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mirror of https://github.com/edk2-porting/linux-next.git synced 2024-12-20 19:23:57 +08:00

Amlogic clock driver updates for 4.14

* meson8b: add the reset controller to the clkc
 * meson: expose all clk ids
 * gxbb-aoclk: Add CEC 32k clock
 * gxbb: add mmc input 0 clocks
 * meson: fix protection against undefined clks
 * gxbb: fix audio divider flags
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Merge tag 'meson-clk-for-4.14' of git://github.com/baylibre/clk-meson into clk-next

Pull Amlogic clock driver updates from Neil Armstrong:

 * meson8b: add the reset controller to the clkc
 * meson: expose all clk ids
 * gxbb-aoclk: Add CEC 32k clock
 * gxbb: add mmc input 0 clocks
 * meson: fix protection against undefined clks
 * gxbb: fix audio divider flags

* tag 'meson-clk-for-4.14' of git://github.com/baylibre/clk-meson:
  clk: meson: gxbb-aoclk: Add CEC 32k clock
  clk: meson: gxbb-aoclk: Switch to regmap for register access
  dt-bindings: clock: amlogic, gxbb-aoclkc: Update bindings
  clk: meson: gxbb: Add sd_emmc clk0 clocks
  clk: meson: gxbb: fix clk_mclk_i958 divider flags
  clk: meson: gxbb: fix meson cts_amclk divider flags
  clk: meson: meson8b: register the built-in reset controller
  dt-bindings: clock: gxbb-aoclk: Add CEC 32k clock
  clk: meson: gxbb: Add sd_emmc clk0 clkids
  clk: meson-gxbb: expose almost every clock in the bindings
  clk: meson8b: expose every clock in the bindings
  clk: meson: gxbb: fix protection against undefined clks
  clk: meson: meson8b: fix protection against undefined clks
  dt-bindings: clock: meson8b: describe the embedded reset controller
This commit is contained in:
Stephen Boyd 2017-08-23 15:28:52 -07:00
commit 3477a72b41
16 changed files with 870 additions and 258 deletions

View File

@ -5,9 +5,11 @@ controllers within the Always-On part of the SoC.
Required Properties:
- compatible: should be "amlogic,gxbb-aoclkc"
- reg: physical base address of the clock controller and length of memory
mapped region.
- compatible: value should be different for each SoC family as :
- GXBB (S905) : "amlogic,meson-gxbb-aoclkc"
- GXL (S905X, S905D) : "amlogic,meson-gxl-aoclkc"
- GXM (S912) : "amlogic,meson-gxm-aoclkc"
followed by the common "amlogic,meson-gx-aoclkc"
- #clock-cells: should be 1.
@ -23,14 +25,22 @@ to specify the reset which they consume. All available resets are defined as
preprocessor macros in the dt-bindings/reset/gxbb-aoclkc.h header and can be
used in device tree sources.
Parent node should have the following properties :
- compatible: "amlogic,meson-gx-ao-sysctrl", "syscon", "simple-mfd"
- reg: base address and size of the AO system control register space.
Example: AO Clock controller node:
clkc_AO: clock-controller@040 {
compatible = "amlogic,gxbb-aoclkc";
reg = <0x0 0x040 0x0 0x4>;
ao_sysctrl: sys-ctrl@0 {
compatible = "amlogic,meson-gx-ao-sysctrl", "syscon", "simple-mfd";
reg = <0x0 0x0 0x0 0x100>;
clkc_AO: clock-controller {
compatible = "amlogic,meson-gxbb-aoclkc", "amlogic,meson-gx-aoclkc";
#clock-cells = <1>;
#reset-cells = <1>;
};
};
Example: UART controller node that consumes the clock and reset generated
by the clock controller:

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@ -16,18 +16,25 @@ Required Properties:
mapped region.
- #clock-cells: should be 1.
- #reset-cells: should be 1.
Each clock is assigned an identifier and client nodes can use this identifier
to specify the clock which they consume. All available clocks are defined as
preprocessor macros in the dt-bindings/clock/meson8b-clkc.h header and can be
used in device tree sources.
Similarly a preprocessor macro for each reset line is defined in
dt-bindings/reset/amlogic,meson8b-clkc-reset.h (which can be used from the
device tree sources).
Example: Clock controller node:
clkc: clock-controller@c1104000 {
#clock-cells = <1>;
compatible = "amlogic,meson8b-clkc";
reg = <0xc1108000 0x4>, <0xc1104000 0x460>;
#clock-cells = <1>;
#reset-cells = <1>;
};

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@ -6,6 +6,7 @@ config COMMON_CLK_AMLOGIC
config COMMON_CLK_MESON8B
bool
depends on COMMON_CLK_AMLOGIC
select RESET_CONTROLLER
help
Support for the clock controller on AmLogic S802 (Meson8),
S805 (Meson8b) and S812 (Meson8m2) devices. Say Y if you

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@ -4,4 +4,4 @@
obj-$(CONFIG_COMMON_CLK_AMLOGIC) += clk-pll.o clk-cpu.o clk-mpll.o clk-audio-divider.o
obj-$(CONFIG_COMMON_CLK_MESON8B) += meson8b.o
obj-$(CONFIG_COMMON_CLK_GXBB) += gxbb.o gxbb-aoclk.o
obj-$(CONFIG_COMMON_CLK_GXBB) += gxbb.o gxbb-aoclk.o gxbb-aoclk-regmap.o gxbb-aoclk-32k.o

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@ -0,0 +1,194 @@
/*
* Copyright (c) 2017 BayLibre, SAS.
* Author: Neil Armstrong <narmstrong@baylibre.com>
*
* SPDX-License-Identifier: GPL-2.0+
*/
#include <linux/clk-provider.h>
#include <linux/bitfield.h>
#include <linux/regmap.h>
#include "gxbb-aoclk.h"
/*
* The AO Domain embeds a dual/divider to generate a more precise
* 32,768KHz clock for low-power suspend mode and CEC.
* ______ ______
* | | | |
* ______ | Div1 |-| Cnt1 | ______
* | | /|______| |______|\ | |
* Xtal-->| Gate |---| ______ ______ X-X--| Gate |-->
* |______| | \| | | |/ | |______|
* | | Div2 |-| Cnt2 | |
* | |______| |______| |
* |_______________________|
*
* The dividing can be switched to single or dual, with a counter
* for each divider to set when the switching is done.
* The entire dividing mechanism can be also bypassed.
*/
#define CLK_CNTL0_N1_MASK GENMASK(11, 0)
#define CLK_CNTL0_N2_MASK GENMASK(23, 12)
#define CLK_CNTL0_DUALDIV_EN BIT(28)
#define CLK_CNTL0_OUT_GATE_EN BIT(30)
#define CLK_CNTL0_IN_GATE_EN BIT(31)
#define CLK_CNTL1_M1_MASK GENMASK(11, 0)
#define CLK_CNTL1_M2_MASK GENMASK(23, 12)
#define CLK_CNTL1_BYPASS_EN BIT(24)
#define CLK_CNTL1_SELECT_OSC BIT(27)
#define PWR_CNTL_ALT_32K_SEL GENMASK(13, 10)
struct cec_32k_freq_table {
unsigned long parent_rate;
unsigned long target_rate;
bool dualdiv;
unsigned int n1;
unsigned int n2;
unsigned int m1;
unsigned int m2;
};
static const struct cec_32k_freq_table aoclk_cec_32k_table[] = {
[0] = {
.parent_rate = 24000000,
.target_rate = 32768,
.dualdiv = true,
.n1 = 733,
.n2 = 732,
.m1 = 8,
.m2 = 11,
},
};
/*
* If CLK_CNTL0_DUALDIV_EN == 0
* - will use N1 divider only
* If CLK_CNTL0_DUALDIV_EN == 1
* - hold M1 cycles of N1 divider then changes to N2
* - hold M2 cycles of N2 divider then changes to N1
* Then we can get more accurate division.
*/
static unsigned long aoclk_cec_32k_recalc_rate(struct clk_hw *hw,
unsigned long parent_rate)
{
struct aoclk_cec_32k *cec_32k = to_aoclk_cec_32k(hw);
unsigned long n1;
u32 reg0, reg1;
regmap_read(cec_32k->regmap, AO_RTC_ALT_CLK_CNTL0, &reg0);
regmap_read(cec_32k->regmap, AO_RTC_ALT_CLK_CNTL1, &reg1);
if (reg1 & CLK_CNTL1_BYPASS_EN)
return parent_rate;
if (reg0 & CLK_CNTL0_DUALDIV_EN) {
unsigned long n2, m1, m2, f1, f2, p1, p2;
n1 = FIELD_GET(CLK_CNTL0_N1_MASK, reg0) + 1;
n2 = FIELD_GET(CLK_CNTL0_N2_MASK, reg0) + 1;
m1 = FIELD_GET(CLK_CNTL1_M1_MASK, reg1) + 1;
m2 = FIELD_GET(CLK_CNTL1_M2_MASK, reg1) + 1;
f1 = DIV_ROUND_CLOSEST(parent_rate, n1);
f2 = DIV_ROUND_CLOSEST(parent_rate, n2);
p1 = DIV_ROUND_CLOSEST(100000000 * m1, f1 * (m1 + m2));
p2 = DIV_ROUND_CLOSEST(100000000 * m2, f2 * (m1 + m2));
return DIV_ROUND_UP(100000000, p1 + p2);
}
n1 = FIELD_GET(CLK_CNTL0_N1_MASK, reg0) + 1;
return DIV_ROUND_CLOSEST(parent_rate, n1);
}
static const struct cec_32k_freq_table *find_cec_32k_freq(unsigned long rate,
unsigned long prate)
{
int i;
for (i = 0 ; i < ARRAY_SIZE(aoclk_cec_32k_table) ; ++i)
if (aoclk_cec_32k_table[i].parent_rate == prate &&
aoclk_cec_32k_table[i].target_rate == rate)
return &aoclk_cec_32k_table[i];
return NULL;
}
static long aoclk_cec_32k_round_rate(struct clk_hw *hw, unsigned long rate,
unsigned long *prate)
{
const struct cec_32k_freq_table *freq = find_cec_32k_freq(rate,
*prate);
/* If invalid return first one */
if (!freq)
return aoclk_cec_32k_table[0].target_rate;
return freq->target_rate;
}
/*
* From the Amlogic init procedure, the IN and OUT gates needs to be handled
* in the init procedure to avoid any glitches.
*/
static int aoclk_cec_32k_set_rate(struct clk_hw *hw, unsigned long rate,
unsigned long parent_rate)
{
const struct cec_32k_freq_table *freq = find_cec_32k_freq(rate,
parent_rate);
struct aoclk_cec_32k *cec_32k = to_aoclk_cec_32k(hw);
u32 reg = 0;
if (!freq)
return -EINVAL;
/* Disable clock */
regmap_update_bits(cec_32k->regmap, AO_RTC_ALT_CLK_CNTL0,
CLK_CNTL0_IN_GATE_EN | CLK_CNTL0_OUT_GATE_EN, 0);
reg = FIELD_PREP(CLK_CNTL0_N1_MASK, freq->n1 - 1);
if (freq->dualdiv)
reg |= CLK_CNTL0_DUALDIV_EN |
FIELD_PREP(CLK_CNTL0_N2_MASK, freq->n2 - 1);
regmap_write(cec_32k->regmap, AO_RTC_ALT_CLK_CNTL0, reg);
reg = FIELD_PREP(CLK_CNTL1_M1_MASK, freq->m1 - 1);
if (freq->dualdiv)
reg |= FIELD_PREP(CLK_CNTL1_M2_MASK, freq->m2 - 1);
regmap_write(cec_32k->regmap, AO_RTC_ALT_CLK_CNTL1, reg);
/* Enable clock */
regmap_update_bits(cec_32k->regmap, AO_RTC_ALT_CLK_CNTL0,
CLK_CNTL0_IN_GATE_EN, CLK_CNTL0_IN_GATE_EN);
udelay(200);
regmap_update_bits(cec_32k->regmap, AO_RTC_ALT_CLK_CNTL0,
CLK_CNTL0_OUT_GATE_EN, CLK_CNTL0_OUT_GATE_EN);
regmap_update_bits(cec_32k->regmap, AO_CRT_CLK_CNTL1,
CLK_CNTL1_SELECT_OSC, CLK_CNTL1_SELECT_OSC);
/* Select 32k from XTAL */
regmap_update_bits(cec_32k->regmap,
AO_RTI_PWR_CNTL_REG0,
PWR_CNTL_ALT_32K_SEL,
FIELD_PREP(PWR_CNTL_ALT_32K_SEL, 4));
return 0;
}
const struct clk_ops meson_aoclk_cec_32k_ops = {
.recalc_rate = aoclk_cec_32k_recalc_rate,
.round_rate = aoclk_cec_32k_round_rate,
.set_rate = aoclk_cec_32k_set_rate,
};

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@ -0,0 +1,46 @@
/*
* Copyright (c) 2017 BayLibre, SAS.
* Author: Neil Armstrong <narmstrong@baylibre.com>
*
* SPDX-License-Identifier: GPL-2.0+
*/
#include <linux/clk-provider.h>
#include <linux/bitfield.h>
#include <linux/regmap.h>
#include "gxbb-aoclk.h"
static int aoclk_gate_regmap_enable(struct clk_hw *hw)
{
struct aoclk_gate_regmap *gate = to_aoclk_gate_regmap(hw);
return regmap_update_bits(gate->regmap, AO_RTI_GEN_CNTL_REG0,
BIT(gate->bit_idx), BIT(gate->bit_idx));
}
static void aoclk_gate_regmap_disable(struct clk_hw *hw)
{
struct aoclk_gate_regmap *gate = to_aoclk_gate_regmap(hw);
regmap_update_bits(gate->regmap, AO_RTI_GEN_CNTL_REG0,
BIT(gate->bit_idx), 0);
}
static int aoclk_gate_regmap_is_enabled(struct clk_hw *hw)
{
struct aoclk_gate_regmap *gate = to_aoclk_gate_regmap(hw);
unsigned int val;
int ret;
ret = regmap_read(gate->regmap, AO_RTI_GEN_CNTL_REG0, &val);
if (ret)
return ret;
return (val & BIT(gate->bit_idx)) != 0;
}
const struct clk_ops meson_aoclk_gate_regmap_ops = {
.enable = aoclk_gate_regmap_enable,
.disable = aoclk_gate_regmap_disable,
.is_enabled = aoclk_gate_regmap_is_enabled,
};

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@ -56,16 +56,20 @@
#include <linux/of_address.h>
#include <linux/platform_device.h>
#include <linux/reset-controller.h>
#include <linux/mfd/syscon.h>
#include <linux/regmap.h>
#include <linux/init.h>
#include <linux/delay.h>
#include <dt-bindings/clock/gxbb-aoclkc.h>
#include <dt-bindings/reset/gxbb-aoclkc.h>
#include "gxbb-aoclk.h"
static DEFINE_SPINLOCK(gxbb_aoclk_lock);
struct gxbb_aoclk_reset_controller {
struct reset_controller_dev reset;
unsigned int *data;
void __iomem *base;
struct regmap *regmap;
};
static int gxbb_aoclk_do_reset(struct reset_controller_dev *rcdev,
@ -74,9 +78,8 @@ static int gxbb_aoclk_do_reset(struct reset_controller_dev *rcdev,
struct gxbb_aoclk_reset_controller *reset =
container_of(rcdev, struct gxbb_aoclk_reset_controller, reset);
writel(BIT(reset->data[id]), reset->base);
return 0;
return regmap_write(reset->regmap, AO_RTI_GEN_CNTL_REG0,
BIT(reset->data[id]));
}
static const struct reset_control_ops gxbb_aoclk_reset_ops = {
@ -84,13 +87,12 @@ static const struct reset_control_ops gxbb_aoclk_reset_ops = {
};
#define GXBB_AO_GATE(_name, _bit) \
static struct clk_gate _name##_ao = { \
.reg = (void __iomem *)0, \
static struct aoclk_gate_regmap _name##_ao = { \
.bit_idx = (_bit), \
.lock = &gxbb_aoclk_lock, \
.hw.init = &(struct clk_init_data) { \
.name = #_name "_ao", \
.ops = &clk_gate_ops, \
.ops = &meson_aoclk_gate_regmap_ops, \
.parent_names = (const char *[]){ "clk81" }, \
.num_parents = 1, \
.flags = (CLK_SET_RATE_PARENT | CLK_IGNORE_UNUSED), \
@ -104,6 +106,17 @@ GXBB_AO_GATE(uart1, 3);
GXBB_AO_GATE(uart2, 5);
GXBB_AO_GATE(ir_blaster, 6);
static struct aoclk_cec_32k cec_32k_ao = {
.lock = &gxbb_aoclk_lock,
.hw.init = &(struct clk_init_data) {
.name = "cec_32k_ao",
.ops = &meson_aoclk_cec_32k_ops,
.parent_names = (const char *[]){ "xtal" },
.num_parents = 1,
.flags = CLK_IGNORE_UNUSED,
},
};
static unsigned int gxbb_aoclk_reset[] = {
[RESET_AO_REMOTE] = 16,
[RESET_AO_I2C_MASTER] = 18,
@ -113,7 +126,7 @@ static unsigned int gxbb_aoclk_reset[] = {
[RESET_AO_IR_BLASTER] = 23,
};
static struct clk_gate *gxbb_aoclk_gate[] = {
static struct aoclk_gate_regmap *gxbb_aoclk_gate[] = {
[CLKID_AO_REMOTE] = &remote_ao,
[CLKID_AO_I2C_MASTER] = &i2c_master_ao,
[CLKID_AO_I2C_SLAVE] = &i2c_slave_ao,
@ -130,30 +143,30 @@ static struct clk_hw_onecell_data gxbb_aoclk_onecell_data = {
[CLKID_AO_UART1] = &uart1_ao.hw,
[CLKID_AO_UART2] = &uart2_ao.hw,
[CLKID_AO_IR_BLASTER] = &ir_blaster_ao.hw,
[CLKID_AO_CEC_32K] = &cec_32k_ao.hw,
},
.num = ARRAY_SIZE(gxbb_aoclk_gate),
.num = 7,
};
static int gxbb_aoclkc_probe(struct platform_device *pdev)
{
struct resource *res;
void __iomem *base;
int ret, clkid;
struct device *dev = &pdev->dev;
struct gxbb_aoclk_reset_controller *rstc;
struct device *dev = &pdev->dev;
struct regmap *regmap;
int ret, clkid;
rstc = devm_kzalloc(dev, sizeof(*rstc), GFP_KERNEL);
if (!rstc)
return -ENOMEM;
/* Generic clocks */
res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
base = devm_ioremap_resource(dev, res);
if (IS_ERR(base))
return PTR_ERR(base);
regmap = syscon_node_to_regmap(of_get_parent(dev->of_node));
if (IS_ERR(regmap)) {
dev_err(dev, "failed to get regmap\n");
return -ENODEV;
}
/* Reset Controller */
rstc->base = base;
rstc->regmap = regmap;
rstc->data = gxbb_aoclk_reset;
rstc->reset.ops = &gxbb_aoclk_reset_ops;
rstc->reset.nr_resets = ARRAY_SIZE(gxbb_aoclk_reset);
@ -161,10 +174,10 @@ static int gxbb_aoclkc_probe(struct platform_device *pdev)
ret = devm_reset_controller_register(dev, &rstc->reset);
/*
* Populate base address and register all clks
* Populate regmap and register all clks
*/
for (clkid = 0; clkid < gxbb_aoclk_onecell_data.num; clkid++) {
gxbb_aoclk_gate[clkid]->reg = base;
for (clkid = 0; clkid < ARRAY_SIZE(gxbb_aoclk_gate); clkid++) {
gxbb_aoclk_gate[clkid]->regmap = regmap;
ret = devm_clk_hw_register(dev,
gxbb_aoclk_onecell_data.hws[clkid]);
@ -172,12 +185,18 @@ static int gxbb_aoclkc_probe(struct platform_device *pdev)
return ret;
}
/* Specific clocks */
cec_32k_ao.regmap = regmap;
ret = devm_clk_hw_register(dev, &cec_32k_ao.hw);
if (ret)
return ret;
return of_clk_add_hw_provider(dev->of_node, of_clk_hw_onecell_get,
&gxbb_aoclk_onecell_data);
}
static const struct of_device_id gxbb_aoclkc_match_table[] = {
{ .compatible = "amlogic,gxbb-aoclkc" },
{ .compatible = "amlogic,meson-gx-aoclkc" },
{ }
};

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@ -0,0 +1,42 @@
/*
* Copyright (c) 2017 BayLibre, SAS
* Author: Neil Armstrong <narmstrong@baylibre.com>
*
* SPDX-License-Identifier: GPL-2.0+
*/
#ifndef __GXBB_AOCLKC_H
#define __GXBB_AOCLKC_H
/* AO Configuration Clock registers offsets */
#define AO_RTI_PWR_CNTL_REG1 0x0c
#define AO_RTI_PWR_CNTL_REG0 0x10
#define AO_RTI_GEN_CNTL_REG0 0x40
#define AO_OSCIN_CNTL 0x58
#define AO_CRT_CLK_CNTL1 0x68
#define AO_RTC_ALT_CLK_CNTL0 0x94
#define AO_RTC_ALT_CLK_CNTL1 0x98
struct aoclk_gate_regmap {
struct clk_hw hw;
unsigned bit_idx;
struct regmap *regmap;
spinlock_t *lock;
};
#define to_aoclk_gate_regmap(_hw) \
container_of(_hw, struct aoclk_gate_regmap, hw)
extern const struct clk_ops meson_aoclk_gate_regmap_ops;
struct aoclk_cec_32k {
struct clk_hw hw;
struct regmap *regmap;
spinlock_t *lock;
};
#define to_aoclk_cec_32k(_hw) container_of(_hw, struct aoclk_cec_32k, hw)
extern const struct clk_ops meson_aoclk_cec_32k_ops;
#endif /* __GXBB_AOCLKC_H */

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@ -850,13 +850,14 @@ static struct meson_clk_audio_divider gxbb_cts_amclk_div = {
.shift = 0,
.width = 8,
},
.flags = CLK_DIVIDER_ROUND_CLOSEST,
.lock = &clk_lock,
.hw.init = &(struct clk_init_data){
.name = "cts_amclk_div",
.ops = &meson_clk_audio_divider_ops,
.parent_names = (const char *[]){ "cts_amclk_sel" },
.num_parents = 1,
.flags = CLK_SET_RATE_PARENT | CLK_DIVIDER_ROUND_CLOSEST,
.flags = CLK_SET_RATE_PARENT,
},
};
@ -880,7 +881,7 @@ static struct clk_mux gxbb_cts_mclk_i958_sel = {
/* Default parent unknown (register reset value: 0) */
.table = (u32[]){ 1, 2, 3 },
.lock = &clk_lock,
.hw.init = &(struct clk_init_data){
.hw.init = &(struct clk_init_data) {
.name = "cts_mclk_i958_sel",
.ops = &clk_mux_ops,
.parent_names = (const char *[]){ "mpll0", "mpll1", "mpll2" },
@ -894,12 +895,13 @@ static struct clk_divider gxbb_cts_mclk_i958_div = {
.shift = 16,
.width = 8,
.lock = &clk_lock,
.hw.init = &(struct clk_init_data){
.flags = CLK_DIVIDER_ROUND_CLOSEST,
.hw.init = &(struct clk_init_data) {
.name = "cts_mclk_i958_div",
.ops = &clk_divider_ops,
.parent_names = (const char *[]){ "cts_mclk_i958_sel" },
.num_parents = 1,
.flags = CLK_SET_RATE_PARENT | CLK_DIVIDER_ROUND_CLOSEST,
.flags = CLK_SET_RATE_PARENT,
},
};
@ -979,6 +981,156 @@ static struct clk_mux gxbb_32k_clk_sel = {
},
};
static const char * const gxbb_sd_emmc_clk0_parent_names[] = {
"xtal", "fclk_div2", "fclk_div3", "fclk_div5", "fclk_div7",
/*
* Following these parent clocks, we should also have had mpll2, mpll3
* and gp0_pll but these clocks are too precious to be used here. All
* the necessary rates for MMC and NAND operation can be acheived using
* xtal or fclk_div clocks
*/
};
/* SDIO clock */
static struct clk_mux gxbb_sd_emmc_a_clk0_sel = {
.reg = (void *)HHI_SD_EMMC_CLK_CNTL,
.mask = 0x7,
.shift = 9,
.lock = &clk_lock,
.hw.init = &(struct clk_init_data) {
.name = "sd_emmc_a_clk0_sel",
.ops = &clk_mux_ops,
.parent_names = gxbb_sd_emmc_clk0_parent_names,
.num_parents = ARRAY_SIZE(gxbb_sd_emmc_clk0_parent_names),
.flags = CLK_SET_RATE_PARENT,
},
};
static struct clk_divider gxbb_sd_emmc_a_clk0_div = {
.reg = (void *)HHI_SD_EMMC_CLK_CNTL,
.shift = 0,
.width = 7,
.lock = &clk_lock,
.flags = CLK_DIVIDER_ROUND_CLOSEST,
.hw.init = &(struct clk_init_data) {
.name = "sd_emmc_a_clk0_div",
.ops = &clk_divider_ops,
.parent_names = (const char *[]){ "sd_emmc_a_clk0_sel" },
.num_parents = 1,
.flags = CLK_SET_RATE_PARENT,
},
};
static struct clk_gate gxbb_sd_emmc_a_clk0 = {
.reg = (void *)HHI_SD_EMMC_CLK_CNTL,
.bit_idx = 7,
.lock = &clk_lock,
.hw.init = &(struct clk_init_data){
.name = "sd_emmc_a_clk0",
.ops = &clk_gate_ops,
.parent_names = (const char *[]){ "sd_emmc_a_clk0_div" },
.num_parents = 1,
/*
* FIXME:
* We need CLK_IGNORE_UNUSED because mmc DT node point to xtal
* instead of this clock. CCF would gate this on boot, killing
* the mmc controller. Please remove this flag once DT properly
* point to this clock instead of xtal
*
* Same goes for emmc B and C clocks
*/
.flags = CLK_SET_RATE_PARENT | CLK_IGNORE_UNUSED,
},
};
/* SDcard clock */
static struct clk_mux gxbb_sd_emmc_b_clk0_sel = {
.reg = (void *)HHI_SD_EMMC_CLK_CNTL,
.mask = 0x7,
.shift = 25,
.lock = &clk_lock,
.hw.init = &(struct clk_init_data) {
.name = "sd_emmc_b_clk0_sel",
.ops = &clk_mux_ops,
.parent_names = gxbb_sd_emmc_clk0_parent_names,
.num_parents = ARRAY_SIZE(gxbb_sd_emmc_clk0_parent_names),
.flags = CLK_SET_RATE_PARENT,
},
};
static struct clk_divider gxbb_sd_emmc_b_clk0_div = {
.reg = (void *)HHI_SD_EMMC_CLK_CNTL,
.shift = 16,
.width = 7,
.lock = &clk_lock,
.flags = CLK_DIVIDER_ROUND_CLOSEST,
.hw.init = &(struct clk_init_data) {
.name = "sd_emmc_b_clk0_div",
.ops = &clk_divider_ops,
.parent_names = (const char *[]){ "sd_emmc_b_clk0_sel" },
.num_parents = 1,
.flags = CLK_SET_RATE_PARENT,
},
};
static struct clk_gate gxbb_sd_emmc_b_clk0 = {
.reg = (void *)HHI_SD_EMMC_CLK_CNTL,
.bit_idx = 23,
.lock = &clk_lock,
.hw.init = &(struct clk_init_data){
.name = "sd_emmc_b_clk0",
.ops = &clk_gate_ops,
.parent_names = (const char *[]){ "sd_emmc_b_clk0_div" },
.num_parents = 1,
.flags = CLK_SET_RATE_PARENT | CLK_IGNORE_UNUSED,
},
};
/* EMMC/NAND clock */
static struct clk_mux gxbb_sd_emmc_c_clk0_sel = {
.reg = (void *)HHI_NAND_CLK_CNTL,
.mask = 0x7,
.shift = 9,
.lock = &clk_lock,
.hw.init = &(struct clk_init_data) {
.name = "sd_emmc_c_clk0_sel",
.ops = &clk_mux_ops,
.parent_names = gxbb_sd_emmc_clk0_parent_names,
.num_parents = ARRAY_SIZE(gxbb_sd_emmc_clk0_parent_names),
.flags = CLK_SET_RATE_PARENT,
},
};
static struct clk_divider gxbb_sd_emmc_c_clk0_div = {
.reg = (void *)HHI_NAND_CLK_CNTL,
.shift = 0,
.width = 7,
.lock = &clk_lock,
.flags = CLK_DIVIDER_ROUND_CLOSEST,
.hw.init = &(struct clk_init_data) {
.name = "sd_emmc_c_clk0_div",
.ops = &clk_divider_ops,
.parent_names = (const char *[]){ "sd_emmc_c_clk0_sel" },
.num_parents = 1,
.flags = CLK_SET_RATE_PARENT,
},
};
static struct clk_gate gxbb_sd_emmc_c_clk0 = {
.reg = (void *)HHI_NAND_CLK_CNTL,
.bit_idx = 7,
.lock = &clk_lock,
.hw.init = &(struct clk_init_data){
.name = "sd_emmc_c_clk0",
.ops = &clk_gate_ops,
.parent_names = (const char *[]){ "sd_emmc_c_clk0_div" },
.num_parents = 1,
.flags = CLK_SET_RATE_PARENT | CLK_IGNORE_UNUSED,
},
};
/* Everything Else (EE) domain gates */
static MESON_GATE(gxbb_ddr, HHI_GCLK_MPEG0, 0);
static MESON_GATE(gxbb_dos, HHI_GCLK_MPEG0, 1);
@ -1188,6 +1340,16 @@ static struct clk_hw_onecell_data gxbb_hw_onecell_data = {
[CLKID_32K_CLK] = &gxbb_32k_clk.hw,
[CLKID_32K_CLK_SEL] = &gxbb_32k_clk_sel.hw,
[CLKID_32K_CLK_DIV] = &gxbb_32k_clk_div.hw,
[CLKID_SD_EMMC_A_CLK0_SEL] = &gxbb_sd_emmc_a_clk0_sel.hw,
[CLKID_SD_EMMC_A_CLK0_DIV] = &gxbb_sd_emmc_a_clk0_div.hw,
[CLKID_SD_EMMC_A_CLK0] = &gxbb_sd_emmc_a_clk0.hw,
[CLKID_SD_EMMC_B_CLK0_SEL] = &gxbb_sd_emmc_b_clk0_sel.hw,
[CLKID_SD_EMMC_B_CLK0_DIV] = &gxbb_sd_emmc_b_clk0_div.hw,
[CLKID_SD_EMMC_B_CLK0] = &gxbb_sd_emmc_b_clk0.hw,
[CLKID_SD_EMMC_C_CLK0_SEL] = &gxbb_sd_emmc_c_clk0_sel.hw,
[CLKID_SD_EMMC_C_CLK0_DIV] = &gxbb_sd_emmc_c_clk0_div.hw,
[CLKID_SD_EMMC_C_CLK0] = &gxbb_sd_emmc_c_clk0.hw,
[NR_CLKS] = NULL,
},
.num = NR_CLKS,
};
@ -1310,6 +1472,16 @@ static struct clk_hw_onecell_data gxl_hw_onecell_data = {
[CLKID_32K_CLK] = &gxbb_32k_clk.hw,
[CLKID_32K_CLK_SEL] = &gxbb_32k_clk_sel.hw,
[CLKID_32K_CLK_DIV] = &gxbb_32k_clk_div.hw,
[CLKID_SD_EMMC_A_CLK0_SEL] = &gxbb_sd_emmc_a_clk0_sel.hw,
[CLKID_SD_EMMC_A_CLK0_DIV] = &gxbb_sd_emmc_a_clk0_div.hw,
[CLKID_SD_EMMC_A_CLK0] = &gxbb_sd_emmc_a_clk0.hw,
[CLKID_SD_EMMC_B_CLK0_SEL] = &gxbb_sd_emmc_b_clk0_sel.hw,
[CLKID_SD_EMMC_B_CLK0_DIV] = &gxbb_sd_emmc_b_clk0_div.hw,
[CLKID_SD_EMMC_B_CLK0] = &gxbb_sd_emmc_b_clk0.hw,
[CLKID_SD_EMMC_C_CLK0_SEL] = &gxbb_sd_emmc_c_clk0_sel.hw,
[CLKID_SD_EMMC_C_CLK0_DIV] = &gxbb_sd_emmc_c_clk0_div.hw,
[CLKID_SD_EMMC_C_CLK0] = &gxbb_sd_emmc_c_clk0.hw,
[NR_CLKS] = NULL,
},
.num = NR_CLKS,
};
@ -1425,6 +1597,9 @@ static struct clk_gate *const gxbb_clk_gates[] = {
&gxbb_cts_amclk,
&gxbb_cts_mclk_i958,
&gxbb_32k_clk,
&gxbb_sd_emmc_a_clk0,
&gxbb_sd_emmc_b_clk0,
&gxbb_sd_emmc_c_clk0,
};
static struct clk_mux *const gxbb_clk_muxes[] = {
@ -1437,6 +1612,9 @@ static struct clk_mux *const gxbb_clk_muxes[] = {
&gxbb_cts_mclk_i958_sel,
&gxbb_cts_i958,
&gxbb_32k_clk_sel,
&gxbb_sd_emmc_a_clk0_sel,
&gxbb_sd_emmc_b_clk0_sel,
&gxbb_sd_emmc_c_clk0_sel,
};
static struct clk_divider *const gxbb_clk_dividers[] = {
@ -1446,6 +1624,9 @@ static struct clk_divider *const gxbb_clk_dividers[] = {
&gxbb_mali_1_div,
&gxbb_cts_mclk_i958_div,
&gxbb_32k_clk_div,
&gxbb_sd_emmc_a_clk0_div,
&gxbb_sd_emmc_b_clk0_div,
&gxbb_sd_emmc_c_clk0_div,
};
static struct meson_clk_audio_divider *const gxbb_audio_dividers[] = {

View File

@ -167,130 +167,33 @@
* CLKID index values
*
* These indices are entirely contrived and do not map onto the hardware.
* Migrate them out of this header and into the DT header file when they need
* to be exposed to client nodes in DT: include/dt-bindings/clock/gxbb-clkc.h
* It has now been decided to expose everything by default in the DT header:
* include/dt-bindings/clock/gxbb-clkc.h. Only the clocks ids we don't want
* to expose, such as the internal muxes and dividers of composite clocks,
* will remain defined here.
*/
#define CLKID_SYS_PLL 0
/* ID 1 is unused (it was used by the non-existing CLKID_CPUCLK before) */
/* CLKID_HDMI_PLL */
#define CLKID_FIXED_PLL 3
/* CLKID_FCLK_DIV2 */
/* CLKID_FCLK_DIV3 */
/* CLKID_FCLK_DIV4 */
#define CLKID_FCLK_DIV5 7
#define CLKID_FCLK_DIV7 8
/* CLKID_GP0_PLL */
#define CLKID_MPEG_SEL 10
#define CLKID_MPEG_DIV 11
/* CLKID_CLK81 */
#define CLKID_MPLL0 13
#define CLKID_MPLL1 14
/* CLKID_MPLL2 */
#define CLKID_DDR 16
#define CLKID_DOS 17
#define CLKID_ISA 18
#define CLKID_PL301 19
#define CLKID_PERIPHS 20
/* CLKID_SPICC */
/* CLKID_I2C */
/* #define CLKID_SAR_ADC */
#define CLKID_SMART_CARD 24
/* CLKID_RNG0 */
/* CLKID_UART0 */
#define CLKID_SDHC 27
#define CLKID_STREAM 28
#define CLKID_ASYNC_FIFO 29
#define CLKID_SDIO 30
#define CLKID_ABUF 31
#define CLKID_HIU_IFACE 32
#define CLKID_ASSIST_MISC 33
/* CLKID_SPI */
#define CLKID_I2S_SPDIF 35
/* CLKID_ETH */
#define CLKID_DEMUX 37
/* CLKID_AIU_GLUE */
/* CLKID_IEC958 */
/* CLKID_I2S_OUT */
#define CLKID_AMCLK 41
#define CLKID_AIFIFO2 42
#define CLKID_MIXER 43
/* CLKID_MIXER_IFACE */
#define CLKID_ADC 45
#define CLKID_BLKMV 46
/* CLKID_AIU */
/* CLKID_UART1 */
#define CLKID_G2D 49
/* CLKID_USB0 */
/* CLKID_USB1 */
#define CLKID_RESET 52
#define CLKID_NAND 53
#define CLKID_DOS_PARSER 54
/* CLKID_USB */
#define CLKID_VDIN1 56
#define CLKID_AHB_ARB0 57
#define CLKID_EFUSE 58
#define CLKID_BOOT_ROM 59
#define CLKID_AHB_DATA_BUS 60
#define CLKID_AHB_CTRL_BUS 61
#define CLKID_HDMI_INTR_SYNC 62
/* CLKID_HDMI_PCLK */
/* CLKID_USB1_DDR_BRIDGE */
/* CLKID_USB0_DDR_BRIDGE */
#define CLKID_MMC_PCLK 66
#define CLKID_DVIN 67
/* CLKID_UART2 */
/* #define CLKID_SANA */
#define CLKID_VPU_INTR 70
#define CLKID_SEC_AHB_AHB3_BRIDGE 71
#define CLKID_CLK81_A53 72
#define CLKID_VCLK2_VENCI0 73
#define CLKID_VCLK2_VENCI1 74
#define CLKID_VCLK2_VENCP0 75
#define CLKID_VCLK2_VENCP1 76
/* CLKID_GCLK_VENCI_INT0 */
#define CLKID_GCLK_VENCI_INT 78
#define CLKID_DAC_CLK 79
/* CLKID_AOCLK_GATE */
/* CLKID_IEC958_GATE */
#define CLKID_ENC480P 82
#define CLKID_RNG1 83
#define CLKID_GCLK_VENCI_INT1 84
#define CLKID_VCLK2_VENCLMCC 85
#define CLKID_VCLK2_VENCL 86
#define CLKID_VCLK_OTHER 87
#define CLKID_EDP 88
#define CLKID_AO_MEDIA_CPU 89
#define CLKID_AO_AHB_SRAM 90
#define CLKID_AO_AHB_BUS 91
#define CLKID_AO_IFACE 92
/* CLKID_AO_I2C */
/* CLKID_SD_EMMC_A */
/* CLKID_SD_EMMC_B */
/* CLKID_SD_EMMC_C */
/* CLKID_SAR_ADC_CLK */
/* CLKID_SAR_ADC_SEL */
#define CLKID_SAR_ADC_DIV 99
/* CLKID_MALI_0_SEL */
#define CLKID_MALI_0_DIV 101
/* CLKID_MALI_0 */
/* CLKID_MALI_1_SEL */
#define CLKID_MALI_1_DIV 104
/* CLKID_MALI_1 */
/* CLKID_MALI */
/* CLKID_CTS_AMCLK */
#define CLKID_MALI_0_DIV 101
#define CLKID_MALI_1_DIV 104
#define CLKID_CTS_AMCLK_SEL 108
#define CLKID_CTS_AMCLK_DIV 109
/* CLKID_CTS_MCLK_I958 */
#define CLKID_CTS_MCLK_I958_SEL 111
#define CLKID_CTS_MCLK_I958_DIV 112
/* CLKID_CTS_I958 */
#define CLKID_32K_CLK 114
#define CLKID_32K_CLK_SEL 115
#define CLKID_32K_CLK_DIV 116
#define CLKID_SD_EMMC_A_CLK0_SEL 117
#define CLKID_SD_EMMC_A_CLK0_DIV 118
#define CLKID_SD_EMMC_B_CLK0_SEL 120
#define CLKID_SD_EMMC_B_CLK0_DIV 121
#define CLKID_SD_EMMC_C_CLK0_SEL 123
#define CLKID_SD_EMMC_C_CLK0_DIV 124
#define NR_CLKS 117
#define NR_CLKS 126
/* include the CLKIDs that have been made part of the stable DT binding */
/* include the CLKIDs that have been made part of the DT binding */
#include <dt-bindings/clock/gxbb-clkc.h>
#endif /* __GXBB_H */

View File

@ -25,6 +25,8 @@
#include <linux/clk-provider.h>
#include <linux/of_address.h>
#include <linux/platform_device.h>
#include <linux/reset-controller.h>
#include <linux/slab.h>
#include <linux/init.h>
#include "clkc.h"
@ -32,6 +34,13 @@
static DEFINE_SPINLOCK(clk_lock);
static void __iomem *clk_base;
struct meson8b_clk_reset {
struct reset_controller_dev reset;
void __iomem *base;
};
static const struct pll_rate_table sys_pll_rate_table[] = {
PLL_RATE(312000000, 52, 1, 2),
PLL_RATE(336000000, 56, 1, 2),
@ -590,6 +599,7 @@ static struct clk_hw_onecell_data meson8b_hw_onecell_data = {
[CLKID_MPLL0] = &meson8b_mpll0.hw,
[CLKID_MPLL1] = &meson8b_mpll1.hw,
[CLKID_MPLL2] = &meson8b_mpll2.hw,
[CLK_NR_CLKS] = NULL,
},
.num = CLK_NR_CLKS,
};
@ -695,20 +705,114 @@ static struct clk_divider *const meson8b_clk_dividers[] = {
&meson8b_mpeg_clk_div,
};
static const struct meson8b_clk_reset_line {
u32 reg;
u8 bit_idx;
} meson8b_clk_reset_bits[] = {
[CLKC_RESET_L2_CACHE_SOFT_RESET] = {
.reg = HHI_SYS_CPU_CLK_CNTL0, .bit_idx = 30
},
[CLKC_RESET_AXI_64_TO_128_BRIDGE_A5_SOFT_RESET] = {
.reg = HHI_SYS_CPU_CLK_CNTL0, .bit_idx = 29
},
[CLKC_RESET_SCU_SOFT_RESET] = {
.reg = HHI_SYS_CPU_CLK_CNTL0, .bit_idx = 28
},
[CLKC_RESET_CPU3_SOFT_RESET] = {
.reg = HHI_SYS_CPU_CLK_CNTL0, .bit_idx = 27
},
[CLKC_RESET_CPU2_SOFT_RESET] = {
.reg = HHI_SYS_CPU_CLK_CNTL0, .bit_idx = 26
},
[CLKC_RESET_CPU1_SOFT_RESET] = {
.reg = HHI_SYS_CPU_CLK_CNTL0, .bit_idx = 25
},
[CLKC_RESET_CPU0_SOFT_RESET] = {
.reg = HHI_SYS_CPU_CLK_CNTL0, .bit_idx = 24
},
[CLKC_RESET_A5_GLOBAL_RESET] = {
.reg = HHI_SYS_CPU_CLK_CNTL0, .bit_idx = 18
},
[CLKC_RESET_A5_AXI_SOFT_RESET] = {
.reg = HHI_SYS_CPU_CLK_CNTL0, .bit_idx = 17
},
[CLKC_RESET_A5_ABP_SOFT_RESET] = {
.reg = HHI_SYS_CPU_CLK_CNTL0, .bit_idx = 16
},
[CLKC_RESET_AXI_64_TO_128_BRIDGE_MMC_SOFT_RESET] = {
.reg = HHI_SYS_CPU_CLK_CNTL1, .bit_idx = 30
},
[CLKC_RESET_VID_CLK_CNTL_SOFT_RESET] = {
.reg = HHI_VID_CLK_CNTL, .bit_idx = 15
},
[CLKC_RESET_VID_DIVIDER_CNTL_SOFT_RESET_POST] = {
.reg = HHI_VID_DIVIDER_CNTL, .bit_idx = 7
},
[CLKC_RESET_VID_DIVIDER_CNTL_SOFT_RESET_PRE] = {
.reg = HHI_VID_DIVIDER_CNTL, .bit_idx = 3
},
[CLKC_RESET_VID_DIVIDER_CNTL_RESET_N_POST] = {
.reg = HHI_VID_DIVIDER_CNTL, .bit_idx = 1
},
[CLKC_RESET_VID_DIVIDER_CNTL_RESET_N_PRE] = {
.reg = HHI_VID_DIVIDER_CNTL, .bit_idx = 0
},
};
static int meson8b_clk_reset_update(struct reset_controller_dev *rcdev,
unsigned long id, bool assert)
{
struct meson8b_clk_reset *meson8b_clk_reset =
container_of(rcdev, struct meson8b_clk_reset, reset);
unsigned long flags;
const struct meson8b_clk_reset_line *reset;
u32 val;
if (id >= ARRAY_SIZE(meson8b_clk_reset_bits))
return -EINVAL;
reset = &meson8b_clk_reset_bits[id];
spin_lock_irqsave(&clk_lock, flags);
val = readl(meson8b_clk_reset->base + reset->reg);
if (assert)
val |= BIT(reset->bit_idx);
else
val &= ~BIT(reset->bit_idx);
writel(val, meson8b_clk_reset->base + reset->reg);
spin_unlock_irqrestore(&clk_lock, flags);
return 0;
}
static int meson8b_clk_reset_assert(struct reset_controller_dev *rcdev,
unsigned long id)
{
return meson8b_clk_reset_update(rcdev, id, true);
}
static int meson8b_clk_reset_deassert(struct reset_controller_dev *rcdev,
unsigned long id)
{
return meson8b_clk_reset_update(rcdev, id, false);
}
static const struct reset_control_ops meson8b_clk_reset_ops = {
.assert = meson8b_clk_reset_assert,
.deassert = meson8b_clk_reset_deassert,
};
static int meson8b_clkc_probe(struct platform_device *pdev)
{
void __iomem *clk_base;
int ret, clkid, i;
struct clk_hw *parent_hw;
struct clk *parent_clk;
struct device *dev = &pdev->dev;
/* Generic clocks and PLLs */
clk_base = of_iomap(dev->of_node, 1);
if (!clk_base) {
pr_err("%s: Unable to map clk base\n", __func__);
if (!clk_base)
return -ENXIO;
}
/* Populate base address for PLLs */
for (i = 0; i < ARRAY_SIZE(meson8b_clk_plls); i++)
@ -748,7 +852,7 @@ static int meson8b_clkc_probe(struct platform_device *pdev)
/* FIXME convert to devm_clk_register */
ret = devm_clk_hw_register(dev, meson8b_hw_onecell_data.hws[clkid]);
if (ret)
goto iounmap;
return ret;
}
/*
@ -771,15 +875,11 @@ static int meson8b_clkc_probe(struct platform_device *pdev)
if (ret) {
pr_err("%s: failed to register clock notifier for cpu_clk\n",
__func__);
goto iounmap;
return ret;
}
return of_clk_add_hw_provider(dev->of_node, of_clk_hw_onecell_get,
&meson8b_hw_onecell_data);
iounmap:
iounmap(clk_base);
return ret;
}
static const struct of_device_id meson8b_clkc_match_table[] = {
@ -798,3 +898,39 @@ static struct platform_driver meson8b_driver = {
};
builtin_platform_driver(meson8b_driver);
static void __init meson8b_clkc_reset_init(struct device_node *np)
{
struct meson8b_clk_reset *rstc;
int ret;
/* Generic clocks, PLLs and some of the reset-bits */
clk_base = of_iomap(np, 1);
if (!clk_base) {
pr_err("%s: Unable to map clk base\n", __func__);
return;
}
rstc = kzalloc(sizeof(*rstc), GFP_KERNEL);
if (!rstc)
return;
/* Reset Controller */
rstc->base = clk_base;
rstc->reset.ops = &meson8b_clk_reset_ops;
rstc->reset.nr_resets = ARRAY_SIZE(meson8b_clk_reset_bits);
rstc->reset.of_node = np;
ret = reset_controller_register(&rstc->reset);
if (ret) {
pr_err("%s: Failed to register clkc reset controller: %d\n",
__func__, ret);
return;
}
}
CLK_OF_DECLARE_DRIVER(meson8_clkc, "amlogic,meson8-clkc",
meson8b_clkc_reset_init);
CLK_OF_DECLARE_DRIVER(meson8b_clkc, "amlogic,meson8b-clkc",
meson8b_clkc_reset_init);
CLK_OF_DECLARE_DRIVER(meson8m2_clkc, "amlogic,meson8m2-clkc",
meson8b_clkc_reset_init);

View File

@ -37,6 +37,9 @@
#define HHI_GCLK_AO 0x154 /* 0x55 offset in data sheet */
#define HHI_SYS_CPU_CLK_CNTL1 0x15c /* 0x57 offset in data sheet */
#define HHI_MPEG_CLK_CNTL 0x174 /* 0x5d offset in data sheet */
#define HHI_VID_CLK_CNTL 0x17c /* 0x5f offset in data sheet */
#define HHI_VID_DIVIDER_CNTL 0x198 /* 0x66 offset in data sheet */
#define HHI_SYS_CPU_CLK_CNTL0 0x19c /* 0x67 offset in data sheet */
#define HHI_MPLL_CNTL 0x280 /* 0xa0 offset in data sheet */
#define HHI_SYS_PLL_CNTL 0x300 /* 0xc0 offset in data sheet */
#define HHI_VID_PLL_CNTL 0x320 /* 0xc8 offset in data sheet */
@ -60,110 +63,19 @@
* CLKID index values
*
* These indices are entirely contrived and do not map onto the hardware.
* Migrate them out of this header and into the DT header file when they need
* to be exposed to client nodes in DT: include/dt-bindings/clock/meson8b-clkc.h
* It has now been decided to expose everything by default in the DT header:
* include/dt-bindings/clock/gxbb-clkc.h. Only the clocks ids we don't want
* to expose, such as the internal muxes and dividers of composite clocks,
* will remain defined here.
*/
/* CLKID_UNUSED */
/* CLKID_XTAL */
/* CLKID_PLL_FIXED */
/* CLKID_PLL_VID */
/* CLKID_PLL_SYS */
/* CLKID_FCLK_DIV2 */
/* CLKID_FCLK_DIV3 */
/* CLKID_FCLK_DIV4 */
/* CLKID_FCLK_DIV5 */
/* CLKID_FCLK_DIV7 */
/* CLKID_CLK81 */
/* CLKID_MALI */
/* CLKID_CPUCLK */
/* CLKID_ZERO */
/* CLKID_MPEG_SEL */
/* CLKID_MPEG_DIV */
#define CLKID_DDR 16
#define CLKID_DOS 17
#define CLKID_ISA 18
#define CLKID_PL301 19
#define CLKID_PERIPHS 20
#define CLKID_SPICC 21
#define CLKID_I2C 22
/* #define CLKID_SAR_ADC */
#define CLKID_SMART_CARD 24
/* #define CLKID_RNG0 */
#define CLKID_UART0 26
#define CLKID_SDHC 27
#define CLKID_STREAM 28
#define CLKID_ASYNC_FIFO 29
/* #define CLKID_SDIO */
#define CLKID_ABUF 31
#define CLKID_HIU_IFACE 32
#define CLKID_ASSIST_MISC 33
#define CLKID_SPI 34
#define CLKID_I2S_SPDIF 35
/* #define CLKID_ETH */
#define CLKID_DEMUX 37
#define CLKID_AIU_GLUE 38
#define CLKID_IEC958 39
#define CLKID_I2S_OUT 40
#define CLKID_AMCLK 41
#define CLKID_AIFIFO2 42
#define CLKID_MIXER 43
#define CLKID_MIXER_IFACE 44
#define CLKID_ADC 45
#define CLKID_BLKMV 46
#define CLKID_AIU 47
#define CLKID_UART1 48
#define CLKID_G2D 49
/* #define CLKID_USB0 */
/* #define CLKID_USB1 */
#define CLKID_RESET 52
#define CLKID_NAND 53
#define CLKID_DOS_PARSER 54
/* #define CLKID_USB */
#define CLKID_VDIN1 56
#define CLKID_AHB_ARB0 57
#define CLKID_EFUSE 58
#define CLKID_BOOT_ROM 59
#define CLKID_AHB_DATA_BUS 60
#define CLKID_AHB_CTRL_BUS 61
#define CLKID_HDMI_INTR_SYNC 62
#define CLKID_HDMI_PCLK 63
/* CLKID_USB1_DDR_BRIDGE */
/* CLKID_USB0_DDR_BRIDGE */
#define CLKID_MMC_PCLK 66
#define CLKID_DVIN 67
#define CLKID_UART2 68
/* #define CLKID_SANA */
#define CLKID_VPU_INTR 70
#define CLKID_SEC_AHB_AHB3_BRIDGE 71
#define CLKID_CLK81_A9 72
#define CLKID_VCLK2_VENCI0 73
#define CLKID_VCLK2_VENCI1 74
#define CLKID_VCLK2_VENCP0 75
#define CLKID_VCLK2_VENCP1 76
#define CLKID_GCLK_VENCI_INT 77
#define CLKID_GCLK_VENCP_INT 78
#define CLKID_DAC_CLK 79
#define CLKID_AOCLK_GATE 80
#define CLKID_IEC958_GATE 81
#define CLKID_ENC480P 82
#define CLKID_RNG1 83
#define CLKID_GCLK_VENCL_INT 84
#define CLKID_VCLK2_VENCLMCC 85
#define CLKID_VCLK2_VENCL 86
#define CLKID_VCLK2_OTHER 87
#define CLKID_EDP 88
#define CLKID_AO_MEDIA_CPU 89
#define CLKID_AO_AHB_SRAM 90
#define CLKID_AO_AHB_BUS 91
#define CLKID_AO_IFACE 92
#define CLKID_MPLL0 93
#define CLKID_MPLL1 94
#define CLKID_MPLL2 95
#define CLK_NR_CLKS 96
/* include the CLKIDs that have been made part of the stable DT binding */
/*
* include the CLKID and RESETID that have
* been made part of the stable DT binding
*/
#include <dt-bindings/clock/meson8b-clkc.h>
#include <dt-bindings/reset/amlogic,meson8b-clkc-reset.h>
#endif /* __MESON8B_H */

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@ -62,5 +62,6 @@
#define CLKID_AO_UART1 3
#define CLKID_AO_UART2 4
#define CLKID_AO_IR_BLASTER 5
#define CLKID_AO_CEC_32K 6
#endif

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@ -5,37 +5,96 @@
#ifndef __GXBB_CLKC_H
#define __GXBB_CLKC_H
#define CLKID_SYS_PLL 0
#define CLKID_HDMI_PLL 2
#define CLKID_FIXED_PLL 3
#define CLKID_FCLK_DIV2 4
#define CLKID_FCLK_DIV3 5
#define CLKID_FCLK_DIV4 6
#define CLKID_FCLK_DIV5 7
#define CLKID_FCLK_DIV7 8
#define CLKID_GP0_PLL 9
#define CLKID_CLK81 12
#define CLKID_MPLL0 13
#define CLKID_MPLL1 14
#define CLKID_MPLL2 15
#define CLKID_DDR 16
#define CLKID_DOS 17
#define CLKID_ISA 18
#define CLKID_PL301 19
#define CLKID_PERIPHS 20
#define CLKID_SPICC 21
#define CLKID_I2C 22
#define CLKID_SAR_ADC 23
#define CLKID_SMART_CARD 24
#define CLKID_RNG0 25
#define CLKID_UART0 26
#define CLKID_SDHC 27
#define CLKID_STREAM 28
#define CLKID_ASYNC_FIFO 29
#define CLKID_SDIO 30
#define CLKID_ABUF 31
#define CLKID_HIU_IFACE 32
#define CLKID_ASSIST_MISC 33
#define CLKID_SPI 34
#define CLKID_ETH 36
#define CLKID_I2S_SPDIF 35
#define CLKID_DEMUX 37
#define CLKID_AIU_GLUE 38
#define CLKID_IEC958 39
#define CLKID_I2S_OUT 40
#define CLKID_AMCLK 41
#define CLKID_AIFIFO2 42
#define CLKID_MIXER 43
#define CLKID_MIXER_IFACE 44
#define CLKID_ADC 45
#define CLKID_BLKMV 46
#define CLKID_AIU 47
#define CLKID_UART1 48
#define CLKID_G2D 49
#define CLKID_USB0 50
#define CLKID_USB1 51
#define CLKID_RESET 52
#define CLKID_NAND 53
#define CLKID_DOS_PARSER 54
#define CLKID_USB 55
#define CLKID_VDIN1 56
#define CLKID_AHB_ARB0 57
#define CLKID_EFUSE 58
#define CLKID_BOOT_ROM 59
#define CLKID_AHB_DATA_BUS 60
#define CLKID_AHB_CTRL_BUS 61
#define CLKID_HDMI_INTR_SYNC 62
#define CLKID_HDMI_PCLK 63
#define CLKID_USB1_DDR_BRIDGE 64
#define CLKID_USB0_DDR_BRIDGE 65
#define CLKID_MMC_PCLK 66
#define CLKID_DVIN 67
#define CLKID_UART2 68
#define CLKID_SANA 69
#define CLKID_VPU_INTR 70
#define CLKID_SEC_AHB_AHB3_BRIDGE 71
#define CLKID_CLK81_A53 72
#define CLKID_VCLK2_VENCI0 73
#define CLKID_VCLK2_VENCI1 74
#define CLKID_VCLK2_VENCP0 75
#define CLKID_VCLK2_VENCP1 76
#define CLKID_GCLK_VENCI_INT0 77
#define CLKID_GCLK_VENCI_INT 78
#define CLKID_DAC_CLK 79
#define CLKID_AOCLK_GATE 80
#define CLKID_IEC958_GATE 81
#define CLKID_ENC480P 82
#define CLKID_RNG1 83
#define CLKID_GCLK_VENCI_INT1 84
#define CLKID_VCLK2_VENCLMCC 85
#define CLKID_VCLK2_VENCL 86
#define CLKID_VCLK_OTHER 87
#define CLKID_EDP 88
#define CLKID_AO_MEDIA_CPU 89
#define CLKID_AO_AHB_SRAM 90
#define CLKID_AO_AHB_BUS 91
#define CLKID_AO_IFACE 92
#define CLKID_AO_I2C 93
#define CLKID_SD_EMMC_A 94
#define CLKID_SD_EMMC_B 95
@ -50,5 +109,9 @@
#define CLKID_CTS_AMCLK 107
#define CLKID_CTS_MCLK_I958 110
#define CLKID_CTS_I958 113
#define CLKID_32K_CLK 114
#define CLKID_SD_EMMC_A_CLK0 119
#define CLKID_SD_EMMC_B_CLK0 122
#define CLKID_SD_EMMC_C_CLK0 125
#endif /* __GXBB_CLKC_H */

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@ -21,15 +21,85 @@
#define CLKID_ZERO 13
#define CLKID_MPEG_SEL 14
#define CLKID_MPEG_DIV 15
#define CLKID_DDR 16
#define CLKID_DOS 17
#define CLKID_ISA 18
#define CLKID_PL301 19
#define CLKID_PERIPHS 20
#define CLKID_SPICC 21
#define CLKID_I2C 22
#define CLKID_SAR_ADC 23
#define CLKID_SMART_CARD 24
#define CLKID_RNG0 25
#define CLKID_UART0 26
#define CLKID_SDHC 27
#define CLKID_STREAM 28
#define CLKID_ASYNC_FIFO 29
#define CLKID_SDIO 30
#define CLKID_ABUF 31
#define CLKID_HIU_IFACE 32
#define CLKID_ASSIST_MISC 33
#define CLKID_SPI 34
#define CLKID_I2S_SPDIF 35
#define CLKID_ETH 36
#define CLKID_DEMUX 37
#define CLKID_AIU_GLUE 38
#define CLKID_IEC958 39
#define CLKID_I2S_OUT 40
#define CLKID_AMCLK 41
#define CLKID_AIFIFO2 42
#define CLKID_MIXER 43
#define CLKID_MIXER_IFACE 44
#define CLKID_ADC 45
#define CLKID_BLKMV 46
#define CLKID_AIU 47
#define CLKID_UART1 48
#define CLKID_G2D 49
#define CLKID_USB0 50
#define CLKID_USB1 51
#define CLKID_RESET 52
#define CLKID_NAND 53
#define CLKID_DOS_PARSER 54
#define CLKID_USB 55
#define CLKID_VDIN1 56
#define CLKID_AHB_ARB0 57
#define CLKID_EFUSE 58
#define CLKID_BOOT_ROM 59
#define CLKID_AHB_DATA_BUS 60
#define CLKID_AHB_CTRL_BUS 61
#define CLKID_HDMI_INTR_SYNC 62
#define CLKID_HDMI_PCLK 63
#define CLKID_USB1_DDR_BRIDGE 64
#define CLKID_USB0_DDR_BRIDGE 65
#define CLKID_MMC_PCLK 66
#define CLKID_DVIN 67
#define CLKID_UART2 68
#define CLKID_SANA 69
#define CLKID_VPU_INTR 70
#define CLKID_SEC_AHB_AHB3_BRIDGE 71
#define CLKID_CLK81_A9 72
#define CLKID_VCLK2_VENCI0 73
#define CLKID_VCLK2_VENCI1 74
#define CLKID_VCLK2_VENCP0 75
#define CLKID_VCLK2_VENCP1 76
#define CLKID_GCLK_VENCI_INT 77
#define CLKID_GCLK_VENCP_INT 78
#define CLKID_DAC_CLK 79
#define CLKID_AOCLK_GATE 80
#define CLKID_IEC958_GATE 81
#define CLKID_ENC480P 82
#define CLKID_RNG1 83
#define CLKID_GCLK_VENCL_INT 84
#define CLKID_VCLK2_VENCLMCC 85
#define CLKID_VCLK2_VENCL 86
#define CLKID_VCLK2_OTHER 87
#define CLKID_EDP 88
#define CLKID_AO_MEDIA_CPU 89
#define CLKID_AO_AHB_SRAM 90
#define CLKID_AO_AHB_BUS 91
#define CLKID_AO_IFACE 92
#define CLKID_MPLL0 93
#define CLKID_MPLL1 94
#define CLKID_MPLL2 95
#endif /* __MESON8B_CLKC_H */

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@ -0,0 +1,27 @@
/*
* Copyright (c) 2017 Martin Blumenstingl <martin.blumenstingl@googlemail.com>.
*
* SPDX-License-Identifier: (GPL-2.0+ OR MIT)
*/
#ifndef _DT_BINDINGS_AMLOGIC_MESON8B_CLKC_RESET_H
#define _DT_BINDINGS_AMLOGIC_MESON8B_CLKC_RESET_H
#define CLKC_RESET_L2_CACHE_SOFT_RESET 0
#define CLKC_RESET_AXI_64_TO_128_BRIDGE_A5_SOFT_RESET 1
#define CLKC_RESET_SCU_SOFT_RESET 2
#define CLKC_RESET_CPU0_SOFT_RESET 3
#define CLKC_RESET_CPU1_SOFT_RESET 4
#define CLKC_RESET_CPU2_SOFT_RESET 5
#define CLKC_RESET_CPU3_SOFT_RESET 6
#define CLKC_RESET_A5_GLOBAL_RESET 7
#define CLKC_RESET_A5_AXI_SOFT_RESET 8
#define CLKC_RESET_A5_ABP_SOFT_RESET 9
#define CLKC_RESET_AXI_64_TO_128_BRIDGE_MMC_SOFT_RESET 10
#define CLKC_RESET_VID_CLK_CNTL_SOFT_RESET 11
#define CLKC_RESET_VID_DIVIDER_CNTL_SOFT_RESET_POST 12
#define CLKC_RESET_VID_DIVIDER_CNTL_SOFT_RESET_PRE 13
#define CLKC_RESET_VID_DIVIDER_CNTL_RESET_N_POST 14
#define CLKC_RESET_VID_DIVIDER_CNTL_RESET_N_PRE 15
#endif /* _DT_BINDINGS_AMLOGIC_MESON8B_CLKC_RESET_H */