numam-dpdk/lib/librte_acl/acl_run_scalar.c

/*-
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#include "acl_run.h"

/*
 * Resolve priority for multiple results (scalar version).
 * This consists comparing the priority of the current traversal with the
 * running set of results for the packet.
 * For each result, keep a running array of the result (rule number) and
 * its priority for each category.
 */
static inline void
resolve_priority_scalar(uint64_t transition, int n,
	const struct rte_acl_ctx *ctx, struct parms *parms,
	const struct rte_acl_match_results *p, uint32_t categories)
{
	uint32_t i;
	int32_t *saved_priority;
	uint32_t *saved_results;
	const int32_t *priority;
	const uint32_t *results;

	saved_results = parms[n].cmplt->results;
	saved_priority = parms[n].cmplt->priority;

	/* results and priorities for completed trie */
	results = p[transition].results;
	priority = p[transition].priority;

	/* if this is not the first completed trie */
	if (parms[n].cmplt->count != ctx->num_tries) {
		for (i = 0; i < categories; i += RTE_ACL_RESULTS_MULTIPLIER) {

			if (saved_priority[i] <= priority[i]) {
				saved_priority[i] = priority[i];
				saved_results[i] = results[i];
			}
			if (saved_priority[i + 1] <= priority[i + 1]) {
				saved_priority[i + 1] = priority[i + 1];
				saved_results[i + 1] = results[i + 1];
			}
			if (saved_priority[i + 2] <= priority[i + 2]) {
				saved_priority[i + 2] = priority[i + 2];
				saved_results[i + 2] = results[i + 2];
			}
			if (saved_priority[i + 3] <= priority[i + 3]) {
				saved_priority[i + 3] = priority[i + 3];
				saved_results[i + 3] = results[i + 3];
			}
		}
	} else {
		for (i = 0; i < categories; i += RTE_ACL_RESULTS_MULTIPLIER) {
			saved_priority[i] = priority[i];
			saved_priority[i + 1] = priority[i + 1];
			saved_priority[i + 2] = priority[i + 2];
			saved_priority[i + 3] = priority[i + 3];

			saved_results[i] = results[i];
			saved_results[i + 1] = results[i + 1];
			saved_results[i + 2] = results[i + 2];
			saved_results[i + 3] = results[i + 3];
		}
	}
}

static inline uint32_t
scan_forward(uint32_t input, uint32_t max)
{
	return (input == 0) ? max : rte_bsf32(input);
}

static inline uint64_t
scalar_transition(const uint64_t *trans_table, uint64_t transition,
	uint8_t input)
{
	uint32_t addr, index, ranges, x, a, b, c;

	/* break transition into component parts */
	ranges = transition >> (sizeof(index) * CHAR_BIT);
	index = transition & ~RTE_ACL_NODE_INDEX;
	addr = transition ^ index;

	if (index != RTE_ACL_NODE_DFA) {
		/* calc address for a QRANGE/SINGLE node */
		c = (uint32_t)input * SCALAR_QRANGE_MULT;
		a = ranges | SCALAR_QRANGE_MIN;
		a -= (c & SCALAR_QRANGE_MASK);
		b = c & SCALAR_QRANGE_MIN;
		a &= SCALAR_QRANGE_MIN;
		a ^= (ranges ^ b) & (a ^ b);
		x = scan_forward(a, 32) >> 3;
	} else {
		/* calc address for a DFA node */
		x = ranges >> (input /
			RTE_ACL_DFA_GR64_SIZE * RTE_ACL_DFA_GR64_BIT);
		x &= UINT8_MAX;
		x = input - x;
	}

	addr += x;

	/* pickup next transition */
	transition = *(trans_table + addr);
	return transition;
}

int
rte_acl_classify_scalar(const struct rte_acl_ctx *ctx, const uint8_t **data,
	uint32_t *results, uint32_t num, uint32_t categories)
{
	int n;
	uint64_t transition0, transition1;
	uint32_t input0, input1;
	struct acl_flow_data flows;
	uint64_t index_array[MAX_SEARCHES_SCALAR];
	struct completion cmplt[MAX_SEARCHES_SCALAR];
	struct parms parms[MAX_SEARCHES_SCALAR];

	acl_set_flow(&flows, cmplt, RTE_DIM(cmplt), data, results, num,
		categories, ctx->trans_table);

	for (n = 0; n < MAX_SEARCHES_SCALAR; n++) {
		cmplt[n].count = 0;
		index_array[n] = acl_start_next_trie(&flows, parms, n, ctx);
	}

	transition0 = index_array[0];
	transition1 = index_array[1];

	while ((transition0 | transition1) & RTE_ACL_NODE_MATCH) {
		transition0 = acl_match_check(transition0,
			0, ctx, parms, &flows, resolve_priority_scalar);
		transition1 = acl_match_check(transition1,
			1, ctx, parms, &flows, resolve_priority_scalar);
	}

	while (flows.started > 0) {

		input0 = GET_NEXT_4BYTES(parms, 0);
		input1 = GET_NEXT_4BYTES(parms, 1);

		for (n = 0; n < 4; n++) {

			transition0 = scalar_transition(flows.trans,
				transition0, (uint8_t)input0);
			input0 >>= CHAR_BIT;

			transition1 = scalar_transition(flows.trans,
				transition1, (uint8_t)input1);
			input1 >>= CHAR_BIT;
		}

		while ((transition0 | transition1) & RTE_ACL_NODE_MATCH) {
			transition0 = acl_match_check(transition0,
				0, ctx, parms, &flows, resolve_priority_scalar);
			transition1 = acl_match_check(transition1,
				1, ctx, parms, &flows, resolve_priority_scalar);
		}
	}
	return 0;
}