esp-idf/components/usb/test/usb_host/msc_client_async_dconn.c

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/*
* SPDX-FileCopyrightText: 2015-2022 Espressif Systems (Shanghai) CO LTD
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <stdint.h>
#include <string.h>
#include <stdlib.h>
#include <sys/param.h>
#include "freertos/FreeRTOS.h"
#include "freertos/task.h"
#include "esp_err.h"
#include "esp_log.h"
#include "test_usb_mock_msc.h"
#include "test_usb_common.h"
#include "msc_client.h"
#include "usb/usb_host.h"
#include "unity.h"
/*
Implementation of an asynchronous MSC client used for USB Host disconnection test.
- The MSC client will:
- Register itself as a client
- Receive USB_HOST_CLIENT_EVENT_NEW_DEV event message, and open the device
- Allocate IN and OUT transfer objects for MSC SCSI transfers
- Trigger a single MSC SCSI transfer
- Split the data stage into multiple transfers (so that the endpoint multiple queued up transfers)
- Cause a disconnection mid-way through the data stage
- All of the transfers should be automatically dequeued
- Then a USB_HOST_CLIENT_EVENT_DEV_GONE event should occur afterwards
- Free transfer objects
- Close device
- Deregister MSC client
*/
#define TEST_DCONN_ITERATIONS 3
typedef enum {
TEST_STAGE_WAIT_CONN,
TEST_STAGE_DEV_OPEN,
TEST_STAGE_MSC_RESET,
TEST_STAGE_MSC_CBW,
TEST_STAGE_MSC_DATA_DCONN,
TEST_STAGE_DEV_CLOSE,
} test_stage_t;
typedef struct {
msc_client_test_param_t test_param;
test_stage_t cur_stage;
test_stage_t next_stage;
uint8_t dev_addr_to_open;
usb_host_client_handle_t client_hdl;
usb_device_handle_t dev_hdl;
int num_data_transfers;
int event_count;
} msc_client_obj_t;
static void msc_reset_cbw_transfer_cb(usb_transfer_t *transfer)
{
msc_client_obj_t *msc_obj = (msc_client_obj_t *)transfer->context;
//We expect the reset and CBW transfers to complete with no issues
TEST_ASSERT_EQUAL_MESSAGE(USB_TRANSFER_STATUS_COMPLETED, transfer->status, "Transfer NOT completed");
TEST_ASSERT_EQUAL(transfer->num_bytes, transfer->actual_num_bytes);
switch (msc_obj->cur_stage) {
case TEST_STAGE_MSC_RESET:
msc_obj->next_stage = TEST_STAGE_MSC_CBW;
break;
case TEST_STAGE_MSC_CBW:
msc_obj->next_stage = TEST_STAGE_MSC_DATA_DCONN;
break;
default:
abort();
break;
}
}
static void msc_data_transfer_cb(usb_transfer_t *transfer)
{
//The data stage should have either completed, or failed due to the disconnection.
TEST_ASSERT(transfer->status == USB_TRANSFER_STATUS_COMPLETED || transfer->status == USB_TRANSFER_STATUS_NO_DEVICE);
if (transfer->status == USB_TRANSFER_STATUS_COMPLETED) {
TEST_ASSERT_EQUAL(transfer->num_bytes, transfer->actual_num_bytes);
} else {
TEST_ASSERT_EQUAL(0, transfer->actual_num_bytes);
}
msc_client_obj_t *msc_obj = (msc_client_obj_t *)transfer->context;
msc_obj->event_count++;
//If all transfers dequeued and device gone event occurred. Go to next stage
if (msc_obj->event_count >= msc_obj->num_data_transfers + 1) {
msc_obj->next_stage = TEST_STAGE_DEV_CLOSE;
}
}
static void msc_client_event_cb(const usb_host_client_event_msg_t *event_msg, void *arg)
{
msc_client_obj_t *msc_obj = (msc_client_obj_t *)arg;
switch (event_msg->event) {
case USB_HOST_CLIENT_EVENT_NEW_DEV:
TEST_ASSERT_EQUAL(TEST_STAGE_WAIT_CONN, msc_obj->cur_stage);
msc_obj->next_stage = TEST_STAGE_DEV_OPEN;
msc_obj->dev_addr_to_open = event_msg->new_dev.address;
break;
case USB_HOST_CLIENT_EVENT_DEV_GONE:
msc_obj->event_count++;
//If all transfers dequeued and device gone event occurred. Go to next stage
if (msc_obj->event_count >= msc_obj->num_data_transfers + 1) {
msc_obj->next_stage = TEST_STAGE_DEV_CLOSE;
}
break;
default:
abort(); //Should never occur in this test
break;
}
}
void msc_client_async_dconn_task(void *arg)
{
msc_client_obj_t msc_obj;
memcpy(&msc_obj.test_param, arg, sizeof(msc_client_test_param_t));
msc_obj.cur_stage = TEST_STAGE_WAIT_CONN;
msc_obj.next_stage = TEST_STAGE_WAIT_CONN;
msc_obj.dev_addr_to_open = 0;
msc_obj.client_hdl = NULL;
msc_obj.dev_hdl = NULL;
msc_obj.num_data_transfers = msc_obj.test_param.num_sectors_per_xfer / MOCK_MSC_SCSI_SECTOR_SIZE;
msc_obj.event_count = 0;
//Register client
usb_host_client_config_t client_config = {
.is_synchronous = false,
.max_num_event_msg = MSC_ASYNC_CLIENT_MAX_EVENT_MSGS,
.async = {
.client_event_callback = msc_client_event_cb,
.callback_arg = (void *)&msc_obj,
},
};
TEST_ASSERT_EQUAL(ESP_OK, usb_host_client_register(&client_config, &msc_obj.client_hdl));
//Allocate transfers
usb_transfer_t *xfer_out; //Must be large enough to contain CBW and MSC reset control transfer
usb_transfer_t *xfer_in[msc_obj.num_data_transfers]; //We manually split the data stage into multiple transfers
size_t xfer_out_size = MAX(sizeof(mock_msc_bulk_cbw_t), sizeof(usb_setup_packet_t));
size_t xfer_in_size = MOCK_MSC_SCSI_SECTOR_SIZE;
TEST_ASSERT_EQUAL(ESP_OK, usb_host_transfer_alloc(xfer_out_size, 0, &xfer_out));
xfer_out->context = (void *)&msc_obj;
for (int i = 0; i < msc_obj.num_data_transfers; i++) {
TEST_ASSERT_EQUAL(ESP_OK, usb_host_transfer_alloc(xfer_in_size, 0, &xfer_in[i]));
xfer_in[i]->context = (void *)&msc_obj;
}
//Wait to be started by main thread
ulTaskNotifyTake(pdTRUE, portMAX_DELAY);
ESP_LOGD(MSC_CLIENT_TAG, "Starting");
bool exit_loop = false;
bool skip_event_handling = false;
int dconn_iter = 0;
while (!exit_loop) {
if (!skip_event_handling) {
TEST_ASSERT_EQUAL(ESP_OK, usb_host_client_handle_events(msc_obj.client_hdl, portMAX_DELAY));
}
skip_event_handling = false;
if (msc_obj.cur_stage == msc_obj.next_stage) {
continue;
}
msc_obj.cur_stage = msc_obj.next_stage;
switch (msc_obj.cur_stage) {
case TEST_STAGE_WAIT_CONN: {
//Nothing to do while waiting for connection
break;
}
case TEST_STAGE_DEV_OPEN: {
ESP_LOGD(MSC_CLIENT_TAG, "Open");
//Open the device
TEST_ASSERT_EQUAL(ESP_OK, usb_host_device_open(msc_obj.client_hdl, msc_obj.dev_addr_to_open, &msc_obj.dev_hdl));
//Target our transfers to the device
xfer_out->device_handle = msc_obj.dev_hdl;
xfer_out->callback = msc_reset_cbw_transfer_cb;
for (int i = 0; i < msc_obj.num_data_transfers; i++) {
xfer_in[i]->device_handle = msc_obj.dev_hdl;
xfer_in[i]->callback = msc_data_transfer_cb;
}
//Check the VID/PID of the opened device
const usb_device_desc_t *device_desc;
TEST_ASSERT_EQUAL(ESP_OK, usb_host_get_device_descriptor(msc_obj.dev_hdl, &device_desc));
TEST_ASSERT_EQUAL(msc_obj.test_param.idVendor, device_desc->idVendor);
TEST_ASSERT_EQUAL(msc_obj.test_param.idProduct, device_desc->idProduct);
//Claim the MSC interface
TEST_ASSERT_EQUAL(ESP_OK, usb_host_interface_claim(msc_obj.client_hdl, msc_obj.dev_hdl, MOCK_MSC_SCSI_INTF_NUMBER, MOCK_MSC_SCSI_INTF_ALT_SETTING));
msc_obj.next_stage = TEST_STAGE_MSC_RESET;
skip_event_handling = true; //Need to execute TEST_STAGE_MSC_RESET
break;
}
case TEST_STAGE_MSC_RESET: {
ESP_LOGD(MSC_CLIENT_TAG, "MSC Reset");
//Send an MSC SCSI interface reset
MOCK_MSC_SCSI_REQ_INIT_RESET((usb_setup_packet_t *)xfer_out->data_buffer, MOCK_MSC_SCSI_INTF_NUMBER);
xfer_out->num_bytes = sizeof(usb_setup_packet_t);
xfer_out->bEndpointAddress = 0;
TEST_ASSERT_EQUAL(ESP_OK, usb_host_transfer_submit_control(msc_obj.client_hdl, xfer_out));
//Next stage set from transfer callback
break;
}
case TEST_STAGE_MSC_CBW: {
ESP_LOGD(MSC_CLIENT_TAG, "CBW");
mock_msc_scsi_init_cbw((mock_msc_bulk_cbw_t *)xfer_out->data_buffer, true, 0, msc_obj.test_param.num_sectors_per_xfer, msc_obj.test_param.msc_scsi_xfer_tag);
xfer_out->num_bytes = sizeof(mock_msc_bulk_cbw_t);
xfer_out->bEndpointAddress = MOCK_MSC_SCSI_BULK_OUT_EP_ADDR;
TEST_ASSERT_EQUAL(ESP_OK, usb_host_transfer_submit(xfer_out));
//Next stage set from transfer callback
break;
}
case TEST_STAGE_MSC_DATA_DCONN: {
ESP_LOGD(MSC_CLIENT_TAG, "Data and disconnect");
//Setup the Data IN transfers
for (int i = 0; i < msc_obj.num_data_transfers; i++) {
xfer_in[i]->num_bytes = usb_round_up_to_mps(MOCK_MSC_SCSI_SECTOR_SIZE, MOCK_MSC_SCSI_BULK_EP_MPS);
xfer_in[i]->bEndpointAddress = MOCK_MSC_SCSI_BULK_IN_EP_ADDR;
}
//Submit those transfers
for (int i = 0; i < msc_obj.num_data_transfers; i++) {
TEST_ASSERT_EQUAL(ESP_OK, usb_host_transfer_submit(xfer_in[i]));
}
//Trigger a disconnect
test_usb_set_phy_state(false, 0);
//Next stage set from transfer callback
break;
}
case TEST_STAGE_DEV_CLOSE: {
ESP_LOGD(MSC_CLIENT_TAG, "Close");
TEST_ASSERT_EQUAL(ESP_OK, usb_host_interface_release(msc_obj.client_hdl, msc_obj.dev_hdl, MOCK_MSC_SCSI_INTF_NUMBER));
TEST_ASSERT_EQUAL(ESP_OK, usb_host_device_close(msc_obj.client_hdl, msc_obj.dev_hdl));
dconn_iter++;
if (dconn_iter < TEST_DCONN_ITERATIONS) {
//Start the next test iteration by going back to TEST_STAGE_WAIT_CONN and reenabling connections
msc_obj.next_stage = TEST_STAGE_WAIT_CONN;
skip_event_handling = true; //Need to execute TEST_STAGE_WAIT_CONN
test_usb_set_phy_state(true, 0);
} else {
exit_loop = true;
}
break;
}
default:
abort();
break;
}
}
//Free transfers
TEST_ASSERT_EQUAL(ESP_OK, usb_host_transfer_free(xfer_out));
for (int i = 0; i < msc_obj.num_data_transfers; i++) {
TEST_ASSERT_EQUAL(ESP_OK, usb_host_transfer_free(xfer_in[i]));
}
//Deregister the client
TEST_ASSERT_EQUAL(ESP_OK, usb_host_client_deregister(msc_obj.client_hdl));
ESP_LOGD(MSC_CLIENT_TAG, "Done");
vTaskDelete(NULL);
}