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|
/* Copyright (c) 2009-2012,2016 The Linux Foundation. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 and
* only version 2 as published by the Free Software Foundation.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
*/
#define pr_fmt(fmt) "%s: " fmt, __func__
#include <linux/kernel.h>
#include <linux/init.h>
#include <linux/err.h>
#include <linux/ctype.h>
#include <linux/bitops.h>
#include <linux/io.h>
#include <linux/spinlock.h>
#include <linux/delay.h>
#include <linux/clk.h>
#include <mach/msm_iomap.h>
#include <mach/clk-provider.h>
#include <mach/clk.h>
#include <mach/scm-io.h>
#include "clock-local.h"
#ifdef CONFIG_MSM_SECURE_IO
#undef readl_relaxed
#undef writel_relaxed
#define readl_relaxed secure_readl
#define writel_relaxed secure_writel
#endif
/*
* When enabling/disabling a clock, check the halt bit up to this number
* number of times (with a 1 us delay in between) before continuing.
*/
#define HALT_CHECK_MAX_LOOPS 200
/* For clock without halt checking, wait this long after enables/disables. */
#define HALT_CHECK_DELAY_US 10
DEFINE_SPINLOCK(local_clock_reg_lock);
struct clk_freq_tbl rcg_dummy_freq = F_END;
/*
* Common Set-Rate Functions
*/
/* For clocks with MND dividers. */
void set_rate_mnd(struct rcg_clk *rcg, struct clk_freq_tbl *nf)
{
uint32_t ns_reg_val, ctl_reg_val;
/* Assert MND reset. */
ns_reg_val = readl_relaxed(rcg->ns_reg);
ns_reg_val |= BIT(7);
writel_relaxed(ns_reg_val, rcg->ns_reg);
/* Program M and D values. */
writel_relaxed(nf->md_val, rcg->md_reg);
/* If the clock has a separate CC register, program it. */
if (rcg->ns_reg != rcg->b.ctl_reg) {
ctl_reg_val = readl_relaxed(rcg->b.ctl_reg);
ctl_reg_val &= ~(rcg->ctl_mask);
ctl_reg_val |= nf->ctl_val;
writel_relaxed(ctl_reg_val, rcg->b.ctl_reg);
}
/* Deassert MND reset. */
ns_reg_val &= ~BIT(7);
writel_relaxed(ns_reg_val, rcg->ns_reg);
}
void set_rate_nop(struct rcg_clk *rcg, struct clk_freq_tbl *nf)
{
/*
* Nothing to do for fixed-rate or integer-divider clocks. Any settings
* in NS registers are applied in the enable path, since power can be
* saved by leaving an un-clocked or slowly-clocked source selected
* until the clock is enabled.
*/
}
void set_rate_mnd_8(struct rcg_clk *rcg, struct clk_freq_tbl *nf)
{
uint32_t ctl_reg_val;
/* Assert MND reset. */
ctl_reg_val = readl_relaxed(rcg->b.ctl_reg);
ctl_reg_val |= BIT(8);
writel_relaxed(ctl_reg_val, rcg->b.ctl_reg);
/* Program M and D values. */
writel_relaxed(nf->md_val, rcg->md_reg);
/* Program MN counter Enable and Mode. */
ctl_reg_val &= ~(rcg->ctl_mask);
ctl_reg_val |= nf->ctl_val;
writel_relaxed(ctl_reg_val, rcg->b.ctl_reg);
/* Deassert MND reset. */
ctl_reg_val &= ~BIT(8);
writel_relaxed(ctl_reg_val, rcg->b.ctl_reg);
}
void set_rate_mnd_banked(struct rcg_clk *rcg, struct clk_freq_tbl *nf)
{
struct bank_masks *banks = rcg->bank_info;
const struct bank_mask_info *new_bank_masks;
const struct bank_mask_info *old_bank_masks;
uint32_t ns_reg_val, ctl_reg_val;
uint32_t bank_sel;
/*
* Determine active bank and program the other one. If the clock is
* off, program the active bank since bank switching won't work if
* both banks aren't running.
*/
ctl_reg_val = readl_relaxed(rcg->b.ctl_reg);
bank_sel = !!(ctl_reg_val & banks->bank_sel_mask);
/* If clock isn't running, don't switch banks. */
bank_sel ^= (!rcg->enabled || rcg->current_freq->freq_hz == 0);
if (bank_sel == 0) {
new_bank_masks = &banks->bank1_mask;
old_bank_masks = &banks->bank0_mask;
} else {
new_bank_masks = &banks->bank0_mask;
old_bank_masks = &banks->bank1_mask;
}
ns_reg_val = readl_relaxed(rcg->ns_reg);
/* Assert bank MND reset. */
ns_reg_val |= new_bank_masks->rst_mask;
writel_relaxed(ns_reg_val, rcg->ns_reg);
/*
* Program NS only if the clock is enabled, since the NS will be set
* as part of the enable procedure and should remain with a low-power
* MUX input selected until then.
*/
if (rcg->enabled) {
ns_reg_val &= ~(new_bank_masks->ns_mask);
ns_reg_val |= (nf->ns_val & new_bank_masks->ns_mask);
writel_relaxed(ns_reg_val, rcg->ns_reg);
}
writel_relaxed(nf->md_val, new_bank_masks->md_reg);
/* Enable counter only if clock is enabled. */
if (rcg->enabled)
ctl_reg_val |= new_bank_masks->mnd_en_mask;
else
ctl_reg_val &= ~(new_bank_masks->mnd_en_mask);
ctl_reg_val &= ~(new_bank_masks->mode_mask);
ctl_reg_val |= (nf->ctl_val & new_bank_masks->mode_mask);
writel_relaxed(ctl_reg_val, rcg->b.ctl_reg);
/* Deassert bank MND reset. */
ns_reg_val &= ~(new_bank_masks->rst_mask);
writel_relaxed(ns_reg_val, rcg->ns_reg);
/*
* Switch to the new bank if clock is running. If it isn't, then
* no switch is necessary since we programmed the active bank.
*/
if (rcg->enabled && rcg->current_freq->freq_hz) {
ctl_reg_val ^= banks->bank_sel_mask;
writel_relaxed(ctl_reg_val, rcg->b.ctl_reg);
/*
* Wait at least 6 cycles of slowest bank's clock
* for the glitch-free MUX to fully switch sources.
*/
mb();
udelay(1);
/* Disable old bank's MN counter. */
ctl_reg_val &= ~(old_bank_masks->mnd_en_mask);
writel_relaxed(ctl_reg_val, rcg->b.ctl_reg);
/* Program old bank to a low-power source and divider. */
ns_reg_val &= ~(old_bank_masks->ns_mask);
ns_reg_val |= (rcg->freq_tbl->ns_val & old_bank_masks->ns_mask);
writel_relaxed(ns_reg_val, rcg->ns_reg);
}
/* Update the MND_EN and NS masks to match the current bank. */
rcg->mnd_en_mask = new_bank_masks->mnd_en_mask;
rcg->ns_mask = new_bank_masks->ns_mask;
}
void set_rate_div_banked(struct rcg_clk *rcg, struct clk_freq_tbl *nf)
{
struct bank_masks *banks = rcg->bank_info;
const struct bank_mask_info *new_bank_masks;
const struct bank_mask_info *old_bank_masks;
uint32_t ns_reg_val, bank_sel;
/*
* Determine active bank and program the other one. If the clock is
* off, program the active bank since bank switching won't work if
* both banks aren't running.
*/
ns_reg_val = readl_relaxed(rcg->ns_reg);
bank_sel = !!(ns_reg_val & banks->bank_sel_mask);
/* If clock isn't running, don't switch banks. */
bank_sel ^= (!rcg->enabled || rcg->current_freq->freq_hz == 0);
if (bank_sel == 0) {
new_bank_masks = &banks->bank1_mask;
old_bank_masks = &banks->bank0_mask;
} else {
new_bank_masks = &banks->bank0_mask;
old_bank_masks = &banks->bank1_mask;
}
/*
* Program NS only if the clock is enabled, since the NS will be set
* as part of the enable procedure and should remain with a low-power
* MUX input selected until then.
*/
if (rcg->enabled) {
ns_reg_val &= ~(new_bank_masks->ns_mask);
ns_reg_val |= (nf->ns_val & new_bank_masks->ns_mask);
writel_relaxed(ns_reg_val, rcg->ns_reg);
}
/*
* Switch to the new bank if clock is running. If it isn't, then
* no switch is necessary since we programmed the active bank.
*/
if (rcg->enabled && rcg->current_freq->freq_hz) {
ns_reg_val ^= banks->bank_sel_mask;
writel_relaxed(ns_reg_val, rcg->ns_reg);
/*
* Wait at least 6 cycles of slowest bank's clock
* for the glitch-free MUX to fully switch sources.
*/
mb();
udelay(1);
/* Program old bank to a low-power source and divider. */
ns_reg_val &= ~(old_bank_masks->ns_mask);
ns_reg_val |= (rcg->freq_tbl->ns_val & old_bank_masks->ns_mask);
writel_relaxed(ns_reg_val, rcg->ns_reg);
}
/* Update the NS mask to match the current bank. */
rcg->ns_mask = new_bank_masks->ns_mask;
}
/*
* Clock enable/disable functions
*/
/* Return non-zero if a clock status registers shows the clock is halted. */
static int branch_clk_is_halted(const struct branch *b)
{
int invert = (b->halt_check == ENABLE);
int status_bit = readl_relaxed(b->halt_reg) & BIT(b->halt_bit);
return invert ? !status_bit : status_bit;
}
static int branch_in_hwcg_mode(const struct branch *b)
{
if (!b->hwcg_mask)
return 0;
return !!(readl_relaxed(b->hwcg_reg) & b->hwcg_mask);
}
void __branch_enable_reg(const struct branch *b, const char *name)
{
u32 reg_val;
if (b->en_mask) {
reg_val = readl_relaxed(b->ctl_reg);
reg_val |= b->en_mask;
writel_relaxed(reg_val, b->ctl_reg);
}
/*
* Use a memory barrier since some halt status registers are
* not within the same 1K segment as the branch/root enable
* registers. It's also needed in the udelay() case to ensure
* the delay starts after the branch enable.
*/
mb();
/* Skip checking halt bit if the clock is in hardware gated mode */
if (branch_in_hwcg_mode(b))
return;
/* Wait for clock to enable before returning. */
if (b->halt_check == DELAY) {
udelay(HALT_CHECK_DELAY_US);
} else if (b->halt_check == ENABLE || b->halt_check == HALT
|| b->halt_check == ENABLE_VOTED
|| b->halt_check == HALT_VOTED) {
int count;
/* Wait up to HALT_CHECK_MAX_LOOPS for clock to enable. */
for (count = HALT_CHECK_MAX_LOOPS; branch_clk_is_halted(b)
&& count > 0; count--)
udelay(1);
WARN(count == 0, "%s status stuck at 'off'", name);
}
}
/* Perform any register operations required to enable the clock. */
static void __rcg_clk_enable_reg(struct rcg_clk *rcg)
{
u32 reg_val;
void __iomem *const reg = rcg->b.ctl_reg;
/*
* Program the NS register, if applicable. NS registers are not
* set in the set_rate path because power can be saved by deferring
* the selection of a clocked source until the clock is enabled.
*/
if (rcg->ns_mask) {
reg_val = readl_relaxed(rcg->ns_reg);
reg_val &= ~(rcg->ns_mask);
reg_val |= (rcg->current_freq->ns_val & rcg->ns_mask);
writel_relaxed(reg_val, rcg->ns_reg);
}
/* Enable MN counter, if applicable. */
reg_val = readl_relaxed(reg);
if (rcg->current_freq->md_val) {
reg_val |= rcg->mnd_en_mask;
writel_relaxed(reg_val, reg);
}
/* Enable root. */
if (rcg->root_en_mask) {
reg_val |= rcg->root_en_mask;
writel_relaxed(reg_val, reg);
}
__branch_enable_reg(&rcg->b, rcg->c.dbg_name);
}
/* Perform any register operations required to disable the branch. */
u32 __branch_disable_reg(const struct branch *b, const char *name)
{
u32 reg_val;
reg_val = b->ctl_reg ? readl_relaxed(b->ctl_reg) : 0;
if (b->en_mask && b->ctl_reg) {
reg_val &= ~(b->en_mask);
writel_relaxed(reg_val, b->ctl_reg);
}
/*
* Use a memory barrier since some halt status registers are
* not within the same K segment as the branch/root enable
* registers. It's also needed in the udelay() case to ensure
* the delay starts after the branch disable.
*/
mb();
/* Skip checking halt bit if the clock is in hardware gated mode */
if (branch_in_hwcg_mode(b))
return reg_val;
/* Wait for clock to disable before continuing. */
if (b->halt_check == DELAY || b->halt_check == ENABLE_VOTED
|| b->halt_check == HALT_VOTED) {
udelay(HALT_CHECK_DELAY_US);
} else if (b->halt_check == ENABLE || b->halt_check == HALT) {
int count;
/* Wait up to HALT_CHECK_MAX_LOOPS for clock to disable. */
for (count = HALT_CHECK_MAX_LOOPS; !branch_clk_is_halted(b)
&& count > 0; count--)
udelay(1);
WARN(count == 0, "%s status stuck at 'on'", name);
}
return reg_val;
}
/* Perform any register operations required to disable the generator. */
static void __rcg_clk_disable_reg(struct rcg_clk *rcg)
{
void __iomem *const reg = rcg->b.ctl_reg;
uint32_t reg_val;
reg_val = __branch_disable_reg(&rcg->b, rcg->c.dbg_name);
/* Disable root. */
if (rcg->root_en_mask) {
reg_val &= ~(rcg->root_en_mask);
writel_relaxed(reg_val, reg);
}
/* Disable MN counter, if applicable. */
if (rcg->current_freq->md_val) {
reg_val &= ~(rcg->mnd_en_mask);
writel_relaxed(reg_val, reg);
}
/*
* Program NS register to low-power value with an un-clocked or
* slowly-clocked source selected.
*/
if (rcg->ns_mask) {
reg_val = readl_relaxed(rcg->ns_reg);
reg_val &= ~(rcg->ns_mask);
reg_val |= (rcg->freq_tbl->ns_val & rcg->ns_mask);
writel_relaxed(reg_val, rcg->ns_reg);
}
}
static int rcg_clk_prepare(struct clk *c)
{
struct rcg_clk *rcg = to_rcg_clk(c);
WARN(rcg->current_freq == &rcg_dummy_freq,
"Attempting to prepare %s before setting its rate. "
"Set the rate first!\n", rcg->c.dbg_name);
rcg->prepared = true;
return 0;
}
/* Enable a rate-settable clock. */
static int rcg_clk_enable(struct clk *c)
{
unsigned long flags;
struct rcg_clk *rcg = to_rcg_clk(c);
spin_lock_irqsave(&local_clock_reg_lock, flags);
__rcg_clk_enable_reg(rcg);
rcg->enabled = true;
spin_unlock_irqrestore(&local_clock_reg_lock, flags);
return 0;
}
/* Disable a rate-settable clock. */
static void rcg_clk_disable(struct clk *c)
{
unsigned long flags;
struct rcg_clk *rcg = to_rcg_clk(c);
spin_lock_irqsave(&local_clock_reg_lock, flags);
__rcg_clk_disable_reg(rcg);
rcg->enabled = false;
spin_unlock_irqrestore(&local_clock_reg_lock, flags);
}
static void rcg_clk_unprepare(struct clk *c)
{
struct rcg_clk *rcg = to_rcg_clk(c);
rcg->prepared = false;
}
/*
* Frequency-related functions
*/
/* Set a clock to an exact rate. */
static int rcg_clk_set_rate(struct clk *c, unsigned long rate)
{
struct rcg_clk *rcg = to_rcg_clk(c);
struct clk_freq_tbl *nf, *cf;
struct clk *chld;
int rc = 0;
unsigned long flags;
for (nf = rcg->freq_tbl; nf->freq_hz != FREQ_END
&& nf->freq_hz != rate; nf++)
;
if (nf->freq_hz == FREQ_END)
return -EINVAL;
cf = rcg->current_freq;
/* Enable source clock dependency for the new frequency */
if (rcg->prepared) {
rc = clk_prepare(nf->src_clk);
if (rc)
return rc;
}
spin_lock_irqsave(&c->lock, flags);
if (rcg->enabled) {
rc = clk_enable(nf->src_clk);
if (rc) {
spin_unlock_irqrestore(&c->lock, flags);
clk_unprepare(nf->src_clk);
return rc;
}
}
spin_lock(&local_clock_reg_lock);
/* Disable branch if clock isn't dual-banked with a glitch-free MUX. */
if (!rcg->bank_info) {
/* Disable all branches to prevent glitches. */
list_for_each_entry(chld, &rcg->c.children, siblings) {
struct branch_clk *x = to_branch_clk(chld);
/*
* We don't need to grab the child's lock because
* we hold the local_clock_reg_lock and 'enabled' is
* only modified within lock.
*/
if (x->enabled)
__branch_disable_reg(&x->b, x->c.dbg_name);
}
if (rcg->enabled)
__rcg_clk_disable_reg(rcg);
}
/* Perform clock-specific frequency switch operations. */
BUG_ON(!rcg->set_rate);
rcg->set_rate(rcg, nf);
/*
* Current freq must be updated before __rcg_clk_enable_reg()
* is called to make sure the MNCNTR_EN bit is set correctly.
*/
rcg->current_freq = nf;
/* Enable any clocks that were disabled. */
if (!rcg->bank_info) {
if (rcg->enabled)
__rcg_clk_enable_reg(rcg);
/* Enable only branches that were ON before. */
list_for_each_entry(chld, &rcg->c.children, siblings) {
struct branch_clk *x = to_branch_clk(chld);
if (x->enabled)
__branch_enable_reg(&x->b, x->c.dbg_name);
}
}
spin_unlock(&local_clock_reg_lock);
/* Release source requirements of the old freq. */
if (rcg->enabled)
clk_disable(cf->src_clk);
spin_unlock_irqrestore(&c->lock, flags);
if (rcg->prepared)
clk_unprepare(cf->src_clk);
return rc;
}
/* Check if a clock is currently enabled. */
static int rcg_clk_is_enabled(struct clk *c)
{
return to_rcg_clk(c)->enabled;
}
/* Return a supported rate that's at least the specified rate. */
static long rcg_clk_round_rate(struct clk *c, unsigned long rate)
{
struct rcg_clk *rcg = to_rcg_clk(c);
struct clk_freq_tbl *f;
for (f = rcg->freq_tbl; f->freq_hz != FREQ_END; f++)
if (f->freq_hz >= rate)
return f->freq_hz;
return -EPERM;
}
/* Return the nth supported frequency for a given clock. */
static int rcg_clk_list_rate(struct clk *c, unsigned n)
{
struct rcg_clk *rcg = to_rcg_clk(c);
if (!rcg->freq_tbl || rcg->freq_tbl->freq_hz == FREQ_END)
return -ENXIO;
return (rcg->freq_tbl + n)->freq_hz;
}
static struct clk *rcg_clk_get_parent(struct clk *c)
{
return to_rcg_clk(c)->current_freq->src_clk;
}
/* Disable hw clock gating if not set at boot */
enum handoff branch_handoff(struct branch *b, struct clk *c)
{
if (!branch_in_hwcg_mode(b)) {
b->hwcg_mask = 0;
if (b->ctl_reg && readl_relaxed(b->ctl_reg) & b->en_mask)
return HANDOFF_ENABLED_CLK;
}
return HANDOFF_DISABLED_CLK;
}
static enum handoff branch_clk_handoff(struct clk *c)
{
struct branch_clk *br = to_branch_clk(c);
return branch_handoff(&br->b, &br->c);
}
static enum handoff rcg_clk_handoff(struct clk *c)
{
struct rcg_clk *rcg = to_rcg_clk(c);
uint32_t ctl_val, ns_val, md_val, ns_mask;
struct clk_freq_tbl *freq;
enum handoff ret;
ctl_val = readl_relaxed(rcg->b.ctl_reg);
ret = branch_handoff(&rcg->b, &rcg->c);
if (ret == HANDOFF_DISABLED_CLK)
return HANDOFF_DISABLED_CLK;
if (rcg->bank_info) {
const struct bank_masks *bank_masks = rcg->bank_info;
const struct bank_mask_info *bank_info;
if (!(ctl_val & bank_masks->bank_sel_mask))
bank_info = &bank_masks->bank0_mask;
else
bank_info = &bank_masks->bank1_mask;
ns_mask = bank_info->ns_mask;
md_val = bank_info->md_reg ?
readl_relaxed(bank_info->md_reg) : 0;
} else {
ns_mask = rcg->ns_mask;
md_val = rcg->md_reg ? readl_relaxed(rcg->md_reg) : 0;
}
if (!ns_mask)
return HANDOFF_UNKNOWN_RATE;
ns_val = readl_relaxed(rcg->ns_reg) & ns_mask;
for (freq = rcg->freq_tbl; freq->freq_hz != FREQ_END; freq++) {
if ((freq->ns_val & ns_mask) == ns_val &&
(!freq->md_val || freq->md_val == md_val))
break;
}
if (freq->freq_hz == FREQ_END)
return HANDOFF_UNKNOWN_RATE;
rcg->current_freq = freq;
c->rate = freq->freq_hz;
return HANDOFF_ENABLED_CLK;
}
struct clk_ops clk_ops_empty;
struct fixed_clk gnd_clk = {
.c = {
.dbg_name = "ground_clk",
.ops = &clk_ops_empty,
CLK_INIT(gnd_clk.c),
},
};
static int branch_clk_enable(struct clk *c)
{
unsigned long flags;
struct branch_clk *br = to_branch_clk(c);
spin_lock_irqsave(&local_clock_reg_lock, flags);
__branch_enable_reg(&br->b, br->c.dbg_name);
br->enabled = true;
spin_unlock_irqrestore(&local_clock_reg_lock, flags);
return 0;
}
static void branch_clk_disable(struct clk *c)
{
unsigned long flags;
struct branch_clk *br = to_branch_clk(c);
spin_lock_irqsave(&local_clock_reg_lock, flags);
__branch_disable_reg(&br->b, br->c.dbg_name);
br->enabled = false;
spin_unlock_irqrestore(&local_clock_reg_lock, flags);
}
static struct clk *branch_clk_get_parent(struct clk *c)
{
return to_branch_clk(c)->parent;
}
static int branch_clk_is_enabled(struct clk *c)
{
return to_branch_clk(c)->enabled;
}
static void branch_enable_hwcg(struct branch *b)
{
unsigned long flags;
u32 reg_val;
spin_lock_irqsave(&local_clock_reg_lock, flags);
reg_val = readl_relaxed(b->hwcg_reg);
reg_val |= b->hwcg_mask;
writel_relaxed(reg_val, b->hwcg_reg);
spin_unlock_irqrestore(&local_clock_reg_lock, flags);
}
static void branch_disable_hwcg(struct branch *b)
{
unsigned long flags;
u32 reg_val;
spin_lock_irqsave(&local_clock_reg_lock, flags);
reg_val = readl_relaxed(b->hwcg_reg);
reg_val &= ~b->hwcg_mask;
writel_relaxed(reg_val, b->hwcg_reg);
spin_unlock_irqrestore(&local_clock_reg_lock, flags);
}
static void branch_clk_enable_hwcg(struct clk *c)
{
branch_enable_hwcg(&to_branch_clk(c)->b);
}
static void branch_clk_disable_hwcg(struct clk *c)
{
branch_disable_hwcg(&to_branch_clk(c)->b);
}
static int branch_set_flags(struct branch *b, unsigned flags)
{
unsigned long irq_flags;
u32 reg_val;
int ret = 0;
if (!b->retain_reg)
return -EPERM;
spin_lock_irqsave(&local_clock_reg_lock, irq_flags);
reg_val = readl_relaxed(b->retain_reg);
switch (flags) {
case CLKFLAG_RETAIN:
reg_val |= b->retain_mask;
break;
case CLKFLAG_NORETAIN:
reg_val &= ~b->retain_mask;
break;
default:
ret = -EINVAL;
}
writel_relaxed(reg_val, b->retain_reg);
spin_unlock_irqrestore(&local_clock_reg_lock, irq_flags);
return ret;
}
static int branch_clk_set_flags(struct clk *clk, unsigned flags)
{
return branch_set_flags(&to_branch_clk(clk)->b, flags);
}
static int branch_clk_in_hwcg_mode(struct clk *c)
{
return branch_in_hwcg_mode(&to_branch_clk(c)->b);
}
static void rcg_clk_enable_hwcg(struct clk *c)
{
branch_enable_hwcg(&to_rcg_clk(c)->b);
}
static void rcg_clk_disable_hwcg(struct clk *c)
{
branch_disable_hwcg(&to_rcg_clk(c)->b);
}
static int rcg_clk_in_hwcg_mode(struct clk *c)
{
return branch_in_hwcg_mode(&to_rcg_clk(c)->b);
}
static int rcg_clk_set_flags(struct clk *clk, unsigned flags)
{
return branch_set_flags(&to_rcg_clk(clk)->b, flags);
}
int branch_reset(struct branch *b, enum clk_reset_action action)
{
int ret = 0;
u32 reg_val;
unsigned long flags;
if (!b->reset_reg)
return -EPERM;
/* Disable hw gating when asserting a reset */
if (b->hwcg_mask && action == CLK_RESET_ASSERT)
branch_disable_hwcg(b);
spin_lock_irqsave(&local_clock_reg_lock, flags);
/* Assert/Deassert reset */
reg_val = readl_relaxed(b->reset_reg);
switch (action) {
case CLK_RESET_ASSERT:
reg_val |= b->reset_mask;
break;
case CLK_RESET_DEASSERT:
reg_val &= ~b->reset_mask;
break;
default:
ret = -EINVAL;
}
writel_relaxed(reg_val, b->reset_reg);
spin_unlock_irqrestore(&local_clock_reg_lock, flags);
/* Enable hw gating when deasserting a reset */
if (b->hwcg_mask && action == CLK_RESET_DEASSERT)
branch_enable_hwcg(b);
/* Make sure write is issued before returning. */
mb();
return ret;
}
static int branch_clk_reset(struct clk *c, enum clk_reset_action action)
{
return branch_reset(&to_branch_clk(c)->b, action);
}
struct clk_ops clk_ops_branch = {
.enable = branch_clk_enable,
.disable = branch_clk_disable,
.enable_hwcg = branch_clk_enable_hwcg,
.disable_hwcg = branch_clk_disable_hwcg,
.in_hwcg_mode = branch_clk_in_hwcg_mode,
.is_enabled = branch_clk_is_enabled,
.reset = branch_clk_reset,
.get_parent = branch_clk_get_parent,
.handoff = branch_clk_handoff,
.set_flags = branch_clk_set_flags,
};
struct clk_ops clk_ops_reset = {
.reset = branch_clk_reset,
};
static int rcg_clk_reset(struct clk *c, enum clk_reset_action action)
{
return branch_reset(&to_rcg_clk(c)->b, action);
}
struct clk_ops clk_ops_rcg = {
.prepare = rcg_clk_prepare,
.enable = rcg_clk_enable,
.disable = rcg_clk_disable,
.unprepare = rcg_clk_unprepare,
.enable_hwcg = rcg_clk_enable_hwcg,
.disable_hwcg = rcg_clk_disable_hwcg,
.in_hwcg_mode = rcg_clk_in_hwcg_mode,
.handoff = rcg_clk_handoff,
.set_rate = rcg_clk_set_rate,
.list_rate = rcg_clk_list_rate,
.is_enabled = rcg_clk_is_enabled,
.round_rate = rcg_clk_round_rate,
.reset = rcg_clk_reset,
.get_parent = rcg_clk_get_parent,
.set_flags = rcg_clk_set_flags,
};
static int cdiv_clk_enable(struct clk *c)
{
unsigned long flags;
struct cdiv_clk *cdiv = to_cdiv_clk(c);
spin_lock_irqsave(&local_clock_reg_lock, flags);
__branch_enable_reg(&cdiv->b, cdiv->c.dbg_name);
spin_unlock_irqrestore(&local_clock_reg_lock, flags);
return 0;
}
static void cdiv_clk_disable(struct clk *c)
{
unsigned long flags;
struct cdiv_clk *cdiv = to_cdiv_clk(c);
spin_lock_irqsave(&local_clock_reg_lock, flags);
__branch_disable_reg(&cdiv->b, cdiv->c.dbg_name);
spin_unlock_irqrestore(&local_clock_reg_lock, flags);
}
static int cdiv_clk_set_rate(struct clk *c, unsigned long rate)
{
struct cdiv_clk *cdiv = to_cdiv_clk(c);
u32 reg_val;
if (rate > cdiv->max_div)
return -EINVAL;
spin_lock(&local_clock_reg_lock);
reg_val = readl_relaxed(cdiv->ns_reg);
reg_val &= ~(cdiv->ext_mask | (cdiv->max_div - 1) << cdiv->div_offset);
/* Non-zero rates mean set a divider, zero means use external input */
if (rate)
reg_val |= (rate - 1) << cdiv->div_offset;
else
reg_val |= cdiv->ext_mask;
writel_relaxed(reg_val, cdiv->ns_reg);
spin_unlock(&local_clock_reg_lock);
cdiv->cur_div = rate;
return 0;
}
static unsigned long cdiv_clk_get_rate(struct clk *c)
{
return to_cdiv_clk(c)->cur_div;
}
static long cdiv_clk_round_rate(struct clk *c, unsigned long rate)
{
return rate > to_cdiv_clk(c)->max_div ? -EPERM : rate;
}
static int cdiv_clk_list_rate(struct clk *c, unsigned n)
{
return n > to_cdiv_clk(c)->max_div ? -ENXIO : n;
}
static enum handoff cdiv_clk_handoff(struct clk *c)
{
struct cdiv_clk *cdiv = to_cdiv_clk(c);
enum handoff ret;
u32 reg_val;
ret = branch_handoff(&cdiv->b, &cdiv->c);
if (ret == HANDOFF_DISABLED_CLK)
return ret;
reg_val = readl_relaxed(cdiv->ns_reg);
if (reg_val & cdiv->ext_mask) {
cdiv->cur_div = 0;
} else {
reg_val >>= cdiv->div_offset;
cdiv->cur_div = (reg_val & (cdiv->max_div - 1)) + 1;
}
return HANDOFF_ENABLED_CLK;
}
static void cdiv_clk_enable_hwcg(struct clk *c)
{
branch_enable_hwcg(&to_cdiv_clk(c)->b);
}
static void cdiv_clk_disable_hwcg(struct clk *c)
{
branch_disable_hwcg(&to_cdiv_clk(c)->b);
}
static int cdiv_clk_in_hwcg_mode(struct clk *c)
{
return branch_in_hwcg_mode(&to_cdiv_clk(c)->b);
}
struct clk_ops clk_ops_cdiv = {
.enable = cdiv_clk_enable,
.disable = cdiv_clk_disable,
.in_hwcg_mode = cdiv_clk_in_hwcg_mode,
.enable_hwcg = cdiv_clk_enable_hwcg,
.disable_hwcg = cdiv_clk_disable_hwcg,
.handoff = cdiv_clk_handoff,
.set_rate = cdiv_clk_set_rate,
.get_rate = cdiv_clk_get_rate,
.list_rate = cdiv_clk_list_rate,
.round_rate = cdiv_clk_round_rate,
};
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