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mirror of https://github.com/VCMP-SqMod/SqMod.git synced 2024-11-09 01:07:16 +01:00
SqMod/source/Library/String.cpp
Sandu Liviu Catalin f300e7ff4a Massive code reduction in the binding utility by using variadic templates.
Extensive code refactoring surrounding the StackStrF helper to facilitate the new changes.
Various other miscellaneous changes and code refactoring to facilitate the new changes.
2018-07-30 00:58:27 +03:00

951 lines
34 KiB
C++

// ------------------------------------------------------------------------------------------------
#include "Library/String.hpp"
#include "Base/Shared.hpp"
#include "Base/Buffer.hpp"
// ------------------------------------------------------------------------------------------------
#include <cctype>
#include <cstdio>
#include <cstdlib>
#include <cstring>
// ------------------------------------------------------------------------------------------------
#include <algorithm>
// ------------------------------------------------------------------------------------------------
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)
{
// 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.Proc(true)))
{
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.Proc(true)))
{
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.Proc(true)))
{
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);
}
} // Namespace:: SqMod