github.com/amazechain/amc@v0.1.3/internal/avm/common/bitutil/compress_test.go (about) 1 // Copyright 2023 The AmazeChain Authors 2 // This file is part of the AmazeChain library. 3 // 4 // The AmazeChain library is free software: you can redistribute it and/or modify 5 // it under the terms of the GNU Lesser General Public License as published by 6 // the Free Software Foundation, either version 3 of the License, or 7 // (at your option) any later version. 8 // 9 // The AmazeChain library is distributed in the hope that it will be useful, 10 // but WITHOUT ANY WARRANTY; without even the implied warranty of 11 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 12 // GNU Lesser General Public License for more details. 13 // 14 // You should have received a copy of the GNU Lesser General Public License 15 // along with the AmazeChain library. If not, see <http://www.gnu.org/licenses/>. 16 17 package bitutil 18 19 import ( 20 "bytes" 21 "math/rand" 22 "testing" 23 24 "github.com/amazechain/amc/common/hexutil" 25 ) 26 27 // Tests that data bitset encoding and decoding works and is bijective. 28 func TestEncodingCycle(t *testing.T) { 29 tests := []string{ 30 // Tests generated by go-fuzz to maximize code coverage 31 "0x000000000000000000", 32 "0xef0400", 33 "0xdf7070533534333636313639343638373532313536346c1bc33339343837313070706336343035336336346c65fefb3930393233383838ac2f65fefb", 34 "0x7b64000000", 35 "0x000034000000000000", 36 "0x0000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000f0000000000000000000", 37 "0x4912385c0e7b64000000", 38 "0x000034000000000000000000000000000000", 39 "0x00", 40 "0x000003e834ff7f0000", 41 "0x0000", 42 "0x0000000000000000000000000000000000000000000000000000000000ff00", 43 "0x895f0c6a020f850c6a020f85f88df88d", 44 "0xdf7070533534333636313639343638373432313536346c1bc3315aac2f65fefb", 45 "0x0000000000", 46 "0xdf70706336346c65fefb", 47 "0x00006d643634000000", 48 "0xdf7070533534333636313639343638373532313536346c1bc333393438373130707063363430353639343638373532313536346c1bc333393438336336346c65fe", 49 } 50 for i, tt := range tests { 51 data := hexutil.MustDecode(tt) 52 53 proc, err := bitsetDecodeBytes(bitsetEncodeBytes(data), len(data)) 54 if err != nil { 55 t.Errorf("test %d: failed to decompress compressed data: %v", i, err) 56 continue 57 } 58 if !bytes.Equal(data, proc) { 59 t.Errorf("test %d: compress/decompress mismatch: have %x, want %x", i, proc, data) 60 } 61 } 62 } 63 64 // Tests that data bitset decoding and rencoding works and is bijective. 65 func TestDecodingCycle(t *testing.T) { 66 tests := []struct { 67 size int 68 input string 69 fail error 70 }{ 71 {size: 0, input: "0x"}, 72 73 // Crashers generated by go-fuzz 74 {size: 0, input: "0x0020", fail: errUnreferencedData}, 75 {size: 0, input: "0x30", fail: errUnreferencedData}, 76 {size: 1, input: "0x00", fail: errUnreferencedData}, 77 {size: 2, input: "0x07", fail: errMissingData}, 78 {size: 1024, input: "0x8000", fail: errZeroContent}, 79 80 // Tests generated by go-fuzz to maximize code coverage 81 {size: 29490, input: "0x343137343733323134333839373334323073333930783e3078333930783e70706336346c65303e", fail: errMissingData}, 82 {size: 59395, input: "0x00", fail: errUnreferencedData}, 83 {size: 52574, input: "0x70706336346c65c0de", fail: errExceededTarget}, 84 {size: 42264, input: "0x07", fail: errMissingData}, 85 {size: 52, input: "0xa5045bad48f4", fail: errExceededTarget}, 86 {size: 52574, input: "0xc0de", fail: errMissingData}, 87 {size: 52574, input: "0x"}, 88 {size: 29490, input: "0x34313734373332313433383937333432307333393078073034333839373334323073333930783e3078333937333432307333393078073061333930783e70706336346c65303e", fail: errMissingData}, 89 {size: 29491, input: "0x3973333930783e30783e", fail: errMissingData}, 90 91 {size: 1024, input: "0x808080608080"}, 92 {size: 1024, input: "0x808470705e3632383337363033313434303137393130306c6580ef46806380635a80"}, 93 {size: 1024, input: "0x8080808070"}, 94 {size: 1024, input: "0x808070705e36346c6580ef46806380635a80"}, 95 {size: 1024, input: "0x80808046802680"}, 96 {size: 1024, input: "0x4040404035"}, 97 {size: 1024, input: "0x4040bf3ba2b3f684402d353234373438373934409fe5b1e7ada94ebfd7d0505e27be4035"}, 98 {size: 1024, input: "0x404040bf3ba2b3f6844035"}, 99 {size: 1024, input: "0x40402d35323437343837393440bfd7d0505e27be4035"}, 100 } 101 for i, tt := range tests { 102 data := hexutil.MustDecode(tt.input) 103 104 orig, err := bitsetDecodeBytes(data, tt.size) 105 if err != tt.fail { 106 t.Errorf("test %d: failure mismatch: have %v, want %v", i, err, tt.fail) 107 } 108 if err != nil { 109 continue 110 } 111 if comp := bitsetEncodeBytes(orig); !bytes.Equal(comp, data) { 112 t.Errorf("test %d: decompress/compress mismatch: have %x, want %x", i, comp, data) 113 } 114 } 115 } 116 117 // TestCompression tests that compression works by returning either the bitset 118 // encoded input, or the actual input if the bitset version is longer. 119 func TestCompression(t *testing.T) { 120 // Check the compression returns the bitset encoding is shorter 121 in := hexutil.MustDecode("0x4912385c0e7b64000000") 122 out := hexutil.MustDecode("0x80fe4912385c0e7b64") 123 124 if data := CompressBytes(in); !bytes.Equal(data, out) { 125 t.Errorf("encoding mismatch for sparse data: have %x, want %x", data, out) 126 } 127 if data, err := DecompressBytes(out, len(in)); err != nil || !bytes.Equal(data, in) { 128 t.Errorf("decoding mismatch for sparse data: have %x, want %x, error %v", data, in, err) 129 } 130 // Check the compression returns the input if the bitset encoding is longer 131 in = hexutil.MustDecode("0xdf7070533534333636313639343638373532313536346c1bc33339343837313070706336343035336336346c65fefb3930393233383838ac2f65fefb") 132 out = hexutil.MustDecode("0xdf7070533534333636313639343638373532313536346c1bc33339343837313070706336343035336336346c65fefb3930393233383838ac2f65fefb") 133 134 if data := CompressBytes(in); !bytes.Equal(data, out) { 135 t.Errorf("encoding mismatch for dense data: have %x, want %x", data, out) 136 } 137 if data, err := DecompressBytes(out, len(in)); err != nil || !bytes.Equal(data, in) { 138 t.Errorf("decoding mismatch for dense data: have %x, want %x, error %v", data, in, err) 139 } 140 // Check that decompressing a longer input than the target fails 141 if _, err := DecompressBytes([]byte{0xc0, 0x01, 0x01}, 2); err != errExceededTarget { 142 t.Errorf("decoding error mismatch for long data: have %v, want %v", err, errExceededTarget) 143 } 144 } 145 146 // Crude benchmark for compressing random slices of bytes. 147 func BenchmarkEncoding1KBVerySparse(b *testing.B) { benchmarkEncoding(b, 1024, 0.0001) } 148 func BenchmarkEncoding2KBVerySparse(b *testing.B) { benchmarkEncoding(b, 2048, 0.0001) } 149 func BenchmarkEncoding4KBVerySparse(b *testing.B) { benchmarkEncoding(b, 4096, 0.0001) } 150 151 func BenchmarkEncoding1KBSparse(b *testing.B) { benchmarkEncoding(b, 1024, 0.001) } 152 func BenchmarkEncoding2KBSparse(b *testing.B) { benchmarkEncoding(b, 2048, 0.001) } 153 func BenchmarkEncoding4KBSparse(b *testing.B) { benchmarkEncoding(b, 4096, 0.001) } 154 155 func BenchmarkEncoding1KBDense(b *testing.B) { benchmarkEncoding(b, 1024, 0.1) } 156 func BenchmarkEncoding2KBDense(b *testing.B) { benchmarkEncoding(b, 2048, 0.1) } 157 func BenchmarkEncoding4KBDense(b *testing.B) { benchmarkEncoding(b, 4096, 0.1) } 158 159 func BenchmarkEncoding1KBSaturated(b *testing.B) { benchmarkEncoding(b, 1024, 0.5) } 160 func BenchmarkEncoding2KBSaturated(b *testing.B) { benchmarkEncoding(b, 2048, 0.5) } 161 func BenchmarkEncoding4KBSaturated(b *testing.B) { benchmarkEncoding(b, 4096, 0.5) } 162 163 func benchmarkEncoding(b *testing.B, bytes int, fill float64) { 164 // Generate a random slice of bytes to compress 165 random := rand.NewSource(0) // reproducible and comparable 166 167 data := make([]byte, bytes) 168 bits := int(float64(bytes) * 8 * fill) 169 170 for i := 0; i < bits; i++ { 171 idx := random.Int63() % int64(len(data)) 172 bit := uint(random.Int63() % 8) 173 data[idx] |= 1 << bit 174 } 175 // Reset the benchmark and measure encoding/decoding 176 b.ResetTimer() 177 b.ReportAllocs() 178 for i := 0; i < b.N; i++ { 179 bitsetDecodeBytes(bitsetEncodeBytes(data), len(data)) 180 } 181 }