// Copyright 2013 Google Inc. All rights reserved. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following disclaimer // in the documentation and/or other materials provided with the // distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived from // this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // Unittests for OMAP related functions. #include "common/windows/omap.h" #include "breakpad_googletest_includes.h" namespace google_breakpad { // Equality operators for ContainerEq. These must be outside of the anonymous // namespace in order for them to be found. bool operator==(const MappedRange& mr1, const MappedRange& mr2) { return mr1.rva_original == mr2.rva_original && mr1.rva_transformed == mr2.rva_transformed && mr1.length == mr2.length && mr1.injected == mr2.injected && mr1.removed == mr2.removed; } bool operator==(const EndpointIndex& ei1, const EndpointIndex& ei2) { return ei1.endpoint == ei2.endpoint && ei1.index == ei2.index; } // Pretty printers for more meaningful error messages. Also need to be outside // the anonymous namespace. std::ostream& operator<<(std::ostream& os, const MappedRange& mr) { os << "MappedRange(rva_original=" << mr.rva_original << ", rva_transformed=" << mr.rva_transformed << ", length=" << mr.length << ", injected=" << mr.injected << ", removed=" << mr.removed << ")"; return os; } std::ostream& operator<<(std::ostream& os, const EndpointIndex& ei) { os << "EndpointIndex(endpoint=" << ei.endpoint << ", index=" << ei.index << ")"; return os; } std::ostream& operator<<(std::ostream& os, const AddressRange& ar) { os << "AddressRange(rva=" << ar.rva << ", length=" << ar.length << ")"; return os; } namespace { OMAP CreateOmap(DWORD rva, DWORD rvaTo) { OMAP o = { rva, rvaTo }; return o; } MappedRange CreateMappedRange(DWORD rva_original, DWORD rva_transformed, DWORD length, DWORD injected, DWORD removed) { MappedRange mr = { rva_original, rva_transformed, length, injected, removed }; return mr; } EndpointIndex CreateEndpointIndex(DWORD endpoint, size_t index) { EndpointIndex ei = { endpoint, index }; return ei; } // (C is removed) // Original : A B C D E F G H // Transformed: A B D F E * H1 G1 G2 H2 // (* is injected, G is copied, H is split) // A is implied. // Layout of the original image. const AddressRange B(100, 15); const AddressRange C(B.end(), 10); const AddressRange D(C.end(), 25); const AddressRange E(D.end(), 10); const AddressRange F(E.end(), 40); const AddressRange G(F.end(), 3); const AddressRange H(G.end(), 7); // Layout of the transformed image. const AddressRange Bt(100, 15); const AddressRange Dt(Bt.end(), 20); // D is shortened. const AddressRange Ft(Dt.end(), F.length); const AddressRange Et(Ft.end(), E.length); const AddressRange injected(Et.end(), 5); const AddressRange H1t(injected.end(), 4); // H is split. const AddressRange G1t(H1t.end(), G.length); // G is copied. const AddressRange G2t(G1t.end(), G.length); // G is copied. const AddressRange H2t(G2t.end(), 3); // H is split. class BuildImageMapTest : public testing::Test { public: static const DWORD kInvalidAddress = 0xFFFFFFFF; void InitOmapData() { omap_data.length_original = H.end(); // Build the OMAPTO vector (from transformed to original). omap_data.omap_to.push_back(CreateOmap(Bt.rva, B.rva)); omap_data.omap_to.push_back(CreateOmap(Dt.rva, D.rva)); omap_data.omap_to.push_back(CreateOmap(Ft.rva, F.rva)); omap_data.omap_to.push_back(CreateOmap(Et.rva, E.rva)); omap_data.omap_to.push_back(CreateOmap(injected.rva, kInvalidAddress)); omap_data.omap_to.push_back(CreateOmap(H1t.rva, H.rva)); omap_data.omap_to.push_back(CreateOmap(G1t.rva, G.rva)); omap_data.omap_to.push_back(CreateOmap(G2t.rva, G.rva)); omap_data.omap_to.push_back(CreateOmap(H2t.rva, H.rva + H1t.length)); omap_data.omap_to.push_back(CreateOmap(H2t.end(), kInvalidAddress)); // Build the OMAPFROM vector (from original to transformed). omap_data.omap_from.push_back(CreateOmap(B.rva, Bt.rva)); omap_data.omap_from.push_back(CreateOmap(C.rva, kInvalidAddress)); omap_data.omap_from.push_back(CreateOmap(D.rva, Dt.rva)); omap_data.omap_from.push_back(CreateOmap(E.rva, Et.rva)); omap_data.omap_from.push_back(CreateOmap(F.rva, Ft.rva)); omap_data.omap_from.push_back(CreateOmap(G.rva, G1t.rva)); omap_data.omap_from.push_back(CreateOmap(H.rva, H1t.rva)); omap_data.omap_from.push_back(CreateOmap(H.rva + H1t.length, H2t.rva)); omap_data.omap_from.push_back(CreateOmap(H.end(), kInvalidAddress)); } OmapData omap_data; }; } // namespace TEST_F(BuildImageMapTest, EmptyImageMapOnEmptyOmapData) { ASSERT_EQ(0u, omap_data.omap_from.size()); ASSERT_EQ(0u, omap_data.omap_to.size()); ASSERT_EQ(0u, omap_data.length_original); ImageMap image_map; BuildImageMap(omap_data, &image_map); EXPECT_EQ(0u, image_map.mapping.size()); EXPECT_EQ(0u, image_map.endpoint_index_map.size()); } TEST_F(BuildImageMapTest, ImageMapIsCorrect) { InitOmapData(); ASSERT_LE(0u, omap_data.omap_from.size()); ASSERT_LE(0u, omap_data.omap_to.size()); ASSERT_LE(0u, omap_data.length_original); ImageMap image_map; BuildImageMap(omap_data, &image_map); EXPECT_LE(9u, image_map.mapping.size()); EXPECT_LE(9u, image_map.endpoint_index_map.size()); Mapping mapping; mapping.push_back(CreateMappedRange(0, 0, B.rva, 0, 0)); // C is removed, and it originally comes immediately after B. mapping.push_back(CreateMappedRange(B.rva, Bt.rva, B.length, 0, C.length)); // D is shortened by a length of 5. mapping.push_back(CreateMappedRange(D.rva, Dt.rva, Dt.length, 0, 5)); // The injected content comes immediately after E in the transformed image. mapping.push_back(CreateMappedRange(E.rva, Et.rva, E.length, injected.length, 0)); mapping.push_back(CreateMappedRange(F.rva, Ft.rva, F.length, 0, 0)); // G is copied so creates two entries. mapping.push_back(CreateMappedRange(G.rva, G1t.rva, G.length, 0, 0)); mapping.push_back(CreateMappedRange(G.rva, G2t.rva, G.length, 0, 0)); // H is split, so create two entries. mapping.push_back(CreateMappedRange(H.rva, H1t.rva, H1t.length, 0, 0)); mapping.push_back(CreateMappedRange(H.rva + H1t.length, H2t.rva, H2t.length, 0, 0)); EXPECT_THAT(mapping, testing::ContainerEq(image_map.mapping)); EndpointIndexMap endpoint_index_map; endpoint_index_map.push_back(CreateEndpointIndex(0, 0)); endpoint_index_map.push_back(CreateEndpointIndex(B.rva, 1)); endpoint_index_map.push_back(CreateEndpointIndex(D.rva, 2)); endpoint_index_map.push_back(CreateEndpointIndex(E.rva, 3)); endpoint_index_map.push_back(CreateEndpointIndex(F.rva, 4)); // G is duplicated so 2 ranges map back to it, hence the skip from 5 to 7. endpoint_index_map.push_back(CreateEndpointIndex(G.rva, 5)); // H is split so we expect 2 endpoints to show up attributed to it. endpoint_index_map.push_back(CreateEndpointIndex(H.rva, 7)); endpoint_index_map.push_back(CreateEndpointIndex(H.rva + H1t.length, 8)); endpoint_index_map.push_back(CreateEndpointIndex(H.end(), 9)); EXPECT_THAT(endpoint_index_map, testing::ContainerEq(image_map.endpoint_index_map)); } namespace { class MapAddressRangeTest : public BuildImageMapTest { public: typedef BuildImageMapTest Super; virtual void SetUp() { Super::SetUp(); InitOmapData(); BuildImageMap(omap_data, &image_map); } ImageMap image_map; private: using BuildImageMapTest::InitOmapData; using BuildImageMapTest::omap_data; }; } // namespace TEST_F(MapAddressRangeTest, EmptyImageMapReturnsIdentity) { ImageMap im; AddressRangeVector mapped_ranges; AddressRange ar(0, 1024); MapAddressRange(im, ar, &mapped_ranges); EXPECT_EQ(1u, mapped_ranges.size()); EXPECT_EQ(ar, mapped_ranges[0]); } TEST_F(MapAddressRangeTest, MapOutOfImage) { AddressRangeVector mapped_ranges; MapAddressRange(image_map, AddressRange(H.end() + 10, 10), &mapped_ranges); EXPECT_EQ(0u, mapped_ranges.size()); } TEST_F(MapAddressRangeTest, MapIdentity) { AddressRangeVector mapped_ranges; MapAddressRange(image_map, B, &mapped_ranges); EXPECT_EQ(1u, mapped_ranges.size()); EXPECT_THAT(mapped_ranges, testing::ElementsAre(B)); } TEST_F(MapAddressRangeTest, MapReorderedContiguous) { AddressRangeVector mapped_ranges; AddressRange DEF(D.rva, F.end() - D.rva); MapAddressRange(image_map, DEF, &mapped_ranges); EXPECT_EQ(1u, mapped_ranges.size()); AddressRange DFEt(Dt.rva, Et.end() - Dt.rva); EXPECT_THAT(mapped_ranges, testing::ElementsAre(DFEt)); } TEST_F(MapAddressRangeTest, MapEmptySingle) { AddressRangeVector mapped_ranges; MapAddressRange(image_map, AddressRange(D.rva, 0), &mapped_ranges); EXPECT_EQ(1u, mapped_ranges.size()); EXPECT_THAT(mapped_ranges, testing::ElementsAre(AddressRange(Dt.rva, 0))); } TEST_F(MapAddressRangeTest, MapEmptyCopied) { AddressRangeVector mapped_ranges; MapAddressRange(image_map, AddressRange(G.rva, 0), &mapped_ranges); EXPECT_EQ(2u, mapped_ranges.size()); EXPECT_THAT(mapped_ranges, testing::ElementsAre(AddressRange(G1t.rva, 0), AddressRange(G2t.rva, 0))); } TEST_F(MapAddressRangeTest, MapCopiedContiguous) { AddressRangeVector mapped_ranges; MapAddressRange(image_map, G, &mapped_ranges); EXPECT_EQ(1u, mapped_ranges.size()); EXPECT_THAT(mapped_ranges, testing::ElementsAre( AddressRange(G1t.rva, G2t.end() - G1t.rva))); } TEST_F(MapAddressRangeTest, MapSplitDiscontiguous) { AddressRangeVector mapped_ranges; MapAddressRange(image_map, H, &mapped_ranges); EXPECT_EQ(2u, mapped_ranges.size()); EXPECT_THAT(mapped_ranges, testing::ElementsAre(H1t, H2t)); } TEST_F(MapAddressRangeTest, MapInjected) { AddressRangeVector mapped_ranges; AddressRange EFGH(E.rva, H.end() - E.rva); MapAddressRange(image_map, EFGH, &mapped_ranges); EXPECT_EQ(1u, mapped_ranges.size()); AddressRange FEHGGHt(Ft.rva, H2t.end() - Ft.rva); EXPECT_THAT(mapped_ranges, testing::ElementsAre(FEHGGHt)); } TEST_F(MapAddressRangeTest, MapRemovedEntirely) { AddressRangeVector mapped_ranges; MapAddressRange(image_map, C, &mapped_ranges); EXPECT_EQ(0u, mapped_ranges.size()); } TEST_F(MapAddressRangeTest, MapRemovedPartly) { AddressRangeVector mapped_ranges; MapAddressRange(image_map, D, &mapped_ranges); EXPECT_EQ(1u, mapped_ranges.size()); EXPECT_THAT(mapped_ranges, testing::ElementsAre(Dt)); } TEST_F(MapAddressRangeTest, MapFull) { AddressRangeVector mapped_ranges; AddressRange AH(0, H.end()); MapAddressRange(image_map, AH, &mapped_ranges); EXPECT_EQ(1u, mapped_ranges.size()); AddressRange AHt(0, H2t.end()); EXPECT_THAT(mapped_ranges, testing::ElementsAre(AHt)); } } // namespace google_breakpad