u-boot/arch/arm/mach-zynqmp/mp.c
Lukas Funke d9efdc7d42 arm64: zynqmp: dynamically mark r5 cores as used
When Linux boot takes over control of the pmu
(by signaling PM_INIT_FINALIZE via ipi), pmu will switch off 'unused'
rpu cores. The Xilinx zynqmp fsbl prevents switching off those cores by
marking rpu cores as 'used' when loading code partitions to those cores.
The current u-boot SPL is missing this behaviour, which results in
halting rpu cores during Linux boot.

This commit mimics the xilinx zynqmp fsbl behavior by marking r5 cores as
used when they are released during boot.

Signed-off-by: Lukas Funke <lukas.funke@weidmueller.com>
Signed-off-by: Lukas Funke <lukas.funke-oss@weidmueller.com>
Link: https://lore.kernel.org/r/20221028121547.26464-2-lukas.funke-oss@weidmueller.com
Signed-off-by: Michal Simek <michal.simek@amd.com>
2022-12-05 08:55:54 +01:00

353 lines
8.3 KiB
C

// SPDX-License-Identifier: GPL-2.0+
/*
* (C) Copyright 2014 - 2015 Xilinx, Inc.
* Michal Simek <michal.simek@xilinx.com>
*/
#include <common.h>
#include <cpu_func.h>
#include <log.h>
#include <asm/arch/hardware.h>
#include <asm/arch/sys_proto.h>
#include <asm/io.h>
#include <linux/delay.h>
#define LOCK 0
#define SPLIT 1
#define HALT 0
#define RELEASE 1
#define ZYNQMP_BOOTADDR_HIGH_MASK 0xFFFFFFFF
#define ZYNQMP_R5_HIVEC_ADDR 0xFFFF0000
#define ZYNQMP_R5_LOVEC_ADDR 0x0
#define ZYNQMP_RPU_CFG_CPU_HALT_MASK 0x01
#define ZYNQMP_RPU_CFG_HIVEC_MASK 0x04
#define ZYNQMP_RPU_GLBL_CTRL_SPLIT_LOCK_MASK 0x08
#define ZYNQMP_RPU_GLBL_CTRL_TCM_COMB_MASK 0x40
#define ZYNQMP_RPU_GLBL_CTRL_SLCLAMP_MASK 0x10
#define ZYNQMP_CRLAPB_RST_LPD_AMBA_RST_MASK 0x04
#define ZYNQMP_CRLAPB_RST_LPD_R50_RST_MASK 0x01
#define ZYNQMP_CRLAPB_RST_LPD_R51_RST_MASK 0x02
#define ZYNQMP_CRLAPB_CPU_R5_CTRL_CLKACT_MASK 0x1000000
#define ZYNQMP_TCM_START_ADDRESS 0xFFE00000
#define ZYNQMP_TCM_BOTH_SIZE 0x40000
#define ZYNQMP_CORE_APU0 0
#define ZYNQMP_CORE_APU3 3
#define ZYNQMP_CORE_RPU0 4
#define ZYNQMP_CORE_RPU1 5
#define ZYNQMP_MAX_CORES 6
#define ZYNQMP_RPU0_USE_MASK BIT(1)
#define ZYNQMP_RPU1_USE_MASK BIT(2)
int is_core_valid(unsigned int core)
{
if (core < ZYNQMP_MAX_CORES)
return 1;
return 0;
}
int cpu_reset(u32 nr)
{
puts("Feature is not implemented.\n");
return 0;
}
static void set_r5_halt_mode(u32 nr, u8 halt, u8 mode)
{
u32 tmp;
if (mode == LOCK || nr == ZYNQMP_CORE_RPU0) {
tmp = readl(&rpu_base->rpu0_cfg);
if (halt == HALT)
tmp &= ~ZYNQMP_RPU_CFG_CPU_HALT_MASK;
else
tmp |= ZYNQMP_RPU_CFG_CPU_HALT_MASK;
writel(tmp, &rpu_base->rpu0_cfg);
}
if (mode == LOCK || nr == ZYNQMP_CORE_RPU1) {
tmp = readl(&rpu_base->rpu1_cfg);
if (halt == HALT)
tmp &= ~ZYNQMP_RPU_CFG_CPU_HALT_MASK;
else
tmp |= ZYNQMP_RPU_CFG_CPU_HALT_MASK;
writel(tmp, &rpu_base->rpu1_cfg);
}
}
static void set_r5_tcm_mode(u8 mode)
{
u32 tmp;
tmp = readl(&rpu_base->rpu_glbl_ctrl);
if (mode == LOCK) {
tmp &= ~ZYNQMP_RPU_GLBL_CTRL_SPLIT_LOCK_MASK;
tmp |= ZYNQMP_RPU_GLBL_CTRL_TCM_COMB_MASK |
ZYNQMP_RPU_GLBL_CTRL_SLCLAMP_MASK;
} else {
tmp |= ZYNQMP_RPU_GLBL_CTRL_SPLIT_LOCK_MASK;
tmp &= ~(ZYNQMP_RPU_GLBL_CTRL_TCM_COMB_MASK |
ZYNQMP_RPU_GLBL_CTRL_SLCLAMP_MASK);
}
writel(tmp, &rpu_base->rpu_glbl_ctrl);
}
static void set_r5_reset(u32 nr, u8 mode)
{
u32 tmp;
tmp = readl(&crlapb_base->rst_lpd_top);
if (mode == LOCK) {
tmp |= (ZYNQMP_CRLAPB_RST_LPD_AMBA_RST_MASK |
ZYNQMP_CRLAPB_RST_LPD_R50_RST_MASK |
ZYNQMP_CRLAPB_RST_LPD_R51_RST_MASK);
} else {
if (nr == ZYNQMP_CORE_RPU0) {
tmp |= ZYNQMP_CRLAPB_RST_LPD_R50_RST_MASK;
if (tmp & ZYNQMP_CRLAPB_RST_LPD_R51_RST_MASK)
tmp |= ZYNQMP_CRLAPB_RST_LPD_AMBA_RST_MASK;
} else {
tmp |= ZYNQMP_CRLAPB_RST_LPD_R51_RST_MASK;
if (tmp & ZYNQMP_CRLAPB_RST_LPD_R50_RST_MASK)
tmp |= ZYNQMP_CRLAPB_RST_LPD_AMBA_RST_MASK;
}
}
writel(tmp, &crlapb_base->rst_lpd_top);
}
static void release_r5_reset(u32 nr, u8 mode)
{
u32 tmp;
tmp = readl(&crlapb_base->rst_lpd_top);
if (mode == LOCK || nr == ZYNQMP_CORE_RPU0)
tmp &= ~(ZYNQMP_CRLAPB_RST_LPD_AMBA_RST_MASK |
ZYNQMP_CRLAPB_RST_LPD_R50_RST_MASK);
if (mode == LOCK || nr == ZYNQMP_CORE_RPU1)
tmp &= ~(ZYNQMP_CRLAPB_RST_LPD_AMBA_RST_MASK |
ZYNQMP_CRLAPB_RST_LPD_R51_RST_MASK);
writel(tmp, &crlapb_base->rst_lpd_top);
}
static void enable_clock_r5(void)
{
u32 tmp;
tmp = readl(&crlapb_base->cpu_r5_ctrl);
tmp |= ZYNQMP_CRLAPB_CPU_R5_CTRL_CLKACT_MASK;
writel(tmp, &crlapb_base->cpu_r5_ctrl);
/* Give some delay for clock
* to propagate */
udelay(0x500);
}
static int check_r5_mode(void)
{
u32 tmp;
tmp = readl(&rpu_base->rpu_glbl_ctrl);
if (tmp & ZYNQMP_RPU_GLBL_CTRL_SPLIT_LOCK_MASK)
return SPLIT;
return LOCK;
}
int cpu_disable(u32 nr)
{
if (nr <= ZYNQMP_CORE_APU3) {
u32 val = readl(&crfapb_base->rst_fpd_apu);
val |= 1 << nr;
writel(val, &crfapb_base->rst_fpd_apu);
} else {
set_r5_reset(nr, check_r5_mode());
}
return 0;
}
int cpu_status(u32 nr)
{
if (nr <= ZYNQMP_CORE_APU3) {
u32 addr_low = readl(((u8 *)&apu_base->rvbar_addr0_l) + nr * 8);
u32 addr_high = readl(((u8 *)&apu_base->rvbar_addr0_h) +
nr * 8);
u32 val = readl(&crfapb_base->rst_fpd_apu);
val &= 1 << nr;
printf("APU CPU%d %s - starting address HI: %x, LOW: %x\n",
nr, val ? "OFF" : "ON" , addr_high, addr_low);
} else {
u32 val = readl(&crlapb_base->rst_lpd_top);
val &= 1 << (nr - 4);
printf("RPU CPU%d %s\n", nr - 4, val ? "OFF" : "ON");
}
return 0;
}
static void set_r5_start(u8 high)
{
u32 tmp;
tmp = readl(&rpu_base->rpu0_cfg);
if (high)
tmp |= ZYNQMP_RPU_CFG_HIVEC_MASK;
else
tmp &= ~ZYNQMP_RPU_CFG_HIVEC_MASK;
writel(tmp, &rpu_base->rpu0_cfg);
tmp = readl(&rpu_base->rpu1_cfg);
if (high)
tmp |= ZYNQMP_RPU_CFG_HIVEC_MASK;
else
tmp &= ~ZYNQMP_RPU_CFG_HIVEC_MASK;
writel(tmp, &rpu_base->rpu1_cfg);
}
static void write_tcm_boot_trampoline(u32 boot_addr)
{
if (boot_addr) {
/*
* Boot trampoline is simple ASM code below.
*
* b over;
* label:
* .word 0
* over: ldr r0, =label
* ldr r1, [r0]
* bx r1
*/
debug("Write boot trampoline for %x\n", boot_addr);
writel(0xea000000, ZYNQMP_TCM_START_ADDRESS);
writel(boot_addr, ZYNQMP_TCM_START_ADDRESS + 0x4);
writel(0xe59f0004, ZYNQMP_TCM_START_ADDRESS + 0x8);
writel(0xe5901000, ZYNQMP_TCM_START_ADDRESS + 0xc);
writel(0xe12fff11, ZYNQMP_TCM_START_ADDRESS + 0x10);
writel(0x00000004, ZYNQMP_TCM_START_ADDRESS + 0x14); // address for
}
}
void initialize_tcm(bool mode)
{
if (!mode) {
set_r5_tcm_mode(LOCK);
set_r5_halt_mode(ZYNQMP_CORE_RPU0, HALT, LOCK);
enable_clock_r5();
release_r5_reset(ZYNQMP_CORE_RPU0, LOCK);
} else {
set_r5_tcm_mode(SPLIT);
set_r5_halt_mode(ZYNQMP_CORE_RPU1, HALT, SPLIT);
enable_clock_r5();
release_r5_reset(ZYNQMP_CORE_RPU1, SPLIT);
}
}
static void mark_r5_used(u32 nr, u8 mode)
{
u32 mask = 0;
if (mode == LOCK) {
mask = ZYNQMP_RPU0_USE_MASK | ZYNQMP_RPU1_USE_MASK;
} else {
switch (nr) {
case ZYNQMP_CORE_RPU0:
mask = ZYNQMP_RPU0_USE_MASK;
break;
case ZYNQMP_CORE_RPU1:
mask = ZYNQMP_RPU1_USE_MASK;
break;
default:
return;
}
}
zynqmp_mmio_write((ulong)&pmu_base->gen_storage4, mask, mask);
}
int cpu_release(u32 nr, int argc, char *const argv[])
{
if (nr <= ZYNQMP_CORE_APU3) {
u64 boot_addr = simple_strtoull(argv[0], NULL, 16);
/* HIGH */
writel((u32)(boot_addr >> 32),
((u8 *)&apu_base->rvbar_addr0_h) + nr * 8);
/* LOW */
writel((u32)(boot_addr & ZYNQMP_BOOTADDR_HIGH_MASK),
((u8 *)&apu_base->rvbar_addr0_l) + nr * 8);
u32 val = readl(&crfapb_base->rst_fpd_apu);
val &= ~(1 << nr);
writel(val, &crfapb_base->rst_fpd_apu);
} else {
if (argc != 2) {
printf("Invalid number of arguments to release.\n");
printf("<addr> <mode>-Start addr lockstep or split\n");
return 1;
}
u32 boot_addr = hextoul(argv[0], NULL);
u32 boot_addr_uniq = 0;
if (!(boot_addr == ZYNQMP_R5_LOVEC_ADDR ||
boot_addr == ZYNQMP_R5_HIVEC_ADDR)) {
printf("Using TCM jump trampoline for address 0x%x\n",
boot_addr);
/* Save boot address for later usage */
boot_addr_uniq = boot_addr;
/*
* R5 needs to start from LOVEC at TCM
* OCM will be probably occupied by ATF
*/
boot_addr = ZYNQMP_R5_LOVEC_ADDR;
}
/*
* Since we don't know where the user may have loaded the image
* for an R5 we have to flush all the data cache to ensure
* the R5 sees it.
*/
flush_dcache_all();
if (!strncmp(argv[1], "lockstep", 8)) {
printf("R5 lockstep mode\n");
set_r5_reset(nr, LOCK);
set_r5_tcm_mode(LOCK);
set_r5_halt_mode(nr, HALT, LOCK);
set_r5_start(boot_addr);
enable_clock_r5();
release_r5_reset(nr, LOCK);
dcache_disable();
write_tcm_boot_trampoline(boot_addr_uniq);
dcache_enable();
set_r5_halt_mode(nr, RELEASE, LOCK);
mark_r5_used(nr, LOCK);
} else if (!strncmp(argv[1], "split", 5)) {
printf("R5 split mode\n");
set_r5_reset(nr, SPLIT);
set_r5_tcm_mode(SPLIT);
set_r5_halt_mode(nr, HALT, SPLIT);
set_r5_start(boot_addr);
enable_clock_r5();
release_r5_reset(nr, SPLIT);
dcache_disable();
write_tcm_boot_trampoline(boot_addr_uniq);
dcache_enable();
set_r5_halt_mode(nr, RELEASE, SPLIT);
mark_r5_used(nr, SPLIT);
} else {
printf("Unsupported mode\n");
return 1;
}
}
return 0;
}