blob: 7e32af371b715d13d3d134b92254daca3341ea08 [file] [log] [blame]
/*
* SPDX-License-Identifier: BSD-2-Clause
*
* Copyright (c) 2020 Western Digital Corporation or its affiliates.
*
* Authors:
* Atish Patra <atish.patra@wdc.com>
*/
#include <sbi/riscv_asm.h>
#include <sbi/riscv_barrier.h>
#include <sbi/riscv_encoding.h>
#include <sbi/riscv_atomic.h>
#include <sbi/sbi_bitops.h>
#include <sbi/sbi_console.h>
#include <sbi/sbi_domain.h>
#include <sbi/sbi_error.h>
#include <sbi/sbi_ecall_interface.h>
#include <sbi/sbi_hart.h>
#include <sbi/sbi_hartmask.h>
#include <sbi/sbi_hsm.h>
#include <sbi/sbi_init.h>
#include <sbi/sbi_ipi.h>
#include <sbi/sbi_scratch.h>
#include <sbi/sbi_system.h>
#include <sbi/sbi_timer.h>
#include <sbi/sbi_console.h>
#define __sbi_hsm_hart_change_state(hdata, oldstate, newstate) \
({ \
long state = atomic_cmpxchg(&(hdata)->state, oldstate, newstate); \
if (state != (oldstate)) \
sbi_printf("%s: ERR: The hart is in invalid state [%lu]\n", \
__func__, state); \
state == (oldstate); \
})
static const struct sbi_hsm_device *hsm_dev = NULL;
static unsigned long hart_data_offset;
/** Per hart specific data to manage state transition **/
struct sbi_hsm_data {
atomic_t state;
unsigned long suspend_type;
unsigned long saved_mie;
unsigned long saved_mip;
unsigned long saved_medeleg;
unsigned long saved_menvcfg;
#if __riscv_xlen == 32
unsigned long saved_menvcfgh;
#endif
atomic_t start_ticket;
};
bool sbi_hsm_hart_change_state(struct sbi_scratch *scratch, long oldstate,
long newstate)
{
struct sbi_hsm_data *hdata = sbi_scratch_offset_ptr(scratch,
hart_data_offset);
return __sbi_hsm_hart_change_state(hdata, oldstate, newstate);
}
int __sbi_hsm_hart_get_state(u32 hartid)
{
struct sbi_hsm_data *hdata;
struct sbi_scratch *scratch;
scratch = sbi_hartid_to_scratch(hartid);
if (!scratch)
return SBI_EINVAL;
hdata = sbi_scratch_offset_ptr(scratch, hart_data_offset);
return atomic_read(&hdata->state);
}
int sbi_hsm_hart_get_state(const struct sbi_domain *dom, u32 hartid)
{
if (!sbi_domain_is_assigned_hart(dom, hartid))
return SBI_EINVAL;
return __sbi_hsm_hart_get_state(hartid);
}
/*
* Try to acquire the ticket for the given target hart to make sure only
* one hart prepares the start of the target hart.
* Returns true if the ticket has been acquired, false otherwise.
*
* The function has "acquire" semantics: no memory operations following it
* in the current hart can be seen before it by other harts.
* atomic_cmpxchg() provides the memory barriers needed for that.
*/
static bool hsm_start_ticket_acquire(struct sbi_hsm_data *hdata)
{
return (atomic_cmpxchg(&hdata->start_ticket, 0, 1) == 0);
}
/*
* Release the ticket for the given target hart.
*
* The function has "release" semantics: no memory operations preceding it
* in the current hart can be seen after it by other harts.
*/
static void hsm_start_ticket_release(struct sbi_hsm_data *hdata)
{
RISCV_FENCE(rw, w);
atomic_write(&hdata->start_ticket, 0);
}
/**
* Get ulong HART mask for given HART base ID
* @param dom the domain to be used for output HART mask
* @param hbase the HART base ID
* @param out_hmask the output ulong HART mask
* @return 0 on success and SBI_Exxx (< 0) on failure
* Note: the output HART mask will be set to zero on failure as well.
*/
int sbi_hsm_hart_interruptible_mask(const struct sbi_domain *dom,
ulong hbase, ulong *out_hmask)
{
int hstate;
ulong i, hmask, dmask;
*out_hmask = 0;
if (!sbi_hartid_valid(hbase))
return SBI_EINVAL;
dmask = sbi_domain_get_assigned_hartmask(dom, hbase);
for (i = 0; i < BITS_PER_LONG; i++) {
hmask = 1UL << i;
if (!(dmask & hmask))
continue;
hstate = __sbi_hsm_hart_get_state(hbase + i);
if (hstate == SBI_HSM_STATE_STARTED ||
hstate == SBI_HSM_STATE_SUSPENDED ||
hstate == SBI_HSM_STATE_RESUME_PENDING)
*out_hmask |= hmask;
}
return 0;
}
void __noreturn sbi_hsm_hart_start_finish(struct sbi_scratch *scratch,
u32 hartid)
{
unsigned long next_arg1;
unsigned long next_addr;
unsigned long next_mode;
struct sbi_hsm_data *hdata = sbi_scratch_offset_ptr(scratch,
hart_data_offset);
if (!__sbi_hsm_hart_change_state(hdata, SBI_HSM_STATE_START_PENDING,
SBI_HSM_STATE_STARTED))
sbi_hart_hang();
next_arg1 = scratch->next_arg1;
next_addr = scratch->next_addr;
next_mode = scratch->next_mode;
hsm_start_ticket_release(hdata);
sbi_hart_switch_mode(hartid, next_arg1, next_addr, next_mode, false);
}
static void sbi_hsm_hart_wait(struct sbi_scratch *scratch, u32 hartid)
{
unsigned long saved_mie;
struct sbi_hsm_data *hdata = sbi_scratch_offset_ptr(scratch,
hart_data_offset);
/* Save MIE CSR */
saved_mie = csr_read(CSR_MIE);
/* Set MSIE and MEIE bits to receive IPI */
csr_set(CSR_MIE, MIP_MSIP | MIP_MEIP);
/* Wait for state transition requested by sbi_hsm_hart_start() */
while (atomic_read(&hdata->state) != SBI_HSM_STATE_START_PENDING) {
wfi();
}
/* Restore MIE CSR */
csr_write(CSR_MIE, saved_mie);
/*
* No need to clear IPI here because the sbi_ipi_init() will
* clear it for current HART via sbi_platform_ipi_init().
*/
}
const struct sbi_hsm_device *sbi_hsm_get_device(void)
{
return hsm_dev;
}
void sbi_hsm_set_device(const struct sbi_hsm_device *dev)
{
if (!dev || hsm_dev)
return;
hsm_dev = dev;
}
static bool hsm_device_has_hart_hotplug(void)
{
if (hsm_dev && hsm_dev->hart_start && hsm_dev->hart_stop)
return true;
return false;
}
static bool hsm_device_has_hart_secondary_boot(void)
{
if (hsm_dev && hsm_dev->hart_start && !hsm_dev->hart_stop)
return true;
return false;
}
static int hsm_device_hart_start(u32 hartid, ulong saddr)
{
if (hsm_dev && hsm_dev->hart_start)
return hsm_dev->hart_start(hartid, saddr);
return SBI_ENOTSUPP;
}
static int hsm_device_hart_stop(void)
{
if (hsm_dev && hsm_dev->hart_stop)
return hsm_dev->hart_stop();
return SBI_ENOTSUPP;
}
static int hsm_device_hart_suspend(u32 suspend_type)
{
if (hsm_dev && hsm_dev->hart_suspend)
return hsm_dev->hart_suspend(suspend_type);
return SBI_ENOTSUPP;
}
static void hsm_device_hart_resume(void)
{
if (hsm_dev && hsm_dev->hart_resume)
hsm_dev->hart_resume();
}
int sbi_hsm_init(struct sbi_scratch *scratch, u32 hartid, bool cold_boot)
{
u32 i;
struct sbi_scratch *rscratch;
struct sbi_hsm_data *hdata;
if (cold_boot) {
hart_data_offset = sbi_scratch_alloc_offset(sizeof(*hdata));
if (!hart_data_offset)
return SBI_ENOMEM;
/* Initialize hart state data for every hart */
for (i = 0; i <= sbi_scratch_last_hartindex(); i++) {
rscratch = sbi_hartindex_to_scratch(i);
if (!rscratch)
continue;
hdata = sbi_scratch_offset_ptr(rscratch,
hart_data_offset);
ATOMIC_INIT(&hdata->state,
(sbi_hartindex_to_hartid(i) == hartid) ?
SBI_HSM_STATE_START_PENDING :
SBI_HSM_STATE_STOPPED);
ATOMIC_INIT(&hdata->start_ticket, 0);
}
} else {
sbi_hsm_hart_wait(scratch, hartid);
}
return 0;
}
void __noreturn sbi_hsm_exit(struct sbi_scratch *scratch)
{
struct sbi_hsm_data *hdata = sbi_scratch_offset_ptr(scratch,
hart_data_offset);
void (*jump_warmboot)(void) = (void (*)(void))scratch->warmboot_addr;
if (!__sbi_hsm_hart_change_state(hdata, SBI_HSM_STATE_STOP_PENDING,
SBI_HSM_STATE_STOPPED))
goto fail_exit;
if (hsm_device_has_hart_hotplug()) {
if (hsm_device_hart_stop() != SBI_ENOTSUPP)
goto fail_exit;
}
/**
* As platform is lacking support for hotplug, directly jump to warmboot
* and wait for interrupts in warmboot. We do it preemptively in order
* preserve the hart states and reuse the code path for hotplug.
*/
jump_warmboot();
fail_exit:
/* It should never reach here */
sbi_printf("ERR: Failed stop hart [%u]\n", current_hartid());
sbi_hart_hang();
}
int sbi_hsm_hart_start(struct sbi_scratch *scratch,
const struct sbi_domain *dom,
u32 hartid, ulong saddr, ulong smode, ulong arg1)
{
unsigned long init_count, entry_count;
unsigned int hstate;
struct sbi_scratch *rscratch;
struct sbi_hsm_data *hdata;
int rc;
/* For now, we only allow start mode to be S-mode or U-mode. */
if (smode != PRV_S && smode != PRV_U)
return SBI_EINVAL;
if (dom && !sbi_domain_is_assigned_hart(dom, hartid))
return SBI_EINVAL;
if (dom && !sbi_domain_check_addr(dom, saddr, smode,
SBI_DOMAIN_EXECUTE))
return SBI_EINVALID_ADDR;
rscratch = sbi_hartid_to_scratch(hartid);
if (!rscratch)
return SBI_EINVAL;
hdata = sbi_scratch_offset_ptr(rscratch, hart_data_offset);
if (!hsm_start_ticket_acquire(hdata))
return SBI_EINVAL;
init_count = sbi_init_count(hartid);
entry_count = sbi_entry_count(hartid);
rscratch->next_arg1 = arg1;
rscratch->next_addr = saddr;
rscratch->next_mode = smode;
/*
* atomic_cmpxchg() is an implicit barrier. It makes sure that
* other harts see reading of init_count and writing to *rscratch
* before hdata->state is set to SBI_HSM_STATE_START_PENDING.
*/
hstate = atomic_cmpxchg(&hdata->state, SBI_HSM_STATE_STOPPED,
SBI_HSM_STATE_START_PENDING);
if (hstate == SBI_HSM_STATE_STARTED) {
rc = SBI_EALREADY;
goto err;
}
/**
* if a hart is already transition to start or stop, another start call
* is considered as invalid request.
*/
if (hstate != SBI_HSM_STATE_STOPPED) {
rc = SBI_EINVAL;
goto err;
}
if ((hsm_device_has_hart_hotplug() && (entry_count == init_count)) ||
(hsm_device_has_hart_secondary_boot() && !init_count)) {
rc = hsm_device_hart_start(hartid, scratch->warmboot_addr);
} else {
rc = sbi_ipi_raw_send(sbi_hartid_to_hartindex(hartid));
}
if (!rc)
return 0;
/* If it fails to start, change hart state back to stop */
__sbi_hsm_hart_change_state(hdata, SBI_HSM_STATE_START_PENDING,
SBI_HSM_STATE_STOPPED);
err:
hsm_start_ticket_release(hdata);
return rc;
}
int sbi_hsm_hart_stop(struct sbi_scratch *scratch, bool exitnow)
{
const struct sbi_domain *dom = sbi_domain_thishart_ptr();
struct sbi_hsm_data *hdata = sbi_scratch_offset_ptr(scratch,
hart_data_offset);
if (!dom)
return SBI_EFAIL;
if (!__sbi_hsm_hart_change_state(hdata, SBI_HSM_STATE_STARTED,
SBI_HSM_STATE_STOP_PENDING))
return SBI_EFAIL;
if (exitnow)
sbi_exit(scratch);
return 0;
}
static int __sbi_hsm_suspend_default(struct sbi_scratch *scratch)
{
/* Wait for interrupt */
wfi();
return 0;
}
void __sbi_hsm_suspend_non_ret_save(struct sbi_scratch *scratch)
{
struct sbi_hsm_data *hdata = sbi_scratch_offset_ptr(scratch,
hart_data_offset);
/*
* We will be resuming in warm-boot path so the MIE and MIP CSRs
* will be back to initial state. It is possible that HART has
* configured timer event before going to suspend state so we
* should save MIE and MIP CSRs and restore it after resuming.
*
* Further, the M-mode bits in MIP CSR are read-only and set by
* external devices (such as interrupt controller) whereas all
* VS-mode bits in MIP are read-only alias of bits in HVIP CSR.
*
* This means we should only save/restore S-mode bits of MIP CSR
* such as MIP.SSIP and MIP.STIP.
*/
hdata->saved_mie = csr_read(CSR_MIE);
hdata->saved_mip = csr_read(CSR_MIP) & (MIP_SSIP | MIP_STIP);
hdata->saved_medeleg = csr_read(CSR_MEDELEG);
#if __riscv_xlen == 32
hdata->saved_menvcfgh = csr_read(CSR_MENVCFGH);
#endif
hdata->saved_menvcfg = csr_read(CSR_MENVCFG);
}
static void __sbi_hsm_suspend_non_ret_restore(struct sbi_scratch *scratch)
{
struct sbi_hsm_data *hdata = sbi_scratch_offset_ptr(scratch,
hart_data_offset);
csr_write(CSR_MENVCFG, hdata->saved_menvcfg);
#if __riscv_xlen == 32
csr_write(CSR_MENVCFGH, hdata->saved_menvcfgh);
#endif
csr_write(CSR_MEDELEG, hdata->saved_medeleg);
csr_write(CSR_MIE, hdata->saved_mie);
csr_set(CSR_MIP, (hdata->saved_mip & (MIP_SSIP | MIP_STIP)));
}
void sbi_hsm_hart_resume_start(struct sbi_scratch *scratch)
{
struct sbi_hsm_data *hdata = sbi_scratch_offset_ptr(scratch,
hart_data_offset);
/* If current HART was SUSPENDED then set RESUME_PENDING state */
if (!__sbi_hsm_hart_change_state(hdata, SBI_HSM_STATE_SUSPENDED,
SBI_HSM_STATE_RESUME_PENDING))
sbi_hart_hang();
hsm_device_hart_resume();
}
void __noreturn sbi_hsm_hart_resume_finish(struct sbi_scratch *scratch,
u32 hartid)
{
struct sbi_hsm_data *hdata = sbi_scratch_offset_ptr(scratch,
hart_data_offset);
/* If current HART was RESUME_PENDING then set STARTED state */
if (!__sbi_hsm_hart_change_state(hdata, SBI_HSM_STATE_RESUME_PENDING,
SBI_HSM_STATE_STARTED))
sbi_hart_hang();
/*
* Restore some of the M-mode CSRs which we are re-configured by
* the warm-boot sequence.
*/
__sbi_hsm_suspend_non_ret_restore(scratch);
sbi_hart_switch_mode(hartid, scratch->next_arg1,
scratch->next_addr,
scratch->next_mode, false);
}
int sbi_hsm_hart_suspend(struct sbi_scratch *scratch, u32 suspend_type,
ulong raddr, ulong rmode, ulong arg1)
{
int ret;
const struct sbi_domain *dom = sbi_domain_thishart_ptr();
struct sbi_hsm_data *hdata = sbi_scratch_offset_ptr(scratch,
hart_data_offset);
/* Sanity check on domain assigned to current HART */
if (!dom)
return SBI_EFAIL;
/* Sanity check on suspend type */
if (SBI_HSM_SUSPEND_RET_DEFAULT < suspend_type &&
suspend_type < SBI_HSM_SUSPEND_RET_PLATFORM)
return SBI_EINVAL;
if (SBI_HSM_SUSPEND_NON_RET_DEFAULT < suspend_type &&
suspend_type < SBI_HSM_SUSPEND_NON_RET_PLATFORM)
return SBI_EINVAL;
/* Additional sanity check for non-retentive suspend */
if (suspend_type & SBI_HSM_SUSP_NON_RET_BIT) {
/*
* For now, we only allow non-retentive suspend from
* S-mode or U-mode.
*/
if (rmode != PRV_S && rmode != PRV_U)
return SBI_EFAIL;
if (dom && !sbi_domain_check_addr(dom, raddr, rmode,
SBI_DOMAIN_EXECUTE))
return SBI_EINVALID_ADDR;
}
/* Save the resume address and resume mode */
scratch->next_arg1 = arg1;
scratch->next_addr = raddr;
scratch->next_mode = rmode;
/* Directly move from STARTED to SUSPENDED state */
if (!__sbi_hsm_hart_change_state(hdata, SBI_HSM_STATE_STARTED,
SBI_HSM_STATE_SUSPENDED))
return SBI_EFAIL;
/* Save the suspend type */
hdata->suspend_type = suspend_type;
/*
* Save context which will be restored after resuming from
* non-retentive suspend.
*/
if (suspend_type & SBI_HSM_SUSP_NON_RET_BIT)
__sbi_hsm_suspend_non_ret_save(scratch);
/* Try platform specific suspend */
ret = hsm_device_hart_suspend(suspend_type);
if (ret == SBI_ENOTSUPP) {
/* Try generic implementation of default suspend types */
if (suspend_type == SBI_HSM_SUSPEND_RET_DEFAULT ||
suspend_type == SBI_HSM_SUSPEND_NON_RET_DEFAULT) {
ret = __sbi_hsm_suspend_default(scratch);
}
}
/*
* The platform may have coordinated a retentive suspend, or it may
* have exited early from a non-retentive suspend. Either way, the
* caller is not expecting a successful return, so jump to the warm
* boot entry point to simulate resume from a non-retentive suspend.
*/
if (ret == 0 && (suspend_type & SBI_HSM_SUSP_NON_RET_BIT)) {
void (*jump_warmboot)(void) =
(void (*)(void))scratch->warmboot_addr;
jump_warmboot();
}
/*
* We might have successfully resumed from retentive suspend
* or suspend failed. In both cases, we restore state of hart.
*/
if (!__sbi_hsm_hart_change_state(hdata, SBI_HSM_STATE_SUSPENDED,
SBI_HSM_STATE_STARTED))
sbi_hart_hang();
return ret;
}