vsf_err_t vsf_malstream_read(struct vsf_malstream_t *malstream, uint64_t addr,
uint32_t size)
{
struct vsf_stream_t *stream = (struct vsf_stream_t *)malstream->mbufstream;
malstream->addr = addr;
malstream->size = size;
stream->callback_tx.param = malstream;
stream->callback_tx.on_inout = vsf_malstream_on_inout;
stream->callback_tx.on_connect = NULL;
stream->callback_tx.on_disconnect = NULL;
stream_connect_tx(stream);
malstream->pt.thread = vsf_malstream_read_thread;
malstream->pt.user_data = malstream;
return vsfsm_pt_init(&malstream->sm, &malstream->pt);
}
void vsfusbd_CDCData_connect(struct vsfusbd_CDC_param_t *param)
{
stream_connect_tx(param->stream_rx);
stream_connect_rx(param->stream_tx);
}
static vsf_err_t vsfip_telnetd_thread(struct vsfsm_pt_t *pt, vsfsm_evt_t evt)
{
struct vsfip_telnetd_t *telnetd = (struct vsfip_telnetd_t *)pt->user_data;
vsf_err_t err = VSFERR_NONE;
int i;
vsfsm_pt_begin(pt);
telnetd->caller_pt.sm = pt->sm;
telnetd->so = vsfip_socket(AF_INET, IPPROTO_TCP);
if (NULL == telnetd->so)
{
return VSFERR_FAIL;
}
if ((vsfip_bind(telnetd->so, telnetd->port) != 0) ||
(vsfip_listen(telnetd->so, telnetd->session_num) != 0))
{
err = VSFERR_FAIL;
goto fail_socket_connect;
}
while (1)
{
telnetd->caller_pt.state = 0;
vsfsm_pt_entry(pt);
err = vsfip_tcp_accept(&telnetd->caller_pt, evt, telnetd->so,
&telnetd->cur_session);
if (err > 0) return err; else if (err < 0)
{
continue;
}
// get session
for (i = 0; i < telnetd->session_num; i++)
{
if (!telnetd->sessions[i].connected)
{
struct vsfip_telnetd_session_t *session = &telnetd->sessions[i];
session->connected = true;
session->disconnect = false;
session->so = telnetd->cur_session;
session->stream_rx->callback_tx.param = session;
session->stream_rx->callback_tx.on_inout =
vsfip_telnetd_session_stream_on_out;
session->stream_tx->callback_rx.param = session;
session->stream_tx->callback_rx.on_inout =
vsfip_telnetd_session_stream_on_in;
stream_connect_tx(session->stream_rx);
stream_connect_rx(session->stream_tx);
vsfsm_sem_init(&session->stream_tx_sem, 0,
VSFIP_TELNETD_EVT_STREAM_IN);
vsfsm_sem_init(&session->stream_rx_sem, 0,
VSFIP_TELNETD_EVT_STREAM_OUT);
session->txpt.thread = vsfip_telnetd_session_tx_thread;
session->txpt.user_data = session;
session->rxpt.thread = vsfip_telnetd_session_rx_thread;
session->rxpt.user_data = session;
vsfsm_pt_init(&session->txsm, &session->txpt);
vsfsm_pt_init(&session->rxsm, &session->rxpt);
break;
}
}
if (i == telnetd->session_num)
{
telnetd->caller_pt.state = 0;
vsfsm_pt_entry(pt);
err = vsfip_tcp_close(&telnetd->caller_pt, evt,
telnetd->cur_session);
if (err > 0) return err;
vsfip_close(telnetd->cur_session);
}
}
fail_socket_connect:
vsfip_close(telnetd->so);
telnetd->so = NULL;
vsfsm_pt_end(pt);
return VSFERR_NONE;
}
static struct vsfsm_state_t *
vsfusbd_HID_evt_handler(struct vsfsm_t *sm, vsfsm_evt_t evt)
{
struct vsfusbd_HID_param_t *param =
(struct vsfusbd_HID_param_t *)sm->user_data;
struct vsfusbd_device_t *device = param->device;
uint8_t i;
switch (evt)
{
case VSFSM_EVT_INIT:
if (param->ep_out != 0)
{
vsfusbd_set_OUT_handler(device, param->ep_out,
vsfusbd_HID_OUT_hanlder);
device->drv->ep.enable_OUT(param->ep_out);
}
param->bufstream.mem.read = true;
param->bufstream.stream.op = &bufstream_op;
param->bufstream.stream.callback_tx.on_connect = NULL;
param->bufstream.stream.callback_tx.on_disconnect = NULL;
param->bufstream.stream.callback_tx.on_inout = NULL;
param->output_state = HID_OUTPUT_STATE_WAIT;
param->busy = false;
for(i = 0; i < param->num_of_report; i++)
{
struct vsfusbd_HID_report_t *report = ¶m->reports[i];
report->pos = 0;
report->idle_cnt = 0;
report->changed = true;
}
// enable timer
param->timer4ms.sm = sm;
param->timer4ms.evt = VSFUSBD_HID_EVT_TIMER4MS;
param->timer4ms.interval = 4;
param->timer4ms.trigger_cnt = -1;
vsftimer_enqueue(¶m->timer4ms);
break;
case VSFUSBD_HID_EVT_TIMER4MS:
{
struct vsfusbd_HID_report_t *report;
uint8_t i;
for (i = 0; i < param->num_of_report; i++)
{
report = ¶m->reports[i];
if ((report->type == USB_HID_REPORT_INPUT) &&
(report->idle != 0))
{
report->idle_cnt++;
}
}
if (param->busy)
{
break;
}
}
// fall through
case VSFUSBD_HID_EVT_INREPORT:
{
struct vsfusbd_transact_t *transact = ¶m->IN_transact;
struct vsfusbd_HID_report_t *report;
uint8_t i;
for (i = 0; i < param->num_of_report; i++)
{
report = ¶m->reports[i];
if ((report->type == USB_HID_REPORT_INPUT) &&
(report->changed || ((report->idle != 0) &&
(report->idle_cnt >= report->idle))))
{
param->bufstream.mem.buffer = report->buffer;
stream_init(¶m->stream);
stream_connect_tx(¶m->stream);
transact->ep = param->ep_in;
transact->data_size = report->buffer.size;
transact->stream = ¶m->stream;
transact->zlp = false;
transact->cb.on_finish = vsfusbd_HID_INREPORT_callback;
transact->cb.param = param;
vsfusbd_ep_send(device, transact);
report->changed = false;
report->idle_cnt = 0;
param->busy = true;
break;
}
}
}
break;
}
return NULL;
}
static struct vsfsm_state_t *
vsfshell_evt_handler(struct vsfsm_t *sm, vsfsm_evt_t evt)
{
struct vsfshell_t *shell = (struct vsfshell_t *)sm->user_data;
switch (evt)
{
case VSFSM_EVT_INIT:
shell->prompted = false;
shell->output_interrupted = false;
shell->tbuffer.buffer.buffer = (uint8_t *)shell->cmd_buff;
shell->tbuffer.buffer.size = sizeof(shell->cmd_buff);
shell->tbuffer.position = 0;
vsfsm_crit_init(&shell->output_crit, VSFSHELL_EVT_OUTPUT_CRIT_AVAIL);
shell->stream_rx->callback_rx.param = shell;
shell->stream_rx->callback_rx.on_inout = vsfshell_streamrx_on_in;
shell->stream_rx->callback_rx.on_connect = vsfshell_streamrx_on_txconn;
shell->stream_tx->callback_tx.param = shell;
shell->stream_tx->callback_tx.on_inout = vsfshell_streamtx_on_out;
shell->stream_tx->callback_tx.on_connect = vsfshell_streamtx_on_rxconn;
// shell->output_pt is only called by shell->input_pt
shell->output_pt.thread = (vsfsm_pt_thread_t)vsfshell_output_thread;
shell->output_pt.sm = sm;
shell->output_pt.user_data = shell;
// shell->input_pt is used to hanlde the events from stream_rx
shell->input_pt.thread = vsfshell_input_thread;
shell->input_pt.sm = sm;
shell->input_pt.user_data = shell;
shell->input_pt.state = 0;
shell->input_pt.thread(&shell->input_pt, VSFSM_EVT_INIT);
// default input sm is shell itself
shell->input_sm = &shell->sm;
stream_connect_rx(shell->stream_rx);
stream_connect_tx(shell->stream_tx);
break;
case VSFSHELL_EVT_STREAMRX_ONCONN:
break;
case VSFSHELL_EVT_STREAMTX_ONCONN:
// pass to shell->input_pt
shell->input_pt.thread(&shell->input_pt, evt);
break;
case VSFSHELL_EVT_STREAMRX_ONIN:
if (shell->input_sm == &shell->sm)
{
// pass to shell->input_pt
shell->input_pt.thread(&shell->input_pt, evt);
}
else if (shell->input_sm != NULL)
{
vsfsm_post_evt(shell->input_sm, evt);
}
break;
case VSFSHELL_EVT_STREAMTX_ONOUT:
if (shell->output_sm == &shell->sm)
{
// pass to shell->input_pt
shell->input_pt.thread(&shell->input_pt, evt);
}
else if (shell->output_sm != NULL)
{
vsfsm_post_evt(shell->output_sm, evt);
}
break;
}
return NULL;
}
static vsf_err_t vsf_mal2scsi_execute(struct vsfscsi_lun_t *lun, uint8_t *CDB,
uint8_t CDB_size, uint32_t size)
{
struct vsf_mal2scsi_t *mal2scsi = (struct vsf_mal2scsi_t *)lun->param;
struct vsfscsi_transact_t *transact = &lun->dev->transact;
struct vsfmal_t *mal = mal2scsi->malstream.mal;
uint8_t group_code = CDB[0] & 0xE0, cmd_code = CDB[0] & 0x1F;
uint8_t *pbuf;
if (transact->lun != NULL)
{
return VSFERR_FAIL;
}
// check user_handler first
if (mal2scsi->vendor_handlers != NULL)
{
struct vsfscsi_handler_t *handler =
vsfscsi_get_handler(mal2scsi->vendor_handlers, CDB[0]);
if (handler != NULL)
{
return handler->handler(lun, CDB);
}
}
if (!mal2scsi->malstream.mal_ready || (transact->lun != NULL))
{
goto exit_not_ready;
}
switch (group_code)
{
case SCSI_GROUPCODE6:
switch (cmd_code)
{
case SCSI_CMDCODE_MODE_SELECT:
case SCSI_CMDCODE_TEST_UNIT_READY:
case SCSI_CMDCODE_VERIFY:
case SCSI_CMDCODE_FORMAT_UNIT:
case SCSI_CMDCODE_START_STOP_UNIT:
case SCSI_CMDCODE_ALLOW_MEDIUM_REMOVAL:
break;
case SCSI_CMDCODE_REQUEST_SENSE:
pbuf = vsf_mal2scsi_prepare_transact(lun, 18, false, true);
if (NULL == pbuf)
{
goto exit_not_ready;
}
pbuf[0] = 0x70;
pbuf[2] = lun->sensekey;
pbuf[7] = 0x0A;
pbuf[12] = lun->asc;
transact->data_size = min(CDB[4], 18);
break;
case SCSI_CMDCODE_READ:
transact->LBA = GET_BE_U16(&CDB[2]);
transact->data_size = CDB[4];
goto do_mal_read;
break;
case SCSI_CMDCODE_WRITE:
transact->LBA = GET_BE_U16(&CDB[2]);
transact->data_size = CDB[4];
goto do_mal_write;
break;
case SCSI_CMDCODE_INQUIRY:
if (CDB[1] & 1)
{
// When the EVPD bit is set to one,
// the PAGE CODE field specifies which page of
// vital product data information the device server shall return
if (CDB[2] != 0)
{
goto exit_invalid_field_in_command;
}
// 0x00: Supported VPD Pages
pbuf = vsf_mal2scsi_prepare_transact(lun, 5, false, true);
if (NULL == pbuf)
{
goto exit_not_ready;
}
}
else
{
struct vsf_mal2scsi_cparam_t *cparam =
(struct vsf_mal2scsi_cparam_t *)&mal2scsi->cparam;
if (CDB[2] != 0)
{
// If the PAGE CODE field is not set to zero
// when the EVPD bit is set to zero,
// the command shall be terminated with CHECK CONDITION status,
// with the sense key set to ILLEGAL REQUEST,
// and the additional sense code set to INVALID FIELD IN CDB.
goto exit_invalid_field_in_command;
}
// If the EVPD bit is set to zero,
// the device server shall return the standard INQUIRY data.
pbuf = vsf_mal2scsi_prepare_transact(lun, 36, false, true);
if (NULL == pbuf)
{
goto exit_not_ready;
}
pbuf[0] = cparam->type;
if (cparam->removable)
{
pbuf[1] = 0x80;
}
pbuf[3] = 2;
pbuf[4] = 31;
pbuf += 8;
memcpy(pbuf, cparam->vendor, sizeof(cparam->vendor));
pbuf += sizeof(cparam->vendor);
memcpy(pbuf, cparam->product, sizeof(cparam->product));
pbuf += sizeof(cparam->product);
memcpy(pbuf, cparam->revision, sizeof(cparam->revision));
}
break;
case SCSI_CMDCODE_MODE_SENSE:
pbuf = vsf_mal2scsi_prepare_transact(lun, 4, false, true);
if (NULL == pbuf)
{
goto exit_not_ready;
}
pbuf[0] = 3;
break;
default:
goto exit_invalid_command;
}
break;
case SCSI_GROUPCODE10_1:
switch (cmd_code)
{
case SCSI_CMDCODE_READ_FORMAT_CAPACITIES:
pbuf = vsf_mal2scsi_prepare_transact(lun, 12, false, true);
if (NULL == pbuf)
{
goto exit_not_ready;
}
pbuf[3] = 8;
SET_BE_U32(&pbuf[4], mal->cap.block_num);
SET_BE_U32(&pbuf[8], mal->cap.block_size);
pbuf[8] = 2;
break;
case SCSI_CMDCODE_READ_CAPACITY:
pbuf = vsf_mal2scsi_prepare_transact(lun, 8, false, true);
if (NULL == pbuf)
{
goto exit_not_ready;
}
SET_BE_U32(&pbuf[0], mal->cap.block_num - 1);
SET_BE_U32(&pbuf[4], mal->cap.block_size);
break;
case SCSI_CMDCODE_READ:
transact->LBA = GET_BE_U32(&CDB[2]);
transact->data_size = GET_BE_U16(&CDB[7]);
goto do_mal_read;
break;
case SCSI_CMDCODE_WRITE:
transact->LBA = GET_BE_U32(&CDB[2]);
transact->data_size = GET_BE_U16(&CDB[7]);
goto do_mal_write;
break;
default:
goto exit_invalid_command;
}
break;
case SCSI_GROUPCODE10_2:
switch (cmd_code)
{
case SCSI_CMDCODE_MODE_SELECT:
break;
case SCSI_CMDCODE_MODE_SENSE:
break;
default:
goto exit_invalid_command;
}
break;
case SCSI_GROUPCODE16:
switch (cmd_code)
{
case SCSI_CMDCODE_READ:
transact->LBA = GET_BE_U64(&CDB[2]);
transact->data_size = GET_BE_U32(&CDB[10]);
do_mal_read:
transact->LBA *= mal->cap.block_size;
transact->data_size *= mal->cap.block_size;
pbuf = vsf_mal2scsi_prepare_transact(lun, transact->data_size,
false, false);
if (NULL == pbuf)
{
goto exit_not_ready;
}
vsf_malstream_read(&mal2scsi->malstream, transact->LBA,
transact->data_size);
break;
case SCSI_CMDCODE_WRITE:
transact->LBA = GET_BE_U64(&CDB[2]);
transact->data_size = GET_BE_U32(&CDB[10]);
do_mal_write:
transact->LBA *= mal->cap.block_size;
transact->data_size *= mal->cap.block_size;
pbuf = vsf_mal2scsi_prepare_transact(lun, transact->data_size,
true, false);
if (NULL == pbuf)
{
goto exit_not_ready;
}
vsf_malstream_write(&mal2scsi->malstream, transact->LBA,
transact->data_size);
break;
default:
goto exit_invalid_command;
}
break;
case SCSI_GROUPCODE12:
switch (cmd_code)
{
case SCSI_CMDCODE_READ:
transact->LBA = GET_BE_U32(&CDB[2]);
transact->data_size = GET_BE_U32(&CDB[6]);
goto do_mal_read;
break;
case SCSI_CMDCODE_WRITE:
transact->LBA = GET_BE_U32(&CDB[2]);
transact->data_size = GET_BE_U32(&CDB[6]);
goto do_mal_write;
break;
default:
goto exit_invalid_command;
}
break;
default:
goto exit_invalid_command;
}
lun->sensekey = SCSI_SENSEKEY_NO_SENSE;
lun->asc = SCSI_ASC_NONE;
if (transact->lun->stream != NULL)
{
if (transact->lun->stream->op == &bufstream_op)
{
stream_connect_tx(transact->lun->stream);
}
}
return VSFERR_NONE;
exit_invalid_command:
lun->sensekey = SCSI_SENSEKEY_ILLEGAL_REQUEST;
lun->asc = SCSI_ASC_INVALID_COMMAND;
return VSFERR_FAIL;
exit_invalid_field_in_command:
lun->sensekey = SCSI_SENSEKEY_ILLEGAL_REQUEST;
lun->asc = SCSI_ASC_INVALID_FIELD_IN_COMMAND;
return VSFERR_FAIL;
exit_not_ready:
lun->sensekey = SCSI_SENSEKEY_NOT_READY;
lun->asc = SCSI_ASC_NONE;
return VSFERR_FAIL;
}
