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// SPDX-License-Identifier: GPL-2.0+
/*
* Copyright (C) 2011
* Heiko Schocher, DENX Software Engineering, hs@denx.de.
*
* Copyright (C) 2012 Stefan Roese <sr@denx.de>
*/
#include <common.h>
#include <spl.h>
#include <version.h>
#include <asm/io.h>
#include <asm/arch/hardware.h>
#include <asm/arch/spr_defs.h>
#include <asm/arch/spr_misc.h>
#include <asm/arch/spr_syscntl.h>
#include <linux/mtd/st_smi.h>
/* Reserve some space to store the BootROM's stack pointer during SPL operation.
* The BSS cannot be used for this purpose because it will be zeroed after
* having stored the pointer, so force the location to the data section.
*/
u32 bootrom_stash_sp __attribute__((section(".data")));
static void ddr_clock_init(void)
{
struct misc_regs *misc_p = (struct misc_regs *)CONFIG_SPEAR_MISCBASE;
u32 clkenb, ddrpll;
clkenb = readl(&misc_p->periph1_clken);
clkenb &= ~PERIPH_MPMCMSK;
clkenb |= PERIPH_MPMC_WE;
/* Intentionally done twice */
writel(clkenb, &misc_p->periph1_clken);
writel(clkenb, &misc_p->periph1_clken);
ddrpll = readl(&misc_p->pll_ctr_reg);
ddrpll &= ~MEM_CLK_SEL_MSK;
#if (CONFIG_DDR_HCLK)
ddrpll |= MEM_CLK_HCLK;
#elif (CONFIG_DDR_2HCLK)
ddrpll |= MEM_CLK_2HCLK;
#elif (CONFIG_DDR_PLL2)
ddrpll |= MEM_CLK_PLL2;
#else
#error "please define one of CONFIG_DDR_(HCLK|2HCLK|PLL2)"
#endif
writel(ddrpll, &misc_p->pll_ctr_reg);
writel(readl(&misc_p->periph1_clken) | PERIPH_MPMC_EN,
&misc_p->periph1_clken);
}
static void mpmc_init_values(void)
{
u32 i;
u32 *mpmc_reg_p = (u32 *)CONFIG_SPEAR_MPMCBASE;
u32 *mpmc_val_p = &mpmc_conf_vals[0];
for (i = 0; i < CONFIG_SPEAR_MPMCREGS; i++, mpmc_reg_p++, mpmc_val_p++)
writel(*mpmc_val_p, mpmc_reg_p);
mpmc_reg_p = (u32 *)CONFIG_SPEAR_MPMCBASE;
/*
* MPMC controller start
* MPMC waiting for DLLLOCKREG high
*/
writel(0x01000100, &mpmc_reg_p[7]);
while (!(readl(&mpmc_reg_p[3]) & 0x10000))
;
}
static void mpmc_init(void)
{
/* Clock related settings for DDR */
ddr_clock_init();
/*
* DDR pad register bits are different for different SoCs
* Compensation values are also handled separately
*/
plat_ddr_init();
/* Initialize mpmc register values */
mpmc_init_values();
}
static void pll_init(void)
{
struct misc_regs *misc_p = (struct misc_regs *)CONFIG_SPEAR_MISCBASE;
/* Initialize PLLs */
writel(FREQ_332, &misc_p->pll1_frq);
writel(0x1C0A, &misc_p->pll1_cntl);
writel(0x1C0E, &misc_p->pll1_cntl);
writel(0x1C06, &misc_p->pll1_cntl);
writel(0x1C0E, &misc_p->pll1_cntl);
writel(FREQ_332, &misc_p->pll2_frq);
writel(0x1C0A, &misc_p->pll2_cntl);
writel(0x1C0E, &misc_p->pll2_cntl);
writel(0x1C06, &misc_p->pll2_cntl);
writel(0x1C0E, &misc_p->pll2_cntl);
/* wait for pll locks */
while (!(readl(&misc_p->pll1_cntl) & 0x1))
;
while (!(readl(&misc_p->pll2_cntl) & 0x1))
;
}
static void mac_init(void)
{
struct misc_regs *misc_p = (struct misc_regs *)CONFIG_SPEAR_MISCBASE;
writel(readl(&misc_p->periph1_clken) & (~PERIPH_GMAC),
&misc_p->periph1_clken);
writel(SYNTH23, &misc_p->gmac_synth_clk);
switch (get_socrev()) {
case SOC_SPEAR600_AA:
case SOC_SPEAR600_AB:
case SOC_SPEAR600_BA:
case SOC_SPEAR600_BB:
case SOC_SPEAR600_BC:
case SOC_SPEAR600_BD:
writel(0x0, &misc_p->gmac_ctr_reg);
break;
case SOC_SPEAR300:
case SOC_SPEAR310:
case SOC_SPEAR320:
writel(0x4, &misc_p->gmac_ctr_reg);
break;
}
writel(readl(&misc_p->periph1_clken) | PERIPH_GMAC,
&misc_p->periph1_clken);
writel(readl(&misc_p->periph1_rst) | PERIPH_GMAC,
&misc_p->periph1_rst);
writel(readl(&misc_p->periph1_rst) & (~PERIPH_GMAC),
&misc_p->periph1_rst);
}
static void sys_init(void)
{
struct misc_regs *misc_p = (struct misc_regs *)CONFIG_SPEAR_MISCBASE;
struct syscntl_regs *syscntl_p =
(struct syscntl_regs *)CONFIG_SPEAR_SYSCNTLBASE;
/* Set system state to SLOW */
writel(SLOW, &syscntl_p->scctrl);
writel(PLL_TIM << 3, &syscntl_p->scpllctrl);
/* Initialize PLLs */
pll_init();
/*
* Ethernet configuration
* To be done only if the tftp boot is not selected already
* Boot code ensures the correct configuration in tftp booting
*/
if (!tftp_boot_selected())
mac_init();
writel(RTC_DISABLE | PLLTIMEEN, &misc_p->periph_clk_cfg);
writel(0x555, &misc_p->amba_clk_cfg);
writel(NORMAL, &syscntl_p->scctrl);
/* Wait for system to switch to normal mode */
while (((readl(&syscntl_p->scctrl) >> MODE_SHIFT) & MODE_MASK)
!= NORMAL)
;
}
/*
* get_socrev
*
* Get SoC Revision.
* @return SOC_SPEARXXX
*/
int get_socrev(void)
{
#if defined(CONFIG_SPEAR600)
struct misc_regs *misc_p = (struct misc_regs *)CONFIG_SPEAR_MISCBASE;
u32 soc_id = readl(&misc_p->soc_core_id);
u32 pri_socid = (soc_id >> SOC_PRI_SHFT) & 0xFF;
u32 sec_socid = (soc_id >> SOC_SEC_SHFT) & 0xFF;
if ((pri_socid == 'B') && (sec_socid == 'B'))
return SOC_SPEAR600_BB;
else if ((pri_socid == 'B') && (sec_socid == 'C'))
return SOC_SPEAR600_BC;
else if ((pri_socid == 'B') && (sec_socid == 'D'))
return SOC_SPEAR600_BD;
else if (soc_id == 0)
return SOC_SPEAR600_BA;
else
return SOC_SPEAR_NA;
#elif defined(CONFIG_SPEAR300)
return SOC_SPEAR300;
#elif defined(CONFIG_SPEAR310)
return SOC_SPEAR310;
#elif defined(CONFIG_SPEAR320)
return SOC_SPEAR320;
#endif
}
/*
* SNOR (Serial NOR flash) related functions
*/
static void snor_init(void)
{
struct smi_regs *const smicntl =
(struct smi_regs * const)CONFIG_SYS_SMI_BASE;
/* Setting the fast mode values. SMI working at 166/4 = 41.5 MHz */
writel(HOLD1 | FAST_MODE | BANK_EN | DSEL_TIME | PRESCAL4,
&smicntl->smi_cr1);
}
u32 spl_boot_device(void)
{
u32 mode = 0;
if (usb_boot_selected()) {
mode = BOOT_DEVICE_BOOTROM;
} else if (snor_boot_selected()) {
/* SNOR-SMI initialization */
snor_init();
mode = BOOT_DEVICE_NOR;
}
return mode;
}
void board_init_f(ulong dummy)
{
struct misc_regs *misc_p = (struct misc_regs *)CONFIG_SPEAR_MISCBASE;
/* Initialize PLLs */
sys_init();
preloader_console_init();
arch_cpu_init();
/* Enable IPs (release reset) */
writel(PERIPH_RST_ALL, &misc_p->periph1_rst);
/* Initialize MPMC */
puts("Configure DDR\n");
mpmc_init();
spear_late_init();
}
/*
* In a few cases (Ethernet, UART or USB boot, we might want to go back into the
* BootROM code right after having initialized a few components like the DRAM).
* The following function is called from SPL common code (board_init_r).
*/
void board_return_to_bootrom(void)
{
/*
* Retrieve the BootROM's stack pointer and jump back to the start of
* the SPL, where we can easily branch back into the BootROM. Don't do
* it right here because SPL might be compiled in Thumb mode while the
* BootROM expects ARM mode.
*/
asm volatile ("ldr r0, =bootrom_stash_sp;"
"ldr r0, [r0];"
"mov sp, r0;"
#if defined(CONFIG_SPL_SYS_THUMB_BUILD)
"blx back_to_bootrom;"
#else
"bl back_to_bootrom;"
#endif
);
}
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