Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Pierre-Louis Bossart | 3116 | 50.34% | 63 | 70.00% |
Vinod Koul | 2482 | 40.10% | 8 | 8.89% |
Bard Liao | 206 | 3.33% | 5 | 5.56% |
Ranjani Sridharan | 152 | 2.46% | 1 | 1.11% |
Rander Wang | 123 | 1.99% | 5 | 5.56% |
Shreyas NC | 96 | 1.55% | 1 | 1.11% |
Charles Keepax | 6 | 0.10% | 1 | 1.11% |
Colin Ian King | 2 | 0.03% | 1 | 1.11% |
Kuninori Morimoto | 2 | 0.03% | 1 | 1.11% |
Libin Yang | 2 | 0.03% | 1 | 1.11% |
Julia Lawall | 1 | 0.02% | 1 | 1.11% |
Srinivas Kandagatla | 1 | 0.02% | 1 | 1.11% |
Zheng Yongjun | 1 | 0.02% | 1 | 1.11% |
Total | 6190 | 90 |
// SPDX-License-Identifier: (GPL-2.0 OR BSD-3-Clause) // Copyright(c) 2015-17 Intel Corporation. /* * Soundwire Intel Master Driver */ #include <linux/acpi.h> #include <linux/debugfs.h> #include <linux/delay.h> #include <linux/io.h> #include <sound/pcm_params.h> #include <linux/pm_runtime.h> #include <sound/soc.h> #include <linux/soundwire/sdw_registers.h> #include <linux/soundwire/sdw.h> #include <linux/soundwire/sdw_intel.h> #include "cadence_master.h" #include "bus.h" #include "intel.h" enum intel_pdi_type { INTEL_PDI_IN = 0, INTEL_PDI_OUT = 1, INTEL_PDI_BD = 2, }; #define cdns_to_intel(_cdns) container_of(_cdns, struct sdw_intel, cdns) /* * Read, write helpers for HW registers */ static inline int intel_readl(void __iomem *base, int offset) { return readl(base + offset); } static inline void intel_writel(void __iomem *base, int offset, int value) { writel(value, base + offset); } static inline u16 intel_readw(void __iomem *base, int offset) { return readw(base + offset); } static inline void intel_writew(void __iomem *base, int offset, u16 value) { writew(value, base + offset); } static int intel_wait_bit(void __iomem *base, int offset, u32 mask, u32 target) { int timeout = 10; u32 reg_read; do { reg_read = readl(base + offset); if ((reg_read & mask) == target) return 0; timeout--; usleep_range(50, 100); } while (timeout != 0); return -EAGAIN; } static int intel_clear_bit(void __iomem *base, int offset, u32 value, u32 mask) { writel(value, base + offset); return intel_wait_bit(base, offset, mask, 0); } static int intel_set_bit(void __iomem *base, int offset, u32 value, u32 mask) { writel(value, base + offset); return intel_wait_bit(base, offset, mask, mask); } /* * debugfs */ #ifdef CONFIG_DEBUG_FS #define RD_BUF (2 * PAGE_SIZE) static ssize_t intel_sprintf(void __iomem *mem, bool l, char *buf, size_t pos, unsigned int reg) { int value; if (l) value = intel_readl(mem, reg); else value = intel_readw(mem, reg); return scnprintf(buf + pos, RD_BUF - pos, "%4x\t%4x\n", reg, value); } static int intel_reg_show(struct seq_file *s_file, void *data) { struct sdw_intel *sdw = s_file->private; void __iomem *s = sdw->link_res->shim; void __iomem *a = sdw->link_res->alh; char *buf; ssize_t ret; int i, j; unsigned int links, reg; buf = kzalloc(RD_BUF, GFP_KERNEL); if (!buf) return -ENOMEM; links = intel_readl(s, SDW_SHIM_LCAP) & SDW_SHIM_LCAP_LCOUNT_MASK; ret = scnprintf(buf, RD_BUF, "Register Value\n"); ret += scnprintf(buf + ret, RD_BUF - ret, "\nShim\n"); for (i = 0; i < links; i++) { reg = SDW_SHIM_LCAP + i * 4; ret += intel_sprintf(s, true, buf, ret, reg); } for (i = 0; i < links; i++) { ret += scnprintf(buf + ret, RD_BUF - ret, "\nLink%d\n", i); ret += intel_sprintf(s, false, buf, ret, SDW_SHIM_CTLSCAP(i)); ret += intel_sprintf(s, false, buf, ret, SDW_SHIM_CTLS0CM(i)); ret += intel_sprintf(s, false, buf, ret, SDW_SHIM_CTLS1CM(i)); ret += intel_sprintf(s, false, buf, ret, SDW_SHIM_CTLS2CM(i)); ret += intel_sprintf(s, false, buf, ret, SDW_SHIM_CTLS3CM(i)); ret += intel_sprintf(s, false, buf, ret, SDW_SHIM_PCMSCAP(i)); ret += scnprintf(buf + ret, RD_BUF - ret, "\n PCMSyCH registers\n"); /* * the value 10 is the number of PDIs. We will need a * cleanup to remove hard-coded Intel configurations * from cadence_master.c */ for (j = 0; j < 10; j++) { ret += intel_sprintf(s, false, buf, ret, SDW_SHIM_PCMSYCHM(i, j)); ret += intel_sprintf(s, false, buf, ret, SDW_SHIM_PCMSYCHC(i, j)); } ret += scnprintf(buf + ret, RD_BUF - ret, "\n IOCTL, CTMCTL\n"); ret += intel_sprintf(s, false, buf, ret, SDW_SHIM_IOCTL(i)); ret += intel_sprintf(s, false, buf, ret, SDW_SHIM_CTMCTL(i)); } ret += scnprintf(buf + ret, RD_BUF - ret, "\nWake registers\n"); ret += intel_sprintf(s, false, buf, ret, SDW_SHIM_WAKEEN); ret += intel_sprintf(s, false, buf, ret, SDW_SHIM_WAKESTS); ret += scnprintf(buf + ret, RD_BUF - ret, "\nALH STRMzCFG\n"); for (i = 0; i < SDW_ALH_NUM_STREAMS; i++) ret += intel_sprintf(a, true, buf, ret, SDW_ALH_STRMZCFG(i)); seq_printf(s_file, "%s", buf); kfree(buf); return 0; } DEFINE_SHOW_ATTRIBUTE(intel_reg); static int intel_set_m_datamode(void *data, u64 value) { struct sdw_intel *sdw = data; struct sdw_bus *bus = &sdw->cdns.bus; if (value > SDW_PORT_DATA_MODE_STATIC_1) return -EINVAL; /* Userspace changed the hardware state behind the kernel's back */ add_taint(TAINT_USER, LOCKDEP_STILL_OK); bus->params.m_data_mode = value; return 0; } DEFINE_DEBUGFS_ATTRIBUTE(intel_set_m_datamode_fops, NULL, intel_set_m_datamode, "%llu\n"); static int intel_set_s_datamode(void *data, u64 value) { struct sdw_intel *sdw = data; struct sdw_bus *bus = &sdw->cdns.bus; if (value > SDW_PORT_DATA_MODE_STATIC_1) return -EINVAL; /* Userspace changed the hardware state behind the kernel's back */ add_taint(TAINT_USER, LOCKDEP_STILL_OK); bus->params.s_data_mode = value; return 0; } DEFINE_DEBUGFS_ATTRIBUTE(intel_set_s_datamode_fops, NULL, intel_set_s_datamode, "%llu\n"); static void intel_debugfs_init(struct sdw_intel *sdw) { struct dentry *root = sdw->cdns.bus.debugfs; if (!root) return; sdw->debugfs = debugfs_create_dir("intel-sdw", root); debugfs_create_file("intel-registers", 0400, sdw->debugfs, sdw, &intel_reg_fops); debugfs_create_file("intel-m-datamode", 0200, sdw->debugfs, sdw, &intel_set_m_datamode_fops); debugfs_create_file("intel-s-datamode", 0200, sdw->debugfs, sdw, &intel_set_s_datamode_fops); sdw_cdns_debugfs_init(&sdw->cdns, sdw->debugfs); } static void intel_debugfs_exit(struct sdw_intel *sdw) { debugfs_remove_recursive(sdw->debugfs); } #else static void intel_debugfs_init(struct sdw_intel *sdw) {} static void intel_debugfs_exit(struct sdw_intel *sdw) {} #endif /* CONFIG_DEBUG_FS */ /* * shim ops */ /* this needs to be called with shim_lock */ static void intel_shim_glue_to_master_ip(struct sdw_intel *sdw) { void __iomem *shim = sdw->link_res->shim; unsigned int link_id = sdw->instance; u16 ioctl; /* Switch to MIP from Glue logic */ ioctl = intel_readw(shim, SDW_SHIM_IOCTL(link_id)); ioctl &= ~(SDW_SHIM_IOCTL_DOE); intel_writew(shim, SDW_SHIM_IOCTL(link_id), ioctl); usleep_range(10, 15); ioctl &= ~(SDW_SHIM_IOCTL_DO); intel_writew(shim, SDW_SHIM_IOCTL(link_id), ioctl); usleep_range(10, 15); ioctl |= (SDW_SHIM_IOCTL_MIF); intel_writew(shim, SDW_SHIM_IOCTL(link_id), ioctl); usleep_range(10, 15); ioctl &= ~(SDW_SHIM_IOCTL_BKE); ioctl &= ~(SDW_SHIM_IOCTL_COE); intel_writew(shim, SDW_SHIM_IOCTL(link_id), ioctl); usleep_range(10, 15); /* at this point Master IP has full control of the I/Os */ } /* this needs to be called with shim_lock */ static void intel_shim_master_ip_to_glue(struct sdw_intel *sdw) { unsigned int link_id = sdw->instance; void __iomem *shim = sdw->link_res->shim; u16 ioctl; /* Glue logic */ ioctl = intel_readw(shim, SDW_SHIM_IOCTL(link_id)); ioctl |= SDW_SHIM_IOCTL_BKE; ioctl |= SDW_SHIM_IOCTL_COE; intel_writew(shim, SDW_SHIM_IOCTL(link_id), ioctl); usleep_range(10, 15); ioctl &= ~(SDW_SHIM_IOCTL_MIF); intel_writew(shim, SDW_SHIM_IOCTL(link_id), ioctl); usleep_range(10, 15); /* at this point Integration Glue has full control of the I/Os */ } /* this needs to be called with shim_lock */ static void intel_shim_init(struct sdw_intel *sdw) { void __iomem *shim = sdw->link_res->shim; unsigned int link_id = sdw->instance; u16 ioctl = 0, act = 0; /* Initialize Shim */ ioctl |= SDW_SHIM_IOCTL_BKE; intel_writew(shim, SDW_SHIM_IOCTL(link_id), ioctl); usleep_range(10, 15); ioctl |= SDW_SHIM_IOCTL_WPDD; intel_writew(shim, SDW_SHIM_IOCTL(link_id), ioctl); usleep_range(10, 15); ioctl |= SDW_SHIM_IOCTL_DO; intel_writew(shim, SDW_SHIM_IOCTL(link_id), ioctl); usleep_range(10, 15); ioctl |= SDW_SHIM_IOCTL_DOE; intel_writew(shim, SDW_SHIM_IOCTL(link_id), ioctl); usleep_range(10, 15); intel_shim_glue_to_master_ip(sdw); u16p_replace_bits(&act, 0x1, SDW_SHIM_CTMCTL_DOAIS); act |= SDW_SHIM_CTMCTL_DACTQE; act |= SDW_SHIM_CTMCTL_DODS; intel_writew(shim, SDW_SHIM_CTMCTL(link_id), act); usleep_range(10, 15); } static int intel_shim_check_wake(struct sdw_intel *sdw) { void __iomem *shim; u16 wake_sts; shim = sdw->link_res->shim; wake_sts = intel_readw(shim, SDW_SHIM_WAKESTS); return wake_sts & BIT(sdw->instance); } static void intel_shim_wake(struct sdw_intel *sdw, bool wake_enable) { void __iomem *shim = sdw->link_res->shim; unsigned int link_id = sdw->instance; u16 wake_en, wake_sts; mutex_lock(sdw->link_res->shim_lock); wake_en = intel_readw(shim, SDW_SHIM_WAKEEN); if (wake_enable) { /* Enable the wakeup */ wake_en |= (SDW_SHIM_WAKEEN_ENABLE << link_id); intel_writew(shim, SDW_SHIM_WAKEEN, wake_en); } else { /* Disable the wake up interrupt */ wake_en &= ~(SDW_SHIM_WAKEEN_ENABLE << link_id); intel_writew(shim, SDW_SHIM_WAKEEN, wake_en); /* Clear wake status */ wake_sts = intel_readw(shim, SDW_SHIM_WAKESTS); wake_sts |= (SDW_SHIM_WAKESTS_STATUS << link_id); intel_writew(shim, SDW_SHIM_WAKESTS, wake_sts); } mutex_unlock(sdw->link_res->shim_lock); } static int intel_link_power_up(struct sdw_intel *sdw) { unsigned int link_id = sdw->instance; void __iomem *shim = sdw->link_res->shim; u32 *shim_mask = sdw->link_res->shim_mask; struct sdw_bus *bus = &sdw->cdns.bus; struct sdw_master_prop *prop = &bus->prop; u32 spa_mask, cpa_mask; u32 link_control; int ret = 0; u32 syncprd; u32 sync_reg; mutex_lock(sdw->link_res->shim_lock); /* * The hardware relies on an internal counter, typically 4kHz, * to generate the SoundWire SSP - which defines a 'safe' * synchronization point between commands and audio transport * and allows for multi link synchronization. The SYNCPRD value * is only dependent on the oscillator clock provided to * the IP, so adjust based on _DSD properties reported in DSDT * tables. The values reported are based on either 24MHz * (CNL/CML) or 38.4 MHz (ICL/TGL+). */ if (prop->mclk_freq % 6000000) syncprd = SDW_SHIM_SYNC_SYNCPRD_VAL_38_4; else syncprd = SDW_SHIM_SYNC_SYNCPRD_VAL_24; if (!*shim_mask) { dev_dbg(sdw->cdns.dev, "powering up all links\n"); /* we first need to program the SyncPRD/CPU registers */ dev_dbg(sdw->cdns.dev, "first link up, programming SYNCPRD\n"); /* set SyncPRD period */ sync_reg = intel_readl(shim, SDW_SHIM_SYNC); u32p_replace_bits(&sync_reg, syncprd, SDW_SHIM_SYNC_SYNCPRD); /* Set SyncCPU bit */ sync_reg |= SDW_SHIM_SYNC_SYNCCPU; intel_writel(shim, SDW_SHIM_SYNC, sync_reg); /* Link power up sequence */ link_control = intel_readl(shim, SDW_SHIM_LCTL); /* only power-up enabled links */ spa_mask = FIELD_PREP(SDW_SHIM_LCTL_SPA_MASK, sdw->link_res->link_mask); cpa_mask = FIELD_PREP(SDW_SHIM_LCTL_CPA_MASK, sdw->link_res->link_mask); link_control |= spa_mask; ret = intel_set_bit(shim, SDW_SHIM_LCTL, link_control, cpa_mask); if (ret < 0) { dev_err(sdw->cdns.dev, "Failed to power up link: %d\n", ret); goto out; } /* SyncCPU will change once link is active */ ret = intel_wait_bit(shim, SDW_SHIM_SYNC, SDW_SHIM_SYNC_SYNCCPU, 0); if (ret < 0) { dev_err(sdw->cdns.dev, "Failed to set SHIM_SYNC: %d\n", ret); goto out; } } *shim_mask |= BIT(link_id); sdw->cdns.link_up = true; intel_shim_init(sdw); out: mutex_unlock(sdw->link_res->shim_lock); return ret; } static int intel_link_power_down(struct sdw_intel *sdw) { u32 link_control, spa_mask, cpa_mask; unsigned int link_id = sdw->instance; void __iomem *shim = sdw->link_res->shim; u32 *shim_mask = sdw->link_res->shim_mask; int ret = 0; mutex_lock(sdw->link_res->shim_lock); if (!(*shim_mask & BIT(link_id))) dev_err(sdw->cdns.dev, "%s: Unbalanced power-up/down calls\n", __func__); sdw->cdns.link_up = false; intel_shim_master_ip_to_glue(sdw); *shim_mask &= ~BIT(link_id); if (!*shim_mask) { dev_dbg(sdw->cdns.dev, "powering down all links\n"); /* Link power down sequence */ link_control = intel_readl(shim, SDW_SHIM_LCTL); /* only power-down enabled links */ spa_mask = FIELD_PREP(SDW_SHIM_LCTL_SPA_MASK, ~sdw->link_res->link_mask); cpa_mask = FIELD_PREP(SDW_SHIM_LCTL_CPA_MASK, sdw->link_res->link_mask); link_control &= spa_mask; ret = intel_clear_bit(shim, SDW_SHIM_LCTL, link_control, cpa_mask); if (ret < 0) { dev_err(sdw->cdns.dev, "%s: could not power down link\n", __func__); /* * we leave the sdw->cdns.link_up flag as false since we've disabled * the link at this point and cannot handle interrupts any longer. */ } } mutex_unlock(sdw->link_res->shim_lock); return ret; } static void intel_shim_sync_arm(struct sdw_intel *sdw) { void __iomem *shim = sdw->link_res->shim; u32 sync_reg; mutex_lock(sdw->link_res->shim_lock); /* update SYNC register */ sync_reg = intel_readl(shim, SDW_SHIM_SYNC); sync_reg |= (SDW_SHIM_SYNC_CMDSYNC << sdw->instance); intel_writel(shim, SDW_SHIM_SYNC, sync_reg); mutex_unlock(sdw->link_res->shim_lock); } static int intel_shim_sync_go_unlocked(struct sdw_intel *sdw) { void __iomem *shim = sdw->link_res->shim; u32 sync_reg; int ret; /* Read SYNC register */ sync_reg = intel_readl(shim, SDW_SHIM_SYNC); /* * Set SyncGO bit to synchronously trigger a bank switch for * all the masters. A write to SYNCGO bit clears CMDSYNC bit for all * the Masters. */ sync_reg |= SDW_SHIM_SYNC_SYNCGO; ret = intel_clear_bit(shim, SDW_SHIM_SYNC, sync_reg, SDW_SHIM_SYNC_SYNCGO); if (ret < 0) dev_err(sdw->cdns.dev, "SyncGO clear failed: %d\n", ret); return ret; } static int intel_shim_sync_go(struct sdw_intel *sdw) { int ret; mutex_lock(sdw->link_res->shim_lock); ret = intel_shim_sync_go_unlocked(sdw); mutex_unlock(sdw->link_res->shim_lock); return ret; } /* * PDI routines */ static void intel_pdi_init(struct sdw_intel *sdw, struct sdw_cdns_stream_config *config) { void __iomem *shim = sdw->link_res->shim; unsigned int link_id = sdw->instance; int pcm_cap; /* PCM Stream Capability */ pcm_cap = intel_readw(shim, SDW_SHIM_PCMSCAP(link_id)); config->pcm_bd = FIELD_GET(SDW_SHIM_PCMSCAP_BSS, pcm_cap); config->pcm_in = FIELD_GET(SDW_SHIM_PCMSCAP_ISS, pcm_cap); config->pcm_out = FIELD_GET(SDW_SHIM_PCMSCAP_OSS, pcm_cap); dev_dbg(sdw->cdns.dev, "PCM cap bd:%d in:%d out:%d\n", config->pcm_bd, config->pcm_in, config->pcm_out); } static int intel_pdi_get_ch_cap(struct sdw_intel *sdw, unsigned int pdi_num) { void __iomem *shim = sdw->link_res->shim; unsigned int link_id = sdw->instance; int count; count = intel_readw(shim, SDW_SHIM_PCMSYCHC(link_id, pdi_num)); /* * WORKAROUND: on all existing Intel controllers, pdi * number 2 reports channel count as 1 even though it * supports 8 channels. Performing hardcoding for pdi * number 2. */ if (pdi_num == 2) count = 7; /* zero based values for channel count in register */ count++; return count; } static int intel_pdi_get_ch_update(struct sdw_intel *sdw, struct sdw_cdns_pdi *pdi, unsigned int num_pdi, unsigned int *num_ch) { int i, ch_count = 0; for (i = 0; i < num_pdi; i++) { pdi->ch_count = intel_pdi_get_ch_cap(sdw, pdi->num); ch_count += pdi->ch_count; pdi++; } *num_ch = ch_count; return 0; } static int intel_pdi_stream_ch_update(struct sdw_intel *sdw, struct sdw_cdns_streams *stream) { intel_pdi_get_ch_update(sdw, stream->bd, stream->num_bd, &stream->num_ch_bd); intel_pdi_get_ch_update(sdw, stream->in, stream->num_in, &stream->num_ch_in); intel_pdi_get_ch_update(sdw, stream->out, stream->num_out, &stream->num_ch_out); return 0; } static int intel_pdi_ch_update(struct sdw_intel *sdw) { intel_pdi_stream_ch_update(sdw, &sdw->cdns.pcm); return 0; } static void intel_pdi_shim_configure(struct sdw_intel *sdw, struct sdw_cdns_pdi *pdi) { void __iomem *shim = sdw->link_res->shim; unsigned int link_id = sdw->instance; int pdi_conf = 0; /* the Bulk and PCM streams are not contiguous */ pdi->intel_alh_id = (link_id * 16) + pdi->num + 3; if (pdi->num >= 2) pdi->intel_alh_id += 2; /* * Program stream parameters to stream SHIM register * This is applicable for PCM stream only. */ if (pdi->type != SDW_STREAM_PCM) return; if (pdi->dir == SDW_DATA_DIR_RX) pdi_conf |= SDW_SHIM_PCMSYCM_DIR; else pdi_conf &= ~(SDW_SHIM_PCMSYCM_DIR); u32p_replace_bits(&pdi_conf, pdi->intel_alh_id, SDW_SHIM_PCMSYCM_STREAM); u32p_replace_bits(&pdi_conf, pdi->l_ch_num, SDW_SHIM_PCMSYCM_LCHN); u32p_replace_bits(&pdi_conf, pdi->h_ch_num, SDW_SHIM_PCMSYCM_HCHN); intel_writew(shim, SDW_SHIM_PCMSYCHM(link_id, pdi->num), pdi_conf); } static void intel_pdi_alh_configure(struct sdw_intel *sdw, struct sdw_cdns_pdi *pdi) { void __iomem *alh = sdw->link_res->alh; unsigned int link_id = sdw->instance; unsigned int conf; /* the Bulk and PCM streams are not contiguous */ pdi->intel_alh_id = (link_id * 16) + pdi->num + 3; if (pdi->num >= 2) pdi->intel_alh_id += 2; /* Program Stream config ALH register */ conf = intel_readl(alh, SDW_ALH_STRMZCFG(pdi->intel_alh_id)); u32p_replace_bits(&conf, SDW_ALH_STRMZCFG_DMAT_VAL, SDW_ALH_STRMZCFG_DMAT); u32p_replace_bits(&conf, pdi->ch_count - 1, SDW_ALH_STRMZCFG_CHN); intel_writel(alh, SDW_ALH_STRMZCFG(pdi->intel_alh_id), conf); } static int intel_params_stream(struct sdw_intel *sdw, int stream, struct snd_soc_dai *dai, struct snd_pcm_hw_params *hw_params, int link_id, int alh_stream_id) { struct sdw_intel_link_res *res = sdw->link_res; struct sdw_intel_stream_params_data params_data; params_data.stream = stream; /* direction */ params_data.dai = dai; params_data.hw_params = hw_params; params_data.link_id = link_id; params_data.alh_stream_id = alh_stream_id; if (res->ops && res->ops->params_stream && res->dev) return res->ops->params_stream(res->dev, ¶ms_data); return -EIO; } static int intel_free_stream(struct sdw_intel *sdw, int stream, struct snd_soc_dai *dai, int link_id) { struct sdw_intel_link_res *res = sdw->link_res; struct sdw_intel_stream_free_data free_data; free_data.stream = stream; /* direction */ free_data.dai = dai; free_data.link_id = link_id; if (res->ops && res->ops->free_stream && res->dev) return res->ops->free_stream(res->dev, &free_data); return 0; } /* * bank switch routines */ static int intel_pre_bank_switch(struct sdw_intel *sdw) { struct sdw_cdns *cdns = &sdw->cdns; struct sdw_bus *bus = &cdns->bus; /* Write to register only for multi-link */ if (!bus->multi_link) return 0; intel_shim_sync_arm(sdw); return 0; } static int intel_post_bank_switch(struct sdw_intel *sdw) { struct sdw_cdns *cdns = &sdw->cdns; struct sdw_bus *bus = &cdns->bus; void __iomem *shim = sdw->link_res->shim; int sync_reg, ret; /* Write to register only for multi-link */ if (!bus->multi_link) return 0; mutex_lock(sdw->link_res->shim_lock); /* Read SYNC register */ sync_reg = intel_readl(shim, SDW_SHIM_SYNC); /* * post_bank_switch() ops is called from the bus in loop for * all the Masters in the steam with the expectation that * we trigger the bankswitch for the only first Master in the list * and do nothing for the other Masters * * So, set the SYNCGO bit only if CMDSYNC bit is set for any Master. */ if (!(sync_reg & SDW_SHIM_SYNC_CMDSYNC_MASK)) { ret = 0; goto unlock; } ret = intel_shim_sync_go_unlocked(sdw); unlock: mutex_unlock(sdw->link_res->shim_lock); if (ret < 0) dev_err(sdw->cdns.dev, "Post bank switch failed: %d\n", ret); return ret; } /* * DAI routines */ static int intel_hw_params(struct snd_pcm_substream *substream, struct snd_pcm_hw_params *params, struct snd_soc_dai *dai) { struct sdw_cdns *cdns = snd_soc_dai_get_drvdata(dai); struct sdw_intel *sdw = cdns_to_intel(cdns); struct sdw_cdns_dai_runtime *dai_runtime; struct sdw_cdns_pdi *pdi; struct sdw_stream_config sconfig; struct sdw_port_config *pconfig; int ch, dir; int ret; dai_runtime = cdns->dai_runtime_array[dai->id]; if (!dai_runtime) return -EIO; ch = params_channels(params); if (substream->stream == SNDRV_PCM_STREAM_CAPTURE) dir = SDW_DATA_DIR_RX; else dir = SDW_DATA_DIR_TX; pdi = sdw_cdns_alloc_pdi(cdns, &cdns->pcm, ch, dir, dai->id); if (!pdi) { ret = -EINVAL; goto error; } /* do run-time configurations for SHIM, ALH and PDI/PORT */ intel_pdi_shim_configure(sdw, pdi); intel_pdi_alh_configure(sdw, pdi); sdw_cdns_config_stream(cdns, ch, dir, pdi); /* store pdi and hw_params, may be needed in prepare step */ dai_runtime->paused = false; dai_runtime->suspended = false; dai_runtime->pdi = pdi; dai_runtime->hw_params = params; /* Inform DSP about PDI stream number */ ret = intel_params_stream(sdw, substream->stream, dai, params, sdw->instance, pdi->intel_alh_id); if (ret) goto error; sconfig.direction = dir; sconfig.ch_count = ch; sconfig.frame_rate = params_rate(params); sconfig.type = dai_runtime->stream_type; sconfig.bps = snd_pcm_format_width(params_format(params)); /* Port configuration */ pconfig = kzalloc(sizeof(*pconfig), GFP_KERNEL); if (!pconfig) { ret = -ENOMEM; goto error; } pconfig->num = pdi->num; pconfig->ch_mask = (1 << ch) - 1; ret = sdw_stream_add_master(&cdns->bus, &sconfig, pconfig, 1, dai_runtime->stream); if (ret) dev_err(cdns->dev, "add master to stream failed:%d\n", ret); kfree(pconfig); error: return ret; } static int intel_prepare(struct snd_pcm_substream *substream, struct snd_soc_dai *dai) { struct sdw_cdns *cdns = snd_soc_dai_get_drvdata(dai); struct sdw_intel *sdw = cdns_to_intel(cdns); struct sdw_cdns_dai_runtime *dai_runtime; int ch, dir; int ret = 0; dai_runtime = cdns->dai_runtime_array[dai->id]; if (!dai_runtime) { dev_err(dai->dev, "failed to get dai runtime in %s\n", __func__); return -EIO; } if (dai_runtime->suspended) { dai_runtime->suspended = false; /* * .prepare() is called after system resume, where we * need to reinitialize the SHIM/ALH/Cadence IP. * .prepare() is also called to deal with underflows, * but in those cases we cannot touch ALH/SHIM * registers */ /* configure stream */ ch = params_channels(dai_runtime->hw_params); if (substream->stream == SNDRV_PCM_STREAM_CAPTURE) dir = SDW_DATA_DIR_RX; else dir = SDW_DATA_DIR_TX; intel_pdi_shim_configure(sdw, dai_runtime->pdi); intel_pdi_alh_configure(sdw, dai_runtime->pdi); sdw_cdns_config_stream(cdns, ch, dir, dai_runtime->pdi); /* Inform DSP about PDI stream number */ ret = intel_params_stream(sdw, substream->stream, dai, dai_runtime->hw_params, sdw->instance, dai_runtime->pdi->intel_alh_id); } return ret; } static int intel_hw_free(struct snd_pcm_substream *substream, struct snd_soc_dai *dai) { struct sdw_cdns *cdns = snd_soc_dai_get_drvdata(dai); struct sdw_intel *sdw = cdns_to_intel(cdns); struct sdw_cdns_dai_runtime *dai_runtime; int ret; dai_runtime = cdns->dai_runtime_array[dai->id]; if (!dai_runtime) return -EIO; /* * The sdw stream state will transition to RELEASED when stream-> * master_list is empty. So the stream state will transition to * DEPREPARED for the first cpu-dai and to RELEASED for the last * cpu-dai. */ ret = sdw_stream_remove_master(&cdns->bus, dai_runtime->stream); if (ret < 0) { dev_err(dai->dev, "remove master from stream %s failed: %d\n", dai_runtime->stream->name, ret); return ret; } ret = intel_free_stream(sdw, substream->stream, dai, sdw->instance); if (ret < 0) { dev_err(dai->dev, "intel_free_stream: failed %d\n", ret); return ret; } dai_runtime->hw_params = NULL; dai_runtime->pdi = NULL; return 0; } static int intel_pcm_set_sdw_stream(struct snd_soc_dai *dai, void *stream, int direction) { return cdns_set_sdw_stream(dai, stream, direction); } static void *intel_get_sdw_stream(struct snd_soc_dai *dai, int direction) { struct sdw_cdns *cdns = snd_soc_dai_get_drvdata(dai); struct sdw_cdns_dai_runtime *dai_runtime; dai_runtime = cdns->dai_runtime_array[dai->id]; if (!dai_runtime) return ERR_PTR(-EINVAL); return dai_runtime->stream; } static int intel_trigger(struct snd_pcm_substream *substream, int cmd, struct snd_soc_dai *dai) { struct sdw_cdns *cdns = snd_soc_dai_get_drvdata(dai); struct sdw_intel *sdw = cdns_to_intel(cdns); struct sdw_intel_link_res *res = sdw->link_res; struct sdw_cdns_dai_runtime *dai_runtime; int ret = 0; /* * The .trigger callback is used to send required IPC to audio * firmware. The .free_stream callback will still be called * by intel_free_stream() in the TRIGGER_SUSPEND case. */ if (res->ops && res->ops->trigger) res->ops->trigger(dai, cmd, substream->stream); dai_runtime = cdns->dai_runtime_array[dai->id]; if (!dai_runtime) { dev_err(dai->dev, "failed to get dai runtime in %s\n", __func__); return -EIO; } switch (cmd) { case SNDRV_PCM_TRIGGER_SUSPEND: /* * The .prepare callback is used to deal with xruns and resume operations. * In the case of xruns, the DMAs and SHIM registers cannot be touched, * but for resume operations the DMAs and SHIM registers need to be initialized. * the .trigger callback is used to track the suspend case only. */ dai_runtime->suspended = true; ret = intel_free_stream(sdw, substream->stream, dai, sdw->instance); break; case SNDRV_PCM_TRIGGER_PAUSE_PUSH: dai_runtime->paused = true; break; case SNDRV_PCM_TRIGGER_STOP: case SNDRV_PCM_TRIGGER_PAUSE_RELEASE: dai_runtime->paused = false; break; default: break; } return ret; } static int intel_component_probe(struct snd_soc_component *component) { int ret; /* * make sure the device is pm_runtime_active before initiating * bus transactions during the card registration. * We use pm_runtime_resume() here, without taking a reference * and releasing it immediately. */ ret = pm_runtime_resume(component->dev); if (ret < 0 && ret != -EACCES) return ret; return 0; } static int intel_component_dais_suspend(struct snd_soc_component *component) { struct snd_soc_dai *dai; /* * In the corner case where a SUSPEND happens during a PAUSE, the ALSA core * does not throw the TRIGGER_SUSPEND. This leaves the DAIs in an unbalanced state. * Since the component suspend is called last, we can trap this corner case * and force the DAIs to release their resources. */ for_each_component_dais(component, dai) { struct sdw_cdns *cdns = snd_soc_dai_get_drvdata(dai); struct sdw_intel *sdw = cdns_to_intel(cdns); struct sdw_cdns_dai_runtime *dai_runtime; int ret; dai_runtime = cdns->dai_runtime_array[dai->id]; if (!dai_runtime) continue; if (dai_runtime->suspended) continue; if (dai_runtime->paused) { dai_runtime->suspended = true; ret = intel_free_stream(sdw, dai_runtime->direction, dai, sdw->instance); if (ret < 0) return ret; } } return 0; } static const struct snd_soc_dai_ops intel_pcm_dai_ops = { .hw_params = intel_hw_params, .prepare = intel_prepare, .hw_free = intel_hw_free, .trigger = intel_trigger, .set_stream = intel_pcm_set_sdw_stream, .get_stream = intel_get_sdw_stream, }; static const struct snd_soc_component_driver dai_component = { .name = "soundwire", .probe = intel_component_probe, .suspend = intel_component_dais_suspend, .legacy_dai_naming = 1, }; static int intel_create_dai(struct sdw_cdns *cdns, struct snd_soc_dai_driver *dais, enum intel_pdi_type type, u32 num, u32 off, u32 max_ch) { int i; if (num == 0) return 0; /* TODO: Read supported rates/formats from hardware */ for (i = off; i < (off + num); i++) { dais[i].name = devm_kasprintf(cdns->dev, GFP_KERNEL, "SDW%d Pin%d", cdns->instance, i); if (!dais[i].name) return -ENOMEM; if (type == INTEL_PDI_BD || type == INTEL_PDI_OUT) { dais[i].playback.channels_min = 1; dais[i].playback.channels_max = max_ch; dais[i].playback.rates = SNDRV_PCM_RATE_48000; dais[i].playback.formats = SNDRV_PCM_FMTBIT_S16_LE; } if (type == INTEL_PDI_BD || type == INTEL_PDI_IN) { dais[i].capture.channels_min = 1; dais[i].capture.channels_max = max_ch; dais[i].capture.rates = SNDRV_PCM_RATE_48000; dais[i].capture.formats = SNDRV_PCM_FMTBIT_S16_LE; } dais[i].ops = &intel_pcm_dai_ops; } return 0; } static int intel_register_dai(struct sdw_intel *sdw) { struct sdw_cdns_dai_runtime **dai_runtime_array; struct sdw_cdns_stream_config config; struct sdw_cdns *cdns = &sdw->cdns; struct sdw_cdns_streams *stream; struct snd_soc_dai_driver *dais; int num_dai, ret, off = 0; /* Read the PDI config and initialize cadence PDI */ intel_pdi_init(sdw, &config); ret = sdw_cdns_pdi_init(cdns, config); if (ret) return ret; intel_pdi_ch_update(sdw); /* DAIs are created based on total number of PDIs supported */ num_dai = cdns->pcm.num_pdi; dai_runtime_array = devm_kcalloc(cdns->dev, num_dai, sizeof(struct sdw_cdns_dai_runtime *), GFP_KERNEL); if (!dai_runtime_array) return -ENOMEM; cdns->dai_runtime_array = dai_runtime_array; dais = devm_kcalloc(cdns->dev, num_dai, sizeof(*dais), GFP_KERNEL); if (!dais) return -ENOMEM; /* Create PCM DAIs */ stream = &cdns->pcm; ret = intel_create_dai(cdns, dais, INTEL_PDI_IN, cdns->pcm.num_in, off, stream->num_ch_in); if (ret) return ret; off += cdns->pcm.num_in; ret = intel_create_dai(cdns, dais, INTEL_PDI_OUT, cdns->pcm.num_out, off, stream->num_ch_out); if (ret) return ret; off += cdns->pcm.num_out; ret = intel_create_dai(cdns, dais, INTEL_PDI_BD, cdns->pcm.num_bd, off, stream->num_ch_bd); if (ret) return ret; return devm_snd_soc_register_component(cdns->dev, &dai_component, dais, num_dai); } static int intel_start_bus(struct sdw_intel *sdw) { struct device *dev = sdw->cdns.dev; struct sdw_cdns *cdns = &sdw->cdns; struct sdw_bus *bus = &cdns->bus; int ret; ret = sdw_cdns_enable_interrupt(cdns, true); if (ret < 0) { dev_err(dev, "%s: cannot enable interrupts: %d\n", __func__, ret); return ret; } /* * follow recommended programming flows to avoid timeouts when * gsync is enabled */ if (bus->multi_link) intel_shim_sync_arm(sdw); ret = sdw_cdns_init(cdns); if (ret < 0) { dev_err(dev, "%s: unable to initialize Cadence IP: %d\n", __func__, ret); goto err_interrupt; } ret = sdw_cdns_exit_reset(cdns); if (ret < 0) { dev_err(dev, "%s: unable to exit bus reset sequence: %d\n", __func__, ret); goto err_interrupt; } if (bus->multi_link) { ret = intel_shim_sync_go(sdw); if (ret < 0) { dev_err(dev, "%s: sync go failed: %d\n", __func__, ret); goto err_interrupt; } } sdw_cdns_check_self_clearing_bits(cdns, __func__, true, INTEL_MASTER_RESET_ITERATIONS); return 0; err_interrupt: sdw_cdns_enable_interrupt(cdns, false); return ret; } static int intel_start_bus_after_reset(struct sdw_intel *sdw) { struct device *dev = sdw->cdns.dev; struct sdw_cdns *cdns = &sdw->cdns; struct sdw_bus *bus = &cdns->bus; bool clock_stop0; int status; int ret; /* * An exception condition occurs for the CLK_STOP_BUS_RESET * case if one or more masters remain active. In this condition, * all the masters are powered on for they are in the same power * domain. Master can preserve its context for clock stop0, so * there is no need to clear slave status and reset bus. */ clock_stop0 = sdw_cdns_is_clock_stop(&sdw->cdns); if (!clock_stop0) { /* * make sure all Slaves are tagged as UNATTACHED and * provide reason for reinitialization */ status = SDW_UNATTACH_REQUEST_MASTER_RESET; sdw_clear_slave_status(bus, status); ret = sdw_cdns_enable_interrupt(cdns, true); if (ret < 0) { dev_err(dev, "cannot enable interrupts during resume\n"); return ret; } /* * follow recommended programming flows to avoid * timeouts when gsync is enabled */ if (bus->multi_link) intel_shim_sync_arm(sdw); /* * Re-initialize the IP since it was powered-off */ sdw_cdns_init(&sdw->cdns); } else { ret = sdw_cdns_enable_interrupt(cdns, true); if (ret < 0) { dev_err(dev, "cannot enable interrupts during resume\n"); return ret; } } ret = sdw_cdns_clock_restart(cdns, !clock_stop0); if (ret < 0) { dev_err(dev, "unable to restart clock during resume\n"); goto err_interrupt; } if (!clock_stop0) { ret = sdw_cdns_exit_reset(cdns); if (ret < 0) { dev_err(dev, "unable to exit bus reset sequence during resume\n"); goto err_interrupt; } if (bus->multi_link) { ret = intel_shim_sync_go(sdw); if (ret < 0) { dev_err(sdw->cdns.dev, "sync go failed during resume\n"); goto err_interrupt; } } } sdw_cdns_check_self_clearing_bits(cdns, __func__, true, INTEL_MASTER_RESET_ITERATIONS); return 0; err_interrupt: sdw_cdns_enable_interrupt(cdns, false); return ret; } static void intel_check_clock_stop(struct sdw_intel *sdw) { struct device *dev = sdw->cdns.dev; bool clock_stop0; clock_stop0 = sdw_cdns_is_clock_stop(&sdw->cdns); if (!clock_stop0) dev_err(dev, "%s: invalid configuration, clock was not stopped\n", __func__); } static int intel_start_bus_after_clock_stop(struct sdw_intel *sdw) { struct device *dev = sdw->cdns.dev; struct sdw_cdns *cdns = &sdw->cdns; int ret; ret = sdw_cdns_enable_interrupt(cdns, true); if (ret < 0) { dev_err(dev, "%s: cannot enable interrupts: %d\n", __func__, ret); return ret; } ret = sdw_cdns_clock_restart(cdns, false); if (ret < 0) { dev_err(dev, "%s: unable to restart clock: %d\n", __func__, ret); sdw_cdns_enable_interrupt(cdns, false); return ret; } sdw_cdns_check_self_clearing_bits(cdns, "intel_resume_runtime no_quirks", true, INTEL_MASTER_RESET_ITERATIONS); return 0; } static int intel_stop_bus(struct sdw_intel *sdw, bool clock_stop) { struct device *dev = sdw->cdns.dev; struct sdw_cdns *cdns = &sdw->cdns; bool wake_enable = false; int ret; if (clock_stop) { ret = sdw_cdns_clock_stop(cdns, true); if (ret < 0) dev_err(dev, "%s: cannot stop clock: %d\n", __func__, ret); else wake_enable = true; } ret = sdw_cdns_enable_interrupt(cdns, false); if (ret < 0) { dev_err(dev, "%s: cannot disable interrupts: %d\n", __func__, ret); return ret; } ret = intel_link_power_down(sdw); if (ret) { dev_err(dev, "%s: Link power down failed: %d\n", __func__, ret); return ret; } intel_shim_wake(sdw, wake_enable); return 0; } const struct sdw_intel_hw_ops sdw_intel_cnl_hw_ops = { .debugfs_init = intel_debugfs_init, .debugfs_exit = intel_debugfs_exit, .register_dai = intel_register_dai, .check_clock_stop = intel_check_clock_stop, .start_bus = intel_start_bus, .start_bus_after_reset = intel_start_bus_after_reset, .start_bus_after_clock_stop = intel_start_bus_after_clock_stop, .stop_bus = intel_stop_bus, .link_power_up = intel_link_power_up, .link_power_down = intel_link_power_down, .shim_check_wake = intel_shim_check_wake, .shim_wake = intel_shim_wake, .pre_bank_switch = intel_pre_bank_switch, .post_bank_switch = intel_post_bank_switch, }; EXPORT_SYMBOL_NS(sdw_intel_cnl_hw_ops, SOUNDWIRE_INTEL);
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