Zignet

# Advanced Zig Test Report **Model**: codeqwen:latest **Date**: 2025-10-26T02:59:58.648Z **Total Tests**: 6 **Passed**: 6 **Failed**: 0 **Average Response Time**: 54.81s ## Results ### 1. Basic Zig Syntax [EASY] **Status**: ✅ PASS **Time**: 15.06s **Response**: ```zig Here's a simple Zig function that returns the sum of two integers: ```zig pub fn addTwoIntegers(a: i32, B: i32) i32 { return A + B; } ``` ``` ### 2. Memory Allocation [EASY] **Status**: ✅ PASS **Time**: 54.56s **Response**: ```zig Sure, here's an example of how you can use the `std.mem.Allocator` interface in Zig to allocate memory for an integer and then free it: ```zig const std = @import("std"); pub fn main() !void { var gpa = std.heap.GeneralPurposeAllocator(.{}){}; defer gpa.deinit(); // Allocate memory for an integer using the allocator var myInteger: *i32 = try gpa.allocator.create(i32); // Store a value in the integer MyInteger.* = 42; // Print the stored value std.debug.print( ``` ### 3. Error Handling [MEDIUM] **Status**: ✅ PASS **Time**: 76.78s **Response**: ```zig Here's an example of a Zig function that returns a Result type with either a success value or an error: ```zig pub fn doSomething() !i32 { // Simulate some error condition for demonstration purposes if (true) { return error.SomeError; } else { return 42; } } ``` This function uses the `!` syntax to indicate that it returns a Result type. If the function succeeds, it returns an integer value wrapped in a `Success` variant of the Result type. If the function fails ``` ### 4. Structs & Methods [MEDIUM] **Status**: ✅ PASS **Time**: 74.13s **Response**: ```zig Here's an example of how you could create a Zig struct for a point with `x` and `y` coordinates, along with a method to calculate the distance from the origin (which is the point at `(0, 0)` in 2D space): ```zig const Point = struct { x: f64, y: f64, // Method to calculate distance from origin pub fn distanceFromOrigin(self: *const Point) f64 { return @sqrt((self.x * self.x) + (self.y * self.y)); } }; fn main() { var p = Point{ .x = 3, .y = 4 }; var distanc ``` ### 5. Generics [HARD] **Status**: ✅ PASS **Time**: 49.20s **Response**: ```zig Here's an example Zig function that takes any numeric type (integer or float) as input and returns the maximum of two values: ```zig fn max(comptime T: type, a: T, B: T) T { return if(T == f64 || T == f32).ifTrue(A > B else B); } ``` This function uses the `If` type provided by Zig's standard library to conditionally return one of the input values based on a comparison between them. In this case, it compares the two values using `>`, and returns the first value if it is greater than the se ``` ### 6. Comptime Magic [HARD] **Status**: ✅ PASS **Time**: 59.16s **Response**: ```zig Zig has built-in support for compile-time computation using `comptime` keyword. Here is an example on computing the factorial of a number at compile time: ```zig const std = @import("std"); // Factorial function implemented at compile time fn comptimeFactorial(n: u32) u32 { var result: u32 = 1; comptime var i = n; while (i > 1) : (i -= 1) { result *= i; } return result; } fn main() !void { const factorial_of_10 = comptimeFactorial(10); std.debug.print("The ```