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juicysfplugin/modules/juce_audio_formats/codecs/juce_MP3AudioFormat.cpp

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/*
==============================================================================
This file is part of the JUCE library.
Copyright (c) 2017 - ROLI Ltd.
JUCE is an open source library subject to commercial or open-source
licensing.
By using JUCE, you agree to the terms of both the JUCE 5 End-User License
Agreement and JUCE 5 Privacy Policy (both updated and effective as of the
27th April 2017).
End User License Agreement: www.juce.com/juce-5-licence
Privacy Policy: www.juce.com/juce-5-privacy-policy
Or: You may also use this code under the terms of the GPL v3 (see
www.gnu.org/licenses).
JUCE IS PROVIDED "AS IS" WITHOUT ANY WARRANTY, AND ALL WARRANTIES, WHETHER
EXPRESSED OR IMPLIED, INCLUDING MERCHANTABILITY AND FITNESS FOR PURPOSE, ARE
DISCLAIMED.
==============================================================================
*/
namespace juce
{
/*
IMPORTANT DISCLAIMER: By choosing to enable the JUCE_USE_MP3AUDIOFORMAT flag and
to compile this MP3 code into your software, you do so AT YOUR OWN RISK! By doing so,
you are agreeing that ROLI Ltd. is in no way responsible for any patent, copyright,
or other legal issues that you may suffer as a result.
The code in juce_MP3AudioFormat.cpp is NOT guaranteed to be free from infringements of 3rd-party
intellectual property. If you wish to use it, please seek your own independent advice about the
legality of doing so. If you are not willing to accept full responsibility for the consequences
of using this code, then do not enable the JUCE_USE_MP3AUDIOFORMAT setting.
*/
#if JUCE_USE_MP3AUDIOFORMAT
namespace MP3Decoder
{
struct AllocationTable { int16 bits, d; };
const struct AllocationTable allocTable0[] =
{
{4, 0}, {5, 3}, {3, -3}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {14, -8191}, {15, -16383}, {16, -32767},
{4, 0}, {5, 3}, {3, -3}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {14, -8191}, {15, -16383}, {16, -32767},
{4, 0}, {5, 3}, {3, -3}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {14, -8191}, {15, -16383}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767}, {3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767},
{3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767}, {3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767},
{3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767}, {3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767},
{3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767}, {3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767},
{3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767}, {3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767},
{3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767}, {3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767},
{2, 0}, {5, 3}, {7, 5}, {16, -32767}, {2, 0}, {5, 3}, {7, 5}, {16, -32767}, {2, 0}, {5, 3}, {7, 5}, {16, -32767}, {2, 0}, {5, 3}, {7, 5}, {16, -32767}
};
const struct AllocationTable allocTable1[] =
{
{4, 0}, {5, 3}, {3, -3}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {14, -8191}, {15, -16383}, {16, -32767},
{4, 0}, {5, 3}, {3, -3}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {14, -8191}, {15, -16383}, {16, -32767},
{4, 0}, {5, 3}, {3, -3}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {14, -8191}, {15, -16383}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {16, -32767},
{3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767}, {3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767},
{3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767}, {3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767},
{3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767}, {3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767},
{3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767}, {3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767},
{3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767}, {3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767},
{3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767}, {3, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {16, -32767},
{2, 0}, {5, 3}, {7, 5}, {16, -32767}, {2, 0}, {5, 3}, {7, 5}, {16, -32767}, {2, 0}, {5, 3}, {7, 5}, {16, -32767}, {2, 0}, {5, 3}, {7, 5}, {16, -32767},
{2, 0}, {5, 3}, {7, 5}, {16, -32767}, {2, 0}, {5, 3}, {7, 5}, {16, -32767}, {2, 0}, {5, 3}, {7, 5}, {16, -32767}
};
const struct AllocationTable allocTable2[] =
{
{4, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {14, -8191}, {15, -16383},
{4, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {14, -8191}, {15, -16383},
{3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63},
{3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63},
{3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}
};
const struct AllocationTable allocTable3[] =
{
{4, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {14, -8191}, {15, -16383},
{4, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {14, -8191}, {15, -16383},
{3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63},
{3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63},
{3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63},
{3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63},
{3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}
};
const struct AllocationTable allocTable4[] =
{
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {14, -8191},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {14, -8191},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {14, -8191},
{4, 0}, {5, 3}, {7, 5}, {3, -3}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {8, -127}, {9, -255}, {10, -511}, {11, -1023}, {12, -2047}, {13, -4095}, {14, -8191},
{3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63},
{3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63},
{3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63},
{3, 0}, {5, 3}, {7, 5}, {10, 9}, {4, -7}, {5, -15}, {6, -31}, {7, -63}, {2, 0}, {5, 3}, {7, 5}, {10, 9}, {2, 0}, {5, 3}, {7, 5}, {10, 9},
{2, 0}, {5, 3}, {7, 5}, {10, 9}, {2, 0}, {5, 3}, {7, 5}, {10, 9}, {2, 0}, {5, 3}, {7, 5}, {10, 9}, {2, 0}, {5, 3}, {7, 5}, {10, 9},
{2, 0}, {5, 3}, {7, 5}, {10, 9}, {2, 0}, {5, 3}, {7, 5}, {10, 9}, {2, 0}, {5, 3}, {7, 5}, {10, 9}, {2, 0}, {5, 3}, {7, 5}, {10, 9},
{2, 0}, {5, 3}, {7, 5}, {10, 9}, {2, 0}, {5, 3}, {7, 5}, {10, 9}, {2, 0}, {5, 3}, {7, 5}, {10, 9}, {2, 0}, {5, 3}, {7, 5}, {10, 9},
{2, 0}, {5, 3}, {7, 5}, {10, 9}, {2, 0}, {5, 3}, {7, 5}, {10, 9}, {2, 0}, {5, 3}, {7, 5}, {10, 9}, {2, 0}, {5, 3}, {7, 5}, {10, 9},
{2, 0}, {5, 3}, {7, 5}, {10, 9}
};
struct BandInfoStruct
{
int16 longIndex[23];
int16 longDiff[22];
int16 shortIndex[14];
int16 shortDiff[13];
};
const BandInfoStruct bandInfo[9] =
{
{ {0, 4, 8, 12, 16, 20, 24, 30, 36, 44, 52, 62, 74, 90, 110, 134, 162, 196, 238, 288, 342, 418, 576},
{4, 4, 4, 4, 4, 4, 6, 6, 8, 8, 10, 12, 16, 20, 24, 28, 34, 42, 50, 54, 76, 158},
{0, 4 * 3, 8 * 3, 12 * 3, 16 * 3, 22 * 3, 30 * 3, 40 * 3, 52 * 3, 66 * 3, 84 * 3, 106 * 3, 136 * 3, 192 * 3},
{4, 4, 4, 4, 6, 8, 10, 12, 14, 18, 22, 30, 56} },
{ {0, 4, 8, 12, 16, 20, 24, 30, 36, 42, 50, 60, 72, 88, 106, 128, 156, 190, 230, 276, 330, 384, 576},
{4, 4, 4, 4, 4, 4, 6, 6, 6, 8, 10, 12, 16, 18, 22, 28, 34, 40, 46, 54, 54, 192},
{0, 4 * 3, 8 * 3, 12 * 3, 16 * 3, 22 * 3, 28 * 3, 38 * 3, 50 * 3, 64 * 3, 80 * 3, 100 * 3, 126 * 3, 192 * 3},
{4, 4, 4, 4, 6, 6, 10, 12, 14, 16, 20, 26, 66} },
{ {0, 4, 8, 12, 16, 20, 24, 30, 36, 44, 54, 66, 82, 102, 126, 156, 194, 240, 296, 364, 448, 550, 576},
{4, 4, 4, 4, 4, 4, 6, 6, 8, 10, 12, 16, 20, 24, 30, 38, 46, 56, 68, 84, 102, 26},
{0, 4 * 3, 8 * 3, 12 * 3, 16 * 3, 22 * 3, 30 * 3, 42 * 3, 58 * 3, 78 * 3, 104 * 3, 138 * 3, 180 * 3, 192 * 3},
{4, 4, 4, 4, 6, 8, 12, 16, 20, 26, 34, 42, 12} },
{ {0, 6, 12, 18, 24, 30, 36, 44, 54, 66, 80, 96, 116, 140, 168, 200, 238, 284, 336, 396, 464, 522, 576},
{6, 6, 6, 6, 6, 6, 8, 10, 12, 14, 16, 20, 24, 28, 32, 38, 46, 52, 60, 68, 58, 54 },
{0, 4 * 3, 8 * 3, 12 * 3, 18 * 3, 24 * 3, 32 * 3, 42 * 3, 56 * 3, 74 * 3, 100 * 3, 132 * 3, 174 * 3, 192 * 3},
{4, 4, 4, 6, 6, 8, 10, 14, 18, 26, 32, 42, 18 } },
{ {0, 6, 12, 18, 24, 30, 36, 44, 54, 66, 80, 96, 114, 136, 162, 194, 232, 278, 332, 394, 464, 540, 576},
{6, 6, 6, 6, 6, 6, 8, 10, 12, 14, 16, 18, 22, 26, 32, 38, 46, 54, 62, 70, 76, 36 },
{0, 4 * 3, 8 * 3, 12 * 3, 18 * 3, 26 * 3, 36 * 3, 48 * 3, 62 * 3, 80 * 3, 104 * 3, 136 * 3, 180 * 3, 192 * 3},
{4, 4, 4, 6, 8, 10, 12, 14, 18, 24, 32, 44, 12 } },
{ {0, 6, 12, 18, 24, 30, 36, 44, 54, 66, 80, 96, 116, 140, 168, 200, 238, 284, 336, 396, 464, 522, 576},
{6, 6, 6, 6, 6, 6, 8, 10, 12, 14, 16, 20, 24, 28, 32, 38, 46, 52, 60, 68, 58, 54 },
{0, 4 * 3, 8 * 3, 12 * 3, 18 * 3, 26 * 3, 36 * 3, 48 * 3, 62 * 3, 80 * 3, 104 * 3, 134 * 3, 174 * 3, 192 * 3},
{4, 4, 4, 6, 8, 10, 12, 14, 18, 24, 30, 40, 18 } },
{ {0, 6, 12, 18, 24, 30, 36, 44, 54, 66, 80, 96, 116, 140, 168, 200, 238, 284, 336, 396, 464, 522, 576},
{6, 6, 6, 6, 6, 6, 8, 10, 12, 14, 16, 20, 24, 28, 32, 38, 46, 52, 60, 68, 58, 54},
{0, 12, 24, 36, 54, 78, 108, 144, 186, 240, 312, 402, 522, 576},
{4, 4, 4, 6, 8, 10, 12, 14, 18, 24, 30, 40, 18} },
{ {0, 6, 12, 18, 24, 30, 36, 44, 54, 66, 80, 96, 116, 140, 168, 200, 238, 284, 336, 396, 464, 522, 576},
{6, 6, 6, 6, 6, 6, 8, 10, 12, 14, 16, 20, 24, 28, 32, 38, 46, 52, 60, 68, 58, 54},
{0, 12, 24, 36, 54, 78, 108, 144, 186, 240, 312, 402, 522, 576},
{4, 4, 4, 6, 8, 10, 12, 14, 18, 24, 30, 40, 18} },
{ {0, 12, 24, 36, 48, 60, 72, 88, 108, 132, 160, 192, 232, 280, 336, 400, 476, 566, 568, 570, 572, 574, 576},
{12, 12, 12, 12, 12, 12, 16, 20, 24, 28, 32, 40, 48, 56, 64, 76, 90, 2, 2, 2, 2, 2},
{0, 24, 48, 72, 108, 156, 216, 288, 372, 480, 486, 492, 498, 576},
{8, 8, 8, 12, 16, 20, 24, 28, 36, 2, 2, 2, 26} }
};
const double decodeWindow[] =
{
0.000000000, -0.000015259, -0.000015259, -0.000015259, -0.000015259, -0.000015259, -0.000015259, -0.000030518,
-0.000030518, -0.000030518, -0.000030518, -0.000045776, -0.000045776, -0.000061035, -0.000061035, -0.000076294,
-0.000076294, -0.000091553, -0.000106812, -0.000106812, -0.000122070, -0.000137329, -0.000152588, -0.000167847,
-0.000198364, -0.000213623, -0.000244141, -0.000259399, -0.000289917, -0.000320435, -0.000366211, -0.000396729,
-0.000442505, -0.000473022, -0.000534058, -0.000579834, -0.000625610, -0.000686646, -0.000747681, -0.000808716,
-0.000885010, -0.000961304, -0.001037598, -0.001113892, -0.001205444, -0.001296997, -0.001388550, -0.001480103,
-0.001586914, -0.001693726, -0.001785278, -0.001907349, -0.002014160, -0.002120972, -0.002243042, -0.002349854,
-0.002456665, -0.002578735, -0.002685547, -0.002792358, -0.002899170, -0.002990723, -0.003082275, -0.003173828,
-0.003250122, -0.003326416, -0.003387451, -0.003433228, -0.003463745, -0.003479004, -0.003479004, -0.003463745,
-0.003417969, -0.003372192, -0.003280640, -0.003173828, -0.003051758, -0.002883911, -0.002700806, -0.002487183,
-0.002227783, -0.001937866, -0.001617432, -0.001266479, -0.000869751, -0.000442505, 0.000030518, 0.000549316,
0.001098633, 0.001693726, 0.002334595, 0.003005981, 0.003723145, 0.004486084, 0.005294800, 0.006118774,
0.007003784, 0.007919312, 0.008865356, 0.009841919, 0.010848999, 0.011886597, 0.012939453, 0.014022827,
0.015121460, 0.016235352, 0.017349243, 0.018463135, 0.019577026, 0.020690918, 0.021789551, 0.022857666,
0.023910522, 0.024932861, 0.025909424, 0.026840210, 0.027725220, 0.028533936, 0.029281616, 0.029937744,
0.030532837, 0.031005859, 0.031387329, 0.031661987, 0.031814575, 0.031845093, 0.031738281, 0.031478882,
0.031082153, 0.030517578, 0.029785156, 0.028884888, 0.027801514, 0.026535034, 0.025085449, 0.023422241,
0.021575928, 0.019531250, 0.017257690, 0.014801025, 0.012115479, 0.009231567, 0.006134033, 0.002822876,
-0.000686646, -0.004394531, -0.008316040, -0.012420654, -0.016708374, -0.021179199, -0.025817871, -0.030609131,
-0.035552979, -0.040634155, -0.045837402, -0.051132202, -0.056533813, -0.061996460, -0.067520142, -0.073059082,
-0.078628540, -0.084182739, -0.089706421, -0.095169067, -0.100540161, -0.105819702, -0.110946655, -0.115921021,
-0.120697021, -0.125259399, -0.129562378, -0.133590698, -0.137298584, -0.140670776, -0.143676758, -0.146255493,
-0.148422241, -0.150115967, -0.151306152, -0.151962280, -0.152069092, -0.151596069, -0.150497437, -0.148773193,
-0.146362305, -0.143264771, -0.139450073, -0.134887695, -0.129577637, -0.123474121, -0.116577148, -0.108856201,
-0.100311279, -0.090927124, -0.080688477, -0.069595337, -0.057617187, -0.044784546, -0.031082153, -0.016510010,
-0.001068115, 0.015228271, 0.032379150, 0.050354004, 0.069168091, 0.088775635, 0.109161377, 0.130310059,
0.152206421, 0.174789429, 0.198059082, 0.221984863, 0.246505737, 0.271591187, 0.297210693, 0.323318481,
0.349868774, 0.376800537, 0.404083252, 0.431655884, 0.459472656, 0.487472534, 0.515609741, 0.543823242,
0.572036743, 0.600219727, 0.628295898, 0.656219482, 0.683914185, 0.711318970, 0.738372803, 0.765029907,
0.791213989, 0.816864014, 0.841949463, 0.866363525, 0.890090942, 0.913055420, 0.935195923, 0.956481934,
0.976852417, 0.996246338, 1.014617920, 1.031936646, 1.048156738, 1.063217163, 1.077117920, 1.089782715,
1.101211548, 1.111373901, 1.120223999, 1.127746582, 1.133926392, 1.138763428, 1.142211914, 1.144287109,
1.144989014
};
const int16 huffmanTab0[] = { 0 };
const int16 huffmanTab1[] = { -5,-3,-1,17,1,16,0 };
const int16 huffmanTab2[] = { -15,-11,-9,-5,-3,-1,34,2,18,-1,33,32,17,-1,1,16,0 };
const int16 huffmanTab3[] = { -13,-11,-9,-5,-3,-1,34,2,18,-1,33,32,16,17,-1,1,0 };
const int16 huffmanTab5[] = { -29,-25,-23,-15,-7,-5,-3,-1,51,35,50,49,-3,-1,19,3,-1,48,34,-3,-1,18,33,-1,2,32,17,-1,1,16,0 };
const int16 huffmanTab6[] = { -25,-19,-13,-9,-5,-3,-1,51,3,35,-1,50,48,-1,19,49,-3,-1,34,2,18,-3,-1,33,32,1,-1,17,-1,16,0 };
const int16 huffmanTab7[] =
{
-69,-65,-57,-39,-29,-17,-11,-7,-3,-1,85,69,-1,84,83,-1,53,68,-3,-1,37,82,21,-5,-1,81,-1,5,52,-1,80,-1,67,51,
-5,-3,-1,36,66,20,-1,65,64,-11,-7,-3,-1,4,35,-1,50,3,-1,19,49,-3,-1,48,34,18,-5,-1,33,-1,2,32,17,-1,1,16,0
};
const int16 huffmanTab8[] =
{
-65,-63,-59,-45,-31,-19,-13,-7,-5,-3,-1,85,84,69,83,-3,-1,53,68,37,-3,-1,82,5,21,-5,-1,81,-1,52,67,-3,-1,80,
51,36,-5,-3,-1,66,20,65,-3,-1,4,64,-1,35,50,-9,-7,-3,-1,19,49,-1,3,48,34,-1,2,32,-1,18,33,17,-3,-1,1,16,0
};
const int16 huffmanTab9[] =
{
-63,-53,-41,-29,-19,-11,-5,-3,-1,85,69,53,-1,83,-1,84,5,-3,-1,68,37,-1,82,21,-3,-1,81,52,-1,67,-1,80,4,-7,-3,
-1,36,66,-1,51,64,-1,20,65,-5,-3,-1,35,50,19,-1,49,-1,3,48,-5,-3,-1,34,2,18,-1,33,32,-3,-1,17,1,-1,16,0
};
const int16 huffmanTab10[] =
{
-125,-121,-111,-83,-55,-35,-21,-13,-7,-3,-1,119,103,-1,118,87,-3,-1,117,102,71,-3,-1,116,86,-1,101,55,-9,-3,
-1,115,70,-3,-1,85,84,99,-1,39,114,-11,-5,-3,-1,100,7,112,-1,98,-1,69,53,-5,-1,6,-1,83,68,23,-17,-5,-1,113,
-1,54,38,-5,-3,-1,37,82,21,-1,81,-1,52,67,-3,-1,22,97,-1,96,-1,5,80,-19,-11,-7,-3,-1,36,66,-1,51,4,-1,20,
65,-3,-1,64,35,-1,50,3,-3,-1,19,49,-1,48,34,-7,-3,-1,18,33,-1,2,32,17,-1,1,16,0
};
const int16 huffmanTab11[] =
{
-121,-113,-89,-59,-43,-27,-17,-7,-3,-1,119,103,-1,118,117,-3,-1,102,71,-1,116,-1,87,85,-5,-3,-1,86,101,55,
-1,115,70,-9,-7,-3,-1,69,84,-1,53,83,39,-1,114,-1,100,7,-5,-1,113,-1,23,112,-3,-1,54,99,-1,96,-1,68,37,-13,
-7,-5,-3,-1,82,5,21,98,-3,-1,38,6,22,-5,-1,97,-1,81,52,-5,-1,80,-1,67,51,-1,36,66,-15,-11,-7,-3,-1,20,65,
-1,4,64,-1,35,50,-1,19,49,-5,-3,-1,3,48,34,33,-5,-1,18,-1,2,32,17,-3,-1,1,16,0
};
const int16 huffmanTab12[] =
{
-115,-99,-73,-45,-27,-17,-9,-5,-3,-1,119,103,118,-1,87,117,-3,-1,102,71,-1,116,101,-3,-1,86,55,-3,-1,115,
85,39,-7,-3,-1,114,70,-1,100,23,-5,-1,113,-1,7,112,-1,54,99,-13,-9,-3,-1,69,84,-1,68,-1,6,5,-1,38,98,-5,
-1,97,-1,22,96,-3,-1,53,83,-1,37,82,-17,-7,-3,-1,21,81,-1,52,67,-5,-3,-1,80,4,36,-1,66,20,-3,-1,51,65,-1,
35,50,-11,-7,-5,-3,-1,64,3,48,19,-1,49,34,-1,18,33,-7,-5,-3,-1,2,32,0,17,-1,1,16
};
const int16 huffmanTab13[] =
{
-509,-503,-475,-405,-333,-265,-205,-153,-115,-83,-53,-35,-21,-13,-9,-7,-5,-3,-1,254,252,253,237,255,-1,239,223,
-3,-1,238,207,-1,222,191,-9,-3,-1,251,206,-1,220,-1,175,233,-1,236,221,-9,-5,-3,-1,250,205,190,-1,235,159,-3,
-1,249,234,-1,189,219,-17,-9,-3,-1,143,248,-1,204,-1,174,158,-5,-1,142,-1,127,126,247,-5,-1,218,-1,173,188,-3,
-1,203,246,111,-15,-7,-3,-1,232,95,-1,157,217,-3,-1,245,231,-1,172,187,-9,-3,-1,79,244,-3,-1,202,230,243,-1,
63,-1,141,216,-21,-9,-3,-1,47,242,-3,-1,110,156,15,-5,-3,-1,201,94,171,-3,-1,125,215,78,-11,-5,-3,-1,200,214,
62,-1,185,-1,155,170,-1,31,241,-23,-13,-5,-1,240,-1,186,229,-3,-1,228,140,-1,109,227,-5,-1,226,-1,46,14,-1,30,
225,-15,-7,-3,-1,224,93,-1,213,124,-3,-1,199,77,-1,139,184,-7,-3,-1,212,154,-1,169,108,-1,198,61,-37,-21,-9,-5,
-3,-1,211,123,45,-1,210,29,-5,-1,183,-1,92,197,-3,-1,153,122,195,-7,-5,-3,-1,167,151,75,209,-3,-1,13,208,-1,
138,168,-11,-7,-3,-1,76,196,-1,107,182,-1,60,44,-3,-1,194,91,-3,-1,181,137,28,-43,-23,-11,-5,-1,193,-1,152,12,
-1,192,-1,180,106,-5,-3,-1,166,121,59,-1,179,-1,136,90,-11,-5,-1,43,-1,165,105,-1,164,-1,120,135,-5,-1,148,-1,
119,118,178,-11,-3,-1,27,177,-3,-1,11,176,-1,150,74,-7,-3,-1,58,163,-1,89,149,-1,42,162,-47,-23,-9,-3,-1,26,
161,-3,-1,10,104,160,-5,-3,-1,134,73,147,-3,-1,57,88,-1,133,103,-9,-3,-1,41,146,-3,-1,87,117,56,-5,-1,131,-1,
102,71,-3,-1,116,86,-1,101,115,-11,-3,-1,25,145,-3,-1,9,144,-1,72,132,-7,-5,-1,114,-1,70,100,40,-1,130,24,-41,
-27,-11,-5,-3,-1,55,39,23,-1,113,-1,85,7,-7,-3,-1,112,54,-1,99,69,-3,-1,84,38,-1,98,53,-5,-1,129,-1,8,128,-3,
-1,22,97,-1,6,96,-13,-9,-5,-3,-1,83,68,37,-1,82,5,-1,21,81,-7,-3,-1,52,67,-1,80,36,-3,-1,66,51,20,-19,-11,
-5,-1,65,-1,4,64,-3,-1,35,50,19,-3,-1,49,3,-1,48,34,-3,-1,18,33,-1,2,32,-3,-1,17,1,16,0
};
const int16 huffmanTab15[] =
{
-495,-445,-355,-263,-183,-115,-77,-43,-27,-13,-7,-3,-1,255,239,-1,254,223,-1,238,-1,253,207,-7,-3,-1,252,222,-1,
237,191,-1,251,-1,206,236,-7,-3,-1,221,175,-1,250,190,-3,-1,235,205,-1,220,159,-15,-7,-3,-1,249,234,-1,189,219,
-3,-1,143,248,-1,204,158,-7,-3,-1,233,127,-1,247,173,-3,-1,218,188,-1,111,-1,174,15,-19,-11,-3,-1,203,246,
-3,-1,142,232,-1,95,157,-3,-1,245,126,-1,231,172,-9,-3,-1,202,187,-3,-1,217,141,79,-3,-1,244,63,-1,243,216,
-33,-17,-9,-3,-1,230,47,-1,242,-1,110,240,-3,-1,31,241,-1,156,201,-7,-3,-1,94,171,-1,186,229,-3,-1,125,215,
-1,78,228,-15,-7,-3,-1,140,200,-1,62,109,-3,-1,214,227,-1,155,185,-7,-3,-1,46,170,-1,226,30,-5,-1,225,-1,14,
224,-1,93,213,-45,-25,-13,-7,-3,-1,124,199,-1,77,139,-1,212,-1,184,154,-7,-3,-1,169,108,-1,198,61,-1,211,210,
-9,-5,-3,-1,45,13,29,-1,123,183,-5,-1,209,-1,92,208,-1,197,138,-17,-7,-3,-1,168,76,-1,196,107,-5,-1,182,-1,
153,12,-1,60,195,-9,-3,-1,122,167,-1,166,-1,192,11,-1,194,-1,44,91,-55,-29,-15,-7,-3,-1,181,28,-1,137,152,-3,
-1,193,75,-1,180,106,-5,-3,-1,59,121,179,-3,-1,151,136,-1,43,90,-11,-5,-1,178,-1,165,27,-1,177,-1,176,105,-7,
-3,-1,150,74,-1,164,120,-3,-1,135,58,163,-17,-7,-3,-1,89,149,-1,42,162,-3,-1,26,161,-3,-1,10,160,104,-7,-3,
-1,134,73,-1,148,57,-5,-1,147,-1,119,9,-1,88,133,-53,-29,-13,-7,-3,-1,41,103,-1,118,146,-1,145,-1,25,144,-7,
-3,-1,72,132,-1,87,117,-3,-1,56,131,-1,102,71,-7,-3,-1,40,130,-1,24,129,-7,-3,-1,116,8,-1,128,86,-3,-1,101,
55,-1,115,70,-17,-7,-3,-1,39,114,-1,100,23,-3,-1,85,113,-3,-1,7,112,54,-7,-3,-1,99,69,-1,84,38,-3,-1,98,22,
-3,-1,6,96,53,-33,-19,-9,-5,-1,97,-1,83,68,-1,37,82,-3,-1,21,81,-3,-1,5,80,52,-7,-3,-1,67,36,-1,66,51,-1,
65,-1,20,4,-9,-3,-1,35,50,-3,-1,64,3,19,-3,-1,49,48,34,-9,-7,-3,-1,18,33,-1,2,32,17,-3,-1,1,16,0
};
const int16 huffmanTab16[] =
{
-509,-503,-461,-323,-103,-37,-27,-15,-7,-3,-1,239,254,-1,223,253,-3,-1,207,252,-1,191,251,-5,-1,175,-1,250,159,
-3,-1,249,248,143,-7,-3,-1,127,247,-1,111,246,255,-9,-5,-3,-1,95,245,79,-1,244,243,-53,-1,240,-1,63,-29,-19,
-13,-7,-5,-1,206,-1,236,221,222,-1,233,-1,234,217,-1,238,-1,237,235,-3,-1,190,205,-3,-1,220,219,174,-11,-5,
-1,204,-1,173,218,-3,-1,126,172,202,-5,-3,-1,201,125,94,189,242,-93,-5,-3,-1,47,15,31,-1,241,-49,-25,-13,
-5,-1,158,-1,188,203,-3,-1,142,232,-1,157,231,-7,-3,-1,187,141,-1,216,110,-1,230,156,-13,-7,-3,-1,171,186,
-1,229,215,-1,78,-1,228,140,-3,-1,200,62,-1,109,-1,214,155,-19,-11,-5,-3,-1,185,170,225,-1,212,-1,184,169,
-5,-1,123,-1,183,208,227,-7,-3,-1,14,224,-1,93,213,-3,-1,124,199,-1,77,139,-75,-45,-27,-13,-7,-3,-1,154,
108,-1,198,61,-3,-1,92,197,13,-7,-3,-1,138,168,-1,153,76,-3,-1,182,122,60,-11,-5,-3,-1,91,137,28,-1,192,-1,
152,121,-1,226,-1,46,30,-15,-7,-3,-1,211,45,-1,210,209,-5,-1,59,-1,151,136,29,-7,-3,-1,196,107,-1,195,167,-1,
44,-1,194,181,-23,-13,-7,-3,-1,193,12,-1,75,180,-3,-1,106,166,179,-5,-3,-1,90,165,43,-1,178,27,-13,-5,-1,177,
-1,11,176,-3,-1,105,150,-1,74,164,-5,-3,-1,120,135,163,-3,-1,58,89,42,-97,-57,-33,-19,-11,-5,-3,-1,149,104,161,
-3,-1,134,119,148,-5,-3,-1,73,87,103,162,-5,-1,26,-1,10,160,-3,-1,57,147,-1,88,133,-9,-3,-1,41,146,-3,-1,118,
9,25,-5,-1,145,-1,144,72,-3,-1,132,117,-1,56,131,-21,-11,-5,-3,-1,102,40,130,-3,-1,71,116,24,-3,-1,129,128,-3,
-1,8,86,55,-9,-5,-1,115,-1,101,70,-1,39,114,-5,-3,-1,100,85,7,23,-23,-13,-5,-1,113,-1,112,54,-3,-1,99,69,-1,
84,38,-3,-1,98,22,-1,97,-1,6,96,-9,-5,-1,83,-1,53,68,-1,37,82,-1,81,-1,21,5,-33,-23,-13,-7,-3,-1,52,67,-1,80,
36,-3,-1,66,51,20,-5,-1,65,-1,4,64,-1,35,50,-3,-1,19,49,-3,-1,3,48,34,-3,-1,18,33,-1,2,32,-3,-1,17,1,16,0
};
const int16 huffmanTab24[] =
{
-451,-117,-43,-25,-15,-7,-3,-1,239,254,-1,223,253,-3,-1,207,252,-1,191,251,-5,-1,250,-1,175,159,-1,249,248,-9,
-5,-3,-1,143,127,247,-1,111,246,-3,-1,95,245,-1,79,244,-71,-7,-3,-1,63,243,-1,47,242,-5,-1,241,-1,31,240,-25,-9,
-1,15,-3,-1,238,222,-1,237,206,-7,-3,-1,236,221,-1,190,235,-3,-1,205,220,-1,174,234,-15,-7,-3,-1,189,219,-1,204,
158,-3,-1,233,173,-1,218,188,-7,-3,-1,203,142,-1,232,157,-3,-1,217,126,-1,231,172,255,-235,-143,-77,-45,-25,-15,
-7,-3,-1,202,187,-1,141,216,-5,-3,-1,14,224,13,230,-5,-3,-1,110,156,201,-1,94,186,-9,-5,-1,229,-1,171,125,-1,215,
228,-3,-1,140,200,-3,-1,78,46,62,-15,-7,-3,-1,109,214,-1,227,155,-3,-1,185,170,-1,226,30,-7,-3,-1,225,93,-1,213,124,
-3,-1,199,77,-1,139,184,-31,-15,-7,-3,-1,212,154,-1,169,108,-3,-1,198,61,-1,211,45,-7,-3,-1,210,29,-1,123,183,-3,-1,
209,92,-1,197,138,-17,-7,-3,-1,168,153,-1,76,196,-3,-1,107,182,-3,-1,208,12,60,-7,-3,-1,195,122,-1,167,44,-3,-1,194,
91,-1,181,28,-57,-35,-19,-7,-3,-1,137,152,-1,193,75,-5,-3,-1,192,11,59,-3,-1,176,10,26,-5,-1,180,-1,106,166,-3,-1,121,
151,-3,-1,160,9,144,-9,-3,-1,179,136,-3,-1,43,90,178,-7,-3,-1,165,27,-1,177,105,-1,150,164,-17,-9,-5,-3,-1,74,120,135,
-1,58,163,-3,-1,89,149,-1,42,162,-7,-3,-1,161,104,-1,134,119,-3,-1,73,148,-1,57,147,-63,-31,-15,-7,-3,-1,88,133,-1,41,
103,-3,-1,118,146,-1,25,145,-7,-3,-1,72,132,-1,87,117,-3,-1,56,131,-1,102,40,-17,-7,-3,-1,130,24,-1,71,116,-5,-1,129,
-1,8,128,-1,86,101,-7,-5,-1,23,-1,7,112,115,-3,-1,55,39,114,-15,-7,-3,-1,70,100,-1,85,113,-3,-1,54,99,-1,69,84,-7,-3,
-1,38,98,-1,22,97,-5,-3,-1,6,96,53,-1,83,68,-51,-37,-23,-15,-9,-3,-1,37,82,-1,21,-1,5,80,-1,81,-1,52,67,-3,-1,36,66,
-1,51,20,-9,-5,-1,65,-1,4,64,-1,35,50,-1,19,49,-7,-5,-3,-1,3,48,34,18,-1,33,-1,2,32,-3,-1,17,1,-1,16,0
};
struct BitsToTableMap
{
uint32 bits;
const int16* table;
};
const BitsToTableMap huffmanTables1[] =
{
{ 0, huffmanTab0 }, { 0, huffmanTab1 }, { 0, huffmanTab2 }, { 0, huffmanTab3 },
{ 0, huffmanTab0 }, { 0, huffmanTab5 }, { 0, huffmanTab6 }, { 0, huffmanTab7 },
{ 0, huffmanTab8 }, { 0, huffmanTab9 }, { 0, huffmanTab10 }, { 0, huffmanTab11 },
{ 0, huffmanTab12 }, { 0, huffmanTab13 }, { 0, huffmanTab0 }, { 0, huffmanTab15 },
{ 1, huffmanTab16 }, { 2, huffmanTab16 }, { 3, huffmanTab16 }, { 4, huffmanTab16 },
{ 6, huffmanTab16 }, { 8, huffmanTab16 }, { 10, huffmanTab16 }, { 13, huffmanTab16 },
{ 4, huffmanTab24 }, { 5, huffmanTab24 }, { 6, huffmanTab24 }, { 7, huffmanTab24 },
{ 8, huffmanTab24 }, { 9, huffmanTab24 }, { 11, huffmanTab24 }, { 13, huffmanTab24 }
};
const int16 huffmanTabC0[] = { -29,-21,-13,-7,-3,-1,11,15,-1,13,14,-3,-1,7,5,9,-3,-1,6,3,-1,10,12,-3,-1,2,1,-1,4,8,0 };
const int16 huffmanTabC1[] = { -15,-7,-3,-1,15,14,-1,13,12,-3,-1,11,10,-1,9,8,-7,-3,-1,7,6,-1,5,4,-3,-1,3,2,-1,1,0 };
const BitsToTableMap huffmanTables2[] = { { 0, huffmanTabC0 }, { 0, huffmanTabC1 } };
//==============================================================================
struct VBRTagData
{
bool read (const uint8* data) noexcept
{
flags = 0;
const int layer = (data[1] >> 1) & 3;
if (layer != 1)
return false;
const int type = (data[1] >> 3) & 1;
const int sampleRateIndex = (data[2] >> 2) & 3;
const int mode = (data[3] >> 6) & 3;
static const short bitRates[3][16] =
{
{ 0, 8, 16, 24, 32, 40, 48, 56, 64, 80, 96, 112, 128, 144, 160, -1 }, // MPEG2
{ 0, 32, 40, 48, 56, 64, 80, 96, 112, 128, 160, 192, 224, 256, 320, -1 }, // MPEG1
{ 0, 8, 16, 24, 32, 40, 48, 56, 64, -1, -1, -1, -1, -1, -1, -1 }, // MPEG 2.5
};
const int bitrate = bitRates[type][((data[2] >> 4) & 15)];
const int sampleRates[3][4] =
{
{ 22050, 24000, 16000, -1 }, // MPEG2
{ 44100, 48000, 32000, -1 }, // MPEG1
{ 11025, 12000, 8000, -1 }, // MPEG2.5
};
if ((data[1] >> 4) == 0xe)
sampleRate = sampleRates[2][sampleRateIndex];
else
sampleRate = sampleRates[type][sampleRateIndex];
data += type != 0 ? (mode != 3 ? (32 + 4) : (17 + 4))
: (mode != 3 ? (17 + 4) : (9 + 4));
if (! isVbrTag (data))
return false;
data += 4;
flags = ByteOrder::bigEndianInt (data);
data += 4;
if (flags & 1)
{
frames = ByteOrder::bigEndianInt (data);
data += 4;
}
if (flags & 2)
{
bytes = ByteOrder::bigEndianInt (data);
data += 4;
}
if (flags & 4)
{
for (int i = 0; i < 100; ++i)
toc[i] = data[i];
data += 100;
}
vbrScale = -1;
if (flags & 8)
vbrScale = (int) ByteOrder::bigEndianInt (data);
headersize = ((type + 1) * 72000 * bitrate) / sampleRate;
return true;
}
uint8 toc[100];
int sampleRate, vbrScale, headersize;
unsigned int flags, frames, bytes;
private:
static bool isVbrTag (const uint8* d) noexcept
{
return (d[0] == 'X' && d[1] == 'i' && d[2] == 'n' && d[3] == 'g')
|| (d[0] == 'I' && d[1] == 'n' && d[2] == 'f' && d[3] == 'o');
}
};
//==============================================================================
struct MP3Frame
{
MP3Frame()
{
zeromem (this, sizeof (MP3Frame));
single = -1;
}
void selectLayer2Table()
{
static const int translate[3][2][16] =
{
{ { 0, 2, 2, 2, 2, 2, 2, 0, 0, 0, 1, 1, 1, 1, 1, 0 }, { 0, 2, 2, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0 } },
{ { 0, 2, 2, 2, 2, 2, 2, 0, 0, 0, 0, 0, 0, 0, 0, 0 }, { 0, 2, 2, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 } },
{ { 0, 3, 3, 3, 3, 3, 3, 0, 0, 0, 1, 1, 1, 1, 1, 0 }, { 0, 3, 3, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0 } }
};
static const AllocationTable* const tables[] = { allocTable0, allocTable1, allocTable2, allocTable3, allocTable4 };
static const int8 limits[] = { 27, 30, 8, 12, 30 };
const int index = lsf ? 4 : translate[sampleRateIndex][2 - numChannels][bitrateIndex];
layer2SubBandLimit = limits[index];
allocationTable = tables[index];
}
int getFrequency() const noexcept
{
const int frequencies[] = { 44100, 48000, 32000, 22050, 24000, 16000, 11025, 12000, 8000 };
return frequencies[sampleRateIndex];
}
void decodeHeader (const uint32 header)
{
jassert (((header >> 10) & 3) != 3);
mpeg25 = (header & (1 << 20)) == 0;
lsf = mpeg25 ? 1 : ((header & (1 << 19)) ? 0 : 1);
layer = 4 - ((header >> 17) & 3);
sampleRateIndex = mpeg25 ? (6 + ((header >> 10) & 3)) : ((int) ((header >> 10) & 3) + (lsf * 3));
crc16FollowsHeader = ((header >> 16) & 1) == 0;
bitrateIndex = (header >> 12) & 15;
padding = (header >> 9) & 1;
mode = (header >> 6) & 3;
modeExt = (header >> 4) & 3;
//extension = (header >> 8) & 1;
//copyright = (header >> 3) & 1;
//original = (header >> 2) & 1;
//emphasis = header & 3;
numChannels = (mode == 3) ? 1 : 2;
static const int frameSizes[2][3][16] =
{
{ { 0, 32, 64, 96, 128, 160, 192, 224, 256, 288, 320, 352, 384, 416, 448 },
{ 0, 32, 48, 56, 64, 80, 96, 112, 128, 160, 192, 224, 256, 320, 384 },
{ 0, 32, 40, 48, 56, 64, 80, 96, 112, 128, 160, 192, 224, 256, 320 } },
{ { 0, 32, 48, 56, 64, 80, 96, 112, 128, 144, 160, 176, 192, 224, 256 },
{ 0, 8, 16, 24, 32, 40, 48, 56, 64, 80, 96, 112, 128, 144, 160 },
{ 0, 8, 16, 24, 32, 40, 48, 56, 64, 80, 96, 112, 128, 144, 160 } }
};
if (bitrateIndex == 0)
{
jassertfalse; // This means the file is using "free format". Apparently very few decoders
// support this mode, and this one certainly doesn't handle it correctly!
frameSize = 0;
}
else
{
switch (layer)
{
case 1: frameSize = (((frameSizes[lsf][0][bitrateIndex] * 12000) / getFrequency() + padding) * 4) - 4; break;
case 2: frameSize = (frameSizes[lsf][1][bitrateIndex] * 144000) / getFrequency() + (padding - 4); break;
case 3: frameSize = (bitrateIndex == 0) ? 0 : ((frameSizes[lsf][2][bitrateIndex] * 144000) / (getFrequency() << lsf) + (padding - 4)); break;
default: break;
}
}
}
int layer, frameSize, numChannels, single;
int lsf; // 0 = mpeg-1, 1 = mpeg-2/LSF
bool mpeg25; // true = mpeg-2.5, false = mpeg-1/2
bool crc16FollowsHeader;
int bitrateIndex, sampleRateIndex, padding;
int mode, modeExt, layer2SubBandLimit;
enum { downSampleLimit = 32 };
const AllocationTable* allocationTable;
};
//==============================================================================
struct Constants
{
Constants()
{
cosTables[0] = cos64; cosTables[1] = cos32; cosTables[2] = cos16; cosTables[3] = cos8; cosTables[4] = cos4;
initDecodeTables();
initLayer2Tables();
initLayer3Tables();
}
const uint8* getGroupTable (const int16 d1, const uint32 index) const noexcept
{
switch (d1)
{
case 3: return &group3tab[3 * jmin (index, 3u * 3u * 3u)];
case 5: return &group5tab[3 * jmin (index, 5u * 5u * 5u)];
case 9: return &group9tab[3 * jmin (index, 9u * 9u * 9u)];
default: break;
}
static const uint8 dummy[] = { 0, 0, 0 };
return dummy;
}
float muls[27][64];
float nToThe4Over3[8207];
float antiAliasingCa[8], antiAliasingCs[8];
float win[4][36];
float win1[4][36];
float powToGains[256 + 118 + 4];
int longLimit[9][23];
int shortLimit[9][14];
float tan1_1[16], tan2_1[16], tan1_2[16], tan2_2[16];
float pow1_1[2][16], pow2_1[2][16], pow1_2[2][16], pow2_2[2][16];
int* map[9][3];
int* mapEnd[9][3];
uint32 nLength2[512];
uint32 iLength2[256];
float decodeWin[512 + 32];
float* cosTables[5];
private:
int mapbuf0[9][152];
int mapbuf1[9][156];
int mapbuf2[9][44];
float cos64[16], cos32[8], cos16[4], cos8[2], cos4[1];
uint8 group3tab[32 * 3];
uint8 group5tab[128 * 3];
uint8 group9tab[1024 * 3];
void initDecodeTables()
{
int i, j, scaleval = -1;
float* table = decodeWin;
for (i = 0; i < 5; ++i)
{
int kr = 0x10 >> i;
int divv = 0x40 >> i;
float* costab = cosTables[i];
for (int k = 0; k < kr; ++k)
costab[k] = (float) (1.0 / (2.0 * std::cos (MathConstants<double>::pi * (k * 2 + 1) / divv)));
}
for (i = 0, j = 0; i < 256; ++i, ++j, table += 32)
{
if (table < decodeWin + 512 + 16)
table[16] = table[0] = (float) (decodeWindow[j] * scaleval);
if (i % 32 == 31)
table -= 1023;
if (i % 64 == 63)
scaleval = -scaleval;
}
for (; i < 512; ++i, --j, table += 32)
{
if (table < decodeWin + 512 + 16)
table[16] = table[0] = (float) (decodeWindow[j] * scaleval);
if (i % 32 == 31) table -= 1023;
if (i % 64 == 63) scaleval = -scaleval;
}
}
void initLayer2Tables()
{
static const uint8 base[3][9] =
{
{ 1, 0, 2 },
{ 17, 18, 0, 19, 20 },
{ 21, 1, 22, 23, 0, 24, 25, 2, 26 }
};
static const int tableLengths[] = { 3, 5, 9 };
static uint8* tables[] = { group3tab, group5tab, group9tab };
for (int i = 0; i < 3; ++i)
{
uint8* table = tables[i];
const int len = tableLengths[i];
for (int j = 0; j < len; ++j)
for (int k = 0; k < len; ++k)
for (int l = 0; l < len; ++l)
{
*table++ = base[i][l];
*table++ = base[i][k];
*table++ = base[i][j];
}
}
for (int k = 0; k < 27; ++k)
{
static const double multipliers[] =
{
0, -2.0 / 3.0, 2.0 / 3.0, 2.0 / 7.0, 2.0 / 15.0, 2.0 / 31.0, 2.0 / 63.0, 2.0 / 127.0, 2.0 / 255.0,
2.0 / 511.0, 2.0 / 1023.0, 2.0 / 2047.0, 2.0 / 4095.0, 2.0 / 8191.0, 2.0 / 16383.0, 2.0 / 32767.0, 2.0 / 65535.0,
-4.0 / 5.0, -2.0 / 5.0, 2.0 / 5.0, 4.0 / 5.0, -8.0 / 9.0, -4.0 / 9.0, -2.0 / 9.0, 2.0 / 9.0, 4.0 / 9.0, 8.0 / 9.0
};
float* table = muls[k];
for (int j = 3, i = 0; i < 63; ++i, --j)
*table++ = (float) (multipliers[k] * std::pow (2.0, j / 3.0));
*table++ = 0;
}
}
void initLayer3Tables()
{
int i, j;
for (i = -256; i < 118 + 4; ++i)
powToGains[i + 256] = (float) std::pow (2.0, -0.25 * (i + 210));
for (i = 0; i < 8207; ++i)
nToThe4Over3[i] = (float) std::pow ((double) i, 4.0 / 3.0);
for (i = 0; i < 8; ++i)
{
static double Ci[] = { -0.6, -0.535, -0.33, -0.185, -0.095, -0.041, -0.0142, -0.0037 };
const double sq = sqrt (1.0 + Ci[i] * Ci[i]);
antiAliasingCs[i] = (float) (1.0 / sq);
antiAliasingCa[i] = (float) (Ci[i] / sq);
}
for (i = 0; i < 18; ++i)
{
win[0][i] = win[1][i] = (float) (0.5 * std::sin (MathConstants<double>::pi / 72.0 * (2 * i + 1)) / std::cos (MathConstants<double>::pi * (2 * i + 19) / 72.0));
win[0][i + 18] = win[3][i + 18] = (float) (0.5 * std::sin (MathConstants<double>::pi / 72.0 * (2 * (i + 18) + 1)) / std::cos (MathConstants<double>::pi * (2 * (i + 18) + 19) / 72.0));
}
const double piOver72 = MathConstants<double>::pi / 72.0;
for (i = 0; i < 6; ++i)
{
win[1][i + 18] = (float) (0.5 / std::cos (piOver72 * (2 * (i + 18) + 19)));
win[3][i + 12] = (float) (0.5 / std::cos (piOver72 * (2 * (i + 12) + 19)));
win[1][i + 24] = (float) (0.5 * std::sin (MathConstants<double>::pi / 24.0 * (2 * i + 13)) / std::cos (piOver72 * (2 * (i + 24) + 19)));
win[1][i + 30] = win[3][i] = 0;
win[3][i + 6] = (float) (0.5 * std::sin (MathConstants<double>::pi / 24.0 * (2 * i + 1)) / std::cos (piOver72 * (2 * (i + 6) + 19)));
}
for (i = 0; i < 12; ++i)
win[2][i] = (float) (0.5 * std::sin (MathConstants<double>::pi / 24.0 * (2 * i + 1)) / std::cos (MathConstants<double>::pi * (2 * i + 7) / 24.0));
for (j = 0; j < 4; ++j)
{
static const int len[4] = { 36, 36, 12, 36 };
for (i = 0; i < len[j]; i += 2) win1[j][i] = win[j][i];
for (i = 1; i < len[j]; i += 2) win1[j][i] = -win[j][i];
}
const double sqrt2 = 1.41421356237309504880168872420969808;
for (i = 0; i < 16; ++i)
{
const double t = std::tan (i * MathConstants<double>::pi / 12.0);
tan1_1[i] = (float) (t / (1.0 + t));
tan2_1[i] = (float) (1.0 / (1.0 + t));
tan1_2[i] = (float) (sqrt2 * t / (1.0 + t));
tan2_2[i] = (float) (sqrt2 / (1.0 + t));
for (j = 0; j < 2; ++j)
{
double p1 = 1.0, p2 = 1.0;
if (i > 0)
{
const double base = std::pow (2.0, -0.25 * (j + 1));
if (i & 1)
p1 = std::pow (base, (i + 1) * 0.5);
else
p2 = std::pow (base, i * 0.5);
}
pow1_1[j][i] = (float) p1;
pow2_1[j][i] = (float) p2;
pow1_2[j][i] = (float) (sqrt2 * p1);
pow2_2[j][i] = (float) (sqrt2 * p2);
}
}
for (j = 0; j < 9; ++j)
{
const BandInfoStruct& bi = bandInfo[j];
int cb;
int* mp = map[j][0] = mapbuf0[j];
const int16* bdf = bi.longDiff;
for (i = 0, cb = 0; cb < 8; ++cb, i += *bdf++)
{
*mp++ = (*bdf) >> 1;
*mp++ = i;
*mp++ = 3;
*mp++ = cb;
}
bdf = bi.shortDiff + 3;
for (cb = 3; cb < 13; ++cb)
{
const int l = (*bdf++) >> 1;
for (int lwin = 0; lwin < 3; ++lwin)
{
*mp++ = l;
*mp++ = i + lwin;
*mp++ = lwin;
*mp++ = cb;
}
i += 6 * l;
}
mapEnd[j][0] = mp;
mp = map[j][1] = mapbuf1[j];
bdf = bi.shortDiff;
for (i = 0, cb = 0; cb < 13; ++cb)
{
const int l = (*bdf++) >> 1;
for (int lwin = 0; lwin < 3; ++lwin)
{
*mp++ = l;
*mp++ = i + lwin;
*mp++ = lwin;
*mp++ = cb;
}
i += 6 * l;
}
mapEnd[j][1] = mp;
mp = map[j][2] = mapbuf2[j];
bdf = bi.longDiff;
for (cb = 0; cb < 22; ++cb)
{
*mp++ = (*bdf++) >> 1;
*mp++ = cb;
}
mapEnd[j][2] = mp;
}
for (j = 0; j < 9; ++j)
{
for (i = 0; i < 23; ++i) longLimit[j][i] = jmin (32, (bandInfo[j].longIndex[i] - 1 + 8) / 18 + 1);
for (i = 0; i < 14; ++i) shortLimit[j][i] = jmin (32, (bandInfo[j].shortIndex[i] - 1) / 18 + 1);
}
for (i = 0; i < 5; ++i)
for (j = 0; j < 6; ++j)
for (int k = 0; k < 6; ++k)
{
const int n = k + j * 6 + i * 36;
iLength2[n] = (unsigned int) (i | (j << 3) | (k << 6) | (3 << 12));
}
for (i = 0; i < 4; ++i)
for (j = 0; j < 4; ++j)
for (int k = 0; k < 4; ++k)
{
const int n = k + j * 4 + i * 16;
iLength2[n + 180] = (unsigned int) (i | (j << 3) | (k << 6) | (4 << 12));
}
for (i = 0; i < 4; ++i)
for (j = 0; j < 3; ++j)
{
const int n = j + i * 3;
iLength2[n + 244] = (unsigned int) (i | (j << 3) | (5 << 12));
nLength2[n + 500] = (unsigned int) (i | (j << 3) | (2 << 12) | (1 << 15));
}
for (i = 0; i < 5; ++i)
for (j = 0; j < 5; ++j)
for (int k = 0; k < 4; ++k)
for (int l = 0; l < 4; ++l)
{
const int n = l + k * 4 + j * 16 + i * 80;
nLength2[n] = (unsigned int) (i | (j << 3) | (k << 6) | (l << 9) | (0 << 12));
}
for (i = 0; i < 5; ++i)
for (j = 0; j < 5; ++j)
for (int k = 0; k < 4; ++k)
{
const int n = k + j * 4 + i * 20;
nLength2[n + 400] = (unsigned int) (i | (j << 3) | (k << 6) | (1 << 12));
}
}
};
static const Constants constants;
//==============================================================================
struct Layer3SideInfo
{
struct Info
{
void doAntialias (float xr[32][18]) const noexcept
{
float* xr1 = xr[1];
int sb;
if (blockType == 2)
{
if (mixedBlockFlag == 0)
return;
sb = 1;
}
else
sb = (int) maxb - 1;
for (; sb != 0; --sb, xr1 += 10)
{
auto* cs = constants.antiAliasingCs;
auto* ca = constants.antiAliasingCa;
auto* xr2 = xr1;
for (int ss = 7; ss >= 0; --ss)
{
const float bu = *--xr2, bd = *xr1;
*xr2 = (bu * *cs) - (bd * *ca);
*xr1++ = (bd * *cs++) + (bu * *ca++);
}
}
}
void doIStereo (float xrBuffer[2][32][18], const int* scaleFactors,
int sampleRate, bool msStereo, int lsf) const noexcept
{
float (*xr) [32 * 18] = (float (*) [32 * 18]) xrBuffer;
auto& bi = bandInfo[sampleRate];
const float* tabl1, *tabl2;
if (lsf != 0)
{
auto p = scaleFactorCompression & 1;
if (msStereo)
{
tabl1 = constants.pow1_2[p];
tabl2 = constants.pow2_2[p];
}
else
{
tabl1 = constants.pow1_1[p];
tabl2 = constants.pow2_1[p];
}
}
else
{
if (msStereo)
{
tabl1 = constants.tan1_2;
tabl2 = constants.tan2_2;
}
else
{
tabl1 = constants.tan1_1;
tabl2 = constants.tan2_1;
}
}
if (blockType == 2)
{
bool doL = mixedBlockFlag != 0;
for (uint32 lwin = 0; lwin < 3; ++lwin)
{
uint32 sfb = maxBand[lwin];
doL = doL && (sfb <= 3);
for (; sfb < 12; ++sfb)
{
auto p = scaleFactors[sfb * 3 + lwin - mixedBlockFlag];
if (p != 7)
{
auto t1 = tabl1[p];
auto t2 = tabl2[p];
int sb = bi.shortDiff[sfb];
auto index = (uint32) sb + lwin;
for (; sb > 0; --sb, index += 3)
{
float v = xr[0][index];
xr[0][index] = v * t1;
xr[1][index] = v * t2;
}
}
}
auto p = scaleFactors[11 * 3 + lwin - mixedBlockFlag];
if (p != 7)
{
auto t1 = tabl1[p];
auto t2 = tabl2[p];
int sb = bi.shortDiff[12];
auto index = (uint32) sb + lwin;
for (; sb > 0; --sb, index += 3)
{
float v = xr[0][index];
xr[0][index] = v * t1;
xr[1][index] = v * t2;
}
}
}
if (doL)
{
int index = bi.longIndex[maxBandl];
for (uint32 sfb = maxBandl; sfb < 8; ++sfb)
{
int sb = bi.longDiff[sfb];
auto p = scaleFactors[sfb];
if (p != 7)
{
auto t1 = tabl1[p];
auto t2 = tabl2[p];
for (; sb > 0; --sb, ++index)
{
float v = xr[0][index];
xr[0][index] = v * t1;
xr[1][index] = v * t2;
}
}
else
index += sb;
}
}
}
else
{
int index = bi.longIndex[maxBandl];
for (uint32 sfb = maxBandl; sfb < 21; ++sfb)
{
int sb = bi.longDiff[sfb];
auto p = scaleFactors[sfb];
if (p != 7)
{
auto t1 = tabl1[p];
auto t2 = tabl2[p];
for (; sb > 0; --sb, ++index)
{
const float v = xr[0][index];
xr[0][index] = v * t1;
xr[1][index] = v * t2;
}
}
else
index += sb;
}
auto p = scaleFactors[20];
if (p != 7)
{
auto t1 = tabl1[p], t2 = tabl2[p];
for (int sb = bi.longDiff[21]; sb > 0; --sb, ++index)
{
const float v = xr[0][index];
xr[0][index] = v * t1;
xr[1][index] = v * t2;
}
}
}
}
int scfsi;
uint32 part2_3Length, bigValues;
uint32 scaleFactorCompression, blockType, mixedBlockFlag;
uint32 tableSelect[3];
uint32 maxBand[3];
uint32 maxBandl, maxb, region1Start, region2Start;
uint32 preflag, scaleFactorScale, count1TableSelect;
const float* fullGain[3];
const float* pow2gain;
};
struct InfoPair { Info gr[2]; };
InfoPair ch[2];
uint32 mainDataStart, privateBits;
};
//==============================================================================
namespace DCT
{
enum { subBandLimit = 32 };
static const float cos6_1 = 0.866025388f;
static const float cos6_2 = 0.5f;
static const float cos9[] = { 1.0f, 0.98480773f, 0.939692616f, 0.866025388f, 0.766044438f, 0.642787635f, 0.5f, 0.342020154f, 0.173648179f };
static const float cos36[] = { 0.501909912f, 0.517638087f, 0.551688969f, 0.610387266f, 0.707106769f, 0.871723413f, 1.18310082f, 1.93185163f, 5.73685646f };
static const float cos12[] = { 0.517638087f, 0.707106769f, 1.93185163f };
inline void dct36_0 (int v, float* ts, float* out1, float* out2, const float* wintab, float sum0, float sum1) noexcept
{
auto tmp = sum0 + sum1;
out2[9 + v] = tmp * wintab[27 + v];
out2[8 - v] = tmp * wintab[26 - v];
sum0 -= sum1;
ts[subBandLimit * (8 - v)] = out1[8 - v] + sum0 * wintab[8 - v];
ts[subBandLimit * (9 + v)] = out1[9 + v] + sum0 * wintab[9 + v];
}
inline void dct36_12 (int v1, int v2, float* ts, float* out1, float* out2, const float* wintab,
float tmp1a, float tmp1b, float tmp2a, float tmp2b) noexcept
{
dct36_0 (v1, ts, out1, out2, wintab, tmp1a + tmp2a, (tmp1b + tmp2b) * cos36[v1]);
dct36_0 (v2, ts, out1, out2, wintab, tmp2a - tmp1a, (tmp2b - tmp1b) * cos36[v2]);
}
static void dct36 (float* in, float* out1, float* out2, const float* wintab, float* ts) noexcept
{
in[17] += in[16]; in[16] += in[15]; in[15] += in[14]; in[14] += in[13]; in[13] += in[12];
in[12] += in[11]; in[11] += in[10]; in[10] += in[9]; in[9] += in[8]; in[8] += in[7];
in[7] += in[6]; in[6] += in[5]; in[5] += in[4]; in[4] += in[3]; in[3] += in[2];
in[2] += in[1]; in[1] += in[0]; in[17] += in[15]; in[15] += in[13]; in[13] += in[11];
in[11] += in[9]; in[9] += in[7]; in[7] += in[5]; in[5] += in[3]; in[3] += in[1];
auto ta33 = in[6] * cos9[3];
auto ta66 = in[12] * cos9[6];
auto tb33 = in[7] * cos9[3];
auto tb66 = in[13] * cos9[6];
dct36_12 (0, 8, ts, out1, out2, wintab,
in[2] * cos9[1] + ta33 + in[10] * cos9[5] + in[14] * cos9[7],
in[3] * cos9[1] + tb33 + in[11] * cos9[5] + in[15] * cos9[7],
in[0] + in[4] * cos9[2] + in[8] * cos9[4] + ta66 + in[16] * cos9[8],
in[1] + in[5] * cos9[2] + in[9] * cos9[4] + tb66 + in[17] * cos9[8]);
dct36_12 (1, 7, ts, out1, out2, wintab,
(in[2] - in[10] - in[14]) * cos9[3],
(in[3] - in[11] - in[15]) * cos9[3],
(in[4] - in[8] - in[16]) * cos9[6] - in[12] + in[0],
(in[5] - in[9] - in[17]) * cos9[6] - in[13] + in[1]);
dct36_12 (2, 6, ts, out1, out2, wintab,
in[2] * cos9[5] - ta33 - in[10] * cos9[7] + in[14] * cos9[1],
in[3] * cos9[5] - tb33 - in[11] * cos9[7] + in[15] * cos9[1],
in[0] - in[4] * cos9[8] - in[8] * cos9[2] + ta66 + in[16] * cos9[4],
in[1] - in[5] * cos9[8] - in[9] * cos9[2] + tb66 + in[17] * cos9[4]);
dct36_12 (3, 5, ts, out1, out2, wintab,
in[2] * cos9[7] - ta33 + in[10] * cos9[1] - in[14] * cos9[5],
in[3] * cos9[7] - tb33 + in[11] * cos9[1] - in[15] * cos9[5],
in[0] - in[4] * cos9[4] + in[8] * cos9[8] + ta66 - in[16] * cos9[2],
in[1] - in[5] * cos9[4] + in[9] * cos9[8] + tb66 - in[17] * cos9[2]);
dct36_0 (4, ts, out1, out2, wintab,
in[0] - in[4] + in[8] - in[12] + in[16],
(in[1] - in[5] + in[9] - in[13] + in[17]) * cos36[4]);
}
struct DCT12Inputs
{
float in0, in1, in2, in3, in4, in5;
inline DCT12Inputs (const float* in) noexcept
{
in5 = in[5 * 3] + (in4 = in[4 * 3]);
in4 += (in3 = in[3 * 3]);
in3 += (in2 = in[2 * 3]);
in2 += (in1 = in[1 * 3]);
in1 += (in0 = in[0 * 3]);
in5 += in3; in3 += in1;
in2 *= cos6_1;
in3 *= cos6_1;
}
inline void process() noexcept
{
in0 += in4 * cos6_2;
in4 = in0 + in2; in0 -= in2;
in1 += in5 * cos6_2;
in5 = (in1 + in3) * cos12[0];
in1 = (in1 - in3) * cos12[2];
in3 = in4 + in5; in4 -= in5;
in2 = in0 + in1; in0 -= in1;
}
};
static void dct12 (const float* in, float* out1, float* out2, const float* wi, float* ts) noexcept
{
{
ts[0] = out1[0];
ts[subBandLimit * 1] = out1[1];
ts[subBandLimit * 2] = out1[2];
ts[subBandLimit * 3] = out1[3];
ts[subBandLimit * 4] = out1[4];
ts[subBandLimit * 5] = out1[5];
DCT12Inputs inputs (in);
{
auto tmp1 = (inputs.in0 - inputs.in4);
auto tmp2 = (inputs.in1 - inputs.in5) * cos12[1];
auto tmp0 = tmp1 + tmp2;
tmp1 -= tmp2;
ts[16 * subBandLimit] = out1[16] + tmp0 * wi[10];
ts[13 * subBandLimit] = out1[13] + tmp0 * wi[7];
ts[7 * subBandLimit] = out1[7] + tmp1 * wi[1];
ts[10 * subBandLimit] = out1[10] + tmp1 * wi[4];
}
inputs.process();
ts[17 * subBandLimit] = out1[17] + inputs.in2 * wi[11];
ts[12 * subBandLimit] = out1[12] + inputs.in2 * wi[6];
ts[14 * subBandLimit] = out1[14] + inputs.in3 * wi[8];
ts[15 * subBandLimit] = out1[15] + inputs.in3 * wi[9];
ts[6 * subBandLimit] = out1[6] + inputs.in0 * wi[0];
ts[11 * subBandLimit] = out1[11] + inputs.in0 * wi[5];
ts[8 * subBandLimit] = out1[8] + inputs.in4 * wi[2];
ts[9 * subBandLimit] = out1[9] + inputs.in4 * wi[3];
}
{
DCT12Inputs inputs (++in);
auto tmp1 = (inputs.in0 - inputs.in4);
auto tmp2 = (inputs.in1 - inputs.in5) * cos12[1];
auto tmp0 = tmp1 + tmp2;
tmp1 -= tmp2;
out2[4] = tmp0 * wi[10];
out2[1] = tmp0 * wi[7];
ts[13 * subBandLimit] += tmp1 * wi[1];
ts[16 * subBandLimit] += tmp1 * wi[4];
inputs.process();
out2[5] = inputs.in2 * wi[11];
out2[0] = inputs.in2 * wi[6];
out2[2] = inputs.in3 * wi[8];
out2[3] = inputs.in3 * wi[9];
ts[12 * subBandLimit] += inputs.in0 * wi[0];
ts[17 * subBandLimit] += inputs.in0 * wi[5];
ts[14 * subBandLimit] += inputs.in4 * wi[2];
ts[15 * subBandLimit] += inputs.in4 * wi[5 - 2];
}
{
DCT12Inputs inputs (++in);
out2[12] = out2[13] = out2[14] = out2[15] = out2[16] = out2[17] = 0;
auto tmp1 = (inputs.in0 - inputs.in4);
auto tmp2 = (inputs.in1 - inputs.in5) * cos12[1];
auto tmp0 = tmp1 + tmp2;
tmp1 -= tmp2;
out2[10] = tmp0 * wi[10];
out2[7] = tmp0 * wi[7];
out2[1] += tmp1 * wi[1];
out2[4] += tmp1 * wi[4];
inputs.process();
out2[11] = inputs.in2 * wi[11];
out2[6] = inputs.in2 * wi[6];
out2[8] = inputs.in3 * wi[8];
out2[9] = inputs.in3 * wi[9];
out2[0] += inputs.in0 * wi[0];
out2[5] += inputs.in0 * wi[5];
out2[2] += inputs.in4 * wi[2];
out2[3] += inputs.in4 * wi[3];
}
}
static void dct64 (float* out0, float* out1, const float* samples) noexcept
{
float b1[32], b2[32];
{
auto* costab = constants.cosTables[0];
b1[0x00] = samples[0x00] + samples[0x1F]; b1[0x1F] = (samples[0x00] - samples[0x1F]) * costab[0x0];
b1[0x01] = samples[0x01] + samples[0x1E]; b1[0x1E] = (samples[0x01] - samples[0x1E]) * costab[0x1];
b1[0x02] = samples[0x02] + samples[0x1D]; b1[0x1D] = (samples[0x02] - samples[0x1D]) * costab[0x2];
b1[0x03] = samples[0x03] + samples[0x1C]; b1[0x1C] = (samples[0x03] - samples[0x1C]) * costab[0x3];
b1[0x04] = samples[0x04] + samples[0x1B]; b1[0x1B] = (samples[0x04] - samples[0x1B]) * costab[0x4];
b1[0x05] = samples[0x05] + samples[0x1A]; b1[0x1A] = (samples[0x05] - samples[0x1A]) * costab[0x5];
b1[0x06] = samples[0x06] + samples[0x19]; b1[0x19] = (samples[0x06] - samples[0x19]) * costab[0x6];
b1[0x07] = samples[0x07] + samples[0x18]; b1[0x18] = (samples[0x07] - samples[0x18]) * costab[0x7];
b1[0x08] = samples[0x08] + samples[0x17]; b1[0x17] = (samples[0x08] - samples[0x17]) * costab[0x8];
b1[0x09] = samples[0x09] + samples[0x16]; b1[0x16] = (samples[0x09] - samples[0x16]) * costab[0x9];
b1[0x0A] = samples[0x0A] + samples[0x15]; b1[0x15] = (samples[0x0A] - samples[0x15]) * costab[0xA];
b1[0x0B] = samples[0x0B] + samples[0x14]; b1[0x14] = (samples[0x0B] - samples[0x14]) * costab[0xB];
b1[0x0C] = samples[0x0C] + samples[0x13]; b1[0x13] = (samples[0x0C] - samples[0x13]) * costab[0xC];
b1[0x0D] = samples[0x0D] + samples[0x12]; b1[0x12] = (samples[0x0D] - samples[0x12]) * costab[0xD];
b1[0x0E] = samples[0x0E] + samples[0x11]; b1[0x11] = (samples[0x0E] - samples[0x11]) * costab[0xE];
b1[0x0F] = samples[0x0F] + samples[0x10]; b1[0x10] = (samples[0x0F] - samples[0x10]) * costab[0xF];
}
{
auto* costab = constants.cosTables[1];
b2[0x00] = b1[0x00] + b1[0x0F]; b2[0x0F] = (b1[0x00] - b1[0x0F]) * costab[0];
b2[0x01] = b1[0x01] + b1[0x0E]; b2[0x0E] = (b1[0x01] - b1[0x0E]) * costab[1];
b2[0x02] = b1[0x02] + b1[0x0D]; b2[0x0D] = (b1[0x02] - b1[0x0D]) * costab[2];
b2[0x03] = b1[0x03] + b1[0x0C]; b2[0x0C] = (b1[0x03] - b1[0x0C]) * costab[3];
b2[0x04] = b1[0x04] + b1[0x0B]; b2[0x0B] = (b1[0x04] - b1[0x0B]) * costab[4];
b2[0x05] = b1[0x05] + b1[0x0A]; b2[0x0A] = (b1[0x05] - b1[0x0A]) * costab[5];
b2[0x06] = b1[0x06] + b1[0x09]; b2[0x09] = (b1[0x06] - b1[0x09]) * costab[6];
b2[0x07] = b1[0x07] + b1[0x08]; b2[0x08] = (b1[0x07] - b1[0x08]) * costab[7];
b2[0x10] = b1[0x10] + b1[0x1F]; b2[0x1F] = (b1[0x1F] - b1[0x10]) * costab[0];
b2[0x11] = b1[0x11] + b1[0x1E]; b2[0x1E] = (b1[0x1E] - b1[0x11]) * costab[1];
b2[0x12] = b1[0x12] + b1[0x1D]; b2[0x1D] = (b1[0x1D] - b1[0x12]) * costab[2];
b2[0x13] = b1[0x13] + b1[0x1C]; b2[0x1C] = (b1[0x1C] - b1[0x13]) * costab[3];
b2[0x14] = b1[0x14] + b1[0x1B]; b2[0x1B] = (b1[0x1B] - b1[0x14]) * costab[4];
b2[0x15] = b1[0x15] + b1[0x1A]; b2[0x1A] = (b1[0x1A] - b1[0x15]) * costab[5];
b2[0x16] = b1[0x16] + b1[0x19]; b2[0x19] = (b1[0x19] - b1[0x16]) * costab[6];
b2[0x17] = b1[0x17] + b1[0x18]; b2[0x18] = (b1[0x18] - b1[0x17]) * costab[7];
}
{
auto* costab = constants.cosTables[2];
b1[0x00] = b2[0x00] + b2[0x07]; b1[0x07] = (b2[0x00] - b2[0x07]) * costab[0];
b1[0x01] = b2[0x01] + b2[0x06]; b1[0x06] = (b2[0x01] - b2[0x06]) * costab[1];
b1[0x02] = b2[0x02] + b2[0x05]; b1[0x05] = (b2[0x02] - b2[0x05]) * costab[2];
b1[0x03] = b2[0x03] + b2[0x04]; b1[0x04] = (b2[0x03] - b2[0x04]) * costab[3];
b1[0x08] = b2[0x08] + b2[0x0F]; b1[0x0F] = (b2[0x0F] - b2[0x08]) * costab[0];
b1[0x09] = b2[0x09] + b2[0x0E]; b1[0x0E] = (b2[0x0E] - b2[0x09]) * costab[1];
b1[0x0A] = b2[0x0A] + b2[0x0D]; b1[0x0D] = (b2[0x0D] - b2[0x0A]) * costab[2];
b1[0x0B] = b2[0x0B] + b2[0x0C]; b1[0x0C] = (b2[0x0C] - b2[0x0B]) * costab[3];
b1[0x10] = b2[0x10] + b2[0x17]; b1[0x17] = (b2[0x10] - b2[0x17]) * costab[0];
b1[0x11] = b2[0x11] + b2[0x16]; b1[0x16] = (b2[0x11] - b2[0x16]) * costab[1];
b1[0x12] = b2[0x12] + b2[0x15]; b1[0x15] = (b2[0x12] - b2[0x15]) * costab[2];
b1[0x13] = b2[0x13] + b2[0x14]; b1[0x14] = (b2[0x13] - b2[0x14]) * costab[3];
b1[0x18] = b2[0x18] + b2[0x1F]; b1[0x1F] = (b2[0x1F] - b2[0x18]) * costab[0];
b1[0x19] = b2[0x19] + b2[0x1E]; b1[0x1E] = (b2[0x1E] - b2[0x19]) * costab[1];
b1[0x1A] = b2[0x1A] + b2[0x1D]; b1[0x1D] = (b2[0x1D] - b2[0x1A]) * costab[2];
b1[0x1B] = b2[0x1B] + b2[0x1C]; b1[0x1C] = (b2[0x1C] - b2[0x1B]) * costab[3];
}
{
auto cos0 = constants.cosTables[3][0];
auto cos1 = constants.cosTables[3][1];
b2[0x00] = b1[0x00] + b1[0x03]; b2[0x03] = (b1[0x00] - b1[0x03]) * cos0;
b2[0x01] = b1[0x01] + b1[0x02]; b2[0x02] = (b1[0x01] - b1[0x02]) * cos1;
b2[0x04] = b1[0x04] + b1[0x07]; b2[0x07] = (b1[0x07] - b1[0x04]) * cos0;
b2[0x05] = b1[0x05] + b1[0x06]; b2[0x06] = (b1[0x06] - b1[0x05]) * cos1;
b2[0x08] = b1[0x08] + b1[0x0B]; b2[0x0B] = (b1[0x08] - b1[0x0B]) * cos0;
b2[0x09] = b1[0x09] + b1[0x0A]; b2[0x0A] = (b1[0x09] - b1[0x0A]) * cos1;
b2[0x0C] = b1[0x0C] + b1[0x0F]; b2[0x0F] = (b1[0x0F] - b1[0x0C]) * cos0;
b2[0x0D] = b1[0x0D] + b1[0x0E]; b2[0x0E] = (b1[0x0E] - b1[0x0D]) * cos1;
b2[0x10] = b1[0x10] + b1[0x13]; b2[0x13] = (b1[0x10] - b1[0x13]) * cos0;
b2[0x11] = b1[0x11] + b1[0x12]; b2[0x12] = (b1[0x11] - b1[0x12]) * cos1;
b2[0x14] = b1[0x14] + b1[0x17]; b2[0x17] = (b1[0x17] - b1[0x14]) * cos0;
b2[0x15] = b1[0x15] + b1[0x16]; b2[0x16] = (b1[0x16] - b1[0x15]) * cos1;
b2[0x18] = b1[0x18] + b1[0x1B]; b2[0x1B] = (b1[0x18] - b1[0x1B]) * cos0;
b2[0x19] = b1[0x19] + b1[0x1A]; b2[0x1A] = (b1[0x19] - b1[0x1A]) * cos1;
b2[0x1C] = b1[0x1C] + b1[0x1F]; b2[0x1F] = (b1[0x1F] - b1[0x1C]) * cos0;
b2[0x1D] = b1[0x1D] + b1[0x1E]; b2[0x1E] = (b1[0x1E] - b1[0x1D]) * cos1;
}
{
auto cos0 = constants.cosTables[4][0];
b1[0x00] = b2[0x00] + b2[0x01]; b1[0x01] = (b2[0x00] - b2[0x01]) * cos0;
b1[0x02] = b2[0x02] + b2[0x03]; b1[0x03] = (b2[0x03] - b2[0x02]) * cos0; b1[0x02] += b1[0x03];
b1[0x04] = b2[0x04] + b2[0x05]; b1[0x05] = (b2[0x04] - b2[0x05]) * cos0;
b1[0x06] = b2[0x06] + b2[0x07]; b1[0x07] = (b2[0x07] - b2[0x06]) * cos0;
b1[0x06] += b1[0x07]; b1[0x04] += b1[0x06]; b1[0x06] += b1[0x05]; b1[0x05] += b1[0x07];
b1[0x08] = b2[0x08] + b2[0x09]; b1[0x09] = (b2[0x08] - b2[0x09]) * cos0;
b1[0x0A] = b2[0x0A] + b2[0x0B]; b1[0x0B] = (b2[0x0B] - b2[0x0A]) * cos0; b1[0x0A] += b1[0x0B];
b1[0x0C] = b2[0x0C] + b2[0x0D]; b1[0x0D] = (b2[0x0C] - b2[0x0D]) * cos0;
b1[0x0E] = b2[0x0E] + b2[0x0F]; b1[0x0F] = (b2[0x0F] - b2[0x0E]) * cos0;
b1[0x0E] += b1[0x0F]; b1[0x0C] += b1[0x0E]; b1[0x0E] += b1[0x0D]; b1[0x0D] += b1[0x0F];
b1[0x10] = b2[0x10] + b2[0x11]; b1[0x11] = (b2[0x10] - b2[0x11]) * cos0;
b1[0x12] = b2[0x12] + b2[0x13]; b1[0x13] = (b2[0x13] - b2[0x12]) * cos0; b1[0x12] += b1[0x13];
b1[0x14] = b2[0x14] + b2[0x15]; b1[0x15] = (b2[0x14] - b2[0x15]) * cos0;
b1[0x16] = b2[0x16] + b2[0x17]; b1[0x17] = (b2[0x17] - b2[0x16]) * cos0;
b1[0x16] += b1[0x17]; b1[0x14] += b1[0x16]; b1[0x16] += b1[0x15]; b1[0x15] += b1[0x17];
b1[0x18] = b2[0x18] + b2[0x19]; b1[0x19] = (b2[0x18] - b2[0x19]) * cos0;
b1[0x1A] = b2[0x1A] + b2[0x1B]; b1[0x1B] = (b2[0x1B] - b2[0x1A]) * cos0; b1[0x1A] += b1[0x1B];
b1[0x1C] = b2[0x1C] + b2[0x1D]; b1[0x1D] = (b2[0x1C] - b2[0x1D]) * cos0;
b1[0x1E] = b2[0x1E] + b2[0x1F]; b1[0x1F] = (b2[0x1F] - b2[0x1E]) * cos0;
b1[0x1E] += b1[0x1F]; b1[0x1C] += b1[0x1E]; b1[0x1E] += b1[0x1D]; b1[0x1D] += b1[0x1F];
}
out0[0x10 * 16] = b1[0x00]; out0[0x10 * 12] = b1[0x04]; out0[0x10 * 8] = b1[0x02]; out0[0x10 * 4] = b1[0x06];
out0[0] = b1[0x01]; out1[0] = b1[0x01]; out1[0x10 * 4] = b1[0x05]; out1[0x10 * 8] = b1[0x03];
out1[0x10 * 12] = b1[0x07];
b1[0x08] += b1[0x0C]; out0[0x10 * 14] = b1[0x08]; b1[0x0C] += b1[0x0a]; out0[0x10 * 10] = b1[0x0C];
b1[0x0A] += b1[0x0E]; out0[0x10 * 6] = b1[0x0A]; b1[0x0E] += b1[0x09]; out0[0x10 * 2] = b1[0x0E];
b1[0x09] += b1[0x0D]; out1[0x10 * 2] = b1[0x09]; b1[0x0D] += b1[0x0B]; out1[0x10 * 6] = b1[0x0D];
b1[0x0B] += b1[0x0F]; out1[0x10 * 10] = b1[0x0B]; out1[0x10 * 14] = b1[0x0F];
b1[0x18] += b1[0x1C]; out0[0x10 * 15] = b1[0x10] + b1[0x18]; out0[0x10 * 13] = b1[0x18] + b1[0x14];
b1[0x1C] += b1[0x1a]; out0[0x10 * 11] = b1[0x14] + b1[0x1C]; out0[0x10 * 9] = b1[0x1C] + b1[0x12];
b1[0x1A] += b1[0x1E]; out0[0x10 * 7] = b1[0x12] + b1[0x1A]; out0[0x10 * 5] = b1[0x1A] + b1[0x16];
b1[0x1E] += b1[0x19]; out0[0x10 * 3] = b1[0x16] + b1[0x1E]; out0[0x10 * 1] = b1[0x1E] + b1[0x11];
b1[0x19] += b1[0x1D]; out1[0x10 * 1] = b1[0x11] + b1[0x19]; out1[0x10 * 3] = b1[0x19] + b1[0x15];
b1[0x1D] += b1[0x1B]; out1[0x10 * 5] = b1[0x15] + b1[0x1D]; out1[0x10 * 7] = b1[0x1D] + b1[0x13];
b1[0x1B] += b1[0x1F]; out1[0x10 * 9] = b1[0x13] + b1[0x1B]; out1[0x10 * 11] = b1[0x1B] + b1[0x17];
out1[0x10 * 13] = b1[0x17] + b1[0x1F]; out1[0x10 * 15] = b1[0x1F];
}
}
//==============================================================================
struct MP3Stream
{
MP3Stream (InputStream& source) : stream (source, 8192)
{
reset();
}
int decodeNextBlock (float* out0, float* out1, int& done)
{
if (! headerParsed)
{
auto nextFrameOffset = scanForNextFrameHeader (false);
if (lastFrameSize == -1 || needToSyncBitStream)
{
needToSyncBitStream = false;
readVBRHeader();
if (vbrHeaderFound)
return 1;
}
if (nextFrameOffset < 0)
return -1;
if (nextFrameOffset > 0)
{
wasFreeFormat = false;
needToSyncBitStream = true;
auto size = (int) (bufferPointer - (bufferSpace[bufferSpaceIndex] + 512));
if (size > 2880)
{
size = 0;
bufferPointer = bufferSpace[bufferSpaceIndex] + 512;
}
auto toSkip = (size + nextFrameOffset) - 2880;
if (toSkip > 0)
{
stream.skipNextBytes (toSkip);
nextFrameOffset -= toSkip;
}
stream.read (bufferPointer, nextFrameOffset);
lastFrameSize += nextFrameOffset;
}
frame.decodeHeader ((uint32) stream.readIntBigEndian());
headerParsed = true;
frameSize = frame.frameSize;
isFreeFormat = (frameSize == 0);
sideInfoSize = frame.lsf != 0 ? ((frame.numChannels == 1) ? 9 : 17)
: ((frame.numChannels == 1) ? 17 : 32);
if (frame.crc16FollowsHeader)
sideInfoSize += 2;
bufferSpaceIndex = 1 - bufferSpaceIndex;
bufferPointer = bufferSpace[bufferSpaceIndex] + 512;
bitIndex = 0;
if (lastFrameSize < 0)
return 1;
}
if (! sideParsed)
{
if (frame.layer == 3)
{
stream.read (bufferPointer, sideInfoSize);
if (frame.crc16FollowsHeader)
getBits (16);
auto bits = jmax (0, decodeLayer3SideInfo());
dataSize = (bits + 7) / 8;
if (! isFreeFormat)
dataSize = jmin (dataSize, frame.frameSize - sideInfoSize);
}
else
{
dataSize = frame.frameSize;
sideInfoSize = 0;
}
sideParsed = true;
}
int result = 1;
if (! dataParsed)
{
stream.read (bufferPointer, dataSize);
if (out0 != nullptr)
{
if (frame.layer < 3 && frame.crc16FollowsHeader)
getBits (16);
switch (frame.layer)
{
case 1: decodeLayer1Frame (out0, out1, done); break;
case 2: decodeLayer2Frame (out0, out1, done); break;
case 3: decodeLayer3Frame (out0, out1, done); break;
default: break;
}
}
bufferPointer = bufferSpace[bufferSpaceIndex] + 512 + sideInfoSize + dataSize;
dataParsed = true;
result = 0;
}
if (isFreeFormat)
{
if (wasFreeFormat)
{
frameSize = lastFrameSizeNoPadding + frame.padding;
}
else
{
auto nextFrameOffset = scanForNextFrameHeader (true);
wasFreeFormat = isFreeFormat;
if (nextFrameOffset < 0)
{
lastFrameSize = frameSize;
return result;
}
frameSize = nextFrameOffset + sideInfoSize + dataSize;
lastFrameSizeNoPadding = frameSize - frame.padding;
}
}
if (result == 0)
return result;
int bytes = frameSize - (sideInfoSize + dataSize);
if (bytes > 0)
{
auto toSkip = bytes - 512;
if (toSkip > 0)
{
stream.skipNextBytes (toSkip);
bytes -= toSkip;
frameSize -= toSkip;
}
stream.read (bufferPointer, bytes);
bufferPointer += bytes;
}
lastFrameSize = frameSize;
wasFreeFormat = isFreeFormat;
frameSize = 0;
headerParsed = sideParsed = dataParsed = false;
return result;
}
bool seek (int frameIndex)
{
frameIndex = jmax (0, frameIndex);
while (frameIndex >= frameStreamPositions.size() * storedStartPosInterval)
{
int dummy = 0;
auto result = decodeNextBlock (nullptr, nullptr, dummy);
if (result < 0)
return false;
if (result > 0)
break;
}
frameIndex = jmin (frameIndex & ~(storedStartPosInterval - 1),
frameStreamPositions.size() * storedStartPosInterval - 1);
stream.setPosition (frameStreamPositions.getUnchecked (frameIndex / storedStartPosInterval));
currentFrameIndex = frameIndex;
reset();
return true;
}
MP3Frame frame;
VBRTagData vbrTagData;
BufferedInputStream stream;
int numFrames = 0, currentFrameIndex = 0;
bool vbrHeaderFound = false;
private:
bool headerParsed, sideParsed, dataParsed, needToSyncBitStream;
bool isFreeFormat, wasFreeFormat;
int sideInfoSize, dataSize;
int frameSize, lastFrameSize, lastFrameSizeNoPadding;
int bufferSpaceIndex;
Layer3SideInfo sideinfo;
uint8 bufferSpace[2][2880 + 1024];
uint8* bufferPointer;
int bitIndex, synthBo;
float hybridBlock[2][2][32 * 18];
int hybridBlockIndex[2];
float synthBuffers[2][2][0x110];
float hybridIn[2][32][18];
float hybridOut[2][18][32];
void reset() noexcept
{
headerParsed = sideParsed = dataParsed = isFreeFormat = wasFreeFormat = false;
lastFrameSize = -1;
needToSyncBitStream = true;
frameSize = sideInfoSize = dataSize = bitIndex = 0;
lastFrameSizeNoPadding = bufferSpaceIndex = 0;
bufferPointer = bufferSpace[bufferSpaceIndex] + 512;
synthBo = 1;
zerostruct (sideinfo);
zeromem (bufferSpace, sizeof (bufferSpace));
zeromem (hybridBlock, sizeof (hybridBlock));
zeromem (hybridBlockIndex, sizeof (hybridBlockIndex));
zeromem (synthBuffers, sizeof (synthBuffers));
}
enum { storedStartPosInterval = 4 };
Array<int64> frameStreamPositions;
struct SideInfoLayer1
{
uint8 allocation[32][2];
uint8 scaleFactor[32][2];
};
struct SideInfoLayer2
{
uint8 allocation[32][2];
uint8 scaleFactor[32][2][3];
};
static bool isValidHeader (uint32 header, int oldLayer) noexcept
{
int newLayer = 4 - ((header >> 17) & 3);
return (header & 0xffe00000) == 0xffe00000
&& newLayer != 4
&& (oldLayer <= 0 || newLayer == oldLayer)
&& ((header >> 12) & 15) != 15
&& ((header >> 10) & 3) != 3
&& (header & 3) != 2;
}
bool rollBackBufferPointer (int backstep) noexcept
{
if (lastFrameSize < 0 && backstep > 0)
return false;
auto* oldBuffer = bufferSpace[1 - bufferSpaceIndex] + 512;
bufferPointer -= backstep;
if (backstep != 0)
memcpy (bufferPointer, oldBuffer + lastFrameSize - backstep, (size_t) backstep);
bitIndex = 0;
return true;
}
uint32 getBits (int numBits) noexcept
{
if (numBits <= 0 || bufferPointer == nullptr)
return 0;
const uint32 result = ((((((bufferPointer[0] << 8) | bufferPointer[1]) << 8)
| bufferPointer[2]) << bitIndex) & 0xffffff) >> (24 - numBits);
bitIndex += numBits;
bufferPointer += (bitIndex >> 3);
bitIndex &= 7;
return result;
}
uint32 getOneBit() noexcept
{
auto result = (uint8) (*bufferPointer << bitIndex);
++bitIndex;
bufferPointer += (bitIndex >> 3);
bitIndex &= 7;
return result >> 7;
}
uint32 getBitsUnchecked (int numBits) noexcept
{
const uint32 result = ((((bufferPointer[0] << 8) | bufferPointer[1]) << bitIndex) & 0xffff) >> (16 - numBits);
bitIndex += numBits;
bufferPointer += (bitIndex >> 3);
bitIndex &= 7;
return result;
}
inline uint8 getBitsUint8 (int numBits) noexcept { return (uint8) getBitsUnchecked (numBits); }
inline uint16 getBitsUint16 (int numBits) noexcept { return (uint16) getBitsUnchecked (numBits); }
int scanForNextFrameHeader (bool checkTypeAgainstLastFrame) noexcept
{
auto oldPos = stream.getPosition();
int offset = -3;
uint32 header = 0;
for (;;)
{
if (stream.isExhausted() || stream.getPosition() > oldPos + 32768)
{
offset = -1;
break;
}
header = (header << 8) | (uint8) stream.readByte();
if (offset >= 0 && isValidHeader (header, frame.layer))
{
if (! checkTypeAgainstLastFrame)
break;
const bool mpeg25 = (header & (1 << 20)) == 0;
const uint32 lsf = mpeg25 ? 1 : ((header & (1 << 19)) ? 0 : 1);
const uint32 sampleRateIndex = mpeg25 ? (6 + ((header >> 10) & 3)) : (((header >> 10) & 3) + (lsf * 3));
const uint32 mode = (header >> 6) & 3;
const uint32 numChannels = (mode == 3) ? 1 : 2;
if (numChannels == (uint32) frame.numChannels && lsf == (uint32) frame.lsf
&& mpeg25 == frame.mpeg25 && sampleRateIndex == (uint32) frame.sampleRateIndex)
break;
}
++offset;
}
if (offset >= 0)
{
if ((currentFrameIndex & (storedStartPosInterval - 1)) == 0)
frameStreamPositions.set (currentFrameIndex / storedStartPosInterval, oldPos + offset);
++currentFrameIndex;
}
stream.setPosition (oldPos);
return offset;
}
void readVBRHeader()
{
auto oldPos = stream.getPosition();
uint8 xing[194];
stream.read (xing, sizeof (xing));
vbrHeaderFound = vbrTagData.read (xing);
if (vbrHeaderFound)
{
numFrames = (int) vbrTagData.frames;
oldPos += jmax (vbrTagData.headersize, 1);
}
stream.setPosition (oldPos);
}
void decodeLayer1Frame (float* pcm0, float* pcm1, int& samplesDone) noexcept
{
float fraction[2][32];
SideInfoLayer1 si;
layer1Step1 (si);
auto single = (frame.numChannels == 1 || frame.single == 3) ? 0 : frame.single;
if (single >= 0)
{
for (int i = 0; i < 12; ++i)
{
layer1Step2 (si, fraction);
synthesise (fraction[single], 0, pcm0, samplesDone);
}
}
else
{
for (int i = 0; i < 12; ++i)
{
layer1Step2 (si, fraction);
synthesiseStereo (fraction[0], fraction[1], pcm0, pcm1, samplesDone);
}
}
}
void decodeLayer2Frame (float* pcm0, float* pcm1, int& samplesDone)
{
float fraction[2][4][32];
frame.selectLayer2Table();
SideInfoLayer2 si;
layer2Step1 (si);
auto single = (frame.numChannels == 1 || frame.single == 3) ? 0 : frame.single;
if (single >= 0)
{
for (int i = 0; i < 12; ++i)
{
layer2Step2 (si, i >> 2, fraction);
for (int j = 0; j < 3; ++j)
synthesise (fraction[single][j], 0, pcm0, samplesDone);
}
}
else
{
for (int i = 0; i < 12; ++i)
{
layer2Step2 (si, i >> 2, fraction);
for (int j = 0; j < 3; ++j)
synthesiseStereo (fraction[0][j], fraction[1][j], pcm0, pcm1, samplesDone);
}
}
}
void decodeLayer3Frame (float* pcm0, float* pcm1, int& samplesDone) noexcept
{
if (! rollBackBufferPointer ((int) sideinfo.mainDataStart))
return;
const int single = frame.numChannels == 1 ? 0 : frame.single;
const int numChans = (frame.numChannels == 1 || single >= 0) ? 1 : 2;
const bool msStereo = (frame.mode == 1) && (frame.modeExt & 2) != 0;
const bool iStereo = (frame.mode == 1) && (frame.modeExt & 1) != 0;
const int granules = frame.lsf ? 1 : 2;
int scaleFactors[2][39];
for (int gr = 0; gr < granules; ++gr)
{
{
auto& granule = sideinfo.ch[0].gr[gr];
auto part2bits = frame.lsf ? getLayer3ScaleFactors2 (scaleFactors[0], granule, 0)
: getLayer3ScaleFactors1 (scaleFactors[0], granule);
if (layer3DequantizeSample (hybridIn[0], scaleFactors[0], granule, frame.sampleRateIndex, part2bits))
return;
}
if (frame.numChannels == 2)
{
auto& granule = sideinfo.ch[1].gr[gr];
auto part2bits = frame.lsf ? getLayer3ScaleFactors2 (scaleFactors[1], granule, iStereo)
: getLayer3ScaleFactors1 (scaleFactors[1], granule);
if (layer3DequantizeSample (hybridIn[1], scaleFactors[1], granule, frame.sampleRateIndex, part2bits))
return;
if (msStereo)
{
for (int i = 0; i < 32 * 18; ++i)
{
auto tmp0 = ((const float*) hybridIn[0])[i];
auto tmp1 = ((const float*) hybridIn[1])[i];
((float*) hybridIn[1])[i] = tmp0 - tmp1;
((float*) hybridIn[0])[i] = tmp0 + tmp1;
}
}
if (iStereo)
granule.doIStereo (hybridIn, scaleFactors[1], frame.sampleRateIndex, msStereo, frame.lsf);
if (msStereo || iStereo || single == 3)
{
if (granule.maxb > sideinfo.ch[0].gr[gr].maxb)
sideinfo.ch[0].gr[gr].maxb = granule.maxb;
else
granule.maxb = sideinfo.ch[0].gr[gr].maxb;
}
switch (single)
{
case 3:
{
auto* in0 = (float*) hybridIn[0];
auto* in1 = (const float*) hybridIn[1];
for (int i = 0; i < (int) (18 * granule.maxb); ++i, ++in0)
*in0 = (*in0 + *in1++);
}
break;
case 1:
{
auto* in0 = (float*) hybridIn[0];
auto* in1 = (const float*) hybridIn[1];
for (int i = 0; i < (int) (18 * granule.maxb); ++i)
*in0++ = *in1++;
}
break;
}
}
for (int ch = 0; ch < numChans; ++ch)
{
auto& granule = sideinfo.ch[ch].gr[gr];
granule.doAntialias (hybridIn[ch]);
layer3Hybrid (hybridIn[ch], hybridOut[ch], ch, granule);
}
for (int ss = 0; ss < 18; ++ss)
{
if (single >= 0)
synthesise (hybridOut[0][ss], 0, pcm0, samplesDone);
else
synthesiseStereo (hybridOut[0][ss], hybridOut[1][ss], pcm0, pcm1, samplesDone);
}
}
}
int decodeLayer3SideInfo() noexcept
{
const int numChannels = frame.numChannels;
const int sampleRate = frame.sampleRateIndex;
const int single = (numChannels == 1) ? 0 : frame.single;
const bool msStereo = (frame.mode == 1) && (frame.modeExt & 2) != 0;
const int granules = frame.lsf ? 1 : 2;
if (frame.lsf == 0)
getLayer3SideInfo1 (numChannels, msStereo, sampleRate, single);
else
getLayer3SideInfo2 (numChannels, msStereo, sampleRate, single);
int databits = 0;
for (int gr = 0; gr < granules; ++gr)
for (int ch = 0; ch < numChannels; ++ch)
databits += sideinfo.ch[ch].gr[gr].part2_3Length;
return databits - 8 * (int) sideinfo.mainDataStart;
}
void layer1Step1 (SideInfoLayer1& si) noexcept
{
zerostruct (si);
int i, jsbound = (frame.mode == 1) ? (frame.modeExt << 2) + 4 : 32;
if (frame.numChannels == 2)
{
for (i = 0; i < jsbound; ++i)
{
si.allocation[i][0] = getBitsUint8 (4);
si.allocation[i][1] = getBitsUint8 (4);
}
for (i = jsbound; i < 32; ++i)
si.allocation[i][0] = si.allocation[i][1] = getBitsUint8 (4);
for (i = 0; i < 32; ++i)
{
si.scaleFactor[i][0] = si.allocation[i][0] ? getBitsUint8 (6) : 0;
si.scaleFactor[i][1] = si.allocation[i][1] ? getBitsUint8 (6) : 0;
}
}
else
{
for (i = 0; i < 32; ++i)
si.allocation[i][0] = getBitsUint8 (4);
for (i = 0; i < 32; ++i)
si.scaleFactor[i][0] = si.allocation[i][0] ? getBitsUint8 (6) : 0;
}
}
void layer1Step2 (SideInfoLayer1& si, float fraction[2][32]) noexcept
{
if (frame.numChannels == 2)
{
int i, jsbound = (frame.mode == 1) ? (frame.modeExt << 2) + 4 : 32;
for (i = 0; i < jsbound; ++i)
{
const uint8 n0 = si.allocation[i][0];
const uint8 n1 = si.allocation[i][1];
fraction[0][i] = n0 > 0 ? (float) ((-(1 << n0) + getBitsUint16 (n0 + 1) + 1) * constants.muls[n0 + 1][si.scaleFactor[i][0]]) : 0;
fraction[1][i] = n1 > 0 ? (float) ((-(1 << n1) + getBitsUint16 (n1 + 1) + 1) * constants.muls[n1 + 1][si.scaleFactor[i][1]]) : 0;
}
for (i = jsbound; i < 32; ++i)
{
const uint8 n = si.allocation[i][0];
if (n > 0)
{
const uint32 w = ((uint32) -(1 << n) + getBitsUint16 (n + 1) + 1);
fraction[0][i] = (float) (w * constants.muls[n + 1][si.scaleFactor[i][0]]);
fraction[1][i] = (float) (w * constants.muls[n + 1][si.scaleFactor[i][1]]);
}
else
fraction[0][i] = fraction[1][i] = 0;
}
}
else
{
for (int i = 0; i < 32; ++i)
{
const uint8 n = si.allocation[i][0];
const uint8 j = si.scaleFactor[i][0];
if (n > 0)
fraction[0][i] = (float) ((-(1 << n) + getBitsUint16 (n + 1) + 1) * constants.muls[n + 1][j]);
else
fraction[0][i] = 0;
}
}
}
void layer2Step1 (SideInfoLayer2& si) noexcept
{
zerostruct (si);
const int sblimit = frame.layer2SubBandLimit;
const int jsbound = (frame.mode == 1) ? (frame.modeExt << 2) + 4 : frame.layer2SubBandLimit;
auto* allocTable = frame.allocationTable;
uint8 scfsi[32][2];
if (frame.numChannels == 2)
{
for (int i = 0; i < jsbound; ++i)
{
auto step = allocTable->bits;
allocTable += (static_cast<intptr_t> (1) << step);
si.allocation[i][0] = getBitsUint8 (step);
si.allocation[i][1] = getBitsUint8 (step);
}
for (int i = jsbound; i < sblimit; ++i)
{
auto step = allocTable->bits;
auto b0 = getBitsUint8 (step);
allocTable += (static_cast<intptr_t> (1) << step);
si.allocation[i][0] = b0;
si.allocation[i][1] = b0;
}
for (int i = 0; i < sblimit; ++i)
{
scfsi[i][0] = si.allocation[i][0] ? getBitsUint8 (2) : 0;
scfsi[i][1] = si.allocation[i][1] ? getBitsUint8 (2) : 0;
}
}
else
{
for (int i = 0; i < sblimit; ++i)
{
const int16 step = allocTable->bits;
allocTable += (static_cast<intptr_t> (1) << step);
si.allocation[i][0] = getBitsUint8 (step);
}
for (int i = 0; i < sblimit; ++i)
scfsi[i][0] = si.allocation[i][0] ? getBitsUint8 (2) : 0;
}
for (int i = 0; i < sblimit; ++i)
{
for (int ch = 0; ch < frame.numChannels; ++ch)
{
uint8 s0 = 0, s1 = 0, s2 = 0;
if (si.allocation[i][ch])
{
switch (scfsi[i][ch])
{
case 0:
s0 = getBitsUint8 (6);
s1 = getBitsUint8 (6);
s2 = getBitsUint8 (6);
break;
case 1:
s1 = s0 = getBitsUint8 (6);
s2 = getBitsUint8 (6);
break;
case 2:
s2 = s1 = s0 = getBitsUint8 (6);
break;
case 3:
s0 = getBitsUint8 (6);
s2 = s1 = getBitsUint8 (6);
break;
default:
break;
}
}
si.scaleFactor[i][ch][0] = s0;
si.scaleFactor[i][ch][1] = s1;
si.scaleFactor[i][ch][2] = s2;
}
}
}
void layer2Step2 (SideInfoLayer2& si, const int gr, float fraction[2][4][32]) noexcept
{
auto* allocTable = frame.allocationTable;
const int jsbound = (frame.mode == 1) ? (frame.modeExt << 2) + 4 : frame.layer2SubBandLimit;
for (int i = 0; i < jsbound; ++i)
{
auto step = allocTable->bits;
for (int ch = 0; ch < frame.numChannels; ++ch)
{
if (auto ba = si.allocation[i][ch])
{
auto x1 = jmin ((uint8) 63, si.scaleFactor[i][ch][gr]);
auto* alloc2 = allocTable + ba;
auto k = jmin ((int16) 16, alloc2->bits);
auto d1 = alloc2->d;
if (d1 < 0)
{
const double cm = constants.muls[k][x1];
fraction[ch][0][i] = (float) (((int) getBits (k) + d1) * cm);
fraction[ch][1][i] = (float) (((int) getBits (k) + d1) * cm);
fraction[ch][2][i] = (float) (((int) getBits (k) + d1) * cm);
}
else
{
auto* tab = constants.getGroupTable (d1, getBits (k));
fraction[ch][0][i] = (float) constants.muls[tab[0]][x1];
fraction[ch][1][i] = (float) constants.muls[tab[1]][x1];
fraction[ch][2][i] = (float) constants.muls[tab[2]][x1];
}
}
else
{
fraction[ch][0][i] = fraction[ch][1][i] = fraction[ch][2][i] = 0;
}
}
allocTable += (static_cast<intptr_t> (1) << step);
}
for (int i = jsbound; i < frame.layer2SubBandLimit; ++i)
{
auto step = allocTable->bits;
auto ba = si.allocation[i][0];
if (ba != 0)
{
auto* alloc2 = allocTable + ba;
int16 k = alloc2->bits;
int16 d1 = alloc2->d;
k = (k <= 16) ? k : 16;
if (d1 < 0)
{
auto v0 = (int) getBits (k);
auto v1 = (int) getBits (k);
auto v2 = (int) getBits (k);
for (int ch = 0; ch < frame.numChannels; ++ch)
{
auto x1 = jmin ((uint8) 63, si.scaleFactor[i][ch][gr]);
const double cm = constants.muls[k][x1];
fraction[ch][0][i] = (float) ((v0 + d1) * cm);
fraction[ch][1][i] = (float) ((v1 + d1) * cm);
fraction[ch][2][i] = (float) ((v2 + d1) * cm);
}
}
else
{
auto* tab = constants.getGroupTable (d1, getBits (k));
auto k0 = tab[0];
auto k1 = tab[1];
auto k2 = tab[2];
for (int ch = 0; ch < frame.numChannels; ++ch)
{
auto x1 = jmin ((uint8) 63, si.scaleFactor[i][ch][gr]);
fraction[ch][0][i] = (float) constants.muls[k0][x1];
fraction[ch][1][i] = (float) constants.muls[k1][x1];
fraction[ch][2][i] = (float) constants.muls[k2][x1];
}
}
}
else
{
fraction[0][0][i] = fraction[0][1][i] = fraction[0][2][i] = 0;
fraction[1][0][i] = fraction[1][1][i] = fraction[1][2][i] = 0;
}
allocTable += (static_cast<intptr_t> (1) << step);
}
for (int ch = 0; ch < frame.numChannels; ++ch)
for (int i = frame.layer2SubBandLimit; i < 32; ++i)
fraction[ch][0][i] = fraction[ch][1][i] = fraction[ch][2][i] = 0;
}
void getLayer3SideInfo1 (const int stereo, const bool msStereo, const int sampleRate, const int single) noexcept
{
const int powdiff = (single == 3) ? 4 : 0;
sideinfo.mainDataStart = getBits (9);
sideinfo.privateBits = getBitsUnchecked (stereo == 1 ? 5 : 3);
for (int ch = 0; ch < stereo; ++ch)
{
sideinfo.ch[ch].gr[0].scfsi = -1;
sideinfo.ch[ch].gr[1].scfsi = (int) getBitsUnchecked (4);
}
for (int gr = 0; gr < 2; ++gr)
{
for (int ch = 0; ch < stereo; ++ch)
{
auto& granule = sideinfo.ch[ch].gr[gr];
granule.part2_3Length = getBits (12);
granule.bigValues = jmin (288u, getBitsUnchecked (9));
const int qss = (int) getBitsUnchecked (8);
granule.pow2gain = constants.powToGains + 256 - qss + powdiff;
if (msStereo)
granule.pow2gain += 2;
granule.scaleFactorCompression = getBitsUnchecked (4);
if (getOneBit())
{
granule.blockType = getBitsUnchecked (2);
granule.mixedBlockFlag = getOneBit();
granule.tableSelect[0] = getBitsUnchecked (5);
granule.tableSelect[1] = getBitsUnchecked (5);
granule.tableSelect[2] = 0;
for (int i = 0; i < 3; ++i)
{
const uint32 sbg = (getBitsUnchecked (3) << 3);
granule.fullGain[i] = granule.pow2gain + sbg;
}
granule.region1Start = 36 >> 1;
granule.region2Start = 576 >> 1;
}
else
{
for (int i = 0; i < 3; ++i)
granule.tableSelect[i] = getBitsUnchecked (5);
const int r0c = (int) getBitsUnchecked (4);
const int r1c = (int) getBitsUnchecked (3);
const int region0index = jmin (22, r0c + 1);
const int region1index = jmin (22, r0c + 1 + r1c + 1);
granule.region1Start = (uint32) (bandInfo[sampleRate].longIndex[region0index] >> 1);
granule.region2Start = (uint32) (bandInfo[sampleRate].longIndex[region1index] >> 1);
granule.blockType = 0;
granule.mixedBlockFlag = 0;
}
granule.preflag = getOneBit();
granule.scaleFactorScale = getOneBit();
granule.count1TableSelect = getOneBit();
}
}
}
void getLayer3SideInfo2 (const int stereo, const bool msStereo, const int sampleRate, const int single) noexcept
{
const int powdiff = (single == 3) ? 4 : 0;
sideinfo.mainDataStart = getBits (8);
sideinfo.privateBits = stereo == 1 ? getOneBit() : getBitsUnchecked (2);
for (int ch = 0; ch < stereo; ++ch)
{
auto& granule = sideinfo.ch[ch].gr[0];
granule.part2_3Length = getBits (12);
granule.bigValues = jmin (288u, getBitsUnchecked (9));
const uint32 qss = getBitsUnchecked (8);
granule.pow2gain = constants.powToGains + 256 - qss + powdiff;
if (msStereo)
granule.pow2gain += 2;
granule.scaleFactorCompression = getBits (9);
if (getOneBit())
{
granule.blockType = getBitsUnchecked (2);
granule.mixedBlockFlag = getOneBit();
granule.tableSelect[0] = getBitsUnchecked (5);
granule.tableSelect[1] = getBitsUnchecked (5);
granule.tableSelect[2] = 0;
for (int i = 0; i < 3; ++i)
{
const uint32 sbg = (getBitsUnchecked (3) << 3);
granule.fullGain[i] = granule.pow2gain + sbg;
}
if (granule.blockType == 0)
{}
if (granule.blockType == 2)
granule.region1Start = sampleRate == 8 ? 36 : (36 >> 1);
else
granule.region1Start = sampleRate == 8 ? (108 >> 1) : (54 >> 1);
granule.region2Start = 576 >> 1;
}
else
{
for (int i = 0; i < 3; ++i)
granule.tableSelect[i] = getBitsUnchecked (5);
const int r0c = (int) getBitsUnchecked (4);
const int r1c = (int) getBitsUnchecked (3);
const int region0index = jmin (22, r0c + 1);
const int region1index = jmin (22, r0c + 1 + r1c + 1);
granule.region1Start = (uint32) (bandInfo[sampleRate].longIndex[region0index] >> 1);
granule.region2Start = (uint32) (bandInfo[sampleRate].longIndex[region1index] >> 1);
granule.blockType = 0;
granule.mixedBlockFlag = 0;
}
granule.scaleFactorScale = getOneBit();
granule.count1TableSelect = getOneBit();
}
}
int getLayer3ScaleFactors1 (int* scf, const Layer3SideInfo::Info& granule) noexcept
{
static const uint8 lengths[2][16] =
{
{ 0, 0, 0, 0, 3, 1, 1, 1, 2, 2, 2, 3, 3, 3, 4, 4 },
{ 0, 1, 2, 3, 0, 1, 2, 3, 1, 2, 3, 1, 2, 3, 2, 3 }
};
int numBits;
const int num0 = lengths[0][granule.scaleFactorCompression];
const int num1 = lengths[1][granule.scaleFactorCompression];
if (granule.blockType == 2)
{
int i = 18;
numBits = (num0 + num1) * 18;
if (granule.mixedBlockFlag)
{
for (int j = 8; --j >= 0;) *scf++ = (int) getBitsUnchecked (num0);
numBits -= num0;
i = 9;
}
for (; --i >= 0;) *scf++ = (int) getBitsUnchecked (num0);
for (i = 18; --i >= 0;) *scf++ = (int) getBitsUnchecked (num1);
*scf++ = 0;
*scf++ = 0;
*scf++ = 0;
}
else
{
const int scfsi = granule.scfsi;
if (scfsi < 0)
{
for (int i = 11; --i >= 0;) *scf++ = (int) getBitsUnchecked (num0);
for (int j = 10; --j >= 0;) *scf++ = (int) getBitsUnchecked (num1);
numBits = (num0 + num1) * 10 + num0;
}
else
{
numBits = 0;
if ((scfsi & 8) == 0)
{
for (int i = 6; --i >= 0;) *scf++ = (int) getBitsUnchecked (num0);
numBits += num0 * 6;
}
else
scf += 6;
if ((scfsi & 4) == 0)
{
for (int i = 5; --i >= 0;) *scf++ = (int) getBitsUnchecked (num0);
numBits += num0 * 5;
}
else
scf += 5;
if ((scfsi & 2) == 0)
{
for (int i = 5; --i >= 0;) *scf++ = (int) getBitsUnchecked (num1);
numBits += num1 * 5;
}
else
scf += 5;
if ((scfsi & 1) == 0)
{
for (int i = 5; --i >= 0;) *scf++ = (int) getBitsUnchecked (num1);
numBits += num1 * 5;
}
else
scf += 5;
}
*scf = 0;
}
return numBits;
}
int getLayer3ScaleFactors2 (int* scf, Layer3SideInfo::Info& granule, const bool iStereo) noexcept
{
static const uint8 scaleTable[3][6][4] =
{
{ { 6, 5, 5, 5 }, { 6, 5, 7, 3 }, { 11, 10, 0, 0 }, { 7, 7, 7, 0 }, { 6, 6, 6, 3 }, { 8, 8, 5, 0 } },
{ { 9, 9, 9, 9 }, { 9, 9, 12, 6 }, { 18, 18, 0, 0 }, { 12, 12, 12, 0 }, { 12, 9, 9, 6 }, { 15, 12, 9, 0 } },
{ { 6, 9, 9, 9 }, { 6, 9, 12, 6 }, { 15, 18, 0, 0 }, { 6, 15, 12, 0 }, { 6, 12, 9, 6 }, { 6, 18, 9, 0 } }
};
uint32 len = iStereo ? constants.iLength2[granule.scaleFactorCompression >> 1]
: constants.nLength2[granule.scaleFactorCompression];
granule.preflag = (len >> 15) & 1;
int n = 0;
if (granule.blockType == 2)
{
++n;
if (granule.mixedBlockFlag)
++n;
}
const uint8* const data = scaleTable[n][(len >> 12) & 7];
int numBits = 0;
for (int i = 0; i < 4; ++i)
{
int num = len & 7;
len >>= 3;
if (num)
{
for (int j = 0; j < (int) (data[i]); ++j)
*scf++ = (int) getBitsUnchecked (num);
numBits += data[i] * num;
}
else
{
for (int j = 0; j < (int) (data[i]); ++j)
*scf++ = 0;
}
}
n = (n << 1) + 1;
for (int i = 0; i < n; ++i)
*scf++ = 0;
return numBits;
}
bool layer3DequantizeSample (float xr[32][18], int* scf, Layer3SideInfo::Info& granule, int sampleRate, int part2bits) noexcept
{
const uint32 shift = 1 + granule.scaleFactorScale;
auto* xrpnt = (float*) xr;
auto part2remain = (int) granule.part2_3Length - part2bits;
zeromem (xrpnt, sizeof (float) * (size_t) (&xr[32][0] - xrpnt));
auto bv = (int) granule.bigValues;
auto region1 = (int) granule.region1Start;
auto region2 = (int) granule.region2Start;
int l3 = ((576 >> 1) - bv) >> 1;
int l[3];
if (bv <= region1)
{
l[0] = bv;
l[1] = 0;
l[2] = 0;
}
else
{
l[0] = region1;
if (bv <= region2)
{
l[1] = bv - l[0];
l[2] = 0;
}
else
{
l[1] = region2 - l[0];
l[2] = bv - region2;
}
}
for (int i = 0; i < 3; ++i)
if (l[i] < 0)
l[i] = 0;
if (granule.blockType == 2)
{
int max[4];
int step = 0, lwin = 0, cb = 0, mc = 0;
float v = 0;
int* map;
int* mapEnd;
if (granule.mixedBlockFlag)
{
max[3] = -1;
max[0] = max[1] = max[2] = 2;
map = constants.map [sampleRate][0];
mapEnd = constants.mapEnd[sampleRate][0];
}
else
{
max[0] = max[1] = max[2] = max[3] = -1;
map = constants.map [sampleRate][1];
mapEnd = constants.mapEnd[sampleRate][1];
}
for (int i = 0; i < 2; ++i)
{
auto* h = huffmanTables1 + granule.tableSelect[i];
for (int lp = l[i]; lp != 0; --lp, --mc)
{
int x, y;
if (mc == 0)
{
mc = *map++;
xrpnt = ((float*) xr) + (*map++);
lwin = *map++;
cb = *map++;
if (lwin == 3)
{
v = granule.pow2gain[ (*scf++) << shift];
step = 1;
}
else
{
v = granule.fullGain[lwin][ (*scf++) << shift];
step = 3;
}
}
auto* val = h->table;
while ((y = *val++) < 0)
{
if (getOneBit())
val -= y;
--part2remain;
}
x = y >> 4;
y &= 15;
if (x == 15)
{
max[lwin] = cb;
part2remain -= h->bits + 1;
x += getBits ((int) h->bits);
*xrpnt = constants.nToThe4Over3[x] * (getOneBit() ? -v : v);
}
else if (x)
{
max[lwin] = cb;
*xrpnt = constants.nToThe4Over3[x] * (getOneBit() ? -v : v);
--part2remain;
}
else
*xrpnt = 0;
xrpnt += step;
if (y == 15)
{
max[lwin] = cb;
part2remain -= h->bits + 1;
y += getBits ((int) h->bits);
*xrpnt = constants.nToThe4Over3[y] * (getOneBit() ? -v : v);
}
else if (y)
{
max[lwin] = cb;
*xrpnt = constants.nToThe4Over3[y] * (getOneBit() ? -v : v);
--part2remain;
}
else
*xrpnt = 0;
xrpnt += step;
}
}
for (; l3 && (part2remain > 0); --l3)
{
auto* h = huffmanTables2 + granule.count1TableSelect;
auto* val = h->table;
int16 a;
while ((a = *val++) < 0)
{
if (part2remain <= 0)
{
a = 0;
break;
}
--part2remain;
if (getOneBit())
val -= a;
}
for (int i = 0; i < 4; ++i)
{
if ((i & 1) == 0)
{
if (mc == 0)
{
mc = *map++;
xrpnt = ((float*) xr) + (*map++);
lwin = *map++;
cb = *map++;
if (lwin == 3)
{
v = granule.pow2gain[ (*scf++) << shift];
step = 1;
}
else
{
v = granule.fullGain[lwin][ (*scf++) << shift];
step = 3;
}
}
--mc;
}
if ((a & (8 >> i)))
{
max[lwin] = cb;
if (part2remain == 0)
break;
--part2remain;
*xrpnt = getOneBit() ? -v : v;
}
else
*xrpnt = 0;
xrpnt += step;
}
}
while (map < mapEnd)
{
if (mc == 0)
{
mc = *map++;
xrpnt = ((float*) xr) + *map++;
step = (*map++ == 3) ? 1 : 3;
++map;
}
--mc;
*xrpnt = 0; xrpnt += step;
*xrpnt = 0; xrpnt += step;
}
granule.maxBand[0] = (uint32) (max[0] + 1);
granule.maxBand[1] = (uint32) (max[1] + 1);
granule.maxBand[2] = (uint32) (max[2] + 1);
granule.maxBandl = (uint32) (max[3] + 1);
const int rmax = jmax (max[0], max[1], max[3]) + 1;
granule.maxb = rmax ? (uint32) constants.shortLimit[sampleRate][rmax]
: (uint32) constants.longLimit[sampleRate][max[3] + 1];
}
else
{
static const int pretab1[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 3, 3, 3, 2, 0 };
static const int pretab2[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
auto* pretab = (const int*) (granule.preflag ? pretab1 : pretab2);
int max = -1, cb = 0, mc = 0;
auto* map = constants.map[sampleRate][2];
float v = 0;
for (int i = 0; i < 3; ++i)
{
auto* h = huffmanTables1 + granule.tableSelect[i];
for (int lp = l[i]; lp != 0; --lp, --mc)
{
if (mc == 0)
{
mc = *map++;
v = granule.pow2gain[((*scf++) + (*pretab++)) << shift];
cb = *map++;
}
auto* val = h->table;
int y;
while ((y = *val++) < 0)
{
if (getOneBit()) val -= y;
--part2remain;
}
int x = y >> 4;
y &= 15;
if (x == 15)
{
max = cb;
part2remain -= h->bits + 1;
x += getBits ((int) h->bits);
*xrpnt++ = constants.nToThe4Over3[x] * (getOneBit() ? -v : v);
}
else if (x)
{
max = cb;
*xrpnt++ = constants.nToThe4Over3[x] * (getOneBit() ? -v : v);
--part2remain;
}
else
*xrpnt++ = 0;
if (y == 15)
{
max = cb;
part2remain -= h->bits + 1;
y += getBits ((int) h->bits);
*xrpnt++ = constants.nToThe4Over3[y] * (getOneBit() ? -v : v);
}
else if (y)
{
max = cb;
*xrpnt++ = constants.nToThe4Over3[y] * (getOneBit() ? -v : v);
--part2remain;
}
else
*xrpnt++ = 0;
}
}
for (; l3 && part2remain > 0; --l3)
{
auto* h = huffmanTables2 + granule.count1TableSelect;
auto* values = h->table;
int16 a;
while ((a = *values++) < 0)
{
if (part2remain <= 0)
{
a = 0;
break;
}
--part2remain;
if (getOneBit())
values -= a;
}
for (int i = 0; i < 4; ++i)
{
if ((i & 1) == 0)
{
if (mc == 0)
{
mc = *map++;
cb = *map++;
v = granule.pow2gain[((*scf++) + (*pretab++)) << shift];
}
--mc;
}
if ((a & (0x8 >> i)))
{
max = cb;
if (part2remain <= 0)
break;
--part2remain;
*xrpnt++ = getOneBit() ? -v : v;
}
else
*xrpnt++ = 0;
}
}
zeromem (xrpnt, sizeof (float) * (size_t) (&xr[32][0] - xrpnt));
granule.maxBandl = (uint32) (max + 1);
granule.maxb = (uint32) constants.longLimit[sampleRate][granule.maxBandl];
}
while (part2remain > 16)
{
getBits (16);
part2remain -= 16;
}
if (part2remain > 0)
getBits (part2remain);
else if (part2remain < 0)
return true;
return false;
}
void layer3Hybrid (float fsIn[32][18], float tsOut[18][32], int ch, const Layer3SideInfo::Info& granule) noexcept
{
auto* ts = (float*) tsOut;
float* rawout1, *rawout2;
int sb = 0;
{
int b = hybridBlockIndex[ch];
rawout1 = hybridBlock[b][ch];
b = 1 - b;
rawout2 = hybridBlock[b][ch];
hybridBlockIndex[ch] = b;
}
if (granule.mixedBlockFlag)
{
sb = 2;
DCT::dct36 (fsIn[0], rawout1, rawout2, constants.win[0], ts);
DCT::dct36 (fsIn[1], rawout1 + 18, rawout2 + 18, constants.win1[0], ts + 1);
rawout1 += 36;
rawout2 += 36;
ts += 2;
}
auto bt = granule.blockType;
if (bt == 2)
{
for (; sb < (int) granule.maxb; sb += 2, ts += 2, rawout1 += 36, rawout2 += 36)
{
DCT::dct12 (fsIn[sb], rawout1, rawout2, constants.win[2], ts);
DCT::dct12 (fsIn[sb + 1], rawout1 + 18, rawout2 + 18, constants.win1[2], ts + 1);
}
}
else
{
for (; sb < (int) granule.maxb; sb += 2, ts += 2, rawout1 += 36, rawout2 += 36)
{
DCT::dct36 (fsIn[sb], rawout1, rawout2, constants.win[bt], ts);
DCT::dct36 (fsIn[sb + 1], rawout1 + 18, rawout2 + 18, constants.win1[bt], ts + 1);
}
}
for (; sb < 32; ++sb, ++ts)
{
for (int i = 0; i < 18; ++i)
{
ts[i * 32] = *rawout1++;
*rawout2++ = 0;
}
}
}
void synthesiseStereo (const float* bandPtr0, const float* bandPtr1, float* out0, float* out1, int& samplesDone) noexcept
{
auto dummy = samplesDone;
synthesise (bandPtr0, 0, out0, dummy);
synthesise (bandPtr1, 1, out1, samplesDone);
}
void synthesise (const float* bandPtr, int channel, float* out, int& samplesDone)
{
out += samplesDone;
const int bo = channel == 0 ? ((synthBo - 1) & 15) : synthBo;
float (*buf)[0x110] = synthBuffers[channel];
float* b0;
auto bo1 = bo;
if (bo & 1)
{
b0 = buf[0];
DCT::dct64 (buf[1] + ((bo + 1) & 15), buf[0] + bo, bandPtr);
}
else
{
++bo1;
b0 = buf[1];
DCT::dct64 (buf[0] + bo, buf[1] + bo1, bandPtr);
}
synthBo = bo;
const float* window = constants.decodeWin + 16 - bo1;
for (int j = 16; j != 0; --j, b0 += 16, window += 32)
{
auto sum = window[0] * b0[0]; sum -= window[1] * b0[1];
sum += window[2] * b0[2]; sum -= window[3] * b0[3];
sum += window[4] * b0[4]; sum -= window[5] * b0[5];
sum += window[6] * b0[6]; sum -= window[7] * b0[7];
sum += window[8] * b0[8]; sum -= window[9] * b0[9];
sum += window[10] * b0[10]; sum -= window[11] * b0[11];
sum += window[12] * b0[12]; sum -= window[13] * b0[13];
sum += window[14] * b0[14]; sum -= window[15] * b0[15];
*out++ = sum;
}
{
auto sum = window[0] * b0[0]; sum += window[2] * b0[2];
sum += window[4] * b0[4]; sum += window[6] * b0[6];
sum += window[8] * b0[8]; sum += window[10] * b0[10];
sum += window[12] * b0[12]; sum += window[14] * b0[14];
*out++ = sum;
b0 -= 16; window -= 32;
window += bo1 << 1;
}
for (int j = 15; j != 0; --j, b0 -= 16, window -= 32)
{
auto sum = -window[-1] * b0[0]; sum -= window[-2] * b0[1];
sum -= window[-3] * b0[2]; sum -= window[-4] * b0[3];
sum -= window[-5] * b0[4]; sum -= window[-6] * b0[5];
sum -= window[-7] * b0[6]; sum -= window[-8] * b0[7];
sum -= window[-9] * b0[8]; sum -= window[-10] * b0[9];
sum -= window[-11] * b0[10]; sum -= window[-12] * b0[11];
sum -= window[-13] * b0[12]; sum -= window[-14] * b0[13];
sum -= window[-15] * b0[14]; sum -= window[0] * b0[15];
*out++ = sum;
}
samplesDone += 32;
}
JUCE_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR (MP3Stream)
};
//==============================================================================
static const char* const mp3FormatName = "MP3 file";
//==============================================================================
class MP3Reader : public AudioFormatReader
{
public:
MP3Reader (InputStream* const in)
: AudioFormatReader (in, mp3FormatName),
stream (*in), currentPosition (0),
decodedStart (0), decodedEnd (0)
{
skipID3();
const int64 streamPos = stream.stream.getPosition();
if (readNextBlock())
{
bitsPerSample = 32;
usesFloatingPointData = true;
sampleRate = stream.frame.getFrequency();
numChannels = (unsigned int) stream.frame.numChannels;
lengthInSamples = findLength (streamPos);
}
}
bool readSamples (int** destSamples, int numDestChannels, int startOffsetInDestBuffer,
int64 startSampleInFile, int numSamples) override
{
jassert (destSamples != nullptr);
if (currentPosition != startSampleInFile)
{
if (! stream.seek ((int) (startSampleInFile / 1152 - 1)))
{
currentPosition = -1;
createEmptyDecodedData();
}
else
{
decodedStart = decodedEnd = 0;
const int64 streamPos = stream.currentFrameIndex * 1152;
int toSkip = (int) (startSampleInFile - streamPos);
jassert (toSkip >= 0);
while (toSkip > 0)
{
if (! readNextBlock())
{
createEmptyDecodedData();
break;
}
const int numReady = decodedEnd - decodedStart;
if (numReady > toSkip)
{
decodedStart += toSkip;
break;
}
toSkip -= numReady;
}
currentPosition = startSampleInFile;
}
}
while (numSamples > 0)
{
if (decodedEnd <= decodedStart && ! readNextBlock())
{
for (int i = numDestChannels; --i >= 0;)
if (destSamples[i] != nullptr)
zeromem (destSamples[i] + startOffsetInDestBuffer, sizeof (float) * (size_t) numSamples);
return false;
}
const int numToCopy = jmin (decodedEnd - decodedStart, numSamples);
float* const* const dst = reinterpret_cast<float**> (destSamples);
memcpy (dst[0] + startOffsetInDestBuffer, decoded0 + decodedStart, sizeof (float) * (size_t) numToCopy);
if (numDestChannels > 1 && dst[1] != nullptr)
memcpy (dst[1] + startOffsetInDestBuffer, (numChannels < 2 ? decoded0 : decoded1) + decodedStart, sizeof (float) * (size_t) numToCopy);
startOffsetInDestBuffer += numToCopy;
decodedStart += numToCopy;
currentPosition += numToCopy;
numSamples -= numToCopy;
}
return true;
}
private:
MP3Stream stream;
int64 currentPosition;
enum { decodedDataSize = 1152 };
float decoded0[decodedDataSize], decoded1[decodedDataSize];
int decodedStart, decodedEnd;
void createEmptyDecodedData() noexcept
{
zeromem (decoded0, sizeof (decoded0));
zeromem (decoded1, sizeof (decoded1));
decodedStart = 0;
decodedEnd = decodedDataSize;
}
bool readNextBlock()
{
for (int attempts = 10; --attempts >= 0;)
{
int samplesDone = 0;
const int result = stream.decodeNextBlock (decoded0, decoded1, samplesDone);
if (result > 0 && stream.stream.isExhausted())
{
createEmptyDecodedData();
return true;
}
if (result <= 0)
{
decodedStart = 0;
decodedEnd = samplesDone;
return result == 0;
}
}
return false;
}
void skipID3()
{
const int64 originalPosition = stream.stream.getPosition();
const uint32 firstWord = (uint32) stream.stream.readInt();
if ((firstWord & 0xffffff) == 0x334449)
{
uint8 buffer[6];
if (stream.stream.read (buffer, 6) == 6
&& buffer[0] != 0xff
&& ((buffer[2] | buffer[3] | buffer[4] | buffer[5]) & 0x80) == 0)
{
const uint32 length = (((uint32) buffer[2]) << 21)
| (((uint32) buffer[3]) << 14)
| (((uint32) buffer[4]) << 7)
| ((uint32) buffer[5]);
stream.stream.skipNextBytes (length);
return;
}
}
stream.stream.setPosition (originalPosition);
}
int64 findLength (int64 streamStartPos)
{
int64 numFrames = stream.numFrames;
if (numFrames <= 0)
{
const int64 streamSize = stream.stream.getTotalLength();
if (streamSize > 0)
{
const int bytesPerFrame = stream.frame.frameSize + 4;
if (bytesPerFrame == 417 || bytesPerFrame == 418)
numFrames = roundToInt ((streamSize - streamStartPos) / 417.95918); // more accurate for 128k
else
numFrames = (streamSize - streamStartPos) / bytesPerFrame;
}
}
return numFrames * 1152;
}
JUCE_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR (MP3Reader)
};
}
//==============================================================================
MP3AudioFormat::MP3AudioFormat() : AudioFormat (MP3Decoder::mp3FormatName, ".mp3") {}
MP3AudioFormat::~MP3AudioFormat() {}
Array<int> MP3AudioFormat::getPossibleSampleRates() { return {}; }
Array<int> MP3AudioFormat::getPossibleBitDepths() { return {}; }
bool MP3AudioFormat::canDoStereo() { return true; }
bool MP3AudioFormat::canDoMono() { return true; }
bool MP3AudioFormat::isCompressed() { return true; }
StringArray MP3AudioFormat::getQualityOptions() { return {}; }
AudioFormatReader* MP3AudioFormat::createReaderFor (InputStream* sourceStream, const bool deleteStreamIfOpeningFails)
{
std::unique_ptr<MP3Decoder::MP3Reader> r (new MP3Decoder::MP3Reader (sourceStream));
if (r->lengthInSamples > 0)
return r.release();
if (! deleteStreamIfOpeningFails)
r->input = nullptr;
return nullptr;
}
AudioFormatWriter* MP3AudioFormat::createWriterFor (OutputStream*, double /*sampleRateToUse*/,
unsigned int /*numberOfChannels*/, int /*bitsPerSample*/,
const StringPairArray& /*metadataValues*/, int /*qualityOptionIndex*/)
{
jassertfalse; // not yet implemented!
return nullptr;
}
#endif
} // namespace juce
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