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/*
* 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_node.h: VLIB buffer handling node helper macros/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_node_h
#define included_vlib_buffer_node_h
/** \file
vlib buffer/node functions
*/
/** \brief Finish enqueueing two buffers forward in the graph.
Standard dual loop boilerplate element. This is a MACRO,
with MULTIPLE SIDE EFFECTS. In the ideal case,
<code>next_index == next0 == next1</code>,
which means that the speculative enqueue at the top of the dual loop
has correctly dealt with both packets. In that case, the macro does
nothing at all.
@param vm vlib_main_t pointer, varies by thread
@param node current node vlib_node_runtime_t pointer
@param next_index speculated next index used for both packets
@param to_next speculated vector pointer used for both packets
@param n_left_to_next number of slots left in speculated vector
@param bi0 first buffer index
@param bi1 second buffer index
@param next0 actual next index to be used for the first packet
@param next1 actual next index to be used for the second packet
@return @c next_index -- speculative next index to be used for future packets
@return @c to_next -- speculative frame to be used for future packets
@return @c n_left_to_next -- number of slots left in speculative frame
*/
#define vlib_validate_buffer_enqueue_x2(vm,node,next_index,to_next,n_left_to_next,bi0,bi1,next0,next1) \
do { \
ASSERT (bi0 != 0); \
ASSERT (bi1 != 0); \
int enqueue_code = (next0 != next_index) + 2*(next1 != next_index); \
\
if (PREDICT_FALSE (enqueue_code != 0)) \
{ \
switch (enqueue_code) \
{ \
case 1: \
/* A B A */ \
to_next[-2] = bi1; \
to_next -= 1; \
n_left_to_next += 1; \
vlib_set_next_frame_buffer (vm, node, next0, bi0); \
break; \
\
case 2: \
/* A A B */ \
to_next -= 1; \
n_left_to_next += 1; \
vlib_set_next_frame_buffer (vm, node, next1, bi1); \
break; \
\
case 3: \
/* A B B or A B C */ \
to_next -= 2; \
n_left_to_next += 2; \
vlib_set_next_frame_buffer (vm, node, next0, bi0); \
vlib_set_next_frame_buffer (vm, node, next1, bi1); \
if (next0 == next1) \
{ \
vlib_put_next_frame (vm, node, next_index, \
n_left_to_next); \
next_index = next1; \
vlib_get_next_frame (vm, node, next_index, to_next, n_left_to_next); \
} \
} \
} \
} while (0)
/** \brief Finish enqueueing four buffers forward in the graph.
Standard quad loop boilerplate element. This is a MACRO,
with MULTIPLE SIDE EFFECTS. In the ideal case,
<code>next_index == next0 == next1 == next2 == next3</code>,
which means that the speculative enqueue at the top of the quad loop
has correctly dealt with all four packets. In that case, the macro does
nothing at all.
@param vm vlib_main_t pointer, varies by thread
@param node current node vlib_node_runtime_t pointer
@param next_index speculated next index used for both packets
@param to_next speculated vector pointer used for both packets
@param n_left_to_next number of slots left in speculated vector
@param bi0 first buffer index
@param bi1 second buffer index
@param bi2 third buffer index
@param bi3 fourth buffer index
@param next0 actual next index to be used for the first packet
@param next1 actual next index to be used for the second packet
@param next2 actual next index to be used for the third packet
@param next3 actual next index to be used for the fourth packet
@return @c next_index -- speculative next index to be used for future packets
@return @c to_next -- speculative frame to be used for future packets
@return @c n_left_to_next -- number of slots left in speculative frame
*/
#define vlib_validate_buffer_enqueue_x4(vm,node,next_index,to_next,n_left_to_next,bi0,bi1,bi2,bi3,next0,next1,next2,next3) \
do { \
ASSERT (bi0 != 0); \
ASSERT (bi1 != 0); \
ASSERT (bi2 != 0); \
ASSERT (bi3 != 0); \
/* After the fact: check the [speculative] enqueue to "next" */ \
u32 fix_speculation = (next_index ^ next0) | (next_index ^ next1) \
| (next_index ^ next2) | (next_index ^ next3); \
if (PREDICT_FALSE(fix_speculation)) \
{ \
/* rewind... */ \
to_next -= 4; \
n_left_to_next += 4; \
\
/* If bi0 belongs to "next", send it there */ \
if (next_index == next0) \
{ \
to_next[0] = bi0; \
to_next++; \
n_left_to_next --; \
} \
else /* send it where it needs to go */ \
vlib_set_next_frame_buffer (vm, node, next0, bi0); \
\
if (next_index == next1) \
{ \
to_next[0] = bi1; \
to_next++; \
n_left_to_next --; \
} \
else \
vlib_set_next_frame_buffer (vm, node, next1, bi1); \
\
if (next_index == next2) \
{ \
to_next[0] = bi2; \
to_next++; \
n_left_to_next --; \
} \
else \
vlib_set_next_frame_buffer (vm, node, next2, bi2); \
\
if (next_index == next3) \
{ \
to_next[0] = bi3; \
to_next++; \
n_left_to_next --; \
} \
else \
{ \
vlib_set_next_frame_buffer (vm, node, next3, bi3); \
\
/* Change speculation: last 2 packets went to the same node*/ \
if (next2 == next3) \
{ \
vlib_put_next_frame (vm, node, next_index, n_left_to_next); \
next_index = next3; \
vlib_get_next_frame (vm, node, next_index, to_next, n_left_to_next); \
} \
} \
} \
} while(0);
/** \brief Finish enqueueing one buffer forward in the graph.
Standard single loop boilerplate element. This is a MACRO,
with MULTIPLE SIDE EFFECTS. In the ideal case,
<code>next_index == next0</code>,
which means that the speculative enqueue at the top of the single loop
has correctly dealt with the packet in hand. In that case, the macro does
nothing at all.
@param vm vlib_main_t pointer, varies by thread
@param node current node vlib_node_runtime_t pointer
@param next_index speculated next index used for both packets
@param to_next speculated vector pointer used for both packets
@param n_left_to_next number of slots left in speculated vector
@param bi0 first buffer index
@param next0 actual next index to be used for the first packet
@return @c next_index -- speculative next index to be used for future packets
@return @c to_next -- speculative frame to be used for future packets
@return @c n_left_to_next -- number of slots left in speculative frame
*/
#define vlib_validate_buffer_enqueue_x1(vm,node,next_index,to_next,n_left_to_next,bi0,next0) \
do { \
ASSERT (bi0 != 0); \
if (PREDICT_FALSE (next0 != next_index)) \
{ \
vlib_put_next_frame (vm, node, next_index, n_left_to_next + 1); \
next_index = next0; \
vlib_get_next_frame (vm, node, next_index, to_next, n_left_to_next); \
\
to_next[0] = bi0; \
to_next += 1; \
n_left_to_next -= 1; \
} \
} while (0)
/** \brief Finish enqueueing one buffer forward in the graph, along with its
aux_data if possible. Standard single loop boilerplate element. This is a
MACRO, with MULTIPLE SIDE EFFECTS. In the ideal case, <code>next_index ==
next0</code>, which means that the speculative enqueue at the top of the
single loop has correctly dealt with the packet in hand. In that case, the
macro does nothing at all. This function MAY return to_next_aux = NULL if
next_index does not support aux data
@param vm vlib_main_t pointer, varies by thread
@param node current node vlib_node_runtime_t pointer
@param next_index speculated next index used for both packets
@param to_next speculated vector pointer used for both packets
@param to_next_aux speculated aux_data pointer used for both packets
@param n_left_to_next number of slots left in speculated vector
@param bi0 first buffer index
@param aux0 first aux_data
@param next0 actual next index to be used for the first packet
@return @c next_index -- speculative next index to be used for future packets
@return @c to_next -- speculative frame to be used for future packets
@return @c n_left_to_next -- number of slots left in speculative frame
*/
#define vlib_validate_buffer_enqueue_with_aux_x1( \
vm, node, next_index, to_next, to_next_aux, n_left_to_next, bi0, aux0, \
next0) \
do \
{ \
ASSERT (bi0 != 0); \
if (PREDICT_FALSE (next0 != next_index)) \
{ \
vlib_put_next_frame (vm, node, next_index, n_left_to_next + 1); \
next_index = next0; \
vlib_get_next_frame_with_aux_safe (vm, node, next_index, to_next, \
to_next_aux, n_left_to_next); \
\
to_next[0] = bi0; \
to_next += 1; \
if (to_next_aux) \
{ \
to_next_aux[0] = aux0; \
to_next_aux += 1; \
} \
n_left_to_next -= 1; \
} \
} \
while (0)
always_inline uword
generic_buffer_node_inline (vlib_main_t * vm,
vlib_node_runtime_t * node,
vlib_frame_t * frame,
uword sizeof_trace,
void *opaque1,
uword opaque2,
void (*two_buffers) (vlib_main_t * vm,
void *opaque1,
uword opaque2,
vlib_buffer_t * b0,
vlib_buffer_t * b1,
u32 * next0, u32 * next1),
void (*one_buffer) (vlib_main_t * vm,
void *opaque1, uword opaque2,
vlib_buffer_t * b0,
u32 * next0))
{
u32 n_left_from, *from, *to_next;
u32 next_index;
from = vlib_frame_vector_args (frame);
n_left_from = frame->n_vectors;
next_index = node->cached_next_index;
if (node->flags & VLIB_NODE_FLAG_TRACE)
vlib_trace_frame_buffers_only (vm, node, from, frame->n_vectors,
/* stride */ 1, sizeof_trace);
while (n_left_from > 0)
{
u32 n_left_to_next;
vlib_get_next_frame (vm, node, next_index, to_next, n_left_to_next);
while (n_left_from >= 4 && n_left_to_next >= 2)
{
vlib_buffer_t *p0, *p1;
u32 pi0, next0;
u32 pi1, next1;
/* Prefetch next iteration. */
{
vlib_buffer_t *p2, *p3;
p2 = vlib_get_buffer (vm, from[2]);
p3 = vlib_get_buffer (vm, from[3]);
vlib_prefetch_buffer_header (p2, LOAD);
vlib_prefetch_buffer_header (p3, LOAD);
clib_prefetch_load (p2->data);
clib_prefetch_load (p3->data);
}
pi0 = to_next[0] = from[0];
pi1 = to_next[1] = from[1];
from += 2;
to_next += 2;
n_left_from -= 2;
n_left_to_next -= 2;
p0 = vlib_get_buffer (vm, pi0);
p1 = vlib_get_buffer (vm, pi1);
two_buffers (vm, opaque1, opaque2, p0, p1, &next0, &next1);
vlib_validate_buffer_enqueue_x2 (vm, node, next_index,
to_next, n_left_to_next,
pi0, pi1, next0, next1);
}
while (n_left_from > 0 && n_left_to_next > 0)
{
vlib_buffer_t *p0;
u32 pi0, next0;
pi0 = from[0];
to_next[0] = pi0;
from += 1;
to_next += 1;
n_left_from -= 1;
n_left_to_next -= 1;
p0 = vlib_get_buffer (vm, pi0);
one_buffer (vm, opaque1, opaque2, p0, &next0);
vlib_validate_buffer_enqueue_x1 (vm, node, next_index,
to_next, n_left_to_next,
pi0, next0);
}
vlib_put_next_frame (vm, node, next_index, n_left_to_next);
}
return frame->n_vectors;
}
/* Minimum size for the 'buffers' and 'nexts' arrays to be used when calling
* vlib_buffer_enqueue_to_next().
* Because of optimizations, vlib_buffer_enqueue_to_next() will access
* past 'count' elements in the 'buffers' and 'nexts' arrays, IOW it
* will overflow.
* Those overflow elements are ignored in the final result so they do not
* need to be properly initialized, however if the array is allocated right
* before the end of a page and the next page is not mapped, accessing the
* overflow elements will trigger a segfault. */
#define VLIB_BUFFER_ENQUEUE_MIN_SIZE(n) round_pow2 ((n), 64)
static_always_inline void
vlib_buffer_enqueue_to_next (vlib_main_t * vm, vlib_node_runtime_t * node,
u32 * buffers, u16 * nexts, uword count)
{
vlib_buffer_enqueue_to_next_fn_t *fn;
fn = vlib_buffer_func_main.buffer_enqueue_to_next_fn;
(fn) (vm, node, buffers, nexts, count);
}
static_always_inline void
vlib_buffer_enqueue_to_next_with_aux (vlib_main_t *vm,
vlib_node_runtime_t *node, u32 *buffers,
u32 *aux_data, u16 *nexts, uword count)
{
vlib_buffer_enqueue_to_next_with_aux_fn_t *fn;
fn = vlib_buffer_func_main.buffer_enqueue_to_next_with_aux_fn;
(fn) (vm, node, buffers, aux_data, nexts, count);
}
static_always_inline void
vlib_buffer_enqueue_to_next_vec (vlib_main_t *vm, vlib_node_runtime_t *node,
u32 **buffers, u16 **nexts, uword count)
{
const u32 bl = vec_len (*buffers), nl = vec_len (*nexts);
const u32 c = VLIB_BUFFER_ENQUEUE_MIN_SIZE (count);
ASSERT (bl >= count && nl >= count);
vec_validate (*buffers, c);
vec_validate (*nexts, c);
vlib_buffer_enqueue_to_next (vm, node, *buffers, *nexts, count);
vec_set_len (*buffers, bl);
vec_set_len (*nexts, nl);
}
static_always_inline void
vlib_buffer_enqueue_to_single_next (vlib_main_t * vm,
vlib_node_runtime_t * node, u32 * buffers,
u16 next_index, u32 count)
{
vlib_buffer_enqueue_to_single_next_fn_t *fn;
fn = vlib_buffer_func_main.buffer_enqueue_to_single_next_fn;
(fn) (vm, node, buffers, next_index, count);
}
static_always_inline void
vlib_buffer_enqueue_to_single_next_with_aux (vlib_main_t *vm,
vlib_node_runtime_t *node,
u32 *buffers, u32 *aux_data,
u16 next_index, u32 count)
{
vlib_buffer_enqueue_to_single_next_with_aux_fn_t *fn;
fn = vlib_buffer_func_main.buffer_enqueue_to_single_next_with_aux_fn;
(fn) (vm, node, buffers, aux_data, next_index, count);
}
static_always_inline u32
vlib_buffer_enqueue_to_thread (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)
{
vlib_buffer_enqueue_to_thread_fn_t *fn;
fn = vlib_buffer_func_main.buffer_enqueue_to_thread_fn;
return (fn) (vm, node, frame_queue_index, buffer_indices, thread_indices,
n_packets, drop_on_congestion);
}
static_always_inline u32
vlib_buffer_enqueue_to_thread_with_aux (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)
{
vlib_buffer_enqueue_to_thread_with_aux_fn_t *fn;
fn = vlib_buffer_func_main.buffer_enqueue_to_thread_with_aux_fn;
return (fn) (vm, node, frame_queue_index, buffer_indices, aux,
thread_indices, n_packets, drop_on_congestion);
}
#endif /* included_vlib_buffer_node_h */
/*
* fd.io coding-style-patch-verification: ON
*
* Local Variables:
* eval: (c-set-style "gnu")
* End:
*/