SuperMarioOdysseyOnline/include/sead/prim/seadSafeString.hpp

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2022-06-16 21:33:18 +00:00
#pragma once
#include <algorithm>
#include <type_traits>
#include <prim/seadMemUtil.h>
#ifndef SEAD_PRIM_SAFE_STRING_H_
#include <prim/seadSafeString.h>
#endif
namespace sead
{
template <typename T>
inline typename SafeStringBase<T>::token_iterator& SafeStringBase<T>::token_iterator::operator++()
{
s32 index = this->mIndex;
const s32 length = this->mString->calcLength();
if (0 <= index && index <= length)
{
while (true)
{
SEAD_ASSERT(0 <= index && index <= length);
if (this->mString->unsafeAt_(index) == cNullChar)
break;
if (mDelimiter.include(this->mString->unsafeAt_(index)))
break;
++index;
}
this->mIndex = index + 1;
}
else
{
SEAD_ASSERT_MSG(false, "index(%d) out of range [0, %d].\n", index, length);
}
return *this;
}
template <typename T>
inline typename SafeStringBase<T>::token_iterator& SafeStringBase<T>::token_iterator::operator--()
{
s32 index = this->mIndex;
const s32 length = this->mString->calcLength();
if (index == 0)
return *this;
if (index == 1)
{
this->mIndex = 0;
return *this;
}
if (0 <= index && index <= length + 1)
{
index -= 2;
s32 j;
while (true)
{
j = index;
SEAD_ASSERT(0 <= index && index <= length);
if (this->mString->unsafeAt_(index) == cNullChar)
break;
if (mDelimiter.include(this->mString->unsafeAt_(index)))
break;
--index;
if (j == 0)
{
j = index;
break;
}
}
this->mIndex = j + 1;
}
else
{
SEAD_ASSERT_MSG(false, "index(%d) out of range [0, %d].\n", index, length + 1);
}
return *this;
}
template <typename T>
inline s32 SafeStringBase<T>::token_iterator::get(BufferedSafeStringBase<T>* out) const
{
token_iterator it = *this;
++it;
const s32 part_length = it.getIndex() - this->getIndex() - 1;
const SafeStringBase<T> part = this->mString->getPart(*this);
return out->copy(part, part_length);
}
template <typename T>
inline s32 SafeStringBase<T>::token_iterator::getAndForward(BufferedSafeStringBase<T>* out)
{
s32 index = this->mIndex;
const s32 length = this->mString->calcLength();
if (index < 0 || index > length)
{
SEAD_ASSERT_MSG(false, "index(%d) out of range [0, %d].\n", index, length);
return 0;
}
T* outc = out->getBuffer();
const s32 out_max_length = out->getBufferSize() - 1;
s32 i = 0;
while (true)
{
SEAD_ASSERT(0 <= index && index <= length);
if (out_max_length < i)
{
SEAD_ASSERT_MSG(false, "token str exceeds out buffer length[%d]", out_max_length);
return 0;
}
const T& c = this->mString->unsafeAt_(index);
if (c == cNullChar || mDelimiter.include(c))
break;
outc[i] = c;
++i;
++index;
}
outc[i] = cNullChar;
this->mIndex = index + 1;
return i;
}
template <typename T>
inline s32 SafeStringBase<T>::token_iterator::cutOffGet(BufferedSafeStringBase<T>* out) const
{
token_iterator it = *this;
++it;
const s32 part_length = it.getIndex() - this->getIndex() - 1;
const SafeStringBase<T> part = this->mString->getPart(this->getIndex());
return out->cutOffCopy(part, part_length);
}
template <typename T>
inline s32 SafeStringBase<T>::token_iterator::cutOffGetAndForward(BufferedSafeStringBase<T>* out)
{
s32 index = this->mIndex;
const s32 length = this->mString->calcLength();
if (index < 0 || index > length)
{
SEAD_ASSERT_MSG(false, "index(%d) out of range [0, %d].\n", index, length);
return 0;
}
T* outc = out->getBuffer();
const s32 out_max_length = out->getBufferSize() - 1;
s32 i = 0;
while (true)
{
SEAD_ASSERT(0 <= index && index <= length);
const T& c = this->mString->unsafeAt_(index);
if (c == cNullChar || mDelimiter.include(c))
break;
if (i < out_max_length)
outc[i++] = c;
++index;
}
SEAD_ASSERT(i <= out_max_length);
outc[i] = cNullChar;
this->mIndex = index + 1;
return i;
}
template <typename T>
inline const T& SafeStringBase<T>::at(s32 idx) const
{
const int length = calcLength();
if (idx < 0 || idx > length)
{
SEAD_ASSERT_MSG(false, "index(%d) out of range[0, %d]", idx, length);
return cNullChar;
}
return mStringTop[idx];
}
template <typename T>
inline SafeStringBase<T> SafeStringBase<T>::getPart(s32 at) const
{
s32 len = calcLength();
if (at < 0 || at > len)
{
SEAD_ASSERT_MSG(false, "index(%d) out of range[0, %d]", at, len);
return SafeStringBase<T>::cEmptyString;
}
return SafeStringBase<T>(mStringTop + at);
}
template <typename T>
inline SafeStringBase<T> SafeStringBase<T>::getPart(const SafeStringBase::iterator& it) const
{
return getPart(it.getIndex());
}
template <typename T>
inline SafeStringBase<T> SafeStringBase<T>::getPart(const SafeStringBase::token_iterator& it) const
{
return getPart(it.getIndex());
}
template <typename T>
inline s32 SafeStringBase<T>::calcLength() const
{
SEAD_ASSERT(mStringTop);
assureTerminationImpl_();
s32 length = 0;
for (;;)
{
if (length > cMaximumLength || mStringTop[length] == cNullChar)
break;
length++;
}
if (length > cMaximumLength)
{
SEAD_ASSERT_MSG(false, "too long string");
return 0;
}
return length;
}
template <typename T>
inline bool SafeStringBase<T>::include(const T& c) const
{
assureTerminationImpl_();
for (s32 i = 0; i <= cMaximumLength; ++i)
{
if (unsafeAt_(i) == cNullChar)
break;
if (unsafeAt_(i) == c)
return true;
}
return false;
}
template <typename T>
inline bool SafeStringBase<T>::include(const SafeStringBase<T>& str) const
{
return findIndex(str) != -1;
}
template <typename T>
inline bool SafeStringBase<T>::isEqual(const SafeStringBase<T>& str) const
{
assureTerminationImpl_();
if (cstr() == str.cstr())
return true;
for (s32 i = 0; i <= cMaximumLength; i++)
{
if (unsafeAt_(i) != str.unsafeAt_(i))
return false;
if (unsafeAt_(i) == cNullChar)
return true;
}
SEAD_ASSERT_MSG(false, "too long string\n");
return false;
}
template <typename T>
inline s32 SafeStringBase<T>::comparen(const SafeStringBase<T>& str, s32 n) const
{
assureTerminationImpl_();
const char* top = cstr();
if (top == str.cstr())
return 0;
if (n > cMaximumLength)
{
SEAD_ASSERT_MSG(false, "paramater(%d) out of bounds [0, %d]", n, cMaximumLength);
n = cMaximumLength;
}
for (s32 i = 0; i < n; ++i)
{
const s32 cmp = unsafeAt_(i) - str.unsafeAt_(i);
if (cmp != 0)
return cmp < 0 ? -1 : 1;
if (unsafeAt_(i) == cNullChar)
return 0;
}
return 0;
}
template <typename T>
inline s32 SafeStringBase<T>::findIndex(const SafeStringBase<T>& str) const
{
const s32 len = calcLength();
const s32 sub_str_len = str.calcLength();
for (s32 i = 0; i <= len - sub_str_len; ++i)
{
if (SafeStringBase<T>(&mStringTop[i]).comparen(str, sub_str_len) == 0)
return i;
}
return -1;
}
template <typename T>
inline s32 SafeStringBase<T>::findIndex(const SafeStringBase<T>& str, s32 start_pos) const
{
const s32 len = calcLength();
if (start_pos < 0 || start_pos > len)
{
SEAD_ASSERT_MSG(false, "start_pos(%d) out of range[0, %d]", start_pos, len);
return -1;
}
const s32 sub_str_len = str.calcLength();
for (s32 i = start_pos; i <= len - sub_str_len; ++i)
{
if (SafeStringBase<T>(&mStringTop[i]).comparen(str, sub_str_len) == 0)
return i;
}
return -1;
}
template <typename T>
inline s32 SafeStringBase<T>::rfindIndex(const SafeStringBase<T>& str) const
{
const s32 len = calcLength();
const s32 sub_str_len = str.calcLength();
for (s32 i = len - sub_str_len; i >= 0; --i)
{
if (SafeStringBase<T>(&mStringTop[i]).comparen(str, sub_str_len) == 0)
return i;
}
return -1;
}
template <typename T>
inline bool SafeStringBase<T>::isEmpty() const
{
return unsafeAt_(0) == cNullChar;
}
template <typename T>
inline bool SafeStringBase<T>::startsWith(const SafeStringBase<T>& prefix) const
{
const T* strc = mStringTop;
const T* prefixc = prefix.mStringTop;
s32 i = 0;
while (prefixc[i] != cNullChar)
{
if (strc[i] != prefixc[i])
return false;
++i;
}
return true;
}
template <typename T>
inline bool SafeStringBase<T>::endsWith(const SafeStringBase<T>& suffix) const
{
const s32 sub_str_len = suffix.calcLength();
if (sub_str_len == 0)
return true;
const T* strc = mStringTop;
const T* suffixc = suffix.mStringTop;
const s32 len = calcLength();
if (len < sub_str_len)
return false;
for (s32 i = 0; i < sub_str_len; ++i)
{
if (strc[len - sub_str_len + i] != suffixc[i])
return false;
}
return true;
}
template <typename T>
inline const T& BufferedSafeStringBase<T>::operator[](s32 idx) const
{
if (idx >= 0 && idx < this->mBufferSize)
return this->mStringTop[idx];
SEAD_ASSERT_MSG(false, "index(%d) out of range[0, %d]", idx, this->mBufferSize - 1);
return this->cNullChar;
}
template <typename T>
inline s32 BufferedSafeStringBase<T>::copy(const SafeStringBase<T>& src, s32 copyLength)
{
T* dst = getMutableStringTop_();
const T* csrc = src.cstr();
if (dst == csrc)
return 0;
if (copyLength < 0)
copyLength = src.calcLength();
if (copyLength >= mBufferSize)
{
SEAD_ASSERT_MSG(false, "Buffer overflow. (Buffer Size: %d, Copy Size: %d)", mBufferSize,
copyLength);
copyLength = mBufferSize - 1;
}
MemUtil::copy(dst, csrc, copyLength * sizeof(T));
dst[copyLength] = SafeStringBase<T>::cNullChar;
return copyLength;
}
template <typename T>
inline s32 BufferedSafeStringBase<T>::copyAt(s32 at, const SafeStringBase<T>& src, s32 copyLength)
{
T* dst = getMutableStringTop_();
s32 len = this->calcLength();
if (at < 0)
{
at = len + at + 1;
if (at < 0)
{
SEAD_ASSERT_MSG(false, "at(%d) out of range[0, %d]", at, len);
at = 0;
}
}
if (copyLength < 0)
copyLength = src.calcLength();
if (copyLength >= mBufferSize - at)
{
SEAD_ASSERT_MSG(false, "Buffer overflow. (Buffer Size: %d, At: %d, Copy Length: %d)",
mBufferSize, at, copyLength);
copyLength = mBufferSize - at - 1;
}
if (copyLength <= 0)
return 0;
MemUtil::copy(dst + at, src.cstr(), copyLength * sizeof(T));
if (at + copyLength > len)
dst[at + copyLength] = SafeStringBase<T>::cNullChar;
return copyLength;
}
template <typename T>
inline s32 BufferedSafeStringBase<T>::cutOffCopy(const SafeStringBase<T>& src, s32 copyLength)
{
T* dst = getMutableStringTop_();
const T* csrc = src.cstr();
if (dst == csrc)
return 0;
if (copyLength < 0)
copyLength = src.calcLength();
if (copyLength >= mBufferSize)
copyLength = mBufferSize - 1;
MemUtil::copy(dst, csrc, copyLength * sizeof(T));
dst[copyLength] = SafeStringBase<T>::cNullChar;
return copyLength;
}
template <typename T>
inline s32 BufferedSafeStringBase<T>::cutOffCopyAt(s32 at, const SafeStringBase<T>& src,
s32 copyLength)
{
T* dst = getMutableStringTop_();
s32 len = this->calcLength();
if (at < 0)
{
at = len + at + 1;
if (at < 0)
at = 0;
}
if (copyLength < 0)
copyLength = src.calcLength();
if (copyLength >= mBufferSize - at)
copyLength = mBufferSize - at - 1;
if (copyLength <= 0)
return 0;
MemUtil::copy(dst + at, src.cstr(), copyLength * sizeof(T));
if (at + copyLength > len)
dst[at + copyLength] = SafeStringBase<T>::cNullChar;
return copyLength;
}
template <typename T>
inline s32 BufferedSafeStringBase<T>::copyAtWithTerminate(s32 at, const SafeStringBase<T>& src,
s32 copyLength)
{
T* dst = getMutableStringTop_();
if (at < 0)
{
const s32 len = this->calcLength();
at = len + at + 1;
if (at < 0)
{
SEAD_ASSERT_MSG(false, "at(%d) out of range[0, %d]", at, len);
at = 0;
}
}
if (copyLength < 0)
copyLength = src.calcLength();
if (copyLength >= mBufferSize - at)
{
SEAD_ASSERT_MSG(false, "Buffer overflow. (Buffer Size: %d, At: %d, Copy Length: %d)",
mBufferSize, at, copyLength);
copyLength = mBufferSize - at - 1;
}
if (copyLength <= 0)
return 0;
MemUtil::copy(dst + at, src.cstr(), copyLength * sizeof(T));
dst[at + copyLength] = SafeStringBase<T>::cNullChar;
return copyLength;
}
template <typename T>
inline s32 BufferedSafeStringBase<T>::append(const SafeStringBase<T>& str, s32 append_length)
{
return copyAt(-1, str, append_length);
}
template <typename T>
inline s32 BufferedSafeStringBase<T>::append(T c, s32 num)
{
if (num < 0)
{
SEAD_ASSERT_MSG(false, "append error. num < 0, num = %d", num);
return 0;
}
if (num < 1)
return 0;
const s32 length = this->calcLength();
if (getBufferSize() - length <= num)
{
SEAD_ASSERT_MSG(false, "Buffer overflow. (Buffer Size: %d, Length: %d, Num: %d)",
getBufferSize(), length, num);
num = getBufferSize() - length - 1;
}
T* top = getMutableStringTop_();
for (s32 i = 0; i < num; ++i)
top[length + i] = c;
top[num + length] = this->cNullChar;
return num;
}
template <typename T>
s32 BufferedSafeStringBase<T>::prepend(const SafeStringBase<T>& str, s32 prepend_length)
{
if (prepend_length == -1)
prepend_length = str.calcLength();
s32 length = this->calcLength();
T* buffer = getMutableStringTop_();
const s32 buffer_size = mBufferSize;
if (prepend_length >= buffer_size - length)
{
SEAD_ASSERT_MSG(false, "Buffer overflow. (Buffer Size: %d, Length: %d, Prepend Length: %d)",
buffer_size, length, prepend_length);
if (prepend_length >= buffer_size)
prepend_length = buffer_size - 1;
length = buffer_size + (-prepend_length - 1);
}
MemUtil::copyOverlap(&buffer[prepend_length], buffer, length * sizeof(T));
MemUtil::copy(buffer, str.cstr(), prepend_length * sizeof(T));
buffer[length + prepend_length] = SafeStringBase<T>::cNullChar;
return length + prepend_length;
}
// UNCHECKED
template <typename T>
inline s32 BufferedSafeStringBase<T>::chop(s32 chop_num)
{
s32 length = this->calcLength();
T* buffer = getMutableStringTop_();
const auto fail = [=] {
SEAD_ASSERT_MSG(false, "chop_num(%d) out of range[0, %d]", chop_num, length);
};
if (chop_num < 0)
{
fail();
return 0;
}
if (chop_num > length)
{
fail();
chop_num = length;
}
const s32 new_length = length - chop_num;
buffer[new_length] = SafeStringBase<T>::cNullChar;
return chop_num;
}
// UNCHECKED
template <typename T>
inline s32 BufferedSafeStringBase<T>::chopMatchedChar(T c)
{
const s32 length = this->calcLength();
if (length < 1)
return 0;
const s32 new_length = length - 1;
T* buffer = getMutableStringTop_();
if (buffer[new_length] == c)
{
buffer[new_length] = SafeStringBase<T>::cNullChar;
return 1;
}
return 0;
}
// UNCHECKED
template <typename T>
inline s32 BufferedSafeStringBase<T>::chopMatchedChar(const T* characters)
{
const s32 length = this->calcLength();
if (length < 1)
return 0;
T* buffer = getMutableStringTop_();
for (const T* it = characters; *it; ++it)
{
if (buffer[length - 1] == *it)
{
buffer[length - 1] = SafeStringBase<T>::cNullChar;
return 1;
}
}
return 0;
}
// UNCHECKED
template <typename T>
inline s32 BufferedSafeStringBase<T>::chopUnprintableAsciiChar()
{
const s32 length = this->calcLength();
if (length < 1)
return 0;
T* buffer = getMutableStringTop_();
if (buffer[length - 1] <= ' ' || buffer[length - 1] == 0x7F)
{
buffer[length - 1] = this->cNullChar;
return 1;
}
return 0;
}
// UNCHECKED
template <typename T>
inline s32 BufferedSafeStringBase<T>::rstrip(const T* characters)
{
const s32 length = this->calcLength();
if (length <= 0)
return 0;
T* buffer = getMutableStringTop_();
s32 new_length = length;
const auto should_strip = [characters, buffer](s32 idx) {
for (auto it = characters; *it; ++it)
{
if (buffer[idx] == *it)
return true;
}
return false;
};
while (new_length >= 1 && should_strip(new_length - 1))
--new_length;
if (length <= new_length)
return 0;
buffer[new_length] = SafeStringBase<T>::cNullChar;
return length - new_length;
}
// UNCHECKED
template <typename T>
inline s32 BufferedSafeStringBase<T>::rstripUnprintableAsciiChars()
{
const s32 length = this->calcLength();
if (length < 1)
return 0;
T* buffer = getMutableStringTop_();
s32 new_length = length;
while (new_length && (buffer[new_length - 1] <= 0x20 || buffer[new_length - 1] == 0x7F))
--new_length;
if (length <= new_length)
return 0;
buffer[new_length] = this->cNullChar;
return length - new_length;
}
template <typename T>
inline s32 BufferedSafeStringBase<T>::trim(s32 trim_length)
{
T* mutableString = getMutableStringTop_();
if (trim_length >= mBufferSize)
{
SEAD_ASSERT_MSG(false, "trim_length(%d) out of bounds. [0, %d)", trim_length, mBufferSize);
return this->calcLength();
}
if (trim_length < 0)
{
SEAD_ASSERT_MSG(false, "trim_length(%d) out of bounds. [0, %d)", trim_length, mBufferSize);
trim_length = 0;
}
mutableString[trim_length] = SafeStringBase<T>::cNullChar;
return trim_length;
}
template <typename T>
inline s32 calcStrLength_(const T* str)
{
s32 len = 0;
while (str[len])
++len;
return len;
}
template <typename T>
inline s32 BufferedSafeStringBase<T>::trimMatchedString(const SafeStringBase<T>& suffix)
{
const s32 length = this->calcLength();
T* buffer = getMutableStringTop_();
const s32 suffix_length = suffix.calcLength();
const s32 new_length = length - suffix_length;
if (length < suffix_length)
return length;
if (SafeStringBase<T>(&buffer[new_length]).comparen(suffix, suffix_length) != 0)
return length;
buffer[new_length] = SafeStringBase<T>::cNullChar;
return new_length;
}
// UNCHECKED
template <typename T>
inline s32 BufferedSafeStringBase<T>::replaceChar(T old_char, T new_char)
{
const s32 length = this->calcLength();
T* buffer = getMutableStringTop_();
s32 replaced_count = 0;
for (s32 i = 0; i < length; ++i)
{
if (buffer[i] == old_char)
{
++replaced_count;
buffer[i] = new_char;
}
}
return replaced_count;
}
template <typename T>
inline s32 BufferedSafeStringBase<T>::replaceCharList(const SafeStringBase<T>& old_chars,
const SafeStringBase<T>& new_chars)
{
const s32 length = this->calcLength();
T* buffer = getMutableStringTop_();
s32 old_chars_len = old_chars.calcLength();
const s32 new_chars_len = new_chars.calcLength();
if (old_chars_len != new_chars_len)
{
// yes, this is undefined behavior for T = char16. Nintendo, fix your code
SEAD_ASSERT_MSG(false, "old_chars(%s).length is not equal to new_chars(%s).length.",
old_chars.cstr(), new_chars.cstr());
if (old_chars_len > new_chars_len)
old_chars_len = new_chars_len;
}
const T* old_chars_c = old_chars.cstr();
const T* new_chars_c = new_chars.cstr();
s32 replaced_count = 0;
for (s32 i = 0; i < length; ++i)
{
for (s32 character_idx = 0; character_idx < old_chars_len; ++character_idx)
{
if (buffer[i] == old_chars_c[character_idx])
{
++replaced_count;
buffer[i] = new_chars_c[character_idx];
break;
}
}
}
return replaced_count;
}
template <typename T>
inline s32 BufferedSafeStringBase<T>::setReplaceString(const SafeStringBase<T>& target_str,
const SafeStringBase<T>& old_str,
const SafeStringBase<T>& new_str)
{
bool is_buffer_overflow = false;
const s32 ret =
replaceStringImpl_(getMutableStringTop_(), nullptr, getBufferSize(), target_str.cstr(),
target_str.calcLength(), old_str, new_str, &is_buffer_overflow);
SEAD_ASSERT_MSG(!is_buffer_overflow, "Buffer overflow! (%s : s/%s/%s/g, Buffer Size: %d )",
target_str.cstr(), old_str.cstr(), new_str.cstr(), getBufferSize());
return ret;
}
template <typename T>
inline s32 BufferedSafeStringBase<T>::replaceString(const SafeStringBase<T>& old_str,
const SafeStringBase<T>& new_str)
{
bool is_buffer_overflow = false;
const s32 ret =
replaceStringImpl_(getMutableStringTop_(), nullptr, getBufferSize(), this->cstr(),
this->calcLength(), old_str, new_str, &is_buffer_overflow);
SEAD_ASSERT_MSG(!is_buffer_overflow,
"Buffer overflow! (%s(replacing) : s/%s/%s/g, Buffer Size: %d )", this->cstr(),
old_str.cstr(), new_str.cstr(), getBufferSize());
return ret;
}
template <typename T>
template <typename OtherType>
inline s32 BufferedSafeStringBase<T>::convertFromOtherType_(const SafeStringBase<OtherType>& src,
s32 src_size)
{
s32 copy_size = src.calcLength();
if (src_size != -1)
{
if (src_size < 0)
{
SEAD_ASSERT_MSG(false, "src_size(%d) out of bounds [%d,%d]", src_size, 0, copy_size);
copy_size = 0;
return copy_size;
}
if (copy_size < src_size)
SEAD_ASSERT_MSG(false, "src_size(%d) out of bounds [%d,%d]", src_size, 0, copy_size);
else
copy_size = src_size;
}
if (getBufferSize() <= copy_size)
{
SEAD_ASSERT_MSG(false, "copy_size(%d) out of bounds[%d, %d)", copy_size, 0,
getBufferSize());
copy_size = getBufferSize() - 1;
}
T* raw_dst = getMutableStringTop_();
const OtherType* raw_src = src.cstr();
for (s32 i = 0; i < copy_size; ++i)
raw_dst[i] = raw_src[i];
raw_dst[copy_size] = this->cNullChar;
return copy_size;
}
template <typename T>
inline s32 BufferedSafeStringBase<T>::convertFromMultiByteString(const SafeStringBase<char>& str,
s32 str_length)
{
if constexpr (std::is_same<char, T>())
return copy(str, str_length);
else
return convertFromOtherType_(str, str_length);
}
template <typename T>
inline s32 BufferedSafeStringBase<T>::convertFromWideCharString(const SafeStringBase<char16>& str,
s32 str_length)
{
if constexpr (std::is_same<char16, T>())
return copy(str, str_length);
else
return convertFromOtherType_(str, str_length);
}
} // namespace sead