OpenCloudOS-Kernel/drivers/clk/ux500/u8500_of_clk.c

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// SPDX-License-Identifier: GPL-2.0-only
/*
* Clock definitions for u8500 platform.
*
* Copyright (C) 2012 ST-Ericsson SA
* Author: Ulf Hansson <ulf.hansson@linaro.org>
*/
#include <linux/of.h>
#include <linux/of_address.h>
#include <linux/clk-provider.h>
#include <linux/mfd/dbx500-prcmu.h>
#include "clk.h"
#include "prcc.h"
#include "reset-prcc.h"
static struct clk *prcc_pclk[(PRCC_NUM_PERIPH_CLUSTERS + 1) * PRCC_PERIPHS_PER_CLUSTER];
static struct clk *prcc_kclk[(PRCC_NUM_PERIPH_CLUSTERS + 1) * PRCC_PERIPHS_PER_CLUSTER];
clk: ux500: Implement the missing CLKOUT clocks This implements the two missing CLKOUT clocks for the ux500 (well really U8500/DB8500) SoC. The clocks are initialized using a specific parent and divider and these are specified in the device tree, see the separate binding patch. The implementation is a bit different in that it will only create the clock in the clock framework if a user appears in the device tree, rather than it being registered upfront like most of the other clocks. This is because the clock needs parameters for source and divider from the consumer phandle for the clock to be set up properly when the clock is registered. There could be more than one user of a CLKOUT clock, but we have not seen this in practice. If this happens the framework prints and info and returns the previously registered clock. Using the clocks requires also muxing the CLKOUT1 or CLKOUT2 to the appropriate pad. In practice this is achived in a pinctrl handle in the DTS node for the device using the CLKOUT clock, so this muxing is done separately from the clock itself. Example: haptic@49 { compatible = "immersion,isa1200"; reg = <0x49>; (...) /* clkout1 from ACLK divided by 8 */ clocks = <&clkout_clk DB8500_CLKOUT_1 DB8500_CLKOUT_SRC_ACLK 8>; pinctrl-names = "default"; pinctrl-0 = <&isa1200_janice_default>; }; isa1200_janice_default: isa1200_janice { /* Bring out clkout1 on pin GPIO227 pin AH7 */ janice_mux { function = "clkout"; groups = "clkout1_a_1"; }; janice_cfg1 { pins = "GPIO227_AH7"; ste,config = <&out_lo>; }; (...) This was tested successfully with the Immersion ISA1200 haptic feedback unit on the Samsung Galaxy S Advance GT-I9070 (Janice) mobile phone. As the CLKOUT clocks need some undefined fixed rate parent clocks that are currently missing from the PRCMU clock implementation, the three simplest are added in this patch: clk38m_to_clkgen, aclk and sysclk. The only parent not yet available in the implementation is clk009, which is a kind of special muxed and divided clock which isn't even implemented in the vendor clock driver. Reviewed-by: Ulf Hansson <ulf.hansson@linaro.org> Signed-off-by: Linus Walleij <linus.walleij@linaro.org> Link: https://lore.kernel.org/r/20220414221751.323525-6-linus.walleij@linaro.org Signed-off-by: Stephen Boyd <sboyd@kernel.org>
2022-04-15 06:17:51 +08:00
static struct clk_hw *clkout_clk[2];
#define PRCC_SHOW(clk, base, bit) \
clk[(base * PRCC_PERIPHS_PER_CLUSTER) + bit]
#define PRCC_PCLK_STORE(clk, base, bit) \
prcc_pclk[(base * PRCC_PERIPHS_PER_CLUSTER) + bit] = clk
#define PRCC_KCLK_STORE(clk, base, bit) \
prcc_kclk[(base * PRCC_PERIPHS_PER_CLUSTER) + bit] = clk
static struct clk *ux500_twocell_get(struct of_phandle_args *clkspec,
void *data)
{
struct clk **clk_data = data;
unsigned int base, bit;
if (clkspec->args_count != 2)
return ERR_PTR(-EINVAL);
base = clkspec->args[0];
bit = clkspec->args[1];
if (base != 1 && base != 2 && base != 3 && base != 5 && base != 6) {
pr_err("%s: invalid PRCC base %d\n", __func__, base);
return ERR_PTR(-EINVAL);
}
return PRCC_SHOW(clk_data, base, bit);
}
static struct clk_hw_onecell_data u8500_prcmu_hw_clks = {
.hws = {
/*
* This assignment makes sure the dynamic array
* gets the right size.
*/
[PRCMU_NUM_CLKS] = NULL,
},
.num = PRCMU_NUM_CLKS,
};
clk: ux500: Implement the missing CLKOUT clocks This implements the two missing CLKOUT clocks for the ux500 (well really U8500/DB8500) SoC. The clocks are initialized using a specific parent and divider and these are specified in the device tree, see the separate binding patch. The implementation is a bit different in that it will only create the clock in the clock framework if a user appears in the device tree, rather than it being registered upfront like most of the other clocks. This is because the clock needs parameters for source and divider from the consumer phandle for the clock to be set up properly when the clock is registered. There could be more than one user of a CLKOUT clock, but we have not seen this in practice. If this happens the framework prints and info and returns the previously registered clock. Using the clocks requires also muxing the CLKOUT1 or CLKOUT2 to the appropriate pad. In practice this is achived in a pinctrl handle in the DTS node for the device using the CLKOUT clock, so this muxing is done separately from the clock itself. Example: haptic@49 { compatible = "immersion,isa1200"; reg = <0x49>; (...) /* clkout1 from ACLK divided by 8 */ clocks = <&clkout_clk DB8500_CLKOUT_1 DB8500_CLKOUT_SRC_ACLK 8>; pinctrl-names = "default"; pinctrl-0 = <&isa1200_janice_default>; }; isa1200_janice_default: isa1200_janice { /* Bring out clkout1 on pin GPIO227 pin AH7 */ janice_mux { function = "clkout"; groups = "clkout1_a_1"; }; janice_cfg1 { pins = "GPIO227_AH7"; ste,config = <&out_lo>; }; (...) This was tested successfully with the Immersion ISA1200 haptic feedback unit on the Samsung Galaxy S Advance GT-I9070 (Janice) mobile phone. As the CLKOUT clocks need some undefined fixed rate parent clocks that are currently missing from the PRCMU clock implementation, the three simplest are added in this patch: clk38m_to_clkgen, aclk and sysclk. The only parent not yet available in the implementation is clk009, which is a kind of special muxed and divided clock which isn't even implemented in the vendor clock driver. Reviewed-by: Ulf Hansson <ulf.hansson@linaro.org> Signed-off-by: Linus Walleij <linus.walleij@linaro.org> Link: https://lore.kernel.org/r/20220414221751.323525-6-linus.walleij@linaro.org Signed-off-by: Stephen Boyd <sboyd@kernel.org>
2022-04-15 06:17:51 +08:00
/* Essentially names for the first PRCMU_CLKSRC_* defines */
static const char * const u8500_clkout_parents[] = {
"clk38m_to_clkgen",
"aclk",
/* Just called "sysclk" in documentation */
"ab8500_sysclk",
"lcdclk",
"sdmmcclk",
"tvclk",
"timclk",
/* CLK009 is not implemented, add it if you need it */
"clk009",
};
static struct clk_hw *ux500_clkout_get(struct of_phandle_args *clkspec,
void *data)
{
u32 id, source, divider;
struct clk_hw *clkout;
if (clkspec->args_count != 3)
return ERR_PTR(-EINVAL);
id = clkspec->args[0];
source = clkspec->args[1];
divider = clkspec->args[2];
if (id > 1) {
pr_err("%s: invalid clkout ID %d\n", __func__, id);
return ERR_PTR(-EINVAL);
}
if (clkout_clk[id]) {
pr_info("%s: clkout%d already registered, not reconfiguring\n",
__func__, id + 1);
return clkout_clk[id];
}
if (source > 7) {
pr_err("%s: invalid source ID %d\n", __func__, source);
return ERR_PTR(-EINVAL);
}
if (divider == 0 || divider > 63) {
pr_err("%s: invalid divider %d\n", __func__, divider);
return ERR_PTR(-EINVAL);
}
pr_debug("registering clkout%d with source %d and divider %d\n",
id + 1, source, divider);
clkout = clk_reg_prcmu_clkout(id ? "clkout2" : "clkout1",
u8500_clkout_parents,
ARRAY_SIZE(u8500_clkout_parents),
source, divider);
if (IS_ERR(clkout)) {
pr_err("failed to register clkout%d\n", id + 1);
return ERR_CAST(clkout);
}
clkout_clk[id] = clkout;
return clkout;
}
static void u8500_clk_init(struct device_node *np)
{
struct prcmu_fw_version *fw_version;
struct device_node *child = NULL;
const char *sgaclk_parent = NULL;
struct clk *clk, *rtc_clk, *twd_clk;
u32 bases[CLKRST_MAX];
struct u8500_prcc_reset *rstc;
int i;
/*
* We allocate the reset controller here so that we can fill in the
* base addresses properly and pass to the reset controller init
* function later on.
*/
rstc = kzalloc(sizeof(*rstc), GFP_KERNEL);
if (!rstc)
return;
for (i = 0; i < ARRAY_SIZE(bases); i++) {
struct resource r;
if (of_address_to_resource(np, i, &r))
/* Not much choice but to continue */
pr_err("failed to get CLKRST %d base address\n",
i + 1);
bases[i] = r.start;
rstc->phy_base[i] = r.start;
}
/* Clock sources */
u8500_prcmu_hw_clks.hws[PRCMU_PLLSOC0] =
clk_reg_prcmu_gate("soc0_pll", NULL, PRCMU_PLLSOC0,
CLK_IGNORE_UNUSED);
u8500_prcmu_hw_clks.hws[PRCMU_PLLSOC1] =
clk_reg_prcmu_gate("soc1_pll", NULL, PRCMU_PLLSOC1,
CLK_IGNORE_UNUSED);
u8500_prcmu_hw_clks.hws[PRCMU_PLLDDR] =
clk_reg_prcmu_gate("ddr_pll", NULL, PRCMU_PLLDDR,
CLK_IGNORE_UNUSED);
clk: ux500: Implement the missing CLKOUT clocks This implements the two missing CLKOUT clocks for the ux500 (well really U8500/DB8500) SoC. The clocks are initialized using a specific parent and divider and these are specified in the device tree, see the separate binding patch. The implementation is a bit different in that it will only create the clock in the clock framework if a user appears in the device tree, rather than it being registered upfront like most of the other clocks. This is because the clock needs parameters for source and divider from the consumer phandle for the clock to be set up properly when the clock is registered. There could be more than one user of a CLKOUT clock, but we have not seen this in practice. If this happens the framework prints and info and returns the previously registered clock. Using the clocks requires also muxing the CLKOUT1 or CLKOUT2 to the appropriate pad. In practice this is achived in a pinctrl handle in the DTS node for the device using the CLKOUT clock, so this muxing is done separately from the clock itself. Example: haptic@49 { compatible = "immersion,isa1200"; reg = <0x49>; (...) /* clkout1 from ACLK divided by 8 */ clocks = <&clkout_clk DB8500_CLKOUT_1 DB8500_CLKOUT_SRC_ACLK 8>; pinctrl-names = "default"; pinctrl-0 = <&isa1200_janice_default>; }; isa1200_janice_default: isa1200_janice { /* Bring out clkout1 on pin GPIO227 pin AH7 */ janice_mux { function = "clkout"; groups = "clkout1_a_1"; }; janice_cfg1 { pins = "GPIO227_AH7"; ste,config = <&out_lo>; }; (...) This was tested successfully with the Immersion ISA1200 haptic feedback unit on the Samsung Galaxy S Advance GT-I9070 (Janice) mobile phone. As the CLKOUT clocks need some undefined fixed rate parent clocks that are currently missing from the PRCMU clock implementation, the three simplest are added in this patch: clk38m_to_clkgen, aclk and sysclk. The only parent not yet available in the implementation is clk009, which is a kind of special muxed and divided clock which isn't even implemented in the vendor clock driver. Reviewed-by: Ulf Hansson <ulf.hansson@linaro.org> Signed-off-by: Linus Walleij <linus.walleij@linaro.org> Link: https://lore.kernel.org/r/20220414221751.323525-6-linus.walleij@linaro.org Signed-off-by: Stephen Boyd <sboyd@kernel.org>
2022-04-15 06:17:51 +08:00
/*
* Read-only clocks that only return their current rate, only used
* as parents to other clocks and not visible in the device tree.
* clk38m_to_clkgen is the same as the SYSCLK, i.e. the root clock.
*/
clk_reg_prcmu_rate("clk38m_to_clkgen", NULL, PRCMU_SYSCLK,
CLK_IGNORE_UNUSED);
clk_reg_prcmu_rate("aclk", NULL, PRCMU_ACLK,
CLK_IGNORE_UNUSED);
/* TODO: add CLK009 if needed */
rtc_clk = clk_register_fixed_rate(NULL, "rtc32k", "NULL",
CLK_IGNORE_UNUSED,
32768);
/* PRCMU clocks */
fw_version = prcmu_get_fw_version();
if (fw_version != NULL) {
switch (fw_version->project) {
case PRCMU_FW_PROJECT_U8500_C2:
case PRCMU_FW_PROJECT_U8500_SSG1:
case PRCMU_FW_PROJECT_U8520:
case PRCMU_FW_PROJECT_U8420:
case PRCMU_FW_PROJECT_U8420_SYSCLK:
case PRCMU_FW_PROJECT_U8500_SSG2:
sgaclk_parent = "soc0_pll";
break;
default:
break;
}
}
if (sgaclk_parent)
u8500_prcmu_hw_clks.hws[PRCMU_SGACLK] =
clk_reg_prcmu_gate("sgclk", sgaclk_parent,
PRCMU_SGACLK, 0);
else
u8500_prcmu_hw_clks.hws[PRCMU_SGACLK] =
clk_reg_prcmu_gate("sgclk", NULL, PRCMU_SGACLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_UARTCLK] =
clk_reg_prcmu_gate("uartclk", NULL, PRCMU_UARTCLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_MSP02CLK] =
clk_reg_prcmu_gate("msp02clk", NULL, PRCMU_MSP02CLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_MSP1CLK] =
clk_reg_prcmu_gate("msp1clk", NULL, PRCMU_MSP1CLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_I2CCLK] =
clk_reg_prcmu_gate("i2cclk", NULL, PRCMU_I2CCLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_SLIMCLK] =
clk_reg_prcmu_gate("slimclk", NULL, PRCMU_SLIMCLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_PER1CLK] =
clk_reg_prcmu_gate("per1clk", NULL, PRCMU_PER1CLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_PER2CLK] =
clk_reg_prcmu_gate("per2clk", NULL, PRCMU_PER2CLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_PER3CLK] =
clk_reg_prcmu_gate("per3clk", NULL, PRCMU_PER3CLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_PER5CLK] =
clk_reg_prcmu_gate("per5clk", NULL, PRCMU_PER5CLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_PER6CLK] =
clk_reg_prcmu_gate("per6clk", NULL, PRCMU_PER6CLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_PER7CLK] =
clk_reg_prcmu_gate("per7clk", NULL, PRCMU_PER7CLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_LCDCLK] =
clk_reg_prcmu_scalable("lcdclk", NULL, PRCMU_LCDCLK, 0,
CLK_SET_RATE_GATE);
u8500_prcmu_hw_clks.hws[PRCMU_BMLCLK] =
clk_reg_prcmu_opp_gate("bmlclk", NULL, PRCMU_BMLCLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_HSITXCLK] =
clk_reg_prcmu_scalable("hsitxclk", NULL, PRCMU_HSITXCLK, 0,
CLK_SET_RATE_GATE);
u8500_prcmu_hw_clks.hws[PRCMU_HSIRXCLK] =
clk_reg_prcmu_scalable("hsirxclk", NULL, PRCMU_HSIRXCLK, 0,
CLK_SET_RATE_GATE);
u8500_prcmu_hw_clks.hws[PRCMU_HDMICLK] =
clk_reg_prcmu_scalable("hdmiclk", NULL, PRCMU_HDMICLK, 0,
CLK_SET_RATE_GATE);
u8500_prcmu_hw_clks.hws[PRCMU_APEATCLK] =
clk_reg_prcmu_gate("apeatclk", NULL, PRCMU_APEATCLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_APETRACECLK] =
clk_reg_prcmu_scalable("apetraceclk", NULL, PRCMU_APETRACECLK, 0,
CLK_SET_RATE_GATE);
u8500_prcmu_hw_clks.hws[PRCMU_MCDECLK] =
clk_reg_prcmu_gate("mcdeclk", NULL, PRCMU_MCDECLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_IPI2CCLK] =
clk_reg_prcmu_opp_gate("ipi2cclk", NULL, PRCMU_IPI2CCLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_DSIALTCLK] =
clk_reg_prcmu_gate("dsialtclk", NULL, PRCMU_DSIALTCLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_DMACLK] =
clk_reg_prcmu_gate("dmaclk", NULL, PRCMU_DMACLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_B2R2CLK] =
clk_reg_prcmu_gate("b2r2clk", NULL, PRCMU_B2R2CLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_TVCLK] =
clk_reg_prcmu_scalable("tvclk", NULL, PRCMU_TVCLK, 0,
CLK_SET_RATE_GATE);
u8500_prcmu_hw_clks.hws[PRCMU_SSPCLK] =
clk_reg_prcmu_gate("sspclk", NULL, PRCMU_SSPCLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_RNGCLK] =
clk_reg_prcmu_gate("rngclk", NULL, PRCMU_RNGCLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_UICCCLK] =
clk_reg_prcmu_gate("uiccclk", NULL, PRCMU_UICCCLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_TIMCLK] =
clk_reg_prcmu_gate("timclk", NULL, PRCMU_TIMCLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_SYSCLK] =
clk_reg_prcmu_gate("ab8500_sysclk", NULL, PRCMU_SYSCLK, 0);
u8500_prcmu_hw_clks.hws[PRCMU_SDMMCCLK] =
clk_reg_prcmu_opp_volt_scalable("sdmmcclk", NULL,
PRCMU_SDMMCCLK, 100000000,
CLK_SET_RATE_GATE);
u8500_prcmu_hw_clks.hws[PRCMU_PLLDSI] =
clk_reg_prcmu_scalable("dsi_pll", "hdmiclk",
PRCMU_PLLDSI, 0, CLK_SET_RATE_GATE);
u8500_prcmu_hw_clks.hws[PRCMU_DSI0CLK] =
clk_reg_prcmu_scalable("dsi0clk", "dsi_pll",
PRCMU_DSI0CLK, 0, CLK_SET_RATE_GATE);
u8500_prcmu_hw_clks.hws[PRCMU_DSI1CLK] =
clk_reg_prcmu_scalable("dsi1clk", "dsi_pll",
PRCMU_DSI1CLK, 0, CLK_SET_RATE_GATE);
u8500_prcmu_hw_clks.hws[PRCMU_DSI0ESCCLK] =
clk_reg_prcmu_scalable("dsi0escclk", "tvclk",
PRCMU_DSI0ESCCLK, 0, CLK_SET_RATE_GATE);
u8500_prcmu_hw_clks.hws[PRCMU_DSI1ESCCLK] =
clk_reg_prcmu_scalable("dsi1escclk", "tvclk",
PRCMU_DSI1ESCCLK, 0, CLK_SET_RATE_GATE);
u8500_prcmu_hw_clks.hws[PRCMU_DSI2ESCCLK] =
clk_reg_prcmu_scalable("dsi2escclk", "tvclk",
PRCMU_DSI2ESCCLK, 0, CLK_SET_RATE_GATE);
u8500_prcmu_hw_clks.hws[PRCMU_ARMSS] =
clk_reg_prcmu_scalable_rate("armss", NULL,
PRCMU_ARMSS, 0, CLK_IGNORE_UNUSED);
twd_clk = clk_register_fixed_factor(NULL, "smp_twd", "armss",
CLK_IGNORE_UNUSED, 1, 2);
/* PRCC P-clocks */
clk = clk_reg_prcc_pclk("p1_pclk0", "per1clk", bases[CLKRST1_INDEX],
BIT(0), 0);
PRCC_PCLK_STORE(clk, 1, 0);
clk = clk_reg_prcc_pclk("p1_pclk1", "per1clk", bases[CLKRST1_INDEX],
BIT(1), 0);
PRCC_PCLK_STORE(clk, 1, 1);
clk = clk_reg_prcc_pclk("p1_pclk2", "per1clk", bases[CLKRST1_INDEX],
BIT(2), 0);
PRCC_PCLK_STORE(clk, 1, 2);
clk = clk_reg_prcc_pclk("p1_pclk3", "per1clk", bases[CLKRST1_INDEX],
BIT(3), 0);
PRCC_PCLK_STORE(clk, 1, 3);
clk = clk_reg_prcc_pclk("p1_pclk4", "per1clk", bases[CLKRST1_INDEX],
BIT(4), 0);
PRCC_PCLK_STORE(clk, 1, 4);
clk = clk_reg_prcc_pclk("p1_pclk5", "per1clk", bases[CLKRST1_INDEX],
BIT(5), 0);
PRCC_PCLK_STORE(clk, 1, 5);
clk = clk_reg_prcc_pclk("p1_pclk6", "per1clk", bases[CLKRST1_INDEX],
BIT(6), 0);
PRCC_PCLK_STORE(clk, 1, 6);
clk = clk_reg_prcc_pclk("p1_pclk7", "per1clk", bases[CLKRST1_INDEX],
BIT(7), 0);
PRCC_PCLK_STORE(clk, 1, 7);
clk = clk_reg_prcc_pclk("p1_pclk8", "per1clk", bases[CLKRST1_INDEX],
BIT(8), 0);
PRCC_PCLK_STORE(clk, 1, 8);
clk = clk_reg_prcc_pclk("p1_pclk9", "per1clk", bases[CLKRST1_INDEX],
BIT(9), 0);
PRCC_PCLK_STORE(clk, 1, 9);
clk = clk_reg_prcc_pclk("p1_pclk10", "per1clk", bases[CLKRST1_INDEX],
BIT(10), 0);
PRCC_PCLK_STORE(clk, 1, 10);
clk = clk_reg_prcc_pclk("p1_pclk11", "per1clk", bases[CLKRST1_INDEX],
BIT(11), 0);
PRCC_PCLK_STORE(clk, 1, 11);
clk = clk_reg_prcc_pclk("p2_pclk0", "per2clk", bases[CLKRST2_INDEX],
BIT(0), 0);
PRCC_PCLK_STORE(clk, 2, 0);
clk = clk_reg_prcc_pclk("p2_pclk1", "per2clk", bases[CLKRST2_INDEX],
BIT(1), 0);
PRCC_PCLK_STORE(clk, 2, 1);
clk = clk_reg_prcc_pclk("p2_pclk2", "per2clk", bases[CLKRST2_INDEX],
BIT(2), 0);
PRCC_PCLK_STORE(clk, 2, 2);
clk = clk_reg_prcc_pclk("p2_pclk3", "per2clk", bases[CLKRST2_INDEX],
BIT(3), 0);
PRCC_PCLK_STORE(clk, 2, 3);
clk = clk_reg_prcc_pclk("p2_pclk4", "per2clk", bases[CLKRST2_INDEX],
BIT(4), 0);
PRCC_PCLK_STORE(clk, 2, 4);
clk = clk_reg_prcc_pclk("p2_pclk5", "per2clk", bases[CLKRST2_INDEX],
BIT(5), 0);
PRCC_PCLK_STORE(clk, 2, 5);
clk = clk_reg_prcc_pclk("p2_pclk6", "per2clk", bases[CLKRST2_INDEX],
BIT(6), 0);
PRCC_PCLK_STORE(clk, 2, 6);
clk = clk_reg_prcc_pclk("p2_pclk7", "per2clk", bases[CLKRST2_INDEX],
BIT(7), 0);
PRCC_PCLK_STORE(clk, 2, 7);
clk = clk_reg_prcc_pclk("p2_pclk8", "per2clk", bases[CLKRST2_INDEX],
BIT(8), 0);
PRCC_PCLK_STORE(clk, 2, 8);
clk = clk_reg_prcc_pclk("p2_pclk9", "per2clk", bases[CLKRST2_INDEX],
BIT(9), 0);
PRCC_PCLK_STORE(clk, 2, 9);
clk = clk_reg_prcc_pclk("p2_pclk10", "per2clk", bases[CLKRST2_INDEX],
BIT(10), 0);
PRCC_PCLK_STORE(clk, 2, 10);
clk = clk_reg_prcc_pclk("p2_pclk11", "per2clk", bases[CLKRST2_INDEX],
BIT(11), 0);
PRCC_PCLK_STORE(clk, 2, 11);
clk = clk_reg_prcc_pclk("p2_pclk12", "per2clk", bases[CLKRST2_INDEX],
BIT(12), 0);
PRCC_PCLK_STORE(clk, 2, 12);
clk = clk_reg_prcc_pclk("p3_pclk0", "per3clk", bases[CLKRST3_INDEX],
BIT(0), 0);
PRCC_PCLK_STORE(clk, 3, 0);
clk = clk_reg_prcc_pclk("p3_pclk1", "per3clk", bases[CLKRST3_INDEX],
BIT(1), 0);
PRCC_PCLK_STORE(clk, 3, 1);
clk = clk_reg_prcc_pclk("p3_pclk2", "per3clk", bases[CLKRST3_INDEX],
BIT(2), 0);
PRCC_PCLK_STORE(clk, 3, 2);
clk = clk_reg_prcc_pclk("p3_pclk3", "per3clk", bases[CLKRST3_INDEX],
BIT(3), 0);
PRCC_PCLK_STORE(clk, 3, 3);
clk = clk_reg_prcc_pclk("p3_pclk4", "per3clk", bases[CLKRST3_INDEX],
BIT(4), 0);
PRCC_PCLK_STORE(clk, 3, 4);
clk = clk_reg_prcc_pclk("p3_pclk5", "per3clk", bases[CLKRST3_INDEX],
BIT(5), 0);
PRCC_PCLK_STORE(clk, 3, 5);
clk = clk_reg_prcc_pclk("p3_pclk6", "per3clk", bases[CLKRST3_INDEX],
BIT(6), 0);
PRCC_PCLK_STORE(clk, 3, 6);
clk = clk_reg_prcc_pclk("p3_pclk7", "per3clk", bases[CLKRST3_INDEX],
BIT(7), 0);
PRCC_PCLK_STORE(clk, 3, 7);
clk = clk_reg_prcc_pclk("p3_pclk8", "per3clk", bases[CLKRST3_INDEX],
BIT(8), 0);
PRCC_PCLK_STORE(clk, 3, 8);
clk = clk_reg_prcc_pclk("p5_pclk0", "per5clk", bases[CLKRST5_INDEX],
BIT(0), 0);
PRCC_PCLK_STORE(clk, 5, 0);
clk = clk_reg_prcc_pclk("p5_pclk1", "per5clk", bases[CLKRST5_INDEX],
BIT(1), 0);
PRCC_PCLK_STORE(clk, 5, 1);
clk = clk_reg_prcc_pclk("p6_pclk0", "per6clk", bases[CLKRST6_INDEX],
BIT(0), 0);
PRCC_PCLK_STORE(clk, 6, 0);
clk = clk_reg_prcc_pclk("p6_pclk1", "per6clk", bases[CLKRST6_INDEX],
BIT(1), 0);
PRCC_PCLK_STORE(clk, 6, 1);
clk = clk_reg_prcc_pclk("p6_pclk2", "per6clk", bases[CLKRST6_INDEX],
BIT(2), 0);
PRCC_PCLK_STORE(clk, 6, 2);
clk = clk_reg_prcc_pclk("p6_pclk3", "per6clk", bases[CLKRST6_INDEX],
BIT(3), 0);
PRCC_PCLK_STORE(clk, 6, 3);
clk = clk_reg_prcc_pclk("p6_pclk4", "per6clk", bases[CLKRST6_INDEX],
BIT(4), 0);
PRCC_PCLK_STORE(clk, 6, 4);
clk = clk_reg_prcc_pclk("p6_pclk5", "per6clk", bases[CLKRST6_INDEX],
BIT(5), 0);
PRCC_PCLK_STORE(clk, 6, 5);
clk = clk_reg_prcc_pclk("p6_pclk6", "per6clk", bases[CLKRST6_INDEX],
BIT(6), 0);
PRCC_PCLK_STORE(clk, 6, 6);
clk = clk_reg_prcc_pclk("p6_pclk7", "per6clk", bases[CLKRST6_INDEX],
BIT(7), 0);
PRCC_PCLK_STORE(clk, 6, 7);
/* PRCC K-clocks
*
* FIXME: Some drivers requires PERPIH[n| to be automatically enabled
* by enabling just the K-clock, even if it is not a valid parent to
* the K-clock. Until drivers get fixed we might need some kind of
* "parent muxed join".
*/
/* Periph1 */
clk = clk_reg_prcc_kclk("p1_uart0_kclk", "uartclk",
bases[CLKRST1_INDEX], BIT(0), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 1, 0);
clk = clk_reg_prcc_kclk("p1_uart1_kclk", "uartclk",
bases[CLKRST1_INDEX], BIT(1), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 1, 1);
clk = clk_reg_prcc_kclk("p1_i2c1_kclk", "i2cclk",
bases[CLKRST1_INDEX], BIT(2), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 1, 2);
clk = clk_reg_prcc_kclk("p1_msp0_kclk", "msp02clk",
bases[CLKRST1_INDEX], BIT(3), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 1, 3);
clk = clk_reg_prcc_kclk("p1_msp1_kclk", "msp1clk",
bases[CLKRST1_INDEX], BIT(4), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 1, 4);
clk = clk_reg_prcc_kclk("p1_sdi0_kclk", "sdmmcclk",
bases[CLKRST1_INDEX], BIT(5), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 1, 5);
clk = clk_reg_prcc_kclk("p1_i2c2_kclk", "i2cclk",
bases[CLKRST1_INDEX], BIT(6), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 1, 6);
clk = clk_reg_prcc_kclk("p1_slimbus0_kclk", "slimclk",
bases[CLKRST1_INDEX], BIT(8), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 1, 8);
clk = clk_reg_prcc_kclk("p1_i2c4_kclk", "i2cclk",
bases[CLKRST1_INDEX], BIT(9), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 1, 9);
clk = clk_reg_prcc_kclk("p1_msp3_kclk", "msp1clk",
bases[CLKRST1_INDEX], BIT(10), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 1, 10);
/* Periph2 */
clk = clk_reg_prcc_kclk("p2_i2c3_kclk", "i2cclk",
bases[CLKRST2_INDEX], BIT(0), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 2, 0);
clk = clk_reg_prcc_kclk("p2_sdi4_kclk", "sdmmcclk",
bases[CLKRST2_INDEX], BIT(2), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 2, 2);
clk = clk_reg_prcc_kclk("p2_msp2_kclk", "msp02clk",
bases[CLKRST2_INDEX], BIT(3), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 2, 3);
clk = clk_reg_prcc_kclk("p2_sdi1_kclk", "sdmmcclk",
bases[CLKRST2_INDEX], BIT(4), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 2, 4);
clk = clk_reg_prcc_kclk("p2_sdi3_kclk", "sdmmcclk",
bases[CLKRST2_INDEX], BIT(5), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 2, 5);
/* Note that rate is received from parent. */
clk = clk_reg_prcc_kclk("p2_ssirx_kclk", "hsirxclk",
bases[CLKRST2_INDEX], BIT(6),
CLK_SET_RATE_GATE|CLK_SET_RATE_PARENT);
PRCC_KCLK_STORE(clk, 2, 6);
clk = clk_reg_prcc_kclk("p2_ssitx_kclk", "hsitxclk",
bases[CLKRST2_INDEX], BIT(7),
CLK_SET_RATE_GATE|CLK_SET_RATE_PARENT);
PRCC_KCLK_STORE(clk, 2, 7);
/* Periph3 */
clk = clk_reg_prcc_kclk("p3_ssp0_kclk", "sspclk",
bases[CLKRST3_INDEX], BIT(1), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 3, 1);
clk = clk_reg_prcc_kclk("p3_ssp1_kclk", "sspclk",
bases[CLKRST3_INDEX], BIT(2), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 3, 2);
clk = clk_reg_prcc_kclk("p3_i2c0_kclk", "i2cclk",
bases[CLKRST3_INDEX], BIT(3), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 3, 3);
clk = clk_reg_prcc_kclk("p3_sdi2_kclk", "sdmmcclk",
bases[CLKRST3_INDEX], BIT(4), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 3, 4);
clk = clk_reg_prcc_kclk("p3_ske_kclk", "rtc32k",
bases[CLKRST3_INDEX], BIT(5), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 3, 5);
clk = clk_reg_prcc_kclk("p3_uart2_kclk", "uartclk",
bases[CLKRST3_INDEX], BIT(6), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 3, 6);
clk = clk_reg_prcc_kclk("p3_sdi5_kclk", "sdmmcclk",
bases[CLKRST3_INDEX], BIT(7), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 3, 7);
/* Periph6 */
clk = clk_reg_prcc_kclk("p3_rng_kclk", "rngclk",
bases[CLKRST6_INDEX], BIT(0), CLK_SET_RATE_GATE);
PRCC_KCLK_STORE(clk, 6, 0);
for_each_child_of_node(np, child) {
if (of_node_name_eq(child, "prcmu-clock"))
of_clk_add_hw_provider(child, of_clk_hw_onecell_get,
&u8500_prcmu_hw_clks);
clk: ux500: Implement the missing CLKOUT clocks This implements the two missing CLKOUT clocks for the ux500 (well really U8500/DB8500) SoC. The clocks are initialized using a specific parent and divider and these are specified in the device tree, see the separate binding patch. The implementation is a bit different in that it will only create the clock in the clock framework if a user appears in the device tree, rather than it being registered upfront like most of the other clocks. This is because the clock needs parameters for source and divider from the consumer phandle for the clock to be set up properly when the clock is registered. There could be more than one user of a CLKOUT clock, but we have not seen this in practice. If this happens the framework prints and info and returns the previously registered clock. Using the clocks requires also muxing the CLKOUT1 or CLKOUT2 to the appropriate pad. In practice this is achived in a pinctrl handle in the DTS node for the device using the CLKOUT clock, so this muxing is done separately from the clock itself. Example: haptic@49 { compatible = "immersion,isa1200"; reg = <0x49>; (...) /* clkout1 from ACLK divided by 8 */ clocks = <&clkout_clk DB8500_CLKOUT_1 DB8500_CLKOUT_SRC_ACLK 8>; pinctrl-names = "default"; pinctrl-0 = <&isa1200_janice_default>; }; isa1200_janice_default: isa1200_janice { /* Bring out clkout1 on pin GPIO227 pin AH7 */ janice_mux { function = "clkout"; groups = "clkout1_a_1"; }; janice_cfg1 { pins = "GPIO227_AH7"; ste,config = <&out_lo>; }; (...) This was tested successfully with the Immersion ISA1200 haptic feedback unit on the Samsung Galaxy S Advance GT-I9070 (Janice) mobile phone. As the CLKOUT clocks need some undefined fixed rate parent clocks that are currently missing from the PRCMU clock implementation, the three simplest are added in this patch: clk38m_to_clkgen, aclk and sysclk. The only parent not yet available in the implementation is clk009, which is a kind of special muxed and divided clock which isn't even implemented in the vendor clock driver. Reviewed-by: Ulf Hansson <ulf.hansson@linaro.org> Signed-off-by: Linus Walleij <linus.walleij@linaro.org> Link: https://lore.kernel.org/r/20220414221751.323525-6-linus.walleij@linaro.org Signed-off-by: Stephen Boyd <sboyd@kernel.org>
2022-04-15 06:17:51 +08:00
if (of_node_name_eq(child, "clkout-clock"))
of_clk_add_hw_provider(child, ux500_clkout_get, NULL);
if (of_node_name_eq(child, "prcc-periph-clock"))
of_clk_add_provider(child, ux500_twocell_get, prcc_pclk);
if (of_node_name_eq(child, "prcc-kernel-clock"))
of_clk_add_provider(child, ux500_twocell_get, prcc_kclk);
if (of_node_name_eq(child, "rtc32k-clock"))
of_clk_add_provider(child, of_clk_src_simple_get, rtc_clk);
if (of_node_name_eq(child, "smp-twd-clock"))
of_clk_add_provider(child, of_clk_src_simple_get, twd_clk);
if (of_node_name_eq(child, "prcc-reset-controller"))
u8500_prcc_reset_init(child, rstc);
}
}
CLK_OF_DECLARE(u8500_clks, "stericsson,u8500-clks", u8500_clk_init);