#pragma once
-#include "../irrlichttypes_bloated.h"
-#include "../exceptions.h" // for SerializationError
-#include "../debug.h" // for assert
+#include "irrlichttypes_bloated.h"
+#include "exceptions.h" // for SerializationError
+#include "debug.h" // for assert
+#include "ieee_float.h"
#include "config.h"
#if HAVE_ENDIAN_H
#define __BIG_ENDIAN 1
#elif defined(__MACH__) && defined(__APPLE__)
#include <machine/endian.h>
- #elif defined(__FreeBSD__)
+ #elif defined(__FreeBSD__) || defined(__DragonFly__)
#include <sys/endian.h>
#else
#include <endian.h>
// not represent the full range, but rather the largest safe range, of values on
// all supported architectures. Note: This definition makes assumptions on
// platform float-to-int conversion behavior.
-#define F1000_MIN ((float)(s32)((-0x7FFFFFFF - 1) / FIXEDPOINT_FACTOR))
-#define F1000_MAX ((float)(s32)((0x7FFFFFFF) / FIXEDPOINT_FACTOR))
+#define F1000_MIN ((float)(s32)((float)(-0x7FFFFFFF - 1) / FIXEDPOINT_FACTOR))
+#define F1000_MAX ((float)(s32)((float)(0x7FFFFFFF) / FIXEDPOINT_FACTOR))
#define STRING_MAX_LEN 0xFFFF
#define WIDE_STRING_MAX_LEN 0xFFFF
#define LONG_STRING_MAX_LEN (64 * 1024 * 1024)
+extern FloatType g_serialize_f32_type;
+
#if HAVE_ENDIAN_H
// use machine native byte swapping routines
// Note: memcpy below is optimized out by modern compilers
return (f32)readS32(data) / FIXEDPOINT_FACTOR;
}
+inline f32 readF32(const u8 *data)
+{
+ u32 u = readU32(data);
+
+ switch (g_serialize_f32_type) {
+ case FLOATTYPE_SYSTEM: {
+ f32 f;
+ memcpy(&f, &u, 4);
+ return f;
+ }
+ case FLOATTYPE_SLOW:
+ return u32Tof32Slow(u);
+ case FLOATTYPE_UNKNOWN: // First initialization
+ g_serialize_f32_type = getFloatSerializationType();
+ return readF32(data);
+ }
+ throw SerializationError("readF32: Unreachable code");
+}
+
inline video::SColor readARGB8(const u8 *data)
{
video::SColor p(readU32(data));
return p;
}
-inline v2f readV2F1000(const u8 *data)
+inline v3f readV3F1000(const u8 *data)
+{
+ v3f p;
+ p.X = readF1000(&data[0]);
+ p.Y = readF1000(&data[4]);
+ p.Z = readF1000(&data[8]);
+ return p;
+}
+
+inline v2f readV2F32(const u8 *data)
{
v2f p;
- p.X = (float)readF1000(&data[0]);
- p.Y = (float)readF1000(&data[4]);
+ p.X = readF32(&data[0]);
+ p.Y = readF32(&data[4]);
return p;
}
-inline v3f readV3F1000(const u8 *data)
+inline v3f readV3F32(const u8 *data)
{
v3f p;
- p.X = (float)readF1000(&data[0]);
- p.Y = (float)readF1000(&data[4]);
- p.Z = (float)readF1000(&data[8]);
+ p.X = readF32(&data[0]);
+ p.Y = readF32(&data[4]);
+ p.Z = readF32(&data[8]);
return p;
}
inline void writeS16(u8 *data, s16 i)
{
- writeU16(data, (u16)i);
+ writeU16(data, (u16)i);
}
inline void writeS32(u8 *data, s32 i)
writeS32(data, i * FIXEDPOINT_FACTOR);
}
+inline void writeF32(u8 *data, f32 i)
+{
+ switch (g_serialize_f32_type) {
+ case FLOATTYPE_SYSTEM: {
+ u32 u;
+ memcpy(&u, &i, 4);
+ return writeU32(data, u);
+ }
+ case FLOATTYPE_SLOW:
+ return writeU32(data, f32Tou32Slow(i));
+ case FLOATTYPE_UNKNOWN: // First initialization
+ g_serialize_f32_type = getFloatSerializationType();
+ return writeF32(data, i);
+ }
+ throw SerializationError("writeF32: Unreachable code");
+}
+
inline void writeARGB8(u8 *data, video::SColor p)
{
writeU32(data, p.color);
writeS32(&data[8], p.Z);
}
-inline void writeV2F1000(u8 *data, v2f p)
+inline void writeV3F1000(u8 *data, v3f p)
{
writeF1000(&data[0], p.X);
writeF1000(&data[4], p.Y);
+ writeF1000(&data[8], p.Z);
}
-inline void writeV3F1000(u8 *data, v3f p)
+inline void writeV2F32(u8 *data, v2f p)
{
- writeF1000(&data[0], p.X);
- writeF1000(&data[4], p.Y);
- writeF1000(&data[8], p.Z);
+ writeF32(&data[0], p.X);
+ writeF32(&data[4], p.Y);
+}
+
+inline void writeV3F32(u8 *data, v3f p)
+{
+ writeF32(&data[0], p.X);
+ writeF32(&data[4], p.Y);
+ writeF32(&data[8], p.Z);
}
////
MAKE_STREAM_READ_FXN(s32, S32, 4);
MAKE_STREAM_READ_FXN(s64, S64, 8);
MAKE_STREAM_READ_FXN(f32, F1000, 4);
+MAKE_STREAM_READ_FXN(f32, F32, 4);
MAKE_STREAM_READ_FXN(v2s16, V2S16, 4);
MAKE_STREAM_READ_FXN(v3s16, V3S16, 6);
MAKE_STREAM_READ_FXN(v2s32, V2S32, 8);
MAKE_STREAM_READ_FXN(v3s32, V3S32, 12);
-MAKE_STREAM_READ_FXN(v2f, V2F1000, 8);
MAKE_STREAM_READ_FXN(v3f, V3F1000, 12);
+MAKE_STREAM_READ_FXN(v2f, V2F32, 8);
+MAKE_STREAM_READ_FXN(v3f, V3F32, 12);
MAKE_STREAM_READ_FXN(video::SColor, ARGB8, 4);
MAKE_STREAM_WRITE_FXN(u8, U8, 1);
MAKE_STREAM_WRITE_FXN(s32, S32, 4);
MAKE_STREAM_WRITE_FXN(s64, S64, 8);
MAKE_STREAM_WRITE_FXN(f32, F1000, 4);
+MAKE_STREAM_WRITE_FXN(f32, F32, 4);
MAKE_STREAM_WRITE_FXN(v2s16, V2S16, 4);
MAKE_STREAM_WRITE_FXN(v3s16, V3S16, 6);
MAKE_STREAM_WRITE_FXN(v2s32, V2S32, 8);
MAKE_STREAM_WRITE_FXN(v3s32, V3S32, 12);
-MAKE_STREAM_WRITE_FXN(v2f, V2F1000, 8);
MAKE_STREAM_WRITE_FXN(v3f, V3F1000, 12);
+MAKE_STREAM_WRITE_FXN(v2f, V2F32, 8);
+MAKE_STREAM_WRITE_FXN(v3f, V3F32, 12);
MAKE_STREAM_WRITE_FXN(video::SColor, ARGB8, 4);
////
////
// Creates a string with the length as the first two bytes
-std::string serializeString(const std::string &plain);
-
-// Creates a string with the length as the first two bytes from wide string
-std::string serializeWideString(const std::wstring &plain);
+std::string serializeString16(const std::string &plain);
// Reads a string with the length as the first two bytes
-std::string deSerializeString(std::istream &is);
-
-// Reads a wide string with the length as the first two bytes
-std::wstring deSerializeWideString(std::istream &is);
+std::string deSerializeString16(std::istream &is);
// Creates a string with the length as the first four bytes
-std::string serializeLongString(const std::string &plain);
+std::string serializeString32(const std::string &plain);
// Reads a string with the length as the first four bytes
-std::string deSerializeLongString(std::istream &is);
+std::string deSerializeString32(std::istream &is);
// Creates a string encoded in JSON format (almost equivalent to a C string literal)
std::string serializeJsonString(const std::string &plain);
// Parses a string serialized by serializeJsonStringIfNeeded.
std::string deSerializeJsonStringIfNeeded(std::istream &is);
-
-// Creates a string consisting of the hexadecimal representation of `data`
-std::string serializeHexString(const std::string &data, bool insert_spaces=false);
-
-// Creates a string containing comma delimited values of a struct whose layout is
-// described by the parameter format
-bool serializeStructToString(std::string *out,
- std::string format, void *value);
-
-// Reads a comma delimited string of values into a struct whose layout is
-// decribed by the parameter format
-bool deSerializeStringToStruct(std::string valstr,
- std::string format, void *out, size_t olen);
-
-////
-//// BufReader
-////
-
-#define MAKE_BUFREADER_GETNOEX_FXN(T, N, S) \
- inline bool get ## N ## NoEx(T *val) \
- { \
- if (pos + S > size) \
- return false; \
- *val = read ## N(data + pos); \
- pos += S; \
- return true; \
- }
-
-#define MAKE_BUFREADER_GET_FXN(T, N) \
- inline T get ## N() \
- { \
- T val; \
- if (!get ## N ## NoEx(&val)) \
- throw SerializationError("Attempted read past end of data"); \
- return val; \
- }
-
-class BufReader {
-public:
- BufReader(const u8 *data_, size_t size_) :
- data(data_),
- size(size_)
- {
- }
-
- MAKE_BUFREADER_GETNOEX_FXN(u8, U8, 1);
- MAKE_BUFREADER_GETNOEX_FXN(u16, U16, 2);
- MAKE_BUFREADER_GETNOEX_FXN(u32, U32, 4);
- MAKE_BUFREADER_GETNOEX_FXN(u64, U64, 8);
- MAKE_BUFREADER_GETNOEX_FXN(s8, S8, 1);
- MAKE_BUFREADER_GETNOEX_FXN(s16, S16, 2);
- MAKE_BUFREADER_GETNOEX_FXN(s32, S32, 4);
- MAKE_BUFREADER_GETNOEX_FXN(s64, S64, 8);
- MAKE_BUFREADER_GETNOEX_FXN(f32, F1000, 4);
- MAKE_BUFREADER_GETNOEX_FXN(v2s16, V2S16, 4);
- MAKE_BUFREADER_GETNOEX_FXN(v3s16, V3S16, 6);
- MAKE_BUFREADER_GETNOEX_FXN(v2s32, V2S32, 8);
- MAKE_BUFREADER_GETNOEX_FXN(v3s32, V3S32, 12);
- MAKE_BUFREADER_GETNOEX_FXN(v2f, V2F1000, 8);
- MAKE_BUFREADER_GETNOEX_FXN(v3f, V3F1000, 12);
- MAKE_BUFREADER_GETNOEX_FXN(video::SColor, ARGB8, 4);
-
- bool getStringNoEx(std::string *val);
- bool getWideStringNoEx(std::wstring *val);
- bool getLongStringNoEx(std::string *val);
- bool getRawDataNoEx(void *data, size_t len);
-
- MAKE_BUFREADER_GET_FXN(u8, U8);
- MAKE_BUFREADER_GET_FXN(u16, U16);
- MAKE_BUFREADER_GET_FXN(u32, U32);
- MAKE_BUFREADER_GET_FXN(u64, U64);
- MAKE_BUFREADER_GET_FXN(s8, S8);
- MAKE_BUFREADER_GET_FXN(s16, S16);
- MAKE_BUFREADER_GET_FXN(s32, S32);
- MAKE_BUFREADER_GET_FXN(s64, S64);
- MAKE_BUFREADER_GET_FXN(f32, F1000);
- MAKE_BUFREADER_GET_FXN(v2s16, V2S16);
- MAKE_BUFREADER_GET_FXN(v3s16, V3S16);
- MAKE_BUFREADER_GET_FXN(v2s32, V2S32);
- MAKE_BUFREADER_GET_FXN(v3s32, V3S32);
- MAKE_BUFREADER_GET_FXN(v2f, V2F1000);
- MAKE_BUFREADER_GET_FXN(v3f, V3F1000);
- MAKE_BUFREADER_GET_FXN(video::SColor, ARGB8);
- MAKE_BUFREADER_GET_FXN(std::string, String);
- MAKE_BUFREADER_GET_FXN(std::wstring, WideString);
- MAKE_BUFREADER_GET_FXN(std::string, LongString);
-
- inline void getRawData(void *val, size_t len)
- {
- if (!getRawDataNoEx(val, len))
- throw SerializationError("Attempted read past end of data");
- }
-
- inline size_t remaining()
- {
- assert(pos <= size);
- return size - pos;
- }
-
- const u8 *data;
- size_t size;
- size_t pos = 0;
-};
-
-#undef MAKE_BUFREADER_GET_FXN
-#undef MAKE_BUFREADER_GETNOEX_FXN
-
-
-////
-//// Vector-based write routines
-////
-
-inline void putU8(std::vector<u8> *dest, u8 val)
-{
- dest->push_back((val >> 0) & 0xFF);
-}
-
-inline void putU16(std::vector<u8> *dest, u16 val)
-{
- dest->push_back((val >> 8) & 0xFF);
- dest->push_back((val >> 0) & 0xFF);
-}
-
-inline void putU32(std::vector<u8> *dest, u32 val)
-{
- dest->push_back((val >> 24) & 0xFF);
- dest->push_back((val >> 16) & 0xFF);
- dest->push_back((val >> 8) & 0xFF);
- dest->push_back((val >> 0) & 0xFF);
-}
-
-inline void putU64(std::vector<u8> *dest, u64 val)
-{
- dest->push_back((val >> 56) & 0xFF);
- dest->push_back((val >> 48) & 0xFF);
- dest->push_back((val >> 40) & 0xFF);
- dest->push_back((val >> 32) & 0xFF);
- dest->push_back((val >> 24) & 0xFF);
- dest->push_back((val >> 16) & 0xFF);
- dest->push_back((val >> 8) & 0xFF);
- dest->push_back((val >> 0) & 0xFF);
-}
-
-inline void putS8(std::vector<u8> *dest, s8 val)
-{
- putU8(dest, val);
-}
-
-inline void putS16(std::vector<u8> *dest, s16 val)
-{
- putU16(dest, val);
-}
-
-inline void putS32(std::vector<u8> *dest, s32 val)
-{
- putU32(dest, val);
-}
-
-inline void putS64(std::vector<u8> *dest, s64 val)
-{
- putU64(dest, val);
-}
-
-inline void putF1000(std::vector<u8> *dest, f32 val)
-{
- putS32(dest, val * FIXEDPOINT_FACTOR);
-}
-
-inline void putV2S16(std::vector<u8> *dest, v2s16 val)
-{
- putS16(dest, val.X);
- putS16(dest, val.Y);
-}
-
-inline void putV3S16(std::vector<u8> *dest, v3s16 val)
-{
- putS16(dest, val.X);
- putS16(dest, val.Y);
- putS16(dest, val.Z);
-}
-
-inline void putV2S32(std::vector<u8> *dest, v2s32 val)
-{
- putS32(dest, val.X);
- putS32(dest, val.Y);
-}
-
-inline void putV3S32(std::vector<u8> *dest, v3s32 val)
-{
- putS32(dest, val.X);
- putS32(dest, val.Y);
- putS32(dest, val.Z);
-}
-
-inline void putV2F1000(std::vector<u8> *dest, v2f val)
-{
- putF1000(dest, val.X);
- putF1000(dest, val.Y);
-}
-
-inline void putV3F1000(std::vector<u8> *dest, v3f val)
-{
- putF1000(dest, val.X);
- putF1000(dest, val.Y);
- putF1000(dest, val.Z);
-}
-
-inline void putARGB8(std::vector<u8> *dest, video::SColor val)
-{
- putU32(dest, val.color);
-}
-
-inline void putString(std::vector<u8> *dest, const std::string &val)
-{
- if (val.size() > STRING_MAX_LEN)
- throw SerializationError("String too long");
-
- putU16(dest, val.size());
- dest->insert(dest->end(), val.begin(), val.end());
-}
-
-inline void putWideString(std::vector<u8> *dest, const std::wstring &val)
-{
- if (val.size() > WIDE_STRING_MAX_LEN)
- throw SerializationError("String too long");
-
- putU16(dest, val.size());
- for (size_t i = 0; i != val.size(); i++)
- putU16(dest, val[i]);
-}
-
-inline void putLongString(std::vector<u8> *dest, const std::string &val)
-{
- if (val.size() > LONG_STRING_MAX_LEN)
- throw SerializationError("String too long");
-
- putU32(dest, val.size());
- dest->insert(dest->end(), val.begin(), val.end());
-}
-
-inline void putRawData(std::vector<u8> *dest, const void *src, size_t len)
-{
- dest->insert(dest->end(), (u8 *)src, (u8 *)src + len);
-}