andrey
/
Marlin_FB4S
1
0
Fork 0
Code Issues Pull Requests Projects Releases Wiki Activity
Marlin 2.0 for Flying Bear 4S/5
You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
15148 Commits
4 Branches
6 Tags
134 MiB
 
 
 
 
 
 
Tree: d1e20eb29f
Branches Tags
${ item.name }
Create tag ${ searchTerm }
Create branch ${ searchTerm }
from 'd1e20eb29f'
${ noResults }
Marlin_FB4S/Marlin/src/HAL/DUE/usb/udi_msc.c

1132 lines
29 KiB
Raw Blame History

/**
* \file
*
* \brief USB Device Mass Storage Class (MSC) interface.
*
* Copyright (c) 2009-2015 Atmel Corporation. All rights reserved.
*
* \asf_license_start
*
* \page License
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an
* Atmel microcontroller product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
* STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
* \asf_license_stop
*
*/
/*
* Support and FAQ: visit <a href="https://www.atmel.com/design-support/">Atmel Support</a>
*/
#ifdef ARDUINO_ARCH_SAM
#include "conf_usb.h"
#include "usb_protocol.h"
#include "usb_protocol_msc.h"
#include "spc_protocol.h"
#include "sbc_protocol.h"
#include "udd.h"
#include "udc.h"
#include "udi_msc.h"
#include "ctrl_access.h"
#include <string.h>
#if ENABLED(SDSUPPORT)
#ifndef UDI_MSC_NOTIFY_TRANS_EXT
# define UDI_MSC_NOTIFY_TRANS_EXT()
#endif
/**
* \ingroup udi_msc_group
* \defgroup udi_msc_group_udc Interface with USB Device Core (UDC)
*
* Structures and functions required by UDC.
*
* @{
*/
bool udi_msc_enable(void);
void udi_msc_disable(void);
bool udi_msc_setup(void);
uint8_t udi_msc_getsetting(void);
//! Global structure which contains standard UDI API for UDC
UDC_DESC_STORAGE udi_api_t udi_api_msc = {
.enable = udi_msc_enable,
.disable = udi_msc_disable,
.setup = udi_msc_setup,
.getsetting = udi_msc_getsetting,
.sof_notify = NULL,
};
//@}
/**
* \ingroup udi_msc_group
* \defgroup udi_msc_group_internal Implementation of UDI MSC
*
* Class internal implementation
* @{
*/
//! Static block size for all memories
#define UDI_MSC_BLOCK_SIZE 512L
/**
* \name Variables to manage SCSI requests
*/
//@{
//! Structure to receive a CBW packet
UDC_BSS(4) static struct usb_msc_cbw udi_msc_cbw;
//! Structure to send a CSW packet
UDC_DATA(4) static struct usb_msc_csw udi_msc_csw =
{.dCSWSignature = CPU_TO_BE32(USB_CSW_SIGNATURE) };
//! Number of lun
UDC_DATA(4) static uint8_t udi_msc_nb_lun = 0;
//! Structure with current SCSI sense data
UDC_BSS(4) static struct scsi_request_sense_data udi_msc_sense;
/**
* \name Variables to manage the background read/write SCSI commands
*/
//@{
//! True if an invalid CBW command has been detected
static bool udi_msc_b_cbw_invalid = false;
//! True if a transfer command must be processed
static bool udi_msc_b_trans_req = false;
//! True if it is a read command, else write command
static bool udi_msc_b_read;
//! Memory address to execute the command
static uint32_t udi_msc_addr;
//! Number of block to transfer
static uint16_t udi_msc_nb_block;
//! Signal end of transfer, if true
volatile bool udi_msc_b_ack_trans = true;
//! Status of transfer, aborted if true
volatile bool udi_msc_b_abort_trans;
//! Signal (re)init of transfer, if true (by reset/reconnect)
volatile bool udi_msc_b_reset_trans = true;
//@}
//@}
/**
* \name Internal routines
*/
//@{
/**
* \name Routines to process CBW packet
*/
//@{
/**
* \brief Stall CBW request
*/
static void udi_msc_cbw_invalid(void);
/**
* \brief Stall CSW request
*/
static void udi_msc_csw_invalid(void);
/**
* \brief Links a callback and buffer on endpoint OUT reception
*
* Called by:
* - enable interface
* - at the end of previous command after sending the CSW
*/
static void udi_msc_cbw_wait(void);
/**
* \brief Callback called after CBW reception
* Called by UDD when a transfer is finished or aborted
*
* \param status UDD_EP_TRANSFER_OK, if transfer is finished
* \param status UDD_EP_TRANSFER_ABORT, if transfer is aborted
* \param nb_received number of data transfered
*/
static void udi_msc_cbw_received(udd_ep_status_t status,
iram_size_t nb_received, udd_ep_id_t ep);
/**
* \brief Function to check the CBW length and direction
* Call it after SCSI command decode to check integrity of command
*
* \param alloc_len number of bytes that device want transfer
* \param dir_flag Direction of transfer (USB_CBW_DIRECTION_IN/OUT)
*
* \retval true if the command can be processed
*/
static bool udi_msc_cbw_validate(uint32_t alloc_len, uint8_t dir_flag);
//@}
/**
* \name Routines to process small data packet
*/
//@{
/**
* \brief Sends data on MSC IN endpoint
* Called by SCSI command which must send a data to host followed by a CSW
*
* \param buffer Internal RAM buffer to send
* \param buf_size Size of buffer to send
*/
static void udi_msc_data_send(uint8_t * buffer, uint8_t buf_size);
/**
* \brief Callback called after data sent
* It start CSW packet process
*
* \param status UDD_EP_TRANSFER_OK, if transfer finish
* \param status UDD_EP_TRANSFER_ABORT, if transfer aborted
* \param nb_sent number of data transfered
*/
static void udi_msc_data_sent(udd_ep_status_t status, iram_size_t nb_sent,
udd_ep_id_t ep);
//@}
/**
* \name Routines to process CSW packet
*/
//@{
/**
* \brief Build CSW packet and send it
*
* Called at the end of SCSI command
*/
static void udi_msc_csw_process(void);
/**
* \brief Sends CSW
*
* Called by #udi_msc_csw_process()
* or UDD callback when endpoint halt is cleared
*/
void udi_msc_csw_send(void);
/**
* \brief Callback called after CSW sent
* It restart CBW reception.
*
* \param status UDD_EP_TRANSFER_OK, if transfer is finished
* \param status UDD_EP_TRANSFER_ABORT, if transfer is aborted
* \param nb_sent number of data transfered
*/
static void udi_msc_csw_sent(udd_ep_status_t status, iram_size_t nb_sent,
udd_ep_id_t ep);
//@}
/**
* \name Routines manage sense data
*/
//@{
/**
* \brief Reinitialize sense data.
*/
static void udi_msc_clear_sense(void);
/**
* \brief Update sense data with new value to signal a fail
*
* \param sense_key Sense key
* \param add_sense Additional Sense Code
* \param lba LBA corresponding at error
*/
static void udi_msc_sense_fail(uint8_t sense_key, uint16_t add_sense,
uint32_t lba);
/**
* \brief Update sense data with new value to signal success
*/
static void udi_msc_sense_pass(void);
/**
* \brief Update sense data to signal that memory is not present
*/
static void udi_msc_sense_fail_not_present(void);
/**
* \brief Update sense data to signal that memory is busy
*/
static void udi_msc_sense_fail_busy_or_change(void);
/**
* \brief Update sense data to signal a hardware error on memory
*/
static void udi_msc_sense_fail_hardware(void);
/**
* \brief Update sense data to signal that memory is protected
*/
static void udi_msc_sense_fail_protected(void);
/**
* \brief Update sense data to signal that CDB fields are not valid
*/
static void udi_msc_sense_fail_cdb_invalid(void);
/**
* \brief Update sense data to signal that command is not supported
*/
static void udi_msc_sense_command_invalid(void);
//@}
/**
* \name Routines manage SCSI Commands
*/
//@{
/**
* \brief Process SPC Request Sense command
* Returns error information about last command
*/
static void udi_msc_spc_requestsense(void);
/**
* \brief Process SPC Inquiry command
* Returns information (name,version) about disk
*/
static void udi_msc_spc_inquiry(void);
/**
* \brief Checks state of disk
*
* \retval true if disk is ready, otherwise false and updates sense data
*/
static bool udi_msc_spc_testunitready_global(void);
/**
* \brief Process test unit ready command
* Returns state of logical unit
*/
static void udi_msc_spc_testunitready(void);
/**
* \brief Process prevent allow medium removal command
*/
static void udi_msc_spc_prevent_allow_medium_removal(void);
/**
* \brief Process mode sense command
*
* \param b_sense10 Sense10 SCSI command, if true
* \param b_sense10 Sense6 SCSI command, if false
*/
static void udi_msc_spc_mode_sense(bool b_sense10);
/**
* \brief Process start stop command
*/
static void udi_msc_sbc_start_stop(void);
/**
* \brief Process read capacity command
*/
static void udi_msc_sbc_read_capacity(void);
/**
* \brief Process read10 or write10 command
*
* \param b_read Read transfer, if true,
* \param b_read Write transfer, if false
*/
static void udi_msc_sbc_trans(bool b_read);
//@}
//@}
bool udi_msc_enable(void)
{
uint8_t lun;
udi_msc_b_trans_req = false;
udi_msc_b_cbw_invalid = false;
udi_msc_b_ack_trans = true;
udi_msc_b_reset_trans = true;
udi_msc_nb_lun = get_nb_lun();
if (0 == udi_msc_nb_lun)
return false; // No lun available, then not authorize to enable interface
udi_msc_nb_lun--;
// Call application callback
// to initialize memories or signal that interface is enabled
if (!UDI_MSC_ENABLE_EXT())
return false;
// Load the medium on each LUN
for (lun = 0; lun <= udi_msc_nb_lun; lun ++) {
mem_unload(lun, false);
}
// Start MSC process by CBW reception
udi_msc_cbw_wait();
return true;
}
void udi_msc_disable(void)
{
udi_msc_b_trans_req = false;
udi_msc_b_ack_trans = true;
udi_msc_b_reset_trans = true;
UDI_MSC_DISABLE_EXT();
}
bool udi_msc_setup(void)
{
if (Udd_setup_is_in()) {
// Requests Interface GET
if (Udd_setup_type() == USB_REQ_TYPE_CLASS) {
// Requests Class Interface Get
switch (udd_g_ctrlreq.req.bRequest) {
case USB_REQ_MSC_GET_MAX_LUN:
// Give the number of memories available
if (1 != udd_g_ctrlreq.req.wLength)
return false; // Error for USB host
if (0 != udd_g_ctrlreq.req.wValue)
return false;
udd_g_ctrlreq.payload = &udi_msc_nb_lun;
udd_g_ctrlreq.payload_size = 1;
return true;
}
}
}
if (Udd_setup_is_out()) {
// Requests Interface SET
if (Udd_setup_type() == USB_REQ_TYPE_CLASS) {
// Requests Class Interface Set
switch (udd_g_ctrlreq.req.bRequest) {
case USB_REQ_MSC_BULK_RESET:
// Reset MSC interface
if (0 != udd_g_ctrlreq.req.wLength)
return false;
if (0 != udd_g_ctrlreq.req.wValue)
return false;
udi_msc_b_cbw_invalid = false;
udi_msc_b_trans_req = false;
// Abort all tasks (transfer or clear stall wait) on endpoints
udd_ep_abort(UDI_MSC_EP_OUT);
udd_ep_abort(UDI_MSC_EP_IN);
// Restart by CBW wait
udi_msc_cbw_wait();
return true;
}
}
}
return false; // Not supported request
}
uint8_t udi_msc_getsetting(void)
{
return 0; // MSC don't have multiple alternate setting
}
// ------------------------
//------- Routines to process CBW packet
static void udi_msc_cbw_invalid(void)
{
if (!udi_msc_b_cbw_invalid)
return; // Don't re-stall endpoint if error reseted by setup
udd_ep_set_halt(UDI_MSC_EP_OUT);
// If stall cleared then re-stall it. Only Setup MSC Reset can clear it
udd_ep_wait_stall_clear(UDI_MSC_EP_OUT, udi_msc_cbw_invalid);
}
static void udi_msc_csw_invalid(void)
{
if (!udi_msc_b_cbw_invalid)
return; // Don't re-stall endpoint if error reseted by setup
udd_ep_set_halt(UDI_MSC_EP_IN);
// If stall cleared then re-stall it. Only Setup MSC Reset can clear it
udd_ep_wait_stall_clear(UDI_MSC_EP_IN, udi_msc_csw_invalid);
}
static void udi_msc_cbw_wait(void)
{
// Register buffer and callback on OUT endpoint
if (!udd_ep_run(UDI_MSC_EP_OUT, true,
(uint8_t *) & udi_msc_cbw,
sizeof(udi_msc_cbw),
udi_msc_cbw_received)) {
// OUT endpoint not available (halted), then wait a clear of halt.
udd_ep_wait_stall_clear(UDI_MSC_EP_OUT, udi_msc_cbw_wait);
}
}
static void udi_msc_cbw_received(udd_ep_status_t status,
iram_size_t nb_received, udd_ep_id_t ep)
{
UNUSED(ep);
// Check status of transfer
if (UDD_EP_TRANSFER_OK != status) {
// Transfer aborted
// Now wait MSC setup reset to relaunch CBW reception
return;
}
// Check CBW integrity:
// transfer status/CBW length/CBW signature
if ((sizeof(udi_msc_cbw) != nb_received)
|| (udi_msc_cbw.dCBWSignature !=
CPU_TO_BE32(USB_CBW_SIGNATURE))) {
// (5.2.1) Devices receiving a CBW with an invalid signature should stall
// further traffic on the Bulk In pipe, and either stall further traffic
// or accept and discard further traffic on the Bulk Out pipe, until
// reset recovery.
udi_msc_b_cbw_invalid = true;
udi_msc_cbw_invalid();
udi_msc_csw_invalid();
return;
}
// Check LUN asked
udi_msc_cbw.bCBWLUN &= USB_CBW_LUN_MASK;
if (udi_msc_cbw.bCBWLUN > udi_msc_nb_lun) {
// Bad LUN, then stop command process
udi_msc_sense_fail_cdb_invalid();
udi_msc_csw_process();
return;
}
// Prepare CSW residue field with the size requested
udi_msc_csw.dCSWDataResidue =
le32_to_cpu(udi_msc_cbw.dCBWDataTransferLength);
// Decode opcode
switch (udi_msc_cbw.CDB[0]) {
case SPC_REQUEST_SENSE:
udi_msc_spc_requestsense();
break;
case SPC_INQUIRY:
udi_msc_spc_inquiry();
break;
case SPC_MODE_SENSE6:
udi_msc_spc_mode_sense(false);
break;
case SPC_MODE_SENSE10:
udi_msc_spc_mode_sense(true);
break;
case SPC_TEST_UNIT_READY:
udi_msc_spc_testunitready();
break;
case SBC_READ_CAPACITY10:
udi_msc_sbc_read_capacity();
break;
case SBC_START_STOP_UNIT:
udi_msc_sbc_start_stop();
break;
// Accepts request to support plug/plug in case of card reader
case SPC_PREVENT_ALLOW_MEDIUM_REMOVAL:
udi_msc_spc_prevent_allow_medium_removal();
break;
// Accepts request to support full format from Windows
case SBC_VERIFY10:
udi_msc_sense_pass();
udi_msc_csw_process();
break;
case SBC_READ10:
udi_msc_sbc_trans(true);
break;
case SBC_WRITE10:
udi_msc_sbc_trans(false);
break;
default:
udi_msc_sense_command_invalid();
udi_msc_csw_process();
break;
}
}
static bool udi_msc_cbw_validate(uint32_t alloc_len, uint8_t dir_flag)
{
/*
* The following cases should result in a phase error:
* - Case 2: Hn < Di
* - Case 3: Hn < Do
* - Case 7: Hi < Di
* - Case 8: Hi <> Do
* - Case 10: Ho <> Di
* - Case 13: Ho < Do
*/
if (((udi_msc_cbw.bmCBWFlags ^ dir_flag) & USB_CBW_DIRECTION_IN)
|| (udi_msc_csw.dCSWDataResidue < alloc_len)) {
udi_msc_sense_fail_cdb_invalid();
udi_msc_csw_process();
return false;
}
/*
* The following cases should result in a stall and nonzero
* residue:
* - Case 4: Hi > Dn
* - Case 5: Hi > Di
* - Case 9: Ho > Dn
* - Case 11: Ho > Do
*/
return true;
}
// ------------------------
//------- Routines to process small data packet
static void udi_msc_data_send(uint8_t * buffer, uint8_t buf_size)
{
// Sends data on IN endpoint
if (!udd_ep_run(UDI_MSC_EP_IN, true,
buffer, buf_size, udi_msc_data_sent)) {
// If endpoint not available, then exit process command
udi_msc_sense_fail_hardware();
udi_msc_csw_process();
}
}
static void udi_msc_data_sent(udd_ep_status_t status, iram_size_t nb_sent,
udd_ep_id_t ep)
{
UNUSED(ep);
if (UDD_EP_TRANSFER_OK != status) {
// Error protocol
// Now wait MSC setup reset to relaunch CBW reception
return;
}
// Update sense data
udi_msc_sense_pass();
// Update CSW
udi_msc_csw.dCSWDataResidue -= nb_sent;
udi_msc_csw_process();
}
// ------------------------
//------- Routines to process CSW packet
static void udi_msc_csw_process(void)
{
if (0 != udi_msc_csw.dCSWDataResidue) {
// Residue not NULL
// then STALL next request from USB host on corresponding endpoint
if (udi_msc_cbw.bmCBWFlags & USB_CBW_DIRECTION_IN)
udd_ep_set_halt(UDI_MSC_EP_IN);
else
udd_ep_set_halt(UDI_MSC_EP_OUT);
}
// Prepare and send CSW
udi_msc_csw.dCSWTag = udi_msc_cbw.dCBWTag;
udi_msc_csw.dCSWDataResidue = cpu_to_le32(udi_msc_csw.dCSWDataResidue);
udi_msc_csw_send();
}
void udi_msc_csw_send(void)
{
// Sends CSW on IN endpoint
if (!udd_ep_run(UDI_MSC_EP_IN, false,
(uint8_t *) & udi_msc_csw,
sizeof(udi_msc_csw),
udi_msc_csw_sent)) {
// Endpoint not available
// then restart CSW sent when endpoint IN STALL will be cleared
udd_ep_wait_stall_clear(UDI_MSC_EP_IN, udi_msc_csw_send);
}
}
static void udi_msc_csw_sent(udd_ep_status_t status, iram_size_t nb_sent,
udd_ep_id_t ep)
{
UNUSED(ep);
UNUSED(status);
UNUSED(nb_sent);
// CSW is sent or not
// In all case, restart process and wait CBW
udi_msc_cbw_wait();
}
// ------------------------
//------- Routines manage sense data
static void udi_msc_clear_sense(void)
{
memset((uint8_t*)&udi_msc_sense, 0, sizeof(struct scsi_request_sense_data));
udi_msc_sense.valid_reponse_code = SCSI_SENSE_VALID | SCSI_SENSE_CURRENT;
udi_msc_sense.AddSenseLen = SCSI_SENSE_ADDL_LEN(sizeof(udi_msc_sense));
}
static void udi_msc_sense_fail(uint8_t sense_key, uint16_t add_sense,
uint32_t lba)
{
udi_msc_clear_sense();
udi_msc_csw.bCSWStatus = USB_CSW_STATUS_FAIL;
udi_msc_sense.sense_flag_key = sense_key;
udi_msc_sense.information[0] = lba >> 24;
udi_msc_sense.information[1] = lba >> 16;
udi_msc_sense.information[2] = lba >> 8;
udi_msc_sense.information[3] = lba;
udi_msc_sense.AddSenseCode = add_sense >> 8;
udi_msc_sense.AddSnsCodeQlfr = add_sense;
}
static void udi_msc_sense_pass(void)
{
udi_msc_clear_sense();
udi_msc_csw.bCSWStatus = USB_CSW_STATUS_PASS;
}
static void udi_msc_sense_fail_not_present(void)
{
udi_msc_sense_fail(SCSI_SK_NOT_READY, SCSI_ASC_MEDIUM_NOT_PRESENT, 0);
}
static void udi_msc_sense_fail_busy_or_change(void)
{
udi_msc_sense_fail(SCSI_SK_UNIT_ATTENTION,
SCSI_ASC_NOT_READY_TO_READY_CHANGE, 0);
}
static void udi_msc_sense_fail_hardware(void)
{
udi_msc_sense_fail(SCSI_SK_HARDWARE_ERROR,
SCSI_ASC_NO_ADDITIONAL_SENSE_INFO, 0);
}
static void udi_msc_sense_fail_protected(void)
{
udi_msc_sense_fail(SCSI_SK_DATA_PROTECT, SCSI_ASC_WRITE_PROTECTED, 0);
}
static void udi_msc_sense_fail_cdb_invalid(void)
{
udi_msc_sense_fail(SCSI_SK_ILLEGAL_REQUEST,
SCSI_ASC_INVALID_FIELD_IN_CDB, 0);
}
static void udi_msc_sense_command_invalid(void)
{
udi_msc_sense_fail(SCSI_SK_ILLEGAL_REQUEST,
SCSI_ASC_INVALID_COMMAND_OPERATION_CODE, 0);
}
// ------------------------
//------- Routines manage SCSI Commands
static void udi_msc_spc_requestsense(void)
{
uint8_t length = udi_msc_cbw.CDB[4];
// Can't send more than sense data length
if (length > sizeof(udi_msc_sense))
length = sizeof(udi_msc_sense);
if (!udi_msc_cbw_validate(length, USB_CBW_DIRECTION_IN))
return;
// Send sense data
udi_msc_data_send((uint8_t*)&udi_msc_sense, length);
}
static void udi_msc_spc_inquiry(void)
{
uint8_t length, i;
UDC_DATA(4)
// Constant inquiry data for all LUNs
static struct scsi_inquiry_data udi_msc_inquiry_data = {
.pq_pdt = SCSI_INQ_PQ_CONNECTED | SCSI_INQ_DT_DIR_ACCESS,
.version = SCSI_INQ_VER_SPC,
.flags3 = SCSI_INQ_RSP_SPC2,
.addl_len = SCSI_INQ_ADDL_LEN(sizeof(struct scsi_inquiry_data)),
.vendor_id = {UDI_MSC_GLOBAL_VENDOR_ID},
.product_rev = {UDI_MSC_GLOBAL_PRODUCT_VERSION},
};
length = udi_msc_cbw.CDB[4];
// Can't send more than inquiry data length
if (length > sizeof(udi_msc_inquiry_data))
length = sizeof(udi_msc_inquiry_data);
if (!udi_msc_cbw_validate(length, USB_CBW_DIRECTION_IN))
return;
if ((0 != (udi_msc_cbw.CDB[1] & (SCSI_INQ_REQ_EVPD | SCSI_INQ_REQ_CMDT)))
|| (0 != udi_msc_cbw.CDB[2])) {
// CMDT and EPVD bits are not at 0
// PAGE or OPERATION CODE fields are not empty
// = No standard inquiry asked
udi_msc_sense_fail_cdb_invalid(); // Command is unsupported
udi_msc_csw_process();
return;
}
udi_msc_inquiry_data.flags1 = mem_removal(udi_msc_cbw.bCBWLUN) ?
SCSI_INQ_RMB : 0;
//* Fill product ID field
// Copy name in product id field
memcpy(udi_msc_inquiry_data.product_id,
mem_name(udi_msc_cbw.bCBWLUN)+1, // To remove first '"'
sizeof(udi_msc_inquiry_data.product_id));
// Search end of name '/0' or '"'
i = 0;
while (sizeof(udi_msc_inquiry_data.product_id) != i) {
if ((0 == udi_msc_inquiry_data.product_id[i])
|| ('"' == udi_msc_inquiry_data.product_id[i])) {
break;
}
i++;
}
// Padding with space char
while (sizeof(udi_msc_inquiry_data.product_id) != i) {
udi_msc_inquiry_data.product_id[i] = ' ';
i++;
}
// Send inquiry data
udi_msc_data_send((uint8_t *) & udi_msc_inquiry_data, length);
}
static bool udi_msc_spc_testunitready_global(void)
{
switch (mem_test_unit_ready(udi_msc_cbw.bCBWLUN)) {
case CTRL_GOOD:
return true; // Don't change sense data
case CTRL_BUSY:
udi_msc_sense_fail_busy_or_change();
break;
case CTRL_NO_PRESENT:
udi_msc_sense_fail_not_present();
break;
case CTRL_FAIL:
default:
udi_msc_sense_fail_hardware();
break;
}
return false;
}
static void udi_msc_spc_testunitready(void)
{
if (udi_msc_spc_testunitready_global()) {
// LUN ready, then update sense data with status pass
udi_msc_sense_pass();
}
// Send status in CSW packet
udi_msc_csw_process();
}
static void udi_msc_spc_mode_sense(bool b_sense10)
{
// Union of all mode sense structures
union sense_6_10 {
struct {
struct scsi_mode_param_header6 header;
struct spc_control_page_info_execpt sense_data;
} s6;
struct {
struct scsi_mode_param_header10 header;
struct spc_control_page_info_execpt sense_data;
} s10;
};
uint8_t data_sense_lgt;
uint8_t mode;
uint8_t request_lgt;
uint8_t wp;
struct spc_control_page_info_execpt *ptr_mode;
UDC_BSS(4) static union sense_6_10 sense;
// Clear all fields
memset(&sense, 0, sizeof(sense));
// Initialize process
if (b_sense10) {
request_lgt = udi_msc_cbw.CDB[8];
ptr_mode = &sense.s10.sense_data;
data_sense_lgt = sizeof(struct scsi_mode_param_header10);
} else {
request_lgt = udi_msc_cbw.CDB[4];
ptr_mode = &sense.s6.sense_data;
data_sense_lgt = sizeof(struct scsi_mode_param_header6);
}
// No Block descriptor
// Fill page(s)
mode = udi_msc_cbw.CDB[2] & SCSI_MS_MODE_ALL;
if ((SCSI_MS_MODE_INFEXP == mode)
|| (SCSI_MS_MODE_ALL == mode)) {
// Informational exceptions control page (from SPC)
ptr_mode->page_code =
SCSI_MS_MODE_INFEXP;
ptr_mode->page_length =
SPC_MP_INFEXP_PAGE_LENGTH;
ptr_mode->mrie =
SPC_MP_INFEXP_MRIE_NO_SENSE;
data_sense_lgt += sizeof(struct spc_control_page_info_execpt);
}
// Can't send more than mode sense data length
if (request_lgt > data_sense_lgt)
request_lgt = data_sense_lgt;
if (!udi_msc_cbw_validate(request_lgt, USB_CBW_DIRECTION_IN))
return;
// Fill mode parameter header length
wp = (mem_wr_protect(udi_msc_cbw.bCBWLUN)) ? SCSI_MS_SBC_WP : 0;
if (b_sense10) {
sense.s10.header.mode_data_length =
cpu_to_be16((data_sense_lgt - 2));
//sense.s10.header.medium_type = 0;
sense.s10.header.device_specific_parameter = wp;
//sense.s10.header.block_descriptor_length = 0;
} else {
sense.s6.header.mode_data_length = data_sense_lgt - 1;
//sense.s6.header.medium_type = 0;
sense.s6.header.device_specific_parameter = wp;
//sense.s6.header.block_descriptor_length = 0;
}
// Send mode sense data
udi_msc_data_send((uint8_t *) & sense, request_lgt);
}
static void udi_msc_spc_prevent_allow_medium_removal(void)
{
uint8_t prevent = udi_msc_cbw.CDB[4];
if (0 == prevent) {
udi_msc_sense_pass();
} else {
udi_msc_sense_fail_cdb_invalid(); // Command is unsupported
}
udi_msc_csw_process();
}
static void udi_msc_sbc_start_stop(void)
{
bool start = 0x1 & udi_msc_cbw.CDB[4];
bool loej = 0x2 & udi_msc_cbw.CDB[4];
if (loej) {
mem_unload(udi_msc_cbw.bCBWLUN, !start);
}
udi_msc_sense_pass();
udi_msc_csw_process();
}
static void udi_msc_sbc_read_capacity(void)
{
UDC_BSS(4) static struct sbc_read_capacity10_data udi_msc_capacity;
if (!udi_msc_cbw_validate(sizeof(udi_msc_capacity),
USB_CBW_DIRECTION_IN))
return;
// Get capacity of LUN
switch (mem_read_capacity(udi_msc_cbw.bCBWLUN,
&udi_msc_capacity.max_lba)) {
case CTRL_GOOD:
break;
case CTRL_BUSY:
udi_msc_sense_fail_busy_or_change();
udi_msc_csw_process();
return;
case CTRL_NO_PRESENT:
udi_msc_sense_fail_not_present();
udi_msc_csw_process();
return;
default:
udi_msc_sense_fail_hardware();
udi_msc_csw_process();
return;
}
// Format capacity data
udi_msc_capacity.block_len = CPU_TO_BE32(UDI_MSC_BLOCK_SIZE);
udi_msc_capacity.max_lba = cpu_to_be32(udi_msc_capacity.max_lba);
// Send the corresponding sense data
udi_msc_data_send((uint8_t *) & udi_msc_capacity,
sizeof(udi_msc_capacity));
}
static void udi_msc_sbc_trans(bool b_read)
{
uint32_t trans_size;
if (!b_read) {
// Write operation then check Write Protect
if (mem_wr_protect(udi_msc_cbw.bCBWLUN)) {
// Write not authorized
udi_msc_sense_fail_protected();
udi_msc_csw_process();
return;
}
}
// Read/Write command fields (address and number of block)
MSB0(udi_msc_addr) = udi_msc_cbw.CDB[2];
MSB1(udi_msc_addr) = udi_msc_cbw.CDB[3];
MSB2(udi_msc_addr) = udi_msc_cbw.CDB[4];
MSB3(udi_msc_addr) = udi_msc_cbw.CDB[5];
MSB(udi_msc_nb_block) = udi_msc_cbw.CDB[7];
LSB(udi_msc_nb_block) = udi_msc_cbw.CDB[8];
// Compute number of byte to transfer and valid it
trans_size = (uint32_t) udi_msc_nb_block *UDI_MSC_BLOCK_SIZE;
if (!udi_msc_cbw_validate(trans_size,
(b_read) ? USB_CBW_DIRECTION_IN :
USB_CBW_DIRECTION_OUT))
return;
// Record transfer request to do it in a task and not under interrupt
udi_msc_b_read = b_read;
udi_msc_b_trans_req = true;
UDI_MSC_NOTIFY_TRANS_EXT();
}
bool udi_msc_process_trans(void)
{
Ctrl_status status;
if (!udi_msc_b_trans_req)
return false; // No Transfer request to do
udi_msc_b_trans_req = false;
udi_msc_b_reset_trans = false;
// Start transfer
if (udi_msc_b_read) {
status = memory_2_usb(udi_msc_cbw.bCBWLUN, udi_msc_addr,
udi_msc_nb_block);
} else {
status = usb_2_memory(udi_msc_cbw.bCBWLUN, udi_msc_addr,
udi_msc_nb_block);
}
// Check if transfer is aborted by reset
if (udi_msc_b_reset_trans) {
udi_msc_b_reset_trans = false;
return true;
}
// Check status of transfer
switch (status) {
case CTRL_GOOD:
udi_msc_sense_pass();
break;
case CTRL_BUSY:
udi_msc_sense_fail_busy_or_change();
break;
case CTRL_NO_PRESENT:
udi_msc_sense_fail_not_present();
break;
default:
case CTRL_FAIL:
udi_msc_sense_fail_hardware();
break;
}
// Send status of transfer in CSW packet
udi_msc_csw_process();
return true;
}
static void udi_msc_trans_ack(udd_ep_status_t status, iram_size_t n,
udd_ep_id_t ep)
{
UNUSED(ep);
UNUSED(n);
// Update variable to signal the end of transfer
udi_msc_b_abort_trans = (UDD_EP_TRANSFER_OK != status) ? true : false;
udi_msc_b_ack_trans = true;
}
bool udi_msc_trans_block(bool b_read, uint8_t * block, iram_size_t block_size,
void (*callback) (udd_ep_status_t status, iram_size_t n, udd_ep_id_t ep))
{
if (!udi_msc_b_ack_trans)
return false; // No possible, transfer on going
// Start transfer Internal RAM<->USB line
udi_msc_b_ack_trans = false;
if (!udd_ep_run((b_read) ? UDI_MSC_EP_IN : UDI_MSC_EP_OUT,
false,
block,
block_size,
(NULL == callback) ? udi_msc_trans_ack :
callback)) {
udi_msc_b_ack_trans = true;
return false;
}
if (NULL == callback) {
while (!udi_msc_b_ack_trans);
if (udi_msc_b_abort_trans) {
return false;
}
udi_msc_csw.dCSWDataResidue -= block_size;
return (!udi_msc_b_abort_trans);
}
udi_msc_csw.dCSWDataResidue -= block_size;
return true;
}
//@}
#endif // SDSUPPORT
#endif // ARDUINO_ARCH_SAM