/*
-Copyright (c) 2005-2006, John Hurst
+Copyright (c) 2005-2015, John Hurst
All rights reserved.
Redistribution and use in source and binary forms, with or without
#include <KM_memio.h>
#include <KM_error.h>
+#include <KM_tai.h>
#include <string.h>
-#include <string>
+#include <list>
namespace Kumu
{
+ // The version number declaration and explanation are in ../configure.ac
+ const char* Version();
// a class that represents the string form of a value
template <class T, int SIZE = 16>
i32_t hex2bin(const char* str, byte_t* buf, ui32_t buf_len, ui32_t* char_count);
// Convert a binary string to NULL-terminated UTF-8 hexadecimal, returns the buffer
- // if the binary buffer was large enough to hold the result. If the output buffer
+ // if the output buffer was large enough to hold the result. If the output buffer
// is too small or any of the pointer arguments are NULL, the subroutine will
// return 0.
//
return (*buf & 0x0f) + 1;
}
+ // Return the BER length required to encode value. A return value of zero
+ // indicates a value too large for this library.
+ ui32_t get_BER_length_for_value(ui64_t valuse);
+
// read a BER value
bool read_BER(const byte_t* buf, ui64_t* val);
{
public:
virtual ~IArchive(){}
- virtual bool HasValue() const = 0;
- virtual bool Archive(MemIOWriter* Writer) const = 0;
- virtual bool Unarchive(MemIOReader* Reader) = 0;
+ virtual bool HasValue() const = 0;
+ virtual ui32_t ArchiveLength() const = 0;
+ virtual bool Archive(MemIOWriter* Writer) const = 0;
+ virtual bool Unarchive(MemIOReader* Reader) = 0;
};
+ //
+ template <class T>
+ class ArchivableList : public std::list<T>, public IArchive
+ {
+ public:
+ ArchivableList() {}
+ virtual ~ArchivableList() {}
+
+ bool HasValue() const { return ! this->empty(); }
+
+ ui32_t ArchiveLength() const
+ {
+ ui32_t arch_size = sizeof(ui32_t);
+
+ typename ArchivableList<T>::const_iterator i = this->begin();
+ for ( ; i != this->end(); i++ )
+ arch_size += i->ArchiveLength();
+
+ return arch_size;
+ }
+
+ bool Unarchive(Kumu::MemIOReader* Reader)
+ {
+ if ( Reader == 0 ) return false;
+ ui32_t read_size = 0;
+ if ( ! Reader->ReadUi32BE(&read_size) ) return false;
+ for ( ui32_t i = 0; i < read_size; i++ )
+ {
+ T TmpTP;
+ if ( ! TmpTP.Unarchive(Reader) ) return false;
+ this->push_back(TmpTP);
+ }
+
+ return true;
+ }
+
+ bool Archive(Kumu::MemIOWriter* Writer) const
+ {
+ if ( Writer == 0 ) return false;
+ if ( ! Writer->WriteUi32BE(static_cast<ui32_t>(this->size())) ) return false;
+ typename ArchivableList<T>::const_iterator i = this->begin();
+ for ( ; i != this->end(); i++ )
+ if ( ! i->Archive(Writer) ) return false;
+
+ return true;
+ }
+ };
+
+ // archivable version of std::string
+
+ //
+ class ArchivableString : public std::string, public Kumu::IArchive
+ {
+
+ public:
+ ArchivableString() {}
+ ArchivableString(const char* sz) : std::string(sz) {}
+ ArchivableString(const std::string& s) : std::string(s) {}
+ virtual ~ArchivableString() {}
+
+ bool HasValue() const { return ! this->empty(); }
+ ui32_t ArchiveLength() const { return sizeof(ui32_t) + static_cast<ui32_t>(this->size()); }
+
+ bool Archive(MemIOWriter* Writer) const {
+ if ( Writer == 0 ) return false;
+ return Writer->WriteString(*this);
+ }
+
+ bool Unarchive(MemIOReader* Reader) {
+ if ( Reader == 0 ) return false;
+ return Reader->ReadString(*this);
+ }
+ };
+
+ //
+ class ArchivableUi16 : public Kumu::IArchive
+ {
+ public:
+ ui16_t value;
+
+ ArchivableUi16() : value(0) {}
+ ArchivableUi16(const ui16_t& val) : value(val) {}
+ virtual ~ArchivableUi16() {}
+
+ bool HasValue() const { return true; }
+ ui32_t ArchiveLength() const { return sizeof(ui16_t); }
+
+ operator ui16_t() const { return value; }
+
+ bool Archive(MemIOWriter* Writer) const {
+ if ( Writer == 0 ) return false;
+ return Writer->WriteUi16BE(value);
+ }
+
+ bool Unarchive(MemIOReader* Reader) {
+ if ( Reader == 0 ) return false;
+ return Reader->ReadUi16BE(&value);
+ }
+
+ const char* EncodeString(char* str_buf, ui32_t buf_len) const {
+ snprintf(str_buf, buf_len, "%hu", value);
+ return str_buf;
+ }
+ };
+
+ //
+ typedef Kumu::ArchivableList<ArchivableString> StringList;
//
// the base of all identifier classes, Identifier is not usually used directly
public:
Identifier() : m_HasValue(false) { memset(m_Value, 0, SIZE); }
Identifier(const byte_t* value) : m_HasValue(true) { memcpy(m_Value, value, SIZE); }
- Identifier(const Identifier& rhs) {
+ Identifier(const Identifier& rhs) : IArchive() {
m_HasValue = rhs.m_HasValue;
memcpy(m_Value, rhs.m_Value, SIZE);
}
}
inline void Set(const byte_t* value) { m_HasValue = true; memcpy(m_Value, value, SIZE); }
+ inline void Reset() { m_HasValue = false; memset(m_Value, 0, SIZE); }
inline const byte_t* Value() const { return m_Value; }
inline ui32_t Size() const { return SIZE; }
return false;
}
+ inline bool operator>(const Identifier& rhs) const {
+ ui32_t test_size = xmin(rhs.Size(), SIZE);
+
+ for ( ui32_t i = 0; i < test_size; i++ )
+ {
+ if ( m_Value[i] != rhs.m_Value[i] )
+ return m_Value[i] > rhs.m_Value[i];
+ }
+
+ return false;
+ }
+
inline bool operator==(const Identifier& rhs) const {
if ( rhs.Size() != SIZE ) return false;
return ( memcmp(m_Value, rhs.m_Value, SIZE) == 0 );
inline bool DecodeHex(const char* str) {
ui32_t char_count;
m_HasValue = ( hex2bin(str, m_Value, SIZE, &char_count) == 0 );
+ if ( m_HasValue && char_count != SIZE )
+ m_HasValue = false;
return m_HasValue;
}
inline bool DecodeBase64(const char* str) {
ui32_t char_count;
m_HasValue = ( base64decode(str, m_Value, SIZE, &char_count) == 0 );
+ if ( m_HasValue && char_count != SIZE )
+ m_HasValue = false;
return m_HasValue;
}
inline bool HasValue() const { return m_HasValue; }
+ inline ui32_t ArchiveLength() const { return SIZE; }
+
inline bool Unarchive(Kumu::MemIOReader* Reader) {
m_HasValue = Reader->ReadRaw(m_Value, SIZE);
return m_HasValue;
}
};
-
+
// UUID
//
const ui32_t UUID_Length = 16;
UUID(const UUID& rhs) : Identifier<UUID_Length>(rhs) {}
virtual ~UUID() {}
+ inline const char* EncodeString(char* buf, ui32_t buf_len) const {
+ return bin2UUIDhex(m_Value, Size(), buf, buf_len);
+ }
+
inline const char* EncodeHex(char* buf, ui32_t buf_len) const {
return bin2UUIDhex(m_Value, Size(), buf, buf_len);
}
void GenRandomUUID(byte_t* buf); // buf must be UUID_Length or longer
void GenRandomValue(UUID&);
+ typedef ArchivableList<UUID> UUIDList;
+
// a self-wiping key container
//
const ui32_t SymmetricKey_Length = 16;
void GenRandomValue(SymmetricKey&);
//
- // 2004-05-01T13:20:00-00:00
+ // 2004-05-01T13:20:00+00:00
const ui32_t DateTimeLen = 25; // the number of chars in the xs:dateTime format (sans milliseconds)
// UTC time+date representation
class Timestamp : public IArchive
{
- public:
- ui16_t Year;
- ui8_t Month;
- ui8_t Day;
- ui8_t Hour;
- ui8_t Minute;
- ui8_t Second;
+ TAI::tai m_Timestamp; // always UTC
+ i32_t m_TZOffsetMinutes;
+ public:
Timestamp();
Timestamp(const Timestamp& rhs);
Timestamp(const char* datestr);
+ Timestamp(const ui16_t& Year, const ui8_t& Month, const ui8_t& Day);
+ Timestamp(const ui16_t& Year, const ui8_t& Month, const ui8_t& Day,
+ const ui8_t& Hour, const ui8_t& Minute, const ui8_t& Second);
virtual ~Timestamp();
const Timestamp& operator=(const Timestamp& rhs);
bool operator<(const Timestamp& rhs) const;
+ bool operator>(const Timestamp& rhs) const;
bool operator==(const Timestamp& rhs) const;
bool operator!=(const Timestamp& rhs) const;
- // Write the timestamp value to the given buffer in the form 2004-05-01T13:20:00-00:00
+ // always UTC
+ void GetComponents(ui16_t& Year, ui8_t& Month, ui8_t& Day,
+ ui8_t& Hour, ui8_t& Minute, ui8_t& Second) const;
+ void SetComponents(const ui16_t& Year, const ui8_t& Month, const ui8_t& Day,
+ const ui8_t& Hour, const ui8_t& Minute, const ui8_t& Second);
+
+ // Write the timestamp value to the given buffer in the form 2004-05-01T13:20:00+00:00
// returns 0 if the buffer is smaller than DateTimeLen
const char* EncodeString(char* str_buf, ui32_t buf_len) const;
// decode and set value from string formatted by EncodeString
bool DecodeString(const char* datestr);
- // Add the given number of days or hours to the timestamp value.
+ // Add the given number of days, hours, minutes, or seconds to the timestamp value.
// Values less than zero will cause the timestamp to decrease
- void AddDays(i32_t);
- void AddHours(i32_t);
+ inline void AddDays(const i32_t& d) { m_Timestamp.add_days(d); }
+ inline void AddHours(const i32_t& h) { m_Timestamp.add_hours(h); }
+ inline void AddMinutes(const i32_t& m) { m_Timestamp.add_minutes(m); }
+ inline void AddSeconds(const i32_t& s) { m_Timestamp.add_seconds(s); }
+
+ // returns false if the requested adjustment is out of range
+ bool SetTZOffsetMinutes(const i32_t& minutes);
+ inline i32_t GetTZOffsetMinutes() const { return m_TZOffsetMinutes; }
- // Read and write the timestamp value as a byte string having
+ // Return the number of seconds since the Unix epoch UTC (1970-01-01T00:00:00+00:00)
+ ui64_t GetCTime() const;
+
+ // Set internal time to the number of seconds since the Unix epoch UTC
+ void SetCTime(const ui64_t& ctime);
+
+ // Read and write the timestamp (always UTC) value as a byte string having
// the following format:
// | 16 bits int, big-endian | 8 bits | 8 bits | 8 bits | 8 bits | 8 bits |
// | Year A.D | Month(1-12) | Day(1-31) | Hour(0-23) | Minute(0-59) | Second(0-59) |
//
- virtual bool HasValue() const;
- virtual bool Archive(MemIOWriter* Writer) const;
- virtual bool Unarchive(MemIOReader* Reader);
+ virtual bool HasValue() const;
+ virtual ui32_t ArchiveLength() const { return 8L; }
+ virtual bool Archive(MemIOWriter* Writer) const;
+ virtual bool Unarchive(MemIOReader* Reader);
};
//
ByteString(ui32_t cap);
virtual ~ByteString();
- // Sets the size of the internally allocated buffer.
- // Resets content Size to zero.
+ // Sets or resets the size of the internally allocated buffer.
Result_t Capacity(ui32_t cap);
Result_t Append(const ByteString&);
inline ui32_t Capacity() const { return m_Capacity; }
// returns a const pointer to the essence data
- inline const byte_t* RoData() const { return m_Data; }
+ inline const byte_t* RoData() const { assert(m_Data); return m_Data; }
// returns a non-const pointer to the essence data
- inline byte_t* Data() { return m_Data; }
+ inline byte_t* Data() { assert(m_Data); return m_Data; }
// set the length of the buffer's contents
inline ui32_t Length(ui32_t l) { return m_Length = l; }
// copy the given data into the ByteString, set Length value.
// Returns error if the ByteString is too small.
Result_t Set(const byte_t* buf, ui32_t buf_len);
+ Result_t Set(const ByteString& Buf);
inline virtual bool HasValue() const { return m_Length > 0; }
+ inline virtual ui32_t ArchiveLength() const { return sizeof(ui32_t) + m_Length; }
+
inline virtual bool Archive(MemIOWriter* Writer) const {
assert(Writer);
if ( ! Writer->WriteUi32BE(m_Length) ) return false;
inline virtual bool Unarchive(MemIOReader* Reader) {
assert(Reader);
- if ( ! Reader->ReadUi32BE(&m_Length) ) return false;
- if ( KM_FAILURE(Capacity(m_Length)) ) return false;
- if ( ! Reader->ReadRaw(m_Data, m_Length) ) return false;
+ ui32_t tmp_len;
+ if ( ! Reader->ReadUi32BE(&tmp_len) ) return false;
+ if ( KM_FAILURE(Capacity(tmp_len)) ) return false;
+ if ( ! Reader->ReadRaw(m_Data, tmp_len) ) return false;
+ m_Length = tmp_len;
return true;
}
};
+ inline void hexdump(const ByteString& buf, FILE* stream = 0) {
+ hexdump(buf.RoData(), buf.Length(), stream);
+ }
+
+ // Locates the first occurrence of the null-terminated string s2 in the string s1, where not more
+ // than n characters are searched. Characters that appear after a `\0' character are not searched.
+ // Reproduced here from BSD for portability.
+ const char *km_strnstr(const char *s1, const char *s2, size_t n);
+
+ // Split the input string into tokens using the given separator. If the separator is not found the
+ // entire string will be returned as a single-item list. Empty items will be recorded for
+ // adjacent instances of the separator. E.g., "/foo//bar/" will return ["", "foo", "", "bar", ""].
+ std::list<std::string> km_token_split(const std::string& str, const std::string& separator);
+
+ // Join the tokens in the given list using delimiter. If prefix is defined then each token
+ // will be concatenated with the prefix before being added to the composite string.
+ template <class T>
+ std::string
+ km_join(const T& list, const std::string& delimiter, const std::string& prefix = "")
+ {
+ std::string result;
+
+ for ( typename T::const_iterator i = list.begin(); i != list.end(); ++i )
+ {
+ if ( i != list.begin() )
+ {
+ result += delimiter;
+ }
+
+ result += prefix + *i;
+ }
+
+ return result;
+ }
+
} // namespace Kumu