/* Copyright (c) 2012-2015, 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 #include #include #include #include #include #include #include #include "mdss.h" #include "mdss_panel.h" #include "mdss_dsi.h" #include "mdss_debug.h" #include "mdss_dsi_phy.h" #include "mdss_dba_utils.h" #define XO_CLK_RATE 19200000 #define CMDLINE_DSI_CTL_NUM_STRING_LEN 2 /* Master structure to hold all the information about the DSI/panel */ static struct mdss_dsi_data *mdss_dsi_res; #define DSI_DISABLE_PC_LATENCY 100 #define DSI_ENABLE_PC_LATENCY PM_QOS_DEFAULT_VALUE static struct pm_qos_request mdss_dsi_pm_qos_request; static void mdss_dsi_pm_qos_add_request(void) { pr_debug("%s: add request", __func__); pm_qos_add_request(&mdss_dsi_pm_qos_request, PM_QOS_CPU_DMA_LATENCY, PM_QOS_DEFAULT_VALUE); } static void mdss_dsi_pm_qos_remove_request(void) { pr_debug("%s: remove request", __func__); pm_qos_remove_request(&mdss_dsi_pm_qos_request); } static void mdss_dsi_pm_qos_update_request(int val) { pr_debug("%s: update request %d", __func__, val); pm_qos_update_request(&mdss_dsi_pm_qos_request, val); } static int mdss_dsi_pinctrl_set_state(struct mdss_dsi_ctrl_pdata *ctrl_pdata, bool active); static struct mdss_dsi_ctrl_pdata *mdss_dsi_get_ctrl(u32 ctrl_id) { if (ctrl_id >= DSI_CTRL_MAX || !mdss_dsi_res) return NULL; return mdss_dsi_res->ctrl_pdata[ctrl_id]; } static void mdss_dsi_config_clk_src(struct platform_device *pdev) { struct mdss_dsi_data *dsi_res = platform_get_drvdata(pdev); struct dsi_shared_data *sdata = dsi_res->shared_data; if (!sdata->ext_byte0_clk || !sdata->ext_byte1_clk || !sdata->ext_pixel0_clk || !sdata->ext_pixel1_clk) { pr_debug("%s: config_clk_src not needed\n", __func__); return; } if (mdss_dsi_is_pll_src_default(sdata)) { /* * Default Mapping: * 1. dual-dsi/single-dsi: * DSI0 <--> PLL0 * DSI1 <--> PLL1 * 2. split-dsi: * DSI0 <--> PLL0 * DSI1 <--> PLL0 */ sdata->byte0_parent = sdata->ext_byte0_clk; sdata->pixel0_parent = sdata->ext_pixel0_clk; if (mdss_dsi_is_hw_config_split(sdata)) { sdata->byte1_parent = sdata->byte0_parent; sdata->pixel1_parent = sdata->pixel0_parent; } else { sdata->byte1_parent = sdata->ext_byte1_clk; sdata->pixel1_parent = sdata->ext_pixel1_clk; } pr_debug("%s: default: DSI0 <--> PLL0, DSI1 <--> %s", __func__, mdss_dsi_is_hw_config_split(sdata) ? "PLL0" : "PLL1"); } else { /* * For split-dsi and single-dsi use cases, map the PLL source * based on the pll source configuration. It is possible that * for split-dsi case, the only supported config is to source * the clocks from PLL0. This is not explictly checked here as * it should have been already enforced when validating the * board configuration. */ if (mdss_dsi_is_pll_src_pll0(sdata)) { pr_debug("%s: single source: PLL0", __func__); sdata->byte0_parent = sdata->ext_byte0_clk; sdata->pixel0_parent = sdata->ext_pixel0_clk; } else if (mdss_dsi_is_pll_src_pll1(sdata)) { pr_debug("%s: single source: PLL1", __func__); sdata->byte0_parent = sdata->ext_byte1_clk; sdata->pixel0_parent = sdata->ext_pixel1_clk; } sdata->byte1_parent = sdata->byte0_parent; sdata->pixel1_parent = sdata->pixel0_parent; } return; } static char const *mdss_dsi_get_clk_src(struct mdss_dsi_ctrl_pdata *ctrl) { struct dsi_shared_data *sdata; if (!ctrl) { pr_err("%s: Invalid input data\n", __func__); return "????"; } sdata = ctrl->shared_data; if (mdss_dsi_is_left_ctrl(ctrl)) { if (sdata->byte0_parent == sdata->ext_byte0_clk) return "PLL0"; else return "PLL1"; } else { if (sdata->byte1_parent == sdata->ext_byte0_clk) return "PLL0"; else return "PLL1"; } } static int mdss_dsi_set_clk_src(struct mdss_dsi_ctrl_pdata *ctrl) { int rc; struct dsi_shared_data *sdata; struct clk *byte_parent, *pixel_parent; if (!ctrl) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } sdata = ctrl->shared_data; if (!ctrl->byte_clk_rcg || !ctrl->pixel_clk_rcg) { pr_debug("%s: set_clk_src not needed\n", __func__); return 0; } if (mdss_dsi_is_left_ctrl(ctrl)) { byte_parent = sdata->byte0_parent; pixel_parent = sdata->pixel0_parent; } else { byte_parent = sdata->byte1_parent; pixel_parent = sdata->pixel1_parent; } rc = clk_set_parent(ctrl->byte_clk_rcg, byte_parent); if (rc) { pr_err("%s: failed to set parent for byte clk for ctrl%d. rc=%d\n", __func__, ctrl->ndx, rc); goto error; } rc = clk_set_parent(ctrl->pixel_clk_rcg, pixel_parent); if (rc) { pr_err("%s: failed to set parent for pixel clk for ctrl%d. rc=%d\n", __func__, ctrl->ndx, rc); goto error; } pr_debug("%s: ctrl%d clock source set to %s", __func__, ctrl->ndx, mdss_dsi_get_clk_src(ctrl)); error: return rc; } static int mdss_dsi_regulator_init(struct platform_device *pdev, struct dsi_shared_data *sdata) { int rc = 0, i = 0, j = 0; if (!pdev || !sdata) { pr_err("%s: invalid input\n", __func__); return -EINVAL; } for (i = DSI_CORE_PM; !rc && (i < DSI_MAX_PM); i++) { rc = msm_dss_config_vreg(&pdev->dev, sdata->power_data[i].vreg_config, sdata->power_data[i].num_vreg, 1); if (rc) { pr_err("%s: failed to init vregs for %s\n", __func__, __mdss_dsi_pm_name(i)); for (j = i-1; j >= DSI_CORE_PM; j--) { msm_dss_config_vreg(&pdev->dev, sdata->power_data[j].vreg_config, sdata->power_data[j].num_vreg, 0); } } } return rc; } static int mdss_dsi_panel_power_off(struct mdss_panel_data *pdata) { int ret = 0; struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; if (pdata == NULL) { pr_err("%s: Invalid input data\n", __func__); ret = -EINVAL; goto end; } ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); ret = mdss_dsi_panel_reset(pdata, 0); if (ret) { pr_warn("%s: Panel reset failed. rc=%d\n", __func__, ret); ret = 0; } if (mdss_dsi_pinctrl_set_state(ctrl_pdata, false)) pr_debug("reset disable: pinctrl not enabled\n"); ret = msm_dss_enable_vreg( ctrl_pdata->panel_power_data.vreg_config, ctrl_pdata->panel_power_data.num_vreg, 0); if (ret) pr_err("%s: failed to disable vregs for %s\n", __func__, __mdss_dsi_pm_name(DSI_PANEL_PM)); end: return ret; } static int mdss_dsi_panel_power_on(struct mdss_panel_data *pdata) { int ret = 0; struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; if (pdata == NULL) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); ret = msm_dss_enable_vreg( ctrl_pdata->panel_power_data.vreg_config, ctrl_pdata->panel_power_data.num_vreg, 1); if (ret) { pr_err("%s: failed to enable vregs for %s\n", __func__, __mdss_dsi_pm_name(DSI_PANEL_PM)); return ret; } /* * If continuous splash screen feature is enabled, then we need to * request all the GPIOs that have already been configured in the * bootloader. This needs to be done irresepective of whether * the lp11_init flag is set or not. */ if (pdata->panel_info.cont_splash_enabled || !pdata->panel_info.mipi.lp11_init) { if (mdss_dsi_pinctrl_set_state(ctrl_pdata, true)) pr_debug("reset enable: pinctrl not enabled\n"); ret = mdss_dsi_panel_reset(pdata, 1); if (ret) pr_err("%s: Panel reset failed. rc=%d\n", __func__, ret); } return ret; } static int mdss_dsi_panel_power_lp(struct mdss_panel_data *pdata, int enable) { /* Panel power control when entering/exiting lp mode */ return 0; } static int mdss_dsi_panel_power_ctrl(struct mdss_panel_data *pdata, int power_state) { int ret; struct mdss_panel_info *pinfo; if (pdata == NULL) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } pinfo = &pdata->panel_info; pr_debug("%s: cur_power_state=%d req_power_state=%d\n", __func__, pinfo->panel_power_state, power_state); if (pinfo->panel_power_state == power_state) { pr_debug("%s: no change needed\n", __func__); return 0; } /* * If a dynamic mode switch is pending, the regulators should not * be turned off or on. */ if (pdata->panel_info.dynamic_switch_pending) return 0; switch (power_state) { case MDSS_PANEL_POWER_OFF: ret = mdss_dsi_panel_power_off(pdata); break; case MDSS_PANEL_POWER_ON: if (mdss_dsi_is_panel_on_lp(pdata)) ret = mdss_dsi_panel_power_lp(pdata, false); else ret = mdss_dsi_panel_power_on(pdata); break; case MDSS_PANEL_POWER_LP1: case MDSS_PANEL_POWER_LP2: ret = mdss_dsi_panel_power_lp(pdata, true); break; default: pr_err("%s: unknown panel power state requested (%d)\n", __func__, power_state); ret = -EINVAL; } if (!ret) pinfo->panel_power_state = power_state; return ret; } static void mdss_dsi_put_dt_vreg_data(struct device *dev, struct dss_module_power *module_power) { if (!module_power) { pr_err("%s: invalid input\n", __func__); return; } if (module_power->vreg_config) { devm_kfree(dev, module_power->vreg_config); module_power->vreg_config = NULL; } module_power->num_vreg = 0; } static int mdss_dsi_get_dt_vreg_data(struct device *dev, struct device_node *of_node, struct dss_module_power *mp, enum dsi_pm_type module) { int i = 0, rc = 0; u32 tmp = 0; struct device_node *supply_node = NULL; const char *pm_supply_name = NULL; struct device_node *supply_root_node = NULL; if (!dev || !mp) { pr_err("%s: invalid input\n", __func__); rc = -EINVAL; return rc; } mp->num_vreg = 0; pm_supply_name = __mdss_dsi_pm_supply_node_name(module); supply_root_node = of_get_child_by_name(of_node, pm_supply_name); if (!supply_root_node) { /* * Try to get the root node for panel power supply using * of_parse_phandle() API if of_get_child_by_name() API fails. */ supply_root_node = of_parse_phandle(of_node, pm_supply_name, 0); if (!supply_root_node) { pr_err("no supply entry present: %s\n", pm_supply_name); goto novreg; } } for_each_child_of_node(supply_root_node, supply_node) { mp->num_vreg++; } if (mp->num_vreg == 0) { pr_debug("%s: no vreg\n", __func__); goto novreg; } else { pr_debug("%s: vreg found. count=%d\n", __func__, mp->num_vreg); } mp->vreg_config = devm_kzalloc(dev, sizeof(struct dss_vreg) * mp->num_vreg, GFP_KERNEL); if (!mp->vreg_config) { pr_err("%s: can't alloc vreg mem\n", __func__); rc = -ENOMEM; goto error; } for_each_child_of_node(supply_root_node, supply_node) { const char *st = NULL; /* vreg-name */ rc = of_property_read_string(supply_node, "qcom,supply-name", &st); if (rc) { pr_err("%s: error reading name. rc=%d\n", __func__, rc); goto error; } snprintf(mp->vreg_config[i].vreg_name, ARRAY_SIZE((mp->vreg_config[i].vreg_name)), "%s", st); /* vreg-min-voltage */ rc = of_property_read_u32(supply_node, "qcom,supply-min-voltage", &tmp); if (rc) { pr_err("%s: error reading min volt. rc=%d\n", __func__, rc); goto error; } mp->vreg_config[i].min_voltage = tmp; /* vreg-max-voltage */ rc = of_property_read_u32(supply_node, "qcom,supply-max-voltage", &tmp); if (rc) { pr_err("%s: error reading max volt. rc=%d\n", __func__, rc); goto error; } mp->vreg_config[i].max_voltage = tmp; /* enable-load */ rc = of_property_read_u32(supply_node, "qcom,supply-enable-load", &tmp); if (rc) { pr_err("%s: error reading enable load. rc=%d\n", __func__, rc); goto error; } mp->vreg_config[i].enable_load = tmp; /* disable-load */ rc = of_property_read_u32(supply_node, "qcom,supply-disable-load", &tmp); if (rc) { pr_err("%s: error reading disable load. rc=%d\n", __func__, rc); goto error; } mp->vreg_config[i].disable_load = tmp; /* pre-sleep */ rc = of_property_read_u32(supply_node, "qcom,supply-pre-on-sleep", &tmp); if (rc) { pr_debug("%s: error reading supply pre sleep value. rc=%d\n", __func__, rc); rc = 0; } else { mp->vreg_config[i].pre_on_sleep = tmp; } rc = of_property_read_u32(supply_node, "qcom,supply-pre-off-sleep", &tmp); if (rc) { pr_debug("%s: error reading supply pre sleep value. rc=%d\n", __func__, rc); rc = 0; } else { mp->vreg_config[i].pre_off_sleep = tmp; } /* post-sleep */ rc = of_property_read_u32(supply_node, "qcom,supply-post-on-sleep", &tmp); if (rc) { pr_debug("%s: error reading supply post sleep value. rc=%d\n", __func__, rc); rc = 0; } else { mp->vreg_config[i].post_on_sleep = tmp; } rc = of_property_read_u32(supply_node, "qcom,supply-post-off-sleep", &tmp); if (rc) { pr_debug("%s: error reading supply post sleep value. rc=%d\n", __func__, rc); rc = 0; } else { mp->vreg_config[i].post_off_sleep = tmp; } pr_debug("%s: %s min=%d, max=%d, enable=%d, disable=%d, preonsleep=%d, postonsleep=%d, preoffsleep=%d, postoffsleep=%d\n", __func__, mp->vreg_config[i].vreg_name, mp->vreg_config[i].min_voltage, mp->vreg_config[i].max_voltage, mp->vreg_config[i].enable_load, mp->vreg_config[i].disable_load, mp->vreg_config[i].pre_on_sleep, mp->vreg_config[i].post_on_sleep, mp->vreg_config[i].pre_off_sleep, mp->vreg_config[i].post_off_sleep ); ++i; } return rc; error: if (mp->vreg_config) { devm_kfree(dev, mp->vreg_config); mp->vreg_config = NULL; } novreg: mp->num_vreg = 0; return rc; } static int mdss_dsi_get_panel_cfg(char *panel_cfg, struct mdss_dsi_ctrl_pdata *ctrl) { int rc; struct mdss_panel_cfg *pan_cfg = NULL; if (!panel_cfg) return MDSS_PANEL_INTF_INVALID; pan_cfg = ctrl->mdss_util->panel_intf_type(MDSS_PANEL_INTF_DSI); if (IS_ERR(pan_cfg)) { return PTR_ERR(pan_cfg); } else if (!pan_cfg) { panel_cfg[0] = 0; return 0; } pr_debug("%s:%d: cfg:[%s]\n", __func__, __LINE__, pan_cfg->arg_cfg); rc = strlcpy(panel_cfg, pan_cfg->arg_cfg, sizeof(pan_cfg->arg_cfg)); return rc; } struct buf_data { char *buf; /* cmd buf */ int blen; /* cmd buf length */ char *string_buf; /* cmd buf as string, 3 bytes per number */ int sblen; /* string buffer length */ int sync_flag; }; struct mdss_dsi_debugfs_info { struct dentry *root; struct mdss_dsi_ctrl_pdata ctrl_pdata; struct buf_data on_cmd; struct buf_data off_cmd; u32 override_flag; }; static int mdss_dsi_cmd_state_open(struct inode *inode, struct file *file) { /* non-seekable */ file->private_data = inode->i_private; return nonseekable_open(inode, file); } static ssize_t mdss_dsi_cmd_state_read(struct file *file, char __user *buf, size_t count, loff_t *ppos) { int *link_state = file->private_data; char buffer[32]; int blen = 0; if (*ppos) return 0; if ((*link_state) == DSI_HS_MODE) blen = snprintf(buffer, sizeof(buffer), "dsi_hs_mode\n"); else blen = snprintf(buffer, sizeof(buffer), "dsi_lp_mode\n"); if (blen < 0) return 0; if (copy_to_user(buf, buffer, blen)) return -EFAULT; *ppos += blen; return blen; } static ssize_t mdss_dsi_cmd_state_write(struct file *file, const char __user *p, size_t count, loff_t *ppos) { int *link_state = file->private_data; char *input; input = kmalloc(count, GFP_KERNEL); if (!input) { pr_err("%s: Failed to allocate memory\n", __func__); return -ENOMEM; } if (copy_from_user(input, p, count)) return -EFAULT; input[count-1] = '\0'; if (strnstr(input, "dsi_hs_mode", strlen("dsi_hs_mode"))) *link_state = DSI_HS_MODE; else *link_state = DSI_LP_MODE; kfree(input); return count; } static const struct file_operations mdss_dsi_cmd_state_fop = { .open = mdss_dsi_cmd_state_open, .read = mdss_dsi_cmd_state_read, .write = mdss_dsi_cmd_state_write, }; static int mdss_dsi_cmd_open(struct inode *inode, struct file *file) { /* non-seekable */ file->private_data = inode->i_private; return nonseekable_open(inode, file); } static ssize_t mdss_dsi_cmd_read(struct file *file, char __user *buf, size_t count, loff_t *ppos) { struct buf_data *pcmds = file->private_data; char *bp; ssize_t ret = 0; if (*ppos == 0) { kfree(pcmds->string_buf); pcmds->string_buf = NULL; pcmds->sblen = 0; } if (!pcmds->string_buf) { /* * Buffer size is the sum of cmd length (3 bytes per number) * with NULL terminater */ int bsize = ((pcmds->blen)*3 + 1); int blen = 0; char *buffer; buffer = kmalloc(bsize, GFP_KERNEL); if (!buffer) { pr_err("%s: Failed to allocate memory\n", __func__); return -ENOMEM; } bp = pcmds->buf; while ((blen < (bsize-1)) && (bp < ((pcmds->buf) + (pcmds->blen)))) { struct dsi_ctrl_hdr dchdr = *((struct dsi_ctrl_hdr *)bp); int dhrlen = sizeof(dchdr), dlen; char *tmp = (char *)(&dchdr); dlen = dchdr.dlen; dchdr.dlen = htons(dchdr.dlen); while (dhrlen--) blen += snprintf(buffer+blen, bsize-blen, "%02x ", (*tmp++)); bp += sizeof(dchdr); while (dlen--) blen += snprintf(buffer+blen, bsize-blen, "%02x ", (*bp++)); buffer[blen-1] = '\n'; } buffer[blen] = '\0'; pcmds->string_buf = buffer; pcmds->sblen = blen; } /* * The max value of count is PAGE_SIZE(4096). * It may need multiple times of reading if string buf is too large */ if (*ppos >= (pcmds->sblen)) { kfree(pcmds->string_buf); pcmds->string_buf = NULL; pcmds->sblen = 0; return 0; /* the end */ } ret = simple_read_from_buffer(buf, count, ppos, pcmds->string_buf, pcmds->sblen); return ret; } static ssize_t mdss_dsi_cmd_write(struct file *file, const char __user *p, size_t count, loff_t *ppos) { struct buf_data *pcmds = file->private_data; ssize_t ret = 0; int blen = 0; char *string_buf; if (*ppos == 0) { kfree(pcmds->string_buf); pcmds->string_buf = NULL; pcmds->sblen = 0; } /* Allocate memory for the received string */ blen = count + (pcmds->sblen); string_buf = krealloc(pcmds->string_buf, blen + 1, GFP_KERNEL); if (!string_buf) { pr_err("%s: Failed to allocate memory\n", __func__); return -ENOMEM; } /* Writing in batches is possible */ ret = simple_write_to_buffer(string_buf, blen, ppos, p, count); string_buf[blen] = '\0'; pcmds->string_buf = string_buf; pcmds->sblen = blen; return ret; } static int mdss_dsi_cmd_flush(struct file *file, fl_owner_t id) { struct buf_data *pcmds = file->private_data; int blen, len, i; char *buf, *bufp, *bp; struct dsi_ctrl_hdr *dchdr; if (!pcmds->string_buf) return 0; /* * Allocate memory for command buffer * 3 bytes per number, and 2 bytes for the last one */ blen = ((pcmds->sblen) + 2) / 3; buf = kzalloc(blen, GFP_KERNEL); if (!buf) { pr_err("%s: Failed to allocate memory\n", __func__); kfree(pcmds->string_buf); pcmds->string_buf = NULL; pcmds->sblen = 0; return -ENOMEM; } /* Translate the input string to command array */ bufp = pcmds->string_buf; for (i = 0; i < blen; i++) { uint32_t value = 0; int step = 0; if (sscanf(bufp, "%02x%n", &value, &step) > 0) { *(buf+i) = (char)value; bufp += step; } } /* Scan dcs commands */ bp = buf; len = blen; while (len >= sizeof(*dchdr)) { dchdr = (struct dsi_ctrl_hdr *)bp; dchdr->dlen = ntohs(dchdr->dlen); if (dchdr->dlen > len) { pr_err("%s: dtsi cmd=%x error, len=%d\n", __func__, dchdr->dtype, dchdr->dlen); kfree(buf); return -EINVAL; } bp += sizeof(*dchdr); len -= sizeof(*dchdr); bp += dchdr->dlen; len -= dchdr->dlen; } if (len != 0) { pr_err("%s: dcs_cmd=%x len=%d error!\n", __func__, bp[0], len); kfree(buf); return -EINVAL; } if (pcmds->sync_flag) { pcmds->buf = buf; pcmds->blen = blen; pcmds->sync_flag = 0; } else { kfree(pcmds->buf); pcmds->buf = buf; pcmds->blen = blen; } return 0; } static const struct file_operations mdss_dsi_cmd_fop = { .open = mdss_dsi_cmd_open, .read = mdss_dsi_cmd_read, .write = mdss_dsi_cmd_write, .flush = mdss_dsi_cmd_flush, }; struct dentry *dsi_debugfs_create_dcs_cmd(const char *name, umode_t mode, struct dentry *parent, struct buf_data *cmd, struct dsi_panel_cmds ctrl_cmds) { cmd->buf = ctrl_cmds.buf; cmd->blen = ctrl_cmds.blen; cmd->string_buf = NULL; cmd->sblen = 0; cmd->sync_flag = 1; return debugfs_create_file(name, mode, parent, cmd, &mdss_dsi_cmd_fop); } #define DEBUGFS_CREATE_DCS_CMD(name, node, cmd, ctrl_cmd) \ dsi_debugfs_create_dcs_cmd(name, 0644, node, cmd, ctrl_cmd) static int mdss_dsi_debugfs_setup(struct mdss_panel_data *pdata, struct dentry *parent) { struct mdss_dsi_ctrl_pdata *ctrl_pdata, *dfs_ctrl; struct mdss_dsi_debugfs_info *dfs; ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); dfs = kzalloc(sizeof(*dfs), GFP_KERNEL); if (!dfs) { pr_err("%s: No memory to create dsi ctrl debugfs info", __func__); return -ENOMEM; } dfs->root = debugfs_create_dir("dsi_ctrl_pdata", parent); if (IS_ERR_OR_NULL(dfs->root)) { pr_err("%s: debugfs_create_dir dsi fail, error %ld\n", __func__, PTR_ERR(dfs->root)); kfree(dfs); return -ENODEV; } dfs_ctrl = &dfs->ctrl_pdata; debugfs_create_u32("override_flag", 0644, dfs->root, &dfs->override_flag); debugfs_create_bool("cmd_sync_wait_broadcast", 0644, dfs->root, (u32 *)&dfs_ctrl->cmd_sync_wait_broadcast); debugfs_create_bool("cmd_sync_wait_trigger", 0644, dfs->root, (u32 *)&dfs_ctrl->cmd_sync_wait_trigger); debugfs_create_file("dsi_on_cmd_state", 0644, dfs->root, &dfs_ctrl->on_cmds.link_state, &mdss_dsi_cmd_state_fop); debugfs_create_file("dsi_off_cmd_state", 0644, dfs->root, &dfs_ctrl->off_cmds.link_state, &mdss_dsi_cmd_state_fop); DEBUGFS_CREATE_DCS_CMD("dsi_on_cmd", dfs->root, &dfs->on_cmd, ctrl_pdata->on_cmds); DEBUGFS_CREATE_DCS_CMD("dsi_off_cmd", dfs->root, &dfs->off_cmd, ctrl_pdata->off_cmds); debugfs_create_u32("dsi_err_counter", 0644, dfs->root, &dfs_ctrl->err_cont.max_err_index); debugfs_create_u32("dsi_err_time_delta", 0644, dfs->root, &dfs_ctrl->err_cont.err_time_delta); dfs->override_flag = 0; dfs->ctrl_pdata = *ctrl_pdata; ctrl_pdata->debugfs_info = dfs; return 0; } static int mdss_dsi_debugfs_init(struct mdss_dsi_ctrl_pdata *ctrl_pdata) { int rc; struct mdss_panel_data *pdata = &ctrl_pdata->panel_data; struct mdss_panel_info panel_info = pdata->panel_info; rc = mdss_dsi_debugfs_setup(pdata, panel_info.debugfs_info->root); if (rc) { pr_err("%s: Error in initilizing dsi ctrl debugfs\n", __func__); return rc; } pr_debug("%s: Initialized mdss_dsi_debugfs_init\n", __func__); return 0; } static void mdss_dsi_debugfs_cleanup(struct mdss_dsi_ctrl_pdata *ctrl_pdata) { struct mdss_panel_data *pdata = &ctrl_pdata->panel_data; do { struct mdss_dsi_ctrl_pdata *ctrl = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); struct mdss_dsi_debugfs_info *dfs = ctrl->debugfs_info; if (dfs && dfs->root) debugfs_remove_recursive(dfs->root); pdata = pdata->next; } while (pdata); pr_debug("%s: Cleaned up mdss_dsi_debugfs_info\n", __func__); } static int _mdss_dsi_refresh_cmd(struct buf_data *new_cmds, struct dsi_panel_cmds *original_pcmds) { char *bp; int len, cnt, i; struct dsi_ctrl_hdr *dchdr; struct dsi_cmd_desc *cmds; if (new_cmds->sync_flag) return 0; bp = new_cmds->buf; len = new_cmds->blen; cnt = 0; /* Scan dcs commands and get dcs command count */ while (len >= sizeof(*dchdr)) { dchdr = (struct dsi_ctrl_hdr *)bp; if (dchdr->dlen > len) { pr_err("%s: dtsi cmd=%x error, len=%d\n", __func__, dchdr->dtype, dchdr->dlen); return -EINVAL; } bp += sizeof(*dchdr) + dchdr->dlen; len -= sizeof(*dchdr) + dchdr->dlen; cnt++; } if (len != 0) { pr_err("%s: dcs_cmd=%x len=%d error!\n", __func__, bp[0], len); return -EINVAL; } /* Reallocate space for dcs commands */ cmds = kzalloc(cnt * sizeof(struct dsi_cmd_desc), GFP_KERNEL); if (!cmds) { pr_err("%s: Failed to allocate memory\n", __func__); return -ENOMEM; } kfree(original_pcmds->buf); kfree(original_pcmds->cmds); original_pcmds->cmd_cnt = cnt; original_pcmds->cmds = cmds; original_pcmds->buf = new_cmds->buf; original_pcmds->blen = new_cmds->blen; bp = original_pcmds->buf; len = original_pcmds->blen; for (i = 0; i < cnt; i++) { dchdr = (struct dsi_ctrl_hdr *)bp; len -= sizeof(*dchdr); bp += sizeof(*dchdr); original_pcmds->cmds[i].dchdr = *dchdr; original_pcmds->cmds[i].payload = bp; bp += dchdr->dlen; len -= dchdr->dlen; } new_cmds->sync_flag = 1; return 0; } static void mdss_dsi_debugfsinfo_to_dsictrl_info( struct mdss_dsi_ctrl_pdata *ctrl_pdata) { struct mdss_dsi_debugfs_info *dfs = ctrl_pdata->debugfs_info; struct dsi_err_container *dfs_err_cont = &dfs->ctrl_pdata.err_cont; struct dsi_err_container *err_cont = &ctrl_pdata->err_cont; ctrl_pdata->cmd_sync_wait_broadcast = dfs->ctrl_pdata.cmd_sync_wait_broadcast; ctrl_pdata->cmd_sync_wait_trigger = dfs->ctrl_pdata.cmd_sync_wait_trigger; _mdss_dsi_refresh_cmd(&dfs->on_cmd, &ctrl_pdata->on_cmds); _mdss_dsi_refresh_cmd(&dfs->off_cmd, &ctrl_pdata->off_cmds); ctrl_pdata->on_cmds.link_state = dfs->ctrl_pdata.on_cmds.link_state; ctrl_pdata->off_cmds.link_state = dfs->ctrl_pdata.off_cmds.link_state; /* keep error counter between 2 to 10 */ if (dfs_err_cont->max_err_index >= 2 && dfs_err_cont->max_err_index <= MAX_ERR_INDEX) { err_cont->max_err_index = dfs_err_cont->max_err_index; } else { dfs_err_cont->max_err_index = err_cont->max_err_index; pr_warn("resetting the dsi error counter to %d\n", err_cont->max_err_index); } /* keep error duration between 16 ms to 100 seconds */ if (dfs_err_cont->err_time_delta >= 16 && dfs_err_cont->err_time_delta <= 100000) { err_cont->err_time_delta = dfs_err_cont->err_time_delta; } else { dfs_err_cont->err_time_delta = err_cont->err_time_delta; pr_warn("resetting the dsi error time delta to %d ms\n", err_cont->err_time_delta); } } static void mdss_dsi_validate_debugfs_info( struct mdss_dsi_ctrl_pdata *ctrl_pdata) { struct mdss_dsi_debugfs_info *dfs = ctrl_pdata->debugfs_info; if (dfs->override_flag) { pr_debug("%s: Overriding dsi ctrl_pdata with debugfs data\n", __func__); dfs->override_flag = 0; mdss_dsi_debugfsinfo_to_dsictrl_info(ctrl_pdata); } } static int mdss_dsi_off(struct mdss_panel_data *pdata, int power_state) { int ret = 0; struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; struct mdss_panel_info *panel_info = NULL; if (pdata == NULL) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); mutex_lock(&ctrl_pdata->mutex); panel_info = &ctrl_pdata->panel_data.panel_info; pr_debug("%s+: ctrl=%p ndx=%d power_state=%d\n", __func__, ctrl_pdata, ctrl_pdata->ndx, power_state); if (power_state == panel_info->panel_power_state) { pr_debug("%s: No change in power state %d -> %d\n", __func__, panel_info->panel_power_state, power_state); goto end; } if (mdss_panel_is_power_on(power_state)) { pr_debug("%s: dsi_off with panel always on\n", __func__); goto panel_power_ctrl; } /* * Link clocks should be turned off before PHY can be disabled. * For command mode panels, all clocks are turned off prior to reaching * here, so core clocks should be turned on before accessing hardware * registers. For video mode panel, turn off link clocks and then * disable PHY */ if (pdata->panel_info.type == MIPI_CMD_PANEL) mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_CORE_CLK, MDSS_DSI_CLK_ON); else mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_LINK_CLK, MDSS_DSI_CLK_OFF); if (!pdata->panel_info.ulps_suspend_enabled) { /* disable DSI controller */ mdss_dsi_controller_cfg(0, pdata); /* disable DSI phy */ mdss_dsi_phy_disable(ctrl_pdata); } ctrl_pdata->ctrl_state &= ~CTRL_STATE_DSI_ACTIVE; mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_CORE_CLK, MDSS_DSI_CLK_OFF); panel_power_ctrl: ret = mdss_dsi_panel_power_ctrl(pdata, power_state); if (ret) { pr_err("%s: Panel power off failed\n", __func__); goto end; } if (panel_info->dynamic_fps && (panel_info->dfps_update == DFPS_SUSPEND_RESUME_MODE) && (panel_info->new_fps != panel_info->mipi.frame_rate)) panel_info->mipi.frame_rate = panel_info->new_fps; /* Initialize Max Packet size for DCS reads */ ctrl_pdata->cur_max_pkt_size = 0; end: mutex_unlock(&ctrl_pdata->mutex); pr_debug("%s-:\n", __func__); return ret; } int mdss_dsi_switch_mode(struct mdss_panel_data *pdata, int mode) { struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; struct mipi_panel_info *pinfo; bool dsi_ctrl_setup_needed = false; if (!pdata) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } pr_debug("%s, start\n", __func__); pinfo = &pdata->panel_info.mipi; ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); if ((pinfo->dms_mode != DYNAMIC_MODE_RESOLUTION_SWITCH_IMMEDIATE) && (pinfo->dms_mode != DYNAMIC_MODE_SWITCH_IMMEDIATE)) { pr_debug("%s: Dynamic mode switch not enabled.\n", __func__); return -EPERM; } if (mode == MIPI_VIDEO_PANEL) { mode = SWITCH_TO_VIDEO_MODE; } else if (mode == MIPI_CMD_PANEL) { mode = SWITCH_TO_CMD_MODE; } else if (mode == SWITCH_RESOLUTION) { dsi_ctrl_setup_needed = true; pr_debug("Resolution switch mode selected\n"); } else { pr_err("Invalid mode selected, mode=%d\n", mode); return -EINVAL; } mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_ON); if (dsi_ctrl_setup_needed) mdss_dsi_ctrl_setup(ctrl_pdata); ctrl_pdata->switch_mode(pdata, mode); mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_OFF); pr_debug("%s, end\n", __func__); return 0; } static int mdss_dsi_reconfig(struct mdss_panel_data *pdata, int mode) { struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; struct mipi_panel_info *pinfo; if (!pdata) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } pr_debug("%s, start\n", __func__); ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); pinfo = &pdata->panel_info.mipi; if (pinfo->dms_mode == DYNAMIC_MODE_SWITCH_IMMEDIATE) { /* reset DSI */ mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_ON); mdss_dsi_sw_reset(ctrl_pdata, true); mdss_dsi_ctrl_setup(ctrl_pdata); mdss_dsi_controller_cfg(true, pdata); mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_OFF); } pr_debug("%s, end\n", __func__); return 0; } static int mdss_dsi_update_panel_config(struct mdss_dsi_ctrl_pdata *ctrl_pdata, int mode) { int ret = 0; struct mdss_panel_info *pinfo = &(ctrl_pdata->panel_data.panel_info); if (mode == DSI_CMD_MODE) { pinfo->mipi.mode = DSI_CMD_MODE; pinfo->type = MIPI_CMD_PANEL; pinfo->mipi.vsync_enable = 1; pinfo->mipi.hw_vsync_mode = 1; pinfo->partial_update_enabled = pinfo->partial_update_supported; } else { /*video mode*/ pinfo->mipi.mode = DSI_VIDEO_MODE; pinfo->type = MIPI_VIDEO_PANEL; pinfo->mipi.vsync_enable = 0; pinfo->mipi.hw_vsync_mode = 0; pinfo->partial_update_enabled = 0; } ctrl_pdata->panel_mode = pinfo->mipi.mode; mdss_panel_get_dst_fmt(pinfo->bpp, pinfo->mipi.mode, pinfo->mipi.pixel_packing, &(pinfo->mipi.dst_format)); pinfo->cont_splash_enabled = 0; return ret; } int mdss_dsi_on(struct mdss_panel_data *pdata) { int ret = 0; struct mdss_panel_info *pinfo; struct mipi_panel_info *mipi; struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; int cur_power_state; if (pdata == NULL) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); if (ctrl_pdata->debugfs_info) mdss_dsi_validate_debugfs_info(ctrl_pdata); cur_power_state = pdata->panel_info.panel_power_state; pr_debug("%s+: ctrl=%p ndx=%d cur_power_state=%d\n", __func__, ctrl_pdata, ctrl_pdata->ndx, cur_power_state); pinfo = &pdata->panel_info; mipi = &pdata->panel_info.mipi; if (mdss_dsi_is_panel_on_interactive(pdata)) { /* * all interrupts are disabled at LK * for cont_splash case, intr mask bits need * to be restored to allow dcs command be * sent to panel */ mdss_dsi_read_hw_revision(ctrl_pdata); mdss_dsi_read_phy_revision(ctrl_pdata); mdss_dsi_restore_intr_mask(ctrl_pdata); pr_debug("%s: panel already on\n", __func__); goto end; } ret = mdss_dsi_panel_power_ctrl(pdata, MDSS_PANEL_POWER_ON); if (ret) { pr_err("%s:Panel power on failed. rc=%d\n", __func__, ret); goto end; } ret = mdss_dsi_set_clk_src(ctrl_pdata); if (ret) { pr_err("%s: failed to set clk src. rc=%d\n", __func__, ret); goto end; } if (mdss_panel_is_power_on(cur_power_state)) { pr_debug("%s: dsi_on from panel low power state\n", __func__); goto end; } /* * Enable DSI core clocks prior to resetting and initializing DSI * Phy. Phy and ctrl setup need to be done before enabling the link * clocks. */ mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_CORE_CLK, MDSS_DSI_CLK_ON); /* Populate DSI Controller and PHY revision */ mdss_dsi_read_hw_revision(ctrl_pdata); mdss_dsi_read_phy_revision(ctrl_pdata); /* * If ULPS during suspend feature is enabled, then DSI PHY was * left on during suspend. In this case, we do not need to reset/init * PHY. This would have already been done when the CORE clocks are * turned on. However, if cont splash is disabled, the first time DSI * is powered on, phy init needs to be done unconditionally. */ if (!pdata->panel_info.ulps_suspend_enabled || !ctrl_pdata->ulps) { mdss_dsi_phy_sw_reset(ctrl_pdata); mdss_dsi_phy_init(ctrl_pdata); mdss_dsi_ctrl_setup(ctrl_pdata); } ctrl_pdata->ctrl_state |= CTRL_STATE_DSI_ACTIVE; /* DSI link clocks need to be on prior to ctrl sw reset */ mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_LINK_CLK, MDSS_DSI_CLK_ON); mdss_dsi_sw_reset(ctrl_pdata, true); /* * Issue hardware reset line after enabling the DSI clocks and data * data lanes for LP11 init */ if (mipi->lp11_init) { if (mdss_dsi_pinctrl_set_state(ctrl_pdata, true)) pr_debug("reset enable: pinctrl not enabled\n"); mdss_dsi_panel_reset(pdata, 1); } if (mipi->init_delay) usleep_range(mipi->init_delay, mipi->init_delay); if (mipi->force_clk_lane_hs) { u32 tmp; tmp = MIPI_INP((ctrl_pdata->ctrl_base) + 0xac); tmp |= (1<<28); MIPI_OUTP((ctrl_pdata->ctrl_base) + 0xac, tmp); wmb(); } if (pdata->panel_info.type == MIPI_CMD_PANEL) mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_OFF); end: pr_debug("%s-:\n", __func__); return ret; } static int mdss_dsi_pinctrl_set_state( struct mdss_dsi_ctrl_pdata *ctrl_pdata, bool active) { struct pinctrl_state *pin_state; struct mdss_panel_info *pinfo = NULL; int rc = -EFAULT; if (IS_ERR_OR_NULL(ctrl_pdata->pin_res.pinctrl)) return PTR_ERR(ctrl_pdata->pin_res.pinctrl); pinfo = &ctrl_pdata->panel_data.panel_info; if ((mdss_dsi_is_right_ctrl(ctrl_pdata) && mdss_dsi_is_hw_config_split(ctrl_pdata->shared_data)) || pinfo->is_dba_panel) { pr_debug("%s:%d, right ctrl pinctrl config not needed\n", __func__, __LINE__); return 0; } pin_state = active ? ctrl_pdata->pin_res.gpio_state_active : ctrl_pdata->pin_res.gpio_state_suspend; if (!IS_ERR_OR_NULL(pin_state)) { rc = pinctrl_select_state(ctrl_pdata->pin_res.pinctrl, pin_state); if (rc) pr_err("%s: can not set %s pins\n", __func__, active ? MDSS_PINCTRL_STATE_DEFAULT : MDSS_PINCTRL_STATE_SLEEP); } else { pr_err("%s: invalid '%s' pinstate\n", __func__, active ? MDSS_PINCTRL_STATE_DEFAULT : MDSS_PINCTRL_STATE_SLEEP); } return rc; } static int mdss_dsi_pinctrl_init(struct platform_device *pdev) { struct mdss_dsi_ctrl_pdata *ctrl_pdata; ctrl_pdata = platform_get_drvdata(pdev); ctrl_pdata->pin_res.pinctrl = devm_pinctrl_get(&pdev->dev); if (IS_ERR_OR_NULL(ctrl_pdata->pin_res.pinctrl)) { pr_err("%s: failed to get pinctrl\n", __func__); return PTR_ERR(ctrl_pdata->pin_res.pinctrl); } ctrl_pdata->pin_res.gpio_state_active = pinctrl_lookup_state(ctrl_pdata->pin_res.pinctrl, MDSS_PINCTRL_STATE_DEFAULT); if (IS_ERR_OR_NULL(ctrl_pdata->pin_res.gpio_state_active)) pr_warn("%s: can not get default pinstate\n", __func__); ctrl_pdata->pin_res.gpio_state_suspend = pinctrl_lookup_state(ctrl_pdata->pin_res.pinctrl, MDSS_PINCTRL_STATE_SLEEP); if (IS_ERR_OR_NULL(ctrl_pdata->pin_res.gpio_state_suspend)) pr_warn("%s: can not get sleep pinstate\n", __func__); return 0; } static int mdss_dsi_unblank(struct mdss_panel_data *pdata) { int ret = 0; struct mipi_panel_info *mipi; struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; struct mdss_dsi_ctrl_pdata *sctrl = NULL; if (pdata == NULL) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); mipi = &pdata->panel_info.mipi; pr_debug("%s+: ctrl=%p ndx=%d cur_power_state=%d ctrl_state=%x\n", __func__, ctrl_pdata, ctrl_pdata->ndx, pdata->panel_info.panel_power_state, ctrl_pdata->ctrl_state); mdss_dsi_pm_qos_update_request(DSI_DISABLE_PC_LATENCY); if (mdss_dsi_is_ctrl_clk_master(ctrl_pdata)) sctrl = mdss_dsi_get_ctrl_clk_slave(); mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_ON); if (sctrl) mdss_dsi_clk_ctrl(sctrl, sctrl->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_ON); if (mdss_dsi_is_panel_on_lp(pdata)) { pr_debug("%s: dsi_unblank with panel always on\n", __func__); if (ctrl_pdata->low_power_config) ret = ctrl_pdata->low_power_config(pdata, false); goto error; } if (!(ctrl_pdata->ctrl_state & CTRL_STATE_PANEL_INIT)) { if (!pdata->panel_info.dynamic_switch_pending) { ATRACE_BEGIN("dsi_panel_on"); ret = ctrl_pdata->on(pdata); if (ret) { pr_err("%s: unable to initialize the panel\n", __func__); goto error; } ATRACE_END("dsi_panel_on"); } ctrl_pdata->ctrl_state |= CTRL_STATE_PANEL_INIT; } if ((pdata->panel_info.type == MIPI_CMD_PANEL) && mipi->vsync_enable && mipi->hw_vsync_mode) { mdss_dsi_set_tear_on(ctrl_pdata); if (mdss_dsi_is_te_based_esd(ctrl_pdata)) enable_irq(gpio_to_irq(ctrl_pdata->disp_te_gpio)); } error: mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_OFF); if (sctrl) mdss_dsi_clk_ctrl(sctrl, sctrl->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_OFF); mdss_dsi_pm_qos_update_request(DSI_ENABLE_PC_LATENCY); pr_debug("%s-:\n", __func__); return ret; } static int mdss_dsi_blank(struct mdss_panel_data *pdata, int power_state) { int ret = 0; struct mipi_panel_info *mipi; struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; if (pdata == NULL) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); mipi = &pdata->panel_info.mipi; pr_debug("%s+: ctrl=%p ndx=%d power_state=%d\n", __func__, ctrl_pdata, ctrl_pdata->ndx, power_state); mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_ON); if (mdss_panel_is_power_on_lp(power_state)) { pr_debug("%s: low power state requested\n", __func__); if (ctrl_pdata->low_power_config) ret = ctrl_pdata->low_power_config(pdata, true); goto error; } if (pdata->panel_info.type == MIPI_VIDEO_PANEL && ctrl_pdata->off_cmds.link_state == DSI_LP_MODE) { mdss_dsi_sw_reset(ctrl_pdata, false); mdss_dsi_host_init(pdata); } mdss_dsi_op_mode_config(DSI_CMD_MODE, pdata); if (pdata->panel_info.dynamic_switch_pending) { pr_info("%s: switching to %s mode\n", __func__, (pdata->panel_info.mipi.mode ? "video" : "command")); if (pdata->panel_info.type == MIPI_CMD_PANEL) { ctrl_pdata->switch_mode(pdata, SWITCH_TO_VIDEO_MODE); } else if (pdata->panel_info.type == MIPI_VIDEO_PANEL) { ctrl_pdata->switch_mode(pdata, SWITCH_TO_CMD_MODE); mdss_dsi_set_tear_off(ctrl_pdata); } } if ((pdata->panel_info.type == MIPI_CMD_PANEL) && mipi->vsync_enable && mipi->hw_vsync_mode) { if (mdss_dsi_is_te_based_esd(ctrl_pdata)) { disable_irq(gpio_to_irq( ctrl_pdata->disp_te_gpio)); atomic_dec(&ctrl_pdata->te_irq_ready); } mdss_dsi_set_tear_off(ctrl_pdata); } if (ctrl_pdata->ctrl_state & CTRL_STATE_PANEL_INIT) { if (!pdata->panel_info.dynamic_switch_pending) { ATRACE_BEGIN("dsi_panel_off"); ret = ctrl_pdata->off(pdata); if (ret) { pr_err("%s: Panel OFF failed\n", __func__); goto error; } ATRACE_END("dsi_panel_off"); } ctrl_pdata->ctrl_state &= ~CTRL_STATE_PANEL_INIT; } error: mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_OFF); pr_debug("%s-:End\n", __func__); return ret; } static int mdss_dsi_post_panel_on(struct mdss_panel_data *pdata) { struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; if (pdata == NULL) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); pr_debug("%s+: ctrl=%p ndx=%d\n", __func__, ctrl_pdata, ctrl_pdata->ndx); mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_ON); if (ctrl_pdata->post_panel_on) ctrl_pdata->post_panel_on(pdata); mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_OFF); pr_debug("%s-:\n", __func__); return 0; } int mdss_dsi_cont_splash_on(struct mdss_panel_data *pdata) { int ret = 0; struct mipi_panel_info *mipi; struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; pr_info("%s:%d DSI on for continuous splash.\n", __func__, __LINE__); if (pdata == NULL) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } mipi = &pdata->panel_info.mipi; ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); pr_debug("%s+: ctrl=%p ndx=%d\n", __func__, ctrl_pdata, ctrl_pdata->ndx); WARN((ctrl_pdata->ctrl_state & CTRL_STATE_PANEL_INIT), "Incorrect Ctrl state=0x%x\n", ctrl_pdata->ctrl_state); mdss_dsi_ctrl_setup(ctrl_pdata); mdss_dsi_sw_reset(ctrl_pdata, true); pr_debug("%s-:End\n", __func__); return ret; } static void __mdss_dsi_update_video_mode_total(struct mdss_panel_data *pdata, int new_fps) { u32 hsync_period, vsync_period; u32 new_dsi_v_total, current_dsi_v_total; struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; if (pdata == NULL) { pr_err("%s Invalid pdata\n", __func__); return; } ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); if (ctrl_pdata == NULL) { pr_err("%s Invalid ctrl_pdata\n", __func__); return; } vsync_period = mdss_panel_get_vtotal(&pdata->panel_info); hsync_period = mdss_panel_get_htotal(&pdata->panel_info, true); current_dsi_v_total = MIPI_INP((ctrl_pdata->ctrl_base) + 0x2C); new_dsi_v_total = ((vsync_period - 1) << 16) | (hsync_period - 1); MIPI_OUTP((ctrl_pdata->ctrl_base) + 0x2C, (current_dsi_v_total | 0x8000000)); if (new_dsi_v_total & 0x8000000) { MIPI_OUTP((ctrl_pdata->ctrl_base) + 0x2C, new_dsi_v_total); } else { MIPI_OUTP((ctrl_pdata->ctrl_base) + 0x2C, (new_dsi_v_total | 0x8000000)); MIPI_OUTP((ctrl_pdata->ctrl_base) + 0x2C, (new_dsi_v_total & 0x7ffffff)); } if (ctrl_pdata->timing_db_mode) MIPI_OUTP((ctrl_pdata->ctrl_base) + 0x1e4, 0x1); pr_debug("%s new_fps:%d vsync:%d hsync:%d frame_rate:%d\n", __func__, new_fps, vsync_period, hsync_period, ctrl_pdata->panel_data.panel_info.mipi.frame_rate); ctrl_pdata->panel_data.panel_info.current_fps = new_fps; MDSS_XLOG(current_dsi_v_total, new_dsi_v_total, new_fps, ctrl_pdata->timing_db_mode); } static void __mdss_dsi_dyn_refresh_config( struct mdss_dsi_ctrl_pdata *ctrl_pdata) { int reg_data = 0; u32 phy_rev = mdss_dsi_get_phy_revision(ctrl_pdata); /* configure only for master control in split display */ if (mdss_dsi_is_hw_config_split(ctrl_pdata->shared_data) && mdss_dsi_is_ctrl_clk_slave(ctrl_pdata)) return; switch (phy_rev) { case DSI_PHY_REV_10: reg_data = MIPI_INP((ctrl_pdata->ctrl_base) + DSI_DYNAMIC_REFRESH_CTRL); reg_data &= ~BIT(12); MIPI_OUTP((ctrl_pdata->ctrl_base) + DSI_DYNAMIC_REFRESH_CTRL, reg_data); break; case DSI_PHY_REV_20: reg_data = BIT(13); MIPI_OUTP((ctrl_pdata->ctrl_base) + DSI_DYNAMIC_REFRESH_CTRL, reg_data); break; default: pr_err("Phy rev %d unsupported\n", phy_rev); break; } pr_debug("Dynamic fps ctrl = 0x%x\n", reg_data); } static void __mdss_dsi_calc_dfps_delay(struct mdss_panel_data *pdata) { u32 esc_clk_rate = XO_CLK_RATE; u32 pipe_delay, pipe_delay2 = 0, pll_delay; u32 hsync_period = 0; u32 pclk_to_esc_ratio, byte_to_esc_ratio, hr_bit_to_esc_ratio; struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; struct mdss_panel_info *pinfo = NULL; struct mdss_dsi_phy_ctrl *pd = NULL; if (pdata == NULL) { pr_err("%s Invalid pdata\n", __func__); return; } ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); if (ctrl_pdata == NULL) { pr_err("%s Invalid ctrl_pdata\n", __func__); return; } if (mdss_dsi_is_hw_config_split(ctrl_pdata->shared_data) && mdss_dsi_is_ctrl_clk_slave(ctrl_pdata)) return; pinfo = &pdata->panel_info; pd = &(pinfo->mipi.dsi_phy_db); pclk_to_esc_ratio = (ctrl_pdata->pclk_rate / esc_clk_rate); byte_to_esc_ratio = (ctrl_pdata->byte_clk_rate / esc_clk_rate); hr_bit_to_esc_ratio = ((ctrl_pdata->byte_clk_rate * 4) / esc_clk_rate); hsync_period = mdss_panel_get_htotal(pinfo, true); pipe_delay = (hsync_period + 1) / pclk_to_esc_ratio; if (pinfo->mipi.eof_bllp_power_stop == 0) pipe_delay += (17 / pclk_to_esc_ratio) + ((21 + (pinfo->mipi.t_clk_pre + 1) + (pinfo->mipi.t_clk_post + 1)) / byte_to_esc_ratio) + ((((pd->timing[8] >> 1) + 1) + ((pd->timing[6] >> 1) + 1) + ((pd->timing[3] * 4) + (pd->timing[5] >> 1) + 1) + ((pd->timing[7] >> 1) + 1) + ((pd->timing[1] >> 1) + 1) + ((pd->timing[4] >> 1) + 1)) / hr_bit_to_esc_ratio); if (pinfo->mipi.force_clk_lane_hs) pipe_delay2 = (6 / byte_to_esc_ratio) + ((((pd->timing[1] >> 1) + 1) + ((pd->timing[4] >> 1) + 1)) / hr_bit_to_esc_ratio); /* 130 us pll delay recommended by h/w doc */ pll_delay = ((130 * esc_clk_rate) / 1000000) * 2; MIPI_OUTP((ctrl_pdata->ctrl_base) + DSI_DYNAMIC_REFRESH_PIPE_DELAY, pipe_delay); MIPI_OUTP((ctrl_pdata->ctrl_base) + DSI_DYNAMIC_REFRESH_PIPE_DELAY2, pipe_delay2); MIPI_OUTP((ctrl_pdata->ctrl_base) + DSI_DYNAMIC_REFRESH_PLL_DELAY, pll_delay); } static int __mdss_dsi_dfps_calc_clks(struct mdss_panel_data *pdata, int new_fps) { int rc = 0; u64 clk_rate; struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; struct mdss_panel_info *pinfo; u32 phy_rev; if (pdata == NULL) { pr_err("%s Invalid pdata\n", __func__); return -EINVAL; } ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); if (ctrl_pdata == NULL) { pr_err("%s Invalid ctrl_pdata\n", __func__); return -EINVAL; } pinfo = &pdata->panel_info; phy_rev = mdss_dsi_get_phy_revision(ctrl_pdata); rc = mdss_dsi_clk_div_config (&ctrl_pdata->panel_data.panel_info, new_fps); if (rc) { pr_err("%s: unable to initialize the clk dividers\n", __func__); return rc; } __mdss_dsi_dyn_refresh_config(ctrl_pdata); if (phy_rev == DSI_PHY_REV_20) mdss_dsi_dfps_config_8996(ctrl_pdata); __mdss_dsi_calc_dfps_delay(pdata); /* take a backup of current clk rates */ ctrl_pdata->pclk_rate_bkp = ctrl_pdata->pclk_rate; ctrl_pdata->byte_clk_rate_bkp = ctrl_pdata->byte_clk_rate; ctrl_pdata->pclk_rate = pinfo->mipi.dsi_pclk_rate; clk_rate = pinfo->clk_rate; do_div(clk_rate, 8U); ctrl_pdata->byte_clk_rate = (u32) clk_rate; pr_debug("byte_rate=%i\n", ctrl_pdata->byte_clk_rate); pr_debug("pclk_rate=%i\n", ctrl_pdata->pclk_rate); return rc; } static int __mdss_dsi_dfps_update_clks(struct mdss_panel_data *pdata, int new_fps) { struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; struct mdss_dsi_ctrl_pdata *sctrl_pdata = NULL; struct mdss_panel_info *pinfo, *spinfo; int rc = 0; u32 data; if (pdata == NULL) { pr_err("%s Invalid pdata\n", __func__); return -EINVAL; } ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); if (IS_ERR_OR_NULL(ctrl_pdata)) { pr_err("Invalid sctrl_pdata = %lu\n", PTR_ERR(ctrl_pdata)); return PTR_ERR(ctrl_pdata); } pinfo = &ctrl_pdata->panel_data.panel_info; /* * In split display case, configure and enable dynamic refresh * register only after both the ctrl data is programmed. So, * ignore enabling dynamic refresh for the master control and * configure only when it is slave control. */ if (mdss_dsi_is_hw_config_split(ctrl_pdata->shared_data) && mdss_dsi_is_ctrl_clk_master(ctrl_pdata)) return 0; if (mdss_dsi_is_hw_config_split(ctrl_pdata->shared_data) && mdss_dsi_is_ctrl_clk_slave(ctrl_pdata)) { sctrl_pdata = ctrl_pdata; spinfo = pinfo; ctrl_pdata = mdss_dsi_get_ctrl_clk_master(); if (IS_ERR_OR_NULL(ctrl_pdata)) { pr_err("Invalid ctrl_pdata = %lu\n", PTR_ERR(ctrl_pdata)); return PTR_ERR(ctrl_pdata); } pinfo = &ctrl_pdata->panel_data.panel_info; } /* * For programming dynamic refresh registers, we need to change * the parent to shadow clocks for the software byte and pixel mux. * After switching to shadow clocks, if there is no ref count on * main byte and pixel clocks, clock driver may shutdown those * unreferenced byte and pixel clocks. Hence add an extra reference * count to avoid shutting down the main byte and pixel clocks. */ rc = clk_prepare_enable(ctrl_pdata->pll_byte_clk); if (rc) { pr_err("Unable to add extra refcnt for byte clock\n"); goto error_byte; } rc = clk_prepare_enable(ctrl_pdata->pll_pixel_clk); if (rc) { pr_err("Unable to add extra refcnt for pixel clock\n"); goto error_pixel; } /* change the parent to shadow clocks*/ rc = clk_set_parent(ctrl_pdata->mux_byte_clk, ctrl_pdata->shadow_byte_clk); if (rc) { pr_err("Unable to set parent to shadow byte clock\n"); goto error_shadow_byte; } rc = clk_set_parent(ctrl_pdata->mux_pixel_clk, ctrl_pdata->shadow_pixel_clk); if (rc) { pr_err("Unable to set parent to shadow pixel clock\n"); goto error_shadow_pixel; } rc = mdss_dsi_clk_set_link_rate(ctrl_pdata->dsi_clk_handle, MDSS_DSI_LINK_BYTE_CLK, ctrl_pdata->byte_clk_rate, 0); if (rc) { pr_err("%s: dsi_byte_clk - clk_set_rate failed\n", __func__); goto error_byte_link; } rc = mdss_dsi_clk_set_link_rate(ctrl_pdata->dsi_clk_handle, MDSS_DSI_LINK_PIX_CLK, ctrl_pdata->pclk_rate, 0); if (rc) { pr_err("%s: dsi_pixel_clk - clk_set_rate failed\n", __func__); goto error_pixel_link; } if (sctrl_pdata) { rc = mdss_dsi_clk_set_link_rate(sctrl_pdata->dsi_clk_handle, MDSS_DSI_LINK_BYTE_CLK, sctrl_pdata->byte_clk_rate, 0); if (rc) { pr_err("%s: slv dsi_byte_clk - clk_set_rate failed\n", __func__); goto error_sbyte_link; } rc = mdss_dsi_clk_set_link_rate(sctrl_pdata->dsi_clk_handle, MDSS_DSI_LINK_PIX_CLK, sctrl_pdata->pclk_rate, 0); if (rc) { pr_err("%s: slv dsi_pixel_clk - clk_set_rate failed\n", __func__); goto error_spixel_link; } } rc = mdss_dsi_en_wait4dynamic_done(ctrl_pdata); if (rc) { pr_err("Unsuccessful dynamic fps change"); goto dfps_timeout; } MIPI_OUTP((ctrl_pdata->ctrl_base) + DSI_DYNAMIC_REFRESH_CTRL, 0x00); if (sctrl_pdata) MIPI_OUTP((sctrl_pdata->ctrl_base) + DSI_DYNAMIC_REFRESH_CTRL, 0x00); data = MIPI_INP((ctrl_pdata->ctrl_base) + 0x0120); if (data & BIT(16)) { pr_debug("pll unlocked: 0x%x\n", data); /* clear PLL unlock bit */ MIPI_OUTP((ctrl_pdata->ctrl_base) + 0x120, BIT(16)); } /* Move the mux clocks to main byte and pixel clocks */ rc = clk_set_parent(ctrl_pdata->mux_byte_clk, ctrl_pdata->pll_byte_clk); if (rc) pr_err("Unable to set parent back to main byte clock\n"); rc = clk_set_parent(ctrl_pdata->mux_pixel_clk, ctrl_pdata->pll_pixel_clk); if (rc) pr_err("Unable to set parent back to main pixel clock\n"); /* Remove extra ref count on parent clocks */ clk_disable_unprepare(ctrl_pdata->pll_byte_clk); clk_disable_unprepare(ctrl_pdata->pll_pixel_clk); /* update new fps that at this point is already updated in hw */ pinfo->current_fps = new_fps; if (sctrl_pdata) { spinfo->current_fps = new_fps; } return rc; dfps_timeout: if (sctrl_pdata) mdss_dsi_clk_set_link_rate(sctrl_pdata->dsi_clk_handle, MDSS_DSI_LINK_PIX_CLK, sctrl_pdata->pclk_rate_bkp, 0); error_spixel_link: if (sctrl_pdata) mdss_dsi_clk_set_link_rate(sctrl_pdata->dsi_clk_handle, MDSS_DSI_LINK_BYTE_CLK, sctrl_pdata->byte_clk_rate_bkp, 0); error_sbyte_link: mdss_dsi_clk_set_link_rate(ctrl_pdata->dsi_clk_handle, MDSS_DSI_LINK_PIX_CLK, ctrl_pdata->pclk_rate_bkp, 0); error_pixel_link: mdss_dsi_clk_set_link_rate(ctrl_pdata->dsi_clk_handle, MDSS_DSI_LINK_BYTE_CLK, ctrl_pdata->byte_clk_rate_bkp, 0); error_byte_link: clk_set_parent(ctrl_pdata->mux_pixel_clk, ctrl_pdata->pll_pixel_clk); error_shadow_pixel: clk_set_parent(ctrl_pdata->mux_byte_clk, ctrl_pdata->pll_byte_clk); error_shadow_byte: clk_disable_unprepare(ctrl_pdata->pll_pixel_clk); error_pixel: clk_disable_unprepare(ctrl_pdata->pll_byte_clk); error_byte: return rc; } static int mdss_dsi_check_params(struct mdss_dsi_ctrl_pdata *ctrl, void *arg) { struct mdss_panel_info *var_pinfo, *pinfo; int rc = 0; if (!ctrl || !arg) return 0; pinfo = &ctrl->panel_data.panel_info; if (!pinfo->is_pluggable) return 0; var_pinfo = (struct mdss_panel_info *)arg; pr_debug("%s: reconfig xres: %d yres: %d, current xres: %d yres: %d\n", __func__, var_pinfo->xres, var_pinfo->yres, pinfo->xres, pinfo->yres); if ((var_pinfo->xres != pinfo->xres) || (var_pinfo->yres != pinfo->yres) || (var_pinfo->lcdc.h_back_porch != pinfo->lcdc.h_back_porch) || (var_pinfo->lcdc.h_front_porch != pinfo->lcdc.h_front_porch) || (var_pinfo->lcdc.h_pulse_width != pinfo->lcdc.h_pulse_width) || (var_pinfo->lcdc.v_back_porch != pinfo->lcdc.v_back_porch) || (var_pinfo->lcdc.v_front_porch != pinfo->lcdc.v_front_porch) || (var_pinfo->lcdc.v_pulse_width != pinfo->lcdc.v_pulse_width) ) rc = 1; return rc; } static int mdss_dsi_dfps_config(struct mdss_panel_data *pdata, int new_fps) { int rc = 0; struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; struct mdss_panel_info *pinfo; u32 phy_rev; u32 frame_rate_bkp; pr_debug("%s+:\n", __func__); if (pdata == NULL) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); if (!ctrl_pdata->panel_data.panel_info.dynamic_fps) { pr_err("Dynamic fps not enabled for this panel\n"); return -EINVAL; } phy_rev = mdss_dsi_get_phy_revision(ctrl_pdata); pinfo = &pdata->panel_info; /* get the fps configured in HW */ frame_rate_bkp = pinfo->current_fps; if (new_fps == pinfo->current_fps) { /* * This is unlikely as mdss driver checks for previously * configured frame rate. */ pr_debug("Panel is already at this FPS\n"); goto end_update; } if (pinfo->dfps_update == DFPS_IMMEDIATE_PORCH_UPDATE_MODE_HFP || pinfo->dfps_update == DFPS_IMMEDIATE_PORCH_UPDATE_MODE_VFP) { /* Porch method */ __mdss_dsi_update_video_mode_total(pdata, new_fps); } else if (pinfo->dfps_update == DFPS_IMMEDIATE_CLK_UPDATE_MODE) { /* Clock update method */ if (phy_rev == DSI_PHY_REV_20) { rc = mdss_dsi_phy_calc_timing_param(pinfo, phy_rev, new_fps); if (rc) { pr_err("PHY calculations failed-%d\n", new_fps); goto end_update; } } rc = __mdss_dsi_dfps_calc_clks(pdata, new_fps); if (rc) { pr_err("error calculating clocks for %d\n", new_fps); goto error_clks; } rc = __mdss_dsi_dfps_update_clks(pdata, new_fps); if (rc) { pr_err("Dynamic refresh failed-%d\n", new_fps); goto error_dfps; } } return rc; error_dfps: if (__mdss_dsi_dfps_calc_clks(pdata, frame_rate_bkp)) pr_err("error reverting clock calculations for %d\n", frame_rate_bkp); error_clks: if (mdss_dsi_phy_calc_timing_param(pinfo, phy_rev, frame_rate_bkp)) pr_err("Unable to revert phy timing-%d\n", frame_rate_bkp); end_update: return rc; } static int mdss_dsi_ctl_partial_roi(struct mdss_panel_data *pdata) { struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; int rc = -EINVAL; if (pdata == NULL) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } if (!pdata->panel_info.partial_update_enabled) return 0; ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); if (ctrl_pdata->set_col_page_addr) rc = ctrl_pdata->set_col_page_addr(pdata, false); return rc; } static int mdss_dsi_set_stream_size(struct mdss_panel_data *pdata) { u32 stream_ctrl, stream_total, idle; struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; struct mdss_panel_info *pinfo; struct dsc_desc *dsc = NULL; struct mdss_rect *roi; struct panel_horizontal_idle *pidle; int i; if (pdata == NULL) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); pinfo = &pdata->panel_info; if (!pinfo->partial_update_supported) return -EINVAL; if (pinfo->compression_mode == COMPRESSION_DSC) dsc = &pinfo->dsc; roi = &pinfo->roi; /* DSI_COMMAND_MODE_MDP_STREAM_CTRL */ if (dsc) { u16 byte_num = dsc->bytes_per_pkt; if (pinfo->mipi.insert_dcs_cmd) byte_num++; stream_ctrl = (byte_num << 16) | (pinfo->mipi.vc << 8) | DTYPE_DCS_LWRITE; stream_total = dsc->pic_height << 16 | dsc->pclk_per_line; } else { stream_ctrl = (((roi->w * 3) + 1) << 16) | (pdata->panel_info.mipi.vc << 8) | DTYPE_DCS_LWRITE; stream_total = roi->h << 16 | roi->w; } MIPI_OUTP((ctrl_pdata->ctrl_base) + 0x60, stream_ctrl); MIPI_OUTP((ctrl_pdata->ctrl_base) + 0x58, stream_ctrl); /* DSI_COMMAND_MODE_MDP_STREAM_TOTAL */ MIPI_OUTP((ctrl_pdata->ctrl_base) + 0x64, stream_total); MIPI_OUTP((ctrl_pdata->ctrl_base) + 0x5C, stream_total); /* set idle control -- dsi clk cycle */ idle = 0; pidle = ctrl_pdata->line_idle; for (i = 0; i < ctrl_pdata->horizontal_idle_cnt; i++) { if (roi->w > pidle->min && roi->w <= pidle->max) { idle = pidle->idle; pr_debug("%s: ndx=%d w=%d range=%d-%d idle=%d\n", __func__, ctrl_pdata->ndx, roi->w, pidle->min, pidle->max, pidle->idle); break; } pidle++; } if (idle) idle |= BIT(12); /* enable */ MIPI_OUTP((ctrl_pdata->ctrl_base) + 0x194, idle); if (dsc) mdss_dsi_dsc_config(ctrl_pdata, dsc); return 0; } static void mdss_dsi_dba_work(struct work_struct *work) { struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; struct delayed_work *dw = to_delayed_work(work); struct mdss_dba_utils_init_data utils_init_data; struct mdss_panel_info *pinfo; ctrl_pdata = container_of(dw, struct mdss_dsi_ctrl_pdata, dba_work); if (!ctrl_pdata) { pr_err("%s: invalid ctrl data\n", __func__); return; } pinfo = &ctrl_pdata->panel_data.panel_info; if (!pinfo) { pr_err("%s: invalid ctrl data\n", __func__); return; } memset(&utils_init_data, 0, sizeof(utils_init_data)); utils_init_data.chip_name = "adv7533"; utils_init_data.client_name = "dsi"; utils_init_data.instance_id = 0; utils_init_data.fb_node = ctrl_pdata->fb_node; utils_init_data.kobj = ctrl_pdata->kobj; utils_init_data.pinfo = pinfo; pinfo->dba_data = mdss_dba_utils_init(&utils_init_data); if (!IS_ERR_OR_NULL(pinfo->dba_data)) { ctrl_pdata->ds_registered = true; } else { pr_debug("%s: dba device not ready, queue again\n", __func__); queue_delayed_work(ctrl_pdata->workq, &ctrl_pdata->dba_work, HZ); } } static int mdss_dsi_reset_write_ptr(struct mdss_panel_data *pdata) { struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; struct mdss_panel_info *pinfo; int rc = 0; if (pdata == NULL) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); pinfo = &ctrl_pdata->panel_data.panel_info; mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_ON); /* Need to reset the DSI core since the pixel stream was stopped. */ mdss_dsi_sw_reset(ctrl_pdata, true); /* * Reset the partial update co-ordinates to the panel height and * width */ if (pinfo->dcs_cmd_by_left && (ctrl_pdata->ndx == 1)) goto skip_cmd_send; pinfo->roi.x = 0; pinfo->roi.y = 0; pinfo->roi.w = pinfo->xres; if (pinfo->dcs_cmd_by_left) pinfo->roi.w = pinfo->xres; if (pdata->next) pinfo->roi.w += pdata->next->panel_info.xres; pinfo->roi.h = pinfo->yres; mdss_dsi_set_stream_size(pdata); if (ctrl_pdata->set_col_page_addr) rc = ctrl_pdata->set_col_page_addr(pdata, true); skip_cmd_send: mdss_dsi_clk_ctrl(ctrl_pdata, ctrl_pdata->dsi_clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_OFF); pr_debug("%s: DSI%d write ptr reset finished\n", __func__, ctrl_pdata->ndx); return rc; } int mdss_dsi_register_recovery_handler(struct mdss_dsi_ctrl_pdata *ctrl, struct mdss_intf_recovery *recovery) { mutex_lock(&ctrl->mutex); ctrl->recovery = recovery; mutex_unlock(&ctrl->mutex); return 0; } static struct device_node *mdss_dsi_get_fb_node_cb(struct platform_device *pdev) { struct device_node *fb_node; struct platform_device *dsi_dev; struct mdss_dsi_ctrl_pdata *ctrl_pdata; if (pdev == NULL) { pr_err("%s: Invalid input data\n", __func__); return NULL; } ctrl_pdata = platform_get_drvdata(pdev); dsi_dev = of_find_device_by_node(pdev->dev.of_node->parent); if (!dsi_dev) { pr_err("Unable to find dsi master device: %s\n", pdev->dev.of_node->full_name); return NULL; } fb_node = of_parse_phandle(dsi_dev->dev.of_node, mdss_dsi_get_fb_name(ctrl_pdata), 0); if (!fb_node) { pr_err("Unable to find fb node for device: %s\n", pdev->name); return NULL; } return fb_node; } static int mdss_dsi_event_handler(struct mdss_panel_data *pdata, int event, void *arg) { int rc = 0; struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; struct fb_info *fbi; int power_state; u32 mode; struct mdss_panel_info *pinfo; if (pdata == NULL) { pr_err("%s: Invalid input data\n", __func__); return -EINVAL; } pinfo = &pdata->panel_info; ctrl_pdata = container_of(pdata, struct mdss_dsi_ctrl_pdata, panel_data); pr_debug("%s+: ctrl=%d event=%d\n", __func__, ctrl_pdata->ndx, event); MDSS_XLOG(event, arg, ctrl_pdata->ndx, 0x3333); switch (event) { case MDSS_EVENT_CHECK_PARAMS: pr_debug("%s:Entered Case MDSS_EVENT_CHECK_PARAMS\n", __func__); if (mdss_dsi_check_params(ctrl_pdata, arg)) { ctrl_pdata->refresh_clk_rate = true; rc = 1; } break; case MDSS_EVENT_LINK_READY: if (ctrl_pdata->refresh_clk_rate) rc = mdss_dsi_clk_refresh(pdata); mdss_dsi_get_hw_revision(ctrl_pdata); mdss_dsi_get_phy_revision(ctrl_pdata); rc = mdss_dsi_on(pdata); mdss_dsi_op_mode_config(pdata->panel_info.mipi.mode, pdata); break; case MDSS_EVENT_UNBLANK: if (ctrl_pdata->on_cmds.link_state == DSI_LP_MODE) rc = mdss_dsi_unblank(pdata); break; case MDSS_EVENT_POST_PANEL_ON: rc = mdss_dsi_post_panel_on(pdata); break; case MDSS_EVENT_PANEL_ON: ctrl_pdata->ctrl_state |= CTRL_STATE_MDP_ACTIVE; if (ctrl_pdata->on_cmds.link_state == DSI_HS_MODE) rc = mdss_dsi_unblank(pdata); pdata->panel_info.esd_rdy = true; break; case MDSS_EVENT_BLANK: power_state = (int) (unsigned long) arg; if (ctrl_pdata->off_cmds.link_state == DSI_HS_MODE) rc = mdss_dsi_blank(pdata, power_state); break; case MDSS_EVENT_PANEL_OFF: power_state = (int) (unsigned long) arg; ctrl_pdata->ctrl_state &= ~CTRL_STATE_MDP_ACTIVE; if (ctrl_pdata->off_cmds.link_state == DSI_LP_MODE) rc = mdss_dsi_blank(pdata, power_state); rc = mdss_dsi_off(pdata, power_state); break; case MDSS_EVENT_CONT_SPLASH_FINISH: if (ctrl_pdata->off_cmds.link_state == DSI_LP_MODE) rc = mdss_dsi_blank(pdata, MDSS_PANEL_POWER_OFF); ctrl_pdata->ctrl_state &= ~CTRL_STATE_MDP_ACTIVE; rc = mdss_dsi_cont_splash_on(pdata); break; case MDSS_EVENT_PANEL_CLK_CTRL: mdss_dsi_clk_req(ctrl_pdata, (struct dsi_panel_clk_ctrl *) arg); break; case MDSS_EVENT_DSI_CMDLIST_KOFF: mdss_dsi_cmdlist_commit(ctrl_pdata, 1); break; case MDSS_EVENT_PANEL_UPDATE_FPS: if (arg != NULL) { rc = mdss_dsi_dfps_config(pdata, (int) (unsigned long) arg); if (rc) pr_err("unable to change fps-%d, error-%d\n", (int) (unsigned long) arg, rc); else pr_debug("panel frame rate changed to %d\n", (int) (unsigned long) arg); } break; case MDSS_EVENT_CONT_SPLASH_BEGIN: if (ctrl_pdata->off_cmds.link_state == DSI_HS_MODE) { /* Panel is Enabled in Bootloader */ rc = mdss_dsi_blank(pdata, MDSS_PANEL_POWER_OFF); } break; case MDSS_EVENT_DSC_PPS_SEND: if (pinfo->compression_mode == COMPRESSION_DSC) mdss_dsi_panel_dsc_pps_send(ctrl_pdata, pinfo); break; case MDSS_EVENT_ENABLE_PARTIAL_ROI: rc = mdss_dsi_ctl_partial_roi(pdata); break; case MDSS_EVENT_DSI_RESET_WRITE_PTR: rc = mdss_dsi_reset_write_ptr(pdata); break; case MDSS_EVENT_DSI_STREAM_SIZE: rc = mdss_dsi_set_stream_size(pdata); break; case MDSS_EVENT_DSI_UPDATE_PANEL_DATA: rc = mdss_dsi_update_panel_config(ctrl_pdata, (int)(unsigned long) arg); break; case MDSS_EVENT_REGISTER_RECOVERY_HANDLER: rc = mdss_dsi_register_recovery_handler(ctrl_pdata, (struct mdss_intf_recovery *)arg); break; case MDSS_EVENT_DSI_DYNAMIC_SWITCH: mode = (u32)(unsigned long) arg; mdss_dsi_switch_mode(pdata, mode); break; case MDSS_EVENT_DSI_RECONFIG_CMD: mode = (u32)(unsigned long) arg; rc = mdss_dsi_reconfig(pdata, mode); break; case MDSS_EVENT_DSI_PANEL_STATUS: if (ctrl_pdata->check_status) rc = ctrl_pdata->check_status(ctrl_pdata); else rc = true; break; case MDSS_EVENT_PANEL_TIMING_SWITCH: rc = mdss_dsi_panel_timing_switch(ctrl_pdata, arg); break; case MDSS_EVENT_FB_REGISTERED: mdss_dsi_debugfs_init(ctrl_pdata); fbi = (struct fb_info *)arg; if (!fbi || !fbi->dev) break; ctrl_pdata->kobj = &fbi->dev->kobj; ctrl_pdata->fb_node = fbi->node; if (IS_ENABLED(CONFIG_MSM_DBA) && pdata->panel_info.is_dba_panel) { queue_delayed_work(ctrl_pdata->workq, &ctrl_pdata->dba_work, HZ); } break; default: pr_debug("%s: unhandled event=%d\n", __func__, event); break; } pr_debug("%s-:event=%d, rc=%d\n", __func__, event, rc); return rc; } static int mdss_dsi_set_override_cfg(char *override_cfg, struct mdss_dsi_ctrl_pdata *ctrl_pdata, char *panel_cfg) { struct mdss_panel_info *pinfo = &ctrl_pdata->panel_data.panel_info; char *token = NULL; pr_debug("%s: override config:%s\n", __func__, override_cfg); while ((token = strsep(&override_cfg, ":"))) { if (!strcmp(token, OVERRIDE_CFG)) { continue; } else if (!strcmp(token, SIM_HW_TE_PANEL)) { pinfo->sim_panel_mode = SIM_HW_TE_MODE; } else if (!strcmp(token, SIM_SW_TE_PANEL)) { pinfo->sim_panel_mode = SIM_SW_TE_MODE; } else if (!strcmp(token, SIM_PANEL)) { pinfo->sim_panel_mode = SIM_MODE; } else { pr_err("%s: invalid override_cfg token: %s\n", __func__, token); return -EINVAL; } } pr_debug("%s:sim_panel_mode:%d\n", __func__, pinfo->sim_panel_mode); return 0; } static struct device_node *mdss_dsi_pref_prim_panel( struct platform_device *pdev) { struct device_node *dsi_pan_node = NULL; pr_debug("%s:%d: Select primary panel from dt\n", __func__, __LINE__); dsi_pan_node = of_parse_phandle(pdev->dev.of_node, "qcom,dsi-pref-prim-pan", 0); if (!dsi_pan_node) pr_err("%s:can't find panel phandle\n", __func__); return dsi_pan_node; } /** * mdss_dsi_find_panel_of_node(): find device node of dsi panel * @pdev: platform_device of the dsi ctrl node * @panel_cfg: string containing intf specific config data * * Function finds the panel device node using the interface * specific configuration data. This configuration data is * could be derived from the result of bootloader's GCDB * panel detection mechanism. If such config data doesn't * exist then this panel returns the default panel configured * in the device tree. * * returns pointer to panel node on success, NULL on error. */ static struct device_node *mdss_dsi_find_panel_of_node( struct platform_device *pdev, char *panel_cfg) { int len, i = 0; int ctrl_id = pdev->id - 1; char panel_name[MDSS_MAX_PANEL_LEN] = ""; char ctrl_id_stream[3] = "0:"; char *str1 = NULL, *str2 = NULL, *override_cfg = NULL; char cfg_np_name[MDSS_MAX_PANEL_LEN] = ""; struct device_node *dsi_pan_node = NULL, *mdss_node = NULL; struct mdss_dsi_ctrl_pdata *ctrl_pdata = platform_get_drvdata(pdev); struct mdss_panel_info *pinfo = &ctrl_pdata->panel_data.panel_info; len = strlen(panel_cfg); if (!len) { /* no panel cfg chg, parse dt */ pr_debug("%s:%d: no cmd line cfg present\n", __func__, __LINE__); goto end; } else { /* check if any override parameters are set */ pinfo->sim_panel_mode = 0; override_cfg = strnstr(panel_cfg, "#" OVERRIDE_CFG, len); if (override_cfg) { *override_cfg = '\0'; if (mdss_dsi_set_override_cfg(override_cfg + 1, ctrl_pdata, panel_cfg)) return NULL; len = strlen(panel_cfg); } if (ctrl_id == 1) strlcpy(ctrl_id_stream, "1:", 3); /* get controller number */ str1 = strnstr(panel_cfg, ctrl_id_stream, len); if (!str1) { pr_err("%s: controller %s is not present in %s\n", __func__, ctrl_id_stream, panel_cfg); goto end; } if ((str1 != panel_cfg) && (*(str1-1) != ':')) { str1 += CMDLINE_DSI_CTL_NUM_STRING_LEN; pr_debug("false match with config node name in \"%s\". search again in \"%s\"\n", panel_cfg, str1); str1 = strnstr(str1, ctrl_id_stream, len); if (!str1) { pr_err("%s: 2. controller %s is not present in %s\n", __func__, ctrl_id_stream, str1); goto end; } } str1 += CMDLINE_DSI_CTL_NUM_STRING_LEN; /* get panel name */ str2 = strnchr(str1, strlen(str1), ':'); if (!str2) { strlcpy(panel_name, str1, MDSS_MAX_PANEL_LEN); } else { for (i = 0; (str1 + i) < str2; i++) panel_name[i] = *(str1 + i); panel_name[i] = 0; } pr_info("%s: cmdline:%s panel_name:%s\n", __func__, panel_cfg, panel_name); if (!strcmp(panel_name, NONE_PANEL)) goto exit; mdss_node = of_parse_phandle(pdev->dev.of_node, "qcom,mdss-mdp", 0); if (!mdss_node) { pr_err("%s: %d: mdss_node null\n", __func__, __LINE__); return NULL; } dsi_pan_node = of_find_node_by_name(mdss_node, panel_name); if (!dsi_pan_node) { pr_err("%s: invalid pan node \"%s\"\n", __func__, panel_name); goto end; } else { /* extract config node name if present */ str1 += i; str2 = strnstr(str1, "config", strlen(str1)); if (str2) { str1 = strnchr(str2, strlen(str2), ':'); if (str1) { for (i = 0; ((str2 + i) < str1) && i < MDSS_MAX_PANEL_LEN; i++) cfg_np_name[i] = *(str2 + i); cfg_np_name[i] = 0; } else { strlcpy(cfg_np_name, str2, MDSS_MAX_PANEL_LEN); } } pr_debug("%s: cfg_np_name:%s\n", __func__, cfg_np_name); if (str2) { ctrl_pdata->panel_data.cfg_np = of_get_child_by_name(dsi_pan_node, cfg_np_name); if (!ctrl_pdata->panel_data.cfg_np) pr_warn("%s: can't find config node:%s. either no such node or bad name\n", __func__, cfg_np_name); } } return dsi_pan_node; } end: if (strcmp(panel_name, NONE_PANEL)) dsi_pan_node = mdss_dsi_pref_prim_panel(pdev); exit: return dsi_pan_node; } static struct device_node *mdss_dsi_config_panel(struct platform_device *pdev, int ndx) { struct mdss_dsi_ctrl_pdata *ctrl_pdata = platform_get_drvdata(pdev); char panel_cfg[MDSS_MAX_PANEL_LEN]; struct device_node *dsi_pan_node = NULL; int rc = 0; if (!ctrl_pdata) { pr_err("%s: Unable to get the ctrl_pdata\n", __func__); return NULL; } /* DSI panels can be different between controllers */ rc = mdss_dsi_get_panel_cfg(panel_cfg, ctrl_pdata); if (!rc) /* dsi panel cfg not present */ pr_warn("%s:%d:dsi specific cfg not present\n", __func__, __LINE__); /* find panel device node */ dsi_pan_node = mdss_dsi_find_panel_of_node(pdev, panel_cfg); if (!dsi_pan_node) { pr_err("%s: can't find panel node %s\n", __func__, panel_cfg); of_node_put(dsi_pan_node); return NULL; } rc = mdss_dsi_panel_init(dsi_pan_node, ctrl_pdata, ndx); if (rc) { pr_err("%s: dsi panel init failed\n", __func__); of_node_put(dsi_pan_node); return NULL; } return dsi_pan_node; } static int mdss_dsi_ctrl_clock_init(struct platform_device *ctrl_pdev, struct mdss_dsi_ctrl_pdata *ctrl_pdata) { int rc = 0; struct mdss_dsi_clk_info info; struct mdss_dsi_clk_client client1 = {"dsi_clk_client"}; struct mdss_dsi_clk_client client2 = {"mdp_event_client"}; void *handle; if (mdss_dsi_link_clk_init(ctrl_pdev, ctrl_pdata)) { pr_err("%s: unable to initialize Dsi ctrl clks\n", __func__); return -EPERM; } memset(&info, 0x0, sizeof(info)); info.core_clks.mdp_core_clk = ctrl_pdata->shared_data->mdp_core_clk; info.core_clks.ahb_clk = ctrl_pdata->shared_data->ahb_clk; info.core_clks.axi_clk = ctrl_pdata->shared_data->axi_clk; info.core_clks.mmss_misc_ahb_clk = ctrl_pdata->shared_data->mmss_misc_ahb_clk; info.link_clks.esc_clk = ctrl_pdata->esc_clk; info.link_clks.byte_clk = ctrl_pdata->byte_clk; info.link_clks.pixel_clk = ctrl_pdata->pixel_clk; info.pre_clkoff_cb = mdss_dsi_pre_clkoff_cb; info.post_clkon_cb = mdss_dsi_post_clkon_cb; info.pre_clkon_cb = mdss_dsi_pre_clkon_cb; info.post_clkoff_cb = mdss_dsi_post_clkoff_cb; info.priv_data = ctrl_pdata; snprintf(info.name, DSI_CLK_NAME_LEN, "DSI%d", ctrl_pdata->ndx); ctrl_pdata->clk_mngr = mdss_dsi_clk_init(&info); if (IS_ERR_OR_NULL(ctrl_pdata->clk_mngr)) { rc = PTR_ERR(ctrl_pdata->clk_mngr); ctrl_pdata->clk_mngr = NULL; pr_err("dsi clock registration failed, rc = %d\n", rc); goto error_link_clk_deinit; } /* * There are two clients that control dsi clocks. MDP driver controls * the clock through MDSS_PANEL_EVENT_CLK_CTRL event and dsi driver * through clock interface. To differentiate between the votes from the * two clients, dsi driver will use two different handles to vote for * clock states from dsi and mdp driver. */ handle = mdss_dsi_clk_register(ctrl_pdata->clk_mngr, &client1); if (IS_ERR_OR_NULL(handle)) { rc = PTR_ERR(handle); pr_err("failed to register %s client, rc = %d\n", client1.client_name, rc); goto error_clk_deinit; } else { ctrl_pdata->dsi_clk_handle = handle; } handle = mdss_dsi_clk_register(ctrl_pdata->clk_mngr, &client2); if (IS_ERR_OR_NULL(handle)) { rc = PTR_ERR(handle); pr_err("failed to register %s client, rc = %d\n", client2.client_name, rc); goto error_clk_client_deregister; } else { ctrl_pdata->mdp_clk_handle = handle; } return rc; error_clk_client_deregister: mdss_dsi_clk_deregister(ctrl_pdata->dsi_clk_handle); error_clk_deinit: mdss_dsi_clk_deinit(ctrl_pdata); error_link_clk_deinit: mdss_dsi_link_clk_deinit(&ctrl_pdev->dev, ctrl_pdata); return rc; } static int mdss_dsi_set_clk_rates(struct mdss_dsi_ctrl_pdata *ctrl_pdata) { int rc = 0; rc = mdss_dsi_clk_set_link_rate(ctrl_pdata->dsi_clk_handle, MDSS_DSI_LINK_BYTE_CLK, ctrl_pdata->byte_clk_rate, MDSS_DSI_CLK_UPDATE_CLK_RATE_AT_ON); if (rc) { pr_err("%s: dsi_byte_clk - clk_set_rate failed\n", __func__); return rc; } rc = mdss_dsi_clk_set_link_rate(ctrl_pdata->dsi_clk_handle, MDSS_DSI_LINK_PIX_CLK, ctrl_pdata->pclk_rate, MDSS_DSI_CLK_UPDATE_CLK_RATE_AT_ON); if (rc) { pr_err("%s: dsi_pixel_clk - clk_set_rate failed\n", __func__); return rc; } rc = mdss_dsi_clk_set_link_rate(ctrl_pdata->dsi_clk_handle, MDSS_DSI_LINK_ESC_CLK, 19200000, MDSS_DSI_CLK_UPDATE_CLK_RATE_AT_ON); if (rc) { pr_err("%s: dsi_esc_clk - clk_set_rate failed\n", __func__); return rc; } return rc; } static int mdss_dsi_cont_splash_config(struct mdss_panel_info *pinfo, struct mdss_dsi_ctrl_pdata *ctrl_pdata) { void *clk_handle; int rc = 0, data; if (pinfo->cont_splash_enabled) { rc = mdss_dsi_panel_power_ctrl(&(ctrl_pdata->panel_data), MDSS_PANEL_POWER_ON); if (rc) { pr_err("%s: Panel power on failed\n", __func__); return rc; } if (ctrl_pdata->bklt_ctrl == BL_PWM) mdss_dsi_panel_pwm_enable(ctrl_pdata); ctrl_pdata->ctrl_state |= (CTRL_STATE_PANEL_INIT | CTRL_STATE_MDP_ACTIVE | CTRL_STATE_DSI_ACTIVE); if (ctrl_pdata->panel_data.panel_info.type == MIPI_CMD_PANEL) clk_handle = ctrl_pdata->mdp_clk_handle; else clk_handle = ctrl_pdata->dsi_clk_handle; mdss_dsi_clk_ctrl(ctrl_pdata, clk_handle, MDSS_DSI_ALL_CLKS, MDSS_DSI_CLK_ON); ctrl_pdata->is_phyreg_enabled = 1; mdss_dsi_get_hw_revision(ctrl_pdata); if ((ctrl_pdata->shared_data->hw_rev >= MDSS_DSI_HW_REV_103) && (pinfo->type == MIPI_CMD_PANEL)) { data = MIPI_INP(ctrl_pdata->ctrl_base + 0x1b8); if (data & BIT(16)) ctrl_pdata->burst_mode_enabled = true; } } else { pinfo->panel_power_state = MDSS_PANEL_POWER_OFF; } return rc; } static int mdss_dsi_ctrl_probe(struct platform_device *pdev) { int rc = 0; u32 index; struct mdss_dsi_ctrl_pdata *ctrl_pdata = NULL; struct mdss_panel_info *pinfo = NULL; struct device_node *dsi_pan_node = NULL; const char *ctrl_name; struct mdss_util_intf *util; if (!pdev || !pdev->dev.of_node) { pr_err("%s: pdev not found for DSI controller\n", __func__); return -ENODEV; } rc = of_property_read_u32(pdev->dev.of_node, "cell-index", &index); if (rc) { dev_err(&pdev->dev, "%s: Cell-index not specified, rc=%d\n", __func__, rc); return rc; } if (index == 0) pdev->id = 1; else pdev->id = 2; ctrl_pdata = mdss_dsi_get_ctrl(index); if (!ctrl_pdata) { pr_err("%s: Unable to get the ctrl_pdata\n", __func__); return -EINVAL; } platform_set_drvdata(pdev, ctrl_pdata); util = mdss_get_util_intf(); if (util == NULL) { pr_err("Failed to get mdss utility functions\n"); return -ENODEV; } ctrl_pdata->mdss_util = util; atomic_set(&ctrl_pdata->te_irq_ready, 0); ctrl_name = of_get_property(pdev->dev.of_node, "label", NULL); if (!ctrl_name) pr_info("%s:%d, DSI Ctrl name not specified\n", __func__, __LINE__); else pr_info("%s: DSI Ctrl name = %s\n", __func__, ctrl_name); rc = mdss_dsi_pinctrl_init(pdev); if (rc) pr_warn("%s: failed to get pin resources\n", __func__); if (index == 0) { ctrl_pdata->panel_data.panel_info.pdest = DISPLAY_1; ctrl_pdata->ndx = DSI_CTRL_0; } else { ctrl_pdata->panel_data.panel_info.pdest = DISPLAY_2; ctrl_pdata->ndx = DSI_CTRL_1; } if (mdss_dsi_ctrl_clock_init(pdev, ctrl_pdata)) { pr_err("%s: unable to initialize dsi clk manager\n", __func__); return -EPERM; } dsi_pan_node = mdss_dsi_config_panel(pdev, index); if (!dsi_pan_node) { pr_err("%s: panel configuration failed\n", __func__); return -EINVAL; } if (!mdss_dsi_is_hw_config_split(ctrl_pdata->shared_data) || (mdss_dsi_is_hw_config_split(ctrl_pdata->shared_data) && (ctrl_pdata->panel_data.panel_info.pdest == DISPLAY_1))) { rc = mdss_panel_parse_bl_settings(dsi_pan_node, ctrl_pdata); if (rc) { pr_warn("%s: dsi bl settings parse failed\n", __func__); /* Panels like AMOLED and dsi2hdmi chip * does not need backlight control. * So we should not fail probe here. */ ctrl_pdata->bklt_ctrl = UNKNOWN_CTRL; } } else { ctrl_pdata->bklt_ctrl = UNKNOWN_CTRL; } rc = dsi_panel_device_register(pdev, dsi_pan_node, ctrl_pdata); if (rc) { pr_err("%s: dsi panel dev reg failed\n", __func__); goto error_pan_node; } pinfo = &(ctrl_pdata->panel_data.panel_info); if (!(mdss_dsi_is_hw_config_split(ctrl_pdata->shared_data) && mdss_dsi_is_ctrl_clk_slave(ctrl_pdata)) && pinfo->dynamic_fps) { rc = mdss_dsi_shadow_clk_init(pdev, ctrl_pdata); if (rc) { pr_err("%s: unable to initialize shadow ctrl clks\n", __func__); rc = -EPERM; } } rc = mdss_dsi_set_clk_rates(ctrl_pdata); if (rc) { pr_err("%s: Failed to set dsi clk rates\n", __func__); return rc; } rc = mdss_dsi_cont_splash_config(pinfo, ctrl_pdata); if (rc) { pr_err("%s: Failed to set dsi splash config\n", __func__); return rc; } if (mdss_dsi_is_te_based_esd(ctrl_pdata)) { rc = devm_request_irq(&pdev->dev, gpio_to_irq(ctrl_pdata->disp_te_gpio), hw_vsync_handler, IRQF_TRIGGER_FALLING, "VSYNC_GPIO", ctrl_pdata); if (rc) { pr_err("TE request_irq failed.\n"); goto error_shadow_clk_deinit; } disable_irq(gpio_to_irq(ctrl_pdata->disp_te_gpio)); } ctrl_pdata->workq = create_workqueue("mdss_dsi_dba"); if (!ctrl_pdata->workq) { pr_err("%s: Error creating workqueue\n", __func__); rc = -EPERM; goto error_pan_node; } INIT_DELAYED_WORK(&ctrl_pdata->dba_work, mdss_dsi_dba_work); pr_debug("%s: Dsi Ctrl->%d initialized\n", __func__, index); if (index == 0) ctrl_pdata->shared_data->dsi0_active = true; else ctrl_pdata->shared_data->dsi1_active = true; mdss_dsi_pm_qos_add_request(); return 0; error_shadow_clk_deinit: mdss_dsi_shadow_clk_deinit(&pdev->dev, ctrl_pdata); error_pan_node: mdss_dsi_unregister_bl_settings(ctrl_pdata); of_node_put(dsi_pan_node); return rc; } static int mdss_dsi_bus_scale_init(struct platform_device *pdev, struct dsi_shared_data *sdata) { int rc = 0; sdata->bus_scale_table = msm_bus_cl_get_pdata(pdev); if (IS_ERR_OR_NULL(sdata->bus_scale_table)) { rc = PTR_ERR(sdata->bus_scale_table); pr_err("%s: msm_bus_cl_get_pdata() failed, rc=%d\n", __func__, rc); return rc; sdata->bus_scale_table = NULL; } sdata->bus_handle = msm_bus_scale_register_client(sdata->bus_scale_table); if (!sdata->bus_handle) { rc = -EINVAL; pr_err("%sbus_client register failed\n", __func__); } return rc; } static void mdss_dsi_bus_scale_deinit(struct dsi_shared_data *sdata) { if (sdata->bus_handle) { if (sdata->bus_refcount) msm_bus_scale_client_update_request(sdata->bus_handle, 0); sdata->bus_refcount = 0; msm_bus_scale_unregister_client(sdata->bus_handle); sdata->bus_handle = 0; } } static int mdss_dsi_parse_dt_params(struct platform_device *pdev, struct dsi_shared_data *sdata) { int rc = 0; rc = of_property_read_u32(pdev->dev.of_node, "qcom,mmss-ulp-clamp-ctrl-offset", &sdata->ulps_clamp_ctrl_off); if (!rc) { rc = of_property_read_u32(pdev->dev.of_node, "qcom,mmss-phyreset-ctrl-offset", &sdata->ulps_phyrst_ctrl_off); } sdata->cmd_clk_ln_recovery_en = of_property_read_bool(pdev->dev.of_node, "qcom,dsi-clk-ln-recovery"); return 0; } static void mdss_dsi_res_deinit(struct platform_device *pdev) { int i; struct mdss_dsi_data *dsi_res = platform_get_drvdata(pdev); struct dsi_shared_data *sdata; if (!dsi_res) { pr_err("%s: DSI root device drvdata not found\n", __func__); return; } for (i = 0; i < DSI_CTRL_MAX; i++) { if (dsi_res->ctrl_pdata[i]) { if (dsi_res->ctrl_pdata[i]->ds_registered) { struct mdss_panel_info *pinfo = &dsi_res->ctrl_pdata[i]-> panel_data.panel_info; if (pinfo) mdss_dba_utils_deinit(pinfo->dba_data); } devm_kfree(&pdev->dev, dsi_res->ctrl_pdata[i]); } } sdata = dsi_res->shared_data; if (!sdata) goto res_release; for (i = (DSI_MAX_PM - 1); i >= DSI_CORE_PM; i--) { if (msm_dss_config_vreg(&pdev->dev, sdata->power_data[i].vreg_config, sdata->power_data[i].num_vreg, 1) < 0) pr_err("%s: failed to de-init vregs for %s\n", __func__, __mdss_dsi_pm_name(i)); mdss_dsi_put_dt_vreg_data(&pdev->dev, &sdata->power_data[i]); } mdss_dsi_bus_scale_deinit(sdata); mdss_dsi_core_clk_deinit(&pdev->dev, sdata); if (sdata) devm_kfree(&pdev->dev, sdata); res_release: if (dsi_res) devm_kfree(&pdev->dev, dsi_res); return; } static int mdss_dsi_res_init(struct platform_device *pdev) { int rc = 0, i; struct dsi_shared_data *sdata; mdss_dsi_res = platform_get_drvdata(pdev); if (!mdss_dsi_res) { mdss_dsi_res = devm_kzalloc(&pdev->dev, sizeof(struct mdss_dsi_data), GFP_KERNEL); if (!mdss_dsi_res) { pr_err("%s: FAILED: cannot alloc dsi data\n", __func__); rc = -ENOMEM; goto mem_fail; } mdss_dsi_res->shared_data = devm_kzalloc(&pdev->dev, sizeof(struct dsi_shared_data), GFP_KERNEL); pr_debug("%s Allocated shared_data=%p\n", __func__, mdss_dsi_res->shared_data); if (!mdss_dsi_res->shared_data) { pr_err("%s Unable to alloc mem for shared_data\n", __func__); rc = -ENOMEM; goto mem_fail; } sdata = mdss_dsi_res->shared_data; rc = mdss_dsi_parse_dt_params(pdev, sdata); if (rc) { pr_err("%s: failed to parse mdss dsi DT params\n", __func__); goto mem_fail; } rc = mdss_dsi_core_clk_init(pdev, sdata); if (rc) { pr_err("%s: failed to initialize DSI core clocks\n", __func__); goto mem_fail; } /* Parse the regulator information */ for (i = DSI_CORE_PM; i < DSI_MAX_PM; i++) { rc = mdss_dsi_get_dt_vreg_data(&pdev->dev, pdev->dev.of_node, &sdata->power_data[i], i); if (rc) { pr_err("%s: '%s' get_dt_vreg_data failed.rc=%d\n", __func__, __mdss_dsi_pm_name(i), rc); i--; for (; i >= DSI_CORE_PM; i--) mdss_dsi_put_dt_vreg_data(&pdev->dev, &sdata->power_data[i]); goto mem_fail; } } rc = mdss_dsi_regulator_init(pdev, sdata); if (rc) { pr_err("%s: failed to init regulator, rc=%d\n", __func__, rc); goto mem_fail; } rc = mdss_dsi_bus_scale_init(pdev, sdata); if (rc) { pr_err("%s: failed to init bus scale settings, rc=%d\n", __func__, rc); goto mem_fail; } mutex_init(&sdata->phy_reg_lock); for (i = 0; i < DSI_CTRL_MAX; i++) { mdss_dsi_res->ctrl_pdata[i] = devm_kzalloc(&pdev->dev, sizeof(struct mdss_dsi_ctrl_pdata), GFP_KERNEL); if (!mdss_dsi_res->ctrl_pdata[i]) { pr_err("%s Unable to alloc mem for ctrl=%d\n", __func__, i); rc = -ENOMEM; goto mem_fail; } pr_debug("%s Allocated ctrl_pdata[%d]=%p\n", __func__, i, mdss_dsi_res->ctrl_pdata[i]); mdss_dsi_res->ctrl_pdata[i]->shared_data = mdss_dsi_res->shared_data; } platform_set_drvdata(pdev, mdss_dsi_res); } mdss_dsi_res->pdev = pdev; pr_debug("%s: Setting up mdss_dsi_res=%p\n", __func__, mdss_dsi_res); return 0; mem_fail: mdss_dsi_res_deinit(pdev); return rc; } static int mdss_dsi_parse_hw_cfg(struct platform_device *pdev, char *pan_cfg) { const char *data; struct mdss_dsi_data *dsi_res = platform_get_drvdata(pdev); struct dsi_shared_data *sdata; char dsi_cfg[20]; char *cfg_prim = NULL, *cfg_sec = NULL, *ch = NULL; int i = 0; if (!dsi_res) { pr_err("%s: DSI root device drvdata not found\n", __func__); return -EINVAL; } sdata = mdss_dsi_res->shared_data; if (!sdata) { pr_err("%s: DSI shared data not found\n", __func__); return -EINVAL; } sdata->hw_config = SINGLE_DSI; if (pan_cfg) cfg_prim = strnstr(pan_cfg, "cfg:", strlen(pan_cfg)); if (cfg_prim) { cfg_prim += 4; cfg_sec = strnchr(cfg_prim, strlen(cfg_prim), ':'); if (!cfg_sec) cfg_sec = cfg_prim + strlen(cfg_prim); for (i = 0; ((cfg_prim + i) < cfg_sec) && (*(cfg_prim+i) != '#'); i++) dsi_cfg[i] = *(cfg_prim + i); dsi_cfg[i] = '\0'; data = dsi_cfg; } else { data = of_get_property(pdev->dev.of_node, "hw-config", NULL); } if (data) { /* * To handle the override parameter (#override:sim) * passed for simulator panels */ ch = strnstr(data, "#", strlen(data)); ch ? *ch = '\0' : false; if (!strcmp(data, "dual_dsi")) sdata->hw_config = DUAL_DSI; else if (!strcmp(data, "split_dsi")) sdata->hw_config = SPLIT_DSI; else if (!strcmp(data, "single_dsi")) sdata->hw_config = SINGLE_DSI; else pr_err("%s: Incorrect string for DSI config:%s. Setting default as SINGLE_DSI\n", __func__, data); } else { pr_err("%s: Error: No DSI HW config found\n", __func__); return -EINVAL; } pr_debug("%s: DSI h/w configuration is %d\n", __func__, sdata->hw_config); return 0; } static void mdss_dsi_parse_pll_src_cfg(struct platform_device *pdev, char *pan_cfg) { const char *data; char *pll_ptr, pll_cfg[10] = {'\0'}; struct dsi_shared_data *sdata = mdss_dsi_res->shared_data; sdata->pll_src_config = PLL_SRC_DEFAULT; if (pan_cfg) { pll_ptr = strnstr(pan_cfg, ":pll0", strlen(pan_cfg)); if (!pll_ptr) { pll_ptr = strnstr(pan_cfg, ":pll1", strlen(pan_cfg)); if (pll_ptr) strlcpy(pll_cfg, "PLL1", strlen(pll_cfg)); } else { strlcpy(pll_cfg, "PLL0", strlen(pll_cfg)); } } data = pll_cfg; if (!data || !strcmp(data, "")) data = of_get_property(pdev->dev.of_node, "pll-src-config", NULL); if (data) { if (!strcmp(data, "PLL0")) sdata->pll_src_config = PLL_SRC_0; else if (!strcmp(data, "PLL1")) sdata->pll_src_config = PLL_SRC_1; else pr_err("%s: invalid pll src config %s\n", __func__, data); } else { pr_debug("%s: PLL src config not specified\n", __func__); } pr_debug("%s: pll_src_config = %d", __func__, sdata->pll_src_config); return; } static int mdss_dsi_validate_pll_src_config(struct dsi_shared_data *sdata) { int rc = 0; /* * DSI PLL1 can only drive DSI PHY1. As such: * - For split dsi config, only PLL0 is supported * - For dual dsi config, DSI0-PLL0 and DSI1-PLL1 is the only * possible configuration */ if (mdss_dsi_is_hw_config_split(sdata) && mdss_dsi_is_pll_src_pll1(sdata)) { pr_err("%s: unsupported PLL config: using PLL1 for split-dsi\n", __func__); rc = -EINVAL; goto error; } if (mdss_dsi_is_hw_config_dual(sdata) && !mdss_dsi_is_pll_src_default(sdata)) { pr_debug("%s: pll src config not applicable for dual-dsi\n", __func__); sdata->pll_src_config = PLL_SRC_DEFAULT; } error: return rc; } static int mdss_dsi_validate_config(struct platform_device *pdev) { struct dsi_shared_data *sdata = mdss_dsi_res->shared_data; return mdss_dsi_validate_pll_src_config(sdata); } static const struct of_device_id mdss_dsi_ctrl_dt_match[] = { {.compatible = "qcom,mdss-dsi-ctrl"}, {} }; MODULE_DEVICE_TABLE(of, mdss_dsi_ctrl_dt_match); static int mdss_dsi_probe(struct platform_device *pdev) { struct mdss_panel_cfg *pan_cfg = NULL; struct mdss_util_intf *util; char *panel_cfg; int rc = 0; util = mdss_get_util_intf(); if (util == NULL) { pr_err("%s: Failed to get mdss utility functions\n", __func__); return -ENODEV; } if (!util->mdp_probe_done) { pr_err("%s: MDP not probed yet!\n", __func__); return -EPROBE_DEFER; } if (!pdev || !pdev->dev.of_node) { pr_err("%s: DSI driver only supports device tree probe\n", __func__); return -ENOTSUPP; } pan_cfg = util->panel_intf_type(MDSS_PANEL_INTF_HDMI); if (IS_ERR(pan_cfg)) { return PTR_ERR(pan_cfg); } else if (pan_cfg) { pr_debug("%s: HDMI is primary\n", __func__); return -ENODEV; } pan_cfg = util->panel_intf_type(MDSS_PANEL_INTF_DSI); if (IS_ERR_OR_NULL(pan_cfg)) { rc = PTR_ERR(pan_cfg); goto error; } else { panel_cfg = pan_cfg->arg_cfg; } rc = mdss_dsi_res_init(pdev); if (rc) { pr_err("%s Unable to set dsi res\n", __func__); return rc; } rc = mdss_dsi_parse_hw_cfg(pdev, panel_cfg); if (rc) { pr_err("%s Unable to parse dsi h/w config\n", __func__); mdss_dsi_res_deinit(pdev); return rc; } mdss_dsi_parse_pll_src_cfg(pdev, panel_cfg); of_platform_populate(pdev->dev.of_node, mdss_dsi_ctrl_dt_match, NULL, &pdev->dev); rc = mdss_dsi_validate_config(pdev); if (rc) { pr_err("%s: Invalid DSI hw configuration\n", __func__); goto error; } mdss_dsi_config_clk_src(pdev); error: return rc; } static int mdss_dsi_remove(struct platform_device *pdev) { mdss_dsi_res_deinit(pdev); return 0; } static int mdss_dsi_ctrl_remove(struct platform_device *pdev) { struct msm_fb_data_type *mfd; struct mdss_dsi_ctrl_pdata *ctrl_pdata = platform_get_drvdata(pdev); if (!ctrl_pdata) { pr_err("%s: no driver data\n", __func__); return -ENODEV; } mdss_dsi_pm_qos_remove_request(); if (msm_dss_config_vreg(&pdev->dev, ctrl_pdata->panel_power_data.vreg_config, ctrl_pdata->panel_power_data.num_vreg, 1) < 0) pr_err("%s: failed to de-init vregs for %s\n", __func__, __mdss_dsi_pm_name(DSI_PANEL_PM)); mdss_dsi_put_dt_vreg_data(&pdev->dev, &ctrl_pdata->panel_power_data); mfd = platform_get_drvdata(pdev); msm_dss_iounmap(&ctrl_pdata->mmss_misc_io); msm_dss_iounmap(&ctrl_pdata->phy_io); msm_dss_iounmap(&ctrl_pdata->ctrl_io); mdss_dsi_debugfs_cleanup(ctrl_pdata); if (ctrl_pdata->workq) destroy_workqueue(ctrl_pdata->workq); return 0; } struct device dsi_dev; int mdss_dsi_retrieve_ctrl_resources(struct platform_device *pdev, int mode, struct mdss_dsi_ctrl_pdata *ctrl) { int rc = 0; u32 index; rc = of_property_read_u32(pdev->dev.of_node, "cell-index", &index); if (rc) { dev_err(&pdev->dev, "%s: Cell-index not specified, rc=%d\n", __func__, rc); return rc; } if (index == 0) { if (mode != DISPLAY_1) { pr_err("%s:%d Panel->Ctrl mapping is wrong\n", __func__, __LINE__); return -EPERM; } } else if (index == 1) { if (mode != DISPLAY_2) { pr_err("%s:%d Panel->Ctrl mapping is wrong\n", __func__, __LINE__); return -EPERM; } } else { pr_err("%s:%d Unknown Ctrl mapped to panel\n", __func__, __LINE__); return -EPERM; } rc = msm_dss_ioremap_byname(pdev, &ctrl->ctrl_io, "dsi_ctrl"); if (rc) { pr_err("%s:%d unable to remap dsi ctrl resources\n", __func__, __LINE__); return rc; } ctrl->ctrl_base = ctrl->ctrl_io.base; ctrl->reg_size = ctrl->ctrl_io.len; rc = msm_dss_ioremap_byname(pdev, &ctrl->phy_io, "dsi_phy"); if (rc) { pr_err("%s:%d unable to remap dsi phy resources\n", __func__, __LINE__); return rc; } rc = msm_dss_ioremap_byname(pdev, &ctrl->phy_regulator_io, "dsi_phy_regulator"); if (rc) pr_debug("%s:%d unable to remap dsi phy regulator resources\n", __func__, __LINE__); else pr_info("%s: phy_regulator_base=%p phy_regulator_size=%x\n", __func__, ctrl->phy_regulator_io.base, ctrl->phy_regulator_io.len); pr_info("%s: ctrl_base=%p ctrl_size=%x phy_base=%p phy_size=%x\n", __func__, ctrl->ctrl_base, ctrl->reg_size, ctrl->phy_io.base, ctrl->phy_io.len); rc = msm_dss_ioremap_byname(pdev, &ctrl->mmss_misc_io, "mmss_misc_phys"); if (rc) { pr_debug("%s:%d mmss_misc IO remap failed\n", __func__, __LINE__); } return 0; } static int mdss_dsi_irq_init(struct device *dev, int irq_no, struct mdss_dsi_ctrl_pdata *ctrl) { int ret; ret = devm_request_irq(dev, irq_no, mdss_dsi_isr, IRQF_DISABLED, "DSI", ctrl); if (ret) { pr_err("msm_dsi_irq_init request_irq() failed!\n"); return ret; } disable_irq(irq_no); ctrl->dsi_hw->irq_info = kzalloc(sizeof(struct irq_info), GFP_KERNEL); if (!ctrl->dsi_hw->irq_info) { pr_err("no mem to save irq info: kzalloc fail\n"); return -ENOMEM; } ctrl->dsi_hw->irq_info->irq = irq_no; ctrl->dsi_hw->irq_info->irq_ena = false; return ret; } static void mdss_dsi_parse_lane_swap(struct device_node *np, char *dlane_swap) { const char *data; *dlane_swap = DSI_LANE_MAP_0123; data = of_get_property(np, "qcom,lane-map", NULL); if (data) { if (!strcmp(data, "lane_map_3012")) *dlane_swap = DSI_LANE_MAP_3012; else if (!strcmp(data, "lane_map_2301")) *dlane_swap = DSI_LANE_MAP_2301; else if (!strcmp(data, "lane_map_1230")) *dlane_swap = DSI_LANE_MAP_1230; else if (!strcmp(data, "lane_map_0321")) *dlane_swap = DSI_LANE_MAP_0321; else if (!strcmp(data, "lane_map_1032")) *dlane_swap = DSI_LANE_MAP_1032; else if (!strcmp(data, "lane_map_2103")) *dlane_swap = DSI_LANE_MAP_2103; else if (!strcmp(data, "lane_map_3210")) *dlane_swap = DSI_LANE_MAP_3210; } } static int mdss_dsi_parse_ctrl_params(struct platform_device *ctrl_pdev, struct device_node *pan_node, struct mdss_dsi_ctrl_pdata *ctrl_pdata) { int i, len; struct mdss_panel_info *pinfo = &(ctrl_pdata->panel_data.panel_info); const char *data; ctrl_pdata->null_insert_enabled = of_property_read_bool( ctrl_pdev->dev.of_node, "qcom,null-insertion-enabled"); data = of_get_property(ctrl_pdev->dev.of_node, "qcom,platform-strength-ctrl", &len); if (!data) { pr_err("%s:%d, Unable to read Phy Strength ctrl settings\n", __func__, __LINE__); return -EINVAL; } else { pinfo->mipi.dsi_phy_db.strength_len = len; for (i = 0; i < len; i++) pinfo->mipi.dsi_phy_db.strength[i] = data[i]; } pinfo->mipi.dsi_phy_db.reg_ldo_mode = of_property_read_bool( ctrl_pdev->dev.of_node, "qcom,regulator-ldo-mode"); data = of_get_property(ctrl_pdev->dev.of_node, "qcom,platform-regulator-settings", &len); if (!data) { pr_err("%s:%d, Unable to read Phy regulator settings\n", __func__, __LINE__); return -EINVAL; } else { pinfo->mipi.dsi_phy_db.regulator_len = len; for (i = 0; i < len; i++) pinfo->mipi.dsi_phy_db.regulator[i] = data[i]; } data = of_get_property(ctrl_pdev->dev.of_node, "qcom,platform-bist-ctrl", &len); if ((!data) || (len != 6)) pr_debug("%s:%d, Unable to read Phy Bist Ctrl settings\n", __func__, __LINE__); else for (i = 0; i < len; i++) pinfo->mipi.dsi_phy_db.bistctrl[i] = data[i]; data = of_get_property(ctrl_pdev->dev.of_node, "qcom,platform-lane-config", &len); if (!data) { pr_err("%s:%d, Unable to read Phy lane configure settings\n", __func__, __LINE__); return -EINVAL; } else { pinfo->mipi.dsi_phy_db.lanecfg_len = len; for (i = 0; i < len; i++) pinfo->mipi.dsi_phy_db.lanecfg[i] = data[i]; } ctrl_pdata->timing_db_mode = of_property_read_bool( ctrl_pdev->dev.of_node, "qcom,timing-db-mode"); ctrl_pdata->cmd_sync_wait_broadcast = of_property_read_bool( pan_node, "qcom,cmd-sync-wait-broadcast"); if (ctrl_pdata->cmd_sync_wait_broadcast && mdss_dsi_is_hw_config_split(ctrl_pdata->shared_data) && (pinfo->pdest == DISPLAY_2)) ctrl_pdata->cmd_sync_wait_trigger = true; pr_debug("%s: cmd_sync_wait_enable=%d trigger=%d\n", __func__, ctrl_pdata->cmd_sync_wait_broadcast, ctrl_pdata->cmd_sync_wait_trigger); mdss_dsi_parse_lane_swap(ctrl_pdev->dev.of_node, &(ctrl_pdata->dlane_swap)); pinfo->is_pluggable = of_property_read_bool(ctrl_pdev->dev.of_node, "qcom,pluggable"); data = of_get_property(ctrl_pdev->dev.of_node, "qcom,display-id", &len); if (!data || len <= 0) pr_err("%s:%d Unable to read qcom,display-id, data=%p,len=%d\n", __func__, __LINE__, data, len); else snprintf(ctrl_pdata->panel_data.panel_info.display_id, MDSS_DISPLAY_ID_MAX_LEN, "%s", data); return 0; } static int mdss_dsi_parse_gpio_params(struct platform_device *ctrl_pdev, struct mdss_dsi_ctrl_pdata *ctrl_pdata) { struct mdss_panel_info *pinfo = &(ctrl_pdata->panel_data.panel_info); /* * If disp_en_gpio has been set previously (disp_en_gpio > 0) * while parsing the panel node, then do not override it */ if (ctrl_pdata->disp_en_gpio <= 0) { ctrl_pdata->disp_en_gpio = of_get_named_gpio( ctrl_pdev->dev.of_node, "qcom,platform-enable-gpio", 0); if (!gpio_is_valid(ctrl_pdata->disp_en_gpio)) pr_debug("%s:%d, Disp_en gpio not specified\n", __func__, __LINE__); } ctrl_pdata->disp_te_gpio = of_get_named_gpio(ctrl_pdev->dev.of_node, "qcom,platform-te-gpio", 0); if (!gpio_is_valid(ctrl_pdata->disp_te_gpio)) pr_err("%s:%d, TE gpio not specified\n", __func__, __LINE__); ctrl_pdata->bklt_en_gpio = of_get_named_gpio(ctrl_pdev->dev.of_node, "qcom,platform-bklight-en-gpio", 0); if (!gpio_is_valid(ctrl_pdata->bklt_en_gpio)) pr_info("%s: bklt_en gpio not specified\n", __func__); ctrl_pdata->rst_gpio = of_get_named_gpio(ctrl_pdev->dev.of_node, "qcom,platform-reset-gpio", 0); if (!gpio_is_valid(ctrl_pdata->rst_gpio)) pr_err("%s:%d, reset gpio not specified\n", __func__, __LINE__); if (pinfo->mode_gpio_state != MODE_GPIO_NOT_VALID) { ctrl_pdata->mode_gpio = of_get_named_gpio( ctrl_pdev->dev.of_node, "qcom,platform-mode-gpio", 0); if (!gpio_is_valid(ctrl_pdata->mode_gpio)) pr_info("%s:%d, mode gpio not specified\n", __func__, __LINE__); } else { ctrl_pdata->mode_gpio = -EINVAL; } return 0; } static void mdss_dsi_set_prim_panel(struct mdss_dsi_ctrl_pdata *ctrl_pdata) { struct mdss_dsi_ctrl_pdata *octrl = NULL; struct mdss_panel_info *pinfo; pinfo = &ctrl_pdata->panel_data.panel_info; /* * for Split and Single DSI case default is always primary * and for Dual dsi case below assumptions are made. * 1. DSI controller with bridge chip is always secondary * 2. When there is no brigde chip, DSI1 is secondary */ pinfo->is_prim_panel = true; if (mdss_dsi_is_hw_config_dual(ctrl_pdata->shared_data)) { if (mdss_dsi_is_right_ctrl(ctrl_pdata)) { octrl = mdss_dsi_get_other_ctrl(ctrl_pdata); if (octrl && octrl->panel_data.panel_info.is_prim_panel) pinfo->is_prim_panel = false; else pinfo->is_prim_panel = true; } } } int dsi_panel_device_register(struct platform_device *ctrl_pdev, struct device_node *pan_node, struct mdss_dsi_ctrl_pdata *ctrl_pdata) { struct mipi_panel_info *mipi; int rc; struct dsi_shared_data *sdata; struct mdss_panel_info *pinfo = &(ctrl_pdata->panel_data.panel_info); struct resource *res; u64 clk_rate; mipi = &(pinfo->mipi); pinfo->type = ((mipi->mode == DSI_VIDEO_MODE) ? MIPI_VIDEO_PANEL : MIPI_CMD_PANEL); rc = mdss_dsi_clk_div_config(pinfo, mipi->frame_rate); if (rc) { pr_err("%s: unable to initialize the clk dividers\n", __func__); return rc; } ctrl_pdata->pclk_rate = mipi->dsi_pclk_rate; clk_rate = pinfo->clk_rate; do_div(clk_rate, 8U); ctrl_pdata->byte_clk_rate = (u32)clk_rate; pr_debug("%s: pclk=%d, bclk=%d\n", __func__, ctrl_pdata->pclk_rate, ctrl_pdata->byte_clk_rate); rc = mdss_dsi_get_dt_vreg_data(&ctrl_pdev->dev, pan_node, &ctrl_pdata->panel_power_data, DSI_PANEL_PM); if (rc) { DEV_ERR("%s: '%s' get_dt_vreg_data failed.rc=%d\n", __func__, __mdss_dsi_pm_name(DSI_PANEL_PM), rc); return rc; } rc = msm_dss_config_vreg(&ctrl_pdev->dev, ctrl_pdata->panel_power_data.vreg_config, ctrl_pdata->panel_power_data.num_vreg, 1); if (rc) { pr_err("%s: failed to init regulator, rc=%d\n", __func__, rc); return rc; } rc = mdss_dsi_parse_ctrl_params(ctrl_pdev, pan_node, ctrl_pdata); if (rc) { pr_err("%s: failed to parse ctrl settings, rc=%d\n", __func__, rc); return rc; } pinfo->panel_max_fps = mdss_panel_get_framerate(pinfo); pinfo->panel_max_vtotal = mdss_panel_get_vtotal(pinfo); rc = mdss_dsi_parse_gpio_params(ctrl_pdev, ctrl_pdata); if (rc) { pr_err("%s: failed to parse gpio params, rc=%d\n", __func__, rc); return rc; } if (mdss_dsi_retrieve_ctrl_resources(ctrl_pdev, pinfo->pdest, ctrl_pdata)) { pr_err("%s: unable to get Dsi controller res\n", __func__); return -EPERM; } ctrl_pdata->panel_data.event_handler = mdss_dsi_event_handler; ctrl_pdata->panel_data.get_fb_node = mdss_dsi_get_fb_node_cb; if (ctrl_pdata->status_mode == ESD_REG || ctrl_pdata->status_mode == ESD_REG_NT35596) ctrl_pdata->check_status = mdss_dsi_reg_status_check; else if (ctrl_pdata->status_mode == ESD_BTA) ctrl_pdata->check_status = mdss_dsi_bta_status_check; if (ctrl_pdata->status_mode == ESD_MAX) { pr_err("%s: Using default BTA for ESD check\n", __func__); ctrl_pdata->check_status = mdss_dsi_bta_status_check; } if (ctrl_pdata->bklt_ctrl == BL_PWM) mdss_dsi_panel_pwm_cfg(ctrl_pdata); mdss_dsi_ctrl_init(&ctrl_pdev->dev, ctrl_pdata); mdss_dsi_set_prim_panel(ctrl_pdata); ctrl_pdata->dsi_irq_line = of_property_read_bool( ctrl_pdev->dev.of_node, "qcom,dsi-irq-line"); if (ctrl_pdata->dsi_irq_line) { /* DSI has it's own irq line */ res = platform_get_resource(ctrl_pdev, IORESOURCE_IRQ, 0); if (!res || res->start == 0) { pr_err("%s:%d unable to get the MDSS irq resources\n", __func__, __LINE__); return -ENODEV; } rc = mdss_dsi_irq_init(&ctrl_pdev->dev, res->start, ctrl_pdata); if (rc) { dev_err(&ctrl_pdev->dev, "%s: failed to init irq\n", __func__); return rc; } } ctrl_pdata->ctrl_state = CTRL_STATE_UNKNOWN; /* * If ULPS during suspend is enabled, add an extra vote for the * DSI CTRL power module. This keeps the regulator always enabled. * This is needed for the DSI PHY to maintain ULPS state during * suspend also. */ sdata = ctrl_pdata->shared_data; if (pinfo->ulps_suspend_enabled) { rc = msm_dss_enable_vreg( sdata->power_data[DSI_PHY_PM].vreg_config, sdata->power_data[DSI_PHY_PM].num_vreg, 1); if (rc) { pr_err("%s: failed to enable vregs for DSI_CTRL_PM\n", __func__); return rc; } } pinfo->cont_splash_enabled = ctrl_pdata->mdss_util->panel_intf_status(pinfo->pdest, MDSS_PANEL_INTF_DSI) ? true : false; pr_info("%s: Continuous splash %s\n", __func__, pinfo->cont_splash_enabled ? "enabled" : "disabled"); rc = mdss_register_panel(ctrl_pdev, &(ctrl_pdata->panel_data)); if (rc) { pr_err("%s: unable to register MIPI DSI panel\n", __func__); return rc; } if (pinfo->pdest == DISPLAY_1) { mdss_debug_register_io("dsi0_ctrl", &ctrl_pdata->ctrl_io, NULL); mdss_debug_register_io("dsi0_phy", &ctrl_pdata->phy_io, NULL); if (ctrl_pdata->phy_regulator_io.len) mdss_debug_register_io("dsi0_phy_regulator", &ctrl_pdata->phy_regulator_io, NULL); } else { mdss_debug_register_io("dsi1_ctrl", &ctrl_pdata->ctrl_io, NULL); mdss_debug_register_io("dsi1_phy", &ctrl_pdata->phy_io, NULL); if (ctrl_pdata->phy_regulator_io.len) mdss_debug_register_io("dsi1_phy_regulator", &ctrl_pdata->phy_regulator_io, NULL); } panel_debug_register_base("panel", ctrl_pdata->ctrl_base, ctrl_pdata->reg_size); pr_debug("%s: Panel data initialized\n", __func__); return 0; } static const struct of_device_id mdss_dsi_dt_match[] = { {.compatible = "qcom,mdss-dsi"}, {} }; MODULE_DEVICE_TABLE(of, mdss_dsi_dt_match); static struct platform_driver mdss_dsi_driver = { .probe = mdss_dsi_probe, .remove = mdss_dsi_remove, .shutdown = NULL, .driver = { .name = "mdss_dsi", .of_match_table = mdss_dsi_dt_match, }, }; static struct platform_driver mdss_dsi_ctrl_driver = { .probe = mdss_dsi_ctrl_probe, .remove = mdss_dsi_ctrl_remove, .shutdown = NULL, .driver = { .name = "mdss_dsi_ctrl", .of_match_table = mdss_dsi_ctrl_dt_match, }, }; static int mdss_dsi_register_driver(void) { return platform_driver_register(&mdss_dsi_driver); } static int __init mdss_dsi_driver_init(void) { int ret; ret = mdss_dsi_register_driver(); if (ret) { pr_err("mdss_dsi_register_driver() failed!\n"); return ret; } return ret; } module_init(mdss_dsi_driver_init); static int mdss_dsi_ctrl_register_driver(void) { return platform_driver_register(&mdss_dsi_ctrl_driver); } static int __init mdss_dsi_ctrl_driver_init(void) { int ret; ret = mdss_dsi_ctrl_register_driver(); if (ret) { pr_err("mdss_dsi_ctrl_register_driver() failed!\n"); return ret; } return ret; } module_init(mdss_dsi_ctrl_driver_init); static void __exit mdss_dsi_driver_cleanup(void) { platform_driver_unregister(&mdss_dsi_ctrl_driver); } module_exit(mdss_dsi_driver_cleanup); MODULE_LICENSE("GPL v2"); MODULE_DESCRIPTION("DSI controller driver"); MODULE_AUTHOR("Chandan Uddaraju ");