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C: add test for map

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C++: add tests for primitive types, stl types, user-defined type
This commit is contained in:
Kazuki Ohta
2009-08-26 11:28:54 +09:00
parent 9374571056
commit c94772104d
2 changed files with 482 additions and 20 deletions
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455
cpp/test.cpp
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@@ -1,24 +1,443 @@
#include "msgpack.hpp"
#include <math.h>
#include <string>
#include <vector>
#include <map>
#include <deque>
#include <set>
#include <list>
#include <gtest/gtest.h>
TEST(MSGPACKC, simple_buffer)
using namespace std;
const unsigned int kLoop = 10000;
const unsigned int kElements = 100;
const double kEPS = 1e-10;
#define GEN_TEST(test_type) \
do { \
vector<test_type> v; \
v.push_back(0); \
v.push_back(1); \
v.push_back(2); \
v.push_back(numeric_limits<test_type>::min()); \
v.push_back(numeric_limits<test_type>::max()); \
for (unsigned int i = 0; i < kLoop; i++) \
v.push_back(rand()); \
for (unsigned int i = 0; i < v.size() ; i++) { \
msgpack::sbuffer sbuf; \
test_type val1 = v[i]; \
msgpack::pack(sbuf, val1); \
msgpack::zone z; \
msgpack::object obj; \
msgpack::unpack_return ret = \
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj); \
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS); \
test_type val2; \
obj.convert(&val2); \
EXPECT_EQ(val1, val2); \
} \
} while(0)
TEST(MSGPACK, simple_buffer_short)
{
msgpack::sbuffer sbuf;
int v = 0;
msgpack::pack(sbuf, v);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
obj.convert(&v);
EXPECT_EQ(0, v);
GEN_TEST(short);
}
TEST(MSGPACK, simple_buffer_int)
{
GEN_TEST(int);
}
TEST(MSGPACK, simple_buffer_long)
{
GEN_TEST(long);
}
TEST(MSGPACK, simple_buffer_long_long)
{
GEN_TEST(long long);
}
TEST(MSGPACK, simple_buffer_unsigned_short)
{
GEN_TEST(unsigned short);
}
TEST(MSGPACK, simple_buffer_unsigned_int)
{
GEN_TEST(unsigned int);
}
TEST(MSGPACK, simple_buffer_unsigned_long)
{
GEN_TEST(unsigned long);
}
TEST(MSGPACK, simple_buffer_unsigned_long_long)
{
GEN_TEST(unsigned long long);
}
TEST(MSGPACK, simple_buffer_uint8)
{
GEN_TEST(uint8_t);
}
TEST(MSGPACK, simple_buffer_uint16)
{
GEN_TEST(uint16_t);
}
TEST(MSGPACK, simple_buffer_uint32)
{
GEN_TEST(uint32_t);
}
TEST(MSGPACK, simple_buffer_uint64)
{
GEN_TEST(uint64_t);
}
TEST(MSGPACK, simple_buffer_int8)
{
GEN_TEST(int8_t);
}
TEST(MSGPACK, simple_buffer_int16)
{
GEN_TEST(int16_t);
}
TEST(MSGPACK, simple_buffer_int32)
{
GEN_TEST(int32_t);
}
TEST(MSGPACK, simple_buffer_int64)
{
GEN_TEST(int64_t);
}
TEST(MSGPACK, simple_buffer_float)
{
vector<float> v;
v.push_back(0);
v.push_back(1);
v.push_back(2);
v.push_back(numeric_limits<float>::min());
v.push_back(numeric_limits<float>::max());
v.push_back(nanf("tag"));
v.push_back(1.0/0.0); // inf
for (unsigned int i = 0; i < kLoop; i++)
v.push_back(drand48());
for (unsigned int i = 0; i < v.size() ; i++) {
msgpack::sbuffer sbuf;
float val1 = v[i];
msgpack::pack(sbuf, val1);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
float val2;
obj.convert(&val2);
if (isnan(val1))
EXPECT_TRUE(isnan(val2));
else if (isinf(val1))
EXPECT_TRUE(isinf(val2));
else
EXPECT_TRUE(fabs(val2 - val1) <= kEPS);
}
}
TEST(MSGPACK, simple_buffer_double)
{
vector<double> v;
v.push_back(0);
v.push_back(1);
v.push_back(2);
v.push_back(numeric_limits<double>::min());
v.push_back(numeric_limits<double>::max());
v.push_back(nanf("tag"));
v.push_back(1.0/0.0); // inf
for (unsigned int i = 0; i < kLoop; i++)
v.push_back(drand48());
for (unsigned int i = 0; i < v.size() ; i++) {
msgpack::sbuffer sbuf;
double val1 = v[i];
msgpack::pack(sbuf, val1);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
double val2;
obj.convert(&val2);
if (isnan(val1))
EXPECT_TRUE(isnan(val2));
else if (isinf(val1))
EXPECT_TRUE(isinf(val2));
else
EXPECT_TRUE(fabs(val2 - val1) <= kEPS);
}
}
TEST(MSGPACK, simple_buffer_true)
{
msgpack::sbuffer sbuf;
bool val1 = true;
msgpack::pack(sbuf, val1);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
bool val2;
obj.convert(&val2);
EXPECT_EQ(val1, val2);
}
TEST(MSGPACK, simple_buffer_false)
{
msgpack::sbuffer sbuf;
bool val1 = false;
msgpack::pack(sbuf, val1);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
bool val2;
obj.convert(&val2);
EXPECT_EQ(val1, val2);
}
//-----------------------------------------------------------------------------
TEST(MSGPACK_STL, simple_buffer_string)
{
for (unsigned int k = 0; k < kLoop; k++) {
string val1;
for (unsigned int i = 0; i < kElements; i++)
val1 += 'a' + rand() % 26;
msgpack::sbuffer sbuf;
msgpack::pack(sbuf, val1);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
string val2;
obj.convert(&val2);
EXPECT_EQ(val1.size(), val2.size());
EXPECT_EQ(val1, val2);
}
}
TEST(MSGPACK_STL, simple_buffer_vector)
{
for (unsigned int k = 0; k < kLoop; k++) {
vector<int> val1;
for (unsigned int i = 0; i < kElements; i++)
val1.push_back(rand());
msgpack::sbuffer sbuf;
msgpack::pack(sbuf, val1);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
vector<int> val2;
obj.convert(&val2);
EXPECT_EQ(val1.size(), val2.size());
EXPECT_TRUE(equal(val1.begin(), val1.end(), val2.begin()));
}
}
TEST(MSGPACK_STL, simple_buffer_map)
{
for (unsigned int k = 0; k < kLoop; k++) {
map<int, int> val1;
for (unsigned int i = 0; i < kElements; i++)
val1[rand()] = rand();
msgpack::sbuffer sbuf;
msgpack::pack(sbuf, val1);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
map<int, int> val2;
obj.convert(&val2);
EXPECT_EQ(val1.size(), val2.size());
EXPECT_TRUE(equal(val1.begin(), val1.end(), val2.begin()));
}
}
TEST(MSGPACK_STL, simple_buffer_deque)
{
for (unsigned int k = 0; k < kLoop; k++) {
deque<int> val1;
for (unsigned int i = 0; i < kElements; i++)
val1.push_back(rand());
msgpack::sbuffer sbuf;
msgpack::pack(sbuf, val1);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
deque<int> val2;
obj.convert(&val2);
EXPECT_EQ(val1.size(), val2.size());
EXPECT_TRUE(equal(val1.begin(), val1.end(), val2.begin()));
}
}
TEST(MSGPACK_STL, simple_buffer_list)
{
for (unsigned int k = 0; k < kLoop; k++) {
list<int> val1;
for (unsigned int i = 0; i < kElements; i++)
val1.push_back(rand());
msgpack::sbuffer sbuf;
msgpack::pack(sbuf, val1);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
list<int> val2;
obj.convert(&val2);
EXPECT_EQ(val1.size(), val2.size());
EXPECT_TRUE(equal(val1.begin(), val1.end(), val2.begin()));
}
}
TEST(MSGPACK_STL, simple_buffer_set)
{
for (unsigned int k = 0; k < kLoop; k++) {
set<int> val1;
for (unsigned int i = 0; i < kElements; i++)
val1.insert(rand());
msgpack::sbuffer sbuf;
msgpack::pack(sbuf, val1);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
set<int> val2;
obj.convert(&val2);
EXPECT_EQ(val1.size(), val2.size());
EXPECT_TRUE(equal(val1.begin(), val1.end(), val2.begin()));
}
}
TEST(MSGPACK_STL, simple_buffer_pair)
{
for (unsigned int k = 0; k < kLoop; k++) {
pair<int, int> val1 = make_pair(rand(), rand());
msgpack::sbuffer sbuf;
msgpack::pack(sbuf, val1);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
pair<int, int> val2;
obj.convert(&val2);
EXPECT_EQ(val1.first, val2.first);
EXPECT_EQ(val1.second, val2.second);
}
}
class TestClass
{
public:
TestClass() : i(0), s("kzk") {}
int i;
string s;
MSGPACK_DEFINE(i, s);
};
TEST(MSGPACK_USER_DEFINED, simple_buffer_class)
{
for (unsigned int k = 0; k < kLoop; k++) {
TestClass val1;
msgpack::sbuffer sbuf;
msgpack::pack(sbuf, val1);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
TestClass val2;
val2.i = -1;
val2.s = "";
obj.convert(&val2);
EXPECT_EQ(val1.i, val2.i);
EXPECT_EQ(val1.s, val2.s);
}
}
class TestClass2
{
public:
TestClass2() : i(0), s("kzk") {
for (unsigned int i = 0; i < kElements; i++)
v.push_back(rand());
}
int i;
string s;
vector<int> v;
MSGPACK_DEFINE(i, s, v);
};
TEST(MSGPACK_USER_DEFINED, simple_buffer_class_old_to_new)
{
for (unsigned int k = 0; k < kLoop; k++) {
TestClass val1;
msgpack::sbuffer sbuf;
msgpack::pack(sbuf, val1);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
TestClass2 val2;
val2.i = -1;
val2.s = "";
val2.v = vector<int>();
obj.convert(&val2);
EXPECT_EQ(val1.i, val2.i);
EXPECT_EQ(val1.s, val2.s);
EXPECT_FALSE(val2.s.empty());
}
}
TEST(MSGPACK_USER_DEFINED, simple_buffer_class_new_to_old)
{
for (unsigned int k = 0; k < kLoop; k++) {
TestClass2 val1;
msgpack::sbuffer sbuf;
msgpack::pack(sbuf, val1);
msgpack::zone z;
msgpack::object obj;
msgpack::unpack_return ret =
msgpack::unpack(sbuf.data(), sbuf.size(), NULL, &z, &obj);
EXPECT_EQ(ret, msgpack::UNPACK_SUCCESS);
TestClass val2;
val2.i = -1;
val2.s = "";
obj.convert(&val2);
EXPECT_EQ(val1.i, val2.i);
EXPECT_EQ(val1.s, val2.s);
EXPECT_FALSE(val2.s.empty());
}
}