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SqMod/source/Library/String.cpp

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// ------------------------------------------------------------------------------------------------
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#include "Library/String.hpp"
#include "Base/Shared.hpp"
#include "Base/Buffer.hpp"
// ------------------------------------------------------------------------------------------------
#include <cctype>
#include <cstdio>
#include <cstdlib>
#include <cstring>
// ------------------------------------------------------------------------------------------------
#include <algorithm>
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// ------------------------------------------------------------------------------------------------
namespace SqMod {
// ------------------------------------------------------------------------------------------------
static LightObj SqLeftStr(SQChar f, Uint32 w, const StackStrF & s)
{
// Is the specified width valid?
if (!w)
{
return _SC(""); // Default to an empty string!
}
// Allocate a buffer with the requested width
Buffer b(w + 1); // + null terminator
// Is the specified string valid?
if (!s.mLen)
{
std::memset(b.Data(), f, w); // Insert only the fill character
}
else
{
// Insert only the fill character first
std::memset(b.Data(), f, w);
// Overwrite with the specified string
std::strncpy(b.Data(), s.mPtr, s.mLen);
}
// Obtain the initial stack size
const StackGuard sg(s.mVM);
// Push the string onto the stack
sq_pushstring(s.mVM, b.Data(), w);
// Obtain the object from the stack and return it
return std::move(Var< LightObj >(s.mVM, -1).value);
}
// ------------------------------------------------------------------------------------------------
static LightObj SqLeftOffsetStr(SQChar f, Uint32 w, Uint32 o, const StackStrF & s)
{
// Is the specified width valid?
if (!w)
{
return _SC(""); // Default to an empty string!
}
// Is the specified offset within width range?
else if (o > w)
{
STHROWF("Offset is out of bounds");
}
// Allocate a buffer with the requested width
Buffer b(w + 1); // + null terminator
// Is the specified string valid?
if (!s.mLen)
{
std::memset(b.Data(), f, w); // Insert only the fill character
}
else
{
// Calculate the string length
const Uint32 n = ConvTo< Uint32 >::From(s.mLen);
// Insert the fill character first
std::memset(b.Data(), f, w);
// Overwrite with the specified string
if (n > (w - o))
{
std::strncpy(b.Data() + o, s.mPtr, n);
}
else
{
std::memcpy(b.Data() + o, s.mPtr, n * sizeof(SQChar));
}
}
// Obtain the initial stack size
const StackGuard sg(s.mVM);
// Push the string onto the stack
sq_pushstring(s.mVM, b.Data(), w);
// Obtain the object from the stack and return it
return std::move(Var< LightObj >(s.mVM, -1).value);
}
// ------------------------------------------------------------------------------------------------
static LightObj SqRightStr(SQChar f, Uint32 w, const StackStrF & s)
{
// Is the specified width valid?
if (!w)
{
return _SC(""); // Default to an empty string!
}
// Allocate a buffer with the requested width
Buffer b(w + 1); // + null terminator
// Is the specified string valid?
if (!s.mLen)
{
std::memset(b.Data(), f, w); // Insert only the fill character
}
else
{
// Calculate the string length
const Uint32 n = ConvTo< Uint32 >::From(s.mLen);
// Insert the fill character first
std::memset(b.Data(), f, w);
// Overwrite with the specified string
if (n >= w)
{
std::strncpy(b.Data(), s.mPtr, w);
}
else
{
std::strncpy(b.Data() + (w - n), s.mPtr, n);
}
}
// Obtain the initial stack size
const StackGuard sg(s.mVM);
// Push the string onto the stack
sq_pushstring(s.mVM, b.Data(), w);
// Obtain the object from the stack and return it
return std::move(Var< LightObj >(s.mVM, -1).value);
}
// ------------------------------------------------------------------------------------------------
static LightObj SqRightOffsetStr(SQChar f, Uint32 w, Uint32 o, const StackStrF & s)
{
// Is the specified width valid?
if (!w)
{
return _SC(""); // Default to an empty string!
}
// Is the specified offset within width range?
else if (o > w)
{
STHROWF("Offset is out of bounds");
}
// Allocate a buffer with the requested width
Buffer b(w + 1); // + null terminator
// Is the specified string valid?
if (!s.mLen)
{
std::memset(b.Data(), f, w); // Insert only the fill character
}
else
{
// Calculate the string length
const Uint32 n = ConvTo< Uint32 >::From(s.mLen);
// Insert the fill character first
std::memset(b.Data(), f, w);
// Overwrite with the specified string
if (n >= w || (n + o) >= w)
{
std::strncpy(b.Data(), s.mPtr, w - o);
}
else
{
std::strncpy(b.Data() + ((w - n) - o), s.mPtr, n);
}
}
// Obtain the initial stack size
const StackGuard sg(s.mVM);
// Push the string onto the stack
sq_pushstring(s.mVM, b.Data(), w);
// Obtain the object from the stack and return it
return std::move(Var< LightObj >(s.mVM, -1).value);
}
// ------------------------------------------------------------------------------------------------
static LightObj SqCenterStr(SQChar f, Uint32 w, const StackStrF & s)
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{
// Is the specified width valid?
if (!w)
{
return _SC(""); // Default to an empty string!
}
// Allocate a buffer with the requested width
Buffer b(w + 1); // + null terminator
// Is the specified string valid?
if (!s.mLen)
{
std::memset(b.Data(), f, w); // Insert only the fill character
}
else
{
// Calculate the insert position
const Int32 p = ((w/2) - (s.mLen/2));
// Insert only the fill character first
std::memset(b.Data(), f, w);
// Overwrite with the specified string
std::strncpy(b.Data() + (p < 0 ? 0 : p), s.mPtr, s.mLen);
}
// Obtain the initial stack size
const StackGuard sg(s.mVM);
// Push the string onto the stack
sq_pushstring(s.mVM, b.Data(), w);
// Obtain the object from the stack and return it
return std::move(Var< LightObj >(s.mVM, -1).value);
}
// ------------------------------------------------------------------------------------------------
static Buffer StrJustAlphaNumImpl(CSStr str, Uint32 len)
{
// See if we actually have something to search for
if(!len)
{
return Buffer(); // Default to an empty buffer!
}
// Obtain a temporary buffer
Buffer b(len + 1); // + null terminator
// Resulted string size
Uint32 n = 0;
// Currently processed character
SQChar c = 0;
// Process characters
while ((c = *(str++)) != '\0')
{
// Is this an alpha-numeric character?
if (std::isalnum(c) != 0)
{
// Save it and move to the next one
b.At(n++) = c;
}
}
// End the resulted string
b.At(n) = '\0';
// Move the cursor to the end
b.Move(n);
// Return ownership of the buffer
return std::move(b);
}
// ------------------------------------------------------------------------------------------------
Buffer StrJustAlphaNumB(CSStr str)
{
// See if we actually have something to search for
if(!str || *str == '\0')
{
return Buffer(); // Default to an empty string!
}
// Attempt to convert and return the result
return StrJustAlphaNumImpl(str, std::strlen(str));
}
// ------------------------------------------------------------------------------------------------
CSStr StrJustAlphaNum(CSStr str)
{
// See if we actually have something to search for
if(!str || *str == '\0')
{
return _SC(""); // Default to an empty string!
}
// Attempt to convert and return the result
return StrJustAlphaNumImpl(str, std::strlen(str)).Get< SQChar >();
}
// ------------------------------------------------------------------------------------------------
static LightObj SqJustAlphaNum(const StackStrF & s)
{
const Buffer b(StrJustAlphaNumImpl(s.mPtr, s.mLen));
// Obtain the initial stack size
const StackGuard sg(s.mVM);
// Push the string onto the stack
sq_pushstring(s.mVM, b.Data(), b.Position());
// Obtain the object from the stack and return it
return std::move(Var< LightObj >(s.mVM, -1).value);
}
// ------------------------------------------------------------------------------------------------
static Buffer StrToLowercaseImpl(CSStr str, Uint32 len)
{
// See if we actually have something to search for
if(!len)
{
return Buffer(); // Default to an empty buffer!
}
// Obtain a temporary buffer
Buffer b(len + 1); // + null terminator
// Resulted string size
Uint32 n = 0;
// Process characters
while (*str != '\0')
{
// Convert it and move to the next one
b.At(n++) = std::tolower(*(str++));
}
// End the resulted string
b.At(n) = '\0';
// Move the cursor to the end
b.Move(n);
// Return ownership of the buffer
return std::move(b);
}
// ------------------------------------------------------------------------------------------------
Buffer StrToLowercaseB(CSStr str)
{
// See if we actually have something to search for
if(!str || *str == '\0')
{
return Buffer(); // Default to an empty string!
}
// Attempt to convert and return the result
return StrToLowercaseImpl(str, std::strlen(str));
}
// ------------------------------------------------------------------------------------------------
CSStr StrToLowercase(CSStr str)
{
// See if we actually have something to search for
if(!str || *str == '\0')
{
return _SC(""); // Default to an empty string!
}
// Attempt to convert and return the result
return StrToLowercaseImpl(str, std::strlen(str)).Get< SQChar >();
}
// ------------------------------------------------------------------------------------------------
static LightObj SqToLowercase(const StackStrF & s)
{
const Buffer b(StrToLowercaseImpl(s.mPtr, s.mLen));
// Obtain the initial stack size
const StackGuard sg(s.mVM);
// Push the string onto the stack
sq_pushstring(s.mVM, b.Data(), b.Position());
// Obtain the object from the stack and return it
return std::move(Var< LightObj >(s.mVM, -1).value);
}
// ------------------------------------------------------------------------------------------------
static Buffer StrToUppercaseImpl(CSStr str, Uint32 len)
{
// See if we actually have something to search for
if(!len)
{
return Buffer(); // Default to an empty buffer!
}
// Obtain a temporary buffer
Buffer b(len + 1); // + null terminator
// Resulted string size
Uint32 n = 0;
// Process characters
while (*str != '\0')
{
// Convert it and move to the next one
b.At(n++) = std::toupper(*(str++));
}
// End the resulted string
b.At(n) = '\0';
// Move the cursor to the end
b.Move(n);
// Return ownership of the buffer
return std::move(b);
}
// ------------------------------------------------------------------------------------------------
Buffer StrToUppercaseB(CSStr str)
{
// See if we actually have something to search for
if(!str || *str == '\0')
{
return Buffer(); // Default to an empty string!
}
// Attempt to convert and return the result
return StrToUppercaseImpl(str, std::strlen(str));
}
// ------------------------------------------------------------------------------------------------
CSStr StrToUppercase(CSStr str)
{
// See if we actually have something to search for
if(!str || *str == '\0')
{
return _SC(""); // Default to an empty string!
}
// Attempt to convert and return the result
return StrToUppercaseImpl(str, std::strlen(str)).Get< SQChar >();
}
// ------------------------------------------------------------------------------------------------
static LightObj SqToUppercase(const StackStrF & s)
{
const Buffer b(StrToUppercaseImpl(s.mPtr, s.mLen));
// Obtain the initial stack size
const StackGuard sg(s.mVM);
// Push the string onto the stack
sq_pushstring(s.mVM, b.Data(), b.Position());
// Obtain the object from the stack and return it
return std::move(Var< LightObj >(s.mVM, -1).value);
}
/* ------------------------------------------------------------------------------------------------
* Checks if all the characters in the specified string are of the specified class or not.
*/
template < int (*Fn)(int) > static bool SqAllChars(const StackStrF & s)
{
// See if we actually have something to search for
if (!s.mLen)
{
// Since there are no other different character then
// we count this as all characters being of this type
return true;
}
// Start iterating characters and find the first that doesn't match
for (CSStr itr = s.mPtr; *itr != '\0'; ++itr)
{
// Call the predicate with the current character
if (Fn(*itr) == 0)
{
return false; // This character did not pass the test
}
}
// All characters passed the test
return true;
}
/* ------------------------------------------------------------------------------------------------
* Find the position of the first character that matches the specified class.
*/
template < int (*Fn)(int), bool Neg > static LightObj SqFirstChar(const StackStrF & s)
{
// See if we actually have something to search for
if (s.mLen)
{
// Start iterating characters and find the first that doesn't match
for (CSStr itr = s.mPtr; *itr != '\0'; ++itr)
{
// Call the predicate with the current character
if ((Fn(*itr) == 0) == Neg)
{
// Obtain the initial stack size
const StackGuard sg(s.mVM);
// This character passed our test, push it's position
sq_pushinteger(s.mVM, itr - s.mPtr);
// Obtain the object from the stack and return it
return std::move(Var< LightObj >(s.mVM, -1).value);
}
}
}
// Since there are no other different character then
// we count this as all characters being of this type
return LightObj();
}
/* ------------------------------------------------------------------------------------------------
* Find the position of the last character that matches the specified class.
*/
template < int (*Fn)(int), bool Neg > static LightObj SqLastChar(const StackStrF & s)
{
// See if we actually have something to search for
if (s.mLen)
{
// Start iterating characters and find the first that doesn't match
for (CSStr itr = (s.mPtr + s.mLen) - 1; itr >= s.mPtr; --itr)
{
// Call the predicate with the current character
if ((Fn(*itr) == 0) == Neg)
{
// Obtain the initial stack size
const StackGuard sg(s.mVM);
// This character passed our test, push it's position
sq_pushinteger(s.mVM, itr - s.mPtr);
// Obtain the object from the stack and return it
return std::move(Var< LightObj >(s.mVM, -1).value);
}
}
}
// Since there are no other different character then
// we count this as all characters being of this type
return LightObj();
}
/* ------------------------------------------------------------------------------------------------
* Split the string into chunks wherever a character matches or not the specified class.
*/
static SQInteger SplitWhereCharImpl(HSQUIRRELVM vm, int(*fn)(int), bool neg)
{
static const SQInteger top = sq_gettop(vm);
// Is there a value to process?
if (top <= 1)
{
return sq_throwerror(vm, "Missing string or value");
}
// Attempt to retrieve the value from the stack as a string
StackStrF val(vm, 2);
// Have we failed to retrieve the string?
if (SQ_FAILED(val.mRes))
{
return val.mRes; // Propagate the error!
}
// Create a new array on the stack
sq_newarray(vm, 0);
// See if we actually have something to search for
if (!(val.mPtr) || *(val.mPtr) == '\0')
{
return 1; // Return an empty array
}
// Remember the position of the last found match
CSStr last = val.mPtr;
// Start iterating characters and slice where a match is found
for (CSStr itr = val.mPtr; *itr != '\0'; ++itr)
{
// Call the predicate with the current character
if ((fn(*itr) == 0) == neg)
{
// Are there any characters before this match?
if ((itr - last) > 0 && (last != '\0'))
{
// Push this chunk of string on the stack
sq_pushstring(vm, last, itr - last);
// Insert this element into the array on the stack
const SQRESULT r = sq_arrayappend(vm, -2);
// Did we fail to append the element?
if (SQ_FAILED(r))
{
return r; // We're done here
}
}
// Push this character as an integer on the stack
sq_pushinteger(vm, *itr);
// Insert this element into the array on the stack
const SQRESULT r = sq_arrayappend(vm, -2);
// Did we fail to append the element?
if (SQ_FAILED(r))
{
return r; // We're done here
}
// Update the position of the last found match
last = (itr + 1);
}
}
// Push the remaining chunk, if any
if (*last != '\0')
{
// Push this chunk of string on the stack
sq_pushstring(vm, last, -1);
// Insert this element into the array on the stack
const SQRESULT r = sq_arrayappend(vm, -2);
// Did we fail to append the element?
if (SQ_FAILED(r))
{
return r; // We're done here
}
}
// We have a value to return on the stack
return 1;
}
/* ------------------------------------------------------------------------------------------------
* Simple forwarder to minimize templated functions with large body and reduce executable size.
*/
template < int (*Fn)(int), bool Neg > static SQInteger SplitWhereCharProxy(HSQUIRRELVM vm)
{
return SplitWhereCharImpl(vm, Fn, Neg);
}
/* ------------------------------------------------------------------------------------------------
* Checks if the specified character is of the specified class.
*/
template < int (*Fn)(int) > static bool IsCharOfType(int c)
{
return (Fn(c) != 0);
}
// ------------------------------------------------------------------------------------------------
static bool OnlyDelimiter(CSStr str, SQChar chr)
{
while (*str != '\0')
{
// Is this different from the delimiter?
if (*(str++) != chr)
{
// Another character was found
return false;
}
}
// No other character was found
return true;
}
// ------------------------------------------------------------------------------------------------
static SQInteger SqStrExplode(HSQUIRRELVM vm)
{
const Int32 top = sq_gettop(vm);
// Was the delimiter character specified?
if (top <= 1)
{
return sq_throwerror(vm, _SC("Missing delimiter character"));
}
// Was the boolean empty specified?
else if (top <= 2)
{
return sq_throwerror(vm, _SC("Missing boolean empty"));
}
// Was the string value specified?
else if (top <= 3)
{
return sq_throwerror(vm, _SC("Missing string value"));
}
// Attempt to generate the string value
StackStrF val(vm, 4);
// Have we failed to retrieve the string?
if (SQ_FAILED(val.mRes))
{
return val.mRes; // Propagate the error!
}
// The delimiter character and boolean empty
SQChar delim = 0;
bool empty = 0;
// Attempt to retrieve the remaining arguments from the stack
try
{
delim = Var< SQChar >(vm, 2).value;
empty = Var< bool >(vm, 3).value;
}
catch (const Sqrat::Exception & e)
{
return sq_throwerror(vm, e.what());
}
catch (...)
{
return sq_throwerror(vm, _SC("Unable to retrieve arguments"));
}
// Grab the string value to a shorter name
CSStr str = val.mPtr;
// Create an empty array on the stack
sq_newarray(vm, 0);
// See if we actually have something to explode
if(!str || *str == '\0')
{
// Specify that we have an argument on the stack
return 1;
}
// Don't modify the specified string pointer
CSStr itr = str, last = str;
// The number of delimiter occurrences
Uint32 num = 0;
// Pre-count how many delimiters of this type exist
while (*itr != '\0')
{
// Is this our delimiter?
if (*(itr++) == delim)
{
// Are we allowed to include empty elements?
if (empty || (itr - last) > 1)
{
// Increase the count
++num;
}
// Update the last delimiter position
last = itr;
}
}
// Were there no delimiters found and can we include empty elements?
if (num == 0 && !empty && (str[1] == '\0' || OnlyDelimiter(str, delim)))
{
// Specify that we have an argument on the stack
return 1;
}
// Have we found any delimiters?
else if (num == 0)
{
// Test against strings with only delimiters
if (str[1] == '\0' || OnlyDelimiter(str, delim))
{
sq_pushstring(vm, _SC(""), 0); // Add an empty string
}
else
{
sq_pushstring(vm, val.mPtr, val.mLen); // Add the whole string
}
// Append the string on the stack to the array
const SQRESULT r = sq_arrayappend(vm, -2);
// Check the result
if (SQ_FAILED(r))
{
return r; // Propagate the error
}
// Specify that we have an argument on the stack
return 1;
}
// Is there anything after the last delimiter?
if (itr != last && *last != delim)
{
++num; // Add it to the counter
}
SQRESULT r = SQ_OK;
// Pre-allocate an array with the number of found delimiters
r = sq_arrayresize(vm, -1, num);
// Check the result
if (SQ_FAILED(r))
{
return r; // Propagate the error
}
// Don't modify the specified string pointer
itr = str, last = str;
// Reset the counter and use it as the element index
num = 0;
// Process the string again, this time slicing the actual elements
while (*itr != '\0')
{
// Is this our delimiter?
if (*itr++ == delim)
{
// Are we allowed to include empty elements?
if (empty || (itr - last) > 1)
{
// Push the element index on the stack and advance to the next one
sq_pushinteger(vm, num++);
// Push the string portion on the stack
sq_pushstring(vm, last, itr - last - 1);
// Assign the string onto the
r = sq_set(vm, -3);
// Check the result
if (SQ_FAILED(r))
{
return r; // Propagate the error
}
}
// Update the last delimiter position
last = itr;
}
}
// Is there anything after the last delimiter?
if (itr != last && *last != delim)
{
// Push the element index on the stack
sq_pushinteger(vm, num);
// Add the remaining string as an element
sq_pushstring(vm, last, itr - last);
// Assign the string onto the
r = sq_set(vm, -3);
// Check the result
if (SQ_FAILED(r))
{
return r; // Propagate the error
}
}
// Specify that we have an argument on the stack
return 1;
}
// ------------------------------------------------------------------------------------------------
static CSStr StrImplode(SQChar chr, Array & arr)
{
// Determine array size
const Int32 length = static_cast< Int32 >(arr.Length());
// Is there anything to implode?
if (length <= 0)
{
return _SC(""); // Default to an empty string
}
// Obtain a temporary buffer
Buffer b(length * 32);
// Process array elements
for (SQInteger i = 0; i < length; ++i)
{
// Retrieve the element value as string
SharedPtr< String > str = arr.GetValue< String >(i);
// Was there any value retrieved?
if (!!str)
{
// Append the value to the buffer
b.AppendS(str->data(), str->size());
}
// Append the delimiter
b.Push(chr);
}
// Move the cursor back one element
b.Retreat(1);
// Set that as the null character
b.Cursor() = '\0';
// Return the string
return b.Get< SQChar >();
}
// ------------------------------------------------------------------------------------------------
static CSStr FromArray(Array & arr)
{
// Determine array size
const Int32 length = ConvTo< Int32 >::From(arr.Length());
// Obtain a temporary buffer
Buffer b(length * sizeof(Int32));
// Get array elements as integers
arr.GetArray< Int32 >(b.Get< Int32 >(), length);
// Overwrite integers with characters
for (Int32 n = 0; n < length; ++n)
{
b.At(n) = ConvTo< SQChar >::From(b.At< Int32 >(n * sizeof(Int32)));
}
// Terminate the resulted string
b.At(length) = '\0';
// Return the string
return b.Get< SQChar >();
}
// ------------------------------------------------------------------------------------------------
static SQInteger StdPrintF(HSQUIRRELVM vm)
{
// Attempt to retrieve the value from the stack as a string
StackStrF val(vm, 2);
// Have we failed to retrieve the string?
if (SQ_FAILED(val.mRes))
{
return val.mRes; // Propagate the error!
}
// Send the resulted string to console as a user message
LogUsr("%s", val.mPtr);
// This function doesn't return anything
return 0;
}
// ================================================================================================
void Register_String(HSQUIRRELVM vm)
{
Table strns(vm);
strns.Func(_SC("FromArray"), &FromArray)
.SquirrelFunc(_SC("Explode"), &SqStrExplode)
.Func(_SC("Implode"), &StrImplode)
.FmtFunc(_SC("Center"), &SqCenterStr)
.FmtFunc(_SC("Left"), &SqLeftStr)
.FmtFunc(_SC("Right"), &SqRightStr)
.FmtFunc(_SC("LeftEx"), &SqLeftOffsetStr)
.FmtFunc(_SC("RightEx"), &SqRightOffsetStr)
.FmtFunc(_SC("ToLower"), &SqToLowercase)
.FmtFunc(_SC("ToUpper"), &SqToUppercase)
.FmtFunc(_SC("Lowercase"), &SqToLowercase)
.FmtFunc(_SC("Uppercase"), &SqToUppercase)
.FmtFunc(_SC("JustAlnum"), &SqJustAlphaNum)
.FmtFunc(_SC("AreAllSpace"), &SqAllChars< std::isspace >)
.FmtFunc(_SC("AreAllPrint"), &SqAllChars< std::isprint >)
.FmtFunc(_SC("AreAllCntrl"), &SqAllChars< std::iscntrl >)
.FmtFunc(_SC("AreAllUpper"), &SqAllChars< std::isupper >)
.FmtFunc(_SC("AreAllLower"), &SqAllChars< std::islower >)
.FmtFunc(_SC("AreAllAlpha"), &SqAllChars< std::isalpha >)
.FmtFunc(_SC("AreAllDigit"), &SqAllChars< std::isdigit >)
.FmtFunc(_SC("AreAllPunct"), &SqAllChars< std::ispunct >)
.FmtFunc(_SC("AreAllXdigit"), &SqAllChars< std::isxdigit >)
.FmtFunc(_SC("AreAllAlnum"), &SqAllChars< std::isalnum >)
.FmtFunc(_SC("AreAllGraph"), &SqAllChars< std::isgraph >)
.FmtFunc(_SC("AreAllBlank"), &SqAllChars< std::isblank >)
.FmtFunc(_SC("FirstSpace"), &SqFirstChar< std::isspace, false >)
.FmtFunc(_SC("FirstPrint"), &SqFirstChar< std::isprint, false >)
.FmtFunc(_SC("FirstCntrl"), &SqFirstChar< std::iscntrl, false >)
.FmtFunc(_SC("FirstUpper"), &SqFirstChar< std::isupper, false >)
.FmtFunc(_SC("FirstLower"), &SqFirstChar< std::islower, false >)
.FmtFunc(_SC("FirstAlpha"), &SqFirstChar< std::isalpha, false >)
.FmtFunc(_SC("FirstDigit"), &SqFirstChar< std::isdigit, false >)
.FmtFunc(_SC("FirstPunct"), &SqFirstChar< std::ispunct, false >)
.FmtFunc(_SC("FirstXdigit"), &SqFirstChar< std::isxdigit, false >)
.FmtFunc(_SC("FirstAlnum"), &SqFirstChar< std::isalnum, false >)
.FmtFunc(_SC("FirstGraph"), &SqFirstChar< std::isgraph, false >)
.FmtFunc(_SC("FirstBlank"), &SqFirstChar< std::isblank, false >)
.FmtFunc(_SC("FirstNotSpace"), &SqFirstChar< std::isspace, true >)
.FmtFunc(_SC("FirstNotPrint"), &SqFirstChar< std::isprint, true >)
.FmtFunc(_SC("FirstNotCntrl"), &SqFirstChar< std::iscntrl, true >)
.FmtFunc(_SC("FirstNotUpper"), &SqFirstChar< std::isupper, true >)
.FmtFunc(_SC("FirstNotLower"), &SqFirstChar< std::islower, true >)
.FmtFunc(_SC("FirstNotAlpha"), &SqFirstChar< std::isalpha, true >)
.FmtFunc(_SC("FirstNotDigit"), &SqFirstChar< std::isdigit, true >)
.FmtFunc(_SC("FirstNotPunct"), &SqFirstChar< std::ispunct, true >)
.FmtFunc(_SC("FirstNotXdigit"), &SqFirstChar< std::isxdigit, true >)
.FmtFunc(_SC("FirstNotAlnum"), &SqFirstChar< std::isalnum, true >)
.FmtFunc(_SC("FirstNotGraph"), &SqFirstChar< std::isgraph, true >)
.FmtFunc(_SC("FirstNotBlank"), &SqFirstChar< std::isblank, true >)
.FmtFunc(_SC("LastSpace"), &SqLastChar< std::isspace, false >)
.FmtFunc(_SC("LastPrint"), &SqLastChar< std::isprint, false >)
.FmtFunc(_SC("LastCntrl"), &SqLastChar< std::iscntrl, false >)
.FmtFunc(_SC("LastUpper"), &SqLastChar< std::isupper, false >)
.FmtFunc(_SC("LastLower"), &SqLastChar< std::islower, false >)
.FmtFunc(_SC("LastAlpha"), &SqLastChar< std::isalpha, false >)
.FmtFunc(_SC("LastDigit"), &SqLastChar< std::isdigit, false >)
.FmtFunc(_SC("LastPunct"), &SqLastChar< std::ispunct, false >)
.FmtFunc(_SC("LastXdigit"), &SqLastChar< std::isxdigit, false >)
.FmtFunc(_SC("LastAlnum"), &SqLastChar< std::isalnum, false >)
.FmtFunc(_SC("LastGraph"), &SqLastChar< std::isgraph, false >)
.FmtFunc(_SC("LastBlank"), &SqLastChar< std::isblank, false >)
.FmtFunc(_SC("LastNotSpace"), &SqLastChar< std::isspace, true >)
.FmtFunc(_SC("LastNotPrint"), &SqLastChar< std::isprint, true >)
.FmtFunc(_SC("LastNotCntrl"), &SqLastChar< std::iscntrl, true >)
.FmtFunc(_SC("LastNotUpper"), &SqLastChar< std::isupper, true >)
.FmtFunc(_SC("LastNotLower"), &SqLastChar< std::islower, true >)
.FmtFunc(_SC("LastNotAlpha"), &SqLastChar< std::isalpha, true >)
.FmtFunc(_SC("LastNotDigit"), &SqLastChar< std::isdigit, true >)
.FmtFunc(_SC("LastNotPunct"), &SqLastChar< std::ispunct, true >)
.FmtFunc(_SC("LastNotXdigit"), &SqLastChar< std::isxdigit, true >)
.FmtFunc(_SC("LastNotAlnum"), &SqLastChar< std::isalnum, true >)
.FmtFunc(_SC("LastNotGraph"), &SqLastChar< std::isgraph, true >)
.FmtFunc(_SC("LastNotBlank"), &SqLastChar< std::isblank, true >)
.SquirrelFunc(_SC("SplitWhereSpace"), &SplitWhereCharProxy< std::isspace, false >)
.SquirrelFunc(_SC("SplitWherePrint"), &SplitWhereCharProxy< std::isprint, false >)
.SquirrelFunc(_SC("SplitWhereCntrl"), &SplitWhereCharProxy< std::iscntrl, false >)
.SquirrelFunc(_SC("SplitWhereUpper"), &SplitWhereCharProxy< std::isupper, false >)
.SquirrelFunc(_SC("SplitWhereLower"), &SplitWhereCharProxy< std::islower, false >)
.SquirrelFunc(_SC("SplitWhereAlpha"), &SplitWhereCharProxy< std::isalpha, false >)
.SquirrelFunc(_SC("SplitWhereDigit"), &SplitWhereCharProxy< std::isdigit, false >)
.SquirrelFunc(_SC("SplitWherePunct"), &SplitWhereCharProxy< std::ispunct, false >)
.SquirrelFunc(_SC("SplitWhereXdigit"), &SplitWhereCharProxy< std::isxdigit, false >)
.SquirrelFunc(_SC("SplitWhereAlnum"), &SplitWhereCharProxy< std::isalnum, false >)
.SquirrelFunc(_SC("SplitWhereGraph"), &SplitWhereCharProxy< std::isgraph, false >)
.SquirrelFunc(_SC("SplitWhereBlank"), &SplitWhereCharProxy< std::isblank, false >)
.SquirrelFunc(_SC("SplitWhereNotSpace"), &SplitWhereCharProxy< std::isspace, true >)
.SquirrelFunc(_SC("SplitWhereNotPrint"), &SplitWhereCharProxy< std::isprint, true >)
.SquirrelFunc(_SC("SplitWhereNotCntrl"), &SplitWhereCharProxy< std::iscntrl, true >)
.SquirrelFunc(_SC("SplitWhereNotUpper"), &SplitWhereCharProxy< std::isupper, true >)
.SquirrelFunc(_SC("SplitWhereNotLower"), &SplitWhereCharProxy< std::islower, true >)
.SquirrelFunc(_SC("SplitWhereNotAlpha"), &SplitWhereCharProxy< std::isalpha, true >)
.SquirrelFunc(_SC("SplitWhereNotDigit"), &SplitWhereCharProxy< std::isdigit, true >)
.SquirrelFunc(_SC("SplitWhereNotPunct"), &SplitWhereCharProxy< std::ispunct, true >)
.SquirrelFunc(_SC("SplitWhereNotXdigit"), &SplitWhereCharProxy< std::isxdigit, true >)
.SquirrelFunc(_SC("SplitWhereNotAlnum"), &SplitWhereCharProxy< std::isalnum, true >)
.SquirrelFunc(_SC("SplitWhereNotGraph"), &SplitWhereCharProxy< std::isgraph, true >)
.SquirrelFunc(_SC("SplitWhereNotBlank"), &SplitWhereCharProxy< std::isblank, true >);
RootTable(vm).Bind(_SC("SqStr"), strns);
RootTable(vm).SquirrelFunc(_SC("printf"), &StdPrintF);
RootTable(vm)
.Func(_SC("IsSpace"), &IsCharOfType< std::isspace >)
.Func(_SC("IsPrint"), &IsCharOfType< std::isprint >)
.Func(_SC("IsCntrl"), &IsCharOfType< std::iscntrl >)
.Func(_SC("IsUpper"), &IsCharOfType< std::isupper >)
.Func(_SC("IsLower"), &IsCharOfType< std::islower >)
.Func(_SC("IsAlpha"), &IsCharOfType< std::isalpha >)
.Func(_SC("IsDigit"), &IsCharOfType< std::isdigit >)
.Func(_SC("IsPunct"), &IsCharOfType< std::ispunct >)
.Func(_SC("IsXdigit"), &IsCharOfType< std::isxdigit >)
.Func(_SC("IsAlnum"), &IsCharOfType< std::isalnum >)
.Func(_SC("IsGraph"), &IsCharOfType< std::isgraph >)
.Func(_SC("IsBlank"), &IsCharOfType< std::isblank >)
.Func(_SC("ToLower"), &tolower)
.Func(_SC("ToUpper"), &toupper);
2015-09-30 02:56:11 +02:00
}
} // Namespace:: SqMod