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docs/next/core/addresses.html

@@ -80,7 +80,7 @@ reason to keep using legacy transaction formats.</p>
 <span class="hljs-keyword">val</span> privkey = <span class="hljs-type">ECPrivateKey</span>()
 <span class="hljs-comment">// privkey: ECPrivateKey = Masked(ECPrivateKeyImpl)</span>
 <span class="hljs-keyword">val</span> pubkey = privkey.publicKey
-<span class="hljs-comment">// pubkey: crypto.ECPublicKey = ECPublicKey(03e5789173139e35795a6a2d32803a9c3f377f9e1ae3997b8d255d7440901052f8)</span>
+<span class="hljs-comment">// pubkey: crypto.ECPublicKey = ECPublicKey(025da35d8178b8acd148efcf305bc6aba79d3995dab3e984c1f5157e3131bb9cc1)</span>
 
 <span class="hljs-keyword">val</span> segwitAddress = {
     <span class="hljs-comment">// see https://bitcoin.org/en/glossary/pubkey-script</span>
@@ -89,10 +89,10 @@ reason to keep using legacy transaction formats.</p>
     <span class="hljs-keyword">val</span> scriptPubKey = <span class="hljs-type">P2WPKHWitnessSPKV0</span>(pubkey)
     <span class="hljs-type">Bech32Address</span>(scriptPubKey, <span class="hljs-type">TestNet3</span>)
 }
-<span class="hljs-comment">// segwitAddress: Bech32Address = Bech32Address(tb1q22pm4uxynp8xu34v5pju72wnnz69uznm9w7qlx)</span>
+<span class="hljs-comment">// segwitAddress: Bech32Address = Bech32Address(tb1qza8u9lu89pxxakhq44qerqcy9m74p2p9qatdlx)</span>
 
 println(segwitAddress.toString)
-<span class="hljs-comment">// Bech32Address(tb1q22pm4uxynp8xu34v5pju72wnnz69uznm9w7qlx)</span>
+<span class="hljs-comment">// Bech32Address(tb1qza8u9lu89pxxakhq44qerqcy9m74p2p9qatdlx)</span>
 </code></pre>
 <h2><a class="anchor" aria-hidden="true" id="generating-legacy-base58-addresses"></a><a href="#generating-legacy-base58-addresses" aria-hidden="true" class="hash-link"><svg class="hash-link-icon" aria-hidden="true" height="16" version="1.1" viewBox="0 0 16 16" width="16"><path fill-rule="evenodd" d="M4 9h1v1H4c-1.5 0-3-1.69-3-3.5S2.55 3 4 3h4c1.45 0 3 1.69 3 3.5 0 1.41-.91 2.72-2 3.25V8.59c.58-.45 1-1.27 1-2.09C10 5.22 8.98 4 8 4H4c-.98 0-2 1.22-2 2.5S3 9 4 9zm9-3h-1v1h1c1 0 2 1.22 2 2.5S13.98 12 13 12H9c-.98 0-2-1.22-2-2.5 0-.83.42-1.64 1-2.09V6.25c-1.09.53-2 1.84-2 3.25C6 11.31 7.55 13 9 13h4c1.45 0 3-1.69 3-3.5S14.5 6 13 6z"></path></svg></a>Generating legacy (base58) addresses</h2>
 <p>If you need to generate legacy addresses for backwards
@@ -101,10 +101,10 @@ Take a look:</p>
 <pre><code class="hljs css language-scala"><span class="hljs-comment">// we're reusing the same private/public key pair</span>
 <span class="hljs-comment">// from before. don't do this in an actual application!</span>
 <span class="hljs-keyword">val</span> legacyAddress = <span class="hljs-type">P2PKHAddress</span>(pubkey, <span class="hljs-type">TestNet3</span>)
-<span class="hljs-comment">// legacyAddress: P2PKHAddress = mo3FWZWnT4UNy8Wzv2FAG8EThVsTasWEVq</span>
+<span class="hljs-comment">// legacyAddress: P2PKHAddress = mheDPQZPQqKcqkdoWd1RRJjWLASjdHxBwD</span>
 
 println(legacyAddress.toString)
-<span class="hljs-comment">// mo3FWZWnT4UNy8Wzv2FAG8EThVsTasWEVq</span>
+<span class="hljs-comment">// mheDPQZPQqKcqkdoWd1RRJjWLASjdHxBwD</span>
 </code></pre>
 </span></div></article></div><div class="docs-prevnext"><a class="docs-prev button" href="/docs/next/core/core-intro"><span class="arrow-prev">← </span><span>Core Module</span></a><a class="docs-next button" href="/docs/next/core/hd-keys"><span>HD Key Generation</span><span class="arrow-next"> →</span></a></div></div></div><nav class="onPageNav"><ul class="toc-headings"><li><a href="#generating-segwit-bech32-addresses">Generating SegWit (bech32) addresses</a></li><li><a href="#generating-legacy-base58-addresses">Generating legacy (base58) addresses</a></li></ul></nav></div><footer class="nav-footer" id="footer"><section class="sitemap"><a href="/" class="nav-home"><img src="/img/favicon.ico" alt="bitcoin-s" width="66" height="58"/></a><div><h5>Docs</h5><a href="/docs/en/getting-started">Getting Started</a><a href="/docs/en/core/core-intro">Guides</a><a href="/api/org/bitcoins">API Reference</a></div><div><h5>Community</h5><a href="/en/users.html">User Showcase</a><a href="https://join.slack.com/t/suredbits/shared_invite/enQtNDEyMjY3MTg1MTg3LTYyYjkwOGUzMDQ4NDAwZjE1M2I3MmQyNWNlZjNlYjg4OGRjYTRjNWUwNjRjNjg4Y2NjZjAxYjU1N2JjMTU1YWM" target="_blank" rel="noreferrer noopener">Slack</a><a href="https://gitter.im/bitcoin-s-core/">Gitter chat</a></div><div><h5>More</h5><a href="https://github.com/bitcoin-s/bitcoin-s">GitHub</a><a class="github-button" href="https://github.com/bitcoin-s/bitcoin-s" data-icon="octicon-star" data-count-href="/bitcoin-s/bitcoin-s-core/stargazers" data-show-count="true" data-count-aria-label="# stargazers on GitHub" aria-label="Star this project on GitHub">Star</a></div></section><section class="copyright">Copyright © 2020 Suredbits &amp; the bitcoin-s developers</section></footer></div><script type="text/javascript" src="https://cdn.jsdelivr.net/docsearch.js/1/docsearch.min.js"></script><script>
                 document.addEventListener('keyup', function(e) {

docs/next/core/addresses/index.html

@@ -80,7 +80,7 @@ reason to keep using legacy transaction formats.</p>
 <span class="hljs-keyword">val</span> privkey = <span class="hljs-type">ECPrivateKey</span>()
 <span class="hljs-comment">// privkey: ECPrivateKey = Masked(ECPrivateKeyImpl)</span>
 <span class="hljs-keyword">val</span> pubkey = privkey.publicKey
-<span class="hljs-comment">// pubkey: crypto.ECPublicKey = ECPublicKey(03e5789173139e35795a6a2d32803a9c3f377f9e1ae3997b8d255d7440901052f8)</span>
+<span class="hljs-comment">// pubkey: crypto.ECPublicKey = ECPublicKey(025da35d8178b8acd148efcf305bc6aba79d3995dab3e984c1f5157e3131bb9cc1)</span>
 
 <span class="hljs-keyword">val</span> segwitAddress = {
     <span class="hljs-comment">// see https://bitcoin.org/en/glossary/pubkey-script</span>
@@ -89,10 +89,10 @@ reason to keep using legacy transaction formats.</p>
     <span class="hljs-keyword">val</span> scriptPubKey = <span class="hljs-type">P2WPKHWitnessSPKV0</span>(pubkey)
     <span class="hljs-type">Bech32Address</span>(scriptPubKey, <span class="hljs-type">TestNet3</span>)
 }
-<span class="hljs-comment">// segwitAddress: Bech32Address = Bech32Address(tb1q22pm4uxynp8xu34v5pju72wnnz69uznm9w7qlx)</span>
+<span class="hljs-comment">// segwitAddress: Bech32Address = Bech32Address(tb1qza8u9lu89pxxakhq44qerqcy9m74p2p9qatdlx)</span>
 
 println(segwitAddress.toString)
-<span class="hljs-comment">// Bech32Address(tb1q22pm4uxynp8xu34v5pju72wnnz69uznm9w7qlx)</span>
+<span class="hljs-comment">// Bech32Address(tb1qza8u9lu89pxxakhq44qerqcy9m74p2p9qatdlx)</span>
 </code></pre>
 <h2><a class="anchor" aria-hidden="true" id="generating-legacy-base58-addresses"></a><a href="#generating-legacy-base58-addresses" aria-hidden="true" class="hash-link"><svg class="hash-link-icon" aria-hidden="true" height="16" version="1.1" viewBox="0 0 16 16" width="16"><path fill-rule="evenodd" d="M4 9h1v1H4c-1.5 0-3-1.69-3-3.5S2.55 3 4 3h4c1.45 0 3 1.69 3 3.5 0 1.41-.91 2.72-2 3.25V8.59c.58-.45 1-1.27 1-2.09C10 5.22 8.98 4 8 4H4c-.98 0-2 1.22-2 2.5S3 9 4 9zm9-3h-1v1h1c1 0 2 1.22 2 2.5S13.98 12 13 12H9c-.98 0-2-1.22-2-2.5 0-.83.42-1.64 1-2.09V6.25c-1.09.53-2 1.84-2 3.25C6 11.31 7.55 13 9 13h4c1.45 0 3-1.69 3-3.5S14.5 6 13 6z"></path></svg></a>Generating legacy (base58) addresses</h2>
 <p>If you need to generate legacy addresses for backwards
@@ -101,10 +101,10 @@ Take a look:</p>
 <pre><code class="hljs css language-scala"><span class="hljs-comment">// we're reusing the same private/public key pair</span>
 <span class="hljs-comment">// from before. don't do this in an actual application!</span>
 <span class="hljs-keyword">val</span> legacyAddress = <span class="hljs-type">P2PKHAddress</span>(pubkey, <span class="hljs-type">TestNet3</span>)
-<span class="hljs-comment">// legacyAddress: P2PKHAddress = mo3FWZWnT4UNy8Wzv2FAG8EThVsTasWEVq</span>
+<span class="hljs-comment">// legacyAddress: P2PKHAddress = mheDPQZPQqKcqkdoWd1RRJjWLASjdHxBwD</span>
 
 println(legacyAddress.toString)
-<span class="hljs-comment">// mo3FWZWnT4UNy8Wzv2FAG8EThVsTasWEVq</span>
+<span class="hljs-comment">// mheDPQZPQqKcqkdoWd1RRJjWLASjdHxBwD</span>
 </code></pre>
 </span></div></article></div><div class="docs-prevnext"><a class="docs-prev button" href="/docs/next/core/core-intro"><span class="arrow-prev">← </span><span>Core Module</span></a><a class="docs-next button" href="/docs/next/core/hd-keys"><span>HD Key Generation</span><span class="arrow-next"> →</span></a></div></div></div><nav class="onPageNav"><ul class="toc-headings"><li><a href="#generating-segwit-bech32-addresses">Generating SegWit (bech32) addresses</a></li><li><a href="#generating-legacy-base58-addresses">Generating legacy (base58) addresses</a></li></ul></nav></div><footer class="nav-footer" id="footer"><section class="sitemap"><a href="/" class="nav-home"><img src="/img/favicon.ico" alt="bitcoin-s" width="66" height="58"/></a><div><h5>Docs</h5><a href="/docs/en/getting-started">Getting Started</a><a href="/docs/en/core/core-intro">Guides</a><a href="/api/org/bitcoins">API Reference</a></div><div><h5>Community</h5><a href="/en/users.html">User Showcase</a><a href="https://join.slack.com/t/suredbits/shared_invite/enQtNDEyMjY3MTg1MTg3LTYyYjkwOGUzMDQ4NDAwZjE1M2I3MmQyNWNlZjNlYjg4OGRjYTRjNWUwNjRjNjg4Y2NjZjAxYjU1N2JjMTU1YWM" target="_blank" rel="noreferrer noopener">Slack</a><a href="https://gitter.im/bitcoin-s-core/">Gitter chat</a></div><div><h5>More</h5><a href="https://github.com/bitcoin-s/bitcoin-s">GitHub</a><a class="github-button" href="https://github.com/bitcoin-s/bitcoin-s" data-icon="octicon-star" data-count-href="/bitcoin-s/bitcoin-s-core/stargazers" data-show-count="true" data-count-aria-label="# stargazers on GitHub" aria-label="Star this project on GitHub">Star</a></div></section><section class="copyright">Copyright © 2020 Suredbits &amp; the bitcoin-s developers</section></footer></div><script type="text/javascript" src="https://cdn.jsdelivr.net/docsearch.js/1/docsearch.min.js"></script><script>
                 document.addEventListener('keyup', function(e) {

docs/next/core/hd-keys.html

@@ -86,13 +86,13 @@ use that to generate further private and public keys:</p>
 <span class="hljs-comment">// how long our phrase ends up being</span>
 <span class="hljs-comment">// 256 bits of entropy results in 24 words</span>
 <span class="hljs-keyword">val</span> entropy: <span class="hljs-type">BitVector</span> = <span class="hljs-type">MnemonicCode</span>.getEntropy256Bits
-<span class="hljs-comment">// entropy: BitVector = BitVector(256 bits, 0x5623e226b3b3c8b2e764dcd327c8de6ff127dc78d93da215c44306b4cf9b15af)</span>
+<span class="hljs-comment">// entropy: BitVector = BitVector(256 bits, 0x15cf9a472642121d42c44ba13670429e9763ecfe7337725f9b9917d5de2e7dd0)</span>
 
 <span class="hljs-keyword">val</span> mnemonicCode = <span class="hljs-type">MnemonicCode</span>.fromEntropy(entropy)
 <span class="hljs-comment">// mnemonicCode: MnemonicCode = Masked(MnemonicCodeImpl)</span>
 
 mnemonicCode.words <span class="hljs-comment">// the phrase the user should write down</span>
-<span class="hljs-comment">// res0: Vector[String] = Vector(file, business, meadow, guess, develop, floor, outside, oppose, spring, dinner, daring, that, bar, until, toddler, chicken, pear, purchase, awkward, aspect, erupt, snow, find, wage) // the phrase the user should write down</span>
+<span class="hljs-comment">// res0: Vector[String] = Vector(beyond, lamp, mushroom, erode, cancel, attitude, arch, maximum, patrol, receive, awful, diamond, involve, wait, what, group, inch, wolf, town, cook, fuel, blame, warrior, blind) // the phrase the user should write down</span>
 
 <span class="hljs-comment">// the password argument is an optional, extra security</span>
 <span class="hljs-comment">// measure. all MnemonicCode instances will give you a</span>
@@ -108,7 +108,7 @@ mnemonicCode.words <span class="hljs-comment">// the phrase the user should writ
                                         bip39Seed)
 <span class="hljs-comment">// xpriv: ExtPrivateKey = Masked(ExtPrivateKeyImpl)</span>
 <span class="hljs-keyword">val</span> xpub = xpriv.extPublicKey
-<span class="hljs-comment">// xpub: ExtPublicKey = zpub6jftahH18ngZwRitW3zXK2b9doBa1ZVKjtKSiJW13Jiocj8BEgpP8C227Mjq7zqxUyTEhenb1zzXb7dVerPhDqfUTfF6gakVj9FLUUvSmXA</span>
+<span class="hljs-comment">// xpub: ExtPublicKey = zpub6jftahH18ngZxaUEHaLEHtisoNpW9okYUbX9W5K3fq4MztxMDQxTwzDy28fFvShrDnRLgYaom5jmxMzE1aoR3SUbzNA6oJHhu1Q2dyJiqL3</span>
 
 <span class="hljs-comment">// you can now use the generated xpriv to derive further</span>
 <span class="hljs-comment">// private or public keys</span>
@@ -154,7 +154,7 @@ spend or steal any of your money.</p>
     <span class="hljs-comment">// can generate addresses with it!</span>
     accountXpriv.extPublicKey
 }
-<span class="hljs-comment">// accountXpub: ExtPublicKey = zpub6rEeuC9KqTydTUBy8RZHwk32WLeADesgTVtmzTJSVdHJuczTX9F9n5wTsVaPZL3rbZ86T1SwB2JqAcgMmsWzVUNFbmHze6FSBD5We4zt65w</span>
+<span class="hljs-comment">// accountXpub: ExtPublicKey = zpub6r6oci4itHPYbPQo2pckwTrBiofMRgi9FCTXVdDPwG6Pv7ajYdfJpcFZN67JTqpahktXzr2UtXgGiKdLfWErhnh6M5Eb8y3VNRJuiULbWH2</span>
 
                               <span class="hljs-comment">// address no. 0 ---------------┐</span>
                               <span class="hljs-comment">// external address ----------┐ |</span>
@@ -177,12 +177,12 @@ spend or steal any of your money.</p>
     <span class="hljs-keyword">val</span> scriptPubKey = <span class="hljs-type">P2WPKHWitnessSPKV0</span>(pubkey)
     <span class="hljs-type">Bech32Address</span>(scriptPubKey, <span class="hljs-type">TestNet3</span>)
 }
-<span class="hljs-comment">// firstAccountAddress: Bech32Address = Bech32Address(tb1qkvv0tml8090ps683jgmpz7erdhvgqu0gw6f52v)</span>
+<span class="hljs-comment">// firstAccountAddress: Bech32Address = Bech32Address(tb1q73nepwecd9lddh9crntka36ycm466d4z9t9796)</span>
 
 <span class="hljs-comment">// tada! We just generated an address you can send money to,</span>
 <span class="hljs-comment">// without having access to the private key!</span>
 firstAccountAddress.value
-<span class="hljs-comment">// res2: String = tb1qkvv0tml8090ps683jgmpz7erdhvgqu0gw6f52v</span>
+<span class="hljs-comment">// res2: String = tb1q73nepwecd9lddh9crntka36ycm466d4z9t9796</span>
 
 <span class="hljs-comment">// you can now continue deriving addresses from the same public</span>
 <span class="hljs-comment">// key, by imitating what we did above. To get the next</span>

docs/next/core/hd-keys/index.html

@@ -86,13 +86,13 @@ use that to generate further private and public keys:</p>
 <span class="hljs-comment">// how long our phrase ends up being</span>
 <span class="hljs-comment">// 256 bits of entropy results in 24 words</span>
 <span class="hljs-keyword">val</span> entropy: <span class="hljs-type">BitVector</span> = <span class="hljs-type">MnemonicCode</span>.getEntropy256Bits
-<span class="hljs-comment">// entropy: BitVector = BitVector(256 bits, 0x5623e226b3b3c8b2e764dcd327c8de6ff127dc78d93da215c44306b4cf9b15af)</span>
+<span class="hljs-comment">// entropy: BitVector = BitVector(256 bits, 0x15cf9a472642121d42c44ba13670429e9763ecfe7337725f9b9917d5de2e7dd0)</span>
 
 <span class="hljs-keyword">val</span> mnemonicCode = <span class="hljs-type">MnemonicCode</span>.fromEntropy(entropy)
 <span class="hljs-comment">// mnemonicCode: MnemonicCode = Masked(MnemonicCodeImpl)</span>
 
 mnemonicCode.words <span class="hljs-comment">// the phrase the user should write down</span>
-<span class="hljs-comment">// res0: Vector[String] = Vector(file, business, meadow, guess, develop, floor, outside, oppose, spring, dinner, daring, that, bar, until, toddler, chicken, pear, purchase, awkward, aspect, erupt, snow, find, wage) // the phrase the user should write down</span>
+<span class="hljs-comment">// res0: Vector[String] = Vector(beyond, lamp, mushroom, erode, cancel, attitude, arch, maximum, patrol, receive, awful, diamond, involve, wait, what, group, inch, wolf, town, cook, fuel, blame, warrior, blind) // the phrase the user should write down</span>
 
 <span class="hljs-comment">// the password argument is an optional, extra security</span>
 <span class="hljs-comment">// measure. all MnemonicCode instances will give you a</span>
@@ -108,7 +108,7 @@ mnemonicCode.words <span class="hljs-comment">// the phrase the user should writ
                                         bip39Seed)
 <span class="hljs-comment">// xpriv: ExtPrivateKey = Masked(ExtPrivateKeyImpl)</span>
 <span class="hljs-keyword">val</span> xpub = xpriv.extPublicKey
-<span class="hljs-comment">// xpub: ExtPublicKey = zpub6jftahH18ngZwRitW3zXK2b9doBa1ZVKjtKSiJW13Jiocj8BEgpP8C227Mjq7zqxUyTEhenb1zzXb7dVerPhDqfUTfF6gakVj9FLUUvSmXA</span>
+<span class="hljs-comment">// xpub: ExtPublicKey = zpub6jftahH18ngZxaUEHaLEHtisoNpW9okYUbX9W5K3fq4MztxMDQxTwzDy28fFvShrDnRLgYaom5jmxMzE1aoR3SUbzNA6oJHhu1Q2dyJiqL3</span>
 
 <span class="hljs-comment">// you can now use the generated xpriv to derive further</span>
 <span class="hljs-comment">// private or public keys</span>
@@ -154,7 +154,7 @@ spend or steal any of your money.</p>
     <span class="hljs-comment">// can generate addresses with it!</span>
     accountXpriv.extPublicKey
 }
-<span class="hljs-comment">// accountXpub: ExtPublicKey = zpub6rEeuC9KqTydTUBy8RZHwk32WLeADesgTVtmzTJSVdHJuczTX9F9n5wTsVaPZL3rbZ86T1SwB2JqAcgMmsWzVUNFbmHze6FSBD5We4zt65w</span>
+<span class="hljs-comment">// accountXpub: ExtPublicKey = zpub6r6oci4itHPYbPQo2pckwTrBiofMRgi9FCTXVdDPwG6Pv7ajYdfJpcFZN67JTqpahktXzr2UtXgGiKdLfWErhnh6M5Eb8y3VNRJuiULbWH2</span>
 
                               <span class="hljs-comment">// address no. 0 ---------------┐</span>
                               <span class="hljs-comment">// external address ----------┐ |</span>
@@ -177,12 +177,12 @@ spend or steal any of your money.</p>
     <span class="hljs-keyword">val</span> scriptPubKey = <span class="hljs-type">P2WPKHWitnessSPKV0</span>(pubkey)
     <span class="hljs-type">Bech32Address</span>(scriptPubKey, <span class="hljs-type">TestNet3</span>)
 }
-<span class="hljs-comment">// firstAccountAddress: Bech32Address = Bech32Address(tb1qkvv0tml8090ps683jgmpz7erdhvgqu0gw6f52v)</span>
+<span class="hljs-comment">// firstAccountAddress: Bech32Address = Bech32Address(tb1q73nepwecd9lddh9crntka36ycm466d4z9t9796)</span>
 
 <span class="hljs-comment">// tada! We just generated an address you can send money to,</span>
 <span class="hljs-comment">// without having access to the private key!</span>
 firstAccountAddress.value
-<span class="hljs-comment">// res2: String = tb1qkvv0tml8090ps683jgmpz7erdhvgqu0gw6f52v</span>
+<span class="hljs-comment">// res2: String = tb1q73nepwecd9lddh9crntka36ycm466d4z9t9796</span>
 
 <span class="hljs-comment">// you can now continue deriving addresses from the same public</span>
 <span class="hljs-comment">// key, by imitating what we did above. To get the next</span>

docs/next/core/sign.html

@@ -96,13 +96,13 @@
 <span class="hljs-comment">// extPrivKey: ExtPrivateKey = Masked(ExtPrivateKeyImpl)</span>
 
 extPrivKey.sign(<span class="hljs-type">DoubleSha256Digest</span>.empty.bytes)
-<span class="hljs-comment">// res0: ECDigitalSignature = ECDigitalSignature(3044022015339a44b69a19095058cbef81f5e64097208f0e8dc4b6ed0370f3f946ff477002203e09a76e060ffb5e0bbb2922fd13dfef0f7a51bb22784d58f5568a0f59917f6f)</span>
+<span class="hljs-comment">// res0: ECDigitalSignature = ECDigitalSignature(304402203435aef2e949b6a5e8897d4d81d6f1f0b848c7bef19d582dfe37ef7725e78cc4022046095c442a4a9ec5b8ed72791f29d69451a729c95d69f2f113feba817ccfdc2c)</span>
 
 <span class="hljs-keyword">val</span> path = <span class="hljs-type">BIP32Path</span>(<span class="hljs-type">Vector</span>(<span class="hljs-type">BIP32Node</span>(<span class="hljs-number">0</span>,<span class="hljs-literal">false</span>)))
 <span class="hljs-comment">// path: BIP32Path = m/0</span>
 
 extPrivKey.sign(<span class="hljs-type">DoubleSha256Digest</span>.empty.bytes,path)
-<span class="hljs-comment">// res1: ECDigitalSignature = ECDigitalSignature(304402207baead228929bf674cc8b37694d2004b9f3909f542a1e2055f6524374af6170702207905ccb418ea708c6ea4abed663562985538686a9185fd77a99fbd6be89b0235)</span>
+<span class="hljs-comment">// res1: ECDigitalSignature = ECDigitalSignature(3045022100cd096078b3b2830ec621c6b3ccb6c88a0b4bfd75261282f1c352e5ccf0cd111902206d45614f7c39dd7f729096b737167b136223b54fc579c9908ae5bcdef0ceb96c)</span>
 </code></pre>
 <p>With <code>ExtSign</code>, you can use <code>ExtPrivateKey</code> to sign transactions inside of <code>TxBuilder</code> since <code>UTXOSpendingInfo</code> takes in <code>Sign</code> as a parameter.</p>
 <p>You can also provide a <code>path</code> to use to derive a child <code>ExtPrivateKey</code>, and then sign with that child private key</p>

docs/next/core/sign/index.html

@@ -96,13 +96,13 @@
 <span class="hljs-comment">// extPrivKey: ExtPrivateKey = Masked(ExtPrivateKeyImpl)</span>
 
 extPrivKey.sign(<span class="hljs-type">DoubleSha256Digest</span>.empty.bytes)
-<span class="hljs-comment">// res0: ECDigitalSignature = ECDigitalSignature(3044022015339a44b69a19095058cbef81f5e64097208f0e8dc4b6ed0370f3f946ff477002203e09a76e060ffb5e0bbb2922fd13dfef0f7a51bb22784d58f5568a0f59917f6f)</span>
+<span class="hljs-comment">// res0: ECDigitalSignature = ECDigitalSignature(304402203435aef2e949b6a5e8897d4d81d6f1f0b848c7bef19d582dfe37ef7725e78cc4022046095c442a4a9ec5b8ed72791f29d69451a729c95d69f2f113feba817ccfdc2c)</span>
 
 <span class="hljs-keyword">val</span> path = <span class="hljs-type">BIP32Path</span>(<span class="hljs-type">Vector</span>(<span class="hljs-type">BIP32Node</span>(<span class="hljs-number">0</span>,<span class="hljs-literal">false</span>)))
 <span class="hljs-comment">// path: BIP32Path = m/0</span>
 
 extPrivKey.sign(<span class="hljs-type">DoubleSha256Digest</span>.empty.bytes,path)
-<span class="hljs-comment">// res1: ECDigitalSignature = ECDigitalSignature(304402207baead228929bf674cc8b37694d2004b9f3909f542a1e2055f6524374af6170702207905ccb418ea708c6ea4abed663562985538686a9185fd77a99fbd6be89b0235)</span>
+<span class="hljs-comment">// res1: ECDigitalSignature = ECDigitalSignature(3045022100cd096078b3b2830ec621c6b3ccb6c88a0b4bfd75261282f1c352e5ccf0cd111902206d45614f7c39dd7f729096b737167b136223b54fc579c9908ae5bcdef0ceb96c)</span>
 </code></pre>
 <p>With <code>ExtSign</code>, you can use <code>ExtPrivateKey</code> to sign transactions inside of <code>TxBuilder</code> since <code>UTXOSpendingInfo</code> takes in <code>Sign</code> as a parameter.</p>
 <p>You can also provide a <code>path</code> to use to derive a child <code>ExtPrivateKey</code>, and then sign with that child private key</p>

docs/next/core/txbuilder.html

@@ -65,25 +65,25 @@
         </script></nav></div><div class="container mainContainer docsContainer"><div class="wrapper"><div class="post"><header class="postHeader"><a class="edit-page-link button" href="https://github.com/bitcoin-s/bitcoin-s/blob/master/docs/core/txbuilder.md" target="_blank" rel="noreferrer noopener">Edit</a><h1 id="__docusaurus" class="postHeaderTitle">TxBuilder Example</h1></header><article><div><span><p>Bitcoin-S features a transaction builder that constructs and signs Bitcoin
 transactions. Here's an example of how to use it</p>
 <pre><code class="hljs css language-scala"><span class="hljs-keyword">implicit</span> <span class="hljs-keyword">val</span> ec: <span class="hljs-type">ExecutionContext</span> = <span class="hljs-type">ExecutionContext</span>.<span class="hljs-type">Implicits</span>.global
-<span class="hljs-comment">// ec: ExecutionContext = scala.concurrent.impl.ExecutionContextImpl$$anon$3@42448218[Running, parallelism = 2, size = 1, active = 0, running = 0, steals = 7, tasks = 0, submissions = 0]</span>
+<span class="hljs-comment">// ec: ExecutionContext = scala.concurrent.impl.ExecutionContextImpl$$anon$3@18668514[Running, parallelism = 2, size = 2, active = 0, running = 0, steals = 4, tasks = 0, submissions = 0]</span>
 
 <span class="hljs-comment">// generate a fresh private key that we are going to use in the scriptpubkey</span>
 <span class="hljs-keyword">val</span> privKey = <span class="hljs-type">ECPrivateKey</span>.freshPrivateKey
 <span class="hljs-comment">// privKey: ECPrivateKey = Masked(ECPrivateKeyImpl)</span>
 <span class="hljs-keyword">val</span> pubKey = privKey.publicKey
-<span class="hljs-comment">// pubKey: ECPublicKey = ECPublicKey(0381a8de12f09a76e7d8c59640be15bcb51db3ccc2b092aa7707bcabb050863882)</span>
+<span class="hljs-comment">// pubKey: ECPublicKey = ECPublicKey(033e2fc29879e842d51ba974ac74b52e8350d5272095ea3e882e6d952ccc267d20)</span>
 
 <span class="hljs-comment">// this is the script that the TxBuilder is going to create a</span>
 <span class="hljs-comment">// script signature that validly spends this scriptPubKey</span>
 <span class="hljs-keyword">val</span> creditingSpk = <span class="hljs-type">P2PKHScriptPubKey</span>(pubKey = privKey.publicKey)
-<span class="hljs-comment">// creditingSpk: P2PKHScriptPubKey = pkh(ee0907430c3ae0435e5f213de2f4a78457275b0f)</span>
+<span class="hljs-comment">// creditingSpk: P2PKHScriptPubKey = pkh(55b0c6fc1a66c26cc6cef25f8d73e2cc4fd3f068)</span>
 <span class="hljs-keyword">val</span> amount = <span class="hljs-number">10000.</span>satoshis
 <span class="hljs-comment">// amount: Satoshis = 10000 sats</span>
 
 <span class="hljs-comment">// this is the UTXO we are going to be spending</span>
 <span class="hljs-keyword">val</span> utxo =
   <span class="hljs-type">TransactionOutput</span>(value = amount, scriptPubKey = creditingSpk)
-<span class="hljs-comment">// utxo: TransactionOutput = TransactionOutput(10000 sats,pkh(ee0907430c3ae0435e5f213de2f4a78457275b0f))</span>
+<span class="hljs-comment">// utxo: TransactionOutput = TransactionOutput(10000 sats,pkh(55b0c6fc1a66c26cc6cef25f8d73e2cc4fd3f068))</span>
 
 <span class="hljs-comment">// the private key that locks the funds for the script we are spending too</span>
 <span class="hljs-keyword">val</span> destinationPrivKey = <span class="hljs-type">ECPrivateKey</span>.freshPrivateKey
@@ -96,7 +96,7 @@ transactions. Here's an example of how to use it</p>
 <span class="hljs-comment">// the script that corresponds to destination private key, this is what is protecting the money</span>
 <span class="hljs-keyword">val</span> destinationSPK =
   <span class="hljs-type">P2PKHScriptPubKey</span>(pubKey = destinationPrivKey.publicKey)
-<span class="hljs-comment">// destinationSPK: P2PKHScriptPubKey = pkh(7ee0bfbfd9be2744e9f6f405ef27e85555bbc181)</span>
+<span class="hljs-comment">// destinationSPK: P2PKHScriptPubKey = pkh(983719e0f050f8f2162abe1e8e57f2cb61e16185)</span>
 
 <span class="hljs-comment">// this is where we are sending money too</span>
 <span class="hljs-comment">// we could add more destinations here if we</span>
@@ -107,7 +107,7 @@ transactions. Here's an example of how to use it</p>
 
     <span class="hljs-type">Vector</span>(destination1)
 }
-<span class="hljs-comment">// destinations: Vector[TransactionOutput] = Vector(TransactionOutput(5000 sats,pkh(7ee0bfbfd9be2744e9f6f405ef27e85555bbc181)))</span>
+<span class="hljs-comment">// destinations: Vector[TransactionOutput] = Vector(TransactionOutput(5000 sats,pkh(983719e0f050f8f2162abe1e8e57f2cb61e16185)))</span>
 
 <span class="hljs-comment">// we have to fabricate a transaction that contains the</span>
 <span class="hljs-comment">// UTXO we are trying to spend. If this were a real blockchain</span>
@@ -116,12 +116,12 @@ transactions. Here's an example of how to use it</p>
                                   inputs = <span class="hljs-type">Vector</span>.empty,
                                   outputs = <span class="hljs-type">Vector</span>(utxo),
                                   lockTime = <span class="hljs-type">UInt32</span>.zero)
-<span class="hljs-comment">// creditingTx: BaseTransaction = BaseTransactionImpl(Int32Impl(1),Vector(),Vector(TransactionOutput(10000 sats,pkh(ee0907430c3ae0435e5f213de2f4a78457275b0f))),UInt32Impl(0))</span>
+<span class="hljs-comment">// creditingTx: BaseTransaction = BaseTransactionImpl(Int32Impl(1),Vector(),Vector(TransactionOutput(10000 sats,pkh(55b0c6fc1a66c26cc6cef25f8d73e2cc4fd3f068))),UInt32Impl(0))</span>
 
 <span class="hljs-comment">// this is the information we need from the crediting TX</span>
 <span class="hljs-comment">// to properly "link" it in the transaction we are creating</span>
 <span class="hljs-keyword">val</span> outPoint = <span class="hljs-type">TransactionOutPoint</span>(creditingTx.txId, <span class="hljs-type">UInt32</span>.zero)
-<span class="hljs-comment">// outPoint: TransactionOutPoint = TransactionOutPoint(a632d313b91b723578e9be749a2513a4ce92069e3f599761ef17d176ff2ceea8:0)</span>
+<span class="hljs-comment">// outPoint: TransactionOutPoint = TransactionOutPoint(d3cff73f79947dab66250608a4ae123661829dd5c55f384658b270cff867b888:0)</span>
 
 <span class="hljs-comment">// this contains all the information we need to</span>
 <span class="hljs-comment">// validly sign the UTXO above</span>
@@ -134,12 +134,12 @@ transactions. Here's an example of how to use it</p>
                                                        <span class="hljs-type">HashType</span>.sigHashAll,
                                                    conditionalPath =
                                                        <span class="hljs-type">ConditionalPath</span>.<span class="hljs-type">NoConditionsLeft</span>)
-<span class="hljs-comment">// utxoSpendingInfo: BitcoinUTXOSpendingInfoFull = P2PKHSpendingInfo(TransactionOutPoint(a632d313b91b723578e9be749a2513a4ce92069e3f599761ef17d176ff2ceea8:0),10000 sats,pkh(ee0907430c3ae0435e5f213de2f4a78457275b0f),Masked(ECPrivateKeyImpl),SIGHASH_ALL(Int32Impl(1)))</span>
+<span class="hljs-comment">// utxoSpendingInfo: BitcoinUTXOSpendingInfoFull = P2PKHSpendingInfo(TransactionOutPoint(d3cff73f79947dab66250608a4ae123661829dd5c55f384658b270cff867b888:0),10000 sats,pkh(55b0c6fc1a66c26cc6cef25f8d73e2cc4fd3f068),Masked(ECPrivateKeyImpl),SIGHASH_ALL(Int32Impl(1)))</span>
 
 <span class="hljs-comment">// all of the UTXO spending information, since we are only</span>
 <span class="hljs-comment">//spending one UTXO, this is just one element</span>
 <span class="hljs-keyword">val</span> utxos: <span class="hljs-type">Vector</span>[<span class="hljs-type">BitcoinUTXOSpendingInfoFull</span>] = <span class="hljs-type">Vector</span>(utxoSpendingInfo)
-<span class="hljs-comment">// utxos: Vector[BitcoinUTXOSpendingInfoFull] = Vector(P2PKHSpendingInfo(TransactionOutPoint(a632d313b91b723578e9be749a2513a4ce92069e3f599761ef17d176ff2ceea8:0),10000 sats,pkh(ee0907430c3ae0435e5f213de2f4a78457275b0f),Masked(ECPrivateKeyImpl),SIGHASH_ALL(Int32Impl(1))))</span>
+<span class="hljs-comment">// utxos: Vector[BitcoinUTXOSpendingInfoFull] = Vector(P2PKHSpendingInfo(TransactionOutPoint(d3cff73f79947dab66250608a4ae123661829dd5c55f384658b270cff867b888:0),10000 sats,pkh(55b0c6fc1a66c26cc6cef25f8d73e2cc4fd3f068),Masked(ECPrivateKeyImpl),SIGHASH_ALL(Int32Impl(1))))</span>
 
 <span class="hljs-comment">// this is how much we are going to pay as a fee to the network</span>
 <span class="hljs-comment">// for this example, we are going to pay 1 satoshi per byte</span>
@@ -149,7 +149,7 @@ transactions. Here's an example of how to use it</p>
 <span class="hljs-keyword">val</span> changePrivKey = <span class="hljs-type">ECPrivateKey</span>.freshPrivateKey
 <span class="hljs-comment">// changePrivKey: ECPrivateKey = Masked(ECPrivateKeyImpl)</span>
 <span class="hljs-keyword">val</span> changeSPK = <span class="hljs-type">P2PKHScriptPubKey</span>(pubKey = changePrivKey.publicKey)
-<span class="hljs-comment">// changeSPK: P2PKHScriptPubKey = pkh(2612422760bfb2420a6827d882f48cd914c5ae18)</span>
+<span class="hljs-comment">// changeSPK: P2PKHScriptPubKey = pkh(474d19d36bbb49e0eddec5a3c1d80fa192f435c3)</span>
 
 <span class="hljs-comment">// the network we are on, for this example we are using</span>
 <span class="hljs-comment">// the regression test network. This is a network you control</span>
@@ -168,7 +168,7 @@ transactions. Here's an example of how to use it</p>
     network = networkParams)
   <span class="hljs-type">Await</span>.result(builderF, <span class="hljs-number">30.</span>seconds)
 }
-<span class="hljs-comment">// txBuilder: BitcoinTxBuilder = BitcoinTxBuilderImpl(Vector(TransactionOutput(5000 sats,pkh(7ee0bfbfd9be2744e9f6f405ef27e85555bbc181))),Map(TransactionOutPoint(a632d313b91b723578e9be749a2513a4ce92069e3f599761ef17d176ff2ceea8:0) -&gt; P2PKHSpendingInfo(TransactionOutPoint(a632d313b91b723578e9be749a2513a4ce92069e3f599761ef17d176ff2ceea8:0),10000 sats,pkh(ee0907430c3ae0435e5f213de2f4a78457275b0f),Masked(ECPrivateKeyImpl),SIGHASH_ALL(Int32Impl(1)))),SatoshisPerByte(1 sat),pkh(2612422760bfb2420a6827d882f48cd914c5ae18),RegTest)</span>
+<span class="hljs-comment">// txBuilder: BitcoinTxBuilder = BitcoinTxBuilderImpl(Vector(TransactionOutput(5000 sats,pkh(983719e0f050f8f2162abe1e8e57f2cb61e16185))),Map(TransactionOutPoint(d3cff73f79947dab66250608a4ae123661829dd5c55f384658b270cff867b888:0) -&gt; P2PKHSpendingInfo(TransactionOutPoint(d3cff73f79947dab66250608a4ae123661829dd5c55f384658b270cff867b888:0),10000 sats,pkh(55b0c6fc1a66c26cc6cef25f8d73e2cc4fd3f068),Masked(ECPrivateKeyImpl),SIGHASH_ALL(Int32Impl(1)))),SatoshisPerByte(1 sat),pkh(474d19d36bbb49e0eddec5a3c1d80fa192f435c3),RegTest)</span>
 
 <span class="hljs-comment">// Let's finally produce a validly signed tx!</span>
 <span class="hljs-comment">// The 'sign' method is going produce a validly signed transaction</span>
@@ -182,7 +182,7 @@ transactions. Here's an example of how to use it</p>
   <span class="hljs-keyword">val</span> signF = txBuilder.sign
   <span class="hljs-type">Await</span>.result(signF, <span class="hljs-number">30.</span>seconds)
 }
-<span class="hljs-comment">// signedTx: Transaction = BaseTransactionImpl(Int32Impl(2),List(TransactionInputImpl(TransactionOutPoint(a632d313b91b723578e9be749a2513a4ce92069e3f599761ef17d176ff2ceea8:0),P2PKHScriptSignature(ECPublicKey(0381a8de12f09a76e7d8c59640be15bcb51db3ccc2b092aa7707bcabb050863882), ECDigitalSignature(3044022011c589321131c082f2f0bdc51e4080c6ff6423e0d1944bcf950bbdbd0d498b40022046067534ce9b44a1492f2f281107bf5b7248ebc2ad9dac89ff4da6533a33062e01)),UInt32Impl(0))),Vector(TransactionOutput(5000 sats,pkh(7ee0bfbfd9be2744e9f6f405ef27e85555bbc181)), TransactionOutput(4774 sats,pkh(2612422760bfb2420a6827d882f48cd914c5ae18))),UInt32Impl(0))</span>
+<span class="hljs-comment">// signedTx: Transaction = BaseTransactionImpl(Int32Impl(2),List(TransactionInputImpl(TransactionOutPoint(d3cff73f79947dab66250608a4ae123661829dd5c55f384658b270cff867b888:0),P2PKHScriptSignature(ECPublicKey(033e2fc29879e842d51ba974ac74b52e8350d5272095ea3e882e6d952ccc267d20), ECDigitalSignature(3045022100fd2542595ab78eac480b2c140a13c3a79d978f6aeddb4e9310074955a7f934c202207e6086a505190d5826fb9928ac326ed7eb2a257a2fd7926f28e52c8089da796501)),UInt32Impl(0))),Vector(TransactionOutput(5000 sats,pkh(983719e0f050f8f2162abe1e8e57f2cb61e16185)), TransactionOutput(4774 sats,pkh(474d19d36bbb49e0eddec5a3c1d80fa192f435c3))),UInt32Impl(0))</span>
 </code></pre>
 <pre><code class="hljs css language-scala">signedTx.inputs.length
 <span class="hljs-comment">// res0: Int = 1</span>
@@ -192,7 +192,7 @@ signedTx.outputs.length
 
 <span class="hljs-comment">//remember, you can call .hex on any bitcoin-s data structure to get the hex representation!</span>
 signedTx.hex
-<span class="hljs-comment">// res2: String = 0200000001a8ee2cff76d117ef6197593f9e0692cea413259a74bee97835721bb913d332a6000000006a473044022011c589321131c082f2f0bdc51e4080c6ff6423e0d1944bcf950bbdbd0d498b40022046067534ce9b44a1492f2f281107bf5b7248ebc2ad9dac89ff4da6533a33062e01210381a8de12f09a76e7d8c59640be15bcb51db3ccc2b092aa7707bcabb050863882000000000288130000000000001976a9147ee0bfbfd9be2744e9f6f405ef27e85555bbc18188aca6120000000000001976a9142612422760bfb2420a6827d882f48cd914c5ae1888ac00000000</span>
+<span class="hljs-comment">// res2: String = 020000000188b867f8cf70b25846385fc5d59d82613612aea408062566ab7d94793ff7cfd3000000006b483045022100fd2542595ab78eac480b2c140a13c3a79d978f6aeddb4e9310074955a7f934c202207e6086a505190d5826fb9928ac326ed7eb2a257a2fd7926f28e52c8089da79650121033e2fc29879e842d51ba974ac74b52e8350d5272095ea3e882e6d952ccc267d20000000000288130000000000001976a914983719e0f050f8f2162abe1e8e57f2cb61e1618588aca6120000000000001976a914474d19d36bbb49e0eddec5a3c1d80fa192f435c388ac00000000</span>
 </code></pre>
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docs/next/core/txbuilder/index.html

@@ -65,25 +65,25 @@
         </script></nav></div><div class="container mainContainer docsContainer"><div class="wrapper"><div class="post"><header class="postHeader"><a class="edit-page-link button" href="https://github.com/bitcoin-s/bitcoin-s/blob/master/docs/core/txbuilder.md" target="_blank" rel="noreferrer noopener">Edit</a><h1 id="__docusaurus" class="postHeaderTitle">TxBuilder Example</h1></header><article><div><span><p>Bitcoin-S features a transaction builder that constructs and signs Bitcoin
 transactions. Here's an example of how to use it</p>
 <pre><code class="hljs css language-scala"><span class="hljs-keyword">implicit</span> <span class="hljs-keyword">val</span> ec: <span class="hljs-type">ExecutionContext</span> = <span class="hljs-type">ExecutionContext</span>.<span class="hljs-type">Implicits</span>.global
-<span class="hljs-comment">// ec: ExecutionContext = scala.concurrent.impl.ExecutionContextImpl$$anon$3@42448218[Running, parallelism = 2, size = 1, active = 0, running = 0, steals = 7, tasks = 0, submissions = 0]</span>
+<span class="hljs-comment">// ec: ExecutionContext = scala.concurrent.impl.ExecutionContextImpl$$anon$3@18668514[Running, parallelism = 2, size = 2, active = 0, running = 0, steals = 4, tasks = 0, submissions = 0]</span>
 
 <span class="hljs-comment">// generate a fresh private key that we are going to use in the scriptpubkey</span>
 <span class="hljs-keyword">val</span> privKey = <span class="hljs-type">ECPrivateKey</span>.freshPrivateKey
 <span class="hljs-comment">// privKey: ECPrivateKey = Masked(ECPrivateKeyImpl)</span>
 <span class="hljs-keyword">val</span> pubKey = privKey.publicKey
-<span class="hljs-comment">// pubKey: ECPublicKey = ECPublicKey(0381a8de12f09a76e7d8c59640be15bcb51db3ccc2b092aa7707bcabb050863882)</span>
+<span class="hljs-comment">// pubKey: ECPublicKey = ECPublicKey(033e2fc29879e842d51ba974ac74b52e8350d5272095ea3e882e6d952ccc267d20)</span>
 
 <span class="hljs-comment">// this is the script that the TxBuilder is going to create a</span>
 <span class="hljs-comment">// script signature that validly spends this scriptPubKey</span>
 <span class="hljs-keyword">val</span> creditingSpk = <span class="hljs-type">P2PKHScriptPubKey</span>(pubKey = privKey.publicKey)
-<span class="hljs-comment">// creditingSpk: P2PKHScriptPubKey = pkh(ee0907430c3ae0435e5f213de2f4a78457275b0f)</span>
+<span class="hljs-comment">// creditingSpk: P2PKHScriptPubKey = pkh(55b0c6fc1a66c26cc6cef25f8d73e2cc4fd3f068)</span>
 <span class="hljs-keyword">val</span> amount = <span class="hljs-number">10000.</span>satoshis
 <span class="hljs-comment">// amount: Satoshis = 10000 sats</span>
 
 <span class="hljs-comment">// this is the UTXO we are going to be spending</span>
 <span class="hljs-keyword">val</span> utxo =
   <span class="hljs-type">TransactionOutput</span>(value = amount, scriptPubKey = creditingSpk)
-<span class="hljs-comment">// utxo: TransactionOutput = TransactionOutput(10000 sats,pkh(ee0907430c3ae0435e5f213de2f4a78457275b0f))</span>
+<span class="hljs-comment">// utxo: TransactionOutput = TransactionOutput(10000 sats,pkh(55b0c6fc1a66c26cc6cef25f8d73e2cc4fd3f068))</span>
 
 <span class="hljs-comment">// the private key that locks the funds for the script we are spending too</span>
 <span class="hljs-keyword">val</span> destinationPrivKey = <span class="hljs-type">ECPrivateKey</span>.freshPrivateKey
@@ -96,7 +96,7 @@ transactions. Here's an example of how to use it</p>
 <span class="hljs-comment">// the script that corresponds to destination private key, this is what is protecting the money</span>
 <span class="hljs-keyword">val</span> destinationSPK =
   <span class="hljs-type">P2PKHScriptPubKey</span>(pubKey = destinationPrivKey.publicKey)
-<span class="hljs-comment">// destinationSPK: P2PKHScriptPubKey = pkh(7ee0bfbfd9be2744e9f6f405ef27e85555bbc181)</span>
+<span class="hljs-comment">// destinationSPK: P2PKHScriptPubKey = pkh(983719e0f050f8f2162abe1e8e57f2cb61e16185)</span>
 
 <span class="hljs-comment">// this is where we are sending money too</span>
 <span class="hljs-comment">// we could add more destinations here if we</span>
@@ -107,7 +107,7 @@ transactions. Here's an example of how to use it</p>
 
     <span class="hljs-type">Vector</span>(destination1)
 }
-<span class="hljs-comment">// destinations: Vector[TransactionOutput] = Vector(TransactionOutput(5000 sats,pkh(7ee0bfbfd9be2744e9f6f405ef27e85555bbc181)))</span>
+<span class="hljs-comment">// destinations: Vector[TransactionOutput] = Vector(TransactionOutput(5000 sats,pkh(983719e0f050f8f2162abe1e8e57f2cb61e16185)))</span>
 
 <span class="hljs-comment">// we have to fabricate a transaction that contains the</span>
 <span class="hljs-comment">// UTXO we are trying to spend. If this were a real blockchain</span>
@@ -116,12 +116,12 @@ transactions. Here's an example of how to use it</p>
                                   inputs = <span class="hljs-type">Vector</span>.empty,
                                   outputs = <span class="hljs-type">Vector</span>(utxo),
                                   lockTime = <span class="hljs-type">UInt32</span>.zero)
-<span class="hljs-comment">// creditingTx: BaseTransaction = BaseTransactionImpl(Int32Impl(1),Vector(),Vector(TransactionOutput(10000 sats,pkh(ee0907430c3ae0435e5f213de2f4a78457275b0f))),UInt32Impl(0))</span>
+<span class="hljs-comment">// creditingTx: BaseTransaction = BaseTransactionImpl(Int32Impl(1),Vector(),Vector(TransactionOutput(10000 sats,pkh(55b0c6fc1a66c26cc6cef25f8d73e2cc4fd3f068))),UInt32Impl(0))</span>
 
 <span class="hljs-comment">// this is the information we need from the crediting TX</span>
 <span class="hljs-comment">// to properly "link" it in the transaction we are creating</span>
 <span class="hljs-keyword">val</span> outPoint = <span class="hljs-type">TransactionOutPoint</span>(creditingTx.txId, <span class="hljs-type">UInt32</span>.zero)
-<span class="hljs-comment">// outPoint: TransactionOutPoint = TransactionOutPoint(a632d313b91b723578e9be749a2513a4ce92069e3f599761ef17d176ff2ceea8:0)</span>
+<span class="hljs-comment">// outPoint: TransactionOutPoint = TransactionOutPoint(d3cff73f79947dab66250608a4ae123661829dd5c55f384658b270cff867b888:0)</span>
 
 <span class="hljs-comment">// this contains all the information we need to</span>
 <span class="hljs-comment">// validly sign the UTXO above</span>
@@ -134,12 +134,12 @@ transactions. Here's an example of how to use it</p>
                                                        <span class="hljs-type">HashType</span>.sigHashAll,
                                                    conditionalPath =
                                                        <span class="hljs-type">ConditionalPath</span>.<span class="hljs-type">NoConditionsLeft</span>)
-<span class="hljs-comment">// utxoSpendingInfo: BitcoinUTXOSpendingInfoFull = P2PKHSpendingInfo(TransactionOutPoint(a632d313b91b723578e9be749a2513a4ce92069e3f599761ef17d176ff2ceea8:0),10000 sats,pkh(ee0907430c3ae0435e5f213de2f4a78457275b0f),Masked(ECPrivateKeyImpl),SIGHASH_ALL(Int32Impl(1)))</span>
+<span class="hljs-comment">// utxoSpendingInfo: BitcoinUTXOSpendingInfoFull = P2PKHSpendingInfo(TransactionOutPoint(d3cff73f79947dab66250608a4ae123661829dd5c55f384658b270cff867b888:0),10000 sats,pkh(55b0c6fc1a66c26cc6cef25f8d73e2cc4fd3f068),Masked(ECPrivateKeyImpl),SIGHASH_ALL(Int32Impl(1)))</span>
 
 <span class="hljs-comment">// all of the UTXO spending information, since we are only</span>
 <span class="hljs-comment">//spending one UTXO, this is just one element</span>
 <span class="hljs-keyword">val</span> utxos: <span class="hljs-type">Vector</span>[<span class="hljs-type">BitcoinUTXOSpendingInfoFull</span>] = <span class="hljs-type">Vector</span>(utxoSpendingInfo)
-<span class="hljs-comment">// utxos: Vector[BitcoinUTXOSpendingInfoFull] = Vector(P2PKHSpendingInfo(TransactionOutPoint(a632d313b91b723578e9be749a2513a4ce92069e3f599761ef17d176ff2ceea8:0),10000 sats,pkh(ee0907430c3ae0435e5f213de2f4a78457275b0f),Masked(ECPrivateKeyImpl),SIGHASH_ALL(Int32Impl(1))))</span>
+<span class="hljs-comment">// utxos: Vector[BitcoinUTXOSpendingInfoFull] = Vector(P2PKHSpendingInfo(TransactionOutPoint(d3cff73f79947dab66250608a4ae123661829dd5c55f384658b270cff867b888:0),10000 sats,pkh(55b0c6fc1a66c26cc6cef25f8d73e2cc4fd3f068),Masked(ECPrivateKeyImpl),SIGHASH_ALL(Int32Impl(1))))</span>
 
 <span class="hljs-comment">// this is how much we are going to pay as a fee to the network</span>
 <span class="hljs-comment">// for this example, we are going to pay 1 satoshi per byte</span>
@@ -149,7 +149,7 @@ transactions. Here's an example of how to use it</p>
 <span class="hljs-keyword">val</span> changePrivKey = <span class="hljs-type">ECPrivateKey</span>.freshPrivateKey
 <span class="hljs-comment">// changePrivKey: ECPrivateKey = Masked(ECPrivateKeyImpl)</span>
 <span class="hljs-keyword">val</span> changeSPK = <span class="hljs-type">P2PKHScriptPubKey</span>(pubKey = changePrivKey.publicKey)
-<span class="hljs-comment">// changeSPK: P2PKHScriptPubKey = pkh(2612422760bfb2420a6827d882f48cd914c5ae18)</span>
+<span class="hljs-comment">// changeSPK: P2PKHScriptPubKey = pkh(474d19d36bbb49e0eddec5a3c1d80fa192f435c3)</span>
 
 <span class="hljs-comment">// the network we are on, for this example we are using</span>
 <span class="hljs-comment">// the regression test network. This is a network you control</span>
@@ -168,7 +168,7 @@ transactions. Here's an example of how to use it</p>
     network = networkParams)
   <span class="hljs-type">Await</span>.result(builderF, <span class="hljs-number">30.</span>seconds)
 }
-<span class="hljs-comment">// txBuilder: BitcoinTxBuilder = BitcoinTxBuilderImpl(Vector(TransactionOutput(5000 sats,pkh(7ee0bfbfd9be2744e9f6f405ef27e85555bbc181))),Map(TransactionOutPoint(a632d313b91b723578e9be749a2513a4ce92069e3f599761ef17d176ff2ceea8:0) -&gt; P2PKHSpendingInfo(TransactionOutPoint(a632d313b91b723578e9be749a2513a4ce92069e3f599761ef17d176ff2ceea8:0),10000 sats,pkh(ee0907430c3ae0435e5f213de2f4a78457275b0f),Masked(ECPrivateKeyImpl),SIGHASH_ALL(Int32Impl(1)))),SatoshisPerByte(1 sat),pkh(2612422760bfb2420a6827d882f48cd914c5ae18),RegTest)</span>
+<span class="hljs-comment">// txBuilder: BitcoinTxBuilder = BitcoinTxBuilderImpl(Vector(TransactionOutput(5000 sats,pkh(983719e0f050f8f2162abe1e8e57f2cb61e16185))),Map(TransactionOutPoint(d3cff73f79947dab66250608a4ae123661829dd5c55f384658b270cff867b888:0) -&gt; P2PKHSpendingInfo(TransactionOutPoint(d3cff73f79947dab66250608a4ae123661829dd5c55f384658b270cff867b888:0),10000 sats,pkh(55b0c6fc1a66c26cc6cef25f8d73e2cc4fd3f068),Masked(ECPrivateKeyImpl),SIGHASH_ALL(Int32Impl(1)))),SatoshisPerByte(1 sat),pkh(474d19d36bbb49e0eddec5a3c1d80fa192f435c3),RegTest)</span>
 
 <span class="hljs-comment">// Let's finally produce a validly signed tx!</span>
 <span class="hljs-comment">// The 'sign' method is going produce a validly signed transaction</span>
@@ -182,7 +182,7 @@ transactions. Here's an example of how to use it</p>
   <span class="hljs-keyword">val</span> signF = txBuilder.sign
   <span class="hljs-type">Await</span>.result(signF, <span class="hljs-number">30.</span>seconds)
 }
-<span class="hljs-comment">// signedTx: Transaction = BaseTransactionImpl(Int32Impl(2),List(TransactionInputImpl(TransactionOutPoint(a632d313b91b723578e9be749a2513a4ce92069e3f599761ef17d176ff2ceea8:0),P2PKHScriptSignature(ECPublicKey(0381a8de12f09a76e7d8c59640be15bcb51db3ccc2b092aa7707bcabb050863882), ECDigitalSignature(3044022011c589321131c082f2f0bdc51e4080c6ff6423e0d1944bcf950bbdbd0d498b40022046067534ce9b44a1492f2f281107bf5b7248ebc2ad9dac89ff4da6533a33062e01)),UInt32Impl(0))),Vector(TransactionOutput(5000 sats,pkh(7ee0bfbfd9be2744e9f6f405ef27e85555bbc181)), TransactionOutput(4774 sats,pkh(2612422760bfb2420a6827d882f48cd914c5ae18))),UInt32Impl(0))</span>
+<span class="hljs-comment">// signedTx: Transaction = BaseTransactionImpl(Int32Impl(2),List(TransactionInputImpl(TransactionOutPoint(d3cff73f79947dab66250608a4ae123661829dd5c55f384658b270cff867b888:0),P2PKHScriptSignature(ECPublicKey(033e2fc29879e842d51ba974ac74b52e8350d5272095ea3e882e6d952ccc267d20), ECDigitalSignature(3045022100fd2542595ab78eac480b2c140a13c3a79d978f6aeddb4e9310074955a7f934c202207e6086a505190d5826fb9928ac326ed7eb2a257a2fd7926f28e52c8089da796501)),UInt32Impl(0))),Vector(TransactionOutput(5000 sats,pkh(983719e0f050f8f2162abe1e8e57f2cb61e16185)), TransactionOutput(4774 sats,pkh(474d19d36bbb49e0eddec5a3c1d80fa192f435c3))),UInt32Impl(0))</span>
 </code></pre>
 <pre><code class="hljs css language-scala">signedTx.inputs.length
 <span class="hljs-comment">// res0: Int = 1</span>
@@ -192,7 +192,7 @@ signedTx.outputs.length
 
 <span class="hljs-comment">//remember, you can call .hex on any bitcoin-s data structure to get the hex representation!</span>
 signedTx.hex
-<span class="hljs-comment">// res2: String = 0200000001a8ee2cff76d117ef6197593f9e0692cea413259a74bee97835721bb913d332a6000000006a473044022011c589321131c082f2f0bdc51e4080c6ff6423e0d1944bcf950bbdbd0d498b40022046067534ce9b44a1492f2f281107bf5b7248ebc2ad9dac89ff4da6533a33062e01210381a8de12f09a76e7d8c59640be15bcb51db3ccc2b092aa7707bcabb050863882000000000288130000000000001976a9147ee0bfbfd9be2744e9f6f405ef27e85555bbc18188aca6120000000000001976a9142612422760bfb2420a6827d882f48cd914c5ae1888ac00000000</span>
+<span class="hljs-comment">// res2: String = 020000000188b867f8cf70b25846385fc5d59d82613612aea408062566ab7d94793ff7cfd3000000006b483045022100fd2542595ab78eac480b2c140a13c3a79d978f6aeddb4e9310074955a7f934c202207e6086a505190d5826fb9928ac326ed7eb2a257a2fd7926f28e52c8089da79650121033e2fc29879e842d51ba974ac74b52e8350d5272095ea3e882e6d952ccc267d20000000000288130000000000001976a914983719e0f050f8f2162abe1e8e57f2cb61e1618588aca6120000000000001976a914474d19d36bbb49e0eddec5a3c1d80fa192f435c388ac00000000</span>
 </code></pre>
 </span></div></article></div><div class="docs-prevnext"><a class="docs-prev button" href="/docs/next/core/psbts"><span class="arrow-prev">← </span><span>Partially Signed Bitcoin Transactions</span></a><a class="docs-next button" href="/docs/next/key-manager/key-manager"><span>Key Manager</span><span class="arrow-next"> →</span></a></div></div></div><nav class="onPageNav"></nav></div><footer class="nav-footer" id="footer"><section class="sitemap"><a href="/" class="nav-home"><img src="/img/favicon.ico" alt="bitcoin-s" width="66" height="58"/></a><div><h5>Docs</h5><a href="/docs/en/getting-started">Getting Started</a><a href="/docs/en/core/core-intro">Guides</a><a href="/api/org/bitcoins">API Reference</a></div><div><h5>Community</h5><a href="/en/users.html">User Showcase</a><a href="https://join.slack.com/t/suredbits/shared_invite/enQtNDEyMjY3MTg1MTg3LTYyYjkwOGUzMDQ4NDAwZjE1M2I3MmQyNWNlZjNlYjg4OGRjYTRjNWUwNjRjNjg4Y2NjZjAxYjU1N2JjMTU1YWM" target="_blank" rel="noreferrer noopener">Slack</a><a href="https://gitter.im/bitcoin-s-core/">Gitter chat</a></div><div><h5>More</h5><a href="https://github.com/bitcoin-s/bitcoin-s">GitHub</a><a class="github-button" href="https://github.com/bitcoin-s/bitcoin-s" data-icon="octicon-star" data-count-href="/bitcoin-s/bitcoin-s-core/stargazers" data-show-count="true" data-count-aria-label="# stargazers on GitHub" aria-label="Star this project on GitHub">Star</a></div></section><section class="copyright">Copyright © 2020 Suredbits &amp; the bitcoin-s developers</section></footer></div><script type="text/javascript" src="https://cdn.jsdelivr.net/docsearch.js/1/docsearch.min.js"></script><script>
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docs/next/getting-started.html

@@ -120,7 +120,7 @@ libraryDependencies += <span class="hljs-string">"org.bitcoin-s"</span> %% <span
 <h3><a class="anchor" aria-hidden="true" id="nightly-builds"></a><a href="#nightly-builds" aria-hidden="true" class="hash-link"><svg class="hash-link-icon" aria-hidden="true" height="16" version="1.1" viewBox="0 0 16 16" width="16"><path fill-rule="evenodd" d="M4 9h1v1H4c-1.5 0-3-1.69-3-3.5S2.55 3 4 3h4c1.45 0 3 1.69 3 3.5 0 1.41-.91 2.72-2 3.25V8.59c.58-.45 1-1.27 1-2.09C10 5.22 8.98 4 8 4H4c-.98 0-2 1.22-2 2.5S3 9 4 9zm9-3h-1v1h1c1 0 2 1.22 2 2.5S13.98 12 13 12H9c-.98 0-2-1.22-2-2.5 0-.83.42-1.64 1-2.09V6.25c-1.09.53-2 1.84-2 3.25C6 11.31 7.55 13 9 13h4c1.45 0 3-1.69 3-3.5S14.5 6 13 6z"></path></svg></a>Nightly builds</h3>
 <p>You can also run on the bleeding edge of Bitcoin-S, by
 adding a snapshot build to your <code>build.sbt</code>. The most
-recent snapshot published is <code>0.3.0+54-719f1762-SNAPSHOT</code>.</p>
+recent snapshot published is <code>0.3.0+55-8d4cbeb9-SNAPSHOT</code>.</p>
 <p>To fetch snapshots, you will need to add the correct
 resolver in your <code>build.sbt</code>:</p>
 <p>​```sbt

docs/next/getting-started/index.html

@@ -120,7 +120,7 @@ libraryDependencies += <span class="hljs-string">"org.bitcoin-s"</span> %% <span
 <h3><a class="anchor" aria-hidden="true" id="nightly-builds"></a><a href="#nightly-builds" aria-hidden="true" class="hash-link"><svg class="hash-link-icon" aria-hidden="true" height="16" version="1.1" viewBox="0 0 16 16" width="16"><path fill-rule="evenodd" d="M4 9h1v1H4c-1.5 0-3-1.69-3-3.5S2.55 3 4 3h4c1.45 0 3 1.69 3 3.5 0 1.41-.91 2.72-2 3.25V8.59c.58-.45 1-1.27 1-2.09C10 5.22 8.98 4 8 4H4c-.98 0-2 1.22-2 2.5S3 9 4 9zm9-3h-1v1h1c1 0 2 1.22 2 2.5S13.98 12 13 12H9c-.98 0-2-1.22-2-2.5 0-.83.42-1.64 1-2.09V6.25c-1.09.53-2 1.84-2 3.25C6 11.31 7.55 13 9 13h4c1.45 0 3-1.69 3-3.5S14.5 6 13 6z"></path></svg></a>Nightly builds</h3>
 <p>You can also run on the bleeding edge of Bitcoin-S, by
 adding a snapshot build to your <code>build.sbt</code>. The most
-recent snapshot published is <code>0.3.0+54-719f1762-SNAPSHOT</code>.</p>
+recent snapshot published is <code>0.3.0+55-8d4cbeb9-SNAPSHOT</code>.</p>
 <p>To fetch snapshots, you will need to add the correct
 resolver in your <code>build.sbt</code>:</p>
 <p>​```sbt

docs/next/key-manager/key-manager.html

@@ -85,14 +85,14 @@ as a logical distinction for further development in subsequent releases.</p>
 
 <span class="hljs-comment">//get 256 bits of random entropy</span>
 <span class="hljs-keyword">val</span> entropy = <span class="hljs-type">MnemonicCode</span>.getEntropy256Bits
-<span class="hljs-comment">// entropy: scodec.bits.BitVector = BitVector(256 bits, 0xb05bb5b336769b7e19beb20b1725be6a48be0bcf7496c2c889938e0965089a36)</span>
+<span class="hljs-comment">// entropy: scodec.bits.BitVector = BitVector(256 bits, 0x7101e9b39e2d8014ba5e4713c53a5e6e49d4e66c79032b25ec8064199ce22bd4)</span>
 
 <span class="hljs-keyword">val</span> mnemonic = <span class="hljs-type">MnemonicCode</span>.fromEntropy(entropy)
 <span class="hljs-comment">// mnemonic: MnemonicCode = Masked(MnemonicCodeImpl)</span>
 
 <span class="hljs-comment">//you can print that mnemonic seed with this</span>
 println(mnemonic.words)
-<span class="hljs-comment">// Vector(raccoon, tank, holiday, hollow, have, sample, group, stone, arch, rice, hurdle, stand, message, album, differ, name, security, dust, gossip, bright, north, lounge, hand, sure)</span>
+<span class="hljs-comment">// Vector(illegal, aunt, hollow, detail, submit, apart, truly, similar, because, clap, nurse, symptom, outer, industry, rapid, call, clinic, control, cactus, sight, oil, illegal, quantum, lucky)</span>
 </code></pre>
 <p>Now that we have a <code>MnemonicCode</code> that was securely generated, we need to now create <code>KeyManagerParams</code> which tells us how to generate
 generate specific kinds of addresses for wallets.</p>
@@ -107,7 +107,7 @@ generate specific kinds of addresses for wallets.</p>
 <pre><code class="hljs css language-scala"><span class="hljs-comment">//this will create a temp directory with the prefix 'key-manager-example` that will</span>
 <span class="hljs-comment">//have a file in it called "encrypted-bitcoin-s-seed.json"</span>
 <span class="hljs-keyword">val</span> seedPath = <span class="hljs-type">Files</span>.createTempDirectory(<span class="hljs-string">"key-manager-example"</span>).resolve(<span class="hljs-type">WalletStorage</span>.<span class="hljs-type">ENCRYPTED_SEED_FILE_NAME</span>)
-<span class="hljs-comment">// seedPath: Path = /tmp/key-manager-example13891847003058512663/encrypted-bitcoin-s-seed.json</span>
+<span class="hljs-comment">// seedPath: Path = /tmp/key-manager-example16031052174349861383/encrypted-bitcoin-s-seed.json</span>
 
 <span class="hljs-comment">//let's create a native segwit key manager</span>
 <span class="hljs-keyword">val</span> purpose = <span class="hljs-type">HDPurposes</span>.<span class="hljs-type">SegWit</span>
@@ -118,16 +118,16 @@ generate specific kinds of addresses for wallets.</p>
 <span class="hljs-comment">// network: RegTest.type = RegTest</span>
 
 <span class="hljs-keyword">val</span> kmParams = <span class="hljs-type">KeyManagerParams</span>(seedPath, purpose, network)
-<span class="hljs-comment">// kmParams: KeyManagerParams = KeyManagerParams(/tmp/key-manager-example13891847003058512663/encrypted-bitcoin-s-seed.json,m/84',RegTest)</span>
+<span class="hljs-comment">// kmParams: KeyManagerParams = KeyManagerParams(/tmp/key-manager-example16031052174349861383/encrypted-bitcoin-s-seed.json,m/84',RegTest)</span>
 
 <span class="hljs-keyword">val</span> km = <span class="hljs-type">BIP39KeyManager</span>.initializeWithMnemonic(mnemonic, <span class="hljs-type">None</span>, kmParams)
-<span class="hljs-comment">// km: Either[KeyManagerInitializeError, BIP39KeyManager] = Right(BIP39KeyManager(Masked(MnemonicCodeImpl),KeyManagerParams(/tmp/key-manager-example13891847003058512663/encrypted-bitcoin-s-seed.json,m/84',RegTest),None))</span>
+<span class="hljs-comment">// km: Either[KeyManagerInitializeError, BIP39KeyManager] = Right(BIP39KeyManager(Masked(MnemonicCodeImpl),KeyManagerParams(/tmp/key-manager-example16031052174349861383/encrypted-bitcoin-s-seed.json,m/84',RegTest),None))</span>
 
 <span class="hljs-keyword">val</span> rootXPub = km.right.get.getRootXPub
-<span class="hljs-comment">// rootXPub: ExtPublicKey = vpub5SLqN2bLY4WeaQNNDHwnfipbP7uqmwWeLrG4D5La39ehiDSmpvk9ELDpjvbEZCeRmkuUAtRn8PLs4wspMrCzer9Hb8Se1qBFDfNFcmJPW7k</span>
+<span class="hljs-comment">// rootXPub: ExtPublicKey = vpub5SLqN2bLY4WeZZWrgLFZ6bFeEbiPU8ffDhcnqJQau8GuLHJtcWZ1x7rKzA7pDfMnqE4dU5snTydPwpjKgu65M9YVkNWmWBNaWLTdAXuH4pr</span>
 
 println(rootXPub)
-<span class="hljs-comment">// vpub5SLqN2bLY4WeaQNNDHwnfipbP7uqmwWeLrG4D5La39ehiDSmpvk9ELDpjvbEZCeRmkuUAtRn8PLs4wspMrCzer9Hb8Se1qBFDfNFcmJPW7k</span>
+<span class="hljs-comment">// vpub5SLqN2bLY4WeZZWrgLFZ6bFeEbiPU8ffDhcnqJQau8GuLHJtcWZ1x7rKzA7pDfMnqE4dU5snTydPwpjKgu65M9YVkNWmWBNaWLTdAXuH4pr</span>
 </code></pre>
 <p>Which should print something that looks like this</p>
 <p><code>vpub5SLqN2bLY4WeXxMqwJHJFBEwxSscGB2uDUnsTS3edVjZEwTrQDFDNqoR2xLqARQPabGaXsHSTenTRcqm2EnB9MpuC4vSk3LqSgNmGGZtuq7</code></p>
@@ -136,17 +136,17 @@ println(rootXPub)
 again after initializing it once. You can use the same <code>mnemonic</code> for different networks, which you control <code>KeyManagerParams</code>.</p>
 <pre><code class="hljs css language-scala"><span class="hljs-comment">//let's create a nested segwit key manager for mainnet</span>
 <span class="hljs-keyword">val</span> mainnetKmParams = <span class="hljs-type">KeyManagerParams</span>(seedPath, <span class="hljs-type">HDPurposes</span>.<span class="hljs-type">SegWit</span>, <span class="hljs-type">MainNet</span>)
-<span class="hljs-comment">// mainnetKmParams: KeyManagerParams = KeyManagerParams(/tmp/key-manager-example13891847003058512663/encrypted-bitcoin-s-seed.json,m/84',MainNet)</span>
+<span class="hljs-comment">// mainnetKmParams: KeyManagerParams = KeyManagerParams(/tmp/key-manager-example16031052174349861383/encrypted-bitcoin-s-seed.json,m/84',MainNet)</span>
 
 <span class="hljs-comment">//we do not need to all `initializeWithMnemonic()` again as we have saved the seed to dis</span>
 <span class="hljs-keyword">val</span> mainnetKeyManager = <span class="hljs-type">BIP39KeyManager</span>(mnemonic, mainnetKmParams, <span class="hljs-type">None</span>)
-<span class="hljs-comment">// mainnetKeyManager: BIP39KeyManager = BIP39KeyManager(Masked(MnemonicCodeImpl),KeyManagerParams(/tmp/key-manager-example13891847003058512663/encrypted-bitcoin-s-seed.json,m/84',MainNet),None)</span>
+<span class="hljs-comment">// mainnetKeyManager: BIP39KeyManager = BIP39KeyManager(Masked(MnemonicCodeImpl),KeyManagerParams(/tmp/key-manager-example16031052174349861383/encrypted-bitcoin-s-seed.json,m/84',MainNet),None)</span>
 
 <span class="hljs-keyword">val</span> mainnetXpub = mainnetKeyManager.getRootXPub
-<span class="hljs-comment">// mainnetXpub: ExtPublicKey = zpub6jftahH18ngZyb8qYj6HW5Cc4zVdYRUe1JLwLev7ZBADvchgqZQPiarNpkRaYqG7QKNhAnp1y2m4c6L5Eds3qnsh4VELMUTCJZcqB2MHN6Y</span>
+<span class="hljs-comment">// mainnetXpub: ExtPublicKey = zpub6jftahH18ngZxkHL1mQ3vwdevUJBEcdet9hfxsz8R9nRYgZod9DGSNUt4yxADHyUTnXrTzG2Jd3bUyBaZgk8Y6GuDjJTqpeXbEiCiqZAdPc</span>
 
 println(mainnetXpub)
-<span class="hljs-comment">// zpub6jftahH18ngZyb8qYj6HW5Cc4zVdYRUe1JLwLev7ZBADvchgqZQPiarNpkRaYqG7QKNhAnp1y2m4c6L5Eds3qnsh4VELMUTCJZcqB2MHN6Y</span>
+<span class="hljs-comment">// zpub6jftahH18ngZxkHL1mQ3vwdevUJBEcdet9hfxsz8R9nRYgZod9DGSNUt4yxADHyUTnXrTzG2Jd3bUyBaZgk8Y6GuDjJTqpeXbEiCiqZAdPc</span>
 </code></pre>
 <p>Which gives us something that looks like this</p>
 <p><code>zpub6jftahH18ngZw98KGjRo5XcxeKTQ2eztsvskb1dC9XF5TLimQquTs6Ry7nBBA425D9joXmfgJJCexmJ1u2SELJZJfRi95gcnXadLpZzYb5c</code></p>

docs/next/key-manager/key-manager/index.html

@@ -85,14 +85,14 @@ as a logical distinction for further development in subsequent releases.</p>
 
 <span class="hljs-comment">//get 256 bits of random entropy</span>
 <span class="hljs-keyword">val</span> entropy = <span class="hljs-type">MnemonicCode</span>.getEntropy256Bits
-<span class="hljs-comment">// entropy: scodec.bits.BitVector = BitVector(256 bits, 0xb05bb5b336769b7e19beb20b1725be6a48be0bcf7496c2c889938e0965089a36)</span>
+<span class="hljs-comment">// entropy: scodec.bits.BitVector = BitVector(256 bits, 0x7101e9b39e2d8014ba5e4713c53a5e6e49d4e66c79032b25ec8064199ce22bd4)</span>
 
 <span class="hljs-keyword">val</span> mnemonic = <span class="hljs-type">MnemonicCode</span>.fromEntropy(entropy)
 <span class="hljs-comment">// mnemonic: MnemonicCode = Masked(MnemonicCodeImpl)</span>
 
 <span class="hljs-comment">//you can print that mnemonic seed with this</span>
 println(mnemonic.words)
-<span class="hljs-comment">// Vector(raccoon, tank, holiday, hollow, have, sample, group, stone, arch, rice, hurdle, stand, message, album, differ, name, security, dust, gossip, bright, north, lounge, hand, sure)</span>
+<span class="hljs-comment">// Vector(illegal, aunt, hollow, detail, submit, apart, truly, similar, because, clap, nurse, symptom, outer, industry, rapid, call, clinic, control, cactus, sight, oil, illegal, quantum, lucky)</span>
 </code></pre>
 <p>Now that we have a <code>MnemonicCode</code> that was securely generated, we need to now create <code>KeyManagerParams</code> which tells us how to generate
 generate specific kinds of addresses for wallets.</p>
@@ -107,7 +107,7 @@ generate specific kinds of addresses for wallets.</p>
 <pre><code class="hljs css language-scala"><span class="hljs-comment">//this will create a temp directory with the prefix 'key-manager-example` that will</span>
 <span class="hljs-comment">//have a file in it called "encrypted-bitcoin-s-seed.json"</span>
 <span class="hljs-keyword">val</span> seedPath = <span class="hljs-type">Files</span>.createTempDirectory(<span class="hljs-string">"key-manager-example"</span>).resolve(<span class="hljs-type">WalletStorage</span>.<span class="hljs-type">ENCRYPTED_SEED_FILE_NAME</span>)
-<span class="hljs-comment">// seedPath: Path = /tmp/key-manager-example13891847003058512663/encrypted-bitcoin-s-seed.json</span>
+<span class="hljs-comment">// seedPath: Path = /tmp/key-manager-example16031052174349861383/encrypted-bitcoin-s-seed.json</span>
 
 <span class="hljs-comment">//let's create a native segwit key manager</span>
 <span class="hljs-keyword">val</span> purpose = <span class="hljs-type">HDPurposes</span>.<span class="hljs-type">SegWit</span>
@@ -118,16 +118,16 @@ generate specific kinds of addresses for wallets.</p>
 <span class="hljs-comment">// network: RegTest.type = RegTest</span>
 
 <span class="hljs-keyword">val</span> kmParams = <span class="hljs-type">KeyManagerParams</span>(seedPath, purpose, network)
-<span class="hljs-comment">// kmParams: KeyManagerParams = KeyManagerParams(/tmp/key-manager-example13891847003058512663/encrypted-bitcoin-s-seed.json,m/84',RegTest)</span>
+<span class="hljs-comment">// kmParams: KeyManagerParams = KeyManagerParams(/tmp/key-manager-example16031052174349861383/encrypted-bitcoin-s-seed.json,m/84',RegTest)</span>
 
 <span class="hljs-keyword">val</span> km = <span class="hljs-type">BIP39KeyManager</span>.initializeWithMnemonic(mnemonic, <span class="hljs-type">None</span>, kmParams)
-<span class="hljs-comment">// km: Either[KeyManagerInitializeError, BIP39KeyManager] = Right(BIP39KeyManager(Masked(MnemonicCodeImpl),KeyManagerParams(/tmp/key-manager-example13891847003058512663/encrypted-bitcoin-s-seed.json,m/84',RegTest),None))</span>
+<span class="hljs-comment">// km: Either[KeyManagerInitializeError, BIP39KeyManager] = Right(BIP39KeyManager(Masked(MnemonicCodeImpl),KeyManagerParams(/tmp/key-manager-example16031052174349861383/encrypted-bitcoin-s-seed.json,m/84',RegTest),None))</span>
 
 <span class="hljs-keyword">val</span> rootXPub = km.right.get.getRootXPub
-<span class="hljs-comment">// rootXPub: ExtPublicKey = vpub5SLqN2bLY4WeaQNNDHwnfipbP7uqmwWeLrG4D5La39ehiDSmpvk9ELDpjvbEZCeRmkuUAtRn8PLs4wspMrCzer9Hb8Se1qBFDfNFcmJPW7k</span>
+<span class="hljs-comment">// rootXPub: ExtPublicKey = vpub5SLqN2bLY4WeZZWrgLFZ6bFeEbiPU8ffDhcnqJQau8GuLHJtcWZ1x7rKzA7pDfMnqE4dU5snTydPwpjKgu65M9YVkNWmWBNaWLTdAXuH4pr</span>
 
 println(rootXPub)
-<span class="hljs-comment">// vpub5SLqN2bLY4WeaQNNDHwnfipbP7uqmwWeLrG4D5La39ehiDSmpvk9ELDpjvbEZCeRmkuUAtRn8PLs4wspMrCzer9Hb8Se1qBFDfNFcmJPW7k</span>
+<span class="hljs-comment">// vpub5SLqN2bLY4WeZZWrgLFZ6bFeEbiPU8ffDhcnqJQau8GuLHJtcWZ1x7rKzA7pDfMnqE4dU5snTydPwpjKgu65M9YVkNWmWBNaWLTdAXuH4pr</span>
 </code></pre>
 <p>Which should print something that looks like this</p>
 <p><code>vpub5SLqN2bLY4WeXxMqwJHJFBEwxSscGB2uDUnsTS3edVjZEwTrQDFDNqoR2xLqARQPabGaXsHSTenTRcqm2EnB9MpuC4vSk3LqSgNmGGZtuq7</code></p>
@@ -136,17 +136,17 @@ println(rootXPub)
 again after initializing it once. You can use the same <code>mnemonic</code> for different networks, which you control <code>KeyManagerParams</code>.</p>
 <pre><code class="hljs css language-scala"><span class="hljs-comment">//let's create a nested segwit key manager for mainnet</span>
 <span class="hljs-keyword">val</span> mainnetKmParams = <span class="hljs-type">KeyManagerParams</span>(seedPath, <span class="hljs-type">HDPurposes</span>.<span class="hljs-type">SegWit</span>, <span class="hljs-type">MainNet</span>)
-<span class="hljs-comment">// mainnetKmParams: KeyManagerParams = KeyManagerParams(/tmp/key-manager-example13891847003058512663/encrypted-bitcoin-s-seed.json,m/84',MainNet)</span>
+<span class="hljs-comment">// mainnetKmParams: KeyManagerParams = KeyManagerParams(/tmp/key-manager-example16031052174349861383/encrypted-bitcoin-s-seed.json,m/84',MainNet)</span>
 
 <span class="hljs-comment">//we do not need to all `initializeWithMnemonic()` again as we have saved the seed to dis</span>
 <span class="hljs-keyword">val</span> mainnetKeyManager = <span class="hljs-type">BIP39KeyManager</span>(mnemonic, mainnetKmParams, <span class="hljs-type">None</span>)
-<span class="hljs-comment">// mainnetKeyManager: BIP39KeyManager = BIP39KeyManager(Masked(MnemonicCodeImpl),KeyManagerParams(/tmp/key-manager-example13891847003058512663/encrypted-bitcoin-s-seed.json,m/84',MainNet),None)</span>
+<span class="hljs-comment">// mainnetKeyManager: BIP39KeyManager = BIP39KeyManager(Masked(MnemonicCodeImpl),KeyManagerParams(/tmp/key-manager-example16031052174349861383/encrypted-bitcoin-s-seed.json,m/84',MainNet),None)</span>
 
 <span class="hljs-keyword">val</span> mainnetXpub = mainnetKeyManager.getRootXPub
-<span class="hljs-comment">// mainnetXpub: ExtPublicKey = zpub6jftahH18ngZyb8qYj6HW5Cc4zVdYRUe1JLwLev7ZBADvchgqZQPiarNpkRaYqG7QKNhAnp1y2m4c6L5Eds3qnsh4VELMUTCJZcqB2MHN6Y</span>
+<span class="hljs-comment">// mainnetXpub: ExtPublicKey = zpub6jftahH18ngZxkHL1mQ3vwdevUJBEcdet9hfxsz8R9nRYgZod9DGSNUt4yxADHyUTnXrTzG2Jd3bUyBaZgk8Y6GuDjJTqpeXbEiCiqZAdPc</span>
 
 println(mainnetXpub)
-<span class="hljs-comment">// zpub6jftahH18ngZyb8qYj6HW5Cc4zVdYRUe1JLwLev7ZBADvchgqZQPiarNpkRaYqG7QKNhAnp1y2m4c6L5Eds3qnsh4VELMUTCJZcqB2MHN6Y</span>
+<span class="hljs-comment">// zpub6jftahH18ngZxkHL1mQ3vwdevUJBEcdet9hfxsz8R9nRYgZod9DGSNUt4yxADHyUTnXrTzG2Jd3bUyBaZgk8Y6GuDjJTqpeXbEiCiqZAdPc</span>
 </code></pre>
 <p>Which gives us something that looks like this</p>
 <p><code>zpub6jftahH18ngZw98KGjRo5XcxeKTQ2eztsvskb1dC9XF5TLimQquTs6Ry7nBBA425D9joXmfgJJCexmJ1u2SELJZJfRi95gcnXadLpZzYb5c</code></p>

docs/next/secp256k1/secp256k1.html

@@ -114,12 +114,12 @@ println(<span class="hljs-string">s"Verified with NativeSecp256k1 again=<span cl
 <pre><code class="hljs css language-scala"><span class="hljs-keyword">val</span> privKey = <span class="hljs-type">ECPrivateKey</span>.freshPrivateKey
 <span class="hljs-comment">// privKey: ECPrivateKey = Masked(ECPrivateKeyImpl)</span>
 <span class="hljs-keyword">val</span> publicKey = privKey.publicKeyWithBouncyCastle
-<span class="hljs-comment">// publicKey: ECPublicKey = ECPublicKey(020705acab2e22bf20b5159bc3352d9f088c4ed735b10832abd9fd6f4d36dcf9e5)</span>
+<span class="hljs-comment">// publicKey: ECPublicKey = ECPublicKey(022c5248c64c9d52c4ecb8be1724ec7f460f0147b7d31e454fb624dcf978cea129)</span>
 <span class="hljs-keyword">val</span> dataToSign = <span class="hljs-type">DoubleSha256Digest</span>.empty
 <span class="hljs-comment">// dataToSign: DoubleSha256Digest = DoubleSha256Digest(0000000000000000000000000000000000000000000000000000000000000000)</span>
 
 <span class="hljs-keyword">val</span> signature = privKey.signWithBouncyCastle(dataToSign.bytes)
-<span class="hljs-comment">// signature: ECDigitalSignature = ECDigitalSignature(3045022100e29ec873bf03f27bdc7a5df2a51ec58e9bd5fc9de7e0578fcf115c0d17fabeb602207fd06106a491474dec65dc7131a2a04bdcad534312405af3553212068cee55a4)</span>
+<span class="hljs-comment">// signature: ECDigitalSignature = ECDigitalSignature(304402203771357b23e876547fda7586dc4c9b5c74c1ae883e8e1671437c6bd5f9e317020220114743779cfe1551cf40c35784e7b154bf9b3bcf1d5ae37e0d99bc0d1a9c3264)</span>
 
 <span class="hljs-keyword">val</span> verified = publicKey.verifyWithBouncyCastle(dataToSign.bytes, signature)
 <span class="hljs-comment">// verified: Boolean = true</span>

docs/next/secp256k1/secp256k1/index.html

@@ -114,12 +114,12 @@ println(<span class="hljs-string">s"Verified with NativeSecp256k1 again=<span cl
 <pre><code class="hljs css language-scala"><span class="hljs-keyword">val</span> privKey = <span class="hljs-type">ECPrivateKey</span>.freshPrivateKey
 <span class="hljs-comment">// privKey: ECPrivateKey = Masked(ECPrivateKeyImpl)</span>
 <span class="hljs-keyword">val</span> publicKey = privKey.publicKeyWithBouncyCastle
-<span class="hljs-comment">// publicKey: ECPublicKey = ECPublicKey(020705acab2e22bf20b5159bc3352d9f088c4ed735b10832abd9fd6f4d36dcf9e5)</span>
+<span class="hljs-comment">// publicKey: ECPublicKey = ECPublicKey(022c5248c64c9d52c4ecb8be1724ec7f460f0147b7d31e454fb624dcf978cea129)</span>
 <span class="hljs-keyword">val</span> dataToSign = <span class="hljs-type">DoubleSha256Digest</span>.empty
 <span class="hljs-comment">// dataToSign: DoubleSha256Digest = DoubleSha256Digest(0000000000000000000000000000000000000000000000000000000000000000)</span>
 
 <span class="hljs-keyword">val</span> signature = privKey.signWithBouncyCastle(dataToSign.bytes)
-<span class="hljs-comment">// signature: ECDigitalSignature = ECDigitalSignature(3045022100e29ec873bf03f27bdc7a5df2a51ec58e9bd5fc9de7e0578fcf115c0d17fabeb602207fd06106a491474dec65dc7131a2a04bdcad534312405af3553212068cee55a4)</span>
+<span class="hljs-comment">// signature: ECDigitalSignature = ECDigitalSignature(304402203771357b23e876547fda7586dc4c9b5c74c1ae883e8e1671437c6bd5f9e317020220114743779cfe1551cf40c35784e7b154bf9b3bcf1d5ae37e0d99bc0d1a9c3264)</span>
 
 <span class="hljs-keyword">val</span> verified = publicKey.verifyWithBouncyCastle(dataToSign.bytes, signature)
 <span class="hljs-comment">// verified: Boolean = true</span>