/* Copyright (c) 2011-2016, The Linux Foundation. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 and * only version 2 as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #include #include #include #include #include #include #include #include "slim-msm.h" int msm_slim_rx_enqueue(struct msm_slim_ctrl *dev, u32 *buf, u8 len) { spin_lock(&dev->rx_lock); if ((dev->tail + 1) % MSM_CONCUR_MSG == dev->head) { spin_unlock(&dev->rx_lock); dev_err(dev->dev, "RX QUEUE full!"); return -EXFULL; } memcpy((u8 *)dev->rx_msgs[dev->tail], (u8 *)buf, len); dev->tail = (dev->tail + 1) % MSM_CONCUR_MSG; spin_unlock(&dev->rx_lock); return 0; } int msm_slim_rx_dequeue(struct msm_slim_ctrl *dev, u8 *buf) { unsigned long flags; spin_lock_irqsave(&dev->rx_lock, flags); if (dev->tail == dev->head) { spin_unlock_irqrestore(&dev->rx_lock, flags); return -ENODATA; } memcpy(buf, (u8 *)dev->rx_msgs[dev->head], 40); dev->head = (dev->head + 1) % MSM_CONCUR_MSG; spin_unlock_irqrestore(&dev->rx_lock, flags); return 0; } int msm_slim_get_ctrl(struct msm_slim_ctrl *dev) { #ifdef CONFIG_PM int ref = 0; int ret = pm_runtime_get_sync(dev->dev); if (ret >= 0) { ref = atomic_read(&dev->dev->power.usage_count); if (ref <= 0) { SLIM_WARN(dev, "reference count -ve:%d", ref); ret = -ENODEV; } } return ret; #else return -ENODEV; #endif } void msm_slim_put_ctrl(struct msm_slim_ctrl *dev) { #ifdef CONFIG_PM int ref; pm_runtime_mark_last_busy(dev->dev); ref = atomic_read(&dev->dev->power.usage_count); if (ref <= 0) SLIM_WARN(dev, "reference count mismatch:%d", ref); else pm_runtime_put_sync(dev->dev); #endif } irqreturn_t msm_slim_port_irq_handler(struct msm_slim_ctrl *dev, u32 pstat) { int i; u32 int_en = readl_relaxed(PGD_THIS_EE(PGD_PORT_INT_EN_EEn, dev->ver)); /* * different port-interrupt than what we enabled, ignore. * This may happen if overflow/underflow is reported, but * was disabled due to unavailability of buffers provided by * client. */ if ((pstat & int_en) == 0) return IRQ_HANDLED; for (i = 0; i < dev->port_nums; i++) { struct msm_slim_endp *endpoint = &dev->pipes[i]; if (pstat & (1 << endpoint->port_b)) { u32 val = readl_relaxed(PGD_PORT(PGD_PORT_STATn, endpoint->port_b, dev->ver)); if (val & MSM_PORT_OVERFLOW) { dev->ctrl.ports[i].err = SLIM_P_OVERFLOW; } else if (val & MSM_PORT_UNDERFLOW) { dev->ctrl.ports[i].err = SLIM_P_UNDERFLOW; } } } /* * Disable port interrupt here. Re-enable when more * buffers are provided for this port. */ writel_relaxed((int_en & (~pstat)), PGD_THIS_EE(PGD_PORT_INT_EN_EEn, dev->ver)); /* clear port interrupts */ writel_relaxed(pstat, PGD_THIS_EE(PGD_PORT_INT_CL_EEn, dev->ver)); SLIM_INFO(dev, "disabled overflow/underflow for port 0x%x", pstat); /* * Guarantee that port interrupt bit(s) clearing writes go * through before exiting ISR */ mb(); return IRQ_HANDLED; } int msm_slim_init_endpoint(struct msm_slim_ctrl *dev, struct msm_slim_endp *ep) { int ret; struct sps_pipe *endpoint; struct sps_connect *config = &ep->config; /* Allocate the endpoint */ endpoint = sps_alloc_endpoint(); if (!endpoint) { dev_err(dev->dev, "sps_alloc_endpoint failed\n"); return -ENOMEM; } /* Get default connection configuration for an endpoint */ ret = sps_get_config(endpoint, config); if (ret) { dev_err(dev->dev, "sps_get_config failed 0x%x\n", ret); goto sps_config_failed; } ep->sps = endpoint; return 0; sps_config_failed: sps_free_endpoint(endpoint); return ret; } void msm_slim_free_endpoint(struct msm_slim_endp *ep) { sps_free_endpoint(ep->sps); ep->sps = NULL; } int msm_slim_sps_mem_alloc( struct msm_slim_ctrl *dev, struct sps_mem_buffer *mem, u32 len) { dma_addr_t phys; mem->size = len; mem->min_size = 0; mem->base = dma_alloc_coherent(dev->dev, mem->size, &phys, GFP_KERNEL); if (!mem->base) { dev_err(dev->dev, "dma_alloc_coherent(%d) failed\n", len); return -ENOMEM; } mem->phys_base = phys; memset(mem->base, 0x00, mem->size); return 0; } void msm_slim_sps_mem_free(struct msm_slim_ctrl *dev, struct sps_mem_buffer *mem) { if (mem->base && mem->phys_base) dma_free_coherent(dev->dev, mem->size, mem->base, mem->phys_base); else dev_err(dev->dev, "cant dma free. they are NULL\n"); mem->size = 0; mem->base = NULL; mem->phys_base = 0; } void msm_hw_set_port(struct msm_slim_ctrl *dev, u8 pipenum, u8 portnum) { struct slim_controller *ctrl; struct slim_ch *chan; struct msm_slim_pshpull_parm *parm; u32 set_cfg = 0; struct slim_port_cfg cfg = dev->ctrl.ports[portnum].cfg; if (!dev) { pr_err("%s:Dev node is null\n", __func__); return; } if (portnum >= dev->port_nums) { pr_err("%s:Invalid port\n", __func__); return; } ctrl = &dev->ctrl; chan = ctrl->ports[portnum].ch; parm = &dev->pipes[portnum].psh_pull; if (cfg.watermark) set_cfg = (cfg.watermark << 1); else set_cfg = DEF_WATERMARK; if (cfg.port_opts & SLIM_OPT_NO_PACK) set_cfg |= DEF_NO_PACK; else set_cfg |= DEF_PACK; if (cfg.port_opts & SLIM_OPT_ALIGN_MSB) set_cfg |= DEF_ALIGN_MSB; else set_cfg |= DEF_ALIGN_LSB; set_cfg |= ENABLE_PORT; writel_relaxed(set_cfg, PGD_PORT(PGD_PORT_CFGn, pipenum, dev->ver)); writel_relaxed(DEF_BLKSZ, PGD_PORT(PGD_PORT_BLKn, pipenum, dev->ver)); writel_relaxed(DEF_TRANSZ, PGD_PORT(PGD_PORT_TRANn, pipenum, dev->ver)); if (chan->prot == SLIM_PUSH || chan->prot == SLIM_PULL) { set_cfg = 0; set_cfg |= ((0xFFFF & parm->num_samples)<<16); set_cfg |= (0xFFFF & parm->rpt_period); writel_relaxed(set_cfg, PGD_PORT(PGD_PORT_PSHPLLn, pipenum, dev->ver)); } /* Make sure that port registers are updated before returning */ mb(); } static void msm_slim_disconn_pipe_port(struct msm_slim_ctrl *dev, u8 pn) { struct msm_slim_endp *endpoint = &dev->pipes[pn]; struct sps_register_event sps_event; u32 int_port = readl_relaxed(PGD_THIS_EE(PGD_PORT_INT_EN_EEn, dev->ver)); writel_relaxed(0, PGD_PORT(PGD_PORT_CFGn, (endpoint->port_b), dev->ver)); writel_relaxed((int_port & ~(1 << endpoint->port_b)), PGD_THIS_EE(PGD_PORT_INT_EN_EEn, dev->ver)); /* Make sure port register is updated */ mb(); memset(&sps_event, 0, sizeof(sps_event)); sps_register_event(endpoint->sps, &sps_event); sps_disconnect(endpoint->sps); dev->pipes[pn].connected = false; } static void msm_slim_calc_pshpull_parm(struct msm_slim_ctrl *dev, u8 pn, struct slim_ch *prop) { struct msm_slim_endp *endpoint = &dev->pipes[pn]; struct msm_slim_pshpull_parm *parm = &endpoint->psh_pull; int chan_freq, round_off, divisor, super_freq; super_freq = dev->ctrl.a_framer->superfreq; if (prop->baser == SLIM_RATE_4000HZ) chan_freq = 4000 * prop->ratem; else if (prop->baser == SLIM_RATE_11025HZ) chan_freq = 11025 * prop->ratem; else chan_freq = prop->baser * prop->ratem; /* * If channel frequency is multiple of super frame frequency * ISO protocol is suggested */ if (!(chan_freq % super_freq)) { prop->prot = SLIM_HARD_ISO; return; } round_off = DIV_ROUND_UP(chan_freq, super_freq); divisor = gcd(round_off * super_freq, chan_freq); parm->num_samples = chan_freq/divisor; parm->rpt_period = (round_off * super_freq)/divisor; } int msm_slim_connect_pipe_port(struct msm_slim_ctrl *dev, u8 pn) { struct msm_slim_endp *endpoint; struct sps_connect *cfg; struct slim_ch *prop; u32 stat; int ret; if (!dev || pn >= dev->port_nums) return -ENODEV; endpoint = &dev->pipes[pn]; cfg = &endpoint->config; prop = dev->ctrl.ports[pn].ch; endpoint = &dev->pipes[pn]; ret = sps_get_config(dev->pipes[pn].sps, cfg); if (ret) { dev_err(dev->dev, "sps pipe-port get config error%x\n", ret); return ret; } cfg->options = SPS_O_DESC_DONE | SPS_O_ERROR | SPS_O_ACK_TRANSFERS | SPS_O_AUTO_ENABLE; if (prop->prot == SLIM_PUSH || prop->prot == SLIM_PULL) msm_slim_calc_pshpull_parm(dev, pn, prop); if (dev->pipes[pn].connected && dev->ctrl.ports[pn].state == SLIM_P_CFG) { return -EISCONN; } else if (dev->pipes[pn].connected) { writel_relaxed(0, PGD_PORT(PGD_PORT_CFGn, (endpoint->port_b), dev->ver)); /* Make sure port disabling goes through */ mb(); /* Is pipe already connected in desired direction */ if ((dev->ctrl.ports[pn].flow == SLIM_SRC && cfg->mode == SPS_MODE_DEST) || (dev->ctrl.ports[pn].flow == SLIM_SINK && cfg->mode == SPS_MODE_SRC)) { msm_hw_set_port(dev, endpoint->port_b, pn); return 0; } msm_slim_disconn_pipe_port(dev, pn); } stat = readl_relaxed(PGD_PORT(PGD_PORT_STATn, endpoint->port_b, dev->ver)); if (dev->ctrl.ports[pn].flow == SLIM_SRC) { cfg->destination = dev->bam.hdl; cfg->source = SPS_DEV_HANDLE_MEM; cfg->dest_pipe_index = ((stat & (0xFF << 4)) >> 4); cfg->src_pipe_index = 0; dev_dbg(dev->dev, "flow src:pipe num:%d", cfg->dest_pipe_index); cfg->mode = SPS_MODE_DEST; } else { cfg->source = dev->bam.hdl; cfg->destination = SPS_DEV_HANDLE_MEM; cfg->src_pipe_index = ((stat & (0xFF << 4)) >> 4); cfg->dest_pipe_index = 0; dev_dbg(dev->dev, "flow dest:pipe num:%d", cfg->src_pipe_index); cfg->mode = SPS_MODE_SRC; } /* Space for desciptor FIFOs */ ret = msm_slim_sps_mem_alloc(dev, &cfg->desc, MSM_SLIM_DESC_NUM * sizeof(struct sps_iovec)); if (ret) pr_err("mem alloc for descr failed:%d", ret); else ret = sps_connect(dev->pipes[pn].sps, cfg); if (!ret) { dev->pipes[pn].connected = true; msm_hw_set_port(dev, endpoint->port_b, pn); } return ret; } int msm_alloc_port(struct slim_controller *ctrl, u8 pn) { struct msm_slim_ctrl *dev = slim_get_ctrldata(ctrl); struct msm_slim_endp *endpoint; int ret = 0; if (ctrl->ports[pn].req == SLIM_REQ_HALF_DUP || ctrl->ports[pn].req == SLIM_REQ_MULTI_CH) return -EPROTONOSUPPORT; if (pn >= dev->port_nums) return -ENODEV; endpoint = &dev->pipes[pn]; ret = msm_slim_init_endpoint(dev, endpoint); dev_dbg(dev->dev, "sps register bam error code:%x\n", ret); return ret; } void msm_dealloc_port(struct slim_controller *ctrl, u8 pn) { struct msm_slim_ctrl *dev = slim_get_ctrldata(ctrl); struct msm_slim_endp *endpoint; if (pn >= dev->port_nums) return; endpoint = &dev->pipes[pn]; if (dev->pipes[pn].connected) { struct sps_connect *config = &endpoint->config; msm_slim_disconn_pipe_port(dev, pn); msm_slim_sps_mem_free(dev, &config->desc); } if (endpoint->sps) msm_slim_free_endpoint(endpoint); } enum slim_port_err msm_slim_port_xfer_status(struct slim_controller *ctr, u8 pn, phys_addr_t *done_buf, u32 *done_len) { struct msm_slim_ctrl *dev = slim_get_ctrldata(ctr); struct sps_iovec sio; int ret; if (done_len) *done_len = 0; if (done_buf) *done_buf = 0; if (!dev->pipes[pn].connected) return SLIM_P_DISCONNECT; ret = sps_get_iovec(dev->pipes[pn].sps, &sio); if (!ret) { if (done_len) *done_len = sio.size; if (done_buf) *done_buf = (phys_addr_t)sio.addr; } dev_dbg(dev->dev, "get iovec returned %d\n", ret); return SLIM_P_INPROGRESS; } static void msm_slim_port_cb(struct sps_event_notify *ev) { struct completion *comp = ev->data.transfer.user; struct sps_iovec *iovec = &ev->data.transfer.iovec; if (ev->event_id == SPS_EVENT_DESC_DONE) { pr_debug("desc done iovec = (0x%x 0x%x 0x%x)\n", iovec->addr, iovec->size, iovec->flags); } else { pr_err("%s: ERR event %d\n", __func__, ev->event_id); } if (comp) complete(comp); } int msm_slim_port_xfer(struct slim_controller *ctrl, u8 pn, phys_addr_t iobuf, u32 len, struct completion *comp) { struct sps_register_event sreg; int ret; struct msm_slim_ctrl *dev = slim_get_ctrldata(ctrl); if (pn >= dev->port_nums) return -ENODEV; if (!dev->pipes[pn].connected) return -ENOTCONN; sreg.options = (SPS_EVENT_DESC_DONE|SPS_EVENT_ERROR); sreg.mode = SPS_TRIGGER_WAIT; sreg.xfer_done = NULL; sreg.callback = msm_slim_port_cb; sreg.user = NULL; ret = sps_register_event(dev->pipes[pn].sps, &sreg); if (ret) { dev_dbg(dev->dev, "sps register event error:%x\n", ret); return ret; } ret = sps_transfer_one(dev->pipes[pn].sps, iobuf, len, comp, SPS_IOVEC_FLAG_INT); dev_dbg(dev->dev, "sps submit xfer error code:%x\n", ret); if (!ret) { /* Enable port interrupts */ u32 int_port = readl_relaxed(PGD_THIS_EE(PGD_PORT_INT_EN_EEn, dev->ver)); if (!(int_port & (1 << (dev->pipes[pn].port_b)))) writel_relaxed((int_port | (1 << dev->pipes[pn].port_b)), PGD_THIS_EE(PGD_PORT_INT_EN_EEn, dev->ver)); /* Make sure that port registers are updated before returning */ mb(); } return ret; } /* Queue up Tx message buffer */ static int msm_slim_post_tx_msgq(struct msm_slim_ctrl *dev, u8 *buf, int len) { int ret; struct msm_slim_endp *endpoint = &dev->tx_msgq; struct sps_mem_buffer *mem = &endpoint->buf; struct sps_pipe *pipe = endpoint->sps; int ix = (buf - (u8 *)mem->base); phys_addr_t phys_addr = mem->phys_base + ix; for (ret = 0; ret < ((len + 3) >> 2); ret++) pr_debug("BAM TX buf[%d]:0x%x", ret, ((u32 *)buf)[ret]); ret = sps_transfer_one(pipe, phys_addr, ((len + 3) & 0xFC), NULL, SPS_IOVEC_FLAG_EOT); if (ret) dev_err(dev->dev, "transfer_one() failed 0x%x, %d\n", ret, ix); return ret; } void msm_slim_tx_msg_return(struct msm_slim_ctrl *dev, int err) { struct msm_slim_endp *endpoint = &dev->tx_msgq; struct sps_mem_buffer *mem = &endpoint->buf; struct sps_pipe *pipe = endpoint->sps; struct sps_iovec iovec; int idx, ret = 0; phys_addr_t addr; if (dev->use_tx_msgqs != MSM_MSGQ_ENABLED) { /* use 1 buffer, non-blocking writes are not possible */ if (dev->wr_comp[0]) { struct completion *comp = dev->wr_comp[0]; dev->wr_comp[0] = NULL; complete(comp); } return; } while (!ret) { ret = sps_get_iovec(pipe, &iovec); addr = DESC_FULL_ADDR(iovec.flags, iovec.addr); if (ret || addr == 0) { if (ret) pr_err("SLIM TX get IOVEC failed:%d", ret); return; } if (addr == dev->bulk.wr_dma) { dma_unmap_single(dev->dev, dev->bulk.wr_dma, dev->bulk.size, DMA_TO_DEVICE); if (!dev->bulk.cb) SLIM_WARN(dev, "no callback for bulk WR?"); else dev->bulk.cb(dev->bulk.ctx, err); dev->bulk.in_progress = false; pm_runtime_mark_last_busy(dev->dev); return; } else if (addr < mem->phys_base || (addr > (mem->phys_base + (MSM_TX_BUFS * SLIM_MSGQ_BUF_LEN)))) { SLIM_WARN(dev, "BUF out of bounds:base:0x%pa, io:0x%pa", &mem->phys_base, &addr); continue; } idx = (int) ((addr - mem->phys_base) / SLIM_MSGQ_BUF_LEN); if (dev->wr_comp[idx]) { struct completion *comp = dev->wr_comp[idx]; dev->wr_comp[idx] = NULL; complete(comp); } if (err) { int i; u32 *addr = (u32 *)mem->base + (idx * (SLIM_MSGQ_BUF_LEN >> 2)); /* print the descriptor that resulted in error */ for (i = 0; i < (SLIM_MSGQ_BUF_LEN >> 2); i++) SLIM_WARN(dev, "err desc[%d]:0x%x", i, addr[i]); } /* reclaim all packets that were delivered out of order */ if (idx != dev->tx_head) SLIM_WARN(dev, "SLIM OUT OF ORDER TX:idx:%d, head:%d", idx, dev->tx_head); dev->tx_head = (dev->tx_head + 1) % MSM_TX_BUFS; } } static u32 *msm_slim_modify_tx_buf(struct msm_slim_ctrl *dev, struct completion *comp) { struct msm_slim_endp *endpoint = &dev->tx_msgq; struct sps_mem_buffer *mem = &endpoint->buf; u32 *retbuf = NULL; if ((dev->tx_tail + 1) % MSM_TX_BUFS == dev->tx_head) return NULL; retbuf = (u32 *)((u8 *)mem->base + (dev->tx_tail * SLIM_MSGQ_BUF_LEN)); dev->wr_comp[dev->tx_tail] = comp; dev->tx_tail = (dev->tx_tail + 1) % MSM_TX_BUFS; return retbuf; } u32 *msm_slim_manage_tx_msgq(struct msm_slim_ctrl *dev, bool getbuf, struct completion *comp, int err) { int ret = 0; int retries = 0; u32 *retbuf = NULL; unsigned long flags; spin_lock_irqsave(&dev->tx_buf_lock, flags); if (!getbuf) { msm_slim_tx_msg_return(dev, err); spin_unlock_irqrestore(&dev->tx_buf_lock, flags); return NULL; } retbuf = msm_slim_modify_tx_buf(dev, comp); if (retbuf) { spin_unlock_irqrestore(&dev->tx_buf_lock, flags); return retbuf; } do { msm_slim_tx_msg_return(dev, err); retbuf = msm_slim_modify_tx_buf(dev, comp); if (!retbuf) ret = -EAGAIN; else { if (retries > 0) SLIM_INFO(dev, "SLIM TX retrieved:%d retries", retries); spin_unlock_irqrestore(&dev->tx_buf_lock, flags); return retbuf; } /* * superframe size will vary based on clock gear * 1 superframe will consume at least 1 message * if HW is in good condition. With MX_RETRIES, * make sure we wait for ~2 superframes * before deciding HW couldn't process descriptors */ udelay(50); retries++; } while (ret && (retries < INIT_MX_RETRIES)); spin_unlock_irqrestore(&dev->tx_buf_lock, flags); return NULL; } int msm_send_msg_buf(struct msm_slim_ctrl *dev, u32 *buf, u8 len, u32 tx_reg) { if (dev->use_tx_msgqs != MSM_MSGQ_ENABLED) { int i; for (i = 0; i < (len + 3) >> 2; i++) { dev_dbg(dev->dev, "AHB TX data:0x%x\n", buf[i]); writel_relaxed(buf[i], dev->base + tx_reg + (i * 4)); } /* Guarantee that message is sent before returning */ mb(); return 0; } return msm_slim_post_tx_msgq(dev, (u8 *)buf, len); } u32 *msm_get_msg_buf(struct msm_slim_ctrl *dev, int len, struct completion *comp) { /* * Currently we block a transaction until the current one completes. * In case we need multiple transactions, use message Q */ if (dev->use_tx_msgqs != MSM_MSGQ_ENABLED) { dev->wr_comp[0] = comp; return dev->tx_buf; } return msm_slim_manage_tx_msgq(dev, true, comp, 0); } static void msm_slim_rx_msgq_event(struct msm_slim_ctrl *dev, struct sps_event_notify *ev) { if (ev->event_id == SPS_EVENT_DESC_DONE) complete(&dev->rx_msgq_notify); else dev_err(dev->dev, "%s: unknown event %d\n", __func__, ev->event_id); } static void msm_slim_handle_rx(struct msm_slim_ctrl *dev, struct sps_event_notify *ev) { int ret = 0; u32 mc = 0; u32 mt = 0; u8 msg_len = 0; if (ev->event_id != SPS_EVENT_EOT) { dev_err(dev->dev, "%s: unknown event %d\n", __func__, ev->event_id); return; } do { ret = msm_slim_rx_msgq_get(dev, dev->current_rx_buf, dev->current_count); if (ret == -ENODATA) { return; } else if (ret) { SLIM_ERR(dev, "rx_msgq_get() failed 0x%x\n", ret); return; } /* Traverse first byte of message for message length */ if (dev->current_count++ == 0) { msg_len = *(dev->current_rx_buf) & 0x1F; mt = (*(dev->current_rx_buf) >> 5) & 0x7; mc = (*(dev->current_rx_buf) >> 8) & 0xff; dev_dbg(dev->dev, "MC: %x, MT: %x\n", mc, mt); } msg_len = (msg_len < 4) ? 0 : (msg_len - 4); if (!msg_len) { dev->rx_slim(dev, (u8 *)dev->current_rx_buf); dev->current_count = 0; } } while (1); } static void msm_slim_rx_msgq_cb(struct sps_event_notify *notify) { struct msm_slim_ctrl *dev = (struct msm_slim_ctrl *)notify->user; /* is this manager controller or NGD controller? */ if (dev->ctrl.wakeup) msm_slim_rx_msgq_event(dev, notify); else msm_slim_handle_rx(dev, notify); } /* Queue up Rx message buffer */ static int msm_slim_post_rx_msgq(struct msm_slim_ctrl *dev, int ix) { int ret; struct msm_slim_endp *endpoint = &dev->rx_msgq; struct sps_mem_buffer *mem = &endpoint->buf; struct sps_pipe *pipe = endpoint->sps; /* Rx message queue buffers are 4 bytes in length */ u8 *virt_addr = mem->base + (4 * ix); phys_addr_t phys_addr = mem->phys_base + (4 * ix); ret = sps_transfer_one(pipe, phys_addr, 4, virt_addr, 0); if (ret) dev_err(dev->dev, "transfer_one() failed 0x%x, %d\n", ret, ix); return ret; } int msm_slim_rx_msgq_get(struct msm_slim_ctrl *dev, u32 *data, int offset) { struct msm_slim_endp *endpoint = &dev->rx_msgq; struct sps_mem_buffer *mem = &endpoint->buf; struct sps_pipe *pipe = endpoint->sps; struct sps_iovec iovec; phys_addr_t addr; int index; int ret; ret = sps_get_iovec(pipe, &iovec); if (ret) { dev_err(dev->dev, "sps_get_iovec() failed 0x%x\n", ret); goto err_exit; } addr = DESC_FULL_ADDR(iovec.flags, iovec.addr); pr_debug("iovec = (0x%x 0x%x 0x%x)\n", iovec.addr, iovec.size, iovec.flags); /* no more descriptors */ if (!ret && (iovec.addr == 0) && (iovec.size == 0)) { ret = -ENODATA; goto err_exit; } /* Calculate buffer index */ index = (addr - mem->phys_base) / 4; *(data + offset) = *((u32 *)mem->base + index); pr_debug("buf = 0x%p, data = 0x%x\n", (u32 *)mem->base + index, *data); /* Add buffer back to the queue */ (void)msm_slim_post_rx_msgq(dev, index); err_exit: return ret; } int msm_slim_connect_endp(struct msm_slim_ctrl *dev, struct msm_slim_endp *endpoint) { int i, ret; struct sps_register_event sps_error_event; /* SPS_ERROR */ struct sps_register_event sps_descr_event; /* DESCR_DONE */ struct sps_connect *config = &endpoint->config; unsigned long flags; ret = sps_connect(endpoint->sps, config); if (ret) { dev_err(dev->dev, "sps_connect failed 0x%x\n", ret); return ret; } memset(&sps_descr_event, 0x00, sizeof(sps_descr_event)); if (endpoint == &dev->rx_msgq) { sps_descr_event.mode = SPS_TRIGGER_CALLBACK; sps_descr_event.options = SPS_O_EOT; sps_descr_event.user = (void *)dev; sps_descr_event.callback = msm_slim_rx_msgq_cb; sps_descr_event.xfer_done = NULL; ret = sps_register_event(endpoint->sps, &sps_descr_event); if (ret) { dev_err(dev->dev, "sps_connect() failed 0x%x\n", ret); goto sps_reg_event_failed; } } /* Register callback for errors */ memset(&sps_error_event, 0x00, sizeof(sps_error_event)); sps_error_event.mode = SPS_TRIGGER_CALLBACK; sps_error_event.options = SPS_O_ERROR; sps_error_event.user = (void *)dev; sps_error_event.callback = msm_slim_rx_msgq_cb; ret = sps_register_event(endpoint->sps, &sps_error_event); if (ret) { dev_err(dev->dev, "sps_connect() failed 0x%x\n", ret); goto sps_reg_event_failed; } /* * Call transfer_one for each 4-byte buffer * Use (buf->size/4) - 1 for the number of buffer to post */ if (endpoint == &dev->rx_msgq) { /* Setup the transfer */ for (i = 0; i < (MSM_SLIM_DESC_NUM - 1); i++) { ret = msm_slim_post_rx_msgq(dev, i); if (ret) { dev_err(dev->dev, "post_rx_msgq() failed 0x%x\n", ret); goto sps_transfer_failed; } } dev->use_rx_msgqs = MSM_MSGQ_ENABLED; } else { spin_lock_irqsave(&dev->tx_buf_lock, flags); dev->tx_tail = 0; dev->tx_head = 0; for (i = 0; i < MSM_TX_BUFS; i++) dev->wr_comp[i] = NULL; spin_unlock_irqrestore(&dev->tx_buf_lock, flags); dev->use_tx_msgqs = MSM_MSGQ_ENABLED; } return 0; sps_transfer_failed: memset(&sps_error_event, 0x00, sizeof(sps_error_event)); sps_register_event(endpoint->sps, &sps_error_event); sps_reg_event_failed: sps_disconnect(endpoint->sps); return ret; } static int msm_slim_init_rx_msgq(struct msm_slim_ctrl *dev, u32 pipe_reg) { int ret; u32 pipe_offset; struct msm_slim_endp *endpoint = &dev->rx_msgq; struct sps_connect *config = &endpoint->config; struct sps_mem_buffer *descr = &config->desc; struct sps_mem_buffer *mem = &endpoint->buf; if (dev->use_rx_msgqs == MSM_MSGQ_DISABLED) return 0; /* Allocate the endpoint */ ret = msm_slim_init_endpoint(dev, endpoint); if (ret) { dev_err(dev->dev, "init_endpoint failed 0x%x\n", ret); goto sps_init_endpoint_failed; } /* Get the pipe indices for the message queues */ pipe_offset = (readl_relaxed(dev->base + pipe_reg) & 0xfc) >> 2; dev_dbg(dev->dev, "Message queue pipe offset %d\n", pipe_offset); config->mode = SPS_MODE_SRC; config->source = dev->bam.hdl; config->destination = SPS_DEV_HANDLE_MEM; config->src_pipe_index = pipe_offset; config->options = SPS_O_EOT | SPS_O_ERROR | SPS_O_ACK_TRANSFERS | SPS_O_AUTO_ENABLE; /* Allocate memory for the FIFO descriptors */ ret = msm_slim_sps_mem_alloc(dev, descr, MSM_SLIM_DESC_NUM * sizeof(struct sps_iovec)); if (ret) { dev_err(dev->dev, "unable to allocate SPS descriptors\n"); goto alloc_descr_failed; } /* Allocate memory for the message buffer(s), N descrs, 4-byte mesg */ ret = msm_slim_sps_mem_alloc(dev, mem, MSM_SLIM_DESC_NUM * 4); if (ret) { dev_err(dev->dev, "dma_alloc_coherent failed\n"); goto alloc_buffer_failed; } ret = msm_slim_connect_endp(dev, endpoint); if (!ret) return 0; msm_slim_sps_mem_free(dev, mem); alloc_buffer_failed: msm_slim_sps_mem_free(dev, descr); alloc_descr_failed: msm_slim_free_endpoint(endpoint); sps_init_endpoint_failed: dev->use_rx_msgqs = MSM_MSGQ_DISABLED; return ret; } static int msm_slim_init_tx_msgq(struct msm_slim_ctrl *dev, u32 pipe_reg) { int ret; u32 pipe_offset; struct msm_slim_endp *endpoint = &dev->tx_msgq; struct sps_connect *config = &endpoint->config; struct sps_mem_buffer *descr = &config->desc; struct sps_mem_buffer *mem = &endpoint->buf; if (dev->use_tx_msgqs == MSM_MSGQ_DISABLED) return 0; /* Allocate the endpoint */ ret = msm_slim_init_endpoint(dev, endpoint); if (ret) { dev_err(dev->dev, "init_endpoint failed 0x%x\n", ret); goto sps_init_endpoint_failed; } /* Get the pipe indices for the message queues */ pipe_offset = (readl_relaxed(dev->base + pipe_reg) & 0xfc) >> 2; pipe_offset += 1; dev_dbg(dev->dev, "TX Message queue pipe offset %d\n", pipe_offset); config->mode = SPS_MODE_DEST; config->source = SPS_DEV_HANDLE_MEM; config->destination = dev->bam.hdl; config->dest_pipe_index = pipe_offset; config->src_pipe_index = 0; config->options = SPS_O_ERROR | SPS_O_NO_Q | SPS_O_ACK_TRANSFERS | SPS_O_AUTO_ENABLE; /* Desc and TX buf are circular queues */ /* Allocate memory for the FIFO descriptors */ ret = msm_slim_sps_mem_alloc(dev, descr, (MSM_TX_BUFS + 1) * sizeof(struct sps_iovec)); if (ret) { dev_err(dev->dev, "unable to allocate SPS descriptors\n"); goto alloc_descr_failed; } /* Allocate TX buffer from which descriptors are created */ ret = msm_slim_sps_mem_alloc(dev, mem, ((MSM_TX_BUFS + 1) * SLIM_MSGQ_BUF_LEN)); if (ret) { dev_err(dev->dev, "dma_alloc_coherent failed\n"); goto alloc_buffer_failed; } ret = msm_slim_connect_endp(dev, endpoint); if (!ret) return 0; msm_slim_sps_mem_free(dev, mem); alloc_buffer_failed: msm_slim_sps_mem_free(dev, descr); alloc_descr_failed: msm_slim_free_endpoint(endpoint); sps_init_endpoint_failed: dev->use_tx_msgqs = MSM_MSGQ_DISABLED; return ret; } static int msm_slim_data_port_assign(struct msm_slim_ctrl *dev) { int i, data_ports = 0; /* First 7 bits are for message Qs */ for (i = 7; i < 32; i++) { /* Check what pipes are owned by Apps. */ if ((dev->pdata.apps_pipes >> i) & 0x1) { if (dev->pipes) dev->pipes[data_ports].port_b = i - 7; data_ports++; } } return data_ports; } /* Registers BAM h/w resource with SPS driver and initializes msgq endpoints */ int msm_slim_sps_init(struct msm_slim_ctrl *dev, struct resource *bam_mem, u32 pipe_reg, bool remote) { int ret; unsigned long bam_handle; struct sps_bam_props bam_props = {0}; static struct sps_bam_sec_config_props sec_props = { .ees = { [0] = { /* LPASS */ .vmid = 0, .pipe_mask = 0xFFFF98, }, [1] = { /* Krait Apps */ .vmid = 1, .pipe_mask = 0x3F000007, }, [2] = { /* Modem */ .vmid = 2, .pipe_mask = 0x00000060, }, }, }; if (dev->bam.hdl) { bam_handle = dev->bam.hdl; goto init_pipes; } bam_props.ee = dev->ee; bam_props.virt_addr = dev->bam.base; bam_props.phys_addr = bam_mem->start; bam_props.irq = dev->bam.irq; if (!remote) { bam_props.manage = SPS_BAM_MGR_LOCAL; bam_props.sec_config = SPS_BAM_SEC_DO_CONFIG; } else { bam_props.manage = SPS_BAM_MGR_DEVICE_REMOTE | SPS_BAM_MGR_MULTI_EE; bam_props.sec_config = SPS_BAM_SEC_DO_NOT_CONFIG; } bam_props.summing_threshold = MSM_SLIM_PERF_SUMM_THRESHOLD; bam_props.p_sec_config_props = &sec_props; bam_props.options = SPS_O_DESC_DONE | SPS_O_ERROR | SPS_O_ACK_TRANSFERS | SPS_O_AUTO_ENABLE; /* override apps channel pipes if specified in platform-data or DT */ if (dev->pdata.apps_pipes) sec_props.ees[dev->ee].pipe_mask = dev->pdata.apps_pipes; /* Register the BAM device with the SPS driver */ ret = sps_register_bam_device(&bam_props, &bam_handle); if (ret) { dev_err(dev->dev, "disabling BAM: reg-bam failed 0x%x\n", ret); dev->use_rx_msgqs = MSM_MSGQ_DISABLED; dev->use_tx_msgqs = MSM_MSGQ_DISABLED; return ret; } dev->bam.hdl = bam_handle; dev_dbg(dev->dev, "SLIM BAM registered, handle = 0x%lx\n", bam_handle); init_pipes: if (dev->port_nums) goto init_msgq; /* get the # of ports first */ dev->port_nums = msm_slim_data_port_assign(dev); if (dev->port_nums && !dev->pipes) { dev->pipes = kzalloc(sizeof(struct msm_slim_endp) * dev->port_nums, GFP_KERNEL); if (IS_ERR_OR_NULL(dev->pipes)) { dev_err(dev->dev, "no memory for data ports"); sps_deregister_bam_device(bam_handle); return PTR_ERR(dev->pipes); } /* assign the ports now */ msm_slim_data_port_assign(dev); } init_msgq: ret = msm_slim_init_rx_msgq(dev, pipe_reg); if (ret) dev_err(dev->dev, "msm_slim_init_rx_msgq failed 0x%x\n", ret); if (ret && bam_handle) dev->use_rx_msgqs = MSM_MSGQ_DISABLED; ret = msm_slim_init_tx_msgq(dev, pipe_reg); if (ret) dev_err(dev->dev, "msm_slim_init_tx_msgq failed 0x%x\n", ret); if (ret && bam_handle) dev->use_tx_msgqs = MSM_MSGQ_DISABLED; /* * If command interface for BAM fails, register interface is used for * commands. * It is possible that other BAM usecases (e.g. apps channels) will * still need BAM. Since BAM is successfully initialized, we can * continue using it for non-command use cases. */ return 0; } void msm_slim_disconnect_endp(struct msm_slim_ctrl *dev, struct msm_slim_endp *endpoint, enum msm_slim_msgq *msgq_flag) { if (*msgq_flag >= MSM_MSGQ_ENABLED) { sps_disconnect(endpoint->sps); *msgq_flag = MSM_MSGQ_RESET; } } static int msm_slim_discard_rx_data(struct msm_slim_ctrl *dev, struct msm_slim_endp *endpoint) { struct sps_iovec sio; int desc_num = 0, ret = 0; ret = sps_get_unused_desc_num(endpoint->sps, &desc_num); if (ret) { dev_err(dev->dev, "sps_get_iovec() failed 0x%x\n", ret); return ret; } while (desc_num--) sps_get_iovec(endpoint->sps, &sio); return ret; } static void msm_slim_remove_ep(struct msm_slim_ctrl *dev, struct msm_slim_endp *endpoint, enum msm_slim_msgq *msgq_flag) { struct sps_connect *config = &endpoint->config; struct sps_mem_buffer *descr = &config->desc; struct sps_mem_buffer *mem = &endpoint->buf; msm_slim_sps_mem_free(dev, mem); msm_slim_sps_mem_free(dev, descr); msm_slim_free_endpoint(endpoint); } void msm_slim_deinit_ep(struct msm_slim_ctrl *dev, struct msm_slim_endp *endpoint, enum msm_slim_msgq *msgq_flag) { int ret = 0; struct sps_connect *config = &endpoint->config; if (*msgq_flag == MSM_MSGQ_ENABLED) { if (config->mode == SPS_MODE_SRC) { ret = msm_slim_discard_rx_data(dev, endpoint); if (ret) SLIM_WARN(dev, "discarding Rx data failed\n"); } msm_slim_disconnect_endp(dev, endpoint, msgq_flag); msm_slim_remove_ep(dev, endpoint, msgq_flag); } } static void msm_slim_sps_unreg_event(struct sps_pipe *sps) { struct sps_register_event sps_event; memset(&sps_event, 0x00, sizeof(sps_event)); /* Disable interrupt and signal notification for Rx/Tx pipe */ sps_register_event(sps, &sps_event); } void msm_slim_sps_exit(struct msm_slim_ctrl *dev, bool dereg) { int i; if (dev->use_rx_msgqs >= MSM_MSGQ_ENABLED) msm_slim_sps_unreg_event(dev->rx_msgq.sps); if (dev->use_tx_msgqs >= MSM_MSGQ_ENABLED) msm_slim_sps_unreg_event(dev->tx_msgq.sps); for (i = 0; i < dev->port_nums; i++) { if (dev->pipes[i].connected) msm_slim_disconn_pipe_port(dev, i); } if (dereg) { for (i = 0; i < dev->port_nums; i++) { if (dev->pipes[i].connected) msm_dealloc_port(&dev->ctrl, i); } sps_deregister_bam_device(dev->bam.hdl); dev->bam.hdl = 0L; kfree(dev->pipes); dev->pipes = NULL; } dev->port_nums = 0; } /* Slimbus QMI Messaging */ #define SLIMBUS_QMI_SELECT_INSTANCE_REQ_V01 0x0020 #define SLIMBUS_QMI_SELECT_INSTANCE_RESP_V01 0x0020 #define SLIMBUS_QMI_POWER_REQ_V01 0x0021 #define SLIMBUS_QMI_POWER_RESP_V01 0x0021 #define SLIMBUS_QMI_CHECK_FRAMER_STATUS_REQ 0x0022 #define SLIMBUS_QMI_CHECK_FRAMER_STATUS_RESP 0x0022 #define SLIMBUS_QMI_POWER_REQ_MAX_MSG_LEN 7 #define SLIMBUS_QMI_POWER_RESP_MAX_MSG_LEN 7 #define SLIMBUS_QMI_SELECT_INSTANCE_REQ_MAX_MSG_LEN 14 #define SLIMBUS_QMI_SELECT_INSTANCE_RESP_MAX_MSG_LEN 7 #define SLIMBUS_QMI_CHECK_FRAMER_STAT_RESP_MAX_MSG_LEN 7 enum slimbus_mode_enum_type_v01 { /* To force a 32 bit signed enum. Do not change or use*/ SLIMBUS_MODE_ENUM_TYPE_MIN_ENUM_VAL_V01 = INT_MIN, SLIMBUS_MODE_SATELLITE_V01 = 1, SLIMBUS_MODE_MASTER_V01 = 2, SLIMBUS_MODE_ENUM_TYPE_MAX_ENUM_VAL_V01 = INT_MAX, }; enum slimbus_pm_enum_type_v01 { /* To force a 32 bit signed enum. Do not change or use*/ SLIMBUS_PM_ENUM_TYPE_MIN_ENUM_VAL_V01 = INT_MIN, SLIMBUS_PM_INACTIVE_V01 = 1, SLIMBUS_PM_ACTIVE_V01 = 2, SLIMBUS_PM_ENUM_TYPE_MAX_ENUM_VAL_V01 = INT_MAX, }; struct slimbus_select_inst_req_msg_v01 { /* Mandatory */ /* Hardware Instance Selection */ uint32_t instance; /* Optional */ /* Optional Mode Request Operation */ /* Must be set to true if mode is being passed */ uint8_t mode_valid; enum slimbus_mode_enum_type_v01 mode; }; struct slimbus_select_inst_resp_msg_v01 { /* Mandatory */ /* Result Code */ struct qmi_response_type_v01 resp; }; struct slimbus_power_req_msg_v01 { /* Mandatory */ /* Power Request Operation */ enum slimbus_pm_enum_type_v01 pm_req; }; struct slimbus_power_resp_msg_v01 { /* Mandatory */ /* Result Code */ struct qmi_response_type_v01 resp; }; struct slimbus_chkfrm_resp_msg { /* Mandatory */ /* Result Code */ struct qmi_response_type_v01 resp; }; static struct elem_info slimbus_select_inst_req_msg_v01_ei[] = { { .data_type = QMI_UNSIGNED_4_BYTE, .elem_len = 1, .elem_size = sizeof(uint32_t), .is_array = NO_ARRAY, .tlv_type = 0x01, .offset = offsetof(struct slimbus_select_inst_req_msg_v01, instance), .ei_array = NULL, }, { .data_type = QMI_OPT_FLAG, .elem_len = 1, .elem_size = sizeof(uint8_t), .is_array = NO_ARRAY, .tlv_type = 0x10, .offset = offsetof(struct slimbus_select_inst_req_msg_v01, mode_valid), .ei_array = NULL, }, { .data_type = QMI_UNSIGNED_4_BYTE, .elem_len = 1, .elem_size = sizeof(enum slimbus_mode_enum_type_v01), .is_array = NO_ARRAY, .tlv_type = 0x10, .offset = offsetof(struct slimbus_select_inst_req_msg_v01, mode), .ei_array = NULL, }, { .data_type = QMI_EOTI, .elem_len = 0, .elem_size = 0, .is_array = NO_ARRAY, .tlv_type = 0x00, .offset = 0, .ei_array = NULL, }, }; static struct elem_info slimbus_select_inst_resp_msg_v01_ei[] = { { .data_type = QMI_STRUCT, .elem_len = 1, .elem_size = sizeof(struct qmi_response_type_v01), .is_array = NO_ARRAY, .tlv_type = 0x02, .offset = offsetof(struct slimbus_select_inst_resp_msg_v01, resp), .ei_array = get_qmi_response_type_v01_ei(), }, { .data_type = QMI_EOTI, .elem_len = 0, .elem_size = 0, .is_array = NO_ARRAY, .tlv_type = 0x00, .offset = 0, .ei_array = NULL, }, }; static struct elem_info slimbus_power_req_msg_v01_ei[] = { { .data_type = QMI_UNSIGNED_4_BYTE, .elem_len = 1, .elem_size = sizeof(enum slimbus_pm_enum_type_v01), .is_array = NO_ARRAY, .tlv_type = 0x01, .offset = offsetof(struct slimbus_power_req_msg_v01, pm_req), .ei_array = NULL, }, { .data_type = QMI_EOTI, .elem_len = 0, .elem_size = 0, .is_array = NO_ARRAY, .tlv_type = 0x00, .offset = 0, .ei_array = NULL, }, }; static struct elem_info slimbus_power_resp_msg_v01_ei[] = { { .data_type = QMI_STRUCT, .elem_len = 1, .elem_size = sizeof(struct qmi_response_type_v01), .is_array = NO_ARRAY, .tlv_type = 0x02, .offset = offsetof(struct slimbus_power_resp_msg_v01, resp), .ei_array = get_qmi_response_type_v01_ei(), }, { .data_type = QMI_EOTI, .elem_len = 0, .elem_size = 0, .is_array = NO_ARRAY, .tlv_type = 0x00, .offset = 0, .ei_array = NULL, }, }; static struct elem_info slimbus_chkfrm_resp_msg_v01_ei[] = { { .data_type = QMI_STRUCT, .elem_len = 1, .elem_size = sizeof(struct qmi_response_type_v01), .is_array = NO_ARRAY, .tlv_type = 0x02, .offset = offsetof(struct slimbus_chkfrm_resp_msg, resp), .ei_array = get_qmi_response_type_v01_ei(), }, { .data_type = QMI_EOTI, .elem_len = 0, .elem_size = 0, .is_array = NO_ARRAY, .tlv_type = 0x00, .offset = 0, .ei_array = NULL, }, }; static void msm_slim_qmi_recv_msg(struct kthread_work *work) { int rc; struct msm_slim_qmi *qmi = container_of(work, struct msm_slim_qmi, kwork); /* Drain all packets received */ do { rc = qmi_recv_msg(qmi->handle); } while (rc == 0); if (rc != -ENOMSG) pr_err("%s: Error receiving QMI message:%d\n", __func__, rc); } static void msm_slim_qmi_notify(struct qmi_handle *handle, enum qmi_event_type event, void *notify_priv) { struct msm_slim_ctrl *dev = notify_priv; struct msm_slim_qmi *qmi = &dev->qmi; switch (event) { case QMI_RECV_MSG: queue_kthread_work(&qmi->kworker, &qmi->kwork); break; default: break; } } static const char *get_qmi_error(struct qmi_response_type_v01 *r) { if (r->result == QMI_RESULT_SUCCESS_V01 || r->error == QMI_ERR_NONE_V01) return "No Error"; else if (r->error == QMI_ERR_NO_MEMORY_V01) return "Out of Memory"; else if (r->error == QMI_ERR_INTERNAL_V01) return "Unexpected error occurred"; else if (r->error == QMI_ERR_INCOMPATIBLE_STATE_V01) return "Slimbus s/w already configured to a different mode"; else if (r->error == QMI_ERR_INVALID_ID_V01) return "Slimbus hardware instance is not valid"; else return "Unknown error"; } static int msm_slim_qmi_send_select_inst_req(struct msm_slim_ctrl *dev, struct slimbus_select_inst_req_msg_v01 *req) { struct slimbus_select_inst_resp_msg_v01 resp = { { 0, 0 } }; struct msg_desc req_desc, resp_desc; int rc; req_desc.msg_id = SLIMBUS_QMI_SELECT_INSTANCE_REQ_V01; req_desc.max_msg_len = SLIMBUS_QMI_SELECT_INSTANCE_REQ_MAX_MSG_LEN; req_desc.ei_array = slimbus_select_inst_req_msg_v01_ei; resp_desc.msg_id = SLIMBUS_QMI_SELECT_INSTANCE_RESP_V01; resp_desc.max_msg_len = SLIMBUS_QMI_SELECT_INSTANCE_RESP_MAX_MSG_LEN; resp_desc.ei_array = slimbus_select_inst_resp_msg_v01_ei; rc = qmi_send_req_wait(dev->qmi.handle, &req_desc, req, sizeof(*req), &resp_desc, &resp, sizeof(resp), SLIM_QMI_RESP_TOUT); if (rc < 0) { SLIM_ERR(dev, "%s: QMI send req failed %d\n", __func__, rc); return rc; } /* Check the response */ if (resp.resp.result != QMI_RESULT_SUCCESS_V01) { SLIM_ERR(dev, "%s: QMI request failed 0x%x (%s)\n", __func__, resp.resp.result, get_qmi_error(&resp.resp)); return -EREMOTEIO; } return 0; } static int msm_slim_qmi_send_power_request(struct msm_slim_ctrl *dev, struct slimbus_power_req_msg_v01 *req) { struct slimbus_power_resp_msg_v01 resp = { { 0, 0 } }; struct msg_desc req_desc, resp_desc; int rc; req_desc.msg_id = SLIMBUS_QMI_POWER_REQ_V01; req_desc.max_msg_len = SLIMBUS_QMI_POWER_REQ_MAX_MSG_LEN; req_desc.ei_array = slimbus_power_req_msg_v01_ei; resp_desc.msg_id = SLIMBUS_QMI_POWER_RESP_V01; resp_desc.max_msg_len = SLIMBUS_QMI_POWER_RESP_MAX_MSG_LEN; resp_desc.ei_array = slimbus_power_resp_msg_v01_ei; rc = qmi_send_req_wait(dev->qmi.handle, &req_desc, req, sizeof(*req), &resp_desc, &resp, sizeof(resp), SLIM_QMI_RESP_TOUT); if (rc < 0) { SLIM_ERR(dev, "%s: QMI send req failed %d\n", __func__, rc); return rc; } /* Check the response */ if (resp.resp.result != QMI_RESULT_SUCCESS_V01) { SLIM_ERR(dev, "%s: QMI request failed 0x%x (%s)\n", __func__, resp.resp.result, get_qmi_error(&resp.resp)); return -EREMOTEIO; } return 0; } int msm_slim_qmi_init(struct msm_slim_ctrl *dev, bool apps_is_master) { int rc = 0; struct qmi_handle *handle; struct slimbus_select_inst_req_msg_v01 req; init_kthread_worker(&dev->qmi.kworker); dev->qmi.task = kthread_run(kthread_worker_fn, &dev->qmi.kworker, "msm_slim_qmi_clnt%d", dev->ctrl.nr); if (IS_ERR(dev->qmi.task)) { pr_err("%s: Failed to create QMI client kthread\n", __func__); return -ENOMEM; } init_kthread_work(&dev->qmi.kwork, msm_slim_qmi_recv_msg); handle = qmi_handle_create(msm_slim_qmi_notify, dev); if (!handle) { rc = -ENOMEM; pr_err("%s: QMI client handle alloc failed\n", __func__); goto qmi_handle_create_failed; } rc = qmi_connect_to_service(handle, SLIMBUS_QMI_SVC_ID, SLIMBUS_QMI_SVC_V1, SLIMBUS_QMI_INS_ID); if (rc < 0) { SLIM_ERR(dev, "%s: QMI server not found\n", __func__); goto qmi_connect_to_service_failed; } /* Instance is 0 based */ req.instance = (dev->ctrl.nr >> 1); req.mode_valid = 1; /* Mode indicates the role of the ADSP */ if (apps_is_master) req.mode = SLIMBUS_MODE_SATELLITE_V01; else req.mode = SLIMBUS_MODE_MASTER_V01; dev->qmi.handle = handle; rc = msm_slim_qmi_send_select_inst_req(dev, &req); if (rc) { pr_err("%s: failed to select h/w instance\n", __func__); goto qmi_select_instance_failed; } return 0; qmi_select_instance_failed: dev->qmi.handle = NULL; qmi_connect_to_service_failed: qmi_handle_destroy(handle); qmi_handle_create_failed: flush_kthread_worker(&dev->qmi.kworker); kthread_stop(dev->qmi.task); dev->qmi.task = NULL; return rc; } void msm_slim_qmi_exit(struct msm_slim_ctrl *dev) { if (!dev->qmi.handle || !dev->qmi.task) return; qmi_handle_destroy(dev->qmi.handle); flush_kthread_worker(&dev->qmi.kworker); kthread_stop(dev->qmi.task); dev->qmi.task = NULL; dev->qmi.handle = NULL; } int msm_slim_qmi_power_request(struct msm_slim_ctrl *dev, bool active) { struct slimbus_power_req_msg_v01 req; if (active) req.pm_req = SLIMBUS_PM_ACTIVE_V01; else req.pm_req = SLIMBUS_PM_INACTIVE_V01; return msm_slim_qmi_send_power_request(dev, &req); } int msm_slim_qmi_check_framer_request(struct msm_slim_ctrl *dev) { struct slimbus_chkfrm_resp_msg resp = { { 0, 0 } }; struct msg_desc req_desc, resp_desc; int rc; req_desc.msg_id = SLIMBUS_QMI_CHECK_FRAMER_STATUS_REQ; req_desc.max_msg_len = 0; req_desc.ei_array = NULL; resp_desc.msg_id = SLIMBUS_QMI_CHECK_FRAMER_STATUS_RESP; resp_desc.max_msg_len = SLIMBUS_QMI_CHECK_FRAMER_STAT_RESP_MAX_MSG_LEN; resp_desc.ei_array = slimbus_chkfrm_resp_msg_v01_ei; rc = qmi_send_req_wait(dev->qmi.handle, &req_desc, NULL, 0, &resp_desc, &resp, sizeof(resp), SLIM_QMI_RESP_TOUT); if (rc < 0) { SLIM_ERR(dev, "%s: QMI send req failed %d\n", __func__, rc); return rc; } /* Check the response */ if (resp.resp.result != QMI_RESULT_SUCCESS_V01) { SLIM_ERR(dev, "%s: QMI request failed 0x%x (%s)\n", __func__, resp.resp.result, get_qmi_error(&resp.resp)); return -EREMOTEIO; } return 0; }