u-boot/arch/arm/mach-socfpga/clock_manager_arria10.c
Marek Vasut 0b8f6378cb ARM: socfpga: Reorder Arria10 SPL
The Arria10 SPL is a complete mess of calls to functions which are
called in the wrong context and it is surprise it works at all. This
patch tries to clean that mess up by shuffling the function calls
around and moving the calls into the correct context. Due to the
delicate nature of the reordering, this is done in one huge patch.

The following changes happen in this patch:
- Security policy init and NIC301 happens first in board_init_f()
- The clock init happens very early in board_init_f() in SPL only
- arch_early_init_r() only registers the FPGA, just like on Gen5
- arch_early_init_r() is never called from any _f() function
- Dedicated FPGA pins are inited in board_init_f() as on Gen5

Signed-off-by: Marek Vasut <marex@denx.de>
Cc: Chin Liang See <chin.liang.see@intel.com>
Cc: Dinh Nguyen <dinguyen@kernel.org>
Cc: Ley Foon Tan <ley.foon.tan@intel.com>
2018-08-24 12:05:20 +02:00

995 lines
30 KiB
C

// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (C) 2016-2017 Intel Corporation
*/
#include <common.h>
#include <fdtdec.h>
#include <asm/io.h>
#include <dm.h>
#include <clk.h>
#include <dm/device-internal.h>
#include <asm/arch/clock_manager.h>
#ifdef CONFIG_SPL_BUILD
static u32 eosc1_hz;
static u32 cb_intosc_hz;
static u32 f2s_free_hz;
struct mainpll_cfg {
u32 vco0_psrc;
u32 vco1_denom;
u32 vco1_numer;
u32 mpuclk;
u32 mpuclk_cnt;
u32 mpuclk_src;
u32 nocclk;
u32 nocclk_cnt;
u32 nocclk_src;
u32 cntr2clk_cnt;
u32 cntr3clk_cnt;
u32 cntr4clk_cnt;
u32 cntr5clk_cnt;
u32 cntr6clk_cnt;
u32 cntr7clk_cnt;
u32 cntr7clk_src;
u32 cntr8clk_cnt;
u32 cntr9clk_cnt;
u32 cntr9clk_src;
u32 cntr15clk_cnt;
u32 nocdiv_l4mainclk;
u32 nocdiv_l4mpclk;
u32 nocdiv_l4spclk;
u32 nocdiv_csatclk;
u32 nocdiv_cstraceclk;
u32 nocdiv_cspdbclk;
};
struct perpll_cfg {
u32 vco0_psrc;
u32 vco1_denom;
u32 vco1_numer;
u32 cntr2clk_cnt;
u32 cntr2clk_src;
u32 cntr3clk_cnt;
u32 cntr3clk_src;
u32 cntr4clk_cnt;
u32 cntr4clk_src;
u32 cntr5clk_cnt;
u32 cntr5clk_src;
u32 cntr6clk_cnt;
u32 cntr6clk_src;
u32 cntr7clk_cnt;
u32 cntr8clk_cnt;
u32 cntr8clk_src;
u32 cntr9clk_cnt;
u32 cntr9clk_src;
u32 emacctl_emac0sel;
u32 emacctl_emac1sel;
u32 emacctl_emac2sel;
u32 gpiodiv_gpiodbclk;
};
struct strtou32 {
const char *str;
const u32 val;
};
static const struct strtou32 mainpll_cfg_tab[] = {
{ "vco0-psrc", offsetof(struct mainpll_cfg, vco0_psrc) },
{ "vco1-denom", offsetof(struct mainpll_cfg, vco1_denom) },
{ "vco1-numer", offsetof(struct mainpll_cfg, vco1_numer) },
{ "mpuclk-cnt", offsetof(struct mainpll_cfg, mpuclk_cnt) },
{ "mpuclk-src", offsetof(struct mainpll_cfg, mpuclk_src) },
{ "nocclk-cnt", offsetof(struct mainpll_cfg, nocclk_cnt) },
{ "nocclk-src", offsetof(struct mainpll_cfg, nocclk_src) },
{ "cntr2clk-cnt", offsetof(struct mainpll_cfg, cntr2clk_cnt) },
{ "cntr3clk-cnt", offsetof(struct mainpll_cfg, cntr3clk_cnt) },
{ "cntr4clk-cnt", offsetof(struct mainpll_cfg, cntr4clk_cnt) },
{ "cntr5clk-cnt", offsetof(struct mainpll_cfg, cntr5clk_cnt) },
{ "cntr6clk-cnt", offsetof(struct mainpll_cfg, cntr6clk_cnt) },
{ "cntr7clk-cnt", offsetof(struct mainpll_cfg, cntr7clk_cnt) },
{ "cntr7clk-src", offsetof(struct mainpll_cfg, cntr7clk_src) },
{ "cntr8clk-cnt", offsetof(struct mainpll_cfg, cntr8clk_cnt) },
{ "cntr9clk-cnt", offsetof(struct mainpll_cfg, cntr9clk_cnt) },
{ "cntr9clk-src", offsetof(struct mainpll_cfg, cntr9clk_src) },
{ "cntr15clk-cnt", offsetof(struct mainpll_cfg, cntr15clk_cnt) },
{ "nocdiv-l4mainclk", offsetof(struct mainpll_cfg, nocdiv_l4mainclk) },
{ "nocdiv-l4mpclk", offsetof(struct mainpll_cfg, nocdiv_l4mpclk) },
{ "nocdiv-l4spclk", offsetof(struct mainpll_cfg, nocdiv_l4spclk) },
{ "nocdiv-csatclk", offsetof(struct mainpll_cfg, nocdiv_csatclk) },
{ "nocdiv-cstraceclk", offsetof(struct mainpll_cfg, nocdiv_cstraceclk) },
{ "nocdiv-cspdbgclk", offsetof(struct mainpll_cfg, nocdiv_cspdbclk) },
};
static const struct strtou32 perpll_cfg_tab[] = {
{ "vco0-psrc", offsetof(struct perpll_cfg, vco0_psrc) },
{ "vco1-denom", offsetof(struct perpll_cfg, vco1_denom) },
{ "vco1-numer", offsetof(struct perpll_cfg, vco1_numer) },
{ "cntr2clk-cnt", offsetof(struct perpll_cfg, cntr2clk_cnt) },
{ "cntr2clk-src", offsetof(struct perpll_cfg, cntr2clk_src) },
{ "cntr3clk-cnt", offsetof(struct perpll_cfg, cntr3clk_cnt) },
{ "cntr3clk-src", offsetof(struct perpll_cfg, cntr3clk_src) },
{ "cntr4clk-cnt", offsetof(struct perpll_cfg, cntr4clk_cnt) },
{ "cntr4clk-src", offsetof(struct perpll_cfg, cntr4clk_src) },
{ "cntr5clk-cnt", offsetof(struct perpll_cfg, cntr5clk_cnt) },
{ "cntr5clk-src", offsetof(struct perpll_cfg, cntr5clk_src) },
{ "cntr6clk-cnt", offsetof(struct perpll_cfg, cntr6clk_cnt) },
{ "cntr6clk-src", offsetof(struct perpll_cfg, cntr6clk_src) },
{ "cntr7clk-cnt", offsetof(struct perpll_cfg, cntr7clk_cnt) },
{ "cntr8clk-cnt", offsetof(struct perpll_cfg, cntr8clk_cnt) },
{ "cntr8clk-src", offsetof(struct perpll_cfg, cntr8clk_src) },
{ "cntr9clk-cnt", offsetof(struct perpll_cfg, cntr9clk_cnt) },
{ "emacctl-emac0sel", offsetof(struct perpll_cfg, emacctl_emac0sel) },
{ "emacctl-emac1sel", offsetof(struct perpll_cfg, emacctl_emac1sel) },
{ "emacctl-emac2sel", offsetof(struct perpll_cfg, emacctl_emac2sel) },
{ "gpiodiv-gpiodbclk", offsetof(struct perpll_cfg, gpiodiv_gpiodbclk) },
};
static const struct strtou32 alteragrp_cfg_tab[] = {
{ "nocclk", offsetof(struct mainpll_cfg, nocclk) },
{ "mpuclk", offsetof(struct mainpll_cfg, mpuclk) },
};
struct strtopu32 {
const char *str;
u32 *p;
};
const struct strtopu32 dt_to_val[] = {
{ "altera_arria10_hps_eosc1", &eosc1_hz },
{ "altera_arria10_hps_cb_intosc_ls", &cb_intosc_hz },
{ "altera_arria10_hps_f2h_free", &f2s_free_hz },
};
static int of_to_struct(const void *blob, int node, const struct strtou32 *cfg_tab,
int cfg_tab_len, void *cfg)
{
int i;
u32 val;
for (i = 0; i < cfg_tab_len; i++) {
if (fdtdec_get_int_array(blob, node, cfg_tab[i].str, &val, 1)) {
/* could not find required property */
return -EINVAL;
}
*(u32 *)(cfg + cfg_tab[i].val) = val;
}
return 0;
}
static int of_get_input_clks(const void *blob)
{
struct udevice *dev;
struct clk clk;
int i, ret;
for (i = 0; i < ARRAY_SIZE(dt_to_val); i++) {
memset(&clk, 0, sizeof(clk));
ret = uclass_get_device_by_name(UCLASS_CLK, dt_to_val[i].str,
&dev);
if (ret)
return ret;
ret = clk_request(dev, &clk);
if (ret)
return ret;
*dt_to_val[i].p = clk_get_rate(&clk);
}
return 0;
}
static int of_get_clk_cfg(const void *blob, struct mainpll_cfg *main_cfg,
struct perpll_cfg *per_cfg)
{
int ret, node, child, len;
const char *node_name;
ret = of_get_input_clks(blob);
if (ret)
return ret;
node = fdtdec_next_compatible(blob, 0, COMPAT_ALTERA_SOCFPGA_CLK_INIT);
if (node < 0)
return -EINVAL;
child = fdt_first_subnode(blob, node);
if (child < 0)
return -EINVAL;
node_name = fdt_get_name(blob, child, &len);
while (node_name) {
if (!strcmp(node_name, "mainpll")) {
if (of_to_struct(blob, child, mainpll_cfg_tab,
ARRAY_SIZE(mainpll_cfg_tab), main_cfg))
return -EINVAL;
} else if (!strcmp(node_name, "perpll")) {
if (of_to_struct(blob, child, perpll_cfg_tab,
ARRAY_SIZE(perpll_cfg_tab), per_cfg))
return -EINVAL;
} else if (!strcmp(node_name, "alteragrp")) {
if (of_to_struct(blob, child, alteragrp_cfg_tab,
ARRAY_SIZE(alteragrp_cfg_tab), main_cfg))
return -EINVAL;
}
child = fdt_next_subnode(blob, child);
if (child < 0)
break;
node_name = fdt_get_name(blob, child, &len);
}
return 0;
}
static const struct socfpga_clock_manager *clock_manager_base =
(struct socfpga_clock_manager *)SOCFPGA_CLKMGR_ADDRESS;
/* calculate the intended main VCO frequency based on handoff */
static unsigned int cm_calc_handoff_main_vco_clk_hz
(struct mainpll_cfg *main_cfg)
{
unsigned int clk_hz;
/* Check main VCO clock source: eosc, intosc or f2s? */
switch (main_cfg->vco0_psrc) {
case CLKMGR_MAINPLL_VCO0_PSRC_EOSC:
clk_hz = eosc1_hz;
break;
case CLKMGR_MAINPLL_VCO0_PSRC_E_INTOSC:
clk_hz = cb_intosc_hz;
break;
case CLKMGR_MAINPLL_VCO0_PSRC_F2S:
clk_hz = f2s_free_hz;
break;
default:
return 0;
}
/* calculate the VCO frequency */
clk_hz /= 1 + main_cfg->vco1_denom;
clk_hz *= 1 + main_cfg->vco1_numer;
return clk_hz;
}
/* calculate the intended periph VCO frequency based on handoff */
static unsigned int cm_calc_handoff_periph_vco_clk_hz(
struct mainpll_cfg *main_cfg, struct perpll_cfg *per_cfg)
{
unsigned int clk_hz;
/* Check periph VCO clock source: eosc, intosc, f2s or mainpll? */
switch (per_cfg->vco0_psrc) {
case CLKMGR_PERPLL_VCO0_PSRC_EOSC:
clk_hz = eosc1_hz;
break;
case CLKMGR_PERPLL_VCO0_PSRC_E_INTOSC:
clk_hz = cb_intosc_hz;
break;
case CLKMGR_PERPLL_VCO0_PSRC_F2S:
clk_hz = f2s_free_hz;
break;
case CLKMGR_PERPLL_VCO0_PSRC_MAIN:
clk_hz = cm_calc_handoff_main_vco_clk_hz(main_cfg);
clk_hz /= main_cfg->cntr15clk_cnt;
break;
default:
return 0;
}
/* calculate the VCO frequency */
clk_hz /= 1 + per_cfg->vco1_denom;
clk_hz *= 1 + per_cfg->vco1_numer;
return clk_hz;
}
/* calculate the intended MPU clock frequency based on handoff */
static unsigned int cm_calc_handoff_mpu_clk_hz(struct mainpll_cfg *main_cfg,
struct perpll_cfg *per_cfg)
{
unsigned int clk_hz;
/* Check MPU clock source: main, periph, osc1, intosc or f2s? */
switch (main_cfg->mpuclk_src) {
case CLKMGR_MAINPLL_MPUCLK_SRC_MAIN:
clk_hz = cm_calc_handoff_main_vco_clk_hz(main_cfg);
clk_hz /= (main_cfg->mpuclk & CLKMGR_MAINPLL_MPUCLK_CNT_MSK)
+ 1;
break;
case CLKMGR_MAINPLL_MPUCLK_SRC_PERI:
clk_hz = cm_calc_handoff_periph_vco_clk_hz(main_cfg, per_cfg);
clk_hz /= ((main_cfg->mpuclk >>
CLKMGR_MAINPLL_MPUCLK_PERICNT_LSB) &
CLKMGR_MAINPLL_MPUCLK_CNT_MSK) + 1;
break;
case CLKMGR_MAINPLL_MPUCLK_SRC_OSC1:
clk_hz = eosc1_hz;
break;
case CLKMGR_MAINPLL_MPUCLK_SRC_INTOSC:
clk_hz = cb_intosc_hz;
break;
case CLKMGR_MAINPLL_MPUCLK_SRC_FPGA:
clk_hz = f2s_free_hz;
break;
default:
return 0;
}
clk_hz /= main_cfg->mpuclk_cnt + 1;
return clk_hz;
}
/* calculate the intended NOC clock frequency based on handoff */
static unsigned int cm_calc_handoff_noc_clk_hz(struct mainpll_cfg *main_cfg,
struct perpll_cfg *per_cfg)
{
unsigned int clk_hz;
/* Check MPU clock source: main, periph, osc1, intosc or f2s? */
switch (main_cfg->nocclk_src) {
case CLKMGR_MAINPLL_NOCCLK_SRC_MAIN:
clk_hz = cm_calc_handoff_main_vco_clk_hz(main_cfg);
clk_hz /= (main_cfg->nocclk & CLKMGR_MAINPLL_NOCCLK_CNT_MSK)
+ 1;
break;
case CLKMGR_MAINPLL_NOCCLK_SRC_PERI:
clk_hz = cm_calc_handoff_periph_vco_clk_hz(main_cfg, per_cfg);
clk_hz /= ((main_cfg->nocclk >>
CLKMGR_MAINPLL_NOCCLK_PERICNT_LSB) &
CLKMGR_MAINPLL_NOCCLK_CNT_MSK) + 1;
break;
case CLKMGR_MAINPLL_NOCCLK_SRC_OSC1:
clk_hz = eosc1_hz;
break;
case CLKMGR_MAINPLL_NOCCLK_SRC_INTOSC:
clk_hz = cb_intosc_hz;
break;
case CLKMGR_MAINPLL_NOCCLK_SRC_FPGA:
clk_hz = f2s_free_hz;
break;
default:
return 0;
}
clk_hz /= main_cfg->nocclk_cnt + 1;
return clk_hz;
}
/* return 1 if PLL ramp is required */
static int cm_is_pll_ramp_required(int main0periph1,
struct mainpll_cfg *main_cfg,
struct perpll_cfg *per_cfg)
{
/* Check for main PLL */
if (main0periph1 == 0) {
/*
* PLL ramp is not required if both MPU clock and NOC clock are
* not sourced from main PLL
*/
if (main_cfg->mpuclk_src != CLKMGR_MAINPLL_MPUCLK_SRC_MAIN &&
main_cfg->nocclk_src != CLKMGR_MAINPLL_NOCCLK_SRC_MAIN)
return 0;
/*
* PLL ramp is required if MPU clock is sourced from main PLL
* and MPU clock is over 900MHz (as advised by HW team)
*/
if (main_cfg->mpuclk_src == CLKMGR_MAINPLL_MPUCLK_SRC_MAIN &&
(cm_calc_handoff_mpu_clk_hz(main_cfg, per_cfg) >
CLKMGR_PLL_RAMP_MPUCLK_THRESHOLD_HZ))
return 1;
/*
* PLL ramp is required if NOC clock is sourced from main PLL
* and NOC clock is over 300MHz (as advised by HW team)
*/
if (main_cfg->nocclk_src == CLKMGR_MAINPLL_NOCCLK_SRC_MAIN &&
(cm_calc_handoff_noc_clk_hz(main_cfg, per_cfg) >
CLKMGR_PLL_RAMP_NOCCLK_THRESHOLD_HZ))
return 2;
} else if (main0periph1 == 1) {
/*
* PLL ramp is not required if both MPU clock and NOC clock are
* not sourced from periph PLL
*/
if (main_cfg->mpuclk_src != CLKMGR_MAINPLL_MPUCLK_SRC_PERI &&
main_cfg->nocclk_src != CLKMGR_MAINPLL_NOCCLK_SRC_PERI)
return 0;
/*
* PLL ramp is required if MPU clock are source from periph PLL
* and MPU clock is over 900MHz (as advised by HW team)
*/
if (main_cfg->mpuclk_src == CLKMGR_MAINPLL_MPUCLK_SRC_PERI &&
(cm_calc_handoff_mpu_clk_hz(main_cfg, per_cfg) >
CLKMGR_PLL_RAMP_MPUCLK_THRESHOLD_HZ))
return 1;
/*
* PLL ramp is required if NOC clock are source from periph PLL
* and NOC clock is over 300MHz (as advised by HW team)
*/
if (main_cfg->nocclk_src == CLKMGR_MAINPLL_NOCCLK_SRC_PERI &&
(cm_calc_handoff_noc_clk_hz(main_cfg, per_cfg) >
CLKMGR_PLL_RAMP_NOCCLK_THRESHOLD_HZ))
return 2;
}
return 0;
}
static u32 cm_calculate_numer(struct mainpll_cfg *main_cfg,
struct perpll_cfg *per_cfg,
u32 safe_hz, u32 clk_hz)
{
u32 cnt;
u32 clk;
u32 shift;
u32 mask;
u32 denom;
if (main_cfg->mpuclk_src == CLKMGR_MAINPLL_MPUCLK_SRC_MAIN) {
cnt = main_cfg->mpuclk_cnt;
clk = main_cfg->mpuclk;
shift = 0;
mask = CLKMGR_MAINPLL_MPUCLK_CNT_MSK;
denom = main_cfg->vco1_denom;
} else if (main_cfg->nocclk_src == CLKMGR_MAINPLL_NOCCLK_SRC_MAIN) {
cnt = main_cfg->nocclk_cnt;
clk = main_cfg->nocclk;
shift = 0;
mask = CLKMGR_MAINPLL_NOCCLK_CNT_MSK;
denom = main_cfg->vco1_denom;
} else if (main_cfg->mpuclk_src == CLKMGR_MAINPLL_MPUCLK_SRC_PERI) {
cnt = main_cfg->mpuclk_cnt;
clk = main_cfg->mpuclk;
shift = CLKMGR_MAINPLL_MPUCLK_PERICNT_LSB;
mask = CLKMGR_MAINPLL_MPUCLK_CNT_MSK;
denom = per_cfg->vco1_denom;
} else if (main_cfg->nocclk_src == CLKMGR_MAINPLL_NOCCLK_SRC_PERI) {
cnt = main_cfg->nocclk_cnt;
clk = main_cfg->nocclk;
shift = CLKMGR_MAINPLL_NOCCLK_PERICNT_LSB;
mask = CLKMGR_MAINPLL_NOCCLK_CNT_MSK;
denom = per_cfg->vco1_denom;
} else {
return 0;
}
return (safe_hz / clk_hz) * (cnt + 1) * (((clk >> shift) & mask) + 1) *
(1 + denom) - 1;
}
/*
* Calculate the new PLL numerator which is based on existing DTS hand off and
* intended safe frequency (safe_hz). Note that PLL ramp is only modifying the
* numerator while maintaining denominator as denominator will influence the
* jitter condition. Please refer A10 HPS TRM for the jitter guide. Note final
* value for numerator is minus with 1 to cater our register value
* representation.
*/
static unsigned int cm_calc_safe_pll_numer(int main0periph1,
struct mainpll_cfg *main_cfg,
struct perpll_cfg *per_cfg,
unsigned int safe_hz)
{
unsigned int clk_hz = 0;
/* Check for main PLL */
if (main0periph1 == 0) {
/* Check main VCO clock source: eosc, intosc or f2s? */
switch (main_cfg->vco0_psrc) {
case CLKMGR_MAINPLL_VCO0_PSRC_EOSC:
clk_hz = eosc1_hz;
break;
case CLKMGR_MAINPLL_VCO0_PSRC_E_INTOSC:
clk_hz = cb_intosc_hz;
break;
case CLKMGR_MAINPLL_VCO0_PSRC_F2S:
clk_hz = f2s_free_hz;
break;
default:
return 0;
}
} else if (main0periph1 == 1) {
/* Check periph VCO clock source: eosc, intosc, f2s, mainpll */
switch (per_cfg->vco0_psrc) {
case CLKMGR_PERPLL_VCO0_PSRC_EOSC:
clk_hz = eosc1_hz;
break;
case CLKMGR_PERPLL_VCO0_PSRC_E_INTOSC:
clk_hz = cb_intosc_hz;
break;
case CLKMGR_PERPLL_VCO0_PSRC_F2S:
clk_hz = f2s_free_hz;
break;
case CLKMGR_PERPLL_VCO0_PSRC_MAIN:
clk_hz = cm_calc_handoff_main_vco_clk_hz(main_cfg);
clk_hz /= main_cfg->cntr15clk_cnt;
break;
default:
return 0;
}
} else {
return 0;
}
return cm_calculate_numer(main_cfg, per_cfg, safe_hz, clk_hz);
}
/* ramping the main PLL to final value */
static void cm_pll_ramp_main(struct mainpll_cfg *main_cfg,
struct perpll_cfg *per_cfg,
unsigned int pll_ramp_main_hz)
{
unsigned int clk_hz = 0, clk_incr_hz = 0, clk_final_hz = 0;
/* find out the increment value */
if (main_cfg->mpuclk_src == CLKMGR_MAINPLL_MPUCLK_SRC_MAIN) {
clk_incr_hz = CLKMGR_PLL_RAMP_MPUCLK_INCREMENT_HZ;
clk_final_hz = cm_calc_handoff_mpu_clk_hz(main_cfg, per_cfg);
} else if (main_cfg->nocclk_src == CLKMGR_MAINPLL_NOCCLK_SRC_MAIN) {
clk_incr_hz = CLKMGR_PLL_RAMP_NOCCLK_INCREMENT_HZ;
clk_final_hz = cm_calc_handoff_noc_clk_hz(main_cfg, per_cfg);
}
/* execute the ramping here */
for (clk_hz = pll_ramp_main_hz + clk_incr_hz;
clk_hz < clk_final_hz; clk_hz += clk_incr_hz) {
writel((main_cfg->vco1_denom <<
CLKMGR_MAINPLL_VCO1_DENOM_LSB) |
cm_calc_safe_pll_numer(0, main_cfg, per_cfg, clk_hz),
&clock_manager_base->main_pll.vco1);
mdelay(1);
cm_wait_for_lock(LOCKED_MASK);
}
writel((main_cfg->vco1_denom << CLKMGR_MAINPLL_VCO1_DENOM_LSB) |
main_cfg->vco1_numer, &clock_manager_base->main_pll.vco1);
mdelay(1);
cm_wait_for_lock(LOCKED_MASK);
}
/* ramping the periph PLL to final value */
static void cm_pll_ramp_periph(struct mainpll_cfg *main_cfg,
struct perpll_cfg *per_cfg,
unsigned int pll_ramp_periph_hz)
{
unsigned int clk_hz = 0, clk_incr_hz = 0, clk_final_hz = 0;
/* find out the increment value */
if (main_cfg->mpuclk_src == CLKMGR_MAINPLL_MPUCLK_SRC_PERI) {
clk_incr_hz = CLKMGR_PLL_RAMP_MPUCLK_INCREMENT_HZ;
clk_final_hz = cm_calc_handoff_mpu_clk_hz(main_cfg, per_cfg);
} else if (main_cfg->nocclk_src == CLKMGR_MAINPLL_NOCCLK_SRC_PERI) {
clk_incr_hz = CLKMGR_PLL_RAMP_NOCCLK_INCREMENT_HZ;
clk_final_hz = cm_calc_handoff_noc_clk_hz(main_cfg, per_cfg);
}
/* execute the ramping here */
for (clk_hz = pll_ramp_periph_hz + clk_incr_hz;
clk_hz < clk_final_hz; clk_hz += clk_incr_hz) {
writel((per_cfg->vco1_denom << CLKMGR_PERPLL_VCO1_DENOM_LSB) |
cm_calc_safe_pll_numer(1, main_cfg, per_cfg, clk_hz),
&clock_manager_base->per_pll.vco1);
mdelay(1);
cm_wait_for_lock(LOCKED_MASK);
}
writel((per_cfg->vco1_denom << CLKMGR_PERPLL_VCO1_DENOM_LSB) |
per_cfg->vco1_numer, &clock_manager_base->per_pll.vco1);
mdelay(1);
cm_wait_for_lock(LOCKED_MASK);
}
/*
* Setup clocks while making no assumptions of the
* previous state of the clocks.
*
* Start by being paranoid and gate all sw managed clocks
*
* Put all plls in bypass
*
* Put all plls VCO registers back to reset value (bgpwr dwn).
*
* Put peripheral and main pll src to reset value to avoid glitch.
*
* Delay 5 us.
*
* Deassert bg pwr dn and set numerator and denominator
*
* Start 7 us timer.
*
* set internal dividers
*
* Wait for 7 us timer.
*
* Enable plls
*
* Set external dividers while plls are locking
*
* Wait for pll lock
*
* Assert/deassert outreset all.
*
* Take all pll's out of bypass
*
* Clear safe mode
*
* set source main and peripheral clocks
*
* Ungate clocks
*/
static int cm_full_cfg(struct mainpll_cfg *main_cfg, struct perpll_cfg *per_cfg)
{
unsigned int pll_ramp_main_hz = 0, pll_ramp_periph_hz = 0,
ramp_required;
/* gate off all mainpll clock excpet HW managed clock */
writel(CLKMGR_MAINPLL_EN_S2FUSER0CLKEN_SET_MSK |
CLKMGR_MAINPLL_EN_HMCPLLREFCLKEN_SET_MSK,
&clock_manager_base->main_pll.enr);
/* now we can gate off the rest of the peripheral clocks */
writel(0, &clock_manager_base->per_pll.en);
/* Put all plls in external bypass */
writel(CLKMGR_MAINPLL_BYPASS_RESET,
&clock_manager_base->main_pll.bypasss);
writel(CLKMGR_PERPLL_BYPASS_RESET,
&clock_manager_base->per_pll.bypasss);
/*
* Put all plls VCO registers back to reset value.
* Some code might have messed with them. At same time set the
* desired clock source
*/
writel(CLKMGR_MAINPLL_VCO0_RESET |
CLKMGR_MAINPLL_VCO0_REGEXTSEL_SET_MSK |
(main_cfg->vco0_psrc << CLKMGR_MAINPLL_VCO0_PSRC_LSB),
&clock_manager_base->main_pll.vco0);
writel(CLKMGR_PERPLL_VCO0_RESET |
CLKMGR_PERPLL_VCO0_REGEXTSEL_SET_MSK |
(per_cfg->vco0_psrc << CLKMGR_PERPLL_VCO0_PSRC_LSB),
&clock_manager_base->per_pll.vco0);
writel(CLKMGR_MAINPLL_VCO1_RESET, &clock_manager_base->main_pll.vco1);
writel(CLKMGR_PERPLL_VCO1_RESET, &clock_manager_base->per_pll.vco1);
/* clear the interrupt register status register */
writel(CLKMGR_CLKMGR_INTR_MAINPLLLOST_SET_MSK |
CLKMGR_CLKMGR_INTR_PERPLLLOST_SET_MSK |
CLKMGR_CLKMGR_INTR_MAINPLLRFSLIP_SET_MSK |
CLKMGR_CLKMGR_INTR_PERPLLRFSLIP_SET_MSK |
CLKMGR_CLKMGR_INTR_MAINPLLFBSLIP_SET_MSK |
CLKMGR_CLKMGR_INTR_PERPLLFBSLIP_SET_MSK |
CLKMGR_CLKMGR_INTR_MAINPLLACHIEVED_SET_MSK |
CLKMGR_CLKMGR_INTR_PERPLLACHIEVED_SET_MSK,
&clock_manager_base->intr);
/* Program VCO Numerator and Denominator for main PLL */
ramp_required = cm_is_pll_ramp_required(0, main_cfg, per_cfg);
if (ramp_required) {
/* set main PLL to safe starting threshold frequency */
if (ramp_required == 1)
pll_ramp_main_hz = CLKMGR_PLL_RAMP_MPUCLK_THRESHOLD_HZ;
else if (ramp_required == 2)
pll_ramp_main_hz = CLKMGR_PLL_RAMP_NOCCLK_THRESHOLD_HZ;
writel((main_cfg->vco1_denom << CLKMGR_MAINPLL_VCO1_DENOM_LSB) |
cm_calc_safe_pll_numer(0, main_cfg, per_cfg,
pll_ramp_main_hz),
&clock_manager_base->main_pll.vco1);
} else
writel((main_cfg->vco1_denom << CLKMGR_MAINPLL_VCO1_DENOM_LSB) |
main_cfg->vco1_numer,
&clock_manager_base->main_pll.vco1);
/* Program VCO Numerator and Denominator for periph PLL */
ramp_required = cm_is_pll_ramp_required(1, main_cfg, per_cfg);
if (ramp_required) {
/* set periph PLL to safe starting threshold frequency */
if (ramp_required == 1)
pll_ramp_periph_hz =
CLKMGR_PLL_RAMP_MPUCLK_THRESHOLD_HZ;
else if (ramp_required == 2)
pll_ramp_periph_hz =
CLKMGR_PLL_RAMP_NOCCLK_THRESHOLD_HZ;
writel((per_cfg->vco1_denom << CLKMGR_PERPLL_VCO1_DENOM_LSB) |
cm_calc_safe_pll_numer(1, main_cfg, per_cfg,
pll_ramp_periph_hz),
&clock_manager_base->per_pll.vco1);
} else
writel((per_cfg->vco1_denom << CLKMGR_PERPLL_VCO1_DENOM_LSB) |
per_cfg->vco1_numer,
&clock_manager_base->per_pll.vco1);
/* Wait for at least 5 us */
udelay(5);
/* Now deassert BGPWRDN and PWRDN */
clrbits_le32(&clock_manager_base->main_pll.vco0,
CLKMGR_MAINPLL_VCO0_BGPWRDN_SET_MSK |
CLKMGR_MAINPLL_VCO0_PWRDN_SET_MSK);
clrbits_le32(&clock_manager_base->per_pll.vco0,
CLKMGR_PERPLL_VCO0_BGPWRDN_SET_MSK |
CLKMGR_PERPLL_VCO0_PWRDN_SET_MSK);
/* Wait for at least 7 us */
udelay(7);
/* enable the VCO and disable the external regulator to PLL */
writel((readl(&clock_manager_base->main_pll.vco0) &
~CLKMGR_MAINPLL_VCO0_REGEXTSEL_SET_MSK) |
CLKMGR_MAINPLL_VCO0_EN_SET_MSK,
&clock_manager_base->main_pll.vco0);
writel((readl(&clock_manager_base->per_pll.vco0) &
~CLKMGR_PERPLL_VCO0_REGEXTSEL_SET_MSK) |
CLKMGR_PERPLL_VCO0_EN_SET_MSK,
&clock_manager_base->per_pll.vco0);
/* setup all the main PLL counter and clock source */
writel(main_cfg->nocclk,
SOCFPGA_CLKMGR_ADDRESS + CLKMGR_MAINPLL_NOC_CLK_OFFSET);
writel(main_cfg->mpuclk,
SOCFPGA_CLKMGR_ADDRESS + CLKMGR_ALTERAGRP_MPU_CLK_OFFSET);
/* main_emaca_clk divider */
writel(main_cfg->cntr2clk_cnt, &clock_manager_base->main_pll.cntr2clk);
/* main_emacb_clk divider */
writel(main_cfg->cntr3clk_cnt, &clock_manager_base->main_pll.cntr3clk);
/* main_emac_ptp_clk divider */
writel(main_cfg->cntr4clk_cnt, &clock_manager_base->main_pll.cntr4clk);
/* main_gpio_db_clk divider */
writel(main_cfg->cntr5clk_cnt, &clock_manager_base->main_pll.cntr5clk);
/* main_sdmmc_clk divider */
writel(main_cfg->cntr6clk_cnt, &clock_manager_base->main_pll.cntr6clk);
/* main_s2f_user0_clk divider */
writel(main_cfg->cntr7clk_cnt |
(main_cfg->cntr7clk_src << CLKMGR_MAINPLL_CNTR7CLK_SRC_LSB),
&clock_manager_base->main_pll.cntr7clk);
/* main_s2f_user1_clk divider */
writel(main_cfg->cntr8clk_cnt, &clock_manager_base->main_pll.cntr8clk);
/* main_hmc_pll_clk divider */
writel(main_cfg->cntr9clk_cnt |
(main_cfg->cntr9clk_src << CLKMGR_MAINPLL_CNTR9CLK_SRC_LSB),
&clock_manager_base->main_pll.cntr9clk);
/* main_periph_ref_clk divider */
writel(main_cfg->cntr15clk_cnt,
&clock_manager_base->main_pll.cntr15clk);
/* setup all the peripheral PLL counter and clock source */
/* peri_emaca_clk divider */
writel(per_cfg->cntr2clk_cnt |
(per_cfg->cntr2clk_src << CLKMGR_PERPLL_CNTR2CLK_SRC_LSB),
&clock_manager_base->per_pll.cntr2clk);
/* peri_emacb_clk divider */
writel(per_cfg->cntr3clk_cnt |
(per_cfg->cntr3clk_src << CLKMGR_PERPLL_CNTR3CLK_SRC_LSB),
&clock_manager_base->per_pll.cntr3clk);
/* peri_emac_ptp_clk divider */
writel(per_cfg->cntr4clk_cnt |
(per_cfg->cntr4clk_src << CLKMGR_PERPLL_CNTR4CLK_SRC_LSB),
&clock_manager_base->per_pll.cntr4clk);
/* peri_gpio_db_clk divider */
writel(per_cfg->cntr5clk_cnt |
(per_cfg->cntr5clk_src << CLKMGR_PERPLL_CNTR5CLK_SRC_LSB),
&clock_manager_base->per_pll.cntr5clk);
/* peri_sdmmc_clk divider */
writel(per_cfg->cntr6clk_cnt |
(per_cfg->cntr6clk_src << CLKMGR_PERPLL_CNTR6CLK_SRC_LSB),
&clock_manager_base->per_pll.cntr6clk);
/* peri_s2f_user0_clk divider */
writel(per_cfg->cntr7clk_cnt, &clock_manager_base->per_pll.cntr7clk);
/* peri_s2f_user1_clk divider */
writel(per_cfg->cntr8clk_cnt |
(per_cfg->cntr8clk_src << CLKMGR_PERPLL_CNTR8CLK_SRC_LSB),
&clock_manager_base->per_pll.cntr8clk);
/* peri_hmc_pll_clk divider */
writel(per_cfg->cntr9clk_cnt, &clock_manager_base->per_pll.cntr9clk);
/* setup all the external PLL counter */
/* mpu wrapper / external divider */
writel(main_cfg->mpuclk_cnt |
(main_cfg->mpuclk_src << CLKMGR_MAINPLL_MPUCLK_SRC_LSB),
&clock_manager_base->main_pll.mpuclk);
/* NOC wrapper / external divider */
writel(main_cfg->nocclk_cnt |
(main_cfg->nocclk_src << CLKMGR_MAINPLL_NOCCLK_SRC_LSB),
&clock_manager_base->main_pll.nocclk);
/* NOC subclock divider such as l4 */
writel(main_cfg->nocdiv_l4mainclk |
(main_cfg->nocdiv_l4mpclk <<
CLKMGR_MAINPLL_NOCDIV_L4MPCLK_LSB) |
(main_cfg->nocdiv_l4spclk <<
CLKMGR_MAINPLL_NOCDIV_L4SPCLK_LSB) |
(main_cfg->nocdiv_csatclk <<
CLKMGR_MAINPLL_NOCDIV_CSATCLK_LSB) |
(main_cfg->nocdiv_cstraceclk <<
CLKMGR_MAINPLL_NOCDIV_CSTRACECLK_LSB) |
(main_cfg->nocdiv_cspdbclk <<
CLKMGR_MAINPLL_NOCDIV_CSPDBGCLK_LSB),
&clock_manager_base->main_pll.nocdiv);
/* gpio_db external divider */
writel(per_cfg->gpiodiv_gpiodbclk,
&clock_manager_base->per_pll.gpiodiv);
/* setup the EMAC clock mux select */
writel((per_cfg->emacctl_emac0sel <<
CLKMGR_PERPLL_EMACCTL_EMAC0SEL_LSB) |
(per_cfg->emacctl_emac1sel <<
CLKMGR_PERPLL_EMACCTL_EMAC1SEL_LSB) |
(per_cfg->emacctl_emac2sel <<
CLKMGR_PERPLL_EMACCTL_EMAC2SEL_LSB),
&clock_manager_base->per_pll.emacctl);
/* at this stage, check for PLL lock status */
cm_wait_for_lock(LOCKED_MASK);
/*
* after locking, but before taking out of bypass,
* assert/deassert outresetall
*/
/* assert mainpll outresetall */
setbits_le32(&clock_manager_base->main_pll.vco0,
CLKMGR_MAINPLL_VCO0_OUTRSTALL_SET_MSK);
/* assert perpll outresetall */
setbits_le32(&clock_manager_base->per_pll.vco0,
CLKMGR_PERPLL_VCO0_OUTRSTALL_SET_MSK);
/* de-assert mainpll outresetall */
clrbits_le32(&clock_manager_base->main_pll.vco0,
CLKMGR_MAINPLL_VCO0_OUTRSTALL_SET_MSK);
/* de-assert perpll outresetall */
clrbits_le32(&clock_manager_base->per_pll.vco0,
CLKMGR_PERPLL_VCO0_OUTRSTALL_SET_MSK);
/* Take all PLLs out of bypass when boot mode is cleared. */
/* release mainpll from bypass */
writel(CLKMGR_MAINPLL_BYPASS_RESET,
&clock_manager_base->main_pll.bypassr);
/* wait till Clock Manager is not busy */
cm_wait_for_fsm();
/* release perpll from bypass */
writel(CLKMGR_PERPLL_BYPASS_RESET,
&clock_manager_base->per_pll.bypassr);
/* wait till Clock Manager is not busy */
cm_wait_for_fsm();
/* clear boot mode */
clrbits_le32(&clock_manager_base->ctrl,
CLKMGR_CLKMGR_CTL_BOOTMOD_SET_MSK);
/* wait till Clock Manager is not busy */
cm_wait_for_fsm();
/* At here, we need to ramp to final value if needed */
if (pll_ramp_main_hz != 0)
cm_pll_ramp_main(main_cfg, per_cfg, pll_ramp_main_hz);
if (pll_ramp_periph_hz != 0)
cm_pll_ramp_periph(main_cfg, per_cfg, pll_ramp_periph_hz);
/* Now ungate non-hw-managed clocks */
writel(CLKMGR_MAINPLL_EN_S2FUSER0CLKEN_SET_MSK |
CLKMGR_MAINPLL_EN_HMCPLLREFCLKEN_SET_MSK,
&clock_manager_base->main_pll.ens);
writel(CLKMGR_PERPLL_EN_RESET, &clock_manager_base->per_pll.ens);
/* Clear the loss lock and slip bits as they might set during
clock reconfiguration */
writel(CLKMGR_CLKMGR_INTR_MAINPLLLOST_SET_MSK |
CLKMGR_CLKMGR_INTR_PERPLLLOST_SET_MSK |
CLKMGR_CLKMGR_INTR_MAINPLLRFSLIP_SET_MSK |
CLKMGR_CLKMGR_INTR_PERPLLRFSLIP_SET_MSK |
CLKMGR_CLKMGR_INTR_MAINPLLFBSLIP_SET_MSK |
CLKMGR_CLKMGR_INTR_PERPLLFBSLIP_SET_MSK,
&clock_manager_base->intr);
return 0;
}
static void cm_use_intosc(void)
{
setbits_le32(&clock_manager_base->ctrl,
CLKMGR_CLKMGR_CTL_BOOTCLK_INTOSC_SET_MSK);
}
int cm_basic_init(const void *blob)
{
struct mainpll_cfg main_cfg;
struct perpll_cfg per_cfg;
int rval;
/* initialize to zero for use case of optional node */
memset(&main_cfg, 0, sizeof(main_cfg));
memset(&per_cfg, 0, sizeof(per_cfg));
rval = of_get_clk_cfg(blob, &main_cfg, &per_cfg);
if (rval)
return rval;
cm_use_intosc();
return cm_full_cfg(&main_cfg, &per_cfg);
}
#endif
static u32 cm_get_rate_dm(char *name)
{
struct uclass *uc;
struct udevice *dev = NULL;
struct clk clk = { 0 };
ulong rate;
int ret;
/* Device addresses start at 1 */
ret = uclass_get(UCLASS_CLK, &uc);
if (ret)
return 0;
ret = uclass_get_device_by_name(UCLASS_CLK, name, &dev);
if (ret)
return 0;
ret = device_probe(dev);
if (ret)
return 0;
ret = clk_request(dev, &clk);
if (ret)
return 0;
rate = clk_get_rate(&clk);
clk_free(&clk);
return rate;
}
static u32 cm_get_rate_dm_khz(char *name)
{
return cm_get_rate_dm(name) / 1000;
}
unsigned long cm_get_mpu_clk_hz(void)
{
return cm_get_rate_dm("main_mpu_base_clk");
}
unsigned int cm_get_qspi_controller_clk_hz(void)
{
return cm_get_rate_dm("qspi_clk");
}
unsigned int cm_get_l4_sp_clk_hz(void)
{
return cm_get_rate_dm("l4_sp_clk");
}
void cm_print_clock_quick_summary(void)
{
printf("MPU %10d kHz\n", cm_get_rate_dm_khz("main_mpu_base_clk"));
printf("MMC %8d kHz\n", cm_get_rate_dm_khz("sdmmc_clk"));
printf("QSPI %8d kHz\n", cm_get_rate_dm_khz("qspi_clk"));
printf("SPI %8d kHz\n", cm_get_rate_dm_khz("spi_m_clk"));
printf("EOSC1 %8d kHz\n", cm_get_rate_dm_khz("osc1"));
printf("cb_intosc %8d kHz\n", cm_get_rate_dm_khz("cb_intosc_ls_clk"));
printf("f2s_free %8d kHz\n", cm_get_rate_dm_khz("f2s_free_clk"));
printf("Main VCO %8d kHz\n", cm_get_rate_dm_khz("main_pll@40"));
printf("NOC %8d kHz\n", cm_get_rate_dm_khz("main_noc_base_clk"));
printf("L4 Main %8d kHz\n", cm_get_rate_dm_khz("l4_main_clk"));
printf("L4 MP %8d kHz\n", cm_get_rate_dm_khz("l4_mp_clk"));
printf("L4 SP %8d kHz\n", cm_get_rate_dm_khz("l4_sp_clk"));
printf("L4 sys free %8d kHz\n", cm_get_rate_dm_khz("l4_sys_free_clk"));
}