u-boot/arch/arm/cpu/armv8/fsl-layerscape/cpu.c
Hou Zhiqiang 904110c7ac armv8/fsl-lsch2: refactor the clock system initialization
Up to now, there are 3 kind of SoCs under Layerscape Chassis 2,
like LS1043A, LS1046A and LS1012A. But the clocks tree has a
lot of differences, for instance, the IP modules have different
dividers to derive its clock from Platform PLL. And the core
cluster PLL and platform PLL maybe have different reference
clocks, such as LS1012A. Another problem is which clock/PLL
should be described by sys_info->freq_systembus, it is confused
in Layerscape Chissis 2.

This patch is to bind the sys_info->freq_systembus to the Platform
PLL, and handle the different divider of IP modules separately
between different SoCs, and separate reference clocks of core
cluster PLL and platform PLL.

Signed-off-by: Hou Zhiqiang <Zhiqiang.Hou@nxp.com>
Reviewed-by: York Sun <york.sun@nxp.com>
2017-01-18 09:27:59 -08:00

538 lines
12 KiB
C

/*
* Copyright 2014-2015 Freescale Semiconductor, Inc.
*
* SPDX-License-Identifier: GPL-2.0+
*/
#include <common.h>
#include <asm/io.h>
#include <linux/errno.h>
#include <asm/system.h>
#include <asm/armv8/mmu.h>
#include <asm/io.h>
#include <asm/arch/fsl_serdes.h>
#include <asm/arch/soc.h>
#include <asm/arch/cpu.h>
#include <asm/arch/speed.h>
#ifdef CONFIG_MP
#include <asm/arch/mp.h>
#endif
#include <efi_loader.h>
#include <fm_eth.h>
#include <fsl-mc/fsl_mc.h>
#ifdef CONFIG_FSL_ESDHC
#include <fsl_esdhc.h>
#endif
#ifdef CONFIG_ARMV8_SEC_FIRMWARE_SUPPORT
#include <asm/armv8/sec_firmware.h>
#endif
#ifdef CONFIG_SYS_FSL_DDR
#include <fsl_ddr.h>
#endif
DECLARE_GLOBAL_DATA_PTR;
struct mm_region *mem_map = early_map;
void cpu_name(char *name)
{
struct ccsr_gur __iomem *gur = (void *)(CONFIG_SYS_FSL_GUTS_ADDR);
unsigned int i, svr, ver;
svr = gur_in32(&gur->svr);
ver = SVR_SOC_VER(svr);
for (i = 0; i < ARRAY_SIZE(cpu_type_list); i++)
if ((cpu_type_list[i].soc_ver & SVR_WO_E) == ver) {
strcpy(name, cpu_type_list[i].name);
if (IS_E_PROCESSOR(svr))
strcat(name, "E");
sprintf(name + strlen(name), " Rev%d.%d",
SVR_MAJ(svr), SVR_MIN(svr));
break;
}
if (i == ARRAY_SIZE(cpu_type_list))
strcpy(name, "unknown");
}
#ifndef CONFIG_SYS_DCACHE_OFF
/*
* To start MMU before DDR is available, we create MMU table in SRAM.
* The base address of SRAM is CONFIG_SYS_FSL_OCRAM_BASE. We use three
* levels of translation tables here to cover 40-bit address space.
* We use 4KB granule size, with 40 bits physical address, T0SZ=24
* Address above EARLY_PGTABLE_SIZE (0x5000) is free for other purpose.
* Note, the debug print in cache_v8.c is not usable for debugging
* these early MMU tables because UART is not yet available.
*/
static inline void early_mmu_setup(void)
{
unsigned int el = current_el();
/* global data is already setup, no allocation yet */
gd->arch.tlb_addr = CONFIG_SYS_FSL_OCRAM_BASE;
gd->arch.tlb_fillptr = gd->arch.tlb_addr;
gd->arch.tlb_size = EARLY_PGTABLE_SIZE;
/* Create early page tables */
setup_pgtables();
/* point TTBR to the new table */
set_ttbr_tcr_mair(el, gd->arch.tlb_addr,
get_tcr(el, NULL, NULL) &
~(TCR_ORGN_MASK | TCR_IRGN_MASK),
MEMORY_ATTRIBUTES);
set_sctlr(get_sctlr() | CR_M);
}
/*
* The final tables look similar to early tables, but different in detail.
* These tables are in DRAM. Sub tables are added to enable cache for
* QBMan and OCRAM.
*
* Put the MMU table in secure memory if gd->arch.secure_ram is valid.
* OCRAM will be not used for this purpose so gd->arch.secure_ram can't be 0.
*/
static inline void final_mmu_setup(void)
{
u64 tlb_addr_save = gd->arch.tlb_addr;
unsigned int el = current_el();
#ifdef CONFIG_SYS_MEM_RESERVE_SECURE
int index;
#endif
mem_map = final_map;
#ifdef CONFIG_SYS_MEM_RESERVE_SECURE
if (gd->arch.secure_ram & MEM_RESERVE_SECURE_MAINTAINED) {
if (el == 3) {
/*
* Only use gd->arch.secure_ram if the address is
* recalculated. Align to 4KB for MMU table.
*/
/* put page tables in secure ram */
index = ARRAY_SIZE(final_map) - 2;
gd->arch.tlb_addr = gd->arch.secure_ram & ~0xfff;
final_map[index].virt = gd->arch.secure_ram & ~0x3;
final_map[index].phys = final_map[index].virt;
final_map[index].size = CONFIG_SYS_MEM_RESERVE_SECURE;
final_map[index].attrs = PTE_BLOCK_OUTER_SHARE;
gd->arch.secure_ram |= MEM_RESERVE_SECURE_SECURED;
tlb_addr_save = gd->arch.tlb_addr;
} else {
/* Use allocated (board_f.c) memory for TLB */
tlb_addr_save = gd->arch.tlb_allocated;
gd->arch.tlb_addr = tlb_addr_save;
}
}
#endif
/* Reset the fill ptr */
gd->arch.tlb_fillptr = tlb_addr_save;
/* Create normal system page tables */
setup_pgtables();
/* Create emergency page tables */
gd->arch.tlb_addr = gd->arch.tlb_fillptr;
gd->arch.tlb_emerg = gd->arch.tlb_addr;
setup_pgtables();
gd->arch.tlb_addr = tlb_addr_save;
/* flush new MMU table */
flush_dcache_range(gd->arch.tlb_addr,
gd->arch.tlb_addr + gd->arch.tlb_size);
/* point TTBR to the new table */
set_ttbr_tcr_mair(el, gd->arch.tlb_addr, get_tcr(el, NULL, NULL),
MEMORY_ATTRIBUTES);
/*
* EL3 MMU is already enabled, just need to invalidate TLB to load the
* new table. The new table is compatible with the current table, if
* MMU somehow walks through the new table before invalidation TLB,
* it still works. So we don't need to turn off MMU here.
* When EL2 MMU table is created by calling this function, MMU needs
* to be enabled.
*/
set_sctlr(get_sctlr() | CR_M);
}
u64 get_page_table_size(void)
{
return 0x10000;
}
int arch_cpu_init(void)
{
icache_enable();
__asm_invalidate_dcache_all();
__asm_invalidate_tlb_all();
early_mmu_setup();
set_sctlr(get_sctlr() | CR_C);
return 0;
}
void mmu_setup(void)
{
final_mmu_setup();
}
/*
* This function is called from common/board_r.c.
* It recreates MMU table in main memory.
*/
void enable_caches(void)
{
mmu_setup();
__asm_invalidate_tlb_all();
icache_enable();
dcache_enable();
}
#endif
u32 initiator_type(u32 cluster, int init_id)
{
struct ccsr_gur *gur = (void *)(CONFIG_SYS_FSL_GUTS_ADDR);
u32 idx = (cluster >> (init_id * 8)) & TP_CLUSTER_INIT_MASK;
u32 type = 0;
type = gur_in32(&gur->tp_ityp[idx]);
if (type & TP_ITYP_AV)
return type;
return 0;
}
u32 cpu_pos_mask(void)
{
struct ccsr_gur __iomem *gur = (void *)(CONFIG_SYS_FSL_GUTS_ADDR);
int i = 0;
u32 cluster, type, mask = 0;
do {
int j;
cluster = gur_in32(&gur->tp_cluster[i].lower);
for (j = 0; j < TP_INIT_PER_CLUSTER; j++) {
type = initiator_type(cluster, j);
if (type && (TP_ITYP_TYPE(type) == TP_ITYP_TYPE_ARM))
mask |= 1 << (i * TP_INIT_PER_CLUSTER + j);
}
i++;
} while ((cluster & TP_CLUSTER_EOC) == 0x0);
return mask;
}
u32 cpu_mask(void)
{
struct ccsr_gur __iomem *gur = (void *)(CONFIG_SYS_FSL_GUTS_ADDR);
int i = 0, count = 0;
u32 cluster, type, mask = 0;
do {
int j;
cluster = gur_in32(&gur->tp_cluster[i].lower);
for (j = 0; j < TP_INIT_PER_CLUSTER; j++) {
type = initiator_type(cluster, j);
if (type) {
if (TP_ITYP_TYPE(type) == TP_ITYP_TYPE_ARM)
mask |= 1 << count;
count++;
}
}
i++;
} while ((cluster & TP_CLUSTER_EOC) == 0x0);
return mask;
}
/*
* Return the number of cores on this SOC.
*/
int cpu_numcores(void)
{
return hweight32(cpu_mask());
}
int fsl_qoriq_core_to_cluster(unsigned int core)
{
struct ccsr_gur __iomem *gur =
(void __iomem *)(CONFIG_SYS_FSL_GUTS_ADDR);
int i = 0, count = 0;
u32 cluster;
do {
int j;
cluster = gur_in32(&gur->tp_cluster[i].lower);
for (j = 0; j < TP_INIT_PER_CLUSTER; j++) {
if (initiator_type(cluster, j)) {
if (count == core)
return i;
count++;
}
}
i++;
} while ((cluster & TP_CLUSTER_EOC) == 0x0);
return -1; /* cannot identify the cluster */
}
u32 fsl_qoriq_core_to_type(unsigned int core)
{
struct ccsr_gur __iomem *gur =
(void __iomem *)(CONFIG_SYS_FSL_GUTS_ADDR);
int i = 0, count = 0;
u32 cluster, type;
do {
int j;
cluster = gur_in32(&gur->tp_cluster[i].lower);
for (j = 0; j < TP_INIT_PER_CLUSTER; j++) {
type = initiator_type(cluster, j);
if (type) {
if (count == core)
return type;
count++;
}
}
i++;
} while ((cluster & TP_CLUSTER_EOC) == 0x0);
return -1; /* cannot identify the cluster */
}
#ifndef CONFIG_FSL_LSCH3
uint get_svr(void)
{
struct ccsr_gur __iomem *gur = (void *)(CONFIG_SYS_FSL_GUTS_ADDR);
return gur_in32(&gur->svr);
}
#endif
#ifdef CONFIG_DISPLAY_CPUINFO
int print_cpuinfo(void)
{
struct ccsr_gur __iomem *gur = (void *)(CONFIG_SYS_FSL_GUTS_ADDR);
struct sys_info sysinfo;
char buf[32];
unsigned int i, core;
u32 type, rcw, svr = gur_in32(&gur->svr);
puts("SoC: ");
cpu_name(buf);
printf(" %s (0x%x)\n", buf, svr);
memset((u8 *)buf, 0x00, ARRAY_SIZE(buf));
get_sys_info(&sysinfo);
puts("Clock Configuration:");
for_each_cpu(i, core, cpu_numcores(), cpu_mask()) {
if (!(i % 3))
puts("\n ");
type = TP_ITYP_VER(fsl_qoriq_core_to_type(core));
printf("CPU%d(%s):%-4s MHz ", core,
type == TY_ITYP_VER_A7 ? "A7 " :
(type == TY_ITYP_VER_A53 ? "A53" :
(type == TY_ITYP_VER_A57 ? "A57" :
(type == TY_ITYP_VER_A72 ? "A72" : " "))),
strmhz(buf, sysinfo.freq_processor[core]));
}
/* Display platform clock as Bus frequency. */
printf("\n Bus: %-4s MHz ",
strmhz(buf, sysinfo.freq_systembus / CONFIG_SYS_FSL_PCLK_DIV));
printf("DDR: %-4s MT/s", strmhz(buf, sysinfo.freq_ddrbus));
#ifdef CONFIG_SYS_DPAA_FMAN
printf(" FMAN: %-4s MHz", strmhz(buf, sysinfo.freq_fman[0]));
#endif
#ifdef CONFIG_SYS_FSL_HAS_DP_DDR
if (soc_has_dp_ddr()) {
printf(" DP-DDR: %-4s MT/s",
strmhz(buf, sysinfo.freq_ddrbus2));
}
#endif
puts("\n");
/*
* Display the RCW, so that no one gets confused as to what RCW
* we're actually using for this boot.
*/
puts("Reset Configuration Word (RCW):");
for (i = 0; i < ARRAY_SIZE(gur->rcwsr); i++) {
rcw = gur_in32(&gur->rcwsr[i]);
if ((i % 4) == 0)
printf("\n %08x:", i * 4);
printf(" %08x", rcw);
}
puts("\n");
return 0;
}
#endif
#ifdef CONFIG_FSL_ESDHC
int cpu_mmc_init(bd_t *bis)
{
return fsl_esdhc_mmc_init(bis);
}
#endif
int cpu_eth_init(bd_t *bis)
{
int error = 0;
#ifdef CONFIG_FSL_MC_ENET
error = fsl_mc_ldpaa_init(bis);
#endif
#ifdef CONFIG_FMAN_ENET
fm_standard_init(bis);
#endif
return error;
}
int arch_early_init_r(void)
{
#ifdef CONFIG_MP
int rv = 1;
u32 psci_ver = 0xffffffff;
#endif
#ifdef CONFIG_SYS_FSL_ERRATUM_A009635
erratum_a009635();
#endif
#if defined(CONFIG_SYS_FSL_ERRATUM_A009942) && defined(CONFIG_SYS_FSL_DDR)
erratum_a009942_check_cpo();
#endif
#ifdef CONFIG_MP
#if defined(CONFIG_ARMV8_SEC_FIRMWARE_SUPPORT) && \
defined(CONFIG_FSL_PPA_ARMV8_PSCI)
/* Check the psci version to determine if the psci is supported */
psci_ver = sec_firmware_support_psci_version();
#endif
if (psci_ver == 0xffffffff) {
rv = fsl_layerscape_wake_seconday_cores();
if (rv)
printf("Did not wake secondary cores\n");
}
#endif
#ifdef CONFIG_SYS_HAS_SERDES
fsl_serdes_init();
#endif
#ifdef CONFIG_FMAN_ENET
fman_enet_init();
#endif
return 0;
}
int timer_init(void)
{
u32 __iomem *cntcr = (u32 *)CONFIG_SYS_FSL_TIMER_ADDR;
#ifdef CONFIG_FSL_LSCH3
u32 __iomem *cltbenr = (u32 *)CONFIG_SYS_FSL_PMU_CLTBENR;
#endif
#ifdef CONFIG_LS2080A
u32 __iomem *pctbenr = (u32 *)FSL_PMU_PCTBENR_OFFSET;
u32 svr_dev_id;
#endif
#ifdef COUNTER_FREQUENCY_REAL
unsigned long cntfrq = COUNTER_FREQUENCY_REAL;
/* Update with accurate clock frequency */
asm volatile("msr cntfrq_el0, %0" : : "r" (cntfrq) : "memory");
#endif
#ifdef CONFIG_FSL_LSCH3
/* Enable timebase for all clusters.
* It is safe to do so even some clusters are not enabled.
*/
out_le32(cltbenr, 0xf);
#endif
#ifdef CONFIG_LS2080A
/*
* In certain Layerscape SoCs, the clock for each core's
* has an enable bit in the PMU Physical Core Time Base Enable
* Register (PCTBENR), which allows the watchdog to operate.
*/
setbits_le32(pctbenr, 0xff);
/*
* For LS2080A SoC and its personalities, timer controller
* offset is different
*/
svr_dev_id = get_svr() >> 16;
if (svr_dev_id == SVR_DEV_LS2080A)
cntcr = (u32 *)SYS_FSL_LS2080A_LS2085A_TIMER_ADDR;
#endif
/* Enable clock for timer
* This is a global setting.
*/
out_le32(cntcr, 0x1);
return 0;
}
__efi_runtime_data u32 __iomem *rstcr = (u32 *)CONFIG_SYS_FSL_RST_ADDR;
void __efi_runtime reset_cpu(ulong addr)
{
u32 val;
/* Raise RESET_REQ_B */
val = scfg_in32(rstcr);
val |= 0x02;
scfg_out32(rstcr, val);
}
#ifdef CONFIG_EFI_LOADER
void __efi_runtime EFIAPI efi_reset_system(
enum efi_reset_type reset_type,
efi_status_t reset_status,
unsigned long data_size, void *reset_data)
{
switch (reset_type) {
case EFI_RESET_COLD:
case EFI_RESET_WARM:
reset_cpu(0);
break;
case EFI_RESET_SHUTDOWN:
/* Nothing we can do */
break;
}
while (1) { }
}
void efi_reset_system_init(void)
{
efi_add_runtime_mmio(&rstcr, sizeof(*rstcr));
}
#endif
phys_size_t board_reserve_ram_top(phys_size_t ram_size)
{
phys_size_t ram_top = ram_size;
#ifdef CONFIG_SYS_MEM_TOP_HIDE
#error CONFIG_SYS_MEM_TOP_HIDE not to be used together with this function
#endif
/* Carve the MC private DRAM block from the end of DRAM */
#ifdef CONFIG_FSL_MC_ENET
ram_top -= mc_get_dram_block_size();
ram_top &= ~(CONFIG_SYS_MC_RSV_MEM_ALIGN - 1);
#endif
return ram_top;
}