mirror of
https://github.com/ziglang/zig.git
synced 2024-11-28 08:02:32 +00:00
2eeb735822
Closes #17811
438 lines
17 KiB
Zig
438 lines
17 KiB
Zig
const std = @import("std");
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const testing = std.testing;
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/// Read a single unsigned LEB128 value from the given reader as type T,
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/// or error.Overflow if the value cannot fit.
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pub fn readULEB128(comptime T: type, reader: anytype) !T {
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const U = if (@typeInfo(T).Int.bits < 8) u8 else T;
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const ShiftT = std.math.Log2Int(U);
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const max_group = (@typeInfo(U).Int.bits + 6) / 7;
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var value: U = 0;
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var group: ShiftT = 0;
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while (group < max_group) : (group += 1) {
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const byte = try reader.readByte();
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const ov = @shlWithOverflow(@as(U, byte & 0x7f), group * 7);
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if (ov[1] != 0) return error.Overflow;
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value |= ov[0];
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if (byte & 0x80 == 0) break;
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} else {
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return error.Overflow;
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}
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// only applies in the case that we extended to u8
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if (U != T) {
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if (value > std.math.maxInt(T)) return error.Overflow;
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}
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return @as(T, @truncate(value));
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}
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/// Write a single unsigned integer as unsigned LEB128 to the given writer.
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pub fn writeULEB128(writer: anytype, uint_value: anytype) !void {
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const T = @TypeOf(uint_value);
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const U = if (@typeInfo(T).Int.bits < 8) u8 else T;
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var value: U = @intCast(uint_value);
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while (true) {
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const byte: u8 = @truncate(value & 0x7f);
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value >>= 7;
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if (value == 0) {
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try writer.writeByte(byte);
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break;
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} else {
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try writer.writeByte(byte | 0x80);
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}
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}
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}
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/// Read a single signed LEB128 value from the given reader as type T,
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/// or error.Overflow if the value cannot fit.
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pub fn readILEB128(comptime T: type, reader: anytype) !T {
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const S = if (@typeInfo(T).Int.bits < 8) i8 else T;
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const U = std.meta.Int(.unsigned, @typeInfo(S).Int.bits);
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const ShiftU = std.math.Log2Int(U);
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const max_group = (@typeInfo(U).Int.bits + 6) / 7;
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var value = @as(U, 0);
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var group = @as(ShiftU, 0);
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while (group < max_group) : (group += 1) {
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const byte = try reader.readByte();
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const shift = group * 7;
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const ov = @shlWithOverflow(@as(U, byte & 0x7f), shift);
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if (ov[1] != 0) {
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// Overflow is ok so long as the sign bit is set and this is the last byte
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if (byte & 0x80 != 0) return error.Overflow;
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if (@as(S, @bitCast(ov[0])) >= 0) return error.Overflow;
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// and all the overflowed bits are 1
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const remaining_shift = @as(u3, @intCast(@typeInfo(U).Int.bits - @as(u16, shift)));
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const remaining_bits = @as(i8, @bitCast(byte | 0x80)) >> remaining_shift;
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if (remaining_bits != -1) return error.Overflow;
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} else {
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// If we don't overflow and this is the last byte and the number being decoded
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// is negative, check that the remaining bits are 1
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if ((byte & 0x80 == 0) and (@as(S, @bitCast(ov[0])) < 0)) {
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const remaining_shift = @as(u3, @intCast(@typeInfo(U).Int.bits - @as(u16, shift)));
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const remaining_bits = @as(i8, @bitCast(byte | 0x80)) >> remaining_shift;
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if (remaining_bits != -1) return error.Overflow;
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}
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}
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value |= ov[0];
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if (byte & 0x80 == 0) {
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const needs_sign_ext = group + 1 < max_group;
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if (byte & 0x40 != 0 and needs_sign_ext) {
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const ones = @as(S, -1);
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value |= @as(U, @bitCast(ones)) << (shift + 7);
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}
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break;
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}
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} else {
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return error.Overflow;
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}
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const result = @as(S, @bitCast(value));
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// Only applies if we extended to i8
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if (S != T) {
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if (result > std.math.maxInt(T) or result < std.math.minInt(T)) return error.Overflow;
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}
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return @as(T, @truncate(result));
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}
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/// Write a single signed integer as signed LEB128 to the given writer.
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pub fn writeILEB128(writer: anytype, int_value: anytype) !void {
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const T = @TypeOf(int_value);
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const S = if (@typeInfo(T).Int.bits < 8) i8 else T;
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const U = std.meta.Int(.unsigned, @typeInfo(S).Int.bits);
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var value: S = @intCast(int_value);
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while (true) {
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const uvalue: U = @bitCast(value);
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const byte: u8 = @truncate(uvalue);
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value >>= 6;
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if (value == -1 or value == 0) {
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try writer.writeByte(byte & 0x7F);
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break;
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} else {
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value >>= 1;
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try writer.writeByte(byte | 0x80);
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}
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}
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}
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/// This is an "advanced" function. It allows one to use a fixed amount of memory to store a
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/// ULEB128. This defeats the entire purpose of using this data encoding; it will no longer use
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/// fewer bytes to store smaller numbers. The advantage of using a fixed width is that it makes
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/// fields have a predictable size and so depending on the use case this tradeoff can be worthwhile.
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/// An example use case of this is in emitting DWARF info where one wants to make a ULEB128 field
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/// "relocatable", meaning that it becomes possible to later go back and patch the number to be a
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/// different value without shifting all the following code.
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pub fn writeUnsignedFixed(comptime l: usize, ptr: *[l]u8, int: std.meta.Int(.unsigned, l * 7)) void {
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const T = @TypeOf(int);
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const U = if (@typeInfo(T).Int.bits < 8) u8 else T;
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var value: U = @intCast(int);
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comptime var i = 0;
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inline while (i < (l - 1)) : (i += 1) {
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const byte = @as(u8, @truncate(value)) | 0b1000_0000;
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value >>= 7;
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ptr[i] = byte;
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}
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ptr[i] = @truncate(value);
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}
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test writeUnsignedFixed {
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{
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var buf: [4]u8 = undefined;
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writeUnsignedFixed(4, &buf, 0);
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try testing.expect((try test_read_uleb128(u64, &buf)) == 0);
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}
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{
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var buf: [4]u8 = undefined;
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writeUnsignedFixed(4, &buf, 1);
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try testing.expect((try test_read_uleb128(u64, &buf)) == 1);
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}
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{
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var buf: [4]u8 = undefined;
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writeUnsignedFixed(4, &buf, 1000);
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try testing.expect((try test_read_uleb128(u64, &buf)) == 1000);
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}
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{
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var buf: [4]u8 = undefined;
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writeUnsignedFixed(4, &buf, 10000000);
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try testing.expect((try test_read_uleb128(u64, &buf)) == 10000000);
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}
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}
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/// This is an "advanced" function. It allows one to use a fixed amount of memory to store an
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/// ILEB128. This defeats the entire purpose of using this data encoding; it will no longer use
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/// fewer bytes to store smaller numbers. The advantage of using a fixed width is that it makes
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/// fields have a predictable size and so depending on the use case this tradeoff can be worthwhile.
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/// An example use case of this is in emitting DWARF info where one wants to make a ILEB128 field
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/// "relocatable", meaning that it becomes possible to later go back and patch the number to be a
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/// different value without shifting all the following code.
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pub fn writeSignedFixed(comptime l: usize, ptr: *[l]u8, int: std.meta.Int(.signed, l * 7)) void {
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const T = @TypeOf(int);
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const U = if (@typeInfo(T).Int.bits < 8) u8 else T;
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var value: U = @intCast(int);
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comptime var i = 0;
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inline while (i < (l - 1)) : (i += 1) {
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const byte: u8 = @bitCast(@as(i8, @truncate(value)) | -0b1000_0000);
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value >>= 7;
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ptr[i] = byte;
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}
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ptr[i] = @as(u7, @bitCast(@as(i7, @truncate(value))));
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}
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test writeSignedFixed {
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{
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var buf: [4]u8 = undefined;
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writeSignedFixed(4, &buf, 0);
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try testing.expect((try test_read_ileb128(i64, &buf)) == 0);
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}
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{
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var buf: [4]u8 = undefined;
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writeSignedFixed(4, &buf, 1);
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try testing.expect((try test_read_ileb128(i64, &buf)) == 1);
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}
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{
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var buf: [4]u8 = undefined;
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writeSignedFixed(4, &buf, -1);
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try testing.expect((try test_read_ileb128(i64, &buf)) == -1);
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}
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{
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var buf: [4]u8 = undefined;
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writeSignedFixed(4, &buf, 1000);
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try testing.expect((try test_read_ileb128(i64, &buf)) == 1000);
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}
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{
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var buf: [4]u8 = undefined;
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writeSignedFixed(4, &buf, -1000);
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try testing.expect((try test_read_ileb128(i64, &buf)) == -1000);
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}
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{
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var buf: [4]u8 = undefined;
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writeSignedFixed(4, &buf, -10000000);
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try testing.expect((try test_read_ileb128(i64, &buf)) == -10000000);
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}
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{
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var buf: [4]u8 = undefined;
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writeSignedFixed(4, &buf, 10000000);
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try testing.expect((try test_read_ileb128(i64, &buf)) == 10000000);
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}
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}
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// tests
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fn test_read_stream_ileb128(comptime T: type, encoded: []const u8) !T {
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var reader = std.io.fixedBufferStream(encoded);
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return try readILEB128(T, reader.reader());
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}
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fn test_read_stream_uleb128(comptime T: type, encoded: []const u8) !T {
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var reader = std.io.fixedBufferStream(encoded);
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return try readULEB128(T, reader.reader());
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}
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fn test_read_ileb128(comptime T: type, encoded: []const u8) !T {
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var reader = std.io.fixedBufferStream(encoded);
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const v1 = try readILEB128(T, reader.reader());
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return v1;
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}
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fn test_read_uleb128(comptime T: type, encoded: []const u8) !T {
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var reader = std.io.fixedBufferStream(encoded);
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const v1 = try readULEB128(T, reader.reader());
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return v1;
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}
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fn test_read_ileb128_seq(comptime T: type, comptime N: usize, encoded: []const u8) !void {
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var reader = std.io.fixedBufferStream(encoded);
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var i: usize = 0;
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while (i < N) : (i += 1) {
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_ = try readILEB128(T, reader.reader());
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}
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}
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fn test_read_uleb128_seq(comptime T: type, comptime N: usize, encoded: []const u8) !void {
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var reader = std.io.fixedBufferStream(encoded);
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var i: usize = 0;
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while (i < N) : (i += 1) {
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_ = try readULEB128(T, reader.reader());
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}
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}
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test "deserialize signed LEB128" {
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// Truncated
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try testing.expectError(error.EndOfStream, test_read_stream_ileb128(i64, "\x80"));
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// Overflow
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try testing.expectError(error.Overflow, test_read_ileb128(i8, "\x80\x80\x40"));
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try testing.expectError(error.Overflow, test_read_ileb128(i16, "\x80\x80\x80\x40"));
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try testing.expectError(error.Overflow, test_read_ileb128(i32, "\x80\x80\x80\x80\x40"));
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try testing.expectError(error.Overflow, test_read_ileb128(i64, "\x80\x80\x80\x80\x80\x80\x80\x80\x80\x40"));
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try testing.expectError(error.Overflow, test_read_ileb128(i8, "\xff\x7e"));
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try testing.expectError(error.Overflow, test_read_ileb128(i32, "\x80\x80\x80\x80\x08"));
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try testing.expectError(error.Overflow, test_read_ileb128(i64, "\x80\x80\x80\x80\x80\x80\x80\x80\x80\x01"));
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// Decode SLEB128
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try testing.expect((try test_read_ileb128(i64, "\x00")) == 0);
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try testing.expect((try test_read_ileb128(i64, "\x01")) == 1);
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try testing.expect((try test_read_ileb128(i64, "\x3f")) == 63);
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try testing.expect((try test_read_ileb128(i64, "\x40")) == -64);
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try testing.expect((try test_read_ileb128(i64, "\x41")) == -63);
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try testing.expect((try test_read_ileb128(i64, "\x7f")) == -1);
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try testing.expect((try test_read_ileb128(i64, "\x80\x01")) == 128);
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try testing.expect((try test_read_ileb128(i64, "\x81\x01")) == 129);
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try testing.expect((try test_read_ileb128(i64, "\xff\x7e")) == -129);
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try testing.expect((try test_read_ileb128(i64, "\x80\x7f")) == -128);
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try testing.expect((try test_read_ileb128(i64, "\x81\x7f")) == -127);
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try testing.expect((try test_read_ileb128(i64, "\xc0\x00")) == 64);
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try testing.expect((try test_read_ileb128(i64, "\xc7\x9f\x7f")) == -12345);
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try testing.expect((try test_read_ileb128(i8, "\xff\x7f")) == -1);
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try testing.expect((try test_read_ileb128(i16, "\xff\xff\x7f")) == -1);
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try testing.expect((try test_read_ileb128(i32, "\xff\xff\xff\xff\x7f")) == -1);
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try testing.expect((try test_read_ileb128(i32, "\x80\x80\x80\x80\x78")) == -0x80000000);
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try testing.expect((try test_read_ileb128(i64, "\x80\x80\x80\x80\x80\x80\x80\x80\x80\x7f")) == @as(i64, @bitCast(@as(u64, @intCast(0x8000000000000000)))));
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try testing.expect((try test_read_ileb128(i64, "\x80\x80\x80\x80\x80\x80\x80\x80\x40")) == -0x4000000000000000);
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try testing.expect((try test_read_ileb128(i64, "\x80\x80\x80\x80\x80\x80\x80\x80\x80\x7f")) == -0x8000000000000000);
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// Decode unnormalized SLEB128 with extra padding bytes.
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try testing.expect((try test_read_ileb128(i64, "\x80\x00")) == 0);
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try testing.expect((try test_read_ileb128(i64, "\x80\x80\x00")) == 0);
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try testing.expect((try test_read_ileb128(i64, "\xff\x00")) == 0x7f);
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try testing.expect((try test_read_ileb128(i64, "\xff\x80\x00")) == 0x7f);
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try testing.expect((try test_read_ileb128(i64, "\x80\x81\x00")) == 0x80);
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try testing.expect((try test_read_ileb128(i64, "\x80\x81\x80\x00")) == 0x80);
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// Decode sequence of SLEB128 values
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try test_read_ileb128_seq(i64, 4, "\x81\x01\x3f\x80\x7f\x80\x80\x80\x00");
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}
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test "deserialize unsigned LEB128" {
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// Truncated
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try testing.expectError(error.EndOfStream, test_read_stream_uleb128(u64, "\x80"));
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// Overflow
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try testing.expectError(error.Overflow, test_read_uleb128(u8, "\x80\x02"));
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try testing.expectError(error.Overflow, test_read_uleb128(u8, "\x80\x80\x40"));
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try testing.expectError(error.Overflow, test_read_uleb128(u16, "\x80\x80\x84"));
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try testing.expectError(error.Overflow, test_read_uleb128(u16, "\x80\x80\x80\x40"));
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try testing.expectError(error.Overflow, test_read_uleb128(u32, "\x80\x80\x80\x80\x90"));
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try testing.expectError(error.Overflow, test_read_uleb128(u32, "\x80\x80\x80\x80\x40"));
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try testing.expectError(error.Overflow, test_read_uleb128(u64, "\x80\x80\x80\x80\x80\x80\x80\x80\x80\x40"));
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// Decode ULEB128
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try testing.expect((try test_read_uleb128(u64, "\x00")) == 0);
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try testing.expect((try test_read_uleb128(u64, "\x01")) == 1);
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try testing.expect((try test_read_uleb128(u64, "\x3f")) == 63);
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try testing.expect((try test_read_uleb128(u64, "\x40")) == 64);
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try testing.expect((try test_read_uleb128(u64, "\x7f")) == 0x7f);
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try testing.expect((try test_read_uleb128(u64, "\x80\x01")) == 0x80);
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try testing.expect((try test_read_uleb128(u64, "\x81\x01")) == 0x81);
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try testing.expect((try test_read_uleb128(u64, "\x90\x01")) == 0x90);
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try testing.expect((try test_read_uleb128(u64, "\xff\x01")) == 0xff);
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try testing.expect((try test_read_uleb128(u64, "\x80\x02")) == 0x100);
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try testing.expect((try test_read_uleb128(u64, "\x81\x02")) == 0x101);
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try testing.expect((try test_read_uleb128(u64, "\x80\xc1\x80\x80\x10")) == 4294975616);
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try testing.expect((try test_read_uleb128(u64, "\x80\x80\x80\x80\x80\x80\x80\x80\x80\x01")) == 0x8000000000000000);
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// Decode ULEB128 with extra padding bytes
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try testing.expect((try test_read_uleb128(u64, "\x80\x00")) == 0);
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try testing.expect((try test_read_uleb128(u64, "\x80\x80\x00")) == 0);
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try testing.expect((try test_read_uleb128(u64, "\xff\x00")) == 0x7f);
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try testing.expect((try test_read_uleb128(u64, "\xff\x80\x00")) == 0x7f);
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try testing.expect((try test_read_uleb128(u64, "\x80\x81\x00")) == 0x80);
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try testing.expect((try test_read_uleb128(u64, "\x80\x81\x80\x00")) == 0x80);
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// Decode sequence of ULEB128 values
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try test_read_uleb128_seq(u64, 4, "\x81\x01\x3f\x80\x7f\x80\x80\x80\x00");
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}
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fn test_write_leb128(value: anytype) !void {
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const T = @TypeOf(value);
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const signedness = @typeInfo(T).Int.signedness;
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const t_signed = signedness == .signed;
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const writeStream = if (t_signed) writeILEB128 else writeULEB128;
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const readStream = if (t_signed) readILEB128 else readULEB128;
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// decode to a larger bit size too, to ensure sign extension
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// is working as expected
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const larger_type_bits = ((@typeInfo(T).Int.bits + 8) / 8) * 8;
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const B = std.meta.Int(signedness, larger_type_bits);
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const bytes_needed = bn: {
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if (@typeInfo(T).Int.bits <= 7) break :bn @as(u16, 1);
|
|
|
|
const unused_bits = if (value < 0) @clz(~value) else @clz(value);
|
|
const used_bits: u16 = (@typeInfo(T).Int.bits - unused_bits) + @intFromBool(t_signed);
|
|
if (used_bits <= 7) break :bn @as(u16, 1);
|
|
break :bn ((used_bits + 6) / 7);
|
|
};
|
|
|
|
const max_groups = if (@typeInfo(T).Int.bits == 0) 1 else (@typeInfo(T).Int.bits + 6) / 7;
|
|
|
|
var buf: [max_groups]u8 = undefined;
|
|
var fbs = std.io.fixedBufferStream(&buf);
|
|
|
|
// stream write
|
|
try writeStream(fbs.writer(), value);
|
|
const w1_pos = fbs.pos;
|
|
try testing.expect(w1_pos == bytes_needed);
|
|
|
|
// stream read
|
|
fbs.pos = 0;
|
|
const sr = try readStream(T, fbs.reader());
|
|
try testing.expect(fbs.pos == w1_pos);
|
|
try testing.expect(sr == value);
|
|
|
|
// bigger type stream read
|
|
fbs.pos = 0;
|
|
const bsr = try readStream(B, fbs.reader());
|
|
try testing.expect(fbs.pos == w1_pos);
|
|
try testing.expect(bsr == value);
|
|
}
|
|
|
|
test "serialize unsigned LEB128" {
|
|
const max_bits = 18;
|
|
|
|
comptime var t = 0;
|
|
inline while (t <= max_bits) : (t += 1) {
|
|
const T = std.meta.Int(.unsigned, t);
|
|
const min = std.math.minInt(T);
|
|
const max = std.math.maxInt(T);
|
|
var i = @as(std.meta.Int(.unsigned, @typeInfo(T).Int.bits + 1), min);
|
|
|
|
while (i <= max) : (i += 1) try test_write_leb128(@as(T, @intCast(i)));
|
|
}
|
|
}
|
|
|
|
test "serialize signed LEB128" {
|
|
// explicitly test i0 because starting `t` at 0
|
|
// will break the while loop
|
|
try test_write_leb128(@as(i0, 0));
|
|
|
|
const max_bits = 18;
|
|
|
|
comptime var t = 1;
|
|
inline while (t <= max_bits) : (t += 1) {
|
|
const T = std.meta.Int(.signed, t);
|
|
const min = std.math.minInt(T);
|
|
const max = std.math.maxInt(T);
|
|
var i = @as(std.meta.Int(.signed, @typeInfo(T).Int.bits + 1), min);
|
|
|
|
while (i <= max) : (i += 1) try test_write_leb128(@as(T, @intCast(i)));
|
|
}
|
|
}
|