Merge branch 'clk-qcom-rpm' into clk-next

Qualcomm RPM Clock Controller Binding

------------------------------------------------

The RPM is a dedicated hardware engine for managing the shared

SoC resources in order to keep the lowest power profile. It

communicates with other hardware subsystems via shared memory

and accepts clock requests, aggregates the requests and turns

the clocks on/off or scales them on demand.

Required properties :

- compatible : shall contain only one of the following. The generic

               compatible "qcom,rpmcc" should be also included.

			"qcom,rpmcc-msm8916", "qcom,rpmcc"

			"qcom,rpmcc-apq8064", "qcom,rpmcc"

- #clock-cells : shall contain 1

Example:

	smd {

		compatible = "qcom,smd";

		rpm {

			interrupts = <0 168 1>;

			qcom,ipc = <&apcs 8 0>;

			qcom,smd-edge = <15>;

			rpm_requests {

				compatible = "qcom,rpm-msm8916";

				qcom,smd-channels = "rpm_requests";

				rpmcc: clock-controller {

					compatible = "qcom,rpmcc-msm8916", "qcom,rpmcc";

					#clock-cells = <1>;

				};

			};

		};

	};

	bool

	select PM_GENERIC_DOMAINS if PM

config QCOM_RPMCC

	bool

config COMMON_CLK_QCOM

	tristate "Support for Qualcomm's clock controllers"

	depends on OF

	select REGMAP_MMIO

	select RESET_CONTROLLER

config QCOM_CLK_RPM

	tristate "RPM based Clock Controller"

	depends on COMMON_CLK_QCOM && MFD_QCOM_RPM

	select QCOM_RPMCC

	help

	  The RPM (Resource Power Manager) is a dedicated hardware engine for

	  managing the shared SoC resources in order to keep the lowest power

	  profile. It communicates with other hardware subsystems via shared

	  memory and accepts clock requests, aggregates the requests and turns

	  the clocks on/off or scales them on demand.

	  Say Y if you want to support the clocks exposed by the RPM on

	  platforms such as apq8064, msm8660, msm8960 etc.

config QCOM_CLK_SMD_RPM

	tristate "RPM over SMD based Clock Controller"

	depends on COMMON_CLK_QCOM && QCOM_SMD_RPM

	select QCOM_RPMCC

	help

	  The RPM (Resource Power Manager) is a dedicated hardware engine for

	  managing the shared SoC resources in order to keep the lowest power

	  profile. It communicates with other hardware subsystems via shared

	  memory and accepts clock requests, aggregates the requests and turns

	  the clocks on/off or scales them on demand.

	  Say Y if you want to support the clocks exposed by the RPM on

	  platforms such as apq8016, apq8084, msm8974 etc.

config APQ_GCC_8084

	tristate "APQ8084 Global Clock Controller"

	select QCOM_GDSC

obj-$(CONFIG_MSM_MMCC_8960) += mmcc-msm8960.o

obj-$(CONFIG_MSM_MMCC_8974) += mmcc-msm8974.o

obj-$(CONFIG_MSM_MMCC_8996) += mmcc-msm8996.o

obj-$(CONFIG_QCOM_CLK_RPM) += clk-rpm.o

obj-$(CONFIG_QCOM_CLK_SMD_RPM) += clk-smd-rpm.o

/*

 * Copyright (c) 2016, Linaro Limited

 * Copyright (c) 2014, The Linux Foundation. All rights reserved.

 *

 * This software is licensed under the terms of the GNU General Public

 * License version 2, as published by the Free Software Foundation, and

 * may be copied, distributed, and modified under those terms.

 *

 * This program is distributed in the hope that it will be useful,

 * but WITHOUT ANY WARRANTY; without even the implied warranty of

 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the

 * GNU General Public License for more details.

 */

#include <linux/clk-provider.h>

#include <linux/err.h>

#include <linux/export.h>

#include <linux/init.h>

#include <linux/kernel.h>

#include <linux/module.h>

#include <linux/mutex.h>

#include <linux/mfd/qcom_rpm.h>

#include <linux/of.h>

#include <linux/of_device.h>

#include <linux/platform_device.h>

#include <dt-bindings/mfd/qcom-rpm.h>

#include <dt-bindings/clock/qcom,rpmcc.h>

#define QCOM_RPM_MISC_CLK_TYPE				0x306b6c63

#define QCOM_RPM_SCALING_ENABLE_ID			0x2

#define DEFINE_CLK_RPM(_platform, _name, _active, r_id)			      \

	static struct clk_rpm _platform##_##_active;			      \

	static struct clk_rpm _platform##_##_name = {			      \

		.rpm_clk_id = (r_id),					      \

		.peer = &_platform##_##_active,				      \

		.rate = INT_MAX,					      \

		.hw.init = &(struct clk_init_data){			      \

			.ops = &clk_rpm_ops,				      \

			.name = #_name,					      \

			.parent_names = (const char *[]){ "pxo_board" },      \

			.num_parents = 1,				      \

		},							      \

	};								      \

	static struct clk_rpm _platform##_##_active = {			      \

		.rpm_clk_id = (r_id),					      \

		.peer = &_platform##_##_name,				      \

		.active_only = true,					      \

		.rate = INT_MAX,					      \

		.hw.init = &(struct clk_init_data){			      \

			.ops = &clk_rpm_ops,				      \

			.name = #_active,				      \

			.parent_names = (const char *[]){ "pxo_board" },      \

			.num_parents = 1,				      \

		},							      \

	}

#define DEFINE_CLK_RPM_PXO_BRANCH(_platform, _name, _active, r_id, r)	      \

	static struct clk_rpm _platform##_##_active;			      \

	static struct clk_rpm _platform##_##_name = {			      \

		.rpm_clk_id = (r_id),					      \

		.active_only = true,					      \

		.peer = &_platform##_##_active,				      \

		.rate = (r),						      \

		.branch = true,						      \

		.hw.init = &(struct clk_init_data){			      \

			.ops = &clk_rpm_branch_ops,			      \

			.name = #_name,					      \

			.parent_names = (const char *[]){ "pxo_board" },      \

			.num_parents = 1,				      \

		},							      \

	};								      \

	static struct clk_rpm _platform##_##_active = {			      \

		.rpm_clk_id = (r_id),					      \

		.peer = &_platform##_##_name,				      \

		.rate = (r),						      \

		.branch = true,						      \

		.hw.init = &(struct clk_init_data){			      \

			.ops = &clk_rpm_branch_ops,			      \

			.name = #_active,				      \

			.parent_names = (const char *[]){ "pxo_board" },      \

			.num_parents = 1,				      \

		},							      \

	}

#define DEFINE_CLK_RPM_CXO_BRANCH(_platform, _name, _active, r_id, r)	      \

	static struct clk_rpm _platform##_##_active;			      \

	static struct clk_rpm _platform##_##_name = {			      \

		.rpm_clk_id = (r_id),					      \

		.peer = &_platform##_##_active,				      \

		.rate = (r),						      \

		.branch = true,						      \

		.hw.init = &(struct clk_init_data){			      \

			.ops = &clk_rpm_branch_ops,			      \

			.name = #_name,					      \

			.parent_names = (const char *[]){ "cxo_board" },      \

			.num_parents = 1,				      \

		},							      \

	};								      \

	static struct clk_rpm _platform##_##_active = {			      \

		.rpm_clk_id = (r_id),					      \

		.active_only = true,					      \

		.peer = &_platform##_##_name,				      \

		.rate = (r),						      \

		.branch = true,						      \

		.hw.init = &(struct clk_init_data){			      \

			.ops = &clk_rpm_branch_ops,			      \

			.name = #_active,				      \

			.parent_names = (const char *[]){ "cxo_board" },      \

			.num_parents = 1,				      \

		},							      \

	}

#define to_clk_rpm(_hw) container_of(_hw, struct clk_rpm, hw)

struct clk_rpm {

	const int rpm_clk_id;

	const bool active_only;

	unsigned long rate;

	bool enabled;

	bool branch;

	struct clk_rpm *peer;

	struct clk_hw hw;

	struct qcom_rpm *rpm;

};

struct rpm_cc {

	struct qcom_rpm *rpm;

	struct clk_hw_onecell_data data;

	struct clk_hw *hws[];

};

struct rpm_clk_desc {

	struct clk_rpm **clks;

	size_t num_clks;

};

static DEFINE_MUTEX(rpm_clk_lock);

static int clk_rpm_handoff(struct clk_rpm *r)

{

	int ret;

	u32 value = INT_MAX;

	ret = qcom_rpm_write(r->rpm, QCOM_RPM_ACTIVE_STATE,

			     r->rpm_clk_id, &value, 1);

	if (ret)

		return ret;

	ret = qcom_rpm_write(r->rpm, QCOM_RPM_SLEEP_STATE,

			     r->rpm_clk_id, &value, 1);

	if (ret)

		return ret;

	return 0;

}

static int clk_rpm_set_rate_active(struct clk_rpm *r, unsigned long rate)

{

	u32 value = DIV_ROUND_UP(rate, 1000); /* to kHz */

	return qcom_rpm_write(r->rpm, QCOM_RPM_ACTIVE_STATE,

			      r->rpm_clk_id, &value, 1);

}

static int clk_rpm_set_rate_sleep(struct clk_rpm *r, unsigned long rate)

{

	u32 value = DIV_ROUND_UP(rate, 1000); /* to kHz */

	return qcom_rpm_write(r->rpm, QCOM_RPM_SLEEP_STATE,

			      r->rpm_clk_id, &value, 1);

}

static void to_active_sleep(struct clk_rpm *r, unsigned long rate,

			    unsigned long *active, unsigned long *sleep)

{

	*active = rate;

	/*

	 * Active-only clocks don't care what the rate is during sleep. So,

	 * they vote for zero.

	 */

	if (r->active_only)

		*sleep = 0;

	else

		*sleep = *active;

}

static int clk_rpm_prepare(struct clk_hw *hw)

{

	struct clk_rpm *r = to_clk_rpm(hw);

	struct clk_rpm *peer = r->peer;

	unsigned long this_rate = 0, this_sleep_rate = 0;

	unsigned long peer_rate = 0, peer_sleep_rate = 0;

	unsigned long active_rate, sleep_rate;

	int ret = 0;

	mutex_lock(&rpm_clk_lock);

	/* Don't send requests to the RPM if the rate has not been set. */

	if (!r->rate)

		goto out;

	to_active_sleep(r, r->rate, &this_rate, &this_sleep_rate);

	/* Take peer clock's rate into account only if it's enabled. */

	if (peer->enabled)

		to_active_sleep(peer, peer->rate,

				&peer_rate, &peer_sleep_rate);

	active_rate = max(this_rate, peer_rate);

	if (r->branch)

		active_rate = !!active_rate;

	ret = clk_rpm_set_rate_active(r, active_rate);

	if (ret)

		goto out;

	sleep_rate = max(this_sleep_rate, peer_sleep_rate);

	if (r->branch)

		sleep_rate = !!sleep_rate;

	ret = clk_rpm_set_rate_sleep(r, sleep_rate);

	if (ret)

		/* Undo the active set vote and restore it */

		ret = clk_rpm_set_rate_active(r, peer_rate);

out:

	if (!ret)

		r->enabled = true;

	mutex_unlock(&rpm_clk_lock);

	return ret;

}

static void clk_rpm_unprepare(struct clk_hw *hw)

{

	struct clk_rpm *r = to_clk_rpm(hw);

	struct clk_rpm *peer = r->peer;

	unsigned long peer_rate = 0, peer_sleep_rate = 0;

	unsigned long active_rate, sleep_rate;

	int ret;

	mutex_lock(&rpm_clk_lock);

	if (!r->rate)

		goto out;

	/* Take peer clock's rate into account only if it's enabled. */

	if (peer->enabled)

		to_active_sleep(peer, peer->rate, &peer_rate,

				&peer_sleep_rate);

	active_rate = r->branch ? !!peer_rate : peer_rate;

	ret = clk_rpm_set_rate_active(r, active_rate);

	if (ret)

		goto out;

	sleep_rate = r->branch ? !!peer_sleep_rate : peer_sleep_rate;

	ret = clk_rpm_set_rate_sleep(r, sleep_rate);

	if (ret)

		goto out;

	r->enabled = false;

out:

	mutex_unlock(&rpm_clk_lock);

}

static int clk_rpm_set_rate(struct clk_hw *hw,

			    unsigned long rate, unsigned long parent_rate)

{

	struct clk_rpm *r = to_clk_rpm(hw);

	struct clk_rpm *peer = r->peer;

	unsigned long active_rate, sleep_rate;

	unsigned long this_rate = 0, this_sleep_rate = 0;

	unsigned long peer_rate = 0, peer_sleep_rate = 0;

	int ret = 0;

	mutex_lock(&rpm_clk_lock);

	if (!r->enabled)

		goto out;

	to_active_sleep(r, rate, &this_rate, &this_sleep_rate);

	/* Take peer clock's rate into account only if it's enabled. */

	if (peer->enabled)

		to_active_sleep(peer, peer->rate,

				&peer_rate, &peer_sleep_rate);

	active_rate = max(this_rate, peer_rate);

	ret = clk_rpm_set_rate_active(r, active_rate);

	if (ret)

		goto out;

	sleep_rate = max(this_sleep_rate, peer_sleep_rate);

	ret = clk_rpm_set_rate_sleep(r, sleep_rate);

	if (ret)

		goto out;

	r->rate = rate;

out:

	mutex_unlock(&rpm_clk_lock);

	return ret;

}

static long clk_rpm_round_rate(struct clk_hw *hw, unsigned long rate,

			       unsigned long *parent_rate)

{

	/*

	 * RPM handles rate rounding and we don't have a way to

	 * know what the rate will be, so just return whatever

	 * rate is requested.

	 */

	return rate;

}

static unsigned long clk_rpm_recalc_rate(struct clk_hw *hw,

					 unsigned long parent_rate)

{

	struct clk_rpm *r = to_clk_rpm(hw);

	/*

	 * RPM handles rate rounding and we don't have a way to

	 * know what the rate will be, so just return whatever

	 * rate was set.

	 */

	return r->rate;

}

static const struct clk_ops clk_rpm_ops = {

	.prepare	= clk_rpm_prepare,

	.unprepare	= clk_rpm_unprepare,

	.set_rate	= clk_rpm_set_rate,

	.round_rate	= clk_rpm_round_rate,

	.recalc_rate	= clk_rpm_recalc_rate,

};

static const struct clk_ops clk_rpm_branch_ops = {

	.prepare	= clk_rpm_prepare,

	.unprepare	= clk_rpm_unprepare,

	.round_rate	= clk_rpm_round_rate,

	.recalc_rate	= clk_rpm_recalc_rate,

};

/* apq8064 */

DEFINE_CLK_RPM(apq8064, afab_clk, afab_a_clk, QCOM_RPM_APPS_FABRIC_CLK);

DEFINE_CLK_RPM(apq8064, cfpb_clk, cfpb_a_clk, QCOM_RPM_CFPB_CLK);

DEFINE_CLK_RPM(apq8064, daytona_clk, daytona_a_clk, QCOM_RPM_DAYTONA_FABRIC_CLK);

DEFINE_CLK_RPM(apq8064, ebi1_clk, ebi1_a_clk, QCOM_RPM_EBI1_CLK);

DEFINE_CLK_RPM(apq8064, mmfab_clk, mmfab_a_clk, QCOM_RPM_MM_FABRIC_CLK);

DEFINE_CLK_RPM(apq8064, mmfpb_clk, mmfpb_a_clk, QCOM_RPM_MMFPB_CLK);

DEFINE_CLK_RPM(apq8064, sfab_clk, sfab_a_clk, QCOM_RPM_SYS_FABRIC_CLK);

DEFINE_CLK_RPM(apq8064, sfpb_clk, sfpb_a_clk, QCOM_RPM_SFPB_CLK);

DEFINE_CLK_RPM(apq8064, qdss_clk, qdss_a_clk, QCOM_RPM_QDSS_CLK);

static struct clk_rpm *apq8064_clks[] = {

	[RPM_APPS_FABRIC_CLK] = &apq8064_afab_clk,

	[RPM_APPS_FABRIC_A_CLK] = &apq8064_afab_a_clk,

	[RPM_CFPB_CLK] = &apq8064_cfpb_clk,

	[RPM_CFPB_A_CLK] = &apq8064_cfpb_a_clk,

	[RPM_DAYTONA_FABRIC_CLK] = &apq8064_daytona_clk,

	[RPM_DAYTONA_FABRIC_A_CLK] = &apq8064_daytona_a_clk,

	[RPM_EBI1_CLK] = &apq8064_ebi1_clk,

	[RPM_EBI1_A_CLK] = &apq8064_ebi1_a_clk,

	[RPM_MM_FABRIC_CLK] = &apq8064_mmfab_clk,

	[RPM_MM_FABRIC_A_CLK] = &apq8064_mmfab_a_clk,

	[RPM_MMFPB_CLK] = &apq8064_mmfpb_clk,

	[RPM_MMFPB_A_CLK] = &apq8064_mmfpb_a_clk,

	[RPM_SYS_FABRIC_CLK] = &apq8064_sfab_clk,

	[RPM_SYS_FABRIC_A_CLK] = &apq8064_sfab_a_clk,

	[RPM_SFPB_CLK] = &apq8064_sfpb_clk,

	[RPM_SFPB_A_CLK] = &apq8064_sfpb_a_clk,

	[RPM_QDSS_CLK] = &apq8064_qdss_clk,

	[RPM_QDSS_A_CLK] = &apq8064_qdss_a_clk,

};

static const struct rpm_clk_desc rpm_clk_apq8064 = {

	.clks = apq8064_clks,

	.num_clks = ARRAY_SIZE(apq8064_clks),

};

static const struct of_device_id rpm_clk_match_table[] = {

	{ .compatible = "qcom,rpmcc-apq8064", .data = &rpm_clk_apq8064 },

	{ }

};

MODULE_DEVICE_TABLE(of, rpm_clk_match_table);

static int rpm_clk_probe(struct platform_device *pdev)

{

	struct clk_hw **hws;

	struct rpm_cc *rcc;

	struct clk_hw_onecell_data *data;

	int ret;

	size_t num_clks, i;

	struct qcom_rpm *rpm;

	struct clk_rpm **rpm_clks;

	const struct rpm_clk_desc *desc;

	rpm = dev_get_drvdata(pdev->dev.parent);

	if (!rpm) {

		dev_err(&pdev->dev, "Unable to retrieve handle to RPM\n");

		return -ENODEV;

	}

	desc = of_device_get_match_data(&pdev->dev);

	if (!desc)

		return -EINVAL;

	rpm_clks = desc->clks;

	num_clks = desc->num_clks;

	rcc = devm_kzalloc(&pdev->dev, sizeof(*rcc) + sizeof(*hws) * num_clks,

			   GFP_KERNEL);

	if (!rcc)

		return -ENOMEM;

	hws = rcc->hws;

	data = &rcc->data;

	data->num = num_clks;

	for (i = 0; i < num_clks; i++) {

		if (!rpm_clks[i])

			continue;

		rpm_clks[i]->rpm = rpm;

		ret = clk_rpm_handoff(rpm_clks[i]);

		if (ret)

			goto err;

	}

	for (i = 0; i < num_clks; i++) {

		if (!rpm_clks[i]) {

			data->hws[i] = ERR_PTR(-ENOENT);

			continue;

		}

		ret = devm_clk_hw_register(&pdev->dev, &rpm_clks[i]->hw);

		if (ret)

			goto err;

	}

	ret = of_clk_add_hw_provider(pdev->dev.of_node, of_clk_hw_onecell_get,

				     data);

	if (ret)

		goto err;

	return 0;

err:

	dev_err(&pdev->dev, "Error registering RPM Clock driver (%d)\n", ret);

	return ret;

}

static int rpm_clk_remove(struct platform_device *pdev)

{

	of_clk_del_provider(pdev->dev.of_node);

	return 0;

}

static struct platform_driver rpm_clk_driver = {

	.driver = {

		.name = "qcom-clk-rpm",

		.of_match_table = rpm_clk_match_table,

	},

	.probe = rpm_clk_probe,

	.remove = rpm_clk_remove,

};

static int __init rpm_clk_init(void)

{

	return platform_driver_register(&rpm_clk_driver);

}

core_initcall(rpm_clk_init);

static void __exit rpm_clk_exit(void)

{

	platform_driver_unregister(&rpm_clk_driver);

}

module_exit(rpm_clk_exit);

MODULE_DESCRIPTION("Qualcomm RPM Clock Controller Driver");

MODULE_LICENSE("GPL v2");

MODULE_ALIAS("platform:qcom-clk-rpm");