} while (0)
struct acl_node_counters {
- int match;
- int match_used;
- int single;
- int quad;
- int quad_vectors;
- int dfa;
- int smallest_match;
+ int32_t match;
+ int32_t match_used;
+ int32_t single;
+ int32_t quad;
+ int32_t quad_vectors;
+ int32_t dfa;
+ int32_t dfa_gr64;
+ int32_t smallest_match;
};
struct rte_acl_indices {
static void
acl_gen_log_stats(const struct rte_acl_ctx *ctx,
- const struct acl_node_counters *counts)
+ const struct acl_node_counters *counts,
+ const struct rte_acl_indices *indices)
{
RTE_LOG(DEBUG, ACL, "Gen phase for ACL \"%s\":\n"
"runtime memory footprint on socket %d:\n"
"single nodes/bytes used: %d/%zu\n"
- "quad nodes/bytes used: %d/%zu\n"
- "DFA nodes/bytes used: %d/%zu\n"
+ "quad nodes/vectors/bytes used: %d/%d/%zu\n"
+ "DFA nodes/group64/bytes used: %d/%d/%zu\n"
"match nodes/bytes used: %d/%zu\n"
"total: %zu bytes\n",
ctx->name, ctx->socket_id,
counts->single, counts->single * sizeof(uint64_t),
- counts->quad, counts->quad_vectors * sizeof(uint64_t),
- counts->dfa, counts->dfa * RTE_ACL_DFA_SIZE * sizeof(uint64_t),
+ counts->quad, counts->quad_vectors,
+ (indices->quad_index - indices->dfa_index) * sizeof(uint64_t),
+ counts->dfa, counts->dfa_gr64,
+ indices->dfa_index * sizeof(uint64_t),
counts->match,
counts->match * sizeof(struct rte_acl_match_results),
ctx->mem_sz);
}
+static uint64_t
+acl_dfa_gen_idx(const struct rte_acl_node *node, uint32_t index)
+{
+ uint64_t idx;
+ uint32_t i;
+
+ idx = 0;
+ for (i = 0; i != RTE_DIM(node->dfa_gr64); i++) {
+ RTE_ACL_VERIFY(node->dfa_gr64[i] < RTE_ACL_DFA_GR64_NUM);
+ RTE_ACL_VERIFY(node->dfa_gr64[i] < node->fanout);
+ idx |= (i - node->dfa_gr64[i]) <<
+ (6 + RTE_ACL_DFA_GR64_BIT * i);
+ }
+
+ return idx << (CHAR_BIT * sizeof(index)) | index | node->node_type;
+}
+
+static void
+acl_dfa_fill_gr64(const struct rte_acl_node *node,
+ const uint64_t src[RTE_ACL_DFA_SIZE], uint64_t dst[RTE_ACL_DFA_SIZE])
+{
+ uint32_t i;
+
+ for (i = 0; i != RTE_DIM(node->dfa_gr64); i++) {
+ memcpy(dst + node->dfa_gr64[i] * RTE_ACL_DFA_GR64_SIZE,
+ src + i * RTE_ACL_DFA_GR64_SIZE,
+ RTE_ACL_DFA_GR64_SIZE * sizeof(dst[0]));
+ }
+}
+
+static uint32_t
+acl_dfa_count_gr64(const uint64_t array_ptr[RTE_ACL_DFA_SIZE],
+ uint8_t gr64[RTE_ACL_DFA_GR64_NUM])
+{
+ uint32_t i, j, k;
+
+ k = 0;
+ for (i = 0; i != RTE_ACL_DFA_GR64_NUM; i++) {
+ gr64[i] = i;
+ for (j = 0; j != i; j++) {
+ if (memcmp(array_ptr + i * RTE_ACL_DFA_GR64_SIZE,
+ array_ptr + j * RTE_ACL_DFA_GR64_SIZE,
+ RTE_ACL_DFA_GR64_SIZE *
+ sizeof(array_ptr[0])) == 0)
+ break;
+ }
+ gr64[i] = (j != i) ? gr64[j] : k++;
+ }
+
+ return k;
+}
+
+static uint32_t
+acl_node_fill_dfa(const struct rte_acl_node *node,
+ uint64_t dfa[RTE_ACL_DFA_SIZE], uint64_t no_match, int32_t resolved)
+{
+ uint32_t n, x;
+ uint32_t ranges, last_bit;
+ struct rte_acl_node *child;
+ struct rte_acl_bitset *bits;
+
+ ranges = 0;
+ last_bit = 0;
+
+ for (n = 0; n < RTE_ACL_DFA_SIZE; n++)
+ dfa[n] = no_match;
+
+ for (x = 0; x < node->num_ptrs; x++) {
+
+ child = node->ptrs[x].ptr;
+ if (child == NULL)
+ continue;
+
+ bits = &node->ptrs[x].values;
+ for (n = 0; n < RTE_ACL_DFA_SIZE; n++) {
+
+ if (bits->bits[n / (sizeof(bits_t) * CHAR_BIT)] &
+ (1 << (n % (sizeof(bits_t) * CHAR_BIT)))) {
+
+ dfa[n] = resolved ? child->node_index : x;
+ ranges += (last_bit == 0);
+ last_bit = 1;
+ } else {
+ last_bit = 0;
+ }
+ }
+ }
+
+ return ranges;
+}
+
/*
* Counts the number of groups of sequential bits that are
* either 0 or 1, as specified by the zero_one parameter. This is used to
*/
static int
acl_count_trie_types(struct acl_node_counters *counts,
- struct rte_acl_node *node, int match, int force_dfa)
+ struct rte_acl_node *node, uint64_t no_match, int match, int force_dfa)
{
uint32_t n;
int num_ptrs;
+ uint64_t dfa[RTE_ACL_DFA_SIZE];
/* skip if this node has been counted */
if (node->node_type != (uint32_t)RTE_ACL_NODE_UNDEFINED)
} else {
counts->dfa++;
node->node_type = RTE_ACL_NODE_DFA;
+ if (force_dfa != 0) {
+ /* always expand to a max number of nodes. */
+ for (n = 0; n != RTE_DIM(node->dfa_gr64); n++)
+ node->dfa_gr64[n] = n;
+ node->fanout = n;
+ } else {
+ acl_node_fill_dfa(node, dfa, no_match, 0);
+ node->fanout = acl_dfa_count_gr64(dfa, node->dfa_gr64);
+ }
+ counts->dfa_gr64 += node->fanout;
}
/*
for (n = 0; n < node->num_ptrs; n++) {
if (node->ptrs[n].ptr != NULL)
match = acl_count_trie_types(counts, node->ptrs[n].ptr,
- match, 0);
+ no_match, match, 0);
}
return match;
acl_add_ptrs(struct rte_acl_node *node, uint64_t *node_array, uint64_t no_match,
int resolved)
{
- uint32_t n, x;
- int m, ranges, last_bit;
- struct rte_acl_node *child;
- struct rte_acl_bitset *bits;
+ uint32_t x;
+ int32_t m;
uint64_t *node_a, index, dfa[RTE_ACL_DFA_SIZE];
- ranges = 0;
- last_bit = 0;
-
- for (n = 0; n < RTE_DIM(dfa); n++)
- dfa[n] = no_match;
-
- for (x = 0; x < node->num_ptrs; x++) {
-
- child = node->ptrs[x].ptr;
- if (child == NULL)
- continue;
-
- bits = &node->ptrs[x].values;
- for (n = 0; n < RTE_DIM(dfa); n++) {
-
- if (bits->bits[n / (sizeof(bits_t) * CHAR_BIT)] &
- (1 << (n % (sizeof(bits_t) * CHAR_BIT)))) {
-
- dfa[n] = resolved ? child->node_index : x;
- ranges += (last_bit == 0);
- last_bit = 1;
- } else {
- last_bit = 0;
- }
- }
- }
+ acl_node_fill_dfa(node, dfa, no_match, resolved);
/*
* Rather than going from 0 to 256, the range count and
RTE_ACL_VERIFY(m <= RTE_ACL_QUAD_SIZE);
} else if (node->node_type == RTE_ACL_NODE_DFA && resolved) {
- for (n = 0; n < RTE_DIM(dfa); n++)
- node_array[n] = dfa[n];
+ acl_dfa_fill_gr64(node, dfa, node_array);
}
}
acl_gen_node(struct rte_acl_node *node, uint64_t *node_array,
uint64_t no_match, struct rte_acl_indices *index, int num_categories)
{
- uint32_t n, *qtrp;
+ uint32_t n, sz, *qtrp;
uint64_t *array_ptr;
struct rte_acl_match_results *match;
switch (node->node_type) {
case RTE_ACL_NODE_DFA:
- node->node_index = index->dfa_index | node->node_type;
array_ptr = &node_array[index->dfa_index];
- index->dfa_index += RTE_ACL_DFA_SIZE;
- for (n = 0; n < RTE_ACL_DFA_SIZE; n++)
+ node->node_index = acl_dfa_gen_idx(node, index->dfa_index);
+ sz = node->fanout * RTE_ACL_DFA_GR64_SIZE;
+ index->dfa_index += sz;
+ for (n = 0; n < sz; n++)
array_ptr[n] = no_match;
break;
case RTE_ACL_NODE_SINGLE:
break;
case RTE_ACL_NODE_QRANGE:
array_ptr = &node_array[index->quad_index];
- acl_add_ptrs(node, array_ptr, no_match, 0);
+ acl_add_ptrs(node, array_ptr, no_match, 0);
qtrp = (uint32_t *)node->transitions;
node->node_index = qtrp[0];
node->node_index <<= sizeof(index->quad_index) * CHAR_BIT;
}
static int
-acl_calc_counts_indicies(struct acl_node_counters *counts,
+acl_calc_counts_indices(struct acl_node_counters *counts,
struct rte_acl_indices *indices, struct rte_acl_trie *trie,
struct rte_acl_bld_trie *node_bld_trie, uint32_t num_tries,
- int match_num)
+ int match_num, uint64_t no_match)
{
uint32_t n;
for (n = 0; n < num_tries; n++) {
counts->smallest_match = INT32_MAX;
match_num = acl_count_trie_types(counts, node_bld_trie[n].trie,
- match_num, 1);
+ no_match, match_num, 1);
trie[n].smallest = counts->smallest_match;
}
indices->dfa_index = RTE_ACL_DFA_SIZE + 1;
indices->quad_index = indices->dfa_index +
- counts->dfa * RTE_ACL_DFA_SIZE;
+ counts->dfa_gr64 * RTE_ACL_DFA_GR64_SIZE;
indices->single_index = indices->quad_index + counts->quad_vectors;
indices->match_index = indices->single_index + counts->single + 1;
indices->match_index = RTE_ALIGN(indices->match_index,
struct acl_node_counters counts;
struct rte_acl_indices indices;
- /* Fill counts and indicies arrays from the nodes. */
- match_num = acl_calc_counts_indicies(&counts, &indices, trie,
- node_bld_trie, num_tries, match_num);
+ no_match = RTE_ACL_NODE_MATCH;
+
+ /* Fill counts and indices arrays from the nodes. */
+ match_num = acl_calc_counts_indices(&counts, &indices, trie,
+ node_bld_trie, num_tries, match_num, no_match);
/* Allocate runtime memory (align to cache boundary) */
- total_size = RTE_ALIGN(data_index_sz, CACHE_LINE_SIZE) +
+ total_size = RTE_ALIGN(data_index_sz, RTE_CACHE_LINE_SIZE) +
indices.match_index * sizeof(uint64_t) +
(match_num + 2) * sizeof(struct rte_acl_match_results) +
XMM_SIZE;
- mem = rte_zmalloc_socket(ctx->name, total_size, CACHE_LINE_SIZE,
+ mem = rte_zmalloc_socket(ctx->name, total_size, RTE_CACHE_LINE_SIZE,
ctx->socket_id);
if (mem == NULL) {
RTE_LOG(ERR, ACL,
/* Fill the runtime structure */
match_index = indices.match_index;
node_array = (uint64_t *)((uintptr_t)mem +
- RTE_ALIGN(data_index_sz, CACHE_LINE_SIZE));
+ RTE_ALIGN(data_index_sz, RTE_CACHE_LINE_SIZE));
/*
* Setup the NOMATCH node (a SINGLE at the
*/
node_array[RTE_ACL_DFA_SIZE] = RTE_ACL_DFA_SIZE | RTE_ACL_NODE_SINGLE;
- no_match = RTE_ACL_NODE_MATCH;
for (n = 0; n < RTE_ACL_DFA_SIZE; n++)
node_array[n] = no_match;
+ /* NOMATCH result at index 0 */
match = ((struct rte_acl_match_results *)(node_array + match_index));
memset(match, 0, sizeof(*match));
ctx->trans_table = node_array;
memcpy(ctx->trie, trie, sizeof(ctx->trie));
- acl_gen_log_stats(ctx, &counts);
+ acl_gen_log_stats(ctx, &counts, &indices);
return 0;
}