llvm-project/clang/test/Analysis/out-of-bounds-new.cpp

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// RUN: %clang_analyze_cc1 -std=c++11 -Wno-array-bounds -analyzer-checker=unix,core,alpha.security.ArrayBoundV2 -verify %s
// Tests doing an out-of-bounds access after the end of an array using:
// - constant integer index
// - constant integer size for buffer
void test1(int x) {
int *buf = new int[100];
buf[100] = 1; // expected-warning{{Out of bound memory access}}
}
void test1_ok(int x) {
int *buf = new int[100];
buf[99] = 1; // no-warning
}
// Tests doing an out-of-bounds access after the end of an array using:
// - indirect pointer to buffer
// - constant integer index
// - constant integer size for buffer
void test1_ptr(int x) {
int *buf = new int[100];
int *p = buf;
p[101] = 1; // expected-warning{{Out of bound memory access}}
}
void test1_ptr_ok(int x) {
int *buf = new int[100];
int *p = buf;
p[99] = 1; // no-warning
}
// Tests doing an out-of-bounds access before the start of an array using:
// - indirect pointer to buffer, manipulated using simple pointer arithmetic
// - constant integer index
// - constant integer size for buffer
void test1_ptr_arith(int x) {
int *buf = new int[100];
int *p = buf;
p = p + 100;
p[0] = 1; // expected-warning{{Out of bound memory access}}
}
void test1_ptr_arith_ok(int x) {
int *buf = new int[100];
int *p = buf;
p = p + 99;
p[0] = 1; // no-warning
}
void test1_ptr_arith_bad(int x) {
int *buf = new int[100];
int *p = buf;
p = p + 99;
p[1] = 1; // expected-warning{{Out of bound memory access}}
}
void test1_ptr_arith_ok2(int x) {
int *buf = new int[100];
int *p = buf;
p = p + 99;
p[-1] = 1; // no-warning
}
// Tests doing an out-of-bounds access before the start of an array using:
// - constant integer index
// - constant integer size for buffer
void test2(int x) {
int *buf = new int[100];
buf[-1] = 1; // expected-warning{{Out of bound memory access}}
}
// Tests doing an out-of-bounds access before the start of an array using:
// - indirect pointer to buffer
// - constant integer index
// - constant integer size for buffer
void test2_ptr(int x) {
int *buf = new int[100];
int *p = buf;
p[-1] = 1; // expected-warning{{Out of bound memory access}}
}
// Tests doing an out-of-bounds access before the start of an array using:
// - indirect pointer to buffer, manipulated using simple pointer arithmetic
// - constant integer index
// - constant integer size for buffer
void test2_ptr_arith(int x) {
int *buf = new int[100];
int *p = buf;
--p;
p[0] = 1; // expected-warning {{Out of bound memory access (accessed memory precedes memory block)}}
}
// Tests under-indexing
// of a multi-dimensional array
void test2_multi(int x) {
auto buf = new int[100][100];
buf[0][-1] = 1; // expected-warning{{Out of bound memory access}}
}
// Tests under-indexing
// of a multi-dimensional array
void test2_multi_b(int x) {
auto buf = new int[100][100];
buf[-1][0] = 1; // expected-warning{{Out of bound memory access}}
}
// Tests over-indexing
// of a multi-dimensional array
void test2_multi_c(int x) {
auto buf = new int[100][100];
buf[100][0] = 1; // expected-warning{{Out of bound memory access}}
}
// Tests over-indexing
// of a multi-dimensional array
void test2_multi_2(int x) {
auto buf = new int[100][100];
buf[99][100] = 1; // expected-warning{{Out of bound memory access}}
}
// Tests normal access of
// a multi-dimensional array
void test2_multi_ok(int x) {
auto buf = new int[100][100];
buf[0][0] = 1; // no-warning
}
// Tests over-indexing using different types
// array
void test_diff_types(int x) {
int *buf = new int[10]; //10*sizeof(int) Bytes allocated
char *cptr = (char *)buf;
cptr[sizeof(int) * 9] = 1; // no-warning
cptr[sizeof(int) * 10] = 1; // expected-warning{{Out of bound memory access}}
}
// Tests over-indexing
//if the allocated area is non-array
void test_non_array(int x) {
int *ip = new int;
ip[0] = 1; // no-warning
ip[1] = 2; // expected-warning{{Out of bound memory access}}
}
//Tests over-indexing
//if the allocated area size is a runtime parameter
void test_dynamic_size(int s) {
int *buf = new int[s];
buf[0] = 1; // no-warning
}
//Tests complex arithmetic
//in new expression
void test_dynamic_size2(unsigned m,unsigned n){
unsigned *U = nullptr;
U = new unsigned[m + n + 1];
}