#ifndef LLARP_ALIGNED_HPP #define LLARP_ALIGNED_HPP #include #include #include #include #include #include #include namespace llarp { /// aligned buffer, sz must be multiple of 8 bytes template < size_t sz > struct AlignedBuffer { static_assert(sz % 8 == 0, "aligned buffer size is not a multiple of 8"); AlignedBuffer() = default; AlignedBuffer(const byte_t* data) { for(size_t idx = 0; idx < sz; ++idx) b[idx] = data[idx]; } AlignedBuffer& operator=(const byte_t* data) { for(size_t idx = 0; idx < sz; ++idx) b[idx] = data[idx]; return *this; } friend std::ostream& operator<<(std::ostream& out, const AlignedBuffer& self) { char tmp[(1 + sz) * 2] = {0}; return out << HexEncode(self, tmp); } bool operator==(const AlignedBuffer& other) const { return memcmp(data(), other.data(), sz) == 0; } bool operator!=(const AlignedBuffer& other) const { return !(*this == other); } size_t size() const { return sz; } size_t size() { return sz; } void Fill(byte_t f) { for(size_t idx = 0; idx < sz; ++idx) b[idx] = f; } void Zero() { for(size_t idx = 0; idx * 8 < sz; ++idx) l[idx] = 0; } void Randomize() { randombytes(b, sz); } byte_t* data() { return &b[0]; } const byte_t* data() const { return &b[0]; } uint64_t* data_l() { return &l[0]; } const uint64_t* data_l() const { return &l[0]; } operator const byte_t*() const { return &b[0]; } operator byte_t*() { return &b[0]; } bool BEncode(llarp_buffer_t* buf) const { return bencode_write_bytestring(buf, b, sz); } bool BDecode(llarp_buffer_t* buf) { llarp_buffer_t strbuf; if(!bencode_read_string(buf, &strbuf)) return false; if(strbuf.sz != sz) return false; memcpy(b, strbuf.base, sz); return true; } protected: union { byte_t b[sz]; uint64_t l[sz / 8]; }; }; } // namespace llarp #endif