void ZTupleIndex_General::WriteDescription(const ZStrimW& s)
{
s << "ZTupleIndex_General. ";
s.Writef("%d entries, indexing on ", fSet.size());
for (size_t x = 0; x < fPropNameCount; ++x)
s << fPropNames[x].AsString() << ", ";
}
void ZTupleIndex_String::WriteDescription(const ZStrimW& s)
{
s << "ZTupleIndex_String. ";
s.Writef("%zu entries, ", fSet.size());
s << "indexing on " << string8(fPropName);
}
static void sWriteIndent(const ZStrimW& iStrimW, int iIndent)
{
ZAssert(iIndent >= 0);
for (int x = 0; x < iIndent; ++x)
iStrimW.WriteCP('\t');
}
static void sWriteLFIndent(const ZStrimW& iStrimW,
size_t iCount, const ZUtil_Tuple::Options& iOptions)
{
iStrimW.Write(iOptions.fEOLString);
sWriteIndent(iStrimW, iCount, iOptions);
}
static void sToStrim_Tuple(const ZStrimW& s, const ZTuple& iTuple,
size_t iLevel, const ZUtil_Tuple::Options& iOptions, bool iMayNeedInitialLF)
{
if (iTuple.Empty())
{
// We've got an empty tuple.
s.Write("{}");
return;
}
const ZTuple::const_iterator theBegin = iTuple.begin();
const ZTuple::const_iterator theEnd = iTuple.end();
bool needsIndentation = false;
if (iOptions.DoIndentation())
{
for (ZTuple::const_iterator i = theBegin; i != theEnd; ++i)
{
if (sIsComplex(iOptions, iTuple.GetValue(i)))
{
needsIndentation = true;
break;
}
}
}
if (needsIndentation)
{
if (iMayNeedInitialLF)
{
// We're going to be indenting, but need to start
// a fresh line to have our { and contents line up.
sWriteLFIndent(s, iLevel, iOptions);
}
s.Write("{");
for (ZTuple::const_iterator i = theBegin; i != theEnd; ++i)
{
sWriteLFIndent(s, iLevel, iOptions);
ZUtil_Tuple::sWrite_PropName(s, iTuple.NameOf(i));
s << " = ";
sToStrim_TupleValue(s, iTuple.GetValue(i), iLevel + 1, iOptions, true);
s.Write(";");
}
sWriteLFIndent(s, iLevel, iOptions);
s.Write("}");
}
else
{
s.Write("{");
for (ZTuple::const_iterator i = theBegin; i != theEnd; ++i)
{
s.Write(" ");
ZUtil_Tuple::sWrite_PropName(s, iTuple.NameOf(i));
s << " = ";
sToStrim_TupleValue(s, iTuple.GetValue(i), iLevel + 1, iOptions, true);
s.Write(";");
}
s.Write(" }");
}
}
static void sWriteIndent(const ZStrimW& iStrimW,
size_t iCount, const ZUtil_Tuple::Options& iOptions)
{
while (iCount--)
iStrimW.Write(iOptions.fIndentString);
}
static void sToStrim_Vector(const ZStrimW& s, const vector<ZTupleValue>& iVector,
size_t iLevel, const ZUtil_Tuple::Options& iOptions, bool iMayNeedInitialLF)
{
if (iVector.empty())
{
// We've got an empty vector.
s.Write("[]");
return;
}
vector<ZTupleValue>::const_iterator theBegin = iVector.begin();
vector<ZTupleValue>::const_iterator theEnd = iVector.end();
bool needsIndentation = false;
if (iOptions.DoIndentation())
{
// We're supposed to be indenting if we're complex, ie if any element is:
// 1. A non-empty vector.
// 2. A non-empty tuple.
// or if iOptions.fBreakStrings is true, any element is a string with embedded
// line breaks or more than iOptions.fStringLineLength characters.
for (vector<ZTupleValue>::const_iterator i = theBegin; i != theEnd; ++i)
{
if (sIsComplex(iOptions, *i))
{
needsIndentation = true;
break;
}
}
}
if (needsIndentation)
{
// We need to indent.
if (iMayNeedInitialLF)
{
// We were invoked by a tuple which has already issued the property
// name and equals sign, so we need to start a fresh line.
sWriteLFIndent(s, iLevel, iOptions);
}
s.Write("[");
for (vector<ZTupleValue>::const_iterator i = theBegin;;)
{
sWriteLFIndent(s, iLevel, iOptions);
sToStrim_TupleValue(s, *i, iLevel, iOptions, false);
++i;
if (i == theEnd)
break;
s.Write(", ");
}
sWriteLFIndent(s, iLevel, iOptions);
s.Write("]");
}
else
{
// We're not indenting, so we can just dump everything out on
// one line, with just some spaces to keep things legible.
s.Write("[");
for (vector<ZTupleValue>::const_iterator i = theBegin;;)
{
sToStrim_TupleValue(s, *i, iLevel, iOptions, false);
++i;
if (i == theEnd)
break;
s.Write(", ");
}
s.Write("]");
}
}
static void sToStrim_TupleValue(const ZStrimW& s, const ZTupleValue& iTV,
size_t iLevel, const ZUtil_Tuple::Options& iOptions, bool iMayNeedInitialLF)
{
switch (iTV.TypeOf())
{
case eZType_Vector:
{
sToStrim_Vector(s, iTV.GetVector(), iLevel, iOptions, iMayNeedInitialLF);
break;
}
case eZType_Tuple:
{
sToStrim_Tuple(s, iTV.GetTuple(), iLevel, iOptions, iMayNeedInitialLF);
break;
}
case eZType_Raw:
{
const void* theData;
size_t theSize;
iTV.GetRawAttributes(&theData, &theSize);
if (theSize == 0)
{
// we've got an empty Raw
s.Write("()");
}
else
{
ZStreamRPos_Memory dataStream(theData, theSize);
if (iOptions.DoIndentation() && theSize > iOptions.fRawChunkSize)
{
if (iMayNeedInitialLF)
sWriteLFIndent(s, iLevel, iOptions);
s.Writef("( // %d bytes", theSize);
sWriteLFIndent(s, iLevel, iOptions);
if (iOptions.fRawAsASCII)
{
for (;;)
{
uint64 lastPos = dataStream.GetPosition();
uint64 countCopied;
ZStreamW_HexStrim(iOptions.fRawByteSeparator, "", 0, s)
.CopyFrom(dataStream, iOptions.fRawChunkSize, &countCopied, nil);
if (countCopied == 0)
break;
dataStream.SetPosition(lastPos);
if (size_t extraSpaces = iOptions.fRawChunkSize - countCopied)
{
// We didn't write a complete line of bytes, so pad it out.
while (extraSpaces--)
{
// Two spaces for the two nibbles
s.Write(" ");
// And then the separator sequence
s.Write(iOptions.fRawByteSeparator);
}
}
s.Write(" // ");
while (countCopied--)
{
char theChar = dataStream.ReadInt8();
if (theChar < 0x20 || theChar > 0x7E)
s.WriteCP('.');
else
s.WriteCP(theChar);
}
sWriteLFIndent(s, iLevel, iOptions);
}
}
else
{
string eol = iOptions.fEOLString;
for (size_t x = 0; x < iLevel; ++x)
eol += iOptions.fIndentString;
ZStreamW_HexStrim(iOptions.fRawByteSeparator,
eol, iOptions.fRawChunkSize, s).CopyAllFrom(dataStream);
sWriteLFIndent(s, iLevel, iOptions);
}
s.Write(")");
}
else
{
s.Write("(");
ZStreamW_HexStrim(iOptions.fRawByteSeparator, "", 0, s)
.CopyAllFrom(dataStream);
if (iOptions.fRawAsASCII)
{
dataStream.SetPosition(0);
s.Write(" /* ");
while (theSize--)
{
char theChar = dataStream.ReadInt8();
if (theChar < 0x20 || theChar > 0x7E)
s.WriteCP('.');
else
s.WriteCP(theChar);
}
s.Write(" */");
}
s.Write(")");
}
}
break;
}
default:
{
// We've got something other than a tuple or a vector.
sSimpleTupleValueToStrim(s, iTV, iLevel, iOptions);
break;
}
}
}
static void sSimpleTupleValueToStrim(const ZStrimW& s, const ZTupleValue& iTV,
size_t iLevel, const ZUtil_Tuple::Options& iOptions)
{
switch (iTV.TypeOf())
{
case eZType_Null:
s.Write("Null");
break;
case eZType_Type:
{
s.Write("Type(");
s.Write(ZTypeAsString(iTV.GetType()));
s.Write(")");
break;
}
case eZType_ID:
{
s.Writef("ID(0x%0llX)", iTV.GetID());
if (iOptions.fIDsHaveDecimalVersionComment)
s.Writef(" /* %lld */", iTV.GetID());
break;
}
case eZType_Int8:
s.Writef("int8(%d)", iTV.GetInt8());
break;
case eZType_Int16:
s.Writef("int16(%d)", iTV.GetInt16());
break;
case eZType_Int32:
s.Writef("int32(%d)", iTV.GetInt32());
break;
case eZType_Int64:
s.Writef("int64(0x%0llX)", iTV.GetInt64());
break;
case eZType_Bool:
{
if (iTV.GetBool())
s.Write("true");
else
s.Write("false");
break;
}
case eZType_Float:
{
// 9 decimal digits are necessary and sufficient for single precision IEEE 754.
// "What Every Computer Scientist Should Know About Floating Point", Goldberg, 1991.
// <http://docs.sun.com/source/806-3568/ncg_goldberg.html>
s.Writef("float(%.9g)", iTV.GetFloat());
break;
}
case eZType_Double:
{
// 17 decimal digits are necessary and sufficient for double precision IEEE 754.
s.Writef("double(%.17g)", iTV.GetDouble());
break;
}
case eZType_Time:
{
// For the moment I'm just writing times as a count of seconds, putting
// the broken-out Gregorian version in a comment. Later we can improve
// the parsing of dates, and then we can write them in human readable form.
if (ZTime theTime = iTV.GetTime())
{
s.Writef("time(%.17g)", theTime.fVal);
if (iOptions.fTimesHaveUserLegibleComment)
{
s << " /*" << ZUtil_Time::sAsStringUTC(theTime, "%Y-%m-%dZ%H:%M:");
// We've got about 10 significant digits in year (-10,000 to +10,000),
// month, day, hour, minutes, and seconds, and no more than 17 in a double.
// To get a leading zero in the seconds' tens column we add 100
// to the count of seconds, so to get up to 7 digits in the fraction we
// need to allow ten digits overall.
s << ZString::sFormat("%.10g", 100.0 + fmod(theTime.fVal, 60)).substr(1);
s << "*/";
};
}
else
{
// We're now allowing empty parens to represent invalid times.
s.Write("time()");
}
break;
}
case eZType_Pointer:
s.Writef("pointer(%08X)", iTV.GetPointer());
break;
case eZType_Rect:
{
const ZRectPOD& theRect = iTV.GetRect();
s.Writef("Rect(%d, %d, %d, %d)",
theRect.left,
theRect.top,
theRect.right,
theRect.bottom);
break;
}
case eZType_Point:
{
const ZPointPOD& thePoint = iTV.GetPoint();
s.Writef("Point(%d, %d)",
thePoint.h,
thePoint.v);
break;
}
case eZType_String:
{
const string& theString = iTV.GetString();
if (iOptions.fBreakStrings && iOptions.DoIndentation())
{
if (string::npos != theString.find_first_of("\n\r"))
{
// We put a newline after the opening """, which will be
// ignored by sFromStrim, so the first line of theString
// will be in column zero.
s << "\"\"\"\n";
ZStrimU_String strim_String(theString);
ZStrimR_Boundary strim_Boundary("\"\"\"", strim_String);
for (;;)
{
s.CopyAllFrom(strim_Boundary);
if (!strim_Boundary.HitBoundary())
{
// We've returned without having hit the boundary, so we're done.
break;
}
strim_Boundary.Reset();
// Close the triple quotes.
s << "\"\"\"";
// A space to separate the triple-quote from the single quote
s << " ";
// An open quote
s << "\"";
// Three escaped quotes.
s << "\\\"\\\"\\\"";
// A close quote.
s << "\"";
// Another space, for symmetry
s << " ";
// And re-open triple quotes again.
s << "\"\"\"";
// With a newline, so the text will again
// start in column zero.
s << "\n";
}
s << "\"\"\"";
break;
}
}
string delimiter = "\"";
bool quoteQuotes = true;
if (string::npos != theString.find('"') && string::npos == theString.find('\''))
{
delimiter = "'";
quoteQuotes = false;
}
s.Write(delimiter);
ZStrimW_Escapify::Options theOptions;
theOptions.fQuoteQuotes = quoteQuotes;
theOptions.fEscapeHighUnicode = false;
ZStrimW_Escapify(theOptions, s).Write(theString);
s.Write(delimiter);
break;
}
case eZType_RefCounted:
s.Writef("RefCounted(%08X)", iTV.GetRefCounted().GetObject());
break;
case eZType_Raw:
case eZType_Tuple:
case eZType_Vector:
{
ZDebugStopf(0,
("sSimpleTupleValueToStrim should only be called on simple tuple values"));
break;
}
default:
{
ZDebugStopf(0, ("Unrecognized type %d", iTV.TypeOf()));
break;
}
}
}
