rust-bitcoin-unsafe-fast/src/blockdata/script.rs

// Rust Bitcoin Library
// Written in 2014 by
//     Andrew Poelstra <apoelstra@wpsoftware.net>
//
// To the extent possible under law, the author(s) have dedicated all
// copyright and related and neighboring rights to this software to
// the public domain worldwide. This software is distributed without
// any warranty.
//
// You should have received a copy of the CC0 Public Domain Dedication
// along with this software.
// If not, see <http://creativecommons.org/publicdomain/zero/1.0/>.
//

//! # Script
//!
//! Scripts define Bitcoin's digital signature scheme: a signature is formed
//! from a script (the second half of which is defined by a coin to be spent,
//! and the first half provided by the spending transaction), and is valid
//! iff the script leaves `TRUE` on the stack after being evaluated.
//! Bitcoin's script is a stack-based assembly language similar in spirit to
//! Forth.
//!
//! This module provides the structures and functions needed to support scripts.
//!

use std::default::Default;
use std::{error, fmt};

use serde;

use blockdata::opcodes;
use network::encodable::{ConsensusDecodable, ConsensusEncodable};
use network::serialize::{SimpleDecoder, SimpleEncoder};

#[derive(Clone, PartialEq, Eq, Hash)]
/// A Bitcoin script
pub struct Script(Box<[u8]>);

impl fmt::Debug for Script {
    fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
        let mut index = 0;

        try!(f.write_str("Script("));
        while index < self.0.len() {
            let opcode = opcodes::All::from(self.0[index]);
            index += 1;

            let data_len = if let opcodes::Class::PushBytes(n) = opcode.classify() {
                n as usize
            } else {
                match opcode {
                    opcodes::All::OP_PUSHDATA1 => {
                        if self.0.len() < index + 1 {
                            try!(f.write_str("<unexpected end>"));
                            break;
                        }
                        match read_uint(&self.0[index..], 1) {
                            Ok(n) => { index += 1; n as usize }
                            Err(_) => { try!(f.write_str("<bad length>")); break; }
                        }
                    }
                    opcodes::All::OP_PUSHDATA2 => {
                        if self.0.len() < index + 2 {
                            try!(f.write_str("<unexpected end>"));
                            break;
                        }
                        match read_uint(&self.0[index..], 2) {
                            Ok(n) => { index += 2; n as usize }
                            Err(_) => { try!(f.write_str("<bad length>")); break; }
                        }
                    }
                    opcodes::All::OP_PUSHDATA4 => {
                        if self.0.len() < index + 4 {
                            try!(f.write_str("<unexpected end>"));
                            break;
                        }
                        match read_uint(&self.0[index..], 4) {
                            Ok(n) => { index += 4; n as usize }
                            Err(_) => { try!(f.write_str("<bad length>")); break; }
                        }
                    }
                    _ => 0
                }
            };

            if index > 1 { try!(f.write_str(" ")); }
            // Write the opcode
            if opcode == opcodes::All::OP_PUSHBYTES_0 {
                try!(f.write_str("OP_0"));
            } else {
                try!(write!(f, "{:?}", opcode));
            }
            // Write any pushdata
            if data_len > 0 {
                try!(f.write_str(" "));
                if index + data_len <= self.0.len() {
                    for ch in &self.0[index..index + data_len] {
                            try!(write!(f, "{:02x}", ch));
                    }
                    index += data_len;
                } else {
                    try!(f.write_str("<push past end>"));
                    break;
                }
            }
        }
        f.write_str(")")
    }
}

impl fmt::Display for Script {
    fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
        fmt::Debug::fmt(self, f)
    }
}

impl fmt::LowerHex for Script {
    fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
        for &ch in self.0.iter() {
            try!(write!(f, "{:02x}", ch));
        }
        Ok(())
    }
}

impl fmt::UpperHex for Script {
    fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
        for &ch in self.0.iter() {
            try!(write!(f, "{:02X}", ch));
        }
        Ok(())
    }
}

#[derive(PartialEq, Eq, Debug, Clone)]
/// An object which can be used to construct a script piece by piece
pub struct Builder(Vec<u8>);
display_from_debug!(Builder);

/// Ways that a script might fail. Not everything is split up as
/// much as it could be; patches welcome if more detailed errors
/// would help you.
#[derive(PartialEq, Eq, Debug, Clone)]
pub enum Error {
    /// Some opcode expected a parameter, but it was missing or truncated
    EarlyEndOfScript,
    /// Tried to read an array off the stack as a number when it was more than 4 bytes
    NumericOverflow,
}

impl fmt::Display for Error {
    fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
        f.write_str(error::Error::description(self))
    }
}

impl error::Error for Error {
    fn cause(&self) -> Option<&error::Error> { None }

    fn description(&self) -> &'static str {
        match *self {
            Error::EarlyEndOfScript => "unexpected end of script",
            Error::NumericOverflow => "numeric overflow (number on stack larger than 4 bytes)",
        }
    }
}

/// Helper to encode an integer in script format
fn build_scriptint(n: i64) -> Vec<u8> {
    if n == 0 { return vec![] }

    let neg = n < 0;

    let mut abs = if neg { -n } else { n } as usize;
    let mut v = vec![];
    while abs > 0xFF {
        v.push((abs & 0xFF) as u8);
        abs >>= 8;
    }
    // If the number's value causes the sign bit to be set, we need an extra
    // byte to get the correct value and correct sign bit
    if abs & 0x80 != 0 {
        v.push(abs as u8);
        v.push(if neg { 0x80u8 } else { 0u8 });
    }
    // Otherwise we just set the sign bit ourselves
    else {
        abs |= if neg { 0x80 } else { 0 };
        v.push(abs as u8);
    }
    v
}

/// Helper to decode an integer in script format
/// Notice that this fails on overflow: the result is the same as in
/// bitcoind, that only 4-byte signed-magnitude values may be read as
/// numbers. They can be added or subtracted (and a long time ago,
/// multiplied and divided), and this may result in numbers which
/// can't be written out in 4 bytes or less. This is ok! The number
/// just can't be read as a number again.
/// This is a bit crazy and subtle, but it makes sense: you can load
/// 32-bit numbers and do anything with them, which back when mult/div
/// was allowed, could result in up to a 64-bit number. We don't want
/// overflow since that's suprising --- and we don't want numbers that
/// don't fit in 64 bits (for efficiency on modern processors) so we
/// simply say, anything in excess of 32 bits is no longer a number.
/// This is basically a ranged type implementation.
pub fn read_scriptint(v: &[u8]) -> Result<i64, Error> {
    let len = v.len();
    if len == 0 { return Ok(0); }
    if len > 4 { return Err(Error::NumericOverflow); }

    let (mut ret, sh) = v.iter()
                         .fold((0, 0), |(acc, sh), n| (acc + ((*n as i64) << sh), sh + 8));
    if v[len - 1] & 0x80 != 0 {
        ret &= (1 << (sh - 1)) - 1;
        ret = -ret;
    }
    Ok(ret)
}

/// This is like "`read_scriptint` then map 0 to false and everything
/// else as true", except that the overflow rules don't apply.
#[inline]
pub fn read_scriptbool(v: &[u8]) -> bool {
    !(v.is_empty() ||
        ((v[v.len() - 1] == 0 || v[v.len() - 1] == 0x80) &&
         v.iter().rev().skip(1).all(|&w| w == 0)))
}

/// Read a script-encoded unsigned integer
pub fn read_uint(data: &[u8], size: usize) -> Result<usize, Error> {
    if data.len() < size {
        Err(Error::EarlyEndOfScript)
    } else {
        let mut ret = 0;
        for (i, item) in data.iter().take(size).enumerate() {
            ret += (*item as usize) << (i * 8);
        }
        Ok(ret)
    }
}

impl Script {
    /// Creates a new empty script
    pub fn new() -> Script { Script(vec![].into_boxed_slice()) }

    /// The length in bytes of the script
    pub fn len(&self) -> usize { self.0.len() }

    /// Whether the script is the empty script
    pub fn is_empty(&self) -> bool { self.0.is_empty() }

    /// Convert the script into a byte vector
    pub fn into_vec(self) -> Vec<u8> { self.0.into_vec() }

    /// Checks whether a script pubkey is a p2sh output
    #[inline]
    pub fn is_p2sh(&self) -> bool {
        self.0.len() == 23 &&
        self.0[0] == opcodes::All::OP_HASH160 as u8 &&
        self.0[1] == opcodes::All::OP_PUSHBYTES_20 as u8 &&
        self.0[22] == opcodes::All::OP_EQUAL as u8
    }

    /// Whether a script can be proven to have no satisfying input
    pub fn is_provably_unspendable(&self) -> bool {
        !self.0.is_empty() && (opcodes::All::from(self.0[0]).classify() == opcodes::Class::ReturnOp ||
                               opcodes::All::from(self.0[0]).classify() == opcodes::Class::IllegalOp)
    }
}

impl Default for Script {
    fn default() -> Script { Script(vec![].into_boxed_slice()) }
}

/// Creates a new script from an existing vector
impl From<Vec<u8>> for Script {
    fn from(v: Vec<u8>) -> Script { Script(v.into_boxed_slice()) }
}

impl_index_newtype!(Script, u8);

/// A "parsed opcode" which allows iterating over a Script in a more sensible way
#[derive(Debug, PartialEq, Eq, Clone)]
pub enum Instruction<'a> {
    /// Push a bunch of data
    PushBytes(&'a [u8]),
    /// Some non-push opcode
    Op(opcodes::All),
    /// An opcode we were unable to parse
    Error(Error)
}

/// Iterator over a script returning parsed opcodes
pub struct Instructions<'a> {
    data: &'a [u8]
}

impl<'a> IntoIterator for &'a Script {
    type Item = Instruction<'a>;
    type IntoIter = Instructions<'a>;
    fn into_iter(self) -> Instructions<'a> { Instructions { data: &self.0[..] } }
}

impl<'a> Iterator for Instructions<'a> {
    type Item = Instruction<'a>;

    fn next(&mut self) -> Option<Instruction<'a>> {
        if self.data.is_empty() {
            return None;
        }

        match opcodes::All::from(self.data[0]).classify() {
            opcodes::Class::PushBytes(n) => {
                let n = n as usize;
                if self.data.len() < n + 1 {
                    return Some(Instruction::Error(Error::EarlyEndOfScript));
                }
                let ret = Some(Instruction::PushBytes(&self.data[1..n+1]));
                self.data = &self.data[n + 1..];
                ret
            }
            opcodes::Class::Ordinary(opcodes::Ordinary::OP_PUSHDATA1) => {
                if self.data.len() < 2 { return Some(Instruction::Error(Error::EarlyEndOfScript)); }
                let n = match read_uint(&self.data[1..], 1) {
                    Ok(n) => n,
                    Err(e) => { return Some(Instruction::Error(e)); }
                };
                if self.data.len() < n + 2 { return Some(Instruction::Error(Error::EarlyEndOfScript)); }
                let ret = Some(Instruction::PushBytes(&self.data[2..n+2]));
                self.data = &self.data[n + 2..];
                ret
            }
            opcodes::Class::Ordinary(opcodes::Ordinary::OP_PUSHDATA2) => {
                if self.data.len() < 3 { return Some(Instruction::Error(Error::EarlyEndOfScript)); }
                let n = match read_uint(&self.data[1..], 2) {
                    Ok(n) => n,
                    Err(e) => { return Some(Instruction::Error(e)); }
                };
                if self.data.len() < n + 3 { return Some(Instruction::Error(Error::EarlyEndOfScript)); }
                let ret = Some(Instruction::PushBytes(&self.data[3..n + 3]));
                self.data = &self.data[n + 3..];
                ret
            }
            opcodes::Class::Ordinary(opcodes::Ordinary::OP_PUSHDATA4) => {
                if self.data.len() < 5 { return Some(Instruction::Error(Error::EarlyEndOfScript)); }
                let n = match read_uint(&self.data[1..], 4) {
                    Ok(n) => n,
                    Err(e) => { return Some(Instruction::Error(e)); }
                };
                if self.data.len() < n + 5 { return Some(Instruction::Error(Error::EarlyEndOfScript)); }
                let ret = Some(Instruction::PushBytes(&self.data[5..n + 5]));
                self.data = &self.data[n + 5..];
                ret
            }
            // Everything else we can push right through
            _ => {
                let ret = Some(Instruction::Op(opcodes::All::from(self.data[0])));
                self.data = &self.data[1..];
                ret
            }
        }
    }
}

impl Builder {
    /// Creates a new empty script
    pub fn new() -> Builder { Builder(vec![]) }

    /// The length in bytes of the script
    pub fn len(&self) -> usize { self.0.len() }

    /// Whether the script is the empty script
    pub fn is_empty(&self) -> bool { self.0.is_empty() }

    /// Adds instructions to push an integer onto the stack. Integers are
    /// encoded as little-endian signed-magnitude numbers, but there are
    /// dedicated opcodes to push some small integers.
    pub fn push_int(mut self, data: i64) -> Builder {
        // We can special-case -1, 1-16
        if data == -1 || (data >= 1 && data <= 16) {
            self.0.push((data - 1 + opcodes::OP_TRUE as i64) as u8);
            self
        }
        // We can also special-case zero
        else if data == 0 {
            self.0.push(opcodes::OP_FALSE as u8);
            self
        }
        // Otherwise encode it as data
        else { self.push_scriptint(data) }
    }

    /// Adds instructions to push an integer onto the stack, using the explicit
    /// encoding regardless of the availability of dedicated opcodes.
    pub fn push_scriptint(self, data: i64) -> Builder {
        self.push_slice(&build_scriptint(data))
    }

    /// Adds instructions to push some arbitrary data onto the stack
    pub fn push_slice(mut self, data: &[u8]) -> Builder {
        // Start with a PUSH opcode
        match data.len() {
            n if n < opcodes::Ordinary::OP_PUSHDATA1 as usize => { self.0.push(n as u8); },
            n if n < 0x100 => {
                self.0.push(opcodes::Ordinary::OP_PUSHDATA1 as u8);
                self.0.push(n as u8);
            },
            n if n < 0x10000 => {
                self.0.push(opcodes::Ordinary::OP_PUSHDATA2 as u8);
                self.0.push((n % 0x100) as u8);
                self.0.push((n / 0x100) as u8);
            },
            n if n < 0x100000000 => {
                self.0.push(opcodes::Ordinary::OP_PUSHDATA4 as u8);
                self.0.push((n % 0x100) as u8);
                self.0.push(((n / 0x100) % 0x100) as u8);
                self.0.push(((n / 0x10000) % 0x100) as u8);
                self.0.push((n / 0x1000000) as u8);
            }
            _ => panic!("tried to put a 4bn+ sized object into a script!")
        }
        // Then push the acraw
        self.0.extend(data.iter().cloned());
        self
    }

    /// Adds a single opcode to the script
    pub fn push_opcode(mut self, data: opcodes::All) -> Builder {
        self.0.push(data as u8);
        self
    }

    /// Converts the `Builder` into an unmodifiable `Script`
    pub fn into_script(self) -> Script {
        Script(self.0.into_boxed_slice())
    }
}

/// Adds an individual opcode to the script
impl Default for Builder {
    fn default() -> Builder { Builder(vec![]) }
}

/// Creates a new script from an existing vector
impl From<Vec<u8>> for Builder {
    fn from(v: Vec<u8>) -> Builder { Builder(v) }
}

impl_index_newtype!(Builder, u8);

// User-facing serialization
impl serde::Serialize for Script {
    fn serialize<S>(&self, s: &mut S) -> Result<(), S::Error>
        where S: serde::Serializer,
    {
        s.visit_str(&format!("{:x}", self))
    }
}

impl serde::Deserialize for Script {
    fn deserialize<D>(d: &mut D) -> Result<Script, D::Error>
        where D: serde::Deserializer
    {
        use serialize::hex::FromHex;

        struct ScriptVisitor;
        impl serde::de::Visitor for ScriptVisitor {
            type Value = Script;

            fn visit_string<E>(&mut self, v: String) -> Result<Script, E>
                where E: serde::de::Error
            {
                self.visit_str(&v)
            }

            fn visit_str<E>(&mut self, hex_str: &str) -> Result<Script, E>
                where E: serde::de::Error
            {
                let raw_vec: Vec<u8> = try!(hex_str.from_hex()
                                                   .map_err(|_| serde::de::Error::syntax("bad script hex")));
                Ok(Script::from(raw_vec))
            }
        }

        d.visit(ScriptVisitor)
    }
}

// Network serialization
impl<S: SimpleEncoder> ConsensusEncodable<S> for Script {
    #[inline]
    fn consensus_encode(&self, s: &mut S) -> Result<(), S::Error> {
        self.0.consensus_encode(s)
    }
}

impl<D: SimpleDecoder> ConsensusDecodable<D> for Script {
    #[inline]
    fn consensus_decode(d: &mut D) -> Result<Script, D::Error> {
        Ok(Script(try!(ConsensusDecodable::consensus_decode(d))))
    }
}

#[cfg(test)]
mod test {
    use serialize::hex::FromHex;

    use super::*;
    use super::build_scriptint;

    use network::serialize::{deserialize, serialize};
    use blockdata::opcodes;

    #[test]
    fn script() {
        let mut comp = vec![];
        let mut script = Builder::new();
        assert_eq!(&script[..], &comp[..]);

        // small ints
        script = script.push_int(1);  comp.push(81u8); assert_eq!(&script[..], &comp[..]);
        script = script.push_int(0);  comp.push(0u8);  assert_eq!(&script[..], &comp[..]);
        script = script.push_int(4);  comp.push(84u8); assert_eq!(&script[..], &comp[..]);
        script = script.push_int(-1); comp.push(79u8); assert_eq!(&script[..], &comp[..]);
        // forced scriptint
        script = script.push_scriptint(4); comp.extend([1u8, 4].iter().cloned()); assert_eq!(&script[..], &comp[..]);
        // big ints
        script = script.push_int(17); comp.extend([1u8, 17].iter().cloned()); assert_eq!(&script[..], &comp[..]);
        script = script.push_int(10000); comp.extend([2u8, 16, 39].iter().cloned()); assert_eq!(&script[..], &comp[..]);
        // notice the sign bit set here, hence the extra zero/128 at the end
        script = script.push_int(10000000); comp.extend([4u8, 128, 150, 152, 0].iter().cloned()); assert_eq!(&script[..], &comp[..]);
        script = script.push_int(-10000000); comp.extend([4u8, 128, 150, 152, 128].iter().cloned()); assert_eq!(&script[..], &comp[..]);

        // data
        script = script.push_slice("NRA4VR".as_bytes()); comp.extend([6u8, 78, 82, 65, 52, 86, 82].iter().cloned()); assert_eq!(&script[..], &comp[..]);

        // opcodes 
        script = script.push_opcode(opcodes::All::OP_CHECKSIG); comp.push(0xACu8); assert_eq!(&script[..], &comp[..]);
        script = script.push_opcode(opcodes::All::OP_CHECKSIG); comp.push(0xACu8); assert_eq!(&script[..], &comp[..]);
    }

    #[test]
    fn script_builder() {
        // from txid 3bb5e6434c11fb93f64574af5d116736510717f2c595eb45b52c28e31622dfff which was in my mempool when I wrote the test
        let script = Builder::new().push_opcode(opcodes::All::OP_DUP)
                                   .push_opcode(opcodes::All::OP_HASH160)
                                   .push_slice(&"16e1ae70ff0fa102905d4af297f6912bda6cce19".from_hex().unwrap())
                                   .push_opcode(opcodes::All::OP_EQUALVERIFY)
                                   .push_opcode(opcodes::All::OP_CHECKSIG)
                                   .into_script();
        assert_eq!(&format!("{:x}", script), "76a91416e1ae70ff0fa102905d4af297f6912bda6cce1988ac");
    }

    #[test]
    fn script_serialize() {
        let hex_script = "6c493046022100f93bb0e7d8db7bd46e40132d1f8242026e045f03a0efe71bbb8e3f475e970d790221009337cd7f1f929f00cc6ff01f03729b069a7c21b59b1736ddfee5db5946c5da8c0121033b9b137ee87d5a812d6f506efdd37f0affa7ffc310711c06c7f3e097c9447c52".from_hex().unwrap();
        let script: Result<Script, _> = deserialize(&hex_script);
        assert!(script.is_ok());
        assert_eq!(serialize(&script.unwrap()).ok(), Some(hex_script));
    }

    #[test]
    fn scriptint_round_trip() {
        assert_eq!(build_scriptint(-1), vec![0x81]);
        assert_eq!(build_scriptint(255), vec![255, 0]);
        assert_eq!(build_scriptint(256), vec![0, 1]);
        assert_eq!(build_scriptint(257), vec![1, 1]);
        assert_eq!(build_scriptint(511), vec![255, 1]);
        for &i in [10, 100, 255, 256, 1000, 10000, 25000, 200000, 5000000, 1000000000,
                             (1 << 31) - 1, -((1 << 31) - 1)].iter() {
            assert_eq!(Ok(i), read_scriptint(&build_scriptint(i)));
            assert_eq!(Ok(-i), read_scriptint(&build_scriptint(-i)));
        }
        assert!(read_scriptint(&build_scriptint(1 << 31)).is_err());
        assert!(read_scriptint(&build_scriptint(-(1 << 31))).is_err());
    }

    macro_rules! hex_script (($s:expr) => (Script::from($s.from_hex().unwrap())));

    #[test]
    fn provably_unspendable_test() {
        // p2pk
        assert_eq!(hex_script!("410446ef0102d1ec5240f0d061a4246c1bdef63fc3dbab7733052fbbf0ecd8f41fc26bf049ebb4f9527f374280259e7cfa99c48b0e3f39c51347a19a5819651503a5ac").is_provably_unspendable(), false);
        assert_eq!(hex_script!("4104ea1feff861b51fe3f5f8a3b12d0f4712db80e919548a80839fc47c6a21e66d957e9c5d8cd108c7a2d2324bad71f9904ac0ae7336507d785b17a2c115e427a32fac").is_provably_unspendable(), false);
        // p2pkhash
        assert_eq!(hex_script!("76a914ee61d57ab51b9d212335b1dba62794ac20d2bcf988ac").is_provably_unspendable(), false);
        assert_eq!(hex_script!("6aa9149eb21980dc9d413d8eac27314938b9da920ee53e87").is_provably_unspendable(), true);
    }

    #[test]
    fn script_json_serialize() {
        use strason;

        let original = hex_script!("827651a0698faaa9a8a7a687");
        let json = strason::from_serialize(&original).unwrap();
        assert_eq!(json.to_bytes(), b"\"827651a0698faaa9a8a7a687\"");
        assert_eq!(json.string(), Some("827651a0698faaa9a8a7a687"));
        let des = json.into_deserialize().unwrap();
        assert_eq!(original, des);
    }

    #[test]
    fn script_debug_display() {
        assert_eq!(format!("{:?}", hex_script!("6363636363686868686800")),
                   "Script(OP_IF OP_IF OP_IF OP_IF OP_IF OP_ENDIF OP_ENDIF OP_ENDIF OP_ENDIF OP_ENDIF OP_0)");
        assert_eq!(format!("{}", hex_script!("6363636363686868686800")),
                   "Script(OP_IF OP_IF OP_IF OP_IF OP_IF OP_ENDIF OP_ENDIF OP_ENDIF OP_ENDIF OP_ENDIF OP_0)");
        assert_eq!(format!("{}", hex_script!("2102715e91d37d239dea832f1460e91e368115d8ca6cc23a7da966795abad9e3b699ac")),
                   "Script(OP_PUSHBYTES_33 02715e91d37d239dea832f1460e91e368115d8ca6cc23a7da966795abad9e3b699 OP_CHECKSIG)");
        // Elements Alpha peg-out transaction with some signatures removed for brevity. Mainly to test PUSHDATA1
        assert_eq!(format!("{}", hex_script!("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")),
                   "Script(OP_0 OP_PUSHBYTES_71 304402202457e78cc1b7f50d0543863c27de75d07982bde8359b9e3316adec0aec165f2f02200203fd331c4e4a4a02f48cf1c291e2c0d6b2f7078a784b5b3649fca41f8794d401 OP_0 OP_PUSHDATA1 552103244e602b46755f24327142a0517288cebd159eccb6ccf41ea6edf1f601e9af952103bbbacc302d19d29dbfa62d23f37944ae19853cf260c745c2bea739c95328fcb721039227e83246bd51140fe93538b2301c9048be82ef2fb3c7fc5d78426ed6f609ad210229bf310c379b90033e2ecb07f77ecf9b8d59acb623ab7be25a0caed539e2e6472103703e2ed676936f10b3ce9149fa2d4a32060fb86fa9a70a4efe3f21d7ab90611921031e9b7c6022400a6bb0424bbcde14cff6c016b91ee3803926f3440abf5c146d05210334667f975f55a8455d515a2ef1c94fdfa3315f12319a14515d2a13d82831f62f57ae)");
    }
}