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// SPDX-License-Identifier: GPL-2.0+
/*
* Copyright (C) 2018 Marvell International Ltd.
*/
#include <common.h>
#include <asm/arch-armada8k/cache_llc.h>
#include <asm/io.h>
#include <asm/arch/cpu.h>
#include <asm/arch/soc.h>
#include <dm/device.h>
#define DEVICE_ID_REG 0x7F90004C
#define DEVICE_ID_MASK 0xffff0
#define REV_ID_MASK 0xf
#define DEVICE_ID_OFFSET 4
#define REV_ID_OFFSET 0
#define DEVICE_SAR_REG 0x944F8204
#define DEVICE_ID_SUB_REV (MVEBU_REGISTER(0x2400230))
#define DEVICE_ID_SUB_REV_OFFSET 7
#define DEVICE_ID_SUB_REV_MASK (0xffff << DEVICE_ID_SUB_REV_OFFSET)
#define AC5X_DEV_ID 0x9800
struct soc_info {
u32 dev_id;
u32 rev_id;
char *soc_name;
};
static struct soc_info soc_info_table[] = {
/* Two reserved entries for unidentified devices - don't change */
{ 0xB4FF, 0x0, "Unidentified Alleycat5"},
{ 0x98FF, 0x0, "Unidentified Alleycat5x"},
{ 0xB400, 0x2, "Alleycat5-plus 98DX2538-A2"},
{ 0xB401, 0x2, "Alleycat5-plus 98DX2535-A2"},
{ 0xB402, 0x2, "Alleycat5-plus 98DX2532-A2"},
{ 0xB403, 0x2, "Alleycat5-plus 98DX2531-A2"},
{ 0xB408, 0x2, "Alleycat5 98DX2528-A2"},
{ 0xB409, 0x2, "Alleycat5 98DX2525-A2"},
{ 0xB40A, 0x2, "Alleycat5 98DX2522-A2"},
{ 0xB40B, 0x2, "Alleycat5 98DX2521-A2"},
{ 0xB410, 0x2, "Alleycat5-lite 98DX2518-A2"},
{ 0xB411, 0x2, "Alleycat5-lite 98DX2515-A2"},
{ 0xB412, 0x2, "Alleycat5-lite 98DX2512-A2"},
{ 0xB413, 0x2, "Alleycat5-lite 98DX2511-A2"},
{ 0xB400, 0x1, "Alleycat5-plus 98DX2538-A1"},
{ 0xB401, 0x1, "Alleycat5-plus 98DX2535-A1"},
{ 0xB402, 0x1, "Alleycat5-plus 98DX2532-A1"},
{ 0xB403, 0x1, "Alleycat5-plus 98DX2531-A1"},
{ 0xB408, 0x1, "Alleycat5 98DX2528-A1"},
{ 0xB409, 0x1, "Alleycat5 98DX2525-A1"},
{ 0xB40A, 0x1, "Alleycat5 98DX2522-A1"},
{ 0xB40B, 0x1, "Alleycat5 98DX2521-A1"},
{ 0xB410, 0x1, "Alleycat5-lite 98DX2518-A1"},
{ 0xB411, 0x1, "Alleycat5-lite 98DX2515-A1"},
{ 0xB412, 0x1, "Alleycat5-lite 98DX2512-A1"},
{ 0xB413, 0x1, "Alleycat5-lite 98DX2511-A1"},
{ 0x9800, 0x1, "Alleycat5X 98DX3500M-A1"},
{ 0x9806, 0x1, "Alleycat5X 98DX3501M-A1"},
{ 0x9801, 0x1, "Alleycat5X 98DX3510M-A1"},
{ 0x9802, 0x1, "Alleycat5X 98DX3520M-A1"},
{ 0x9803, 0x1, "Alleycat5X 98DX3530M-A1"},
{ 0x9804, 0x1, "Alleycat5X 98DX3540M-A1"},
{ 0x9805, 0x1, "Alleycat5X 98DX3550M-A1"},
{ 0x9820, 0x1, "Alleycat5X 98DX3500-A1"},
{ 0x9826, 0x1, "Alleycat5X 98DX3501-A1"},
{ 0x9821, 0x1, "Alleycat5X 98DX3510-A1"},
{ 0x9861, 0x1, "Alleycat5X 98DX3510H-A1"},
{ 0x9841, 0x1, "Alleycat5X 98DX3510MH-A1"},
{ 0x9822, 0x1, "Alleycat5X 98DX3520-A1"},
{ 0x9823, 0x1, "Alleycat5X 98DX3530-A1"},
{ 0x9863, 0x1, "Alleycat5X 98DX3530H-A1"},
{ 0x9824, 0x1, "Alleycat5X 98DX3540-A1"},
{ 0x9825, 0x1, "Alleycat5X 98DX3550-A1"},
{ 0xB400, 0x0, "Alleycat5-plus 98DX2538-A0"},
{ 0xB401, 0x0, "Alleycat5-plus 98DX2535-A0"},
{ 0xB402, 0x0, "Alleycat5-plus 98DX2532-A0"},
{ 0xB403, 0x0, "Alleycat5-plus 98DX2531-A0"},
{ 0xB408, 0x0, "Alleycat5 98DX2528-A0"},
{ 0xB409, 0x0, "Alleycat5 98DX2525-A0"},
{ 0xB40A, 0x0, "Alleycat5 98DX2522-A0"},
{ 0xB40B, 0x0, "Alleycat5 98DX2521-A0"},
{ 0xB410, 0x0, "Alleycat5-lite 98DX2518-A0"},
{ 0xB411, 0x0, "Alleycat5-lite 98DX2515-A0"},
{ 0xB412, 0x0, "Alleycat5-lite 98DX2512-A0"},
{ 0xB413, 0x0, "Alleycat5-lite 98DX2511-A0"},
{ 0x9800, 0x0, "Alleycat5X 98DX3500M-A0"},
{ 0x9806, 0x0, "Alleycat5X 98DX3501M-A0"},
{ 0x9801, 0x0, "Alleycat5X 98DX3510M-A0"},
{ 0x9802, 0x0, "Alleycat5X 98DX3520M-A0"},
{ 0x9803, 0x0, "Alleycat5X 98DX3530M-A0"},
{ 0x9804, 0x0, "Alleycat5X 98DX3540M-A0"},
{ 0x9805, 0x0, "Alleycat5X 98DX3550M-A0"},
{ 0x9820, 0x0, "Alleycat5X 98DX3500-A0"},
{ 0x9826, 0x0, "Alleycat5X 98DX3501-A0"},
{ 0x9821, 0x0, "Alleycat5X 98DX3510-A0"},
{ 0x9861, 0x0, "Alleycat5X 98DX3510H-A0"},
{ 0x9841, 0x0, "Alleycat5X 98DX3510MH-A0"},
{ 0x9822, 0x0, "Alleycat5X 98DX3520-A0"},
{ 0x9823, 0x0, "Alleycat5X 98DX3530-A0"},
{ 0x9863, 0x0, "Alleycat5X 98DX3530H-A0"},
{ 0x9824, 0x0, "Alleycat5X 98DX3540-A0"},
{ 0x9825, 0x0, "Alleycat5X 98DX3550-A0"},
};
#define BIT_VAL(b) ((1ULL << ((b) + 1)) - 1)
#define BIT_RANGE(bl, bh) (BIT_VAL(bh) - BIT_VAL((bl) - 1))
#define PLL_MAX_CHOICE 4
#define CPU_TYPE_AC5 0
#define CPU_TYPE_AC5x 1
#define CPU_TYPE_LAST 2
enum mvebu_sar_opts {
SAR_CPU_FREQ = 0,
SAR_DDR_FREQ,
SAR_AP_FABRIC_FREQ,
SAR_CP_FABRIC_FREQ,
SAR_CP0_PCIE0_CLK,
SAR_CP0_PCIE1_CLK,
SAR_CP1_PCIE0_CLK,
SAR_CP1_PCIE1_CLK,
SAR_BOOT_SRC,
SAR_MAX_IDX
};
static const u32 pll_freq_tbl[CPU_TYPE_LAST][SAR_AP_FABRIC_FREQ + 1][PLL_MAX_CHOICE] = {
[CPU_TYPE_AC5] = {
[SAR_CPU_FREQ] = {
800, 1200, 1400, 1000
},
[SAR_DDR_FREQ] = {
1200, 800, 0, 0
},
[SAR_AP_FABRIC_FREQ] = {
396, 290, 197, 0
},
},
[CPU_TYPE_AC5x] = {
[SAR_CPU_FREQ] = {
800, 1200, 1500, 1600
},
[SAR_DDR_FREQ] = {
1200, 800, 0, 0
},
[SAR_AP_FABRIC_FREQ] = {
0, 0, 0, 0
}
}
};
static const u32 soc_sar_masks_tbl[CPU_TYPE_LAST][SAR_AP_FABRIC_FREQ + 1] = {
[CPU_TYPE_AC5] = {
[SAR_CPU_FREQ] = BIT_RANGE(18, 20),
[SAR_DDR_FREQ] = BIT_RANGE(16, 17),
[SAR_AP_FABRIC_FREQ] = BIT_RANGE(22, 23),
},
[CPU_TYPE_AC5x] = {
[SAR_CPU_FREQ] = BIT_RANGE(8, 10),
[SAR_DDR_FREQ] = BIT_RANGE(6, 7),
[SAR_AP_FABRIC_FREQ] = 1,
},
};
static int get_soc_type_rev(u32 *type, u32 *rev)
{
*type = (readl(DEVICE_ID_REG) & DEVICE_ID_MASK) >> DEVICE_ID_OFFSET;
*rev = (readl(DEVICE_ID_REG) & REV_ID_MASK) >> REV_ID_OFFSET;
return 0;
}
static void get_one_sar_freq(int cpu_type, u32 sar_reg_val, enum mvebu_sar_opts sar_opt, u32 *freq)
{
u32 mask;
unsigned char choice;
mask = soc_sar_masks_tbl[cpu_type][sar_opt];
choice = (sar_reg_val & mask) >> (__builtin_ffs(mask) - 1);
*freq = pll_freq_tbl[cpu_type][sar_opt][choice];
}
void get_sar_freq(struct sar_freq_modes *sar_freq)
{
int cpu_type;
u32 soc_type, rev;
u32 sar_reg_val = readl(DEVICE_SAR_REG);
get_soc_type_rev(&soc_type, &rev);
cpu_type = (soc_type & 0xFF00) == AC5X_DEV_ID ? CPU_TYPE_AC5x : CPU_TYPE_AC5;
get_one_sar_freq(cpu_type, sar_reg_val, SAR_CPU_FREQ, &sar_freq->p_clk);
get_one_sar_freq(cpu_type, sar_reg_val, SAR_AP_FABRIC_FREQ, &sar_freq->nb_clk);
get_one_sar_freq(cpu_type, sar_reg_val, SAR_DDR_FREQ, &sar_freq->d_clk);
}
static int get_soc_table_index(u32 *index)
{
u32 soc_type;
u32 rev, i, ret = 1;
*index = 0;
get_soc_type_rev(&soc_type, &rev);
for (i = 0; i < ARRAY_SIZE(soc_info_table) && ret != 0; i++) {
if (soc_type != soc_info_table[i].dev_id ||
rev != soc_info_table[i].rev_id)
continue;
*index = i;
ret = 0;
}
if (ret && ((soc_type & 0xFF00) == AC5X_DEV_ID))
*index = 1;
return ret;
}
static int get_soc_name(char **soc_name)
{
u32 index;
get_soc_table_index(&index);
*soc_name = soc_info_table[index].soc_name;
return 0;
}
/* Print device's SoC name and AP & CP information */
void soc_print_device_info(void)
{
char *soc_name = NULL;
get_soc_name(&soc_name);
printf("SoC: %s\n", soc_name);
}
void soc_print_clock_info(void)
{
struct sar_freq_modes sar_freq;
get_sar_freq(&sar_freq);
printf("Clock: CPU %4d MHz\n", sar_freq.p_clk);
printf("\tDDR %4d MHz\n", sar_freq.d_clk);
printf("\tFABRIC %4d MHz\n", sar_freq.nb_clk);
printf("\tMSS %4d MHz\n", 200);
}
/* Return NAND clock in Hz */
u32 mvebu_get_nand_clock(void)
{
return 400 * 1000000;
}
/*
* Override of __weak int mach_cpu_init(void) :
* SoC/machine dependent CPU setup
*/
int mach_cpu_init(void)
{
u32 phy_i;
u64 new_val, phy_base = 0x7F080800;
/* Init USB PHY */
#define USB_STEPPING 0x20000
#define WRITE_MASK(addr, mask, val) \
{ new_val = (readl(addr) & (~(mask))) | (val);\
writel(new_val, addr); }
for (phy_i = 0; phy_i < 2; phy_i++, phy_base += USB_STEPPING) {
WRITE_MASK(phy_base + 0x4, 0x3, 0x2);
WRITE_MASK(phy_base + 0xC, 0x3000000, 0x2000000);
WRITE_MASK(phy_base + 0x1C, 0x3, 0x2);
WRITE_MASK(phy_base + 0x0, 0x1FF007F, 0x600005);
WRITE_MASK(phy_base + 0xC, 0x000F000, 0x0002000);
/* Calibration Threshold Setting = 4*/
WRITE_MASK(phy_base + 0x8, 0x700, 0x400)
WRITE_MASK(phy_base + 0x14, 0x000000F, 0x000000a);
/* Change AMP to 4*/
WRITE_MASK(phy_base + 0xC, 0x3700000, 0x3400000);
WRITE_MASK(phy_base + 0x4, 0x3, 0x3);
/* Impedance calibration triggering is performed by USB probe */
}
return 0;
}
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