/* * Copyright (C) 2010-2011 Canonical Ltd * Copyright (C) 2011-2012 Linaro Ltd * Copyright (c) 2017-2019, 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 as * published by the Free Software Foundation. * * Standard functionality for the common clock API. See Documentation/driver-api/clk.rst */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "clk.h" static DEFINE_SPINLOCK(enable_lock); static DEFINE_MUTEX(prepare_lock); static struct task_struct *prepare_owner; static struct task_struct *enable_owner; static int prepare_refcnt; static int enable_refcnt; static HLIST_HEAD(clk_root_list); static HLIST_HEAD(clk_orphan_list); static LIST_HEAD(clk_notifier_list); static struct hlist_head *all_lists[] = { &clk_root_list, &clk_orphan_list, NULL, }; #ifdef CONFIG_DEBUG_FS static struct hlist_head *orphan_list[] = { &clk_orphan_list, NULL, }; #endif /* * clk_rate_change_list is used during clk_core_set_rate_nolock() calls to * handle vdd_class vote tracking. core->rate_change_node is added to * clk_rate_change_list when core->new_rate requires a different voltage level * (core->new_vdd_class_vote) than core->vdd_class_vote. Elements are removed * from the list after unvoting core->vdd_class_vote immediately before * returning from clk_core_set_rate_nolock(). */ static LIST_HEAD(clk_rate_change_list); /*** private data structures ***/ struct clk_core { const char *name; const struct clk_ops *ops; struct clk_hw *hw; struct module *owner; struct device *dev; struct clk_core *parent; const char **parent_names; struct clk_core **parents; unsigned int num_parents; unsigned int new_parent_index; unsigned long rate; unsigned long req_rate; unsigned long new_rate; struct clk_core *new_parent; struct clk_core *new_child; unsigned long flags; bool orphan; bool rpm_enabled; bool need_sync; bool boot_enabled; unsigned int enable_count; unsigned int prepare_count; unsigned int protect_count; bool need_handoff_enable; bool need_handoff_prepare; unsigned long min_rate; unsigned long max_rate; unsigned long accuracy; int phase; struct clk_duty duty; struct hlist_head children; struct hlist_node child_node; struct hlist_head clks; unsigned int notifier_count; #ifdef CONFIG_DEBUG_FS struct dentry *dentry; struct hlist_node debug_node; #endif struct kref ref; struct clk_vdd_class *vdd_class; int vdd_class_vote; int new_vdd_class_vote; struct list_head rate_change_node; unsigned long *rate_max; int num_rate_max; }; #define CREATE_TRACE_POINTS #include struct clk { struct clk_core *core; const char *dev_id; const char *con_id; unsigned long min_rate; unsigned long max_rate; unsigned int exclusive_count; struct hlist_node clks_node; }; /*** runtime pm ***/ static int clk_pm_runtime_get(struct clk_core *core) { int ret; if (!core->rpm_enabled) return 0; ret = pm_runtime_get_sync(core->dev); if (ret < 0) { pm_runtime_put_noidle(core->dev); return ret; } return 0; } static void clk_pm_runtime_put(struct clk_core *core) { if (!core->rpm_enabled) return; pm_runtime_put_sync(core->dev); } /*** locking ***/ static void clk_prepare_lock(void) { if (!mutex_trylock(&prepare_lock)) { if (prepare_owner == current) { prepare_refcnt++; return; } mutex_lock(&prepare_lock); } WARN_ON_ONCE(prepare_owner != NULL); WARN_ON_ONCE(prepare_refcnt != 0); prepare_owner = current; prepare_refcnt = 1; } static void clk_prepare_unlock(void) { WARN_ON_ONCE(prepare_owner != current); WARN_ON_ONCE(prepare_refcnt == 0); if (--prepare_refcnt) return; prepare_owner = NULL; mutex_unlock(&prepare_lock); } static unsigned long clk_enable_lock(void) __acquires(enable_lock) { unsigned long flags; /* * On UP systems, spin_trylock_irqsave() always returns true, even if * we already hold the lock. So, in that case, we rely only on * reference counting. */ if (!IS_ENABLED(CONFIG_SMP) || !spin_trylock_irqsave(&enable_lock, flags)) { if (enable_owner == current) { enable_refcnt++; __acquire(enable_lock); if (!IS_ENABLED(CONFIG_SMP)) local_save_flags(flags); return flags; } spin_lock_irqsave(&enable_lock, flags); } WARN_ON_ONCE(enable_owner != NULL); WARN_ON_ONCE(enable_refcnt != 0); enable_owner = current; enable_refcnt = 1; return flags; } static void clk_enable_unlock(unsigned long flags) __releases(enable_lock) { WARN_ON_ONCE(enable_owner != current); WARN_ON_ONCE(enable_refcnt == 0); if (--enable_refcnt) { __release(enable_lock); return; } enable_owner = NULL; spin_unlock_irqrestore(&enable_lock, flags); } static bool clk_core_rate_is_protected(struct clk_core *core) { return core->protect_count; } static bool clk_core_is_prepared(struct clk_core *core) { bool ret = false; /* * .is_prepared is optional for clocks that can prepare * fall back to software usage counter if it is missing */ if (!core->ops->is_prepared) return core->prepare_count; if (!clk_pm_runtime_get(core)) { ret = core->ops->is_prepared(core->hw); clk_pm_runtime_put(core); } return ret; } static bool clk_core_is_enabled(struct clk_core *core) { bool ret = false; /* * .is_enabled is only mandatory for clocks that gate * fall back to software usage counter if .is_enabled is missing */ if (!core->ops->is_enabled) return core->enable_count; /* * Check if clock controller's device is runtime active before * calling .is_enabled callback. If not, assume that clock is * disabled, because we might be called from atomic context, from * which pm_runtime_get() is not allowed. * This function is called mainly from clk_disable_unused_subtree, * which ensures proper runtime pm activation of controller before * taking enable spinlock, but the below check is needed if one tries * to call it from other places. */ if (core->rpm_enabled) { pm_runtime_get_noresume(core->dev); if (!pm_runtime_active(core->dev)) { ret = false; goto done; } } ret = core->ops->is_enabled(core->hw); done: if (core->rpm_enabled) pm_runtime_put(core->dev); return ret; } /*** helper functions ***/ const char *__clk_get_name(const struct clk *clk) { return !clk ? NULL : clk->core->name; } EXPORT_SYMBOL_GPL(__clk_get_name); const char *clk_hw_get_name(const struct clk_hw *hw) { return hw->core->name; } EXPORT_SYMBOL_GPL(clk_hw_get_name); struct clk_hw *__clk_get_hw(struct clk *clk) { return !clk ? NULL : clk->core->hw; } EXPORT_SYMBOL_GPL(__clk_get_hw); unsigned int clk_hw_get_num_parents(const struct clk_hw *hw) { return hw->core->num_parents; } EXPORT_SYMBOL_GPL(clk_hw_get_num_parents); struct clk_hw *clk_hw_get_parent(const struct clk_hw *hw) { return hw->core->parent ? hw->core->parent->hw : NULL; } EXPORT_SYMBOL_GPL(clk_hw_get_parent); static struct clk_core *__clk_lookup_subtree(const char *name, struct clk_core *core) { struct clk_core *child; struct clk_core *ret; if (!strcmp(core->name, name)) return core; hlist_for_each_entry(child, &core->children, child_node) { ret = __clk_lookup_subtree(name, child); if (ret) return ret; } return NULL; } static struct clk_core *clk_core_lookup(const char *name) { struct clk_core *root_clk; struct clk_core *ret; if (!name) return NULL; /* search the 'proper' clk tree first */ hlist_for_each_entry(root_clk, &clk_root_list, child_node) { ret = __clk_lookup_subtree(name, root_clk); if (ret) return ret; } /* if not found, then search the orphan tree */ hlist_for_each_entry(root_clk, &clk_orphan_list, child_node) { ret = __clk_lookup_subtree(name, root_clk); if (ret) return ret; } return NULL; } static struct clk_core *clk_core_get_parent_by_index(struct clk_core *core, u8 index) { if (!core || index >= core->num_parents) return NULL; if (!core->parents[index]) core->parents[index] = clk_core_lookup(core->parent_names[index]); return core->parents[index]; } struct clk_hw * clk_hw_get_parent_by_index(const struct clk_hw *hw, unsigned int index) { struct clk_core *parent; parent = clk_core_get_parent_by_index(hw->core, index); return !parent ? NULL : parent->hw; } EXPORT_SYMBOL_GPL(clk_hw_get_parent_by_index); unsigned int __clk_get_enable_count(struct clk *clk) { return !clk ? 0 : clk->core->enable_count; } static unsigned long clk_core_get_rate_nolock(struct clk_core *core) { unsigned long ret; if (!core) { ret = 0; goto out; } ret = core->rate; if (!core->num_parents) goto out; if (!core->parent) ret = 0; out: return ret; } unsigned long clk_hw_get_rate(const struct clk_hw *hw) { return clk_core_get_rate_nolock(hw->core); } EXPORT_SYMBOL_GPL(clk_hw_get_rate); static unsigned long __clk_get_accuracy(struct clk_core *core) { if (!core) return 0; return core->accuracy; } unsigned long __clk_get_flags(struct clk *clk) { return !clk ? 0 : clk->core->flags; } EXPORT_SYMBOL_GPL(__clk_get_flags); unsigned long clk_hw_get_flags(const struct clk_hw *hw) { return hw->core->flags; } EXPORT_SYMBOL_GPL(clk_hw_get_flags); bool clk_hw_is_prepared(const struct clk_hw *hw) { return clk_core_is_prepared(hw->core); } EXPORT_SYMBOL_GPL(clk_hw_is_prepared); bool clk_hw_rate_is_protected(const struct clk_hw *hw) { return clk_core_rate_is_protected(hw->core); } bool clk_hw_is_enabled(const struct clk_hw *hw) { return clk_core_is_enabled(hw->core); } EXPORT_SYMBOL_GPL(clk_hw_is_enabled); bool __clk_is_enabled(struct clk *clk) { if (!clk) return false; return clk_core_is_enabled(clk->core); } EXPORT_SYMBOL_GPL(__clk_is_enabled); static bool mux_is_better_rate(unsigned long rate, unsigned long now, unsigned long best, unsigned long flags) { if (flags & CLK_MUX_ROUND_CLOSEST) return abs(now - rate) < abs(best - rate); return now <= rate && now > best; } int clk_mux_determine_rate_flags(struct clk_hw *hw, struct clk_rate_request *req, unsigned long flags) { struct clk_core *core = hw->core, *parent, *best_parent = NULL; int i, num_parents, ret; unsigned long best = 0; struct clk_rate_request parent_req = *req; /* if NO_REPARENT flag set, pass through to current parent */ if (core->flags & CLK_SET_RATE_NO_REPARENT) { parent = core->parent; if (core->flags & CLK_SET_RATE_PARENT) { ret = __clk_determine_rate(parent ? parent->hw : NULL, &parent_req); if (ret) return ret; best = parent_req.rate; } else if (parent) { best = clk_core_get_rate_nolock(parent); } else { best = clk_core_get_rate_nolock(core); } goto out; } /* find the parent that can provide the fastest rate <= rate */ num_parents = core->num_parents; for (i = 0; i < num_parents; i++) { parent = clk_core_get_parent_by_index(core, i); if (!parent) continue; if (core->flags & CLK_SET_RATE_PARENT) { parent_req = *req; ret = __clk_determine_rate(parent->hw, &parent_req); if (ret) continue; } else { parent_req.rate = clk_core_get_rate_nolock(parent); } if (mux_is_better_rate(req->rate, parent_req.rate, best, flags)) { best_parent = parent; best = parent_req.rate; } } if (!best_parent) return -EINVAL; out: if (best_parent) req->best_parent_hw = best_parent->hw; req->best_parent_rate = best; req->rate = best; return 0; } EXPORT_SYMBOL_GPL(clk_mux_determine_rate_flags); struct clk *__clk_lookup(const char *name) { struct clk_core *core = clk_core_lookup(name); return !core ? NULL : core->hw->clk; } static void clk_core_get_boundaries(struct clk_core *core, unsigned long *min_rate, unsigned long *max_rate) { struct clk *clk_user; *min_rate = core->min_rate; *max_rate = core->max_rate; hlist_for_each_entry(clk_user, &core->clks, clks_node) *min_rate = max(*min_rate, clk_user->min_rate); hlist_for_each_entry(clk_user, &core->clks, clks_node) *max_rate = min(*max_rate, clk_user->max_rate); } void clk_hw_set_rate_range(struct clk_hw *hw, unsigned long min_rate, unsigned long max_rate) { hw->core->min_rate = min_rate; hw->core->max_rate = max_rate; } EXPORT_SYMBOL_GPL(clk_hw_set_rate_range); /* * Aggregate the rate of all the enabled child nodes and exclude that * of the child node for which this request was made. */ unsigned long clk_aggregate_rate(struct clk_hw *hw, const struct clk_core *parent) { struct clk_core *child; unsigned long aggre_rate = 0; hlist_for_each_entry(child, &parent->children, child_node) { if (child->enable_count && strcmp(child->name, hw->init->name)) aggre_rate = max(child->rate, aggre_rate); } return aggre_rate; } EXPORT_SYMBOL_GPL(clk_aggregate_rate); /* * Helper for finding best parent to provide a given frequency. This can be used * directly as a determine_rate callback (e.g. for a mux), or from a more * complex clock that may combine a mux with other operations. */ int __clk_mux_determine_rate(struct clk_hw *hw, struct clk_rate_request *req) { return clk_mux_determine_rate_flags(hw, req, 0); } EXPORT_SYMBOL_GPL(__clk_mux_determine_rate); int __clk_mux_determine_rate_closest(struct clk_hw *hw, struct clk_rate_request *req) { return clk_mux_determine_rate_flags(hw, req, CLK_MUX_ROUND_CLOSEST); } EXPORT_SYMBOL_GPL(__clk_mux_determine_rate_closest); /* * Find the voltage level required for a given clock rate. */ static int clk_find_vdd_level(struct clk_core *clk, unsigned long rate) { int level; /* * For certain PLLs, due to the limitation in the bits allocated for * programming the fractional divider, the actual rate of the PLL will * be slightly higher than the requested rate (in the order of several * Hz). To accommodate this difference, convert the FMAX rate and the * clock frequency to KHz and use that for deriving the voltage level. */ for (level = 0; level < clk->num_rate_max; level++) if (DIV_ROUND_CLOSEST(rate, 1000) <= DIV_ROUND_CLOSEST(clk->rate_max[level], 1000) && clk->rate_max[level] > 0) break; if (level == clk->num_rate_max) { pr_err("Rate %lu for %s is greater than highest Fmax\n", rate, clk->name); return -EINVAL; } return level; } /* * Update voltage level given the current votes. */ static int clk_update_vdd(struct clk_vdd_class *vdd_class) { int level, rc = 0, i, ignore; struct regulator **r = vdd_class->regulator; int *uv = vdd_class->vdd_uv; int n_reg = vdd_class->num_regulators; int cur_lvl = vdd_class->cur_level; int max_lvl = vdd_class->num_levels - 1; int cur_base = cur_lvl * n_reg; int new_base; /* aggregate votes */ for (level = max_lvl; level > 0; level--) if (vdd_class->level_votes[level]) break; if (level == cur_lvl) return 0; max_lvl = max_lvl * n_reg; new_base = level * n_reg; for (i = 0; i < vdd_class->num_regulators; i++) { pr_debug("Set Voltage level Min %d, Max %d\n", uv[new_base + i], uv[max_lvl + i]); rc = regulator_set_voltage(r[i], uv[new_base + i], INT_MAX); if (rc) goto set_voltage_fail; if (cur_lvl == 0 || cur_lvl == vdd_class->num_levels) rc = regulator_enable(r[i]); else if (level == 0) rc = regulator_disable(r[i]); if (rc) goto enable_disable_fail; } if (vdd_class->set_vdd && !vdd_class->num_regulators) rc = vdd_class->set_vdd(vdd_class, level); if (!rc) vdd_class->cur_level = level; return rc; enable_disable_fail: regulator_set_voltage(r[i], uv[cur_base + i], INT_MAX); set_voltage_fail: for (i--; i >= 0; i--) { regulator_set_voltage(r[i], uv[cur_base + i], INT_MAX); if (cur_lvl == 0 || cur_lvl == vdd_class->num_levels) regulator_disable(r[i]); else if (level == 0) ignore = regulator_enable(r[i]); } return rc; } /* * Vote for a voltage level. */ int clk_vote_vdd_level(struct clk_vdd_class *vdd_class, int level) { int rc = 0; if (level >= vdd_class->num_levels) return -EINVAL; mutex_lock(&vdd_class->lock); vdd_class->level_votes[level]++; rc = clk_update_vdd(vdd_class); if (rc) vdd_class->level_votes[level]--; mutex_unlock(&vdd_class->lock); return rc; } EXPORT_SYMBOL_GPL(clk_vote_vdd_level); /* * Remove vote for a voltage level. */ int clk_unvote_vdd_level(struct clk_vdd_class *vdd_class, int level) { int rc = 0; if (level >= vdd_class->num_levels) return -EINVAL; mutex_lock(&vdd_class->lock); if (WARN(!vdd_class->level_votes[level], "Reference counts are incorrect for %s level %d\n", vdd_class->class_name, level)) { rc = -EINVAL; goto out; } vdd_class->level_votes[level]--; rc = clk_update_vdd(vdd_class); if (rc) vdd_class->level_votes[level]++; out: mutex_unlock(&vdd_class->lock); return rc; } EXPORT_SYMBOL_GPL(clk_unvote_vdd_level); /* * Vote for a voltage level corresponding to a clock's rate. */ int clk_vote_rate_vdd(struct clk_core *core, unsigned long rate) { int level; if (!core->vdd_class) return 0; level = clk_find_vdd_level(core, rate); if (level < 0) return level; return clk_vote_vdd_level(core->vdd_class, level); } EXPORT_SYMBOL_GPL(clk_vote_rate_vdd); /* * Remove vote for a voltage level corresponding to a clock's rate. */ void clk_unvote_rate_vdd(struct clk_core *core, unsigned long rate) { int level; if (!core->vdd_class) return; level = clk_find_vdd_level(core, rate); if (level < 0) return; clk_unvote_vdd_level(core->vdd_class, level); } EXPORT_SYMBOL_GPL(clk_unvote_rate_vdd); static bool clk_is_rate_level_valid(struct clk_core *core, unsigned long rate) { int level; if (!core->vdd_class) return true; level = clk_find_vdd_level(core, rate); return level >= 0; } /*** clk api ***/ static void clk_core_rate_unprotect(struct clk_core *core) { lockdep_assert_held(&prepare_lock); if (!core) return; if (WARN(core->protect_count == 0, "%s already unprotected\n", core->name)) return; if (--core->protect_count > 0) return; clk_core_rate_unprotect(core->parent); } static int clk_core_rate_nuke_protect(struct clk_core *core) { int ret; lockdep_assert_held(&prepare_lock); if (!core) return -EINVAL; if (core->protect_count == 0) return 0; ret = core->protect_count; core->protect_count = 1; clk_core_rate_unprotect(core); return ret; } /** * clk_rate_exclusive_put - release exclusivity over clock rate control * @clk: the clk over which the exclusivity is released * * clk_rate_exclusive_put() completes a critical section during which a clock * consumer cannot tolerate any other consumer making any operation on the * clock which could result in a rate change or rate glitch. Exclusive clocks * cannot have their rate changed, either directly or indirectly due to changes * further up the parent chain of clocks. As a result, clocks up parent chain * also get under exclusive control of the calling consumer. * * If exlusivity is claimed more than once on clock, even by the same consumer, * the rate effectively gets locked as exclusivity can't be preempted. * * Calls to clk_rate_exclusive_put() must be balanced with calls to * clk_rate_exclusive_get(). Calls to this function may sleep, and do not return * error status. */ void clk_rate_exclusive_put(struct clk *clk) { if (!clk) return; clk_prepare_lock(); /* * if there is something wrong with this consumer protect count, stop * here before messing with the provider */ if (WARN_ON(clk->exclusive_count <= 0)) goto out; clk_core_rate_unprotect(clk->core); clk->exclusive_count--; out: clk_prepare_unlock(); } EXPORT_SYMBOL_GPL(clk_rate_exclusive_put); static void clk_core_rate_protect(struct clk_core *core) { lockdep_assert_held(&prepare_lock); if (!core) return; if (core->protect_count == 0) clk_core_rate_protect(core->parent); core->protect_count++; } static void clk_core_rate_restore_protect(struct clk_core *core, int count) { lockdep_assert_held(&prepare_lock); if (!core) return; if (count == 0) return; clk_core_rate_protect(core); core->protect_count = count; } /** * clk_rate_exclusive_get - get exclusivity over the clk rate control * @clk: the clk over which the exclusity of rate control is requested * * clk_rate_exlusive_get() begins a critical section during which a clock * consumer cannot tolerate any other consumer making any operation on the * clock which could result in a rate change or rate glitch. Exclusive clocks * cannot have their rate changed, either directly or indirectly due to changes * further up the parent chain of clocks. As a result, clocks up parent chain * also get under exclusive control of the calling consumer. * * If exlusivity is claimed more than once on clock, even by the same consumer, * the rate effectively gets locked as exclusivity can't be preempted. * * Calls to clk_rate_exclusive_get() should be balanced with calls to * clk_rate_exclusive_put(). Calls to this function may sleep. * Returns 0 on success, -EERROR otherwise */ int clk_rate_exclusive_get(struct clk *clk) { if (!clk) return 0; clk_prepare_lock(); clk_core_rate_protect(clk->core); clk->exclusive_count++; clk_prepare_unlock(); return 0; } EXPORT_SYMBOL_GPL(clk_rate_exclusive_get); static void clk_core_unprepare(struct clk_core *core) { lockdep_assert_held(&prepare_lock); if (!core) return; if (WARN(core->prepare_count == 0, "%s already unprepared\n", core->name)) return; if (WARN(core->prepare_count == 1 && core->flags & CLK_IS_CRITICAL, "Unpreparing critical %s\n", core->name)) return; if (core->flags & CLK_SET_RATE_GATE) clk_core_rate_unprotect(core); if (--core->prepare_count > 0) return; WARN(core->enable_count > 0, "Unpreparing enabled %s\n", core->name); trace_clk_unprepare(core); if (core->ops->unprepare) core->ops->unprepare(core->hw); clk_pm_runtime_put(core); trace_clk_unprepare_complete(core); if (core->vdd_class) { clk_unvote_vdd_level(core->vdd_class, core->vdd_class_vote); core->vdd_class_vote = 0; core->new_vdd_class_vote = 0; } clk_core_unprepare(core->parent); } static void clk_core_unprepare_lock(struct clk_core *core) { clk_prepare_lock(); clk_core_unprepare(core); clk_prepare_unlock(); } /** * clk_unprepare - undo preparation of a clock source * @clk: the clk being unprepared * * clk_unprepare may sleep, which differentiates it from clk_disable. In a * simple case, clk_unprepare can be used instead of clk_disable to gate a clk * if the operation may sleep. One example is a clk which is accessed over * I2c. In the complex case a clk gate operation may require a fast and a slow * part. It is this reason that clk_unprepare and clk_disable are not mutually * exclusive. In fact clk_disable must be called before clk_unprepare. */ void clk_unprepare(struct clk *clk) { if (IS_ERR_OR_NULL(clk)) return; clk_core_unprepare_lock(clk->core); } EXPORT_SYMBOL_GPL(clk_unprepare); static int clk_core_prepare(struct clk_core *core) { int ret = 0; lockdep_assert_held(&prepare_lock); if (!core) return 0; if (core->prepare_count == 0) { ret = clk_pm_runtime_get(core); if (ret) return ret; ret = clk_core_prepare(core->parent); if (ret) goto runtime_put; trace_clk_prepare(core); ret = clk_vote_rate_vdd(core, core->rate); if (ret) { clk_core_unprepare(core->parent); return ret; } if (core->vdd_class) { core->vdd_class_vote = clk_find_vdd_level(core, core->rate); core->new_vdd_class_vote = core->vdd_class_vote; } if (core->ops->prepare) ret = core->ops->prepare(core->hw); trace_clk_prepare_complete(core); if (ret) { clk_unvote_rate_vdd(core, core->rate); core->vdd_class_vote = 0; core->new_vdd_class_vote = 0; goto unprepare; } } core->prepare_count++; /* * CLK_SET_RATE_GATE is a special case of clock protection * Instead of a consumer claiming exclusive rate control, it is * actually the provider which prevents any consumer from making any * operation which could result in a rate change or rate glitch while * the clock is prepared. */ if (core->flags & CLK_SET_RATE_GATE) clk_core_rate_protect(core); return 0; unprepare: clk_core_unprepare(core->parent); runtime_put: clk_pm_runtime_put(core); return ret; } static int clk_core_prepare_lock(struct clk_core *core) { int ret; clk_prepare_lock(); ret = clk_core_prepare(core); clk_prepare_unlock(); return ret; } /** * clk_prepare - prepare a clock source * @clk: the clk being prepared * * clk_prepare may sleep, which differentiates it from clk_enable. In a simple * case, clk_prepare can be used instead of clk_enable to ungate a clk if the * operation may sleep. One example is a clk which is accessed over I2c. In * the complex case a clk ungate operation may require a fast and a slow part. * It is this reason that clk_prepare and clk_enable are not mutually * exclusive. In fact clk_prepare must be called before clk_enable. * Returns 0 on success, -EERROR otherwise. */ int clk_prepare(struct clk *clk) { if (!clk) return 0; return clk_core_prepare_lock(clk->core); } EXPORT_SYMBOL_GPL(clk_prepare); static void clk_core_disable(struct clk_core *core) { lockdep_assert_held(&enable_lock); if (!core) return; if (WARN(core->enable_count == 0, "%s already disabled\n", core->name)) return; if (WARN(core->enable_count == 1 && core->flags & CLK_IS_CRITICAL, "Disabling critical %s\n", core->name)) return; if (--core->enable_count > 0) return; trace_clk_disable_rcuidle(core); if (core->ops->disable) core->ops->disable(core->hw); trace_clk_disable_complete_rcuidle(core); clk_core_disable(core->parent); } static void clk_core_disable_lock(struct clk_core *core) { unsigned long flags; flags = clk_enable_lock(); clk_core_disable(core); clk_enable_unlock(flags); } /** * clk_disable - gate a clock * @clk: the clk being gated * * clk_disable must not sleep, which differentiates it from clk_unprepare. In * a simple case, clk_disable can be used instead of clk_unprepare to gate a * clk if the operation is fast and will never sleep. One example is a * SoC-internal clk which is controlled via simple register writes. In the * complex case a clk gate operation may require a fast and a slow part. It is * this reason that clk_unprepare and clk_disable are not mutually exclusive. * In fact clk_disable must be called before clk_unprepare. */ void clk_disable(struct clk *clk) { if (IS_ERR_OR_NULL(clk)) return; clk_core_disable_lock(clk->core); } EXPORT_SYMBOL_GPL(clk_disable); static int clk_core_enable(struct clk_core *core) { int ret = 0; lockdep_assert_held(&enable_lock); if (!core) return 0; if (WARN(core->prepare_count == 0, "Enabling unprepared %s\n", core->name)) return -ESHUTDOWN; if (core->enable_count == 0) { ret = clk_core_enable(core->parent); if (ret) return ret; trace_clk_enable_rcuidle(core); if (core->ops->enable) ret = core->ops->enable(core->hw); trace_clk_enable_complete_rcuidle(core); if (ret) { clk_core_disable(core->parent); return ret; } } core->enable_count++; return 0; } static int clk_core_enable_lock(struct clk_core *core) { unsigned long flags; int ret; flags = clk_enable_lock(); ret = clk_core_enable(core); clk_enable_unlock(flags); return ret; } /** * clk_enable - ungate a clock * @clk: the clk being ungated * * clk_enable must not sleep, which differentiates it from clk_prepare. In a * simple case, clk_enable can be used instead of clk_prepare to ungate a clk * if the operation will never sleep. One example is a SoC-internal clk which * is controlled via simple register writes. In the complex case a clk ungate * operation may require a fast and a slow part. It is this reason that * clk_enable and clk_prepare are not mutually exclusive. In fact clk_prepare * must be called before clk_enable. Returns 0 on success, -EERROR * otherwise. */ int clk_enable(struct clk *clk) { if (!clk) return 0; return clk_core_enable_lock(clk->core); } EXPORT_SYMBOL_GPL(clk_enable); static int clk_core_prepare_enable(struct clk_core *core) { int ret; ret = clk_core_prepare_lock(core); if (ret) return ret; ret = clk_core_enable_lock(core); if (ret) clk_core_unprepare_lock(core); return ret; } static void clk_core_disable_unprepare(struct clk_core *core) { clk_core_disable_lock(core); clk_core_unprepare_lock(core); } #if (!defined(CONFIG_MACH_MT6779) \ && !defined(CONFIG_MACH_MT6739) \ && !defined(CONFIG_MACH_MT6768) \ && !defined(CONFIG_MACH_MT6785)) static void clk_unprepare_unused_subtree(struct clk_core *core) { struct clk_core *child; lockdep_assert_held(&prepare_lock); hlist_for_each_entry(child, &core->children, child_node) clk_unprepare_unused_subtree(child); if (dev_has_sync_state(core->dev) && !(core->flags & CLK_DONT_HOLD_STATE)) return; /* * setting CLK_ENABLE_HAND_OFF flag triggers this conditional * * need_handoff_prepare implies this clk was already prepared by * __clk_init. now we have a proper user, so unset the flag in our * internal bookkeeping. See CLK_ENABLE_HAND_OFF flag in clk-provider.h * for details. */ if (core->need_handoff_prepare) { core->need_handoff_prepare = false; clk_core_unprepare(core); } if (core->prepare_count) return; if (core->flags & CLK_IGNORE_UNUSED) return; if (clk_pm_runtime_get(core)) return; if (clk_core_is_prepared(core)) { trace_clk_unprepare(core); if (core->ops->unprepare_unused) core->ops->unprepare_unused(core->hw); else if (core->ops->unprepare) core->ops->unprepare(core->hw); trace_clk_unprepare_complete(core); } clk_pm_runtime_put(core); } static void clk_disable_unused_subtree(struct clk_core *core) { struct clk_core *child; unsigned long flags; lockdep_assert_held(&prepare_lock); hlist_for_each_entry(child, &core->children, child_node) clk_disable_unused_subtree(child); if (dev_has_sync_state(core->dev) && !(core->flags & CLK_DONT_HOLD_STATE)) return; /* * setting CLK_ENABLE_HAND_OFF flag triggers this conditional * * need_handoff_enable implies this clk was already enabled by * __clk_init. now we have a proper user, so unset the flag in our * internal bookkeeping. See CLK_ENABLE_HAND_OFF flag in clk-provider.h * for details. */ if (core->need_handoff_enable) { core->need_handoff_enable = false; flags = clk_enable_lock(); clk_core_disable(core); clk_enable_unlock(flags); } if (core->flags & CLK_OPS_PARENT_ENABLE) clk_core_prepare_enable(core->parent); if (clk_pm_runtime_get(core)) goto unprepare_out; flags = clk_enable_lock(); if (core->enable_count) goto unlock_out; if (core->flags & CLK_IGNORE_UNUSED) goto unlock_out; /* * some gate clocks have special needs during the disable-unused * sequence. call .disable_unused if available, otherwise fall * back to .disable */ if (clk_core_is_enabled(core)) { trace_clk_disable(core); if (core->ops->disable_unused) core->ops->disable_unused(core->hw); else if (core->ops->disable) core->ops->disable(core->hw); trace_clk_disable_complete(core); } unlock_out: clk_enable_unlock(flags); clk_pm_runtime_put(core); unprepare_out: if (core->flags & CLK_OPS_PARENT_ENABLE) clk_core_disable_unprepare(core->parent); } #endif static bool clk_ignore_unused; static int __init clk_ignore_unused_setup(char *__unused) { clk_ignore_unused = true; return 1; } __setup("clk_ignore_unused", clk_ignore_unused_setup); static int clk_disable_unused(void) { #if (!defined(CONFIG_MACH_MT6779) \ && !defined(CONFIG_MACH_MT6739) \ && !defined(CONFIG_MACH_MT6768) \ && !defined(CONFIG_MACH_MT6785)) struct clk_core *core; #endif if (clk_ignore_unused) { pr_warn("clk: Not disabling unused clocks\n"); return 0; } #if (!defined(CONFIG_MACH_MT6779) \ && !defined(CONFIG_MACH_MT6739) \ && !defined(CONFIG_MACH_MT6768) \ && !defined(CONFIG_MACH_MT6785)) clk_prepare_lock(); hlist_for_each_entry(core, &clk_root_list, child_node) clk_disable_unused_subtree(core); hlist_for_each_entry(core, &clk_orphan_list, child_node) clk_disable_unused_subtree(core); hlist_for_each_entry(core, &clk_root_list, child_node) clk_unprepare_unused_subtree(core); hlist_for_each_entry(core, &clk_orphan_list, child_node) clk_unprepare_unused_subtree(core); clk_prepare_unlock(); #endif return 0; } late_initcall_sync(clk_disable_unused); static void clk_unprepare_disable_dev_subtree(struct clk_core *core, struct device *dev) { struct clk_core *child; lockdep_assert_held(&prepare_lock); hlist_for_each_entry(child, &core->children, child_node) clk_unprepare_disable_dev_subtree(child, dev); if (core->dev != dev || !core->need_sync) return; clk_core_disable_unprepare(core); } void clk_sync_state(struct device *dev) { struct clk_core *core; clk_prepare_lock(); hlist_for_each_entry(core, &clk_root_list, child_node) clk_unprepare_disable_dev_subtree(core, dev); hlist_for_each_entry(core, &clk_orphan_list, child_node) clk_unprepare_disable_dev_subtree(core, dev); clk_prepare_unlock(); } EXPORT_SYMBOL_GPL(clk_sync_state); static int clk_core_determine_round_nolock(struct clk_core *core, struct clk_rate_request *req) { long rate; lockdep_assert_held(&prepare_lock); if (!core) return 0; /* * At this point, core protection will be disabled if * - if the provider is not protected at all * - if the calling consumer is the only one which has exclusivity * over the provider */ if (clk_core_rate_is_protected(core)) { req->rate = core->rate; } else if (core->ops->determine_rate) { return core->ops->determine_rate(core->hw, req); } else if (core->ops->round_rate) { rate = core->ops->round_rate(core->hw, req->rate, &req->best_parent_rate); if (rate < 0) return rate; req->rate = rate; } else { return -EINVAL; } return 0; } static void clk_core_init_rate_req(struct clk_core * const core, struct clk_rate_request *req) { struct clk_core *parent; if (WARN_ON(!core || !req)) return; parent = core->parent; if (parent) { req->best_parent_hw = parent->hw; req->best_parent_rate = parent->rate; } else { req->best_parent_hw = NULL; req->best_parent_rate = 0; } } static bool clk_core_can_round(struct clk_core * const core) { if (core->ops->determine_rate || core->ops->round_rate) return true; return false; } static int clk_core_round_rate_nolock(struct clk_core *core, struct clk_rate_request *req) { lockdep_assert_held(&prepare_lock); if (!core) { req->rate = 0; return 0; } clk_core_init_rate_req(core, req); if (clk_core_can_round(core)) return clk_core_determine_round_nolock(core, req); else if (core->flags & CLK_SET_RATE_PARENT) return clk_core_round_rate_nolock(core->parent, req); req->rate = core->rate; return 0; } /** * __clk_determine_rate - get the closest rate actually supported by a clock * @hw: determine the rate of this clock * @req: target rate request * * Useful for clk_ops such as .set_rate and .determine_rate. */ int __clk_determine_rate(struct clk_hw *hw, struct clk_rate_request *req) { if (!hw) { req->rate = 0; return 0; } return clk_core_round_rate_nolock(hw->core, req); } EXPORT_SYMBOL_GPL(__clk_determine_rate); unsigned long clk_hw_round_rate(struct clk_hw *hw, unsigned long rate) { int ret; struct clk_rate_request req; clk_core_get_boundaries(hw->core, &req.min_rate, &req.max_rate); req.rate = rate; ret = clk_core_round_rate_nolock(hw->core, &req); if (ret) return 0; return req.rate; } EXPORT_SYMBOL_GPL(clk_hw_round_rate); /** * clk_round_rate - round the given rate for a clk * @clk: the clk for which we are rounding a rate * @rate: the rate which is to be rounded * * Takes in a rate as input and rounds it to a rate that the clk can actually * use which is then returned. If clk doesn't support round_rate operation * then the parent rate is returned. */ long clk_round_rate(struct clk *clk, unsigned long rate) { struct clk_rate_request req; int ret; if (!clk) return 0; clk_prepare_lock(); if (clk->exclusive_count) clk_core_rate_unprotect(clk->core); clk_core_get_boundaries(clk->core, &req.min_rate, &req.max_rate); req.rate = rate; ret = clk_core_round_rate_nolock(clk->core, &req); if (clk->exclusive_count) clk_core_rate_protect(clk->core); clk_prepare_unlock(); if (ret) return ret; return req.rate; } EXPORT_SYMBOL_GPL(clk_round_rate); /** * __clk_notify - call clk notifier chain * @core: clk that is changing rate * @msg: clk notifier type (see include/linux/clk.h) * @old_rate: old clk rate * @new_rate: new clk rate * * Triggers a notifier call chain on the clk rate-change notification * for 'clk'. Passes a pointer to the struct clk and the previous * and current rates to the notifier callback. Intended to be called by * internal clock code only. Returns NOTIFY_DONE from the last driver * called if all went well, or NOTIFY_STOP or NOTIFY_BAD immediately if * a driver returns that. */ static int __clk_notify(struct clk_core *core, unsigned long msg, unsigned long old_rate, unsigned long new_rate) { struct clk_notifier *cn; struct clk_notifier_data cnd; int ret = NOTIFY_DONE; cnd.old_rate = old_rate; cnd.new_rate = new_rate; list_for_each_entry(cn, &clk_notifier_list, node) { if (cn->clk->core == core) { cnd.clk = cn->clk; ret = srcu_notifier_call_chain(&cn->notifier_head, msg, &cnd); if (ret & NOTIFY_STOP_MASK) return ret; } } return ret; } /** * __clk_recalc_accuracies * @core: first clk in the subtree * * Walks the subtree of clks starting with clk and recalculates accuracies as * it goes. Note that if a clk does not implement the .recalc_accuracy * callback then it is assumed that the clock will take on the accuracy of its * parent. */ static void __clk_recalc_accuracies(struct clk_core *core) { unsigned long parent_accuracy = 0; struct clk_core *child; lockdep_assert_held(&prepare_lock); if (core->parent) parent_accuracy = core->parent->accuracy; if (core->ops->recalc_accuracy) core->accuracy = core->ops->recalc_accuracy(core->hw, parent_accuracy); else core->accuracy = parent_accuracy; hlist_for_each_entry(child, &core->children, child_node) __clk_recalc_accuracies(child); } static long clk_core_get_accuracy(struct clk_core *core) { unsigned long accuracy; clk_prepare_lock(); if (core && (core->flags & CLK_GET_ACCURACY_NOCACHE)) __clk_recalc_accuracies(core); accuracy = __clk_get_accuracy(core); clk_prepare_unlock(); return accuracy; } /** * clk_get_accuracy - return the accuracy of clk * @clk: the clk whose accuracy is being returned * * Simply returns the cached accuracy of the clk, unless * CLK_GET_ACCURACY_NOCACHE flag is set, which means a recalc_rate will be * issued. * If clk is NULL then returns 0. */ long clk_get_accuracy(struct clk *clk) { if (!clk) return 0; return clk_core_get_accuracy(clk->core); } EXPORT_SYMBOL_GPL(clk_get_accuracy); static unsigned long clk_recalc(struct clk_core *core, unsigned long parent_rate) { unsigned long rate = parent_rate; if (core->ops->recalc_rate && !clk_pm_runtime_get(core)) { rate = core->ops->recalc_rate(core->hw, parent_rate); clk_pm_runtime_put(core); } return rate; } /** * __clk_recalc_rates * @core: first clk in the subtree * @msg: notification type (see include/linux/clk.h) * * Walks the subtree of clks starting with clk and recalculates rates as it * goes. Note that if a clk does not implement the .recalc_rate callback then * it is assumed that the clock will take on the rate of its parent. * * clk_recalc_rates also propagates the POST_RATE_CHANGE notification, * if necessary. */ static void __clk_recalc_rates(struct clk_core *core, unsigned long msg) { unsigned long old_rate; unsigned long parent_rate = 0; struct clk_core *child; lockdep_assert_held(&prepare_lock); old_rate = core->rate; if (core->parent) parent_rate = core->parent->rate; core->rate = clk_recalc(core, parent_rate); /* * ignore NOTIFY_STOP and NOTIFY_BAD return values for POST_RATE_CHANGE * & ABORT_RATE_CHANGE notifiers */ if (core->notifier_count && msg) __clk_notify(core, msg, old_rate, core->rate); hlist_for_each_entry(child, &core->children, child_node) __clk_recalc_rates(child, msg); } static unsigned long clk_core_get_rate(struct clk_core *core) { unsigned long rate; clk_prepare_lock(); if (core && (core->flags & CLK_GET_RATE_NOCACHE)) __clk_recalc_rates(core, 0); rate = clk_core_get_rate_nolock(core); clk_prepare_unlock(); return rate; } /** * clk_get_rate - return the rate of clk * @clk: the clk whose rate is being returned * * Simply returns the cached rate of the clk, unless CLK_GET_RATE_NOCACHE flag * is set, which means a recalc_rate will be issued. * If clk is NULL then returns 0. */ unsigned long clk_get_rate(struct clk *clk) { if (!clk) return 0; return clk_core_get_rate(clk->core); } EXPORT_SYMBOL_GPL(clk_get_rate); static int clk_fetch_parent_index(struct clk_core *core, struct clk_core *parent) { int i; if (!parent) return -EINVAL; for (i = 0; i < core->num_parents; i++) if (clk_core_get_parent_by_index(core, i) == parent) return i; return -EINVAL; } static void clk_core_hold_state(struct clk_core *core) { if (core->need_sync || !core->boot_enabled) return; if (core->orphan || !dev_has_sync_state(core->dev)) return; if (core->flags & CLK_DONT_HOLD_STATE) return; core->need_sync = !clk_core_prepare_enable(core); } static void __clk_core_update_orphan_hold_state(struct clk_core *core) { struct clk_core *child; if (core->orphan) return; clk_core_hold_state(core); hlist_for_each_entry(child, &core->children, child_node) __clk_core_update_orphan_hold_state(child); } /* * Update the orphan status of @core and all its children. */ static void clk_core_update_orphan_status(struct clk_core *core, bool is_orphan) { struct clk_core *child; core->orphan = is_orphan; hlist_for_each_entry(child, &core->children, child_node) clk_core_update_orphan_status(child, is_orphan); } static void clk_reparent(struct clk_core *core, struct clk_core *new_parent) { bool was_orphan = core->orphan; hlist_del(&core->child_node); if (new_parent) { bool becomes_orphan = new_parent->orphan; /* avoid duplicate POST_RATE_CHANGE notifications */ if (new_parent->new_child == core) new_parent->new_child = NULL; hlist_add_head(&core->child_node, &new_parent->children); if (was_orphan != becomes_orphan) clk_core_update_orphan_status(core, becomes_orphan); } else { hlist_add_head(&core->child_node, &clk_orphan_list); if (!was_orphan) clk_core_update_orphan_status(core, true); } core->parent = new_parent; } static struct clk_core *__clk_set_parent_before(struct clk_core *core, struct clk_core *parent) { unsigned long flags; struct clk_core *old_parent = core->parent; /* * 1. enable parents for CLK_OPS_PARENT_ENABLE clock * * 2. Migrate prepare state between parents and prevent race with * clk_enable(). * * If the clock is not prepared, then a race with * clk_enable/disable() is impossible since we already have the * prepare lock (future calls to clk_enable() need to be preceded by * a clk_prepare()). * * If the clock is prepared, migrate the prepared state to the new * parent and also protect against a race with clk_enable() by * forcing the clock and the new parent on. This ensures that all * future calls to clk_enable() are practically NOPs with respect to * hardware and software states. * * See also: Comment for clk_set_parent() below. */ /* enable old_parent & parent if CLK_OPS_PARENT_ENABLE is set */ if (core->flags & CLK_OPS_PARENT_ENABLE) { clk_core_prepare_enable(old_parent); clk_core_prepare_enable(parent); } /* migrate prepare count if > 0 */ if (core->prepare_count) { clk_core_prepare_enable(parent); clk_core_enable_lock(core); } /* update the clk tree topology */ flags = clk_enable_lock(); clk_reparent(core, parent); clk_enable_unlock(flags); return old_parent; } static void __clk_set_parent_after(struct clk_core *core, struct clk_core *parent, struct clk_core *old_parent) { /* * Finish the migration of prepare state and undo the changes done * for preventing a race with clk_enable(). */ if (core->prepare_count) { clk_core_disable_lock(core); clk_core_disable_unprepare(old_parent); } /* re-balance ref counting if CLK_OPS_PARENT_ENABLE is set */ if (core->flags & CLK_OPS_PARENT_ENABLE) { clk_core_disable_unprepare(parent); clk_core_disable_unprepare(old_parent); } } static int __clk_set_parent(struct clk_core *core, struct clk_core *parent, u8 p_index) { unsigned long flags; int ret = 0; struct clk_core *old_parent; old_parent = __clk_set_parent_before(core, parent); trace_clk_set_parent(core, parent); /* change clock input source */ if (parent && core->ops->set_parent) ret = core->ops->set_parent(core->hw, p_index); trace_clk_set_parent_complete(core, parent); if (ret) { flags = clk_enable_lock(); clk_reparent(core, old_parent); clk_enable_unlock(flags); __clk_set_parent_after(core, old_parent, parent); return ret; } __clk_set_parent_after(core, parent, old_parent); return 0; } /** * __clk_speculate_rates * @core: first clk in the subtree * @parent_rate: the "future" rate of clk's parent * * Walks the subtree of clks starting with clk, speculating rates as it * goes and firing off PRE_RATE_CHANGE notifications as necessary. * * Unlike clk_recalc_rates, clk_speculate_rates exists only for sending * pre-rate change notifications and returns early if no clks in the * subtree have subscribed to the notifications. Note that if a clk does not * implement the .recalc_rate callback then it is assumed that the clock will * take on the rate of its parent. */ static int __clk_speculate_rates(struct clk_core *core, unsigned long parent_rate) { struct clk_core *child; unsigned long new_rate; int ret = NOTIFY_DONE; lockdep_assert_held(&prepare_lock); new_rate = clk_recalc(core, parent_rate); /* abort rate change if a driver returns NOTIFY_BAD or NOTIFY_STOP */ if (core->notifier_count) ret = __clk_notify(core, PRE_RATE_CHANGE, core->rate, new_rate); if (ret & NOTIFY_STOP_MASK) { pr_debug("%s: clk notifier callback for clock %s aborted with error %d\n", __func__, core->name, ret); goto out; } hlist_for_each_entry(child, &core->children, child_node) { ret = __clk_speculate_rates(child, new_rate); if (ret & NOTIFY_STOP_MASK) break; } out: return ret; } /* * Vote for the voltage level required for core->new_rate. Keep track of all * clocks with a changed voltage level in clk_rate_change_list. */ static int clk_vote_new_rate_vdd(struct clk_core *core) { int cur_level, next_level; int ret; if (IS_ERR_OR_NULL(core) || !core->vdd_class) return 0; if (!clk_core_is_prepared(core)) return 0; cur_level = core->new_vdd_class_vote; next_level = clk_find_vdd_level(core, core->new_rate); if (cur_level == next_level) return 0; ret = clk_vote_vdd_level(core->vdd_class, next_level); if (ret) return ret; core->new_vdd_class_vote = next_level; if (list_empty(&core->rate_change_node)) { list_add(&core->rate_change_node, &clk_rate_change_list); } else { /* * A different new_rate has been determined for a clock that * was already encountered in the clock tree traversal so the * level that was previously voted for it should be removed. */ ret = clk_unvote_vdd_level(core->vdd_class, cur_level); if (ret) return ret; } return 0; } static int clk_calc_subtree(struct clk_core *core, unsigned long new_rate, struct clk_core *new_parent, u8 p_index) { struct clk_core *child; int ret; core->new_rate = new_rate; ret = clk_vote_new_rate_vdd(core); if (ret) return ret; core->new_parent = new_parent; core->new_parent_index = p_index; /* include clk in new parent's PRE_RATE_CHANGE notifications */ core->new_child = NULL; if (new_parent && new_parent != core->parent) new_parent->new_child = core; hlist_for_each_entry(child, &core->children, child_node) { child->new_rate = clk_recalc(child, new_rate); ret = clk_calc_subtree(child, child->new_rate, NULL, 0); if (ret) return ret; } return 0; } /* * calculate the new rates returning the topmost clock that has to be * changed. */ static struct clk_core *clk_calc_new_rates(struct clk_core *core, unsigned long rate) { struct clk_core *top = core; struct clk_core *old_parent, *parent; unsigned long best_parent_rate = 0; unsigned long new_rate; unsigned long min_rate; unsigned long max_rate; int p_index = 0; long ret; /* sanity */ if (IS_ERR_OR_NULL(core)) return NULL; /* save parent rate, if it exists */ parent = old_parent = core->parent; if (parent) best_parent_rate = parent->rate; clk_core_get_boundaries(core, &min_rate, &max_rate); /* find the closest rate and parent clk/rate */ if (clk_core_can_round(core)) { struct clk_rate_request req; req.rate = rate; req.min_rate = min_rate; req.max_rate = max_rate; clk_core_init_rate_req(core, &req); ret = clk_core_determine_round_nolock(core, &req); if (ret < 0) return NULL; best_parent_rate = req.best_parent_rate; new_rate = req.rate; parent = req.best_parent_hw ? req.best_parent_hw->core : NULL; if (new_rate < min_rate || new_rate > max_rate) return NULL; } else if (!parent || !(core->flags & CLK_SET_RATE_PARENT)) { /* pass-through clock without adjustable parent */ core->new_rate = core->rate; return NULL; } else { /* pass-through clock with adjustable parent */ top = clk_calc_new_rates(parent, rate); new_rate = parent->new_rate; goto out; } /* some clocks must be gated to change parent */ if (parent != old_parent && (core->flags & CLK_SET_PARENT_GATE) && core->prepare_count) { pr_debug("%s: %s not gated but wants to reparent\n", __func__, core->name); return NULL; } /* try finding the new parent index */ if (parent && core->num_parents > 1) { p_index = clk_fetch_parent_index(core, parent); if (p_index < 0) { pr_debug("%s: clk %s can not be parent of clk %s\n", __func__, parent->name, core->name); return NULL; } } /* * Certain PLLs only have 16 bits to program the fractional divider. * Hence the programmed rate might be slightly different than the * requested one. */ if ((core->flags & CLK_SET_RATE_PARENT) && parent && (DIV_ROUND_CLOSEST(best_parent_rate, 1000) != DIV_ROUND_CLOSEST(parent->rate, 1000))) top = clk_calc_new_rates(parent, best_parent_rate); out: if (!clk_is_rate_level_valid(core, rate)) return NULL; ret = clk_calc_subtree(core, new_rate, parent, p_index); if (ret) return NULL; return top; } /* * Notify about rate changes in a subtree. Always walk down the whole tree * so that in case of an error we can walk down the whole tree again and * abort the change. */ static struct clk_core *clk_propagate_rate_change(struct clk_core *core, unsigned long event) { struct clk_core *child, *tmp_clk, *fail_clk = NULL; int ret = NOTIFY_DONE; if (core->rate == core->new_rate) return NULL; if (core->notifier_count) { ret = __clk_notify(core, event, core->rate, core->new_rate); if (ret & NOTIFY_STOP_MASK) fail_clk = core; } hlist_for_each_entry(child, &core->children, child_node) { /* Skip children who will be reparented to another clock */ if (child->new_parent && child->new_parent != core) continue; tmp_clk = clk_propagate_rate_change(child, event); if (tmp_clk) fail_clk = tmp_clk; } /* handle the new child who might not be in core->children yet */ if (core->new_child) { tmp_clk = clk_propagate_rate_change(core->new_child, event); if (tmp_clk) fail_clk = tmp_clk; } return fail_clk; } /* * walk down a subtree and set the new rates notifying the rate * change on the way */ static int clk_change_rate(struct clk_core *core) { struct clk_core *child; struct hlist_node *tmp; unsigned long old_rate; unsigned long best_parent_rate = 0; bool skip_set_rate = false; struct clk_core *old_parent; struct clk_core *parent = NULL; int rc = 0; old_rate = core->rate; if (core->new_parent) { parent = core->new_parent; best_parent_rate = core->new_parent->rate; } else if (core->parent) { parent = core->parent; best_parent_rate = core->parent->rate; } rc = clk_pm_runtime_get(core); if (rc) return rc; if (core->flags & CLK_SET_RATE_UNGATE) { unsigned long flags; clk_core_prepare(core); flags = clk_enable_lock(); clk_core_enable(core); clk_enable_unlock(flags); } trace_clk_set_rate(core, core->new_rate); if (core->new_parent && core->new_parent != core->parent) { old_parent = __clk_set_parent_before(core, core->new_parent); trace_clk_set_parent(core, core->new_parent); if (core->ops->set_rate_and_parent) { skip_set_rate = true; core->ops->set_rate_and_parent(core->hw, core->new_rate, best_parent_rate, core->new_parent_index); } else if (core->ops->set_parent) { core->ops->set_parent(core->hw, core->new_parent_index); } trace_clk_set_parent_complete(core, core->new_parent); __clk_set_parent_after(core, core->new_parent, old_parent); } if (core->flags & CLK_OPS_PARENT_ENABLE) clk_core_prepare_enable(parent); if (!skip_set_rate && core->ops->set_rate) { rc = core->ops->set_rate(core->hw, core->new_rate, best_parent_rate); if (rc) { trace_clk_set_rate_complete(core, core->new_rate); goto err_set_rate; } } trace_clk_set_rate_complete(core, core->new_rate); core->rate = clk_recalc(core, best_parent_rate); if (core->flags & CLK_SET_RATE_UNGATE) { unsigned long flags; flags = clk_enable_lock(); clk_core_disable(core); clk_enable_unlock(flags); clk_core_unprepare(core); } if (core->flags & CLK_OPS_PARENT_ENABLE) clk_core_disable_unprepare(parent); if (core->notifier_count && old_rate != core->rate) __clk_notify(core, POST_RATE_CHANGE, old_rate, core->rate); if (core->flags & CLK_RECALC_NEW_RATES) (void)clk_calc_new_rates(core, core->new_rate); /* * Use safe iteration, as change_rate can actually swap parents * for certain clock types. */ hlist_for_each_entry_safe(child, tmp, &core->children, child_node) { /* Skip children who will be reparented to another clock */ if (child->new_parent && child->new_parent != core) continue; rc = clk_change_rate(child); if (rc) goto err_set_rate; } /* handle the new child who might not be in core->children yet */ if (core->new_child) rc = clk_change_rate(core->new_child); err_set_rate: clk_pm_runtime_put(core); return rc; } static unsigned long clk_core_req_round_rate_nolock(struct clk_core *core, unsigned long req_rate) { int ret, cnt; struct clk_rate_request req; lockdep_assert_held(&prepare_lock); if (!core) return 0; /* simulate what the rate would be if it could be freely set */ cnt = clk_core_rate_nuke_protect(core); if (cnt < 0) return cnt; clk_core_get_boundaries(core, &req.min_rate, &req.max_rate); req.rate = req_rate; ret = clk_core_round_rate_nolock(core, &req); /* restore the protection */ clk_core_rate_restore_protect(core, cnt); return ret ? 0 : req.rate; } /* * Unvote for the voltage level required for each core->new_vdd_class_vote in * clk_rate_change_list. This is used when undoing voltage requests after an * error is encountered before any physical rate changing. */ static void clk_unvote_new_rate_vdd(void) { struct clk_core *core; list_for_each_entry(core, &clk_rate_change_list, rate_change_node) { clk_unvote_vdd_level(core->vdd_class, core->new_vdd_class_vote); core->new_vdd_class_vote = core->vdd_class_vote; } } /* * Unvote for the voltage level required for each core->vdd_class_vote in * clk_rate_change_list. */ static int clk_unvote_old_rate_vdd(void) { struct clk_core *core; int ret; list_for_each_entry(core, &clk_rate_change_list, rate_change_node) { ret = clk_unvote_vdd_level(core->vdd_class, core->vdd_class_vote); if (ret) return ret; } return 0; } /* * In the case that rate setting fails, apply the max voltage level needed * by either the old or new rate for each changed clock. */ static void clk_vote_safe_vdd(void) { struct clk_core *core; list_for_each_entry(core, &clk_rate_change_list, rate_change_node) { if (core->vdd_class_vote > core->new_vdd_class_vote) { clk_vote_vdd_level(core->vdd_class, core->vdd_class_vote); clk_unvote_vdd_level(core->vdd_class, core->new_vdd_class_vote); core->new_vdd_class_vote = core->vdd_class_vote; } } } static void clk_cleanup_vdd_votes(void) { struct clk_core *core, *temp; list_for_each_entry_safe(core, temp, &clk_rate_change_list, rate_change_node) { core->vdd_class_vote = core->new_vdd_class_vote; list_del_init(&core->rate_change_node); } } static int clk_core_set_rate_nolock(struct clk_core *core, unsigned long req_rate) { struct clk_core *top, *fail_clk; unsigned long rate; int ret = 0; /* * The prepare lock ensures mutual exclusion with other tasks. * set_rate_nesting_count is a static so that it can be incremented in * the case of reentrancy caused by a set_rate() ops callback itself * calling clk_set_rate(). That way, the voltage level votes for the * old rates are safely removed when the original invocation of this * function completes. */ static unsigned int set_rate_nesting_count; if (!core) return 0; rate = clk_core_req_round_rate_nolock(core, req_rate); /* bail early if nothing to do */ if (rate == clk_core_get_rate_nolock(core)) return 0; /* fail on a direct rate set of a protected provider */ if (clk_core_rate_is_protected(core)) return -EBUSY; set_rate_nesting_count++; /* calculate new rates and get the topmost changed clock */ top = clk_calc_new_rates(core, req_rate); if (!top) { ret = -EINVAL; goto pre_rate_change_err; } ret = clk_pm_runtime_get(core); if (ret) goto pre_rate_change_err; /* notify that we are about to change rates */ fail_clk = clk_propagate_rate_change(top, PRE_RATE_CHANGE); if (fail_clk) { pr_debug("%s: failed to set %s clock to run at %lu\n", __func__, fail_clk->name, req_rate); clk_propagate_rate_change(top, ABORT_RATE_CHANGE); ret = -EBUSY; clk_pm_runtime_put(core); goto pre_rate_change_err; } /* change the rates */ ret = clk_change_rate(top); set_rate_nesting_count--; if (ret) { pr_err("%s: failed to set %s clock to run at %lu\n", __func__, top->name, req_rate); clk_propagate_rate_change(top, ABORT_RATE_CHANGE); clk_vote_safe_vdd(); goto post_rate_change_err; } core->req_rate = req_rate; post_rate_change_err: /* * Only remove vdd_class level votes for old clock rates after all * nested clk_set_rate() calls have completed. */ if (set_rate_nesting_count == 0) { ret |= clk_unvote_old_rate_vdd(); clk_cleanup_vdd_votes(); } clk_pm_runtime_put(core); return ret; pre_rate_change_err: set_rate_nesting_count--; if (set_rate_nesting_count == 0) { clk_unvote_new_rate_vdd(); clk_cleanup_vdd_votes(); } return ret; } /** * clk_set_rate - specify a new rate for clk * @clk: the clk whose rate is being changed * @rate: the new rate for clk * * In the simplest case clk_set_rate will only adjust the rate of clk. * * Setting the CLK_SET_RATE_PARENT flag allows the rate change operation to * propagate up to clk's parent; whether or not this happens depends on the * outcome of clk's .round_rate implementation. If *parent_rate is unchanged * after calling .round_rate then upstream parent propagation is ignored. If * *parent_rate comes back with a new rate for clk's parent then we propagate * up to clk's parent and set its rate. Upward propagation will continue * until either a clk does not support the CLK_SET_RATE_PARENT flag or * .round_rate stops requesting changes to clk's parent_rate. * * Rate changes are accomplished via tree traversal that also recalculates the * rates for the clocks and fires off POST_RATE_CHANGE notifiers. * * Returns 0 on success, -EERROR otherwise. */ int clk_set_rate(struct clk *clk, unsigned long rate) { int ret; if (!clk) return 0; /* prevent racing with updates to the clock topology */ clk_prepare_lock(); if (clk->exclusive_count) clk_core_rate_unprotect(clk->core); ret = clk_core_set_rate_nolock(clk->core, rate); if (clk->exclusive_count) clk_core_rate_protect(clk->core); clk_prepare_unlock(); return ret; } EXPORT_SYMBOL_GPL(clk_set_rate); /** * clk_set_rate_exclusive - specify a new rate get exclusive control * @clk: the clk whose rate is being changed * @rate: the new rate for clk * * This is a combination of clk_set_rate() and clk_rate_exclusive_get() * within a critical section * * This can be used initially to ensure that at least 1 consumer is * statisfied when several consumers are competing for exclusivity over the * same clock provider. * * The exclusivity is not applied if setting the rate failed. * * Calls to clk_rate_exclusive_get() should be balanced with calls to * clk_rate_exclusive_put(). * * Returns 0 on success, -EERROR otherwise. */ int clk_set_rate_exclusive(struct clk *clk, unsigned long rate) { int ret; if (!clk) return 0; /* prevent racing with updates to the clock topology */ clk_prepare_lock(); /* * The temporary protection removal is not here, on purpose * This function is meant to be used instead of clk_rate_protect, * so before the consumer code path protect the clock provider */ ret = clk_core_set_rate_nolock(clk->core, rate); if (!ret) { clk_core_rate_protect(clk->core); clk->exclusive_count++; } clk_prepare_unlock(); return ret; } EXPORT_SYMBOL_GPL(clk_set_rate_exclusive); /** * clk_set_rate_range - set a rate range for a clock source * @clk: clock source * @min: desired minimum clock rate in Hz, inclusive * @max: desired maximum clock rate in Hz, inclusive * * Returns success (0) or negative errno. */ int clk_set_rate_range(struct clk *clk, unsigned long min, unsigned long max) { int ret = 0; unsigned long old_min, old_max, rate; if (!clk) return 0; if (min > max) { pr_err("%s: clk %s dev %s con %s: invalid range [%lu, %lu]\n", __func__, clk->core->name, clk->dev_id, clk->con_id, min, max); return -EINVAL; } clk_prepare_lock(); if (clk->exclusive_count) clk_core_rate_unprotect(clk->core); /* Save the current values in case we need to rollback the change */ old_min = clk->min_rate; old_max = clk->max_rate; clk->min_rate = min; clk->max_rate = max; rate = clk_core_get_rate_nolock(clk->core); if (rate < min || rate > max) { /* * FIXME: * We are in bit of trouble here, current rate is outside the * the requested range. We are going try to request appropriate * range boundary but there is a catch. It may fail for the * usual reason (clock broken, clock protected, etc) but also * because: * - round_rate() was not favorable and fell on the wrong * side of the boundary * - the determine_rate() callback does not really check for * this corner case when determining the rate */ if (rate < min) rate = min; else rate = max; ret = clk_core_set_rate_nolock(clk->core, rate); if (ret) { /* rollback the changes */ clk->min_rate = old_min; clk->max_rate = old_max; } } if (clk->exclusive_count) clk_core_rate_protect(clk->core); clk_prepare_unlock(); return ret; } EXPORT_SYMBOL_GPL(clk_set_rate_range); /** * clk_set_min_rate - set a minimum clock rate for a clock source * @clk: clock source * @rate: desired minimum clock rate in Hz, inclusive * * Returns success (0) or negative errno. */ int clk_set_min_rate(struct clk *clk, unsigned long rate) { if (!clk) return 0; return clk_set_rate_range(clk, rate, clk->max_rate); } EXPORT_SYMBOL_GPL(clk_set_min_rate); /** * clk_set_max_rate - set a maximum clock rate for a clock source * @clk: clock source * @rate: desired maximum clock rate in Hz, inclusive * * Returns success (0) or negative errno. */ int clk_set_max_rate(struct clk *clk, unsigned long rate) { if (!clk) return 0; return clk_set_rate_range(clk, clk->min_rate, rate); } EXPORT_SYMBOL_GPL(clk_set_max_rate); /** * clk_get_parent - return the parent of a clk * @clk: the clk whose parent gets returned * * Simply returns clk->parent. Returns NULL if clk is NULL. */ struct clk *clk_get_parent(struct clk *clk) { struct clk *parent; if (!clk) return NULL; clk_prepare_lock(); /* TODO: Create a per-user clk and change callers to call clk_put */ parent = !clk->core->parent ? NULL : clk->core->parent->hw->clk; clk_prepare_unlock(); return parent; } EXPORT_SYMBOL_GPL(clk_get_parent); static struct clk_core *__clk_init_parent(struct clk_core *core) { u8 index = 0; if (core->num_parents > 1 && core->ops->get_parent) index = core->ops->get_parent(core->hw); return clk_core_get_parent_by_index(core, index); } static void clk_core_reparent(struct clk_core *core, struct clk_core *new_parent) { clk_reparent(core, new_parent); __clk_recalc_accuracies(core); __clk_recalc_rates(core, POST_RATE_CHANGE); } void clk_hw_reparent(struct clk_hw *hw, struct clk_hw *new_parent) { if (!hw) return; clk_core_reparent(hw->core, !new_parent ? NULL : new_parent->core); } /** * clk_has_parent - check if a clock is a possible parent for another * @clk: clock source * @parent: parent clock source * * This function can be used in drivers that need to check that a clock can be * the parent of another without actually changing the parent. * * Returns true if @parent is a possible parent for @clk, false otherwise. */ bool clk_has_parent(struct clk *clk, struct clk *parent) { struct clk_core *core, *parent_core; /* NULL clocks should be nops, so return success if either is NULL. */ if (!clk || !parent) return true; core = clk->core; parent_core = parent->core; /* Optimize for the case where the parent is already the parent. */ if (core->parent == parent_core) return true; return match_string(core->parent_names, core->num_parents, parent_core->name) >= 0; } EXPORT_SYMBOL_GPL(clk_has_parent); static int clk_core_set_parent_nolock(struct clk_core *core, struct clk_core *parent) { int ret = 0; int p_index = 0; unsigned long p_rate = 0; lockdep_assert_held(&prepare_lock); if (!core) return 0; if (core->parent == parent && !(core->flags & CLK_IS_MEASURE)) return 0; /* verify ops for for multi-parent clks */ if (core->num_parents > 1 && !core->ops->set_parent) return -EPERM; /* check that we are allowed to re-parent if the clock is in use */ if ((core->flags & CLK_SET_PARENT_GATE) && core->prepare_count) return -EBUSY; if (clk_core_rate_is_protected(core)) return -EBUSY; /* try finding the new parent index */ if (parent) { p_index = clk_fetch_parent_index(core, parent); if (p_index < 0) { pr_debug("%s: clk %s can not be parent of clk %s\n", __func__, parent->name, core->name); return p_index; } p_rate = parent->rate; } ret = clk_pm_runtime_get(core); if (ret) return ret; /* propagate PRE_RATE_CHANGE notifications */ ret = __clk_speculate_rates(core, p_rate); /* abort if a driver objects */ if (ret & NOTIFY_STOP_MASK) goto runtime_put; /* do the re-parent */ ret = __clk_set_parent(core, parent, p_index); /* propagate rate an accuracy recalculation accordingly */ if (ret) { __clk_recalc_rates(core, ABORT_RATE_CHANGE); } else { __clk_recalc_rates(core, POST_RATE_CHANGE); __clk_recalc_accuracies(core); } runtime_put: clk_pm_runtime_put(core); return ret; } /** * clk_set_parent - switch the parent of a mux clk * @clk: the mux clk whose input we are switching * @parent: the new input to clk * * Re-parent clk to use parent as its new input source. If clk is in * prepared state, the clk will get enabled for the duration of this call. If * that's not acceptable for a specific clk (Eg: the consumer can't handle * that, the reparenting is glitchy in hardware, etc), use the * CLK_SET_PARENT_GATE flag to allow reparenting only when clk is unprepared. * * After successfully changing clk's parent clk_set_parent will update the * clk topology, sysfs topology and propagate rate recalculation via * __clk_recalc_rates. * * Returns 0 on success, -EERROR otherwise. */ int clk_set_parent(struct clk *clk, struct clk *parent) { int ret; if (!clk) return 0; clk_prepare_lock(); if (clk->exclusive_count) clk_core_rate_unprotect(clk->core); ret = clk_core_set_parent_nolock(clk->core, parent ? parent->core : NULL); if (clk->exclusive_count) clk_core_rate_protect(clk->core); clk_prepare_unlock(); return ret; } EXPORT_SYMBOL_GPL(clk_set_parent); static int clk_core_set_phase_nolock(struct clk_core *core, int degrees) { int ret = -EINVAL; lockdep_assert_held(&prepare_lock); if (!core) return 0; if (clk_core_rate_is_protected(core)) return -EBUSY; trace_clk_set_phase(core, degrees); if (core->ops->set_phase) { ret = core->ops->set_phase(core->hw, degrees); if (!ret) core->phase = degrees; } trace_clk_set_phase_complete(core, degrees); return ret; } /** * clk_set_phase - adjust the phase shift of a clock signal * @clk: clock signal source * @degrees: number of degrees the signal is shifted * * Shifts the phase of a clock signal by the specified * degrees. Returns 0 on success, -EERROR otherwise. * * This function makes no distinction about the input or reference * signal that we adjust the clock signal phase against. For example * phase locked-loop clock signal generators we may shift phase with * respect to feedback clock signal input, but for other cases the * clock phase may be shifted with respect to some other, unspecified * signal. * * Additionally the concept of phase shift does not propagate through * the clock tree hierarchy, which sets it apart from clock rates and * clock accuracy. A parent clock phase attribute does not have an * impact on the phase attribute of a child clock. */ int clk_set_phase(struct clk *clk, int degrees) { int ret; if (!clk) return 0; /* sanity check degrees */ degrees %= 360; if (degrees < 0) degrees += 360; clk_prepare_lock(); if (clk->exclusive_count) clk_core_rate_unprotect(clk->core); ret = clk_core_set_phase_nolock(clk->core, degrees); if (clk->exclusive_count) clk_core_rate_protect(clk->core); clk_prepare_unlock(); return ret; } EXPORT_SYMBOL_GPL(clk_set_phase); static int clk_core_get_phase(struct clk_core *core) { int ret; clk_prepare_lock(); /* Always try to update cached phase if possible */ if (core->ops->get_phase) core->phase = core->ops->get_phase(core->hw); ret = core->phase; clk_prepare_unlock(); return ret; } /** * clk_get_phase - return the phase shift of a clock signal * @clk: clock signal source * * Returns the phase shift of a clock node in degrees, otherwise returns * -EERROR. */ int clk_get_phase(struct clk *clk) { if (!clk) return 0; return clk_core_get_phase(clk->core); } EXPORT_SYMBOL_GPL(clk_get_phase); static void clk_core_reset_duty_cycle_nolock(struct clk_core *core) { /* Assume a default value of 50% */ core->duty.num = 1; core->duty.den = 2; } static int clk_core_update_duty_cycle_parent_nolock(struct clk_core *core); static int clk_core_update_duty_cycle_nolock(struct clk_core *core) { struct clk_duty *duty = &core->duty; int ret = 0; if (!core->ops->get_duty_cycle) return clk_core_update_duty_cycle_parent_nolock(core); ret = core->ops->get_duty_cycle(core->hw, duty); if (ret) goto reset; /* Don't trust the clock provider too much */ if (duty->den == 0 || duty->num > duty->den) { ret = -EINVAL; goto reset; } return 0; reset: clk_core_reset_duty_cycle_nolock(core); return ret; } static int clk_core_update_duty_cycle_parent_nolock(struct clk_core *core) { int ret = 0; if (core->parent && core->flags & CLK_DUTY_CYCLE_PARENT) { ret = clk_core_update_duty_cycle_nolock(core->parent); memcpy(&core->duty, &core->parent->duty, sizeof(core->duty)); } else { clk_core_reset_duty_cycle_nolock(core); } return ret; } static int clk_core_set_duty_cycle_parent_nolock(struct clk_core *core, struct clk_duty *duty); static int clk_core_set_duty_cycle_nolock(struct clk_core *core, struct clk_duty *duty) { int ret; lockdep_assert_held(&prepare_lock); if (clk_core_rate_is_protected(core)) return -EBUSY; trace_clk_set_duty_cycle(core, duty); if (!core->ops->set_duty_cycle) return clk_core_set_duty_cycle_parent_nolock(core, duty); ret = core->ops->set_duty_cycle(core->hw, duty); if (!ret) memcpy(&core->duty, duty, sizeof(*duty)); trace_clk_set_duty_cycle_complete(core, duty); return ret; } static int clk_core_set_duty_cycle_parent_nolock(struct clk_core *core, struct clk_duty *duty) { int ret = 0; if (core->parent && core->flags & (CLK_DUTY_CYCLE_PARENT | CLK_SET_RATE_PARENT)) { ret = clk_core_set_duty_cycle_nolock(core->parent, duty); memcpy(&core->duty, &core->parent->duty, sizeof(core->duty)); } return ret; } /** * clk_set_duty_cycle - adjust the duty cycle ratio of a clock signal * @clk: clock signal source * @num: numerator of the duty cycle ratio to be applied * @den: denominator of the duty cycle ratio to be applied * * Apply the duty cycle ratio if the ratio is valid and the clock can * perform this operation * * Returns (0) on success, a negative errno otherwise. */ int clk_set_duty_cycle(struct clk *clk, unsigned int num, unsigned int den) { int ret; struct clk_duty duty; if (!clk) return 0; /* sanity check the ratio */ if (den == 0 || num > den) return -EINVAL; duty.num = num; duty.den = den; clk_prepare_lock(); if (clk->exclusive_count) clk_core_rate_unprotect(clk->core); ret = clk_core_set_duty_cycle_nolock(clk->core, &duty); if (clk->exclusive_count) clk_core_rate_protect(clk->core); clk_prepare_unlock(); return ret; } EXPORT_SYMBOL_GPL(clk_set_duty_cycle); static int clk_core_get_scaled_duty_cycle(struct clk_core *core, unsigned int scale) { struct clk_duty *duty = &core->duty; int ret; clk_prepare_lock(); ret = clk_core_update_duty_cycle_nolock(core); if (!ret) ret = mult_frac(scale, duty->num, duty->den); clk_prepare_unlock(); return ret; } /** * clk_get_scaled_duty_cycle - return the duty cycle ratio of a clock signal * @clk: clock signal source * @scale: scaling factor to be applied to represent the ratio as an integer * * Returns the duty cycle ratio of a clock node multiplied by the provided * scaling factor, or negative errno on error. */ int clk_get_scaled_duty_cycle(struct clk *clk, unsigned int scale) { if (!clk) return 0; return clk_core_get_scaled_duty_cycle(clk->core, scale); } EXPORT_SYMBOL_GPL(clk_get_scaled_duty_cycle); /** * clk_is_match - check if two clk's point to the same hardware clock * @p: clk compared against q * @q: clk compared against p * * Returns true if the two struct clk pointers both point to the same hardware * clock node. Put differently, returns true if struct clk *p and struct clk *q * share the same struct clk_core object. * * Returns false otherwise. Note that two NULL clks are treated as matching. */ bool clk_is_match(const struct clk *p, const struct clk *q) { /* trivial case: identical struct clk's or both NULL */ if (p == q) return true; /* true if clk->core pointers match. Avoid dereferencing garbage */ if (!IS_ERR_OR_NULL(p) && !IS_ERR_OR_NULL(q)) if (p->core == q->core) return true; return false; } EXPORT_SYMBOL_GPL(clk_is_match); int clk_set_flags(struct clk *clk, unsigned long flags) { if (!clk) return 0; if (!clk->core->ops->set_flags) return -EINVAL; return clk->core->ops->set_flags(clk->core->hw, flags); } EXPORT_SYMBOL_GPL(clk_set_flags); void clk_debug_print_hw(struct clk_core *clk, struct seq_file *f) { } EXPORT_SYMBOL(clk_debug_print_hw); #ifdef CONFIG_SEC_PM static struct hlist_head *debug_all_lists[] = { &clk_root_list, &clk_orphan_list, NULL, }; static int sec_clock_debug_print_clock(struct clk_core *c, int level) { int count = 0; struct clk_core *child; if (!c || !c->enable_count) return count; pr_info("%*s%-*s %11d %12d %11lu %10lu %-3d\n", level * 3 + 1, "", 30 - level * 3, c->name, c->enable_count, c->prepare_count, clk_core_get_rate(c), clk_core_get_accuracy(c), clk_core_get_phase(c)); count++; hlist_for_each_entry(child, &c->children, child_node) count += sec_clock_debug_print_clock(child, level + 1); return count; } void sec_clock_debug_print_enabled(void) { int count = 0; struct clk_core *c; struct hlist_head **lists = (struct hlist_head **)debug_all_lists; pr_info("Enabled clocks:\n"); pr_info(" clock enable_cnt prepare_cnt rate accuracy phase\n"); pr_info("----------------------------------------------------------------------------------------\n"); clk_prepare_lock(); for (; *lists; lists++) hlist_for_each_entry(c, *lists, child_node) count += sec_clock_debug_print_clock(c, 0); clk_prepare_unlock(); pr_info("Enabled clock count: %d\n", count); } EXPORT_SYMBOL(sec_clock_debug_print_enabled); #endif /* CONFIG_SEC_PM */ /*** debugfs support ***/ #ifdef CONFIG_DEBUG_FS #include static struct dentry *rootdir; static int inited = 0; static DEFINE_MUTEX(clk_debug_lock); static HLIST_HEAD(clk_debug_list); static void clk_summary_show_one(struct seq_file *s, struct clk_core *c, int level) { if (!c) return; seq_printf(s, "%*s%-*s %7d %8d %8d %11lu %10lu %5d %6d\n", level * 3 + 1, "", 30 - level * 3, c->name, c->enable_count, c->prepare_count, c->protect_count, clk_core_get_rate(c), clk_core_get_accuracy(c), clk_core_get_phase(c), clk_core_get_scaled_duty_cycle(c, 100000)); } static void clk_summary_show_subtree(struct seq_file *s, struct clk_core *c, int level) { struct clk_core *child; if (!c) return; clk_summary_show_one(s, c, level); hlist_for_each_entry(child, &c->children, child_node) clk_summary_show_subtree(s, child, level + 1); } static int clk_summary_show(struct seq_file *s, void *data) { struct clk_core *c; struct hlist_head **lists = (struct hlist_head **)s->private; seq_puts(s, " enable prepare protect duty\n"); seq_puts(s, " clock count count count rate accuracy phase cycle\n"); seq_puts(s, "---------------------------------------------------------------------------------------------\n"); clk_prepare_lock(); for (; *lists; lists++) hlist_for_each_entry(c, *lists, child_node) clk_summary_show_subtree(s, c, 0); clk_prepare_unlock(); return 0; } DEFINE_SHOW_ATTRIBUTE(clk_summary); static void clk_dump_one(struct seq_file *s, struct clk_core *c, int level) { if (!c) return; /* This should be JSON format, i.e. elements separated with a comma */ seq_printf(s, "\"%s\": { ", c->name); seq_printf(s, "\"enable_count\": %d,", c->enable_count); seq_printf(s, "\"prepare_count\": %d,", c->prepare_count); seq_printf(s, "\"protect_count\": %d,", c->protect_count); seq_printf(s, "\"rate\": %lu,", clk_core_get_rate(c)); seq_printf(s, "\"accuracy\": %lu,", clk_core_get_accuracy(c)); seq_printf(s, "\"phase\": %d,", clk_core_get_phase(c)); seq_printf(s, "\"duty_cycle\": %u", clk_core_get_scaled_duty_cycle(c, 100000)); } static void clk_dump_subtree(struct seq_file *s, struct clk_core *c, int level) { struct clk_core *child; if (!c) return; clk_dump_one(s, c, level); hlist_for_each_entry(child, &c->children, child_node) { seq_putc(s, ','); clk_dump_subtree(s, child, level + 1); } seq_putc(s, '}'); } static int clk_dump_show(struct seq_file *s, void *data) { struct clk_core *c; bool first_node = true; struct hlist_head **lists = (struct hlist_head **)s->private; seq_putc(s, '{'); clk_prepare_lock(); for (; *lists; lists++) { hlist_for_each_entry(c, *lists, child_node) { if (!first_node) seq_putc(s, ','); first_node = false; clk_dump_subtree(s, c, 0); } } clk_prepare_unlock(); seq_puts(s, "}\n"); return 0; } DEFINE_SHOW_ATTRIBUTE(clk_dump); static const struct { unsigned long flag; const char *name; } clk_flags[] = { #define ENTRY(f) { f, #f } ENTRY(CLK_SET_RATE_GATE), ENTRY(CLK_SET_PARENT_GATE), ENTRY(CLK_SET_RATE_PARENT), ENTRY(CLK_IGNORE_UNUSED), ENTRY(CLK_IS_BASIC), ENTRY(CLK_GET_RATE_NOCACHE), ENTRY(CLK_SET_RATE_NO_REPARENT), ENTRY(CLK_GET_ACCURACY_NOCACHE), ENTRY(CLK_RECALC_NEW_RATES), ENTRY(CLK_SET_RATE_UNGATE), ENTRY(CLK_IS_CRITICAL), ENTRY(CLK_OPS_PARENT_ENABLE), ENTRY(CLK_DUTY_CYCLE_PARENT), #undef ENTRY }; static int clk_flags_show(struct seq_file *s, void *data) { struct clk_core *core = s->private; unsigned long flags = core->flags; unsigned int i; for (i = 0; flags && i < ARRAY_SIZE(clk_flags); i++) { if (flags & clk_flags[i].flag) { seq_printf(s, "%s\n", clk_flags[i].name); flags &= ~clk_flags[i].flag; } } if (flags) { /* Unknown flags */ seq_printf(s, "0x%lx\n", flags); } return 0; } DEFINE_SHOW_ATTRIBUTE(clk_flags); static int possible_parents_show(struct seq_file *s, void *data) { struct clk_core *core = s->private; int i; for (i = 0; i < core->num_parents - 1; i++) seq_printf(s, "%s ", core->parent_names[i]); seq_printf(s, "%s\n", core->parent_names[i]); return 0; } DEFINE_SHOW_ATTRIBUTE(possible_parents); static int clk_duty_cycle_show(struct seq_file *s, void *data) { struct clk_core *core = s->private; struct clk_duty *duty = &core->duty; seq_printf(s, "%u/%u\n", duty->num, duty->den); return 0; } DEFINE_SHOW_ATTRIBUTE(clk_duty_cycle); static void clk_debug_create_one(struct clk_core *core, struct dentry *pdentry) { struct dentry *root; if (!core || !pdentry) return; root = debugfs_create_dir(core->name, pdentry); core->dentry = root; debugfs_create_ulong("clk_rate", 0444, root, &core->rate); debugfs_create_ulong("clk_accuracy", 0444, root, &core->accuracy); debugfs_create_u32("clk_phase", 0444, root, &core->phase); debugfs_create_file("clk_flags", 0444, root, core, &clk_flags_fops); debugfs_create_u32("clk_prepare_count", 0444, root, &core->prepare_count); debugfs_create_u32("clk_enable_count", 0444, root, &core->enable_count); debugfs_create_u32("clk_protect_count", 0444, root, &core->protect_count); debugfs_create_u32("clk_notifier_count", 0444, root, &core->notifier_count); debugfs_create_file("clk_duty_cycle", 0444, root, core, &clk_duty_cycle_fops); if (core->num_parents > 1) debugfs_create_file("clk_possible_parents", 0444, root, core, &possible_parents_fops); if (core->ops->debug_init) core->ops->debug_init(core->hw, core->dentry); } /** * clk_debug_register - add a clk node to the debugfs clk directory * @core: the clk being added to the debugfs clk directory * * Dynamically adds a clk to the debugfs clk directory if debugfs has been * initialized. Otherwise it bails out early since the debugfs clk directory * will be created lazily by clk_debug_init as part of a late_initcall. */ static void clk_debug_register(struct clk_core *core) { mutex_lock(&clk_debug_lock); hlist_add_head(&core->debug_node, &clk_debug_list); if (inited) clk_debug_create_one(core, rootdir); mutex_unlock(&clk_debug_lock); } /** * clk_debug_unregister - remove a clk node from the debugfs clk directory * @core: the clk being removed from the debugfs clk directory * * Dynamically removes a clk and all its child nodes from the * debugfs clk directory if clk->dentry points to debugfs created by * clk_debug_register in __clk_core_init. */ static void clk_debug_unregister(struct clk_core *core) { mutex_lock(&clk_debug_lock); hlist_del_init(&core->debug_node); debugfs_remove_recursive(core->dentry); core->dentry = NULL; mutex_unlock(&clk_debug_lock); } /** * clk_debug_init - lazily populate the debugfs clk directory * * clks are often initialized very early during boot before memory can be * dynamically allocated and well before debugfs is setup. This function * populates the debugfs clk directory once at boot-time when we know that * debugfs is setup. It should only be called once at boot-time, all other clks * added dynamically will be done so with clk_debug_register. */ static int __init clk_debug_init(void) { struct clk_core *core; rootdir = debugfs_create_dir("clk", NULL); debugfs_create_file("clk_summary", 0444, rootdir, &all_lists, &clk_summary_fops); debugfs_create_file("clk_dump", 0444, rootdir, &all_lists, &clk_dump_fops); debugfs_create_file("clk_orphan_summary", 0444, rootdir, &orphan_list, &clk_summary_fops); debugfs_create_file("clk_orphan_dump", 0444, rootdir, &orphan_list, &clk_dump_fops); mutex_lock(&clk_debug_lock); hlist_for_each_entry(core, &clk_debug_list, debug_node) clk_debug_create_one(core, rootdir); inited = 1; mutex_unlock(&clk_debug_lock); return 0; } late_initcall(clk_debug_init); #else static inline void clk_debug_register(struct clk_core *core) { } static inline void clk_debug_reparent(struct clk_core *core, struct clk_core *new_parent) { } static inline void clk_debug_unregister(struct clk_core *core) { } #endif /** * __clk_core_init - initialize the data structures in a struct clk_core * @core: clk_core being initialized * * Initializes the lists in struct clk_core, queries the hardware for the * parent and rate and sets them both. */ static int __clk_core_init(struct clk_core *core) { int i, ret; struct clk_core *orphan; struct hlist_node *tmp2; unsigned long rate; if (!core) return -EINVAL; clk_prepare_lock(); ret = clk_pm_runtime_get(core); if (ret) goto unlock; /* check to see if a clock with this name is already registered */ if (clk_core_lookup(core->name)) { pr_debug("%s: clk %s already initialized\n", __func__, core->name); ret = -EEXIST; goto out; } /* check that clk_ops are sane. See Documentation/driver-api/clk.rst */ if (core->ops->set_rate && !((core->ops->round_rate || core->ops->determine_rate) && core->ops->recalc_rate)) { pr_err("%s: %s must implement .round_rate or .determine_rate in addition to .recalc_rate\n", __func__, core->name); ret = -EINVAL; goto out; } if (core->ops->set_parent && !core->ops->get_parent) { pr_err("%s: %s must implement .get_parent & .set_parent\n", __func__, core->name); ret = -EINVAL; goto out; } if (core->num_parents > 1 && !core->ops->get_parent) { pr_err("%s: %s must implement .get_parent as it has multi parents\n", __func__, core->name); ret = -EINVAL; goto out; } if (core->ops->set_rate_and_parent && !(core->ops->set_parent && core->ops->set_rate)) { pr_err("%s: %s must implement .set_parent & .set_rate\n", __func__, core->name); ret = -EINVAL; goto out; } /* throw a WARN if any entries in parent_names are NULL */ for (i = 0; i < core->num_parents; i++) WARN(!core->parent_names[i], "%s: invalid NULL in %s's .parent_names\n", __func__, core->name); core->parent = __clk_init_parent(core); /* * Populate core->parent if parent has already been clk_core_init'd. If * parent has not yet been clk_core_init'd then place clk in the orphan * list. If clk doesn't have any parents then place it in the root * clk list. * * Every time a new clk is clk_init'd then we walk the list of orphan * clocks and re-parent any that are children of the clock currently * being clk_init'd. */ if (core->parent) { hlist_add_head(&core->child_node, &core->parent->children); core->orphan = core->parent->orphan; } else if (!core->num_parents) { hlist_add_head(&core->child_node, &clk_root_list); core->orphan = false; } else { hlist_add_head(&core->child_node, &clk_orphan_list); core->orphan = true; } /* * optional platform-specific magic * * The .init callback is not used by any of the basic clock types, but * exists for weird hardware that must perform initialization magic. * Please consider other ways of solving initialization problems before * using this callback, as its use is discouraged. */ if (core->ops->init) core->ops->init(core->hw); /* * Set clk's accuracy. The preferred method is to use * .recalc_accuracy. For simple clocks and lazy developers the default * fallback is to use the parent's accuracy. If a clock doesn't have a * parent (or is orphaned) then accuracy is set to zero (perfect * clock). */ if (core->ops->recalc_accuracy) core->accuracy = core->ops->recalc_accuracy(core->hw, __clk_get_accuracy(core->parent)); else if (core->parent) core->accuracy = core->parent->accuracy; else core->accuracy = 0; /* * Set clk's phase. * Since a phase is by definition relative to its parent, just * query the current clock phase, or just assume it's in phase. */ if (core->ops->get_phase) core->phase = core->ops->get_phase(core->hw); else core->phase = 0; /* * Set clk's duty cycle. */ clk_core_update_duty_cycle_nolock(core); /* * Set clk's rate. The preferred method is to use .recalc_rate. For * simple clocks and lazy developers the default fallback is to use the * parent's rate. If a clock doesn't have a parent (or is orphaned) * then rate is set to zero. */ if (core->ops->recalc_rate) rate = core->ops->recalc_rate(core->hw, clk_core_get_rate_nolock(core->parent)); else if (core->parent) rate = core->parent->rate; else rate = 0; core->rate = core->req_rate = rate; core->boot_enabled = clk_core_is_enabled(core); /* * Enable CLK_IS_CRITICAL clocks so newly added critical clocks * don't get accidentally disabled when walking the orphan tree and * reparenting clocks */ if (core->flags & CLK_IS_CRITICAL) { unsigned long flags; clk_core_prepare(core); flags = clk_enable_lock(); clk_core_enable(core); clk_enable_unlock(flags); } clk_core_hold_state(core); /* * walk the list of orphan clocks and reparent any that newly finds a * parent. */ hlist_for_each_entry_safe(orphan, tmp2, &clk_orphan_list, child_node) { struct clk_core *parent = __clk_init_parent(orphan); /* * We need to use __clk_set_parent_before() and _after() to * to properly migrate any prepare/enable count of the orphan * clock. This is important for CLK_IS_CRITICAL clocks, which * are enabled during init but might not have a parent yet. */ if (parent) { /* update the clk tree topology */ __clk_set_parent_before(orphan, parent); __clk_set_parent_after(orphan, parent, NULL); __clk_recalc_accuracies(orphan); __clk_recalc_rates(orphan, 0); __clk_core_update_orphan_hold_state(orphan); } } /* * optional platform-specific magic * * The .init callback is not used by any of the basic clock types, but * exists for weird hardware that must perform initialization magic. * Please consider other ways of solving initialization problems before * using this callback, as its use is discouraged. */ if (core->ops->init) core->ops->init(core->hw); if (core->flags & CLK_IS_CRITICAL) { unsigned long flags; clk_core_prepare(core); flags = clk_enable_lock(); clk_core_enable(core); clk_enable_unlock(flags); } /* * enable clocks with the CLK_ENABLE_HAND_OFF flag set * * This flag causes the framework to enable the clock at registration * time, which is sometimes necessary for clocks that would cause a * system crash when gated (e.g. cpu, memory, etc). The prepare_count * is migrated over to the first clk consumer to call clk_prepare(). * Similarly the clk's enable_count is migrated to the first consumer * to call clk_enable(). */ if (core->flags & CLK_ENABLE_HAND_OFF) { unsigned long flags; /* * Few clocks might have hardware gating which would be * required to be ON before prepare/enabling the clocks. So * check if the clock has been turned ON earlier and we should * prepare/enable those clocks. */ if (clk_core_is_enabled(core)) { core->need_handoff_prepare = true; core->need_handoff_enable = true; ret = clk_core_prepare(core); if (ret) goto out; flags = clk_enable_lock(); clk_core_enable(core); clk_enable_unlock(flags); } } kref_init(&core->ref); out: clk_pm_runtime_put(core); unlock: if (ret) hlist_del_init(&core->child_node); clk_prepare_unlock(); if (!ret) clk_debug_register(core); return ret; } struct clk *__clk_create_clk(struct clk_hw *hw, const char *dev_id, const char *con_id) { struct clk *clk; /* This is to allow this function to be chained to others */ if (IS_ERR_OR_NULL(hw)) return ERR_CAST(hw); clk = kzalloc(sizeof(*clk), GFP_KERNEL); if (!clk) return ERR_PTR(-ENOMEM); clk->core = hw->core; clk->dev_id = dev_id; clk->con_id = kstrdup_const(con_id, GFP_KERNEL); clk->max_rate = ULONG_MAX; clk_prepare_lock(); hlist_add_head(&clk->clks_node, &hw->core->clks); clk_prepare_unlock(); return clk; } /* keep in sync with __clk_put */ void __clk_free_clk(struct clk *clk) { clk_prepare_lock(); hlist_del(&clk->clks_node); clk_prepare_unlock(); kfree_const(clk->con_id); kfree(clk); } /** * clk_register - allocate a new clock, register it and return an opaque cookie * @dev: device that is registering this clock * @hw: link to hardware-specific clock data * * clk_register is the primary interface for populating the clock tree with new * clock nodes. It returns a pointer to the newly allocated struct clk which * cannot be dereferenced by driver code but may be used in conjunction with the * rest of the clock API. In the event of an error clk_register will return an * error code; drivers must test for an error code after calling clk_register. */ struct clk *clk_register(struct device *dev, struct clk_hw *hw) { int i, ret; struct clk_core *core; core = kzalloc(sizeof(*core), GFP_KERNEL); if (!core) { ret = -ENOMEM; goto fail_out; } core->name = kstrdup_const(hw->init->name, GFP_KERNEL); if (!core->name) { ret = -ENOMEM; goto fail_name; } if (WARN_ON(!hw->init->ops)) { ret = -EINVAL; goto fail_ops; } core->ops = hw->init->ops; if (dev && pm_runtime_enabled(dev)) core->rpm_enabled = true; core->dev = dev; if (dev && dev->driver) core->owner = dev->driver->owner; core->hw = hw; core->flags = hw->init->flags; core->num_parents = hw->init->num_parents; core->min_rate = 0; core->max_rate = ULONG_MAX; core->vdd_class = hw->init->vdd_class; core->rate_max = hw->init->rate_max; core->num_rate_max = hw->init->num_rate_max; hw->core = core; /* allocate local copy in case parent_names is __initdata */ core->parent_names = kcalloc(core->num_parents, sizeof(char *), GFP_KERNEL); if (!core->parent_names) { ret = -ENOMEM; goto fail_parent_names; } /* copy each string name in case parent_names is __initdata */ for (i = 0; i < core->num_parents; i++) { core->parent_names[i] = kstrdup_const(hw->init->parent_names[i], GFP_KERNEL); if (!core->parent_names[i]) { ret = -ENOMEM; goto fail_parent_names_copy; } } /* avoid unnecessary string look-ups of clk_core's possible parents. */ core->parents = kcalloc(core->num_parents, sizeof(*core->parents), GFP_KERNEL); if (!core->parents) { ret = -ENOMEM; goto fail_parents; }; INIT_HLIST_HEAD(&core->clks); INIT_LIST_HEAD(&core->rate_change_node); hw->clk = __clk_create_clk(hw, NULL, NULL); if (IS_ERR(hw->clk)) { ret = PTR_ERR(hw->clk); goto fail_parents; } ret = __clk_core_init(core); if (!ret) return hw->clk; __clk_free_clk(hw->clk); hw->clk = NULL; fail_parents: kfree(core->parents); fail_parent_names_copy: while (--i >= 0) kfree_const(core->parent_names[i]); kfree(core->parent_names); fail_parent_names: fail_ops: kfree_const(core->name); fail_name: kfree(core); fail_out: return ERR_PTR(ret); } EXPORT_SYMBOL_GPL(clk_register); /** * clk_hw_register - register a clk_hw and return an error code * @dev: device that is registering this clock * @hw: link to hardware-specific clock data * * clk_hw_register is the primary interface for populating the clock tree with * new clock nodes. It returns an integer equal to zero indicating success or * less than zero indicating failure. Drivers must test for an error code after * calling clk_hw_register(). */ int clk_hw_register(struct device *dev, struct clk_hw *hw) { return PTR_ERR_OR_ZERO(clk_register(dev, hw)); } EXPORT_SYMBOL_GPL(clk_hw_register); /* Free memory allocated for a clock. */ static void __clk_release(struct kref *ref) { struct clk_core *core = container_of(ref, struct clk_core, ref); int i = core->num_parents; lockdep_assert_held(&prepare_lock); kfree(core->parents); while (--i >= 0) kfree_const(core->parent_names[i]); kfree(core->parent_names); kfree_const(core->name); kfree(core); } /* * Empty clk_ops for unregistered clocks. These are used temporarily * after clk_unregister() was called on a clock and until last clock * consumer calls clk_put() and the struct clk object is freed. */ static int clk_nodrv_prepare_enable(struct clk_hw *hw) { return -ENXIO; } static void clk_nodrv_disable_unprepare(struct clk_hw *hw) { WARN_ON_ONCE(1); } static int clk_nodrv_set_rate(struct clk_hw *hw, unsigned long rate, unsigned long parent_rate) { return -ENXIO; } static int clk_nodrv_set_parent(struct clk_hw *hw, u8 index) { return -ENXIO; } static const struct clk_ops clk_nodrv_ops = { .enable = clk_nodrv_prepare_enable, .disable = clk_nodrv_disable_unprepare, .prepare = clk_nodrv_prepare_enable, .unprepare = clk_nodrv_disable_unprepare, .set_rate = clk_nodrv_set_rate, .set_parent = clk_nodrv_set_parent, }; static void clk_core_evict_parent_cache_subtree(struct clk_core *root, struct clk_core *target) { int i; struct clk_core *child; for (i = 0; i < root->num_parents; i++) if (root->parents[i] == target) root->parents[i] = NULL; hlist_for_each_entry(child, &root->children, child_node) clk_core_evict_parent_cache_subtree(child, target); } /* Remove this clk from all parent caches */ static void clk_core_evict_parent_cache(struct clk_core *core) { struct hlist_head **lists; struct clk_core *root; lockdep_assert_held(&prepare_lock); for (lists = all_lists; *lists; lists++) hlist_for_each_entry(root, *lists, child_node) clk_core_evict_parent_cache_subtree(root, core); } /** * clk_unregister - unregister a currently registered clock * @clk: clock to unregister */ void clk_unregister(struct clk *clk) { unsigned long flags; if (!clk || WARN_ON_ONCE(IS_ERR(clk))) return; clk_debug_unregister(clk->core); clk_prepare_lock(); if (clk->core->ops == &clk_nodrv_ops) { pr_err("%s: unregistered clock: %s\n", __func__, clk->core->name); goto unlock; } /* * Assign empty clock ops for consumers that might still hold * a reference to this clock. */ flags = clk_enable_lock(); clk->core->ops = &clk_nodrv_ops; clk_enable_unlock(flags); if (!hlist_empty(&clk->core->children)) { struct clk_core *child; struct hlist_node *t; /* Reparent all children to the orphan list. */ hlist_for_each_entry_safe(child, t, &clk->core->children, child_node) clk_core_set_parent_nolock(child, NULL); } clk_core_evict_parent_cache(clk->core); hlist_del_init(&clk->core->child_node); if (clk->core->prepare_count) pr_warn("%s: unregistering prepared clock: %s\n", __func__, clk->core->name); if (clk->core->protect_count) pr_warn("%s: unregistering protected clock: %s\n", __func__, clk->core->name); kref_put(&clk->core->ref, __clk_release); unlock: clk_prepare_unlock(); } EXPORT_SYMBOL_GPL(clk_unregister); /** * clk_hw_unregister - unregister a currently registered clk_hw * @hw: hardware-specific clock data to unregister */ void clk_hw_unregister(struct clk_hw *hw) { clk_unregister(hw->clk); } EXPORT_SYMBOL_GPL(clk_hw_unregister); static void devm_clk_release(struct device *dev, void *res) { clk_unregister(*(struct clk **)res); } static void devm_clk_hw_release(struct device *dev, void *res) { clk_hw_unregister(*(struct clk_hw **)res); } #define MAX_LEN_OPP_HANDLE 50 #define LEN_OPP_HANDLE 16 static int derive_device_list(struct device **device_list, struct clk_core *core, struct device_node *np, char *clk_handle_name, int count) { int j; struct platform_device *pdev; struct device_node *dev_node; for (j = 0; j < count; j++) { device_list[j] = NULL; dev_node = of_parse_phandle(np, clk_handle_name, j); if (!dev_node) { pr_err("Unable to get device_node pointer for %s opp-handle (%s)\n", core->name, clk_handle_name); return -ENODEV; } pdev = of_find_device_by_node(dev_node); if (!pdev) { pr_err("Unable to find platform_device node for %s opp-handle\n", core->name); return -ENODEV; } device_list[j] = &pdev->dev; } return 0; } static int clk_get_voltage(struct clk_core *core, unsigned long rate, int n) { struct clk_vdd_class *vdd; int level, corner; /* Use the first regulator in the vdd class for the OPP table. */ vdd = core->vdd_class; if (vdd->num_regulators > 1) { corner = vdd->vdd_uv[vdd->num_regulators * n]; } else { level = clk_find_vdd_level(core, rate); if (level < 0) { pr_err("Could not find vdd level\n"); return -EINVAL; } corner = vdd->vdd_uv[level]; } if (!corner) { pr_err("%s: Unable to find vdd level for rate %lu\n", core->name, rate); return -EINVAL; } return corner; } static int clk_add_and_print_opp(struct clk_hw *hw, struct device **device_list, int count, unsigned long rate, int uv, int n) { struct clk_core *core = hw->core; int j, ret = 0; for (j = 0; j < count; j++) { ret = dev_pm_opp_add(device_list[j], rate, uv); if (ret) { pr_err("%s: couldn't add OPP for %lu - err: %d\n", core->name, rate, ret); return ret; } if (n == 0 || n == core->num_rate_max - 1 || rate == clk_hw_round_rate(hw, INT_MAX)) pr_info("%s: set OPP pair(%lu Hz: %u uV) on %s\n", core->name, rate, uv, dev_name(device_list[j])); } return ret; } static void clk_populate_clock_opp_table(struct device_node *np, struct clk_hw *hw) { struct device **device_list; struct clk_core *core = hw->core; char clk_handle_name[MAX_LEN_OPP_HANDLE]; int n, len, count, uv, ret; unsigned long rate = 0, rrate = 0; if (!core || !core->num_rate_max) return; if (strlen(core->name) + LEN_OPP_HANDLE < MAX_LEN_OPP_HANDLE) { ret = snprintf(clk_handle_name, ARRAY_SIZE(clk_handle_name), "qcom,%s-opp-handle", core->name); if (ret < strlen(core->name) + LEN_OPP_HANDLE) { pr_err("%s: Failed to hold clk_handle_name\n", core->name); return; } } else { pr_err("clk name (%s) too large to fit in clk_handle_name\n", core->name); return; } if (of_find_property(np, clk_handle_name, &len)) { count = len/sizeof(u32); device_list = kmalloc_array(count, sizeof(struct device *), GFP_KERNEL); if (!device_list) return; ret = derive_device_list(device_list, core, np, clk_handle_name, count); if (ret < 0) { pr_err("Failed to fill device_list for %s\n", clk_handle_name); goto err_derive_device_list; } } else { pr_debug("Unable to find %s\n", clk_handle_name); return; } for (n = 0; ; n++) { rrate = clk_hw_round_rate(hw, rate + 1); if (!rrate) { pr_err("clk_round_rate failed for %s\n", core->name); goto err_derive_device_list; } /* * If clk_hw_round_rate gives the same value on consecutive * iterations, exit the loop since we're at the maximum clock * frequency. */ if (rate == rrate) break; rate = rrate; uv = clk_get_voltage(core, rate, n); if (uv < 0) goto err_derive_device_list; ret = clk_add_and_print_opp(hw, device_list, count, rate, uv, n); if (ret) goto err_derive_device_list; } err_derive_device_list: kfree(device_list); } /** * devm_clk_register - resource managed clk_register() * @dev: device that is registering this clock * @hw: link to hardware-specific clock data * * Managed clk_register(). Clocks returned from this function are * automatically clk_unregister()ed on driver detach. See clk_register() for * more information. */ struct clk *devm_clk_register(struct device *dev, struct clk_hw *hw) { struct clk *clk; struct clk **clkp; clkp = devres_alloc(devm_clk_release, sizeof(*clkp), GFP_KERNEL); if (!clkp) return ERR_PTR(-ENOMEM); clk = clk_register(dev, hw); if (!IS_ERR(clk)) { *clkp = clk; devres_add(dev, clkp); } else { devres_free(clkp); } clk_populate_clock_opp_table(dev->of_node, hw); return clk; } EXPORT_SYMBOL_GPL(devm_clk_register); /** * devm_clk_hw_register - resource managed clk_hw_register() * @dev: device that is registering this clock * @hw: link to hardware-specific clock data * * Managed clk_hw_register(). Clocks registered by this function are * automatically clk_hw_unregister()ed on driver detach. See clk_hw_register() * for more information. */ int devm_clk_hw_register(struct device *dev, struct clk_hw *hw) { struct clk_hw **hwp; int ret; hwp = devres_alloc(devm_clk_hw_release, sizeof(*hwp), GFP_KERNEL); if (!hwp) return -ENOMEM; ret = clk_hw_register(dev, hw); if (!ret) { *hwp = hw; devres_add(dev, hwp); } else { devres_free(hwp); } clk_populate_clock_opp_table(dev->of_node, hw); return ret; } EXPORT_SYMBOL_GPL(devm_clk_hw_register); static int devm_clk_match(struct device *dev, void *res, void *data) { struct clk *c = res; if (WARN_ON(!c)) return 0; return c == data; } static int devm_clk_hw_match(struct device *dev, void *res, void *data) { struct clk_hw *hw = res; if (WARN_ON(!hw)) return 0; return hw == data; } /** * devm_clk_unregister - resource managed clk_unregister() * @clk: clock to unregister * * Deallocate a clock allocated with devm_clk_register(). Normally * this function will not need to be called and the resource management * code will ensure that the resource is freed. */ void devm_clk_unregister(struct device *dev, struct clk *clk) { WARN_ON(devres_release(dev, devm_clk_release, devm_clk_match, clk)); } EXPORT_SYMBOL_GPL(devm_clk_unregister); /** * devm_clk_hw_unregister - resource managed clk_hw_unregister() * @dev: device that is unregistering the hardware-specific clock data * @hw: link to hardware-specific clock data * * Unregister a clk_hw registered with devm_clk_hw_register(). Normally * this function will not need to be called and the resource management * code will ensure that the resource is freed. */ void devm_clk_hw_unregister(struct device *dev, struct clk_hw *hw) { WARN_ON(devres_release(dev, devm_clk_hw_release, devm_clk_hw_match, hw)); } EXPORT_SYMBOL_GPL(devm_clk_hw_unregister); /* * clkdev helpers */ int __clk_get(struct clk *clk) { struct clk_core *core = !clk ? NULL : clk->core; if (core) { if (!try_module_get(core->owner)) return 0; kref_get(&core->ref); } return 1; } /* keep in sync with __clk_free_clk */ void __clk_put(struct clk *clk) { struct module *owner; if (!clk || WARN_ON_ONCE(IS_ERR(clk))) return; clk_prepare_lock(); /* * Before calling clk_put, all calls to clk_rate_exclusive_get() from a * given user should be balanced with calls to clk_rate_exclusive_put() * and by that same consumer */ if (WARN_ON(clk->exclusive_count)) { /* We voiced our concern, let's sanitize the situation */ clk->core->protect_count -= (clk->exclusive_count - 1); clk_core_rate_unprotect(clk->core); clk->exclusive_count = 0; } hlist_del(&clk->clks_node); if (clk->min_rate > clk->core->req_rate || clk->max_rate < clk->core->req_rate) clk_core_set_rate_nolock(clk->core, clk->core->req_rate); owner = clk->core->owner; kref_put(&clk->core->ref, __clk_release); clk_prepare_unlock(); module_put(owner); kfree_const(clk->con_id); kfree(clk); } /*** clk rate change notifiers ***/ /** * clk_notifier_register - add a clk rate change notifier * @clk: struct clk * to watch * @nb: struct notifier_block * with callback info * * Request notification when clk's rate changes. This uses an SRCU * notifier because we want it to block and notifier unregistrations are * uncommon. The callbacks associated with the notifier must not * re-enter into the clk framework by calling any top-level clk APIs; * this will cause a nested prepare_lock mutex. * * In all notification cases (pre, post and abort rate change) the original * clock rate is passed to the callback via struct clk_notifier_data.old_rate * and the new frequency is passed via struct clk_notifier_data.new_rate. * * clk_notifier_register() must be called from non-atomic context. * Returns -EINVAL if called with null arguments, -ENOMEM upon * allocation failure; otherwise, passes along the return value of * srcu_notifier_chain_register(). */ int clk_notifier_register(struct clk *clk, struct notifier_block *nb) { struct clk_notifier *cn; int ret = -ENOMEM; if (!clk || !nb) return -EINVAL; clk_prepare_lock(); /* search the list of notifiers for this clk */ list_for_each_entry(cn, &clk_notifier_list, node) if (cn->clk == clk) goto found; /* if clk wasn't in the notifier list, allocate new clk_notifier */ cn = kzalloc(sizeof(*cn), GFP_KERNEL); if (!cn) goto out; cn->clk = clk; srcu_init_notifier_head(&cn->notifier_head); list_add(&cn->node, &clk_notifier_list); found: ret = srcu_notifier_chain_register(&cn->notifier_head, nb); clk->core->notifier_count++; out: clk_prepare_unlock(); return ret; } EXPORT_SYMBOL_GPL(clk_notifier_register); /** * clk_notifier_unregister - remove a clk rate change notifier * @clk: struct clk * * @nb: struct notifier_block * with callback info * * Request no further notification for changes to 'clk' and frees memory * allocated in clk_notifier_register. * * Returns -EINVAL if called with null arguments; otherwise, passes * along the return value of srcu_notifier_chain_unregister(). */ int clk_notifier_unregister(struct clk *clk, struct notifier_block *nb) { struct clk_notifier *cn; int ret = -ENOENT; if (!clk || !nb) return -EINVAL; clk_prepare_lock(); list_for_each_entry(cn, &clk_notifier_list, node) { if (cn->clk == clk) { ret = srcu_notifier_chain_unregister(&cn->notifier_head, nb); clk->core->notifier_count--; /* XXX the notifier code should handle this better */ if (!cn->notifier_head.head) { srcu_cleanup_notifier_head(&cn->notifier_head); list_del(&cn->node); kfree(cn); } break; } } clk_prepare_unlock(); return ret; } EXPORT_SYMBOL_GPL(clk_notifier_unregister); #ifdef CONFIG_OF /** * struct of_clk_provider - Clock provider registration structure * @link: Entry in global list of clock providers * @node: Pointer to device tree node of clock provider * @get: Get clock callback. Returns NULL or a struct clk for the * given clock specifier * @data: context pointer to be passed into @get callback */ struct of_clk_provider { struct list_head link; struct device_node *node; struct clk *(*get)(struct of_phandle_args *clkspec, void *data); struct clk_hw *(*get_hw)(struct of_phandle_args *clkspec, void *data); void *data; }; static const struct of_device_id __clk_of_table_sentinel __used __section(__clk_of_table_end); static LIST_HEAD(of_clk_providers); static DEFINE_MUTEX(of_clk_mutex); struct clk *of_clk_src_simple_get(struct of_phandle_args *clkspec, void *data) { return data; } EXPORT_SYMBOL_GPL(of_clk_src_simple_get); struct clk_hw *of_clk_hw_simple_get(struct of_phandle_args *clkspec, void *data) { return data; } EXPORT_SYMBOL_GPL(of_clk_hw_simple_get); struct clk *of_clk_src_onecell_get(struct of_phandle_args *clkspec, void *data) { struct clk_onecell_data *clk_data = data; unsigned int idx = clkspec->args[0]; if (idx >= clk_data->clk_num) { pr_err("%s: invalid clock index %u\n", __func__, idx); return ERR_PTR(-EINVAL); } return clk_data->clks[idx]; } EXPORT_SYMBOL_GPL(of_clk_src_onecell_get); struct clk_hw * of_clk_hw_onecell_get(struct of_phandle_args *clkspec, void *data) { struct clk_hw_onecell_data *hw_data = data; unsigned int idx = clkspec->args[0]; if (idx >= hw_data->num) { pr_err("%s: invalid index %u\n", __func__, idx); return ERR_PTR(-EINVAL); } return hw_data->hws[idx]; } EXPORT_SYMBOL_GPL(of_clk_hw_onecell_get); /** * of_clk_add_provider() - Register a clock provider for a node * @np: Device node pointer associated with clock provider * @clk_src_get: callback for decoding clock * @data: context pointer for @clk_src_get callback. */ int of_clk_add_provider(struct device_node *np, struct clk *(*clk_src_get)(struct of_phandle_args *clkspec, void *data), void *data) { struct of_clk_provider *cp; int ret; cp = kzalloc(sizeof(*cp), GFP_KERNEL); if (!cp) return -ENOMEM; cp->node = of_node_get(np); cp->data = data; cp->get = clk_src_get; mutex_lock(&of_clk_mutex); list_add(&cp->link, &of_clk_providers); mutex_unlock(&of_clk_mutex); pr_debug("Added clock from %pOF\n", np); ret = of_clk_set_defaults(np, true); if (ret < 0) of_clk_del_provider(np); return ret; } EXPORT_SYMBOL_GPL(of_clk_add_provider); /** * of_clk_add_hw_provider() - Register a clock provider for a node * @np: Device node pointer associated with clock provider * @get: callback for decoding clk_hw * @data: context pointer for @get callback. */ int of_clk_add_hw_provider(struct device_node *np, struct clk_hw *(*get)(struct of_phandle_args *clkspec, void *data), void *data) { struct of_clk_provider *cp; int ret; cp = kzalloc(sizeof(*cp), GFP_KERNEL); if (!cp) return -ENOMEM; cp->node = of_node_get(np); cp->data = data; cp->get_hw = get; mutex_lock(&of_clk_mutex); list_add(&cp->link, &of_clk_providers); mutex_unlock(&of_clk_mutex); pr_debug("Added clk_hw provider from %pOF\n", np); ret = of_clk_set_defaults(np, true); if (ret < 0) of_clk_del_provider(np); return ret; } EXPORT_SYMBOL_GPL(of_clk_add_hw_provider); static void devm_of_clk_release_provider(struct device *dev, void *res) { of_clk_del_provider(*(struct device_node **)res); } int devm_of_clk_add_hw_provider(struct device *dev, struct clk_hw *(*get)(struct of_phandle_args *clkspec, void *data), void *data) { struct device_node **ptr, *np; int ret; ptr = devres_alloc(devm_of_clk_release_provider, sizeof(*ptr), GFP_KERNEL); if (!ptr) return -ENOMEM; np = dev->of_node; ret = of_clk_add_hw_provider(np, get, data); if (!ret) { *ptr = np; devres_add(dev, ptr); } else { devres_free(ptr); } return ret; } EXPORT_SYMBOL_GPL(devm_of_clk_add_hw_provider); /** * of_clk_del_provider() - Remove a previously registered clock provider * @np: Device node pointer associated with clock provider */ void of_clk_del_provider(struct device_node *np) { struct of_clk_provider *cp; mutex_lock(&of_clk_mutex); list_for_each_entry(cp, &of_clk_providers, link) { if (cp->node == np) { list_del(&cp->link); of_node_put(cp->node); kfree(cp); break; } } mutex_unlock(&of_clk_mutex); } EXPORT_SYMBOL_GPL(of_clk_del_provider); static int devm_clk_provider_match(struct device *dev, void *res, void *data) { struct device_node **np = res; if (WARN_ON(!np || !*np)) return 0; return *np == data; } void devm_of_clk_del_provider(struct device *dev) { int ret; ret = devres_release(dev, devm_of_clk_release_provider, devm_clk_provider_match, dev->of_node); WARN_ON(ret); } EXPORT_SYMBOL(devm_of_clk_del_provider); static struct clk_hw * __of_clk_get_hw_from_provider(struct of_clk_provider *provider, struct of_phandle_args *clkspec) { struct clk *clk; if (provider->get_hw) return provider->get_hw(clkspec, provider->data); clk = provider->get(clkspec, provider->data); if (IS_ERR(clk)) return ERR_CAST(clk); return __clk_get_hw(clk); } struct clk *__of_clk_get_from_provider(struct of_phandle_args *clkspec, const char *dev_id, const char *con_id) { struct of_clk_provider *provider; struct clk *clk = ERR_PTR(-EPROBE_DEFER); struct clk_hw *hw; if (!clkspec) return ERR_PTR(-EINVAL); /* Check if we have such a provider in our array */ mutex_lock(&of_clk_mutex); list_for_each_entry(provider, &of_clk_providers, link) { if (provider->node == clkspec->np) { hw = __of_clk_get_hw_from_provider(provider, clkspec); clk = __clk_create_clk(hw, dev_id, con_id); } if (!IS_ERR(clk)) { if (!__clk_get(clk)) { __clk_free_clk(clk); clk = ERR_PTR(-ENOENT); } break; } } mutex_unlock(&of_clk_mutex); return clk; } /** * of_clk_get_from_provider() - Lookup a clock from a clock provider * @clkspec: pointer to a clock specifier data structure * * This function looks up a struct clk from the registered list of clock * providers, an input is a clock specifier data structure as returned * from the of_parse_phandle_with_args() function call. */ struct clk *of_clk_get_from_provider(struct of_phandle_args *clkspec) { return __of_clk_get_from_provider(clkspec, NULL, __func__); } EXPORT_SYMBOL_GPL(of_clk_get_from_provider); /** * of_clk_get_parent_count() - Count the number of clocks a device node has * @np: device node to count * * Returns: The number of clocks that are possible parents of this node */ unsigned int of_clk_get_parent_count(struct device_node *np) { int count; count = of_count_phandle_with_args(np, "clocks", "#clock-cells"); if (count < 0) return 0; return count; } EXPORT_SYMBOL_GPL(of_clk_get_parent_count); const char *of_clk_get_parent_name(struct device_node *np, int index) { struct of_phandle_args clkspec; struct property *prop; const char *clk_name; const __be32 *vp; u32 pv; int rc; int count; struct clk *clk; rc = of_parse_phandle_with_args(np, "clocks", "#clock-cells", index, &clkspec); if (rc) return NULL; index = clkspec.args_count ? clkspec.args[0] : 0; count = 0; /* if there is an indices property, use it to transfer the index * specified into an array offset for the clock-output-names property. */ of_property_for_each_u32(clkspec.np, "clock-indices", prop, vp, pv) { if (index == pv) { index = count; break; } count++; } /* We went off the end of 'clock-indices' without finding it */ if (prop && !vp) return NULL; if (of_property_read_string_index(clkspec.np, "clock-output-names", index, &clk_name) < 0) { /* * Best effort to get the name if the clock has been * registered with the framework. If the clock isn't * registered, we return the node name as the name of * the clock as long as #clock-cells = 0. */ clk = of_clk_get_from_provider(&clkspec); if (IS_ERR(clk)) { if (clkspec.args_count == 0) clk_name = clkspec.np->name; else clk_name = NULL; } else { clk_name = __clk_get_name(clk); clk_put(clk); } } of_node_put(clkspec.np); return clk_name; } EXPORT_SYMBOL_GPL(of_clk_get_parent_name); /** * of_clk_parent_fill() - Fill @parents with names of @np's parents and return * number of parents * @np: Device node pointer associated with clock provider * @parents: pointer to char array that hold the parents' names * @size: size of the @parents array * * Return: number of parents for the clock node. */ int of_clk_parent_fill(struct device_node *np, const char **parents, unsigned int size) { unsigned int i = 0; while (i < size && (parents[i] = of_clk_get_parent_name(np, i)) != NULL) i++; return i; } EXPORT_SYMBOL_GPL(of_clk_parent_fill); struct clock_provider { void (*clk_init_cb)(struct device_node *); struct device_node *np; struct list_head node; }; /* * This function looks for a parent clock. If there is one, then it * checks that the provider for this parent clock was initialized, in * this case the parent clock will be ready. */ static int parent_ready(struct device_node *np) { int i = 0; while (true) { struct clk *clk = of_clk_get(np, i); /* this parent is ready we can check the next one */ if (!IS_ERR(clk)) { clk_put(clk); i++; continue; } /* at least one parent is not ready, we exit now */ if (PTR_ERR(clk) == -EPROBE_DEFER) return 0; /* * Here we make assumption that the device tree is * written correctly. So an error means that there is * no more parent. As we didn't exit yet, then the * previous parent are ready. If there is no clock * parent, no need to wait for them, then we can * consider their absence as being ready */ return 1; } } /** * of_clk_detect_critical() - set CLK_IS_CRITICAL flag from Device Tree * @np: Device node pointer associated with clock provider * @index: clock index * @flags: pointer to top-level framework flags * * Detects if the clock-critical property exists and, if so, sets the * corresponding CLK_IS_CRITICAL flag. * * Do not use this function. It exists only for legacy Device Tree * bindings, such as the one-clock-per-node style that are outdated. * Those bindings typically put all clock data into .dts and the Linux * driver has no clock data, thus making it impossible to set this flag * correctly from the driver. Only those drivers may call * of_clk_detect_critical from their setup functions. * * Return: error code or zero on success */ int of_clk_detect_critical(struct device_node *np, int index, unsigned long *flags) { struct property *prop; const __be32 *cur; uint32_t idx; if (!np || !flags) return -EINVAL; of_property_for_each_u32(np, "clock-critical", prop, cur, idx) if (index == idx) *flags |= CLK_IS_CRITICAL; return 0; } /** * of_clk_init() - Scan and init clock providers from the DT * @matches: array of compatible values and init functions for providers. * * This function scans the device tree for matching clock providers * and calls their initialization functions. It also does it by trying * to follow the dependencies. */ void __init of_clk_init(const struct of_device_id *matches) { const struct of_device_id *match; struct device_node *np; struct clock_provider *clk_provider, *next; bool is_init_done; bool force = false; LIST_HEAD(clk_provider_list); if (!matches) matches = &__clk_of_table; /* First prepare the list of the clocks providers */ for_each_matching_node_and_match(np, matches, &match) { struct clock_provider *parent; if (!of_device_is_available(np)) continue; parent = kzalloc(sizeof(*parent), GFP_KERNEL); if (!parent) { list_for_each_entry_safe(clk_provider, next, &clk_provider_list, node) { list_del(&clk_provider->node); of_node_put(clk_provider->np); kfree(clk_provider); } of_node_put(np); return; } parent->clk_init_cb = match->data; parent->np = of_node_get(np); list_add_tail(&parent->node, &clk_provider_list); } while (!list_empty(&clk_provider_list)) { is_init_done = false; list_for_each_entry_safe(clk_provider, next, &clk_provider_list, node) { if (force || parent_ready(clk_provider->np)) { /* Don't populate platform devices */ of_node_set_flag(clk_provider->np, OF_POPULATED); clk_provider->clk_init_cb(clk_provider->np); of_clk_set_defaults(clk_provider->np, true); list_del(&clk_provider->node); of_node_put(clk_provider->np); kfree(clk_provider); is_init_done = true; } } /* * We didn't manage to initialize any of the * remaining providers during the last loop, so now we * initialize all the remaining ones unconditionally * in case the clock parent was not mandatory */ if (!is_init_done) force = true; } } #endif