u-boot/arch/arm/mach-imx/imx8ulp/cgc.c
Ye Li 509b8e7ba1 imx: imx8ulp: cgc: Switch to NICLPAV to FRO192 before PLL4 init
When reset with dual boot mode, the LPAV domain won't power down
due to its master is not assigned to APD. So the NICLPAV keeps the
last setting to use PLL4PFD1. So before SPL initialize the PLL4,
we need to switch NICLPAV to FRO192, otherwise system will hang.

Reviewed-by: Peng Fan <peng.fan@nxp.com>
Signed-off-by: Ye Li <ye.li@nxp.com>
Signed-off-by: Peng Fan <peng.fan@nxp.com>
2022-04-12 17:33:56 +02:00

730 lines
16 KiB
C

// SPDX-License-Identifier: GPL-2.0+
/*
* Copyright 2021 NXP
*/
#include <common.h>
#include <div64.h>
#include <asm/io.h>
#include <errno.h>
#include <asm/arch/imx-regs.h>
#include <asm/arch/cgc.h>
#include <asm/arch/clock.h>
#include <asm/arch/sys_proto.h>
#include <asm/global_data.h>
#include <linux/delay.h>
#include <hang.h>
DECLARE_GLOBAL_DATA_PTR;
static struct cgc1_regs *cgc1_regs = (struct cgc1_regs *)0x292C0000UL;
static struct cgc2_regs *cgc2_regs = (struct cgc2_regs *)0x2da60000UL;
void cgc1_soscdiv_init(void)
{
/* Configure SOSC/FRO DIV1 ~ DIV3 */
clrbits_le32(&cgc1_regs->soscdiv, BIT(7));
clrbits_le32(&cgc1_regs->soscdiv, BIT(15));
clrbits_le32(&cgc1_regs->soscdiv, BIT(23));
clrbits_le32(&cgc1_regs->soscdiv, BIT(31));
clrbits_le32(&cgc1_regs->frodiv, BIT(7));
}
void cgc1_pll2_init(ulong freq)
{
u32 reg;
if (readl(&cgc1_regs->pll2csr) & BIT(23))
clrbits_le32(&cgc1_regs->pll2csr, BIT(23));
/* Disable PLL2 */
clrbits_le32(&cgc1_regs->pll2csr, BIT(0));
mdelay(1);
/* wait valid bit false */
while ((readl(&cgc1_regs->pll2csr) & BIT(24)))
;
/* Select SOSC as source */
reg = (freq / MHZ(24)) << 16;
writel(reg, &cgc1_regs->pll2cfg);
/* Enable PLL2 */
setbits_le32(&cgc1_regs->pll2csr, BIT(0));
/* Wait for PLL2 clock ready */
while (!(readl(&cgc1_regs->pll2csr) & BIT(24)))
;
}
static void cgc1_set_a35_clk(u32 clk_src, u32 div_core)
{
u32 reg;
/* ulock */
if (readl(&cgc1_regs->ca35clk) & BIT(31))
clrbits_le32(&cgc1_regs->ca35clk, BIT(31));
reg = readl(&cgc1_regs->ca35clk);
reg &= ~GENMASK(29, 21);
reg |= ((clk_src & 0x3) << 28);
reg |= (((div_core - 1) & 0x3f) << 21);
writel(reg, &cgc1_regs->ca35clk);
while (!(readl(&cgc1_regs->ca35clk) & BIT(27)))
;
}
void cgc1_init_core_clk(ulong freq)
{
u32 reg = readl(&cgc1_regs->ca35clk);
/* if already selected to PLL2, switch to FRO firstly */
if (((reg >> 28) & 0x3) == 0x1)
cgc1_set_a35_clk(0, 1);
cgc1_pll2_init(freq);
/* Set A35 clock to pll2 */
cgc1_set_a35_clk(1, 1);
}
void cgc1_enet_stamp_sel(u32 clk_src)
{
writel((clk_src & 0x7) << 24, &cgc1_regs->enetstamp);
}
void cgc1_pll3_init(ulong freq)
{
/* Gate off VCO */
setbits_le32(&cgc1_regs->pll3div_vco, BIT(7));
/* Disable PLL3 */
clrbits_le32(&cgc1_regs->pll3csr, BIT(0));
/* Gate off PFDxDIV */
setbits_le32(&cgc1_regs->pll3div_pfd0, BIT(7) | BIT(15) | BIT(23) | BIT(31));
setbits_le32(&cgc1_regs->pll3div_pfd1, BIT(7) | BIT(15) | BIT(23) | BIT(31));
/* Gate off PFDx */
setbits_le32(&cgc1_regs->pll3pfdcfg, BIT(7));
setbits_le32(&cgc1_regs->pll3pfdcfg, BIT(15));
setbits_le32(&cgc1_regs->pll3pfdcfg, BIT(23));
setbits_le32(&cgc1_regs->pll3pfdcfg, BIT(31));
/* Select SOSC as source */
clrbits_le32(&cgc1_regs->pll3cfg, BIT(0));
switch (freq) {
case 540672000:
writel(0x16 << 16, &cgc1_regs->pll3cfg);
writel(0x16e3600, &cgc1_regs->pll3denom);
writel(0xc15c00, &cgc1_regs->pll3num);
break;
default:
hang();
}
/* Enable PLL3 */
setbits_le32(&cgc1_regs->pll3csr, BIT(0));
/* Wait for PLL3 clock ready */
while (!(readl(&cgc1_regs->pll3csr) & BIT(24)))
;
/* Gate on VCO */
clrbits_le32(&cgc1_regs->pll3div_vco, BIT(7));
clrbits_le32(&cgc1_regs->pll3pfdcfg, 0x3F);
if (IS_ENABLED(CONFIG_IMX8ULP_LD_MODE)) {
setbits_le32(&cgc1_regs->pll3pfdcfg, 25 << 0);
clrsetbits_le32(&cgc1_regs->nicclk, GENMASK(26, 21), 3 << 21); /* 195M */
} else if (IS_ENABLED(CONFIG_IMX8ULP_ND_MODE)) {
setbits_le32(&cgc1_regs->pll3pfdcfg, 21 << 0);
clrsetbits_le32(&cgc1_regs->nicclk, GENMASK(26, 21), 1 << 21); /* 231M */
} else {
setbits_le32(&cgc1_regs->pll3pfdcfg, 30 << 0); /* 324M */
}
clrbits_le32(&cgc1_regs->pll3pfdcfg, BIT(7));
while (!(readl(&cgc1_regs->pll3pfdcfg) & BIT(6)))
;
clrbits_le32(&cgc1_regs->pll3pfdcfg, 0x3F << 8);
setbits_le32(&cgc1_regs->pll3pfdcfg, 25 << 8);
clrbits_le32(&cgc1_regs->pll3pfdcfg, BIT(15));
while (!(readl(&cgc1_regs->pll3pfdcfg) & BIT(14)))
;
clrbits_le32(&cgc1_regs->pll3pfdcfg, 0x3F << 16);
setbits_le32(&cgc1_regs->pll3pfdcfg, 25 << 16);
clrbits_le32(&cgc1_regs->pll3pfdcfg, BIT(23));
while (!(readl(&cgc1_regs->pll3pfdcfg) & BIT(22)))
;
clrbits_le32(&cgc1_regs->pll3pfdcfg, 0x3F << 24);
setbits_le32(&cgc1_regs->pll3pfdcfg, 29 << 24);
clrbits_le32(&cgc1_regs->pll3pfdcfg, BIT(31));
while (!(readl(&cgc1_regs->pll3pfdcfg) & BIT(30)))
;
clrbits_le32(&cgc1_regs->pll3div_pfd0, BIT(7));
clrbits_le32(&cgc1_regs->pll3div_pfd0, BIT(15));
clrbits_le32(&cgc1_regs->pll3div_pfd0, BIT(23));
clrbits_le32(&cgc1_regs->pll3div_pfd0, BIT(31));
clrbits_le32(&cgc1_regs->pll3div_pfd1, BIT(7));
clrbits_le32(&cgc1_regs->pll3div_pfd1, BIT(15));
clrbits_le32(&cgc1_regs->pll3div_pfd1, BIT(23));
clrbits_le32(&cgc1_regs->pll3div_pfd1, BIT(31));
if (!IS_ENABLED(CONFIG_IMX8ULP_LD_MODE) && !IS_ENABLED(CONFIG_IMX8ULP_ND_MODE)) {
/* nicclk select pll3 pfd0 */
clrsetbits_le32(&cgc1_regs->nicclk, GENMASK(29, 28), BIT(28));
while (!(readl(&cgc1_regs->nicclk) & BIT(27)))
;
}
}
void cgc2_pll4_init(bool pll4_reset)
{
/* Check the NICLPAV first to ensure not from PLL4 PFD1 clock */
if ((readl(&cgc2_regs->niclpavclk) & GENMASK(29, 28)) == BIT(28)) {
/* switch to FRO 192 first */
clrbits_le32(&cgc2_regs->niclpavclk, GENMASK(29, 28));
while (!(readl(&cgc2_regs->niclpavclk) & BIT(27)))
;
}
/* Disable PFD DIV and clear DIV */
writel(0x80808080, &cgc2_regs->pll4div_pfd0);
writel(0x80808080, &cgc2_regs->pll4div_pfd1);
/* Gate off and clear PFD */
writel(0x80808080, &cgc2_regs->pll4pfdcfg);
if (pll4_reset) {
/* Disable PLL4 */
writel(0x0, &cgc2_regs->pll4csr);
/* Configure PLL4 to 528Mhz and clock source from SOSC */
writel(22 << 16, &cgc2_regs->pll4cfg);
writel(0x1, &cgc2_regs->pll4csr);
/* wait for PLL4 output valid */
while (!(readl(&cgc2_regs->pll4csr) & BIT(24)))
;
}
/* Enable all 4 PFDs */
setbits_le32(&cgc2_regs->pll4pfdcfg, 18 << 0); /* 528 */
if (IS_ENABLED(CONFIG_IMX8ULP_LD_MODE)) {
setbits_le32(&cgc2_regs->pll4pfdcfg, 24 << 8);
/* 99Mhz for NIC_LPAV */
clrsetbits_le32(&cgc2_regs->niclpavclk, GENMASK(26, 21), 3 << 21);
} else if (IS_ENABLED(CONFIG_IMX8ULP_ND_MODE)) {
setbits_le32(&cgc2_regs->pll4pfdcfg, 24 << 8);
/* 198Mhz for NIC_LPAV */
clrsetbits_le32(&cgc2_regs->niclpavclk, GENMASK(26, 21), 1 << 21);
} else {
setbits_le32(&cgc2_regs->pll4pfdcfg, 30 << 8); /* 316.8Mhz for NIC_LPAV */
clrbits_le32(&cgc2_regs->niclpavclk, GENMASK(26, 21));
}
setbits_le32(&cgc2_regs->pll4pfdcfg, 12 << 16); /* 792 */
setbits_le32(&cgc2_regs->pll4pfdcfg, 24 << 24); /* 396 */
clrbits_le32(&cgc2_regs->pll4pfdcfg, BIT(7) | BIT(15) | BIT(23) | BIT(31));
while ((readl(&cgc2_regs->pll4pfdcfg) & (BIT(30) | BIT(22) | BIT(14) | BIT(6)))
!= (BIT(30) | BIT(22) | BIT(14) | BIT(6)))
;
/* Enable PFD DIV */
clrbits_le32(&cgc2_regs->pll4div_pfd0, BIT(7) | BIT(15) | BIT(23) | BIT(31));
clrbits_le32(&cgc2_regs->pll4div_pfd1, BIT(7) | BIT(15) | BIT(23) | BIT(31));
clrsetbits_le32(&cgc2_regs->niclpavclk, GENMASK(29, 28), BIT(28));
while (!(readl(&cgc2_regs->niclpavclk) & BIT(27)))
;
}
void cgc2_pll4_pfd_config(enum cgc_clk pllpfd, u32 pfd)
{
void __iomem *reg = &cgc2_regs->pll4div_pfd0;
u32 halt_mask = BIT(7) | BIT(15);
u32 pfd_shift = (pllpfd - PLL4_PFD0) * 8;
u32 val;
if (pllpfd < PLL4_PFD0 || pllpfd > PLL4_PFD3)
return;
if ((pllpfd - PLL4_PFD0) >> 1)
reg = &cgc2_regs->pll4div_pfd1;
halt_mask = halt_mask << (((pllpfd - PLL4_PFD0) & 0x1) * 16);
/* halt pfd div */
setbits_le32(reg, halt_mask);
/* gate pfd */
setbits_le32(&cgc2_regs->pll4pfdcfg, BIT(7) << pfd_shift);
val = readl(&cgc2_regs->pll4pfdcfg);
val &= ~(0x3f << pfd_shift);
val |= (pfd << pfd_shift);
writel(val, &cgc2_regs->pll4pfdcfg);
/* ungate */
clrbits_le32(&cgc2_regs->pll4pfdcfg, BIT(7) << pfd_shift);
/* Wait stable */
while ((readl(&cgc2_regs->pll4pfdcfg) & (BIT(6) << pfd_shift))
!= (BIT(6) << pfd_shift))
;
/* enable pfd div */
clrbits_le32(reg, halt_mask);
}
void cgc2_pll4_pfddiv_config(enum cgc_clk pllpfddiv, u32 div)
{
void __iomem *reg = &cgc2_regs->pll4div_pfd0;
u32 shift = ((pllpfddiv - PLL4_PFD0_DIV1) & 0x3) * 8;
if (pllpfddiv < PLL4_PFD0_DIV1 || pllpfddiv > PLL4_PFD3_DIV2)
return;
if ((pllpfddiv - PLL4_PFD0_DIV1) >> 2)
reg = &cgc2_regs->pll4div_pfd1;
/* Halt pfd div */
setbits_le32(reg, BIT(7) << shift);
/* Clear div */
clrbits_le32(reg, 0x3f << shift);
/* Set div*/
setbits_le32(reg, div << shift);
/* Enable pfd div */
clrbits_le32(reg, BIT(7) << shift);
}
void cgc2_ddrclk_config(u32 src, u32 div)
{
/* If reg lock is set, wait until unlock by HW */
/* This lock is triggered by div updating and ddrclk halt status change, */
while ((readl(&cgc2_regs->ddrclk) & BIT(31)))
;
writel((src << 28) | (div << 21), &cgc2_regs->ddrclk);
/* wait for DDRCLK switching done */
while (!(readl(&cgc2_regs->ddrclk) & BIT(27)))
;
}
void cgc2_ddrclk_wait_unlock(void)
{
while ((readl(&cgc2_regs->ddrclk) & BIT(31)))
;
}
void cgc2_lpav_init(enum cgc_clk clk)
{
u32 i, scs, reg;
const enum cgc_clk src[] = {FRO, PLL4_PFD1, SOSC, LVDS};
reg = readl(&cgc2_regs->niclpavclk);
scs = (reg >> 28) & 0x3;
for (i = 0; i < 4; i++) {
if (clk == src[i]) {
if (scs == i)
return;
reg &= ~(0x3 << 28);
reg |= (i << 28);
writel(reg, &cgc2_regs->niclpavclk);
break;
}
}
if (i == 4)
printf("Invalid clock source [%u] for LPAV\n", clk);
}
u32 cgc2_nic_get_rate(enum cgc_clk clk)
{
u32 reg, rate;
u32 scs, lpav_axi_clk, lpav_ahb_clk, lpav_bus_clk;
const enum cgc_clk src[] = {FRO, PLL4_PFD1, SOSC, LVDS};
reg = readl(&cgc2_regs->niclpavclk);
scs = (reg >> 28) & 0x3;
lpav_axi_clk = ((reg >> 21) & 0x3f) + 1;
lpav_ahb_clk = ((reg >> 14) & 0x3f) + 1;
lpav_bus_clk = ((reg >> 7) & 0x3f) + 1;
rate = cgc_clk_get_rate(src[scs]);
switch (clk) {
case LPAV_AXICLK:
rate = rate / lpav_axi_clk;
break;
case LPAV_AHBCLK:
rate = rate / (lpav_axi_clk * lpav_ahb_clk);
break;
case LPAV_BUSCLK:
rate = rate / (lpav_axi_clk * lpav_bus_clk);
break;
default:
return 0;
}
return rate;
}
u32 decode_pll(enum cgc_clk pll)
{
u32 reg, infreq, mult;
u32 num, denom;
infreq = 24000000U;
/*
* Alought there are four choices for the bypass src,
* we choose SOSC 24M which is the default set in ROM.
* TODO: check more the comments
*/
switch (pll) {
case PLL2:
reg = readl(&cgc1_regs->pll2csr);
if (!(reg & BIT(24)))
return 0;
reg = readl(&cgc1_regs->pll2cfg);
mult = (reg >> 16) & 0x7F;
denom = readl(&cgc1_regs->pll2denom) & 0x3FFFFFFF;
num = readl(&cgc1_regs->pll2num) & 0x3FFFFFFF;
return (u64)infreq * mult + (u64)infreq * num / denom;
case PLL3:
reg = readl(&cgc1_regs->pll3csr);
if (!(reg & BIT(24)))
return 0;
reg = readl(&cgc1_regs->pll3cfg);
mult = (reg >> 16) & 0x7F;
denom = readl(&cgc1_regs->pll3denom) & 0x3FFFFFFF;
num = readl(&cgc1_regs->pll3num) & 0x3FFFFFFF;
return (u64)infreq * mult + (u64)infreq * num / denom;
case PLL4:
reg = readl(&cgc2_regs->pll4csr);
if (!(reg & BIT(24)))
return 0;
reg = readl(&cgc2_regs->pll4cfg);
mult = (reg >> 16) & 0x7F;
denom = readl(&cgc2_regs->pll4denom) & 0x3FFFFFFF;
num = readl(&cgc2_regs->pll4num) & 0x3FFFFFFF;
return (u64)infreq * mult + (u64)infreq * num / denom;
default:
printf("Unsupported pll clocks %d\n", pll);
break;
}
return 0;
}
u32 cgc_pll_vcodiv_rate(enum cgc_clk clk)
{
u32 reg, gate, div;
void __iomem *plldiv_vco;
enum cgc_clk pll;
if (clk == PLL3_VCODIV) {
plldiv_vco = &cgc1_regs->pll3div_vco;
pll = PLL3;
} else {
plldiv_vco = &cgc2_regs->pll4div_vco;
pll = PLL4;
}
reg = readl(plldiv_vco);
gate = BIT(7) & reg;
div = reg & 0x3F;
return gate ? 0 : decode_pll(pll) / (div + 1);
}
u32 cgc_pll_pfd_rate(enum cgc_clk clk)
{
u32 index, gate, vld, reg;
void __iomem *pllpfdcfg;
enum cgc_clk pll;
switch (clk) {
case PLL3_PFD0:
case PLL3_PFD1:
case PLL3_PFD2:
case PLL3_PFD3:
index = clk - PLL3_PFD0;
pllpfdcfg = &cgc1_regs->pll3pfdcfg;
pll = PLL3;
break;
case PLL4_PFD0:
case PLL4_PFD1:
case PLL4_PFD2:
case PLL4_PFD3:
index = clk - PLL4_PFD0;
pllpfdcfg = &cgc2_regs->pll4pfdcfg;
pll = PLL4;
break;
default:
return 0;
}
reg = readl(pllpfdcfg);
gate = reg & (BIT(7) << (index * 8));
vld = reg & (BIT(6) << (index * 8));
if (gate || !vld)
return 0;
return (u64)decode_pll(pll) * 18 / ((reg >> (index * 8)) & 0x3F);
}
u32 cgc_pll_pfd_div(enum cgc_clk clk)
{
void __iomem *base;
u32 pfd, index, gate, reg;
switch (clk) {
case PLL3_PFD0_DIV1:
case PLL3_PFD0_DIV2:
base = &cgc1_regs->pll3div_pfd0;
pfd = PLL3_PFD0;
index = clk - PLL3_PFD0_DIV1;
break;
case PLL3_PFD1_DIV1:
case PLL3_PFD1_DIV2:
base = &cgc1_regs->pll3div_pfd0;
pfd = PLL3_PFD1;
index = clk - PLL3_PFD0_DIV1;
break;
case PLL3_PFD2_DIV1:
case PLL3_PFD2_DIV2:
base = &cgc1_regs->pll3div_pfd1;
pfd = PLL3_PFD2;
index = clk - PLL3_PFD2_DIV1;
break;
case PLL3_PFD3_DIV1:
case PLL3_PFD3_DIV2:
base = &cgc1_regs->pll3div_pfd1;
pfd = PLL3_PFD3;
index = clk - PLL3_PFD2_DIV1;
break;
case PLL4_PFD0_DIV1:
case PLL4_PFD0_DIV2:
base = &cgc2_regs->pll4div_pfd0;
pfd = PLL4_PFD0;
index = clk - PLL4_PFD0_DIV1;
break;
case PLL4_PFD1_DIV1:
case PLL4_PFD1_DIV2:
base = &cgc2_regs->pll4div_pfd0;
pfd = PLL4_PFD1;
index = clk - PLL4_PFD0_DIV1;
break;
case PLL4_PFD2_DIV1:
case PLL4_PFD2_DIV2:
base = &cgc2_regs->pll4div_pfd1;
pfd = PLL4_PFD2;
index = clk - PLL4_PFD2_DIV1;
break;
case PLL4_PFD3_DIV1:
case PLL4_PFD3_DIV2:
base = &cgc2_regs->pll4div_pfd1;
pfd = PLL4_PFD3;
index = clk - PLL4_PFD2_DIV1;
break;
default:
return 0;
}
reg = readl(base);
gate = reg & (BIT(7) << (index * 8));
if (gate)
return 0;
return cgc_pll_pfd_rate(pfd) / (((reg >> (index * 8)) & 0x3F) + 1);
}
u32 cgc1_nic_get_rate(enum cgc_clk clk)
{
u32 reg, rate;
u32 scs, nic_ad_divplat, nic_per_divplat;
u32 xbar_ad_divplat, xbar_divbus, ad_slow;
const enum cgc_clk src[] = {FRO, PLL3_PFD0, SOSC, LVDS};
reg = readl(&cgc1_regs->nicclk);
scs = (reg >> 28) & 0x3;
nic_ad_divplat = ((reg >> 21) & 0x3f) + 1;
nic_per_divplat = ((reg >> 14) & 0x3f) + 1;
reg = readl(&cgc1_regs->xbarclk);
xbar_ad_divplat = ((reg >> 14) & 0x3f) + 1;
xbar_divbus = ((reg >> 7) & 0x3f) + 1;
ad_slow = (reg & 0x3f) + 1;
rate = cgc_clk_get_rate(src[scs]);
switch (clk) {
case NIC_APCLK:
rate = rate / nic_ad_divplat;
break;
case NIC_PERCLK:
rate = rate / (nic_ad_divplat * nic_per_divplat);
break;
case XBAR_APCLK:
rate = rate / (nic_ad_divplat * xbar_ad_divplat);
break;
case XBAR_BUSCLK:
rate = rate / (nic_ad_divplat * xbar_ad_divplat * xbar_divbus);
break;
case AD_SLOWCLK:
rate = rate / (nic_ad_divplat * xbar_ad_divplat * ad_slow);
break;
default:
return 0;
}
return rate;
}
u32 cgc1_sosc_div(enum cgc_clk clk)
{
u32 reg, gate, index;
switch (clk) {
case SOSC:
return 24000000;
case SOSC_DIV1:
index = 0;
break;
case SOSC_DIV2:
index = 1;
break;
case SOSC_DIV3:
index = 2;
break;
default:
return 0;
}
reg = readl(&cgc1_regs->soscdiv);
gate = reg & (BIT(7) << (index * 8));
if (gate)
return 0;
return 24000000 / (((reg >> (index * 8)) & 0x3F) + 1);
}
u32 cgc1_fro_div(enum cgc_clk clk)
{
u32 reg, gate, vld, index;
switch (clk) {
case FRO:
return 192000000;
case FRO_DIV1:
index = 0;
break;
case FRO_DIV2:
index = 1;
break;
case FRO_DIV3:
index = 2;
break;
default:
return 0;
}
reg = readl(&cgc1_regs->frodiv);
gate = reg & (BIT(7) << (index * 8));
vld = reg & (BIT(6) << (index * 8));
if (gate || !vld)
return 0;
return 24000000 / (((reg >> (index * 8)) & 0x3F) + 1);
}
u32 cgc_clk_get_rate(enum cgc_clk clk)
{
switch (clk) {
case LVDS:
return 0; /* No external LVDS clock used */
case SOSC:
case SOSC_DIV1:
case SOSC_DIV2:
case SOSC_DIV3:
return cgc1_sosc_div(clk);
case FRO:
case FRO_DIV1:
case FRO_DIV2:
case FRO_DIV3:
return cgc1_fro_div(clk);
case PLL2:
case PLL3:
case PLL4:
return decode_pll(clk);
case PLL3_VCODIV:
case PLL4_VCODIV:
return cgc_pll_vcodiv_rate(clk);
case PLL3_PFD0:
case PLL3_PFD1:
case PLL3_PFD2:
case PLL3_PFD3:
case PLL4_PFD0:
case PLL4_PFD1:
case PLL4_PFD2:
case PLL4_PFD3:
return cgc_pll_pfd_rate(clk);
case PLL3_PFD0_DIV1:
case PLL3_PFD0_DIV2:
case PLL3_PFD1_DIV1:
case PLL3_PFD1_DIV2:
case PLL3_PFD2_DIV1:
case PLL3_PFD2_DIV2:
case PLL3_PFD3_DIV1:
case PLL3_PFD3_DIV2:
case PLL4_PFD0_DIV1:
case PLL4_PFD0_DIV2:
case PLL4_PFD1_DIV1:
case PLL4_PFD1_DIV2:
case PLL4_PFD2_DIV1:
case PLL4_PFD2_DIV2:
case PLL4_PFD3_DIV1:
case PLL4_PFD3_DIV2:
return cgc_pll_pfd_div(clk);
case NIC_APCLK:
case NIC_PERCLK:
case XBAR_APCLK:
case XBAR_BUSCLK:
case AD_SLOWCLK:
return cgc1_nic_get_rate(clk);
case LPAV_AXICLK:
case LPAV_AHBCLK:
case LPAV_BUSCLK:
return cgc2_nic_get_rate(clk);
default:
printf("Unsupported cgc clock: %d\n", clk);
return 0;
}
}