fix: CodeQL warnings (#1827)

* fix: CodeQL warnings * clang-format and clang-tidy fixes for 4d357c46 * clang-format and clang-tidy fixes for 72322fb7 * accept suggestion * clang-format and clang-tidy fixes for 9a4dc07c Co-authored-by: David Leal <halfpacho@gmail.com> Co-authored-by: github-actions <${GITHUB_ACTOR}@users.noreply.github.com> Co-authored-by: Ayaan Khan <ayaankhan98@gmail.com>
2023-10-11 13:05:55 +08:00 · 2021-11-08 02:49:33 +09:00 · 2021-11-08 02:49:33 +09:00 · e64e3df18f
commit e64e3df18f
parent b98dcdfd08
7 changed files with 65 additions and 66 deletions
--- a/ciphers/uint128_t.hpp
+++ b/ciphers/uint128_t.hpp
@ -462,7 +462,7 @@ class uint128_t {
        tmp <<= left;
        uint128_t quotient(0);
        uint128_t zero(0);
-        while (left >= 0 && tmp2 >= p) {
+        while (tmp2 >= p) {
            uint16_t shf = tmp2._lez() - tmp._lez();
            if (shf) {
                tmp >>= shf;
--- a/ciphers/uint256_t.hpp
+++ b/ciphers/uint256_t.hpp
@ -429,7 +429,7 @@ class uint256_t {
        tmp <<= left;
        uint256_t quotient(0);
        uint256_t zero(0);
-        while (left >= 0 && tmp2 >= p) {
+        while (tmp2 >= p) {
            uint16_t shf = tmp2._lez() - tmp._lez();
            if (shf) {
                tmp >>= shf;
--- a/data_structures/reverse_a_linked_list.cpp
+++ b/data_structures/reverse_a_linked_list.cpp
@ -121,12 +121,10 @@ void list::reverseList() {
 * @returns the top element of the list
 */
 int32_t list::top() {
-    try {
-        if (!isEmpty()) {
-            return head->val;
-        }
-    } catch (const std::exception &e) {
-        std::cerr << "List is empty" << e.what() << '\n';
+    if (!isEmpty()) {
+        return head->val;
+    } else {
+        throw std::logic_error("List is empty");
    }
 }
 /**
@ -134,16 +132,14 @@ int32_t list::top() {
 *  @returns the last element of the list
 */
 int32_t list::last() {
-    try {
-        if (!isEmpty()) {
-            Node *t = head;
-            while (t->next != nullptr) {
-                t = t->next;
-            }
-            return t->val;
+    if (!isEmpty()) {
+        Node *t = head;
+        while (t->next != nullptr) {
+            t = t->next;
        }
-    } catch (const std::exception &e) {
-        std::cerr << "List is empty" << e.what() << '\n';
+        return t->val;
+    } else {
+        throw std::logic_error("List is empty");
    }
 }
 /**
@ -164,7 +160,7 @@ int32_t list::traverse(int index) {

    /* if we get to this line,the caller was asking for a non-existent element
    so we assert fail */
-    assert(0);
+    exit(1);
 }

 }  // namespace linked_list
--- a/numerical_methods/babylonian_method.cpp
+++ b/numerical_methods/babylonian_method.cpp
@ -9,11 +9,10 @@
 * @author [Ameya Chawla](https://github.com/ameyachawlaggsipu)
 */

-#include <cassert>   /// for assert
+#include <cassert>  /// for assert
+#include <cmath>
 #include <iostream>  /// for IO operations

-#include "math.h"
-
 /**
 * @namespace numerical_methods
 * @brief Numerical algorithms/methods
--- a/numerical_methods/composite_simpson_rule.cpp
+++ b/numerical_methods/composite_simpson_rule.cpp
@ -35,8 +35,9 @@
 *
 */

-#include <cassert>     /// for assert
-#include <cmath>       /// for math functions
+#include <cassert>  /// for assert
+#include <cmath>    /// for math functions
+#include <cmath>
 #include <cstdint>     /// for integer allocation
 #include <cstdlib>     /// for std::atof
 #include <functional>  /// for std::function
@ -64,13 +65,13 @@ namespace simpson_method {
 * @returns the result of the integration
 */
 double evaluate_by_simpson(std::int32_t N, double h, double a,
-                           std::function<double(double)> func) {
+                           const std::function<double(double)>& func) {
    std::map<std::int32_t, double>
        data_table;  // Contains the data points. key: i, value: f(xi)
    double xi = a;   // Initialize xi to the starting point x0 = a

    // Create the data table
-    double temp;
+    double temp = NAN;
    for (std::int32_t i = 0; i <= N; i++) {
        temp = func(xi);
        data_table.insert(
@ -82,12 +83,13 @@ double evaluate_by_simpson(std::int32_t N, double h, double a,
    // Remember: f(x0) + 4*f(x1) + 2*f(x2) + ... + 2*f(xN-2) + 4*f(xN-1) + f(xN)
    double evaluate_integral = 0;
    for (std::int32_t i = 0; i <= N; i++) {
-        if (i == 0 || i == N)
+        if (i == 0 || i == N) {
            evaluate_integral += data_table.at(i);
-        else if (i % 2 == 1)
+        } else if (i % 2 == 1) {
            evaluate_integral += 4 * data_table.at(i);
-        else
+        } else {
            evaluate_integral += 2 * data_table.at(i);
+        }
    }

    // Multiply by the coefficient h/3
@ -170,7 +172,7 @@ int main(int argc, char** argv) {
                          /// interval. MUST BE EVEN
    double a = 1, b = 3;  /// Starting and ending point of the integration in
                          /// the real axis
-    double h;             /// Step, calculated by a, b and N
+    double h = NAN;       /// Step, calculated by a, b and N

    bool used_argv_parameters =
        false;  // If argv parameters are used then the assert must be omitted
@ -180,18 +182,20 @@ int main(int argc, char** argv) {
    // displaying messages)
    if (argc == 4) {
        N = std::atoi(argv[1]);
-        a = (double)std::atof(argv[2]);
-        b = (double)std::atof(argv[3]);
+        a = std::atof(argv[2]);
+        b = std::atof(argv[3]);
        // Check if a<b else abort
        assert(a < b && "a has to be less than b");
        assert(N > 0 && "N has to be > 0");
-        if (N < 16 || a != 1 || b != 3)
+        if (N < 16 || a != 1 || b != 3) {
            used_argv_parameters = true;
+        }
        std::cout << "You selected N=" << N << ", a=" << a << ", b=" << b
                  << std::endl;
-    } else
+    } else {
        std::cout << "Default N=" << N << ", a=" << a << ", b=" << b
                  << std::endl;
+    }

    // Find the step
    h = (b - a) / N;
--- a/numerical_methods/fast_fourier_transform.cpp
+++ b/numerical_methods/fast_fourier_transform.cpp
@ -6,7 +6,8 @@
 * discrete Fourier transform (DFT) of a sequence, or its inverse (IDFT).
 * @details
 * This
- * algorithm has application in use case scenario where a user wants to find points of a
+ * algorithm has application in use case scenario where a user wants to find
+ points of a
 * function
 * in a short time by just using the coefficients of the polynomial
 * function.
@ -56,8 +57,9 @@ std::complex<double> *FastFourierTransform(std::complex<double> *p, uint8_t n) {
        if (j % 2 == 0) {
            pe[k1++] = p[j];  /// Assigning values of even Coefficients

-        } else
+        } else {
            po[k2++] = p[j];  /// Assigning value of odd Coefficients
+        }
    }

    std::complex<double> *ye =
@ -80,11 +82,9 @@ std::complex<double> *FastFourierTransform(std::complex<double> *p, uint8_t n) {
        k2++;
    }

-    if(n!=2){
-     
+    if (n != 2) {
        delete[] pe;
        delete[] po;
-        
    }

    delete[] ye;  /// Deleting dynamic array ye
@ -123,9 +123,11 @@ static void test() {
        {10, 0}, {-2, -2}, {-2, 0}, {-2, 2}};  /// True Answer for test case 2

    std::complex<double> *o1 = numerical_methods::FastFourierTransform(t1, n1);
-    std::complex<double> *t3=o1;  /// Temporary variable used to delete memory location of o1
+    std::complex<double> *t3 =
+        o1;  /// Temporary variable used to delete memory location of o1
    std::complex<double> *o2 = numerical_methods::FastFourierTransform(t2, n2);
-    std::complex<double> *t4=o2; /// Temporary variable used to delete memory location of o2
+    std::complex<double> *t4 =
+        o2;  /// Temporary variable used to delete memory location of o2
    for (uint8_t i = 0; i < n1; i++) {
        assert((r1[i].real() - o1->real() < 0.000000000001) &&
               (r1[i].imag() - o1->imag() <
@ -142,7 +144,6 @@ static void test() {
        o2++;
    }

-    
    delete[] t1;
    delete[] t2;
    delete[] t3;
@ -160,6 +161,6 @@ static void test() {

 int main(int argc, char const *argv[]) {
    test();  //  run self-test implementations
-              //  with 2 defined test cases
+             //  with 2 defined test cases
    return 0;
 }
--- a/numerical_methods/inverse_fast_fourier_transform.cpp
+++ b/numerical_methods/inverse_fast_fourier_transform.cpp
@ -4,10 +4,10 @@
 * (IFFT)](https://www.geeksforgeeks.org/python-inverse-fast-fourier-transformation/)
 * is an algorithm that computes the inverse fourier transform.
 * @details
- * This algorithm has an application in use case scenario where a user wants find coefficients of
- * a function in a short time by just using points generated by DFT.
- * Time complexity
- * this algorithm computes the IDFT in O(nlogn) time in comparison to traditional O(n^2).
+ * This algorithm has an application in use case scenario where a user wants
+ * find coefficients of a function in a short time by just using points
+ * generated by DFT. Time complexity this algorithm computes the IDFT in
+ * O(nlogn) time in comparison to traditional O(n^2).
 * @author [Ameya Chawla](https://github.com/ameyachawlaggsipu)
 */

@ -23,14 +23,15 @@
 */
 namespace numerical_methods {
 /**
- * @brief InverseFastFourierTransform is a recursive function which returns list of
- * complex numbers
+ * @brief InverseFastFourierTransform is a recursive function which returns list
+ * of complex numbers
 * @param p List of Coefficents in form of complex numbers
 * @param n Count of elements in list p
 * @returns p if n==1
 * @returns y if n!=1
 */
-std::complex<double> *InverseFastFourierTransform(std::complex<double> *p, uint8_t n) {
+std::complex<double> *InverseFastFourierTransform(std::complex<double> *p,
+                                                  uint8_t n) {
    if (n == 1) {
        return p;  /// Base Case To return
    }
@ -40,8 +41,8 @@ std::complex<double> *InverseFastFourierTransform(std::complex<double> *p, uint8
    std::complex<double> om = std::complex<double>(
        cos(2 * pi / n), sin(2 * pi / n));  /// Calculating value of omega

-    om.real(om.real()/n); /// One change in comparison with DFT
-    om.imag(om.imag()/n); /// One change in comparison with DFT
+    om.real(om.real() / n);  /// One change in comparison with DFT
+    om.imag(om.imag() / n);  /// One change in comparison with DFT

    auto *pe = new std::complex<double>[n / 2];  /// Coefficients of even power

@ -52,8 +53,9 @@ std::complex<double> *InverseFastFourierTransform(std::complex<double> *p, uint8
        if (j % 2 == 0) {
            pe[k1++] = p[j];  /// Assigning values of even Coefficients

-        } else
+        } else {
            po[k2++] = p[j];  /// Assigning value of odd Coefficients
+        }
    }

    std::complex<double> *ye =
@ -76,11 +78,9 @@ std::complex<double> *InverseFastFourierTransform(std::complex<double> *p, uint8
        k2++;
    }

-    if(n!=2){
-     
+    if (n != 2) {
        delete[] pe;
        delete[] po;
-        
    }

    delete[] ye;  /// Deleting dynamic array ye
@ -118,16 +118,17 @@ static void test() {
    std::vector<std::complex<double>> r2 = {
        {1, 0}, {2, 0}, {3, 0}, {4, 0}};  /// True Answer for test case 2

-    std::complex<double> *o1 = numerical_methods::InverseFastFourierTransform(t1, n1);
+    std::complex<double> *o1 =
+        numerical_methods::InverseFastFourierTransform(t1, n1);

-    std::complex<double> *o2 = numerical_methods::InverseFastFourierTransform(t2, n2);
+    std::complex<double> *o2 =
+        numerical_methods::InverseFastFourierTransform(t2, n2);

    for (uint8_t i = 0; i < n1; i++) {
        assert((r1[i].real() - o1[i].real() < 0.000000000001) &&
               (r1[i].imag() - o1[i].imag() <
                0.000000000001));  /// Comparing for both real and imaginary
                                   /// values for test case 1
-        
    }

    for (uint8_t i = 0; i < n2; i++) {
@ -135,10 +136,8 @@ static void test() {
               (r2[i].imag() - o2[i].imag() <
                0.000000000001));  /// Comparing for both real and imaginary
                                   /// values for test case 2
-        
    }

-    
    delete[] t1;
    delete[] t2;
    delete[] o1;