1 // SPDX-License-Identifier: BSD-3-Clause OR GPL-2.0
2 /* Copyright (c) 2018 Mellanox Technologies. All rights reserved */
4 #include <linux/kernel.h>
5 #include <linux/bitops.h>
10 #include "resources.h"
12 struct mlxsw_sp2_kvdl_part_info {
14 /* For each defined partititon we need to know how many
15 * usage bits we need and how many indexes there are
16 * represented by a single bit. This could be got from FW
17 * querying appropriate resources. So have the resource
18 * ids for this purpose in partition definition.
20 enum mlxsw_res_id usage_bit_count_res_id;
21 enum mlxsw_res_id index_range_res_id;
24 #define MLXSW_SP2_KVDL_PART_INFO(_entry_type, _res_type, \
25 _usage_bit_count_res_id, _index_range_res_id) \
26 [MLXSW_SP_KVDL_ENTRY_TYPE_##_entry_type] = { \
27 .res_type = _res_type, \
28 .usage_bit_count_res_id = MLXSW_RES_ID_##_usage_bit_count_res_id, \
29 .index_range_res_id = MLXSW_RES_ID_##_index_range_res_id, \
32 static const struct mlxsw_sp2_kvdl_part_info mlxsw_sp2_kvdl_parts_info[] = {
33 MLXSW_SP2_KVDL_PART_INFO(ADJ, 0x21, KVD_SIZE, MAX_KVD_LINEAR_RANGE),
34 MLXSW_SP2_KVDL_PART_INFO(ACTSET, 0x23, MAX_KVD_ACTION_SETS,
36 MLXSW_SP2_KVDL_PART_INFO(PBS, 0x24, KVD_SIZE, KVD_SIZE),
37 MLXSW_SP2_KVDL_PART_INFO(MCRIGR, 0x26, KVD_SIZE, KVD_SIZE),
38 MLXSW_SP2_KVDL_PART_INFO(IPV6_ADDRESS, 0x28, KVD_SIZE, KVD_SIZE),
39 MLXSW_SP2_KVDL_PART_INFO(TNUMT, 0x29, KVD_SIZE, KVD_SIZE),
42 #define MLXSW_SP2_KVDL_PARTS_INFO_LEN ARRAY_SIZE(mlxsw_sp2_kvdl_parts_info)
44 struct mlxsw_sp2_kvdl_part {
45 const struct mlxsw_sp2_kvdl_part_info *info;
46 unsigned int usage_bit_count;
47 unsigned int indexes_per_usage_bit;
48 unsigned int last_allocated_bit;
49 unsigned long usage[]; /* Usage bits */
52 struct mlxsw_sp2_kvdl {
53 struct mlxsw_sp2_kvdl_part *parts[MLXSW_SP2_KVDL_PARTS_INFO_LEN];
56 static int mlxsw_sp2_kvdl_part_find_zero_bits(struct mlxsw_sp2_kvdl_part *part,
57 unsigned int bit_count,
60 unsigned int start_bit;
65 start_bit = part->last_allocated_bit + 1;
66 if (start_bit == part->usage_bit_count)
70 bit = find_next_zero_bit(part->usage, part->usage_bit_count, bit);
71 if (!wrap && bit + bit_count >= part->usage_bit_count) {
76 if (wrap && bit + bit_count >= start_bit)
78 for (i = 0; i < bit_count; i++) {
79 if (test_bit(bit + i, part->usage)) {
88 static int mlxsw_sp2_kvdl_part_alloc(struct mlxsw_sp2_kvdl_part *part,
92 unsigned int bit_count;
97 bit_count = DIV_ROUND_UP(size, part->indexes_per_usage_bit);
98 err = mlxsw_sp2_kvdl_part_find_zero_bits(part, bit_count, &bit);
101 for (i = 0; i < bit_count; i++)
102 __set_bit(bit + i, part->usage);
103 *p_kvdl_index = bit * part->indexes_per_usage_bit;
107 static int mlxsw_sp2_kvdl_rec_del(struct mlxsw_sp *mlxsw_sp, u8 res_type,
108 u16 size, u32 kvdl_index)
113 iedr_pl = kmalloc(MLXSW_REG_IEDR_LEN, GFP_KERNEL);
117 mlxsw_reg_iedr_pack(iedr_pl);
118 mlxsw_reg_iedr_rec_pack(iedr_pl, 0, res_type, size, kvdl_index);
119 err = mlxsw_reg_write(mlxsw_sp->core, MLXSW_REG(iedr), iedr_pl);
124 static void mlxsw_sp2_kvdl_part_free(struct mlxsw_sp *mlxsw_sp,
125 struct mlxsw_sp2_kvdl_part *part,
126 unsigned int size, u32 kvdl_index)
128 unsigned int bit_count;
133 /* We need to ask FW to delete previously used KVD linear index */
134 err = mlxsw_sp2_kvdl_rec_del(mlxsw_sp, part->info->res_type,
139 bit_count = DIV_ROUND_UP(size, part->indexes_per_usage_bit);
140 bit = kvdl_index / part->indexes_per_usage_bit;
141 for (i = 0; i < bit_count; i++)
142 __clear_bit(bit + i, part->usage);
145 static int mlxsw_sp2_kvdl_alloc(struct mlxsw_sp *mlxsw_sp, void *priv,
146 enum mlxsw_sp_kvdl_entry_type type,
147 unsigned int entry_count,
150 unsigned int size = entry_count * mlxsw_sp_kvdl_entry_size(type);
151 struct mlxsw_sp2_kvdl *kvdl = priv;
152 struct mlxsw_sp2_kvdl_part *part = kvdl->parts[type];
154 return mlxsw_sp2_kvdl_part_alloc(part, size, p_entry_index);
157 static void mlxsw_sp2_kvdl_free(struct mlxsw_sp *mlxsw_sp, void *priv,
158 enum mlxsw_sp_kvdl_entry_type type,
159 unsigned int entry_count,
162 unsigned int size = entry_count * mlxsw_sp_kvdl_entry_size(type);
163 struct mlxsw_sp2_kvdl *kvdl = priv;
164 struct mlxsw_sp2_kvdl_part *part = kvdl->parts[type];
166 return mlxsw_sp2_kvdl_part_free(mlxsw_sp, part, size, entry_index);
169 static int mlxsw_sp2_kvdl_alloc_size_query(struct mlxsw_sp *mlxsw_sp,
171 enum mlxsw_sp_kvdl_entry_type type,
172 unsigned int entry_count,
173 unsigned int *p_alloc_count)
175 *p_alloc_count = entry_count;
179 static struct mlxsw_sp2_kvdl_part *
180 mlxsw_sp2_kvdl_part_init(struct mlxsw_sp *mlxsw_sp,
181 const struct mlxsw_sp2_kvdl_part_info *info)
183 unsigned int indexes_per_usage_bit;
184 struct mlxsw_sp2_kvdl_part *part;
185 unsigned int index_range;
186 unsigned int usage_bit_count;
189 if (!mlxsw_core_res_valid(mlxsw_sp->core,
190 info->usage_bit_count_res_id) ||
191 !mlxsw_core_res_valid(mlxsw_sp->core,
192 info->index_range_res_id))
193 return ERR_PTR(-EIO);
194 usage_bit_count = mlxsw_core_res_get(mlxsw_sp->core,
195 info->usage_bit_count_res_id);
196 index_range = mlxsw_core_res_get(mlxsw_sp->core,
197 info->index_range_res_id);
199 /* For some partitions, one usage bit represents a group of indexes.
200 * That's why we compute the number of indexes per usage bit here,
201 * according to queried resources.
203 indexes_per_usage_bit = index_range / usage_bit_count;
205 usage_size = BITS_TO_LONGS(usage_bit_count) * sizeof(unsigned long);
206 part = kzalloc(sizeof(*part) + usage_size, GFP_KERNEL);
208 return ERR_PTR(-ENOMEM);
210 part->usage_bit_count = usage_bit_count;
211 part->indexes_per_usage_bit = indexes_per_usage_bit;
212 part->last_allocated_bit = usage_bit_count - 1;
216 static void mlxsw_sp2_kvdl_part_fini(struct mlxsw_sp2_kvdl_part *part)
221 static int mlxsw_sp2_kvdl_parts_init(struct mlxsw_sp *mlxsw_sp,
222 struct mlxsw_sp2_kvdl *kvdl)
224 const struct mlxsw_sp2_kvdl_part_info *info;
228 for (i = 0; i < MLXSW_SP2_KVDL_PARTS_INFO_LEN; i++) {
229 info = &mlxsw_sp2_kvdl_parts_info[i];
230 kvdl->parts[i] = mlxsw_sp2_kvdl_part_init(mlxsw_sp, info);
231 if (IS_ERR(kvdl->parts[i])) {
232 err = PTR_ERR(kvdl->parts[i]);
233 goto err_kvdl_part_init;
239 for (i--; i >= 0; i--)
240 mlxsw_sp2_kvdl_part_fini(kvdl->parts[i]);
244 static void mlxsw_sp2_kvdl_parts_fini(struct mlxsw_sp2_kvdl *kvdl)
248 for (i = 0; i < MLXSW_SP2_KVDL_PARTS_INFO_LEN; i++)
249 mlxsw_sp2_kvdl_part_fini(kvdl->parts[i]);
252 static int mlxsw_sp2_kvdl_init(struct mlxsw_sp *mlxsw_sp, void *priv)
254 struct mlxsw_sp2_kvdl *kvdl = priv;
256 return mlxsw_sp2_kvdl_parts_init(mlxsw_sp, kvdl);
259 static void mlxsw_sp2_kvdl_fini(struct mlxsw_sp *mlxsw_sp, void *priv)
261 struct mlxsw_sp2_kvdl *kvdl = priv;
263 mlxsw_sp2_kvdl_parts_fini(kvdl);
266 const struct mlxsw_sp_kvdl_ops mlxsw_sp2_kvdl_ops = {
267 .priv_size = sizeof(struct mlxsw_sp2_kvdl),
268 .init = mlxsw_sp2_kvdl_init,
269 .fini = mlxsw_sp2_kvdl_fini,
270 .alloc = mlxsw_sp2_kvdl_alloc,
271 .free = mlxsw_sp2_kvdl_free,
272 .alloc_size_query = mlxsw_sp2_kvdl_alloc_size_query,