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linux/drivers/misc/cxl/native.c

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// SPDX-License-Identifier: GPL-2.0-or-later
/*
* Copyright 2014 IBM Corp.
*/
#include <linux/spinlock.h>
#include <linux/sched.h>
#include <linux/sched/clock.h>
#include <linux/slab.h>
#include <linux/mutex.h>
#include <linux/mm.h>
#include <linux/uaccess.h>
#include <linux/delay.h>
#include <asm/synch.h>
#include <asm/switch_to.h>
#include <misc/cxl-base.h>
#include "cxl.h"
#include "trace.h"
static int afu_control(struct cxl_afu *afu, u64 command, u64 clear,
u64 result, u64 mask, bool enabled)
{
u64 AFU_Cntl;
unsigned long timeout = jiffies + (HZ * CXL_TIMEOUT);
int rc = 0;
spin_lock(&afu->afu_cntl_lock);
pr_devel("AFU command starting: %llx\n", command);
trace_cxl_afu_ctrl(afu, command);
AFU_Cntl = cxl_p2n_read(afu, CXL_AFU_Cntl_An);
cxl_p2n_write(afu, CXL_AFU_Cntl_An, (AFU_Cntl & ~clear) | command);
AFU_Cntl = cxl_p2n_read(afu, CXL_AFU_Cntl_An);
while ((AFU_Cntl & mask) != result) {
if (time_after_eq(jiffies, timeout)) {
dev_warn(&afu->dev, "WARNING: AFU control timed out!\n");
rc = -EBUSY;
goto out;
}
if (!cxl_ops->link_ok(afu->adapter, afu)) {
afu->enabled = enabled;
rc = -EIO;
goto out;
}
pr_devel_ratelimited("AFU control... (0x%016llx)\n",
AFU_Cntl | command);
cpu_relax();
AFU_Cntl = cxl_p2n_read(afu, CXL_AFU_Cntl_An);
}
if (AFU_Cntl & CXL_AFU_Cntl_An_RA) {
/*
* Workaround for a bug in the XSL used in the Mellanox CX4
* that fails to clear the RA bit after an AFU reset,
* preventing subsequent AFU resets from working.
*/
cxl_p2n_write(afu, CXL_AFU_Cntl_An, AFU_Cntl & ~CXL_AFU_Cntl_An_RA);
}
pr_devel("AFU command complete: %llx\n", command);
afu->enabled = enabled;
out:
trace_cxl_afu_ctrl_done(afu, command, rc);
spin_unlock(&afu->afu_cntl_lock);
return rc;
}
static int afu_enable(struct cxl_afu *afu)
{
pr_devel("AFU enable request\n");
return afu_control(afu, CXL_AFU_Cntl_An_E, 0,
CXL_AFU_Cntl_An_ES_Enabled,
CXL_AFU_Cntl_An_ES_MASK, true);
}
int cxl_afu_disable(struct cxl_afu *afu)
{
pr_devel("AFU disable request\n");
return afu_control(afu, 0, CXL_AFU_Cntl_An_E,
CXL_AFU_Cntl_An_ES_Disabled,
CXL_AFU_Cntl_An_ES_MASK, false);
}
/* This will disable as well as reset */
static int native_afu_reset(struct cxl_afu *afu)
{
int rc;
u64 serr;
pr_devel("AFU reset request\n");
rc = afu_control(afu, CXL_AFU_Cntl_An_RA, 0,
CXL_AFU_Cntl_An_RS_Complete | CXL_AFU_Cntl_An_ES_Disabled,
CXL_AFU_Cntl_An_RS_MASK | CXL_AFU_Cntl_An_ES_MASK,
false);
/*
* Re-enable any masked interrupts when the AFU is not
* activated to avoid side effects after attaching a process
* in dedicated mode.
*/
if (afu->current_mode == 0) {
serr = cxl_p1n_read(afu, CXL_PSL_SERR_An);
serr &= ~CXL_PSL_SERR_An_IRQ_MASKS;
cxl_p1n_write(afu, CXL_PSL_SERR_An, serr);
}
return rc;
}
static int native_afu_check_and_enable(struct cxl_afu *afu)
{
if (!cxl_ops->link_ok(afu->adapter, afu)) {
WARN(1, "Refusing to enable afu while link down!\n");
return -EIO;
}
if (afu->enabled)
return 0;
return afu_enable(afu);
}
int cxl_psl_purge(struct cxl_afu *afu)
{
u64 PSL_CNTL = cxl_p1n_read(afu, CXL_PSL_SCNTL_An);
u64 AFU_Cntl = cxl_p2n_read(afu, CXL_AFU_Cntl_An);
u64 dsisr, dar;
u64 start, end;
u64 trans_fault = 0x0ULL;
unsigned long timeout = jiffies + (HZ * CXL_TIMEOUT);
int rc = 0;
trace_cxl_psl_ctrl(afu, CXL_PSL_SCNTL_An_Pc);
pr_devel("PSL purge request\n");
if (cxl_is_power8())
trans_fault = CXL_PSL_DSISR_TRANS;
if (cxl_is_power9())
trans_fault = CXL_PSL9_DSISR_An_TF;
if (!cxl_ops->link_ok(afu->adapter, afu)) {
dev_warn(&afu->dev, "PSL Purge called with link down, ignoring\n");
rc = -EIO;
goto out;
}
if ((AFU_Cntl & CXL_AFU_Cntl_An_ES_MASK) != CXL_AFU_Cntl_An_ES_Disabled) {
WARN(1, "psl_purge request while AFU not disabled!\n");
cxl_afu_disable(afu);
}
cxl_p1n_write(afu, CXL_PSL_SCNTL_An,
PSL_CNTL | CXL_PSL_SCNTL_An_Pc);
start = local_clock();
PSL_CNTL = cxl_p1n_read(afu, CXL_PSL_SCNTL_An);
while ((PSL_CNTL & CXL_PSL_SCNTL_An_Ps_MASK)
== CXL_PSL_SCNTL_An_Ps_Pending) {
if (time_after_eq(jiffies, timeout)) {
dev_warn(&afu->dev, "WARNING: PSL Purge timed out!\n");
rc = -EBUSY;
goto out;
}
if (!cxl_ops->link_ok(afu->adapter, afu)) {
rc = -EIO;
goto out;
}
dsisr = cxl_p2n_read(afu, CXL_PSL_DSISR_An);
pr_devel_ratelimited("PSL purging... PSL_CNTL: 0x%016llx PSL_DSISR: 0x%016llx\n",
PSL_CNTL, dsisr);
if (dsisr & trans_fault) {
dar = cxl_p2n_read(afu, CXL_PSL_DAR_An);
dev_notice(&afu->dev, "PSL purge terminating pending translation, DSISR: 0x%016llx, DAR: 0x%016llx\n",
dsisr, dar);
cxl_p2n_write(afu, CXL_PSL_TFC_An, CXL_PSL_TFC_An_AE);
} else if (dsisr) {
dev_notice(&afu->dev, "PSL purge acknowledging pending non-translation fault, DSISR: 0x%016llx\n",
dsisr);
cxl_p2n_write(afu, CXL_PSL_TFC_An, CXL_PSL_TFC_An_A);
} else {
cpu_relax();
}
PSL_CNTL = cxl_p1n_read(afu, CXL_PSL_SCNTL_An);
}
end = local_clock();
pr_devel("PSL purged in %lld ns\n", end - start);
cxl_p1n_write(afu, CXL_PSL_SCNTL_An,
PSL_CNTL & ~CXL_PSL_SCNTL_An_Pc);
out:
trace_cxl_psl_ctrl_done(afu, CXL_PSL_SCNTL_An_Pc, rc);
return rc;
}
static int spa_max_procs(int spa_size)
{
/*
* From the CAIA:
* end_of_SPA_area = SPA_Base + ((n+4) * 128) + (( ((n*8) + 127) >> 7) * 128) + 255
* Most of that junk is really just an overly-complicated way of saying
* the last 256 bytes are __aligned(128), so it's really:
* end_of_SPA_area = end_of_PSL_queue_area + __aligned(128) 255
* and
* end_of_PSL_queue_area = SPA_Base + ((n+4) * 128) + (n*8) - 1
* so
* sizeof(SPA) = ((n+4) * 128) + (n*8) + __aligned(128) 256
* Ignore the alignment (which is safe in this case as long as we are
* careful with our rounding) and solve for n:
*/
return ((spa_size / 8) - 96) / 17;
}
static int cxl_alloc_spa(struct cxl_afu *afu, int mode)
{
unsigned spa_size;
/* Work out how many pages to allocate */
afu->native->spa_order = -1;
do {
afu->native->spa_order++;
spa_size = (1 << afu->native->spa_order) * PAGE_SIZE;
if (spa_size > 0x100000) {
dev_warn(&afu->dev, "num_of_processes too large for the SPA, limiting to %i (0x%x)\n",
afu->native->spa_max_procs, afu->native->spa_size);
if (mode != CXL_MODE_DEDICATED)
afu->num_procs = afu->native->spa_max_procs;
break;
}
afu->native->spa_size = spa_size;
afu->native->spa_max_procs = spa_max_procs(afu->native->spa_size);
} while (afu->native->spa_max_procs < afu->num_procs);
if (!(afu->native->spa = (struct cxl_process_element *)
__get_free_pages(GFP_KERNEL | __GFP_ZERO, afu->native->spa_order))) {
pr_err("cxl_alloc_spa: Unable to allocate scheduled process area\n");
return -ENOMEM;
}
pr_devel("spa pages: %i afu->spa_max_procs: %i afu->num_procs: %i\n",
1<<afu->native->spa_order, afu->native->spa_max_procs, afu->num_procs);
return 0;
}
static void attach_spa(struct cxl_afu *afu)
{
u64 spap;
afu->native->sw_command_status = (__be64 *)((char *)afu->native->spa +
((afu->native->spa_max_procs + 3) * 128));
spap = virt_to_phys(afu->native->spa) & CXL_PSL_SPAP_Addr;
spap |= ((afu->native->spa_size >> (12 - CXL_PSL_SPAP_Size_Shift)) - 1) & CXL_PSL_SPAP_Size;
spap |= CXL_PSL_SPAP_V;
pr_devel("cxl: SPA allocated at 0x%p. Max processes: %i, sw_command_status: 0x%p CXL_PSL_SPAP_An=0x%016llx\n",
afu->native->spa, afu->native->spa_max_procs,
afu->native->sw_command_status, spap);
cxl_p1n_write(afu, CXL_PSL_SPAP_An, spap);
}
static inline void detach_spa(struct cxl_afu *afu)
{
cxl_p1n_write(afu, CXL_PSL_SPAP_An, 0);
}
void cxl_release_spa(struct cxl_afu *afu)
{
if (afu->native->spa) {
free_pages((unsigned long) afu->native->spa,
afu->native->spa_order);
afu->native->spa = NULL;
}
}
/*
* Invalidation of all ERAT entries is no longer required by CAIA2. Use
* only for debug.
*/
int cxl_invalidate_all_psl9(struct cxl *adapter)
{
unsigned long timeout = jiffies + (HZ * CXL_TIMEOUT);
u64 ierat;
pr_devel("CXL adapter - invalidation of all ERAT entries\n");
/* Invalidates all ERAT entries for Radix or HPT */
ierat = CXL_XSL9_IERAT_IALL;
if (radix_enabled())
ierat |= CXL_XSL9_IERAT_INVR;
cxl_p1_write(adapter, CXL_XSL9_IERAT, ierat);
while (cxl_p1_read(adapter, CXL_XSL9_IERAT) & CXL_XSL9_IERAT_IINPROG) {
if (time_after_eq(jiffies, timeout)) {
dev_warn(&adapter->dev,
"WARNING: CXL adapter invalidation of all ERAT entries timed out!\n");
return -EBUSY;
}
if (!cxl_ops->link_ok(adapter, NULL))
return -EIO;
cpu_relax();
}
return 0;
}
int cxl_invalidate_all_psl8(struct cxl *adapter)
{
unsigned long timeout = jiffies + (HZ * CXL_TIMEOUT);
pr_devel("CXL adapter wide TLBIA & SLBIA\n");
cxl_p1_write(adapter, CXL_PSL_AFUSEL, CXL_PSL_AFUSEL_A);
cxl_p1_write(adapter, CXL_PSL_TLBIA, CXL_TLB_SLB_IQ_ALL);
while (cxl_p1_read(adapter, CXL_PSL_TLBIA) & CXL_TLB_SLB_P) {
if (time_after_eq(jiffies, timeout)) {
dev_warn(&adapter->dev, "WARNING: CXL adapter wide TLBIA timed out!\n");
return -EBUSY;
}
if (!cxl_ops->link_ok(adapter, NULL))
return -EIO;
cpu_relax();
}
cxl_p1_write(adapter, CXL_PSL_SLBIA, CXL_TLB_SLB_IQ_ALL);
while (cxl_p1_read(adapter, CXL_PSL_SLBIA) & CXL_TLB_SLB_P) {
if (time_after_eq(jiffies, timeout)) {
dev_warn(&adapter->dev, "WARNING: CXL adapter wide SLBIA timed out!\n");
return -EBUSY;
}
if (!cxl_ops->link_ok(adapter, NULL))
return -EIO;
cpu_relax();
}
return 0;
}
int cxl_data_cache_flush(struct cxl *adapter)
{
u64 reg;
unsigned long timeout = jiffies + (HZ * CXL_TIMEOUT);
/*
* Do a datacache flush only if datacache is available.
* In case of PSL9D datacache absent hence flush operation.
* would timeout.
*/
if (adapter->native->no_data_cache) {
pr_devel("No PSL data cache. Ignoring cache flush req.\n");
return 0;
}
pr_devel("Flushing data cache\n");
reg = cxl_p1_read(adapter, CXL_PSL_Control);
reg |= CXL_PSL_Control_Fr;
cxl_p1_write(adapter, CXL_PSL_Control, reg);
reg = cxl_p1_read(adapter, CXL_PSL_Control);
while ((reg & CXL_PSL_Control_Fs_MASK) != CXL_PSL_Control_Fs_Complete) {
if (time_after_eq(jiffies, timeout)) {
dev_warn(&adapter->dev, "WARNING: cache flush timed out!\n");
return -EBUSY;
}
if (!cxl_ops->link_ok(adapter, NULL)) {
dev_warn(&adapter->dev, "WARNING: link down when flushing cache\n");
return -EIO;
}
cpu_relax();
reg = cxl_p1_read(adapter, CXL_PSL_Control);
}
reg &= ~CXL_PSL_Control_Fr;
cxl_p1_write(adapter, CXL_PSL_Control, reg);
return 0;
}
static int cxl_write_sstp(struct cxl_afu *afu, u64 sstp0, u64 sstp1)
{
int rc;
/* 1. Disable SSTP by writing 0 to SSTP1[V] */
cxl_p2n_write(afu, CXL_SSTP1_An, 0);
/* 2. Invalidate all SLB entries */
if ((rc = cxl_afu_slbia(afu)))
return rc;
/* 3. Set SSTP0_An */
cxl_p2n_write(afu, CXL_SSTP0_An, sstp0);
/* 4. Set SSTP1_An */
cxl_p2n_write(afu, CXL_SSTP1_An, sstp1);
return 0;
}
/* Using per slice version may improve performance here. (ie. SLBIA_An) */
static void slb_invalid(struct cxl_context *ctx)
{
struct cxl *adapter = ctx->afu->adapter;
u64 slbia;
WARN_ON(!mutex_is_locked(&ctx->afu->native->spa_mutex));
cxl_p1_write(adapter, CXL_PSL_LBISEL,
((u64)be32_to_cpu(ctx->elem->common.pid) << 32) |
be32_to_cpu(ctx->elem->lpid));
cxl_p1_write(adapter, CXL_PSL_SLBIA, CXL_TLB_SLB_IQ_LPIDPID);
while (1) {
if (!cxl_ops->link_ok(adapter, NULL))
break;
slbia = cxl_p1_read(adapter, CXL_PSL_SLBIA);
if (!(slbia & CXL_TLB_SLB_P))
break;
cpu_relax();
}
}
static int do_process_element_cmd(struct cxl_context *ctx,
u64 cmd, u64 pe_state)
{
u64 state;
unsigned long timeout = jiffies + (HZ * CXL_TIMEOUT);
int rc = 0;
trace_cxl_llcmd(ctx, cmd);
WARN_ON(!ctx->afu->enabled);
ctx->elem->software_state = cpu_to_be32(pe_state);
smp_wmb();
*(ctx->afu->native->sw_command_status) = cpu_to_be64(cmd | 0 | ctx->pe);
smp_mb();
cxl_p1n_write(ctx->afu, CXL_PSL_LLCMD_An, cmd | ctx->pe);
while (1) {
if (time_after_eq(jiffies, timeout)) {
dev_warn(&ctx->afu->dev, "WARNING: Process Element Command timed out!\n");
rc = -EBUSY;
goto out;
}
if (!cxl_ops->link_ok(ctx->afu->adapter, ctx->afu)) {
dev_warn(&ctx->afu->dev, "WARNING: Device link down, aborting Process Element Command!\n");
rc = -EIO;
goto out;
}
state = be64_to_cpup(ctx->afu->native->sw_command_status);
if (state == ~0ULL) {
pr_err("cxl: Error adding process element to AFU\n");
rc = -1;
goto out;
}
if ((state & (CXL_SPA_SW_CMD_MASK | CXL_SPA_SW_STATE_MASK | CXL_SPA_SW_LINK_MASK)) ==
(cmd | (cmd >> 16) | ctx->pe))
break;
/*
* The command won't finish in the PSL if there are
* outstanding DSIs. Hence we need to yield here in
* case there are outstanding DSIs that we need to
* service. Tuning possiblity: we could wait for a
* while before sched
*/
schedule();
}
out:
trace_cxl_llcmd_done(ctx, cmd, rc);
return rc;
}
static int add_process_element(struct cxl_context *ctx)
{
int rc = 0;
mutex_lock(&ctx->afu->native->spa_mutex);
pr_devel("%s Adding pe: %i started\n", __func__, ctx->pe);
if (!(rc = do_process_element_cmd(ctx, CXL_SPA_SW_CMD_ADD, CXL_PE_SOFTWARE_STATE_V)))
ctx->pe_inserted = true;
pr_devel("%s Adding pe: %i finished\n", __func__, ctx->pe);
mutex_unlock(&ctx->afu->native->spa_mutex);
return rc;
}
static int terminate_process_element(struct cxl_context *ctx)
{
int rc = 0;
/* fast path terminate if it's already invalid */
if (!(ctx->elem->software_state & cpu_to_be32(CXL_PE_SOFTWARE_STATE_V)))
return rc;
mutex_lock(&ctx->afu->native->spa_mutex);
pr_devel("%s Terminate pe: %i started\n", __func__, ctx->pe);
/* We could be asked to terminate when the hw is down. That
* should always succeed: it's not running if the hw has gone
* away and is being reset.
*/
if (cxl_ops->link_ok(ctx->afu->adapter, ctx->afu))
rc = do_process_element_cmd(ctx, CXL_SPA_SW_CMD_TERMINATE,
CXL_PE_SOFTWARE_STATE_V | CXL_PE_SOFTWARE_STATE_T);
ctx->elem->software_state = 0; /* Remove Valid bit */
pr_devel("%s Terminate pe: %i finished\n", __func__, ctx->pe);
mutex_unlock(&ctx->afu->native->spa_mutex);
return rc;
}
static int remove_process_element(struct cxl_context *ctx)
{
int rc = 0;
mutex_lock(&ctx->afu->native->spa_mutex);
pr_devel("%s Remove pe: %i started\n", __func__, ctx->pe);
/* We could be asked to remove when the hw is down. Again, if
* the hw is down, the PE is gone, so we succeed.
*/
if (cxl_ops->link_ok(ctx->afu->adapter, ctx->afu))
rc = do_process_element_cmd(ctx, CXL_SPA_SW_CMD_REMOVE, 0);
if (!rc)
ctx->pe_inserted = false;
if (cxl_is_power8())
slb_invalid(ctx);
pr_devel("%s Remove pe: %i finished\n", __func__, ctx->pe);
mutex_unlock(&ctx->afu->native->spa_mutex);
return rc;
}
void cxl_assign_psn_space(struct cxl_context *ctx)
{
if (!ctx->afu->pp_size || ctx->master) {
ctx->psn_phys = ctx->afu->psn_phys;
ctx->psn_size = ctx->afu->adapter->ps_size;
} else {
ctx->psn_phys = ctx->afu->psn_phys +
(ctx->afu->native->pp_offset + ctx->afu->pp_size * ctx->pe);
ctx->psn_size = ctx->afu->pp_size;
}
}
static int activate_afu_directed(struct cxl_afu *afu)
{
int rc;
dev_info(&afu->dev, "Activating AFU directed mode\n");
afu->num_procs = afu->max_procs_virtualised;
if (afu->native->spa == NULL) {
if (cxl_alloc_spa(afu, CXL_MODE_DIRECTED))
return -ENOMEM;
}
attach_spa(afu);
cxl_p1n_write(afu, CXL_PSL_SCNTL_An, CXL_PSL_SCNTL_An_PM_AFU);
if (cxl_is_power8())
cxl_p1n_write(afu, CXL_PSL_AMOR_An, 0xFFFFFFFFFFFFFFFFULL);
cxl_p1n_write(afu, CXL_PSL_ID_An, CXL_PSL_ID_An_F | CXL_PSL_ID_An_L);
afu->current_mode = CXL_MODE_DIRECTED;
if ((rc = cxl_chardev_m_afu_add(afu)))
return rc;
if ((rc = cxl_sysfs_afu_m_add(afu)))
goto err;
if ((rc = cxl_chardev_s_afu_add(afu)))
goto err1;
return 0;
err1:
cxl_sysfs_afu_m_remove(afu);
err:
cxl_chardev_afu_remove(afu);
return rc;
}
#ifdef CONFIG_CPU_LITTLE_ENDIAN
#define set_endian(sr) ((sr) |= CXL_PSL_SR_An_LE)
#else
#define set_endian(sr) ((sr) &= ~(CXL_PSL_SR_An_LE))
#endif
u64 cxl_calculate_sr(bool master, bool kernel, bool real_mode, bool p9)
{
u64 sr = 0;
set_endian(sr);
if (master)
sr |= CXL_PSL_SR_An_MP;
if (mfspr(SPRN_LPCR) & LPCR_TC)
sr |= CXL_PSL_SR_An_TC;
if (kernel) {
if (!real_mode)
sr |= CXL_PSL_SR_An_R;
sr |= (mfmsr() & MSR_SF) | CXL_PSL_SR_An_HV;
} else {
sr |= CXL_PSL_SR_An_PR | CXL_PSL_SR_An_R;
if (radix_enabled())
sr |= CXL_PSL_SR_An_HV;
else
sr &= ~(CXL_PSL_SR_An_HV);
if (!test_tsk_thread_flag(current, TIF_32BIT))
sr |= CXL_PSL_SR_An_SF;
}
if (p9) {
if (radix_enabled())
sr |= CXL_PSL_SR_An_XLAT_ror;
else
sr |= CXL_PSL_SR_An_XLAT_hpt;
}
return sr;
}
static u64 calculate_sr(struct cxl_context *ctx)
{
return cxl_calculate_sr(ctx->master, ctx->kernel, false,
cxl_is_power9());
}
static void update_ivtes_directed(struct cxl_context *ctx)
{
bool need_update = (ctx->status == STARTED);
int r;
if (need_update) {
WARN_ON(terminate_process_element(ctx));
WARN_ON(remove_process_element(ctx));
}
for (r = 0; r < CXL_IRQ_RANGES; r++) {
ctx->elem->ivte_offsets[r] = cpu_to_be16(ctx->irqs.offset[r]);
ctx->elem->ivte_ranges[r] = cpu_to_be16(ctx->irqs.range[r]);
}
/*
* Theoretically we could use the update llcmd, instead of a
* terminate/remove/add (or if an atomic update was required we could
* do a suspend/update/resume), however it seems there might be issues
* with the update llcmd on some cards (including those using an XSL on
* an ASIC) so for now it's safest to go with the commands that are
* known to work. In the future if we come across a situation where the
* card may be performing transactions using the same PE while we are
* doing this update we might need to revisit this.
*/
if (need_update)
WARN_ON(add_process_element(ctx));
}
static int process_element_entry_psl9(struct cxl_context *ctx, u64 wed, u64 amr)
{
u32 pid;
int rc;
cxl_assign_psn_space(ctx);
ctx->elem->ctxtime = 0; /* disable */
ctx->elem->lpid = cpu_to_be32(mfspr(SPRN_LPID));
ctx->elem->haurp = 0; /* disable */
if (ctx->kernel)
pid = 0;
else {
if (ctx->mm == NULL) {
pr_devel("%s: unable to get mm for pe=%d pid=%i\n",
__func__, ctx->pe, pid_nr(ctx->pid));
return -EINVAL;
}
pid = ctx->mm->context.id;
}
/* Assign a unique TIDR (thread id) for the current thread */
if (!(ctx->tidr) && (ctx->assign_tidr)) {
rc = set_thread_tidr(current);
if (rc)
return -ENODEV;
ctx->tidr = current->thread.tidr;
pr_devel("%s: current tidr: %d\n", __func__, ctx->tidr);
}
ctx->elem->common.tid = cpu_to_be32(ctx->tidr);
ctx->elem->common.pid = cpu_to_be32(pid);
ctx->elem->sr = cpu_to_be64(calculate_sr(ctx));
ctx->elem->common.csrp = 0; /* disable */
cxl_prefault(ctx, wed);
/*
* Ensure we have the multiplexed PSL interrupt set up to take faults
* for kernel contexts that may not have allocated any AFU IRQs at all:
*/
if (ctx->irqs.range[0] == 0) {
ctx->irqs.offset[0] = ctx->afu->native->psl_hwirq;
ctx->irqs.range[0] = 1;
}
ctx->elem->common.amr = cpu_to_be64(amr);
ctx->elem->common.wed = cpu_to_be64(wed);
return 0;
}
int cxl_attach_afu_directed_psl9(struct cxl_context *ctx, u64 wed, u64 amr)
{
int result;
/* fill the process element entry */
result = process_element_entry_psl9(ctx, wed, amr);
if (result)
return result;
update_ivtes_directed(ctx);
/* first guy needs to enable */
result = cxl_ops->afu_check_and_enable(ctx->afu);
if (result)
return result;
return add_process_element(ctx);
}
int cxl_attach_afu_directed_psl8(struct cxl_context *ctx, u64 wed, u64 amr)
{
u32 pid;
int result;
cxl_assign_psn_space(ctx);
ctx->elem->ctxtime = 0; /* disable */
ctx->elem->lpid = cpu_to_be32(mfspr(SPRN_LPID));
ctx->elem->haurp = 0; /* disable */
ctx->elem->u.sdr = cpu_to_be64(mfspr(SPRN_SDR1));
pid = current->pid;
if (ctx->kernel)
pid = 0;
ctx->elem->common.tid = 0;
ctx->elem->common.pid = cpu_to_be32(pid);
ctx->elem->sr = cpu_to_be64(calculate_sr(ctx));
ctx->elem->common.csrp = 0; /* disable */
ctx->elem->common.u.psl8.aurp0 = 0; /* disable */
ctx->elem->common.u.psl8.aurp1 = 0; /* disable */
cxl_prefault(ctx, wed);
ctx->elem->common.u.psl8.sstp0 = cpu_to_be64(ctx->sstp0);
ctx->elem->common.u.psl8.sstp1 = cpu_to_be64(ctx->sstp1);
/*
* Ensure we have the multiplexed PSL interrupt set up to take faults
* for kernel contexts that may not have allocated any AFU IRQs at all:
*/
if (ctx->irqs.range[0] == 0) {
ctx->irqs.offset[0] = ctx->afu->native->psl_hwirq;
ctx->irqs.range[0] = 1;
}
update_ivtes_directed(ctx);
ctx->elem->common.amr = cpu_to_be64(amr);
ctx->elem->common.wed = cpu_to_be64(wed);
/* first guy needs to enable */
if ((result = cxl_ops->afu_check_and_enable(ctx->afu)))
return result;
return add_process_element(ctx);
}
static int deactivate_afu_directed(struct cxl_afu *afu)
{
dev_info(&afu->dev, "Deactivating AFU directed mode\n");
afu->current_mode = 0;
afu->num_procs = 0;
cxl_sysfs_afu_m_remove(afu);
cxl_chardev_afu_remove(afu);
/*
* The CAIA section 2.2.1 indicates that the procedure for starting and
* stopping an AFU in AFU directed mode is AFU specific, which is not
* ideal since this code is generic and with one exception has no
* knowledge of the AFU. This is in contrast to the procedure for
* disabling a dedicated process AFU, which is documented to just
* require a reset. The architecture does indicate that both an AFU
* reset and an AFU disable should result in the AFU being disabled and
* we do both followed by a PSL purge for safety.
*
* Notably we used to have some issues with the disable sequence on PSL
* cards, which is why we ended up using this heavy weight procedure in
* the first place, however a bug was discovered that had rendered the
* disable operation ineffective, so it is conceivable that was the
* sole explanation for those difficulties. Careful regression testing
* is recommended if anyone attempts to remove or reorder these
* operations.
*
* The XSL on the Mellanox CX4 behaves a little differently from the
* PSL based cards and will time out an AFU reset if the AFU is still
* enabled. That card is special in that we do have a means to identify
* it from this code, so in that case we skip the reset and just use a
* disable/purge to avoid the timeout and corresponding noise in the
* kernel log.
*/
if (afu->adapter->native->sl_ops->needs_reset_before_disable)
cxl_ops->afu_reset(afu);
cxl_afu_disable(afu);
cxl_psl_purge(afu);
return 0;
}
int cxl_activate_dedicated_process_psl9(struct cxl_afu *afu)
{
dev_info(&afu->dev, "Activating dedicated process mode\n");
/*
* If XSL is set to dedicated mode (Set in PSL_SCNTL reg), the
* XSL and AFU are programmed to work with a single context.
* The context information should be configured in the SPA area
* index 0 (so PSL_SPAP must be configured before enabling the
* AFU).
*/
afu->num_procs = 1;
if (afu->native->spa == NULL) {
if (cxl_alloc_spa(afu, CXL_MODE_DEDICATED))
return -ENOMEM;
}
attach_spa(afu);
cxl_p1n_write(afu, CXL_PSL_SCNTL_An, CXL_PSL_SCNTL_An_PM_Process);
cxl_p1n_write(afu, CXL_PSL_ID_An, CXL_PSL_ID_An_F | CXL_PSL_ID_An_L);
afu->current_mode = CXL_MODE_DEDICATED;
return cxl_chardev_d_afu_add(afu);
}
int cxl_activate_dedicated_process_psl8(struct cxl_afu *afu)
{
dev_info(&afu->dev, "Activating dedicated process mode\n");
cxl_p1n_write(afu, CXL_PSL_SCNTL_An, CXL_PSL_SCNTL_An_PM_Process);
cxl_p1n_write(afu, CXL_PSL_CtxTime_An, 0); /* disable */
cxl_p1n_write(afu, CXL_PSL_SPAP_An, 0); /* disable */
cxl_p1n_write(afu, CXL_PSL_AMOR_An, 0xFFFFFFFFFFFFFFFFULL);
cxl_p1n_write(afu, CXL_PSL_LPID_An, mfspr(SPRN_LPID));
cxl_p1n_write(afu, CXL_HAURP_An, 0); /* disable */
cxl_p1n_write(afu, CXL_PSL_SDR_An, mfspr(SPRN_SDR1));
cxl_p2n_write(afu, CXL_CSRP_An, 0); /* disable */
cxl_p2n_write(afu, CXL_AURP0_An, 0); /* disable */
cxl_p2n_write(afu, CXL_AURP1_An, 0); /* disable */
afu->current_mode = CXL_MODE_DEDICATED;
afu->num_procs = 1;
return cxl_chardev_d_afu_add(afu);
}
void cxl_update_dedicated_ivtes_psl9(struct cxl_context *ctx)
{
int r;
for (r = 0; r < CXL_IRQ_RANGES; r++) {
ctx->elem->ivte_offsets[r] = cpu_to_be16(ctx->irqs.offset[r]);
ctx->elem->ivte_ranges[r] = cpu_to_be16(ctx->irqs.range[r]);
}
}
void cxl_update_dedicated_ivtes_psl8(struct cxl_context *ctx)
{
struct cxl_afu *afu = ctx->afu;
cxl_p1n_write(afu, CXL_PSL_IVTE_Offset_An,
(((u64)ctx->irqs.offset[0] & 0xffff) << 48) |
(((u64)ctx->irqs.offset[1] & 0xffff) << 32) |
(((u64)ctx->irqs.offset[2] & 0xffff) << 16) |
((u64)ctx->irqs.offset[3] & 0xffff));
cxl_p1n_write(afu, CXL_PSL_IVTE_Limit_An, (u64)
(((u64)ctx->irqs.range[0] & 0xffff) << 48) |
(((u64)ctx->irqs.range[1] & 0xffff) << 32) |
(((u64)ctx->irqs.range[2] & 0xffff) << 16) |
((u64)ctx->irqs.range[3] & 0xffff));
}
int cxl_attach_dedicated_process_psl9(struct cxl_context *ctx, u64 wed, u64 amr)
{
struct cxl_afu *afu = ctx->afu;
int result;
/* fill the process element entry */
result = process_element_entry_psl9(ctx, wed, amr);
if (result)
return result;
if (ctx->afu->adapter->native->sl_ops->update_dedicated_ivtes)
afu->adapter->native->sl_ops->update_dedicated_ivtes(ctx);
ctx->elem->software_state = cpu_to_be32(CXL_PE_SOFTWARE_STATE_V);
/*
* Ideally we should do a wmb() here to make sure the changes to the
* PE are visible to the card before we call afu_enable.
* On ppc64 though all mmios are preceded by a 'sync' instruction hence
* we dont dont need one here.
*/
result = cxl_ops->afu_reset(afu);
if (result)
return result;
return afu_enable(afu);
}
int cxl_attach_dedicated_process_psl8(struct cxl_context *ctx, u64 wed, u64 amr)
{
struct cxl_afu *afu = ctx->afu;
u64 pid;
int rc;
pid = (u64)current->pid << 32;
if (ctx->kernel)
pid = 0;
cxl_p2n_write(afu, CXL_PSL_PID_TID_An, pid);
cxl_p1n_write(afu, CXL_PSL_SR_An, calculate_sr(ctx));
if ((rc = cxl_write_sstp(afu, ctx->sstp0, ctx->sstp1)))
return rc;
cxl_prefault(ctx, wed);
if (ctx->afu->adapter->native->sl_ops->update_dedicated_ivtes)
afu->adapter->native->sl_ops->update_dedicated_ivtes(ctx);
cxl_p2n_write(afu, CXL_PSL_AMR_An, amr);
/* master only context for dedicated */
cxl_assign_psn_space(ctx);
if ((rc = cxl_ops->afu_reset(afu)))
return rc;
cxl_p2n_write(afu, CXL_PSL_WED_An, wed);
return afu_enable(afu);
}
static int deactivate_dedicated_process(struct cxl_afu *afu)
{
dev_info(&afu->dev, "Deactivating dedicated process mode\n");
afu->current_mode = 0;
afu->num_procs = 0;
cxl_chardev_afu_remove(afu);
return 0;
}
static int native_afu_deactivate_mode(struct cxl_afu *afu, int mode)
{
if (mode == CXL_MODE_DIRECTED)
return deactivate_afu_directed(afu);
if (mode == CXL_MODE_DEDICATED)
return deactivate_dedicated_process(afu);
return 0;
}
static int native_afu_activate_mode(struct cxl_afu *afu, int mode)
{
if (!mode)
return 0;
if (!(mode & afu->modes_supported))
return -EINVAL;
if (!cxl_ops->link_ok(afu->adapter, afu)) {
WARN(1, "Device link is down, refusing to activate!\n");
return -EIO;
}
if (mode == CXL_MODE_DIRECTED)
return activate_afu_directed(afu);
if ((mode == CXL_MODE_DEDICATED) &&
(afu->adapter->native->sl_ops->activate_dedicated_process))
return afu->adapter->native->sl_ops->activate_dedicated_process(afu);
return -EINVAL;
}
static int native_attach_process(struct cxl_context *ctx, bool kernel,
u64 wed, u64 amr)
{
if (!cxl_ops->link_ok(ctx->afu->adapter, ctx->afu)) {
WARN(1, "Device link is down, refusing to attach process!\n");
return -EIO;
}
ctx->kernel = kernel;
if ((ctx->afu->current_mode == CXL_MODE_DIRECTED) &&
(ctx->afu->adapter->native->sl_ops->attach_afu_directed))
return ctx->afu->adapter->native->sl_ops->attach_afu_directed(ctx, wed, amr);
if ((ctx->afu->current_mode == CXL_MODE_DEDICATED) &&
(ctx->afu->adapter->native->sl_ops->attach_dedicated_process))
return ctx->afu->adapter->native->sl_ops->attach_dedicated_process(ctx, wed, amr);
return -EINVAL;
}
static inline int detach_process_native_dedicated(struct cxl_context *ctx)
{
/*
* The CAIA section 2.1.1 indicates that we need to do an AFU reset to
* stop the AFU in dedicated mode (we therefore do not make that
* optional like we do in the afu directed path). It does not indicate
* that we need to do an explicit disable (which should occur
* implicitly as part of the reset) or purge, but we do these as well
* to be on the safe side.
*
* Notably we used to have some issues with the disable sequence
* (before the sequence was spelled out in the architecture) which is
* why we were so heavy weight in the first place, however a bug was
* discovered that had rendered the disable operation ineffective, so
* it is conceivable that was the sole explanation for those
* difficulties. Point is, we should be careful and do some regression
* testing if we ever attempt to remove any part of this procedure.
*/
cxl_ops->afu_reset(ctx->afu);
cxl_afu_disable(ctx->afu);
cxl_psl_purge(ctx->afu);
return 0;
}
static void native_update_ivtes(struct cxl_context *ctx)
{
if (ctx->afu->current_mode == CXL_MODE_DIRECTED)
return update_ivtes_directed(ctx);
if ((ctx->afu->current_mode == CXL_MODE_DEDICATED) &&
(ctx->afu->adapter->native->sl_ops->update_dedicated_ivtes))
return ctx->afu->adapter->native->sl_ops->update_dedicated_ivtes(ctx);
WARN(1, "native_update_ivtes: Bad mode\n");
}
static inline int detach_process_native_afu_directed(struct cxl_context *ctx)
{
if (!ctx->pe_inserted)
return 0;
if (terminate_process_element(ctx))
return -1;
if (remove_process_element(ctx))
return -1;
return 0;
}
static int native_detach_process(struct cxl_context *ctx)
{
trace_cxl_detach(ctx);
if (ctx->afu->current_mode == CXL_MODE_DEDICATED)
return detach_process_native_dedicated(ctx);
return detach_process_native_afu_directed(ctx);
}
static int native_get_irq_info(struct cxl_afu *afu, struct cxl_irq_info *info)
{
/* If the adapter has gone away, we can't get any meaningful
* information.
*/
if (!cxl_ops->link_ok(afu->adapter, afu))
return -EIO;
info->dsisr = cxl_p2n_read(afu, CXL_PSL_DSISR_An);
info->dar = cxl_p2n_read(afu, CXL_PSL_DAR_An);
if (cxl_is_power8())
info->dsr = cxl_p2n_read(afu, CXL_PSL_DSR_An);
info->afu_err = cxl_p2n_read(afu, CXL_AFU_ERR_An);
info->errstat = cxl_p2n_read(afu, CXL_PSL_ErrStat_An);
info->proc_handle = 0;
return 0;
}
void cxl_native_irq_dump_regs_psl9(struct cxl_context *ctx)
{
u64 fir1, serr;
fir1 = cxl_p1_read(ctx->afu->adapter, CXL_PSL9_FIR1);
dev_crit(&ctx->afu->dev, "PSL_FIR1: 0x%016llx\n", fir1);
if (ctx->afu->adapter->native->sl_ops->register_serr_irq) {
serr = cxl_p1n_read(ctx->afu, CXL_PSL_SERR_An);
cxl_afu_decode_psl_serr(ctx->afu, serr);
}
}
void cxl_native_irq_dump_regs_psl8(struct cxl_context *ctx)
{
u64 fir1, fir2, fir_slice, serr, afu_debug;
fir1 = cxl_p1_read(ctx->afu->adapter, CXL_PSL_FIR1);
fir2 = cxl_p1_read(ctx->afu->adapter, CXL_PSL_FIR2);
fir_slice = cxl_p1n_read(ctx->afu, CXL_PSL_FIR_SLICE_An);
afu_debug = cxl_p1n_read(ctx->afu, CXL_AFU_DEBUG_An);
dev_crit(&ctx->afu->dev, "PSL_FIR1: 0x%016llx\n", fir1);
dev_crit(&ctx->afu->dev, "PSL_FIR2: 0x%016llx\n", fir2);
if (ctx->afu->adapter->native->sl_ops->register_serr_irq) {
serr = cxl_p1n_read(ctx->afu, CXL_PSL_SERR_An);
cxl_afu_decode_psl_serr(ctx->afu, serr);
}
dev_crit(&ctx->afu->dev, "PSL_FIR_SLICE_An: 0x%016llx\n", fir_slice);
dev_crit(&ctx->afu->dev, "CXL_PSL_AFU_DEBUG_An: 0x%016llx\n", afu_debug);
}
static irqreturn_t native_handle_psl_slice_error(struct cxl_context *ctx,
u64 dsisr, u64 errstat)
{
dev_crit(&ctx->afu->dev, "PSL ERROR STATUS: 0x%016llx\n", errstat);
if (ctx->afu->adapter->native->sl_ops->psl_irq_dump_registers)
ctx->afu->adapter->native->sl_ops->psl_irq_dump_registers(ctx);
if (ctx->afu->adapter->native->sl_ops->debugfs_stop_trace) {
dev_crit(&ctx->afu->dev, "STOPPING CXL TRACE\n");
ctx->afu->adapter->native->sl_ops->debugfs_stop_trace(ctx->afu->adapter);
}
return cxl_ops->ack_irq(ctx, 0, errstat);
}
static bool cxl_is_translation_fault(struct cxl_afu *afu, u64 dsisr)
{
if ((cxl_is_power8()) && (dsisr & CXL_PSL_DSISR_TRANS))
return true;
if ((cxl_is_power9()) && (dsisr & CXL_PSL9_DSISR_An_TF))
return true;
return false;
}
irqreturn_t cxl_fail_irq_psl(struct cxl_afu *afu, struct cxl_irq_info *irq_info)
{
if (cxl_is_translation_fault(afu, irq_info->dsisr))
cxl_p2n_write(afu, CXL_PSL_TFC_An, CXL_PSL_TFC_An_AE);
else
cxl_p2n_write(afu, CXL_PSL_TFC_An, CXL_PSL_TFC_An_A);
return IRQ_HANDLED;
}
static irqreturn_t native_irq_multiplexed(int irq, void *data)
{
struct cxl_afu *afu = data;
struct cxl_context *ctx;
struct cxl_irq_info irq_info;
u64 phreg = cxl_p2n_read(afu, CXL_PSL_PEHandle_An);
int ph, ret = IRQ_HANDLED, res;
/* check if eeh kicked in while the interrupt was in flight */
if (unlikely(phreg == ~0ULL)) {
dev_warn(&afu->dev,
"Ignoring slice interrupt(%d) due to fenced card",
irq);
return IRQ_HANDLED;
}
/* Mask the pe-handle from register value */
ph = phreg & 0xffff;
if ((res = native_get_irq_info(afu, &irq_info))) {
WARN(1, "Unable to get CXL IRQ Info: %i\n", res);
if (afu->adapter->native->sl_ops->fail_irq)
return afu->adapter->native->sl_ops->fail_irq(afu, &irq_info);
return ret;
}
rcu_read_lock();
ctx = idr_find(&afu->contexts_idr, ph);
if (ctx) {
if (afu->adapter->native->sl_ops->handle_interrupt)
ret = afu->adapter->native->sl_ops->handle_interrupt(irq, ctx, &irq_info);
rcu_read_unlock();
return ret;
}
rcu_read_unlock();
WARN(1, "Unable to demultiplex CXL PSL IRQ for PE %i DSISR %016llx DAR"
" %016llx\n(Possible AFU HW issue - was a term/remove acked"
" with outstanding transactions?)\n", ph, irq_info.dsisr,
irq_info.dar);
if (afu->adapter->native->sl_ops->fail_irq)
ret = afu->adapter->native->sl_ops->fail_irq(afu, &irq_info);
return ret;
}
static void native_irq_wait(struct cxl_context *ctx)
{
u64 dsisr;
int timeout = 1000;
int ph;
/*
* Wait until no further interrupts are presented by the PSL
* for this context.
*/
while (timeout--) {
ph = cxl_p2n_read(ctx->afu, CXL_PSL_PEHandle_An) & 0xffff;
if (ph != ctx->pe)
return;
dsisr = cxl_p2n_read(ctx->afu, CXL_PSL_DSISR_An);
if (cxl_is_power8() &&
((dsisr & CXL_PSL_DSISR_PENDING) == 0))
return;
if (cxl_is_power9() &&
((dsisr & CXL_PSL9_DSISR_PENDING) == 0))
return;
/*
* We are waiting for the workqueue to process our
* irq, so need to let that run here.
*/
msleep(1);
}
dev_warn(&ctx->afu->dev, "WARNING: waiting on DSI for PE %i"
" DSISR %016llx!\n", ph, dsisr);
return;
}
static irqreturn_t native_slice_irq_err(int irq, void *data)
{
struct cxl_afu *afu = data;
u64 errstat, serr, afu_error, dsisr;
u64 fir_slice, afu_debug, irq_mask;
/*
* slice err interrupt is only used with full PSL (no XSL)
*/
serr = cxl_p1n_read(afu, CXL_PSL_SERR_An);
errstat = cxl_p2n_read(afu, CXL_PSL_ErrStat_An);
afu_error = cxl_p2n_read(afu, CXL_AFU_ERR_An);
dsisr = cxl_p2n_read(afu, CXL_PSL_DSISR_An);
cxl_afu_decode_psl_serr(afu, serr);
if (cxl_is_power8()) {
fir_slice = cxl_p1n_read(afu, CXL_PSL_FIR_SLICE_An);
afu_debug = cxl_p1n_read(afu, CXL_AFU_DEBUG_An);
dev_crit(&afu->dev, "PSL_FIR_SLICE_An: 0x%016llx\n", fir_slice);
dev_crit(&afu->dev, "CXL_PSL_AFU_DEBUG_An: 0x%016llx\n", afu_debug);
}
dev_crit(&afu->dev, "CXL_PSL_ErrStat_An: 0x%016llx\n", errstat);
dev_crit(&afu->dev, "AFU_ERR_An: 0x%.16llx\n", afu_error);
dev_crit(&afu->dev, "PSL_DSISR_An: 0x%.16llx\n", dsisr);
/* mask off the IRQ so it won't retrigger until the AFU is reset */
irq_mask = (serr & CXL_PSL_SERR_An_IRQS) >> 32;
serr |= irq_mask;
cxl_p1n_write(afu, CXL_PSL_SERR_An, serr);
dev_info(&afu->dev, "Further such interrupts will be masked until the AFU is reset\n");
return IRQ_HANDLED;
}
void cxl_native_err_irq_dump_regs_psl9(struct cxl *adapter)
{
u64 fir1;
fir1 = cxl_p1_read(adapter, CXL_PSL9_FIR1);
dev_crit(&adapter->dev, "PSL_FIR: 0x%016llx\n", fir1);
}
void cxl_native_err_irq_dump_regs_psl8(struct cxl *adapter)
{
u64 fir1, fir2;
fir1 = cxl_p1_read(adapter, CXL_PSL_FIR1);
fir2 = cxl_p1_read(adapter, CXL_PSL_FIR2);
dev_crit(&adapter->dev,
"PSL_FIR1: 0x%016llx\nPSL_FIR2: 0x%016llx\n",
fir1, fir2);
}
static irqreturn_t native_irq_err(int irq, void *data)
{
struct cxl *adapter = data;
u64 err_ivte;
WARN(1, "CXL ERROR interrupt %i\n", irq);
err_ivte = cxl_p1_read(adapter, CXL_PSL_ErrIVTE);
dev_crit(&adapter->dev, "PSL_ErrIVTE: 0x%016llx\n", err_ivte);
if (adapter->native->sl_ops->debugfs_stop_trace) {
dev_crit(&adapter->dev, "STOPPING CXL TRACE\n");
adapter->native->sl_ops->debugfs_stop_trace(adapter);
}
if (adapter->native->sl_ops->err_irq_dump_registers)
adapter->native->sl_ops->err_irq_dump_registers(adapter);
return IRQ_HANDLED;
}
int cxl_native_register_psl_err_irq(struct cxl *adapter)
{
int rc;
adapter->irq_name = kasprintf(GFP_KERNEL, "cxl-%s-err",
dev_name(&adapter->dev));
if (!adapter->irq_name)
return -ENOMEM;
if ((rc = cxl_register_one_irq(adapter, native_irq_err, adapter,
&adapter->native->err_hwirq,
&adapter->native->err_virq,
adapter->irq_name))) {
kfree(adapter->irq_name);
adapter->irq_name = NULL;
return rc;
}
cxl_p1_write(adapter, CXL_PSL_ErrIVTE, adapter->native->err_hwirq & 0xffff);
return 0;
}
void cxl_native_release_psl_err_irq(struct cxl *adapter)
{
if (adapter->native->err_virq == 0 ||
adapter->native->err_virq !=
irq_find_mapping(NULL, adapter->native->err_hwirq))
return;
cxl_p1_write(adapter, CXL_PSL_ErrIVTE, 0x0000000000000000);
cxl_unmap_irq(adapter->native->err_virq, adapter);
cxl_ops->release_one_irq(adapter, adapter->native->err_hwirq);
kfree(adapter->irq_name);
adapter->native->err_virq = 0;
}
int cxl_native_register_serr_irq(struct cxl_afu *afu)
{
u64 serr;
int rc;
afu->err_irq_name = kasprintf(GFP_KERNEL, "cxl-%s-err",
dev_name(&afu->dev));
if (!afu->err_irq_name)
return -ENOMEM;
if ((rc = cxl_register_one_irq(afu->adapter, native_slice_irq_err, afu,
&afu->serr_hwirq,
&afu->serr_virq, afu->err_irq_name))) {
kfree(afu->err_irq_name);
afu->err_irq_name = NULL;
return rc;
}
serr = cxl_p1n_read(afu, CXL_PSL_SERR_An);
if (cxl_is_power8())
serr = (serr & 0x00ffffffffff0000ULL) | (afu->serr_hwirq & 0xffff);
if (cxl_is_power9()) {
/*
* By default, all errors are masked. So don't set all masks.
* Slice errors will be transfered.
*/
serr = (serr & ~0xff0000007fffffffULL) | (afu->serr_hwirq & 0xffff);
}
cxl_p1n_write(afu, CXL_PSL_SERR_An, serr);
return 0;
}
void cxl_native_release_serr_irq(struct cxl_afu *afu)
{
if (afu->serr_virq == 0 ||
afu->serr_virq != irq_find_mapping(NULL, afu->serr_hwirq))
return;
cxl_p1n_write(afu, CXL_PSL_SERR_An, 0x0000000000000000);
cxl_unmap_irq(afu->serr_virq, afu);
cxl_ops->release_one_irq(afu->adapter, afu->serr_hwirq);
kfree(afu->err_irq_name);
afu->serr_virq = 0;
}
int cxl_native_register_psl_irq(struct cxl_afu *afu)
{
int rc;
afu->psl_irq_name = kasprintf(GFP_KERNEL, "cxl-%s",
dev_name(&afu->dev));
if (!afu->psl_irq_name)
return -ENOMEM;
if ((rc = cxl_register_one_irq(afu->adapter, native_irq_multiplexed,
afu, &afu->native->psl_hwirq, &afu->native->psl_virq,
afu->psl_irq_name))) {
kfree(afu->psl_irq_name);
afu->psl_irq_name = NULL;
}
return rc;
}
void cxl_native_release_psl_irq(struct cxl_afu *afu)
{
if (afu->native->psl_virq == 0 ||
afu->native->psl_virq !=
irq_find_mapping(NULL, afu->native->psl_hwirq))
return;
cxl_unmap_irq(afu->native->psl_virq, afu);
cxl_ops->release_one_irq(afu->adapter, afu->native->psl_hwirq);
kfree(afu->psl_irq_name);
afu->native->psl_virq = 0;
}
static void recover_psl_err(struct cxl_afu *afu, u64 errstat)
{
u64 dsisr;
pr_devel("RECOVERING FROM PSL ERROR... (0x%016llx)\n", errstat);
/* Clear PSL_DSISR[PE] */
dsisr = cxl_p2n_read(afu, CXL_PSL_DSISR_An);
cxl_p2n_write(afu, CXL_PSL_DSISR_An, dsisr & ~CXL_PSL_DSISR_An_PE);
/* Write 1s to clear error status bits */
cxl_p2n_write(afu, CXL_PSL_ErrStat_An, errstat);
}
static int native_ack_irq(struct cxl_context *ctx, u64 tfc, u64 psl_reset_mask)
{
trace_cxl_psl_irq_ack(ctx, tfc);
if (tfc)
cxl_p2n_write(ctx->afu, CXL_PSL_TFC_An, tfc);
if (psl_reset_mask)
recover_psl_err(ctx->afu, psl_reset_mask);
return 0;
}
int cxl_check_error(struct cxl_afu *afu)
{
return (cxl_p1n_read(afu, CXL_PSL_SCNTL_An) == ~0ULL);
}
static bool native_support_attributes(const char *attr_name,
enum cxl_attrs type)
{
return true;
}
static int native_afu_cr_read64(struct cxl_afu *afu, int cr, u64 off, u64 *out)
{
if (unlikely(!cxl_ops->link_ok(afu->adapter, afu)))
return -EIO;
if (unlikely(off >= afu->crs_len))
return -ERANGE;
*out = in_le64(afu->native->afu_desc_mmio + afu->crs_offset +
(cr * afu->crs_len) + off);
return 0;
}
static int native_afu_cr_read32(struct cxl_afu *afu, int cr, u64 off, u32 *out)
{
if (unlikely(!cxl_ops->link_ok(afu->adapter, afu)))
return -EIO;
if (unlikely(off >= afu->crs_len))
return -ERANGE;
*out = in_le32(afu->native->afu_desc_mmio + afu->crs_offset +
(cr * afu->crs_len) + off);
return 0;
}
static int native_afu_cr_read16(struct cxl_afu *afu, int cr, u64 off, u16 *out)
{
u64 aligned_off = off & ~0x3L;
u32 val;
int rc;
rc = native_afu_cr_read32(afu, cr, aligned_off, &val);
if (!rc)
*out = (val >> ((off & 0x3) * 8)) & 0xffff;
return rc;
}
static int native_afu_cr_read8(struct cxl_afu *afu, int cr, u64 off, u8 *out)
{
u64 aligned_off = off & ~0x3L;
u32 val;
int rc;
rc = native_afu_cr_read32(afu, cr, aligned_off, &val);
if (!rc)
*out = (val >> ((off & 0x3) * 8)) & 0xff;
return rc;
}
static int native_afu_cr_write32(struct cxl_afu *afu, int cr, u64 off, u32 in)
{
if (unlikely(!cxl_ops->link_ok(afu->adapter, afu)))
return -EIO;
if (unlikely(off >= afu->crs_len))
return -ERANGE;
out_le32(afu->native->afu_desc_mmio + afu->crs_offset +
(cr * afu->crs_len) + off, in);
return 0;
}
static int native_afu_cr_write16(struct cxl_afu *afu, int cr, u64 off, u16 in)
{
u64 aligned_off = off & ~0x3L;
u32 val32, mask, shift;
int rc;
rc = native_afu_cr_read32(afu, cr, aligned_off, &val32);
if (rc)
return rc;
shift = (off & 0x3) * 8;
WARN_ON(shift == 24);
mask = 0xffff << shift;
val32 = (val32 & ~mask) | (in << shift);
rc = native_afu_cr_write32(afu, cr, aligned_off, val32);
return rc;
}
static int native_afu_cr_write8(struct cxl_afu *afu, int cr, u64 off, u8 in)
{
u64 aligned_off = off & ~0x3L;
u32 val32, mask, shift;
int rc;
rc = native_afu_cr_read32(afu, cr, aligned_off, &val32);
if (rc)
return rc;
shift = (off & 0x3) * 8;
mask = 0xff << shift;
val32 = (val32 & ~mask) | (in << shift);
rc = native_afu_cr_write32(afu, cr, aligned_off, val32);
return rc;
}
const struct cxl_backend_ops cxl_native_ops = {
.module = THIS_MODULE,
.adapter_reset = cxl_pci_reset,
.alloc_one_irq = cxl_pci_alloc_one_irq,
.release_one_irq = cxl_pci_release_one_irq,
.alloc_irq_ranges = cxl_pci_alloc_irq_ranges,
.release_irq_ranges = cxl_pci_release_irq_ranges,
.setup_irq = cxl_pci_setup_irq,
.handle_psl_slice_error = native_handle_psl_slice_error,
.psl_interrupt = NULL,
.ack_irq = native_ack_irq,
.irq_wait = native_irq_wait,
.attach_process = native_attach_process,
.detach_process = native_detach_process,
.update_ivtes = native_update_ivtes,
.support_attributes = native_support_attributes,
.link_ok = cxl_adapter_link_ok,
.release_afu = cxl_pci_release_afu,
.afu_read_err_buffer = cxl_pci_afu_read_err_buffer,
.afu_check_and_enable = native_afu_check_and_enable,
.afu_activate_mode = native_afu_activate_mode,
.afu_deactivate_mode = native_afu_deactivate_mode,
.afu_reset = native_afu_reset,
.afu_cr_read8 = native_afu_cr_read8,
.afu_cr_read16 = native_afu_cr_read16,
.afu_cr_read32 = native_afu_cr_read32,
.afu_cr_read64 = native_afu_cr_read64,
.afu_cr_write8 = native_afu_cr_write8,
.afu_cr_write16 = native_afu_cr_write16,
.afu_cr_write32 = native_afu_cr_write32,
.read_adapter_vpd = cxl_pci_read_adapter_vpd,
};
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