// commands.rs
// *************************************************************************
// * Copyright (C) 2018-2020 Daniel Mueller (deso@posteo.net) *
// * *
// * This program is free software: you can redistribute it and/or modify *
// * it under the terms of the GNU General Public License as published by *
// * the Free Software Foundation, either version 3 of the License, or *
// * (at your option) any later version. *
// * *
// * This program is distributed in the hope that it will be useful, *
// * but WITHOUT ANY WARRANTY; without even the implied warranty of *
// * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
// * GNU General Public License for more details. *
// * *
// * You should have received a copy of the GNU General Public License *
// * along with this program. If not, see . *
// *************************************************************************
use std::convert::TryFrom as _;
use std::fmt;
use std::mem;
use std::thread;
use std::time;
use std::u8;
use anyhow::Context as _;
use libc::sync;
use nitrokey::ConfigureOtp;
use nitrokey::Device;
use nitrokey::GenerateOtp;
use nitrokey::GetPasswordSafe;
use crate::args;
use crate::pinentry;
use crate::ExecCtx;
/// Set `libnitrokey`'s log level based on the execution context's verbosity.
fn set_log_level(ctx: &mut ExecCtx<'_>) {
let log_lvl = match ctx.verbosity {
// The error log level is what libnitrokey uses by default. As such,
// there is no harm in us setting that as well when the user did not
// ask for higher verbosity.
0 => nitrokey::LogLevel::Error,
1 => nitrokey::LogLevel::Warning,
2 => nitrokey::LogLevel::Info,
3 => nitrokey::LogLevel::DebugL1,
4 => nitrokey::LogLevel::Debug,
_ => nitrokey::LogLevel::DebugL2,
};
nitrokey::set_log_level(log_lvl);
}
/// Connect to any Nitrokey device and do something with it.
fn with_device(ctx: &mut ExecCtx<'_>, op: F) -> anyhow::Result<()>
where
F: FnOnce(&mut ExecCtx<'_>, nitrokey::DeviceWrapper<'_>) -> anyhow::Result<()>,
{
let mut manager =
nitrokey::take().context("Failed to acquire access to Nitrokey device manager")?;
set_log_level(ctx);
let device = match ctx.model {
Some(model) => manager.connect_model(model.into()).with_context(|| {
anyhow::anyhow!("Nitrokey {} device not found", model.as_user_facing_str())
})?,
None => manager.connect().context("Nitrokey device not found")?,
};
op(ctx, device)
}
/// Connect to a Nitrokey Storage device and do something with it.
fn with_storage_device(ctx: &mut ExecCtx<'_>, op: F) -> anyhow::Result<()>
where
F: FnOnce(&mut ExecCtx<'_>, nitrokey::Storage<'_>) -> anyhow::Result<()>,
{
let mut manager =
nitrokey::take().context("Failed to acquire access to Nitrokey device manager")?;
set_log_level(ctx);
if let Some(model) = ctx.model {
if model != args::DeviceModel::Storage {
anyhow::bail!("This command is only available on the Nitrokey Storage");
}
}
let device = manager
.connect_storage()
.context("Nitrokey Storage device not found")?;
op(ctx, device)
}
/// Connect to any Nitrokey device, retrieve a password safe handle, and
/// do something with it.
fn with_password_safe(ctx: &mut ExecCtx<'_>, mut op: F) -> anyhow::Result<()>
where
F: FnMut(&mut ExecCtx<'_>, nitrokey::PasswordSafe<'_, '_>) -> anyhow::Result<()>,
{
with_device(ctx, |ctx, mut device| {
let pin_entry = pinentry::PinEntry::from(args::PinType::User, &device)?;
try_with_pin_and_data(ctx, &pin_entry, (), move |ctx, _, pin| {
let pws = device.get_password_safe(pin).or_else(|err| {
Err(err)
.context("Could not access the password safe")
.map_err(|err| ((), err))
})?;
op(ctx, pws).map_err(|err| ((), err))
})
})?;
Ok(())
}
/// Authenticate the given device using the given PIN type and operation.
fn authenticate<'mgr, D, A, F>(
ctx: &mut ExecCtx<'_>,
device: D,
pin_type: args::PinType,
op: F,
) -> anyhow::Result
where
D: Device<'mgr>,
F: FnMut(&mut ExecCtx<'_>, D, &str) -> Result,
{
let pin_entry = pinentry::PinEntry::from(pin_type, &device)?;
try_with_pin_and_data(ctx, &pin_entry, device, op)
}
/// Authenticate the given device with the user PIN.
fn authenticate_user<'mgr, T>(
ctx: &mut ExecCtx<'_>,
device: T,
) -> anyhow::Result>
where
T: Device<'mgr>,
{
authenticate(ctx, device, args::PinType::User, |_ctx, device, pin| {
device.authenticate_user(pin).or_else(|(x, err)| {
Err(err)
.context("Failed to authenticate as user")
.map_err(|err| (x, err))
})
})
}
/// Authenticate the given device with the admin PIN.
fn authenticate_admin<'mgr, T>(
ctx: &mut ExecCtx<'_>,
device: T,
) -> anyhow::Result>
where
T: Device<'mgr>,
{
authenticate(ctx, device, args::PinType::Admin, |_ctx, device, pin| {
device.authenticate_admin(pin).or_else(|(x, err)| {
Err(err)
.context("Failed to authenticate as admin")
.map_err(|err| (x, err))
})
})
}
/// Return a string representation of the given volume status.
fn get_volume_status(status: &nitrokey::VolumeStatus) -> &'static str {
if status.active {
if status.read_only {
"read-only"
} else {
"active"
}
} else {
"inactive"
}
}
/// Try to execute the given function with a pin queried using pinentry.
///
/// This function will query the pin of the given type from the user
/// using pinentry. It will then execute the given function. If this
/// function returns a result, the result will be passed on. If it
/// returns a `CommandError::WrongPassword`, the user will be asked
/// again to enter the pin. Otherwise, this function returns an error
/// containing the given error message. The user will have at most
/// three tries to get the pin right.
///
/// The data argument can be used to pass on data between the tries. At
/// the first try, this function will call `op` with `data`. At the
/// second or third try, it will call `op` with the data returned by the
/// previous call to `op`.
fn try_with_pin_and_data_with_pinentry(
ctx: &mut ExecCtx<'_>,
pin_entry: &pinentry::PinEntry,
data: D,
mut op: F,
) -> anyhow::Result
where
F: FnMut(&mut ExecCtx<'_>, D, &str) -> Result,
{
let mut data = data;
let mut retry = 3;
let mut error_msg = None;
loop {
let pin = pinentry::inquire(ctx, pin_entry, pinentry::Mode::Query, error_msg)?;
match op(ctx, data, &pin) {
Ok(result) => return Ok(result),
Err((new_data, err)) => match err.downcast::() {
Ok(err) => match err {
nitrokey::Error::CommandError(nitrokey::CommandError::WrongPassword) => {
pinentry::clear(pin_entry).context("Failed to clear cached secret")?;
retry -= 1;
if retry > 0 {
error_msg = Some("Wrong password, please reenter");
data = new_data;
continue;
}
anyhow::bail!(err);
}
err => anyhow::bail!(err),
},
Err(err) => anyhow::bail!(err),
},
};
}
}
/// Try to execute the given function with a PIN.
fn try_with_pin_and_data(
ctx: &mut ExecCtx<'_>,
pin_entry: &pinentry::PinEntry,
data: D,
mut op: F,
) -> anyhow::Result
where
F: FnMut(&mut ExecCtx<'_>, D, &str) -> Result,
{
let pin = match pin_entry.pin_type() {
// Ideally we would not clone here, but that would require us to
// restrict op to work with an immutable ExecCtx, which is not
// possible given that some clients print data.
args::PinType::Admin => ctx.admin_pin.clone(),
args::PinType::User => ctx.user_pin.clone(),
};
if let Some(pin) = pin {
let pin = pin
.to_str()
.ok_or_else(|| anyhow::anyhow!("Failed to read PIN: Invalid Unicode data found"))?;
op(ctx, data, &pin).map_err(|(_, err)| err)
} else {
try_with_pin_and_data_with_pinentry(ctx, pin_entry, data, op)
}
}
/// Try to execute the given function with a pin queried using pinentry.
///
/// This function behaves exactly as `try_with_pin_and_data`, but
/// it refrains from passing any data to it.
fn try_with_pin(
ctx: &mut ExecCtx<'_>,
pin_entry: &pinentry::PinEntry,
mut op: F,
) -> anyhow::Result<()>
where
F: FnMut(&str) -> anyhow::Result<()>,
{
try_with_pin_and_data(ctx, pin_entry, (), |_ctx, data, pin| {
op(pin).map_err(|err| (data, err))
})
}
/// Pretty print the status of a Nitrokey Storage.
fn print_storage_status(
ctx: &mut ExecCtx<'_>,
status: &nitrokey::StorageStatus,
) -> anyhow::Result<()> {
println!(
ctx,
r#" Storage:
SD card ID: {id:#x}
firmware: {fw}
storage keys: {sk}
volumes:
unencrypted: {vu}
encrypted: {ve}
hidden: {vh}"#,
id = status.serial_number_sd_card,
fw = if status.firmware_locked {
"locked"
} else {
"unlocked"
},
sk = if status.stick_initialized {
"created"
} else {
"not created"
},
vu = get_volume_status(&status.unencrypted_volume),
ve = get_volume_status(&status.encrypted_volume),
vh = get_volume_status(&status.hidden_volume),
)?;
Ok(())
}
/// Query and pretty print the status that is common to all Nitrokey devices.
fn print_status(
ctx: &mut ExecCtx<'_>,
model: &'static str,
device: &nitrokey::DeviceWrapper<'_>,
) -> anyhow::Result<()> {
let serial_number = device
.get_serial_number()
.context("Could not query the serial number")?;
println!(
ctx,
r#"Status:
model: {model}
serial number: {id}
firmware version: {fwv}
user retry count: {urc}
admin retry count: {arc}"#,
model = model,
id = serial_number,
fwv = device
.get_firmware_version()
.context("Failed to retrieve firmware version")?,
urc = device
.get_user_retry_count()
.context("Failed to retrieve user retry count")?,
arc = device
.get_admin_retry_count()
.context("Failed to retrieve admin retry count")?,
)?;
if let nitrokey::DeviceWrapper::Storage(device) = device {
let status = device
.get_storage_status()
.context("Failed to retrieve storage status")?;
print_storage_status(ctx, &status)
} else {
Ok(())
}
}
/// Inquire the status of the nitrokey.
pub fn status(ctx: &mut ExecCtx<'_>) -> anyhow::Result<()> {
with_device(ctx, |ctx, device| {
let model = match device {
nitrokey::DeviceWrapper::Pro(_) => "Pro",
nitrokey::DeviceWrapper::Storage(_) => "Storage",
};
print_status(ctx, model, &device)
})
}
/// List the attached Nitrokey devices.
pub fn list(ctx: &mut ExecCtx<'_>, no_connect: bool) -> anyhow::Result<()> {
set_log_level(ctx);
let device_infos =
nitrokey::list_devices().context("Failed to list connected Nitrokey devices")?;
if device_infos.is_empty() {
println!(ctx, "No Nitrokey device connected")?;
} else {
println!(ctx, "device path\tmodel\tserial number")?;
let mut manager =
nitrokey::take().context("Failed to acquire access to Nitrokey device manager")?;
for device_info in device_infos {
let model = device_info
.model
.map(|m| m.to_string())
.unwrap_or_else(|| "unknown".into());
let serial_number = match device_info.serial_number {
Some(serial_number) => serial_number.to_string(),
None => {
// Storage devices do not have the serial number present in
// the device information. We have to connect to them to
// retrieve the information.
if no_connect {
"N/A".to_string()
} else {
let device = manager
.connect_path(device_info.path.clone())
.context("Failed to connect to Nitrokey")?;
device
.get_serial_number()
.context("Failed to retrieve device serial number")?
.to_string()
}
}
};
println!(ctx, "{}\t{}\t{}", device_info.path, model, serial_number)?;
}
}
Ok(())
}
/// Perform a factory reset.
pub fn reset(ctx: &mut ExecCtx<'_>) -> anyhow::Result<()> {
with_device(ctx, |ctx, mut device| {
let pin_entry = pinentry::PinEntry::from(args::PinType::Admin, &device)?;
// To force the user to enter the admin PIN before performing a
// factory reset, we clear the pinentry cache for the admin PIN.
pinentry::clear(&pin_entry).context("Failed to clear cached secret")?;
try_with_pin(ctx, &pin_entry, |pin| {
device
.factory_reset(&pin)
.context("Failed to reset to factory settings")?;
// Work around for a timing issue between factory_reset and
// build_aes_key, see
// https://github.com/Nitrokey/nitrokey-storage-firmware/issues/80
thread::sleep(time::Duration::from_secs(3));
// Another work around for spurious WrongPassword returns of
// build_aes_key after a factory reset on Pro devices.
// https://github.com/Nitrokey/nitrokey-pro-firmware/issues/57
let _ = device.get_user_retry_count();
device
.build_aes_key(nitrokey::DEFAULT_ADMIN_PIN)
.context("Failed to rebuild AES key")
})
})
}
/// Change the configuration of the unencrypted volume.
pub fn unencrypted_set(
ctx: &mut ExecCtx<'_>,
mode: args::UnencryptedVolumeMode,
) -> anyhow::Result<()> {
with_storage_device(ctx, |ctx, mut device| {
let pin_entry = pinentry::PinEntry::from(args::PinType::Admin, &device)?;
let mode = match mode {
args::UnencryptedVolumeMode::ReadWrite => nitrokey::VolumeMode::ReadWrite,
args::UnencryptedVolumeMode::ReadOnly => nitrokey::VolumeMode::ReadOnly,
};
// The unencrypted volume may reconnect, so be sure to flush caches to
// disk.
unsafe { sync() };
try_with_pin(ctx, &pin_entry, |pin| {
device
.set_unencrypted_volume_mode(&pin, mode)
.context("Failed to change unencrypted volume mode")
})
})
}
/// Open the encrypted volume on the Nitrokey.
pub fn encrypted_open(ctx: &mut ExecCtx<'_>) -> anyhow::Result<()> {
with_storage_device(ctx, |ctx, mut device| {
let pin_entry = pinentry::PinEntry::from(args::PinType::User, &device)?;
// We may forcefully close a hidden volume, if active, so be sure to
// flush caches to disk.
unsafe { sync() };
try_with_pin(ctx, &pin_entry, |pin| {
device
.enable_encrypted_volume(&pin)
.context("Failed to open encrypted volume")
})
})
}
/// Close the previously opened encrypted volume.
pub fn encrypted_close(ctx: &mut ExecCtx<'_>) -> anyhow::Result<()> {
with_storage_device(ctx, |_ctx, mut device| {
// Flush all filesystem caches to disk. We are mostly interested in
// making sure that the encrypted volume on the Nitrokey we are
// about to close is not closed while not all data was written to
// it.
unsafe { sync() };
device
.disable_encrypted_volume()
.context("Failed to close encrypted volume")
})
}
/// Create a hidden volume.
pub fn hidden_create(ctx: &mut ExecCtx<'_>, slot: u8, start: u8, end: u8) -> anyhow::Result<()> {
with_storage_device(ctx, |ctx, mut device| {
let pwd_entry = pinentry::PwdEntry::from(&device)?;
let pwd = if let Some(pwd) = &ctx.password {
pwd
.to_str()
.ok_or_else(|| anyhow::anyhow!("Failed to read password: invalid unicode data found"))
.map(ToOwned::to_owned)
} else {
pinentry::choose(ctx, &pwd_entry).context("Failed to select new PIN")
}?;
device
.create_hidden_volume(slot, start, end, &pwd)
.context("Failed to create hidden volume")
})
}
/// Open a hidden volume.
pub fn hidden_open(ctx: &mut ExecCtx<'_>) -> anyhow::Result<()> {
with_storage_device(ctx, |ctx, mut device| {
let pwd_entry = pinentry::PwdEntry::from(&device)?;
let pwd = if let Some(pwd) = &ctx.password {
pwd
.to_str()
.ok_or_else(|| anyhow::anyhow!("Failed to read password: Invalid Unicode data found"))
.map(ToOwned::to_owned)
} else {
pinentry::inquire(ctx, &pwd_entry, pinentry::Mode::Query, None)
.context("Failed to inquire PIN")
}?;
// We may forcefully close an encrypted volume, if active, so be sure
// to flush caches to disk.
unsafe { sync() };
device
.enable_hidden_volume(&pwd)
.context("Failed to open hidden volume")
})
}
/// Close a previously opened hidden volume.
pub fn hidden_close(ctx: &mut ExecCtx<'_>) -> anyhow::Result<()> {
with_storage_device(ctx, |_ctx, mut device| {
unsafe { sync() };
device
.disable_hidden_volume()
.context("Failed to close hidden volume")
})
}
/// Return a String representation of the given Option.
fn format_option(option: Option) -> String {
match option {
Some(value) => format!("{}", value),
None => "not set".to_string(),
}
}
/// Read the Nitrokey configuration.
pub fn config_get(ctx: &mut ExecCtx<'_>) -> anyhow::Result<()> {
with_device(ctx, |ctx, device| {
let config = device.get_config().context("Failed to get configuration")?;
println!(
ctx,
r#"Config:
numlock binding: {nl}
capslock binding: {cl}
scrollock binding: {sl}
require user PIN for OTP: {otp}"#,
nl = format_option(config.numlock),
cl = format_option(config.capslock),
sl = format_option(config.scrollock),
otp = config.user_password,
)?;
Ok(())
})
}
/// Write the Nitrokey configuration.
pub fn config_set(ctx: &mut ExecCtx<'_>, args: args::ConfigSetArgs) -> anyhow::Result<()> {
let numlock = args::ConfigOption::try_from(args.no_numlock, args.numlock, "numlock")
.context("Failed to apply numlock configuration")?;
let capslock = args::ConfigOption::try_from(args.no_capslock, args.capslock, "capslock")
.context("Failed to apply capslock configuration")?;
let scrollock = args::ConfigOption::try_from(args.no_scrollock, args.scrollock, "scrollock")
.context("Failed to apply scrollock configuration")?;
let otp_pin = if args.otp_pin {
Some(true)
} else if args.no_otp_pin {
Some(false)
} else {
None
};
with_device(ctx, |ctx, device| {
let mut device = authenticate_admin(ctx, device)?;
let config = device
.get_config()
.context("Failed to get current configuration")?;
let config = nitrokey::Config {
numlock: numlock.or(config.numlock),
capslock: capslock.or(config.capslock),
scrollock: scrollock.or(config.scrollock),
user_password: otp_pin.unwrap_or(config.user_password),
};
device
.write_config(config)
.context("Failed to set new configuration")
})
}
/// Lock the Nitrokey device.
pub fn lock(ctx: &mut ExecCtx<'_>) -> anyhow::Result<()> {
with_device(ctx, |_ctx, mut device| {
device.lock().context("Failed to lock the device")
})
}
fn get_otp(slot: u8, algorithm: args::OtpAlgorithm, device: &mut T) -> anyhow::Result
where
T: GenerateOtp,
{
match algorithm {
args::OtpAlgorithm::Hotp => device.get_hotp_code(slot),
args::OtpAlgorithm::Totp => device.get_totp_code(slot),
}
.context("Failed to generate OTP")
}
fn get_unix_timestamp() -> anyhow::Result {
time::SystemTime::now()
.duration_since(time::UNIX_EPOCH)
.context("Current system time is before the Unix epoch")
.map(|duration| duration.as_secs())
}
/// Generate a one-time password on the Nitrokey device.
pub fn otp_get(
ctx: &mut ExecCtx<'_>,
slot: u8,
algorithm: args::OtpAlgorithm,
time: Option,
) -> anyhow::Result<()> {
with_device(ctx, |ctx, mut device| {
if algorithm == args::OtpAlgorithm::Totp {
device
.set_time(
match time {
Some(time) => time,
None => get_unix_timestamp().context("Failed to retrieve current time")?,
},
true,
)
.context("Failed to set new time")?;
}
let config = device
.get_config()
.context("Failed to get get current device configuration")?;
let otp = if config.user_password {
let mut user = authenticate_user(ctx, device)?;
get_otp(slot, algorithm, &mut user)
} else {
get_otp(slot, algorithm, &mut device)
}?;
println!(ctx, "{}", otp)?;
Ok(())
})
}
/// Format a byte vector as a hex string.
fn format_bytes(bytes: &[u8]) -> String {
bytes
.iter()
.map(|c| format!("{:02x}", c))
.collect::>()
.join("")
}
/// Prepare an ASCII secret string for libnitrokey.
///
/// libnitrokey expects secrets as hexadecimal strings. This function transforms an ASCII string
/// into a hexadecimal string or returns an error if the given string contains non-ASCII
/// characters.
fn prepare_ascii_secret(secret: &str) -> anyhow::Result {
if secret.is_ascii() {
Ok(format_bytes(&secret.as_bytes()))
} else {
anyhow::bail!("The given secret is not an ASCII string as expected")
}
}
/// Prepare a base32 secret string for libnitrokey.
fn prepare_base32_secret(secret: &str) -> anyhow::Result {
base32::decode(base32::Alphabet::RFC4648 { padding: false }, secret)
.map(|vec| format_bytes(&vec))
.ok_or_else(|| anyhow::anyhow!("Failed to parse base32 secret"))
}
/// Configure a one-time password slot on the Nitrokey device.
pub fn otp_set(ctx: &mut ExecCtx<'_>, mut args: args::OtpSetArgs) -> anyhow::Result<()> {
let mut data = nitrokey::OtpSlotData {
number: args.slot,
name: mem::take(&mut args.name),
secret: mem::take(&mut args.secret),
mode: args.digits.into(),
use_enter: false,
token_id: None,
};
with_device(ctx, |ctx, device| {
let secret = match args.format {
args::OtpSecretFormat::Ascii => prepare_ascii_secret(&data.secret)?,
args::OtpSecretFormat::Base32 => prepare_base32_secret(&data.secret)?,
args::OtpSecretFormat::Hex => {
// We need to ensure to provide a string with an even number of
// characters in it, just because that's what libnitrokey
// expects. So prepend a '0' if that is not the case.
// TODO: This code can be removed once upstream issue #164
// (https://github.com/Nitrokey/libnitrokey/issues/164) is
// addressed.
if data.secret.len() % 2 != 0 {
data.secret.insert(0, '0')
}
data.secret
}
};
let data = nitrokey::OtpSlotData { secret, ..data };
let mut device = authenticate_admin(ctx, device)?;
match args.algorithm {
args::OtpAlgorithm::Hotp => device.write_hotp_slot(data, args.counter),
args::OtpAlgorithm::Totp => device.write_totp_slot(data, args.time_window),
}
.context("Failed to write OTP slot")?;
Ok(())
})
}
/// Clear an OTP slot.
pub fn otp_clear(
ctx: &mut ExecCtx<'_>,
slot: u8,
algorithm: args::OtpAlgorithm,
) -> anyhow::Result<()> {
with_device(ctx, |ctx, device| {
let mut device = authenticate_admin(ctx, device)?;
match algorithm {
args::OtpAlgorithm::Hotp => device.erase_hotp_slot(slot),
args::OtpAlgorithm::Totp => device.erase_totp_slot(slot),
}
.context("Failed to clear OTP slot")?;
Ok(())
})
}
fn print_otp_status(
ctx: &mut ExecCtx<'_>,
algorithm: args::OtpAlgorithm,
device: &nitrokey::DeviceWrapper<'_>,
all: bool,
) -> anyhow::Result<()> {
let mut slot: u8 = 0;
loop {
let result = match algorithm {
args::OtpAlgorithm::Hotp => device.get_hotp_slot_name(slot),
args::OtpAlgorithm::Totp => device.get_totp_slot_name(slot),
};
slot = slot
.checked_add(1)
.ok_or_else(|| anyhow::anyhow!("Encountered integer overflow when iterating OTP slots"))?;
let name = match result {
Ok(name) => name,
Err(nitrokey::Error::LibraryError(nitrokey::LibraryError::InvalidSlot)) => return Ok(()),
Err(nitrokey::Error::CommandError(nitrokey::CommandError::SlotNotProgrammed)) => {
if all {
"[not programmed]".to_string()
} else {
continue;
}
}
Err(err) => return Err(err).context("Failed to check OTP slot"),
};
println!(ctx, "{}\t{}\t{}", algorithm, slot - 1, name)?;
}
}
/// Print the status of the OTP slots.
pub fn otp_status(ctx: &mut ExecCtx<'_>, all: bool) -> anyhow::Result<()> {
with_device(ctx, |ctx, device| {
println!(ctx, "alg\tslot\tname")?;
print_otp_status(ctx, args::OtpAlgorithm::Hotp, &device, all)?;
print_otp_status(ctx, args::OtpAlgorithm::Totp, &device, all)?;
Ok(())
})
}
/// Clear the PIN stored by various operations.
pub fn pin_clear(ctx: &mut ExecCtx<'_>) -> anyhow::Result<()> {
with_device(ctx, |_ctx, device| {
pinentry::clear(&pinentry::PinEntry::from(args::PinType::Admin, &device)?)
.context("Failed to clear admin PIN")?;
pinentry::clear(&pinentry::PinEntry::from(args::PinType::User, &device)?)
.context("Failed to clear user PIN")?;
Ok(())
})
}
/// Choose a PIN of the given type.
///
/// If the user has set the respective environment variable for the
/// given PIN type, it will be used.
fn choose_pin(
ctx: &mut ExecCtx<'_>,
pin_entry: &pinentry::PinEntry,
new: bool,
) -> anyhow::Result {
let new_pin = match pin_entry.pin_type() {
args::PinType::Admin => {
if new {
&ctx.new_admin_pin
} else {
&ctx.admin_pin
}
}
args::PinType::User => {
if new {
&ctx.new_user_pin
} else {
&ctx.user_pin
}
}
};
if let Some(new_pin) = new_pin {
new_pin
.to_str()
.ok_or_else(|| anyhow::anyhow!("Failed to read PIN: Invalid Unicode data found"))
.map(ToOwned::to_owned)
} else {
pinentry::choose(ctx, pin_entry).context("Failed to select PIN")
}
}
/// Change a PIN.
pub fn pin_set(ctx: &mut ExecCtx<'_>, pin_type: args::PinType) -> anyhow::Result<()> {
with_device(ctx, |ctx, mut device| {
let pin_entry = pinentry::PinEntry::from(pin_type, &device)?;
let new_pin = choose_pin(ctx, &pin_entry, true)?;
try_with_pin(ctx, &pin_entry, |current_pin| match pin_type {
args::PinType::Admin => device
.change_admin_pin(¤t_pin, &new_pin)
.context("Failed to change admin PIN"),
args::PinType::User => device
.change_user_pin(¤t_pin, &new_pin)
.context("Failed to change user PIN"),
})?;
// We just changed the PIN but confirmed the action with the old PIN,
// which may have caused it to be cached. Since it no longer applies,
// make sure to evict the corresponding entry from the cache.
pinentry::clear(&pin_entry)
})
}
/// Unblock and reset the user PIN.
pub fn pin_unblock(ctx: &mut ExecCtx<'_>) -> anyhow::Result<()> {
with_device(ctx, |ctx, mut device| {
let pin_entry = pinentry::PinEntry::from(args::PinType::User, &device)?;
let user_pin = choose_pin(ctx, &pin_entry, false)?;
let pin_entry = pinentry::PinEntry::from(args::PinType::Admin, &device)?;
try_with_pin(ctx, &pin_entry, |admin_pin| {
device
.unlock_user_pin(&admin_pin, &user_pin)
.context("Failed to unblock user PIN")
})
})
}
fn print_pws_data(
ctx: &mut ExecCtx<'_>,
description: &'static str,
result: Result,
quiet: bool,
) -> anyhow::Result<()> {
let value = result.context("Failed to access PWS slot")?;
if quiet {
println!(ctx, "{}", value)?;
} else {
println!(ctx, "{} {}", description, value)?;
}
Ok(())
}
fn check_slot(pws: &nitrokey::PasswordSafe<'_, '_>, slot: u8) -> anyhow::Result<()> {
if slot >= nitrokey::SLOT_COUNT {
anyhow::bail!("Slot {} is not valid", slot);
}
let status = pws
.get_slot_status()
.context("Failed to read PWS slot status")?;
if status[slot as usize] {
Ok(())
} else {
anyhow::bail!("Slot {} is not programmed", slot)
}
}
/// Read a PWS slot.
pub fn pws_get(
ctx: &mut ExecCtx<'_>,
slot: u8,
show_name: bool,
show_login: bool,
show_password: bool,
quiet: bool,
) -> anyhow::Result<()> {
with_password_safe(ctx, |ctx, pws| {
check_slot(&pws, slot).context("Failed to access PWS slot")?;
let show_all = !show_name && !show_login && !show_password;
if show_all || show_name {
print_pws_data(ctx, "name: ", pws.get_slot_name(slot), quiet)?;
}
if show_all || show_login {
print_pws_data(ctx, "login: ", pws.get_slot_login(slot), quiet)?;
}
if show_all || show_password {
print_pws_data(ctx, "password:", pws.get_slot_password(slot), quiet)?;
}
Ok(())
})
}
/// Write a PWS slot.
pub fn pws_set(
ctx: &mut ExecCtx<'_>,
slot: u8,
name: &str,
login: &str,
password: &str,
) -> anyhow::Result<()> {
with_password_safe(ctx, |_ctx, mut pws| {
pws
.write_slot(slot, name, login, password)
.context("Failed to write PWS slot")
})
}
/// Clear a PWS slot.
pub fn pws_clear(ctx: &mut ExecCtx<'_>, slot: u8) -> anyhow::Result<()> {
with_password_safe(ctx, |_ctx, mut pws| {
pws.erase_slot(slot).context("Failed to clear PWS slot")
})
}
fn print_pws_slot(
ctx: &mut ExecCtx<'_>,
pws: &nitrokey::PasswordSafe<'_, '_>,
slot: usize,
programmed: bool,
) -> anyhow::Result<()> {
let slot = u8::try_from(slot).map_err(|_| anyhow::anyhow!("Invalid PWS slot number"))?;
let name = if programmed {
pws
.get_slot_name(slot)
.context("Failed to read PWS slot name")?
} else {
"[not programmed]".to_string()
};
println!(ctx, "{}\t{}", slot, name)?;
Ok(())
}
/// Print the status of all PWS slots.
pub fn pws_status(ctx: &mut ExecCtx<'_>, all: bool) -> anyhow::Result<()> {
with_password_safe(ctx, |ctx, pws| {
let slots = pws
.get_slot_status()
.context("Failed to read PWS slot status")?;
println!(ctx, "slot\tname")?;
for (i, &value) in slots.iter().enumerate().filter(|(_, &value)| all || value) {
print_pws_slot(ctx, &pws, i, value)?;
}
Ok(())
})
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn prepare_secret_ascii() {
let result = prepare_ascii_secret("12345678901234567890");
assert_eq!(
"3132333435363738393031323334353637383930".to_string(),
result.unwrap()
);
}
#[test]
fn prepare_secret_non_ascii() {
let result = prepare_ascii_secret("Österreich");
assert!(result.is_err());
}
#[test]
fn hex_string() {
assert_eq!(format_bytes(&[b' ']), "20");
assert_eq!(format_bytes(&[b' ', b' ']), "2020");
assert_eq!(format_bytes(&[b'\n', b'\n']), "0a0a");
}
}