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// Bitcoin Dev Kit
// Written in 2020 by Alekos Filini <alekos.filini@gmail.com>
//
// Copyright (c) 2020-2021 Bitcoin Dev Kit Developers
//
// This file is licensed under the Apache License, Version 2.0 <LICENSE-APACHE
// or http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your option.
// You may not use this file except in accordance with one or both of these
// licenses.

//! Descriptors
//!
//! This module contains generic utilities to work with descriptors, plus some re-exported types
//! from [`miniscript`].

use crate::collections::BTreeMap;
use alloc::string::String;
use alloc::vec::Vec;

use bitcoin::bip32::{ChildNumber, DerivationPath, ExtendedPubKey, Fingerprint, KeySource};
use bitcoin::{key::XOnlyPublicKey, secp256k1, PublicKey};
use bitcoin::{psbt, taproot};
use bitcoin::{Network, TxOut};

use miniscript::descriptor::{
    DefiniteDescriptorKey, DescriptorMultiXKey, DescriptorSecretKey, DescriptorType,
    DescriptorXKey, InnerXKey, KeyMap, SinglePubKey, Wildcard,
};
pub use miniscript::{
    Descriptor, DescriptorPublicKey, Legacy, Miniscript, ScriptContext, Segwitv0,
};
use miniscript::{ForEachKey, MiniscriptKey, TranslatePk};

use crate::descriptor::policy::BuildSatisfaction;

pub mod checksum;
#[doc(hidden)]
pub mod dsl;
pub mod error;
pub mod policy;
pub mod template;

pub use self::checksum::calc_checksum;
use self::checksum::calc_checksum_bytes;
pub use self::error::Error as DescriptorError;
pub use self::policy::Policy;
use self::template::DescriptorTemplateOut;
use crate::keys::{IntoDescriptorKey, KeyError};
use crate::wallet::signer::SignersContainer;
use crate::wallet::utils::SecpCtx;

/// Alias for a [`Descriptor`] that can contain extended keys using [`DescriptorPublicKey`]
pub type ExtendedDescriptor = Descriptor<DescriptorPublicKey>;

/// Alias for a [`Descriptor`] that contains extended **derived** keys
pub type DerivedDescriptor = Descriptor<DefiniteDescriptorKey>;

/// Alias for the type of maps that represent derivation paths in a [`psbt::Input`] or
/// [`psbt::Output`]
///
/// [`psbt::Input`]: bitcoin::psbt::Input
/// [`psbt::Output`]: bitcoin::psbt::Output
pub type HdKeyPaths = BTreeMap<secp256k1::PublicKey, KeySource>;

/// Alias for the type of maps that represent taproot key origins in a [`psbt::Input`] or
/// [`psbt::Output`]
///
/// [`psbt::Input`]: bitcoin::psbt::Input
/// [`psbt::Output`]: bitcoin::psbt::Output
pub type TapKeyOrigins = BTreeMap<XOnlyPublicKey, (Vec<taproot::TapLeafHash>, KeySource)>;

/// Trait for types which can be converted into an [`ExtendedDescriptor`] and a [`KeyMap`] usable by a wallet in a specific [`Network`]
pub trait IntoWalletDescriptor {
    /// Convert to wallet descriptor
    fn into_wallet_descriptor(
        self,
        secp: &SecpCtx,
        network: Network,
    ) -> Result<(ExtendedDescriptor, KeyMap), DescriptorError>;
}

impl IntoWalletDescriptor for &str {
    fn into_wallet_descriptor(
        self,
        secp: &SecpCtx,
        network: Network,
    ) -> Result<(ExtendedDescriptor, KeyMap), DescriptorError> {
        let descriptor = match self.split_once('#') {
            Some((desc, original_checksum)) => {
                let checksum = calc_checksum_bytes(desc)?;
                if original_checksum.as_bytes() != checksum {
                    return Err(DescriptorError::InvalidDescriptorChecksum);
                }
                desc
            }
            None => self,
        };

        ExtendedDescriptor::parse_descriptor(secp, descriptor)?
            .into_wallet_descriptor(secp, network)
    }
}

impl IntoWalletDescriptor for &String {
    fn into_wallet_descriptor(
        self,
        secp: &SecpCtx,
        network: Network,
    ) -> Result<(ExtendedDescriptor, KeyMap), DescriptorError> {
        self.as_str().into_wallet_descriptor(secp, network)
    }
}

impl IntoWalletDescriptor for ExtendedDescriptor {
    fn into_wallet_descriptor(
        self,
        secp: &SecpCtx,
        network: Network,
    ) -> Result<(ExtendedDescriptor, KeyMap), DescriptorError> {
        (self, KeyMap::default()).into_wallet_descriptor(secp, network)
    }
}

impl IntoWalletDescriptor for (ExtendedDescriptor, KeyMap) {
    fn into_wallet_descriptor(
        self,
        secp: &SecpCtx,
        network: Network,
    ) -> Result<(ExtendedDescriptor, KeyMap), DescriptorError> {
        use crate::keys::DescriptorKey;

        struct Translator<'s, 'd> {
            secp: &'s SecpCtx,
            descriptor: &'d ExtendedDescriptor,
            network: Network,
        }

        impl<'s, 'd> miniscript::Translator<DescriptorPublicKey, String, DescriptorError>
            for Translator<'s, 'd>
        {
            fn pk(&mut self, pk: &DescriptorPublicKey) -> Result<String, DescriptorError> {
                let secp = &self.secp;

                let (_, _, networks) = if self.descriptor.is_taproot() {
                    let descriptor_key: DescriptorKey<miniscript::Tap> =
                        pk.clone().into_descriptor_key()?;
                    descriptor_key.extract(secp)?
                } else if self.descriptor.is_witness() {
                    let descriptor_key: DescriptorKey<miniscript::Segwitv0> =
                        pk.clone().into_descriptor_key()?;
                    descriptor_key.extract(secp)?
                } else {
                    let descriptor_key: DescriptorKey<miniscript::Legacy> =
                        pk.clone().into_descriptor_key()?;
                    descriptor_key.extract(secp)?
                };

                if networks.contains(&self.network) {
                    Ok(Default::default())
                } else {
                    Err(DescriptorError::Key(KeyError::InvalidNetwork))
                }
            }
            fn sha256(
                &mut self,
                _sha256: &<DescriptorPublicKey as MiniscriptKey>::Sha256,
            ) -> Result<String, DescriptorError> {
                Ok(Default::default())
            }
            fn hash256(
                &mut self,
                _hash256: &<DescriptorPublicKey as MiniscriptKey>::Hash256,
            ) -> Result<String, DescriptorError> {
                Ok(Default::default())
            }
            fn ripemd160(
                &mut self,
                _ripemd160: &<DescriptorPublicKey as MiniscriptKey>::Ripemd160,
            ) -> Result<String, DescriptorError> {
                Ok(Default::default())
            }
            fn hash160(
                &mut self,
                _hash160: &<DescriptorPublicKey as MiniscriptKey>::Hash160,
            ) -> Result<String, DescriptorError> {
                Ok(Default::default())
            }
        }

        // check the network for the keys
        use miniscript::TranslateErr;
        match self.0.translate_pk(&mut Translator {
            secp,
            network,
            descriptor: &self.0,
        }) {
            Ok(_) => {}
            Err(TranslateErr::TranslatorErr(e)) => return Err(e),
            Err(TranslateErr::OuterError(e)) => return Err(e.into()),
        }

        Ok(self)
    }
}

impl IntoWalletDescriptor for DescriptorTemplateOut {
    fn into_wallet_descriptor(
        self,
        _secp: &SecpCtx,
        network: Network,
    ) -> Result<(ExtendedDescriptor, KeyMap), DescriptorError> {
        struct Translator {
            network: Network,
        }

        impl miniscript::Translator<DescriptorPublicKey, DescriptorPublicKey, DescriptorError>
            for Translator
        {
            fn pk(
                &mut self,
                pk: &DescriptorPublicKey,
            ) -> Result<DescriptorPublicKey, DescriptorError> {
                // workaround for xpubs generated by other key types, like bip39: since when the
                // conversion is made one network has to be chosen, what we generally choose
                // "mainnet", but then override the set of valid networks to specify that all of
                // them are valid. here we reset the network to make sure the wallet struct gets a
                // descriptor with the right network everywhere.
                let pk = match pk {
                    DescriptorPublicKey::XPub(ref xpub) => {
                        let mut xpub = xpub.clone();
                        xpub.xkey.network = self.network;

                        DescriptorPublicKey::XPub(xpub)
                    }
                    other => other.clone(),
                };

                Ok(pk)
            }
            miniscript::translate_hash_clone!(
                DescriptorPublicKey,
                DescriptorPublicKey,
                DescriptorError
            );
        }

        let (desc, keymap, networks) = self;

        if !networks.contains(&network) {
            return Err(DescriptorError::Key(KeyError::InvalidNetwork));
        }

        // fixup the network for keys that need it in the descriptor
        use miniscript::TranslateErr;
        let translated = match desc.translate_pk(&mut Translator { network }) {
            Ok(descriptor) => descriptor,
            Err(TranslateErr::TranslatorErr(e)) => return Err(e),
            Err(TranslateErr::OuterError(e)) => return Err(e.into()),
        };
        // ...and in the key map
        let fixed_keymap = keymap
            .into_iter()
            .map(|(mut k, mut v)| {
                match (&mut k, &mut v) {
                    (DescriptorPublicKey::XPub(xpub), DescriptorSecretKey::XPrv(xprv)) => {
                        xpub.xkey.network = network;
                        xprv.xkey.network = network;
                    }
                    (_, DescriptorSecretKey::Single(key)) => {
                        key.key.network = network;
                    }
                    _ => {}
                }

                (k, v)
            })
            .collect();

        Ok((translated, fixed_keymap))
    }
}

/// Wrapper for `IntoWalletDescriptor` that performs additional checks on the keys contained in the
/// descriptor
pub(crate) fn into_wallet_descriptor_checked<T: IntoWalletDescriptor>(
    inner: T,
    secp: &SecpCtx,
    network: Network,
) -> Result<(ExtendedDescriptor, KeyMap), DescriptorError> {
    let (descriptor, keymap) = inner.into_wallet_descriptor(secp, network)?;

    // Ensure the keys don't contain any hardened derivation steps or hardened wildcards
    let descriptor_contains_hardened_steps = descriptor.for_any_key(|k| {
        if let DescriptorPublicKey::XPub(DescriptorXKey {
            derivation_path,
            wildcard,
            ..
        }) = k
        {
            return *wildcard == Wildcard::Hardened
                || derivation_path.into_iter().any(ChildNumber::is_hardened);
        }

        false
    });
    if descriptor_contains_hardened_steps {
        return Err(DescriptorError::HardenedDerivationXpub);
    }

    if descriptor.is_multipath() {
        return Err(DescriptorError::MultiPath);
    }

    // Run miniscript's sanity check, which will look for duplicated keys and other potential
    // issues
    descriptor.sanity_check()?;

    Ok((descriptor, keymap))
}

#[doc(hidden)]
/// Used internally mainly by the `descriptor!()` and `fragment!()` macros
pub trait CheckMiniscript<Ctx: miniscript::ScriptContext> {
    fn check_miniscript(&self) -> Result<(), miniscript::Error>;
}

impl<Ctx: miniscript::ScriptContext, Pk: miniscript::MiniscriptKey> CheckMiniscript<Ctx>
    for miniscript::Miniscript<Pk, Ctx>
{
    fn check_miniscript(&self) -> Result<(), miniscript::Error> {
        Ctx::check_global_validity(self)?;

        Ok(())
    }
}

/// Trait implemented on [`Descriptor`]s to add a method to extract the spending [`policy`]
pub trait ExtractPolicy {
    /// Extract the spending [`policy`]
    fn extract_policy(
        &self,
        signers: &SignersContainer,
        psbt: BuildSatisfaction,
        secp: &SecpCtx,
    ) -> Result<Option<Policy>, DescriptorError>;
}

pub(crate) trait XKeyUtils {
    fn root_fingerprint(&self, secp: &SecpCtx) -> Fingerprint;
}

impl<T> XKeyUtils for DescriptorMultiXKey<T>
where
    T: InnerXKey,
{
    fn root_fingerprint(&self, secp: &SecpCtx) -> Fingerprint {
        match self.origin {
            Some((fingerprint, _)) => fingerprint,
            None => self.xkey.xkey_fingerprint(secp),
        }
    }
}

impl<T> XKeyUtils for DescriptorXKey<T>
where
    T: InnerXKey,
{
    fn root_fingerprint(&self, secp: &SecpCtx) -> Fingerprint {
        match self.origin {
            Some((fingerprint, _)) => fingerprint,
            None => self.xkey.xkey_fingerprint(secp),
        }
    }
}

pub(crate) trait DescriptorMeta {
    fn is_witness(&self) -> bool;
    fn is_taproot(&self) -> bool;
    fn get_extended_keys(&self) -> Vec<DescriptorXKey<ExtendedPubKey>>;
    fn derive_from_hd_keypaths(
        &self,
        hd_keypaths: &HdKeyPaths,
        secp: &SecpCtx,
    ) -> Option<DerivedDescriptor>;
    fn derive_from_tap_key_origins(
        &self,
        tap_key_origins: &TapKeyOrigins,
        secp: &SecpCtx,
    ) -> Option<DerivedDescriptor>;
    fn derive_from_psbt_key_origins(
        &self,
        key_origins: BTreeMap<Fingerprint, (&DerivationPath, SinglePubKey)>,
        secp: &SecpCtx,
    ) -> Option<DerivedDescriptor>;
    fn derive_from_psbt_input(
        &self,
        psbt_input: &psbt::Input,
        utxo: Option<TxOut>,
        secp: &SecpCtx,
    ) -> Option<DerivedDescriptor>;
}

impl DescriptorMeta for ExtendedDescriptor {
    fn is_witness(&self) -> bool {
        matches!(
            self.desc_type(),
            DescriptorType::Wpkh
                | DescriptorType::ShWpkh
                | DescriptorType::Wsh
                | DescriptorType::ShWsh
                | DescriptorType::ShWshSortedMulti
                | DescriptorType::WshSortedMulti
        )
    }

    fn is_taproot(&self) -> bool {
        self.desc_type() == DescriptorType::Tr
    }

    fn get_extended_keys(&self) -> Vec<DescriptorXKey<ExtendedPubKey>> {
        let mut answer = Vec::new();

        self.for_each_key(|pk| {
            if let DescriptorPublicKey::XPub(xpub) = pk {
                answer.push(xpub.clone());
            }

            true
        });

        answer
    }

    fn derive_from_psbt_key_origins(
        &self,
        key_origins: BTreeMap<Fingerprint, (&DerivationPath, SinglePubKey)>,
        secp: &SecpCtx,
    ) -> Option<DerivedDescriptor> {
        // Ensure that deriving `xpub` with `path` yields `expected`
        let verify_key = |xpub: &DescriptorXKey<ExtendedPubKey>,
                          path: &DerivationPath,
                          expected: &SinglePubKey| {
            let derived = xpub
                .xkey
                .derive_pub(secp, path)
                .expect("The path should never contain hardened derivation steps")
                .public_key;

            match expected {
                SinglePubKey::FullKey(pk) if &PublicKey::new(derived) == pk => true,
                SinglePubKey::XOnly(pk) if &XOnlyPublicKey::from(derived) == pk => true,
                _ => false,
            }
        };

        let mut path_found = None;

        // using `for_any_key` should make this stop as soon as we return `true`
        self.for_any_key(|key| {
            if let DescriptorPublicKey::XPub(xpub) = key {
                // Check if the key matches one entry in our `key_origins`. If it does, `matches()` will
                // return the "prefix" that matched, so we remove that prefix from the full path
                // found in `key_origins` and save it in `derive_path`. We expect this to be a derivation
                // path of length 1 if the key is `wildcard` and an empty path otherwise.
                let root_fingerprint = xpub.root_fingerprint(secp);
                let derive_path = key_origins
                    .get_key_value(&root_fingerprint)
                    .and_then(|(fingerprint, (path, expected))| {
                        xpub.matches(&(*fingerprint, (*path).clone()), secp)
                            .zip(Some((path, expected)))
                    })
                    .and_then(|(prefix, (full_path, expected))| {
                        let derive_path = full_path
                            .into_iter()
                            .skip(prefix.into_iter().count())
                            .cloned()
                            .collect::<DerivationPath>();

                        // `derive_path` only contains the replacement index for the wildcard, if present, or
                        // an empty path for fixed descriptors. To verify the key we also need the normal steps
                        // that come before the wildcard, so we take them directly from `xpub` and then append
                        // the final index
                        if verify_key(
                            xpub,
                            &xpub.derivation_path.extend(derive_path.clone()),
                            expected,
                        ) {
                            Some(derive_path)
                        } else {
                            None
                        }
                    });

                match derive_path {
                    Some(path) if xpub.wildcard != Wildcard::None && path.len() == 1 => {
                        // Ignore hardened wildcards
                        if let ChildNumber::Normal { index } = path[0] {
                            path_found = Some(index);
                            return true;
                        }
                    }
                    Some(path) if xpub.wildcard == Wildcard::None && path.is_empty() => {
                        path_found = Some(0);
                        return true;
                    }
                    _ => {}
                }
            }

            false
        });

        path_found.map(|path| {
            self.at_derivation_index(path)
                .expect("We ignore hardened wildcards")
        })
    }

    fn derive_from_hd_keypaths(
        &self,
        hd_keypaths: &HdKeyPaths,
        secp: &SecpCtx,
    ) -> Option<DerivedDescriptor> {
        // "Convert" an hd_keypaths map to the format required by `derive_from_psbt_key_origins`
        let key_origins = hd_keypaths
            .iter()
            .map(|(pk, (fingerprint, path))| {
                (
                    *fingerprint,
                    (path, SinglePubKey::FullKey(PublicKey::new(*pk))),
                )
            })
            .collect();
        self.derive_from_psbt_key_origins(key_origins, secp)
    }

    fn derive_from_tap_key_origins(
        &self,
        tap_key_origins: &TapKeyOrigins,
        secp: &SecpCtx,
    ) -> Option<DerivedDescriptor> {
        // "Convert" a tap_key_origins map to the format required by `derive_from_psbt_key_origins`
        let key_origins = tap_key_origins
            .iter()
            .map(|(pk, (_, (fingerprint, path)))| (*fingerprint, (path, SinglePubKey::XOnly(*pk))))
            .collect();
        self.derive_from_psbt_key_origins(key_origins, secp)
    }

    fn derive_from_psbt_input(
        &self,
        psbt_input: &psbt::Input,
        utxo: Option<TxOut>,
        secp: &SecpCtx,
    ) -> Option<DerivedDescriptor> {
        if let Some(derived) = self.derive_from_hd_keypaths(&psbt_input.bip32_derivation, secp) {
            return Some(derived);
        }
        if let Some(derived) = self.derive_from_tap_key_origins(&psbt_input.tap_key_origins, secp) {
            return Some(derived);
        }
        if self.has_wildcard() {
            // We can't try to bruteforce the derivation index, exit here
            return None;
        }

        let descriptor = self.at_derivation_index(0).expect("0 is not hardened");
        match descriptor.desc_type() {
            // TODO: add pk() here
            DescriptorType::Pkh
            | DescriptorType::Wpkh
            | DescriptorType::ShWpkh
            | DescriptorType::Tr
                if utxo.is_some()
                    && descriptor.script_pubkey() == utxo.as_ref().unwrap().script_pubkey =>
            {
                Some(descriptor)
            }
            DescriptorType::Bare | DescriptorType::Sh | DescriptorType::ShSortedMulti
                if psbt_input.redeem_script.is_some()
                    && &descriptor.explicit_script().unwrap()
                        == psbt_input.redeem_script.as_ref().unwrap() =>
            {
                Some(descriptor)
            }
            DescriptorType::Wsh
            | DescriptorType::ShWsh
            | DescriptorType::ShWshSortedMulti
            | DescriptorType::WshSortedMulti
                if psbt_input.witness_script.is_some()
                    && &descriptor.explicit_script().unwrap()
                        == psbt_input.witness_script.as_ref().unwrap() =>
            {
                Some(descriptor)
            }
            _ => None,
        }
    }
}

#[cfg(test)]
mod test {
    use alloc::string::ToString;
    use core::str::FromStr;

    use assert_matches::assert_matches;
    use bitcoin::hashes::hex::FromHex;
    use bitcoin::secp256k1::Secp256k1;
    use bitcoin::ScriptBuf;
    use bitcoin::{bip32, psbt::Psbt};

    use super::*;
    use crate::psbt::PsbtUtils;

    #[test]
    fn test_derive_from_psbt_input_wpkh_wif() {
        let descriptor = Descriptor::<DescriptorPublicKey>::from_str(
            "wpkh(02b4632d08485ff1df2db55b9dafd23347d1c47a457072a1e87be26896549a8737)",
        )
        .unwrap();
        let psbt = Psbt::deserialize(
            &Vec::<u8>::from_hex(
                "70736274ff010052010000000162307be8e431fbaff807cdf9cdc3fde44d7402\
                 11bc8342c31ffd6ec11fe35bcc0100000000ffffffff01328601000000000016\
                 001493ce48570b55c42c2af816aeaba06cfee1224fae000000000001011fa086\
                 01000000000016001493ce48570b55c42c2af816aeaba06cfee1224fae010304\
                 010000000000",
            )
            .unwrap(),
        )
        .unwrap();

        assert!(descriptor
            .derive_from_psbt_input(&psbt.inputs[0], psbt.get_utxo_for(0), &Secp256k1::new())
            .is_some());
    }

    #[test]
    fn test_derive_from_psbt_input_pkh_tpub() {
        let descriptor = Descriptor::<DescriptorPublicKey>::from_str(
            "pkh([0f056943/44h/0h/0h]tpubDDpWvmUrPZrhSPmUzCMBHffvC3HyMAPnWDSAQNBTnj1iZeJa7BZQEttFiP4DS4GCcXQHezdXhn86Hj6LHX5EDstXPWrMaSneRWM8yUf6NFd/10/*)",
        )
        .unwrap();
        let psbt = Psbt::deserialize(
            &Vec::<u8>::from_hex(
                "70736274ff010053010000000145843b86be54a3cd8c9e38444e1162676c00df\
                 e7964122a70df491ea12fd67090100000000ffffffff01c19598000000000017\
                 a91432bb94283282f72b2e034709e348c44d5a4db0ef8700000000000100f902\
                 0000000001010167e99c0eb67640f3a1b6805f2d8be8238c947f8aaf49eb0a9c\
                 bee6a42c984200000000171600142b29a22019cca05b9c2b2d283a4c4489e1cf\
                 9f8ffeffffff02a01dced06100000017a914e2abf033cadbd74f0f4c74946201\
                 decd20d5c43c8780969800000000001976a9148b0fce5fb1264e599a65387313\
                 3c95478b902eb288ac02473044022015d9211576163fa5b001e84dfa3d44efd9\
                 86b8f3a0d3d2174369288b2b750906022048dacc0e5d73ae42512fd2b97e2071\
                 a8d0bce443b390b1fe0b8128fe70ec919e01210232dad1c5a67dcb0116d407e2\
                 52584228ab7ec00e8b9779d0c3ffe8114fc1a7d2c80600000103040100000022\
                 0603433b83583f8c4879b329dd08bbc7da935e4cc02f637ff746e05f0466ffb2\
                 a6a2180f0569432c00008000000080000000800a000000000000000000",
            )
            .unwrap(),
        )
        .unwrap();

        assert!(descriptor
            .derive_from_psbt_input(&psbt.inputs[0], psbt.get_utxo_for(0), &Secp256k1::new())
            .is_some());
    }

    #[test]
    fn test_derive_from_psbt_input_wsh() {
        let descriptor = Descriptor::<DescriptorPublicKey>::from_str(
            "wsh(and_v(v:pk(03b6633fef2397a0a9de9d7b6f23aef8368a6e362b0581f0f0af70d5ecfd254b14),older(6)))",
        )
        .unwrap();
        let psbt = Psbt::deserialize(
            &Vec::<u8>::from_hex(
                "70736274ff01005302000000011c8116eea34408ab6529223c9a176606742207\
                 67a1ff1d46a6e3c4a88243ea6e01000000000600000001109698000000000017\
                 a914ad105f61102e0d01d7af40d06d6a5c3ae2f7fde387000000000001012b80\
                 969800000000002200203ca72f106a72234754890ca7640c43f65d2174e44d33\
                 336030f9059345091044010304010000000105252103b6633fef2397a0a9de9d\
                 7b6f23aef8368a6e362b0581f0f0af70d5ecfd254b14ad56b20000",
            )
            .unwrap(),
        )
        .unwrap();

        assert!(descriptor
            .derive_from_psbt_input(&psbt.inputs[0], psbt.get_utxo_for(0), &Secp256k1::new())
            .is_some());
    }

    #[test]
    fn test_derive_from_psbt_input_sh() {
        let descriptor = Descriptor::<DescriptorPublicKey>::from_str(
            "sh(and_v(v:pk(021403881a5587297818fcaf17d239cefca22fce84a45b3b1d23e836c4af671dbb),after(630000)))",
        )
        .unwrap();
        let psbt = Psbt::deserialize(
            &Vec::<u8>::from_hex(
                "70736274ff0100530100000001bc8c13df445dfadcc42afa6dc841f85d22b01d\
                 a6270ebf981740f4b7b1d800390000000000feffffff01ba9598000000000017\
                 a91457b148ba4d3e5fa8608a8657875124e3d1c9390887f09c0900000100e002\
                 0000000001016ba1bbe05cc93574a0d611ec7d93ad0ab6685b28d0cd80e8a82d\
                 debb326643c90100000000feffffff02809698000000000017a914d9a6e8c455\
                 8e16c8253afe53ce37ad61cf4c38c487403504cf6100000017a9144044fb6e0b\
                 757dfc1b34886b6a95aef4d3db137e870247304402202a9b72d939bcde8ba2a1\
                 e0980597e47af4f5c152a78499143c3d0a78ac2286a602207a45b1df9e93b8c9\
                 6f09f5c025fe3e413ca4b905fe65ee55d32a3276439a9b8f012102dc1fcc2636\
                 4da1aa718f03d8d9bd6f2ff410ed2cf1245a168aa3bcc995ac18e0a806000001\
                 03040100000001042821021403881a5587297818fcaf17d239cefca22fce84a4\
                 5b3b1d23e836c4af671dbbad03f09c09b10000",
            )
            .unwrap(),
        )
        .unwrap();

        assert!(descriptor
            .derive_from_psbt_input(&psbt.inputs[0], psbt.get_utxo_for(0), &Secp256k1::new())
            .is_some());
    }

    #[test]
    fn test_to_wallet_descriptor_fixup_networks() {
        use crate::keys::{any_network, IntoDescriptorKey};

        let secp = Secp256k1::new();

        let xprv = bip32::ExtendedPrivKey::from_str("xprv9s21ZrQH143K3c3gF1DUWpWNr2SG2XrG8oYPpqYh7hoWsJy9NjabErnzriJPpnGHyKz5NgdXmq1KVbqS1r4NXdCoKitWg5e86zqXHa8kxyB").unwrap();
        let path = bip32::DerivationPath::from_str("m/0").unwrap();

        // here `to_descriptor_key` will set the valid networks for the key to only mainnet, since
        // we are using an "xpub"
        let key = (xprv, path.clone()).into_descriptor_key().unwrap();
        // override it with any. this happens in some key conversions, like bip39
        let key = key.override_valid_networks(any_network());

        // make a descriptor out of it
        let desc = crate::descriptor!(wpkh(key)).unwrap();
        // this should convert the key that supports "any_network" to the right network (testnet)
        let (wallet_desc, keymap) = desc
            .into_wallet_descriptor(&secp, Network::Testnet)
            .unwrap();

        let mut xprv_testnet = xprv;
        xprv_testnet.network = Network::Testnet;

        let xpub_testnet = bip32::ExtendedPubKey::from_priv(&secp, &xprv_testnet);
        let desc_pubkey = DescriptorPublicKey::XPub(DescriptorXKey {
            xkey: xpub_testnet,
            origin: None,
            derivation_path: path,
            wildcard: Wildcard::Unhardened,
        });

        assert_eq!(wallet_desc.to_string(), "wpkh(tpubD6NzVbkrYhZ4XtJzoDja5snUjBNQRP5B3f4Hyn1T1x6PVPxzzVjvw6nJx2D8RBCxog9GEVjZoyStfepTz7TtKoBVdkCtnc7VCJh9dD4RAU9/0/*)#a3svx0ha");
        assert_eq!(
            keymap
                .get(&desc_pubkey)
                .map(|key| key.to_public(&secp).unwrap()),
            Some(desc_pubkey)
        );
    }

    // test IntoWalletDescriptor trait from &str with and without checksum appended
    #[test]
    fn test_descriptor_from_str_with_checksum() {
        let secp = Secp256k1::new();

        let desc = "wpkh(tprv8ZgxMBicQKsPdpkqS7Eair4YxjcuuvDPNYmKX3sCniCf16tHEVrjjiSXEkFRnUH77yXc6ZcwHHcLNfjdi5qUvw3VDfgYiH5mNsj5izuiu2N/1/2/*)#tqz0nc62"
            .into_wallet_descriptor(&secp, Network::Testnet);
        assert!(desc.is_ok());

        let desc = "wpkh(tprv8ZgxMBicQKsPdpkqS7Eair4YxjcuuvDPNYmKX3sCniCf16tHEVrjjiSXEkFRnUH77yXc6ZcwHHcLNfjdi5qUvw3VDfgYiH5mNsj5izuiu2N/1/2/*)"
            .into_wallet_descriptor(&secp, Network::Testnet);
        assert!(desc.is_ok());

        let desc = "wpkh(tpubD6NzVbkrYhZ4XHndKkuB8FifXm8r5FQHwrN6oZuWCz13qb93rtgKvD4PQsqC4HP4yhV3tA2fqr2RbY5mNXfM7RxXUoeABoDtsFUq2zJq6YK/1/2/*)#67ju93jw"
            .into_wallet_descriptor(&secp, Network::Testnet);
        assert!(desc.is_ok());

        let desc = "wpkh(tpubD6NzVbkrYhZ4XHndKkuB8FifXm8r5FQHwrN6oZuWCz13qb93rtgKvD4PQsqC4HP4yhV3tA2fqr2RbY5mNXfM7RxXUoeABoDtsFUq2zJq6YK/1/2/*)"
            .into_wallet_descriptor(&secp, Network::Testnet);
        assert!(desc.is_ok());

        let desc = "wpkh(tprv8ZgxMBicQKsPdpkqS7Eair4YxjcuuvDPNYmKX3sCniCf16tHEVrjjiSXEkFRnUH77yXc6ZcwHHcLNfjdi5qUvw3VDfgYiH5mNsj5izuiu2N/1/2/*)#67ju93jw"
            .into_wallet_descriptor(&secp, Network::Testnet);
        assert_matches!(desc, Err(DescriptorError::InvalidDescriptorChecksum));

        let desc = "wpkh(tprv8ZgxMBicQKsPdpkqS7Eair4YxjcuuvDPNYmKX3sCniCf16tHEVrjjiSXEkFRnUH77yXc6ZcwHHcLNfjdi5qUvw3VDfgYiH5mNsj5izuiu2N/1/2/*)#67ju93jw"
            .into_wallet_descriptor(&secp, Network::Testnet);
        assert_matches!(desc, Err(DescriptorError::InvalidDescriptorChecksum));
    }

    // test IntoWalletDescriptor trait from &str with keys from right and wrong network
    #[test]
    fn test_descriptor_from_str_with_keys_network() {
        let secp = Secp256k1::new();

        let desc = "wpkh(tprv8ZgxMBicQKsPdpkqS7Eair4YxjcuuvDPNYmKX3sCniCf16tHEVrjjiSXEkFRnUH77yXc6ZcwHHcLNfjdi5qUvw3VDfgYiH5mNsj5izuiu2N/1/2/*)"
            .into_wallet_descriptor(&secp, Network::Testnet);
        assert!(desc.is_ok());

        let desc = "wpkh(tprv8ZgxMBicQKsPdpkqS7Eair4YxjcuuvDPNYmKX3sCniCf16tHEVrjjiSXEkFRnUH77yXc6ZcwHHcLNfjdi5qUvw3VDfgYiH5mNsj5izuiu2N/1/2/*)"
            .into_wallet_descriptor(&secp, Network::Regtest);
        assert!(desc.is_ok());

        let desc = "wpkh(tpubD6NzVbkrYhZ4XHndKkuB8FifXm8r5FQHwrN6oZuWCz13qb93rtgKvD4PQsqC4HP4yhV3tA2fqr2RbY5mNXfM7RxXUoeABoDtsFUq2zJq6YK/1/2/*)"
            .into_wallet_descriptor(&secp, Network::Testnet);
        assert!(desc.is_ok());

        let desc = "wpkh(tpubD6NzVbkrYhZ4XHndKkuB8FifXm8r5FQHwrN6oZuWCz13qb93rtgKvD4PQsqC4HP4yhV3tA2fqr2RbY5mNXfM7RxXUoeABoDtsFUq2zJq6YK/1/2/*)"
            .into_wallet_descriptor(&secp, Network::Regtest);
        assert!(desc.is_ok());

        let desc = "sh(wpkh(02864bb4ad00cefa806098a69e192bbda937494e69eb452b87bb3f20f6283baedb))"
            .into_wallet_descriptor(&secp, Network::Testnet);
        assert!(desc.is_ok());

        let desc = "sh(wpkh(02864bb4ad00cefa806098a69e192bbda937494e69eb452b87bb3f20f6283baedb))"
            .into_wallet_descriptor(&secp, Network::Bitcoin);
        assert!(desc.is_ok());

        let desc = "wpkh(tprv8ZgxMBicQKsPdpkqS7Eair4YxjcuuvDPNYmKX3sCniCf16tHEVrjjiSXEkFRnUH77yXc6ZcwHHcLNfjdi5qUvw3VDfgYiH5mNsj5izuiu2N/1/2/*)"
            .into_wallet_descriptor(&secp, Network::Bitcoin);
        assert_matches!(desc, Err(DescriptorError::Key(KeyError::InvalidNetwork)));

        let desc = "wpkh(tpubD6NzVbkrYhZ4XHndKkuB8FifXm8r5FQHwrN6oZuWCz13qb93rtgKvD4PQsqC4HP4yhV3tA2fqr2RbY5mNXfM7RxXUoeABoDtsFUq2zJq6YK/1/2/*)"
            .into_wallet_descriptor(&secp, Network::Bitcoin);
        assert_matches!(desc, Err(DescriptorError::Key(KeyError::InvalidNetwork)));
    }

    // test IntoWalletDescriptor trait from the output of the descriptor!() macro
    #[test]
    fn test_descriptor_from_str_from_output_of_macro() {
        let secp = Secp256k1::new();

        let tpub = bip32::ExtendedPubKey::from_str("tpubD6NzVbkrYhZ4XHndKkuB8FifXm8r5FQHwrN6oZuWCz13qb93rtgKvD4PQsqC4HP4yhV3tA2fqr2RbY5mNXfM7RxXUoeABoDtsFUq2zJq6YK").unwrap();
        let path = bip32::DerivationPath::from_str("m/1/2").unwrap();
        let key = (tpub, path).into_descriptor_key().unwrap();

        // make a descriptor out of it
        let desc = crate::descriptor!(wpkh(key)).unwrap();

        let (wallet_desc, _) = desc
            .into_wallet_descriptor(&secp, Network::Testnet)
            .unwrap();
        let wallet_desc_str = wallet_desc.to_string();
        assert_eq!(wallet_desc_str, "wpkh(tpubD6NzVbkrYhZ4XHndKkuB8FifXm8r5FQHwrN6oZuWCz13qb93rtgKvD4PQsqC4HP4yhV3tA2fqr2RbY5mNXfM7RxXUoeABoDtsFUq2zJq6YK/1/2/*)#67ju93jw");

        let (wallet_desc2, _) = wallet_desc_str
            .into_wallet_descriptor(&secp, Network::Testnet)
            .unwrap();
        assert_eq!(wallet_desc, wallet_desc2)
    }

    #[test]
    fn test_into_wallet_descriptor_checked() {
        let secp = Secp256k1::new();

        let descriptor = "wpkh(tpubD6NzVbkrYhZ4XHndKkuB8FifXm8r5FQHwrN6oZuWCz13qb93rtgKvD4PQsqC4HP4yhV3tA2fqr2RbY5mNXfM7RxXUoeABoDtsFUq2zJq6YK/0'/1/2/*)";
        let result = into_wallet_descriptor_checked(descriptor, &secp, Network::Testnet);

        assert_matches!(result, Err(DescriptorError::HardenedDerivationXpub));

        let descriptor = "wpkh(tpubD6NzVbkrYhZ4XHndKkuB8FifXm8r5FQHwrN6oZuWCz13qb93rtgKvD4PQsqC4HP4yhV3tA2fqr2RbY5mNXfM7RxXUoeABoDtsFUq2zJq6YK/<0;1>/*)";
        let result = into_wallet_descriptor_checked(descriptor, &secp, Network::Testnet);

        assert_matches!(result, Err(DescriptorError::MultiPath));

        // repeated pubkeys
        let descriptor = "wsh(multi(2,tpubD6NzVbkrYhZ4XHndKkuB8FifXm8r5FQHwrN6oZuWCz13qb93rtgKvD4PQsqC4HP4yhV3tA2fqr2RbY5mNXfM7RxXUoeABoDtsFUq2zJq6YK/0/*,tpubD6NzVbkrYhZ4XHndKkuB8FifXm8r5FQHwrN6oZuWCz13qb93rtgKvD4PQsqC4HP4yhV3tA2fqr2RbY5mNXfM7RxXUoeABoDtsFUq2zJq6YK/0/*))";
        let result = into_wallet_descriptor_checked(descriptor, &secp, Network::Testnet);

        assert!(result.is_err());
    }

    #[test]
    fn test_sh_wsh_sortedmulti_redeemscript() {
        use miniscript::psbt::PsbtInputExt;

        let secp = Secp256k1::new();

        let descriptor = "sh(wsh(sortedmulti(3,tpubDEsqS36T4DVsKJd9UH8pAKzrkGBYPLEt9jZMwpKtzh1G6mgYehfHt9WCgk7MJG5QGSFWf176KaBNoXbcuFcuadAFKxDpUdMDKGBha7bY3QM/0/*,tpubDF3cpwfs7fMvXXuoQbohXtLjNM6ehwYT287LWtmLsd4r77YLg6MZg4vTETx5MSJ2zkfigbYWu31VA2Z2Vc1cZugCYXgS7FQu6pE8V6TriEH/0/*,tpubDE1SKfcW76Tb2AASv5bQWMuScYNAdoqLHoexw13sNDXwmUhQDBbCD3QAedKGLhxMrWQdMDKENzYtnXPDRvexQPNuDrLj52wAjHhNEm8sJ4p/0/*,tpubDFLc6oXwJmhm3FGGzXkfJNTh2KitoY3WhmmQvuAjMhD8YbyWn5mAqckbxXfm2etM3p5J6JoTpSrMqRSTfMLtNW46poDaEZJ1kjd3csRSjwH/0/*,tpubDEWD9NBeWP59xXmdqSNt4VYdtTGwbpyP8WS962BuqpQeMZmX9Pur14dhXdZT5a7wR1pK6dPtZ9fP5WR493hPzemnBvkfLLYxnUjAKj1JCQV/0/*,tpubDEHyZkkwd7gZWCTgQuYQ9C4myF2hMEmyHsBCCmLssGqoqUxeT3gzohF5uEVURkf9TtmeepJgkSUmteac38FwZqirjApzNX59XSHLcwaTZCH/0/*,tpubDEqLouCekwnMUWN486kxGzD44qVgeyuqHyxUypNEiQt5RnUZNJe386TKPK99fqRV1vRkZjYAjtXGTECz98MCsdLcnkM67U6KdYRzVubeCgZ/0/*)))";
        let (descriptor, _) =
            into_wallet_descriptor_checked(descriptor, &secp, Network::Testnet).unwrap();

        let descriptor = descriptor.at_derivation_index(0).unwrap();

        let script = ScriptBuf::from_hex("5321022f533b667e2ea3b36e21961c9fe9dca340fbe0af5210173a83ae0337ab20a57621026bb53a98e810bd0ee61a0ed1164ba6c024786d76554e793e202dc6ce9c78c4ea2102d5b8a7d66a41ffdb6f4c53d61994022e886b4f45001fb158b95c9164d45f8ca3210324b75eead2c1f9c60e8adeb5e7009fec7a29afcdb30d829d82d09562fe8bae8521032d34f8932200833487bd294aa219dcbe000b9f9b3d824799541430009f0fa55121037468f8ea99b6c64788398b5ad25480cad08f4b0d65be54ce3a55fd206b5ae4722103f72d3d96663b0ea99b0aeb0d7f273cab11a8de37885f1dddc8d9112adb87169357ae").unwrap();

        let mut psbt_input = psbt::Input::default();
        psbt_input
            .update_with_descriptor_unchecked(&descriptor)
            .unwrap();

        assert_eq!(psbt_input.redeem_script, Some(script.to_v0_p2wsh()));
        assert_eq!(psbt_input.witness_script, Some(script));
    }
}