#include "bnxt.h"
-
#define PTU_PTE_VALID 0x1UL
#define PTU_PTE_LAST 0x2UL
#define PTU_PTE_NEXT_TO_LAST 0x4UL
/* Number of pointers per page_size */
#define MAX_PAGE_PTRS(page_size) ((page_size) / sizeof(void *))
-#define TF_EM_PG_SZ_4K (1 << 12)
-#define TF_EM_PG_SZ_8K (1 << 13)
-#define TF_EM_PG_SZ_64K (1 << 16)
-#define TF_EM_PG_SZ_256K (1 << 18)
-#define TF_EM_PG_SZ_1M (1 << 20)
-#define TF_EM_PG_SZ_2M (1 << 21)
-#define TF_EM_PG_SZ_4M (1 << 22)
-#define TF_EM_PG_SZ_1G (1 << 30)
-
-#define TF_EM_CTX_ID_INVALID 0xFFFF
-
-#define TF_EM_MIN_ENTRIES (1 << 15) /* 32K */
-#define TF_EM_MAX_ENTRIES (1 << 27) /* 128M */
-
/**
* EM DBs.
*/
extern void *eem_db[TF_DIR_MAX];
-#define TF_EEM_DB_TBL_SCOPE 1
extern struct tf_tbl_scope_cb tbl_scopes[TF_NUM_TBL_SCOPE];
tbl->l0_dma_addr = tbl->pg_tbl[TF_PT_LVL_0].pg_pa_tbl[0];
}
-/**
- * Given the page size, size of each data item (entry size),
- * and the total number of entries needed, determine the number
- * of page table levels and the number of data pages required.
- *
- * [in] page_size
- * Page size
- *
- * [in] entry_size
- * Entry size
- *
- * [in] num_entries
- * Number of entries needed
- *
- * [out] num_data_pages
- * Number of pages required
- *
- * Returns:
- * Success - Number of EM page levels required
- * -ENOMEM - Out of memory
- */
-static int
-tf_em_size_page_tbl_lvl(uint32_t page_size,
- uint32_t entry_size,
- uint32_t num_entries,
- uint64_t *num_data_pages)
-{
- uint64_t lvl_data_size = page_size;
- int lvl = TF_PT_LVL_0;
- uint64_t data_size;
-
- *num_data_pages = 0;
- data_size = (uint64_t)num_entries * entry_size;
-
- while (lvl_data_size < data_size) {
- lvl++;
-
- if (lvl == TF_PT_LVL_1)
- lvl_data_size = (uint64_t)MAX_PAGE_PTRS(page_size) *
- page_size;
- else if (lvl == TF_PT_LVL_2)
- lvl_data_size = (uint64_t)MAX_PAGE_PTRS(page_size) *
- MAX_PAGE_PTRS(page_size) * page_size;
- else
- return -ENOMEM;
- }
-
- *num_data_pages = roundup(data_size, page_size) / page_size;
-
- return lvl;
-}
-
-/**
- * Return the number of page table pages needed to
- * reference the given number of next level pages.
- *
- * [in] num_pages
- * Number of EM pages
- *
- * [in] page_size
- * Size of each EM page
- *
- * Returns:
- * Number of EM page table pages
- */
-static uint32_t
-tf_em_page_tbl_pgcnt(uint32_t num_pages,
- uint32_t page_size)
-{
- return roundup(num_pages, MAX_PAGE_PTRS(page_size)) /
- MAX_PAGE_PTRS(page_size);
- return 0;
-}
-
-/**
- * Given the number of data pages, page_size and the maximum
- * number of page table levels (already determined), size
- * the number of page table pages required at each level.
- *
- * [in] max_lvl
- * Max number of levels
- *
- * [in] num_data_pages
- * Number of EM data pages
- *
- * [in] page_size
- * Size of an EM page
- *
- * [out] *page_cnt
- * EM page count
- */
-static void
-tf_em_size_page_tbls(int max_lvl,
- uint64_t num_data_pages,
- uint32_t page_size,
- uint32_t *page_cnt)
-{
- if (max_lvl == TF_PT_LVL_0) {
- page_cnt[TF_PT_LVL_0] = num_data_pages;
- } else if (max_lvl == TF_PT_LVL_1) {
- page_cnt[TF_PT_LVL_1] = num_data_pages;
- page_cnt[TF_PT_LVL_0] =
- tf_em_page_tbl_pgcnt(page_cnt[TF_PT_LVL_1], page_size);
- } else if (max_lvl == TF_PT_LVL_2) {
- page_cnt[TF_PT_LVL_2] = num_data_pages;
- page_cnt[TF_PT_LVL_1] =
- tf_em_page_tbl_pgcnt(page_cnt[TF_PT_LVL_2], page_size);
- page_cnt[TF_PT_LVL_0] =
- tf_em_page_tbl_pgcnt(page_cnt[TF_PT_LVL_1], page_size);
- } else {
- return;
- }
-}
-
-/**
- * Size the EM table based on capabilities
- *
- * [in] tbl
- * EM table to size
- *
- * Returns:
- * 0 - Success
- * - EINVAL - Parameter error
- * - ENOMEM - Out of memory
- */
-static int
-tf_em_size_table(struct hcapi_cfa_em_table *tbl)
-{
- uint64_t num_data_pages;
- uint32_t *page_cnt;
- int max_lvl;
- uint32_t num_entries;
- uint32_t cnt = TF_EM_MIN_ENTRIES;
-
- /* Ignore entry if both size and number are zero */
- if (!tbl->entry_size && !tbl->num_entries)
- return 0;
-
- /* If only one is set then error */
- if (!tbl->entry_size || !tbl->num_entries)
- return -EINVAL;
-
- /* Determine number of page table levels and the number
- * of data pages needed to process the given eem table.
- */
- if (tbl->type == TF_RECORD_TABLE) {
- /*
- * For action records just a memory size is provided. Work
- * backwards to resolve to number of entries
- */
- num_entries = tbl->num_entries / tbl->entry_size;
- if (num_entries < TF_EM_MIN_ENTRIES) {
- num_entries = TF_EM_MIN_ENTRIES;
- } else {
- while (num_entries > cnt && cnt <= TF_EM_MAX_ENTRIES)
- cnt *= 2;
- num_entries = cnt;
- }
- } else {
- num_entries = tbl->num_entries;
- }
-
- max_lvl = tf_em_size_page_tbl_lvl(TF_EM_PAGE_SIZE,
- tbl->entry_size,
- tbl->num_entries,
- &num_data_pages);
- if (max_lvl < 0) {
- TFP_DRV_LOG(WARNING, "EEM: Failed to size page table levels\n");
- TFP_DRV_LOG(WARNING,
- "table: %d data-sz: %016" PRIu64 " page-sz: %u\n",
- tbl->type, (uint64_t)num_entries * tbl->entry_size,
- TF_EM_PAGE_SIZE);
- return -ENOMEM;
- }
-
- tbl->num_lvl = max_lvl + 1;
- tbl->num_data_pages = num_data_pages;
-
- /* Determine the number of pages needed at each level */
- page_cnt = tbl->page_cnt;
- memset(page_cnt, 0, sizeof(tbl->page_cnt));
- tf_em_size_page_tbls(max_lvl, num_data_pages, TF_EM_PAGE_SIZE,
- page_cnt);
-
- TFP_DRV_LOG(INFO, "EEM: Sized page table: %d\n", tbl->type);
- TFP_DRV_LOG(INFO,
- "EEM: lvls: %d sz: %016" PRIu64 " pgs: %016" PRIu64 " l0: %u l1: %u l2: %u\n",
- max_lvl + 1,
- (uint64_t)num_data_pages * TF_EM_PAGE_SIZE,
- num_data_pages,
- page_cnt[TF_PT_LVL_0],
- page_cnt[TF_PT_LVL_1],
- page_cnt[TF_PT_LVL_2]);
-
- return 0;
-}
-
/**
* Unregisters EM Ctx in Firmware
*
{
struct hcapi_cfa_em_ctx_mem_info *ctxp = &tbl_scope_cb->em_ctx_info[dir];
struct hcapi_cfa_em_table *tbl;
- int rc;
+ int rc = 0;
int i;
for (i = TF_KEY0_TABLE; i < TF_MAX_TABLE; i++) {
tbl = &ctxp->em_tables[i];
if (tbl->num_entries && tbl->entry_size) {
- rc = tf_em_size_table(tbl);
+ rc = tf_em_size_table(tbl, TF_EM_PAGE_SIZE);
if (rc)
goto cleanup;
return rc;
}
-
-/**
- * Validates EM number of entries requested
- *
- * [in] tbl_scope_cb
- * Pointer to table scope control block to be populated
- *
- * [in] parms
- * Pointer to input parameters
- *
- * Returns:
- * 0 - Success
- * -EINVAL - Parameter error
- */
-static int
-tf_em_validate_num_entries(struct tf_tbl_scope_cb *tbl_scope_cb,
- struct tf_alloc_tbl_scope_parms *parms)
-{
- uint32_t cnt;
-
- if (parms->rx_mem_size_in_mb != 0) {
- uint32_t key_b = 2 * ((parms->rx_max_key_sz_in_bits / 8) + 1);
- uint32_t action_b = ((parms->rx_max_action_entry_sz_in_bits / 8)
- + 1);
- uint32_t num_entries = (parms->rx_mem_size_in_mb *
- TF_MEGABYTE) / (key_b + action_b);
-
- if (num_entries < TF_EM_MIN_ENTRIES) {
- TFP_DRV_LOG(ERR, "EEM: Insufficient memory requested:"
- "%uMB\n",
- parms->rx_mem_size_in_mb);
- return -EINVAL;
- }
-
- cnt = TF_EM_MIN_ENTRIES;
- while (num_entries > cnt &&
- cnt <= TF_EM_MAX_ENTRIES)
- cnt *= 2;
-
- if (cnt > TF_EM_MAX_ENTRIES) {
- TFP_DRV_LOG(ERR, "EEM: Invalid number of Tx requested: "
- "%u\n",
- (parms->tx_num_flows_in_k * TF_KILOBYTE));
- return -EINVAL;
- }
-
- parms->rx_num_flows_in_k = cnt / TF_KILOBYTE;
- } else {
- if ((parms->rx_num_flows_in_k * TF_KILOBYTE) <
- TF_EM_MIN_ENTRIES ||
- (parms->rx_num_flows_in_k * TF_KILOBYTE) >
- tbl_scope_cb->em_caps[TF_DIR_RX].max_entries_supported) {
- TFP_DRV_LOG(ERR,
- "EEM: Invalid number of Rx flows "
- "requested:%u max:%u\n",
- parms->rx_num_flows_in_k * TF_KILOBYTE,
- tbl_scope_cb->em_caps[TF_DIR_RX].max_entries_supported);
- return -EINVAL;
- }
-
- /* must be a power-of-2 supported value
- * in the range 32K - 128M
- */
- cnt = TF_EM_MIN_ENTRIES;
- while ((parms->rx_num_flows_in_k * TF_KILOBYTE) != cnt &&
- cnt <= TF_EM_MAX_ENTRIES)
- cnt *= 2;
-
- if (cnt > TF_EM_MAX_ENTRIES) {
- TFP_DRV_LOG(ERR,
- "EEM: Invalid number of Rx requested: %u\n",
- (parms->rx_num_flows_in_k * TF_KILOBYTE));
- return -EINVAL;
- }
- }
-
- if (parms->tx_mem_size_in_mb != 0) {
- uint32_t key_b = 2 * (parms->tx_max_key_sz_in_bits / 8 + 1);
- uint32_t action_b = ((parms->tx_max_action_entry_sz_in_bits / 8)
- + 1);
- uint32_t num_entries = (parms->tx_mem_size_in_mb *
- (TF_KILOBYTE * TF_KILOBYTE)) /
- (key_b + action_b);
-
- if (num_entries < TF_EM_MIN_ENTRIES) {
- TFP_DRV_LOG(ERR,
- "EEM: Insufficient memory requested:%uMB\n",
- parms->rx_mem_size_in_mb);
- return -EINVAL;
- }
-
- cnt = TF_EM_MIN_ENTRIES;
- while (num_entries > cnt &&
- cnt <= TF_EM_MAX_ENTRIES)
- cnt *= 2;
-
- if (cnt > TF_EM_MAX_ENTRIES) {
- TFP_DRV_LOG(ERR,
- "EEM: Invalid number of Tx requested: %u\n",
- (parms->tx_num_flows_in_k * TF_KILOBYTE));
- return -EINVAL;
- }
-
- parms->tx_num_flows_in_k = cnt / TF_KILOBYTE;
- } else {
- if ((parms->tx_num_flows_in_k * TF_KILOBYTE) <
- TF_EM_MIN_ENTRIES ||
- (parms->tx_num_flows_in_k * TF_KILOBYTE) >
- tbl_scope_cb->em_caps[TF_DIR_TX].max_entries_supported) {
- TFP_DRV_LOG(ERR,
- "EEM: Invalid number of Tx flows "
- "requested:%u max:%u\n",
- (parms->tx_num_flows_in_k * TF_KILOBYTE),
- tbl_scope_cb->em_caps[TF_DIR_TX].max_entries_supported);
- return -EINVAL;
- }
-
- cnt = TF_EM_MIN_ENTRIES;
- while ((parms->tx_num_flows_in_k * TF_KILOBYTE) != cnt &&
- cnt <= TF_EM_MAX_ENTRIES)
- cnt *= 2;
-
- if (cnt > TF_EM_MAX_ENTRIES) {
- TFP_DRV_LOG(ERR,
- "EEM: Invalid number of Tx requested: %u\n",
- (parms->tx_num_flows_in_k * TF_KILOBYTE));
- return -EINVAL;
- }
- }
-
- if (parms->rx_num_flows_in_k != 0 &&
- (parms->rx_max_key_sz_in_bits / 8 == 0)) {
- TFP_DRV_LOG(ERR,
- "EEM: Rx key size required: %u\n",
- (parms->rx_max_key_sz_in_bits));
- return -EINVAL;
- }
-
- if (parms->tx_num_flows_in_k != 0 &&
- (parms->tx_max_key_sz_in_bits / 8 == 0)) {
- TFP_DRV_LOG(ERR,
- "EEM: Tx key size required: %u\n",
- (parms->tx_max_key_sz_in_bits));
- return -EINVAL;
- }
- /* Rx */
- tbl_scope_cb->em_ctx_info[TF_DIR_RX].em_tables[TF_KEY0_TABLE].num_entries =
- parms->rx_num_flows_in_k * TF_KILOBYTE;
- tbl_scope_cb->em_ctx_info[TF_DIR_RX].em_tables[TF_KEY0_TABLE].entry_size =
- parms->rx_max_key_sz_in_bits / 8;
-
- tbl_scope_cb->em_ctx_info[TF_DIR_RX].em_tables[TF_KEY1_TABLE].num_entries =
- parms->rx_num_flows_in_k * TF_KILOBYTE;
- tbl_scope_cb->em_ctx_info[TF_DIR_RX].em_tables[TF_KEY1_TABLE].entry_size =
- parms->rx_max_key_sz_in_bits / 8;
-
- tbl_scope_cb->em_ctx_info[TF_DIR_RX].em_tables[TF_RECORD_TABLE].num_entries =
- parms->rx_num_flows_in_k * TF_KILOBYTE;
- tbl_scope_cb->em_ctx_info[TF_DIR_RX].em_tables[TF_RECORD_TABLE].entry_size =
- parms->rx_max_action_entry_sz_in_bits / 8;
-
- tbl_scope_cb->em_ctx_info[TF_DIR_RX].em_tables[TF_EFC_TABLE].num_entries = 0;
-
- /* Tx */
- tbl_scope_cb->em_ctx_info[TF_DIR_TX].em_tables[TF_KEY0_TABLE].num_entries =
- parms->tx_num_flows_in_k * TF_KILOBYTE;
- tbl_scope_cb->em_ctx_info[TF_DIR_TX].em_tables[TF_KEY0_TABLE].entry_size =
- parms->tx_max_key_sz_in_bits / 8;
-
- tbl_scope_cb->em_ctx_info[TF_DIR_TX].em_tables[TF_KEY1_TABLE].num_entries =
- parms->tx_num_flows_in_k * TF_KILOBYTE;
- tbl_scope_cb->em_ctx_info[TF_DIR_TX].em_tables[TF_KEY1_TABLE].entry_size =
- parms->tx_max_key_sz_in_bits / 8;
-
- tbl_scope_cb->em_ctx_info[TF_DIR_TX].em_tables[TF_RECORD_TABLE].num_entries =
- parms->tx_num_flows_in_k * TF_KILOBYTE;
- tbl_scope_cb->em_ctx_info[TF_DIR_TX].em_tables[TF_RECORD_TABLE].entry_size =
- parms->tx_max_action_entry_sz_in_bits / 8;
-
- tbl_scope_cb->em_ctx_info[TF_DIR_TX].em_tables[TF_EFC_TABLE].num_entries = 0;
-
- return 0;
-}
-
-/** insert EEM entry API
- *
- * returns:
- * 0
- * TF_ERR - unable to get lock
- *
- * insert callback returns:
- * 0
- * TF_ERR_EM_DUP - key is already in table
- */
-static int
-tf_insert_eem_entry(struct tf_tbl_scope_cb *tbl_scope_cb,
- struct tf_insert_em_entry_parms *parms)
-{
- uint32_t mask;
- uint32_t key0_hash;
- uint32_t key1_hash;
- uint32_t key0_index;
- uint32_t key1_index;
- struct cfa_p4_eem_64b_entry key_entry;
- uint32_t index;
- enum hcapi_cfa_em_table_type table_type;
- uint32_t gfid;
- struct hcapi_cfa_hwop op;
- struct hcapi_cfa_key_tbl key_tbl;
- struct hcapi_cfa_key_data key_obj;
- struct hcapi_cfa_key_loc key_loc;
- uint64_t big_hash;
- int rc;
-
- /* Get mask to use on hash */
- mask = tf_em_get_key_mask(tbl_scope_cb->em_ctx_info[parms->dir].em_tables[TF_KEY0_TABLE].num_entries);
-
- if (!mask)
- return -EINVAL;
-
-#ifdef TF_EEM_DEBUG
- dump_raw((uint8_t *)parms->key, TF_HW_EM_KEY_MAX_SIZE + 4, "In Key");
-#endif
-
- big_hash = hcapi_cfa_key_hash((uint64_t *)parms->key,
- (TF_HW_EM_KEY_MAX_SIZE + 4) * 8);
- key0_hash = (uint32_t)(big_hash >> 32);
- key1_hash = (uint32_t)(big_hash & 0xFFFFFFFF);
-
- key0_index = key0_hash & mask;
- key1_index = key1_hash & mask;
-
-#ifdef TF_EEM_DEBUG
- TFP_DRV_LOG(DEBUG, "Key0 hash:0x%08x\n", key0_hash);
- TFP_DRV_LOG(DEBUG, "Key1 hash:0x%08x\n", key1_hash);
-#endif
- /*
- * Use the "result" arg to populate all of the key entry then
- * store the byte swapped "raw" entry in a local copy ready
- * for insertion in to the table.
- */
- tf_em_create_key_entry((struct cfa_p4_eem_entry_hdr *)parms->em_record,
- ((uint8_t *)parms->key),
- &key_entry);
-
- /*
- * Try to add to Key0 table, if that does not work then
- * try the key1 table.
- */
- index = key0_index;
- op.opcode = HCAPI_CFA_HWOPS_ADD;
- key_tbl.base0 = (uint8_t *)
- &tbl_scope_cb->em_ctx_info[parms->dir].em_tables[TF_KEY0_TABLE];
- key_obj.offset = (index * TF_EM_KEY_RECORD_SIZE) % TF_EM_PAGE_SIZE;
- key_obj.data = (uint8_t *)&key_entry;
- key_obj.size = TF_EM_KEY_RECORD_SIZE;
-
- rc = hcapi_cfa_key_hw_op(&op,
- &key_tbl,
- &key_obj,
- &key_loc);
-
- if (rc == 0) {
- table_type = TF_KEY0_TABLE;
- } else {
- index = key1_index;
-
- key_tbl.base0 = (uint8_t *)
- &tbl_scope_cb->em_ctx_info[parms->dir].em_tables[TF_KEY1_TABLE];
- key_obj.offset =
- (index * TF_EM_KEY_RECORD_SIZE) % TF_EM_PAGE_SIZE;
-
- rc = hcapi_cfa_key_hw_op(&op,
- &key_tbl,
- &key_obj,
- &key_loc);
- if (rc != 0)
- return rc;
-
- table_type = TF_KEY1_TABLE;
- }
-
- TF_SET_GFID(gfid,
- index,
- table_type);
- TF_SET_FLOW_ID(parms->flow_id,
- gfid,
- TF_GFID_TABLE_EXTERNAL,
- parms->dir);
- TF_SET_FIELDS_IN_FLOW_HANDLE(parms->flow_handle,
- 0,
- 0,
- 0,
- index,
- 0,
- table_type);
-
- return 0;
-}
-
-/** delete EEM hash entry API
- *
- * returns:
- * 0
- * -EINVAL - parameter error
- * TF_NO_SESSION - bad session ID
- * TF_ERR_TBL_SCOPE - invalid table scope
- * TF_ERR_TBL_IF - invalid table interface
- *
- * insert callback returns
- * 0
- * TF_NO_EM_MATCH - entry not found
- */
-static int
-tf_delete_eem_entry(struct tf_tbl_scope_cb *tbl_scope_cb,
- struct tf_delete_em_entry_parms *parms)
-{
- enum hcapi_cfa_em_table_type hash_type;
- uint32_t index;
- struct hcapi_cfa_hwop op;
- struct hcapi_cfa_key_tbl key_tbl;
- struct hcapi_cfa_key_data key_obj;
- struct hcapi_cfa_key_loc key_loc;
- int rc;
-
- if (parms->flow_handle == 0)
- return -EINVAL;
-
- TF_GET_HASH_TYPE_FROM_FLOW_HANDLE(parms->flow_handle, hash_type);
- TF_GET_INDEX_FROM_FLOW_HANDLE(parms->flow_handle, index);
-
- op.opcode = HCAPI_CFA_HWOPS_DEL;
- key_tbl.base0 = (uint8_t *)
- &tbl_scope_cb->em_ctx_info[parms->dir].em_tables[(hash_type == 0 ?
- TF_KEY0_TABLE :
- TF_KEY1_TABLE)];
- key_obj.offset = (index * TF_EM_KEY_RECORD_SIZE) % TF_EM_PAGE_SIZE;
- key_obj.data = NULL;
- key_obj.size = TF_EM_KEY_RECORD_SIZE;
-
- rc = hcapi_cfa_key_hw_op(&op,
- &key_tbl,
- &key_obj,
- &key_loc);
-
- if (!rc)
- return rc;
-
- return 0;
-}
-
-/** insert EM hash entry API
- *
- * returns:
- * 0 - Success
- * -EINVAL - Error
- */
int
-tf_em_insert_ext_entry(struct tf *tfp __rte_unused,
- struct tf_insert_em_entry_parms *parms)
-{
- struct tf_tbl_scope_cb *tbl_scope_cb;
-
- tbl_scope_cb = tbl_scope_cb_find(parms->tbl_scope_id);
- if (tbl_scope_cb == NULL) {
- TFP_DRV_LOG(ERR, "Invalid tbl_scope_cb\n");
- return -EINVAL;
- }
-
- return tf_insert_eem_entry(tbl_scope_cb, parms);
-}
-
-/** Delete EM hash entry API
- *
- * returns:
- * 0 - Success
- * -EINVAL - Error
- */
-int
-tf_em_delete_ext_entry(struct tf *tfp __rte_unused,
- struct tf_delete_em_entry_parms *parms)
-{
- struct tf_tbl_scope_cb *tbl_scope_cb;
-
- tbl_scope_cb = tbl_scope_cb_find(parms->tbl_scope_id);
- if (tbl_scope_cb == NULL) {
- TFP_DRV_LOG(ERR, "Invalid tbl_scope_cb\n");
- return -EINVAL;
- }
-
- return tf_delete_eem_entry(tbl_scope_cb, parms);
-}
-
-int
-tf_em_ext_host_alloc(struct tf *tfp,
- struct tf_alloc_tbl_scope_parms *parms)
+tf_em_ext_alloc(struct tf *tfp, struct tf_alloc_tbl_scope_parms *parms)
{
int rc;
enum tf_dir dir;
/* Get Table Scope control block from the session pool */
aparms.rm_db = eem_db[TF_DIR_RX];
- aparms.db_index = TF_EEM_DB_TBL_SCOPE;
+ aparms.db_index = TF_EM_TBL_TYPE_TBL_SCOPE;
aparms.index = (uint32_t *)&parms->tbl_scope_id;
rc = tf_rm_allocate(&aparms);
if (rc) {
tbl_scope_cb->index = parms->tbl_scope_id;
tbl_scope_cb->tbl_scope_id = parms->tbl_scope_id;
+ rc = tfp_get_pf(tfp, &tbl_scope_cb->pf);
+ if (rc) {
+ TFP_DRV_LOG(ERR,
+ "EEM: PF query error rc:%s\n",
+ strerror(-rc));
+ goto cleanup;
+ }
+
for (dir = 0; dir < TF_DIR_MAX; dir++) {
rc = tf_msg_em_qcaps(tfp,
dir,
cleanup_full:
free_parms.tbl_scope_id = parms->tbl_scope_id;
- tf_em_ext_host_free(tfp, &free_parms);
+ tf_em_ext_free(tfp, &free_parms);
return -EINVAL;
cleanup:
/* Free Table control block */
fparms.rm_db = eem_db[TF_DIR_RX];
- fparms.db_index = TF_EEM_DB_TBL_SCOPE;
+ fparms.db_index = TF_EM_TBL_TYPE_TBL_SCOPE;
fparms.index = parms->tbl_scope_id;
tf_rm_free(&fparms);
return -EINVAL;
}
int
-tf_em_ext_host_free(struct tf *tfp,
- struct tf_free_tbl_scope_parms *parms)
+tf_em_ext_free(struct tf *tfp,
+ struct tf_free_tbl_scope_parms *parms)
{
int rc = 0;
enum tf_dir dir;
/* Free Table control block */
aparms.rm_db = eem_db[TF_DIR_RX];
- aparms.db_index = TF_EEM_DB_TBL_SCOPE;
+ aparms.db_index = TF_EM_TBL_TYPE_TBL_SCOPE;
aparms.index = parms->tbl_scope_id;
rc = tf_rm_free(&aparms);
if (rc) {
tf_em_ctx_unreg(tfp, tbl_scope_cb, dir);
}
- tbl_scopes[parms->tbl_scope_id].tbl_scope_id = -1;
+ tbl_scopes[parms->tbl_scope_id].tbl_scope_id = TF_TBL_SCOPE_INVALID;
return rc;
}