upstream u-boot with additional patches for our devices/boards: https://lists.denx.de/pipermail/u-boot/2017-March/282789.html (AXP crashes) ; Gbit ethernet patch for some LIME2 revisions ; with SPI flash support
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u-boot/arch/arm/mach-imx/mx7ulp/scg.c

1087 lines
26 KiB

// SPDX-License-Identifier: GPL-2.0+
/*
* Copyright (C) 2016 Freescale Semiconductor, Inc.
*/
#include <common.h>
#include <div64.h>
#include <asm/io.h>
#include <errno.h>
#include <asm/arch/imx-regs.h>
#include <asm/arch/pcc.h>
#include <asm/arch/sys_proto.h>
scg_p scg1_regs = (scg_p)SCG1_RBASE;
static u32 scg_src_get_rate(enum scg_clk clksrc)
{
u32 reg;
switch (clksrc) {
case SCG_SOSC_CLK:
reg = readl(&scg1_regs->sosccsr);
if (!(reg & SCG_SOSC_CSR_SOSCVLD_MASK))
return 0;
return 24000000;
case SCG_FIRC_CLK:
reg = readl(&scg1_regs->firccsr);
if (!(reg & SCG_FIRC_CSR_FIRCVLD_MASK))
return 0;
return 48000000;
case SCG_SIRC_CLK:
reg = readl(&scg1_regs->sirccsr);
if (!(reg & SCG_SIRC_CSR_SIRCVLD_MASK))
return 0;
return 16000000;
case SCG_ROSC_CLK:
reg = readl(&scg1_regs->rtccsr);
if (!(reg & SCG_ROSC_CSR_ROSCVLD_MASK))
return 0;
return 32768;
default:
break;
}
return 0;
}
static u32 scg_sircdiv_get_rate(enum scg_clk clk)
{
u32 reg, val, rate;
u32 shift, mask;
switch (clk) {
case SCG_SIRC_DIV1_CLK:
mask = SCG_SIRCDIV_DIV1_MASK;
shift = SCG_SIRCDIV_DIV1_SHIFT;
break;
case SCG_SIRC_DIV2_CLK:
mask = SCG_SIRCDIV_DIV2_MASK;
shift = SCG_SIRCDIV_DIV2_SHIFT;
break;
case SCG_SIRC_DIV3_CLK:
mask = SCG_SIRCDIV_DIV3_MASK;
shift = SCG_SIRCDIV_DIV3_SHIFT;
break;
default:
return 0;
}
reg = readl(&scg1_regs->sirccsr);
if (!(reg & SCG_SIRC_CSR_SIRCVLD_MASK))
return 0;
reg = readl(&scg1_regs->sircdiv);
val = (reg & mask) >> shift;
if (!val) /*clock disabled*/
return 0;
rate = scg_src_get_rate(SCG_SIRC_CLK);
rate = rate / (1 << (val - 1));
return rate;
}
static u32 scg_fircdiv_get_rate(enum scg_clk clk)
{
u32 reg, val, rate;
u32 shift, mask;
switch (clk) {
case SCG_FIRC_DIV1_CLK:
mask = SCG_FIRCDIV_DIV1_MASK;
shift = SCG_FIRCDIV_DIV1_SHIFT;
break;
case SCG_FIRC_DIV2_CLK:
mask = SCG_FIRCDIV_DIV2_MASK;
shift = SCG_FIRCDIV_DIV2_SHIFT;
break;
case SCG_FIRC_DIV3_CLK:
mask = SCG_FIRCDIV_DIV3_MASK;
shift = SCG_FIRCDIV_DIV3_SHIFT;
break;
default:
return 0;
}
reg = readl(&scg1_regs->firccsr);
if (!(reg & SCG_FIRC_CSR_FIRCVLD_MASK))
return 0;
reg = readl(&scg1_regs->fircdiv);
val = (reg & mask) >> shift;
if (!val) /*clock disabled*/
return 0;
rate = scg_src_get_rate(SCG_FIRC_CLK);
rate = rate / (1 << (val - 1));
return rate;
}
static u32 scg_soscdiv_get_rate(enum scg_clk clk)
{
u32 reg, val, rate;
u32 shift, mask;
switch (clk) {
case SCG_SOSC_DIV1_CLK:
mask = SCG_SOSCDIV_DIV1_MASK;
shift = SCG_SOSCDIV_DIV1_SHIFT;
break;
case SCG_SOSC_DIV2_CLK:
mask = SCG_SOSCDIV_DIV2_MASK;
shift = SCG_SOSCDIV_DIV2_SHIFT;
break;
case SCG_SOSC_DIV3_CLK:
mask = SCG_SOSCDIV_DIV3_MASK;
shift = SCG_SOSCDIV_DIV3_SHIFT;
break;
default:
return 0;
}
reg = readl(&scg1_regs->sosccsr);
if (!(reg & SCG_SOSC_CSR_SOSCVLD_MASK))
return 0;
reg = readl(&scg1_regs->soscdiv);
val = (reg & mask) >> shift;
if (!val) /*clock disabled*/
return 0;
rate = scg_src_get_rate(SCG_SOSC_CLK);
rate = rate / (1 << (val - 1));
return rate;
}
static u32 scg_apll_pfd_get_rate(enum scg_clk clk)
{
u32 reg, val, rate;
u32 shift, mask, gate, valid;
switch (clk) {
case SCG_APLL_PFD0_CLK:
gate = SCG_PLL_PFD0_GATE_MASK;
valid = SCG_PLL_PFD0_VALID_MASK;
mask = SCG_PLL_PFD0_FRAC_MASK;
shift = SCG_PLL_PFD0_FRAC_SHIFT;
break;
case SCG_APLL_PFD1_CLK:
gate = SCG_PLL_PFD1_GATE_MASK;
valid = SCG_PLL_PFD1_VALID_MASK;
mask = SCG_PLL_PFD1_FRAC_MASK;
shift = SCG_PLL_PFD1_FRAC_SHIFT;
break;
case SCG_APLL_PFD2_CLK:
gate = SCG_PLL_PFD2_GATE_MASK;
valid = SCG_PLL_PFD2_VALID_MASK;
mask = SCG_PLL_PFD2_FRAC_MASK;
shift = SCG_PLL_PFD2_FRAC_SHIFT;
break;
case SCG_APLL_PFD3_CLK:
gate = SCG_PLL_PFD3_GATE_MASK;
valid = SCG_PLL_PFD3_VALID_MASK;
mask = SCG_PLL_PFD3_FRAC_MASK;
shift = SCG_PLL_PFD3_FRAC_SHIFT;
break;
default:
return 0;
}
reg = readl(&scg1_regs->apllpfd);
if (reg & gate || !(reg & valid))
return 0;
clk_debug("scg_apll_pfd_get_rate reg 0x%x\n", reg);
val = (reg & mask) >> shift;
rate = decode_pll(PLL_A7_APLL);
rate = rate / val * 18;
clk_debug("scg_apll_pfd_get_rate rate %u\n", rate);
return rate;
}
static u32 scg_spll_pfd_get_rate(enum scg_clk clk)
{
u32 reg, val, rate;
u32 shift, mask, gate, valid;
switch (clk) {
case SCG_SPLL_PFD0_CLK:
gate = SCG_PLL_PFD0_GATE_MASK;
valid = SCG_PLL_PFD0_VALID_MASK;
mask = SCG_PLL_PFD0_FRAC_MASK;
shift = SCG_PLL_PFD0_FRAC_SHIFT;
break;
case SCG_SPLL_PFD1_CLK:
gate = SCG_PLL_PFD1_GATE_MASK;
valid = SCG_PLL_PFD1_VALID_MASK;
mask = SCG_PLL_PFD1_FRAC_MASK;
shift = SCG_PLL_PFD1_FRAC_SHIFT;
break;
case SCG_SPLL_PFD2_CLK:
gate = SCG_PLL_PFD2_GATE_MASK;
valid = SCG_PLL_PFD2_VALID_MASK;
mask = SCG_PLL_PFD2_FRAC_MASK;
shift = SCG_PLL_PFD2_FRAC_SHIFT;
break;
case SCG_SPLL_PFD3_CLK:
gate = SCG_PLL_PFD3_GATE_MASK;
valid = SCG_PLL_PFD3_VALID_MASK;
mask = SCG_PLL_PFD3_FRAC_MASK;
shift = SCG_PLL_PFD3_FRAC_SHIFT;
break;
default:
return 0;
}
reg = readl(&scg1_regs->spllpfd);
if (reg & gate || !(reg & valid))
return 0;
clk_debug("scg_spll_pfd_get_rate reg 0x%x\n", reg);
val = (reg & mask) >> shift;
rate = decode_pll(PLL_A7_SPLL);
rate = rate / val * 18;
clk_debug("scg_spll_pfd_get_rate rate %u\n", rate);
return rate;
}
static u32 scg_apll_get_rate(void)
{
u32 reg, val, rate;
reg = readl(&scg1_regs->apllcfg);
val = (reg & SCG_PLL_CFG_PLLSEL_MASK) >> SCG_PLL_CFG_PLLSEL_SHIFT;
if (!val) {
/* APLL clock after two dividers */
rate = decode_pll(PLL_A7_APLL);
val = (reg & SCG_PLL_CFG_POSTDIV1_MASK) >>
SCG_PLL_CFG_POSTDIV1_SHIFT;
rate = rate / (val + 1);
val = (reg & SCG_PLL_CFG_POSTDIV2_MASK) >>
SCG_PLL_CFG_POSTDIV2_SHIFT;
rate = rate / (val + 1);
} else {
/* APLL PFD clock */
val = (reg & SCG_PLL_CFG_PFDSEL_MASK) >>
SCG_PLL_CFG_PFDSEL_SHIFT;
rate = scg_apll_pfd_get_rate(SCG_APLL_PFD0_CLK + val);
}
return rate;
}
static u32 scg_spll_get_rate(void)
{
u32 reg, val, rate;
reg = readl(&scg1_regs->spllcfg);
val = (reg & SCG_PLL_CFG_PLLSEL_MASK) >> SCG_PLL_CFG_PLLSEL_SHIFT;
clk_debug("scg_spll_get_rate reg 0x%x\n", reg);
if (!val) {
/* APLL clock after two dividers */
rate = decode_pll(PLL_A7_SPLL);
val = (reg & SCG_PLL_CFG_POSTDIV1_MASK) >>
SCG_PLL_CFG_POSTDIV1_SHIFT;
rate = rate / (val + 1);
val = (reg & SCG_PLL_CFG_POSTDIV2_MASK) >>
SCG_PLL_CFG_POSTDIV2_SHIFT;
rate = rate / (val + 1);
clk_debug("scg_spll_get_rate SPLL %u\n", rate);
} else {
/* APLL PFD clock */
val = (reg & SCG_PLL_CFG_PFDSEL_MASK) >>
SCG_PLL_CFG_PFDSEL_SHIFT;
rate = scg_spll_pfd_get_rate(SCG_SPLL_PFD0_CLK + val);
clk_debug("scg_spll_get_rate PFD %u\n", rate);
}
return rate;
}
static u32 scg_ddr_get_rate(void)
{
u32 reg, val, rate, div;
reg = readl(&scg1_regs->ddrccr);
val = (reg & SCG_DDRCCR_DDRCS_MASK) >> SCG_DDRCCR_DDRCS_SHIFT;
div = (reg & SCG_DDRCCR_DDRDIV_MASK) >> SCG_DDRCCR_DDRDIV_SHIFT;
if (!div)
return 0;
if (!val) {
reg = readl(&scg1_regs->apllcfg);
val = (reg & SCG_PLL_CFG_PFDSEL_MASK) >>
SCG_PLL_CFG_PFDSEL_SHIFT;
rate = scg_apll_pfd_get_rate(SCG_APLL_PFD0_CLK + val);
} else {
rate = decode_pll(PLL_USB);
}
rate = rate / (1 << (div - 1));
return rate;
}
static u32 scg_nic_get_rate(enum scg_clk clk)
{
u32 reg, val, rate;
u32 shift, mask;
reg = readl(&scg1_regs->niccsr);
val = (reg & SCG_NICCSR_NICCS_MASK) >> SCG_NICCSR_NICCS_SHIFT;
clk_debug("scg_nic_get_rate niccsr 0x%x\n", reg);
if (!val)
rate = scg_src_get_rate(SCG_FIRC_CLK);
else
rate = scg_ddr_get_rate();
clk_debug("scg_nic_get_rate parent rate %u\n", rate);
val = (reg & SCG_NICCSR_NIC0DIV_MASK) >> SCG_NICCSR_NIC0DIV_SHIFT;
rate = rate / (val + 1);
clk_debug("scg_nic_get_rate NIC0 rate %u\n", rate);
switch (clk) {
case SCG_NIC0_CLK:
return rate;
case SCG_GPU_CLK:
mask = SCG_NICCSR_GPUDIV_MASK;
shift = SCG_NICCSR_GPUDIV_SHIFT;
break;
case SCG_NIC1_EXT_CLK:
case SCG_NIC1_BUS_CLK:
case SCG_NIC1_CLK:
mask = SCG_NICCSR_NIC1DIV_MASK;
shift = SCG_NICCSR_NIC1DIV_SHIFT;
break;
default:
return 0;
}
val = (reg & mask) >> shift;
rate = rate / (val + 1);
clk_debug("scg_nic_get_rate NIC1 rate %u\n", rate);
switch (clk) {
case SCG_GPU_CLK:
case SCG_NIC1_CLK:
return rate;
case SCG_NIC1_EXT_CLK:
mask = SCG_NICCSR_NIC1EXTDIV_MASK;
shift = SCG_NICCSR_NIC1EXTDIV_SHIFT;
break;
case SCG_NIC1_BUS_CLK:
mask = SCG_NICCSR_NIC1BUSDIV_MASK;
shift = SCG_NICCSR_NIC1BUSDIV_SHIFT;
break;
default:
return 0;
}
val = (reg & mask) >> shift;
rate = rate / (val + 1);
clk_debug("scg_nic_get_rate NIC1 bus rate %u\n", rate);
return rate;
}
static enum scg_clk scg_scs_array[4] = {
SCG_SOSC_CLK, SCG_SIRC_CLK, SCG_FIRC_CLK, SCG_ROSC_CLK,
};
static u32 scg_sys_get_rate(enum scg_clk clk)
{
u32 reg, val, rate;
if (clk != SCG_CORE_CLK && clk != SCG_BUS_CLK)
return 0;
reg = readl(&scg1_regs->csr);
val = (reg & SCG_CCR_SCS_MASK) >> SCG_CCR_SCS_SHIFT;
clk_debug("scg_sys_get_rate reg 0x%x\n", reg);
switch (val) {
case SCG_SCS_SYS_OSC:
case SCG_SCS_SLOW_IRC:
case SCG_SCS_FAST_IRC:
case SCG_SCS_RTC_OSC:
rate = scg_src_get_rate(scg_scs_array[val]);
break;
case 5:
rate = scg_apll_get_rate();
break;
case 6:
rate = scg_spll_get_rate();
break;
default:
return 0;
}
clk_debug("scg_sys_get_rate parent rate %u\n", rate);
val = (reg & SCG_CCR_DIVCORE_MASK) >> SCG_CCR_DIVCORE_SHIFT;
rate = rate / (val + 1);
if (clk == SCG_BUS_CLK) {
val = (reg & SCG_CCR_DIVBUS_MASK) >> SCG_CCR_DIVBUS_SHIFT;
rate = rate / (val + 1);
}
return rate;
}
u32 decode_pll(enum pll_clocks pll)
{
u32 reg, pre_div, infreq, mult;
u32 num, denom;
/*
* Alought there are four choices for the bypass src,
* we choose OSC_24M which is the default set in ROM.
*/
switch (pll) {
case PLL_A7_SPLL:
reg = readl(&scg1_regs->spllcsr);
if (!(reg & SCG_SPLL_CSR_SPLLVLD_MASK))
return 0;
reg = readl(&scg1_regs->spllcfg);
pre_div = (reg & SCG_PLL_CFG_PREDIV_MASK) >>
SCG_PLL_CFG_PREDIV_SHIFT;
pre_div += 1;
mult = (reg & SCG1_SPLL_CFG_MULT_MASK) >>
SCG_PLL_CFG_MULT_SHIFT;
infreq = (reg & SCG_PLL_CFG_CLKSRC_MASK) >>
SCG_PLL_CFG_CLKSRC_SHIFT;
if (!infreq)
infreq = scg_src_get_rate(SCG_SOSC_CLK);
else
infreq = scg_src_get_rate(SCG_FIRC_CLK);
num = readl(&scg1_regs->spllnum);
denom = readl(&scg1_regs->splldenom);
infreq = infreq / pre_div;
return infreq * mult + infreq * num / denom;
case PLL_A7_APLL:
reg = readl(&scg1_regs->apllcsr);
if (!(reg & SCG_APLL_CSR_APLLVLD_MASK))
return 0;
reg = readl(&scg1_regs->apllcfg);
pre_div = (reg & SCG_PLL_CFG_PREDIV_MASK) >>
SCG_PLL_CFG_PREDIV_SHIFT;
pre_div += 1;
mult = (reg & SCG_APLL_CFG_MULT_MASK) >>
SCG_PLL_CFG_MULT_SHIFT;
infreq = (reg & SCG_PLL_CFG_CLKSRC_MASK) >>
SCG_PLL_CFG_CLKSRC_SHIFT;
if (!infreq)
infreq = scg_src_get_rate(SCG_SOSC_CLK);
else
infreq = scg_src_get_rate(SCG_FIRC_CLK);
num = readl(&scg1_regs->apllnum);
denom = readl(&scg1_regs->aplldenom);
infreq = infreq / pre_div;
return infreq * mult + infreq * num / denom;
case PLL_USB:
reg = readl(&scg1_regs->upllcsr);
if (!(reg & SCG_UPLL_CSR_UPLLVLD_MASK))
return 0;
return 480000000u;
case PLL_MIPI:
return 480000000u;
default:
printf("Unsupported pll clocks %d\n", pll);
break;
}
return 0;
}
u32 scg_clk_get_rate(enum scg_clk clk)
{
switch (clk) {
case SCG_SIRC_DIV1_CLK:
case SCG_SIRC_DIV2_CLK:
case SCG_SIRC_DIV3_CLK:
return scg_sircdiv_get_rate(clk);
case SCG_FIRC_DIV1_CLK:
case SCG_FIRC_DIV2_CLK:
case SCG_FIRC_DIV3_CLK:
return scg_fircdiv_get_rate(clk);
case SCG_SOSC_DIV1_CLK:
case SCG_SOSC_DIV2_CLK:
case SCG_SOSC_DIV3_CLK:
return scg_soscdiv_get_rate(clk);
case SCG_CORE_CLK:
case SCG_BUS_CLK:
return scg_sys_get_rate(clk);
case SCG_SPLL_PFD0_CLK:
case SCG_SPLL_PFD1_CLK:
case SCG_SPLL_PFD2_CLK:
case SCG_SPLL_PFD3_CLK:
return scg_spll_pfd_get_rate(clk);
case SCG_APLL_PFD0_CLK:
case SCG_APLL_PFD1_CLK:
case SCG_APLL_PFD2_CLK:
case SCG_APLL_PFD3_CLK:
return scg_apll_pfd_get_rate(clk);
case SCG_DDR_CLK:
return scg_ddr_get_rate();
case SCG_NIC0_CLK:
case SCG_GPU_CLK:
case SCG_NIC1_CLK:
case SCG_NIC1_BUS_CLK:
case SCG_NIC1_EXT_CLK:
return scg_nic_get_rate(clk);
case USB_PLL_OUT:
return decode_pll(PLL_USB);
case MIPI_PLL_OUT:
return decode_pll(PLL_MIPI);
case SCG_SOSC_CLK:
case SCG_FIRC_CLK:
case SCG_SIRC_CLK:
case SCG_ROSC_CLK:
return scg_src_get_rate(clk);
default:
return 0;
}
}
int scg_enable_pll_pfd(enum scg_clk clk, u32 frac)
{
u32 reg;
u32 shift, mask, gate, valid;
u32 addr;
if (frac < 12 || frac > 35)
return -EINVAL;
switch (clk) {
case SCG_SPLL_PFD0_CLK:
case SCG_APLL_PFD0_CLK:
gate = SCG_PLL_PFD0_GATE_MASK;
valid = SCG_PLL_PFD0_VALID_MASK;
mask = SCG_PLL_PFD0_FRAC_MASK;
shift = SCG_PLL_PFD0_FRAC_SHIFT;
if (clk == SCG_SPLL_PFD0_CLK)
addr = (u32)(&scg1_regs->spllpfd);
else
addr = (u32)(&scg1_regs->apllpfd);
break;
case SCG_SPLL_PFD1_CLK:
case SCG_APLL_PFD1_CLK:
gate = SCG_PLL_PFD1_GATE_MASK;
valid = SCG_PLL_PFD1_VALID_MASK;
mask = SCG_PLL_PFD1_FRAC_MASK;
shift = SCG_PLL_PFD1_FRAC_SHIFT;
if (clk == SCG_SPLL_PFD1_CLK)
addr = (u32)(&scg1_regs->spllpfd);
else
addr = (u32)(&scg1_regs->apllpfd);
break;
case SCG_SPLL_PFD2_CLK:
case SCG_APLL_PFD2_CLK:
gate = SCG_PLL_PFD2_GATE_MASK;
valid = SCG_PLL_PFD2_VALID_MASK;
mask = SCG_PLL_PFD2_FRAC_MASK;
shift = SCG_PLL_PFD2_FRAC_SHIFT;
if (clk == SCG_SPLL_PFD2_CLK)
addr = (u32)(&scg1_regs->spllpfd);
else
addr = (u32)(&scg1_regs->apllpfd);
break;
case SCG_SPLL_PFD3_CLK:
case SCG_APLL_PFD3_CLK:
gate = SCG_PLL_PFD3_GATE_MASK;
valid = SCG_PLL_PFD3_VALID_MASK;
mask = SCG_PLL_PFD3_FRAC_MASK;
shift = SCG_PLL_PFD3_FRAC_SHIFT;
if (clk == SCG_SPLL_PFD3_CLK)
addr = (u32)(&scg1_regs->spllpfd);
else
addr = (u32)(&scg1_regs->apllpfd);
break;
default:
return -EINVAL;
}
/* Gate the PFD */
reg = readl(addr);
reg |= gate;
writel(reg, addr);
/* Write Frac divider */
reg &= ~mask;
reg |= (frac << shift) & mask;
writel(reg, addr);
/*
* Un-gate the PFD
* (Need un-gate before checking valid, not align with RM)
*/
reg &= ~gate;
writel(reg, addr);
/* Wait for PFD clock being valid */
do {
reg = readl(addr);
} while (!(reg & valid));
return 0;
}
#define SIM_MISC_CTRL0_USB_PLL_EN_MASK (0x1 << 2)
int scg_enable_usb_pll(bool usb_control)
{
u32 sosc_rate;
s32 timeout = 1000000;
u32 reg;
struct usbphy_regs *usbphy =
(struct usbphy_regs *)USBPHY_RBASE;
sosc_rate = scg_src_get_rate(SCG_SOSC_CLK);
if (!sosc_rate)
return -EPERM;
reg = readl(SIM0_RBASE + 0x3C);
if (usb_control)
reg &= ~SIM_MISC_CTRL0_USB_PLL_EN_MASK;
else
reg |= SIM_MISC_CTRL0_USB_PLL_EN_MASK;
writel(reg, SIM0_RBASE + 0x3C);
if (!(readl(&usbphy->usb1_pll_480_ctrl) & PLL_USB_LOCK_MASK)) {
writel(0x1c00000, &usbphy->usb1_pll_480_ctrl_clr);
switch (sosc_rate) {
case 24000000:
writel(0xc00000, &usbphy->usb1_pll_480_ctrl_set);
break;
case 30000000:
writel(0x800000, &usbphy->usb1_pll_480_ctrl_set);
break;
case 19200000:
writel(0x1400000, &usbphy->usb1_pll_480_ctrl_set);
break;
default:
writel(0xc00000, &usbphy->usb1_pll_480_ctrl_set);
break;
}
/* Enable the regulator first */
writel(PLL_USB_REG_ENABLE_MASK,
&usbphy->usb1_pll_480_ctrl_set);
/* Wait at least 15us */
udelay(15);
/* Enable the power */
writel(PLL_USB_PWR_MASK, &usbphy->usb1_pll_480_ctrl_set);
/* Wait lock */
while (timeout--) {
if (readl(&usbphy->usb1_pll_480_ctrl) &
PLL_USB_LOCK_MASK)
break;
}
if (timeout <= 0) {
/* If timeout, we power down the pll */
writel(PLL_USB_PWR_MASK,
&usbphy->usb1_pll_480_ctrl_clr);
return -ETIME;
}
}
/* Clear the bypass */
writel(PLL_USB_BYPASS_MASK, &usbphy->usb1_pll_480_ctrl_clr);
/* Enable the PLL clock out to USB */
writel((PLL_USB_EN_USB_CLKS_MASK | PLL_USB_ENABLE_MASK),
&usbphy->usb1_pll_480_ctrl_set);
if (!usb_control) {
while (timeout--) {
if (readl(&scg1_regs->upllcsr) &
SCG_UPLL_CSR_UPLLVLD_MASK)
break;
}
if (timeout <= 0) {
reg = readl(SIM0_RBASE + 0x3C);
reg &= ~SIM_MISC_CTRL0_USB_PLL_EN_MASK;
writel(reg, SIM0_RBASE + 0x3C);
return -ETIME;
}
}
return 0;
}
/* A7 domain system clock source is SPLL */
#define SCG1_RCCR_SCS_NUM ((SCG_SCS_SYS_PLL) << SCG_CCR_SCS_SHIFT)
/* A7 Core clck = SPLL PFD0 / 1 = 500MHz / 1 = 500MHz */
#define SCG1_RCCR_DIVCORE_NUM ((0x0) << SCG_CCR_DIVCORE_SHIFT)
#define SCG1_RCCR_CFG_MASK (SCG_CCR_SCS_MASK | SCG_CCR_DIVBUS_MASK)
/* A7 Plat clck = A7 Core Clock / 2 = 250MHz / 1 = 250MHz */
#define SCG1_RCCR_DIVBUS_NUM ((0x1) << SCG_CCR_DIVBUS_SHIFT)
#define SCG1_RCCR_CFG_NUM (SCG1_RCCR_SCS_NUM | SCG1_RCCR_DIVBUS_NUM)
void scg_a7_rccr_init(void)
{
u32 rccr_reg_val = 0;
rccr_reg_val = readl(&scg1_regs->rccr);
rccr_reg_val &= (~SCG1_RCCR_CFG_MASK);
rccr_reg_val |= (SCG1_RCCR_CFG_NUM);
writel(rccr_reg_val, &scg1_regs->rccr);
}
/* POSTDIV2 = 1 */
#define SCG1_SPLL_CFG_POSTDIV2_NUM ((0x0) << SCG_PLL_CFG_POSTDIV2_SHIFT)
/* POSTDIV1 = 1 */
#define SCG1_SPLL_CFG_POSTDIV1_NUM ((0x0) << SCG_PLL_CFG_POSTDIV1_SHIFT)
/* MULT = 22 */
#define SCG1_SPLL_CFG_MULT_NUM ((22) << SCG_PLL_CFG_MULT_SHIFT)
/* PFD0 output clock selected */
#define SCG1_SPLL_CFG_PFDSEL_NUM ((0) << SCG_PLL_CFG_PFDSEL_SHIFT)
/* PREDIV = 1 */
#define SCG1_SPLL_CFG_PREDIV_NUM ((0x0) << SCG_PLL_CFG_PREDIV_SHIFT)
/* SPLL output clocks (including PFD outputs) selected */
#define SCG1_SPLL_CFG_BYPASS_NUM ((0x0) << SCG_PLL_CFG_BYPASS_SHIFT)
/* SPLL PFD output clock selected */
#define SCG1_SPLL_CFG_PLLSEL_NUM ((0x1) << SCG_PLL_CFG_PLLSEL_SHIFT)
/* Clock source is System OSC */
#define SCG1_SPLL_CFG_CLKSRC_NUM ((0x0) << SCG_PLL_CFG_CLKSRC_SHIFT)
#define SCG1_SPLL_CFG_NUM_24M_OSC (SCG1_SPLL_CFG_POSTDIV2_NUM | \
SCG1_SPLL_CFG_POSTDIV1_NUM | \
(22 << SCG_PLL_CFG_MULT_SHIFT) | \
SCG1_SPLL_CFG_PFDSEL_NUM | \
SCG1_SPLL_CFG_PREDIV_NUM | \
SCG1_SPLL_CFG_BYPASS_NUM | \
SCG1_SPLL_CFG_PLLSEL_NUM | \
SCG1_SPLL_CFG_CLKSRC_NUM)
/*413Mhz = A7 SPLL(528MHz) * 18/23 */
#define SCG1_SPLL_PFD0_FRAC_NUM ((23) << SCG_PLL_PFD0_FRAC_SHIFT)
void scg_a7_spll_init(void)
{
u32 val = 0;
/* Disable A7 System PLL */
val = readl(&scg1_regs->spllcsr);
val &= ~SCG_SPLL_CSR_SPLLEN_MASK;
writel(val, &scg1_regs->spllcsr);
/*
* Per block guide,
* "When changing PFD values, it is recommneded PFDx clock
* gets gated first by writing a value of 1 to PFDx_CLKGATE register,
* then program the new PFD value, then poll the PFDx_VALID
* flag to set before writing a value of 0 to PFDx_CLKGATE
* to ungate the PFDx clock and allow PFDx clock to run"
*/
/* Gate off A7 SPLL PFD0 ~ PDF4 */
val = readl(&scg1_regs->spllpfd);
val |= (SCG_PLL_PFD3_GATE_MASK |
SCG_PLL_PFD2_GATE_MASK |
SCG_PLL_PFD1_GATE_MASK |
SCG_PLL_PFD0_GATE_MASK);
writel(val, &scg1_regs->spllpfd);
/* ================ A7 SPLL Configuration Start ============== */
/* Configure A7 System PLL */
writel(SCG1_SPLL_CFG_NUM_24M_OSC, &scg1_regs->spllcfg);
/* Enable A7 System PLL */
val = readl(&scg1_regs->spllcsr);
val |= SCG_SPLL_CSR_SPLLEN_MASK;
writel(val, &scg1_regs->spllcsr);
/* Wait for A7 SPLL clock ready */
while (!(readl(&scg1_regs->spllcsr) & SCG_SPLL_CSR_SPLLVLD_MASK))
;
/* Configure A7 SPLL PFD0 */
val = readl(&scg1_regs->spllpfd);
val &= ~SCG_PLL_PFD0_FRAC_MASK;
val |= SCG1_SPLL_PFD0_FRAC_NUM;
writel(val, &scg1_regs->spllpfd);
/* Un-gate A7 SPLL PFD0 */
val = readl(&scg1_regs->spllpfd);
val &= ~SCG_PLL_PFD0_GATE_MASK;
writel(val, &scg1_regs->spllpfd);
/* Wait for A7 SPLL PFD0 clock being valid */
while (!(readl(&scg1_regs->spllpfd) & SCG_PLL_PFD0_VALID_MASK))
;
/* ================ A7 SPLL Configuration End ============== */
}
/* DDR clock source is APLL PFD0 (396MHz) */
#define SCG1_DDRCCR_DDRCS_NUM ((0x0) << SCG_DDRCCR_DDRCS_SHIFT)
/* DDR clock = APLL PFD0 / 1 = 396MHz / 1 = 396MHz */
#define SCG1_DDRCCR_DDRDIV_NUM ((0x1) << SCG_DDRCCR_DDRDIV_SHIFT)
/* DDR clock = APLL PFD0 / 2 = 396MHz / 2 = 198MHz */
#define SCG1_DDRCCR_DDRDIV_LF_NUM ((0x2) << SCG_DDRCCR_DDRDIV_SHIFT)
#define SCG1_DDRCCR_CFG_NUM (SCG1_DDRCCR_DDRCS_NUM | \
SCG1_DDRCCR_DDRDIV_NUM)
#define SCG1_DDRCCR_CFG_LF_NUM (SCG1_DDRCCR_DDRCS_NUM | \
SCG1_DDRCCR_DDRDIV_LF_NUM)
void scg_a7_ddrclk_init(void)
{
writel(SCG1_DDRCCR_CFG_NUM, &scg1_regs->ddrccr);
}
/* SCG1(A7) APLLCFG configurations */
/* divide by 1 <<28 */
#define SCG1_APLL_CFG_POSTDIV2_NUM ((0x0) << SCG_PLL_CFG_POSTDIV2_SHIFT)
/* divide by 1 <<24 */
#define SCG1_APLL_CFG_POSTDIV1_NUM ((0x0) << SCG_PLL_CFG_POSTDIV1_SHIFT)
/* MULT is 22 <<16 */
#define SCG1_APLL_CFG_MULT_NUM ((22) << SCG_PLL_CFG_MULT_SHIFT)
/* PFD0 output clock selected <<14 */
#define SCG1_APLL_CFG_PFDSEL_NUM ((0) << SCG_PLL_CFG_PFDSEL_SHIFT)
/* PREDIV = 1 <<8 */
#define SCG1_APLL_CFG_PREDIV_NUM ((0x0) << SCG_PLL_CFG_PREDIV_SHIFT)
/* APLL output clocks (including PFD outputs) selected <<2 */
#define SCG1_APLL_CFG_BYPASS_NUM ((0x0) << SCG_PLL_CFG_BYPASS_SHIFT)
/* APLL PFD output clock selected <<1 */
#define SCG1_APLL_CFG_PLLSEL_NUM ((0x0) << SCG_PLL_CFG_PLLSEL_SHIFT)
/* Clock source is System OSC <<0 */
#define SCG1_APLL_CFG_CLKSRC_NUM ((0x0) << SCG_PLL_CFG_CLKSRC_SHIFT)
/*
* A7 APLL = 24MHz / 1 * 22 / 1 / 1 = 528MHz,
* system PLL is sourced from APLL,
* APLL clock source is system OSC (24MHz)
*/
#define SCG1_APLL_CFG_NUM_24M_OSC (SCG1_APLL_CFG_POSTDIV2_NUM | \
SCG1_APLL_CFG_POSTDIV1_NUM | \
(22 << SCG_PLL_CFG_MULT_SHIFT) | \
SCG1_APLL_CFG_PFDSEL_NUM | \
SCG1_APLL_CFG_PREDIV_NUM | \
SCG1_APLL_CFG_BYPASS_NUM | \
SCG1_APLL_CFG_PLLSEL_NUM | \
SCG1_APLL_CFG_CLKSRC_NUM)
/* PFD0 Freq = A7 APLL(528MHz) * 18 / 27 = 352MHz */
#define SCG1_APLL_PFD0_FRAC_NUM (27)
void scg_a7_apll_init(void)
{
u32 val = 0;
/* Disable A7 Auxiliary PLL */
val = readl(&scg1_regs->apllcsr);
val &= ~SCG_APLL_CSR_APLLEN_MASK;
writel(val, &scg1_regs->apllcsr);
/* Gate off A7 APLL PFD0 ~ PDF4 */
val = readl(&scg1_regs->apllpfd);
val |= 0x80808080;
writel(val, &scg1_regs->apllpfd);
/* ================ A7 APLL Configuration Start ============== */
/* Configure A7 Auxiliary PLL */
writel(SCG1_APLL_CFG_NUM_24M_OSC, &scg1_regs->apllcfg);
/* Enable A7 Auxiliary PLL */
val = readl(&scg1_regs->apllcsr);
val |= SCG_APLL_CSR_APLLEN_MASK;
writel(val, &scg1_regs->apllcsr);
/* Wait for A7 APLL clock ready */
while (!(readl(&scg1_regs->apllcsr) & SCG_APLL_CSR_APLLVLD_MASK))
;
/* Configure A7 APLL PFD0 */
val = readl(&scg1_regs->apllpfd);
val &= ~SCG_PLL_PFD0_FRAC_MASK;
val |= SCG1_APLL_PFD0_FRAC_NUM;
writel(val, &scg1_regs->apllpfd);
/* Un-gate A7 APLL PFD0 */
val = readl(&scg1_regs->apllpfd);
val &= ~SCG_PLL_PFD0_GATE_MASK;
writel(val, &scg1_regs->apllpfd);
/* Wait for A7 APLL PFD0 clock being valid */
while (!(readl(&scg1_regs->apllpfd) & SCG_PLL_PFD0_VALID_MASK))
;
}
/* SCG1(A7) FIRC DIV configurations */
/* Disable FIRC DIV3 */
#define SCG1_FIRCDIV_DIV3_NUM ((0x0) << SCG_FIRCDIV_DIV3_SHIFT)
/* FIRC DIV2 = 48MHz / 1 = 48MHz */
#define SCG1_FIRCDIV_DIV2_NUM ((0x1) << SCG_FIRCDIV_DIV2_SHIFT)
/* Disable FIRC DIV1 */
#define SCG1_FIRCDIV_DIV1_NUM ((0x0) << SCG_FIRCDIV_DIV1_SHIFT)
void scg_a7_firc_init(void)
{
/* Wait for FIRC clock ready */
while (!(readl(&scg1_regs->firccsr) & SCG_FIRC_CSR_FIRCVLD_MASK))
;
/* Configure A7 FIRC DIV1 ~ DIV3 */
writel((SCG1_FIRCDIV_DIV3_NUM |
SCG1_FIRCDIV_DIV2_NUM |
SCG1_FIRCDIV_DIV1_NUM), &scg1_regs->fircdiv);
}
/* SCG1(A7) NICCCR configurations */
/* NIC clock source is DDR clock (396/198MHz) */
#define SCG1_NICCCR_NICCS_NUM ((0x1) << SCG_NICCCR_NICCS_SHIFT)
/* NIC0 clock = DDR Clock / 2 = 396MHz / 2 = 198MHz */
#define SCG1_NICCCR_NIC0_DIV_NUM ((0x1) << SCG_NICCCR_NIC0_DIV_SHIFT)
/* NIC0 clock = DDR Clock / 1 = 198MHz / 1 = 198MHz */
#define SCG1_NICCCR_NIC0_DIV_LF_NUM ((0x0) << SCG_NICCCR_NIC0_DIV_SHIFT)
/* NIC1 clock = NIC0 Clock / 1 = 198MHz / 2 = 198MHz */
#define SCG1_NICCCR_NIC1_DIV_NUM ((0x0) << SCG_NICCCR_NIC1_DIV_SHIFT)
/* NIC1 bus clock = NIC1 Clock / 3 = 198MHz / 3 = 66MHz */
#define SCG1_NICCCR_NIC1_DIVBUS_NUM ((0x2) << SCG_NICCCR_NIC1_DIVBUS_SHIFT)
#define SCG1_NICCCR_CFG_NUM (SCG1_NICCCR_NICCS_NUM | \
SCG1_NICCCR_NIC0_DIV_NUM | \
SCG1_NICCCR_NIC1_DIV_NUM | \
SCG1_NICCCR_NIC1_DIVBUS_NUM)
void scg_a7_nicclk_init(void)
{
writel(SCG1_NICCCR_CFG_NUM, &scg1_regs->nicccr);
}
/* SCG1(A7) FIRC DIV configurations */
/* Enable FIRC DIV3 */
#define SCG1_SOSCDIV_DIV3_NUM ((0x1) << SCG_SOSCDIV_DIV3_SHIFT)
/* FIRC DIV2 = 48MHz / 1 = 48MHz */
#define SCG1_SOSCDIV_DIV2_NUM ((0x1) << SCG_SOSCDIV_DIV2_SHIFT)
/* Enable FIRC DIV1 */
#define SCG1_SOSCDIV_DIV1_NUM ((0x1) << SCG_SOSCDIV_DIV1_SHIFT)
void scg_a7_soscdiv_init(void)
{
/* Wait for FIRC clock ready */
while (!(readl(&scg1_regs->sosccsr) & SCG_SOSC_CSR_SOSCVLD_MASK))
;
/* Configure A7 FIRC DIV1 ~ DIV3 */
writel((SCG1_SOSCDIV_DIV3_NUM | SCG1_SOSCDIV_DIV2_NUM |
SCG1_SOSCDIV_DIV1_NUM), &scg1_regs->soscdiv);
}
void scg_a7_sys_clk_sel(enum scg_sys_src clk)
{
u32 rccr_reg_val = 0;
clk_debug("%s: system clock selected as %s\n", "[SCG]",
clk == SCG_SCS_SYS_OSC ? "SYS_OSC" :
clk == SCG_SCS_SLOW_IRC ? "SLOW_IRC" :
clk == SCG_SCS_FAST_IRC ? "FAST_IRC" :
clk == SCG_SCS_RTC_OSC ? "RTC_OSC" :
clk == SCG_SCS_AUX_PLL ? "AUX_PLL" :
clk == SCG_SCS_SYS_PLL ? "SYS_PLL" :
clk == SCG_SCS_USBPHY_PLL ? "USBPHY_PLL" :
"Invalid source"
);
rccr_reg_val = readl(&scg1_regs->rccr);
rccr_reg_val &= ~SCG_CCR_SCS_MASK;
rccr_reg_val |= (clk << SCG_CCR_SCS_SHIFT);
writel(rccr_reg_val, &scg1_regs->rccr);
}
void scg_a7_info(void)
{
debug("SCG Version: 0x%x\n", readl(&scg1_regs->verid));
debug("SCG Parameter: 0x%x\n", readl(&scg1_regs->param));
debug("SCG RCCR Value: 0x%x\n", readl(&scg1_regs->rccr));
debug("SCG Clock Status: 0x%x\n", readl(&scg1_regs->csr));
}