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533 lines
23 KiB
533 lines
23 KiB
/*==LICENSE==* |
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CyanWorlds.com Engine - MMOG client, server and tools |
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Copyright (C) 2011 Cyan Worlds, Inc. |
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This program is free software: you can redistribute it and/or modify |
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it under the terms of the GNU General Public License as published by |
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the Free Software Foundation, either version 3 of the License, or |
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(at your option) any later version. |
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This program is distributed in the hope that it will be useful, |
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but WITHOUT ANY WARRANTY; without even the implied warranty of |
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the |
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GNU General Public License for more details. |
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You should have received a copy of the GNU General Public License |
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along with this program. If not, see <http://www.gnu.org/licenses/>. |
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Additional permissions under GNU GPL version 3 section 7 |
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If you modify this Program, or any covered work, by linking or |
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combining it with any of RAD Game Tools Bink SDK, Autodesk 3ds Max SDK, |
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NVIDIA PhysX SDK, Microsoft DirectX SDK, OpenSSL library, Independent |
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JPEG Group JPEG library, Microsoft Windows Media SDK, or Apple QuickTime SDK |
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(or a modified version of those libraries), |
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containing parts covered by the terms of the Bink SDK EULA, 3ds Max EULA, |
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PhysX SDK EULA, DirectX SDK EULA, OpenSSL and SSLeay licenses, IJG |
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JPEG Library README, Windows Media SDK EULA, or QuickTime SDK EULA, the |
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licensors of this Program grant you additional |
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permission to convey the resulting work. Corresponding Source for a |
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non-source form of such a combination shall include the source code for |
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the parts of OpenSSL and IJG JPEG Library used as well as that of the covered |
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work. |
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You can contact Cyan Worlds, Inc. by email legal@cyan.com |
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or by snail mail at: |
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Cyan Worlds, Inc. |
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14617 N Newport Hwy |
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Mead, WA 99021 |
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*==LICENSE==*/ |
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#ifndef hsStream_Defined |
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#define hsStream_Defined |
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#include <stdarg.h> // Included for GCC 3.2.2+ |
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#include "HeadSpin.h" |
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#include "hsMemory.h" |
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#include "plString.h" |
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// Define this for use of Streams with Logging (commonly used w/ a packet sniffer) |
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// These streams log their reads to an event list |
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//#define STREAM_LOGGER |
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#ifndef STREAM_LOGGER |
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#define hsReadOnlyLoggingStream hsReadOnlyStream |
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#define LogRead(byteCount, buffer, desc) Read(byteCount, buffer) |
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#define LogReadSafeString() ReadSafeString() |
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#define LogReadSafeString_TEMP() ReadSafeString_TEMP() |
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#define LogReadSafeStringLong() ReadSafeStringLong(); |
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#define LogSkip(deltaByteCount, desc) Skip(deltaByteCount) |
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#define LogReadLE(value, desc) ReadLE(value) |
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#define LogReadLEArray(count, values, desc) ReadLE(count, values) |
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#define LogSubStreamStart(desc) LogVoidFunc() |
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#define LogSubStreamPushDesc(desc) LogVoidFunc() |
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#define LogSubStreamEnd() LogVoidFunc() |
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#define LogStringString(s) LogVoidFunc() |
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#endif |
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class hsStream { |
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public: |
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enum { |
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kEolnCode = '\n', |
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kComment = '#' |
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}; |
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protected: |
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uint32_t fBytesRead; |
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uint32_t fPosition; |
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bool IsTokenSeparator(char c); |
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public: |
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hsStream() : fBytesRead(0), fPosition(0) {} |
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virtual ~hsStream(); |
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virtual bool Open(const char *, const char * = "rb")=0; |
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virtual bool Open(const wchar_t *, const wchar_t * = L"rb")=0; |
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virtual bool Close()=0; |
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virtual bool AtEnd(); |
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virtual uint32_t Read(uint32_t byteCount, void * buffer) = 0; |
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virtual uint32_t Write(uint32_t byteCount, const void* buffer) = 0; |
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virtual void Skip(uint32_t deltaByteCount) = 0; |
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virtual void Rewind() = 0; |
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virtual void FastFwd(); |
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virtual uint32_t GetPosition() const; |
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virtual void SetPosition(uint32_t position); |
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virtual void Truncate(); |
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virtual void Flush() {} |
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#ifdef STREAM_LOGGER |
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// Logging Reads & Skips |
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virtual uint32_t LogRead(uint32_t byteCount, void * buffer, const char* desc) { return Read(byteCount,buffer); } |
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virtual char* LogReadSafeString() { return ReadSafeString(); } |
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virtual char* LogReadSafeStringLong() { return ReadSafeStringLong(); } |
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virtual void LogSkip(uint32_t deltaByteCount, const char* desc) { Skip(deltaByteCount); } |
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|
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// Stream Notes for Logging |
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virtual void LogStringString(const char* s) { } |
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virtual void LogSubStreamStart(const char* desc) { } |
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virtual void LogSubStreamEnd() { } |
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virtual void LogSubStreamPushDesc(const char* desc) { } |
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#endif |
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void LogVoidFunc() { } |
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// Optimization for small Reads |
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virtual uint8_t ReadByte(); |
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virtual bool Read4Bytes(void *buffer); // Reads 4 bytes, return true if success |
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virtual bool Read8Bytes(void *buffer); // Reads 8 bytes, return true if success |
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virtual bool Read12Bytes(void *buffer); // Reads 12 bytes, return true if success |
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virtual uint32_t GetEOF(); |
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uint32_t GetSizeLeft(); |
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virtual void CopyToMem(void* mem); |
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virtual bool IsCompressed() { return false; } |
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uint32_t WriteString(const char cstring[]); |
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uint32_t WriteString(const plString & string) { return WriteString(string.c_str()); } |
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uint32_t WriteFmt(const char * fmt, ...); |
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uint32_t WriteFmtV(const char * fmt, va_list av); |
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uint32_t WriteSafeStringLong(const plString &string); // uses 4 bytes for length |
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uint32_t WriteSafeWStringLong(const plString &string); |
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char * ReadSafeStringLong(); |
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wchar_t * ReadSafeWStringLong(); |
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uint32_t WriteSafeString(const plString &string); // uses 2 bytes for length |
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uint32_t WriteSafeWString(const plString &string); |
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char * ReadSafeString(); |
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wchar_t * ReadSafeWString(); |
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plString ReadSafeString_TEMP(); |
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plString ReadSafeWString_TEMP(); |
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bool GetToken(char *s, uint32_t maxLen=uint32_t(-1), const char beginComment=kComment, const char endComment=kEolnCode); |
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bool ReadLn(char* s, uint32_t maxLen=uint32_t(-1), const char beginComment=kComment, const char endComment=kEolnCode); |
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// Reads a 4-byte BOOLean |
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bool ReadBOOL(); |
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// Reads a 1-byte boolean |
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bool ReadBool(); |
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void ReadBool(int count, bool values[]); |
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uint16_t ReadLE16(); |
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void ReadLE16(int count, uint16_t values[]); |
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uint32_t ReadLE32(); |
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void ReadLE32(int count, uint32_t values[]); |
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uint32_t ReadBE32(); |
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void WriteBOOL(bool value); |
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void WriteBool(bool value); |
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void WriteBool(int count, const bool values[]); |
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void WriteByte(uint8_t value); |
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void WriteLE16(uint16_t value); |
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void WriteLE16(int count, const uint16_t values[]); |
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void WriteLE32(uint32_t value); |
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void WriteLE32(int count, const uint32_t values[]); |
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void WriteBE32(uint32_t value); |
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/* Overloaded Begin (8 & 16 & 32 int)*/ |
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/* yes, swapping an 8 bit value does nothing, just useful*/ |
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void ReadLE(bool* value) { *value = this->ReadByte() ? true : false; } |
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void ReadLE(uint8_t* value) { *value = this->ReadByte(); } |
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void ReadLE(int count, uint8_t values[]) { this->Read(count, values); } |
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void ReadLE(uint16_t* value) { *value = this->ReadLE16(); } |
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void ReadLE(int count, uint16_t values[]) { this->ReadLE16(count, values); } |
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void ReadLE(uint32_t* value) { *value = this->ReadLE32(); } |
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void ReadLE(int count, uint32_t values[]) { this->ReadLE32(count, values); } |
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#ifdef STREAM_LOGGER |
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// Begin LogReadLEs |
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virtual void LogReadLE(bool* value, const char* desc) { this->ReadLE(value); } |
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virtual void LogReadLE(uint8_t* value, const char* desc) { this->ReadLE(value); } |
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virtual void LogReadLEArray(int count, uint8_t values[], const char* desc) { this->ReadLE(count, values); } |
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virtual void LogReadLE(uint16_t* value, const char* desc) { this->ReadLE(value); } |
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virtual void LogReadLEArray(int count, uint16_t values[], const char* desc) { this->ReadLE(count, values); } |
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virtual void LogReadLE(uint32_t* value, const char* desc) { this->ReadLE(value); } |
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virtual void LogReadLEArray(int count, uint32_t values[], const char* desc) { this->ReadLE(count, values); } |
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// End LogReadLEs |
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#endif |
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void WriteLE(bool value) { this->Write(1,&value); } |
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void WriteLE(uint8_t value) { this->Write(1,&value); } |
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void WriteLE(int count, const uint8_t values[]) { this->Write(count, values); } |
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void WriteLE(uint16_t value) { this->WriteLE16(value); } |
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void WriteLE(int count, const uint16_t values[]) { this->WriteLE16(count, values); } |
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void WriteLE(uint32_t value) { this->WriteLE32(value); } |
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void WriteLE(int count, const uint32_t values[]) { this->WriteLE32(count, values); } |
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void ReadLE(int8_t* value) { *value = this->ReadByte(); } |
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void ReadLE(int count, int8_t values[]) { this->Read(count, values); } |
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void ReadLE(char* value) { *value = (char)this->ReadByte(); } |
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void ReadLE(int count, char values[]) { this->Read(count, values); } |
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void ReadLE(int16_t* value) { *value = (int16_t)this->ReadLE16(); } |
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void ReadLE(int count, int16_t values[]) { this->ReadLE16(count, (uint16_t*)values); } |
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void ReadLE(int32_t* value) { *value = (int32_t)this->ReadLE32(); } |
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void ReadLE(int count, int32_t values[]) { this->ReadLE32(count, (uint32_t*)values); } |
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#ifdef STREAM_LOGGER |
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// Begin LogReadLEs |
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virtual void LogReadLE(int8_t* value, const char* desc) { this->ReadLE(value); } |
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virtual void LogReadLEArray(int count, int8_t values[], const char* desc) { this->ReadLE(count, values); } |
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virtual void LogReadLE(char* value, const char* desc) { this->ReadLE(value); } |
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virtual void LogReadLEArray(int count, char values[], const char* desc) { this->ReadLE(count, values); } |
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virtual void LogReadLE(int16_t* value, const char* desc) { this->ReadLE(value); } |
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virtual void LogReadLEArray(int count, int16_t values[], const char* desc) { this->ReadLE(count, (uint16_t*)values); } |
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virtual void LogReadLE(int32_t* value, const char* desc) { this->ReadLE(value); } |
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virtual void LogReadLEArray(int count, int32_t values[], const char* desc) { this->ReadLE(count, (uint32_t*)values); } |
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virtual void LogReadLE(int* value, const char* desc) { this->ReadLE(value); } |
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virtual void LogReadLEArray(int count, int values[], const char* desc) { this->ReadLE(count, (uint32_t*)values); } |
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// End LogReadLEs |
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#endif |
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void WriteLE(int8_t value) { this->Write(1,&value); } |
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void WriteLE(int count, const int8_t values[]) { this->Write(count, values); } |
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void WriteLE(char value) { this->Write(1,(uint8_t*)&value); } |
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void WriteLE(int count, const char values[]) { this->Write(count, (uint8_t*)values); } |
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void WriteLE(int16_t value) { this->WriteLE16((uint16_t)value); } |
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void WriteLE(int count, const int16_t values[]) { this->WriteLE16(count, (uint16_t*)values); } |
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void WriteLE(int32_t value) { this->WriteLE32((uint32_t)value); } |
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void WriteLE(int count, const int32_t values[]) { this->WriteLE32(count, (uint32_t*)values); } |
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/* Overloaded End */ |
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float ReadLEFloat(); |
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void ReadLEFloat(int count, float values[]); |
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double ReadLEDouble(); |
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void ReadLEDouble(int count, double values[]); |
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float ReadBEFloat(); |
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void WriteLEFloat(float value); |
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void WriteLEFloat(int count, const float values[]); |
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void WriteLEDouble(double value); |
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void WriteLEDouble(int count, const double values[]); |
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void WriteBEFloat(float value); |
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/* Overloaded Begin (Float)*/ |
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void ReadLE(float* value) { *value = ReadLEFloat(); } |
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void ReadLE(int count, float values[]) { ReadLEFloat(count, values); } |
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void ReadLE(double* value) { *value = ReadLEDouble(); } |
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void ReadLE(int count, double values[]) { ReadLEDouble(count, values); } |
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#ifdef STREAM_LOGGER |
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// Begin LogReadLEs |
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virtual void LogReadLE(float* value, const char* desc) { ReadLE(value); } |
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virtual void LogReadLEArray(int count, float values[], const char* desc) { ReadLE(count, values); } |
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virtual void LogReadLE(double* value, const char* desc) { ReadLE(value); } |
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virtual void LogReadLEArray(int count, double values[], const char* desc) { ReadLE(count, values); } |
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// End LogReadLEs |
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#endif |
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void WriteLE(float value) { WriteLEFloat(value); } |
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void WriteLE(int count, const float values[]) { WriteLEFloat(count, values); } |
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void WriteLE(double value) { WriteLEDouble(value); } |
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void WriteLE(int count, const double values[]) { WriteLEDouble(count, values); } |
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/* Overloaded End */ |
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float ReadLEScalar() { return (float)this->ReadLEFloat(); } |
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void ReadLEScalar(int count, float values[]) |
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{ |
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this->ReadLEFloat(count, (float*)values); |
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} |
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float ReadBEScalar() { return (float)this->ReadBEFloat(); } |
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void WriteLEScalar(float value) { this->WriteLEFloat(value); } |
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void WriteLEScalar(int count, const float values[]) |
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{ |
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this->WriteLEFloat(count, (float*)values); |
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} |
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void WriteBEScalar(float value) { this->WriteBEFloat(value); } |
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void WriteLEAtom(uint32_t tag, uint32_t size); |
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uint32_t ReadLEAtom(uint32_t* size); |
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/* Overloaded Begin (Atom)*/ |
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void WriteLE(uint32_t* tag, uint32_t size) { WriteLEAtom(*tag, size); } |
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void ReadLE(uint32_t* tag, uint32_t *size) { *tag = ReadLEAtom(size); } |
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/* Overloaded End */ |
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}; |
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class hsStreamable { |
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public: |
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virtual void Read(hsStream* stream) = 0; |
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virtual void Write(hsStream* stream) = 0; |
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virtual uint32_t GetStreamSize() = 0; |
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}; |
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class hsFileStream: public hsStream |
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{ |
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uint32_t fRef; |
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public: |
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hsFileStream(); |
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virtual ~hsFileStream(); |
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virtual bool Open(const char *name, const char *mode = "rb"); |
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virtual bool Open(const wchar_t *name, const wchar_t *mode = L"rb"); |
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virtual bool Close(); |
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virtual bool AtEnd(); |
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virtual uint32_t Read(uint32_t byteCount, void* buffer); |
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virtual uint32_t Write(uint32_t byteCount, const void* buffer); |
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virtual void Skip(uint32_t deltaByteCount); |
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virtual void Rewind(); |
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virtual void Truncate(); |
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virtual uint32_t GetFileRef(); |
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virtual void SetFileRef(uint32_t refNum); |
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}; |
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class hsUNIXStream: public hsStream |
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{ |
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FILE* fRef; |
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char* fBuff; |
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public: |
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hsUNIXStream(): fRef(0), fBuff(nil) {} |
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~hsUNIXStream(); |
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virtual bool Open(const char* name, const char* mode = "rb"); |
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virtual bool Open(const wchar_t *name, const wchar_t *mode = L"rb"); |
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virtual bool Close(); |
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virtual bool AtEnd(); |
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virtual uint32_t Read(uint32_t byteCount, void* buffer); |
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virtual uint32_t Write(uint32_t byteCount, const void* buffer); |
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virtual void SetPosition(uint32_t position); |
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virtual void Skip(uint32_t deltaByteCount); |
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virtual void Rewind(); |
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virtual void FastFwd(); |
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virtual void Truncate(); |
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virtual void Flush(); |
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FILE* GetFILE() { return fRef; } |
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void SetFILE(FILE* file) { fRef = file; } |
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virtual uint32_t GetEOF(); |
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}; |
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// Small substream class: give it a base stream, an offset and a length, and it'll |
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// treat all ops as if you had a chunk from the base stream as a separate, vanilla |
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// stream of the given length. |
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class plReadOnlySubStream: public hsStream |
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{ |
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hsStream *fBase; |
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uint32_t fOffset, fLength; |
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void IFixPosition( void ); |
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public: |
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plReadOnlySubStream(): fBase( nil ), fOffset( 0 ), fLength( 0 ) {} |
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~plReadOnlySubStream(); |
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virtual bool Open(const char *, const char *) { hsAssert(0, "plReadOnlySubStream::Open NotImplemented"); return false; } |
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virtual bool Open(const wchar_t *, const wchar_t *) { hsAssert(0, "plReadOnlySubStream::Open NotImplemented"); return false; } |
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void Open( hsStream *base, uint32_t offset, uint32_t length ); |
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virtual bool Close() { fBase = nil; fOffset = 0; fLength = 0; return true; } |
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virtual bool AtEnd(); |
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virtual uint32_t Read(uint32_t byteCount, void* buffer); |
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virtual uint32_t Write(uint32_t byteCount, const void* buffer); |
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virtual void Skip(uint32_t deltaByteCount); |
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virtual void Rewind(); |
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virtual void FastFwd(); |
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virtual void Truncate(); |
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virtual uint32_t GetEOF(); |
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}; |
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class hsRAMStream : public hsStream { |
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hsAppender fAppender; |
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hsAppenderIterator fIter; |
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public: |
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hsRAMStream(); |
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hsRAMStream(uint32_t chunkSize); |
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virtual ~hsRAMStream(); |
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virtual bool Open(const char *, const char *) { hsAssert(0, "hsRAMStream::Open NotImplemented"); return false; } |
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virtual bool Open(const wchar_t *, const wchar_t *) { hsAssert(0, "hsRAMStream::Open NotImplemented"); return false; } |
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virtual bool Close() { hsAssert(0, "hsRAMStream::Close NotImplemented"); return false; } |
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virtual bool AtEnd(); |
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virtual uint32_t Read(uint32_t byteCount, void * buffer); |
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virtual uint32_t Write(uint32_t byteCount, const void* buffer); |
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virtual void Skip(uint32_t deltaByteCount); |
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virtual void Rewind(); |
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virtual void Truncate(); |
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virtual uint32_t GetEOF(); |
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virtual void CopyToMem(void* mem); |
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void Reset(); // clears the buffers |
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}; |
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class hsNullStream : public hsStream { |
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public: |
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virtual bool Open(const char *, const char *) { return true; } |
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virtual bool Open(const wchar_t *, const wchar_t *) { return true; } |
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virtual bool Close() { return true; } |
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virtual uint32_t Read(uint32_t byteCount, void * buffer); // throw's exception |
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virtual uint32_t Write(uint32_t byteCount, const void* buffer); |
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virtual void Skip(uint32_t deltaByteCount); |
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virtual void Rewind(); |
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virtual void Truncate(); |
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uint32_t GetBytesWritten() const { return fBytesRead; } |
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void Reset( ) { fBytesRead = 0; } |
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}; |
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// read only mem stream |
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class hsReadOnlyStream : public hsStream { |
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protected: |
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char* fStart; |
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char* fData; |
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char* fStop; |
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public: |
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hsReadOnlyStream(int size, const void* data) { Init(size, data); } |
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hsReadOnlyStream() {} |
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virtual void Init(int size, const void* data) { fStart=((char*)data); fData=((char*)data); fStop=((char*)data + size); } |
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virtual bool Open(const char *, const char *) { hsAssert(0, "hsReadOnlyStream::Open NotImplemented"); return false; } |
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virtual bool Open(const wchar_t *, const wchar_t *) { hsAssert(0, "hsReadOnlyStream::Open NotImplemented"); return false; } |
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virtual bool Close() { hsAssert(0, "hsReadOnlyStream::Close NotImplemented"); return false; } |
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virtual bool AtEnd(); |
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virtual uint32_t Read(uint32_t byteCount, void * buffer); |
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virtual uint32_t Write(uint32_t byteCount, const void* buffer); // throws exception |
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virtual void Skip(uint32_t deltaByteCount); |
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virtual void Rewind(); |
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virtual void Truncate(); |
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virtual uint32_t GetBytesRead() const { return fBytesRead; } |
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virtual uint32_t GetEOF() { return (uint32_t)(fStop-fStart); } |
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virtual void CopyToMem(void* mem); |
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}; |
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// write only mem stream |
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class hsWriteOnlyStream : public hsReadOnlyStream { |
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public: |
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hsWriteOnlyStream(int size, const void* data) : hsReadOnlyStream(size, data) {} |
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hsWriteOnlyStream() {} |
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virtual bool Open(const char *, const char *) { hsAssert(0, "hsWriteOnlyStream::Open NotImplemented"); return false; } |
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virtual bool Open(const wchar_t *, const wchar_t *) { hsAssert(0, "hsWriteOnlyStream::Open NotImplemented"); return false; } |
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virtual bool Close() { hsAssert(0, "hsWriteOnlyStream::Close NotImplemented"); return false; } |
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virtual uint32_t Read(uint32_t byteCount, void * buffer); // throws exception |
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virtual uint32_t Write(uint32_t byteCount, const void* buffer); |
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virtual uint32_t GetBytesRead() const { return 0; } |
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virtual uint32_t GetBytesWritten() const { return fBytesRead; } |
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}; |
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// circular queue stream |
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class hsQueueStream : public hsStream { |
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private: |
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char* fQueue; |
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uint32_t fReadCursor; |
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uint32_t fWriteCursor; |
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uint32_t fSize; |
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public: |
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hsQueueStream(int32_t size); |
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~hsQueueStream(); |
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virtual bool Open(const char *, const char *) { hsAssert(0, "hsQueueStream::Open NotImplemented"); return false; } |
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virtual bool Open(const wchar_t *, const wchar_t *) { hsAssert(0, "hsQueueStream::Open NotImplemented"); return false; } |
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virtual bool Close() { hsAssert(0, "hsQueueStream::Close NotImplemented"); return false; } |
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virtual uint32_t Read(uint32_t byteCount, void * buffer); |
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virtual uint32_t Write(uint32_t byteCount, const void* buffer); |
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virtual void Skip(uint32_t deltaByteCount); |
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virtual void Rewind(); |
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virtual void FastFwd(); |
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virtual bool AtEnd(); |
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uint32_t GetSize() { return fSize; } |
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const char* GetQueue() { return fQueue; } |
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uint32_t GetReadCursor() { return fReadCursor; } |
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uint32_t GetWriteCursor() { return fWriteCursor; } |
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}; |
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class hsBufferedStream : public hsStream |
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{ |
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FILE* fRef; |
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uint32_t fFileSize; |
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enum { kBufferSize = 2*1024 }; |
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char fBuffer[kBufferSize]; |
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// If the buffer is empty, this is zero. Otherwise it is the size of the |
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// buffer (if we read a full block), or something less than that if we read |
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// a partial block at the end of the file. |
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uint32_t fBufferLen; |
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bool fWriteBufferUsed; |
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#ifdef HS_DEBUGGING |
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// For doing statistics on how efficient we are |
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int fBufferHits, fBufferMisses; |
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uint32_t fBufferReadIn, fBufferReadOut, fReadDirect, fLastReadPos; |
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char* fFilename; |
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const char* fCloseReason; |
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#endif |
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public: |
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hsBufferedStream(); |
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virtual ~hsBufferedStream(); |
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virtual bool Open(const char* name, const char* mode = "rb"); |
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virtual bool Open(const wchar_t* name, const wchar_t* mode = L"rb"); |
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virtual bool Close(); |
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virtual bool AtEnd(); |
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virtual uint32_t Read(uint32_t byteCount, void* buffer); |
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virtual uint32_t Write(uint32_t byteCount, const void* buffer); |
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virtual void Skip(uint32_t deltaByteCount); |
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virtual void Rewind(); |
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virtual void Truncate(); |
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virtual uint32_t GetEOF(); |
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FILE* GetFileRef(); |
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void SetFileRef(FILE* file); |
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// Something optional for when we're doing stats. Will log the reason why |
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// the file was closed. Really just for plRegistryPageNode. |
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void SetCloseReason(const char* reason) |
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{ |
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#ifdef HS_DEBUGGING |
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fCloseReason = reason; |
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#endif |
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} |
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}; |
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#endif
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