blob: 9ff2e1b414539ddd0fc465dd3d262cd0a1f873eb [file] [log] [blame]
/* Copyright (c) 2024, Google Inc.
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
* SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION
* OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
* CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */
#include <gtest/gtest.h>
#include <openssl/aead.h>
#include <openssl/ssl.h>
#include "internal.h"
#if !defined(BORINGSSL_SHARED_LIBRARY)
BSSL_NAMESPACE_BEGIN
namespace {
TEST(ArrayTest, InitValueConstructs) {
Array<uint8_t> array;
ASSERT_TRUE(array.Init(10));
EXPECT_EQ(array.size(), 10u);
for (size_t i = 0; i < 10u; i++) {
EXPECT_EQ(0u, array[i]);
}
}
TEST(ArrayDeathTest, BoundsChecks) {
Array<int> array;
const int v[] = {1, 2, 3, 4};
ASSERT_TRUE(array.CopyFrom(v));
EXPECT_DEATH_IF_SUPPORTED(array[4], "");
}
TEST(VectorTest, Resize) {
Vector<size_t> vec;
ASSERT_TRUE(vec.empty());
EXPECT_EQ(vec.size(), 0u);
ASSERT_TRUE(vec.Push(42));
ASSERT_TRUE(!vec.empty());
EXPECT_EQ(vec.size(), 1u);
// Force a resize operation to occur
for (size_t i = 0; i < 16; i++) {
ASSERT_TRUE(vec.Push(i + 1));
}
EXPECT_EQ(vec.size(), 17u);
// Verify that expected values are still contained in vec
for (size_t i = 0; i < vec.size(); i++) {
EXPECT_EQ(vec[i], i == 0 ? 42 : i);
}
// Clearing the vector should give an empty one.
vec.clear();
ASSERT_TRUE(vec.empty());
EXPECT_EQ(vec.size(), 0u);
ASSERT_TRUE(vec.Push(42));
ASSERT_TRUE(!vec.empty());
EXPECT_EQ(vec.size(), 1u);
EXPECT_EQ(vec[0], 42u);
}
TEST(VectorTest, MoveConstructor) {
Vector<size_t> vec;
for (size_t i = 0; i < 100; i++) {
ASSERT_TRUE(vec.Push(i));
}
Vector<size_t> vec_moved(std::move(vec));
for (size_t i = 0; i < 100; i++) {
EXPECT_EQ(vec_moved[i], i);
}
}
TEST(VectorTest, VectorContainingVectors) {
// Representative example of a struct that contains a Vector.
struct TagAndArray {
size_t tag;
Vector<size_t> vec;
};
Vector<TagAndArray> vec;
for (size_t i = 0; i < 100; i++) {
TagAndArray elem;
elem.tag = i;
for (size_t j = 0; j < i; j++) {
ASSERT_TRUE(elem.vec.Push(j));
}
ASSERT_TRUE(vec.Push(std::move(elem)));
}
EXPECT_EQ(vec.size(), static_cast<size_t>(100));
Vector<TagAndArray> vec_moved(std::move(vec));
EXPECT_EQ(vec_moved.size(), static_cast<size_t>(100));
size_t count = 0;
for (const TagAndArray &elem : vec_moved) {
// Test the square bracket operator returns the same value as iteration.
EXPECT_EQ(&elem, &vec_moved[count]);
EXPECT_EQ(elem.tag, count);
EXPECT_EQ(elem.vec.size(), count);
for (size_t j = 0; j < count; j++) {
EXPECT_EQ(elem.vec[j], j);
}
count++;
}
}
TEST(VectorTest, NotDefaultConstructible) {
struct NotDefaultConstructible {
explicit NotDefaultConstructible(size_t n) { array.Init(n); }
Array<int> array;
};
Vector<NotDefaultConstructible> vec;
vec.Push(NotDefaultConstructible(0));
vec.Push(NotDefaultConstructible(1));
vec.Push(NotDefaultConstructible(2));
vec.Push(NotDefaultConstructible(3));
EXPECT_EQ(vec.size(), 4u);
EXPECT_EQ(0u, vec[0].array.size());
EXPECT_EQ(1u, vec[1].array.size());
EXPECT_EQ(2u, vec[2].array.size());
EXPECT_EQ(3u, vec[3].array.size());
}
TEST(VectorDeathTest, BoundsChecks) {
Vector<int> vec;
ASSERT_TRUE(vec.Push(1));
// Within bounds of the capacity, but not the vector.
EXPECT_DEATH_IF_SUPPORTED(vec[1], "");
// Not within bounds of the capacity either.
EXPECT_DEATH_IF_SUPPORTED(vec[10000], "");
}
TEST(InplaceVector, Basic) {
InplaceVector<int, 4> vec;
EXPECT_TRUE(vec.empty());
EXPECT_EQ(0u, vec.size());
EXPECT_EQ(vec.begin(), vec.end());
int data3[] = {1, 2, 3};
ASSERT_TRUE(vec.TryCopyFrom(data3));
EXPECT_FALSE(vec.empty());
EXPECT_EQ(3u, vec.size());
auto iter = vec.begin();
EXPECT_EQ(1, vec[0]);
EXPECT_EQ(1, *iter);
iter++;
EXPECT_EQ(2, vec[1]);
EXPECT_EQ(2, *iter);
iter++;
EXPECT_EQ(3, vec[2]);
EXPECT_EQ(3, *iter);
iter++;
EXPECT_EQ(iter, vec.end());
EXPECT_EQ(MakeConstSpan(vec), MakeConstSpan(data3));
InplaceVector<int, 4> vec2 = vec;
EXPECT_EQ(MakeConstSpan(vec), MakeConstSpan(vec2));
InplaceVector<int, 4> vec3;
vec3 = vec;
EXPECT_EQ(MakeConstSpan(vec), MakeConstSpan(vec2));
int data4[] = {1, 2, 3, 4};
ASSERT_TRUE(vec.TryCopyFrom(data4));
EXPECT_EQ(MakeConstSpan(vec), MakeConstSpan(data4));
int data5[] = {1, 2, 3, 4, 5};
EXPECT_FALSE(vec.TryCopyFrom(data5));
EXPECT_FALSE(vec.TryResize(5));
// Shrink the vector.
ASSERT_TRUE(vec.TryResize(3));
EXPECT_EQ(MakeConstSpan(vec), MakeConstSpan(data3));
// Enlarge it again. The new value should have been value-initialized.
ASSERT_TRUE(vec.TryResize(4));
EXPECT_EQ(vec[3], 0);
// Self-assignment should not break the vector. Indirect through a pointer to
// avoid tripping a compiler warning.
vec.CopyFrom(data4);
const auto *ptr = &vec;
vec = *ptr;
EXPECT_EQ(MakeConstSpan(vec), MakeConstSpan(data4));
}
TEST(InplaceVectorTest, ComplexType) {
InplaceVector<std::vector<int>, 4> vec_of_vecs;
const std::vector<int> data[] = {{1, 2, 3}, {4, 5, 6}, {7, 8, 9}};
vec_of_vecs.CopyFrom(data);
EXPECT_EQ(MakeConstSpan(vec_of_vecs), MakeConstSpan(data));
vec_of_vecs.Resize(2);
EXPECT_EQ(MakeConstSpan(vec_of_vecs), MakeConstSpan(data, 2));
vec_of_vecs.Resize(4);
EXPECT_EQ(4u, vec_of_vecs.size());
EXPECT_EQ(vec_of_vecs[0], data[0]);
EXPECT_EQ(vec_of_vecs[1], data[1]);
EXPECT_TRUE(vec_of_vecs[2].empty());
EXPECT_TRUE(vec_of_vecs[3].empty());
// Copy-construction.
InplaceVector<std::vector<int>, 4> vec_of_vecs2 = vec_of_vecs;
EXPECT_EQ(4u, vec_of_vecs2.size());
EXPECT_EQ(vec_of_vecs2[0], data[0]);
EXPECT_EQ(vec_of_vecs2[1], data[1]);
EXPECT_TRUE(vec_of_vecs2[2].empty());
EXPECT_TRUE(vec_of_vecs2[3].empty());
// Copy-assignment.
InplaceVector<std::vector<int>, 4> vec_of_vecs3;
vec_of_vecs3 = vec_of_vecs;
EXPECT_EQ(4u, vec_of_vecs3.size());
EXPECT_EQ(vec_of_vecs3[0], data[0]);
EXPECT_EQ(vec_of_vecs3[1], data[1]);
EXPECT_TRUE(vec_of_vecs3[2].empty());
EXPECT_TRUE(vec_of_vecs3[3].empty());
// Move-construction.
InplaceVector<std::vector<int>, 4> vec_of_vecs4 = std::move(vec_of_vecs);
EXPECT_EQ(4u, vec_of_vecs4.size());
EXPECT_EQ(vec_of_vecs4[0], data[0]);
EXPECT_EQ(vec_of_vecs4[1], data[1]);
EXPECT_TRUE(vec_of_vecs4[2].empty());
EXPECT_TRUE(vec_of_vecs4[3].empty());
// The elements of the original vector should have been moved-from.
EXPECT_EQ(4u, vec_of_vecs.size());
for (const auto &vec : vec_of_vecs) {
EXPECT_TRUE(vec.empty());
}
// Move-assignment.
InplaceVector<std::vector<int>, 4> vec_of_vecs5;
vec_of_vecs5 = std::move(vec_of_vecs4);
EXPECT_EQ(4u, vec_of_vecs5.size());
EXPECT_EQ(vec_of_vecs5[0], data[0]);
EXPECT_EQ(vec_of_vecs5[1], data[1]);
EXPECT_TRUE(vec_of_vecs5[2].empty());
EXPECT_TRUE(vec_of_vecs5[3].empty());
// The elements of the original vector should have been moved-from.
EXPECT_EQ(4u, vec_of_vecs4.size());
for (const auto &vec : vec_of_vecs4) {
EXPECT_TRUE(vec.empty());
}
std::vector<int> v = {42};
vec_of_vecs5.Resize(3);
EXPECT_TRUE(vec_of_vecs5.TryPushBack(v));
EXPECT_EQ(v, vec_of_vecs5[3]);
EXPECT_FALSE(vec_of_vecs5.TryPushBack(v));
}
TEST(InplaceVectorTest, EraseIf) {
// Test that EraseIf never causes a self-move, and also correctly works with
// a move-only type that cannot be default-constructed.
class NoSelfMove {
public:
explicit NoSelfMove(int v) : v_(std::make_unique<int>(v)) {}
NoSelfMove(NoSelfMove &&other) { *this = std::move(other); }
NoSelfMove &operator=(NoSelfMove &&other) {
BSSL_CHECK(this != &other);
v_ = std::move(other.v_);
return *this;
}
int value() const { return *v_; }
private:
std::unique_ptr<int> v_;
};
InplaceVector<NoSelfMove, 8> vec;
auto reset = [&] {
vec.clear();
for (int i = 0; i < 8; i++) {
vec.PushBack(NoSelfMove(i));
}
};
auto expect = [&](const std::vector<int> &expected) {
ASSERT_EQ(vec.size(), expected.size());
for (size_t i = 0; i < vec.size(); i++) {
SCOPED_TRACE(i);
EXPECT_EQ(vec[i].value(), expected[i]);
}
};
reset();
vec.EraseIf([](const auto &) { return false; });
expect({0, 1, 2, 3, 4, 5, 6, 7});
reset();
vec.EraseIf([](const auto &) { return true; });
expect({});
reset();
vec.EraseIf([](const auto &v) { return v.value() < 4; });
expect({4, 5, 6, 7});
reset();
vec.EraseIf([](const auto &v) { return v.value() >= 4; });
expect({0, 1, 2, 3});
reset();
vec.EraseIf([](const auto &v) { return v.value() % 2 == 0; });
expect({1, 3, 5, 7});
reset();
vec.EraseIf([](const auto &v) { return v.value() % 2 == 1; });
expect({0, 2, 4, 6});
reset();
vec.EraseIf([](const auto &v) { return 2 <= v.value() && v.value() <= 5; });
expect({0, 1, 6, 7});
reset();
vec.EraseIf([](const auto &v) { return v.value() == 0; });
expect({1, 2, 3, 4, 5, 6, 7});
reset();
vec.EraseIf([](const auto &v) { return v.value() == 4; });
expect({0, 1, 2, 3, 5, 6, 7});
reset();
vec.EraseIf([](const auto &v) { return v.value() == 7; });
expect({0, 1, 2, 3, 4, 5, 6});
}
TEST(InplaceVectorDeathTest, BoundsChecks) {
InplaceVector<int, 4> vec;
// The vector is currently empty.
EXPECT_DEATH_IF_SUPPORTED(vec[0], "");
int data[] = {1, 2, 3};
vec.CopyFrom(data);
// Some more out-of-bounds elements.
EXPECT_DEATH_IF_SUPPORTED(vec[3], "");
EXPECT_DEATH_IF_SUPPORTED(vec[4], "");
EXPECT_DEATH_IF_SUPPORTED(vec[1000], "");
// The vector cannot be resized past the capacity.
EXPECT_DEATH_IF_SUPPORTED(vec.Resize(5), "");
EXPECT_DEATH_IF_SUPPORTED(vec.ResizeForOverwrite(5), "");
int too_much_data[] = {1, 2, 3, 4, 5};
EXPECT_DEATH_IF_SUPPORTED(vec.CopyFrom(too_much_data), "");
vec.Resize(4);
EXPECT_DEATH_IF_SUPPORTED(vec.PushBack(42), "");
}
TEST(ReconstructSeqnumTest, Increment) {
// Test simple cases from the beginning of an epoch with both 8- and 16-bit
// wire sequence numbers.
EXPECT_EQ(reconstruct_seqnum(0, 0xff, 0), 0u);
EXPECT_EQ(reconstruct_seqnum(1, 0xff, 0), 1u);
EXPECT_EQ(reconstruct_seqnum(2, 0xff, 0), 2u);
EXPECT_EQ(reconstruct_seqnum(0, 0xffff, 0), 0u);
EXPECT_EQ(reconstruct_seqnum(1, 0xffff, 0), 1u);
EXPECT_EQ(reconstruct_seqnum(2, 0xffff, 0), 2u);
// When the max seen sequence number is 0, the numerically closest
// reconstructed sequence number could be negative. Sequence numbers are
// non-negative, so reconstruct_seqnum should instead return the closest
// non-negative number instead of returning a number congruent to that
// closest negative number mod 2^64.
EXPECT_EQ(reconstruct_seqnum(0xff, 0xff, 0), 0xffu);
EXPECT_EQ(reconstruct_seqnum(0xfe, 0xff, 0), 0xfeu);
EXPECT_EQ(reconstruct_seqnum(0xffff, 0xffff, 0), 0xffffu);
EXPECT_EQ(reconstruct_seqnum(0xfffe, 0xffff, 0), 0xfffeu);
// When the wire sequence number is less than the corresponding low bytes of
// the max seen sequence number, check that the next larger sequence number
// is reconstructed as its numerically closer than the corresponding sequence
// number that would keep the high order bits the same.
EXPECT_EQ(reconstruct_seqnum(0, 0xff, 0xff), 0x100u);
EXPECT_EQ(reconstruct_seqnum(1, 0xff, 0xff), 0x101u);
EXPECT_EQ(reconstruct_seqnum(2, 0xff, 0xff), 0x102u);
EXPECT_EQ(reconstruct_seqnum(0, 0xffff, 0xffff), 0x10000u);
EXPECT_EQ(reconstruct_seqnum(1, 0xffff, 0xffff), 0x10001u);
EXPECT_EQ(reconstruct_seqnum(2, 0xffff, 0xffff), 0x10002u);
// Test cases when the wire sequence number is close to the largest magnitude
// that can be represented in 8 or 16 bits.
EXPECT_EQ(reconstruct_seqnum(0xff, 0xff, 0x2f0), 0x2ffu);
EXPECT_EQ(reconstruct_seqnum(0xfe, 0xff, 0x2f0), 0x2feu);
EXPECT_EQ(reconstruct_seqnum(0xffff, 0xffff, 0x2f000), 0x2ffffu);
EXPECT_EQ(reconstruct_seqnum(0xfffe, 0xffff, 0x2f000), 0x2fffeu);
// Test that reconstruct_seqnum can return the maximum sequence number,
// 2^48-1.
constexpr uint64_t kMaxSequence = (uint64_t{1} << 48) - 1;
EXPECT_EQ(reconstruct_seqnum(0xff, 0xff, kMaxSequence), kMaxSequence);
EXPECT_EQ(reconstruct_seqnum(0xff, 0xff, kMaxSequence - 1), kMaxSequence);
EXPECT_EQ(reconstruct_seqnum(0xffff, 0xffff, kMaxSequence), kMaxSequence);
EXPECT_EQ(reconstruct_seqnum(0xffff, 0xffff, kMaxSequence - 1), kMaxSequence);
}
TEST(ReconstructSeqnumTest, Decrement) {
// Test that the sequence number 0 can be reconstructed when the max
// seen sequence number is greater than 0.
EXPECT_EQ(reconstruct_seqnum(0, 0xff, 0x10), 0u);
EXPECT_EQ(reconstruct_seqnum(0, 0xffff, 0x1000), 0u);
// Test cases where the reconstructed sequence number is less than the max
// seen sequence number.
EXPECT_EQ(reconstruct_seqnum(0, 0xff, 0x210), 0x200u);
EXPECT_EQ(reconstruct_seqnum(2, 0xff, 0x210), 0x202u);
EXPECT_EQ(reconstruct_seqnum(0, 0xffff, 0x43210), 0x40000u);
EXPECT_EQ(reconstruct_seqnum(2, 0xffff, 0x43210), 0x40002u);
// Test when the wire sequence number is greater than the low bits of the
// max seen sequence number.
EXPECT_EQ(reconstruct_seqnum(0xff, 0xff, 0x200), 0x1ffu);
EXPECT_EQ(reconstruct_seqnum(0xfe, 0xff, 0x200), 0x1feu);
EXPECT_EQ(reconstruct_seqnum(0xffff, 0xffff, 0x20000), 0x1ffffu);
EXPECT_EQ(reconstruct_seqnum(0xfffe, 0xffff, 0x20000), 0x1fffeu);
constexpr uint64_t kMaxSequence = (uint64_t{1} << 48) - 1;
// kMaxSequence00 is kMaxSequence with the last byte replaced with 0x00.
constexpr uint64_t kMaxSequence00 = kMaxSequence - 0xff;
// kMaxSequence0000 is kMaxSequence with the last byte replaced with 0x0000.
constexpr uint64_t kMaxSequence0000 = kMaxSequence - 0xffff;
// Test when the max seen sequence number is close to the 2^48-1 max value.
// In some cases, the closest numerical value in the integers will exceed the
// limit. In this case, reconstruct_seqnum should return the closest integer
// within range.
EXPECT_EQ(reconstruct_seqnum(0, 0xff, kMaxSequence), kMaxSequence00);
EXPECT_EQ(reconstruct_seqnum(0, 0xff, kMaxSequence - 1), kMaxSequence00);
EXPECT_EQ(reconstruct_seqnum(1, 0xff, kMaxSequence), kMaxSequence00 + 0x01);
EXPECT_EQ(reconstruct_seqnum(1, 0xff, kMaxSequence - 1),
kMaxSequence00 + 0x01);
EXPECT_EQ(reconstruct_seqnum(0xfe, 0xff, kMaxSequence),
kMaxSequence00 + 0xfe);
EXPECT_EQ(reconstruct_seqnum(0xfd, 0xff, kMaxSequence - 1),
kMaxSequence00 + 0xfd);
EXPECT_EQ(reconstruct_seqnum(0, 0xffff, kMaxSequence), kMaxSequence0000);
EXPECT_EQ(reconstruct_seqnum(0, 0xffff, kMaxSequence - 1), kMaxSequence0000);
EXPECT_EQ(reconstruct_seqnum(1, 0xffff, kMaxSequence),
kMaxSequence0000 + 0x0001);
EXPECT_EQ(reconstruct_seqnum(1, 0xffff, kMaxSequence - 1),
kMaxSequence0000 + 0x0001);
EXPECT_EQ(reconstruct_seqnum(0xfffe, 0xffff, kMaxSequence),
kMaxSequence0000 + 0xfffe);
EXPECT_EQ(reconstruct_seqnum(0xfffd, 0xffff, kMaxSequence - 1),
kMaxSequence0000 + 0xfffd);
}
TEST(ReconstructSeqnumTest, Halfway) {
// Test wire sequence numbers that are close to halfway away from the max
// seen sequence number. The algorithm specifies that the output should be
// numerically closest to 1 plus the max seen (0x100 in the following test
// cases). With a max seen of 0x100 and a wire sequence of 0x81, the two
// closest values to 1+0x100 are 0x81 and 0x181, which are both the same
// amount away. The algorithm doesn't specify what to do on this edge case;
// our implementation chooses the larger value (0x181), on the assumption that
// it's more likely to be a new or larger sequence number rather than a replay
// or an out-of-order packet.
EXPECT_EQ(reconstruct_seqnum(0x80, 0xff, 0x100), 0x180u);
EXPECT_EQ(reconstruct_seqnum(0x81, 0xff, 0x100), 0x181u);
EXPECT_EQ(reconstruct_seqnum(0x82, 0xff, 0x100), 0x82u);
// Repeat these tests with 16-bit wire sequence numbers.
EXPECT_EQ(reconstruct_seqnum(0x8000, 0xffff, 0x10000), 0x18000u);
EXPECT_EQ(reconstruct_seqnum(0x8001, 0xffff, 0x10000), 0x18001u);
EXPECT_EQ(reconstruct_seqnum(0x8002, 0xffff, 0x10000), 0x8002u);
}
TEST(DTLSMessageBitmapTest, Basic) {
// expect_bitmap checks that |b|'s unmarked bits are those listed in |ranges|.
// Each element of |ranges| must be non-empty and non-overlapping, and
// |ranges| must be sorted.
auto expect_bitmap = [](const DTLSMessageBitmap &b,
const std::vector<DTLSMessageBitmap::Range> &ranges) {
EXPECT_EQ(ranges.empty(), b.IsComplete());
size_t start = 0;
for (const auto &r : ranges) {
for (; start < r.start; start++) {
SCOPED_TRACE(start);
EXPECT_EQ(b.NextUnmarkedRange(start), r);
}
for (; start < r.end; start++) {
SCOPED_TRACE(start);
EXPECT_EQ(b.NextUnmarkedRange(start),
(DTLSMessageBitmap::Range{start, r.end}));
}
}
EXPECT_TRUE(b.NextUnmarkedRange(start).empty());
EXPECT_TRUE(b.NextUnmarkedRange(start + 1).empty());
EXPECT_TRUE(b.NextUnmarkedRange(start + 42).empty());
// This is implied from the previous checks, but NextUnmarkedRange should
// work as an iterator to reconstruct the ranges.
std::vector<DTLSMessageBitmap::Range> got_ranges;
for (auto r = b.NextUnmarkedRange(0); !r.empty();
r = b.NextUnmarkedRange(r.end)) {
got_ranges.push_back(r);
}
EXPECT_EQ(ranges, got_ranges);
};
// Initially, the bitmap is empty (fully marked).
DTLSMessageBitmap bitmap;
expect_bitmap(bitmap, {});
// It can also be initialized to the empty message and marked.
ASSERT_TRUE(bitmap.Init(0));
expect_bitmap(bitmap, {});
bitmap.MarkRange(0, 0);
expect_bitmap(bitmap, {});
// Track 100 bits and mark byte by byte.
ASSERT_TRUE(bitmap.Init(100));
expect_bitmap(bitmap, {{0, 100}});
for (size_t i = 0; i < 100; i++) {
SCOPED_TRACE(i);
bitmap.MarkRange(i, i + 1);
if (i < 99) {
expect_bitmap(bitmap, {{i + 1, 100}});
} else {
expect_bitmap(bitmap, {});
}
}
// Do the same but in reverse.
ASSERT_TRUE(bitmap.Init(100));
expect_bitmap(bitmap, {{0, 100}});
for (size_t i = 100; i > 0; i--) {
SCOPED_TRACE(i);
bitmap.MarkRange(i - 1, i);
if (i > 1) {
expect_bitmap(bitmap, {{0, i - 1}});
} else {
expect_bitmap(bitmap, {});
}
}
// Overlapping ranges are fine.
ASSERT_TRUE(bitmap.Init(100));
expect_bitmap(bitmap, {{0, 100}});
for (size_t i = 0; i < 100; i++) {
SCOPED_TRACE(i);
bitmap.MarkRange(i / 2, i + 1);
if (i < 99) {
expect_bitmap(bitmap, {{i + 1, 100}});
} else {
expect_bitmap(bitmap, {});
}
}
// Mark the middle chunk of every power of 3.
ASSERT_TRUE(bitmap.Init(100));
bitmap.MarkRange(1, 2);
bitmap.MarkRange(3, 6);
bitmap.MarkRange(9, 18);
bitmap.MarkRange(27, 54);
bitmap.MarkRange(81, 162);
expect_bitmap(bitmap, {{0, 1}, {2, 3}, {6, 9}, {18, 27}, {54, 81}});
// Mark most of the chunk shifted down a bit, so it both overlaps the previous
// and also leaves some of the right chunks unmarked.
bitmap.MarkRange(6 - 2, 9 - 2);
bitmap.MarkRange(18 - 4, 27 - 4);
bitmap.MarkRange(54 - 8, 81 - 8);
expect_bitmap(bitmap,
{{0, 1}, {2, 3}, {9 - 2, 9}, {27 - 4, 27}, {81 - 8, 81}});
// Re-mark things that have already been marked.
bitmap.MarkRange(1, 2);
bitmap.MarkRange(3, 6);
bitmap.MarkRange(9, 18);
bitmap.MarkRange(27, 54);
bitmap.MarkRange(81, 162);
expect_bitmap(bitmap,
{{0, 1}, {2, 3}, {9 - 2, 9}, {27 - 4, 27}, {81 - 8, 81}});
// Moves should work.
DTLSMessageBitmap bitmap2 = std::move(bitmap);
expect_bitmap(bitmap, {});
expect_bitmap(bitmap2,
{{0, 1}, {2, 3}, {9 - 2, 9}, {27 - 4, 27}, {81 - 8, 81}});
// Mark everything in two large ranges.
bitmap2.MarkRange(27 - 2, 100);
expect_bitmap(bitmap2, {{0, 1}, {2, 3}, {9 - 2, 9}, {27 - 4, 27 - 2}});
bitmap2.MarkRange(0, 50);
expect_bitmap(bitmap2, {});
// MarkRange inputs may be "out of bounds". The bitmap has conceptually
// infinitely many marked bits past where it was initialized.
ASSERT_TRUE(bitmap.Init(10));
expect_bitmap(bitmap, {{0, 10}});
bitmap.MarkRange(5, SIZE_MAX);
expect_bitmap(bitmap, {{0, 5}});
bitmap.MarkRange(0, SIZE_MAX);
expect_bitmap(bitmap, {});
}
TEST(MRUQueueTest, Basic) {
// Use a complex type to confirm the queue handles them correctly.
MRUQueue<std::unique_ptr<int>, 8> queue;
auto expect_queue = [&](const std::vector<int> &expected) {
EXPECT_EQ(queue.size(), expected.size());
EXPECT_EQ(queue.empty(), expected.empty());
std::vector<int> queue_values;
for (size_t i = 0; i < queue.size(); i++) {
queue_values.push_back(*queue[i]);
}
EXPECT_EQ(queue_values, expected);
};
expect_queue({});
queue.PushBack(std::make_unique<int>(1));
expect_queue({1});
queue.PushBack(std::make_unique<int>(2));
expect_queue({1, 2});
queue.PushBack(std::make_unique<int>(3));
expect_queue({1, 2, 3});
queue.PushBack(std::make_unique<int>(4));
expect_queue({1, 2, 3, 4});
queue.PushBack(std::make_unique<int>(5));
expect_queue({1, 2, 3, 4, 5});
queue.PushBack(std::make_unique<int>(6));
expect_queue({1, 2, 3, 4, 5, 6});
queue.PushBack(std::make_unique<int>(7));
expect_queue({1, 2, 3, 4, 5, 6, 7});
queue.PushBack(std::make_unique<int>(8));
expect_queue({1, 2, 3, 4, 5, 6, 7, 8});
// We are at capacity, so later additions will drop the start. Do more than 8
// insertions to test that the start index can wrap around.
queue.PushBack(std::make_unique<int>(9));
expect_queue({2, 3, 4, 5, 6, 7, 8, 9});
queue.PushBack(std::make_unique<int>(10));
expect_queue({3, 4, 5, 6, 7, 8, 9, 10});
queue.PushBack(std::make_unique<int>(11));
expect_queue({4, 5, 6, 7, 8, 9, 10, 11});
queue.PushBack(std::make_unique<int>(12));
expect_queue({5, 6, 7, 8, 9, 10, 11, 12});
queue.PushBack(std::make_unique<int>(13));
expect_queue({6, 7, 8, 9, 10, 11, 12, 13});
queue.PushBack(std::make_unique<int>(14));
expect_queue({7, 8, 9, 10, 11, 12, 13, 14});
queue.PushBack(std::make_unique<int>(15));
expect_queue({8, 9, 10, 11, 12, 13, 14, 15});
queue.PushBack(std::make_unique<int>(16));
expect_queue({9, 10, 11, 12, 13, 14, 15, 16});
queue.PushBack(std::make_unique<int>(17));
expect_queue({10, 11, 12, 13, 14, 15, 16, 17});
// Clearing the queue should not leave the start index in a bad place.
queue.Clear();
expect_queue({});
queue.PushBack(std::make_unique<int>(1));
expect_queue({1});
queue.PushBack(std::make_unique<int>(2));
expect_queue({1, 2});
queue.PushBack(std::make_unique<int>(3));
expect_queue({1, 2, 3});
}
#if !defined(BORINGSSL_UNSAFE_FUZZER_MODE)
TEST(SSLAEADContextTest, Lengths) {
struct LengthTest {
// All plaintext lengths from |min_plaintext_len| to |max_plaintext_len|
// should return in |cipertext_len|.
size_t min_plaintext_len;
size_t max_plaintext_len;
size_t ciphertext_len;
};
struct CipherLengthTest {
// |SSL3_CK_*| and |TLS1_CK_*| constants include an extra byte at the front,
// so these constants must be masked with 0xffff.
uint16_t cipher;
uint16_t version;
size_t enc_key_len, mac_key_len, fixed_iv_len;
size_t block_size;
std::vector<LengthTest> length_tests;
};
const CipherLengthTest kTests[] = {
// 20-byte MAC, 8-byte CBC blocks with padding
{
/*cipher=*/SSL3_CK_RSA_DES_192_CBC3_SHA & 0xffff,
/*version=*/TLS1_2_VERSION,
/*enc_key_len=*/24,
/*mac_key_len=*/20,
/*fixed_iv_len=*/0,
/*block_size=*/8,
{
{/*min_plaintext_len=*/0,
/*max_plaintext_len=*/3,
/*ciphertext_len=*/32},
{/*min_plaintext_len=*/4,
/*max_plaintext_len=*/11,
/*ciphertext_len=*/40},
{/*min_plaintext_len=*/12,
/*max_plaintext_len=*/19,
/*ciphertext_len=*/48},
},
},
// 20-byte MAC, 16-byte CBC blocks with padding
{
/*cipher=*/TLS1_CK_RSA_WITH_AES_128_SHA & 0xffff,
/*version=*/TLS1_2_VERSION,
/*enc_key_len=*/16,
/*mac_key_len=*/20,
/*fixed_iv_len=*/0,
/*block_size=*/16,
{
{/*min_plaintext_len=*/0,
/*max_plaintext_len=*/11,
/*ciphertext_len=*/48},
{/*min_plaintext_len=*/12,
/*max_plaintext_len=*/27,
/*ciphertext_len=*/64},
{/*min_plaintext_len=*/38,
/*max_plaintext_len=*/43,
/*ciphertext_len=*/80},
},
},
// 32-byte MAC, 16-byte CBC blocks with padding
{
/*cipher=*/TLS1_CK_ECDHE_RSA_WITH_AES_128_CBC_SHA256 & 0xffff,
/*version=*/TLS1_2_VERSION,
/*enc_key_len=*/16,
/*mac_key_len=*/32,
/*fixed_iv_len=*/0,
/*block_size=*/16,
{
{/*min_plaintext_len=*/0,
/*max_plaintext_len=*/15,
/*ciphertext_len=*/64},
{/*min_plaintext_len=*/16,
/*max_plaintext_len=*/31,
/*ciphertext_len=*/80},
{/*min_plaintext_len=*/32,
/*max_plaintext_len=*/47,
/*ciphertext_len=*/96},
},
},
// 8-byte explicit IV, 16-byte tag
{
/*cipher=*/TLS1_CK_ECDHE_RSA_WITH_AES_128_GCM_SHA256 & 0xffff,
/*version=*/TLS1_2_VERSION,
/*enc_key_len=*/16,
/*mac_key_len=*/0,
/*fixed_iv_len=*/4,
/*block_size=*/1,
{
{/*min_plaintext_len=*/0,
/*max_plaintext_len=*/0,
/*ciphertext_len=*/24},
{/*min_plaintext_len=*/1,
/*max_plaintext_len=*/1,
/*ciphertext_len=*/25},
{/*min_plaintext_len=*/2,
/*max_plaintext_len=*/2,
/*ciphertext_len=*/26},
{/*min_plaintext_len=*/42,
/*max_plaintext_len=*/42,
/*ciphertext_len=*/66},
},
},
// No explicit IV, 16-byte tag. TLS 1.3's padding and record type overhead
// is added at another layer.
{
/*cipher=*/TLS1_CK_ECDHE_RSA_WITH_CHACHA20_POLY1305_SHA256 & 0xffff,
/*version=*/TLS1_2_VERSION,
/*enc_key_len=*/32,
/*mac_key_len=*/0,
/*fixed_iv_len=*/12,
/*block_size=*/1,
{
{/*min_plaintext_len=*/0,
/*max_plaintext_len=*/0,
/*ciphertext_len=*/16},
{/*min_plaintext_len=*/1,
/*max_plaintext_len=*/1,
/*ciphertext_len=*/17},
{/*min_plaintext_len=*/2,
/*max_plaintext_len=*/2,
/*ciphertext_len=*/18},
{/*min_plaintext_len=*/42,
/*max_plaintext_len=*/42,
/*ciphertext_len=*/58},
},
},
{
/*cipher=*/TLS1_CK_AES_128_GCM_SHA256 & 0xffff,
/*version=*/TLS1_3_VERSION,
/*enc_key_len=*/16,
/*mac_key_len=*/0,
/*fixed_iv_len=*/12,
/*block_size=*/1,
{
{/*min_plaintext_len=*/0,
/*max_plaintext_len=*/0,
/*ciphertext_len=*/16},
{/*min_plaintext_len=*/1,
/*max_plaintext_len=*/1,
/*ciphertext_len=*/17},
{/*min_plaintext_len=*/2,
/*max_plaintext_len=*/2,
/*ciphertext_len=*/18},
{/*min_plaintext_len=*/42,
/*max_plaintext_len=*/42,
/*ciphertext_len=*/58},
},
},
{
/*cipher=*/TLS1_CK_CHACHA20_POLY1305_SHA256 & 0xffff,
/*version=*/TLS1_3_VERSION,
/*enc_key_len=*/32,
/*mac_key_len=*/0,
/*fixed_iv_len=*/12,
/*block_size=*/1,
{
{/*min_plaintext_len=*/0,
/*max_plaintext_len=*/0,
/*ciphertext_len=*/16},
{/*min_plaintext_len=*/1,
/*max_plaintext_len=*/1,
/*ciphertext_len=*/17},
{/*min_plaintext_len=*/2,
/*max_plaintext_len=*/2,
/*ciphertext_len=*/18},
{/*min_plaintext_len=*/42,
/*max_plaintext_len=*/42,
/*ciphertext_len=*/58},
},
},
};
for (const auto &cipher_test : kTests) {
const SSL_CIPHER *cipher =
SSL_get_cipher_by_value(static_cast<uint16_t>(cipher_test.cipher));
ASSERT_TRUE(cipher) << "Could not find cipher " << cipher_test.cipher;
SCOPED_TRACE(SSL_CIPHER_standard_name(cipher));
const uint8_t kZeros[EVP_AEAD_MAX_KEY_LENGTH] = {0};
UniquePtr<SSLAEADContext> aead = SSLAEADContext::Create(
evp_aead_seal, cipher_test.version, cipher,
MakeConstSpan(kZeros).first(cipher_test.enc_key_len),
MakeConstSpan(kZeros).first(cipher_test.mac_key_len),
MakeConstSpan(kZeros).first(cipher_test.fixed_iv_len));
ASSERT_TRUE(aead);
for (const auto &t : cipher_test.length_tests) {
SCOPED_TRACE(t.ciphertext_len);
for (size_t plaintext_len = t.min_plaintext_len;
plaintext_len <= t.max_plaintext_len; plaintext_len++) {
SCOPED_TRACE(plaintext_len);
size_t out_len;
ASSERT_TRUE(aead->CiphertextLen(&out_len, plaintext_len, 0));
EXPECT_EQ(out_len, t.ciphertext_len);
}
EXPECT_EQ(aead->MaxSealInputLen(t.ciphertext_len), t.max_plaintext_len);
for (size_t extra = 0; extra < cipher_test.block_size; extra++) {
// Adding up to block_size - 1 bytes of space should not change how much
// room we have.
SCOPED_TRACE(extra);
EXPECT_EQ(aead->MaxSealInputLen(t.ciphertext_len + extra),
t.max_plaintext_len);
}
}
}
}
#endif // !BORINGSSL_UNSAFE_FUZZER_MODE
} // namespace
BSSL_NAMESPACE_END
#endif // !BORINGSSL_SHARED_LIBRARY