// SPDX-License-Identifier: GPL-2.0-only /* * skl-nhlt.c - Intel SKL Platform NHLT parsing * * Copyright (C) 2015 Intel Corp * Author: Sanjiv Kumar * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ */ #include #include #include "skl.h" #include "skl-i2s.h" static struct nhlt_specific_cfg *skl_get_specific_cfg( struct device *dev, struct nhlt_fmt *fmt, u8 no_ch, u32 rate, u16 bps, u8 linktype) { struct nhlt_specific_cfg *sp_config; struct wav_fmt *wfmt; struct nhlt_fmt_cfg *fmt_config = fmt->fmt_config; int i; dev_dbg(dev, "Format count =%d\n", fmt->fmt_count); for (i = 0; i < fmt->fmt_count; i++) { wfmt = &fmt_config->fmt_ext.fmt; dev_dbg(dev, "ch=%d fmt=%d s_rate=%d\n", wfmt->channels, wfmt->bits_per_sample, wfmt->samples_per_sec); if (wfmt->channels == no_ch && wfmt->bits_per_sample == bps) { /* * if link type is dmic ignore rate check as the blob is * generic for all rates */ sp_config = &fmt_config->config; if (linktype == NHLT_LINK_DMIC) return sp_config; if (wfmt->samples_per_sec == rate) return sp_config; } fmt_config = (struct nhlt_fmt_cfg *)(fmt_config->config.caps + fmt_config->config.size); } return NULL; } static void dump_config(struct device *dev, u32 instance_id, u8 linktype, u8 s_fmt, u8 num_channels, u32 s_rate, u8 dirn, u16 bps) { dev_dbg(dev, "Input configuration\n"); dev_dbg(dev, "ch=%d fmt=%d s_rate=%d\n", num_channels, s_fmt, s_rate); dev_dbg(dev, "vbus_id=%d link_type=%d\n", instance_id, linktype); dev_dbg(dev, "bits_per_sample=%d\n", bps); } static bool skl_check_ep_match(struct device *dev, struct nhlt_endpoint *epnt, u32 instance_id, u8 link_type, u8 dirn, u8 dev_type) { dev_dbg(dev, "vbus_id=%d link_type=%d dir=%d dev_type = %d\n", epnt->virtual_bus_id, epnt->linktype, epnt->direction, epnt->device_type); if ((epnt->virtual_bus_id == instance_id) && (epnt->linktype == link_type) && (epnt->direction == dirn)) { /* do not check dev_type for DMIC link type */ if (epnt->linktype == NHLT_LINK_DMIC) return true; if (epnt->device_type == dev_type) return true; } return false; } struct nhlt_specific_cfg *skl_get_ep_blob(struct skl_dev *skl, u32 instance, u8 link_type, u8 s_fmt, u8 num_ch, u32 s_rate, u8 dirn, u8 dev_type) { struct nhlt_fmt *fmt; struct nhlt_endpoint *epnt; struct hdac_bus *bus = skl_to_bus(skl); struct device *dev = bus->dev; struct nhlt_specific_cfg *sp_config; struct nhlt_acpi_table *nhlt = skl->nhlt; u16 bps = (s_fmt == 16) ? 16 : 32; u8 j; dump_config(dev, instance, link_type, s_fmt, num_ch, s_rate, dirn, bps); epnt = (struct nhlt_endpoint *)nhlt->desc; dev_dbg(dev, "endpoint count =%d\n", nhlt->endpoint_count); for (j = 0; j < nhlt->endpoint_count; j++) { if (skl_check_ep_match(dev, epnt, instance, link_type, dirn, dev_type)) { fmt = (struct nhlt_fmt *)(epnt->config.caps + epnt->config.size); sp_config = skl_get_specific_cfg(dev, fmt, num_ch, s_rate, bps, link_type); if (sp_config) return sp_config; } epnt = (struct nhlt_endpoint *)((u8 *)epnt + epnt->length); } return NULL; } static void skl_nhlt_trim_space(char *trim) { char *s = trim; int cnt; int i; cnt = 0; for (i = 0; s[i]; i++) { if (!isspace(s[i])) s[cnt++] = s[i]; } s[cnt] = '\0'; } int skl_nhlt_update_topology_bin(struct skl_dev *skl) { struct nhlt_acpi_table *nhlt = (struct nhlt_acpi_table *)skl->nhlt; struct hdac_bus *bus = skl_to_bus(skl); struct device *dev = bus->dev; dev_dbg(dev, "oem_id %.6s, oem_table_id %.8s oem_revision %d\n", nhlt->header.oem_id, nhlt->header.oem_table_id, nhlt->header.oem_revision); snprintf(skl->tplg_name, sizeof(skl->tplg_name), "%x-%.6s-%.8s-%d%s", skl->pci_id, nhlt->header.oem_id, nhlt->header.oem_table_id, nhlt->header.oem_revision, "-tplg.bin"); skl_nhlt_trim_space(skl->tplg_name); return 0; } static ssize_t skl_nhlt_platform_id_show(struct device *dev, struct device_attribute *attr, char *buf) { struct pci_dev *pci = to_pci_dev(dev); struct hdac_bus *bus = pci_get_drvdata(pci); struct skl_dev *skl = bus_to_skl(bus); struct nhlt_acpi_table *nhlt = (struct nhlt_acpi_table *)skl->nhlt; char platform_id[32]; sprintf(platform_id, "%x-%.6s-%.8s-%d", skl->pci_id, nhlt->header.oem_id, nhlt->header.oem_table_id, nhlt->header.oem_revision); skl_nhlt_trim_space(platform_id); return sprintf(buf, "%s\n", platform_id); } static DEVICE_ATTR(platform_id, 0444, skl_nhlt_platform_id_show, NULL); int skl_nhlt_create_sysfs(struct skl_dev *skl) { struct device *dev = &skl->pci->dev; if (sysfs_create_file(&dev->kobj, &dev_attr_platform_id.attr)) dev_warn(dev, "Error creating sysfs entry\n"); return 0; } void skl_nhlt_remove_sysfs(struct skl_dev *skl) { struct device *dev = &skl->pci->dev; if (skl->nhlt) sysfs_remove_file(&dev->kobj, &dev_attr_platform_id.attr); } /* * Queries NHLT for all the fmt configuration for a particular endpoint and * stores all possible rates supported in a rate table for the corresponding * sclk/sclkfs. */ static void skl_get_ssp_clks(struct skl_dev *skl, struct skl_ssp_clk *ssp_clks, struct nhlt_fmt *fmt, u8 id) { struct skl_i2s_config_blob_ext *i2s_config_ext; struct skl_i2s_config_blob_legacy *i2s_config; struct skl_clk_parent_src *parent; struct skl_ssp_clk *sclk, *sclkfs; struct nhlt_fmt_cfg *fmt_cfg; struct wav_fmt_ext *wav_fmt; unsigned long rate; int rate_index = 0; u16 channels, bps; u8 clk_src; int i, j; u32 fs; sclk = &ssp_clks[SKL_SCLK_OFS]; sclkfs = &ssp_clks[SKL_SCLKFS_OFS]; if (fmt->fmt_count == 0) return; fmt_cfg = (struct nhlt_fmt_cfg *)fmt->fmt_config; for (i = 0; i < fmt->fmt_count; i++) { struct nhlt_fmt_cfg *saved_fmt_cfg = fmt_cfg; bool present = false; wav_fmt = &saved_fmt_cfg->fmt_ext; channels = wav_fmt->fmt.channels; bps = wav_fmt->fmt.bits_per_sample; fs = wav_fmt->fmt.samples_per_sec; /* * In case of TDM configuration on a ssp, there can * be more than one blob in which channel masks are * different for each usecase for a specific rate and bps. * But the sclk rate will be generated for the total * number of channels used for that endpoint. * * So for the given fs and bps, choose blob which has * the superset of all channels for that endpoint and * derive the rate. */ for (j = i; j < fmt->fmt_count; j++) { struct nhlt_fmt_cfg *tmp_fmt_cfg = fmt_cfg; wav_fmt = &tmp_fmt_cfg->fmt_ext; if ((fs == wav_fmt->fmt.samples_per_sec) && (bps == wav_fmt->fmt.bits_per_sample)) { channels = max_t(u16, channels, wav_fmt->fmt.channels); saved_fmt_cfg = tmp_fmt_cfg; } /* Move to the next nhlt_fmt_cfg */ tmp_fmt_cfg = (struct nhlt_fmt_cfg *)(tmp_fmt_cfg->config.caps + tmp_fmt_cfg->config.size); } rate = channels * bps * fs; /* check if the rate is added already to the given SSP's sclk */ for (j = 0; (j < SKL_MAX_CLK_RATES) && (sclk[id].rate_cfg[j].rate != 0); j++) { if (sclk[id].rate_cfg[j].rate == rate) { present = true; break; } } /* Fill rate and parent for sclk/sclkfs */ if (!present) { struct nhlt_fmt_cfg *first_fmt_cfg; first_fmt_cfg = (struct nhlt_fmt_cfg *)fmt->fmt_config; i2s_config_ext = (struct skl_i2s_config_blob_ext *) first_fmt_cfg->config.caps; /* MCLK Divider Source Select */ if (is_legacy_blob(i2s_config_ext->hdr.sig)) { i2s_config = ext_to_legacy_blob(i2s_config_ext); clk_src = get_clk_src(i2s_config->mclk, SKL_MNDSS_DIV_CLK_SRC_MASK); } else { clk_src = get_clk_src(i2s_config_ext->mclk, SKL_MNDSS_DIV_CLK_SRC_MASK); } parent = skl_get_parent_clk(clk_src); /* Move to the next nhlt_fmt_cfg */ fmt_cfg = (struct nhlt_fmt_cfg *)(fmt_cfg->config.caps + fmt_cfg->config.size); /* * Do not copy the config data if there is no parent * clock available for this clock source select */ if (!parent) continue; sclk[id].rate_cfg[rate_index].rate = rate; sclk[id].rate_cfg[rate_index].config = saved_fmt_cfg; sclkfs[id].rate_cfg[rate_index].rate = rate; sclkfs[id].rate_cfg[rate_index].config = saved_fmt_cfg; sclk[id].parent_name = parent->name; sclkfs[id].parent_name = parent->name; rate_index++; } } } static void skl_get_mclk(struct skl_dev *skl, struct skl_ssp_clk *mclk, struct nhlt_fmt *fmt, u8 id) { struct skl_i2s_config_blob_ext *i2s_config_ext; struct skl_i2s_config_blob_legacy *i2s_config; struct nhlt_fmt_cfg *fmt_cfg; struct skl_clk_parent_src *parent; u32 clkdiv, div_ratio; u8 clk_src; fmt_cfg = (struct nhlt_fmt_cfg *)fmt->fmt_config; i2s_config_ext = (struct skl_i2s_config_blob_ext *)fmt_cfg->config.caps; /* MCLK Divider Source Select and divider */ if (is_legacy_blob(i2s_config_ext->hdr.sig)) { i2s_config = ext_to_legacy_blob(i2s_config_ext); clk_src = get_clk_src(i2s_config->mclk, SKL_MCLK_DIV_CLK_SRC_MASK); clkdiv = i2s_config->mclk.mdivr & SKL_MCLK_DIV_RATIO_MASK; } else { clk_src = get_clk_src(i2s_config_ext->mclk, SKL_MCLK_DIV_CLK_SRC_MASK); clkdiv = i2s_config_ext->mclk.mdivr[0] & SKL_MCLK_DIV_RATIO_MASK; } /* bypass divider */ div_ratio = 1; if (clkdiv != SKL_MCLK_DIV_RATIO_MASK) /* Divider is 2 + clkdiv */ div_ratio = clkdiv + 2; /* Calculate MCLK rate from source using div value */ parent = skl_get_parent_clk(clk_src); if (!parent) return; mclk[id].rate_cfg[0].rate = parent->rate/div_ratio; mclk[id].rate_cfg[0].config = fmt_cfg; mclk[id].parent_name = parent->name; } void skl_get_clks(struct skl_dev *skl, struct skl_ssp_clk *ssp_clks) { struct nhlt_acpi_table *nhlt = (struct nhlt_acpi_table *)skl->nhlt; struct nhlt_endpoint *epnt; struct nhlt_fmt *fmt; int i; u8 id; epnt = (struct nhlt_endpoint *)nhlt->desc; for (i = 0; i < nhlt->endpoint_count; i++) { if (epnt->linktype == NHLT_LINK_SSP) { id = epnt->virtual_bus_id; fmt = (struct nhlt_fmt *)(epnt->config.caps + epnt->config.size); skl_get_ssp_clks(skl, ssp_clks, fmt, id); skl_get_mclk(skl, ssp_clks, fmt, id); } epnt = (struct nhlt_endpoint *)((u8 *)epnt + epnt->length); } }