arcade-mcp/libs/tests/core/converters/test_openai.py
jottakka 98fad93d21
Adding MCP Servers supports to Arcade Evals (#689)
# MCP Server Tool Evaluation Support

## Overview
Add support for evaluating tools from remote MCP servers without
requiring Python callables. Enables direct evaluation of any
MCP-compatible tool server.

## What's New

### Core Features
- **`MCPToolRegistry`**: Evaluate tools from a single MCP server
- **`CompositeMCPRegistry`**: Evaluate tools from multiple MCP servers
simultaneously
- **Automatic loaders**: `load_from_stdio()` and `load_from_http()` to
fetch tools from running servers
- **Automatic namespacing**: Tools prefixed with server name (e.g.,
`server_tool_name`)
- **Smart name resolution**: Use short names if unique, full names if
ambiguous
- **OpenAI strict mode**: Automatic schema conversion prevents parameter
hallucinations

### Usage

**Automatic Loading:**
```python
from arcade_evals import load_from_stdio, MCPToolRegistry

# Load tools automatically from MCP server
tools = load_from_stdio(["npx", "-y", "@modelcontextprotocol/server-github"])
registry = MCPToolRegistry(tools)
```

**Single MCP Server:**
```python
from arcade_evals import MCPToolRegistry, ExpectedToolCall

registry = MCPToolRegistry(mcp_tools)
suite = EvalSuite(catalog=registry)

suite.add_case(
    expected_tool_calls=[
        ExpectedToolCall(tool_name="tool_name", args={...})
    ]
)
```

**Multiple MCP Servers:**
```python
from arcade_evals import CompositeMCPRegistry, load_from_stdio

# Load from multiple servers
github_tools = load_from_stdio(["npx", "-y", "@modelcontextprotocol/server-github"])
slack_tools = load_from_stdio(["npx", "-y", "@modelcontextprotocol/server-slack"])

composite = CompositeMCPRegistry(
    tool_lists={
        "github": github_tools,
        "slack": slack_tools,
    }
)

suite = EvalSuite(catalog=composite)

suite.add_case(
    expected_tool_calls=[
        ExpectedToolCall(tool_name="github_list_issues", args={...})
    ]
)
```

## Implementation

### Files Changed
- **`libs/arcade-evals/arcade_evals/registry.py`** (NEW): Registry
abstractions and implementations
- **`libs/arcade-evals/arcade_evals/loaders.py`** (NEW): Automatic tool
loading from MCP servers
- **`libs/arcade-evals/arcade_evals/eval.py`** (MODIFIED): Enhanced
`ExpectedToolCall` and evaluation logic
- **`libs/arcade-evals/arcade_evals/__init__.py`** (MODIFIED): Exported
new registries and loaders

### Key Technical Details
- Added `BaseToolRegistry` interface for abstraction
- `MCPToolRegistry` handles single server tools
- `CompositeMCPRegistry` manages multiple servers with collision
detection
- `load_from_stdio()` and `load_from_http()` for automatic tool
discovery
- Fixed name normalization bug: MCP tools use underscores (not dots)
- Optimized tool copying: 2.5x faster via shallow copy

## Testing
-  41 tests passing (25 new tests added)
-  `test_eval_mcp_registry.py`: MCPToolRegistry functionality
-  `test_eval_composite_mcp.py`: CompositeMCPRegistry with multiple
servers
-  Verified backward compatibility with Python tools

## Backward Compatibility
 **100% backward compatible** - No breaking changes


## Breaking Changes
**None**


<!-- CURSOR_SUMMARY -->
---

> [!NOTE]
> Adds end-to-end eval UX: examples, a robust CLI runner, and rich
outputs.
> 
> - **New examples**: `eval_arcade_gateway.py`,
`eval_stdio_mcp_server.py`, `eval_http_mcp_server.py`,
`eval_comprehensive_comparison.py` with timeouts, error handling, and
track-based comparisons; detailed `README.md`
> - **CLI runner**: `arcade_cli/evals_runner.py` to execute
evals/capture in parallel with progress, error isolation, failed-only
filtering, context inclusion, and multi-provider/model support
> - **Output formatters**: `arcade_cli/formatters/` (txt, md, html,
json) for evals and capture; comparative and multi-model HTML with tabs
and context rendering
> - **Display refactor**: `display.py` now supports writing multiple
formats, failed-only disclaimers, include-context, and improved console
summaries
> 
> <sup>Written by [Cursor
Bugbot](https://cursor.com/dashboard?tab=bugbot) for commit
ff8acf9c34a6b61462a019a1ee9df081006517d0. This will update automatically
on new commits. Configure
[here](https://cursor.com/dashboard?tab=bugbot).</sup>
<!-- /CURSOR_SUMMARY -->

---------

Co-authored-by: Francisco Liberal <francisco@arcade.dev>
Co-authored-by: Mateo Torres <torresmateo@gmail.com>
2026-01-07 20:26:23 -03:00

547 lines
20 KiB
Python

"""Tests for OpenAI converter utilities."""
from typing import Annotated
import pytest
from arcade_core.catalog import MaterializedTool, ToolMeta, create_func_models
from arcade_core.converters.openai import (
OpenAIFunctionParameters,
_convert_input_parameters_to_json_schema,
_convert_value_schema_to_json_schema,
_create_tool_schema,
to_openai,
)
from arcade_core.schema import (
InputParameter,
ToolDefinition,
ToolInput,
ToolkitDefinition,
ToolOutput,
ToolRequirements,
ValueSchema,
)
class TestOpenAIConverter:
"""Test OpenAI converter functions."""
@pytest.fixture
def sample_tool_def(self):
"""Create a sample tool definition."""
return ToolDefinition(
name="calculate",
fully_qualified_name="MathToolkit.calculate",
description="Perform a calculation",
toolkit=ToolkitDefinition(
name="MathToolkit",
description="Math tools",
version="1.0.0",
),
input=ToolInput(
parameters=[
InputParameter(
name="expression",
required=True,
description="Math expression to evaluate",
value_schema=ValueSchema(val_type="string"),
),
InputParameter(
name="precision",
required=False,
description="Decimal precision",
value_schema=ValueSchema(val_type="integer"),
),
]
),
output=ToolOutput(
description="Calculation result",
value_schema=ValueSchema(val_type="number"),
),
requirements=ToolRequirements(),
)
@pytest.fixture
def materialized_tool(self, sample_tool_def):
"""Create a materialized tool."""
def calculate(
expression: Annotated[str, "Math expression"] = "1 + 1",
precision: Annotated[int, "Decimal precision"] = 2,
) -> Annotated[float, "Calculation result"]:
"""Perform a calculation."""
return round(eval(expression), precision) # noqa: S307
input_model, output_model = create_func_models(calculate)
meta = ToolMeta(module=calculate.__module__, toolkit=sample_tool_def.toolkit.name)
return MaterializedTool(
tool=calculate,
definition=sample_tool_def,
meta=meta,
input_model=input_model,
output_model=output_model,
)
def test_to_openai_basic(self, materialized_tool):
"""Test basic OpenAI tool conversion."""
result = to_openai(materialized_tool)
assert isinstance(result, dict)
assert result["type"] == "function"
assert "function" in result
function = result["function"]
assert function["name"] == "MathToolkit_calculate"
assert function["description"] == "Perform a calculation"
assert function["strict"] is True
assert "parameters" in function
def test_function_name_conversion(self, materialized_tool):
"""Test that dots in fully_qualified_name are converted to underscores."""
result = to_openai(materialized_tool)
assert result["function"]["name"] == "MathToolkit_calculate"
def test_function_parameters_structure(self, materialized_tool):
"""Test the structure of function parameters."""
result = to_openai(materialized_tool)
params = result["function"]["parameters"]
assert params["type"] == "object"
assert params["additionalProperties"] is False
assert "properties" in params
assert "required" in params
# All parameters should be in required list for strict mode
assert set(params["required"]) == {"expression", "precision"}
def test_required_parameter_schema(self, materialized_tool):
"""Test required parameter schema generation."""
result = to_openai(materialized_tool)
props = result["function"]["parameters"]["properties"]
expression_prop = props["expression"]
assert expression_prop["type"] == "string"
assert expression_prop["description"] == "Math expression to evaluate"
def test_optional_parameter_schema(self, materialized_tool):
"""Test optional parameter schema with null union type."""
result = to_openai(materialized_tool)
props = result["function"]["parameters"]["properties"]
precision_prop = props["precision"]
# Optional parameters should have union type with null
assert precision_prop["type"] == ["integer", "null"]
assert precision_prop["description"] == "Decimal precision"
def test_no_parameters_tool(self):
"""Test tool with no parameters."""
tool_def = ToolDefinition(
name="get_time",
fully_qualified_name="TimeToolkit.get_time",
description="Get current time",
toolkit=ToolkitDefinition(name="TimeToolkit"),
input=ToolInput(parameters=[]),
output=ToolOutput(),
requirements=ToolRequirements(),
)
def get_time() -> Annotated[str, "current time"]:
return "2023-01-01T00:00:00Z"
input_model, output_model = create_func_models(get_time)
meta = ToolMeta(module=get_time.__module__, toolkit=tool_def.toolkit.name)
mat_tool = MaterializedTool(
tool=get_time,
definition=tool_def,
meta=meta,
input_model=input_model,
output_model=output_model,
)
result = to_openai(mat_tool)
params = result["function"]["parameters"]
assert params["type"] == "object"
assert params["properties"] == {}
assert params["additionalProperties"] is False
# No required field when there are no parameters
assert "required" not in params
@pytest.mark.parametrize(
"arcade_type,expected_json_type",
[
("string", "string"),
("integer", "integer"),
("number", "number"),
("boolean", "boolean"),
("array", "array"),
("json", "object"),
],
)
def test_parameter_type_conversion(self, arcade_type, expected_json_type):
"""Test different parameter type conversions."""
tool_def = ToolDefinition(
name="test",
fully_qualified_name="Test.test",
description="Test tool",
toolkit=ToolkitDefinition(name="Test"),
input=ToolInput(
parameters=[
InputParameter(
name="param",
required=True,
description="Test parameter",
value_schema=ValueSchema(val_type=arcade_type),
)
]
),
output=ToolOutput(),
requirements=ToolRequirements(),
)
def test_func(param: Annotated[str, "Test parameter"]):
return param
input_model, output_model = create_func_models(test_func)
meta = ToolMeta(module=test_func.__module__, toolkit=tool_def.toolkit.name)
mat_tool = MaterializedTool(
tool=test_func,
definition=tool_def,
meta=meta,
input_model=input_model,
output_model=output_model,
)
result = to_openai(mat_tool)
param_schema = result["function"]["parameters"]["properties"]["param"]
assert param_schema["type"] == expected_json_type
def test_array_parameter_with_inner_type(self):
"""Test array parameter with inner type specification."""
tool_def = ToolDefinition(
name="process_items",
fully_qualified_name="ArrayToolkit.process_items",
description="Process a list of items",
toolkit=ToolkitDefinition(name="ArrayToolkit"),
input=ToolInput(
parameters=[
InputParameter(
name="items",
required=True,
description="List of string items",
value_schema=ValueSchema(
val_type="array",
inner_val_type="string",
),
)
]
),
output=ToolOutput(),
requirements=ToolRequirements(),
)
def process_items(items: Annotated[list[str], "List of string items"]):
return items
input_model, output_model = create_func_models(process_items)
meta = ToolMeta(module=process_items.__module__, toolkit=tool_def.toolkit.name)
mat_tool = MaterializedTool(
tool=process_items,
definition=tool_def,
meta=meta,
input_model=input_model,
output_model=output_model,
)
result = to_openai(mat_tool)
param_schema = result["function"]["parameters"]["properties"]["items"]
assert param_schema["type"] == "array"
assert param_schema["items"]["type"] == "string"
def test_enum_parameter(self):
"""Test parameter with enum values."""
tool_def = ToolDefinition(
name="set_color",
fully_qualified_name="ColorToolkit.set_color",
description="Set a color",
toolkit=ToolkitDefinition(name="ColorToolkit"),
input=ToolInput(
parameters=[
InputParameter(
name="color",
required=True,
description="Color choice",
value_schema=ValueSchema(
val_type="string",
enum=["red", "green", "blue"],
),
)
]
),
output=ToolOutput(),
requirements=ToolRequirements(),
)
def set_color(color: Annotated[str, "Color choice"]):
return color
input_model, output_model = create_func_models(set_color)
meta = ToolMeta(module=set_color.__module__, toolkit=tool_def.toolkit.name)
mat_tool = MaterializedTool(
tool=set_color,
definition=tool_def,
meta=meta,
input_model=input_model,
output_model=output_model,
)
result = to_openai(mat_tool)
param_schema = result["function"]["parameters"]["properties"]["color"]
assert param_schema["type"] == "string"
assert param_schema["enum"] == ["red", "green", "blue"]
def test_array_with_enum_items(self):
"""Test array parameter where items have enum values."""
tool_def = ToolDefinition(
name="set_colors",
fully_qualified_name="ColorToolkit.set_colors",
description="Set multiple colors",
toolkit=ToolkitDefinition(name="ColorToolkit"),
input=ToolInput(
parameters=[
InputParameter(
name="colors",
required=True,
description="List of colors",
value_schema=ValueSchema(
val_type="array",
inner_val_type="string",
enum=["red", "green", "blue"],
),
)
]
),
output=ToolOutput(),
requirements=ToolRequirements(),
)
def set_colors(colors: Annotated[list[str], "List of colors"]):
return colors
input_model, output_model = create_func_models(set_colors)
meta = ToolMeta(module=set_colors.__module__, toolkit=tool_def.toolkit.name)
mat_tool = MaterializedTool(
tool=set_colors,
definition=tool_def,
meta=meta,
input_model=input_model,
output_model=output_model,
)
result = to_openai(mat_tool)
param_schema = result["function"]["parameters"]["properties"]["colors"]
assert param_schema["type"] == "array"
assert param_schema["items"]["type"] == "string"
assert param_schema["items"]["enum"] == ["red", "green", "blue"]
def test_json_parameter_with_properties(self):
"""Test JSON parameter with nested properties."""
tool_def = ToolDefinition(
name="create_user",
fully_qualified_name="UserToolkit.create_user",
description="Create a user",
toolkit=ToolkitDefinition(name="UserToolkit"),
input=ToolInput(
parameters=[
InputParameter(
name="user_data",
required=True,
description="User information",
value_schema=ValueSchema(
val_type="json",
properties={
"name": ValueSchema(val_type="string"),
"age": ValueSchema(val_type="integer"),
"active": ValueSchema(val_type="boolean"),
},
),
)
]
),
output=ToolOutput(),
requirements=ToolRequirements(),
)
def create_user(user_data: Annotated[dict, "User information"]):
return user_data
input_model, output_model = create_func_models(create_user)
meta = ToolMeta(module=create_user.__module__, toolkit=tool_def.toolkit.name)
mat_tool = MaterializedTool(
tool=create_user,
definition=tool_def,
meta=meta,
input_model=input_model,
output_model=output_model,
)
result = to_openai(mat_tool)
param_schema = result["function"]["parameters"]["properties"]["user_data"]
assert param_schema["type"] == "object"
assert "properties" in param_schema
assert param_schema["properties"]["name"]["type"] == "string"
assert param_schema["properties"]["age"]["type"] == "integer"
assert param_schema["properties"]["active"]["type"] == "boolean"
def test_multiple_optional_parameters(self):
"""Test tool with multiple optional parameters."""
tool_def = ToolDefinition(
name="search",
fully_qualified_name="SearchToolkit.search",
description="Search with filters",
toolkit=ToolkitDefinition(name="SearchToolkit"),
input=ToolInput(
parameters=[
InputParameter(
name="query",
required=True,
description="Search query",
value_schema=ValueSchema(val_type="string"),
),
InputParameter(
name="limit",
required=False,
description="Result limit",
value_schema=ValueSchema(val_type="integer"),
),
InputParameter(
name="include_metadata",
required=False,
description="Include metadata in results",
value_schema=ValueSchema(val_type="boolean"),
),
]
),
output=ToolOutput(),
requirements=ToolRequirements(),
)
def search(
query: Annotated[str, "Search query"],
limit: Annotated[int, "Result limit"] = 10,
include_metadata: Annotated[bool, "Include metadata"] = False,
):
return f"Search results for {query}"
input_model, output_model = create_func_models(search)
meta = ToolMeta(module=search.__module__, toolkit=tool_def.toolkit.name)
mat_tool = MaterializedTool(
tool=search,
definition=tool_def,
meta=meta,
input_model=input_model,
output_model=output_model,
)
result = to_openai(mat_tool)
props = result["function"]["parameters"]["properties"]
# Required parameter should have single type
assert props["query"]["type"] == "string"
# Optional parameters should have union types with null
assert props["limit"]["type"] == ["integer", "null"]
assert props["include_metadata"]["type"] == ["boolean", "null"]
# All parameters should be in required list for strict mode
assert set(result["function"]["parameters"]["required"]) == {
"query",
"limit",
"include_metadata",
}
class TestHelperFunctions:
"""Test helper functions used by the converter."""
def test_create_tool_schema(self):
"""Test _create_tool_schema helper function."""
params: OpenAIFunctionParameters = {
"type": "object",
"properties": {"test": {"type": "string"}},
"required": ["test"],
"additionalProperties": False,
}
result = _create_tool_schema("test_func", "Test function", params)
assert result["type"] == "function"
assert result["function"]["name"] == "test_func"
assert result["function"]["description"] == "Test function"
assert result["function"]["parameters"] == params
assert result["function"]["strict"] is True
def test_convert_value_schema_to_json_schema_basic_types(self):
"""Test _convert_value_schema_to_json_schema for basic types."""
test_cases = [
("string", "string"),
("integer", "integer"),
("number", "number"),
("boolean", "boolean"),
("json", "object"),
("array", "array"),
]
for arcade_type, expected_json_type in test_cases:
schema = ValueSchema(val_type=arcade_type)
result = _convert_value_schema_to_json_schema(schema)
assert result["type"] == expected_json_type
def test_convert_value_schema_with_enum(self):
"""Test _convert_value_schema_to_json_schema with enum values."""
schema = ValueSchema(val_type="string", enum=["a", "b", "c"])
result = _convert_value_schema_to_json_schema(schema)
assert result["type"] == "string"
assert result["enum"] == ["a", "b", "c"]
def test_convert_input_parameters_empty_list(self):
"""Test _convert_input_parameters_to_json_schema with empty parameters."""
result = _convert_input_parameters_to_json_schema([])
assert result["type"] == "object"
assert result["properties"] == {}
assert result["additionalProperties"] is False
assert "required" not in result
def test_convert_input_parameters_with_required_and_optional(self):
"""Test _convert_input_parameters_to_json_schema with mixed parameters."""
params = [
InputParameter(
name="required_param",
required=True,
description="Required parameter",
value_schema=ValueSchema(val_type="string"),
),
InputParameter(
name="optional_param",
required=False,
description="Optional parameter",
value_schema=ValueSchema(val_type="integer"),
),
]
result = _convert_input_parameters_to_json_schema(params)
assert result["type"] == "object"
assert result["additionalProperties"] is False
assert set(result["required"]) == {"required_param", "optional_param"}
# Required parameter should have single type
assert result["properties"]["required_param"]["type"] == "string"
# Optional parameter should have union type with null
assert result["properties"]["optional_param"]["type"] == ["integer", "null"]