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u-boot-brain/board/synopsys/hsdk/hsdk.c
Tom Rini 83d290c56f SPDX: Convert all of our single license tags to Linux Kernel style 
When U-Boot started using SPDX tags we were among the early adopters and
there weren't a lot of other examples to borrow from.  So we picked the
area of the file that usually had a full license text and replaced it
with an appropriate SPDX-License-Identifier: entry.  Since then, the
Linux Kernel has adopted SPDX tags and they place it as the very first
line in a file (except where shebangs are used, then it's second line)
and with slightly different comment styles than us.

In part due to community overlap, in part due to better tag visibility
and in part for other minor reasons, switch over to that style.

This commit changes all instances where we have a single declared
license in the tag as both the before and after are identical in tag
contents.  There's also a few places where I found we did not have a tag
and have introduced one.

Signed-off-by: Tom Rini <trini@konsulko.com>
2018-05-07 09:34:12 -04:00

1049 lines
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// SPDX-License-Identifier: GPL-2.0+
/*
* Copyright (C) 2018 Synopsys, Inc. All rights reserved.
* Author: Eugeniy Paltsev <Eugeniy.Paltsev@synopsys.com>
*/
#include <common.h>
#include <config.h>
#include <linux/printk.h>
#include <linux/kernel.h>
#include <linux/io.h>
#include <asm/arcregs.h>
#include <fdt_support.h>
#include <dwmmc.h>
#include <malloc.h>
#include <usb.h>
#include "clk-lib.h"
#include "env-lib.h"
DECLARE_GLOBAL_DATA_PTR;
#define ALL_CPU_MASK GENMASK(NR_CPUS - 1, 0)
#define MASTER_CPU_ID 0
#define APERTURE_SHIFT 28
#define NO_CCM 0x10
#define SLAVE_CPU_READY 0x12345678
#define BOOTSTAGE_1 1 /* after SP, FP setup, before HW init */
#define BOOTSTAGE_2 2 /* after HW init, before self halt */
#define BOOTSTAGE_3 3 /* after self halt */
#define BOOTSTAGE_4 4 /* before app launch */
#define BOOTSTAGE_5 5 /* after app launch, unreachable */
#define RESET_VECTOR_ADDR 0x0
#define CREG_BASE (ARC_PERIPHERAL_BASE + 0x1000)
#define CREG_CPU_START (CREG_BASE + 0x400)
#define CREG_CPU_START_MASK 0xF
#define SDIO_BASE (ARC_PERIPHERAL_BASE + 0xA000)
#define SDIO_UHS_REG_EXT (SDIO_BASE + 0x108)
#define SDIO_UHS_REG_EXT_DIV_2 (2 << 30)
/* Uncached access macros */
#define arc_read_uncached_32(ptr) \
({ \
unsigned int __ret; \
__asm__ __volatile__( \
" ld.di %0, [%1] \n" \
: "=r"(__ret) \
: "r"(ptr)); \
__ret; \
})
#define arc_write_uncached_32(ptr, data)\
({ \
__asm__ __volatile__( \
" st.di %0, [%1] \n" \
: \
: "r"(data), "r"(ptr)); \
})
struct hsdk_env_core_ctl {
u32_env entry[NR_CPUS];
u32_env iccm[NR_CPUS];
u32_env dccm[NR_CPUS];
};
struct hsdk_env_common_ctl {
bool halt_on_boot;
u32_env core_mask;
u32_env cpu_freq;
u32_env axi_freq;
u32_env tun_freq;
u32_env nvlim;
u32_env icache;
u32_env dcache;
};
/*
* Uncached cross-cpu structure. All CPUs must access to this structure fields
* only with arc_read_uncached_32() / arc_write_uncached_32() accessors (which
* implement ld.di / st.di instructions). Simultaneous cached and uncached
* access to this area will lead to data loss.
* We flush all data caches in board_early_init_r() as we don't want to have
* any dirty line in L1d$ or SL$ in this area.
*/
struct hsdk_cross_cpu {
/* slave CPU ready flag */
u32 ready_flag;
/* address of the area, which can be used for stack by slave CPU */
u32 stack_ptr;
/* slave CPU status - bootstage number */
s32 status[NR_CPUS];
/*
* Slave CPU data - it is copy of corresponding fields in
* hsdk_env_core_ctl and hsdk_env_common_ctl structures which are
* required for slave CPUs initialization.
* This fields can be populated by copying from hsdk_env_core_ctl
* and hsdk_env_common_ctl structures with sync_cross_cpu_data()
* function.
*/
u32 entry[NR_CPUS];
u32 iccm[NR_CPUS];
u32 dccm[NR_CPUS];
u32 core_mask;
u32 icache;
u32 dcache;
u8 cache_padding[ARCH_DMA_MINALIGN];
} __aligned(ARCH_DMA_MINALIGN);
/* Place for slave CPUs temporary stack */
static u32 slave_stack[256 * NR_CPUS] __aligned(ARCH_DMA_MINALIGN);
static struct hsdk_env_common_ctl env_common = {};
static struct hsdk_env_core_ctl env_core = {};
static struct hsdk_cross_cpu cross_cpu_data;
static const struct env_map_common env_map_common[] = {
{ "core_mask", ENV_HEX, true, 0x1, 0xF, &env_common.core_mask },
{ "non_volatile_limit", ENV_HEX, true, 0, 0xF, &env_common.nvlim },
{ "icache_ena", ENV_HEX, true, 0, 1, &env_common.icache },
{ "dcache_ena", ENV_HEX, true, 0, 1, &env_common.dcache },
{}
};
static const struct env_map_common env_map_clock[] = {
{ "cpu_freq", ENV_DEC, false, 100, 1000, &env_common.cpu_freq },
{ "axi_freq", ENV_DEC, false, 200, 800, &env_common.axi_freq },
{ "tun_freq", ENV_DEC, false, 0, 150, &env_common.tun_freq },
{}
};
static const struct env_map_percpu env_map_core[] = {
{ "core_iccm", ENV_HEX, true, {NO_CCM, 0, NO_CCM, 0}, {NO_CCM, 0xF, NO_CCM, 0xF}, &env_core.iccm },
{ "core_dccm", ENV_HEX, true, {NO_CCM, 0, NO_CCM, 0}, {NO_CCM, 0xF, NO_CCM, 0xF}, &env_core.dccm },
{}
};
static const struct env_map_common env_map_mask[] = {
{ "core_mask", ENV_HEX, false, 0x1, 0xF, &env_common.core_mask },
{}
};
static const struct env_map_percpu env_map_go[] = {
{ "core_entry", ENV_HEX, true, {0, 0, 0, 0}, {U32_MAX, U32_MAX, U32_MAX, U32_MAX}, &env_core.entry },
{}
};
static void sync_cross_cpu_data(void)
{
u32 value;
for (u32 i = 0; i < NR_CPUS; i++) {
value = env_core.entry[i].val;
arc_write_uncached_32(&cross_cpu_data.entry[i], value);
}
for (u32 i = 0; i < NR_CPUS; i++) {
value = env_core.iccm[i].val;
arc_write_uncached_32(&cross_cpu_data.iccm[i], value);
}
for (u32 i = 0; i < NR_CPUS; i++) {
value = env_core.dccm[i].val;
arc_write_uncached_32(&cross_cpu_data.dccm[i], value);
}
value = env_common.core_mask.val;
arc_write_uncached_32(&cross_cpu_data.core_mask, value);
value = env_common.icache.val;
arc_write_uncached_32(&cross_cpu_data.icache, value);
value = env_common.dcache.val;
arc_write_uncached_32(&cross_cpu_data.dcache, value);
}
/* Can be used only on master CPU */
static bool is_cpu_used(u32 cpu_id)
{
return !!(env_common.core_mask.val & BIT(cpu_id));
}
/* TODO: add ICCM BCR and DCCM BCR runtime check */
static void init_slave_cpu_func(u32 core)
{
u32 val;
/* Remap ICCM to another memory region if it exists */
val = arc_read_uncached_32(&cross_cpu_data.iccm[core]);
if (val != NO_CCM)
write_aux_reg(ARC_AUX_ICCM_BASE, val << APERTURE_SHIFT);
/* Remap DCCM to another memory region if it exists */
val = arc_read_uncached_32(&cross_cpu_data.dccm[core]);
if (val != NO_CCM)
write_aux_reg(ARC_AUX_DCCM_BASE, val << APERTURE_SHIFT);
if (arc_read_uncached_32(&cross_cpu_data.icache))
icache_enable();
else
icache_disable();
if (arc_read_uncached_32(&cross_cpu_data.dcache))
dcache_enable();
else
dcache_disable();
}
static void init_cluster_nvlim(void)
{
u32 val = env_common.nvlim.val << APERTURE_SHIFT;
flush_dcache_all();
write_aux_reg(ARC_AUX_NON_VOLATILE_LIMIT, val);
write_aux_reg(AUX_AUX_CACHE_LIMIT, val);
flush_n_invalidate_dcache_all();
}
static void init_master_icache(void)
{
if (icache_status()) {
/* I$ is enabled - we need to disable it */
if (!env_common.icache.val)
icache_disable();
} else {
/* I$ is disabled - we need to enable it */
if (env_common.icache.val) {
icache_enable();
/* invalidate I$ right after enable */
invalidate_icache_all();
}
}
}
static void init_master_dcache(void)
{
if (dcache_status()) {
/* D$ is enabled - we need to disable it */
if (!env_common.dcache.val)
dcache_disable();
} else {
/* D$ is disabled - we need to enable it */
if (env_common.dcache.val)
dcache_enable();
/* TODO: probably we need ti invalidate D$ right after enable */
}
}
static int cleanup_before_go(void)
{
disable_interrupts();
sync_n_cleanup_cache_all();
return 0;
}
void slave_cpu_set_boot_addr(u32 addr)
{
/* All cores have reset vector pointing to 0 */
writel(addr, (void __iomem *)RESET_VECTOR_ADDR);
/* Make sure other cores see written value in memory */
sync_n_cleanup_cache_all();
}
static inline void halt_this_cpu(void)
{
__builtin_arc_flag(1);
}
static void smp_kick_cpu_x(u32 cpu_id)
{
int cmd = readl((void __iomem *)CREG_CPU_START);
if (cpu_id > NR_CPUS)
return;
cmd &= ~CREG_CPU_START_MASK;
cmd |= (1 << cpu_id);
writel(cmd, (void __iomem *)CREG_CPU_START);
}
static u32 prepare_cpu_ctart_reg(void)
{
int cmd = readl((void __iomem *)CREG_CPU_START);
cmd &= ~CREG_CPU_START_MASK;
return cmd | env_common.core_mask.val;
}
/* slave CPU entry for configuration */
__attribute__((naked, noreturn, flatten)) noinline void hsdk_core_init_f(void)
{
__asm__ __volatile__(
"ld.di r8, [%0]\n"
"mov %%sp, r8\n"
"mov %%fp, %%sp\n"
: /* no output */
: "r" (&cross_cpu_data.stack_ptr));
invalidate_icache_all();
arc_write_uncached_32(&cross_cpu_data.status[CPU_ID_GET()], BOOTSTAGE_1);
init_slave_cpu_func(CPU_ID_GET());
arc_write_uncached_32(&cross_cpu_data.ready_flag, SLAVE_CPU_READY);
arc_write_uncached_32(&cross_cpu_data.status[CPU_ID_GET()], BOOTSTAGE_2);
/* Halt the processor until the master kick us again */
halt_this_cpu();
/*
* 3 NOPs after FLAG 1 instruction are no longer required for ARCv2
* cores but we leave them for gebug purposes.
*/
__builtin_arc_nop();
__builtin_arc_nop();
__builtin_arc_nop();
arc_write_uncached_32(&cross_cpu_data.status[CPU_ID_GET()], BOOTSTAGE_3);
/* get the updated entry - invalidate i$ */
invalidate_icache_all();
arc_write_uncached_32(&cross_cpu_data.status[CPU_ID_GET()], BOOTSTAGE_4);
/* Run our program */
((void (*)(void))(arc_read_uncached_32(&cross_cpu_data.entry[CPU_ID_GET()])))();
/* This bootstage is unreachable as we don't return from app we launch */
arc_write_uncached_32(&cross_cpu_data.status[CPU_ID_GET()], BOOTSTAGE_5);
/* Something went terribly wrong */
while (true)
halt_this_cpu();
}
static void clear_cross_cpu_data(void)
{
arc_write_uncached_32(&cross_cpu_data.ready_flag, 0);
arc_write_uncached_32(&cross_cpu_data.stack_ptr, 0);
for (u32 i = 0; i < NR_CPUS; i++)
arc_write_uncached_32(&cross_cpu_data.status[i], 0);
}
static noinline void do_init_slave_cpu(u32 cpu_id)
{
/* attempts number for check clave CPU ready_flag */
u32 attempts = 100;
u32 stack_ptr = (u32)(slave_stack + (64 * cpu_id));
if (cpu_id >= NR_CPUS)
return;
arc_write_uncached_32(&cross_cpu_data.ready_flag, 0);
/* Use global unique place for each slave cpu stack */
arc_write_uncached_32(&cross_cpu_data.stack_ptr, stack_ptr);
debug("CPU %u: stack pool base: %p\n", cpu_id, slave_stack);
debug("CPU %u: current slave stack base: %x\n", cpu_id, stack_ptr);
slave_cpu_set_boot_addr((u32)hsdk_core_init_f);
smp_kick_cpu_x(cpu_id);
debug("CPU %u: cross-cpu flag: %x [before timeout]\n", cpu_id,
arc_read_uncached_32(&cross_cpu_data.ready_flag));
while (!arc_read_uncached_32(&cross_cpu_data.ready_flag) && attempts--)
mdelay(10);
/* Just to be sure that slave cpu is halted after it set ready_flag */
mdelay(20);
/*
* Only print error here if we reach timeout as there is no option to
* halt slave cpu (or check that slave cpu is halted)
*/
if (!attempts)
pr_err("CPU %u is not responding after init!\n", cpu_id);
/* Check current stage of slave cpu */
if (arc_read_uncached_32(&cross_cpu_data.status[cpu_id]) != BOOTSTAGE_2)
pr_err("CPU %u status is unexpected: %d\n", cpu_id,
arc_read_uncached_32(&cross_cpu_data.status[cpu_id]));
debug("CPU %u: cross-cpu flag: %x [after timeout]\n", cpu_id,
arc_read_uncached_32(&cross_cpu_data.ready_flag));
debug("CPU %u: status: %d [after timeout]\n", cpu_id,
arc_read_uncached_32(&cross_cpu_data.status[cpu_id]));
}
static void do_init_slave_cpus(void)
{
clear_cross_cpu_data();
sync_cross_cpu_data();
debug("cross_cpu_data location: %#x\n", (u32)&cross_cpu_data);
for (u32 i = MASTER_CPU_ID + 1; i < NR_CPUS; i++)
if (is_cpu_used(i))
do_init_slave_cpu(i);
}
static void do_init_master_cpu(void)
{
/*
* Setup master caches even if master isn't used as we want to use
* same cache configuration on all running CPUs
*/
init_master_icache();
init_master_dcache();
}
enum hsdk_axi_masters {
M_HS_CORE = 0,
M_HS_RTT,
M_AXI_TUN,
M_HDMI_VIDEO,
M_HDMI_AUDIO,
M_USB_HOST,
M_ETHERNET,
M_SDIO,
M_GPU,
M_DMAC_0,
M_DMAC_1,
M_DVFS
};
#define UPDATE_VAL 1
/*
* m master AXI_M_m_SLV0 AXI_M_m_SLV1 AXI_M_m_OFFSET0 AXI_M_m_OFFSET1
* 0 HS (CBU) 0x11111111 0x63111111 0xFEDCBA98 0x0E543210
* 1 HS (RTT) 0x77777777 0x77777777 0xFEDCBA98 0x76543210
* 2 AXI Tunnel 0x88888888 0x88888888 0xFEDCBA98 0x76543210
* 3 HDMI-VIDEO 0x77777777 0x77777777 0xFEDCBA98 0x76543210
* 4 HDMI-ADUIO 0x77777777 0x77777777 0xFEDCBA98 0x76543210
* 5 USB-HOST 0x77777777 0x77999999 0xFEDCBA98 0x76DCBA98
* 6 ETHERNET 0x77777777 0x77999999 0xFEDCBA98 0x76DCBA98
* 7 SDIO 0x77777777 0x77999999 0xFEDCBA98 0x76DCBA98
* 8 GPU 0x77777777 0x77777777 0xFEDCBA98 0x76543210
* 9 DMAC (port #1) 0x77777777 0x77777777 0xFEDCBA98 0x76543210
* 10 DMAC (port #2) 0x77777777 0x77777777 0xFEDCBA98 0x76543210
* 11 DVFS 0x00000000 0x60000000 0x00000000 0x00000000
*
* Please read ARC HS Development IC Specification, section 17.2 for more
* information about apertures configuration.
* NOTE: we intentionally modify default settings in U-boot. Default settings
* are specified in "Table 111 CREG Address Decoder register reset values".
*/
#define CREG_AXI_M_SLV0(m) ((void __iomem *)(CREG_BASE + 0x020 * (m)))
#define CREG_AXI_M_SLV1(m) ((void __iomem *)(CREG_BASE + 0x020 * (m) + 0x004))
#define CREG_AXI_M_OFT0(m) ((void __iomem *)(CREG_BASE + 0x020 * (m) + 0x008))
#define CREG_AXI_M_OFT1(m) ((void __iomem *)(CREG_BASE + 0x020 * (m) + 0x00C))
#define CREG_AXI_M_UPDT(m) ((void __iomem *)(CREG_BASE + 0x020 * (m) + 0x014))
#define CREG_AXI_M_HS_CORE_BOOT ((void __iomem *)(CREG_BASE + 0x010))
#define CREG_PAE ((void __iomem *)(CREG_BASE + 0x180))
#define CREG_PAE_UPDT ((void __iomem *)(CREG_BASE + 0x194))
void init_memory_bridge(void)
{
u32 reg;
/*
* M_HS_CORE has one unic register - BOOT.
* We need to clean boot mirror (BOOT[1:0]) bits in them.
*/
reg = readl(CREG_AXI_M_HS_CORE_BOOT) & (~0x3);
writel(reg, CREG_AXI_M_HS_CORE_BOOT);
writel(0x11111111, CREG_AXI_M_SLV0(M_HS_CORE));
writel(0x63111111, CREG_AXI_M_SLV1(M_HS_CORE));
writel(0xFEDCBA98, CREG_AXI_M_OFT0(M_HS_CORE));
writel(0x0E543210, CREG_AXI_M_OFT1(M_HS_CORE));
writel(UPDATE_VAL, CREG_AXI_M_UPDT(M_HS_CORE));
writel(0x77777777, CREG_AXI_M_SLV0(M_HS_RTT));
writel(0x77777777, CREG_AXI_M_SLV1(M_HS_RTT));
writel(0xFEDCBA98, CREG_AXI_M_OFT0(M_HS_RTT));
writel(0x76543210, CREG_AXI_M_OFT1(M_HS_RTT));
writel(UPDATE_VAL, CREG_AXI_M_UPDT(M_HS_RTT));
writel(0x88888888, CREG_AXI_M_SLV0(M_AXI_TUN));
writel(0x88888888, CREG_AXI_M_SLV1(M_AXI_TUN));
writel(0xFEDCBA98, CREG_AXI_M_OFT0(M_AXI_TUN));
writel(0x76543210, CREG_AXI_M_OFT1(M_AXI_TUN));
writel(UPDATE_VAL, CREG_AXI_M_UPDT(M_AXI_TUN));
writel(0x77777777, CREG_AXI_M_SLV0(M_HDMI_VIDEO));
writel(0x77777777, CREG_AXI_M_SLV1(M_HDMI_VIDEO));
writel(0xFEDCBA98, CREG_AXI_M_OFT0(M_HDMI_VIDEO));
writel(0x76543210, CREG_AXI_M_OFT1(M_HDMI_VIDEO));
writel(UPDATE_VAL, CREG_AXI_M_UPDT(M_HDMI_VIDEO));
writel(0x77777777, CREG_AXI_M_SLV0(M_HDMI_AUDIO));
writel(0x77777777, CREG_AXI_M_SLV1(M_HDMI_AUDIO));
writel(0xFEDCBA98, CREG_AXI_M_OFT0(M_HDMI_AUDIO));
writel(0x76543210, CREG_AXI_M_OFT1(M_HDMI_AUDIO));
writel(UPDATE_VAL, CREG_AXI_M_UPDT(M_HDMI_AUDIO));
writel(0x77777777, CREG_AXI_M_SLV0(M_USB_HOST));
writel(0x77999999, CREG_AXI_M_SLV1(M_USB_HOST));
writel(0xFEDCBA98, CREG_AXI_M_OFT0(M_USB_HOST));
writel(0x76DCBA98, CREG_AXI_M_OFT1(M_USB_HOST));
writel(UPDATE_VAL, CREG_AXI_M_UPDT(M_USB_HOST));
writel(0x77777777, CREG_AXI_M_SLV0(M_ETHERNET));
writel(0x77999999, CREG_AXI_M_SLV1(M_ETHERNET));
writel(0xFEDCBA98, CREG_AXI_M_OFT0(M_ETHERNET));
writel(0x76DCBA98, CREG_AXI_M_OFT1(M_ETHERNET));
writel(UPDATE_VAL, CREG_AXI_M_UPDT(M_ETHERNET));
writel(0x77777777, CREG_AXI_M_SLV0(M_SDIO));
writel(0x77999999, CREG_AXI_M_SLV1(M_SDIO));
writel(0xFEDCBA98, CREG_AXI_M_OFT0(M_SDIO));
writel(0x76DCBA98, CREG_AXI_M_OFT1(M_SDIO));
writel(UPDATE_VAL, CREG_AXI_M_UPDT(M_SDIO));
writel(0x77777777, CREG_AXI_M_SLV0(M_GPU));
writel(0x77777777, CREG_AXI_M_SLV1(M_GPU));
writel(0xFEDCBA98, CREG_AXI_M_OFT0(M_GPU));
writel(0x76543210, CREG_AXI_M_OFT1(M_GPU));
writel(UPDATE_VAL, CREG_AXI_M_UPDT(M_GPU));
writel(0x77777777, CREG_AXI_M_SLV0(M_DMAC_0));
writel(0x77777777, CREG_AXI_M_SLV1(M_DMAC_0));
writel(0xFEDCBA98, CREG_AXI_M_OFT0(M_DMAC_0));
writel(0x76543210, CREG_AXI_M_OFT1(M_DMAC_0));
writel(UPDATE_VAL, CREG_AXI_M_UPDT(M_DMAC_0));
writel(0x77777777, CREG_AXI_M_SLV0(M_DMAC_1));
writel(0x77777777, CREG_AXI_M_SLV1(M_DMAC_1));
writel(0xFEDCBA98, CREG_AXI_M_OFT0(M_DMAC_1));
writel(0x76543210, CREG_AXI_M_OFT1(M_DMAC_1));
writel(UPDATE_VAL, CREG_AXI_M_UPDT(M_DMAC_1));
writel(0x00000000, CREG_AXI_M_SLV0(M_DVFS));
writel(0x60000000, CREG_AXI_M_SLV1(M_DVFS));
writel(0x00000000, CREG_AXI_M_OFT0(M_DVFS));
writel(0x00000000, CREG_AXI_M_OFT1(M_DVFS));
writel(UPDATE_VAL, CREG_AXI_M_UPDT(M_DVFS));
writel(0x00000000, CREG_PAE);
writel(UPDATE_VAL, CREG_PAE_UPDT);
}
static void setup_clocks(void)
{
ulong rate;
/* Setup CPU clock */
if (env_common.cpu_freq.set) {
rate = env_common.cpu_freq.val;
soc_clk_ctl("cpu-clk", &rate, CLK_ON | CLK_SET | CLK_MHZ);
}
/* Setup TUN clock */
if (env_common.tun_freq.set) {
rate = env_common.tun_freq.val;
if (rate)
soc_clk_ctl("tun-clk", &rate, CLK_ON | CLK_SET | CLK_MHZ);
else
soc_clk_ctl("tun-clk", NULL, CLK_OFF);
}
if (env_common.axi_freq.set) {
rate = env_common.axi_freq.val;
soc_clk_ctl("axi-clk", &rate, CLK_SET | CLK_ON | CLK_MHZ);
}
}
static void do_init_cluster(void)
{
/*
* A multi-core ARC HS configuration always includes only one
* ARC_AUX_NON_VOLATILE_LIMIT register, which is shared by all the
* cores.
*/
init_cluster_nvlim();
}
static int check_master_cpu_id(void)
{
if (CPU_ID_GET() == MASTER_CPU_ID)
return 0;
pr_err("u-boot runs on non-master cpu with id: %lu\n", CPU_ID_GET());
return -ENOENT;
}
static noinline int prepare_cpus(void)
{
int ret;
ret = check_master_cpu_id();
if (ret)
return ret;
ret = envs_process_and_validate(env_map_common, env_map_core, is_cpu_used);
if (ret)
return ret;
printf("CPU start mask is %#x\n", env_common.core_mask.val);
do_init_slave_cpus();
do_init_master_cpu();
do_init_cluster();
return 0;
}
static int hsdk_go_run(u32 cpu_start_reg)
{
/* Cleanup caches, disable interrupts */
cleanup_before_go();
if (env_common.halt_on_boot)
halt_this_cpu();
/*
* 3 NOPs after FLAG 1 instruction are no longer required for ARCv2
* cores but we leave them for gebug purposes.
*/
__builtin_arc_nop();
__builtin_arc_nop();
__builtin_arc_nop();
/* Kick chosen slave CPUs */
writel(cpu_start_reg, (void __iomem *)CREG_CPU_START);
if (is_cpu_used(MASTER_CPU_ID))
((void (*)(void))(env_core.entry[MASTER_CPU_ID].val))();
else
halt_this_cpu();
pr_err("u-boot still runs on cpu [%ld]\n", CPU_ID_GET());
/*
* We will never return after executing our program if master cpu used
* otherwise halt master cpu manually.
*/
while (true)
halt_this_cpu();
return 0;
}
int board_prep_linux(bootm_headers_t *images)
{
int ret, ofst;
char mask[15];
ret = envs_read_validate_common(env_map_mask);
if (ret)
return ret;
/* Rollback to default values */
if (!env_common.core_mask.set) {
env_common.core_mask.val = ALL_CPU_MASK;
env_common.core_mask.set = true;
}
printf("CPU start mask is %#x\n", env_common.core_mask.val);
if (!is_cpu_used(MASTER_CPU_ID))
pr_err("ERR: try to launch linux with CPU[0] disabled! It doesn't work for ARC.\n");
/*
* If we want to launch linux on all CPUs we don't need to patch
* linux DTB as it is default configuration
*/
if (env_common.core_mask.val == ALL_CPU_MASK)
return 0;
if (!IMAGE_ENABLE_OF_LIBFDT || !images->ft_len) {
pr_err("WARN: core_mask setup will work properly only with external DTB!\n");
return 0;
}
/* patch '/possible-cpus' property according to cpu mask */
ofst = fdt_path_offset(images->ft_addr, "/");
sprintf(mask, "%s%s%s%s",
is_cpu_used(0) ? "0," : "",
is_cpu_used(1) ? "1," : "",
is_cpu_used(2) ? "2," : "",
is_cpu_used(3) ? "3," : "");
ret = fdt_setprop_string(images->ft_addr, ofst, "possible-cpus", mask);
/*
* If we failed to patch '/possible-cpus' property we don't need break
* linux loading process: kernel will handle it but linux will print
* warning like "Timeout: CPU1 FAILED to comeup !!!".
* So warn here about error, but return 0 like no error had occurred.
*/
if (ret)
pr_err("WARN: failed to patch '/possible-cpus' property, ret=%d\n",
ret);
return 0;
}
void board_jump_and_run(ulong entry, int zero, int arch, uint params)
{
void (*kernel_entry)(int zero, int arch, uint params);
u32 cpu_start_reg;
kernel_entry = (void (*)(int, int, uint))entry;
/* Prepare CREG_CPU_START for kicking chosen CPUs */
cpu_start_reg = prepare_cpu_ctart_reg();
/* In case of run without hsdk_init */
slave_cpu_set_boot_addr(entry);
/* In case of run with hsdk_init */
for (u32 i = 0; i < NR_CPUS; i++) {
env_core.entry[i].val = entry;
env_core.entry[i].set = true;
}
/* sync cross_cpu struct as we updated core-entry variables */
sync_cross_cpu_data();
/* Kick chosen slave CPUs */
writel(cpu_start_reg, (void __iomem *)CREG_CPU_START);
if (is_cpu_used(0))
kernel_entry(zero, arch, params);
}
static int hsdk_go_prepare_and_run(void)
{
/* Prepare CREG_CPU_START for kicking chosen CPUs */
u32 reg = prepare_cpu_ctart_reg();
if (env_common.halt_on_boot)
printf("CPU will halt before application start, start application with debugger.\n");
return hsdk_go_run(reg);
}
static int do_hsdk_go(cmd_tbl_t *cmdtp, int flag, int argc, char *const argv[])
{
int ret;
/*
* Check for 'halt' parameter. 'halt' = enter halt-mode just before
* starting the application; can be used for debug.
*/
if (argc > 1) {
env_common.halt_on_boot = !strcmp(argv[1], "halt");
if (!env_common.halt_on_boot) {
pr_err("Unrecognised parameter: \'%s\'\n", argv[1]);
return CMD_RET_FAILURE;
}
}
ret = check_master_cpu_id();
if (ret)
return ret;
ret = envs_process_and_validate(env_map_mask, env_map_go, is_cpu_used);
if (ret)
return ret;
/* sync cross_cpu struct as we updated core-entry variables */
sync_cross_cpu_data();
ret = hsdk_go_prepare_and_run();
return ret ? CMD_RET_FAILURE : CMD_RET_SUCCESS;
}
U_BOOT_CMD(
hsdk_go, 3, 0, do_hsdk_go,
"Synopsys HSDK specific command",
" - Boot stand-alone application on HSDK\n"
"hsdk_go halt - Boot stand-alone application on HSDK, halt CPU just before application run\n"
);
static int do_hsdk_init(cmd_tbl_t *cmdtp, int flag, int argc, char *const argv[])
{
static bool done = false;
int ret;
/* hsdk_init can be run only once */
if (done) {
printf("HSDK HW is already initialized! Please reset the board if you want to change the configuration.\n");
return CMD_RET_FAILURE;
}
ret = prepare_cpus();
if (!ret)
done = true;
return ret ? CMD_RET_FAILURE : CMD_RET_SUCCESS;
}
U_BOOT_CMD(
hsdk_init, 1, 0, do_hsdk_init,
"Synopsys HSDK specific command",
"- Init HSDK HW\n"
);
static int do_hsdk_clock_set(cmd_tbl_t *cmdtp, int flag, int argc,
char *const argv[])
{
int ret = 0;
/* Strip off leading subcommand argument */
argc--;
argv++;
envs_cleanup_common(env_map_clock);
if (!argc) {
printf("Set clocks to values specified in environment\n");
ret = envs_read_common(env_map_clock);
} else {
printf("Set clocks to values specified in args\n");
ret = args_envs_enumerate(env_map_clock, 2, argc, argv);
}
if (ret)
return CMD_RET_FAILURE;
ret = envs_validate_common(env_map_clock);
if (ret)
return CMD_RET_FAILURE;
/* Setup clock tree HW */
setup_clocks();
return CMD_RET_SUCCESS;
}
static int do_hsdk_clock_get(cmd_tbl_t *cmdtp, int flag, int argc,
char *const argv[])
{
ulong rate;
if (soc_clk_ctl("cpu-clk", &rate, CLK_GET | CLK_MHZ))
return CMD_RET_FAILURE;
if (env_set_ulong("cpu_freq", rate))
return CMD_RET_FAILURE;
if (soc_clk_ctl("tun-clk", &rate, CLK_GET | CLK_MHZ))
return CMD_RET_FAILURE;
if (env_set_ulong("tun_freq", rate))
return CMD_RET_FAILURE;
if (soc_clk_ctl("axi-clk", &rate, CLK_GET | CLK_MHZ))
return CMD_RET_FAILURE;
if (env_set_ulong("axi_freq", rate))
return CMD_RET_FAILURE;
printf("Clock values are saved to environment\n");
return CMD_RET_SUCCESS;
}
static int do_hsdk_clock_print(cmd_tbl_t *cmdtp, int flag, int argc,
char *const argv[])
{
/* Main clocks */
soc_clk_ctl("cpu-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("tun-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("axi-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("ddr-clk", NULL, CLK_PRINT | CLK_MHZ);
return CMD_RET_SUCCESS;
}
static int do_hsdk_clock_print_all(cmd_tbl_t *cmdtp, int flag, int argc,
char *const argv[])
{
/*
* NOTE: as of today we don't use some peripherals like HDMI / EBI
* so we don't want to print their clocks ("hdmi-sys-clk", "hdmi-pll",
* "hdmi-clk", "ebi-clk"). Nevertheless their clock subsystems is fully
* functional and we can print their clocks if it is required
*/
/* CPU clock domain */
soc_clk_ctl("cpu-pll", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("cpu-clk", NULL, CLK_PRINT | CLK_MHZ);
printf("\n");
/* SYS clock domain */
soc_clk_ctl("sys-pll", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("apb-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("axi-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("eth-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("usb-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("sdio-clk", NULL, CLK_PRINT | CLK_MHZ);
/* soc_clk_ctl("hdmi-sys-clk", NULL, CLK_PRINT | CLK_MHZ); */
soc_clk_ctl("gfx-core-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("gfx-dma-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("gfx-cfg-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("dmac-core-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("dmac-cfg-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("sdio-ref-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("spi-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("i2c-clk", NULL, CLK_PRINT | CLK_MHZ);
/* soc_clk_ctl("ebi-clk", NULL, CLK_PRINT | CLK_MHZ); */
soc_clk_ctl("uart-clk", NULL, CLK_PRINT | CLK_MHZ);
printf("\n");
/* DDR clock domain */
soc_clk_ctl("ddr-clk", NULL, CLK_PRINT | CLK_MHZ);
printf("\n");
/* HDMI clock domain */
/* soc_clk_ctl("hdmi-pll", NULL, CLK_PRINT | CLK_MHZ); */
/* soc_clk_ctl("hdmi-clk", NULL, CLK_PRINT | CLK_MHZ); */
/* printf("\n"); */
/* TUN clock domain */
soc_clk_ctl("tun-pll", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("tun-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("rom-clk", NULL, CLK_PRINT | CLK_MHZ);
soc_clk_ctl("pwm-clk", NULL, CLK_PRINT | CLK_MHZ);
printf("\n");
return CMD_RET_SUCCESS;
}
cmd_tbl_t cmd_hsdk_clock[] = {
U_BOOT_CMD_MKENT(set, 3, 0, do_hsdk_clock_set, "", ""),
U_BOOT_CMD_MKENT(get, 3, 0, do_hsdk_clock_get, "", ""),
U_BOOT_CMD_MKENT(print, 4, 0, do_hsdk_clock_print, "", ""),
U_BOOT_CMD_MKENT(print_all, 4, 0, do_hsdk_clock_print_all, "", ""),
};
static int do_hsdk_clock(cmd_tbl_t *cmdtp, int flag, int argc, char *const argv[])
{
cmd_tbl_t *c;
if (argc < 2)
return CMD_RET_USAGE;
/* Strip off leading 'hsdk_clock' command argument */
argc--;
argv++;
c = find_cmd_tbl(argv[0], cmd_hsdk_clock, ARRAY_SIZE(cmd_hsdk_clock));
if (!c)
return CMD_RET_USAGE;
return c->cmd(cmdtp, flag, argc, argv);
}
U_BOOT_CMD(
hsdk_clock, CONFIG_SYS_MAXARGS, 0, do_hsdk_clock,
"Synopsys HSDK specific clock command",
"set - Set clock to values specified in environment / command line arguments\n"
"hsdk_clock get - Save clock values to environment\n"
"hsdk_clock print - Print main clock values to console\n"
"hsdk_clock print_all - Print all clock values to console\n"
);
/* init calls */
int board_early_init_f(void)
{
/*
* Setup AXI apertures unconditionally as we want to have DDR
* in 0x00000000 region when we are kicking slave cpus.
*/
init_memory_bridge();
return 0;
}
int board_early_init_r(void)
{
/*
* TODO: Init USB here to be able read environment from USB MSD.
* It can be done with usb_init() call. We can't do it right now
* due to brocken USB IP SW reset and lack of USB IP HW reset in
* linux kernel (if we init USB here we will break USB in linux)
*/
/*
* Flush all d$ as we want to use uncached area with st.di / ld.di
* instructions and we don't want to have any dirty line in L1d$ or SL$
* in this area. It is enough to flush all d$ once here as we access to
* uncached area with regular st (non .di) instruction only when we copy
* data during u-boot relocation.
*/
flush_dcache_all();
printf("Relocation Offset is: %08lx\n", gd->reloc_off);
return 0;
}
int board_late_init(void)
{
/*
* Populate environment with clock frequency values -
* run hsdk_clock get callback without uboot command run.
*/
do_hsdk_clock_get(NULL, 0, 0, NULL);
return 0;
}
int board_mmc_init(bd_t *bis)
{
struct dwmci_host *host = NULL;
host = malloc(sizeof(struct dwmci_host));
if (!host) {
printf("dwmci_host malloc fail!\n");
return 1;
}
/*
* Switch SDIO external ciu clock divider from default div-by-8 to
* minimum possible div-by-2.
*/
writel(SDIO_UHS_REG_EXT_DIV_2, (void __iomem *)SDIO_UHS_REG_EXT);
memset(host, 0, sizeof(struct dwmci_host));
host->name = "Synopsys Mobile storage";
host->ioaddr = (void *)ARC_DWMMC_BASE;
host->buswidth = 4;
host->dev_index = 0;
host->bus_hz = 50000000;
add_dwmci(host, host->bus_hz / 2, 400000);
return 0;
}
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