/* Copyright (c) 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. * */ #define pr_fmt(fmt) "mdss-dsi-clk:[%s] " fmt, __func__ #include #include #include #include "mdss_dsi_clk.h" #include "mdss_dsi.h" #include "mdss_debug.h" #define MAX_CLIENT_NAME_LEN 20 struct dsi_core_clks { struct mdss_dsi_core_clk_info clks; u32 current_clk_state; }; struct dsi_link_clks { struct mdss_dsi_link_clk_info clks; u32 current_clk_state; u32 byte_clk_rate; u32 pix_clk_rate; u32 esc_clk_rate; }; struct mdss_dsi_clk_mngr { char name[DSI_CLK_NAME_LEN]; struct dsi_core_clks core_clks; struct dsi_link_clks link_clks; struct reg_bus_client *reg_bus_clt; pre_clockoff_cb pre_clkoff_cb; post_clockoff_cb post_clkoff_cb; post_clockon_cb post_clkon_cb; pre_clockon_cb pre_clkon_cb; struct list_head client_list; struct mutex clk_mutex; void *priv_data; }; struct mdss_dsi_clk_client_info { char name[MAX_CLIENT_NAME_LEN]; u32 core_refcount; u32 link_refcount; u32 core_clk_state; u32 link_clk_state; struct list_head list; struct mdss_dsi_clk_mngr *mngr; }; static int dsi_core_clk_start(struct dsi_core_clks *c_clks) { int rc = 0; struct mdss_dsi_clk_mngr *mngr; mngr = container_of(c_clks, struct mdss_dsi_clk_mngr, core_clks); rc = clk_prepare_enable(c_clks->clks.mdp_core_clk); if (rc) { pr_err("%s: failed to enable mdp_core_clock. rc=%d\n", __func__, rc); goto error; } rc = clk_prepare_enable(c_clks->clks.ahb_clk); if (rc) { pr_err("%s: failed to enable ahb clock. rc=%d\n", __func__, rc); goto disable_core_clk; } rc = clk_prepare_enable(c_clks->clks.axi_clk); if (rc) { pr_err("%s: failed to enable ahb clock. rc=%d\n", __func__, rc); goto disable_ahb_clk; } if (c_clks->clks.mmss_misc_ahb_clk) { rc = clk_prepare_enable(c_clks->clks.mmss_misc_ahb_clk); if (rc) { pr_err("%s: failed to enable mmss misc ahb clk.rc=%d\n", __func__, rc); goto disable_axi_clk; } } rc = mdss_update_reg_bus_vote(mngr->reg_bus_clt, VOTE_INDEX_19_MHZ); if (rc) { pr_err("failed to vote for reg bus\n"); goto disable_mmss_misc_clk; } pr_debug("%s:CORE CLOCK IS ON\n", mngr->name); return rc; disable_mmss_misc_clk: if (c_clks->clks.mmss_misc_ahb_clk) clk_disable_unprepare(c_clks->clks.mmss_misc_ahb_clk); disable_axi_clk: clk_disable_unprepare(c_clks->clks.axi_clk); disable_ahb_clk: clk_disable_unprepare(c_clks->clks.ahb_clk); disable_core_clk: clk_disable_unprepare(c_clks->clks.mdp_core_clk); error: pr_debug("%s: EXIT, rc = %d\n", mngr->name, rc); return rc; } static int dsi_core_clk_stop(struct dsi_core_clks *c_clks) { int rc = 0; struct mdss_dsi_clk_mngr *mngr; mngr = container_of(c_clks, struct mdss_dsi_clk_mngr, core_clks); mdss_update_reg_bus_vote(mngr->reg_bus_clt, VOTE_INDEX_DISABLE); if (c_clks->clks.mmss_misc_ahb_clk) clk_disable_unprepare(c_clks->clks.mmss_misc_ahb_clk); clk_disable_unprepare(c_clks->clks.axi_clk); clk_disable_unprepare(c_clks->clks.ahb_clk); clk_disable_unprepare(c_clks->clks.mdp_core_clk); pr_debug("%s: CORE CLOCK IS OFF\n", mngr->name); return rc; } static int dsi_link_clk_set_rate(struct dsi_link_clks *l_clks) { int rc = 0; struct mdss_dsi_clk_mngr *mngr; struct mdss_dsi_ctrl_pdata *ctrl; mngr = container_of(l_clks, struct mdss_dsi_clk_mngr, link_clks); /* * In an ideal world, cont_splash_enabled should not be required inside * the clock manager. But, in the current driver cont_splash_enabled * flag is set inside mdp driver and there is no interface event * associated with this flag setting. Also, set rate for clock need not * be called for every enable call. It should be done only once when * coming out of suspend. */ ctrl = mngr->priv_data; if (ctrl->panel_data.panel_info.cont_splash_enabled) return 0; rc = clk_set_rate(l_clks->clks.esc_clk, l_clks->esc_clk_rate); if (rc) { pr_err("clk_set_rate failed for esc_clk rc = %d\n", rc); goto error; } rc = clk_set_rate(l_clks->clks.byte_clk, l_clks->byte_clk_rate); if (rc) { pr_err("clk_set_rate failed for byte_clk rc = %d\n", rc); goto error; } rc = clk_set_rate(l_clks->clks.pixel_clk, l_clks->pix_clk_rate); if (rc) { pr_err("clk_set_rate failed for pixel_clk rc = %d\n", rc); goto error; } error: return rc; } static int dsi_link_clk_prepare(struct dsi_link_clks *l_clks) { int rc = 0; rc = clk_prepare(l_clks->clks.esc_clk); if (rc) { pr_err("%s: Failed to prepare dsi esc clk\n", __func__); goto esc_clk_err; } rc = clk_prepare(l_clks->clks.byte_clk); if (rc) { pr_err("%s: Failed to prepare dsi byte clk\n", __func__); goto byte_clk_err; } rc = clk_prepare(l_clks->clks.pixel_clk); if (rc) { pr_err("%s: Failed to prepare dsi pixel clk\n", __func__); goto pixel_clk_err; } return rc; pixel_clk_err: clk_unprepare(l_clks->clks.byte_clk); byte_clk_err: clk_unprepare(l_clks->clks.esc_clk); esc_clk_err: return rc; } static int dsi_link_clk_unprepare(struct dsi_link_clks *l_clks) { int rc = 0; clk_unprepare(l_clks->clks.pixel_clk); clk_unprepare(l_clks->clks.byte_clk); clk_unprepare(l_clks->clks.esc_clk); return rc; } static int dsi_link_clk_enable(struct dsi_link_clks *l_clks) { int rc = 0; rc = clk_enable(l_clks->clks.esc_clk); if (rc) { pr_err("%s: Failed to enable dsi esc clk\n", __func__); goto esc_clk_err; } rc = clk_enable(l_clks->clks.byte_clk); if (rc) { pr_err("%s: Failed to enable dsi byte clk\n", __func__); goto byte_clk_err; } rc = clk_enable(l_clks->clks.pixel_clk); if (rc) { pr_err("%s: Failed to enable dsi pixel clk\n", __func__); goto pixel_clk_err; } return rc; pixel_clk_err: clk_disable(l_clks->clks.byte_clk); byte_clk_err: clk_disable(l_clks->clks.esc_clk); esc_clk_err: return rc; } static int dsi_link_clk_disable(struct dsi_link_clks *l_clks) { int rc = 0; clk_disable(l_clks->clks.esc_clk); clk_disable(l_clks->clks.pixel_clk); clk_disable(l_clks->clks.byte_clk); return rc; } static int dsi_link_clk_start(struct dsi_link_clks *l_clks) { int rc = 0; struct mdss_dsi_clk_mngr *mngr; mngr = container_of(l_clks, struct mdss_dsi_clk_mngr, link_clks); rc = dsi_link_clk_set_rate(l_clks); if (rc) { pr_err("failed to set clk rates, rc = %d\n", rc); goto error; } rc = dsi_link_clk_prepare(l_clks); if (rc) { pr_err("failed to prepare link clks, rc = %d\n", rc); goto error; } rc = dsi_link_clk_enable(l_clks); if (rc) { pr_err("failed to enable link clks, rc = %d\n", rc); goto error_unprepare; } pr_debug("%s: LINK CLOCK IS ON\n", mngr->name); return rc; error_unprepare: dsi_link_clk_unprepare(l_clks); error: return rc; } static int dsi_link_clk_stop(struct dsi_link_clks *l_clks) { int rc = 0; struct mdss_dsi_clk_mngr *mngr; mngr = container_of(l_clks, struct mdss_dsi_clk_mngr, link_clks); (void)dsi_link_clk_disable(l_clks); (void)dsi_link_clk_unprepare(l_clks); pr_debug("%s: LINK CLOCK IS OFF\n", mngr->name); return rc; } static int dsi_update_clk_state(struct dsi_core_clks *c_clks, u32 c_state, struct dsi_link_clks *l_clks, u32 l_state) { int rc = 0; struct mdss_dsi_clk_mngr *mngr; bool l_c_on = false; if (c_clks) { mngr = container_of(c_clks, struct mdss_dsi_clk_mngr, core_clks); } else if (l_clks) { mngr = container_of(l_clks, struct mdss_dsi_clk_mngr, link_clks); } else { mngr = NULL; } pr_debug("%s: c_state = %d, l_state = %d\n", mngr ? mngr->name : "NA", c_clks ? c_state : -1, l_clks ? l_state : -1); /* * Clock toggle order: * 1. When turning on, Core clocks before link clocks * 2. When turning off, Link clocks before core clocks. */ if (c_clks && (c_state == MDSS_DSI_CLK_ON)) { if (c_clks->current_clk_state == MDSS_DSI_CLK_OFF) { rc = mngr->pre_clkon_cb(mngr->priv_data, MDSS_DSI_CORE_CLK, MDSS_DSI_CLK_ON); if (rc) { pr_err("failed to turn on MDP FS rc= %d\n", rc); goto error; } } rc = dsi_core_clk_start(c_clks); if (rc) { pr_err("failed to turn on core clks rc = %d\n", rc); goto error; } if (mngr->post_clkon_cb) { rc = mngr->post_clkon_cb(mngr->priv_data, MDSS_DSI_CORE_CLK, MDSS_DSI_CLK_ON); if (rc) pr_err("post clk on cb failed, rc = %d\n", rc); } c_clks->current_clk_state = MDSS_DSI_CLK_ON; } if (l_clks) { if (l_state == MDSS_DSI_CLK_ON) { if (mngr->pre_clkon_cb) { rc = mngr->pre_clkon_cb(mngr->priv_data, MDSS_DSI_LINK_CLK, l_state); if (rc) pr_err("pre link clk on cb failed\n"); } rc = dsi_link_clk_start(l_clks); if (rc) { pr_err("failed to start link clk rc= %d\n", rc); goto error; } if (mngr->post_clkon_cb) { rc = mngr->post_clkon_cb(mngr->priv_data, MDSS_DSI_LINK_CLK, l_state); if (rc) pr_err("post link clk on cb failed\n"); } } else { /* * Two conditions that need to be checked for Link * clocks: * 1. Link clocks need core clocks to be on when * transitioning from EARLY_GATE to OFF state. * 2. ULPS mode might have to be enabled in case of OFF * state. For ULPS, Link clocks should be turned ON * first before they are turned off again. * * If Link is going from EARLY_GATE to OFF state AND * Core clock is already in EARLY_GATE or OFF state, * turn on Core clocks and link clocks. * * ULPS state is managed as part of the pre_clkoff_cb. */ if ((l_state == MDSS_DSI_CLK_OFF) && (l_clks->current_clk_state == MDSS_DSI_CLK_EARLY_GATE) && (mngr->core_clks.current_clk_state != MDSS_DSI_CLK_ON)) { rc = dsi_core_clk_start(&mngr->core_clks); if (rc) { pr_err("core clks did not start\n"); goto error; } rc = dsi_link_clk_start(l_clks); if (rc) { pr_err("Link clks did not start\n"); goto error; } l_c_on = true; pr_debug("ECG: core and Link_on\n"); } if (mngr->pre_clkoff_cb) { rc = mngr->pre_clkoff_cb(mngr->priv_data, MDSS_DSI_LINK_CLK, l_state); if (rc) pr_err("pre link clk off cb failed\n"); } rc = dsi_link_clk_stop(l_clks); if (rc) { pr_err("failed to stop link clk, rc = %d\n", rc); goto error; } if (mngr->post_clkoff_cb) { rc = mngr->post_clkoff_cb(mngr->priv_data, MDSS_DSI_LINK_CLK, l_state); if (rc) pr_err("post link clk off cb failed\n"); } /* * This check is to save unnecessary clock state * change when going from EARLY_GATE to OFF. In the * case where the request happens for both Core and Link * clocks in the same call, core clocks need to be * turned on first before OFF state can be entered. * * Core clocks are turned on here for Link clocks to go * to OFF state. If core clock request is also present, * then core clocks can be turned off Core clocks are * transitioned to OFF state. */ if (l_c_on && (!(c_clks && (c_state == MDSS_DSI_CLK_OFF) && (c_clks->current_clk_state == MDSS_DSI_CLK_EARLY_GATE)))) { rc = dsi_core_clk_stop(&mngr->core_clks); if (rc) { pr_err("core clks did not stop\n"); goto error; } l_c_on = false; pr_debug("ECG: core off\n"); } else pr_debug("ECG: core off skip\n"); } l_clks->current_clk_state = l_state; } if (c_clks && (c_state != MDSS_DSI_CLK_ON)) { /* * When going to OFF state from EARLY GATE state, Core clocks * should be turned on first so that the IOs can be clamped. * l_c_on flag is set, then the core clocks were turned before * to the Link clocks go to OFF state. So Core clocks are * already ON and this step can be skipped. * * IOs are clamped in pre_clkoff_cb callback. */ if ((c_state == MDSS_DSI_CLK_OFF) && (c_clks->current_clk_state == MDSS_DSI_CLK_EARLY_GATE) && !l_c_on) { rc = dsi_core_clk_start(&mngr->core_clks); if (rc) { pr_err("core clks did not start\n"); goto error; } pr_debug("ECG: core on\n"); } else pr_debug("ECG: core on skip\n"); if (mngr->pre_clkoff_cb) { rc = mngr->pre_clkoff_cb(mngr->priv_data, MDSS_DSI_CORE_CLK, c_state); if (rc) pr_err("pre core clk off cb failed\n"); } rc = dsi_core_clk_stop(c_clks); if (rc) { pr_err("failed to turn off core clks rc = %d\n", rc); goto error; } if (c_state == MDSS_DSI_CLK_OFF) { if (mngr->post_clkoff_cb) { rc = mngr->post_clkoff_cb(mngr->priv_data, MDSS_DSI_CORE_CLK, MDSS_DSI_CLK_OFF); if (rc) pr_err("post clkoff cb fail, rc = %d\n", rc); } } c_clks->current_clk_state = c_state; } error: return rc; } static int dsi_recheck_clk_state(struct mdss_dsi_clk_mngr *mngr) { int rc = 0; struct list_head *pos = NULL; struct mdss_dsi_clk_client_info *c; u32 new_core_clk_state = MDSS_DSI_CLK_OFF; u32 new_link_clk_state = MDSS_DSI_CLK_OFF; u32 old_c_clk_state = MDSS_DSI_CLK_OFF; u32 old_l_clk_state = MDSS_DSI_CLK_OFF; struct dsi_core_clks *c_clks = NULL; struct dsi_link_clks *l_clks = NULL; /* * Rules to maintain clock state: * 1. If any client is in ON state, clocks should be ON. * 2. If any client is in ECG state with rest of them turned OFF, * go to Early gate state. * 3. If all clients are off, then goto OFF state. */ list_for_each(pos, &mngr->client_list) { c = list_entry(pos, struct mdss_dsi_clk_client_info, list); if (c->core_clk_state == MDSS_DSI_CLK_ON) { new_core_clk_state = MDSS_DSI_CLK_ON; break; } else if (c->core_clk_state == MDSS_DSI_CLK_EARLY_GATE) { new_core_clk_state = MDSS_DSI_CLK_EARLY_GATE; } } list_for_each(pos, &mngr->client_list) { c = list_entry(pos, struct mdss_dsi_clk_client_info, list); if (c->link_clk_state == MDSS_DSI_CLK_ON) { new_link_clk_state = MDSS_DSI_CLK_ON; break; } else if (c->link_clk_state == MDSS_DSI_CLK_EARLY_GATE) { new_link_clk_state = MDSS_DSI_CLK_EARLY_GATE; } } if (new_core_clk_state != mngr->core_clks.current_clk_state) c_clks = &mngr->core_clks; if (new_link_clk_state != mngr->link_clks.current_clk_state) l_clks = &mngr->link_clks; old_c_clk_state = mngr->core_clks.current_clk_state; old_l_clk_state = mngr->link_clks.current_clk_state; pr_debug("%s: c_clk_state (%d -> %d)\n", mngr->name, old_c_clk_state, new_core_clk_state); pr_debug("%s: l_clk_state (%d -> %d)\n", mngr->name, old_l_clk_state, new_link_clk_state); MDSS_XLOG(old_c_clk_state, new_core_clk_state, old_l_clk_state, new_link_clk_state); if (c_clks || l_clks) { rc = dsi_update_clk_state(c_clks, new_core_clk_state, l_clks, new_link_clk_state); if (rc) { pr_err("failed to update clock state, rc = %d\n", rc); goto error; } } error: return rc; } static int dsi_set_clk_rate(struct mdss_dsi_clk_mngr *mngr, int clk, u32 rate, u32 flags) { int rc = 0; pr_debug("%s: clk = %d, rate = %d, flags = %d\n", mngr->name, clk, rate, flags); MDSS_XLOG(clk, rate, flags); switch (clk) { case MDSS_DSI_LINK_ESC_CLK: mngr->link_clks.esc_clk_rate = rate; if (!flags) { rc = clk_set_rate(mngr->link_clks.clks.esc_clk, rate); if (rc) pr_err("set rate failed for esc clk rc=%d\n", rc); } break; case MDSS_DSI_LINK_BYTE_CLK: mngr->link_clks.byte_clk_rate = rate; if (!flags) { rc = clk_set_rate(mngr->link_clks.clks.byte_clk, rate); if (rc) pr_err("set rate failed for byte clk rc=%d\n", rc); } break; case MDSS_DSI_LINK_PIX_CLK: mngr->link_clks.pix_clk_rate = rate; if (!flags) { rc = clk_set_rate(mngr->link_clks.clks.pixel_clk, rate); if (rc) pr_err("failed to set rate for pix clk rc=%d\n", rc); } break; default: pr_err("Unsupported clock (%d)\n", clk); rc = -ENOTSUPP; break; } return rc; } void *mdss_dsi_clk_register(void *clk_mngr, struct mdss_dsi_clk_client *client) { void *handle = NULL; struct mdss_dsi_clk_mngr *mngr = clk_mngr; struct mdss_dsi_clk_client_info *c; if (!mngr) { pr_err("bad params\n"); return ERR_PTR(-EINVAL); } pr_debug("%s: ENTER\n", mngr->name); mutex_lock(&mngr->clk_mutex); c = kzalloc(sizeof(*c), GFP_KERNEL); if (!c) { handle = ERR_PTR(-ENOMEM); goto error; } strlcpy(c->name, client->client_name, MAX_CLIENT_NAME_LEN); c->mngr = mngr; list_add(&c->list, &mngr->client_list); pr_debug("%s: Added new client (%s)\n", mngr->name, c->name); handle = c; error: mutex_unlock(&mngr->clk_mutex); pr_debug("%s: EXIT, rc = %ld\n", mngr->name, PTR_ERR(handle)); return handle; } int mdss_dsi_clk_deregister(void *client) { int rc = 0; struct mdss_dsi_clk_client_info *c = client; struct mdss_dsi_clk_mngr *mngr; struct list_head *pos = NULL; struct list_head *tmp = NULL; struct mdss_dsi_clk_client_info *node; if (!client) { pr_err("Invalid params\n"); return -EINVAL; } mngr = c->mngr; pr_debug("%s: ENTER\n", mngr->name); mutex_lock(&mngr->clk_mutex); c->core_clk_state = MDSS_DSI_CLK_OFF; c->link_clk_state = MDSS_DSI_CLK_OFF; rc = dsi_recheck_clk_state(mngr); if (rc) { pr_err("clock state recheck failed rc = %d\n", rc); goto error; } list_for_each_safe(pos, tmp, &mngr->client_list) { node = list_entry(pos, struct mdss_dsi_clk_client_info, list); if (node == c) { list_del(&node->list); pr_debug("Removed device (%s)\n", node->name); kfree(node); break; } } error: mutex_unlock(&mngr->clk_mutex); pr_debug("%s: EXIT, rc = %d\n", mngr->name, rc); return rc; } int mdss_dsi_clk_req_state(void *client, enum mdss_dsi_clk_type clk, enum mdss_dsi_clk_state state) { int rc = 0; struct mdss_dsi_clk_client_info *c = client; struct mdss_dsi_clk_mngr *mngr; bool changed = false; if (!client || !clk || clk > (MDSS_DSI_CORE_CLK | MDSS_DSI_LINK_CLK) || state > MDSS_DSI_CLK_EARLY_GATE) { pr_err("Invalid params, client = %p, clk = 0x%x, state = %d\n", client, clk, state); return -EINVAL; } mngr = c->mngr; mutex_lock(&mngr->clk_mutex); pr_debug("[%s]%s: CLK=%d, new_state=%d, core=%d, linkl=%d\n", c->name, mngr->name, clk, state, c->core_clk_state, c->link_clk_state); MDSS_XLOG(clk, state, c->core_clk_state, c->link_clk_state); /* * Refcount handling rules: * 1. Increment refcount whenever ON is called * 2. Do not decrement when going from EARLY_GATE to OFF. * 3. Decrement refcount when either OFF or EARLY_GATE is called */ if (state == MDSS_DSI_CLK_ON) { if (clk & MDSS_DSI_CORE_CLK) { c->core_refcount++; if (c->core_clk_state != MDSS_DSI_CLK_ON) { c->core_clk_state = MDSS_DSI_CLK_ON; changed = true; } } if (clk & MDSS_DSI_LINK_CLK) { c->link_refcount++; if (c->link_clk_state != MDSS_DSI_CLK_ON) { c->link_clk_state = MDSS_DSI_CLK_ON; changed = true; } } } else if ((state == MDSS_DSI_CLK_EARLY_GATE) || (state == MDSS_DSI_CLK_OFF)) { if (clk & MDSS_DSI_CORE_CLK) { if (c->core_refcount == 0) { if ((c->core_clk_state == MDSS_DSI_CLK_EARLY_GATE) && (state == MDSS_DSI_CLK_OFF)) { changed = true; c->core_clk_state = MDSS_DSI_CLK_OFF; } else { pr_warn("Core refcount is zero for %s", c->name); } } else { c->core_refcount--; if (c->core_refcount == 0) { c->core_clk_state = state; changed = true; } } } if (clk & MDSS_DSI_LINK_CLK) { if (c->link_refcount == 0) { if ((c->link_clk_state == MDSS_DSI_CLK_EARLY_GATE) && (state == MDSS_DSI_CLK_OFF)) { changed = true; c->link_clk_state = MDSS_DSI_CLK_OFF; } else { pr_warn("Link refcount is zero for %s", c->name); } } else { c->link_refcount--; if (c->link_refcount == 0) { c->link_clk_state = state; changed = true; } } } } pr_debug("[%s]%s: change=%d, Core (ref=%d, state=%d), Link (ref=%d, state=%d)\n", c->name, mngr->name, changed, c->core_refcount, c->core_clk_state, c->link_refcount, c->link_clk_state); MDSS_XLOG(clk, state, c->core_clk_state, c->link_clk_state); if (changed) { rc = dsi_recheck_clk_state(mngr); if (rc) pr_err("Failed to adjust clock state rc = %d\n", rc); } mutex_unlock(&mngr->clk_mutex); return rc; } int mdss_dsi_clk_set_link_rate(void *client, enum mdss_dsi_link_clk_type clk, u32 rate, u32 flags) { int rc = 0; struct mdss_dsi_clk_client_info *c = client; struct mdss_dsi_clk_mngr *mngr; if (!client || (clk > MDSS_DSI_LINK_CLK_MAX)) { pr_err("Invalid params, client = %p, clk = 0x%x", client, clk); return -EINVAL; } mngr = c->mngr; pr_debug("%s: ENTER\n", mngr->name); mutex_lock(&mngr->clk_mutex); rc = dsi_set_clk_rate(mngr, clk, rate, flags); if (rc) pr_err("Failed to set rate for clk %d, rate = %d, rc = %d\n", clk, rate, rc); mutex_unlock(&mngr->clk_mutex); pr_debug("%s: EXIT, rc = %d\n", mngr->name, rc); return rc; } void *mdss_dsi_clk_init(struct mdss_dsi_clk_info *info) { struct mdss_dsi_clk_mngr *mngr; if (!info) { pr_err("Invalid params\n"); return ERR_PTR(-EINVAL); } pr_debug("ENTER %s\n", info->name); mngr = kzalloc(sizeof(*mngr), GFP_KERNEL); if (!mngr) { mngr = ERR_PTR(-ENOMEM); goto error; } mutex_init(&mngr->clk_mutex); memcpy(&mngr->core_clks.clks, &info->core_clks, sizeof(struct mdss_dsi_core_clk_info)); memcpy(&mngr->link_clks.clks, &info->link_clks, sizeof(struct mdss_dsi_link_clk_info)); INIT_LIST_HEAD(&mngr->client_list); mngr->pre_clkon_cb = info->pre_clkon_cb; mngr->post_clkon_cb = info->post_clkon_cb; mngr->pre_clkoff_cb = info->pre_clkoff_cb; mngr->post_clkoff_cb = info->post_clkoff_cb; mngr->priv_data = info->priv_data; mngr->reg_bus_clt = mdss_reg_bus_vote_client_create(info->name); if (IS_ERR_OR_NULL(mngr->reg_bus_clt)) { pr_err("Unable to get handle for reg bus vote\n"); kfree(mngr); mngr = ERR_PTR(-EINVAL); goto error; } memcpy(mngr->name, info->name, DSI_CLK_NAME_LEN); error: pr_debug("EXIT %s, rc = %ld\n", mngr->name, PTR_ERR(mngr)); return mngr; } int mdss_dsi_clk_deinit(void *clk_mngr) { int rc = 0; struct mdss_dsi_clk_mngr *mngr = clk_mngr; struct list_head *position = NULL; struct list_head *tmp = NULL; struct mdss_dsi_clk_client_info *node; if (!mngr) { pr_err("Invalid params\n"); return -EINVAL; } pr_debug("%s: ENTER\n", mngr->name); mutex_lock(&mngr->clk_mutex); list_for_each_safe(position, tmp, &mngr->client_list) { node = list_entry(position, struct mdss_dsi_clk_client_info, list); list_del(&node->list); pr_debug("Removed device (%s)\n", node->name); kfree(node); } rc = dsi_recheck_clk_state(mngr); if (rc) pr_err("failed to disable all clocks\n"); mdss_reg_bus_vote_client_destroy(mngr->reg_bus_clt); mutex_unlock(&mngr->clk_mutex); pr_debug("%s: EXIT, rc = %d\n", mngr->name, rc); kfree(mngr); return rc; } int mdss_dsi_clk_force_toggle(void *client, u32 clk) { int rc = 0; struct mdss_dsi_clk_client_info *c = client; struct mdss_dsi_clk_mngr *mngr; if (!client || !clk || clk >= MDSS_DSI_CLKS_MAX) { pr_err("Invalid params, client = %p, clk = 0x%x\n", client, clk); return -EINVAL; } mngr = c->mngr; mutex_lock(&mngr->clk_mutex); if ((clk & MDSS_DSI_CORE_CLK) && (mngr->core_clks.current_clk_state == MDSS_DSI_CLK_ON)) { rc = dsi_core_clk_stop(&mngr->core_clks); if (rc) { pr_err("failed to stop core clks\n"); goto error; } rc = dsi_core_clk_start(&mngr->core_clks); if (rc) pr_err("failed to start core clks\n"); } else if (clk & MDSS_DSI_CORE_CLK) { pr_err("cannot reset, core clock is off\n"); rc = -ENOTSUPP; goto error; } if ((clk & MDSS_DSI_LINK_CLK) && (mngr->link_clks.current_clk_state == MDSS_DSI_CLK_ON)) { rc = dsi_link_clk_stop(&mngr->link_clks); if (rc) { pr_err("failed to stop link clks\n"); goto error; } rc = dsi_link_clk_start(&mngr->link_clks); if (rc) pr_err("failed to start link clks\n"); } else if (clk & MDSS_DSI_LINK_CLK) { pr_err("cannot reset, link clock is off\n"); rc = -ENOTSUPP; goto error; } error: mutex_unlock(&mngr->clk_mutex); return rc; }