blob: 6eff56fb1b345d1fd440f18c6b39541186157ac2 [file] [log] [blame]
/*
* CXL Utility library for mailbox interface
*
* Copyright(C) 2020 Intel Corporation.
*
* This work is licensed under the terms of the GNU GPL, version 2. See the
* COPYING file in the top-level directory.
*/
#include "qemu/osdep.h"
#include "hw/pci/msi.h"
#include "hw/pci/msix.h"
#include "hw/cxl/cxl.h"
#include "hw/cxl/cxl_events.h"
#include "hw/pci/pci.h"
#include "hw/pci-bridge/cxl_upstream_port.h"
#include "qemu/cutils.h"
#include "qemu/log.h"
#include "qemu/units.h"
#include "qemu/uuid.h"
#include "sysemu/hostmem.h"
#define CXL_CAPACITY_MULTIPLIER (256 * MiB)
/*
* How to add a new command, example. The command set FOO, with cmd BAR.
* 1. Add the command set and cmd to the enum.
* FOO = 0x7f,
* #define BAR 0
* 2. Implement the handler
* static CXLRetCode cmd_foo_bar(struct cxl_cmd *cmd,
* CXLDeviceState *cxl_dstate, uint16_t *len)
* 3. Add the command to the cxl_cmd_set[][]
* [FOO][BAR] = { "FOO_BAR", cmd_foo_bar, x, y },
* 4. Implement your handler
* define_mailbox_handler(FOO_BAR) { ... return CXL_MBOX_SUCCESS; }
*
*
* Writing the handler:
* The handler will provide the &struct cxl_cmd, the &CXLDeviceState, and the
* in/out length of the payload. The handler is responsible for consuming the
* payload from cmd->payload and operating upon it as necessary. It must then
* fill the output data into cmd->payload (overwriting what was there),
* setting the length, and returning a valid return code.
*
* XXX: The handler need not worry about endianness. The payload is read out of
* a register interface that already deals with it.
*/
enum {
INFOSTAT = 0x00,
#define IS_IDENTIFY 0x1
#define BACKGROUND_OPERATION_STATUS 0x2
EVENTS = 0x01,
#define GET_RECORDS 0x0
#define CLEAR_RECORDS 0x1
#define GET_INTERRUPT_POLICY 0x2
#define SET_INTERRUPT_POLICY 0x3
FIRMWARE_UPDATE = 0x02,
#define GET_INFO 0x0
TIMESTAMP = 0x03,
#define GET 0x0
#define SET 0x1
LOGS = 0x04,
#define GET_SUPPORTED 0x0
#define GET_LOG 0x1
IDENTIFY = 0x40,
#define MEMORY_DEVICE 0x0
CCLS = 0x41,
#define GET_PARTITION_INFO 0x0
#define GET_LSA 0x2
#define SET_LSA 0x3
SANITIZE = 0x44,
#define OVERWRITE 0x0
#define SECURE_ERASE 0x1
PERSISTENT_MEM = 0x45,
#define GET_SECURITY_STATE 0x0
MEDIA_AND_POISON = 0x43,
#define GET_POISON_LIST 0x0
#define INJECT_POISON 0x1
#define CLEAR_POISON 0x2
PHYSICAL_SWITCH = 0x51,
#define IDENTIFY_SWITCH_DEVICE 0x0
#define GET_PHYSICAL_PORT_STATE 0x1
TUNNEL = 0x53,
#define MANAGEMENT_COMMAND 0x0
};
/* CCI Message Format CXL r3.0 Figure 7-19 */
typedef struct CXLCCIMessage {
uint8_t category;
#define CXL_CCI_CAT_REQ 0
#define CXL_CCI_CAT_RSP 1
uint8_t tag;
uint8_t resv1;
uint8_t command;
uint8_t command_set;
uint8_t pl_length[3];
uint16_t rc;
uint16_t vendor_specific;
uint8_t payload[];
} QEMU_PACKED CXLCCIMessage;
/* This command is only defined to an MLD FM Owned LD or an MHD */
static CXLRetCode cmd_tunnel_management_cmd(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
PCIDevice *tunnel_target;
CXLCCI *target_cci;
struct {
uint8_t port_or_ld_id;
uint8_t target_type;
uint16_t size;
CXLCCIMessage ccimessage;
} QEMU_PACKED *in;
struct {
uint16_t resp_len;
uint8_t resv[2];
CXLCCIMessage ccimessage;
} QEMU_PACKED *out;
size_t pl_length, length_out;
bool bg_started;
int rc;
if (cmd->in < sizeof(*in)) {
return CXL_MBOX_INVALID_INPUT;
}
in = (void *)payload_in;
out = (void *)payload_out;
/* Enough room for minimum sized message - no payload */
if (in->size < sizeof(in->ccimessage)) {
return CXL_MBOX_INVALID_PAYLOAD_LENGTH;
}
/* Length of input payload should be in->size + a wrapping tunnel header */
if (in->size != len_in - offsetof(typeof(*out), ccimessage)) {
return CXL_MBOX_INVALID_PAYLOAD_LENGTH;
}
if (in->ccimessage.category != CXL_CCI_CAT_REQ) {
return CXL_MBOX_INVALID_INPUT;
}
if (in->target_type != 0) {
qemu_log_mask(LOG_UNIMP,
"Tunneled Command sent to non existent FM-LD");
return CXL_MBOX_INVALID_INPUT;
}
/*
* Target of a tunnel unfortunately depends on type of CCI readint
* the message.
* If in a switch, then it's the port number.
* If in an MLD it is the ld number.
* If in an MHD target type indicate where we are going.
*/
if (object_dynamic_cast(OBJECT(cci->d), TYPE_CXL_TYPE3)) {
CXLType3Dev *ct3d = CXL_TYPE3(cci->d);
if (in->port_or_ld_id != 0) {
/* Only pretending to have one for now! */
return CXL_MBOX_INVALID_INPUT;
}
target_cci = &ct3d->ld0_cci;
} else if (object_dynamic_cast(OBJECT(cci->d), TYPE_CXL_USP)) {
CXLUpstreamPort *usp = CXL_USP(cci->d);
tunnel_target = pcie_find_port_by_pn(&PCI_BRIDGE(usp)->sec_bus,
in->port_or_ld_id);
if (!tunnel_target) {
return CXL_MBOX_INVALID_INPUT;
}
tunnel_target =
pci_bridge_get_sec_bus(PCI_BRIDGE(tunnel_target))->devices[0];
if (!tunnel_target) {
return CXL_MBOX_INVALID_INPUT;
}
if (object_dynamic_cast(OBJECT(tunnel_target), TYPE_CXL_TYPE3)) {
CXLType3Dev *ct3d = CXL_TYPE3(tunnel_target);
/* Tunneled VDMs always land on FM Owned LD */
target_cci = &ct3d->vdm_fm_owned_ld_mctp_cci;
} else {
return CXL_MBOX_INVALID_INPUT;
}
} else {
return CXL_MBOX_INVALID_INPUT;
}
pl_length = in->ccimessage.pl_length[2] << 16 |
in->ccimessage.pl_length[1] << 8 | in->ccimessage.pl_length[0];
rc = cxl_process_cci_message(target_cci,
in->ccimessage.command_set,
in->ccimessage.command,
pl_length, in->ccimessage.payload,
&length_out, out->ccimessage.payload,
&bg_started);
/* Payload should be in place. Rest of CCI header and needs filling */
out->resp_len = length_out + sizeof(CXLCCIMessage);
st24_le_p(out->ccimessage.pl_length, length_out);
out->ccimessage.rc = rc;
out->ccimessage.category = CXL_CCI_CAT_RSP;
out->ccimessage.command = in->ccimessage.command;
out->ccimessage.command_set = in->ccimessage.command_set;
out->ccimessage.tag = in->ccimessage.tag;
*len_out = length_out + sizeof(*out);
return CXL_MBOX_SUCCESS;
}
static CXLRetCode cmd_events_get_records(const struct cxl_cmd *cmd,
uint8_t *payload_in, size_t len_in,
uint8_t *payload_out, size_t *len_out,
CXLCCI *cci)
{
CXLDeviceState *cxlds = &CXL_TYPE3(cci->d)->cxl_dstate;
CXLGetEventPayload *pl;
uint8_t log_type;
int max_recs;
if (cmd->in < sizeof(log_type)) {
return CXL_MBOX_INVALID_INPUT;
}
log_type = payload_in[0];
pl = (CXLGetEventPayload *)payload_out;
memset(pl, 0, sizeof(*pl));
max_recs = (cxlds->payload_size - CXL_EVENT_PAYLOAD_HDR_SIZE) /
CXL_EVENT_RECORD_SIZE;
if (max_recs > 0xFFFF) {
max_recs = 0xFFFF;
}
return cxl_event_get_records(cxlds, pl, log_type, max_recs, len_out);
}
static CXLRetCode cmd_events_clear_records(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
CXLDeviceState *cxlds = &CXL_TYPE3(cci->d)->cxl_dstate;
CXLClearEventPayload *pl;
pl = (CXLClearEventPayload *)payload_in;
*len_out = 0;
return cxl_event_clear_records(cxlds, pl);
}
static CXLRetCode cmd_events_get_interrupt_policy(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
CXLDeviceState *cxlds = &CXL_TYPE3(cci->d)->cxl_dstate;
CXLEventInterruptPolicy *policy;
CXLEventLog *log;
policy = (CXLEventInterruptPolicy *)payload_out;
memset(policy, 0, sizeof(*policy));
log = &cxlds->event_logs[CXL_EVENT_TYPE_INFO];
if (log->irq_enabled) {
policy->info_settings = CXL_EVENT_INT_SETTING(log->irq_vec);
}
log = &cxlds->event_logs[CXL_EVENT_TYPE_WARN];
if (log->irq_enabled) {
policy->warn_settings = CXL_EVENT_INT_SETTING(log->irq_vec);
}
log = &cxlds->event_logs[CXL_EVENT_TYPE_FAIL];
if (log->irq_enabled) {
policy->failure_settings = CXL_EVENT_INT_SETTING(log->irq_vec);
}
log = &cxlds->event_logs[CXL_EVENT_TYPE_FATAL];
if (log->irq_enabled) {
policy->fatal_settings = CXL_EVENT_INT_SETTING(log->irq_vec);
}
log = &cxlds->event_logs[CXL_EVENT_TYPE_DYNAMIC_CAP];
if (log->irq_enabled) {
/* Dynamic Capacity borrows the same vector as info */
policy->dyn_cap_settings = CXL_INT_MSI_MSIX;
}
*len_out = sizeof(*policy);
return CXL_MBOX_SUCCESS;
}
static CXLRetCode cmd_events_set_interrupt_policy(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
CXLDeviceState *cxlds = &CXL_TYPE3(cci->d)->cxl_dstate;
CXLEventInterruptPolicy *policy;
CXLEventLog *log;
if (len_in < CXL_EVENT_INT_SETTING_MIN_LEN) {
return CXL_MBOX_INVALID_PAYLOAD_LENGTH;
}
policy = (CXLEventInterruptPolicy *)payload_in;
log = &cxlds->event_logs[CXL_EVENT_TYPE_INFO];
log->irq_enabled = (policy->info_settings & CXL_EVENT_INT_MODE_MASK) ==
CXL_INT_MSI_MSIX;
log = &cxlds->event_logs[CXL_EVENT_TYPE_WARN];
log->irq_enabled = (policy->warn_settings & CXL_EVENT_INT_MODE_MASK) ==
CXL_INT_MSI_MSIX;
log = &cxlds->event_logs[CXL_EVENT_TYPE_FAIL];
log->irq_enabled = (policy->failure_settings & CXL_EVENT_INT_MODE_MASK) ==
CXL_INT_MSI_MSIX;
log = &cxlds->event_logs[CXL_EVENT_TYPE_FATAL];
log->irq_enabled = (policy->fatal_settings & CXL_EVENT_INT_MODE_MASK) ==
CXL_INT_MSI_MSIX;
/* DCD is optional */
if (len_in < sizeof(*policy)) {
return CXL_MBOX_SUCCESS;
}
log = &cxlds->event_logs[CXL_EVENT_TYPE_DYNAMIC_CAP];
log->irq_enabled = (policy->dyn_cap_settings & CXL_EVENT_INT_MODE_MASK) ==
CXL_INT_MSI_MSIX;
*len_out = 0;
return CXL_MBOX_SUCCESS;
}
/* CXL r3.0 section 8.2.9.1.1: Identify (Opcode 0001h) */
static CXLRetCode cmd_infostat_identify(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
PCIDeviceClass *class = PCI_DEVICE_GET_CLASS(cci->d);
struct {
uint16_t pcie_vid;
uint16_t pcie_did;
uint16_t pcie_subsys_vid;
uint16_t pcie_subsys_id;
uint64_t sn;
uint8_t max_message_size;
uint8_t component_type;
} QEMU_PACKED *is_identify;
QEMU_BUILD_BUG_ON(sizeof(*is_identify) != 18);
is_identify = (void *)payload_out;
memset(is_identify, 0, sizeof(*is_identify));
is_identify->pcie_vid = class->vendor_id;
is_identify->pcie_did = class->device_id;
if (object_dynamic_cast(OBJECT(cci->d), TYPE_CXL_USP)) {
is_identify->sn = CXL_USP(cci->d)->sn;
/* Subsystem info not defined for a USP */
is_identify->pcie_subsys_vid = 0;
is_identify->pcie_subsys_id = 0;
is_identify->component_type = 0x0; /* Switch */
} else if (object_dynamic_cast(OBJECT(cci->d), TYPE_CXL_TYPE3)) {
PCIDevice *pci_dev = PCI_DEVICE(cci->d);
is_identify->sn = CXL_TYPE3(cci->d)->sn;
/*
* We can't always use class->subsystem_vendor_id as
* it is not set if the defaults are used.
*/
is_identify->pcie_subsys_vid =
pci_get_word(pci_dev->config + PCI_SUBSYSTEM_VENDOR_ID);
is_identify->pcie_subsys_id =
pci_get_word(pci_dev->config + PCI_SUBSYSTEM_ID);
is_identify->component_type = 0x3; /* Type 3 */
}
/* TODO: Allow this to vary across different CCIs */
is_identify->max_message_size = 9; /* 512 bytes - MCTP_CXL_MAILBOX_BYTES */
*len_out = sizeof(*is_identify);
return CXL_MBOX_SUCCESS;
}
static void cxl_set_dsp_active_bm(PCIBus *b, PCIDevice *d,
void *private)
{
uint8_t *bm = private;
if (object_dynamic_cast(OBJECT(d), TYPE_CXL_DSP)) {
uint8_t port = PCIE_PORT(d)->port;
bm[port / 8] |= 1 << (port % 8);
}
}
/* CXL r3 8.2.9.1.1 */
static CXLRetCode cmd_identify_switch_device(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
PCIEPort *usp = PCIE_PORT(cci->d);
PCIBus *bus = &PCI_BRIDGE(cci->d)->sec_bus;
int num_phys_ports = pcie_count_ds_ports(bus);
struct cxl_fmapi_ident_switch_dev_resp_pl {
uint8_t ingress_port_id;
uint8_t rsvd;
uint8_t num_physical_ports;
uint8_t num_vcss;
uint8_t active_port_bitmask[0x20];
uint8_t active_vcs_bitmask[0x20];
uint16_t total_vppbs;
uint16_t bound_vppbs;
uint8_t num_hdm_decoders_per_usp;
} QEMU_PACKED *out;
QEMU_BUILD_BUG_ON(sizeof(*out) != 0x49);
out = (struct cxl_fmapi_ident_switch_dev_resp_pl *)payload_out;
*out = (struct cxl_fmapi_ident_switch_dev_resp_pl) {
.num_physical_ports = num_phys_ports + 1, /* 1 USP */
.num_vcss = 1, /* Not yet support multiple VCS - potentially tricky */
.active_vcs_bitmask[0] = 0x1,
.total_vppbs = num_phys_ports + 1,
.bound_vppbs = num_phys_ports + 1,
.num_hdm_decoders_per_usp = 4,
};
/* Depends on the CCI type */
if (object_dynamic_cast(OBJECT(cci->intf), TYPE_PCIE_PORT)) {
out->ingress_port_id = PCIE_PORT(cci->intf)->port;
} else {
/* MCTP? */
out->ingress_port_id = 0;
}
pci_for_each_device_under_bus(bus, cxl_set_dsp_active_bm,
out->active_port_bitmask);
out->active_port_bitmask[usp->port / 8] |= (1 << usp->port % 8);
*len_out = sizeof(*out);
return CXL_MBOX_SUCCESS;
}
/* CXL r3.0 Section 7.6.7.1.2: Get Physical Port State (Opcode 5101h) */
static CXLRetCode cmd_get_physical_port_state(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
/* CXL r3.0 Table 7-18: Get Physical Port State Request Payload */
struct cxl_fmapi_get_phys_port_state_req_pl {
uint8_t num_ports;
uint8_t ports[];
} QEMU_PACKED *in;
/*
* CXL r3.0 Table 7-20: Get Physical Port State Port Information Block
* Format
*/
struct cxl_fmapi_port_state_info_block {
uint8_t port_id;
uint8_t config_state;
uint8_t connected_device_cxl_version;
uint8_t rsv1;
uint8_t connected_device_type;
uint8_t port_cxl_version_bitmask;
uint8_t max_link_width;
uint8_t negotiated_link_width;
uint8_t supported_link_speeds_vector;
uint8_t max_link_speed;
uint8_t current_link_speed;
uint8_t ltssm_state;
uint8_t first_lane_num;
uint16_t link_state;
uint8_t supported_ld_count;
} QEMU_PACKED;
/* CXL r3.0 Table 7-19: Get Physical Port State Response Payload */
struct cxl_fmapi_get_phys_port_state_resp_pl {
uint8_t num_ports;
uint8_t rsv1[3];
struct cxl_fmapi_port_state_info_block ports[];
} QEMU_PACKED *out;
PCIBus *bus = &PCI_BRIDGE(cci->d)->sec_bus;
PCIEPort *usp = PCIE_PORT(cci->d);
size_t pl_size;
int i;
in = (struct cxl_fmapi_get_phys_port_state_req_pl *)payload_in;
out = (struct cxl_fmapi_get_phys_port_state_resp_pl *)payload_out;
/* Check if what was requested can fit */
if (sizeof(*out) + sizeof(*out->ports) * in->num_ports > cci->payload_max) {
return CXL_MBOX_INVALID_INPUT;
}
/* For success there should be a match for each requested */
out->num_ports = in->num_ports;
for (i = 0; i < in->num_ports; i++) {
struct cxl_fmapi_port_state_info_block *port;
/* First try to match on downstream port */
PCIDevice *port_dev;
uint16_t lnkcap, lnkcap2, lnksta;
port = &out->ports[i];
port_dev = pcie_find_port_by_pn(bus, in->ports[i]);
if (port_dev) { /* DSP */
PCIDevice *ds_dev = pci_bridge_get_sec_bus(PCI_BRIDGE(port_dev))
->devices[0];
port->config_state = 3;
if (ds_dev) {
if (object_dynamic_cast(OBJECT(ds_dev), TYPE_CXL_TYPE3)) {
port->connected_device_type = 5; /* Assume MLD for now */
} else {
port->connected_device_type = 1;
}
} else {
port->connected_device_type = 0;
}
port->supported_ld_count = 3;
} else if (usp->port == in->ports[i]) { /* USP */
port_dev = PCI_DEVICE(usp);
port->config_state = 4;
port->connected_device_type = 0;
} else {
return CXL_MBOX_INVALID_INPUT;
}
port->port_id = in->ports[i];
/* Information on status of this port in lnksta, lnkcap */
if (!port_dev->exp.exp_cap) {
return CXL_MBOX_INTERNAL_ERROR;
}
lnksta = port_dev->config_read(port_dev,
port_dev->exp.exp_cap + PCI_EXP_LNKSTA,
sizeof(lnksta));
lnkcap = port_dev->config_read(port_dev,
port_dev->exp.exp_cap + PCI_EXP_LNKCAP,
sizeof(lnkcap));
lnkcap2 = port_dev->config_read(port_dev,
port_dev->exp.exp_cap + PCI_EXP_LNKCAP2,
sizeof(lnkcap2));
port->max_link_width = (lnkcap & PCI_EXP_LNKCAP_MLW) >> 4;
port->negotiated_link_width = (lnksta & PCI_EXP_LNKSTA_NLW) >> 4;
/* No definition for SLS field in linux/pci_regs.h */
port->supported_link_speeds_vector = (lnkcap2 & 0xFE) >> 1;
port->max_link_speed = lnkcap & PCI_EXP_LNKCAP_SLS;
port->current_link_speed = lnksta & PCI_EXP_LNKSTA_CLS;
/* TODO: Track down if we can get the rest of the info */
port->ltssm_state = 0x7;
port->first_lane_num = 0;
port->link_state = 0;
port->port_cxl_version_bitmask = 0x2;
port->connected_device_cxl_version = 0x2;
}
pl_size = sizeof(*out) + sizeof(*out->ports) * in->num_ports;
*len_out = pl_size;
return CXL_MBOX_SUCCESS;
}
/* CXL r3.0 8.2.9.1.2 */
static CXLRetCode cmd_infostat_bg_op_sts(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
struct {
uint8_t status;
uint8_t rsvd;
uint16_t opcode;
uint16_t returncode;
uint16_t vendor_ext_status;
} QEMU_PACKED *bg_op_status;
QEMU_BUILD_BUG_ON(sizeof(*bg_op_status) != 8);
bg_op_status = (void *)payload_out;
memset(bg_op_status, 0, sizeof(*bg_op_status));
bg_op_status->status = cci->bg.complete_pct << 1;
if (cci->bg.runtime > 0) {
bg_op_status->status |= 1U << 0;
}
bg_op_status->opcode = cci->bg.opcode;
bg_op_status->returncode = cci->bg.ret_code;
*len_out = sizeof(*bg_op_status);
return CXL_MBOX_SUCCESS;
}
/* 8.2.9.2.1 */
static CXLRetCode cmd_firmware_update_get_info(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
CXLDeviceState *cxl_dstate = &CXL_TYPE3(cci->d)->cxl_dstate;
struct {
uint8_t slots_supported;
uint8_t slot_info;
uint8_t caps;
uint8_t rsvd[0xd];
char fw_rev1[0x10];
char fw_rev2[0x10];
char fw_rev3[0x10];
char fw_rev4[0x10];
} QEMU_PACKED *fw_info;
QEMU_BUILD_BUG_ON(sizeof(*fw_info) != 0x50);
if ((cxl_dstate->vmem_size < CXL_CAPACITY_MULTIPLIER) ||
(cxl_dstate->pmem_size < CXL_CAPACITY_MULTIPLIER)) {
return CXL_MBOX_INTERNAL_ERROR;
}
fw_info = (void *)payload_out;
memset(fw_info, 0, sizeof(*fw_info));
fw_info->slots_supported = 2;
fw_info->slot_info = BIT(0) | BIT(3);
fw_info->caps = 0;
pstrcpy(fw_info->fw_rev1, sizeof(fw_info->fw_rev1), "BWFW VERSION 0");
*len_out = sizeof(*fw_info);
return CXL_MBOX_SUCCESS;
}
/* 8.2.9.3.1 */
static CXLRetCode cmd_timestamp_get(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
CXLDeviceState *cxl_dstate = &CXL_TYPE3(cci->d)->cxl_dstate;
uint64_t final_time = cxl_device_get_timestamp(cxl_dstate);
stq_le_p(payload_out, final_time);
*len_out = 8;
return CXL_MBOX_SUCCESS;
}
/* 8.2.9.3.2 */
static CXLRetCode cmd_timestamp_set(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
CXLDeviceState *cxl_dstate = &CXL_TYPE3(cci->d)->cxl_dstate;
cxl_dstate->timestamp.set = true;
cxl_dstate->timestamp.last_set = qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL);
cxl_dstate->timestamp.host_set = le64_to_cpu(*(uint64_t *)payload_in);
*len_out = 0;
return CXL_MBOX_SUCCESS;
}
/* CXL 3.0 8.2.9.5.2.1 Command Effects Log (CEL) */
static const QemuUUID cel_uuid = {
.data = UUID(0x0da9c0b5, 0xbf41, 0x4b78, 0x8f, 0x79,
0x96, 0xb1, 0x62, 0x3b, 0x3f, 0x17)
};
/* 8.2.9.4.1 */
static CXLRetCode cmd_logs_get_supported(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
struct {
uint16_t entries;
uint8_t rsvd[6];
struct {
QemuUUID uuid;
uint32_t size;
} log_entries[1];
} QEMU_PACKED *supported_logs = (void *)payload_out;
QEMU_BUILD_BUG_ON(sizeof(*supported_logs) != 0x1c);
supported_logs->entries = 1;
supported_logs->log_entries[0].uuid = cel_uuid;
supported_logs->log_entries[0].size = 4 * cci->cel_size;
*len_out = sizeof(*supported_logs);
return CXL_MBOX_SUCCESS;
}
/* 8.2.9.4.2 */
static CXLRetCode cmd_logs_get_log(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
struct {
QemuUUID uuid;
uint32_t offset;
uint32_t length;
} QEMU_PACKED QEMU_ALIGNED(16) *get_log;
get_log = (void *)payload_in;
/*
* 8.2.9.4.2
* The device shall return Invalid Parameter if the Offset or Length
* fields attempt to access beyond the size of the log as reported by Get
* Supported Logs.
*
* XXX: Spec is wrong, "Invalid Parameter" isn't a thing.
* XXX: Spec doesn't address incorrect UUID incorrectness.
*
* The CEL buffer is large enough to fit all commands in the emulation, so
* the only possible failure would be if the mailbox itself isn't big
* enough.
*/
if (get_log->offset + get_log->length > cci->payload_max) {
return CXL_MBOX_INVALID_INPUT;
}
if (!qemu_uuid_is_equal(&get_log->uuid, &cel_uuid)) {
return CXL_MBOX_UNSUPPORTED;
}
/* Store off everything to local variables so we can wipe out the payload */
*len_out = get_log->length;
memmove(payload_out, cci->cel_log + get_log->offset, get_log->length);
return CXL_MBOX_SUCCESS;
}
/* 8.2.9.5.1.1 */
static CXLRetCode cmd_identify_memory_device(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
struct {
char fw_revision[0x10];
uint64_t total_capacity;
uint64_t volatile_capacity;
uint64_t persistent_capacity;
uint64_t partition_align;
uint16_t info_event_log_size;
uint16_t warning_event_log_size;
uint16_t failure_event_log_size;
uint16_t fatal_event_log_size;
uint32_t lsa_size;
uint8_t poison_list_max_mer[3];
uint16_t inject_poison_limit;
uint8_t poison_caps;
uint8_t qos_telemetry_caps;
} QEMU_PACKED *id;
QEMU_BUILD_BUG_ON(sizeof(*id) != 0x43);
CXLType3Dev *ct3d = CXL_TYPE3(cci->d);
CXLType3Class *cvc = CXL_TYPE3_GET_CLASS(ct3d);
CXLDeviceState *cxl_dstate = &ct3d->cxl_dstate;
if ((!QEMU_IS_ALIGNED(cxl_dstate->vmem_size, CXL_CAPACITY_MULTIPLIER)) ||
(!QEMU_IS_ALIGNED(cxl_dstate->pmem_size, CXL_CAPACITY_MULTIPLIER))) {
return CXL_MBOX_INTERNAL_ERROR;
}
id = (void *)payload_out;
memset(id, 0, sizeof(*id));
snprintf(id->fw_revision, 0x10, "BWFW VERSION %02d", 0);
stq_le_p(&id->total_capacity,
cxl_dstate->mem_size / CXL_CAPACITY_MULTIPLIER);
stq_le_p(&id->persistent_capacity,
cxl_dstate->pmem_size / CXL_CAPACITY_MULTIPLIER);
stq_le_p(&id->volatile_capacity,
cxl_dstate->vmem_size / CXL_CAPACITY_MULTIPLIER);
stl_le_p(&id->lsa_size, cvc->get_lsa_size(ct3d));
/* 256 poison records */
st24_le_p(id->poison_list_max_mer, 256);
/* No limit - so limited by main poison record limit */
stw_le_p(&id->inject_poison_limit, 0);
*len_out = sizeof(*id);
return CXL_MBOX_SUCCESS;
}
static CXLRetCode cmd_ccls_get_partition_info(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
CXLDeviceState *cxl_dstate = &CXL_TYPE3(cci->d)->cxl_dstate;
struct {
uint64_t active_vmem;
uint64_t active_pmem;
uint64_t next_vmem;
uint64_t next_pmem;
} QEMU_PACKED *part_info = (void *)payload_out;
QEMU_BUILD_BUG_ON(sizeof(*part_info) != 0x20);
if ((!QEMU_IS_ALIGNED(cxl_dstate->vmem_size, CXL_CAPACITY_MULTIPLIER)) ||
(!QEMU_IS_ALIGNED(cxl_dstate->pmem_size, CXL_CAPACITY_MULTIPLIER))) {
return CXL_MBOX_INTERNAL_ERROR;
}
stq_le_p(&part_info->active_vmem,
cxl_dstate->vmem_size / CXL_CAPACITY_MULTIPLIER);
/*
* When both next_vmem and next_pmem are 0, there is no pending change to
* partitioning.
*/
stq_le_p(&part_info->next_vmem, 0);
stq_le_p(&part_info->active_pmem,
cxl_dstate->pmem_size / CXL_CAPACITY_MULTIPLIER);
stq_le_p(&part_info->next_pmem, 0);
*len_out = sizeof(*part_info);
return CXL_MBOX_SUCCESS;
}
static CXLRetCode cmd_ccls_get_lsa(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
struct {
uint32_t offset;
uint32_t length;
} QEMU_PACKED *get_lsa;
CXLType3Dev *ct3d = CXL_TYPE3(cci->d);
CXLType3Class *cvc = CXL_TYPE3_GET_CLASS(ct3d);
uint32_t offset, length;
get_lsa = (void *)payload_in;
offset = get_lsa->offset;
length = get_lsa->length;
if (offset + length > cvc->get_lsa_size(ct3d)) {
*len_out = 0;
return CXL_MBOX_INVALID_INPUT;
}
*len_out = cvc->get_lsa(ct3d, payload_out, length, offset);
return CXL_MBOX_SUCCESS;
}
static CXLRetCode cmd_ccls_set_lsa(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
struct set_lsa_pl {
uint32_t offset;
uint32_t rsvd;
uint8_t data[];
} QEMU_PACKED;
struct set_lsa_pl *set_lsa_payload = (void *)payload_in;
CXLType3Dev *ct3d = CXL_TYPE3(cci->d);
CXLType3Class *cvc = CXL_TYPE3_GET_CLASS(ct3d);
const size_t hdr_len = offsetof(struct set_lsa_pl, data);
*len_out = 0;
if (!len_in) {
return CXL_MBOX_SUCCESS;
}
if (set_lsa_payload->offset + len_in > cvc->get_lsa_size(ct3d) + hdr_len) {
return CXL_MBOX_INVALID_INPUT;
}
len_in -= hdr_len;
cvc->set_lsa(ct3d, set_lsa_payload->data, len_in, set_lsa_payload->offset);
return CXL_MBOX_SUCCESS;
}
/* Perform the actual device zeroing */
static void __do_sanitization(CXLType3Dev *ct3d)
{
MemoryRegion *mr;
if (ct3d->hostvmem) {
mr = host_memory_backend_get_memory(ct3d->hostvmem);
if (mr) {
void *hostmem = memory_region_get_ram_ptr(mr);
memset(hostmem, 0, memory_region_size(mr));
}
}
if (ct3d->hostpmem) {
mr = host_memory_backend_get_memory(ct3d->hostpmem);
if (mr) {
void *hostmem = memory_region_get_ram_ptr(mr);
memset(hostmem, 0, memory_region_size(mr));
}
}
if (ct3d->lsa) {
mr = host_memory_backend_get_memory(ct3d->lsa);
if (mr) {
void *lsa = memory_region_get_ram_ptr(mr);
memset(lsa, 0, memory_region_size(mr));
}
}
}
/*
* CXL 3.0 spec section 8.2.9.8.5.1 - Sanitize.
*
* Once the Sanitize command has started successfully, the device shall be
* placed in the media disabled state. If the command fails or is interrupted
* by a reset or power failure, it shall remain in the media disabled state
* until a successful Sanitize command has been completed. During this state:
*
* 1. Memory writes to the device will have no effect, and all memory reads
* will return random values (no user data returned, even for locations that
* the failed Sanitize operation didn’t sanitize yet).
*
* 2. Mailbox commands shall still be processed in the disabled state, except
* that commands that access Sanitized areas shall fail with the Media Disabled
* error code.
*/
static CXLRetCode cmd_sanitize_overwrite(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
CXLType3Dev *ct3d = CXL_TYPE3(cci->d);
uint64_t total_mem; /* in Mb */
int secs;
total_mem = (ct3d->cxl_dstate.vmem_size + ct3d->cxl_dstate.pmem_size) >> 20;
if (total_mem <= 512) {
secs = 4;
} else if (total_mem <= 1024) {
secs = 8;
} else if (total_mem <= 2 * 1024) {
secs = 15;
} else if (total_mem <= 4 * 1024) {
secs = 30;
} else if (total_mem <= 8 * 1024) {
secs = 60;
} else if (total_mem <= 16 * 1024) {
secs = 2 * 60;
} else if (total_mem <= 32 * 1024) {
secs = 4 * 60;
} else if (total_mem <= 64 * 1024) {
secs = 8 * 60;
} else if (total_mem <= 128 * 1024) {
secs = 15 * 60;
} else if (total_mem <= 256 * 1024) {
secs = 30 * 60;
} else if (total_mem <= 512 * 1024) {
secs = 60 * 60;
} else if (total_mem <= 1024 * 1024) {
secs = 120 * 60;
} else {
secs = 240 * 60; /* max 4 hrs */
}
/* EBUSY other bg cmds as of now */
cci->bg.runtime = secs * 1000UL;
*len_out = 0;
cxl_dev_disable_media(&ct3d->cxl_dstate);
if (secs > 2) {
/* sanitize when done */
return CXL_MBOX_BG_STARTED;
} else {
__do_sanitization(ct3d);
cxl_dev_enable_media(&ct3d->cxl_dstate);
return CXL_MBOX_SUCCESS;
}
}
static CXLRetCode cmd_get_security_state(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
uint32_t *state = (uint32_t *)payload_out;
*state = 0;
*len_out = 4;
return CXL_MBOX_SUCCESS;
}
/*
* This is very inefficient, but good enough for now!
* Also the payload will always fit, so no need to handle the MORE flag and
* make this stateful. We may want to allow longer poison lists to aid
* testing that kernel functionality.
*/
static CXLRetCode cmd_media_get_poison_list(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
struct get_poison_list_pl {
uint64_t pa;
uint64_t length;
} QEMU_PACKED;
struct get_poison_list_out_pl {
uint8_t flags;
uint8_t rsvd1;
uint64_t overflow_timestamp;
uint16_t count;
uint8_t rsvd2[0x14];
struct {
uint64_t addr;
uint32_t length;
uint32_t resv;
} QEMU_PACKED records[];
} QEMU_PACKED;
struct get_poison_list_pl *in = (void *)payload_in;
struct get_poison_list_out_pl *out = (void *)payload_out;
CXLType3Dev *ct3d = CXL_TYPE3(cci->d);
uint16_t record_count = 0, i = 0;
uint64_t query_start, query_length;
CXLPoisonList *poison_list = &ct3d->poison_list;
CXLPoison *ent;
uint16_t out_pl_len;
query_start = ldq_le_p(&in->pa);
/* 64 byte alignment required */
if (query_start & 0x3f) {
return CXL_MBOX_INVALID_INPUT;
}
query_length = ldq_le_p(&in->length) * CXL_CACHE_LINE_SIZE;
QLIST_FOREACH(ent, poison_list, node) {
/* Check for no overlap */
if (ent->start >= query_start + query_length ||
ent->start + ent->length <= query_start) {
continue;
}
record_count++;
}
out_pl_len = sizeof(*out) + record_count * sizeof(out->records[0]);
assert(out_pl_len <= CXL_MAILBOX_MAX_PAYLOAD_SIZE);
memset(out, 0, out_pl_len);
QLIST_FOREACH(ent, poison_list, node) {
uint64_t start, stop;
/* Check for no overlap */
if (ent->start >= query_start + query_length ||
ent->start + ent->length <= query_start) {
continue;
}
/* Deal with overlap */
start = MAX(ROUND_DOWN(ent->start, 64ull), query_start);
stop = MIN(ROUND_DOWN(ent->start, 64ull) + ent->length,
query_start + query_length);
stq_le_p(&out->records[i].addr, start | (ent->type & 0x7));
stl_le_p(&out->records[i].length, (stop - start) / CXL_CACHE_LINE_SIZE);
i++;
}
if (ct3d->poison_list_overflowed) {
out->flags = (1 << 1);
stq_le_p(&out->overflow_timestamp, ct3d->poison_list_overflow_ts);
}
stw_le_p(&out->count, record_count);
*len_out = out_pl_len;
return CXL_MBOX_SUCCESS;
}
static CXLRetCode cmd_media_inject_poison(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
CXLType3Dev *ct3d = CXL_TYPE3(cci->d);
CXLPoisonList *poison_list = &ct3d->poison_list;
CXLPoison *ent;
struct inject_poison_pl {
uint64_t dpa;
};
struct inject_poison_pl *in = (void *)payload_in;
uint64_t dpa = ldq_le_p(&in->dpa);
CXLPoison *p;
QLIST_FOREACH(ent, poison_list, node) {
if (dpa >= ent->start &&
dpa + CXL_CACHE_LINE_SIZE <= ent->start + ent->length) {
return CXL_MBOX_SUCCESS;
}
}
if (ct3d->poison_list_cnt == CXL_POISON_LIST_LIMIT) {
return CXL_MBOX_INJECT_POISON_LIMIT;
}
p = g_new0(CXLPoison, 1);
p->length = CXL_CACHE_LINE_SIZE;
p->start = dpa;
p->type = CXL_POISON_TYPE_INJECTED;
/*
* Possible todo: Merge with existing entry if next to it and if same type
*/
QLIST_INSERT_HEAD(poison_list, p, node);
ct3d->poison_list_cnt++;
*len_out = 0;
return CXL_MBOX_SUCCESS;
}
static CXLRetCode cmd_media_clear_poison(const struct cxl_cmd *cmd,
uint8_t *payload_in,
size_t len_in,
uint8_t *payload_out,
size_t *len_out,
CXLCCI *cci)
{
CXLType3Dev *ct3d = CXL_TYPE3(cci->d);
CXLDeviceState *cxl_dstate = &ct3d->cxl_dstate;
CXLPoisonList *poison_list = &ct3d->poison_list;
CXLType3Class *cvc = CXL_TYPE3_GET_CLASS(ct3d);
struct clear_poison_pl {
uint64_t dpa;
uint8_t data[64];
};
CXLPoison *ent;
uint64_t dpa;
struct clear_poison_pl *in = (void *)payload_in;
dpa = ldq_le_p(&in->dpa);
if (dpa + CXL_CACHE_LINE_SIZE > cxl_dstate->mem_size) {
return CXL_MBOX_INVALID_PA;
}
/* Clearing a region with no poison is not an error so always do so */
if (cvc->set_cacheline) {
if (!cvc->set_cacheline(ct3d, dpa, in->data)) {
return CXL_MBOX_INTERNAL_ERROR;
}
}
QLIST_FOREACH(ent, poison_list, node) {
/*
* Test for contained in entry. Simpler than general case
* as clearing 64 bytes and entries 64 byte aligned
*/
if ((dpa >= ent->start) && (dpa < ent->start + ent->length)) {
break;
}
}
if (!ent) {
return CXL_MBOX_SUCCESS;
}
QLIST_REMOVE(ent, node);
ct3d->poison_list_cnt--;
if (dpa > ent->start) {
CXLPoison *frag;
/* Cannot overflow as replacing existing entry */
frag = g_new0(CXLPoison, 1);
frag->start = ent->start;
frag->length = dpa - ent->start;
frag->type = ent->type;
QLIST_INSERT_HEAD(poison_list, frag, node);
ct3d->poison_list_cnt++;
}
if (dpa + CXL_CACHE_LINE_SIZE < ent->start + ent->length) {
CXLPoison *frag;
if (ct3d->poison_list_cnt == CXL_POISON_LIST_LIMIT) {
cxl_set_poison_list_overflowed(ct3d);
} else {
frag = g_new0(CXLPoison, 1);
frag->start = dpa + CXL_CACHE_LINE_SIZE;
frag->length = ent->start + ent->length - frag->start;
frag->type = ent->type;
QLIST_INSERT_HEAD(poison_list, frag, node);
ct3d->poison_list_cnt++;
}
}
/* Any fragments have been added, free original entry */
g_free(ent);
*len_out = 0;
return CXL_MBOX_SUCCESS;
}
#define IMMEDIATE_CONFIG_CHANGE (1 << 1)
#define IMMEDIATE_DATA_CHANGE (1 << 2)
#define IMMEDIATE_POLICY_CHANGE (1 << 3)
#define IMMEDIATE_LOG_CHANGE (1 << 4)
#define SECURITY_STATE_CHANGE (1 << 5)
#define BACKGROUND_OPERATION (1 << 6)
static const struct cxl_cmd cxl_cmd_set[256][256] = {
[EVENTS][GET_RECORDS] = { "EVENTS_GET_RECORDS",
cmd_events_get_records, 1, 0 },
[EVENTS][CLEAR_RECORDS] = { "EVENTS_CLEAR_RECORDS",
cmd_events_clear_records, ~0, IMMEDIATE_LOG_CHANGE },
[EVENTS][GET_INTERRUPT_POLICY] = { "EVENTS_GET_INTERRUPT_POLICY",
cmd_events_get_interrupt_policy, 0, 0 },
[EVENTS][SET_INTERRUPT_POLICY] = { "EVENTS_SET_INTERRUPT_POLICY",
cmd_events_set_interrupt_policy,
~0, IMMEDIATE_CONFIG_CHANGE },
[FIRMWARE_UPDATE][GET_INFO] = { "FIRMWARE_UPDATE_GET_INFO",
cmd_firmware_update_get_info, 0, 0 },
[TIMESTAMP][GET] = { "TIMESTAMP_GET", cmd_timestamp_get, 0, 0 },
[TIMESTAMP][SET] = { "TIMESTAMP_SET", cmd_timestamp_set,
8, IMMEDIATE_POLICY_CHANGE },
[LOGS][GET_SUPPORTED] = { "LOGS_GET_SUPPORTED", cmd_logs_get_supported,
0, 0 },
[LOGS][GET_LOG] = { "LOGS_GET_LOG", cmd_logs_get_log, 0x18, 0 },
[IDENTIFY][MEMORY_DEVICE] = { "IDENTIFY_MEMORY_DEVICE",
cmd_identify_memory_device, 0, 0 },
[CCLS][GET_PARTITION_INFO] = { "CCLS_GET_PARTITION_INFO",
cmd_ccls_get_partition_info, 0, 0 },
[CCLS][GET_LSA] = { "CCLS_GET_LSA", cmd_ccls_get_lsa, 8, 0 },
[CCLS][SET_LSA] = { "CCLS_SET_LSA", cmd_ccls_set_lsa,
~0, IMMEDIATE_CONFIG_CHANGE | IMMEDIATE_DATA_CHANGE },
[SANITIZE][OVERWRITE] = { "SANITIZE_OVERWRITE", cmd_sanitize_overwrite, 0,
IMMEDIATE_DATA_CHANGE | SECURITY_STATE_CHANGE | BACKGROUND_OPERATION },
[PERSISTENT_MEM][GET_SECURITY_STATE] = { "GET_SECURITY_STATE",
cmd_get_security_state, 0, 0 },
[MEDIA_AND_POISON][GET_POISON_LIST] = { "MEDIA_AND_POISON_GET_POISON_LIST",
cmd_media_get_poison_list, 16, 0 },
[MEDIA_AND_POISON][INJECT_POISON] = { "MEDIA_AND_POISON_INJECT_POISON",
cmd_media_inject_poison, 8, 0 },
[MEDIA_AND_POISON][CLEAR_POISON] = { "MEDIA_AND_POISON_CLEAR_POISON",
cmd_media_clear_poison, 72, 0 },
};
static const struct cxl_cmd cxl_cmd_set_sw[256][256] = {
[INFOSTAT][IS_IDENTIFY] = { "IDENTIFY", cmd_infostat_identify, 0, 0 },
[INFOSTAT][BACKGROUND_OPERATION_STATUS] = { "BACKGROUND_OPERATION_STATUS",
cmd_infostat_bg_op_sts, 0, 0 },
[TIMESTAMP][GET] = { "TIMESTAMP_GET", cmd_timestamp_get, 0, 0 },
[TIMESTAMP][SET] = { "TIMESTAMP_SET", cmd_timestamp_set, 0,
IMMEDIATE_POLICY_CHANGE },
[LOGS][GET_SUPPORTED] = { "LOGS_GET_SUPPORTED", cmd_logs_get_supported, 0,
0 },
[LOGS][GET_LOG] = { "LOGS_GET_LOG", cmd_logs_get_log, 0x18, 0 },
[PHYSICAL_SWITCH][IDENTIFY_SWITCH_DEVICE] = { "IDENTIFY_SWITCH_DEVICE",
cmd_identify_switch_device, 0, 0 },
[PHYSICAL_SWITCH][GET_PHYSICAL_PORT_STATE] = { "SWITCH_PHYSICAL_PORT_STATS",
cmd_get_physical_port_state, ~0, 0 },
[TUNNEL][MANAGEMENT_COMMAND] = { "TUNNEL_MANAGEMENT_COMMAND",
cmd_tunnel_management_cmd, ~0, 0 },
};
/*
* While the command is executing in the background, the device should
* update the percentage complete in the Background Command Status Register
* at least once per second.
*/
#define CXL_MBOX_BG_UPDATE_FREQ 1000UL
int cxl_process_cci_message(CXLCCI *cci, uint8_t set, uint8_t cmd,
size_t len_in, uint8_t *pl_in, size_t *len_out,
uint8_t *pl_out, bool *bg_started)
{
int ret;
const struct cxl_cmd *cxl_cmd;
opcode_handler h;
*len_out = 0;
cxl_cmd = &cci->cxl_cmd_set[set][cmd];
h = cxl_cmd->handler;
if (!h) {
qemu_log_mask(LOG_UNIMP, "Command %04xh not implemented\n",
set << 8 | cmd);
return CXL_MBOX_UNSUPPORTED;
}
if (len_in != cxl_cmd->in && cxl_cmd->in != ~0) {
return CXL_MBOX_INVALID_PAYLOAD_LENGTH;
}
/* Only one bg command at a time */
if ((cxl_cmd->effect & BACKGROUND_OPERATION) &&
cci->bg.runtime > 0) {
return CXL_MBOX_BUSY;
}
/* forbid any selected commands while overwriting */
if (sanitize_running(cci)) {
if (h == cmd_events_get_records ||
h == cmd_ccls_get_partition_info ||
h == cmd_ccls_set_lsa ||
h == cmd_ccls_get_lsa ||
h == cmd_logs_get_log ||
h == cmd_media_get_poison_list ||
h == cmd_media_inject_poison ||
h == cmd_media_clear_poison ||
h == cmd_sanitize_overwrite) {
return CXL_MBOX_MEDIA_DISABLED;
}
}
ret = (*h)(cxl_cmd, pl_in, len_in, pl_out, len_out, cci);
if ((cxl_cmd->effect & BACKGROUND_OPERATION) &&
ret == CXL_MBOX_BG_STARTED) {
*bg_started = true;
} else {
*bg_started = false;
}
/* Set bg and the return code */
if (*bg_started) {
uint64_t now;
cci->bg.opcode = (set << 8) | cmd;
cci->bg.complete_pct = 0;
cci->bg.ret_code = 0;
now = qemu_clock_get_ms(QEMU_CLOCK_VIRTUAL);
cci->bg.starttime = now;
timer_mod(cci->bg.timer, now + CXL_MBOX_BG_UPDATE_FREQ);
}
return ret;
}
static void bg_timercb(void *opaque)
{
CXLCCI *cci = opaque;
uint64_t now = qemu_clock_get_ms(QEMU_CLOCK_VIRTUAL);
uint64_t total_time = cci->bg.starttime + cci->bg.runtime;
assert(cci->bg.runtime > 0);
if (now >= total_time) { /* we are done */
uint16_t ret = CXL_MBOX_SUCCESS;
cci->bg.complete_pct = 100;
cci->bg.ret_code = ret;
if (ret == CXL_MBOX_SUCCESS) {
switch (cci->bg.opcode) {
case 0x4400: /* sanitize */
{
CXLType3Dev *ct3d = CXL_TYPE3(cci->d);
__do_sanitization(ct3d);
cxl_dev_enable_media(&ct3d->cxl_dstate);
}
break;
case 0x4304: /* TODO: scan media */
break;
default:
__builtin_unreachable();
break;
}
}
qemu_log("Background command %04xh finished: %s\n",
cci->bg.opcode,
ret == CXL_MBOX_SUCCESS ? "success" : "aborted");
} else {
/* estimate only */
cci->bg.complete_pct = 100 * now / total_time;
timer_mod(cci->bg.timer, now + CXL_MBOX_BG_UPDATE_FREQ);
}
if (cci->bg.complete_pct == 100) {
/* TODO: generalize to switch CCI */
CXLType3Dev *ct3d = CXL_TYPE3(cci->d);
CXLDeviceState *cxl_dstate = &ct3d->cxl_dstate;
PCIDevice *pdev = PCI_DEVICE(cci->d);
cci->bg.starttime = 0;
/* registers are updated, allow new bg-capable cmds */
cci->bg.runtime = 0;
if (msix_enabled(pdev)) {
msix_notify(pdev, cxl_dstate->mbox_msi_n);
} else if (msi_enabled(pdev)) {
msi_notify(pdev, cxl_dstate->mbox_msi_n);
}
}
}
void cxl_init_cci(CXLCCI *cci, size_t payload_max)
{
cci->payload_max = payload_max;
for (int set = 0; set < 256; set++) {
for (int cmd = 0; cmd < 256; cmd++) {
if (cci->cxl_cmd_set[set][cmd].handler) {
const struct cxl_cmd *c = &cci->cxl_cmd_set[set][cmd];
struct cel_log *log =
&cci->cel_log[cci->cel_size];
log->opcode = (set << 8) | cmd;
log->effect = c->effect;
cci->cel_size++;
}
}
}
cci->bg.complete_pct = 0;
cci->bg.starttime = 0;
cci->bg.runtime = 0;
cci->bg.timer = timer_new_ms(QEMU_CLOCK_VIRTUAL,
bg_timercb, cci);
}
void cxl_initialize_mailbox_swcci(CXLCCI *cci, DeviceState *intf,
DeviceState *d, size_t payload_max)
{
cci->cxl_cmd_set = cxl_cmd_set_sw;
cci->d = d;
cci->intf = intf;
cxl_init_cci(cci, payload_max);
}
void cxl_initialize_mailbox_t3(CXLCCI *cci, DeviceState *d, size_t payload_max)
{
cci->cxl_cmd_set = cxl_cmd_set;
cci->d = d;
/* No separation for PCI MB as protocol handled in PCI device */
cci->intf = d;
cxl_init_cci(cci, payload_max);
}
static const struct cxl_cmd cxl_cmd_set_t3_ld[256][256] = {
[INFOSTAT][IS_IDENTIFY] = { "IDENTIFY", cmd_infostat_identify, 0, 0 },
[LOGS][GET_SUPPORTED] = { "LOGS_GET_SUPPORTED", cmd_logs_get_supported, 0,
0 },
[LOGS][GET_LOG] = { "LOGS_GET_LOG", cmd_logs_get_log, 0x18, 0 },
};
void cxl_initialize_t3_ld_cci(CXLCCI *cci, DeviceState *d, DeviceState *intf,
size_t payload_max)
{
cci->cxl_cmd_set = cxl_cmd_set_t3_ld;
cci->d = d;
cci->intf = intf;
cxl_init_cci(cci, payload_max);
}
static const struct cxl_cmd cxl_cmd_set_t3_fm_owned_ld_mctp[256][256] = {
[INFOSTAT][IS_IDENTIFY] = { "IDENTIFY", cmd_infostat_identify, 0, 0},
[LOGS][GET_SUPPORTED] = { "LOGS_GET_SUPPORTED", cmd_logs_get_supported, 0,
0 },
[LOGS][GET_LOG] = { "LOGS_GET_LOG", cmd_logs_get_log, 0x18, 0 },
[TIMESTAMP][GET] = { "TIMESTAMP_GET", cmd_timestamp_get, 0, 0 },
[TUNNEL][MANAGEMENT_COMMAND] = { "TUNNEL_MANAGEMENT_COMMAND",
cmd_tunnel_management_cmd, ~0, 0 },
};
void cxl_initialize_t3_fm_owned_ld_mctpcci(CXLCCI *cci, DeviceState *d,
DeviceState *intf,
size_t payload_max)
{
cci->cxl_cmd_set = cxl_cmd_set_t3_fm_owned_ld_mctp;
cci->d = d;
cci->intf = intf;
cxl_init_cci(cci, payload_max);
}