configured with L2 bridge-\
| ... | domain and MAC learning enabled. DUT1 and DUT2 tested with 2p10GE NI
| ... | X710 by Intel.
| ... | *[Ver] TG verification:* In MaxReceivedRate tests TG sends traffic\
| ... | at line rate and reports total received/sent packets over trial period.\
| ... | Test packets are generated by TG on\
| ... | links to DUTs. TG traffic profile contains two L3 flow-groups\
| ... | (flow-group per direction, 500k flows per flow-group) with all packets\
| ... | containing Ethernet header, IPv4 header with IP protocol=61 and static\
| ... | payload. MAC addresses ranges are incremented as follows:
| ... | port01_src ca:fe:00:00:00:00 - port01_src ca:fe:00:07:a1:1f,\
| ... | port01_dst fa:ce:00:00:00:00 - port01_dst fa:ce:00:07:a1:1f,\
| ... | port02_src fa:ce:00:00:00:00 - port02_src fa:ce:00:07:a1:1f,\
| ... | port02_dst ca:fe:00:00:00:00 - port02_dst ca:fe:00:07:a1:1f,\
| ... | *[Ref] Applicable standard specifications:* RFC2544.

*** Variables ***
# X710-DA2 bandwidth limit
| ${s_limit}= | ${10000000000}
# Traffic profile:
| ${traffic_profile}= | trex-sl-3n-ethip4-macsrc500kdst500k

*** Keywords ***
| Check RR for L2BD eth-l2bdscale
| | [Documentation]
| | ... | [Cfg] DUT runs L2BD config with ${wt} thread(s), ${wt}\
| | ... | phy core(s), ${rxq} receive queue(s) per NIC port.
| | ... | [Ver] Measure MaxReceivedRate for ${framesize} frames using single\
| | ... | trial throughput test.
| | ...
| | [Arguments] | ${framesize} | ${wt} | ${rxq}
| | ...
| | # Test Variables required for test teardown
| | Set Test Variable | ${framesize}
| | ${get_framesize}= | Get Frame Size | ${framesize}
| | ${max_rate}= | Calculate pps | ${s_limit} | ${get_framesize}
| | ...
| | Given Add '${wt}' worker threads and '${rxq}' rxqueues in 3-node single-link circular topology
| | And Add PCI devices to all DUTs
| | And Run Keyword If | ${get_framesize} < ${1522}
| | ... | Add no multi seg to all DUTs
| | And Apply startup configuration on all VPP DUTs
| | When Initialize L2 bridge domain in 3-node circular topology
| | Then Traffic should pass with maximum rate | ${perf_trial_duration}
| | ... | ${max_rate}pps | ${framesize} | ${traffic_profile}

*** Test Cases ***
| tc01-64B-1t1c-eth-l2bdscale1mmaclrn-mrr
| | [Documentation]
| | ... | [Cfg] DUT runs L2BD switching config with with\
| | ... | 1 thread, 1 phy core, 1 receive queue per NIC port.
| | ... | [Ver] Measure MaxReceivedRate for 64B frames using single trial\
| | ... | throughput test.
| | ...
| | [Tags] | 64B | 1T1C | STHREAD
| | [Template] | Check RR for L2BD eth-l2bdscale
| | framesize=${64} | wt=1 | rxq=1

| tc02-1518B-1t1c-eth-l2bdscale1mmaclrn-mrr
| | [Documentation]
| | ... | [Cfg] DUT runs L2BD switching config with with\
| | ... | 1 thread, 1 phy core, 1 receive queue per NIC port.
| | ... | [Ver] Measure MaxReceivedRate for 1518B frames using single trial\
| | ... | throughput test.
| | ...
| | [Tags] | 1518B | 1T1C | STHREAD
| | ...
| | [Template] | Check RR for L2BD eth-l2bdscale
| | framesize=${1518} | wt=1 | rxq=1

| tc03-9000B-1t1c-eth-l2bdscale1mmaclrn-mrr
| | [Documentation]
| | ... | [Cfg] DUT runs L2BD switching config with with\
| | ... | 1 thread, 1 phy core, 1 receive queue per NIC port.
| | ... | [Ver] Measure MaxReceivedRate for 9000B frames using single trial\
| | ... | throughput test.
| | ...
| | [Tags] | 9000B | 1T1C | STHREAD
| | ...
| | [Template] | Check RR for L2BD eth-l2bdscale
| | framesize=${9000} | wt=1 | rxq=1

| tc04-IMIX-1t1c-eth-l2bdscale1mmaclrn-mrr
| | [Documentation]
| | ... | [Cfg] DUT runs L2BD switching config with with\
| | ... | 1 thread, 1 phy core, 1 receive queue per NIC port.
| | ... | [Ver] Measure MaxReceivedRate for IMIX_v4_1 frames using single trial\
| | ... | throughput test.
| | ... | IMIX_v4_1 = (28x64B; 16x570B; 4x1518B)
| | ...
| | [Tags] | IMIX | 1T1C | STHREAD
| | ...
| | [Template] | Check RR for L2BD eth-l2bdscale
| | framesize=IMIX_v4_1 | wt=1 | rxq=1

| tc05-64B-2t2c-eth-l2bdscale1mmaclrn-mrr
| | [Documentation]
| | ... | [Cfg] DUT runs L2BD switching config with with\
| | ... | 2 threads, 2 phy cores, 1 receive queue per NIC port.
| | ... | [Ver] Measure MaxReceivedRate for 64B frames using single trial\
| | ... | throughput test.
| | ...
| | [Tags] | 64B | 2T2C | MTHREAD
| | ...
| | [Template] | Check RR for L2BD eth-l2bdscale
| | framesize=${64} | wt=2 | rxq=1

| tc06-1518B-2t2c-eth-l2bdscale1mmaclrn-mrr
| | [Documentation]
| | ... | [Cfg] DUT runs L2BD switching config with with\
| | ... | 2 threads, 2 phy cores, 1 receive queue per NIC port.
| | ... | [Ver] Measure MaxReceivedRate for 1518B frames using single trial\
| | ... | throughput test.
| | ...
| | [Tags] | 1518B | 2T2C | MTHREAD
| | ...
| | [Template] | Check RR for L2BD eth-l2bdscale
| | framesize=${1518} | wt=2 | rxq=1

| tc07-9000B-2t2c-eth-l2bdscale1mmaclrn-mrr
| | [Documentation]
| | ... | [Cfg] DUT runs L2BD switching config with with\
| | ... | 2 threads, 2 phy cores, 1 receive queue per NIC port.
| | ... | [Ver] Measure MaxReceivedRate for 9000B frames using single trial\
| | ... | throughput test.
| | ...
| | [Tags] | 9000B | 2T2C | MTHREAD
| | ...
| | [Template] | Check RR for L2BD eth-l2bdscale
| | framesize=${9000} | wt=2 | rxq=1

| tc08-9000B-2t2c-eth-l2bdscale1mmaclrn-mrr
| | [Documentation]
| | ... | [Cfg] DUT runs L2BD switching config with with\
| | ... | 2 threads, 2 phy cores, 1 receive queue per NIC port.
| | ... | [Ver] Measure MaxReceivedRate for IMIX_v4_1 frames using single trial\
| | ... | throughput test.
| | ... | IMIX_v4_1 = (28x64B; 16x570B; 4x1518B)
| | ...
| | [Tags] | IMIX | 2T2C | MTHREAD
| | ...
| | [Template] | Check RR for L2BD eth-l2bdscale
| | framesize=IMIX_v4_1 | wt=2 | rxq=1

| tc09-64B-4t4c-eth-l2bdscale1mmaclrn-mrr
| | [Documentation]
| | ... | [Cfg] DUT runs L2BD switching config with with\
| | ... | 4 threads, 4 phy cores, 2 receive queues per NIC port.
| | ... | [Ver] Measure MaxReceivedRate for 64B frames using single trial\
| | ... | throughput test.
| | ...
| | [Tags] | 64B | 4T4C | MTHREAD
| | ...
| | [Template] | Check RR for L2BD eth-l2bdscale
| | framesize=${64} | wt=4 | rxq=2

| tc10-1518B-4t4c-eth-l2bdscale1mmaclrn-mrr
| | [Documentation]
| | ... | [Cfg] DUT runs L2BD switching config with with\
| | ... | 4 threads, 4 phy cores, 2 receive queues per NIC port.
| | ... | [Ver] Measure MaxReceivedRate for 1518B frames using single trial\
| | ... | throughput test.
| | ...
| | [Tags] | 1518B | 4T4C | MTHREAD
| | ...
| | [Template] | Check RR for L2BD eth-l2bdscale
| | framesize=${1518} | wt=4 | rxq=2

| tc11-9000B-4t4c-eth-l2bdscale1mmaclrn-mrr
| | [Documentation]
| | ... | [Cfg] DUT runs L2BD switching config with with\
| | ... | 4 threads, 4 phy cores, 2 receive queues per NIC port.
| | ... | [Ver] Measure MaxReceivedRate for 9000B frames using single trial\
| | ... | throughput test.
| | ...
| | [Tags] | 9000B | 4T4C | MTHREAD
| | ...
| | [Template] | Check RR for L2BD eth-l2bdscale
| | framesize=${9000} | wt=4 | rxq=2

| tc12-IMIX-4t4c-eth-l2bdscale1mmaclrn-mrr
| | [Documentation]
| | ... | [Cfg] DUT runs L2BD switching config with with\
| | ... | 4 threads, 4 phy cores, 2 receive queues per NIC port.
| | ... | [Ver] Measure MaxReceivedRate for IMIX_v4_1 frames using single trial\
| | ... | throughput test.
| | ... | IMIX_v4_1 = (28x64B; 16x570B; 4x1518B)
| | ...
| | [Tags] | IMIX | 4T4C | MTHREAD
| | ...
| | [Template] | Check RR for L2BD eth-l2bdscale
| | framesize=IMIX_v4_1 | wt=4 | rxq=2
'#n1487'>1487 1488 1489 1490 1491 1492 1493 1494 1495 1496 1497 1498 1499 1500 1501 1502 1503 1504 1505 1506 1507 1508 1509 1510 1511 1512 1513 1514 1515 1516 1517 1518 1519 1520 1521 1522 1523 1524 1525 1526 1527 1528 1529 1530 1531 1532 1533 1534 1535 1536 1537 1538 1539 1540 1541 1542 1543 1544 1545 1546 1547 1548 1549 1550 1551 1552 1553 1554 1555 1556 1557 1558 1559 1560 1561 1562 1563 1564 1565 1566 1567 1568 1569 1570 1571 1572 
/*
 * Copyright (c) 2015 Cisco and/or its affiliates.
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at:
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
/*
 * buffer_funcs.h: VLIB buffer related functions/inlines
 *
 * Copyright (c) 2008 Eliot Dresselhaus
 *
 * Permission is hereby granted, free of charge, to any person obtaining
 * a copy of this software and associated documentation files (the
 * "Software"), to deal in the Software without restriction, including
 * without limitation the rights to use, copy, modify, merge, publish,
 * distribute, sublicense, and/or sell copies of the Software, and to
 * permit persons to whom the Software is furnished to do so, subject to
 * the following conditions:
 *
 * The above copyright notice and this permission notice shall be
 * included in all copies or substantial portions of the Software.
 *
 *  THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
 *  EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
 *  MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
 *  NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
 *  LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
 *  OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
 *  WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
 */

#ifndef included_vlib_buffer_funcs_h
#define included_vlib_buffer_funcs_h

#include <vppinfra/hash.h>
#include <vppinfra/fifo.h>
#include <vppinfra/vector/index_to_ptr.h>
#include <vlib/buffer.h>
#include <vlib/physmem_funcs.h>
#include <vlib/main.h>
#include <vlib/node.h>

/** \file
    vlib buffer access methods.
*/

typedef void (vlib_buffer_enqueue_to_next_fn_t) (vlib_main_t *vm,
						 vlib_node_runtime_t *node,
						 u32 *buffers, u16 *nexts,
						 uword count);
typedef void (vlib_buffer_enqueue_to_next_with_aux_fn_t) (
  vlib_main_t *vm, vlib_node_runtime_t *node, u32 *buffers, u32 *aux_data,
  u16 *nexts, uword count);
typedef void (vlib_buffer_enqueue_to_single_next_fn_t) (
  vlib_main_t *vm, vlib_node_runtime_t *node, u32 *ers, u16 next_index,
  u32 count);

typedef void (vlib_buffer_enqueue_to_single_next_with_aux_fn_t) (
  vlib_main_t *vm, vlib_node_runtime_t *node, u32 *ers, u32 *aux_data,
  u16 next_index, u32 count);

typedef u32 (vlib_buffer_enqueue_to_thread_fn_t) (
  vlib_main_t *vm, vlib_node_runtime_t *node, u32 frame_queue_index,
  u32 *buffer_indices, u16 *thread_indices, u32 n_packets,
  int drop_on_congestion);

typedef u32 (vlib_buffer_enqueue_to_thread_with_aux_fn_t) (
  vlib_main_t *vm, vlib_node_runtime_t *node, u32 frame_queue_index,
  u32 *buffer_indices, u32 *aux, u16 *thread_indices, u32 n_packets,
  int drop_on_congestion);

typedef struct
{
  vlib_buffer_enqueue_to_next_fn_t *buffer_enqueue_to_next_fn;
  vlib_buffer_enqueue_to_next_with_aux_fn_t
    *buffer_enqueue_to_next_with_aux_fn;
  vlib_buffer_enqueue_to_single_next_fn_t *buffer_enqueue_to_single_next_fn;
  vlib_buffer_enqueue_to_single_next_with_aux_fn_t
    *buffer_enqueue_to_single_next_with_aux_fn;
  vlib_buffer_enqueue_to_thread_fn_t *buffer_enqueue_to_thread_fn;
  vlib_buffer_enqueue_to_thread_with_aux_fn_t
    *buffer_enqueue_to_thread_with_aux_fn;
} vlib_buffer_func_main_t;

extern vlib_buffer_func_main_t vlib_buffer_func_main;

always_inline void
vlib_buffer_validate (vlib_main_t * vm, vlib_buffer_t * b)
{
  vlib_buffer_main_t *bm = vm->buffer_main;
  vlib_buffer_pool_t *bp;

  /* reference count in allocated buffer always must be 1 or higher */
  ASSERT (b->ref_count > 0);

  /* verify that buffer pool index is valid */
  bp = vec_elt_at_index (bm->buffer_pools, b->buffer_pool_index);
  ASSERT (pointer_to_uword (b) >= bp->start);
  ASSERT (pointer_to_uword (b) < bp->start + bp->size -
	  (bp->data_size + sizeof (vlib_buffer_t)));
}

always_inline void *
vlib_buffer_ptr_from_index (uword buffer_mem_start, u32 buffer_index,
			    uword offset)
{
  offset += ((uword) buffer_index) << CLIB_LOG2_CACHE_LINE_BYTES;
  return uword_to_pointer (buffer_mem_start + offset, vlib_buffer_t *);
}

/** \brief Translate buffer index into buffer pointer

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param buffer_index - (u32) buffer index
    @return - (vlib_buffer_t *) buffer pointer
*/
always_inline vlib_buffer_t *
vlib_get_buffer (vlib_main_t * vm, u32 buffer_index)
{
  vlib_buffer_main_t *bm = vm->buffer_main;
  vlib_buffer_t *b;

  b = vlib_buffer_ptr_from_index (bm->buffer_mem_start, buffer_index, 0);
  vlib_buffer_validate (vm, b);
  return b;
}

static_always_inline u32
vlib_buffer_get_default_data_size (vlib_main_t * vm)
{
  return vm->buffer_main->default_data_size;
}

static_always_inline void
vlib_buffer_copy_indices (u32 * dst, u32 * src, u32 n_indices)
{
  clib_memcpy_u32 (dst, src, n_indices);
}

always_inline void
vlib_buffer_copy_indices_from_ring (u32 * dst, u32 * ring, u32 start,
				    u32 ring_size, u32 n_buffers)
{
  ASSERT (n_buffers <= ring_size);

  if (PREDICT_TRUE (start + n_buffers <= ring_size))
    {
      vlib_buffer_copy_indices (dst, ring + start, n_buffers);
    }
  else
    {
      u32 n = ring_size - start;
      vlib_buffer_copy_indices (dst, ring + start, n);
      vlib_buffer_copy_indices (dst + n, ring, n_buffers - n);
    }
}

always_inline void
vlib_buffer_copy_indices_to_ring (u32 * ring, u32 * src, u32 start,
				  u32 ring_size, u32 n_buffers)
{
  ASSERT (n_buffers <= ring_size);

  if (PREDICT_TRUE (start + n_buffers <= ring_size))
    {
      vlib_buffer_copy_indices (ring + start, src, n_buffers);
    }
  else
    {
      u32 n = ring_size - start;
      vlib_buffer_copy_indices (ring + start, src, n);
      vlib_buffer_copy_indices (ring, src + n, n_buffers - n);
    }
}

STATIC_ASSERT_OFFSET_OF (vlib_buffer_t, template_end, 64);
static_always_inline void
vlib_buffer_copy_template (vlib_buffer_t * b, vlib_buffer_t * bt)
{
#if defined CLIB_HAVE_VEC512
  b->as_u8x64[0] = bt->as_u8x64[0];
#elif defined (CLIB_HAVE_VEC256)
  b->as_u8x32[0] = bt->as_u8x32[0];
  b->as_u8x32[1] = bt->as_u8x32[1];
#elif defined (CLIB_HAVE_VEC128)
  b->as_u8x16[0] = bt->as_u8x16[0];
  b->as_u8x16[1] = bt->as_u8x16[1];
  b->as_u8x16[2] = bt->as_u8x16[2];
  b->as_u8x16[3] = bt->as_u8x16[3];
#else
  clib_memcpy_fast (b, bt, 64);
#endif
}

always_inline u8
vlib_buffer_pool_get_default_for_numa (vlib_main_t * vm, u32 numa_node)
{
  ASSERT (numa_node < VLIB_BUFFER_MAX_NUMA_NODES);
  return vm->buffer_main->default_buffer_pool_index_for_numa[numa_node];
}

/** \brief Translate array of buffer indices into buffer pointers with offset

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param bi - (u32 *) array of buffer indices
    @param b - (void **) array to store buffer pointers
    @param count - (uword) number of elements
    @param offset - (i32) offset applied to each pointer
*/
static_always_inline void
vlib_get_buffers_with_offset (vlib_main_t *vm, u32 *bi, void **b, u32 count,
			      i32 offset)
{
  uword buffer_mem_start = vm->buffer_main->buffer_mem_start;
  void *base = (void *) (buffer_mem_start + offset);
  int objsize = __builtin_object_size (b, 0);
  const int sh = CLIB_LOG2_CACHE_LINE_BYTES;

  if (COMPILE_TIME_CONST (count) == 0 && objsize >= 64 * sizeof (b[0]) &&
      (objsize & ((8 * sizeof (b[0])) - 1)) == 0)
    {
      u32 n = round_pow2 (count, 8);
      ASSERT (objsize >= count);
      CLIB_ASSUME (objsize >= count);
      while (n >= 64)
	{
	  clib_index_to_ptr_u32 (bi, base, sh, b, 64);
	  b += 64;
	  bi += 64;
	  n -= 64;
	}

      while (n)
	{
	  clib_index_to_ptr_u32 (bi, base, sh, b, 8);
	  b += 8;
	  bi += 8;
	  n -= 8;
	}
    }
  else
    clib_index_to_ptr_u32 (bi, base, sh, b, count);
}

/** \brief Translate array of buffer indices into buffer pointers

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param bi - (u32 *) array of buffer indices
    @param b - (vlib_buffer_t **) array to store buffer pointers
    @param count - (uword) number of elements
*/

static_always_inline void
vlib_get_buffers (vlib_main_t *vm, u32 *bi, vlib_buffer_t **b, u32 count)
{
  vlib_get_buffers_with_offset (vm, bi, (void **) b, count, 0);
}

/** \brief Translate buffer pointer into buffer index

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param p - (void *) buffer pointer
    @return - (u32) buffer index
*/

always_inline u32
vlib_get_buffer_index (vlib_main_t * vm, void *p)
{
  vlib_buffer_main_t *bm = vm->buffer_main;
  uword offset = pointer_to_uword (p) - bm->buffer_mem_start;
  ASSERT (pointer_to_uword (p) >= bm->buffer_mem_start);
  ASSERT (offset < bm->buffer_mem_size);
  ASSERT ((offset % (1 << CLIB_LOG2_CACHE_LINE_BYTES)) == 0);
  return offset >> CLIB_LOG2_CACHE_LINE_BYTES;
}

/** \brief Translate array of buffer pointers into buffer indices with offset

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param b - (void **) array of buffer pointers
    @param bi - (u32 *) array to store buffer indices
    @param count - (uword) number of elements
    @param offset - (i32) offset applied to each pointer
*/
static_always_inline void
vlib_get_buffer_indices_with_offset (vlib_main_t * vm, void **b, u32 * bi,
				     uword count, i32 offset)
{
#ifdef CLIB_HAVE_VEC256
  u32x8 mask = { 0, 2, 4, 6, 1, 3, 5, 7 };
  u64x4 off4 = u64x4_splat (vm->buffer_main->buffer_mem_start - offset);

  while (count >= 8)
    {
      /* load 4 pointers into 256-bit register */
      u64x4 v0 = u64x4_load_unaligned (b);
      u64x4 v1 = u64x4_load_unaligned (b + 4);
      u32x8 v2, v3;

      v0 -= off4;
      v1 -= off4;

      v0 >>= CLIB_LOG2_CACHE_LINE_BYTES;
      v1 >>= CLIB_LOG2_CACHE_LINE_BYTES;

      /* permute 256-bit register so lower u32s of each buffer index are
       * placed into lower 128-bits */
      v2 = u32x8_permute ((u32x8) v0, mask);
      v3 = u32x8_permute ((u32x8) v1, mask);

      /* extract lower 128-bits and save them to the array of buffer indices */
      u32x4_store_unaligned (u32x8_extract_lo (v2), bi);
      u32x4_store_unaligned (u32x8_extract_lo (v3), bi + 4);
      bi += 8;
      b += 8;
      count -= 8;
    }
#endif
  while (count >= 4)
    {
      /* equivalent non-nector implementation */
      bi[0] = vlib_get_buffer_index (vm, ((u8 *) b[0]) + offset);
      bi[1] = vlib_get_buffer_index (vm, ((u8 *) b[1]) + offset);
      bi[2] = vlib_get_buffer_index (vm, ((u8 *) b[2]) + offset);
      bi[3] = vlib_get_buffer_index (vm, ((u8 *) b[3]) + offset);
      bi += 4;
      b += 4;
      count -= 4;
    }
  while (count)
    {
      bi[0] = vlib_get_buffer_index (vm, ((u8 *) b[0]) + offset);
      bi += 1;
      b += 1;
      count -= 1;
    }
}

/** \brief Translate array of buffer pointers into buffer indices

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param b - (vlib_buffer_t **) array of buffer pointers
    @param bi - (u32 *) array to store buffer indices
    @param count - (uword) number of elements
*/
static_always_inline void
vlib_get_buffer_indices (vlib_main_t * vm, vlib_buffer_t ** b, u32 * bi,
			 uword count)
{
  vlib_get_buffer_indices_with_offset (vm, (void **) b, bi, count, 0);
}

/** \brief Get next buffer in buffer linklist, or zero for end of list.

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param b - (void *) buffer pointer
    @return - (vlib_buffer_t *) next buffer, or NULL
*/
always_inline vlib_buffer_t *
vlib_get_next_buffer (vlib_main_t * vm, vlib_buffer_t * b)
{
  return (b->flags & VLIB_BUFFER_NEXT_PRESENT
	  ? vlib_get_buffer (vm, b->next_buffer) : 0);
}

uword vlib_buffer_length_in_chain_slow_path (vlib_main_t * vm,
					     vlib_buffer_t * b_first);

/** \brief Get length in bytes of the buffer chain

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param b - (void *) buffer pointer
    @return - (uword) length of buffer chain
*/
always_inline uword
vlib_buffer_length_in_chain (vlib_main_t * vm, vlib_buffer_t * b)
{
  uword len = b->current_length;

  if (PREDICT_TRUE ((b->flags & VLIB_BUFFER_NEXT_PRESENT) == 0))
    return len;

  if (PREDICT_TRUE (b->flags & VLIB_BUFFER_TOTAL_LENGTH_VALID))
    return len + b->total_length_not_including_first_buffer;

  return vlib_buffer_length_in_chain_slow_path (vm, b);
}

/** \brief Get length in bytes of the buffer index buffer chain

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param bi - (u32) buffer index
    @return - (uword) length of buffer chain
*/
always_inline uword
vlib_buffer_index_length_in_chain (vlib_main_t * vm, u32 bi)
{
  vlib_buffer_t *b = vlib_get_buffer (vm, bi);
  return vlib_buffer_length_in_chain (vm, b);
}

/** \brief Copy buffer contents to memory

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param buffer_index - (u32) buffer index
    @param contents - (u8 *) memory, <strong>must be large enough</strong>
    @return - (uword) length of buffer chain
*/
always_inline uword
vlib_buffer_contents (vlib_main_t * vm, u32 buffer_index, u8 * contents)
{
  uword content_len = 0;
  uword l;
  vlib_buffer_t *b;

  while (1)
    {
      b = vlib_get_buffer (vm, buffer_index);
      l = b->current_length;
      clib_memcpy_fast (contents + content_len, b->data + b->current_data, l);
      content_len += l;
      if (!(b->flags & VLIB_BUFFER_NEXT_PRESENT))
	break;
      buffer_index = b->next_buffer;
    }

  return content_len;
}

always_inline uword
vlib_buffer_get_pa (vlib_main_t * vm, vlib_buffer_t * b)
{
  return vlib_physmem_get_pa (vm, b->data);
}

always_inline uword
vlib_buffer_get_current_pa (vlib_main_t * vm, vlib_buffer_t * b)
{
  return vlib_buffer_get_pa (vm, b) + b->current_data;
}

/** \brief Prefetch buffer metadata by buffer index
    The first 64 bytes of buffer contains most header information

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param bi - (u32) buffer index
    @param type - LOAD, STORE. In most cases, STORE is the right answer
*/
/* Prefetch buffer header given index. */
#define vlib_prefetch_buffer_with_index(vm,bi,type)	\
  do {							\
    vlib_buffer_t * _b = vlib_get_buffer (vm, bi);	\
    vlib_prefetch_buffer_header (_b, type);		\
  } while (0)

typedef enum
{
  /* Index is unknown. */
  VLIB_BUFFER_UNKNOWN,

  /* Index is known and free/allocated. */
  VLIB_BUFFER_KNOWN_FREE,
  VLIB_BUFFER_KNOWN_ALLOCATED,
} vlib_buffer_known_state_t;

void vlib_buffer_validate_alloc_free (vlib_main_t * vm, u32 * buffers,
				      uword n_buffers,
				      vlib_buffer_known_state_t
				      expected_state);

always_inline vlib_buffer_known_state_t
vlib_buffer_is_known (vlib_main_t * vm, u32 buffer_index)
{
  vlib_buffer_main_t *bm = vm->buffer_main;

  clib_spinlock_lock (&bm->buffer_known_hash_lockp);
  uword *p = hash_get (bm->buffer_known_hash, buffer_index);
  clib_spinlock_unlock (&bm->buffer_known_hash_lockp);
  return p ? p[0] : VLIB_BUFFER_UNKNOWN;
}

/* Validates sanity of a single buffer.
   Returns format'ed vector with error message if any. */
u8 *vlib_validate_buffer (vlib_main_t * vm, u32 buffer_index,
			  uword follow_chain);

u8 *vlib_validate_buffers (vlib_main_t * vm,
			   u32 * buffers,
			   uword next_buffer_stride,
			   uword n_buffers,
			   vlib_buffer_known_state_t known_state,
			   uword follow_buffer_next);

static_always_inline vlib_buffer_pool_t *
vlib_get_buffer_pool (vlib_main_t * vm, u8 buffer_pool_index)
{
  vlib_buffer_main_t *bm = vm->buffer_main;
  return vec_elt_at_index (bm->buffer_pools, buffer_pool_index);
}

static_always_inline __clib_warn_unused_result uword
vlib_buffer_pool_get (vlib_main_t * vm, u8 buffer_pool_index, u32 * buffers,
		      u32 n_buffers)
{
  vlib_buffer_pool_t *bp = vlib_get_buffer_pool (vm, buffer_pool_index);
  u32 len;

  ASSERT (bp->buffers);

  clib_spinlock_lock (&bp->lock);
  len = bp->n_avail;
  if (PREDICT_TRUE (n_buffers < len))
    {
      len -= n_buffers;
      vlib_buffer_copy_indices (buffers, bp->buffers + len, n_buffers);
      bp->n_avail = len;
      clib_spinlock_unlock (&bp->lock);
      return n_buffers;
    }
  else
    {
      vlib_buffer_copy_indices (buffers, bp->buffers, len);
      bp->n_avail = 0;
      clib_spinlock_unlock (&bp->lock);
      return len;
    }
}


/** \brief Allocate buffers from specific pool into supplied array

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param buffers - (u32 * ) buffer index array
    @param n_buffers - (u32) number of buffers requested
    @return - (u32) number of buffers actually allocated, may be
    less than the number requested or zero
*/

always_inline __clib_warn_unused_result u32
vlib_buffer_alloc_from_pool (vlib_main_t * vm, u32 * buffers, u32 n_buffers,
			     u8 buffer_pool_index)
{
  vlib_buffer_main_t *bm = vm->buffer_main;
  vlib_buffer_pool_t *bp;
  vlib_buffer_pool_thread_t *bpt;
  u32 *src, *dst, len, n_left;

  /* If buffer allocation fault injection is configured */
  if (VLIB_BUFFER_ALLOC_FAULT_INJECTOR > 0)
    {
      u32 vlib_buffer_alloc_may_fail (vlib_main_t *, u32);

      /* See how many buffers we're willing to allocate */
      n_buffers = vlib_buffer_alloc_may_fail (vm, n_buffers);
      if (n_buffers == 0)
	return (n_buffers);
    }

  bp = vec_elt_at_index (bm->buffer_pools, buffer_pool_index);
  bpt = vec_elt_at_index (bp->threads, vm->thread_index);

  dst = buffers;
  n_left = n_buffers;
  len = bpt->n_cached;

  /* per-thread cache contains enough buffers */
  if (len >= n_buffers)
    {
      src = bpt->cached_buffers + len - n_buffers;
      vlib_buffer_copy_indices (dst, src, n_buffers);
      bpt->n_cached -= n_buffers;
      goto done;
    }

  /* alloc bigger than cache - take buffers directly from main pool */
  if (n_buffers >= VLIB_BUFFER_POOL_PER_THREAD_CACHE_SZ)
    {
      n_buffers = vlib_buffer_pool_get (vm, buffer_pool_index, buffers,
					n_buffers);
      goto done;
    }

  /* take everything available in the cache */
  if (len)
    {
      vlib_buffer_copy_indices (dst, bpt->cached_buffers, len);
      bpt->n_cached = 0;
      dst += len;
      n_left -= len;
    }

  len = round_pow2 (n_left, 32);
  len = vlib_buffer_pool_get (vm, buffer_pool_index, bpt->cached_buffers,
			      len);
  bpt->n_cached = len;

  if (len)
    {
      u32 n_copy = clib_min (len, n_left);
      src = bpt->cached_buffers + len - n_copy;
      vlib_buffer_copy_indices (dst, src, n_copy);
      bpt->n_cached -= n_copy;
      n_left -= n_copy;
    }

  n_buffers -= n_left;

done:
  /* Verify that buffers are known free. */
  if (CLIB_DEBUG > 0)
    vlib_buffer_validate_alloc_free (vm, buffers, n_buffers,
				     VLIB_BUFFER_KNOWN_FREE);
  if (PREDICT_FALSE (bm->alloc_callback_fn != 0))
    bm->alloc_callback_fn (vm, buffer_pool_index, buffers, n_buffers);
  return n_buffers;
}

/** \brief Allocate buffers from specific numa node into supplied array

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param buffers - (u32 * ) buffer index array
    @param n_buffers - (u32) number of buffers requested
    @param numa_node - (u32) numa node
    @return - (u32) number of buffers actually allocated, may be
    less than the number requested or zero
*/
always_inline __clib_warn_unused_result u32
vlib_buffer_alloc_on_numa (vlib_main_t * vm, u32 * buffers, u32 n_buffers,
			   u32 numa_node)
{
  u8 index = vlib_buffer_pool_get_default_for_numa (vm, numa_node);
  return vlib_buffer_alloc_from_pool (vm, buffers, n_buffers, index);
}

/** \brief Allocate buffers into supplied array

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param buffers - (u32 * ) buffer index array
    @param n_buffers - (u32) number of buffers requested
    @return - (u32) number of buffers actually allocated, may be
    less than the number requested or zero
*/

always_inline __clib_warn_unused_result u32
vlib_buffer_alloc (vlib_main_t * vm, u32 * buffers, u32 n_buffers)
{
  return vlib_buffer_alloc_on_numa (vm, buffers, n_buffers, vm->numa_node);
}

/** \brief Allocate buffers into ring

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param buffers - (u32 * ) buffer index ring
    @param start - (u32) first slot in the ring
    @param ring_size - (u32) ring size
    @param n_buffers - (u32) number of buffers requested
    @return - (u32) number of buffers actually allocated, may be
    less than the number requested or zero
*/
always_inline __clib_warn_unused_result u32
vlib_buffer_alloc_to_ring (vlib_main_t * vm, u32 * ring, u32 start,
			   u32 ring_size, u32 n_buffers)
{
  u32 n_alloc;

  ASSERT (n_buffers <= ring_size);

  if (PREDICT_TRUE (start + n_buffers <= ring_size))
    return vlib_buffer_alloc (vm, ring + start, n_buffers);

  n_alloc = vlib_buffer_alloc (vm, ring + start, ring_size - start);

  if (PREDICT_TRUE (n_alloc == ring_size - start))
    n_alloc += vlib_buffer_alloc (vm, ring, n_buffers - n_alloc);

  return n_alloc;
}

/** \brief Allocate buffers into ring from specific buffer pool

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param buffers - (u32 * ) buffer index ring
    @param start - (u32) first slot in the ring
    @param ring_size - (u32) ring size
    @param n_buffers - (u32) number of buffers requested
    @return - (u32) number of buffers actually allocated, may be
    less than the number requested or zero
*/
always_inline __clib_warn_unused_result u32
vlib_buffer_alloc_to_ring_from_pool (vlib_main_t * vm, u32 * ring, u32 start,
				     u32 ring_size, u32 n_buffers,
				     u8 buffer_pool_index)
{
  u32 n_alloc;

  ASSERT (n_buffers <= ring_size);

  if (PREDICT_TRUE (start + n_buffers <= ring_size))
    return vlib_buffer_alloc_from_pool (vm, ring + start, n_buffers,
					buffer_pool_index);

  n_alloc = vlib_buffer_alloc_from_pool (vm, ring + start, ring_size - start,
					 buffer_pool_index);

  if (PREDICT_TRUE (n_alloc == ring_size - start))
    n_alloc += vlib_buffer_alloc_from_pool (vm, ring, n_buffers - n_alloc,
					    buffer_pool_index);

  return n_alloc;
}

static_always_inline void
vlib_buffer_pool_put (vlib_main_t * vm, u8 buffer_pool_index,
		      u32 * buffers, u32 n_buffers)
{
  vlib_buffer_main_t *bm = vm->buffer_main;
  vlib_buffer_pool_t *bp = vlib_get_buffer_pool (vm, buffer_pool_index);
  vlib_buffer_pool_thread_t *bpt = vec_elt_at_index (bp->threads,
						     vm->thread_index);
  u32 n_cached, n_empty;

  if (CLIB_DEBUG > 0)
    vlib_buffer_validate_alloc_free (vm, buffers, n_buffers,
				     VLIB_BUFFER_KNOWN_ALLOCATED);
  if (PREDICT_FALSE (bm->free_callback_fn != 0))
    bm->free_callback_fn (vm, buffer_pool_index, buffers, n_buffers);

  n_cached = bpt->n_cached;
  n_empty = VLIB_BUFFER_POOL_PER_THREAD_CACHE_SZ - n_cached;
  if (n_buffers <= n_empty)
    {
      vlib_buffer_copy_indices (bpt->cached_buffers + n_cached,
				buffers, n_buffers);
      bpt->n_cached = n_cached + n_buffers;
      return;
    }

  vlib_buffer_copy_indices (bpt->cached_buffers + n_cached,
			    buffers + n_buffers - n_empty, n_empty);
  bpt->n_cached = VLIB_BUFFER_POOL_PER_THREAD_CACHE_SZ;

  clib_spinlock_lock (&bp->lock);
  vlib_buffer_copy_indices (bp->buffers + bp->n_avail, buffers,
			    n_buffers - n_empty);
  bp->n_avail += n_buffers - n_empty;
  clib_spinlock_unlock (&bp->lock);
}

static_always_inline void
vlib_buffer_free_inline (vlib_main_t * vm, u32 * buffers, u32 n_buffers,
			 int maybe_next)
{
  const int queue_size = 128;
  vlib_buffer_pool_t *bp = 0;
  u8 buffer_pool_index = ~0;
  u32 n_queue = 0, queue[queue_size + 4];
  vlib_buffer_t bt = { };
#if defined(CLIB_HAVE_VEC128)
  vlib_buffer_t bpi_mask = {.buffer_pool_index = ~0 };
  vlib_buffer_t bpi_vec = {};
  vlib_buffer_t flags_refs_mask = {
    .flags = VLIB_BUFFER_NEXT_PRESENT,
    .ref_count = ~1
  };
#endif

  if (PREDICT_FALSE (n_buffers == 0))
    return;

  vlib_buffer_t *b = vlib_get_buffer (vm, buffers[0]);
  buffer_pool_index = b->buffer_pool_index;
  bp = vlib_get_buffer_pool (vm, buffer_pool_index);
  vlib_buffer_copy_template (&bt, &bp->buffer_template);
#if defined(CLIB_HAVE_VEC128)
  bpi_vec.buffer_pool_index = buffer_pool_index;
#endif

  while (n_buffers)
    {
      vlib_buffer_t *b[8];
      u32 bi, sum = 0, flags, next;

      if (n_buffers < 4)
	goto one_by_one;

      vlib_get_buffers (vm, buffers, b, 4);

      if (n_buffers >= 12)
	{
	  vlib_get_buffers (vm, buffers + 8, b + 4, 4);
	  vlib_prefetch_buffer_header (b[4], LOAD);
	  vlib_prefetch_buffer_header (b[5], LOAD);
	  vlib_prefetch_buffer_header (b[6], LOAD);
	  vlib_prefetch_buffer_header (b[7], LOAD);
	}

#if defined(CLIB_HAVE_VEC128)
      u8x16 p0, p1, p2, p3, r;
      p0 = u8x16_load_unaligned (b[0]);
      p1 = u8x16_load_unaligned (b[1]);
      p2 = u8x16_load_unaligned (b[2]);
      p3 = u8x16_load_unaligned (b[3]);

      r = p0 ^ bpi_vec.as_u8x16[0];
      r |= p1 ^ bpi_vec.as_u8x16[0];
      r |= p2 ^ bpi_vec.as_u8x16[0];
      r |= p3 ^ bpi_vec.as_u8x16[0];
      r &= bpi_mask.as_u8x16[0];
      r |= (p0 | p1 | p2 | p3) & flags_refs_mask.as_u8x16[0];

      sum = !u8x16_is_all_zero (r);
#else
      sum |= b[0]->flags;
      sum |= b[1]->flags;
      sum |= b[2]->flags;
      sum |= b[3]->flags;
      sum &= VLIB_BUFFER_NEXT_PRESENT;
      sum += b[0]->ref_count - 1;
      sum += b[1]->ref_count - 1;
      sum += b[2]->ref_count - 1;
      sum += b[3]->ref_count - 1;
      sum |= b[0]->buffer_pool_index ^ buffer_pool_index;
      sum |= b[1]->buffer_pool_index ^ buffer_pool_index;
      sum |= b[2]->buffer_pool_index ^ buffer_pool_index;
      sum |= b[3]->buffer_pool_index ^ buffer_pool_index;
#endif

      if (sum)
	goto one_by_one;

      vlib_buffer_copy_indices (queue + n_queue, buffers, 4);
      vlib_buffer_copy_template (b[0], &bt);
      vlib_buffer_copy_template (b[1], &bt);
      vlib_buffer_copy_template (b[2], &bt);
      vlib_buffer_copy_template (b[3], &bt);
      n_queue += 4;

      vlib_buffer_validate (vm, b[0]);
      vlib_buffer_validate (vm, b[1]);
      vlib_buffer_validate (vm, b[2]);
      vlib_buffer_validate (vm, b[3]);

      VLIB_BUFFER_TRACE_TRAJECTORY_INIT (b[0]);
      VLIB_BUFFER_TRACE_TRAJECTORY_INIT (b[1]);
      VLIB_BUFFER_TRACE_TRAJECTORY_INIT (b[2]);
      VLIB_BUFFER_TRACE_TRAJECTORY_INIT (b[3]);

      if (n_queue >= queue_size)
	{
	  vlib_buffer_pool_put (vm, buffer_pool_index, queue, n_queue);
	  n_queue = 0;
	}
      buffers += 4;
      n_buffers -= 4;
      continue;

    one_by_one:
      bi = buffers[0];

    next_in_chain:
      b[0] = vlib_get_buffer (vm, bi);
      flags = b[0]->flags;
      next = b[0]->next_buffer;

      if (PREDICT_FALSE (buffer_pool_index != b[0]->buffer_pool_index))
	{

	  if (n_queue)
	    {
	      vlib_buffer_pool_put (vm, buffer_pool_index, queue, n_queue);
	      n_queue = 0;
	    }

	  buffer_pool_index = b[0]->buffer_pool_index;
#if defined(CLIB_HAVE_VEC128)
	  bpi_vec.buffer_pool_index = buffer_pool_index;
#endif
	  bp = vlib_get_buffer_pool (vm, buffer_pool_index);
	  vlib_buffer_copy_template (&bt, &bp->buffer_template);
	}

      vlib_buffer_validate (vm, b[0]);

      VLIB_BUFFER_TRACE_TRAJECTORY_INIT (b[0]);

      if (clib_atomic_sub_fetch (&b[0]->ref_count, 1) == 0)
	{
	  vlib_buffer_copy_template (b[0], &bt);
	  queue[n_queue++] = bi;
	}

      if (n_queue == queue_size)
	{
	  vlib_buffer_pool_put (vm, buffer_pool_index, queue, queue_size);
	  n_queue = 0;
	}

      if (maybe_next && (flags & VLIB_BUFFER_NEXT_PRESENT))
	{
	  bi = next;
	  goto next_in_chain;
	}

      buffers++;
      n_buffers--;
    }

  if (n_queue)
    vlib_buffer_pool_put (vm, buffer_pool_index, queue, n_queue);
}


/** \brief Free buffers
    Frees the entire buffer chain for each buffer

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param buffers - (u32 * ) buffer index array
    @param n_buffers - (u32) number of buffers to free

*/
always_inline void
vlib_buffer_free (vlib_main_t * vm,
		  /* pointer to first buffer */
		  u32 * buffers,
		  /* number of buffers to free */
		  u32 n_buffers)
{
  vlib_buffer_free_inline (vm, buffers, n_buffers, /* maybe next */ 1);
}

/** \brief Free buffers, does not free the buffer chain for each buffer

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param buffers - (u32 * ) buffer index array
    @param n_buffers - (u32) number of buffers to free

*/
always_inline void
vlib_buffer_free_no_next (vlib_main_t * vm,
			  /* pointer to first buffer */
			  u32 * buffers,
			  /* number of buffers to free */
			  u32 n_buffers)
{
  vlib_buffer_free_inline (vm, buffers, n_buffers, /* maybe next */ 0);
}

/** \brief Free one buffer
    Shorthand to free a single buffer chain.

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param buffer_index - (u32) buffer index to free
*/
always_inline void
vlib_buffer_free_one (vlib_main_t * vm, u32 buffer_index)
{
  vlib_buffer_free_inline (vm, &buffer_index, 1, /* maybe next */ 1);
}

/** \brief Free buffers from ring

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param buffers - (u32 * ) buffer index ring
    @param start - (u32) first slot in the ring
    @param ring_size - (u32) ring size
    @param n_buffers - (u32) number of buffers
*/
always_inline void
vlib_buffer_free_from_ring (vlib_main_t * vm, u32 * ring, u32 start,
			    u32 ring_size, u32 n_buffers)
{
  ASSERT (n_buffers <= ring_size);

  if (PREDICT_TRUE (start + n_buffers <= ring_size))
    {
      vlib_buffer_free (vm, ring + start, n_buffers);
    }
  else
    {
      vlib_buffer_free (vm, ring + start, ring_size - start);
      vlib_buffer_free (vm, ring, n_buffers - (ring_size - start));
    }
}

/** \brief Free buffers from ring without freeing tail buffers

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param buffers - (u32 * ) buffer index ring
    @param start - (u32) first slot in the ring
    @param ring_size - (u32) ring size
    @param n_buffers - (u32) number of buffers
*/
always_inline void
vlib_buffer_free_from_ring_no_next (vlib_main_t * vm, u32 * ring, u32 start,
				    u32 ring_size, u32 n_buffers)
{
  ASSERT (n_buffers <= ring_size);

  if (PREDICT_TRUE (start + n_buffers <= ring_size))
    {
      vlib_buffer_free_no_next (vm, ring + start, n_buffers);
    }
  else
    {
      vlib_buffer_free_no_next (vm, ring + start, ring_size - start);
      vlib_buffer_free_no_next (vm, ring, n_buffers - (ring_size - start));
    }
}

/* Append given data to end of buffer, possibly allocating new buffers. */
int vlib_buffer_add_data (vlib_main_t * vm, u32 * buffer_index, void *data,
			  u32 n_data_bytes);

/* Define vlib_buffer and vnet_buffer flags bits preserved for copy/clone */
#define VLIB_BUFFER_COPY_CLONE_FLAGS_MASK                     	\
  (VLIB_BUFFER_NEXT_PRESENT | VLIB_BUFFER_TOTAL_LENGTH_VALID |	\
   VLIB_BUFFER_IS_TRACED | ~VLIB_BUFFER_FLAGS_ALL)

/* duplicate all buffers in chain */
always_inline vlib_buffer_t *
vlib_buffer_copy (vlib_main_t * vm, vlib_buffer_t * b)
{
  vlib_buffer_t *s, *d, *fd;
  uword n_alloc, n_buffers = 1;
  u32 flag_mask = VLIB_BUFFER_COPY_CLONE_FLAGS_MASK;
  int i;

  s = b;
  while (s->flags & VLIB_BUFFER_NEXT_PRESENT)
    {
      n_buffers++;
      s = vlib_get_buffer (vm, s->next_buffer);
    }
  u32 new_buffers[n_buffers];

  n_alloc = vlib_buffer_alloc (vm, new_buffers, n_buffers);

  /* No guarantee that we'll get all the buffers we asked for */
  if (PREDICT_FALSE (n_alloc < n_buffers))
    {
      if (n_alloc > 0)
	vlib_buffer_free (vm, new_buffers, n_alloc);
      return 0;
    }

  /* 1st segment */
  s = b;
  fd = d = vlib_get_buffer (vm, new_buffers[0]);
  d->current_data = s->current_data;
  d->current_length = s->current_length;
  d->flags = s->flags & flag_mask;
  d->trace_handle = s->trace_handle;
  d->total_length_not_including_first_buffer =
    s->total_length_not_including_first_buffer;
  clib_memcpy_fast (d->opaque, s->opaque, sizeof (s->opaque));
  clib_memcpy_fast (d->opaque2, s->opaque2, sizeof (s->opaque2));
  clib_memcpy_fast (vlib_buffer_get_current (d),
		    vlib_buffer_get_current (s), s->current_length);

  /* next segments */
  for (i = 1; i < n_buffers; i++)
    {
      /* previous */
      d->next_buffer = new_buffers[i];
      /* current */
      s = vlib_get_buffer (vm, s->next_buffer);
      d = vlib_get_buffer (vm, new_buffers[i]);
      d->current_data = s->current_data;
      d->current_length = s->current_length;
      clib_memcpy_fast (vlib_buffer_get_current (d),
			vlib_buffer_get_current (s), s->current_length);
      d->flags = s->flags & flag_mask;
    }

  return fd;
}

/* duplicate first buffer in chain */
always_inline vlib_buffer_t *
vlib_buffer_copy_no_chain (vlib_main_t * vm, vlib_buffer_t * b, u32 * di)
{
  vlib_buffer_t *d;

  if ((vlib_buffer_alloc (vm, di, 1)) != 1)
    return 0;

  d = vlib_get_buffer (vm, *di);
  /* 1st segment */
  d->current_data = b->current_data;
  d->current_length = b->current_length;
  clib_memcpy_fast (d->opaque, b->opaque, sizeof (b->opaque));
  clib_memcpy_fast (d->opaque2, b->opaque2, sizeof (b->opaque2));
  clib_memcpy_fast (vlib_buffer_get_current (d),
		    vlib_buffer_get_current (b), b->current_length);

  return d;
}

/*  \brief Move packet from current position to offset position in buffer.
    Only work for small packet using one buffer with room to fit the move
    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param b -  (vlib_buffer_t *) pointer to buffer
    @param offset - (i16) position to move the packet in buffer
 */
always_inline void
vlib_buffer_move (vlib_main_t * vm, vlib_buffer_t * b, i16 offset)
{
  ASSERT ((b->flags & VLIB_BUFFER_NEXT_PRESENT) == 0);
  ASSERT (offset + VLIB_BUFFER_PRE_DATA_SIZE >= 0);
  ASSERT (offset + b->current_length <
	  vlib_buffer_get_default_data_size (vm));

  u8 *source = vlib_buffer_get_current (b);
  b->current_data = offset;
  u8 *destination = vlib_buffer_get_current (b);
  u16 length = b->current_length;

  if (source + length <= destination)	/* no overlap */
    clib_memcpy_fast (destination, source, length);
  else
    memmove (destination, source, length);
}

/** \brief Create a maximum of 256 clones of buffer and store them
    in the supplied array

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param src_buffer - (u32) source buffer index
    @param buffers - (u32 * ) buffer index array
    @param n_buffers - (u16) number of buffer clones requested (<=256)
    @param head_end_offset - (u16) offset relative to current position
           where packet head ends
    @param offset - (i16) copy packet head at current position if 0,
           else at offset position to change headroom space as specified
    @return - (u16) number of buffers actually cloned, may be
    less than the number requested or zero
*/
always_inline u16
vlib_buffer_clone_256 (vlib_main_t * vm, u32 src_buffer, u32 * buffers,
		       u16 n_buffers, u16 head_end_offset, i16 offset)
{
  u16 i;
  vlib_buffer_t *s = vlib_get_buffer (vm, src_buffer);

  ASSERT (s->ref_count == 1);
  ASSERT (n_buffers);
  ASSERT (n_buffers <= 256);
  ASSERT (offset + VLIB_BUFFER_PRE_DATA_SIZE >= 0);
  ASSERT ((offset + head_end_offset) <
	  vlib_buffer_get_default_data_size (vm));

  if (s->current_length <= head_end_offset + CLIB_CACHE_LINE_BYTES * 2)
    {
      buffers[0] = src_buffer;
      if (offset)
	vlib_buffer_move (vm, s, offset);

      for (i = 1; i < n_buffers; i++)
	{
	  vlib_buffer_t *d;
	  d = vlib_buffer_copy (vm, s);
	  if (d == 0)
	    return i;
	  buffers[i] = vlib_get_buffer_index (vm, d);

	}
      return n_buffers;
    }

  if (PREDICT_FALSE ((n_buffers == 1) && (offset == 0)))
    {
      buffers[0] = src_buffer;
      return 1;
    }

  n_buffers = vlib_buffer_alloc_from_pool (vm, buffers, n_buffers,
					   s->buffer_pool_index);

  for (i = 0; i < n_buffers; i++)
    {
      vlib_buffer_t *d = vlib_get_buffer (vm, buffers[i]);
      if (offset)
	d->current_data = offset;
      else
	d->current_data = s->current_data;

      d->current_length = head_end_offset;
      ASSERT (d->buffer_pool_index == s->buffer_pool_index);

      d->total_length_not_including_first_buffer = s->current_length -
	head_end_offset;
      if (PREDICT_FALSE (s->flags & VLIB_BUFFER_NEXT_PRESENT))
	{
	  d->total_length_not_including_first_buffer +=
	    s->total_length_not_including_first_buffer;
	}
      d->flags = (s->flags & VLIB_BUFFER_COPY_CLONE_FLAGS_MASK) |
	VLIB_BUFFER_NEXT_PRESENT;
      d->trace_handle = s->trace_handle;
      clib_memcpy_fast (d->opaque, s->opaque, sizeof (s->opaque));
      clib_memcpy_fast (d->opaque2, s->opaque2, sizeof (s->opaque2));
      clib_memcpy_fast (vlib_buffer_get_current (d),
			vlib_buffer_get_current (s), head_end_offset);
      d->next_buffer = src_buffer;
    }
  vlib_buffer_advance (s, head_end_offset);
  s->ref_count = n_buffers ? n_buffers : s->ref_count;
  while (s->flags & VLIB_BUFFER_NEXT_PRESENT)
    {
      s = vlib_get_buffer (vm, s->next_buffer);
      s->ref_count = n_buffers ? n_buffers : s->ref_count;
    }

  return n_buffers;
}

/** \brief Create multiple clones of buffer and store them
    in the supplied array

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param src_buffer - (u32) source buffer index
    @param buffers - (u32 * ) buffer index array
    @param n_buffers - (u16) number of buffer clones requested (<=256)
    @param head_end_offset - (u16) offset relative to current position
           where packet head ends
    @param offset - (i16) copy packet head at current position if 0,
           else at offset position to change headroom space as specified
    @return - (u16) number of buffers actually cloned, may be
    less than the number requested or zero
*/
always_inline u16
vlib_buffer_clone_at_offset (vlib_main_t * vm, u32 src_buffer, u32 * buffers,
			     u16 n_buffers, u16 head_end_offset, i16 offset)
{
  vlib_buffer_t *s = vlib_get_buffer (vm, src_buffer);
  u16 n_cloned = 0;

  while (n_buffers > 256)
    {
      vlib_buffer_t *copy;
      copy = vlib_buffer_copy (vm, s);
      n_cloned += vlib_buffer_clone_256 (vm,
					 vlib_get_buffer_index (vm, copy),
					 (buffers + n_cloned),
					 256, head_end_offset, offset);
      n_buffers -= 256;
    }
  n_cloned += vlib_buffer_clone_256 (vm, src_buffer,
				     buffers + n_cloned,
				     n_buffers, head_end_offset, offset);

  return n_cloned;
}

/** \brief Create multiple clones of buffer and store them
    in the supplied array

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param src_buffer - (u32) source buffer index
    @param buffers - (u32 * ) buffer index array
    @param n_buffers - (u16) number of buffer clones requested (<=256)
    @param head_end_offset - (u16) offset relative to current position
           where packet head ends
    @return - (u16) number of buffers actually cloned, may be
    less than the number requested or zero
*/
always_inline u16
vlib_buffer_clone (vlib_main_t * vm, u32 src_buffer, u32 * buffers,
		   u16 n_buffers, u16 head_end_offset)
{
  return vlib_buffer_clone_at_offset (vm, src_buffer, buffers, n_buffers,
				      head_end_offset, 0);
}

/** \brief Attach cloned tail to the buffer

    @param vm - (vlib_main_t *) vlib main data structure pointer
    @param head - (vlib_buffer_t *) head buffer
    @param tail - (Vlib buffer_t *) tail buffer to clone and attach to head
*/

always_inline void
vlib_buffer_attach_clone (vlib_main_t * vm, vlib_buffer_t * head,
			  vlib_buffer_t * tail)
{
  ASSERT ((head->flags & VLIB_BUFFER_NEXT_PRESENT) == 0);
  ASSERT (head->buffer_pool_index == tail->buffer_pool_index);

  head->flags |= VLIB_BUFFER_NEXT_PRESENT;
  head->flags &= ~VLIB_BUFFER_TOTAL_LENGTH_VALID;
  head->flags &= ~VLIB_BUFFER_EXT_HDR_VALID;
  head->flags |= (tail->flags & VLIB_BUFFER_TOTAL_LENGTH_VALID);
  head->next_buffer = vlib_get_buffer_index (vm, tail);
  head->total_length_not_including_first_buffer = tail->current_length +
    tail->total_length_not_including_first_buffer;

next_segment:
  clib_atomic_add_fetch (&tail->ref_count, 1);

  if (tail->flags & VLIB_BUFFER_NEXT_PRESENT)
    {
      tail = vlib_get_buffer (vm, tail->next_buffer);
      goto next_segment;
    }
}

/* Initializes the buffer as an empty packet with no chained buffers. */
always_inline void
vlib_buffer_chain_init (vlib_buffer_t * first)
{
  first->total_length_not_including_first_buffer = 0;
  first->current_length = 0;
  first->flags &= ~VLIB_BUFFER_NEXT_PRESENT;
  first->flags |= VLIB_BUFFER_TOTAL_LENGTH_VALID;
}

/* The provided next_bi buffer index is appended to the end of the packet. */
always_inline vlib_buffer_t *
vlib_buffer_chain_buffer (vlib_main_t * vm, vlib_buffer_t * last, u32 next_bi)
{
  vlib_buffer_t *next_buffer = vlib_get_buffer (vm, next_bi);
  last->next_buffer = next_bi;
  last->flags |= VLIB_BUFFER_NEXT_PRESENT;
  next_buffer->current_length = 0;
  next_buffer->flags &= ~VLIB_BUFFER_NEXT_PRESENT;
  return next_buffer;
}

/* Increases or decreases the packet length.
 * It does not allocate or deallocate new buffers.
 * Therefore, the added length must be compatible
 * with the last buffer. */
always_inline void
vlib_buffer_chain_increase_length (vlib_buffer_t * first,
				   vlib_buffer_t * last, i32 len)
{
  last->current_length += len;
  if (first != last)
    first->total_length_not_including_first_buffer += len;
}

/* Copy data to the end of the packet and increases its length.
 * It does not allocate new buffers.
 * Returns the number of copied bytes. */
always_inline u16
vlib_buffer_chain_append_data (vlib_main_t * vm,
			       vlib_buffer_t * first,
			       vlib_buffer_t * last, void *data, u16 data_len)
{
  u32 n_buffer_bytes = vlib_buffer_get_default_data_size (vm);
  ASSERT (n_buffer_bytes >= last->current_length + last->current_data);
  u16 len = clib_min (data_len,
		      n_buffer_bytes - last->current_length -
		      last->current_data);
  clib_memcpy_fast (vlib_buffer_get_current (last) + last->current_length,
		    data, len);
  vlib_buffer_chain_increase_length (first, last, len);
  return len;
}

/* Copy data to the end of the packet and increases its length.
 * Allocates additional buffers from the free list if necessary.
 * Returns the number of copied bytes.
 * 'last' value is modified whenever new buffers are allocated and
 * chained and points to the last buffer in the chain. */
u16
vlib_buffer_chain_append_data_with_alloc (vlib_main_t * vm,
					  vlib_buffer_t * first,
					  vlib_buffer_t ** last, void *data,
					  u16 data_len);
void vlib_buffer_chain_validate (vlib_main_t * vm, vlib_buffer_t * first);

format_function_t format_vlib_buffer, format_vlib_buffer_and_data,
  format_vlib_buffer_contents, format_vlib_buffer_no_chain;

typedef struct
{
  /* Vector of packet data. */
  u8 *packet_data;

  /* Number of buffers to allocate in each call to allocator. */
  u32 min_n_buffers_each_alloc;

  u8 *name;
} vlib_packet_template_t;

void vlib_packet_template_init (vlib_main_t * vm,
				vlib_packet_template_t * t,
				void *packet_data,
				uword n_packet_data_bytes,
				uword min_n_buffers_each_alloc,
				char *fmt, ...);

void *vlib_packet_template_get_packet (vlib_main_t * vm,
				       vlib_packet_template_t * t,
				       u32 * bi_result);

always_inline void
vlib_packet_template_free (vlib_main_t * vm, vlib_packet_template_t * t)
{
  vec_free (t->packet_data);
}

always_inline u32
vlib_buffer_space_left_at_end (vlib_main_t * vm, vlib_buffer_t * b)
{
  return b->data + vlib_buffer_get_default_data_size (vm) -
    ((u8 *) vlib_buffer_get_current (b) + b->current_length);
}

#define VLIB_BUFFER_LINEARIZE_MAX 64

always_inline u32
vlib_buffer_chain_linearize (vlib_main_t * vm, vlib_buffer_t * b)
{
  vlib_buffer_t *dst_b;
  u32 n_buffers = 1, to_free = 0;
  u16 rem_len, dst_len, data_size, src_len = 0;
  u8 *dst, *src = 0;

  if (PREDICT_TRUE ((b->flags & VLIB_BUFFER_NEXT_PRESENT) == 0))
    return 1;

  ASSERT (1 == b->ref_count);
  if (PREDICT_FALSE (1 != b->ref_count))
    return 0;

  data_size = vlib_buffer_get_default_data_size (vm);
  rem_len = vlib_buffer_length_in_chain (vm, b) - b->current_length;

  dst_b = b;
  dst = vlib_buffer_get_tail (dst_b);
  dst_len = vlib_buffer_space_left_at_end (vm, dst_b);

  b->total_length_not_including_first_buffer -= dst_len;

  while (rem_len > 0)
    {
      u16 copy_len;

      while (0 == src_len)
	{
	  ASSERT (b->flags & VLIB_BUFFER_NEXT_PRESENT);
	  if (PREDICT_FALSE (!(b->flags & VLIB_BUFFER_NEXT_PRESENT)))
	    break; /* malformed chained buffer */

	  b = vlib_get_buffer (vm, b->next_buffer);
	  src = vlib_buffer_get_current (b);
	  src_len = b->current_length;
	}

      if (0 == dst_len)
	{
	  ASSERT (dst_b->flags & VLIB_BUFFER_NEXT_PRESENT);
	  if (PREDICT_FALSE (!(dst_b->flags & VLIB_BUFFER_NEXT_PRESENT)))
	    break; /* malformed chained buffer */

	  vlib_buffer_t *next_dst_b = vlib_get_buffer (vm, dst_b->next_buffer);

	  if (PREDICT_TRUE (1 == next_dst_b->ref_count))
	    {
	      /* normal case: buffer is not cloned, just use it */
	      dst_b = next_dst_b;
	    }
	  else
	    {
	      /* cloned buffer, build a new dest chain from there */
	      vlib_buffer_t *bufs[VLIB_BUFFER_LINEARIZE_MAX];
	      u32 bis[VLIB_BUFFER_LINEARIZE_MAX + 1];
	      const int n = (rem_len + data_size - 1) / data_size;
	      int n_alloc;
	      int i;

	      ASSERT (n <= VLIB_BUFFER_LINEARIZE_MAX);
	      if (PREDICT_FALSE (n > VLIB_BUFFER_LINEARIZE_MAX))
		return 0;

	      n_alloc = vlib_buffer_alloc (vm, bis, n);
	      if (PREDICT_FALSE (n_alloc != n))
		{
		  vlib_buffer_free (vm, bis, n_alloc);
		  return 0;
		}

	      vlib_get_buffers (vm, bis, bufs, n);

	      for (i = 0; i < n - 1; i++)
		{
		  bufs[i]->flags |= VLIB_BUFFER_NEXT_PRESENT;
		  bufs[i]->next_buffer = bis[i + 1];
		}

	      to_free = dst_b->next_buffer;
	      dst_b->next_buffer = bis[0];
	      dst_b = bufs[0];
	    }

	  n_buffers++;

	  dst_b->current_data = clib_min (0, dst_b->current_data);
	  dst_b->current_length = 0;

	  dst = dst_b->data + dst_b->current_data;
	  dst_len = data_size - dst_b->current_data;
	}

      copy_len = clib_min (src_len, dst_len);

      if (PREDICT_TRUE (src == dst))
	{
	  /* nothing to do */
	}
      else if (src + copy_len > dst && dst + copy_len > src)
	{
	  /* src and dst overlap */
	  ASSERT (b == dst_b);
	  memmove (dst, src, copy_len);
	}
      else
	{
	  clib_memcpy_fast (dst, src, copy_len);
	}

      dst_b->current_length += copy_len;

      dst += copy_len;
      src += copy_len;
      dst_len -= copy_len;
      src_len -= copy_len;
      rem_len -= copy_len;
    }

  /* in case of a malformed chain buffer, we'll exit early from the loop. */
  ASSERT (0 == rem_len);
  b->total_length_not_including_first_buffer -= rem_len;

  if (to_free)
    vlib_buffer_free_one (vm, to_free);

  if (dst_b->flags & VLIB_BUFFER_NEXT_PRESENT)
    {
      /* the resulting chain is smaller than the original, cut it there */
      dst_b->flags &= ~VLIB_BUFFER_NEXT_PRESENT;
      vlib_buffer_free_one (vm, dst_b->next_buffer);
      if (1 == n_buffers)
	{
	  /* no longer a chained buffer */
	  dst_b->flags &= ~VLIB_BUFFER_TOTAL_LENGTH_VALID;
	  dst_b->total_length_not_including_first_buffer = 0;
	}
    }

  return n_buffers;
}

#endif /* included_vlib_buffer_funcs_h */

/*
 * fd.io coding-style-patch-verification: ON
 *
 * Local Variables:
 * eval: (c-set-style "gnu")
 * End:
 */