#pragma once namespace nall { //nall::format is a vector of parameters that can be applied to a string //each {#} token will be replaced with its appropriate format parameter auto string::format(const nall::string_format& params) -> type& { auto size = (int)this->size(); auto data = (char*)memory::allocate(size); memory::copy(data, this->data(), size); int x = 0; while(x < size - 2) { //2 = minimum tag length if(data[x] != '{') { x++; continue; } int y = x + 1; while(y < size - 1) { //-1 avoids going out of bounds on test after this loop if(data[y] != '}') { y++; continue; } break; } if(data[y++] != '}') { x++; continue; } static auto isNumeric = [](char* s, char* e) -> bool { if(s == e) return false; //ignore empty tags: {} while(s < e) { if(*s >= '0' && *s <= '9') { s++; continue; } return false; } return true; }; if(!isNumeric(&data[x + 1], &data[y - 1])) { x++; continue; } uint index = toNatural(&data[x + 1]); if(index >= params.size()) { x++; continue; } uint sourceSize = y - x; uint targetSize = params[index].size(); uint remaining = size - x; if(sourceSize > targetSize) { uint difference = sourceSize - targetSize; memory::move(&data[x], &data[x + difference], remaining); size -= difference; } else if(targetSize > sourceSize) { uint difference = targetSize - sourceSize; data = (char*)realloc(data, size + difference); size += difference; memory::move(&data[x + difference], &data[x], remaining); } memory::copy(&data[x], params[index].data(), targetSize); x += targetSize; } resize(size); memory::copy(get(), data, size); memory::free(data); return *this; } template auto string_format::append(const T& value, P&&... p) -> string_format& { vector::append(value); return append(forward

(p)...); } auto string_format::append() -> string_format& { return *this; } template auto print(P&&... p) -> void { string s{forward

(p)...}; fwrite(s.data(), 1, s.size(), stdout); } template auto print(FILE* fp, P&&... p) -> void { string s{forward

(p)...}; fwrite(s.data(), 1, s.size(), fp); } template auto pad(const T& value, long precision, char padchar) -> string { string buffer{value}; if(precision) buffer.size(precision, padchar); return buffer; } auto hex(uintmax value, long precision, char padchar) -> string { string buffer; buffer.resize(sizeof(uintmax) * 2); char* p = buffer.get(); uint size = 0; do { uint n = value & 15; p[size++] = n < 10 ? '0' + n : 'a' + n - 10; value >>= 4; } while(value); buffer.resize(size); buffer.reverse(); if(precision) buffer.size(precision, padchar); return buffer; } auto octal(uintmax value, long precision, char padchar) -> string { string buffer; buffer.resize(sizeof(uintmax) * 3); char* p = buffer.get(); uint size = 0; do { p[size++] = '0' + (value & 7); value >>= 3; } while(value); buffer.resize(size); buffer.reverse(); if(precision) buffer.size(precision, padchar); return buffer; } auto binary(uintmax value, long precision, char padchar) -> string { string buffer; buffer.resize(sizeof(uintmax) * 8); char* p = buffer.get(); uint size = 0; do { p[size++] = '0' + (value & 1); value >>= 1; } while(value); buffer.resize(size); buffer.reverse(); if(precision) buffer.size(precision, padchar); return buffer; } template auto pointer(const T* value, long precision) -> string { if(value == nullptr) return "(nullptr)"; return {"0x", hex((uintptr)value, precision)}; } auto pointer(uintptr value, long precision) -> string { if(value == 0) return "(nullptr)"; return {"0x", hex(value, precision)}; } /* auto real(long double value) -> string { string temp; temp.resize(fromReal(nullptr, value)); fromReal(temp.get(), value); return temp; } */ }