proxmox-backup/src/tools/sgutils2.rs

615 lines
17 KiB
Rust

//! Bindings for libsgutils2
//!
//! Incomplete, but we currently do not need more.
//!
//! See: `/usr/include/scsi/sg_pt.h`
//!
//! The SCSI Commands Reference Manual also contains some usefull information.
use std::os::unix::io::AsRawFd;
use std::ptr::NonNull;
use anyhow::{bail, format_err, Error};
use endian_trait::Endian;
use serde::{Deserialize, Serialize};
use libc::{c_char, c_int};
use std::ffi::CStr;
use proxmox::tools::io::ReadExt;
#[derive(Debug)]
pub struct SenseInfo {
pub sense_key: u8,
pub asc: u8,
pub ascq: u8,
}
impl ToString for SenseInfo {
fn to_string(&self) -> String {
let sense_text = SENSE_KEY_DESCRIPTIONS
.get(self.sense_key as usize)
.map(|s| String::from(*s))
.unwrap_or_else(|| format!("Invalid sense {:02X}", self.sense_key));
if self.asc == 0 && self.ascq == 0 {
return sense_text;
}
let additional_sense_text = get_asc_ascq_string(self.asc, self.ascq);
format!("{}, {}", sense_text, additional_sense_text)
}
}
#[derive(Debug)]
pub struct ScsiError {
pub error: Error,
pub sense: Option<SenseInfo>,
}
impl std::fmt::Display for ScsiError {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
write!(f, "{}", self.error)
}
}
impl std::error::Error for ScsiError {
fn source(&self) -> Option<&(dyn std::error::Error + 'static)> {
self.error.source()
}
}
impl From<anyhow::Error> for ScsiError {
fn from(error: anyhow::Error) -> Self {
Self { error, sense: None }
}
}
impl From<std::io::Error> for ScsiError {
fn from(error: std::io::Error) -> Self {
Self { error: error.into(), sense: None }
}
}
// Opaque wrapper for sg_pt_base
#[repr(C)]
struct SgPtBase { _private: [u8; 0] }
#[repr(transparent)]
struct SgPt {
raw: NonNull<SgPtBase>,
}
impl Drop for SgPt {
fn drop(&mut self) {
unsafe { destruct_scsi_pt_obj(self.as_mut_ptr()) };
}
}
impl SgPt {
fn new() -> Result<Self, Error> {
Ok(Self {
raw: NonNull::new(unsafe { construct_scsi_pt_obj() })
.ok_or_else(|| format_err!("construct_scsi_pt_ob failed"))?,
})
}
fn as_ptr(&self) -> *const SgPtBase {
self.raw.as_ptr()
}
fn as_mut_ptr(&mut self) -> *mut SgPtBase {
self.raw.as_ptr()
}
}
/// Peripheral device type text (see `inquiry` command)
///
/// see [https://en.wikipedia.org/wiki/SCSI_Peripheral_Device_Type]
pub const PERIPHERAL_DEVICE_TYPE_TEXT: [&'static str; 32] = [
"Disk Drive",
"Tape Drive",
"Printer",
"Processor",
"Write-once",
"CD-ROM", // 05h
"Scanner",
"Optical",
"Medium Changer", // 08h
"Communications",
"ASC IT8",
"ASC IT8",
"RAID Array",
"Enclosure Services",
"Simplified direct-access",
"Optical card reader/writer",
"Bridging Expander",
"Object-based Storage",
"Automation/Drive Interface",
"Security manager",
"Reserved",
"Reserved",
"Reserved",
"Reserved",
"Reserved",
"Reserved",
"Reserved",
"Reserved",
"Reserved",
"Reserved",
"Reserved",
"Unknown",
];
// SENSE KEYS
pub const SENSE_KEY_NO_SENSE: u8 = 0x00;
pub const SENSE_KEY_RECOVERED_ERROR: u8 = 0x01;
pub const SENSE_KEY_NOT_READY: u8 = 0x02;
pub const SENSE_KEY_MEDIUM_ERROR: u8 = 0x03;
pub const SENSE_KEY_HARDWARE_ERROR: u8 = 0x04;
pub const SENSE_KEY_ILLEGAL_REQUEST: u8 = 0x05;
pub const SENSE_KEY_UNIT_ATTENTION: u8 = 0x06;
pub const SENSE_KEY_DATA_PROTECT: u8 = 0x07;
pub const SENSE_KEY_BLANK_CHECK: u8 = 0x08;
pub const SENSE_KEY_COPY_ABORTED: u8 = 0x0a;
pub const SENSE_KEY_ABORTED_COMMAND: u8 = 0x0b;
pub const SENSE_KEY_VOLUME_OVERFLOW: u8 = 0x0d;
pub const SENSE_KEY_MISCOMPARE: u8 = 0x0e;
/// Sense Key Descriptions
pub const SENSE_KEY_DESCRIPTIONS: [&'static str; 16] = [
"No Sense",
"Recovered Error",
"Not Ready",
"Medium Error",
"Hardware Error",
"Illegal Request",
"Unit Attention",
"Data Protect",
"Blank Check",
"Vendor specific",
"Copy Aborted",
"Aborted Command",
"Equal",
"Volume Overflow",
"Miscompare",
"Completed",
];
#[repr(C, packed)]
#[derive(Endian)]
// Standard Inquiry page - 36 bytes
struct InquiryPage {
peripheral_type: u8,
rmb: u8,
version: u8,
flags3: u8,
additional_length: u8,
flags5: u8,
flags6: u8,
flags7: u8,
vendor: [u8; 8],
product: [u8; 16],
revision: [u8; 4],
}
#[repr(C, packed)]
#[derive(Endian, Debug)]
struct RequestSenseFixed {
response_code: u8,
obsolete: u8,
flags2: u8,
information: [u8;4],
additional_sense_len: u8,
command_specific_information: [u8;4],
additional_sense_code: u8,
additional_sense_code_qualifier: u8,
field_replacable_unit_code: u8,
sense_key_specific: [u8; 3],
}
#[repr(C, packed)]
#[derive(Endian, Debug)]
struct RequestSenseDescriptor{
response_code: u8,
sense_key: u8,
additional_sense_code: u8,
additional_sense_code_qualifier: u8,
reserved: [u8;4],
additional_sense_len: u8,
}
/// Inquiry result
#[derive(Serialize, Deserialize, Debug)]
pub struct InquiryInfo {
/// Peripheral device type (0-31)
pub peripheral_type: u8,
/// Peripheral device type as string
pub peripheral_type_text: String,
/// Vendor
pub vendor: String,
/// Product
pub product: String,
/// Revision
pub revision: String,
}
pub const SCSI_PT_DO_START_OK:c_int = 0;
pub const SCSI_PT_DO_BAD_PARAMS:c_int = 1;
pub const SCSI_PT_DO_TIMEOUT:c_int = 2;
pub const SCSI_PT_RESULT_GOOD:c_int = 0;
pub const SCSI_PT_RESULT_STATUS:c_int = 1;
pub const SCSI_PT_RESULT_SENSE:c_int = 2;
pub const SCSI_PT_RESULT_TRANSPORT_ERR:c_int = 3;
pub const SCSI_PT_RESULT_OS_ERR:c_int = 4;
#[link(name = "sgutils2")]
extern "C" {
#[allow(dead_code)]
fn scsi_pt_open_device(
device_name: * const c_char,
read_only: bool,
verbose: c_int,
) -> c_int;
fn sg_is_scsi_cdb(
cdbp: *const u8,
clen: c_int,
) -> bool;
fn construct_scsi_pt_obj() -> *mut SgPtBase;
fn destruct_scsi_pt_obj(objp: *mut SgPtBase);
fn set_scsi_pt_data_in(
objp: *mut SgPtBase,
dxferp: *mut u8,
dxfer_ilen: c_int,
);
fn set_scsi_pt_data_out(
objp: *mut SgPtBase,
dxferp: *const u8,
dxfer_olen: c_int,
);
fn set_scsi_pt_cdb(
objp: *mut SgPtBase,
cdb: *const u8,
cdb_len: c_int,
);
fn set_scsi_pt_sense(
objp: *mut SgPtBase,
sense: *mut u8,
max_sense_len: c_int,
);
fn do_scsi_pt(
objp: *mut SgPtBase,
fd: c_int,
timeout_secs: c_int,
verbose: c_int,
) -> c_int;
fn get_scsi_pt_resid(objp: *const SgPtBase) -> c_int;
fn get_scsi_pt_sense_len(objp: *const SgPtBase) -> c_int;
fn get_scsi_pt_status_response(objp: *const SgPtBase) -> c_int;
fn get_scsi_pt_result_category(objp: *const SgPtBase) -> c_int;
fn get_scsi_pt_os_err(objp: *const SgPtBase) -> c_int;
fn sg_get_asc_ascq_str(
asc: c_int,
ascq:c_int,
buff_len: c_int,
buffer: *mut c_char,
) -> * const c_char;
}
/// Safe interface to run RAW SCSI commands
pub struct SgRaw<'a, F> {
file: &'a mut F,
buffer: Box<[u8]>,
sense_buffer: [u8; 32],
timeout: i32,
}
/// Get the string associated with ASC/ASCQ values
pub fn get_asc_ascq_string(asc: u8, ascq: u8) -> String {
let mut buffer = [0u8; 1024];
let res = unsafe {
sg_get_asc_ascq_str(
asc as c_int,
ascq as c_int,
buffer.len() as c_int,
buffer.as_mut_ptr() as * mut c_char,
)
};
proxmox::try_block!({
if res.is_null() { // just to be safe
bail!("unexpected NULL ptr");
}
Ok(unsafe { CStr::from_ptr(res) }.to_str()?.to_owned())
}).unwrap_or_else(|_err: Error| {
format!("ASC={:02x}x, ASCQ={:02x}x", asc, ascq)
})
}
/// Allocate a page aligned buffer
///
/// SG RAWIO commands needs page aligned transfer buffers.
pub fn alloc_page_aligned_buffer(buffer_size: usize) -> Result<Box<[u8]> , Error> {
let page_size = unsafe { libc::sysconf(libc::_SC_PAGESIZE) } as usize;
let layout = std::alloc::Layout::from_size_align(buffer_size, page_size)?;
let dinp = unsafe { std::alloc::alloc_zeroed(layout) };
if dinp.is_null() {
bail!("alloc SCSI output buffer failed");
}
let buffer_slice = unsafe { std::slice::from_raw_parts_mut(dinp, buffer_size)};
Ok(unsafe { Box::from_raw(buffer_slice) })
}
impl <'a, F: AsRawFd> SgRaw<'a, F> {
/// Create a new instance to run commands
///
/// The file must be a handle to a SCSI device.
pub fn new(file: &'a mut F, buffer_size: usize) -> Result<Self, Error> {
let buffer;
if buffer_size > 0 {
buffer = alloc_page_aligned_buffer(buffer_size)?;
} else {
buffer = Box::new([]);
}
let sense_buffer = [0u8; 32];
Ok(Self { file, buffer, sense_buffer, timeout: 0 })
}
/// Set the command timeout in seconds (0 means default (60 seconds))
pub fn set_timeout(&mut self, seconds: usize) {
if seconds > (i32::MAX as usize) {
self.timeout = i32::MAX; // don't care about larger values
} else {
self.timeout = seconds as i32;
}
}
// create new object with initialized data_in and sense buffer
fn create_scsi_pt_obj(&mut self) -> Result<SgPt, Error> {
let mut ptvp = SgPt::new()?;
if self.buffer.len() > 0 {
unsafe {
set_scsi_pt_data_in(
ptvp.as_mut_ptr(),
self.buffer.as_mut_ptr(),
self.buffer.len() as c_int,
)
};
}
unsafe {
set_scsi_pt_sense(
ptvp.as_mut_ptr(),
self.sense_buffer.as_mut_ptr(),
self.sense_buffer.len() as c_int,
)
};
Ok(ptvp)
}
fn do_scsi_pt_checked(&mut self, ptvp: &mut SgPt) -> Result<(), ScsiError> {
let res = unsafe { do_scsi_pt(ptvp.as_mut_ptr(), self.file.as_raw_fd(), self.timeout, 0) };
match res {
SCSI_PT_DO_START_OK => { /* Ok */ },
SCSI_PT_DO_BAD_PARAMS => return Err(format_err!("do_scsi_pt failed - bad pass through setup").into()),
SCSI_PT_DO_TIMEOUT => return Err(format_err!("do_scsi_pt failed - timeout").into()),
code if code < 0 => {
let errno = unsafe { get_scsi_pt_os_err(ptvp.as_ptr()) };
let err = nix::Error::from_errno(nix::errno::Errno::from_i32(errno));
return Err(format_err!("do_scsi_pt failed with err {}", err).into());
}
unknown => return Err(format_err!("do_scsi_pt failed: unknown error {}", unknown).into()),
}
if res < 0 {
let err = nix::Error::last();
return Err(format_err!("do_scsi_pt failed - {}", err).into());
}
if res != 0 {
return Err(format_err!("do_scsi_pt failed {}", res).into());
}
let sense_len = unsafe { get_scsi_pt_sense_len(ptvp.as_ptr()) };
let res_cat = unsafe { get_scsi_pt_result_category(ptvp.as_ptr()) };
match res_cat {
SCSI_PT_RESULT_GOOD => return Ok(()),
SCSI_PT_RESULT_STATUS => {
let status = unsafe { get_scsi_pt_status_response(ptvp.as_ptr()) };
if status != 0 {
return Err(format_err!("unknown scsi error - status response {}", status).into());
}
return Ok(());
}
SCSI_PT_RESULT_SENSE => {
if sense_len == 0 {
return Err(format_err!("scsi command failed, but got no sense data").into());
}
let code = self.sense_buffer[0] & 0x7f;
let mut reader = &self.sense_buffer[..(sense_len as usize)];
let sense = match code {
0x70 => {
let sense: RequestSenseFixed = unsafe { reader.read_be_value()? };
SenseInfo {
sense_key: sense.flags2 & 0xf,
asc: sense.additional_sense_code,
ascq: sense.additional_sense_code_qualifier,
}
}
0x72 => {
let sense: RequestSenseDescriptor = unsafe { reader.read_be_value()? };
SenseInfo {
sense_key: sense.sense_key & 0xf,
asc: sense.additional_sense_code,
ascq: sense.additional_sense_code_qualifier,
}
}
0x71 | 0x73 => {
return Err(format_err!("scsi command failed: received deferred Sense").into());
}
unknown => {
return Err(format_err!("scsi command failed: invalid Sense response code {:x}", unknown).into());
}
};
return Err(ScsiError {
error: format_err!("{}", sense.to_string()),
sense: Some(sense),
});
}
SCSI_PT_RESULT_TRANSPORT_ERR => return Err(format_err!("scsi command failed: transport error").into()),
SCSI_PT_RESULT_OS_ERR => {
let errno = unsafe { get_scsi_pt_os_err(ptvp.as_ptr()) };
let err = nix::Error::from_errno(nix::errno::Errno::from_i32(errno));
return Err(format_err!("scsi command failed with err {}", err).into());
}
unknown => return Err(format_err!("scsi command failed: unknown result category {}", unknown).into()),
}
}
/// Run the specified RAW SCSI command
pub fn do_command(&mut self, cmd: &[u8]) -> Result<&[u8], ScsiError> {
if !unsafe { sg_is_scsi_cdb(cmd.as_ptr(), cmd.len() as c_int) } {
return Err(format_err!("no valid SCSI command").into());
}
if self.buffer.len() < 16 {
return Err(format_err!("output buffer too small").into());
}
let mut ptvp = self.create_scsi_pt_obj()?;
unsafe {
set_scsi_pt_cdb(
ptvp.as_mut_ptr(),
cmd.as_ptr(),
cmd.len() as c_int,
)
};
self.do_scsi_pt_checked(&mut ptvp)?;
let resid = unsafe { get_scsi_pt_resid(ptvp.as_ptr()) } as usize;
if resid > self.buffer.len() {
return Err(format_err!("do_scsi_pt failed - got strange resid (value too big)").into());
}
let data_len = self.buffer.len() - resid;
Ok(&self.buffer[..data_len])
}
/// Run dataout command
///
/// Note: use alloc_page_aligned_buffer to alloc data transfer buffer
pub fn do_out_command(&mut self, cmd: &[u8], data: &[u8]) -> Result<(), Error> {
if !unsafe { sg_is_scsi_cdb(cmd.as_ptr(), cmd.len() as c_int) } {
bail!("no valid SCSI command");
}
let page_size = unsafe { libc::sysconf(libc::_SC_PAGESIZE) } as usize;
if ((data.as_ptr() as usize) & (page_size -1)) != 0 {
bail!("wrong transfer buffer alignment");
}
let mut ptvp = self.create_scsi_pt_obj()?;
unsafe {
set_scsi_pt_data_out(
ptvp.as_mut_ptr(),
data.as_ptr(),
data.len() as c_int,
);
set_scsi_pt_cdb(
ptvp.as_mut_ptr(),
cmd.as_ptr(),
cmd.len() as c_int,
);
};
self.do_scsi_pt_checked(&mut ptvp)?;
Ok(())
}
}
// Useful helpers
/// Converts SCSI ASCII text into String, trim zero and spaces
pub fn scsi_ascii_to_string(data: &[u8]) -> String {
String::from_utf8_lossy(data)
.trim_matches(char::from(0))
.trim()
.to_string()
}
/// Read SCSI Inquiry page
///
/// Returns Product/Vendor/Revision and device type.
pub fn scsi_inquiry<F: AsRawFd>(
file: &mut F,
) -> Result<InquiryInfo, Error> {
let allocation_len: u8 = std::mem::size_of::<InquiryPage>() as u8;
let mut sg_raw = SgRaw::new(file, allocation_len as usize)?;
sg_raw.set_timeout(30); // use short timeout
let mut cmd = Vec::new();
cmd.extend(&[0x12, 0, 0, 0, allocation_len, 0]); // INQUIRY
let data = sg_raw.do_command(&cmd)
.map_err(|err| format_err!("SCSI inquiry failed - {}", err))?;
proxmox::try_block!({
let mut reader = &data[..];
let page: InquiryPage = unsafe { reader.read_be_value()? };
let peripheral_type = page.peripheral_type & 31;
let info = InquiryInfo {
peripheral_type,
peripheral_type_text: PERIPHERAL_DEVICE_TYPE_TEXT[peripheral_type as usize].to_string(),
vendor: scsi_ascii_to_string(&page.vendor),
product: scsi_ascii_to_string(&page.product),
revision: scsi_ascii_to_string(&page.revision),
};
Ok(info)
}).map_err(|err: Error| format_err!("decode inquiry page failed - {}", err))
}