#pragma once #include #include using namespace nall; using int8 = Integer< 8>; using int16 = Integer<16>; using int24 = Integer<24>; using int32 = Integer<32>; using int64 = Integer<64>; using uint8 = Natural< 8>; using uint16 = Natural<16>; using uint24 = Natural<24>; using uint32 = Natural<32>; using uint64 = Natural<64>; struct FX { auto open(string_vector& args) -> bool; auto close() -> void; auto readable() -> bool; auto read() -> uint8_t; auto writable() -> bool; auto write(uint8_t data) -> void; auto read(uint offset, uint length) -> vector; auto write(uint offset, const void* buffer, uint length) -> void; auto write(uint offset, const vector& buffer) -> void { write(offset, buffer.data(), buffer.size()); } auto execute(uint offset) -> void; auto read(uint offset) -> uint8_t; auto write(uint offset, uint8_t data) -> void; serial device; }; auto FX::open(string_vector& args) -> bool { //device name override support string name; for(uint n : range(args)) { if(args[n].beginsWith("--device=")) { name = args.take(n).trimLeft("--device=", 1L); break; } } if(!device.open(name)) { print("[21fx] error: unable to open hardware device\n"); return false; } //flush the device (to clear floating inputs) while(true) { while(readable()) read(); auto iplrom = read(0x2184, 122); auto sha256 = Hash::SHA256(iplrom.data(), iplrom.size()).digest(); if(sha256 == "41b79712a4a2d16d39894ae1b38cde5c41dad22eadc560df631d39f13df1e4b9") break; } return true; } auto FX::close() -> void { device.close(); } auto FX::readable() -> bool { return device.readable(); } //1000ns delay avoids burning CPU core at 100%; does not slow down max transfer rate at all auto FX::read() -> uint8_t { while(!readable()) usleep(1000); uint8_t buffer[1] = {0}; device.read(buffer, 1); return buffer[0]; } auto FX::writable() -> bool { return device.writable(); } auto FX::write(uint8_t data) -> void { while(!writable()) usleep(1000); uint8_t buffer[1] = {data}; device.write(buffer, 1); } // auto FX::read(uint offset, uint length) -> vector { write(0x21); write(0x66); write(0x78); write(offset >> 16); write(offset >> 8); write(offset >> 0); write(0x01); write(length >> 8); write(length >> 0); write(0x00); vector buffer; while(length--) buffer.append(read()); return buffer; } auto FX::write(uint offset, const void* data, uint length) -> void { write(0x21); write(0x66); write(0x78); write(offset >> 16); write(offset >> 8); write(offset >> 0); write(0x01); write(length >> 8); write(length >> 0); write(0x01); auto buffer = (uint8_t*)data; for(auto n : range(length)) write(buffer[n]); write(0x00); } auto FX::execute(uint offset) -> void { write(0x21); write(0x66); write(0x78); write(offset >> 16); write(offset >> 8); write(offset >> 0); write(0x00); } // auto FX::read(uint offset) -> uint8_t { auto buffer = read(offset, 1); return buffer[0]; } auto FX::write(uint offset, uint8_t data) -> void { vector buffer = {data}; write(offset, buffer); }