drivers/event/octeontx/timvf_evdev.c

   1 /*
   2  * SPDX-License-Identifier: BSD-3-Clause
   3  * Copyright(c) 2017 Cavium, Inc
   4  */
   5
   6 #include "timvf_evdev.h"
   7
   8 int otx_logtype_timvf;
   9
  10 RTE_INIT(otx_timvf_init_log);
  11 static void
  12 otx_timvf_init_log(void)
  13 {
  14         otx_logtype_timvf = rte_log_register("pmd.event.octeontx.timer");
  15         if (otx_logtype_timvf >= 0)
  16                 rte_log_set_level(otx_logtype_timvf, RTE_LOG_NOTICE);
  17 }
  18
  19 struct __rte_packed timvf_mbox_dev_info {
  20         uint64_t ring_active[4];
  21         uint64_t clk_freq;
  22 };
  23
  24 /* Response messages */
  25 enum {
  26         MBOX_RET_SUCCESS,
  27         MBOX_RET_INVALID,
  28         MBOX_RET_INTERNAL_ERR,
  29 };
  30
  31 static int
  32 timvf_mbox_dev_info_get(struct timvf_mbox_dev_info *info)
  33 {
  34         struct octeontx_mbox_hdr hdr = {0};
  35         uint16_t len = sizeof(struct timvf_mbox_dev_info);
  36
  37         hdr.coproc = TIM_COPROC;
  38         hdr.msg = TIM_GET_DEV_INFO;
  39         hdr.vfid = 0; /* TIM DEV is always 0. TIM RING ID changes. */
  40
  41         memset(info, 0, len);
  42         return octeontx_mbox_send(&hdr, NULL, 0, info, len);
  43 }
  44
  45 static void
  46 timvf_ring_info_get(const struct rte_event_timer_adapter *adptr,
  47                 struct rte_event_timer_adapter_info *adptr_info)
  48 {
  49         struct timvf_ring *timr = adptr->data->adapter_priv;
  50         adptr_info->max_tmo_ns = timr->max_tout;
  51         adptr_info->min_resolution_ns = timr->tck_nsec;
  52         rte_memcpy(&adptr_info->conf, &adptr->data->conf,
  53                         sizeof(struct rte_event_timer_adapter_conf));
  54 }
  55
  56 static int
  57 timvf_ring_conf_set(struct timvf_ctrl_reg *rctl, uint8_t ring_id)
  58 {
  59         struct octeontx_mbox_hdr hdr = {0};
  60         uint16_t len = sizeof(struct timvf_ctrl_reg);
  61         int ret;
  62
  63         hdr.coproc = TIM_COPROC;
  64         hdr.msg = TIM_SET_RING_INFO;
  65         hdr.vfid = ring_id;
  66
  67         ret = octeontx_mbox_send(&hdr, rctl, len, NULL, 0);
  68         if (ret < 0 || hdr.res_code != MBOX_RET_SUCCESS)
  69                 return -EACCES;
  70         return 0;
  71 }
  72
  73 static int
  74 timvf_get_start_cyc(uint64_t *now, uint8_t ring_id)
  75 {
  76         struct octeontx_mbox_hdr hdr = {0};
  77
  78         hdr.coproc = TIM_COPROC;
  79         hdr.msg = TIM_RING_START_CYC_GET;
  80         hdr.vfid = ring_id;
  81         *now = 0;
  82         return octeontx_mbox_send(&hdr, NULL, 0, now, sizeof(uint64_t));
  83 }
  84
  85 static int
  86 timvf_ring_start(const struct rte_event_timer_adapter *adptr)
  87 {
  88         int ret;
  89         uint64_t interval;
  90         struct timvf_ctrl_reg rctrl;
  91         struct timvf_mbox_dev_info dinfo;
  92         struct timvf_ring *timr = adptr->data->adapter_priv;
  93
  94         ret = timvf_mbox_dev_info_get(&dinfo);
  95         if (ret < 0 || ret != sizeof(struct timvf_mbox_dev_info))
  96                 return -EINVAL;
  97
  98         /* Calculate the interval cycles according to clock source. */
  99         switch (timr->clk_src) {
 100         case TIM_CLK_SRC_SCLK:
 101                 interval = NSEC2CLK(timr->tck_nsec, dinfo.clk_freq);
 102                 break;
 103         case TIM_CLK_SRC_GPIO:
 104                 /* GPIO doesn't work on tck_nsec. */
 105                 interval = 0;
 106                 break;
 107         case TIM_CLK_SRC_GTI:
 108                 interval = NSEC2CLK(timr->tck_nsec, dinfo.clk_freq);
 109                 break;
 110         case TIM_CLK_SRC_PTP:
 111                 interval = NSEC2CLK(timr->tck_nsec, dinfo.clk_freq);
 112                 break;
 113         default:
 114                 timvf_log_err("Unsupported clock source configured %d",
 115                                 timr->clk_src);
 116                 return -EINVAL;
 117         }
 118
 119         /*CTRL0 register.*/
 120         rctrl.rctrl0 = interval;
 121
 122         /*CTRL1 register.*/
 123         rctrl.rctrl1 =  (uint64_t)(timr->clk_src) << 51 |
 124                 1ull << 48 /* LOCK_EN (Enable hw bucket lock mechanism) */ |
 125                 1ull << 47 /* ENA */ |
 126                 1ull << 44 /* ENA_LDWB */ |
 127                 (timr->nb_bkts - 1);
 128
 129         rctrl.rctrl2 = (uint64_t)(TIM_CHUNK_SIZE / 16) << 40;
 130
 131         timvf_write64((uintptr_t)timr->bkt,
 132                         (uint8_t *)timr->vbar0 + TIM_VRING_BASE);
 133         if (timvf_ring_conf_set(&rctrl, timr->tim_ring_id)) {
 134                 ret = -EACCES;
 135                 goto error;
 136         }
 137
 138         if (timvf_get_start_cyc(&timr->ring_start_cyc,
 139                                 timr->tim_ring_id) < 0) {
 140                 ret = -EACCES;
 141                 goto error;
 142         }
 143         timr->tck_int = NSEC2CLK(timr->tck_nsec, rte_get_timer_hz());
 144         timr->fast_div = rte_reciprocal_value_u64(timr->tck_int);
 145         timvf_log_info("nb_bkts %d min_ns %"PRIu64" min_cyc %"PRIu64""
 146                         " maxtmo %"PRIu64"\n",
 147                         timr->nb_bkts, timr->tck_nsec, interval,
 148                         timr->max_tout);
 149
 150         return 0;
 151 error:
 152         rte_free(timr->bkt);
 153         rte_mempool_free(timr->chunk_pool);
 154         return ret;
 155 }
 156
 157 static int
 158 timvf_ring_stop(const struct rte_event_timer_adapter *adptr)
 159 {
 160         struct timvf_ring *timr = adptr->data->adapter_priv;
 161         struct timvf_ctrl_reg rctrl = {0};
 162         rctrl.rctrl0 = timvf_read64((uint8_t *)timr->vbar0 + TIM_VRING_CTL0);
 163         rctrl.rctrl1 = timvf_read64((uint8_t *)timr->vbar0 + TIM_VRING_CTL1);
 164         rctrl.rctrl1 &= ~(1ull << 47); /* Disable */
 165         rctrl.rctrl2 = timvf_read64((uint8_t *)timr->vbar0 + TIM_VRING_CTL2);
 166
 167         if (timvf_ring_conf_set(&rctrl, timr->tim_ring_id))
 168                 return -EACCES;
 169         return 0;
 170 }
 171
 172 static int
 173 timvf_ring_create(struct rte_event_timer_adapter *adptr)
 174 {
 175         char pool_name[25];
 176         int ret;
 177         uint64_t nb_timers;
 178         struct rte_event_timer_adapter_conf *rcfg = &adptr->data->conf;
 179         struct timvf_ring *timr;
 180         struct timvf_info tinfo;
 181         const char *mempool_ops;
 182
 183         if (timvf_info(&tinfo) < 0)
 184                 return -ENODEV;
 185
 186         if (adptr->data->id >= tinfo.total_timvfs)
 187                 return -ENODEV;
 188
 189         timr = rte_zmalloc("octeontx_timvf_priv",
 190                         sizeof(struct timvf_ring), 0);
 191         if (timr == NULL)
 192                 return -ENOMEM;
 193
 194         adptr->data->adapter_priv = timr;
 195         /* Check config parameters. */
 196         if ((rcfg->clk_src != RTE_EVENT_TIMER_ADAPTER_CPU_CLK) &&
 197                         (!rcfg->timer_tick_ns ||
 198                          rcfg->timer_tick_ns < TIM_MIN_INTERVAL)) {
 199                 timvf_log_err("Too low timer ticks");
 200                 goto cfg_err;
 201         }
 202
 203         timr->clk_src = (int) rcfg->clk_src;
 204         timr->tim_ring_id = adptr->data->id;
 205         timr->tck_nsec = rcfg->timer_tick_ns;
 206         timr->max_tout = rcfg->max_tmo_ns;
 207         timr->nb_bkts = (timr->max_tout / timr->tck_nsec);
 208         timr->vbar0 = timvf_bar(timr->tim_ring_id, 0);
 209         timr->bkt_pos = (uint8_t *)timr->vbar0 + TIM_VRING_REL;
 210         nb_timers = rcfg->nb_timers;
 211         timr->get_target_bkt = bkt_mod;
 212
 213         timr->nb_chunks = nb_timers / nb_chunk_slots;
 214
 215         timr->bkt = rte_zmalloc("octeontx_timvf_bucket",
 216                         (timr->nb_bkts) * sizeof(struct tim_mem_bucket),
 217                         0);
 218         if (timr->bkt == NULL)
 219                 goto mem_err;
 220
 221         snprintf(pool_name, 30, "timvf_chunk_pool%d", timr->tim_ring_id);
 222         timr->chunk_pool = (void *)rte_mempool_create_empty(pool_name,
 223                         timr->nb_chunks, TIM_CHUNK_SIZE, 0, 0, rte_socket_id(),
 224                         0);
 225
 226         if (!timr->chunk_pool) {
 227                 rte_free(timr->bkt);
 228                 timvf_log_err("Unable to create chunkpool.");
 229                 return -ENOMEM;
 230         }
 231
 232         mempool_ops = rte_mbuf_best_mempool_ops();
 233         ret = rte_mempool_set_ops_byname(timr->chunk_pool,
 234                         mempool_ops, NULL);
 235
 236         if (ret != 0) {
 237                 timvf_log_err("Unable to set chunkpool ops.");
 238                 goto mem_err;
 239         }
 240
 241         ret = rte_mempool_populate_default(timr->chunk_pool);
 242         if (ret < 0) {
 243                 timvf_log_err("Unable to set populate chunkpool.");
 244                 goto mem_err;
 245         }
 246         timvf_write64(0, (uint8_t *)timr->vbar0 + TIM_VRING_BASE);
 247         timvf_write64(0, (uint8_t *)timr->vbar0 + TIM_VF_NRSPERR_INT);
 248         timvf_write64(0, (uint8_t *)timr->vbar0 + TIM_VF_NRSPERR_INT_W1S);
 249         timvf_write64(0x7, (uint8_t *)timr->vbar0 + TIM_VF_NRSPERR_ENA_W1C);
 250         timvf_write64(0x7, (uint8_t *)timr->vbar0 + TIM_VF_NRSPERR_ENA_W1S);
 251
 252         return 0;
 253 mem_err:
 254         rte_free(timr);
 255         return -ENOMEM;
 256 cfg_err:
 257         rte_free(timr);
 258         return -EINVAL;
 259 }
 260
 261 static int
 262 timvf_ring_free(struct rte_event_timer_adapter *adptr)
 263 {
 264         struct timvf_ring *timr = adptr->data->adapter_priv;
 265         rte_mempool_free(timr->chunk_pool);
 266         rte_free(timr->bkt);
 267         rte_free(adptr->data->adapter_priv);
 268         return 0;
 269 }
 270
 271 static int
 272 timvf_stats_get(const struct rte_event_timer_adapter *adapter,
 273                 struct rte_event_timer_adapter_stats *stats)
 274 {
 275         struct timvf_ring *timr = adapter->data->adapter_priv;
 276         uint64_t bkt_cyc = rte_rdtsc() - timr->ring_start_cyc;
 277
 278         stats->evtim_exp_count = timr->tim_arm_cnt;
 279         stats->ev_enq_count = timr->tim_arm_cnt;
 280         stats->adapter_tick_count = rte_reciprocal_divide_u64(bkt_cyc,
 281                                 &timr->fast_div);
 282         return 0;
 283 }
 284
 285 static int
 286 timvf_stats_reset(const struct rte_event_timer_adapter *adapter)
 287 {
 288         struct timvf_ring *timr = adapter->data->adapter_priv;
 289
 290         timr->tim_arm_cnt = 0;
 291         return 0;
 292 }
 293
 294 static struct rte_event_timer_adapter_ops timvf_ops = {
 295         .init           = timvf_ring_create,
 296         .uninit         = timvf_ring_free,
 297         .start          = timvf_ring_start,
 298         .stop           = timvf_ring_stop,
 299         .get_info       = timvf_ring_info_get,
 300 };
 301
 302 int
 303 timvf_timer_adapter_caps_get(const struct rte_eventdev *dev, uint64_t flags,
 304                 uint32_t *caps, const struct rte_event_timer_adapter_ops **ops,
 305                 uint8_t enable_stats)
 306 {
 307         RTE_SET_USED(dev);
 308         RTE_SET_USED(flags);
 309
 310         if (enable_stats) {
 311                 timvf_ops.stats_get   = timvf_stats_get;
 312                 timvf_ops.stats_reset = timvf_stats_reset;
 313         }
 314
 315         *caps = RTE_EVENT_TIMER_ADAPTER_CAP_INTERNAL_PORT;
 316         *ops = &timvf_ops;
 317         return -EINVAL;
 318 }