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Nathan Conrad
2020-01-14 23:30:39 -05:00
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/*
* The MIT License (MIT)
*
* Copyright (c) 2019 Ha Thach (tinyusb.org)
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*
* This file is part of the TinyUSB stack.
*/
/** \ingroup group_class
* \defgroup ClassDriver_MSC MassStorage (MSC)
* @{ */
/** \defgroup ClassDriver_MSC_Common Common Definitions
* @{ */
#ifndef _TUSB_MSC_H_
#define _TUSB_MSC_H_
#include "common/tusb_common.h"
#ifdef __cplusplus
extern "C" {
#endif
//--------------------------------------------------------------------+
// Mass Storage Class Constant
//--------------------------------------------------------------------+
/// MassStorage Subclass
typedef enum
{
MSC_SUBCLASS_RBC = 1 , ///< Reduced Block Commands (RBC) T10 Project 1240-D
MSC_SUBCLASS_SFF_MMC , ///< SFF-8020i, MMC-2 (ATAPI). Typically used by a CD/DVD device
MSC_SUBCLASS_QIC , ///< QIC-157. Typically used by a tape device
MSC_SUBCLASS_UFI , ///< UFI. Typically used by Floppy Disk Drive (FDD) device
MSC_SUBCLASS_SFF , ///< SFF-8070i. Can be used by Floppy Disk Drive (FDD) device
MSC_SUBCLASS_SCSI ///< SCSI transparent command set
}msc_subclass_type_t;
enum {
MSC_CBW_SIGNATURE = 0x43425355, ///< Constant value of 43425355h (little endian)
MSC_CSW_SIGNATURE = 0x53425355 ///< Constant value of 53425355h (little endian)
};
/// \brief MassStorage Protocol.
/// \details CBI only approved to use with full-speed floopy disk & should not used with highspeed or device other than floopy
typedef enum
{
MSC_PROTOCOL_CBI = 0 , ///< Control/Bulk/Interrupt protocol (with command completion interrupt)
MSC_PROTOCOL_CBI_NO_INTERRUPT = 1 , ///< Control/Bulk/Interrupt protocol (without command completion interrupt)
MSC_PROTOCOL_BOT = 0x50 ///< Bulk-Only Transport
}msc_protocol_type_t;
/// MassStorage Class-Specific Control Request
typedef enum
{
MSC_REQ_GET_MAX_LUN = 254, ///< The Get Max LUN device request is used to determine the number of logical units supported by the device. Logical Unit Numbers on the device shall be numbered contiguously starting from LUN 0 to a maximum LUN of 15
MSC_REQ_RESET = 255 ///< This request is used to reset the mass storage device and its associated interface. This class-specific request shall ready the device for the next CBW from the host.
}msc_request_type_t;
/// \brief Command Block Status Values
/// \details Indicates the success or failure of the command. The device shall set this byte to zero if the command completed
/// successfully. A non-zero value shall indicate a failure during command execution according to the following
typedef enum
{
MSC_CSW_STATUS_PASSED = 0 , ///< MSC_CSW_STATUS_PASSED
MSC_CSW_STATUS_FAILED , ///< MSC_CSW_STATUS_FAILED
MSC_CSW_STATUS_PHASE_ERROR ///< MSC_CSW_STATUS_PHASE_ERROR
}msc_csw_status_t;
/// Command Block Wrapper
typedef struct TU_ATTR_PACKED
{
uint32_t signature; ///< Signature that helps identify this data packet as a CBW. The signature field shall contain the value 43425355h (little endian), indicating a CBW.
uint32_t tag; ///< Tag sent by the host. The device shall echo the contents of this field back to the host in the dCSWTagfield of the associated CSW. The dCSWTagpositively associates a CSW with the corresponding CBW.
uint32_t total_bytes; ///< The number of bytes of data that the host expects to transfer on the Bulk-In or Bulk-Out endpoint (as indicated by the Direction bit) during the execution of this command. If this field is zero, the device and the host shall transfer no data between the CBW and the associated CSW, and the device shall ignore the value of the Direction bit in bmCBWFlags.
uint8_t dir; ///< Bit 7 of this field define transfer direction \n - 0 : Data-Out from host to the device. \n - 1 : Data-In from the device to the host.
uint8_t lun; ///< The device Logical Unit Number (LUN) to which the command block is being sent. For devices that support multiple LUNs, the host shall place into this field the LUN to which this command block is addressed. Otherwise, the host shall set this field to zero.
uint8_t cmd_len; ///< The valid length of the CBWCBin bytes. This defines the valid length of the command block. The only legal values are 1 through 16
uint8_t command[16]; ///< The command block to be executed by the device. The device shall interpret the first cmd_len bytes in this field as a command block
}msc_cbw_t;
TU_VERIFY_STATIC(sizeof(msc_cbw_t) == 31, "size is not correct");
/// Command Status Wrapper
typedef struct TU_ATTR_PACKED
{
uint32_t signature ; ///< Signature that helps identify this data packet as a CSW. The signature field shall contain the value 53425355h (little endian), indicating CSW.
uint32_t tag ; ///< The device shall set this field to the value received in the dCBWTag of the associated CBW.
uint32_t data_residue ; ///< For Data-Out the device shall report in the dCSWDataResiduethe difference between the amount of data expected as stated in the dCBWDataTransferLength, and the actual amount of data processed by the device. For Data-In the device shall report in the dCSWDataResiduethe difference between the amount of data expected as stated in the dCBWDataTransferLengthand the actual amount of relevant data sent by the device
uint8_t status ; ///< indicates the success or failure of the command. Values from \ref msc_csw_status_t
}msc_csw_t;
TU_VERIFY_STATIC(sizeof(msc_csw_t) == 13, "size is not correct");
//--------------------------------------------------------------------+
// SCSI Constant
//--------------------------------------------------------------------+
/// SCSI Command Operation Code
typedef enum
{
SCSI_CMD_TEST_UNIT_READY = 0x00, ///< The SCSI Test Unit Ready command is used to determine if a device is ready to transfer data (read/write), i.e. if a disk has spun up, if a tape is loaded and ready etc. The device does not perform a self-test operation.
SCSI_CMD_INQUIRY = 0x12, ///< The SCSI Inquiry command is used to obtain basic information from a target device.
SCSI_CMD_MODE_SELECT_6 = 0x15, ///< provides a means for the application client to specify medium, logical unit, or peripheral device parameters to the device server. Device servers that implement the MODE SELECT(6) command shall also implement the MODE SENSE(6) command. Application clients should issue MODE SENSE(6) prior to each MODE SELECT(6) to determine supported mode pages, page lengths, and other parameters.
SCSI_CMD_MODE_SENSE_6 = 0x1A, ///< provides a means for a device server to report parameters to an application client. It is a complementary command to the MODE SELECT(6) command. Device servers that implement the MODE SENSE(6) command shall also implement the MODE SELECT(6) command.
SCSI_CMD_START_STOP_UNIT = 0x1B,
SCSI_CMD_PREVENT_ALLOW_MEDIUM_REMOVAL = 0x1E,
SCSI_CMD_READ_CAPACITY_10 = 0x25, ///< The SCSI Read Capacity command is used to obtain data capacity information from a target device.
SCSI_CMD_REQUEST_SENSE = 0x03, ///< The SCSI Request Sense command is part of the SCSI computer protocol standard. This command is used to obtain sense data -- status/error information -- from a target device.
SCSI_CMD_READ_FORMAT_CAPACITY = 0x23, ///< The command allows the Host to request a list of the possible format capacities for an installed writable media. This command also has the capability to report the writable capacity for a media when it is installed
SCSI_CMD_READ_10 = 0x28, ///< The READ (10) command requests that the device server read the specified logical block(s) and transfer them to the data-in buffer.
SCSI_CMD_WRITE_10 = 0x2A, ///< The WRITE (10) command requests thatthe device server transfer the specified logical block(s) from the data-out buffer and write them.
}scsi_cmd_type_t;
/// SCSI Sense Key
typedef enum
{
SCSI_SENSE_NONE = 0x00, ///< no specific Sense Key. This would be the case for a successful command
SCSI_SENSE_RECOVERED_ERROR = 0x01, ///< ndicates the last command completed successfully with some recovery action performed by the disc drive.
SCSI_SENSE_NOT_READY = 0x02, ///< Indicates the logical unit addressed cannot be accessed.
SCSI_SENSE_MEDIUM_ERROR = 0x03, ///< Indicates the command terminated with a non-recovered error condition.
SCSI_SENSE_HARDWARE_ERROR = 0x04, ///< Indicates the disc drive detected a nonrecoverable hardware failure while performing the command or during a self test.
SCSI_SENSE_ILLEGAL_REQUEST = 0x05, ///< Indicates an illegal parameter in the command descriptor block or in the additional parameters
SCSI_SENSE_UNIT_ATTENTION = 0x06, ///< Indicates the disc drive may have been reset.
SCSI_SENSE_DATA_PROTECT = 0x07, ///< Indicates that a command that reads or writes the medium was attempted on a block that is protected from this operation. The read or write operation is not performed.
SCSI_SENSE_FIRMWARE_ERROR = 0x08, ///< Vendor specific sense key.
SCSI_SENSE_ABORTED_COMMAND = 0x0b, ///< Indicates the disc drive aborted the command.
SCSI_SENSE_EQUAL = 0x0c, ///< Indicates a SEARCH DATA command has satisfied an equal comparison.
SCSI_SENSE_VOLUME_OVERFLOW = 0x0d, ///< Indicates a buffered peripheral device has reached the end of medium partition and data remains in the buffer that has not been written to the medium.
SCSI_SENSE_MISCOMPARE = 0x0e ///< ndicates that the source data did not match the data read from the medium.
}scsi_sense_key_type_t;
//--------------------------------------------------------------------+
// SCSI Primary Command (SPC-4)
//--------------------------------------------------------------------+
/// SCSI Test Unit Ready Command
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code ; ///< SCSI OpCode for \ref SCSI_CMD_TEST_UNIT_READY
uint8_t lun ; ///< Logical Unit
uint8_t reserved[3] ;
uint8_t control ;
} scsi_test_unit_ready_t;
TU_VERIFY_STATIC(sizeof(scsi_test_unit_ready_t) == 6, "size is not correct");
/// SCSI Inquiry Command
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code ; ///< SCSI OpCode for \ref SCSI_CMD_INQUIRY
uint8_t reserved1 ;
uint8_t page_code ;
uint8_t reserved2 ;
uint8_t alloc_length ; ///< specifies the maximum number of bytes that USB host has allocated in the Data-In Buffer. An allocation length of zero specifies that no data shall be transferred.
uint8_t control ;
} scsi_inquiry_t, scsi_request_sense_t;
TU_VERIFY_STATIC(sizeof(scsi_inquiry_t) == 6, "size is not correct");
/// SCSI Inquiry Response Data
typedef struct TU_ATTR_PACKED
{
uint8_t peripheral_device_type : 5;
uint8_t peripheral_qualifier : 3;
uint8_t : 7;
uint8_t is_removable : 1;
uint8_t version;
uint8_t response_data_format : 4;
uint8_t hierarchical_support : 1;
uint8_t normal_aca : 1;
uint8_t : 2;
uint8_t additional_length;
uint8_t protect : 1;
uint8_t : 2;
uint8_t third_party_copy : 1;
uint8_t target_port_group_support : 2;
uint8_t access_control_coordinator : 1;
uint8_t scc_support : 1;
uint8_t addr16 : 1;
uint8_t : 3;
uint8_t multi_port : 1;
uint8_t : 1; // vendor specific
uint8_t enclosure_service : 1;
uint8_t : 1;
uint8_t : 1; // vendor specific
uint8_t cmd_que : 1;
uint8_t : 2;
uint8_t sync : 1;
uint8_t wbus16 : 1;
uint8_t : 2;
uint8_t vendor_id[8] ; ///< 8 bytes of ASCII data identifying the vendor of the product.
uint8_t product_id[16]; ///< 16 bytes of ASCII data defined by the vendor.
uint8_t product_rev[4]; ///< 4 bytes of ASCII data defined by the vendor.
} scsi_inquiry_resp_t;
TU_VERIFY_STATIC(sizeof(scsi_inquiry_resp_t) == 36, "size is not correct");
typedef struct TU_ATTR_PACKED
{
uint8_t response_code : 7; ///< 70h - current errors, Fixed Format 71h - deferred errors, Fixed Format
uint8_t valid : 1;
uint8_t reserved;
uint8_t sense_key : 4;
uint8_t : 1;
uint8_t ili : 1; ///< Incorrect length indicator
uint8_t end_of_medium : 1;
uint8_t filemark : 1;
uint32_t information;
uint8_t add_sense_len;
uint32_t command_specific_info;
uint8_t add_sense_code;
uint8_t add_sense_qualifier;
uint8_t field_replaceable_unit_code;
uint8_t sense_key_specific[3]; ///< sense key specific valid bit is bit 7 of key[0], aka MSB in Big Endian layout
} scsi_sense_fixed_resp_t;
TU_VERIFY_STATIC(sizeof(scsi_sense_fixed_resp_t) == 18, "size is not correct");
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code ; ///< SCSI OpCode for \ref SCSI_CMD_MODE_SENSE_6
uint8_t : 3;
uint8_t disable_block_descriptor : 1;
uint8_t : 0;
uint8_t page_code : 6;
uint8_t page_control : 2;
uint8_t subpage_code;
uint8_t alloc_length;
uint8_t control;
} scsi_mode_sense6_t;
TU_VERIFY_STATIC( sizeof(scsi_mode_sense6_t) == 6, "size is not correct");
// This is only a Mode parameter header(6).
typedef struct TU_ATTR_PACKED
{
uint8_t data_len;
uint8_t medium_type;
uint8_t reserved : 7;
bool write_protected : 1;
uint8_t block_descriptor_len;
} scsi_mode_sense6_resp_t;
TU_VERIFY_STATIC( sizeof(scsi_mode_sense6_resp_t) == 4, "size is not correct");
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code; ///< SCSI OpCode for \ref SCSI_CMD_PREVENT_ALLOW_MEDIUM_REMOVAL
uint8_t reserved[3];
uint8_t prohibit_removal;
uint8_t control;
} scsi_prevent_allow_medium_removal_t;
TU_VERIFY_STATIC( sizeof(scsi_prevent_allow_medium_removal_t) == 6, "size is not correct");
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code;
uint8_t immded : 1;
uint8_t : 7;
uint8_t TU_RESERVED;
uint8_t power_condition_mod : 4;
uint8_t : 4;
uint8_t start : 1;
uint8_t load_eject : 1;
uint8_t no_flush : 1;
uint8_t : 1;
uint8_t power_condition : 4;
uint8_t control;
} scsi_start_stop_unit_t;
TU_VERIFY_STATIC( sizeof(scsi_start_stop_unit_t) == 6, "size is not correct");
//--------------------------------------------------------------------+
// SCSI MMC
//--------------------------------------------------------------------+
/// SCSI Read Format Capacity: Write Capacity
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code;
uint8_t reserved[6];
uint16_t alloc_length;
uint8_t control;
} scsi_read_format_capacity_t;
TU_VERIFY_STATIC( sizeof(scsi_read_format_capacity_t) == 10, "size is not correct");
typedef struct TU_ATTR_PACKED{
uint8_t reserved[3];
uint8_t list_length; /// must be 8*n, length in bytes of formattable capacity descriptor followed it.
uint32_t block_num; /// Number of Logical Blocks
uint8_t descriptor_type; // 00: reserved, 01 unformatted media , 10 Formatted media, 11 No media present
uint8_t reserved2;
uint16_t block_size_u16;
} scsi_read_format_capacity_data_t;
TU_VERIFY_STATIC( sizeof(scsi_read_format_capacity_data_t) == 12, "size is not correct");
//--------------------------------------------------------------------+
// SCSI Block Command (SBC-3)
// NOTE: All data in SCSI command are in Big Endian
//--------------------------------------------------------------------+
/// SCSI Read Capacity 10 Command: Read Capacity
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code ; ///< SCSI OpCode for \ref SCSI_CMD_READ_CAPACITY_10
uint8_t reserved1 ;
uint32_t lba ; ///< The first Logical Block Address (LBA) accessed by this command
uint16_t reserved2 ;
uint8_t partial_medium_indicator ;
uint8_t control ;
} scsi_read_capacity10_t;
TU_VERIFY_STATIC(sizeof(scsi_read_capacity10_t) == 10, "size is not correct");
/// SCSI Read Capacity 10 Response Data
typedef struct {
uint32_t last_lba ; ///< The last Logical Block Address of the device
uint32_t block_size ; ///< Block size in bytes
} scsi_read_capacity10_resp_t;
TU_VERIFY_STATIC(sizeof(scsi_read_capacity10_resp_t) == 8, "size is not correct");
/// SCSI Read 10 Command
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code ; ///< SCSI OpCode
uint8_t reserved ; // has LUN according to wiki
uint32_t lba ; ///< The first Logical Block Address (LBA) accessed by this command
uint8_t reserved2 ;
uint16_t block_count ; ///< Number of Blocks used by this command
uint8_t control ;
} scsi_read10_t, scsi_write10_t;
TU_VERIFY_STATIC(sizeof(scsi_read10_t) == 10, "size is not correct");
TU_VERIFY_STATIC(sizeof(scsi_write10_t) == 10, "size is not correct");
#ifdef __cplusplus
}
#endif
#endif /* _TUSB_MSC_H_ */
/// @}
/// @}
/*
* The MIT License (MIT)
*
* Copyright (c) 2019 Ha Thach (tinyusb.org)
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*
* This file is part of the TinyUSB stack.
*/
/** \ingroup group_class
* \defgroup ClassDriver_MSC MassStorage (MSC)
* @{ */
/** \defgroup ClassDriver_MSC_Common Common Definitions
* @{ */
#ifndef _TUSB_MSC_H_
#define _TUSB_MSC_H_
#include "common/tusb_common.h"
#ifdef __cplusplus
extern "C" {
#endif
//--------------------------------------------------------------------+
// Mass Storage Class Constant
//--------------------------------------------------------------------+
/// MassStorage Subclass
typedef enum
{
MSC_SUBCLASS_RBC = 1 , ///< Reduced Block Commands (RBC) T10 Project 1240-D
MSC_SUBCLASS_SFF_MMC , ///< SFF-8020i, MMC-2 (ATAPI). Typically used by a CD/DVD device
MSC_SUBCLASS_QIC , ///< QIC-157. Typically used by a tape device
MSC_SUBCLASS_UFI , ///< UFI. Typically used by Floppy Disk Drive (FDD) device
MSC_SUBCLASS_SFF , ///< SFF-8070i. Can be used by Floppy Disk Drive (FDD) device
MSC_SUBCLASS_SCSI ///< SCSI transparent command set
}msc_subclass_type_t;
enum {
MSC_CBW_SIGNATURE = 0x43425355, ///< Constant value of 43425355h (little endian)
MSC_CSW_SIGNATURE = 0x53425355 ///< Constant value of 53425355h (little endian)
};
/// \brief MassStorage Protocol.
/// \details CBI only approved to use with full-speed floopy disk & should not used with highspeed or device other than floopy
typedef enum
{
MSC_PROTOCOL_CBI = 0 , ///< Control/Bulk/Interrupt protocol (with command completion interrupt)
MSC_PROTOCOL_CBI_NO_INTERRUPT = 1 , ///< Control/Bulk/Interrupt protocol (without command completion interrupt)
MSC_PROTOCOL_BOT = 0x50 ///< Bulk-Only Transport
}msc_protocol_type_t;
/// MassStorage Class-Specific Control Request
typedef enum
{
MSC_REQ_GET_MAX_LUN = 254, ///< The Get Max LUN device request is used to determine the number of logical units supported by the device. Logical Unit Numbers on the device shall be numbered contiguously starting from LUN 0 to a maximum LUN of 15
MSC_REQ_RESET = 255 ///< This request is used to reset the mass storage device and its associated interface. This class-specific request shall ready the device for the next CBW from the host.
}msc_request_type_t;
/// \brief Command Block Status Values
/// \details Indicates the success or failure of the command. The device shall set this byte to zero if the command completed
/// successfully. A non-zero value shall indicate a failure during command execution according to the following
typedef enum
{
MSC_CSW_STATUS_PASSED = 0 , ///< MSC_CSW_STATUS_PASSED
MSC_CSW_STATUS_FAILED , ///< MSC_CSW_STATUS_FAILED
MSC_CSW_STATUS_PHASE_ERROR ///< MSC_CSW_STATUS_PHASE_ERROR
}msc_csw_status_t;
/// Command Block Wrapper
typedef struct TU_ATTR_PACKED
{
uint32_t signature; ///< Signature that helps identify this data packet as a CBW. The signature field shall contain the value 43425355h (little endian), indicating a CBW.
uint32_t tag; ///< Tag sent by the host. The device shall echo the contents of this field back to the host in the dCSWTagfield of the associated CSW. The dCSWTagpositively associates a CSW with the corresponding CBW.
uint32_t total_bytes; ///< The number of bytes of data that the host expects to transfer on the Bulk-In or Bulk-Out endpoint (as indicated by the Direction bit) during the execution of this command. If this field is zero, the device and the host shall transfer no data between the CBW and the associated CSW, and the device shall ignore the value of the Direction bit in bmCBWFlags.
uint8_t dir; ///< Bit 7 of this field define transfer direction \n - 0 : Data-Out from host to the device. \n - 1 : Data-In from the device to the host.
uint8_t lun; ///< The device Logical Unit Number (LUN) to which the command block is being sent. For devices that support multiple LUNs, the host shall place into this field the LUN to which this command block is addressed. Otherwise, the host shall set this field to zero.
uint8_t cmd_len; ///< The valid length of the CBWCBin bytes. This defines the valid length of the command block. The only legal values are 1 through 16
uint8_t command[16]; ///< The command block to be executed by the device. The device shall interpret the first cmd_len bytes in this field as a command block
}msc_cbw_t;
TU_VERIFY_STATIC(sizeof(msc_cbw_t) == 31, "size is not correct");
/// Command Status Wrapper
typedef struct TU_ATTR_PACKED
{
uint32_t signature ; ///< Signature that helps identify this data packet as a CSW. The signature field shall contain the value 53425355h (little endian), indicating CSW.
uint32_t tag ; ///< The device shall set this field to the value received in the dCBWTag of the associated CBW.
uint32_t data_residue ; ///< For Data-Out the device shall report in the dCSWDataResiduethe difference between the amount of data expected as stated in the dCBWDataTransferLength, and the actual amount of data processed by the device. For Data-In the device shall report in the dCSWDataResiduethe difference between the amount of data expected as stated in the dCBWDataTransferLengthand the actual amount of relevant data sent by the device
uint8_t status ; ///< indicates the success or failure of the command. Values from \ref msc_csw_status_t
}msc_csw_t;
TU_VERIFY_STATIC(sizeof(msc_csw_t) == 13, "size is not correct");
//--------------------------------------------------------------------+
// SCSI Constant
//--------------------------------------------------------------------+
/// SCSI Command Operation Code
typedef enum
{
SCSI_CMD_TEST_UNIT_READY = 0x00, ///< The SCSI Test Unit Ready command is used to determine if a device is ready to transfer data (read/write), i.e. if a disk has spun up, if a tape is loaded and ready etc. The device does not perform a self-test operation.
SCSI_CMD_INQUIRY = 0x12, ///< The SCSI Inquiry command is used to obtain basic information from a target device.
SCSI_CMD_MODE_SELECT_6 = 0x15, ///< provides a means for the application client to specify medium, logical unit, or peripheral device parameters to the device server. Device servers that implement the MODE SELECT(6) command shall also implement the MODE SENSE(6) command. Application clients should issue MODE SENSE(6) prior to each MODE SELECT(6) to determine supported mode pages, page lengths, and other parameters.
SCSI_CMD_MODE_SENSE_6 = 0x1A, ///< provides a means for a device server to report parameters to an application client. It is a complementary command to the MODE SELECT(6) command. Device servers that implement the MODE SENSE(6) command shall also implement the MODE SELECT(6) command.
SCSI_CMD_START_STOP_UNIT = 0x1B,
SCSI_CMD_PREVENT_ALLOW_MEDIUM_REMOVAL = 0x1E,
SCSI_CMD_READ_CAPACITY_10 = 0x25, ///< The SCSI Read Capacity command is used to obtain data capacity information from a target device.
SCSI_CMD_REQUEST_SENSE = 0x03, ///< The SCSI Request Sense command is part of the SCSI computer protocol standard. This command is used to obtain sense data -- status/error information -- from a target device.
SCSI_CMD_READ_FORMAT_CAPACITY = 0x23, ///< The command allows the Host to request a list of the possible format capacities for an installed writable media. This command also has the capability to report the writable capacity for a media when it is installed
SCSI_CMD_READ_10 = 0x28, ///< The READ (10) command requests that the device server read the specified logical block(s) and transfer them to the data-in buffer.
SCSI_CMD_WRITE_10 = 0x2A, ///< The WRITE (10) command requests thatthe device server transfer the specified logical block(s) from the data-out buffer and write them.
}scsi_cmd_type_t;
/// SCSI Sense Key
typedef enum
{
SCSI_SENSE_NONE = 0x00, ///< no specific Sense Key. This would be the case for a successful command
SCSI_SENSE_RECOVERED_ERROR = 0x01, ///< ndicates the last command completed successfully with some recovery action performed by the disc drive.
SCSI_SENSE_NOT_READY = 0x02, ///< Indicates the logical unit addressed cannot be accessed.
SCSI_SENSE_MEDIUM_ERROR = 0x03, ///< Indicates the command terminated with a non-recovered error condition.
SCSI_SENSE_HARDWARE_ERROR = 0x04, ///< Indicates the disc drive detected a nonrecoverable hardware failure while performing the command or during a self test.
SCSI_SENSE_ILLEGAL_REQUEST = 0x05, ///< Indicates an illegal parameter in the command descriptor block or in the additional parameters
SCSI_SENSE_UNIT_ATTENTION = 0x06, ///< Indicates the disc drive may have been reset.
SCSI_SENSE_DATA_PROTECT = 0x07, ///< Indicates that a command that reads or writes the medium was attempted on a block that is protected from this operation. The read or write operation is not performed.
SCSI_SENSE_FIRMWARE_ERROR = 0x08, ///< Vendor specific sense key.
SCSI_SENSE_ABORTED_COMMAND = 0x0b, ///< Indicates the disc drive aborted the command.
SCSI_SENSE_EQUAL = 0x0c, ///< Indicates a SEARCH DATA command has satisfied an equal comparison.
SCSI_SENSE_VOLUME_OVERFLOW = 0x0d, ///< Indicates a buffered peripheral device has reached the end of medium partition and data remains in the buffer that has not been written to the medium.
SCSI_SENSE_MISCOMPARE = 0x0e ///< ndicates that the source data did not match the data read from the medium.
}scsi_sense_key_type_t;
//--------------------------------------------------------------------+
// SCSI Primary Command (SPC-4)
//--------------------------------------------------------------------+
/// SCSI Test Unit Ready Command
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code ; ///< SCSI OpCode for \ref SCSI_CMD_TEST_UNIT_READY
uint8_t lun ; ///< Logical Unit
uint8_t reserved[3] ;
uint8_t control ;
} scsi_test_unit_ready_t;
TU_VERIFY_STATIC(sizeof(scsi_test_unit_ready_t) == 6, "size is not correct");
/// SCSI Inquiry Command
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code ; ///< SCSI OpCode for \ref SCSI_CMD_INQUIRY
uint8_t reserved1 ;
uint8_t page_code ;
uint8_t reserved2 ;
uint8_t alloc_length ; ///< specifies the maximum number of bytes that USB host has allocated in the Data-In Buffer. An allocation length of zero specifies that no data shall be transferred.
uint8_t control ;
} scsi_inquiry_t, scsi_request_sense_t;
TU_VERIFY_STATIC(sizeof(scsi_inquiry_t) == 6, "size is not correct");
/// SCSI Inquiry Response Data
typedef struct TU_ATTR_PACKED
{
uint8_t peripheral_device_type : 5;
uint8_t peripheral_qualifier : 3;
uint8_t : 7;
uint8_t is_removable : 1;
uint8_t version;
uint8_t response_data_format : 4;
uint8_t hierarchical_support : 1;
uint8_t normal_aca : 1;
uint8_t : 2;
uint8_t additional_length;
uint8_t protect : 1;
uint8_t : 2;
uint8_t third_party_copy : 1;
uint8_t target_port_group_support : 2;
uint8_t access_control_coordinator : 1;
uint8_t scc_support : 1;
uint8_t addr16 : 1;
uint8_t : 3;
uint8_t multi_port : 1;
uint8_t : 1; // vendor specific
uint8_t enclosure_service : 1;
uint8_t : 1;
uint8_t : 1; // vendor specific
uint8_t cmd_que : 1;
uint8_t : 2;
uint8_t sync : 1;
uint8_t wbus16 : 1;
uint8_t : 2;
uint8_t vendor_id[8] ; ///< 8 bytes of ASCII data identifying the vendor of the product.
uint8_t product_id[16]; ///< 16 bytes of ASCII data defined by the vendor.
uint8_t product_rev[4]; ///< 4 bytes of ASCII data defined by the vendor.
} scsi_inquiry_resp_t;
TU_VERIFY_STATIC(sizeof(scsi_inquiry_resp_t) == 36, "size is not correct");
typedef struct TU_ATTR_PACKED
{
uint8_t response_code : 7; ///< 70h - current errors, Fixed Format 71h - deferred errors, Fixed Format
uint8_t valid : 1;
uint8_t reserved;
uint8_t sense_key : 4;
uint8_t : 1;
uint8_t ili : 1; ///< Incorrect length indicator
uint8_t end_of_medium : 1;
uint8_t filemark : 1;
uint32_t information;
uint8_t add_sense_len;
uint32_t command_specific_info;
uint8_t add_sense_code;
uint8_t add_sense_qualifier;
uint8_t field_replaceable_unit_code;
uint8_t sense_key_specific[3]; ///< sense key specific valid bit is bit 7 of key[0], aka MSB in Big Endian layout
} scsi_sense_fixed_resp_t;
TU_VERIFY_STATIC(sizeof(scsi_sense_fixed_resp_t) == 18, "size is not correct");
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code ; ///< SCSI OpCode for \ref SCSI_CMD_MODE_SENSE_6
uint8_t : 3;
uint8_t disable_block_descriptor : 1;
uint8_t : 0;
uint8_t page_code : 6;
uint8_t page_control : 2;
uint8_t subpage_code;
uint8_t alloc_length;
uint8_t control;
} scsi_mode_sense6_t;
TU_VERIFY_STATIC( sizeof(scsi_mode_sense6_t) == 6, "size is not correct");
// This is only a Mode parameter header(6).
typedef struct TU_ATTR_PACKED
{
uint8_t data_len;
uint8_t medium_type;
uint8_t reserved : 7;
bool write_protected : 1;
uint8_t block_descriptor_len;
} scsi_mode_sense6_resp_t;
TU_VERIFY_STATIC( sizeof(scsi_mode_sense6_resp_t) == 4, "size is not correct");
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code; ///< SCSI OpCode for \ref SCSI_CMD_PREVENT_ALLOW_MEDIUM_REMOVAL
uint8_t reserved[3];
uint8_t prohibit_removal;
uint8_t control;
} scsi_prevent_allow_medium_removal_t;
TU_VERIFY_STATIC( sizeof(scsi_prevent_allow_medium_removal_t) == 6, "size is not correct");
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code;
uint8_t immded : 1;
uint8_t : 7;
uint8_t TU_RESERVED;
uint8_t power_condition_mod : 4;
uint8_t : 4;
uint8_t start : 1;
uint8_t load_eject : 1;
uint8_t no_flush : 1;
uint8_t : 1;
uint8_t power_condition : 4;
uint8_t control;
} scsi_start_stop_unit_t;
TU_VERIFY_STATIC( sizeof(scsi_start_stop_unit_t) == 6, "size is not correct");
//--------------------------------------------------------------------+
// SCSI MMC
//--------------------------------------------------------------------+
/// SCSI Read Format Capacity: Write Capacity
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code;
uint8_t reserved[6];
uint16_t alloc_length;
uint8_t control;
} scsi_read_format_capacity_t;
TU_VERIFY_STATIC( sizeof(scsi_read_format_capacity_t) == 10, "size is not correct");
typedef struct TU_ATTR_PACKED{
uint8_t reserved[3];
uint8_t list_length; /// must be 8*n, length in bytes of formattable capacity descriptor followed it.
uint32_t block_num; /// Number of Logical Blocks
uint8_t descriptor_type; // 00: reserved, 01 unformatted media , 10 Formatted media, 11 No media present
uint8_t reserved2;
uint16_t block_size_u16;
} scsi_read_format_capacity_data_t;
TU_VERIFY_STATIC( sizeof(scsi_read_format_capacity_data_t) == 12, "size is not correct");
//--------------------------------------------------------------------+
// SCSI Block Command (SBC-3)
// NOTE: All data in SCSI command are in Big Endian
//--------------------------------------------------------------------+
/// SCSI Read Capacity 10 Command: Read Capacity
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code ; ///< SCSI OpCode for \ref SCSI_CMD_READ_CAPACITY_10
uint8_t reserved1 ;
uint32_t lba ; ///< The first Logical Block Address (LBA) accessed by this command
uint16_t reserved2 ;
uint8_t partial_medium_indicator ;
uint8_t control ;
} scsi_read_capacity10_t;
TU_VERIFY_STATIC(sizeof(scsi_read_capacity10_t) == 10, "size is not correct");
/// SCSI Read Capacity 10 Response Data
typedef struct {
uint32_t last_lba ; ///< The last Logical Block Address of the device
uint32_t block_size ; ///< Block size in bytes
} scsi_read_capacity10_resp_t;
TU_VERIFY_STATIC(sizeof(scsi_read_capacity10_resp_t) == 8, "size is not correct");
/// SCSI Read 10 Command
typedef struct TU_ATTR_PACKED
{
uint8_t cmd_code ; ///< SCSI OpCode
uint8_t reserved ; // has LUN according to wiki
uint32_t lba ; ///< The first Logical Block Address (LBA) accessed by this command
uint8_t reserved2 ;
uint16_t block_count ; ///< Number of Blocks used by this command
uint8_t control ;
} scsi_read10_t, scsi_write10_t;
TU_VERIFY_STATIC(sizeof(scsi_read10_t) == 10, "size is not correct");
TU_VERIFY_STATIC(sizeof(scsi_write10_t) == 10, "size is not correct");
#ifdef __cplusplus
}
#endif
#endif /* _TUSB_MSC_H_ */
/// @}
/// @}
+700 -700
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+165 -165
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@@ -1,165 +1,165 @@
/*
* The MIT License (MIT)
*
* Copyright (c) 2019 Ha Thach (tinyusb.org)
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*
* This file is part of the TinyUSB stack.
*/
#ifndef _TUSB_MSC_DEVICE_H_
#define _TUSB_MSC_DEVICE_H_
#include "common/tusb_common.h"
#include "device/usbd.h"
#include "msc.h"
#ifdef __cplusplus
extern "C" {
#endif
//--------------------------------------------------------------------+
// Class Driver Configuration
//--------------------------------------------------------------------+
TU_VERIFY_STATIC(CFG_TUD_MSC_BUFSIZE < UINT16_MAX, "Size is not correct");
#ifndef CFG_TUD_MSC_BUFSIZE
#error CFG_TUD_MSC_BUFSIZE must be defined, value of a block size should work well, the more the better
#endif
/** \addtogroup ClassDriver_MSC
* @{
* \defgroup MSC_Device Device
* @{ */
bool tud_msc_set_sense(uint8_t lun, uint8_t sense_key, uint8_t add_sense_code, uint8_t add_sense_qualifier);
//--------------------------------------------------------------------+
// Application Callbacks (WEAK is optional)
//--------------------------------------------------------------------+
/**
* Invoked when received \ref SCSI_CMD_READ_10 command
* \param[in] lun Logical unit number
* \param[in] lba Logical Block Address to be read
* \param[in] offset Byte offset from LBA
* \param[out] buffer Buffer which application need to update with the response data.
* \param[in] bufsize Requested bytes
*
* \return Number of byte read, if it is less than requested bytes by \a \b bufsize. Tinyusb will transfer
* this amount first and invoked this again for remaining data.
*
* \retval zero Indicate application is not ready yet to response e.g disk I/O is not complete.
* tinyusb will invoke this callback with the same parameters again some time later.
*
* \retval negative Indicate error e.g reading disk I/O. tinyusb will \b STALL the corresponding
* endpoint and return failed status in command status wrapper phase.
*/
int32_t tud_msc_read10_cb (uint8_t lun, uint32_t lba, uint32_t offset, void* buffer, uint32_t bufsize);
/**
* Invoked when received \ref SCSI_CMD_WRITE_10 command
* \param[in] lun Logical unit number
* \param[in] lba Logical Block Address to be write
* \param[in] offset Byte offset from LBA
* \param[out] buffer Buffer which holds written data.
* \param[in] bufsize Requested bytes
*
* \return Number of byte written, if it is less than requested bytes by \a \b bufsize. Tinyusb will proceed with
* other work and invoked this again with adjusted parameters.
*
* \retval zero Indicate application is not ready yet e.g disk I/O is not complete.
* Tinyusb will invoke this callback with the same parameters again some time later.
*
* \retval negative Indicate error writing disk I/O. Tinyusb will \b STALL the corresponding
* endpoint and return failed status in command status wrapper phase.
*/
int32_t tud_msc_write10_cb (uint8_t lun, uint32_t lba, uint32_t offset, uint8_t* buffer, uint32_t bufsize);
// Invoked when received SCSI_CMD_INQUIRY
// Application fill vendor id, product id and revision with string up to 8, 16, 4 characters respectively
void tud_msc_inquiry_cb(uint8_t lun, uint8_t vendor_id[8], uint8_t product_id[16], uint8_t product_rev[4]);
// Invoked when received Test Unit Ready command.
// return true allowing host to read/write this LUN e.g SD card inserted
bool tud_msc_test_unit_ready_cb(uint8_t lun);
// Invoked when received SCSI_CMD_READ_CAPACITY_10 and SCSI_CMD_READ_FORMAT_CAPACITY to determine the disk size
// Application update block count and block size
void tud_msc_capacity_cb(uint8_t lun, uint32_t* block_count, uint16_t* block_size);
/**
* Invoked when received an SCSI command not in built-in list below.
* - READ_CAPACITY10, READ_FORMAT_CAPACITY, INQUIRY, TEST_UNIT_READY, START_STOP_UNIT, MODE_SENSE6, REQUEST_SENSE
* - READ10 and WRITE10 has their own callbacks
*
* \param[in] lun Logical unit number
* \param[in] scsi_cmd SCSI command contents which application must examine to response accordingly
* \param[out] buffer Buffer for SCSI Data Stage.
* - For INPUT: application must fill this with response.
* - For OUTPUT it holds the Data from host
* \param[in] bufsize Buffer's length.
*
* \return Actual bytes processed, can be zero for no-data command.
* \retval negative Indicate error e.g unsupported command, tinyusb will \b STALL the corresponding
* endpoint and return failed status in command status wrapper phase.
*/
int32_t tud_msc_scsi_cb (uint8_t lun, uint8_t const scsi_cmd[16], void* buffer, uint16_t bufsize);
/*------------- Optional callbacks -------------*/
// Invoked when received GET_MAX_LUN request, required for multiple LUNs implementation
TU_ATTR_WEAK uint8_t tud_msc_get_maxlun_cb(void);
// Invoked when received Start Stop Unit command
// - Start = 0 : stopped power mode, if load_eject = 1 : unload disk storage
// - Start = 1 : active mode, if load_eject = 1 : load disk storage
TU_ATTR_WEAK bool tud_msc_start_stop_cb(uint8_t lun, uint8_t power_condition, bool start, bool load_eject);
// Invoked when Read10 command is complete
TU_ATTR_WEAK void tud_msc_read10_complete_cb(uint8_t lun);
// Invoke when Write10 command is complete, can be used to flush flash caching
TU_ATTR_WEAK void tud_msc_write10_complete_cb(uint8_t lun);
// Invoked when command in tud_msc_scsi_cb is complete
TU_ATTR_WEAK void tud_msc_scsi_complete_cb(uint8_t lun, uint8_t const scsi_cmd[16]);
// Hook to make a mass storage device read-only. TODO remove
TU_ATTR_WEAK bool tud_msc_is_writable_cb(uint8_t lun);
/** @} */
/** @} */
//--------------------------------------------------------------------+
// Internal Class Driver API
//--------------------------------------------------------------------+
void mscd_init (void);
void mscd_reset (uint8_t rhport);
bool mscd_open (uint8_t rhport, tusb_desc_interface_t const * itf_desc, uint16_t *p_length);
bool mscd_control_request (uint8_t rhport, tusb_control_request_t const * p_request);
bool mscd_control_complete (uint8_t rhport, tusb_control_request_t const * p_request);
bool mscd_xfer_cb (uint8_t rhport, uint8_t ep_addr, xfer_result_t event, uint32_t xferred_bytes);
#ifdef __cplusplus
}
#endif
#endif /* _TUSB_MSC_DEVICE_H_ */
/*
* The MIT License (MIT)
*
* Copyright (c) 2019 Ha Thach (tinyusb.org)
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*
* This file is part of the TinyUSB stack.
*/
#ifndef _TUSB_MSC_DEVICE_H_
#define _TUSB_MSC_DEVICE_H_
#include "common/tusb_common.h"
#include "device/usbd.h"
#include "msc.h"
#ifdef __cplusplus
extern "C" {
#endif
//--------------------------------------------------------------------+
// Class Driver Configuration
//--------------------------------------------------------------------+
TU_VERIFY_STATIC(CFG_TUD_MSC_BUFSIZE < UINT16_MAX, "Size is not correct");
#ifndef CFG_TUD_MSC_BUFSIZE
#error CFG_TUD_MSC_BUFSIZE must be defined, value of a block size should work well, the more the better
#endif
/** \addtogroup ClassDriver_MSC
* @{
* \defgroup MSC_Device Device
* @{ */
bool tud_msc_set_sense(uint8_t lun, uint8_t sense_key, uint8_t add_sense_code, uint8_t add_sense_qualifier);
//--------------------------------------------------------------------+
// Application Callbacks (WEAK is optional)
//--------------------------------------------------------------------+
/**
* Invoked when received \ref SCSI_CMD_READ_10 command
* \param[in] lun Logical unit number
* \param[in] lba Logical Block Address to be read
* \param[in] offset Byte offset from LBA
* \param[out] buffer Buffer which application need to update with the response data.
* \param[in] bufsize Requested bytes
*
* \return Number of byte read, if it is less than requested bytes by \a \b bufsize. Tinyusb will transfer
* this amount first and invoked this again for remaining data.
*
* \retval zero Indicate application is not ready yet to response e.g disk I/O is not complete.
* tinyusb will invoke this callback with the same parameters again some time later.
*
* \retval negative Indicate error e.g reading disk I/O. tinyusb will \b STALL the corresponding
* endpoint and return failed status in command status wrapper phase.
*/
int32_t tud_msc_read10_cb (uint8_t lun, uint32_t lba, uint32_t offset, void* buffer, uint32_t bufsize);
/**
* Invoked when received \ref SCSI_CMD_WRITE_10 command
* \param[in] lun Logical unit number
* \param[in] lba Logical Block Address to be write
* \param[in] offset Byte offset from LBA
* \param[out] buffer Buffer which holds written data.
* \param[in] bufsize Requested bytes
*
* \return Number of byte written, if it is less than requested bytes by \a \b bufsize. Tinyusb will proceed with
* other work and invoked this again with adjusted parameters.
*
* \retval zero Indicate application is not ready yet e.g disk I/O is not complete.
* Tinyusb will invoke this callback with the same parameters again some time later.
*
* \retval negative Indicate error writing disk I/O. Tinyusb will \b STALL the corresponding
* endpoint and return failed status in command status wrapper phase.
*/
int32_t tud_msc_write10_cb (uint8_t lun, uint32_t lba, uint32_t offset, uint8_t* buffer, uint32_t bufsize);
// Invoked when received SCSI_CMD_INQUIRY
// Application fill vendor id, product id and revision with string up to 8, 16, 4 characters respectively
void tud_msc_inquiry_cb(uint8_t lun, uint8_t vendor_id[8], uint8_t product_id[16], uint8_t product_rev[4]);
// Invoked when received Test Unit Ready command.
// return true allowing host to read/write this LUN e.g SD card inserted
bool tud_msc_test_unit_ready_cb(uint8_t lun);
// Invoked when received SCSI_CMD_READ_CAPACITY_10 and SCSI_CMD_READ_FORMAT_CAPACITY to determine the disk size
// Application update block count and block size
void tud_msc_capacity_cb(uint8_t lun, uint32_t* block_count, uint16_t* block_size);
/**
* Invoked when received an SCSI command not in built-in list below.
* - READ_CAPACITY10, READ_FORMAT_CAPACITY, INQUIRY, TEST_UNIT_READY, START_STOP_UNIT, MODE_SENSE6, REQUEST_SENSE
* - READ10 and WRITE10 has their own callbacks
*
* \param[in] lun Logical unit number
* \param[in] scsi_cmd SCSI command contents which application must examine to response accordingly
* \param[out] buffer Buffer for SCSI Data Stage.
* - For INPUT: application must fill this with response.
* - For OUTPUT it holds the Data from host
* \param[in] bufsize Buffer's length.
*
* \return Actual bytes processed, can be zero for no-data command.
* \retval negative Indicate error e.g unsupported command, tinyusb will \b STALL the corresponding
* endpoint and return failed status in command status wrapper phase.
*/
int32_t tud_msc_scsi_cb (uint8_t lun, uint8_t const scsi_cmd[16], void* buffer, uint16_t bufsize);
/*------------- Optional callbacks -------------*/
// Invoked when received GET_MAX_LUN request, required for multiple LUNs implementation
TU_ATTR_WEAK uint8_t tud_msc_get_maxlun_cb(void);
// Invoked when received Start Stop Unit command
// - Start = 0 : stopped power mode, if load_eject = 1 : unload disk storage
// - Start = 1 : active mode, if load_eject = 1 : load disk storage
TU_ATTR_WEAK bool tud_msc_start_stop_cb(uint8_t lun, uint8_t power_condition, bool start, bool load_eject);
// Invoked when Read10 command is complete
TU_ATTR_WEAK void tud_msc_read10_complete_cb(uint8_t lun);
// Invoke when Write10 command is complete, can be used to flush flash caching
TU_ATTR_WEAK void tud_msc_write10_complete_cb(uint8_t lun);
// Invoked when command in tud_msc_scsi_cb is complete
TU_ATTR_WEAK void tud_msc_scsi_complete_cb(uint8_t lun, uint8_t const scsi_cmd[16]);
// Hook to make a mass storage device read-only. TODO remove
TU_ATTR_WEAK bool tud_msc_is_writable_cb(uint8_t lun);
/** @} */
/** @} */
//--------------------------------------------------------------------+
// Internal Class Driver API
//--------------------------------------------------------------------+
void mscd_init (void);
void mscd_reset (uint8_t rhport);
bool mscd_open (uint8_t rhport, tusb_desc_interface_t const * itf_desc, uint16_t *p_length);
bool mscd_control_request (uint8_t rhport, tusb_control_request_t const * p_request);
bool mscd_control_complete (uint8_t rhport, tusb_control_request_t const * p_request);
bool mscd_xfer_cb (uint8_t rhport, uint8_t ep_addr, xfer_result_t event, uint32_t xferred_bytes);
#ifdef __cplusplus
}
#endif
#endif /* _TUSB_MSC_DEVICE_H_ */
+413 -413
View File
@@ -1,413 +1,413 @@
/*
* The MIT License (MIT)
*
* Copyright (c) 2019 Ha Thach (tinyusb.org)
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*
* This file is part of the TinyUSB stack.
*/
#include "tusb_option.h"
#if TUSB_OPT_HOST_ENABLED & CFG_TUH_MSC
//--------------------------------------------------------------------+
// INCLUDE
//--------------------------------------------------------------------+
#include "common/tusb_common.h"
#include "msc_host.h"
//--------------------------------------------------------------------+
// MACRO CONSTANT TYPEDEF
//--------------------------------------------------------------------+
CFG_TUSB_MEM_SECTION static msch_interface_t msch_data[CFG_TUSB_HOST_DEVICE_MAX];
//------------- Initalization Data -------------//
static osal_semaphore_def_t msch_sem_def;
static osal_semaphore_t msch_sem_hdl;
// buffer used to read scsi information when mounted, largest response data currently is inquiry
CFG_TUSB_MEM_SECTION TU_ATTR_ALIGNED(4) static uint8_t msch_buffer[sizeof(scsi_inquiry_resp_t)];
//--------------------------------------------------------------------+
// INTERNAL OBJECT & FUNCTION DECLARATION
//--------------------------------------------------------------------+
//--------------------------------------------------------------------+
// PUBLIC API
//--------------------------------------------------------------------+
bool tuh_msc_is_mounted(uint8_t dev_addr)
{
return tuh_device_is_configured(dev_addr) && // is configured can be omitted
msch_data[dev_addr-1].is_initialized;
}
bool tuh_msc_is_busy(uint8_t dev_addr)
{
return msch_data[dev_addr-1].is_initialized &&
hcd_edpt_busy(dev_addr, msch_data[dev_addr-1].ep_in);
}
uint8_t const* tuh_msc_get_vendor_name(uint8_t dev_addr)
{
return msch_data[dev_addr-1].is_initialized ? msch_data[dev_addr-1].vendor_id : NULL;
}
uint8_t const* tuh_msc_get_product_name(uint8_t dev_addr)
{
return msch_data[dev_addr-1].is_initialized ? msch_data[dev_addr-1].product_id : NULL;
}
tusb_error_t tuh_msc_get_capacity(uint8_t dev_addr, uint32_t* p_last_lba, uint32_t* p_block_size)
{
if ( !msch_data[dev_addr-1].is_initialized ) return TUSB_ERROR_MSCH_DEVICE_NOT_MOUNTED;
TU_ASSERT(p_last_lba != NULL && p_block_size != NULL, TUSB_ERROR_INVALID_PARA);
(*p_last_lba) = msch_data[dev_addr-1].last_lba;
(*p_block_size) = (uint32_t) msch_data[dev_addr-1].block_size;
return TUSB_ERROR_NONE;
}
//--------------------------------------------------------------------+
// PUBLIC API: SCSI COMMAND
//--------------------------------------------------------------------+
static inline void msc_cbw_add_signature(msc_cbw_t *p_cbw, uint8_t lun)
{
p_cbw->signature = MSC_CBW_SIGNATURE;
p_cbw->tag = 0xCAFECAFE;
p_cbw->lun = lun;
}
static tusb_error_t msch_command_xfer(uint8_t dev_addr, msch_interface_t * p_msch, void* p_buffer)
{
if ( NULL != p_buffer)
{ // there is data phase
if (p_msch->cbw.dir & TUSB_DIR_IN_MASK)
{
TU_ASSERT( hcd_pipe_xfer(dev_addr, p_msch->ep_out, (uint8_t*) &p_msch->cbw, sizeof(msc_cbw_t), false), TUSB_ERROR_FAILED );
TU_ASSERT( hcd_pipe_queue_xfer(dev_addr, p_msch->ep_in , p_buffer, p_msch->cbw.total_bytes), TUSB_ERROR_FAILED );
}else
{
TU_ASSERT( hcd_pipe_queue_xfer(dev_addr, p_msch->ep_out, (uint8_t*) &p_msch->cbw, sizeof(msc_cbw_t)), TUSB_ERROR_FAILED );
TU_ASSERT( hcd_pipe_xfer(dev_addr, p_msch->ep_out , p_buffer, p_msch->cbw.total_bytes, false), TUSB_ERROR_FAILED );
}
}
TU_ASSERT( hcd_pipe_xfer(dev_addr, p_msch->ep_in , (uint8_t*) &p_msch->csw, sizeof(msc_csw_t), true), TUSB_ERROR_FAILED);
return TUSB_ERROR_NONE;
}
tusb_error_t tusbh_msc_inquiry(uint8_t dev_addr, uint8_t lun, uint8_t *p_data)
{
msch_interface_t* p_msch = &msch_data[dev_addr-1];
//------------- Command Block Wrapper -------------//
msc_cbw_add_signature(&p_msch->cbw, lun);
p_msch->cbw.total_bytes = sizeof(scsi_inquiry_resp_t);
p_msch->cbw.dir = TUSB_DIR_IN_MASK;
p_msch->cbw.cmd_len = sizeof(scsi_inquiry_t);
//------------- SCSI command -------------//
scsi_inquiry_t cmd_inquiry =
{
.cmd_code = SCSI_CMD_INQUIRY,
.alloc_length = sizeof(scsi_inquiry_resp_t)
};
memcpy(p_msch->cbw.command, &cmd_inquiry, p_msch->cbw.cmd_len);
TU_ASSERT_ERR ( msch_command_xfer(dev_addr, p_msch, p_data) );
return TUSB_ERROR_NONE;
}
tusb_error_t tusbh_msc_read_capacity10(uint8_t dev_addr, uint8_t lun, uint8_t *p_data)
{
msch_interface_t* p_msch = &msch_data[dev_addr-1];
//------------- Command Block Wrapper -------------//
msc_cbw_add_signature(&p_msch->cbw, lun);
p_msch->cbw.total_bytes = sizeof(scsi_read_capacity10_resp_t);
p_msch->cbw.dir = TUSB_DIR_IN_MASK;
p_msch->cbw.cmd_len = sizeof(scsi_read_capacity10_t);
//------------- SCSI command -------------//
scsi_read_capacity10_t cmd_read_capacity10 =
{
.cmd_code = SCSI_CMD_READ_CAPACITY_10,
.lba = 0,
.partial_medium_indicator = 0
};
memcpy(p_msch->cbw.command, &cmd_read_capacity10, p_msch->cbw.cmd_len);
TU_ASSERT_ERR ( msch_command_xfer(dev_addr, p_msch, p_data) );
return TUSB_ERROR_NONE;
}
tusb_error_t tuh_msc_request_sense(uint8_t dev_addr, uint8_t lun, uint8_t *p_data)
{
(void) lun; // TODO [MSCH] multiple lun support
msch_interface_t* p_msch = &msch_data[dev_addr-1];
//------------- Command Block Wrapper -------------//
p_msch->cbw.total_bytes = 18;
p_msch->cbw.dir = TUSB_DIR_IN_MASK;
p_msch->cbw.cmd_len = sizeof(scsi_request_sense_t);
//------------- SCSI command -------------//
scsi_request_sense_t cmd_request_sense =
{
.cmd_code = SCSI_CMD_REQUEST_SENSE,
.alloc_length = 18
};
memcpy(p_msch->cbw.command, &cmd_request_sense, p_msch->cbw.cmd_len);
TU_ASSERT_ERR ( msch_command_xfer(dev_addr, p_msch, p_data) );
return TUSB_ERROR_NONE;
}
tusb_error_t tuh_msc_test_unit_ready(uint8_t dev_addr, uint8_t lun, msc_csw_t * p_csw)
{
msch_interface_t* p_msch = &msch_data[dev_addr-1];
//------------- Command Block Wrapper -------------//
msc_cbw_add_signature(&p_msch->cbw, lun);
p_msch->cbw.total_bytes = 0; // Number of bytes
p_msch->cbw.dir = TUSB_DIR_OUT;
p_msch->cbw.cmd_len = sizeof(scsi_test_unit_ready_t);
//------------- SCSI command -------------//
scsi_test_unit_ready_t cmd_test_unit_ready =
{
.cmd_code = SCSI_CMD_TEST_UNIT_READY,
.lun = lun // according to wiki
};
memcpy(p_msch->cbw.command, &cmd_test_unit_ready, p_msch->cbw.cmd_len);
// TODO MSCH refractor test uinit ready
TU_ASSERT( hcd_pipe_xfer(dev_addr, p_msch->ep_out, (uint8_t*) &p_msch->cbw, sizeof(msc_cbw_t), false), TUSB_ERROR_FAILED );
TU_ASSERT( hcd_pipe_xfer(dev_addr, p_msch->ep_in , (uint8_t*) p_csw, sizeof(msc_csw_t), true), TUSB_ERROR_FAILED );
return TUSB_ERROR_NONE;
}
tusb_error_t tuh_msc_read10(uint8_t dev_addr, uint8_t lun, void * p_buffer, uint32_t lba, uint16_t block_count)
{
msch_interface_t* p_msch = &msch_data[dev_addr-1];
//------------- Command Block Wrapper -------------//
msc_cbw_add_signature(&p_msch->cbw, lun);
p_msch->cbw.total_bytes = p_msch->block_size*block_count; // Number of bytes
p_msch->cbw.dir = TUSB_DIR_IN_MASK;
p_msch->cbw.cmd_len = sizeof(scsi_read10_t);
//------------- SCSI command -------------//
scsi_read10_t cmd_read10 =
{
.cmd_code = SCSI_CMD_READ_10,
.lba = tu_htonl(lba),
.block_count = tu_htons(block_count)
};
memcpy(p_msch->cbw.command, &cmd_read10, p_msch->cbw.cmd_len);
TU_ASSERT_ERR ( msch_command_xfer(dev_addr, p_msch, p_buffer));
return TUSB_ERROR_NONE;
}
tusb_error_t tuh_msc_write10(uint8_t dev_addr, uint8_t lun, void const * p_buffer, uint32_t lba, uint16_t block_count)
{
msch_interface_t* p_msch = &msch_data[dev_addr-1];
//------------- Command Block Wrapper -------------//
msc_cbw_add_signature(&p_msch->cbw, lun);
p_msch->cbw.total_bytes = p_msch->block_size*block_count; // Number of bytes
p_msch->cbw.dir = TUSB_DIR_OUT;
p_msch->cbw.cmd_len = sizeof(scsi_write10_t);
//------------- SCSI command -------------//
scsi_write10_t cmd_write10 =
{
.cmd_code = SCSI_CMD_WRITE_10,
.lba = tu_htonl(lba),
.block_count = tu_htons(block_count)
};
memcpy(p_msch->cbw.command, &cmd_write10, p_msch->cbw.cmd_len);
TU_ASSERT_ERR ( msch_command_xfer(dev_addr, p_msch, (void*) p_buffer));
return TUSB_ERROR_NONE;
}
//--------------------------------------------------------------------+
// CLASS-USBH API (don't require to verify parameters)
//--------------------------------------------------------------------+
void msch_init(void)
{
tu_memclr(msch_data, sizeof(msch_interface_t)*CFG_TUSB_HOST_DEVICE_MAX);
msch_sem_hdl = osal_semaphore_create(&msch_sem_def);
}
bool msch_open(uint8_t rhport, uint8_t dev_addr, tusb_desc_interface_t const *itf_desc, uint16_t *p_length)
{
TU_VERIFY (MSC_SUBCLASS_SCSI == itf_desc->bInterfaceSubClass &&
MSC_PROTOCOL_BOT == itf_desc->bInterfaceProtocol);
msch_interface_t* p_msc = &msch_data[dev_addr-1];
//------------- Open Data Pipe -------------//
tusb_desc_endpoint_t const * ep_desc = (tusb_desc_endpoint_t const *) tu_desc_next(itf_desc);
for(uint32_t i=0; i<2; i++)
{
TU_ASSERT(TUSB_DESC_ENDPOINT == ep_desc->bDescriptorType);
TU_ASSERT(TUSB_XFER_BULK == ep_desc->bmAttributes.xfer);
TU_ASSERT(hcd_edpt_open(rhport, dev_addr, ep_desc));
if ( tu_edpt_dir(ep_desc->bEndpointAddress) == TUSB_DIR_IN )
{
p_msc->ep_in = ep_desc->bEndpointAddress;
}else
{
p_msc->ep_out = ep_desc->bEndpointAddress;
}
ep_desc = (tusb_desc_endpoint_t const *) tu_desc_next(ep_desc);
}
p_msc->itf_numr = itf_desc->bInterfaceNumber;
(*p_length) += sizeof(tusb_desc_interface_t) + 2*sizeof(tusb_desc_endpoint_t);
//------------- Get Max Lun -------------//
tusb_control_request_t request = {
.bmRequestType_bit = { .recipient = TUSB_REQ_RCPT_INTERFACE, .type = TUSB_REQ_TYPE_CLASS, .direction = TUSB_DIR_IN },
.bRequest = MSC_REQ_GET_MAX_LUN,
.wValue = 0,
.wIndex = p_msc->itf_numr,
.wLength = 1
};
// TODO STALL means zero
TU_ASSERT( usbh_control_xfer( dev_addr, &request, msch_buffer ) );
p_msc->max_lun = msch_buffer[0];
#if 0
//------------- Reset -------------//
request = (tusb_control_request_t) {
.bmRequestType_bit = { .recipient = TUSB_REQ_RCPT_INTERFACE, .type = TUSB_REQ_TYPE_CLASS, .direction = TUSB_DIR_OUT },
.bRequest = MSC_REQ_RESET,
.wValue = 0,
.wIndex = p_msc->itf_numr,
.wLength = 0
};
TU_ASSERT( usbh_control_xfer( dev_addr, &request, NULL ) );
#endif
enum { SCSI_XFER_TIMEOUT = 2000 };
//------------- SCSI Inquiry -------------//
tusbh_msc_inquiry(dev_addr, 0, msch_buffer);
TU_ASSERT( osal_semaphore_wait(msch_sem_hdl, SCSI_XFER_TIMEOUT) );
memcpy(p_msc->vendor_id , ((scsi_inquiry_resp_t*) msch_buffer)->vendor_id , 8);
memcpy(p_msc->product_id, ((scsi_inquiry_resp_t*) msch_buffer)->product_id, 16);
//------------- SCSI Read Capacity 10 -------------//
tusbh_msc_read_capacity10(dev_addr, 0, msch_buffer);
TU_ASSERT( osal_semaphore_wait(msch_sem_hdl, SCSI_XFER_TIMEOUT));
// NOTE: my toshiba thumb-drive stall the first Read Capacity and require the sequence
// Read Capacity --> Stalled --> Clear Stall --> Request Sense --> Read Capacity (2) to work
if ( hcd_edpt_stalled(dev_addr, p_msc->ep_in) )
{
// clear stall TODO abstract clear stall function
request = (tusb_control_request_t) {
.bmRequestType_bit = { .recipient = TUSB_REQ_RCPT_ENDPOINT, .type = TUSB_REQ_TYPE_STANDARD, .direction = TUSB_DIR_OUT },
.bRequest = TUSB_REQ_CLEAR_FEATURE,
.wValue = 0,
.wIndex = p_msc->ep_in,
.wLength = 0
};
TU_ASSERT(usbh_control_xfer( dev_addr, &request, NULL ));
hcd_edpt_clear_stall(dev_addr, p_msc->ep_in);
TU_ASSERT( osal_semaphore_wait(msch_sem_hdl, SCSI_XFER_TIMEOUT) ); // wait for SCSI status
//------------- SCSI Request Sense -------------//
(void) tuh_msc_request_sense(dev_addr, 0, msch_buffer);
TU_ASSERT(osal_semaphore_wait(msch_sem_hdl, SCSI_XFER_TIMEOUT));
//------------- Re-read SCSI Read Capactity -------------//
tusbh_msc_read_capacity10(dev_addr, 0, msch_buffer);
TU_ASSERT(osal_semaphore_wait(msch_sem_hdl, SCSI_XFER_TIMEOUT));
}
p_msc->last_lba = tu_ntohl( ((scsi_read_capacity10_resp_t*)msch_buffer)->last_lba );
p_msc->block_size = (uint16_t) tu_ntohl( ((scsi_read_capacity10_resp_t*)msch_buffer)->block_size );
p_msc->is_initialized = true;
tuh_msc_mounted_cb(dev_addr);
return true;
}
void msch_isr(uint8_t dev_addr, uint8_t ep_addr, xfer_result_t event, uint32_t xferred_bytes)
{
msch_interface_t* p_msc = &msch_data[dev_addr-1];
if ( ep_addr == p_msc->ep_in )
{
if (p_msc->is_initialized)
{
tuh_msc_isr(dev_addr, event, xferred_bytes);
}else
{ // still initializing under open subtask
osal_semaphore_post(msch_sem_hdl, true);
}
}
}
void msch_close(uint8_t dev_addr)
{
tu_memclr(&msch_data[dev_addr-1], sizeof(msch_interface_t));
osal_semaphore_reset(msch_sem_hdl);
tuh_msc_unmounted_cb(dev_addr); // invoke Application Callback
}
//--------------------------------------------------------------------+
// INTERNAL & HELPER
//--------------------------------------------------------------------+
#endif
/*
* The MIT License (MIT)
*
* Copyright (c) 2019 Ha Thach (tinyusb.org)
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*
* This file is part of the TinyUSB stack.
*/
#include "tusb_option.h"
#if TUSB_OPT_HOST_ENABLED & CFG_TUH_MSC
//--------------------------------------------------------------------+
// INCLUDE
//--------------------------------------------------------------------+
#include "common/tusb_common.h"
#include "msc_host.h"
//--------------------------------------------------------------------+
// MACRO CONSTANT TYPEDEF
//--------------------------------------------------------------------+
CFG_TUSB_MEM_SECTION static msch_interface_t msch_data[CFG_TUSB_HOST_DEVICE_MAX];
//------------- Initalization Data -------------//
static osal_semaphore_def_t msch_sem_def;
static osal_semaphore_t msch_sem_hdl;
// buffer used to read scsi information when mounted, largest response data currently is inquiry
CFG_TUSB_MEM_SECTION TU_ATTR_ALIGNED(4) static uint8_t msch_buffer[sizeof(scsi_inquiry_resp_t)];
//--------------------------------------------------------------------+
// INTERNAL OBJECT & FUNCTION DECLARATION
//--------------------------------------------------------------------+
//--------------------------------------------------------------------+
// PUBLIC API
//--------------------------------------------------------------------+
bool tuh_msc_is_mounted(uint8_t dev_addr)
{
return tuh_device_is_configured(dev_addr) && // is configured can be omitted
msch_data[dev_addr-1].is_initialized;
}
bool tuh_msc_is_busy(uint8_t dev_addr)
{
return msch_data[dev_addr-1].is_initialized &&
hcd_edpt_busy(dev_addr, msch_data[dev_addr-1].ep_in);
}
uint8_t const* tuh_msc_get_vendor_name(uint8_t dev_addr)
{
return msch_data[dev_addr-1].is_initialized ? msch_data[dev_addr-1].vendor_id : NULL;
}
uint8_t const* tuh_msc_get_product_name(uint8_t dev_addr)
{
return msch_data[dev_addr-1].is_initialized ? msch_data[dev_addr-1].product_id : NULL;
}
tusb_error_t tuh_msc_get_capacity(uint8_t dev_addr, uint32_t* p_last_lba, uint32_t* p_block_size)
{
if ( !msch_data[dev_addr-1].is_initialized ) return TUSB_ERROR_MSCH_DEVICE_NOT_MOUNTED;
TU_ASSERT(p_last_lba != NULL && p_block_size != NULL, TUSB_ERROR_INVALID_PARA);
(*p_last_lba) = msch_data[dev_addr-1].last_lba;
(*p_block_size) = (uint32_t) msch_data[dev_addr-1].block_size;
return TUSB_ERROR_NONE;
}
//--------------------------------------------------------------------+
// PUBLIC API: SCSI COMMAND
//--------------------------------------------------------------------+
static inline void msc_cbw_add_signature(msc_cbw_t *p_cbw, uint8_t lun)
{
p_cbw->signature = MSC_CBW_SIGNATURE;
p_cbw->tag = 0xCAFECAFE;
p_cbw->lun = lun;
}
static tusb_error_t msch_command_xfer(uint8_t dev_addr, msch_interface_t * p_msch, void* p_buffer)
{
if ( NULL != p_buffer)
{ // there is data phase
if (p_msch->cbw.dir & TUSB_DIR_IN_MASK)
{
TU_ASSERT( hcd_pipe_xfer(dev_addr, p_msch->ep_out, (uint8_t*) &p_msch->cbw, sizeof(msc_cbw_t), false), TUSB_ERROR_FAILED );
TU_ASSERT( hcd_pipe_queue_xfer(dev_addr, p_msch->ep_in , p_buffer, p_msch->cbw.total_bytes), TUSB_ERROR_FAILED );
}else
{
TU_ASSERT( hcd_pipe_queue_xfer(dev_addr, p_msch->ep_out, (uint8_t*) &p_msch->cbw, sizeof(msc_cbw_t)), TUSB_ERROR_FAILED );
TU_ASSERT( hcd_pipe_xfer(dev_addr, p_msch->ep_out , p_buffer, p_msch->cbw.total_bytes, false), TUSB_ERROR_FAILED );
}
}
TU_ASSERT( hcd_pipe_xfer(dev_addr, p_msch->ep_in , (uint8_t*) &p_msch->csw, sizeof(msc_csw_t), true), TUSB_ERROR_FAILED);
return TUSB_ERROR_NONE;
}
tusb_error_t tusbh_msc_inquiry(uint8_t dev_addr, uint8_t lun, uint8_t *p_data)
{
msch_interface_t* p_msch = &msch_data[dev_addr-1];
//------------- Command Block Wrapper -------------//
msc_cbw_add_signature(&p_msch->cbw, lun);
p_msch->cbw.total_bytes = sizeof(scsi_inquiry_resp_t);
p_msch->cbw.dir = TUSB_DIR_IN_MASK;
p_msch->cbw.cmd_len = sizeof(scsi_inquiry_t);
//------------- SCSI command -------------//
scsi_inquiry_t cmd_inquiry =
{
.cmd_code = SCSI_CMD_INQUIRY,
.alloc_length = sizeof(scsi_inquiry_resp_t)
};
memcpy(p_msch->cbw.command, &cmd_inquiry, p_msch->cbw.cmd_len);
TU_ASSERT_ERR ( msch_command_xfer(dev_addr, p_msch, p_data) );
return TUSB_ERROR_NONE;
}
tusb_error_t tusbh_msc_read_capacity10(uint8_t dev_addr, uint8_t lun, uint8_t *p_data)
{
msch_interface_t* p_msch = &msch_data[dev_addr-1];
//------------- Command Block Wrapper -------------//
msc_cbw_add_signature(&p_msch->cbw, lun);
p_msch->cbw.total_bytes = sizeof(scsi_read_capacity10_resp_t);
p_msch->cbw.dir = TUSB_DIR_IN_MASK;
p_msch->cbw.cmd_len = sizeof(scsi_read_capacity10_t);
//------------- SCSI command -------------//
scsi_read_capacity10_t cmd_read_capacity10 =
{
.cmd_code = SCSI_CMD_READ_CAPACITY_10,
.lba = 0,
.partial_medium_indicator = 0
};
memcpy(p_msch->cbw.command, &cmd_read_capacity10, p_msch->cbw.cmd_len);
TU_ASSERT_ERR ( msch_command_xfer(dev_addr, p_msch, p_data) );
return TUSB_ERROR_NONE;
}
tusb_error_t tuh_msc_request_sense(uint8_t dev_addr, uint8_t lun, uint8_t *p_data)
{
(void) lun; // TODO [MSCH] multiple lun support
msch_interface_t* p_msch = &msch_data[dev_addr-1];
//------------- Command Block Wrapper -------------//
p_msch->cbw.total_bytes = 18;
p_msch->cbw.dir = TUSB_DIR_IN_MASK;
p_msch->cbw.cmd_len = sizeof(scsi_request_sense_t);
//------------- SCSI command -------------//
scsi_request_sense_t cmd_request_sense =
{
.cmd_code = SCSI_CMD_REQUEST_SENSE,
.alloc_length = 18
};
memcpy(p_msch->cbw.command, &cmd_request_sense, p_msch->cbw.cmd_len);
TU_ASSERT_ERR ( msch_command_xfer(dev_addr, p_msch, p_data) );
return TUSB_ERROR_NONE;
}
tusb_error_t tuh_msc_test_unit_ready(uint8_t dev_addr, uint8_t lun, msc_csw_t * p_csw)
{
msch_interface_t* p_msch = &msch_data[dev_addr-1];
//------------- Command Block Wrapper -------------//
msc_cbw_add_signature(&p_msch->cbw, lun);
p_msch->cbw.total_bytes = 0; // Number of bytes
p_msch->cbw.dir = TUSB_DIR_OUT;
p_msch->cbw.cmd_len = sizeof(scsi_test_unit_ready_t);
//------------- SCSI command -------------//
scsi_test_unit_ready_t cmd_test_unit_ready =
{
.cmd_code = SCSI_CMD_TEST_UNIT_READY,
.lun = lun // according to wiki
};
memcpy(p_msch->cbw.command, &cmd_test_unit_ready, p_msch->cbw.cmd_len);
// TODO MSCH refractor test uinit ready
TU_ASSERT( hcd_pipe_xfer(dev_addr, p_msch->ep_out, (uint8_t*) &p_msch->cbw, sizeof(msc_cbw_t), false), TUSB_ERROR_FAILED );
TU_ASSERT( hcd_pipe_xfer(dev_addr, p_msch->ep_in , (uint8_t*) p_csw, sizeof(msc_csw_t), true), TUSB_ERROR_FAILED );
return TUSB_ERROR_NONE;
}
tusb_error_t tuh_msc_read10(uint8_t dev_addr, uint8_t lun, void * p_buffer, uint32_t lba, uint16_t block_count)
{
msch_interface_t* p_msch = &msch_data[dev_addr-1];
//------------- Command Block Wrapper -------------//
msc_cbw_add_signature(&p_msch->cbw, lun);
p_msch->cbw.total_bytes = p_msch->block_size*block_count; // Number of bytes
p_msch->cbw.dir = TUSB_DIR_IN_MASK;
p_msch->cbw.cmd_len = sizeof(scsi_read10_t);
//------------- SCSI command -------------//
scsi_read10_t cmd_read10 =
{
.cmd_code = SCSI_CMD_READ_10,
.lba = tu_htonl(lba),
.block_count = tu_htons(block_count)
};
memcpy(p_msch->cbw.command, &cmd_read10, p_msch->cbw.cmd_len);
TU_ASSERT_ERR ( msch_command_xfer(dev_addr, p_msch, p_buffer));
return TUSB_ERROR_NONE;
}
tusb_error_t tuh_msc_write10(uint8_t dev_addr, uint8_t lun, void const * p_buffer, uint32_t lba, uint16_t block_count)
{
msch_interface_t* p_msch = &msch_data[dev_addr-1];
//------------- Command Block Wrapper -------------//
msc_cbw_add_signature(&p_msch->cbw, lun);
p_msch->cbw.total_bytes = p_msch->block_size*block_count; // Number of bytes
p_msch->cbw.dir = TUSB_DIR_OUT;
p_msch->cbw.cmd_len = sizeof(scsi_write10_t);
//------------- SCSI command -------------//
scsi_write10_t cmd_write10 =
{
.cmd_code = SCSI_CMD_WRITE_10,
.lba = tu_htonl(lba),
.block_count = tu_htons(block_count)
};
memcpy(p_msch->cbw.command, &cmd_write10, p_msch->cbw.cmd_len);
TU_ASSERT_ERR ( msch_command_xfer(dev_addr, p_msch, (void*) p_buffer));
return TUSB_ERROR_NONE;
}
//--------------------------------------------------------------------+
// CLASS-USBH API (don't require to verify parameters)
//--------------------------------------------------------------------+
void msch_init(void)
{
tu_memclr(msch_data, sizeof(msch_interface_t)*CFG_TUSB_HOST_DEVICE_MAX);
msch_sem_hdl = osal_semaphore_create(&msch_sem_def);
}
bool msch_open(uint8_t rhport, uint8_t dev_addr, tusb_desc_interface_t const *itf_desc, uint16_t *p_length)
{
TU_VERIFY (MSC_SUBCLASS_SCSI == itf_desc->bInterfaceSubClass &&
MSC_PROTOCOL_BOT == itf_desc->bInterfaceProtocol);
msch_interface_t* p_msc = &msch_data[dev_addr-1];
//------------- Open Data Pipe -------------//
tusb_desc_endpoint_t const * ep_desc = (tusb_desc_endpoint_t const *) tu_desc_next(itf_desc);
for(uint32_t i=0; i<2; i++)
{
TU_ASSERT(TUSB_DESC_ENDPOINT == ep_desc->bDescriptorType);
TU_ASSERT(TUSB_XFER_BULK == ep_desc->bmAttributes.xfer);
TU_ASSERT(hcd_edpt_open(rhport, dev_addr, ep_desc));
if ( tu_edpt_dir(ep_desc->bEndpointAddress) == TUSB_DIR_IN )
{
p_msc->ep_in = ep_desc->bEndpointAddress;
}else
{
p_msc->ep_out = ep_desc->bEndpointAddress;
}
ep_desc = (tusb_desc_endpoint_t const *) tu_desc_next(ep_desc);
}
p_msc->itf_numr = itf_desc->bInterfaceNumber;
(*p_length) += sizeof(tusb_desc_interface_t) + 2*sizeof(tusb_desc_endpoint_t);
//------------- Get Max Lun -------------//
tusb_control_request_t request = {
.bmRequestType_bit = { .recipient = TUSB_REQ_RCPT_INTERFACE, .type = TUSB_REQ_TYPE_CLASS, .direction = TUSB_DIR_IN },
.bRequest = MSC_REQ_GET_MAX_LUN,
.wValue = 0,
.wIndex = p_msc->itf_numr,
.wLength = 1
};
// TODO STALL means zero
TU_ASSERT( usbh_control_xfer( dev_addr, &request, msch_buffer ) );
p_msc->max_lun = msch_buffer[0];
#if 0
//------------- Reset -------------//
request = (tusb_control_request_t) {
.bmRequestType_bit = { .recipient = TUSB_REQ_RCPT_INTERFACE, .type = TUSB_REQ_TYPE_CLASS, .direction = TUSB_DIR_OUT },
.bRequest = MSC_REQ_RESET,
.wValue = 0,
.wIndex = p_msc->itf_numr,
.wLength = 0
};
TU_ASSERT( usbh_control_xfer( dev_addr, &request, NULL ) );
#endif
enum { SCSI_XFER_TIMEOUT = 2000 };
//------------- SCSI Inquiry -------------//
tusbh_msc_inquiry(dev_addr, 0, msch_buffer);
TU_ASSERT( osal_semaphore_wait(msch_sem_hdl, SCSI_XFER_TIMEOUT) );
memcpy(p_msc->vendor_id , ((scsi_inquiry_resp_t*) msch_buffer)->vendor_id , 8);
memcpy(p_msc->product_id, ((scsi_inquiry_resp_t*) msch_buffer)->product_id, 16);
//------------- SCSI Read Capacity 10 -------------//
tusbh_msc_read_capacity10(dev_addr, 0, msch_buffer);
TU_ASSERT( osal_semaphore_wait(msch_sem_hdl, SCSI_XFER_TIMEOUT));
// NOTE: my toshiba thumb-drive stall the first Read Capacity and require the sequence
// Read Capacity --> Stalled --> Clear Stall --> Request Sense --> Read Capacity (2) to work
if ( hcd_edpt_stalled(dev_addr, p_msc->ep_in) )
{
// clear stall TODO abstract clear stall function
request = (tusb_control_request_t) {
.bmRequestType_bit = { .recipient = TUSB_REQ_RCPT_ENDPOINT, .type = TUSB_REQ_TYPE_STANDARD, .direction = TUSB_DIR_OUT },
.bRequest = TUSB_REQ_CLEAR_FEATURE,
.wValue = 0,
.wIndex = p_msc->ep_in,
.wLength = 0
};
TU_ASSERT(usbh_control_xfer( dev_addr, &request, NULL ));
hcd_edpt_clear_stall(dev_addr, p_msc->ep_in);
TU_ASSERT( osal_semaphore_wait(msch_sem_hdl, SCSI_XFER_TIMEOUT) ); // wait for SCSI status
//------------- SCSI Request Sense -------------//
(void) tuh_msc_request_sense(dev_addr, 0, msch_buffer);
TU_ASSERT(osal_semaphore_wait(msch_sem_hdl, SCSI_XFER_TIMEOUT));
//------------- Re-read SCSI Read Capactity -------------//
tusbh_msc_read_capacity10(dev_addr, 0, msch_buffer);
TU_ASSERT(osal_semaphore_wait(msch_sem_hdl, SCSI_XFER_TIMEOUT));
}
p_msc->last_lba = tu_ntohl( ((scsi_read_capacity10_resp_t*)msch_buffer)->last_lba );
p_msc->block_size = (uint16_t) tu_ntohl( ((scsi_read_capacity10_resp_t*)msch_buffer)->block_size );
p_msc->is_initialized = true;
tuh_msc_mounted_cb(dev_addr);
return true;
}
void msch_isr(uint8_t dev_addr, uint8_t ep_addr, xfer_result_t event, uint32_t xferred_bytes)
{
msch_interface_t* p_msc = &msch_data[dev_addr-1];
if ( ep_addr == p_msc->ep_in )
{
if (p_msc->is_initialized)
{
tuh_msc_isr(dev_addr, event, xferred_bytes);
}else
{ // still initializing under open subtask
osal_semaphore_post(msch_sem_hdl, true);
}
}
}
void msch_close(uint8_t dev_addr)
{
tu_memclr(&msch_data[dev_addr-1], sizeof(msch_interface_t));
osal_semaphore_reset(msch_sem_hdl);
tuh_msc_unmounted_cb(dev_addr); // invoke Application Callback
}
//--------------------------------------------------------------------+
// INTERNAL & HELPER
//--------------------------------------------------------------------+
#endif
+206 -206
View File
@@ -1,206 +1,206 @@
/*
* The MIT License (MIT)
*
* Copyright (c) 2019 Ha Thach (tinyusb.org)
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*
* This file is part of the TinyUSB stack.
*/
#ifndef _TUSB_MSC_HOST_H_
#define _TUSB_MSC_HOST_H_
#include "common/tusb_common.h"
#include "host/usbh.h"
#include "msc.h"
#ifdef __cplusplus
extern "C" {
#endif
/** \addtogroup ClassDriver_MSC
* @{
* \defgroup MSC_Host Host
* The interface API includes status checking function, data transferring function and callback functions
* @{ */
//--------------------------------------------------------------------+
// MASS STORAGE Application API
//--------------------------------------------------------------------+
/** \brief Check if device supports MassStorage interface or not
* \param[in] dev_addr device address
* \retval true if device supports
* \retval false if device does not support or is not mounted
*/
bool tuh_msc_is_mounted(uint8_t dev_addr);
/** \brief Check if the interface is currently busy or not
* \param[in] dev_addr device address
* \retval true if the interface is busy meaning the stack is still transferring/waiting data from/to device
* \retval false if the interface is not busy meaning the stack successfully transferred data from/to device
* \note This function is used to check if previous transfer is complete (success or error), so that the next transfer
* can be scheduled. User needs to make sure the corresponding interface is mounted (by \ref tuh_msc_is_mounted)
* before calling this function
*/
bool tuh_msc_is_busy(uint8_t dev_addr);
/** \brief Get SCSI vendor's name of MassStorage device
* \param[in] dev_addr device address
* \return pointer to vendor's name or NULL if specified device does not support MassStorage
* \note SCSI vendor's name is 8-byte length field in \ref scsi_inquiry_data_t. During enumeration, the stack has already
* retrieved (via SCSI INQUIRY) and store this information internally. There is no need for application to re-send SCSI INQUIRY
* command or allocate buffer for this.
*/
uint8_t const* tuh_msc_get_vendor_name(uint8_t dev_addr);
/** \brief Get SCSI product's name of MassStorage device
* \param[in] dev_addr device address
* \return pointer to product's name or NULL if specified device does not support MassStorage
* \note SCSI product's name is 16-byte length field in \ref scsi_inquiry_data_t. During enumeration, the stack has already
* retrieved (via SCSI INQUIRY) and store this information internally. There is no need for application to re-send SCSI INQUIRY
* command or allocate buffer for this.
*/
uint8_t const* tuh_msc_get_product_name(uint8_t dev_addr);
/** \brief Get SCSI Capacity of MassStorage device
* \param[in] dev_addr device address
* \param[out] p_last_lba Last Logical Block Address of device
* \param[out] p_block_size Block Size of device in bytes
* \retval pointer to product's name or NULL if specified device does not support MassStorage
* \note MassStorage's capacity can be computed by last LBA x block size (in bytes). During enumeration, the stack has already
* retrieved (via SCSI READ CAPACITY 10) and store this information internally. There is no need for application
* to re-send SCSI READ CAPACITY 10 command
*/
tusb_error_t tuh_msc_get_capacity(uint8_t dev_addr, uint32_t* p_last_lba, uint32_t* p_block_size);
/** \brief Perform SCSI READ 10 command to read data from MassStorage device
* \param[in] dev_addr device address
* \param[in] lun Targeted Logical Unit
* \param[out] p_buffer Buffer used to store data read from device. Must be accessible by USB controller (see \ref CFG_TUSB_MEM_SECTION)
* \param[in] lba Starting Logical Block Address to be read
* \param[in] block_count Number of Block to be read
* \retval TUSB_ERROR_NONE on success
* \retval TUSB_ERROR_INTERFACE_IS_BUSY if the interface is already transferring data with device
* \retval TUSB_ERROR_DEVICE_NOT_READY if device is not yet configured (by SET CONFIGURED request)
* \retval TUSB_ERROR_INVALID_PARA if input parameters are not correct
* \note This function is non-blocking and returns immediately. The result of USB transfer will be reported by the interface's callback function
*/
tusb_error_t tuh_msc_read10 (uint8_t dev_addr, uint8_t lun, void * p_buffer, uint32_t lba, uint16_t block_count);
/** \brief Perform SCSI WRITE 10 command to write data to MassStorage device
* \param[in] dev_addr device address
* \param[in] lun Targeted Logical Unit
* \param[in] p_buffer Buffer containing data. Must be accessible by USB controller (see \ref CFG_TUSB_MEM_SECTION)
* \param[in] lba Starting Logical Block Address to be written
* \param[in] block_count Number of Block to be written
* \retval TUSB_ERROR_NONE on success
* \retval TUSB_ERROR_INTERFACE_IS_BUSY if the interface is already transferring data with device
* \retval TUSB_ERROR_DEVICE_NOT_READY if device is not yet configured (by SET CONFIGURED request)
* \retval TUSB_ERROR_INVALID_PARA if input parameters are not correct
* \note This function is non-blocking and returns immediately. The result of USB transfer will be reported by the interface's callback function
*/
tusb_error_t tuh_msc_write10(uint8_t dev_addr, uint8_t lun, void const * p_buffer, uint32_t lba, uint16_t block_count);
/** \brief Perform SCSI REQUEST SENSE command, used to retrieve sense data from MassStorage device
* \param[in] dev_addr device address
* \param[in] lun Targeted Logical Unit
* \param[in] p_data Buffer to store response's data from device. Must be accessible by USB controller (see \ref CFG_TUSB_MEM_SECTION)
* \retval TUSB_ERROR_NONE on success
* \retval TUSB_ERROR_INTERFACE_IS_BUSY if the interface is already transferring data with device
* \retval TUSB_ERROR_DEVICE_NOT_READY if device is not yet configured (by SET CONFIGURED request)
* \retval TUSB_ERROR_INVALID_PARA if input parameters are not correct
* \note This function is non-blocking and returns immediately. The result of USB transfer will be reported by the interface's callback function
*/
tusb_error_t tuh_msc_request_sense(uint8_t dev_addr, uint8_t lun, uint8_t *p_data);
/** \brief Perform SCSI TEST UNIT READY command to test if MassStorage device is ready
* \param[in] dev_addr device address
* \param[in] lun Targeted Logical Unit
* \retval TUSB_ERROR_NONE on success
* \retval TUSB_ERROR_INTERFACE_IS_BUSY if the interface is already transferring data with device
* \retval TUSB_ERROR_DEVICE_NOT_READY if device is not yet configured (by SET CONFIGURED request)
* \retval TUSB_ERROR_INVALID_PARA if input parameters are not correct
* \note This function is non-blocking and returns immediately. The result of USB transfer will be reported by the interface's callback function
*/
tusb_error_t tuh_msc_test_unit_ready(uint8_t dev_addr, uint8_t lun, msc_csw_t * p_csw); // TODO to be refractor
//tusb_error_t tusbh_msc_scsi_send(uint8_t dev_addr, uint8_t lun, bool is_direction_in,
// uint8_t const * p_command, uint8_t cmd_len,
// uint8_t * p_response, uint32_t resp_len);
//------------- Application Callback -------------//
/** \brief Callback function that will be invoked when a device with MassStorage interface is mounted
* \param[in] dev_addr Address of newly mounted device
* \note This callback should be used by Application to set-up interface-related data
*/
void tuh_msc_mounted_cb(uint8_t dev_addr);
/** \brief Callback function that will be invoked when a device with MassStorage interface is unmounted
* \param[in] dev_addr Address of newly unmounted device
* \note This callback should be used by Application to tear-down interface-related data
*/
void tuh_msc_unmounted_cb(uint8_t dev_addr);
/** \brief Callback function that is invoked when an transferring event occurred
* \param[in] dev_addr Address of device
* \param[in] event an value from \ref xfer_result_t
* \param[in] xferred_bytes Number of bytes transferred via USB bus
* \note event can be one of following
* - XFER_RESULT_SUCCESS : previously scheduled transfer completes successfully.
* - XFER_RESULT_FAILED : previously scheduled transfer encountered a transaction error.
* - XFER_RESULT_STALLED : previously scheduled transfer is stalled by device.
* \note
*/
void tuh_msc_isr(uint8_t dev_addr, xfer_result_t event, uint32_t xferred_bytes);
//--------------------------------------------------------------------+
// Internal Class Driver API
//--------------------------------------------------------------------+
typedef struct
{
uint8_t itf_numr;
uint8_t ep_in;
uint8_t ep_out;
uint8_t max_lun;
uint16_t block_size;
uint32_t last_lba; // last logical block address
volatile bool is_initialized;
uint8_t vendor_id[8];
uint8_t product_id[16];
msc_cbw_t cbw;
msc_csw_t csw;
}msch_interface_t;
void msch_init(void);
bool msch_open(uint8_t rhport, uint8_t dev_addr, tusb_desc_interface_t const *itf_desc, uint16_t *p_length);
void msch_isr(uint8_t dev_addr, uint8_t ep_addr, xfer_result_t event, uint32_t xferred_bytes);
void msch_close(uint8_t dev_addr);
#ifdef __cplusplus
}
#endif
#endif /* _TUSB_MSC_HOST_H_ */
/// @}
/// @}
/*
* The MIT License (MIT)
*
* Copyright (c) 2019 Ha Thach (tinyusb.org)
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*
* This file is part of the TinyUSB stack.
*/
#ifndef _TUSB_MSC_HOST_H_
#define _TUSB_MSC_HOST_H_
#include "common/tusb_common.h"
#include "host/usbh.h"
#include "msc.h"
#ifdef __cplusplus
extern "C" {
#endif
/** \addtogroup ClassDriver_MSC
* @{
* \defgroup MSC_Host Host
* The interface API includes status checking function, data transferring function and callback functions
* @{ */
//--------------------------------------------------------------------+
// MASS STORAGE Application API
//--------------------------------------------------------------------+
/** \brief Check if device supports MassStorage interface or not
* \param[in] dev_addr device address
* \retval true if device supports
* \retval false if device does not support or is not mounted
*/
bool tuh_msc_is_mounted(uint8_t dev_addr);
/** \brief Check if the interface is currently busy or not
* \param[in] dev_addr device address
* \retval true if the interface is busy meaning the stack is still transferring/waiting data from/to device
* \retval false if the interface is not busy meaning the stack successfully transferred data from/to device
* \note This function is used to check if previous transfer is complete (success or error), so that the next transfer
* can be scheduled. User needs to make sure the corresponding interface is mounted (by \ref tuh_msc_is_mounted)
* before calling this function
*/
bool tuh_msc_is_busy(uint8_t dev_addr);
/** \brief Get SCSI vendor's name of MassStorage device
* \param[in] dev_addr device address
* \return pointer to vendor's name or NULL if specified device does not support MassStorage
* \note SCSI vendor's name is 8-byte length field in \ref scsi_inquiry_data_t. During enumeration, the stack has already
* retrieved (via SCSI INQUIRY) and store this information internally. There is no need for application to re-send SCSI INQUIRY
* command or allocate buffer for this.
*/
uint8_t const* tuh_msc_get_vendor_name(uint8_t dev_addr);
/** \brief Get SCSI product's name of MassStorage device
* \param[in] dev_addr device address
* \return pointer to product's name or NULL if specified device does not support MassStorage
* \note SCSI product's name is 16-byte length field in \ref scsi_inquiry_data_t. During enumeration, the stack has already
* retrieved (via SCSI INQUIRY) and store this information internally. There is no need for application to re-send SCSI INQUIRY
* command or allocate buffer for this.
*/
uint8_t const* tuh_msc_get_product_name(uint8_t dev_addr);
/** \brief Get SCSI Capacity of MassStorage device
* \param[in] dev_addr device address
* \param[out] p_last_lba Last Logical Block Address of device
* \param[out] p_block_size Block Size of device in bytes
* \retval pointer to product's name or NULL if specified device does not support MassStorage
* \note MassStorage's capacity can be computed by last LBA x block size (in bytes). During enumeration, the stack has already
* retrieved (via SCSI READ CAPACITY 10) and store this information internally. There is no need for application
* to re-send SCSI READ CAPACITY 10 command
*/
tusb_error_t tuh_msc_get_capacity(uint8_t dev_addr, uint32_t* p_last_lba, uint32_t* p_block_size);
/** \brief Perform SCSI READ 10 command to read data from MassStorage device
* \param[in] dev_addr device address
* \param[in] lun Targeted Logical Unit
* \param[out] p_buffer Buffer used to store data read from device. Must be accessible by USB controller (see \ref CFG_TUSB_MEM_SECTION)
* \param[in] lba Starting Logical Block Address to be read
* \param[in] block_count Number of Block to be read
* \retval TUSB_ERROR_NONE on success
* \retval TUSB_ERROR_INTERFACE_IS_BUSY if the interface is already transferring data with device
* \retval TUSB_ERROR_DEVICE_NOT_READY if device is not yet configured (by SET CONFIGURED request)
* \retval TUSB_ERROR_INVALID_PARA if input parameters are not correct
* \note This function is non-blocking and returns immediately. The result of USB transfer will be reported by the interface's callback function
*/
tusb_error_t tuh_msc_read10 (uint8_t dev_addr, uint8_t lun, void * p_buffer, uint32_t lba, uint16_t block_count);
/** \brief Perform SCSI WRITE 10 command to write data to MassStorage device
* \param[in] dev_addr device address
* \param[in] lun Targeted Logical Unit
* \param[in] p_buffer Buffer containing data. Must be accessible by USB controller (see \ref CFG_TUSB_MEM_SECTION)
* \param[in] lba Starting Logical Block Address to be written
* \param[in] block_count Number of Block to be written
* \retval TUSB_ERROR_NONE on success
* \retval TUSB_ERROR_INTERFACE_IS_BUSY if the interface is already transferring data with device
* \retval TUSB_ERROR_DEVICE_NOT_READY if device is not yet configured (by SET CONFIGURED request)
* \retval TUSB_ERROR_INVALID_PARA if input parameters are not correct
* \note This function is non-blocking and returns immediately. The result of USB transfer will be reported by the interface's callback function
*/
tusb_error_t tuh_msc_write10(uint8_t dev_addr, uint8_t lun, void const * p_buffer, uint32_t lba, uint16_t block_count);
/** \brief Perform SCSI REQUEST SENSE command, used to retrieve sense data from MassStorage device
* \param[in] dev_addr device address
* \param[in] lun Targeted Logical Unit
* \param[in] p_data Buffer to store response's data from device. Must be accessible by USB controller (see \ref CFG_TUSB_MEM_SECTION)
* \retval TUSB_ERROR_NONE on success
* \retval TUSB_ERROR_INTERFACE_IS_BUSY if the interface is already transferring data with device
* \retval TUSB_ERROR_DEVICE_NOT_READY if device is not yet configured (by SET CONFIGURED request)
* \retval TUSB_ERROR_INVALID_PARA if input parameters are not correct
* \note This function is non-blocking and returns immediately. The result of USB transfer will be reported by the interface's callback function
*/
tusb_error_t tuh_msc_request_sense(uint8_t dev_addr, uint8_t lun, uint8_t *p_data);
/** \brief Perform SCSI TEST UNIT READY command to test if MassStorage device is ready
* \param[in] dev_addr device address
* \param[in] lun Targeted Logical Unit
* \retval TUSB_ERROR_NONE on success
* \retval TUSB_ERROR_INTERFACE_IS_BUSY if the interface is already transferring data with device
* \retval TUSB_ERROR_DEVICE_NOT_READY if device is not yet configured (by SET CONFIGURED request)
* \retval TUSB_ERROR_INVALID_PARA if input parameters are not correct
* \note This function is non-blocking and returns immediately. The result of USB transfer will be reported by the interface's callback function
*/
tusb_error_t tuh_msc_test_unit_ready(uint8_t dev_addr, uint8_t lun, msc_csw_t * p_csw); // TODO to be refractor
//tusb_error_t tusbh_msc_scsi_send(uint8_t dev_addr, uint8_t lun, bool is_direction_in,
// uint8_t const * p_command, uint8_t cmd_len,
// uint8_t * p_response, uint32_t resp_len);
//------------- Application Callback -------------//
/** \brief Callback function that will be invoked when a device with MassStorage interface is mounted
* \param[in] dev_addr Address of newly mounted device
* \note This callback should be used by Application to set-up interface-related data
*/
void tuh_msc_mounted_cb(uint8_t dev_addr);
/** \brief Callback function that will be invoked when a device with MassStorage interface is unmounted
* \param[in] dev_addr Address of newly unmounted device
* \note This callback should be used by Application to tear-down interface-related data
*/
void tuh_msc_unmounted_cb(uint8_t dev_addr);
/** \brief Callback function that is invoked when an transferring event occurred
* \param[in] dev_addr Address of device
* \param[in] event an value from \ref xfer_result_t
* \param[in] xferred_bytes Number of bytes transferred via USB bus
* \note event can be one of following
* - XFER_RESULT_SUCCESS : previously scheduled transfer completes successfully.
* - XFER_RESULT_FAILED : previously scheduled transfer encountered a transaction error.
* - XFER_RESULT_STALLED : previously scheduled transfer is stalled by device.
* \note
*/
void tuh_msc_isr(uint8_t dev_addr, xfer_result_t event, uint32_t xferred_bytes);
//--------------------------------------------------------------------+
// Internal Class Driver API
//--------------------------------------------------------------------+
typedef struct
{
uint8_t itf_numr;
uint8_t ep_in;
uint8_t ep_out;
uint8_t max_lun;
uint16_t block_size;
uint32_t last_lba; // last logical block address
volatile bool is_initialized;
uint8_t vendor_id[8];
uint8_t product_id[16];
msc_cbw_t cbw;
msc_csw_t csw;
}msch_interface_t;
void msch_init(void);
bool msch_open(uint8_t rhport, uint8_t dev_addr, tusb_desc_interface_t const *itf_desc, uint16_t *p_length);
void msch_isr(uint8_t dev_addr, uint8_t ep_addr, xfer_result_t event, uint32_t xferred_bytes);
void msch_close(uint8_t dev_addr);
#ifdef __cplusplus
}
#endif
#endif /* _TUSB_MSC_HOST_H_ */
/// @}
/// @}