std::longjmp
| Defined in header <csetjmp>
|
||
| void longjmp( std::jmp_buf env, int status ); |
(until C++17) | |
| [[noreturn]] void longjmp( std::jmp_buf env, int status ); |
(since C++17) | |
Loads the execution context env saved by a previous call to setjmp. This function does not return. Control is transferred to the call site of the macro setjmp that set up env. That setjmp then returns the value, passed as the status.
If the function that called setjmp has exited, the behavior is undefined (in other words, only long jumps up the call stack are allowed)
No destructors for automatic objects are called. If replacing of std::longjmp with throw and setjmp with catch would execute a non-trivial destructor for any automatic object, the behavior of such std::longjmp is undefined.
Contents |
Parameters
| env | - | variable referring to the execution state of the program saved by setjmp |
| status | - | the value to return from setjmp. If it is equal to 0, 1 is used instead |
Return value
(none)
Notes
longjmp is the mechanism used in C to handle unexpected error conditions where the function cannot return meaningfully. C++ generally uses exception handling for this purpose.
Example
#include <array> #include <cmath> #include <csetjmp> #include <cstdlib> #include <format> #include <iostream> std::jmp_buf solver_error_handler; std::array<double, 2> solve_quadratic_equation(double a, double b, double c) { const double discriminant = b * b - 4.0 * a * c; if (discriminant < 0) std::longjmp(solver_error_handler, true); // Go to error handler const double delta = std::sqrt(discriminant) / (2.0 * a); const double argmin = -b / (2.0 * a); return {argmin - delta, argmin + delta}; } void show_quadratic_equation_solution(double a, double b, double c) { std::cout << std::format("Solving {}x² + {}x + {} = 0...\n", a, b, c); auto [x_0, x_1] = solve_quadratic_equation(a, b, c); std::cout << std::format("x₁ = {}, x₂ = {}\n\n", x_0, x_1); } int main() { if (setjmp(solver_error_handler)) { // Error handler for solver std::cout << "No real solution\n"; return EXIT_FAILURE; } for (auto [a, b, c] : {std::array{1, -3, 2}, {2, -3, -2}, {1, 2, 3}}) show_quadratic_equation_solution(a, b, c); return EXIT_SUCCESS; }
Output:
Solving 1x² + -3x + 2 = 0... x₁ = 1, x₂ = 2 Solving 2x² + -3x + -2 = 0... x₁ = -0.5, x₂ = 2 Solving 1x² + 2x + 3 = 0... No real solution
See also
| saves the context (function macro) | |
| C documentation for longjmp
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