mirror of
https://github.com/kwsch/PKHeX
synced 2024-12-22 10:23:09 +00:00
47071b41f3
Existing `get`/`set` logic is flawed in that it doesn't work on Big Endian operating systems, and it allocates heap objects when it doesn't need to. `System.Buffers.Binary.BinaryPrimitives` in the `System.Memory` NuGet package provides both Little Endian and Big Endian methods to read and write data; all the `get`/`set` operations have been reworked to use this new API. This removes the need for PKHeX's manual `BigEndian` class, as all functions are already covered by the BinaryPrimitives API. The `StringConverter` has now been rewritten to accept a Span to read from & write to, no longer requiring a temporary StringBuilder. Other Fixes included: - The Super Training UI for Gen6 has been reworked according to the latest block structure additions. - Cloning a Stadium2 Save File now works correctly (opening from the Folder browser list). - Checksum & Sanity properties removed from parent PKM class, and is now implemented via interface.
41 lines
2.9 KiB
C#
41 lines
2.9 KiB
C#
using System;
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using static System.Buffers.Binary.BinaryPrimitives;
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namespace PKHeX.Core
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{
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public sealed class HallOfFame7 : SaveBlock
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{
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public HallOfFame7(SAV7SM sav, int offset) : base(sav) => Offset = offset;
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public HallOfFame7(SAV7USUM sav, int offset) : base(sav) => Offset = offset;
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// this HoF region is immediately after the Event Flags
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private const int MaxCount = 12;
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public int First1 { get => ReadUInt16LittleEndian(Data.AsSpan(Offset + 0x00)); set => WriteUInt16LittleEndian(Data.AsSpan(Offset + 0x00), (ushort)value); }
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public int First2 { get => ReadUInt16LittleEndian(Data.AsSpan(Offset + 0x02)); set => WriteUInt16LittleEndian(Data.AsSpan(Offset + 0x02), (ushort)value); }
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public int First3 { get => ReadUInt16LittleEndian(Data.AsSpan(Offset + 0x04)); set => WriteUInt16LittleEndian(Data.AsSpan(Offset + 0x04), (ushort)value); }
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public int First4 { get => ReadUInt16LittleEndian(Data.AsSpan(Offset + 0x04)); set => WriteUInt16LittleEndian(Data.AsSpan(Offset + 0x04), (ushort)value); }
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public int First5 { get => ReadUInt16LittleEndian(Data.AsSpan(Offset + 0x06)); set => WriteUInt16LittleEndian(Data.AsSpan(Offset + 0x06), (ushort)value); }
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public int First6 { get => ReadUInt16LittleEndian(Data.AsSpan(Offset + 0x08)); set => WriteUInt16LittleEndian(Data.AsSpan(Offset + 0x08), (ushort)value); }
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public int Current1 { get => ReadUInt16LittleEndian(Data.AsSpan(Offset + 0x0A)); set => WriteUInt16LittleEndian(Data.AsSpan(Offset + 0x0A), (ushort)value); }
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public int Current2 { get => ReadUInt16LittleEndian(Data.AsSpan(Offset + 0x0C)); set => WriteUInt16LittleEndian(Data.AsSpan(Offset + 0x0C), (ushort)value); }
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public int Current3 { get => ReadUInt16LittleEndian(Data.AsSpan(Offset + 0x0E)); set => WriteUInt16LittleEndian(Data.AsSpan(Offset + 0x0E), (ushort)value); }
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public int Current4 { get => ReadUInt16LittleEndian(Data.AsSpan(Offset + 0x10)); set => WriteUInt16LittleEndian(Data.AsSpan(Offset + 0x10), (ushort)value); }
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public int Current5 { get => ReadUInt16LittleEndian(Data.AsSpan(Offset + 0x12)); set => WriteUInt16LittleEndian(Data.AsSpan(Offset + 0x12), (ushort)value); }
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public int Current6 { get => ReadUInt16LittleEndian(Data.AsSpan(Offset + 0x14)); set => WriteUInt16LittleEndian(Data.AsSpan(Offset + 0x14), (ushort)value); }
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public int GetEntry(int index)
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{
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if ((uint)index >= MaxCount)
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throw new ArgumentOutOfRangeException(nameof(index));
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return ReadUInt16LittleEndian(SAV.Data.AsSpan(Offset + (index * 2)));
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}
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public void SetEntry(int index, ushort value)
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{
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if ((uint)index >= MaxCount)
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throw new ArgumentOutOfRangeException(nameof(index));
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WriteUInt16LittleEndian(SAV.Data.AsSpan(Offset + (index * 2)), value);
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}
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}
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}
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