// SPDX-License-Identifier: LGPL-2.1-or-later
/**
* This file is part of libnvme.
* Copyright (c) 2022 Code Construct
*/
#undef NDEBUG
#include <assert.h>
#include <stdlib.h>
#include <stdio.h>
#include <unistd.h>
#include <ccan/array_size/array_size.h>
#include <ccan/endian/endian.h>
/* we define a custom transport, so need the internal headers */
#include "nvme/private.h"
#include "libnvme-mi.h"
#include "utils.h"
typedef int (*test_submit_cb)(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data);
struct test_transport_data {
unsigned int magic;
bool named;
test_submit_cb submit_cb;
void *submit_cb_data;
};
static const int test_transport_magic = 0x74657374;
static int test_transport_submit(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp)
{
struct test_transport_data *tpd = ep->transport_data;
assert(tpd->magic == test_transport_magic);
/* start from a minimal response: zeroed data, nmp to match request */
memset(resp->hdr, 0, resp->hdr_len);
if (resp->data_len)
memset(resp->data, 0, resp->data_len);
resp->hdr->type = NVME_MI_MSGTYPE_NVME;
resp->hdr->nmp = req->hdr->nmp | (NVME_MI_ROR_RSP << 7);
if (tpd->submit_cb)
return tpd->submit_cb(ep, req, resp, tpd->submit_cb_data);
return 0;
}
static void test_transport_close(struct nvme_mi_ep *ep)
{
struct test_transport_data *tpd = ep->transport_data;
assert(tpd->magic == test_transport_magic);
free(tpd);
}
static int test_transport_desc_ep(struct nvme_mi_ep *ep,
char *buf, size_t len)
{
struct test_transport_data *tpd = ep->transport_data;
assert(tpd->magic == test_transport_magic);
if (!tpd->named)
return -1;
snprintf(buf, len, "test endpoint 0x%x", tpd->magic);
return 0;
}
/* internal test helper to generate correct response crc */
static void test_transport_resp_calc_mic(struct nvme_mi_resp *resp)
{
extern __u32 nvme_mi_crc32_update(__u32 crc, void *data, size_t len);
__u32 crc = 0xffffffff;
crc = nvme_mi_crc32_update(crc, resp->hdr, resp->hdr_len);
crc = nvme_mi_crc32_update(crc, resp->data, resp->data_len);
resp->mic = ~crc;
}
static const struct nvme_mi_transport test_transport = {
.name = "test-mi",
.mic_enabled = true,
.submit = test_transport_submit,
.close = test_transport_close,
.desc_ep = test_transport_desc_ep,
};
static void test_set_transport_callback(nvme_mi_ep_t ep, test_submit_cb cb,
void *data)
{
struct test_transport_data *tpd = ep->transport_data;
assert(tpd->magic == test_transport_magic);
tpd->submit_cb = cb;
tpd->submit_cb_data = data;
}
nvme_mi_ep_t nvme_mi_open_test(nvme_root_t root)
{
struct test_transport_data *tpd;
struct nvme_mi_ep *ep;
ep = nvme_mi_init_ep(root);
assert(ep);
tpd = malloc(sizeof(*tpd));
assert(tpd);
tpd->magic = test_transport_magic;
tpd->named = true;
ep->transport = &test_transport;
ep->transport_data = tpd;
return ep;
}
unsigned int count_root_eps(nvme_root_t root)
{
unsigned int i = 0;
nvme_mi_ep_t ep;
nvme_mi_for_each_endpoint(root, ep)
i++;
return i;
}
/* test that the root->endpoints list is updated on endpoint
* creation/destruction */
static void test_endpoint_lifetime(nvme_mi_ep_t ep)
{
nvme_root_t root = ep->root;
unsigned int count;
nvme_mi_ep_t ep2;
count = count_root_eps(root);
assert(count == 1);
ep2 = nvme_mi_open_test(root);
count = count_root_eps(root);
assert(count == 2);
nvme_mi_close(ep2);
count = count_root_eps(root);
assert(count == 1);
}
unsigned int count_ep_controllers(nvme_mi_ep_t ep)
{
unsigned int i = 0;
nvme_mi_ctrl_t ctrl;
nvme_mi_for_each_ctrl(ep, ctrl)
i++;
return i;
}
/* test that the ep->controllers list is updated on controller
* creation/destruction */
static void test_ctrl_lifetime(nvme_mi_ep_t ep)
{
nvme_mi_ctrl_t c1, c2;
int count;
ep->controllers_scanned = true;
count = count_ep_controllers(ep);
assert(count == 0);
c1 = nvme_mi_init_ctrl(ep, 1);
count = count_ep_controllers(ep);
assert(count == 1);
c2 = nvme_mi_init_ctrl(ep, 2);
count = count_ep_controllers(ep);
assert(count == 2);
nvme_mi_close_ctrl(c1);
count = count_ep_controllers(ep);
assert(count == 1);
nvme_mi_close_ctrl(c2);
count = count_ep_controllers(ep);
assert(count == 0);
}
/* test: basic read MI datastructure command */
static int test_read_mi_data_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
__u8 ror, mt, *hdr, *buf;
assert(req->hdr->type == NVME_MI_MSGTYPE_NVME);
ror = req->hdr->nmp >> 7;
mt = req->hdr->nmp >> 3 & 0x7;
assert(ror == NVME_MI_ROR_REQ);
assert(mt == NVME_MI_MT_MI);
/* do we have enough for a mi header? */
assert(req->hdr_len == sizeof(struct nvme_mi_mi_req_hdr));
/* inspect response as raw bytes */
hdr = (__u8 *)req->hdr;
assert(hdr[4] == nvme_mi_mi_opcode_mi_data_read);
/* create basic response */
assert(resp->hdr_len >= sizeof(struct nvme_mi_mi_resp_hdr));
assert(resp->data_len >= 4);
hdr = (__u8 *)resp->hdr;
hdr[4] = 0; /* status */
buf = (__u8 *)resp->data;
memset(buf, 0, resp->data_len);
buf[0] = 1; /* NUMP */
buf[1] = 1; /* MJR */
buf[2] = 2; /* MNR */
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_read_mi_data(nvme_mi_ep_t ep)
{
struct nvme_mi_read_nvm_ss_info ss_info;
int rc;
test_set_transport_callback(ep, test_read_mi_data_cb, NULL);
rc = nvme_mi_mi_read_mi_data_subsys(ep, &ss_info);
assert(rc == 0);
}
/* test: failed transport */
static int test_transport_fail_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
return -1;
}
static void test_transport_fail(nvme_mi_ep_t ep)
{
struct nvme_mi_read_nvm_ss_info ss_info;
int rc;
test_set_transport_callback(ep, test_transport_fail_cb, NULL);
rc = nvme_mi_mi_read_mi_data_subsys(ep, &ss_info);
assert(rc != 0);
}
static void test_transport_describe(nvme_mi_ep_t ep)
{
struct test_transport_data *tpd;
char *str;
tpd = (struct test_transport_data *)ep->transport_data;
tpd->named = false;
str = nvme_mi_endpoint_desc(ep);
assert(str);
assert(!strcmp(str, "test-mi endpoint"));
free(str);
tpd->named = true;
str = nvme_mi_endpoint_desc(ep);
assert(str);
assert(!strcmp(str, "test-mi: test endpoint 0x74657374"));
free(str);
}
/* test: invalid crc */
static int test_invalid_crc_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
resp->mic = 0;
return 0;
}
static void test_invalid_crc(nvme_mi_ep_t ep)
{
struct nvme_mi_read_nvm_ss_info ss_info;
int rc;
test_set_transport_callback(ep, test_invalid_crc_cb, NULL);
rc = nvme_mi_mi_read_mi_data_subsys(ep, &ss_info);
assert(rc < 0);
}
/* test: test that the controller list populates the endpoint's list of
* controllers */
static int test_scan_ctrl_list_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
__u8 ror, mt, *hdr, *buf;
assert(req->hdr->type == NVME_MI_MSGTYPE_NVME);
ror = req->hdr->nmp >> 7;
mt = req->hdr->nmp >> 3 & 0x7;
assert(ror == NVME_MI_ROR_REQ);
assert(mt == NVME_MI_MT_MI);
/* do we have enough for a mi header? */
assert(req->hdr_len == sizeof(struct nvme_mi_mi_req_hdr));
/* inspect response as raw bytes */
hdr = (__u8 *)req->hdr;
assert(hdr[4] == nvme_mi_mi_opcode_mi_data_read);
assert(hdr[11] == nvme_mi_dtyp_ctrl_list);
/* create basic response */
assert(resp->hdr_len >= sizeof(struct nvme_mi_mi_resp_hdr));
assert(resp->data_len >= 4);
hdr = (__u8 *)resp->hdr;
hdr[4] = 0; /* status */
buf = (__u8 *)resp->data;
memset(buf, 0, resp->data_len);
buf[0] = 3; buf[1] = 0; /* num controllers */
buf[2] = 1; buf[3] = 0; /* id 1 */
buf[4] = 4; buf[5] = 0; /* id 4 */
buf[6] = 5; buf[7] = 0; /* id 5 */
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_scan_ctrl_list(nvme_mi_ep_t ep)
{
struct nvme_mi_ctrl *ctrl;
ep->controllers_scanned = false;
test_set_transport_callback(ep, test_scan_ctrl_list_cb, NULL);
nvme_mi_scan_ep(ep, false);
ctrl = nvme_mi_first_ctrl(ep);
assert(ctrl);
assert(ctrl->id == 1);
ctrl = nvme_mi_next_ctrl(ep, ctrl);
assert(ctrl);
assert(ctrl->id == 4);
ctrl = nvme_mi_next_ctrl(ep, ctrl);
assert(ctrl);
assert(ctrl->id == 5);
ctrl = nvme_mi_next_ctrl(ep, ctrl);
assert(ctrl == NULL);
}
/* test: simple NVMe admin request/response */
static int test_admin_id_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
__u8 ror, mt, *hdr;
__u32 dlen, cdw10;
__u16 ctrl_id;
__u8 flags;
assert(req->hdr->type == NVME_MI_MSGTYPE_NVME);
ror = req->hdr->nmp >> 7;
mt = req->hdr->nmp >> 3 & 0x7;
assert(ror == NVME_MI_ROR_REQ);
assert(mt == NVME_MI_MT_ADMIN);
/* do we have enough for a mi header? */
assert(req->hdr_len == sizeof(struct nvme_mi_admin_req_hdr));
/* inspect response as raw bytes */
hdr = (__u8 *)req->hdr;
assert(hdr[4] == nvme_admin_identify);
flags = hdr[5];
ctrl_id = hdr[7] << 8 | hdr[6];
assert(ctrl_id == 0x5); /* controller id */
/* we requested a full id; if we've set the length flag,
* ensure the length matches */
dlen = hdr[35] << 24 | hdr[34] << 16 | hdr[33] << 8 | hdr[32];
if (flags & 0x1) {
assert(dlen == sizeof(struct nvme_id_ctrl));
}
assert(!(flags & 0x2));
/* CNS value of 1 in cdw10 field */
cdw10 = hdr[47] << 24 | hdr[46] << 16 | hdr[45] << 8 | hdr[44];
assert(cdw10 == 0x1);
/* create valid (but somewhat empty) response */
hdr = (__u8 *)resp->hdr;
hdr[4] = 0x00; /* status: success */
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_admin_id(nvme_mi_ep_t ep)
{
struct nvme_id_ctrl id;
nvme_mi_ctrl_t ctrl;
int rc;
test_set_transport_callback(ep, test_admin_id_cb, NULL);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
rc = nvme_mi_admin_identify_ctrl(ctrl, &id);
assert(rc == 0);
}
/* test: simple NVMe error response, error reported in the MI header */
static int test_admin_err_mi_resp_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
__u8 ror, mt, *hdr;
assert(req->hdr->type == NVME_MI_MSGTYPE_NVME);
ror = req->hdr->nmp >> 7;
mt = req->hdr->nmp >> 3 & 0x7;
assert(ror == NVME_MI_ROR_REQ);
assert(mt == NVME_MI_MT_ADMIN);
/* do we have enough for a mi header? */
assert(req->hdr_len == sizeof(struct nvme_mi_admin_req_hdr));
/* inspect response as raw bytes */
hdr = (__u8 *)req->hdr;
assert(hdr[4] == nvme_admin_identify);
/* we need at least 8 bytes for error information */
assert(resp->hdr_len >= 8);
/* create error response */
hdr = (__u8 *)resp->hdr;
hdr[4] = 0x02; /* status: internal error */
hdr[5] = 0;
hdr[6] = 0;
hdr[7] = 0;
resp->hdr_len = 8;
resp->data_len = 0;
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_admin_err_mi_resp(nvme_mi_ep_t ep)
{
struct nvme_id_ctrl id;
nvme_mi_ctrl_t ctrl;
int rc;
test_set_transport_callback(ep, test_admin_err_mi_resp_cb, NULL);
ctrl = nvme_mi_init_ctrl(ep, 1);
assert(ctrl);
rc = nvme_mi_admin_identify_ctrl(ctrl, &id);
assert(rc != 0);
assert(nvme_status_get_type(rc) == NVME_STATUS_TYPE_MI);
assert(nvme_status_get_value(rc) == NVME_MI_RESP_INTERNAL_ERR);
}
/* test: NVMe Admin error, with the error reported in the Admin response */
static int test_admin_err_nvme_resp_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
__u8 ror, mt, *hdr;
assert(req->hdr->type == NVME_MI_MSGTYPE_NVME);
ror = req->hdr->nmp >> 7;
mt = req->hdr->nmp >> 3 & 0x7;
assert(ror == NVME_MI_ROR_REQ);
assert(mt == NVME_MI_MT_ADMIN);
/* do we have enough for a mi header? */
assert(req->hdr_len == sizeof(struct nvme_mi_admin_req_hdr));
/* inspect response as raw bytes */
hdr = (__u8 *)req->hdr;
assert(hdr[4] == nvme_admin_identify);
/* we need at least 8 bytes for error information */
assert(resp->hdr_len >= sizeof(struct nvme_mi_admin_resp_hdr));
/* create error response */
hdr = (__u8 *)resp->hdr;
hdr[4] = 0; /* MI status: success */
hdr[5] = 0;
hdr[6] = 0;
hdr[7] = 0;
hdr[16] = 0; /* cdw3: SC: internal, SCT: generic, DNR */
hdr[17] = 0;
hdr[18] = 0x0c;
hdr[19] = 0x80;
resp->hdr_len = sizeof(struct nvme_mi_admin_resp_hdr);
resp->data_len = 0;
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_admin_err_nvme_resp(nvme_mi_ep_t ep)
{
struct nvme_id_ctrl id;
nvme_mi_ctrl_t ctrl;
int rc;
test_set_transport_callback(ep, test_admin_err_nvme_resp_cb, NULL);
ctrl = nvme_mi_init_ctrl(ep, 1);
assert(ctrl);
rc = nvme_mi_admin_identify_ctrl(ctrl, &id);
assert(rc != 0);
assert(nvme_status_get_type(rc) == NVME_STATUS_TYPE_NVME);
assert(nvme_status_get_value(rc) ==
(NVME_SC_INTERNAL | (NVME_SCT_GENERIC << NVME_SCT_SHIFT)
| NVME_SC_DNR));
}
/* invalid Admin command transfers */
static int test_admin_invalid_formats_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
/* none of the tests should result in message transfer */
assert(0);
return -1;
}
static void test_admin_invalid_formats(nvme_mi_ep_t ep)
{
struct {
struct nvme_mi_admin_req_hdr hdr;
uint8_t data[4];
} req = { 0 };
struct nvme_mi_admin_resp_hdr resp = { 0 };
nvme_mi_ctrl_t ctrl;
size_t len;
int rc;
test_set_transport_callback(ep, test_admin_invalid_formats_cb, NULL);
ctrl = nvme_mi_init_ctrl(ep, 1);
assert(ctrl);
/* unaligned req size */
len = 0;
rc = nvme_mi_admin_xfer(ctrl, &req.hdr, 1, &resp, 0, &len);
assert(rc != 0);
/* unaligned resp size */
len = 1;
rc = nvme_mi_admin_xfer(ctrl, &req.hdr, 0, &resp, 0, &len);
assert(rc != 0);
/* unaligned resp offset */
len = 4;
rc = nvme_mi_admin_xfer(ctrl, &req.hdr, 0, &resp, 1, &len);
assert(rc != 0);
/* resp too large */
len = 4096 + 4;
rc = nvme_mi_admin_xfer(ctrl, &req.hdr, 0, &resp, 0, &len);
assert(rc != 0);
/* resp offset too large */
len = 4;
rc = nvme_mi_admin_xfer(ctrl, &req.hdr, 0, &resp, (off_t)1 << 32, &len);
assert(rc != 0);
/* resp offset with no len */
len = 0;
rc = nvme_mi_admin_xfer(ctrl, &req.hdr, 0, &resp, 4, &len);
assert(rc != 0);
/* req and resp payloads */
len = 4;
rc = nvme_mi_admin_xfer(ctrl, &req.hdr, 4, &resp, 0, &len);
assert(rc != 0);
}
/* test: header length too small */
static int test_resp_hdr_small_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
resp->hdr_len = 2;
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_resp_hdr_small(nvme_mi_ep_t ep)
{
struct nvme_mi_read_nvm_ss_info ss_info;
int rc;
test_set_transport_callback(ep, test_resp_hdr_small_cb, NULL);
rc = nvme_mi_mi_read_mi_data_subsys(ep, &ss_info);
assert(rc != 0);
}
/* test: respond with a request message */
static int test_resp_req_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
resp->hdr->nmp &= ~(NVME_MI_ROR_RSP << 7);
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_resp_req(nvme_mi_ep_t ep)
{
struct nvme_mi_read_nvm_ss_info ss_info;
int rc;
test_set_transport_callback(ep, test_resp_req_cb, NULL);
rc = nvme_mi_mi_read_mi_data_subsys(ep, &ss_info);
assert(rc != 0);
}
/* test: invalid MCTP type in response */
static int test_resp_invalid_type_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
resp->hdr->type = 0x3;
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_resp_invalid_type(nvme_mi_ep_t ep)
{
struct nvme_mi_read_nvm_ss_info ss_info;
int rc;
test_set_transport_callback(ep, test_resp_invalid_type_cb, NULL);
rc = nvme_mi_mi_read_mi_data_subsys(ep, &ss_info);
assert(rc != 0);
}
/* test: response with mis-matching command slot */
static int test_resp_csi_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
resp->hdr->nmp ^= 0x1;
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_resp_csi(nvme_mi_ep_t ep)
{
struct nvme_mi_read_nvm_ss_info ss_info;
int rc;
test_set_transport_callback(ep, test_resp_csi_cb, NULL);
rc = nvme_mi_mi_read_mi_data_subsys(ep, &ss_info);
assert(rc != 0);
}
/* test: config get MTU request & response layout, ensure we're handling
* endianness in the 3-byte NMRESP field correctly */
static int test_mi_config_get_mtu_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
struct nvme_mi_mi_resp_hdr *mi_resp;
uint8_t *buf;
assert(req->hdr_len == sizeof(struct nvme_mi_mi_req_hdr));
assert(req->data_len == 0);
/* validate req as raw bytes */
buf = (void *)req->hdr;
assert(buf[4] == nvme_mi_mi_opcode_configuration_get);
/* dword 0: port and config id */
assert(buf[11] == 0x5);
assert(buf[8] == NVME_MI_CONFIG_MCTP_MTU);
/* set MTU in response */
mi_resp = (void *)resp->hdr;
mi_resp->nmresp[1] = 0x12;
mi_resp->nmresp[0] = 0x34;
resp->hdr_len = sizeof(*mi_resp);
resp->data_len = 0;
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_mi_config_get_mtu(nvme_mi_ep_t ep)
{
uint16_t mtu;
int rc;
test_set_transport_callback(ep, test_mi_config_get_mtu_cb, NULL);
rc = nvme_mi_mi_config_get_mctp_mtu(ep, 5, &mtu);
assert(rc == 0);
assert(mtu == 0x1234);
}
/* test: config set SMBus freq, both valid and invalid */
static int test_mi_config_set_freq_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
struct nvme_mi_mi_resp_hdr *mi_resp;
uint8_t *buf;
assert(req->hdr_len == sizeof(struct nvme_mi_mi_req_hdr));
assert(req->data_len == 0);
/* validate req as raw bytes */
buf = (void *)req->hdr;
assert(buf[4] == nvme_mi_mi_opcode_configuration_set);
/* dword 0: port and config id */
assert(buf[11] == 0x5);
assert(buf[8] == NVME_MI_CONFIG_SMBUS_FREQ);
mi_resp = (void *)resp->hdr;
resp->hdr_len = sizeof(*mi_resp);
resp->data_len = 0;
/* accept 100 & 400, reject others */
switch (buf[9]) {
case NVME_MI_CONFIG_SMBUS_FREQ_100kHz:
case NVME_MI_CONFIG_SMBUS_FREQ_400kHz:
mi_resp->status = 0;
break;
case NVME_MI_CONFIG_SMBUS_FREQ_1MHz:
default:
mi_resp->status = 0x4;
break;
}
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_mi_config_set_freq(nvme_mi_ep_t ep)
{
int rc;
test_set_transport_callback(ep, test_mi_config_set_freq_cb, NULL);
rc = nvme_mi_mi_config_set_smbus_freq(ep, 5,
NVME_MI_CONFIG_SMBUS_FREQ_100kHz);
assert(rc == 0);
}
static void test_mi_config_set_freq_invalid(nvme_mi_ep_t ep)
{
int rc;
test_set_transport_callback(ep, test_mi_config_set_freq_cb, NULL);
rc = nvme_mi_mi_config_set_smbus_freq(ep, 5,
NVME_MI_CONFIG_SMBUS_FREQ_1MHz);
assert(rc == 4);
}
/* Get Features callback, implementing Arbitration (which doesn't return
* additional data) and Timestamp (which does).
*/
static int test_admin_get_features_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
__u8 sel, fid, ror, mt, *rq_hdr, *rs_hdr, *rs_data;
__u16 ctrl_id;
int i;
assert(req->hdr->type == NVME_MI_MSGTYPE_NVME);
ror = req->hdr->nmp >> 7;
mt = req->hdr->nmp >> 3 & 0x7;
assert(ror == NVME_MI_ROR_REQ);
assert(mt == NVME_MI_MT_ADMIN);
/* do we have enough for a mi header? */
assert(req->hdr_len == sizeof(struct nvme_mi_admin_req_hdr));
/* inspect response as raw bytes */
rq_hdr = (__u8 *)req->hdr;
/* opcode */
assert(rq_hdr[4] == nvme_admin_get_features);
/* controller */
ctrl_id = rq_hdr[7] << 8 | rq_hdr[6];
assert(ctrl_id == 0x5); /* controller id */
/* sel & fid from lower bytes of cdw10 */
fid = rq_hdr[44];
sel = rq_hdr[45] & 0x7;
/* reserved fields */
assert(!(rq_hdr[46] || rq_hdr[47] || rq_hdr[45] & 0xf8));
assert(sel == 0x00);
rs_hdr = (__u8 *)resp->hdr;
rs_hdr[4] = 0x00; /* status: success */
rs_data = resp->data;
/* feature-id specific checks, and response generation */
switch (fid) {
case NVME_FEAT_FID_ARBITRATION:
/* arbitrary (hah!) arbitration value in cdw0 of response */
rs_hdr[8] = 1;
rs_hdr[9] = 2;
rs_hdr[10] = 3;
rs_hdr[11] = 4;
resp->data_len = 0;
break;
case NVME_FEAT_FID_TIMESTAMP:
resp->data_len = 8;
for (i = 0; i < 6; i++)
rs_data[i] = i;
rs_data[6] = 1;
break;
default:
assert(0);
}
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_get_features_nodata(nvme_mi_ep_t ep)
{
struct nvme_get_features_args args = { 0 };
nvme_mi_ctrl_t ctrl;
uint32_t res;
int rc;
test_set_transport_callback(ep, test_admin_get_features_cb, NULL);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
args.args_size = sizeof(args);
args.fid = NVME_FEAT_FID_ARBITRATION;
args.sel = 0;
args.result = &res;
rc = nvme_mi_admin_get_features(ctrl, &args);
assert(rc == 0);
assert(args.data_len == 0);
assert(res == 0x04030201);
}
static void test_get_features_data(nvme_mi_ep_t ep)
{
struct nvme_get_features_args args = { 0 };
struct nvme_timestamp tstamp;
nvme_mi_ctrl_t ctrl;
uint8_t exp[6];
uint32_t res;
int rc, i;
test_set_transport_callback(ep, test_admin_get_features_cb, NULL);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
args.args_size = sizeof(args);
args.fid = NVME_FEAT_FID_TIMESTAMP;
args.sel = 0;
args.result = &res;
args.data = &tstamp;
args.data_len = sizeof(tstamp);
/* expected timestamp value */
for (i = 0; i < sizeof(tstamp.timestamp); i++)
exp[i] = i;
rc = nvme_mi_admin_get_features(ctrl, &args);
assert(rc == 0);
assert(args.data_len == sizeof(tstamp));
assert(tstamp.attr == 1);
assert(!memcmp(tstamp.timestamp, exp, sizeof(tstamp.timestamp)));
}
/* Set Features callback for timestamp */
static int test_admin_set_features_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
__u8 save, fid, ror, mt, *rq_hdr, *rq_data, *rs_hdr;
__u16 ctrl_id;
uint8_t ts[6];
int i;
assert(req->hdr->type == NVME_MI_MSGTYPE_NVME);
ror = req->hdr->nmp >> 7;
mt = req->hdr->nmp >> 3 & 0x7;
assert(ror == NVME_MI_ROR_REQ);
assert(mt == NVME_MI_MT_ADMIN);
assert(req->hdr_len == sizeof(struct nvme_mi_admin_req_hdr));
assert(req->data_len == 8);
rq_hdr = (__u8 *)req->hdr;
rq_data = req->data;
/* opcode */
assert(rq_hdr[4] == nvme_admin_set_features);
/* controller */
ctrl_id = rq_hdr[7] << 8 | rq_hdr[6];
assert(ctrl_id == 0x5); /* controller id */
/* fid from lower bytes of cdw10, save from top bit */
fid = rq_hdr[44];
save = rq_hdr[47] & 0x80;
/* reserved fields */
assert(!(rq_hdr[45] || rq_hdr[46]));
assert(fid == NVME_FEAT_FID_TIMESTAMP);
assert(save == 0x80);
for (i = 0; i < sizeof(ts); i++)
ts[i] = i;
assert(!memcmp(ts, rq_data, sizeof(ts)));
rs_hdr = (__u8 *)resp->hdr;
rs_hdr[4] = 0x00;
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_set_features(nvme_mi_ep_t ep)
{
struct nvme_set_features_args args = { 0 };
struct nvme_timestamp tstamp = { 0 };
nvme_mi_ctrl_t ctrl;
uint32_t res;
int rc, i;
test_set_transport_callback(ep, test_admin_set_features_cb, NULL);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
for (i = 0; i < sizeof(tstamp.timestamp); i++)
tstamp.timestamp[i] = i;
args.args_size = sizeof(args);
args.fid = NVME_FEAT_FID_TIMESTAMP;
args.save = 1;
args.result = &res;
args.data = &tstamp;
args.data_len = sizeof(tstamp);
rc = nvme_mi_admin_set_features(ctrl, &args);
assert(rc == 0);
assert(args.data_len == 0);
}
enum ns_type {
NS_ACTIVE,
NS_ALLOC,
};
static int test_admin_id_ns_list_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
struct nvme_ns_list *list;
enum ns_type type;
int offset;
__u8 *hdr;
__u16 cns;
hdr = (__u8 *)req->hdr;
assert(hdr[4] == nvme_admin_identify);
assert(req->data_len == 0);
cns = hdr[45] << 8 | hdr[44];
/* NSID */
assert(hdr[8] == 1 && !hdr[9] && !hdr[10] && !hdr[11]);
type = *(enum ns_type *)data;
resp->data_len = sizeof(*list);
list = resp->data;
switch (type) {
case NS_ALLOC:
assert(cns == NVME_IDENTIFY_CNS_ALLOCATED_NS_LIST);
offset = 2;
break;
case NS_ACTIVE:
assert(cns == NVME_IDENTIFY_CNS_NS_ACTIVE_LIST);
offset = 4;
break;
default:
assert(0);
}
list->ns[0] = cpu_to_le32(offset);
list->ns[1] = cpu_to_le32(offset + 1);
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_admin_id_alloc_ns_list(struct nvme_mi_ep *ep)
{
struct nvme_ns_list list;
nvme_mi_ctrl_t ctrl;
enum ns_type type;
int rc;
type = NS_ALLOC;
test_set_transport_callback(ep, test_admin_id_ns_list_cb, &type);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
rc = nvme_mi_admin_identify_allocated_ns_list(ctrl, 1, &list);
assert(!rc);
assert(le32_to_cpu(list.ns[0]) == 2);
assert(le32_to_cpu(list.ns[1]) == 3);
assert(le32_to_cpu(list.ns[2]) == 0);
}
static void test_admin_id_active_ns_list(struct nvme_mi_ep *ep)
{
struct nvme_ns_list list;
nvme_mi_ctrl_t ctrl;
enum ns_type type;
int rc;
type = NS_ACTIVE;
test_set_transport_callback(ep, test_admin_id_ns_list_cb, &type);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
rc = nvme_mi_admin_identify_active_ns_list(ctrl, 1, &list);
assert(!rc);
assert(le32_to_cpu(list.ns[0]) == 4);
assert(le32_to_cpu(list.ns[1]) == 5);
assert(le32_to_cpu(list.ns[2]) == 0);
}
static int test_admin_id_ns_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
struct nvme_id_ns *id;
enum ns_type type;
__u16 nsid, cns;
__u8 *hdr;
hdr = (__u8 *)req->hdr;
assert(hdr[4] == nvme_admin_identify);
assert(req->data_len == 0);
cns = hdr[45] << 8 | hdr[44];
/* NSID */
nsid = hdr[8];
assert(!hdr[9] && !hdr[10] && !hdr[11]);
type = *(enum ns_type *)data;
resp->data_len = sizeof(*id);
id = resp->data;
id->nsze = cpu_to_le64(nsid);
switch (type) {
case NS_ALLOC:
assert(cns == NVME_IDENTIFY_CNS_ALLOCATED_NS);
break;
case NS_ACTIVE:
assert(cns == NVME_IDENTIFY_CNS_NS);
break;
default:
assert(0);
}
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_admin_id_alloc_ns(struct nvme_mi_ep *ep)
{
struct nvme_id_ns id;
nvme_mi_ctrl_t ctrl;
enum ns_type type;
int rc;
type = NS_ALLOC;
test_set_transport_callback(ep, test_admin_id_ns_cb, &type);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
rc = nvme_mi_admin_identify_allocated_ns(ctrl, 1, &id);
assert(!rc);
assert(le64_to_cpu(id.nsze) == 1);
}
static void test_admin_id_active_ns(struct nvme_mi_ep *ep)
{
struct nvme_id_ns id;
nvme_mi_ctrl_t ctrl;
enum ns_type type;
int rc;
type = NS_ACTIVE;
test_set_transport_callback(ep, test_admin_id_ns_cb, &type);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
rc = nvme_mi_admin_identify_ns(ctrl, 1, &id);
assert(!rc);
assert(le64_to_cpu(id.nsze) == 1);
}
static int test_admin_id_nsid_ctrl_list_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
__u16 cns, ctrlid;
__u32 nsid;
__u8 *hdr;
hdr = (__u8 *)req->hdr;
assert(hdr[4] == nvme_admin_identify);
assert(req->data_len == 0);
cns = hdr[45] << 8 | hdr[44];
assert(cns == NVME_IDENTIFY_CNS_NS_CTRL_LIST);
nsid = hdr[11] << 24 | hdr[10] << 16 | hdr[9] << 8 | hdr[8];
assert(nsid == 0x01020304);
ctrlid = hdr[47] << 8 | hdr[46];
assert(ctrlid == 5);
resp->data_len = sizeof(struct nvme_ctrl_list);
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_admin_id_nsid_ctrl_list(struct nvme_mi_ep *ep)
{
struct nvme_ctrl_list list;
nvme_mi_ctrl_t ctrl;
int rc;
test_set_transport_callback(ep, test_admin_id_nsid_ctrl_list_cb, NULL);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
rc = nvme_mi_admin_identify_nsid_ctrl_list(ctrl, 0x01020304, 5, &list);
assert(!rc);
}
static int test_admin_id_secondary_ctrl_list_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
__u16 cns, ctrlid;
__u8 *hdr;
hdr = (__u8 *)req->hdr;
assert(hdr[4] == nvme_admin_identify);
assert(req->data_len == 0);
cns = hdr[45] << 8 | hdr[44];
assert(cns == NVME_IDENTIFY_CNS_SECONDARY_CTRL_LIST);
ctrlid = hdr[47] << 8 | hdr[46];
assert(ctrlid == 5);
resp->data_len = sizeof(struct nvme_secondary_ctrl_list);
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_admin_id_secondary_ctrl_list(struct nvme_mi_ep *ep)
{
struct nvme_secondary_ctrl_list list;
nvme_mi_ctrl_t ctrl;
int rc;
test_set_transport_callback(ep, test_admin_id_secondary_ctrl_list_cb,
NULL);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
rc = nvme_mi_admin_identify_secondary_ctrl_list(ctrl, 5, &list);
assert(!rc);
}
static int test_admin_ns_mgmt_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
__u8 *rq_hdr, *rs_hdr, sel, csi;
struct nvme_ns_mgmt_host_sw_specified *create_data;
__u32 nsid;
rq_hdr = (__u8 *)req->hdr;
assert(rq_hdr[4] == nvme_admin_ns_mgmt);
sel = rq_hdr[44];
csi = rq_hdr[45];
nsid = rq_hdr[11] << 24 | rq_hdr[10] << 16 | rq_hdr[9] << 8 | rq_hdr[8];
rs_hdr = (__u8 *)resp->hdr;
switch (sel) {
case NVME_NS_MGMT_SEL_CREATE:
assert(req->data_len == sizeof(struct nvme_ns_mgmt_host_sw_specified));
create_data = req->data;
/* No NSID on created namespaces */
assert(nsid == 0);
assert(csi == 0);
/* allow operations on nsze == 42, reject others */
if (le64_to_cpu(create_data->nsze) != 42) {
rs_hdr[4] = 0;
/* response cdw0 is created NSID */
rs_hdr[8] = 0x04;
rs_hdr[9] = 0x03;
rs_hdr[10] = 0x02;
rs_hdr[11] = 0x01;
} else {
rs_hdr[4] = NVME_MI_RESP_INVALID_PARAM;
}
break;
case NVME_NS_MGMT_SEL_DELETE:
assert(req->data_len == 0);
/* NSID required on delete */
assert(nsid == 0x05060708);
break;
default:
assert(0);
}
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_admin_ns_mgmt_create(struct nvme_mi_ep *ep)
{
struct nvme_ns_mgmt_host_sw_specified data = { 0 };
nvme_mi_ctrl_t ctrl;
__u32 ns;
int rc;
test_set_transport_callback(ep, test_admin_ns_mgmt_cb, NULL);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
rc = nvme_mi_admin_ns_mgmt_create(ctrl, NULL, 0, &ns, &data);
assert(!rc);
assert(ns == 0x01020304);
data.nsze = cpu_to_le64(42);
rc = nvme_mi_admin_ns_mgmt_create(ctrl, NULL, 0, &ns, &data);
assert(rc);
}
static void test_admin_ns_mgmt_delete(struct nvme_mi_ep *ep)
{
nvme_mi_ctrl_t ctrl;
int rc;
test_set_transport_callback(ep, test_admin_ns_mgmt_cb, NULL);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
rc = nvme_mi_admin_ns_mgmt_delete(ctrl, 0x05060708);
assert(!rc);
}
struct attach_op {
enum {
NS_ATTACH,
NS_DETACH,
} op;
struct nvme_ctrl_list *list;
};
static int test_admin_ns_attach_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
struct attach_op *op = data;
__u8 *rq_hdr, sel;
__u32 nsid;
rq_hdr = (__u8 *)req->hdr;
assert(rq_hdr[4] == nvme_admin_ns_attach);
sel = rq_hdr[44];
nsid = rq_hdr[11] << 24 | rq_hdr[10] << 16 | rq_hdr[9] << 8 | rq_hdr[8];
assert(req->data_len == sizeof(*op->list));
assert(nsid == 0x02030405);
switch (op->op) {
case NS_ATTACH:
assert(sel == NVME_NS_ATTACH_SEL_CTRL_ATTACH);
break;
case NS_DETACH:
assert(sel == NVME_NS_ATTACH_SEL_CTRL_DEATTACH);
break;
default:
assert(0);
}
assert(!memcmp(req->data, op->list, sizeof(*op->list)));
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_admin_ns_attach(struct nvme_mi_ep *ep)
{
struct nvme_ctrl_list list = { 0 };
struct attach_op aop;
nvme_mi_ctrl_t ctrl;
int rc;
list.num = cpu_to_le16(2);
list.identifier[0] = 4;
list.identifier[1] = 5;
aop.op = NS_ATTACH;
aop.list = &list;
test_set_transport_callback(ep, test_admin_ns_attach_cb, &aop);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
rc = nvme_mi_admin_ns_attach_ctrls(ctrl, 0x02030405, &list);
assert(!rc);
}
static void test_admin_ns_detach(struct nvme_mi_ep *ep)
{
struct nvme_ctrl_list list = { 0 };
struct attach_op aop;
nvme_mi_ctrl_t ctrl;
int rc;
list.num = cpu_to_le16(2);
list.identifier[0] = 6;
list.identifier[1] = 7;
aop.op = NS_DETACH;
aop.list = &list;
test_set_transport_callback(ep, test_admin_ns_attach_cb, &aop);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
rc = nvme_mi_admin_ns_detach_ctrls(ctrl, 0x02030405, &list);
assert(!rc);
}
struct fw_download_info {
uint32_t offset;
uint32_t len;
void *data;
};
static int test_admin_fw_download_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
struct fw_download_info *info = data;
__u32 len, off;
__u8 *rq_hdr;
rq_hdr = (__u8 *)req->hdr;
assert(rq_hdr[4] == nvme_admin_fw_download);
len = rq_hdr[47] << 24 | rq_hdr[46] << 16 | rq_hdr[45] << 8 | rq_hdr[44];
off = rq_hdr[51] << 24 | rq_hdr[50] << 16 | rq_hdr[49] << 8 | rq_hdr[48];
assert(off << 2 == info->offset);
assert(((len+1) << 2) == info->len);
/* ensure that the request len matches too */
assert(req->data_len == info->len);
assert(!memcmp(req->data, info->data, len));
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_admin_fw_download(struct nvme_mi_ep *ep)
{
struct nvme_fw_download_args args;
struct fw_download_info info;
unsigned char fw[4096];
nvme_mi_ctrl_t ctrl;
int rc, i;
for (i = 0; i < sizeof(fw); i++)
fw[i] = i % 0xff;
info.offset = 0;
info.len = 0;
info.data = fw;
args.data = fw;
args.args_size = sizeof(args);
test_set_transport_callback(ep, test_admin_fw_download_cb, &info);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
/* invalid (zero) len */
args.data_len = info.len = 1;
args.offset = info.offset = 0;
rc = nvme_mi_admin_fw_download(ctrl, &args);
assert(rc);
/* invalid (unaligned) len */
args.data_len = info.len = 1;
args.offset = info.offset = 0;
rc = nvme_mi_admin_fw_download(ctrl, &args);
assert(rc);
/* invalid offset */
args.data_len = info.len = 4;
args.offset = info.offset = 1;
rc = nvme_mi_admin_fw_download(ctrl, &args);
assert(rc);
/* smallest len */
args.data_len = info.len = 4;
args.offset = info.offset = 0;
rc = nvme_mi_admin_fw_download(ctrl, &args);
assert(!rc);
/* largest len */
args.data_len = info.len = 4096;
args.offset = info.offset = 0;
rc = nvme_mi_admin_fw_download(ctrl, &args);
assert(!rc);
/* offset value */
args.data_len = info.len = 4096;
args.offset = info.offset = 4096;
rc = nvme_mi_admin_fw_download(ctrl, &args);
assert(!rc);
}
struct fw_commit_info {
__u8 bpid;
__u8 action;
__u8 slot;
};
static int test_admin_fw_commit_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
struct fw_commit_info *info = data;
__u8 bpid, action, slot;
__u8 *rq_hdr;
rq_hdr = (__u8 *)req->hdr;
assert(rq_hdr[4] == nvme_admin_fw_commit);
bpid = (rq_hdr[47] >> 7) & 0x1;
slot = rq_hdr[44] & 0x7;
action = (rq_hdr[44] >> 3) & 0x7;
assert(!!bpid == !!info->bpid);
assert(slot == info->slot);
assert(action == info->action);
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_admin_fw_commit(struct nvme_mi_ep *ep)
{
struct nvme_fw_commit_args args;
struct fw_commit_info info;
nvme_mi_ctrl_t ctrl;
int rc;
args.args_size = sizeof(args);
info.bpid = args.bpid = 0;
test_set_transport_callback(ep, test_admin_fw_commit_cb, &info);
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
/* all zeros */
info.bpid = args.bpid = 0;
info.slot = args.slot = 0;
info.action = args.action = 0;
rc = nvme_mi_admin_fw_commit(ctrl, &args);
assert(!rc);
/* all ones */
info.bpid = args.bpid = 1;
info.slot = args.slot = 0x7;
info.action = args.action = 0x7;
rc = nvme_mi_admin_fw_commit(ctrl, &args);
assert(!rc);
/* correct fields */
info.bpid = args.bpid = 1;
info.slot = args.slot = 2;
info.action = args.action = 3;
rc = nvme_mi_admin_fw_commit(ctrl, &args);
assert(!rc);
}
struct format_data {
__u32 nsid;
__u8 lbafu;
__u8 ses;
__u8 pil;
__u8 pi;
__u8 mset;
__u8 lbafl;
};
static int test_admin_format_nvm_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
struct nvme_format_nvm_args *args = data;
__u8 *rq_hdr;
__u32 nsid;
assert(req->data_len == 0);
rq_hdr = (__u8 *)req->hdr;
assert(rq_hdr[4] == nvme_admin_format_nvm);
nsid = (__u32)rq_hdr[11] << 24
| rq_hdr[10] << 16
| rq_hdr[9] << 8
| rq_hdr[8];
assert(nsid == args->nsid);
assert(((rq_hdr[44] >> 0) & 0xf) == args->lbaf);
assert(((rq_hdr[44] >> 4) & 0x1) == args->mset);
assert(((rq_hdr[44] >> 5) & 0x7) == args->pi);
assert(((rq_hdr[45] >> 0) & 0x1) == args->pil);
assert(((rq_hdr[45] >> 1) & 0x7) == args->ses);
assert(((rq_hdr[45] >> 4) & 0x3) == args->lbafu);
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_admin_format_nvm(struct nvme_mi_ep *ep)
{
struct nvme_format_nvm_args args = { 0 };
nvme_mi_ctrl_t ctrl;
int rc;
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
test_set_transport_callback(ep, test_admin_format_nvm_cb, &args);
/* ensure we have the cdw0 bit field encoding correct, by testing twice
* with inverted bit values */
args.args_size = sizeof(args);
args.nsid = 0x04030201;
args.lbafu = 0x3;
args.ses = 0x0;
args.pil = 0x1;
args.pi = 0x0;
args.mset = 0x1;
args.lbaf = 0x0;
rc = nvme_mi_admin_format_nvm(ctrl, &args);
assert(!rc);
args.nsid = ~args.nsid;
args.lbafu = 0;
args.ses = 0x7;
args.pil = 0x0;
args.pi = 0x7;
args.mset = 0x0;
args.lbaf = 0xf;
rc = nvme_mi_admin_format_nvm(ctrl, &args);
assert(!rc);
}
static int test_admin_sanitize_nvm_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
struct nvme_sanitize_nvm_args *args = data;
__u8 *rq_hdr;
__u32 ovrpat;
assert(req->data_len == 0);
rq_hdr = (__u8 *)req->hdr;
assert(rq_hdr[4] == nvme_admin_sanitize_nvm);
assert(((rq_hdr[44] >> 0) & 0x7) == args->sanact);
assert(((rq_hdr[44] >> 3) & 0x1) == args->ause);
assert(((rq_hdr[44] >> 4) & 0xf) == args->owpass);
assert(((rq_hdr[45] >> 0) & 0x1) == args->oipbp);
assert(((rq_hdr[45] >> 1) & 0x1) == args->nodas);
ovrpat = (__u32)rq_hdr[51] << 24 | rq_hdr[50] << 16 |
rq_hdr[49] << 8 | rq_hdr[48];
assert(ovrpat == args->ovrpat);
test_transport_resp_calc_mic(resp);
return 0;
}
static void test_admin_sanitize_nvm(struct nvme_mi_ep *ep)
{
struct nvme_sanitize_nvm_args args = { 0 };
nvme_mi_ctrl_t ctrl;
int rc;
ctrl = nvme_mi_init_ctrl(ep, 5);
assert(ctrl);
test_set_transport_callback(ep, test_admin_sanitize_nvm_cb, &args);
args.args_size = sizeof(args);
args.sanact = 0x7;
args.ause = 0x0;
args.owpass = 0xf;
args.oipbp = 0x0;
args.nodas = 0x1;
args.ovrpat = ~0x04030201;
rc = nvme_mi_admin_sanitize_nvm(ctrl, &args);
assert(!rc);
args.sanact = 0x0;
args.ause = 0x1;
args.owpass = 0x0;
args.oipbp = 0x1;
args.nodas = 0x0;
args.ovrpat = 0x04030201;
rc = nvme_mi_admin_sanitize_nvm(ctrl, &args);
assert(!rc);
}
/* test that we set the correct offset and size on get_log() calls that
* are split into multiple requests */
struct log_data {
int n;
};
static int test_admin_get_log_split_cb(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp,
void *data)
{
uint32_t log_page_offset_lower;
struct log_data *ldata = data;
uint32_t len, off;
__u8 *rq_hdr;
assert(req->data_len == 0);
rq_hdr = (__u8 *)req->hdr;
assert(rq_hdr[4] == nvme_admin_get_log_page);
/* from the MI message's DOFST/DLEN fields */
off = rq_hdr[31] << 24 | rq_hdr[30] << 16 | rq_hdr[29] << 8 | rq_hdr[28];
len = rq_hdr[35] << 24 | rq_hdr[34] << 16 | rq_hdr[33] << 8 | rq_hdr[32];
/* From the MI message's Command Dword 12 */
log_page_offset_lower = rq_hdr[55] << 24 | rq_hdr[54] << 16 | rq_hdr[53] << 8 | rq_hdr[52];
/* we should have a full-sized start and middle, and a short end */
switch (ldata->n) {
case 0:
assert(log_page_offset_lower == 0);
assert(len == 4096);
assert(off == 0);
break;
case 1:
assert(log_page_offset_lower == 4096);
assert(len == 4096);
assert(off == 0);
break;
case 2:
assert(log_page_offset_lower == 8192);
assert(len == 4);
assert(off == 0);
break;
default:
assert(0);
}
/* ensure we've sized the expected response correctly */
assert(resp->data_len == len);
memset(resp->data, ldata->n & 0xff, len);
test_transport_resp_calc_mic(resp);
ldata->n++;
return 0;
}
static void test_admin_get_log_split(struct nvme_mi_ep *ep)
{
struct nvme_get_log_args args = { 0 };
unsigned char buf[4096 * 2 + 4];
struct log_data ldata;
nvme_mi_ctrl_t ctrl;
int rc;
ldata.n = 0;
test_set_transport_callback(ep, test_admin_get_log_split_cb, &ldata);
ctrl = nvme_mi_init_ctrl(ep, 5);
args.args_size = sizeof(args);
args.lid = 1;
args.log = buf;
args.len = sizeof(buf);
args.lpo = 0;
args.ot = false;
rc = nvme_mi_admin_get_log(ctrl, &args);
assert(!rc);
/* we should have sent three commands */
assert(ldata.n == 3);
}
#define DEFINE_TEST(name) { #name, test_ ## name }
struct test {
const char *name;
void (*fn)(nvme_mi_ep_t);
} tests[] = {
DEFINE_TEST(endpoint_lifetime),
DEFINE_TEST(ctrl_lifetime),
DEFINE_TEST(read_mi_data),
DEFINE_TEST(transport_fail),
DEFINE_TEST(transport_describe),
DEFINE_TEST(scan_ctrl_list),
DEFINE_TEST(invalid_crc),
DEFINE_TEST(admin_id),
DEFINE_TEST(admin_err_mi_resp),
DEFINE_TEST(admin_err_nvme_resp),
DEFINE_TEST(admin_invalid_formats),
DEFINE_TEST(resp_req),
DEFINE_TEST(resp_hdr_small),
DEFINE_TEST(resp_invalid_type),
DEFINE_TEST(resp_csi),
DEFINE_TEST(mi_config_get_mtu),
DEFINE_TEST(mi_config_set_freq),
DEFINE_TEST(mi_config_set_freq_invalid),
DEFINE_TEST(get_features_nodata),
DEFINE_TEST(get_features_data),
DEFINE_TEST(set_features),
DEFINE_TEST(admin_id_alloc_ns_list),
DEFINE_TEST(admin_id_active_ns_list),
DEFINE_TEST(admin_id_alloc_ns),
DEFINE_TEST(admin_id_active_ns),
DEFINE_TEST(admin_id_nsid_ctrl_list),
DEFINE_TEST(admin_id_secondary_ctrl_list),
DEFINE_TEST(admin_ns_mgmt_create),
DEFINE_TEST(admin_ns_mgmt_delete),
DEFINE_TEST(admin_ns_attach),
DEFINE_TEST(admin_ns_detach),
DEFINE_TEST(admin_fw_download),
DEFINE_TEST(admin_fw_commit),
DEFINE_TEST(admin_format_nvm),
DEFINE_TEST(admin_sanitize_nvm),
DEFINE_TEST(admin_get_log_split),
};
static void run_test(struct test *test, FILE *logfd, nvme_mi_ep_t ep)
{
printf("Running test %s...", test->name);
fflush(stdout);
test->fn(ep);
/* tests will assert on failure; if we're here, we're OK */
printf(" OK\n");
test_print_log_buf(logfd);
}
int main(void)
{
nvme_root_t root;
nvme_mi_ep_t ep;
unsigned int i;
FILE *fd;
fd = test_setup_log();
root = nvme_mi_create_root(fd, DEFAULT_LOGLEVEL);
assert(root);
ep = nvme_mi_open_test(root);
assert(ep);
for (i = 0; i < ARRAY_SIZE(tests); i++) {
run_test(&tests[i], fd, ep);
}
nvme_mi_close(ep);
nvme_mi_free_root(root);
test_close_log(fd);
return EXIT_SUCCESS;
}