Jarbij
Open Trade
High-Frequency Trader
3.7 Years
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Andy666
$BTC
{spot}(BTCUSDT)
ๅคงๅฎถๆฏไธๆฏๆๅฟตๆ็USDT๐งง๏ผๅคง็่ฆๆฅไบๅ ณๆณจโ่ฏ่ฎบ่ฝฌๅ
{spot}(BTCUSDT)
ๅคงๅฎถๆฏไธๆฏๆๅฟตๆ็USDT๐งง๏ผๅคง็่ฆๆฅไบๅ ณๆณจโ่ฏ่ฎบ่ฝฌๅ
ๆญฃ็กฎ็ไบคๆไปๆฅ้ฝไธๆฏๅคฉๅคฉ่ต้บป
้ฆๅธญๆ็ๆ
--
ๅคๅๆญข็ไบ๏ผๅจๆซไฝๆตๅจ่กๆ
ๆ็ๅผๅ้ข็ๅคงๅฎถ้ฝ็ฅ้๏ผๅบๆฌไธ3ๅฐ5ๅคฉๆๅผไธๅ๏ผๅผไบไธๅๆฟไธช3ๅฐ5ๅคฉ๐ๆๅฐฑไธๅญฆ็ฅๆฃๅไธป้ฃไบ๏ผๅคฉๅคฉๅผๅๅๆ็ปญ่ดน็ๅฅ่ทฏไบ
้ฑๆๅๆฌข๏ผๆง่่ฏๅฟ็้ฑ๏ผๆไธๅๆฌข
่ฟๆๅฆๆๆๅฒ้ญ่๏ผๆ่ฆๆฏๅฒ้ญ่ๆๅบ่ฏฅไธๅคฉๅฅฝๅ ไธชๅ๏ผๆปๆไธๅๆญข็็ๅบๆฅ่ต้บปไบๆๅนฟๅ๏ผๅฏนไธ่ตทๅฝไบ3ๅนดๅไธป๏ผๆฒกๆไธๅคฉ่ฟไนๅนฒ่ฟ๐คทโโ๏ธ
ๆ็ๅผๅ้ข็ๅคงๅฎถ้ฝ็ฅ้๏ผๅบๆฌไธ3ๅฐ5ๅคฉๆๅผไธๅ๏ผๅผไบไธๅๆฟไธช3ๅฐ5ๅคฉ๐ๆๅฐฑไธๅญฆ็ฅๆฃๅไธป้ฃไบ๏ผๅคฉๅคฉๅผๅๅๆ็ปญ่ดน็ๅฅ่ทฏไบ
้ฑๆๅๆฌข๏ผๆง่่ฏๅฟ็้ฑ๏ผๆไธๅๆฌข
่ฟๆๅฆๆๆๅฒ้ญ่๏ผๆ่ฆๆฏๅฒ้ญ่ๆๅบ่ฏฅไธๅคฉๅฅฝๅ ไธชๅ๏ผๆปๆไธๅๆญข็็ๅบๆฅ่ต้บปไบๆๅนฟๅ๏ผๅฏนไธ่ตทๅฝไบ3ๅนดๅไธป๏ผๆฒกๆไธๅคฉ่ฟไนๅนฒ่ฟ๐คทโโ๏ธ
In this campaign,I am getting reward or noT,,plz coment..โค๏ธโค๏ธ
Happy NeW year 2026____Start with a big blow๐ฏ๏ธ๐ฏ๏ธ
#binancetradingchlange
Trading Marks
0 trades
BNB/USD1
great
As we conclude 2025, the #2025withBinance campaign celebrates a landmark year where the global crypto community reached over 300 million users. Throughout the year, Binance facilitated a staggering $64 trillion in cumulative trading volume, proving that liquidity never sleeps. The personalized "Year in Review" reports allowed users to relive their unique milestones, from their first venture into the Web3 Walletโwhich saw $546.7 billion in transactionsโto mastering Binance Earn, where 14.9 million participants collected over $1.2 billion in rewards. With the GENIUS Act providing regulatory clarity and stablecoins surpassing $300 billion, 2025 solidified cryptoโs role in the mainstream financial landscape. This journey reflects our collective resilience, turning raw trading data into a shared story of growth, innovation, and a decentralized future.
2025 Binance Community Milestones
Feature2025 AchievementImpactBinance Pay1.36 billion transactions$121 billion spent globallyWeb3 Wallet13.2 million active users$546.7 billion in volumeBinance Earn14.9 million users$1.2 billion in rewards collectedEducation3.2 million usersUtilized new Binance AI summaries
Would you like me to help you find the specific link to your personalized 2025 report or explain how to participate in the 5,000 USDC Binance Square giveaway?
2025 Binance Community Milestones
Feature2025 AchievementImpactBinance Pay1.36 billion transactions$121 billion spent globallyWeb3 Wallet13.2 million active users$546.7 billion in volumeBinance Earn14.9 million users$1.2 billion in rewards collectedEducation3.2 million usersUtilized new Binance AI summaries
Would you like me to help you find the specific link to your personalized 2025 report or explain how to participate in the 5,000 USDC Binance Square giveaway?
yes sirโค๏ธโค๏ธ
As we conclude 2025, the #2025withBinance campaign celebrates a landmark year where the global crypto community reached over 300 million users. Throughout the year, Binance facilitated a staggering $64 trillion in cumulative trading volume, proving that liquidity never sleeps. The personalized "Year in Review" reports allowed users to relive their unique milestones, from their first venture into the Web3 Walletโwhich saw $546.7 billion in transactionsโto mastering Binance Earn, where 14.9 million participants collected over $1.2 billion in rewards. With the GENIUS Act providing regulatory clarity and stablecoins surpassing $300 billion, 2025 solidified cryptoโs role in the mainstream financial landscape. This journey reflects our collective resilience, turning raw trading data into a shared story of growth, innovation, and a decentralized future.
2025 Binance Community Milestones
Feature2025 AchievementImpactBinance Pay1.36 billion transactions$121 billion spent globallyWeb3 Wallet13.2 million active users$546.7 billion in volumeBinance Earn14.9 million users$1.2 billion in rewards collectedEducation3.2 million usersUtilized new Binance AI summaries
Would you like me to help you find the specific link to your personalized 2025 report or explain how to participate in the 5,000 USDC Binance Square giveaway?
2025 Binance Community Milestones
Feature2025 AchievementImpactBinance Pay1.36 billion transactions$121 billion spent globallyWeb3 Wallet13.2 million active users$546.7 billion in volumeBinance Earn14.9 million users$1.2 billion in rewards collectedEducation3.2 million usersUtilized new Binance AI summaries
Would you like me to help you find the specific link to your personalized 2025 report or explain how to participate in the 5,000 USDC Binance Square giveaway?
superโค๏ธโค๏ธ
#2025withBinance
As we wrap up 2025, the #2025withBinance campaign has emerged as a powerful celebration of the global crypto communityโs resilience and growth. This year marked a significant turning point, with Binance reaching over 250 million users and driving a staggering $64 trillion in cumulative trading volume. Through personalized "Year in Review" reports, users are reliving their unique milestones, from their first Web3 venture to mastering the Binance Earn ecosystem, which saw nearly 15 million participants. With the introduction of the GENIUS Act providing regulatory clarity and stablecoins surpassing $300 billion, 2025 has solidified crypto's role in the mainstream financial landscape. As we look toward 2026, the focus remains on building a transparent, user-centric future together.
2025 Binance Ecosystem Highlights
Feature2025 AchievementBinance Pay1.36 billion transactions completedWeb3 Wallet$546.7 billion in total transaction volumeCommunityOver 26 million users using crypto for daily payments
Would you like me to help you find your personalized 2025 Binance summary or explain how to join the latest rewards campaign?
Binance 2025 Year in Review
This video provides insights into the digital marketing and social trends that shaped campaigns like #2025withBinance throughout the year.
As we wrap up 2025, the #2025withBinance campaign has emerged as a powerful celebration of the global crypto communityโs resilience and growth. This year marked a significant turning point, with Binance reaching over 250 million users and driving a staggering $64 trillion in cumulative trading volume. Through personalized "Year in Review" reports, users are reliving their unique milestones, from their first Web3 venture to mastering the Binance Earn ecosystem, which saw nearly 15 million participants. With the introduction of the GENIUS Act providing regulatory clarity and stablecoins surpassing $300 billion, 2025 has solidified crypto's role in the mainstream financial landscape. As we look toward 2026, the focus remains on building a transparent, user-centric future together.
2025 Binance Ecosystem Highlights
Feature2025 AchievementBinance Pay1.36 billion transactions completedWeb3 Wallet$546.7 billion in total transaction volumeCommunityOver 26 million users using crypto for daily payments
Would you like me to help you find your personalized 2025 Binance summary or explain how to join the latest rewards campaign?
Binance 2025 Year in Review
This video provides insights into the digital marketing and social trends that shaped campaigns like #2025withBinance throughout the year.
#2025withBinance
In 2025, Binance continues to solidify its position as a leading global cryptocurrency exchange, offering innovative solutions for traders and investors alike. With the rapid adoption of blockchain technology, Binance has expanded its services beyond simple trading, integrating decentralized finance (DeFi) products, NFTs, and staking opportunities. The platform emphasizes security, transparency, and user-friendly interfaces, making crypto accessible to newcomers and professionals. Binanceโs global reach allows seamless transactions across borders, while its educational initiatives help users understand the evolving crypto landscape. As digital assets gain mainstream acceptance, Binance remains at the forefront, driving adoption, innovation, and financial empowerment, making 2025 a landmark year in the growth of the cryptocurrency ecosystem.$BNB
In 2025, Binance continues to solidify its position as a leading global cryptocurrency exchange, offering innovative solutions for traders and investors alike. With the rapid adoption of blockchain technology, Binance has expanded its services beyond simple trading, integrating decentralized finance (DeFi) products, NFTs, and staking opportunities. The platform emphasizes security, transparency, and user-friendly interfaces, making crypto accessible to newcomers and professionals. Binanceโs global reach allows seamless transactions across borders, while its educational initiatives help users understand the evolving crypto landscape. As digital assets gain mainstream acceptance, Binance remains at the forefront, driving adoption, innovation, and financial empowerment, making 2025 a landmark year in the growth of the cryptocurrency ecosystem.$BNB
Trading Marks
2 trades
BNB/USD1
ๅ ๆฒน
ๆ็ ็ๅ
--
็ปๅ
ๅผไปฌๅไธช็บขๅ
ๅง๏ผ่ฟๆณข่ตท้ฃไบ
ๆๅฅๅธฆๅ่ดฆๆทๅ จ้จ่ตฐๅฎไบ๏ผ่ฟๆ5000ไธช็ฐ่ดงๆฒกๆ่ตฐ๏ผๅฐฑ่ฟๆ ทๅง๏ผๅ้ฃๆฐธ่ต๏ผ
่ฟๆณข่ดฆๆทๆปไฝ่ฟๅฏไปฅ1000Uๆๅฐ็ฎๅ38000ๅ๏ผๅ ๆฒนๅ ๅผไปฌ๏ผ
ๆๅฅๅธฆๅ่ดฆๆทๅ จ้จ่ตฐๅฎไบ๏ผ่ฟๆ5000ไธช็ฐ่ดงๆฒกๆ่ตฐ๏ผๅฐฑ่ฟๆ ทๅง๏ผๅ้ฃๆฐธ่ต๏ผ
่ฟๆณข่ดฆๆทๆปไฝ่ฟๅฏไปฅ1000Uๆๅฐ็ฎๅ38000ๅ๏ผๅ ๆฒนๅ ๅผไปฌ๏ผ
4
#Max ๆ่ฒๆ
ๅ็คพๅบๅ
ฑ่ฏๅจๅธๅฎๅนฟๅบ็้ฆ็งๆฐๆฎใ่ฐข่ฐขๆๆๅไธ็ดๆญ็ๆๅไปฌใ$GIGGLE
{spot}(GIGGLEUSDT)
{spot}(GIGGLEUSDT)
ANOTHER LOOS๐ข
BIG LOSS TODY๐
#BNBATH and $BNB Until now, every Bitcoin Improvement Proposal (BIP) that needed cryptographic primitives had to reinvent the wheel. Each one came bundled with its own custom Python implementation of the secp256k1 elliptic curve and related algorithms, each subtly different from one another. These inconsistencies introduced quiet liabilities and made reviewing BIPs unnecessarily complicated. This problem was recently highlighted inย Bitcoin Optech Newsletter #348, and itโs something at least a handful of developers in the Bitcoin development community have long felt: there should be a unified, reusable standard for cryptographic BIP reference secp256k1 code.
Last week, Jonas Nick and Tim Ruffing of Blockstream research and Sebastian Falbesoner made big progress towards this. As part of their existingย ChillDKG proposal, the team releasedย secp256k1lab. A new,ย intentionally INSECUREย Python library for prototyping, experimenting, and BIP specifications. Itโs not for production use (because itโs not constant-time and therefore vulnerable to side-channel attacks), but it fills a critical gap: it offers a clean, consistent reference for secp256k1 functionality, including BIP-340-style Schnorr signatures, ECDH, and low-level field/group arithmetic. The goal is simple: make it easier and safer to write future BIPs by avoiding redundant, one-off implementations. For BIP authors, this means: less custom code, fewer spec issues, and a clearer path from prototype to proposal.
Last week, Jonas Nick and Tim Ruffing of Blockstream research and Sebastian Falbesoner made big progress towards this. As part of their existingย ChillDKG proposal, the team releasedย secp256k1lab. A new,ย intentionally INSECUREย Python library for prototyping, experimenting, and BIP specifications. Itโs not for production use (because itโs not constant-time and therefore vulnerable to side-channel attacks), but it fills a critical gap: it offers a clean, consistent reference for secp256k1 functionality, including BIP-340-style Schnorr signatures, ECDH, and low-level field/group arithmetic. The goal is simple: make it easier and safer to write future BIPs by avoiding redundant, one-off implementations. For BIP authors, this means: less custom code, fewer spec issues, and a clearer path from prototype to proposal.
#Plume $PLUME Until now, every Bitcoin Improvement Proposal (BIP) that needed cryptographic primitives had to reinvent the wheel. Each one came bundled with its own custom Python implementation of the secp256k1 elliptic curve and related algorithms, each subtly different from one another. These inconsistencies introduced quiet liabilities and made reviewing BIPs unnecessarily complicated. This problem was recently highlighted inย Bitcoin Optech Newsletter #348, and itโs something at least a handful of developers in the Bitcoin development community have long felt: there should be a unified, reusable standard for cryptographic BIP reference secp256k1 code.
Last week, Jonas Nick and Tim Ruffing of Blockstream research and Sebastian Falbesoner made big progress towards this. As part of their existingย ChillDKG proposal, the team releasedย secp256k1lab. A new,ย intentionally INSECUREย Python library for prototyping, experimenting, and BIP specifications. Itโs not for production use (because itโs not constant-time and therefore vulnerable to side-channel attacks), but it fills a critical gap: it offers a clean, consistent reference for secp256k1 functionality, including BIP-340-style Schnorr signatures, ECDH, and low-level field/group arithmetic. The goal is simple: make it easier and safer to write future BIPs by avoiding redundant, one-off implementations. For BIP authors, this means: less custom code, fewer spec issues, and a clearer path from prototype to proposal.
Last week, Jonas Nick and Tim Ruffing of Blockstream research and Sebastian Falbesoner made big progress towards this. As part of their existingย ChillDKG proposal, the team releasedย secp256k1lab. A new,ย intentionally INSECUREย Python library for prototyping, experimenting, and BIP specifications. Itโs not for production use (because itโs not constant-time and therefore vulnerable to side-channel attacks), but it fills a critical gap: it offers a clean, consistent reference for secp256k1 functionality, including BIP-340-style Schnorr signatures, ECDH, and low-level field/group arithmetic. The goal is simple: make it easier and safer to write future BIPs by avoiding redundant, one-off implementations. For BIP authors, this means: less custom code, fewer spec issues, and a clearer path from prototype to proposal.
#Dolomite $DOLO
Until now, every Bitcoin Improvement Proposal (BIP) that needed cryptographic primitives had to reinvent the wheel. Each one came bundled with its own custom Python implementation of the secp256k1 elliptic curve and related algorithms, each subtly different from one another. These inconsistencies introduced quiet liabilities and made reviewing BIPs unnecessarily complicated. This problem was recently highlighted inย Bitcoin Optech Newsletter #348, and itโs something at least a handful of developers in the Bitcoin development community have long felt: there should be a unified, reusable standard for cryptographic BIP reference secp256k1 code.
Last week, Jonas Nick and Tim Ruffing of Blockstream research and Sebastian Falbesoner made big progress towards this. As part of their existingย ChillDKG proposal, the team releasedย secp256k1lab. A new,ย intentionally INSECUREย Python library for prototyping, experimenting, and BIP specifications. Itโs not for production use (because itโs not constant-time and therefore vulnerable to side-channel attacks), but it fills a critical gap: it offers a clean, consistent reference for secp256k1 functionality, including BIP-340-style Schnorr signatures, ECDH, and low-level field/group arithmetic. The goal is simple: make it easier and safer to write future BIPs by avoiding redundant, one-off implementations. For BIP authors, this means: less custom code, fewer spec issues, and a clearer path from prototype to proposal.
Until now, every Bitcoin Improvement Proposal (BIP) that needed cryptographic primitives had to reinvent the wheel. Each one came bundled with its own custom Python implementation of the secp256k1 elliptic curve and related algorithms, each subtly different from one another. These inconsistencies introduced quiet liabilities and made reviewing BIPs unnecessarily complicated. This problem was recently highlighted inย Bitcoin Optech Newsletter #348, and itโs something at least a handful of developers in the Bitcoin development community have long felt: there should be a unified, reusable standard for cryptographic BIP reference secp256k1 code.
Last week, Jonas Nick and Tim Ruffing of Blockstream research and Sebastian Falbesoner made big progress towards this. As part of their existingย ChillDKG proposal, the team releasedย secp256k1lab. A new,ย intentionally INSECUREย Python library for prototyping, experimenting, and BIP specifications. Itโs not for production use (because itโs not constant-time and therefore vulnerable to side-channel attacks), but it fills a critical gap: it offers a clean, consistent reference for secp256k1 functionality, including BIP-340-style Schnorr signatures, ECDH, and low-level field/group arithmetic. The goal is simple: make it easier and safer to write future BIPs by avoiding redundant, one-off implementations. For BIP authors, this means: less custom code, fewer spec issues, and a clearer path from prototype to proposal.
ย #BounceBitPrime $BB Until now, every Bitcoin Improvement Proposal (BIP) that needed cryptographic primitives had to reinvent the wheel. Each one came bundled with its own custom Python implementation of the secp256k1 elliptic curve and related algorithms, each subtly different from one another. These inconsistencies introduced quiet liabilities and made reviewing BIPs unnecessarily complicated. This problem was recently highlighted inย Bitcoin Optech Newsletter #348, and itโs something at least a handful of developers in the Bitcoin development community have long felt: there should be a unified, reusable standard for cryptographic BIP reference secp256k1 code.
Last week, Jonas Nick and Tim Ruffing of Blockstream research and Sebastian Falbesoner made big progress towards this. As part of their existingย ChillDKG proposal, the team releasedย secp256k1lab. A new,ย intentionally INSECUREย Python library for prototyping, experimenting, and BIP specifications. Itโs not for production use (because itโs not constant-time and therefore vulnerable to side-channel attacks), but it fills a critical gap: it offers a clean, consistent reference for secp256k1 functionality, including BIP-340-style Schnorr signatures, ECDH, and low-level field/group arithmetic. The goal is simple: make it easier and safer to write future BIPs by avoiding redundant, one-off implementations. For BIP authors, this means: less custom code, fewer spec issues, and a clearer path from prototype to proposal.
Last week, Jonas Nick and Tim Ruffing of Blockstream research and Sebastian Falbesoner made big progress towards this. As part of their existingย ChillDKG proposal, the team releasedย secp256k1lab. A new,ย intentionally INSECUREย Python library for prototyping, experimenting, and BIP specifications. Itโs not for production use (because itโs not constant-time and therefore vulnerable to side-channel attacks), but it fills a critical gap: it offers a clean, consistent reference for secp256k1 functionality, including BIP-340-style Schnorr signatures, ECDH, and low-level field/group arithmetic. The goal is simple: make it easier and safer to write future BIPs by avoiding redundant, one-off implementations. For BIP authors, this means: less custom code, fewer spec issues, and a clearer path from prototype to proposal.
#walletconnect $WCT Until now, every Bitcoin Improvement Proposal (BIP) that needed cryptographic primitives had to reinvent the wheel. Each one came bundled with its own custom Python implementation of the secp256k1 elliptic curve and related algorithms, each subtly different from one another. These inconsistencies introduced quiet liabilities and made reviewing BIPs unnecessarily complicated. This problem was recently highlighted inย Bitcoin Optech Newsletter #348, and itโs something at least a handful of developers in the Bitcoin development community have long felt: there should be a unified, reusable standard for cryptographic BIP reference secp256k1 code.
Last week, Jonas Nick and Tim Ruffing of Blockstream research and Sebastian Falbesoner made big progress towards this. As part of their existingย ChillDKG proposal, the team releasedย secp256k1lab. A new,ย intentionally INSECUREย Python library for prototyping, experimenting, and BIP specifications. Itโs not for production use (because itโs not constant-time and therefore vulnerable to side-channel attacks), but it fills a critical gap: it offers a clean, consistent reference for secp256k1 functionality, including BIP-340-style Schnorr signatures, ECDH, and low-level field/group arithmetic. The goal is simple: make it easier and safer to write future BIPs by avoiding redundant, one-off implementations. For BIP authors, this means: less custom code, fewer spec issues, and a clearer path from prototype to proposal.
Last week, Jonas Nick and Tim Ruffing of Blockstream research and Sebastian Falbesoner made big progress towards this. As part of their existingย ChillDKG proposal, the team releasedย secp256k1lab. A new,ย intentionally INSECUREย Python library for prototyping, experimenting, and BIP specifications. Itโs not for production use (because itโs not constant-time and therefore vulnerable to side-channel attacks), but it fills a critical gap: it offers a clean, consistent reference for secp256k1 functionality, including BIP-340-style Schnorr signatures, ECDH, and low-level field/group arithmetic. The goal is simple: make it easier and safer to write future BIPs by avoiding redundant, one-off implementations. For BIP authors, this means: less custom code, fewer spec issues, and a clearer path from prototype to proposal.
ย ย #Mitosis $MITO Until now, every Bitcoin Improvement Proposal (BIP) that needed cryptographic primitives had to reinvent the wheel. Each one came bundled with its own custom Python implementation of the secp256k1 elliptic curve and related algorithms, each subtly different from one another. These inconsistencies introduced quiet liabilities and made reviewing BIPs unnecessarily complicated. This problem was recently highlighted inย Bitcoin Optech Newsletter #348, and itโs something at least a handful of developers in the Bitcoin development community have long felt: there should be a unified, reusable standard for cryptographic BIP reference secp256k1 code.
Last week, Jonas Nick and Tim Ruffing of Blockstream research and Sebastian Falbesoner made big progress towards this. As part of their existingย ChillDKG proposal, the team releasedย secp256k1lab. A new,ย intentionally INSECUREย Python library for prototyping, experimenting, and BIP specifications. Itโs not for production use (because itโs not constant-time and therefore vulnerable to side-channel attacks), but it fills a critical gap: it offers a clean, consistent reference for secp256k1 functionality, including BIP-340-style Schnorr signatures, ECDH, and low-level field/group arithmetic. The goal is simple: make it easier and safer to write future BIPs by avoiding redundant, one-off implementations. For BIP authors, this means: less custom code, fewer spec issues, and a clearer path from prototype to proposal.
Last week, Jonas Nick and Tim Ruffing of Blockstream research and Sebastian Falbesoner made big progress towards this. As part of their existingย ChillDKG proposal, the team releasedย secp256k1lab. A new,ย intentionally INSECUREย Python library for prototyping, experimenting, and BIP specifications. Itโs not for production use (because itโs not constant-time and therefore vulnerable to side-channel attacks), but it fills a critical gap: it offers a clean, consistent reference for secp256k1 functionality, including BIP-340-style Schnorr signatures, ECDH, and low-level field/group arithmetic. The goal is simple: make it easier and safer to write future BIPs by avoiding redundant, one-off implementations. For BIP authors, this means: less custom code, fewer spec issues, and a clearer path from prototype to proposal.
ย #Somnia and $SOMI Until now, every Bitcoin Improvement Proposal (BIP) that needed cryptographic primitives had to reinvent the wheel. Each one came bundled with its own custom Python implementation of the secp256k1 elliptic curve and related algorithms, each subtly different from one another. These inconsistencies introduced quiet liabilities and made reviewing BIPs unnecessarily complicated. This problem was recently highlighted inย Bitcoin Optech Newsletter #348, and itโs something at least a handful of developers in the Bitcoin development community have long felt: there should be a unified, reusable standard for cryptographic BIP reference secp256k1 code.
Last week, Jonas Nick and Tim Ruffing of Blockstream research and Sebastian Falbesoner made big progress towards this. As part of their existingย ChillDKG proposal, the team releasedย secp256k1lab. A new,ย intentionally INSECUREย Python library for prototyping, experimenting, and BIP specifications. Itโs not for production use (because itโs not constant-time and therefore vulnerable to side-channel attacks), but it fills a critical gap: it offers a clean, consistent reference for secp256k1 functionality, including BIP-340-style Schnorr signatures, ECDH, and low-level field/group arithmetic. The goal is simple: make it easier and safer to write future BIPs by avoiding redundant, one-off implementations. For BIP authors, this means: less custom code, fewer spec issues, and a clearer path from prototype to proposal.
Last week, Jonas Nick and Tim Ruffing of Blockstream research and Sebastian Falbesoner made big progress towards this. As part of their existingย ChillDKG proposal, the team releasedย secp256k1lab. A new,ย intentionally INSECUREย Python library for prototyping, experimenting, and BIP specifications. Itโs not for production use (because itโs not constant-time and therefore vulnerable to side-channel attacks), but it fills a critical gap: it offers a clean, consistent reference for secp256k1 functionality, including BIP-340-style Schnorr signatures, ECDH, and low-level field/group arithmetic. The goal is simple: make it easier and safer to write future BIPs by avoiding redundant, one-off implementations. For BIP authors, this means: less custom code, fewer spec issues, and a clearer path from prototype to proposal.
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