diff --git a/docs/source/build_with_arch/agent.rst b/docs/source/build_with_arch/agent.rst index 2e41f5fa..ffced78d 100644 --- a/docs/source/build_with_arch/agent.rst +++ b/docs/source/build_with_arch/agent.rst @@ -5,14 +5,14 @@ Agentic Workflow Arch helps you easily personalize your applications by calling application-specific (API) functions via user prompts. This involves any predefined functions or APIs you want to expose to users to perform tasks, -gather information, or manipulate data. This capability is generally referred to as **function calling**, where +gather information, or manipulate data. This capability is generally referred to as :ref:`function calling `, where you have the flexibility to support “agentic” apps tailored to specific use cases - from updating insurance claims to creating ad campaigns - via prompts. Arch analyzes prompts, extracts critical information from prompts, engages in lightweight conversation with the user to gather any missing parameters and makes API calls so that you can focus on writing business logic. -Arch does this via its purpose-built :ref:`Arch-Function ` - the fastest (200ms p90 - 10x faser than GPT-4o) -and cheapest (100x than GPT-40) function-calling LLM that matches performance with frontier models. +Arch does this via its purpose-built `Arch-Function `_ - the fastest (200ms p90 - 10x faser than GPT-4o) +and cheapest (100x than GPT-4o) function calling LLM that matches performance with frontier models. .. image:: includes/agent/function-calling-flow.jpg :width: 100% @@ -31,7 +31,7 @@ Step 1: Define Prompt Targets .. literalinclude:: includes/agent/function-calling-agent.yaml :language: yaml :linenos: - :emphasize-lines: 21-34 + :emphasize-lines: 19-49 :caption: Prompt Target Example Configuration Step 2: Process Request Parameters @@ -66,5 +66,5 @@ Example of Multiple Prompt Targets in YAML: .. literalinclude:: includes/agent/function-calling-agent.yaml :language: yaml :linenos: - :emphasize-lines: 21-34 + :emphasize-lines: 19-49 :caption: Prompt Target Example Configuration diff --git a/docs/source/build_with_arch/includes/agent/function-calling-agent.yaml b/docs/source/build_with_arch/includes/agent/function-calling-agent.yaml index 50264c1b..5e31615b 100644 --- a/docs/source/build_with_arch/includes/agent/function-calling-agent.yaml +++ b/docs/source/build_with_arch/includes/agent/function-calling-agent.yaml @@ -46,7 +46,7 @@ prompt_targets: - name: time_range type: int description: Time range in days for which to gather device statistics. Defaults to 7. - default: "7" + default: 7 # Arch creates a round-robin load balancing between different endpoints, managed via the cluster subsystem. endpoints: diff --git a/docs/source/build_with_arch/rag.rst b/docs/source/build_with_arch/rag.rst index 3e50d603..9961b133 100644 --- a/docs/source/build_with_arch/rag.rst +++ b/docs/source/build_with_arch/rag.rst @@ -9,7 +9,7 @@ Retrieval-Augmented Generation (RAG) applications. Parameter Extraction for RAG ---------------------------- -To build RAG (Retrieval-Augmented Generation) applications, you can configure prompt targets with parameters, +To build RAG (Retrieval Augmented Generation) applications, you can configure prompt targets with parameters, enabling Arch to retrieve critical information in a structured way for processing. This approach improves the retrieval quality and speed of your application. By extracting parameters from the conversation, you can pull the appropriate chunks from a vector database or SQL-like data store to enhance accuracy. With Arch, you can @@ -37,12 +37,12 @@ Once the prompt targets are configured as above, handling those parameters is ----------------------------------------------------------------------------------------------------------------------------------------- Developers struggle to efficiently handle ``follow-up`` or ``clarification`` questions. Specifically, when users ask for changes or additions to previous responses their AI applications often generate entirely new responses instead of adjusting -previous ones.Arch offers **intent** tracking as a feature so that developers can know when the user has shifted away from a +previous ones. Arch offers ``intent tracking`` as a feature so that developers can know when the user has shifted away from a previous intent so that they can dramatically improve retrieval accuracy, lower overall token cost and improve the speed of their responses back to users. Arch uses its built-in lightweight NLI and embedding models to know if the user has steered away from an active intent. -Arch's intent-drift detection mechanism is based on its' :ref:`prompt_targets ` primtive. Arch tries to match an incoming +Arch's intent-drift detection mechanism is based on its :ref:`prompt target ` primtive. Arch tries to match an incoming prompt to one of the prompt_targets configured in the gateway. Once it detects that the user has moved away from an active active intent, Arch adds the ``x-arch-intent-marker`` headers to the request before sending it your application servers. @@ -50,15 +50,15 @@ active intent, Arch adds the ``x-arch-intent-marker`` headers to the request bef :language: python :linenos: :lines: 101-157 - :emphasize-lines: 14-24 + :emphasize-lines: 14-25 :caption: Intent Detection Example .. Note:: Arch is (mostly) stateless so that it can scale in an embarrassingly parrallel fashion. So, while Arch offers - intent-drift detetction, you still have to maintain converational state with intent drift as meta-data. The - following code snippets show how easily you can build and enrich conversational history with Langchain (in python), + intent-drift detetction, you still have to maintain converational state with intent drift as metadata. The + following code snippets show how easily you can build and enrich conversational history with Langchain (in Python), so that you can use the most relevant prompts for your retrieval and for prompting upstream LLMs. diff --git a/docs/source/concepts/llm_provider.rst b/docs/source/concepts/llm_provider.rst index 68b4ba61..498ee875 100644 --- a/docs/source/concepts/llm_provider.rst +++ b/docs/source/concepts/llm_provider.rst @@ -23,7 +23,7 @@ Below is an example of how you can configure ``llm_providers`` with an instance .. Note:: When you start Arch, it creates a listener port for egress traffic based on the presence of ``llm_providers`` configuration section in the ``arch_config.yml`` file. Arch binds itself to a local address such as - ``127.0.0.1:51001/v1``. + ``127.0.0.1:12000``. Arch also offers vendor-agnostic SDKs and libraries to make LLM calls to API-based LLM providers (like OpenAI, Anthropic, Mistral, Cohere, etc.) and supports calls to OSS LLMs that are hosted on your infrastructure. Arch @@ -40,7 +40,7 @@ Example: Using the OpenAI Python SDK from openai import OpenAI # Initialize the Arch client - client = OpenAI(base_url="http://127.0.0.1:51001/v1") + client = OpenAI(base_url="http://127.0.0.12000/") # Define your LLM provider and prompt llm_provider = "openai" diff --git a/docs/source/concepts/prompt_target.rst b/docs/source/concepts/prompt_target.rst index 8e0ac1c9..b489b0c1 100644 --- a/docs/source/concepts/prompt_target.rst +++ b/docs/source/concepts/prompt_target.rst @@ -80,7 +80,7 @@ Here is a full list of parameter attributes that Arch can support: Example Configuration ~~~~~~~~~~~~~~~~~~~~~ -.. code-block:: python +.. code-block:: yaml prompt_targets: - name: get_weather diff --git a/docs/source/concepts/tech_overview/error_target.rst b/docs/source/concepts/tech_overview/error_target.rst index cce92e57..e901ae5e 100644 --- a/docs/source/concepts/tech_overview/error_target.rst +++ b/docs/source/concepts/tech_overview/error_target.rst @@ -16,8 +16,6 @@ Key Concepts - **Error Message**: A clear, human-readable message describing the error. This should provide enough detail to inform users or developers of the root cause or required action. -- **Target Prompt**: The specific prompt or operation where the error occurred. Understanding where the error happened helps with debugging and pinpointing the source of the problem. - - **Parameter-Specific Errors**: Errors that arise due to invalid or missing parameters when invoking a function. These errors are critical for ensuring the correctness of inputs. diff --git a/docs/source/concepts/tech_overview/prompt.rst b/docs/source/concepts/tech_overview/prompt.rst index 5473941c..4cc9e56b 100644 --- a/docs/source/concepts/tech_overview/prompt.rst +++ b/docs/source/concepts/tech_overview/prompt.rst @@ -27,7 +27,7 @@ containing two key-value pairs: Prompt Guard ----------------- -Arch is engineered with :ref:`Arch-Guard `, an industry leading safety layer, powered by a +Arch is engineered with `Arch-Guard `_, an industry leading safety layer, powered by a compact and high-performimg LLM that monitors incoming prompts to detect and reject jailbreak attempts - ensuring that unauthorized or harmful behaviors are intercepted early in the process. @@ -50,7 +50,7 @@ Prompt Targets -------------- Once a prompt passes any configured guardrail checks, Arch processes the contents of the incoming conversation -and identifies where to forwad the conversation to via its ``prompt_targets`` primitve. Prompt targets are endpoints +and identifies where to forwad the conversation to via its ``prompt target`` primitve. Prompt targets are endpoints that receive prompts that are processed by Arch. For example, Arch enriches incoming prompts with metadata like knowing when a user's intent has changed so that you can build faster, more accurate RAG apps. @@ -67,48 +67,39 @@ Configuring ``prompt_targets`` is simple. See example below: Check :ref:`Prompt Target ` for more details! -Intent Detection and Prompt Matching: -^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +Intent Matching +^^^^^^^^^^^^^^^ -Arch uses fast Natural Language Inference (NLI) and embedding approaches to first detect the intent of each -incoming prompt. This intent detection phase analyzes the prompt's content and matches it against predefined -prompt targets, ensuring that each prompt is forwarded to the most appropriate endpoint. Arch’s intent -detection framework considers both the name and description of each prompt target, and uses a composite matching -score between an NLI and cosine similarity to enchance accuracy in forwarding decisions. +Arch uses fast text embedding and intent recognition approaches to first detect the intent of each incoming prompt. +This intent matching phase analyzes the prompt's content and matches it against predefined prompt targets, ensuring that each prompt is forwarded to the most appropriate endpoint. +Arch’s intent matching framework considers both the name and description of each prompt target, and uses a composite matching score between embedding similarity and intent classification scores to enchance accuracy in forwarding decisions. -- **Embeddings**: By embedding the prompt and comparing it to known target vectors, Arch effectively identifies - the closest match, ensuring that the prompt is handled by the correct downstream service. +- **Intent Recognition**: NLI techniques further refine the matching process by evaluating the semantic alignment between the prompt and potential targets. -- **NLI**: NLI techniques further refine the matching process by evaluating the semantic alignment between the - prompt and potential targets. +- **Text Embedding**: By embedding the prompt and comparing it to known target vectors, Arch effectively identifies the closest match, ensuring that the prompt is handled by the correct downstream service. Agentic Apps via Prompt Targets ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ -To support agentic apps, like scheduling travel plans or sharing comments on a document - via prompts, Arch uses -its function calling abilities to extract critical information from the incoming prompt (or a set of prompts) -needed by a downstream backend API or function call before calling it directly. For more details on how you can -build agentic applications using Arch, see our full guide :ref:`here `: +To support agentic apps, like scheduling travel plans or sharing comments on a document - via prompts, Arch uses its function calling abilities to extract critical information from the incoming prompt (or a set of prompts) needed by a downstream backend API or function call before calling it directly. +For more details on how you can build agentic applications using Arch, see our full guide :ref:`here `: .. Note:: - Arch :ref:`Arch-Function ` is the dedicated agentic model engineered in Arch to extract information from - a (set of) prompts and executes necessary backend API calls. This allows for efficient handling of agentic tasks, - such as scheduling data retrieval, by dynamically interacting with backend services. Arch-Function is a flagship 1.3 - billion parameter model that matches performance with frontier models like Claude Sonnet 3.5 ang GPT-4, while - being 100x cheaper ($0.05M/token hosted) and 10x faster (p50 latencies of 200ms). + `Arch-Function `_ is a collection of dedicated agentic models engineered in Arch to extract information from a (set of) prompts and executes necessary backend API calls. + This allows for efficient handling of agentic tasks, such as scheduling data retrieval, by dynamically interacting with backend services. + Arch-Function achieves state-of-the-art performance, comparable with frontier models like Claude Sonnet 3.5 ang GPT-4, while being 100x cheaper ($0.05M/token hosted) and 10x faster (p50 latencies of 200ms). Prompting LLMs -------------- -Arch is a single piece of software that is designed to manage both ingress and egress prompt traffic, drawing its -distributed proxy nature from the robust `Envoy `_. This makes it extremely efficient and capable -of handling upstream connections to LLMs. If your application is originating code to an API-based LLM, simply use -the OpenAI client and configure it with Arch. By sending traffic through Arch, you can propagate traces, manage and monitor -traffic, apply rate limits, and utilize a large set of traffic management capabilities in a centralized way. +Arch is a single piece of software that is designed to manage both ingress and egress prompt traffic, drawing its distributed proxy nature from the robust `Envoy `_. +This makes it extremely efficient and capable of handling upstream connections to LLMs. +If your application is originating code to an API-based LLM, simply use the OpenAI client and configure it with Arch. +By sending traffic through Arch, you can propagate traces, manage and monitor traffic, apply rate limits, and utilize a large set of traffic management capabilities in a centralized way. .. Attention:: When you start Arch, it automatically creates a listener port for egress calls to upstream LLMs. This is based on the ``llm_providers`` configuration section in the ``arch_config.yml`` file. Arch binds itself to a local address such as - 127.0.0.1:12000/v1. + ``127.0.0.1:12000``. Example: Using OpenAI Client with Arch as an Egress Gateway @@ -119,7 +110,7 @@ Example: Using OpenAI Client with Arch as an Egress Gateway import openai # Set the OpenAI API base URL to the Arch gateway endpoint - openai.api_base = "http://127.0.0.1:12000/v1" + openai.api_base = "http://127.0.0.1:12000" # No need to set openai.api_key since it's configured in Arch's gateway @@ -132,5 +123,5 @@ Example: Using OpenAI Client with Arch as an Egress Gateway print("OpenAI Response:", response.choices[0].text.strip()) In these examples, the OpenAI client is used to send traffic directly through the Arch egress proxy to the LLM of your choice, such as OpenAI. -The OpenAI client is configured to route traffic via Arch by setting the proxy to ``127.0.0.1:51001``, assuming Arch is running locally and bound to that address and port. +The OpenAI client is configured to route traffic via Arch by setting the proxy to ``127.0.0.1:12000``, assuming Arch is running locally and bound to that address and port. This setup allows you to take advantage of Arch's advanced traffic management features while interacting with LLM APIs like OpenAI. diff --git a/docs/source/concepts/tech_overview/request_lifecycle.rst b/docs/source/concepts/tech_overview/request_lifecycle.rst index dd6084ee..dd3bcc8f 100644 --- a/docs/source/concepts/tech_overview/request_lifecycle.rst +++ b/docs/source/concepts/tech_overview/request_lifecycle.rst @@ -87,8 +87,6 @@ Today, only support a static bootstrap configuration file for simplicity today: Request Flow (Ingress) ---------------------- -Overview -^^^^^^^^ A brief outline of the lifecycle of a request and response using the example configuration above: 1. **TCP Connection Establishment**: @@ -105,7 +103,7 @@ A brief outline of the lifecycle of a request and response using the example con intent matching via is **prompt-handler** subsystem using the name and description of the defined prompt targets, determining which endpoint should handle the prompt. -4. **Parameter Gathering with Arch-FC**: +4. **Parameter Gathering with Arch-Function**: If a prompt target requires specific parameters, Arch engages Arch-FC to extract the necessary details from the incoming prompt(s). This process gathers the critical information needed for downstream API calls. @@ -115,7 +113,7 @@ A brief outline of the lifecycle of a request and response using the example con 6. **Default Summarization by Upstream LLM**: By default, if no specific endpoint processing is needed, the prompt is sent to an upstream LLM for summarization. - This ensures that responses are concise and relevant, enhancing user experience in RAG (Retrieval-Augmented Generation) + This ensures that responses are concise and relevant, enhancing user experience in RAG (Retrieval Augmented Generation) and agentic applications. 7. **Error Handling and Forwarding**: @@ -134,11 +132,7 @@ A brief outline of the lifecycle of a request and response using the example con Request Flow (Egress) --------------------- -Overview --------- - -A brief outline of the lifecycle of a request and response in the context of egress traffic from an application -to Large Language Models (LLMs) via Arch: +A brief outline of the lifecycle of a request and response in the context of egress traffic from an application to Large Language Models (LLMs) via Arch: 1. **HTTP Connection Establishment to LLM**: Arch initiates an HTTP connection to the upstream LLM service. This connection is handled by Arch’s egress listener diff --git a/docs/source/concepts/tech_overview/terminology.rst b/docs/source/concepts/tech_overview/terminology.rst index eb461b95..2f1c9c6d 100644 --- a/docs/source/concepts/tech_overview/terminology.rst +++ b/docs/source/concepts/tech_overview/terminology.rst @@ -29,7 +29,7 @@ networking operations (auth, tls, observability, etc) and the second process to decisions on how to accept, handle and forward prompts. The second process is optional, as the model serving sevice could be hosted on a different network (an API call). But these two processes are considered a single instance of Arch. -**Prompt Target**: Arch offers a primitive called :ref:`prompt_target ` to help separate business logic from undifferentiated +**Prompt Target**: Arch offers a primitive called :ref:`prompt target ` to help separate business logic from undifferentiated work in building generative AI apps. Prompt targets are endpoints that receive prompts that are processed by Arch. For example, Arch enriches incoming prompts with metadata like knowing when a request is a follow-up or clarifying prompt so that you can build faster, more accurate retrieval (RAG) apps. To support agentic apps, like scheduling travel plans or diff --git a/docs/source/get_started/intro_to_arch.rst b/docs/source/get_started/intro_to_arch.rst index 63931b84..7f61b4f9 100644 --- a/docs/source/get_started/intro_to_arch.rst +++ b/docs/source/get_started/intro_to_arch.rst @@ -3,13 +3,8 @@ Intro to Arch ============= -Arch is an intelligent `(Layer 7) `_ gateway -designed for generative AI apps, AI agents, and Co-pilots that work with prompts. Engineered with purpose-built -large language models (LLMs), Arch handles all the critical but undifferentiated tasks related to the handling and -processing of prompts, including detecting and rejecting `jailbreak `_ -attempts, intelligently calling “backend” APIs to fulfill the user's request represented in a prompt, routing to -and offering disaster recovery between upstream LLMs, and managing the observability of prompts and LLM interactions -in a centralized way. +Arch is an intelligent `(Layer 7) `_ gateway designed for generative AI apps, AI agents, and AI copilots that work with prompts. +Engineered with purpose-built large language models (LLMs), Arch handles all the critical but undifferentiated tasks related to the handling and processing of prompts, including detecting and rejecting jailbreak attempts, intelligently calling “backend” APIs to fulfill the user's request represented in a prompt, routing to and offering disaster recovery between upstream LLMs, and managing the observability of prompts and LLM interactions in a centralized way. .. image:: /_static/img/arch-logo.png :width: 100% @@ -21,70 +16,51 @@ in a centralized way. including secure handling, intelligent routing, robust observability, and integration with backend (API) systems for personalization - all outside business logic.* +In practice, achieving the above goal is incredibly difficult. +Arch attempts to do so by providing the following high level features: -In practice, achieving the above goal is incredibly difficult. Arch attempts to do so by providing the -following high level features: +**Out-of-process architecture, built on** `Envoy `_: +Arch is takes a dependency on Envoy and is a self-contained process that is designed to run alongside your application servers. +Arch uses Envoy's HTTP connection management subsystem, HTTP L7 filtering and telemetry capabilities to extend the functionality exclusively for prompts and LLMs. +This gives Arch several advantages: -_____________________________________________________________________________________________________________ +* Arch builds on Envoy's proven success. Envoy is used at masssive sacle by the leading technology companies of our time including `AirBnB `_, `Dropbox `_, `Google `_, `Reddit `_, `Stripe `_, etc. Its battle tested and scales linearly with usage and enables developers to focus on what really matters: application features and business logic. -**Out-of-process architecture, built on** `Envoy `_: Arch is takes a dependency on -Envoy and is a self-contained process that is designed to run alongside your application servers. Arch uses -Envoy's HTTP connection management subsystem, HTTP L7 filtering and telemetry capabilities to extend the -functionality exclusively for prompts and LLMs. This gives Arch several advantages: +* Arch works with any application language. A single Arch deployment can act as gateway for AI applications written in Python, Java, C++, Go, Php, etc. -* Arch builds on Envoy's proven success. Envoy is used at masssive sacle by the leading technology companies of - our time including `AirBnB `_, `Dropbox `_, - `Google `_, `Reddit `_, `Stripe `_, - etc. Its battle tested and scales linearly with usage and enables developers to focus on what really matters: - application features and business logic. +* Arch can be deployed and upgraded quickly across your infrastructure transparently without the horrid pain of deploying library upgrades in your applications. -* Arch works with any application language. A single Arch deployment can act as gateway for AI applications - written in Python, Java, C++, Go, Php, etc. +**Engineered with Fast LLMs:** Arch is engineered with specialized tiny LLMs that are desgined for fast, cost-effective and acurrate handling of prompts. +These LLMs are designed to be best-in-class for critcal prompt-related tasks like: -* Arch can be deployed and upgraded quickly across your infrastructure transparently without the horrid pain - of deploying library upgrades in your applications. +* **Function Calling:** Arch helps you easily personalize your applications by enabling calls to application-specific (API) operations via user prompts. + This involves any predefined functions or APIs you want to expose to users to perform tasks, gather information, or manipulate data. + With function calling, you have flexibility to support "agentic" experiences tailored to specific use cases - from updating insurance claims to creating ad campaigns - via prompts. + Arch analyzes prompts, extracts critical information from prompts, engages in lightweight conversation to gather any missing parameters and makes API calls so that you can focus on writing business logic. + For more details, read :ref:`Function Calling `. -**Engineered with Fast LLMs:** Arch is engineered with specialized (sub-billion) LLMs that are desgined for -fast, cost-effective and acurrate handling of prompts. These LLMs are designed to be -best-in-class for critcal prompt-related tasks like: +* **Prompt Guard:** Arch helps you improve the safety of your application by applying prompt guardrails in a centralized way for better governance hygiene. + With prompt guardrails you can prevent ``jailbreak attempts`` present in user's prompts without having to write a single line of code. + To learn more about how to configure guardrails available in Arch, read :ref:`Prompt Guard `. -* **Function/API Calling:** Arch helps you easily personalize your applications by enabling calls to - application-specific (API) operations via user prompts. This involves any predefined functions or APIs - you want to expose to users to perform tasks, gather information, or manipulate data. With function calling, - you have flexibility to support "agentic" experiences tailored to specific use cases - from updating insurance - claims to creating ad campaigns - via prompts. Arch analyzes prompts, extracts critical information from - prompts, engages in lightweight conversation to gather any missing parameters and makes API calls so that you can - focus on writing business logic. For more details, read :ref:`prompt processing `. +* **[Coming Soon] Intent-Markers:** Developers struggle to handle ``follow-up`` or ``clarifying`` questions. + Specifically, when users ask for modifications or additions to previous responses their AI applications often generate entirely new responses instead of adjusting the previous ones. + Arch offers intent-markers as a feature so that developers know when the user has shifted away from the previous intent so that they can improve their retrieval, lower overall token cost and dramatically improve the speed and accuracy of their responses back to users. + For more details :ref:`intent markers `. -* **Prompt Guardrails:** Arch helps you improve the safety of your application by applying prompt guardrails in - a centralized way for better governance hygiene. With prompt guardrails you can prevent `jailbreak `_ - attempts or toxicity present in user's prompts without having to write a single line of code. To learn more - about how to configure guardrails available in Arch, read :ref:`prompt processing `. +**Traffic Management:** Arch offers several capabilities for LLM calls originating from your applications, including smart retries on errors from upstream LLMs, and automatic cutover to other LLMs configured in Arch for continuous availability and disaster recovery scenarios. +Arch extends Envoy's `cluster subsystem `_ to manage upstream connections to LLMs so that you can build resilient AI applications. -* **[Coming Soon] Intent-Markers:** Developers struggle to handle `follow-up `_, - or `clarifying `_ - questions. Specifically, when users ask for modifications or additions to previous responses their AI applications - often generate entirely new responses instead of adjusting the previous ones. Arch offers intent-markers as a - feature so that developers know when the user has shifted away from the previous intent so that they can improve - their retrieval, lower overall token cost and dramatically improve the speed and accuracy of their responses back - to users. For more details :ref:`intent markers` - -**Traffic Management:** Arch offers several capabilities for LLM calls originating from your applications, including smart -retries on errors from upstream LLMs, and automatic cutover to other LLMs configured in Arch for continuous availability -and disaster recovery scenarios. Arch extends Envoy's `cluster subsystem `_ -to manage upstream connections to LLMs so that you can build resilient AI applications. - -**Front/edge Gateway:** There is substantial benefit in using the same software at the edge (observability, -traffic shaping alogirithms, applying guardrails, etc.) as for outbound LLM inference use cases. Arch has the feature set -that makes it exceptionally well suited as an edge gateway for AI applications. This includes TLS termination, applying -guardrail early in the pricess, intelligent parameter gathering from prompts, and prompt-based routing to backend APIs. +**Front/edge Gateway:** There is substantial benefit in using the same software at the edge (observability, traffic shaping alogirithms, applying guardrails, etc.) as for outbound LLM inference use cases. +Arch has the feature set that makes it exceptionally well suited as an edge gateway for AI applications. +This includes TLS termination, applying guardrail early in the pricess, intelligent parameter gathering from prompts, and prompt-based routing to backend APIs. **Best-In Class Monitoring:** Arch offers several monitoring metrics that help you understand three critical aspects of your application: latency, token usage, and error rates by an upstream LLM provider. Latency measures the speed at which your application is responding to users, which includes metrics like time to first token (TFT), time per output token (TOT) metrics, and the total latency as perceived by users. -**End-to-End Tracing:** Arch propagates trace context using the W3C Trace Context standard, specifically through the -``traceparent`` header. This allows each component in the system to record its part of the request flow, enabling **end-to-end tracing** -across the entire application. By using OpenTelemetry, Arch ensures that developers can capture this trace data consistently and -in a format compatible with various observability tools. For more details, read :ref:`tracing `. +**End-to-End Tracing:** Arch propagates trace context using the W3C Trace Context standard, specifically through the ``traceparent`` header. +This allows each component in the system to record its part of the request flow, enabling end-to-end tracing across the entire application. +By using OpenTelemetry, Arch ensures that developers can capture this trace data consistently and in a format compatible with various observability tools. +For more details, read :ref:`Tracing `. diff --git a/docs/source/get_started/quickstart.rst b/docs/source/get_started/quickstart.rst index 23a76379..1d6ff635 100644 --- a/docs/source/get_started/quickstart.rst +++ b/docs/source/get_started/quickstart.rst @@ -16,7 +16,7 @@ Before you begin, ensure you have the following: - ``Docker`` & ``Python`` installed on your system - ``API Keys`` for LLM providers (if using external LLMs) -The fastest way to get started using Arch is to use `katanemo/arch `_ pre-built binaries. +The fastest way to get started using Arch is to use `katanemo/archgw `_ pre-built binaries. You can also build it from source. diff --git a/docs/source/guides/function_calling.rst b/docs/source/guides/function_calling.rst index 907326a0..cb09bc6b 100644 --- a/docs/source/guides/function_calling.rst +++ b/docs/source/guides/function_calling.rst @@ -35,7 +35,7 @@ Function Calling Workflow Arch-Function ------------------------- -The `Arch-Function `_ collection of large language models (LLMs) is a collection state-of-the-art (SOTA) LLMs specifically designed for **function calling** tasks. +The `Arch-Function `_ collection of large language models (LLMs) is a collection state-of-the-art (SOTA) LLMs specifically designed for **function calling** tasks. The models are designed to understand complex function signatures, identify required parameters, and produce accurate function call outputs based on natural language prompts. Achieving performance on par with GPT-4, these models set a new benchmark in the domain of function-oriented tasks, making them suitable for scenarios where automated API interaction and function execution is crucial. diff --git a/docs/source/guides/prompt_guard.rst b/docs/source/guides/prompt_guard.rst index e6e2beaf..2f9bbd01 100644 --- a/docs/source/guides/prompt_guard.rst +++ b/docs/source/guides/prompt_guard.rst @@ -39,7 +39,7 @@ Arch-Guard is designed to address this challenge. What Is Arch-Guard ~~~~~~~~~~~~~~~~~~ -`Arch-Guard `_ is a robust classifier model specifically trained on a diverse corpus of prompt attacks. +`Arch-Guard `_ is a robust classifier model specifically trained on a diverse corpus of prompt attacks. It excels at detecting explicitly malicious prompts, providing an essential layer of security for LLM applications. By embedding Arch-Guard within the Arch architecture, we empower developers to build robust, LLM-powered applications while prioritizing security and safety. With Arch-Guard, you can navigate the complexities of prompt management with confidence, knowing you have a reliable defense against malicious input. diff --git a/docs/source/index.rst b/docs/source/index.rst index 1079b99e..bda66032 100644 --- a/docs/source/index.rst +++ b/docs/source/index.rst @@ -23,6 +23,7 @@ Arch (built by the contributors of `Envoy `_ ) was b .. toctree:: :caption: Get Started :titlesonly: + :maxdepth: 2 get_started/overview get_started/intro_to_arch @@ -33,6 +34,7 @@ Arch (built by the contributors of `Envoy `_ ) was b .. toctree:: :caption: Concepts :titlesonly: + :maxdepth: 2 concepts/tech_overview/tech_overview concepts/llm_provider @@ -43,6 +45,7 @@ Arch (built by the contributors of `Envoy `_ ) was b .. toctree:: :caption: Guides :titlesonly: + :maxdepth: 2 guides/prompt_guard guides/function_calling @@ -53,6 +56,7 @@ Arch (built by the contributors of `Envoy `_ ) was b .. toctree:: :caption: Build with Arch :titlesonly: + :maxdepth: 2 build_with_arch/agent build_with_arch/rag @@ -62,5 +66,6 @@ Arch (built by the contributors of `Envoy `_ ) was b .. toctree:: :caption: Resources :titlesonly: + :maxdepth: 2 resources/configuration_reference