| name | code-instrumentation-generator |
| description | Automatically instruments source code to collect runtime information such as function calls, branch decisions, variable values, and execution traces while preserving original program semantics. Use when users need to: (1) Add logging or tracing to code for debugging, (2) Collect runtime execution data for analysis, (3) Monitor function calls and control flow, (4) Track variable values during execution, (5) Generate execution traces for testing or profiling. Supports Python, Java, JavaScript, and C/C++ with configurable instrumentation levels. |
Code Instrumentation Generator
Automatically instrument source code to collect runtime information while preserving program semantics.
Workflow
Follow these steps to instrument code:
1. Analyze the Source Code
Understand the code structure and identify instrumentation points:
- Language detection: Identify the programming language
- Code structure: Parse functions, classes, branches, loops
- Entry/exit points: Locate function boundaries
- Control flow: Identify branches (if/else, switch, loops)
- Variable scope: Understand variable declarations and usage
2. Determine Instrumentation Strategy
Choose appropriate instrumentation based on requirements:
Instrumentation levels:
- Function-level: Entry/exit of functions with parameters and return values
- Branch-level: Execution of conditional branches (if/else, switch cases)
- Statement-level: Individual statement execution
- Variable-level: Variable assignments and value changes
Configuration options:
- Enable/disable specific instrumentation types
- Filter by function names or file patterns
- Set verbosity level
- Choose output format (logs, JSON, CSV)
3. Insert Instrumentation Code
Add instrumentation hooks at identified points:
Function instrumentation:
- Insert entry hook at function start
- Capture function name, parameters, timestamp
- Insert exit hook before returns
- Capture return value, execution time
Branch instrumentation:
- Insert hooks at branch conditions
- Record which branch was taken
- Track branch coverage
Variable instrumentation:
- Insert hooks after variable assignments
- Capture variable name and value
- Track value changes over time
4. Ensure Semantic Preservation
Verify that instrumentation doesn't change program behavior:
- No side effects: Instrumentation code doesn't modify program state
- Exception safety: Instrumentation handles exceptions properly
- Performance: Minimal overhead added
- Thread safety: Instrumentation is safe in concurrent code
5. Generate Output
Provide instrumented code and documentation:
- Instrumented source code: Modified code with instrumentation
- Probe description: Documentation of inserted instrumentation points
- Configuration file: Settings to enable/disable instrumentation
- Usage instructions: How to run and collect data
Language-Specific Patterns
Python
def calculate_sum(a, b):
result = a + b
return result
import logging
logging.basicConfig(level=logging.INFO)
def calculate_sum(a, b):
logging.info(f"ENTER calculate_sum(a={a}, b={b})")
result = a + b
logging.info(f"VAR result={result}")
logging.info(f"EXIT calculate_sum() -> {result}")
return result
Java
public int calculateSum(int a, int b) {
int result = a + b;
return result;
}
public int calculateSum(int a, int b) {
System.out.println("ENTER calculateSum(a=" + a + ", b=" + b + ")");
int result = a + b;
System.out.println("VAR result=" + result);
System.out.println("EXIT calculateSum() -> " + result);
return result;
}
JavaScript
function calculateSum(a, b) {
const result = a + b;
return result;
}
function calculateSum(a, b) {
console.log(`ENTER calculateSum(a=${a}, b=${b})`);
const result = a + b;
console.log(`VAR result=${result}`);
console.log(`EXIT calculateSum() -> ${result}`);
return result;
}
C/C++
int calculate_sum(int a, int b) {
int result = a + b;
return result;
}
#include <stdio.h>
int calculate_sum(int a, int b) {
printf("ENTER calculate_sum(a=%d, b=%d)\n", a, b);
int result = a + b;
printf("VAR result=%d\n", result);
printf("EXIT calculate_sum() -> %d\n", result);
return result;
}
Branch Instrumentation Example
def check_value(x):
if x > 0:
return "positive"
else:
return "non-positive"
def check_value(x):
logging.info(f"ENTER check_value(x={x})")
if x > 0:
logging.info("BRANCH if(x > 0) -> TRUE")
result = "positive"
else:
logging.info("BRANCH if(x > 0) -> FALSE")
result = "non-positive"
logging.info(f"EXIT check_value() -> {result}")
return result
Configuration-Based Instrumentation
Generate a configuration file to control instrumentation:
INSTRUMENTATION_ENABLED = True
INSTRUMENT_FUNCTIONS = True
INSTRUMENT_BRANCHES = True
INSTRUMENT_VARIABLES = False
LOG_LEVEL = "INFO"
OUTPUT_FORMAT = "text"
import instrumentation_config as config
def calculate_sum(a, b):
if config.INSTRUMENT_FUNCTIONS:
logging.info(f"ENTER calculate_sum(a={a}, b={b})")
result = a + b
if config.INSTRUMENT_VARIABLES:
logging.info(f"VAR result={result}")
if config.INSTRUMENT_FUNCTIONS:
logging.info(f"EXIT calculate_sum() -> {result}")
return result
Output Format
Probe Description Document
## Instrumentation Report
**File**: calculator.py
**Instrumentation Date**: 2024-02-17
**Configuration**: Function-level + Branch-level
### Instrumented Functions
1. **calculate_sum(a, b)**
- Entry probe: Line 3
- Exit probe: Line 8
- Captures: Parameters (a, b), return value
2. **check_value(x)**
- Entry probe: Line 11
- Branch probe: Line 14 (if x > 0)
- Exit probe: Line 19
- Captures: Parameter (x), branch decision, return value
### Instrumentation Statistics
- Total functions instrumented: 2
- Total branches instrumented: 1
- Total variables instrumented: 0
- Estimated overhead: <5%
### Usage
Run the instrumented code normally. Instrumentation output will be written to:
- Console (stdout)
- Log file: instrumentation.log (if configured)
Best Practices
- Minimize overhead: Only instrument what's necessary
- Use conditional compilation: Allow disabling instrumentation in production
- Handle exceptions: Ensure instrumentation doesn't crash the program
- Preserve semantics: Never modify program logic
- Thread-safe logging: Use thread-safe logging mechanisms
- Structured output: Use consistent format for easy parsing
- Timestamp everything: Include timestamps for temporal analysis
Advanced Features
Selective Instrumentation
INSTRUMENTED_FUNCTIONS = ["calculate_sum", "process_data"]
def should_instrument(func_name):
return func_name in INSTRUMENTED_FUNCTIONS
if should_instrument("calculate_sum"):
pass
Performance Monitoring
import time
def calculate_sum(a, b):
start_time = time.time()
logging.info(f"ENTER calculate_sum(a={a}, b={b})")
result = a + b
elapsed = time.time() - start_time
logging.info(f"EXIT calculate_sum() -> {result} [time={elapsed:.6f}s]")
return result
JSON Output Format
import json
import time
def calculate_sum(a, b):
entry_event = {
"type": "function_entry",
"function": "calculate_sum",
"params": {"a": a, "b": b},
"timestamp": time.time()
}
print(json.dumps(entry_event))
result = a + b
exit_event = {
"type": "function_exit",
"function": "calculate_sum",
"return_value": result,
"timestamp": time.time()
}
print(json.dumps(exit_event))
return result
Constraints
- Preserve semantics: Never change program behavior
- Minimal overhead: Keep instrumentation lightweight
- No side effects: Instrumentation shouldn't modify program state
- Exception safety: Handle errors gracefully
- Configurable: Allow enabling/disabling instrumentation