Reasoning and actions synergize. The ReAct paper interleaves reasoning traces and task-specific actions to achieve a synergy between the two.

A reasoning trace is a record or a description of the mental steps or thought process used to arrive at a particular conclusion or solution. It is a detailed account of how someone reasons through a problem or question, including the assumptions made, the evidence considered, the inferences drawn, and the logical steps taken to reach a conclusion. By examining the reasoning trace, one can identify potential biases, errors in reasoning, or gaps in logic that may have influenced the person’s decision-making process.

A task-specific action is an action that can help a reasoning task. This depends on the task at hand. Some examples

1. In a mathematical problem-solving task, a task-specific action might be to break down a complex problem into smaller, more manageable parts.
2. In a critical thinking task, a task-specific action might be to evaluate the evidence provided and identify any biases or assumptions that might be influencing the conclusion.
3. In a decision-making task, a task-specific action might be to weigh the pros and cons of each available option and consider how each option aligns with one’s goals or values.
4. In a scientific inquiry task, a task-specific action might be to design a controlled experiment to test a hypothesis and systematically collect and analyze data to draw conclusions.
5. In a legal reasoning task, a task-specific action might be to interpret and analyze case law and statutes, apply legal principles to the facts of a case, and argue persuasively for a particular legal outcome.

Task-specific actions can vary widely depending on the task and the context, but they generally involve applying relevant knowledge, skills, and strategies to solve a particular problem or achieve a specific goal.

From the ReAct ( paper – “The best approach overall is a combination of ReAct and CoT that allows for the use of both internal knowledge and externally obtained information during reasoning. On ALFWorld and WebShop, two or even one-shot ReAct prompting is able to outperform imitation or reinforcement learning methods trained with 103 ∼ 105 task instances, with an absolute improvement of 34% and 10% in success rates respectively. We also demonstrate the importance of sparse, versatile reasoning in decision making by showing consistent advantages over controlled baselines with actions only. Besides general applicability and performance boost, the combination of reasoning and acting also contributes to model interpretability, trustworthiness, and diagnosability across all domains, as humans can readily distinguish information from model’s internal knowledge versus external environments, as well as inspect reasoning traces to understand the decision basis of model actions.”

The Self-Ask paper discusses compositional reasoning and narrowing the “compositionality gap”.

Compositional reasoning is the ability to combine smaller pieces of knowledge or information to deduce new knowledge or solve a problem. It involves taking a set of facts or ideas and using them to create a new idea or answer a question that cannot be answered by any single fact alone. This type of reasoning is important in many areas, including natural language understanding, problem solving, and decision-making. Compositional reasoning allows us to use our knowledge in a more flexible and adaptive way, and is essential for many advanced cognitive tasks.

The compositionality gap is a metric used to measure the ability of language models to perform compositional reasoning tasks. It is defined as the ratio of the number of compositional questions for which the model answers the sub-questions correctly but not the overall question, to the total number of compositional questions. In other words, it measures how often models can correctly answer all sub-problems but not generate the overall solution. A high compositionality gap indicates that the model is struggling with compositional reasoning, while a low gap indicates that the model is better at composing multiple facts to answer complex questions.

The paper proposes a solution called “self-ask,” a new method of prompting language models to perform compositional reasoning tasks. With self-ask, the model explicitly asks itself follow-up questions before answering the initial question. By breaking down the reasoning process into smaller steps, the model is better able to combine relevant information from different sources and answer multi-hop questions correctly. Additionally, self-ask allows for plugging in a search engine to answer the follow-up questions, which further improves accuracy. The paper shows that self-ask narrows the compositionality gap by reasoning explicitly instead of implicitly.

What does Apache Iceberg do ?

• manages large slow-changing tabular data and gives a sql interface to the data so that it can be queried efficiently
• breaks files into partitions and stores those files into an object store such as s3. partitions can be filtered based on the partition key(s). the partitioning is “invisible partitioning” meaning it is done by the system for you, without exposing the details to the client.
• separates out metadata management from the data. metadata is not stored in the data files.
• separates table schema away from the data . a change of column name will not affect the data files. see Schema Evolutuon.
• allows accessing data as it existed at a specific point in time. this Time Travel feature is useful for auditing, debugging and reproducing issues that occurred in the past . Time travel is implemented using “snapshot isolation” which allows multiple versions of the same table to exist at the same time. (Copy on Write is used in the implementation)
• provides ACID compliant transactions for data modifications and snapshot isolation for queries, which help ensure consistency and correctness of data
• does all this through a lightweight design with minimal coordination

Figure. iceberg table format is used by multiple engines and is capable of writing to multiple storage types. source.

Ryan Blue’s discussion on the rationale for the design is here and a presentation with performance improvements is at https://conferences.oreilly.com/strata/strata-ny-2018/cdn.oreillystatic.com/en/assets/1/event/278/Introducing%20Iceberg_%20Tables%20designed%20for%20object%20stores%20Presentation.pdf

“By building support for Iceberg, data warehouses can skip the query layer and share data directly. Iceberg was built on the assumption that there is no single query layer. Instead, many different processes all use the same underlying data and coordinate through the table format along with a very lightweight catalog. Iceberg enables direct data access needed by all of these use cases and, uniquely, does it without compromising the SQL behavior of data warehouses.”

The client is a java jar file which can be embedded.

How does iceberg store files in s3 ?

The top level directory contains the table’s metadata files including the schema and partition information. The metadata files are stored in S3 object store using the table name as the s3 prefix.

The data files are stored in a directory structure that reflects the table partitioning. Partition values are encoded in the directory name.

s3://bucket-name/table-name/date=YYYY-MM-DD/region=us-west-1/0001.parquet

s3://bucket-name/table-name/date=YYYY-MM-DD/region=us-west-1/0002.parquet

Why a new table format – https://github.com/Netflix/iceberg

A hands-on look at Iceberg table by dremio is here .

A blog on the Adobe experience with Iceberg is here.

A blog on creating a real-time datawarehouse with Flink and Iceberg – https://www.alibabacloud.com/blog/flink-%20-iceberg-how-to-construct-a-whole-scenario-real-time-data-warehouse_597824

YuniKorn is an alternative scheduler to the default scheduler in kubernetes which benefits complex and mixed workloads. It provides advanced scheduling options like workload queueing and shared quotas. This helps improve the user experience and provides cost savings by providing better resource utilization.

Gang Scheduling refers to a scheduling algorithm for parallel systems that schedules related threads or processes to run simultaneously on different processors. In the distributed computing world, this refers to the mechanism to schedule correlated tasks in an All or Nothing manner.

Bin packing refers to the process of allocation and reallocation of pods to nodes in a way that achieves a high utilization of the nodes. When a node has a low level of utilization, its pods are moved to a node with the highest level of utilization and that has space for the pods available; after which the low utilization node is freed and released.

Yunikorn scheduler talk at ApacheCon’21 – link.

https://yunikorn.apache.org/community/events/#past-conference–meetup-recordings

Pinterest talk on their use of Yunikorn – link.

download_images >> train >> serve

This line sets the sequence of operations for an ML pipeline in Airflow. source

A metaphor to think of Airflow is that of an air-traffic controller that is orchestrating, sequencing, mediating, managing the flow of the flights of airplanes (source). It is an example of the mediator pattern which decouples dependencies in a complex system. The airplanes do not talk directly to each other, they talk to the air-traffic controller.

A functional alternative to Airflow is to use a bunch of cron jobs to schedule bash scripts. Airflow instead defines pipelines as Directed Acyclic Graphs (DAGs) in python code. This critical talk on “Don’t use Apache Airflow” describes it as cron on steroids.

A complete example of an ML pipeline built with airflow that outputs the results to a streamlit app – https://github.com/bhlr/docker-airflow-streamlit

Each operation calls an operator to do the job locally or remotely.

How does it perform an operation remotely on another node ? ssh/remote execution ? docker daemon ? k8s operator ? There can be many different ways – this logic is encapsulated by an Executor.

Local Executors

• Debug Executor
• Local Executor
• Sequential Executor

Remote Executors

• Celery Executor
• CeleryKubernetes Executor
• Dask Executor
• Kubernetes Executor
• LocalKubernetes Executor

A thread on airflow and alternatives- https://news.ycombinator.com/item?id=23349507 .

https://github.com/pditommaso/awesome-pipeline – A number of pipeline tools for ETL

Intro talk on Airflow by Astronomer – https://www.youtube.com/watch?v=GIztRAHc3as ,

and on an ETL use case with Snowflake – https://www.youtube.com/watch?v=3-XGY0bGJ6g

How can one compose these DAGs further and manage cross-DAG depedencies ? An approach is discussed in https://medium.com/quintoandar-tech-blog/effective-cross-dags-dependency-in-apache-airflow-1885dc7ece9f to define an explicit mediator between multiple DAGs.

Smart Contracts are relatively short blocks of code that run on the Ethereum Virtual Machine (EVM), and deal with tokens of value. For example a contract may release funds when certain preconditions such are met, such as time elapsed, or a signed request received. The number of smart contracts and the value of transactions in smart contracts has grown quite a bit in the last few years along with the prices of cryptocurrencies. The code of the Smart Contract is always publicly available as bytecode which can be reverse engineered, and often the source code in solidity language is often publicly available. As a result, bugs in smart contracts have become attractive exploit targets. EVMs are a distributed computing construct that run in parallel on a network of participating nodes, coordinating their actions by a consensus mechanism and protocol that runs between the nodes.

A collection of links on this topic –

https://blog.sigmaprime.io/solidity-security.html

https://rekt.news/superfluid-rekt/ newsletter reporting high level analysis recent attacks.

https://secureum.xyz

https://solidity-by-example.org/variables/ Solidity has 3 types of variables 1. local (inside function), 2. state (inside contract, outside function), 3. global (e.g. block.timestamp, msg.sender – chain level. provides info about the blockchain)

https://solidity-by-example.org/data-locations (storage, memory, calldata)

https://solidity-by-example.org/visibility/ (public, private, internal, external)

https://solidity-by-example.org/function-modifier (onlyOwner to restrict access, validAddress to validate address, noReentrancy to prevent reentrancy) Incorrect reentrancy is a source of bugs.

https://www.saurik.com/optimism.html – instrumenting the blockchain to find gaps (EthDenver talk).

Security of Bridges. Bridges are implemented as smart contracts between two different chains.

https://www.bitdefender.com/blog/hotforsecurity/smart-contract-exploit-costs-nomad-crypto-bridge-200-million/

Sequence diagram of a bridge operation in https://blog.harmony.one/introducing-horizon-an-ethereum-harmony-cross-chain-bridge/

Within the last year, bridges have accounted for a majority of the total funds stolen across all of the crypto ecosystem. Massive bridge hacks have occurred on average every few months, and each losing extremely large amounts of user funds. Some bridge hacks in the last couple of years have included the Axie Infinity Ronin bridge hack, losing users $625 million, the Wormhole bridge hack costing users $300 million, the Harmony bridge hack losing users $100 million, and just this last week the Nomad bridge hack, losing users almost $200 million.

Methods for Detecting attacks

• Code reviews for reentrancy bugs
• Detection of source of a txn as a bad actor
• Using ML for code analysis and bad actor detection

https://github.com/DicksonWu654/ethdenverhack – This submission attempts using ML for detecting reentrancy attacks in Solidity code, by using transfer learning on DistilBERT, to train on good and bad smart contract code examples, and use the trained model to detect bad code on new code samples.

“from transformers import TFDistilBertModel, DistilBertTokenizerFast” # using a hugging face model

These guys had a funny presentation – https://www.youtube.com/watch?v=9oLuxJdrZwo