/** * Marlin 3D Printer Firmware * Copyright (c) 2020 MarlinFirmware [https://github.com/MarlinFirmware/Marlin] * * Based on Sprinter and grbl. * Copyright (c) 2011 Camiel Gubbels / Erik van der Zalm * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . * */ #ifdef __STM32F1__ #include "../../inc/MarlinConfig.h" #include "MarlinSerial.h" #include // Copied from ~/.platformio/packages/framework-arduinoststm32-maple/STM32F1/system/libmaple/usart_private.h // Changed to handle Emergency Parser static inline __always_inline void my_usart_irq(ring_buffer *rb, ring_buffer *wb, usart_reg_map *regs, MSerialT &serial) { /* Handle RXNEIE and TXEIE interrupts. * RXNE signifies availability of a byte in DR. * * See table 198 (sec 27.4, p809) in STM document RM0008 rev 15. * We enable RXNEIE. */ uint32_t srflags = regs->SR, cr1its = regs->CR1; if ((cr1its & USART_CR1_RXNEIE) && (srflags & USART_SR_RXNE)) { if (srflags & USART_SR_FE || srflags & USART_SR_PE ) { // framing error or parity error regs->DR; // Read and throw away the data, which also clears FE and PE } else { uint8_t c = (uint8)regs->DR; #ifdef USART_SAFE_INSERT // If the buffer is full and the user defines USART_SAFE_INSERT, // ignore new bytes. rb_safe_insert(rb, c); #else // By default, push bytes around in the ring buffer. rb_push_insert(rb, c); #endif #if ENABLED(EMERGENCY_PARSER) if (serial.emergency_parser_enabled()) emergency_parser.update(serial.emergency_state, c); #endif } } else if (srflags & USART_SR_ORE) { // overrun and empty data, just do a dummy read to clear ORE // and prevent a raise condition where a continous interrupt stream (due to ORE set) occurs // (see chapter "Overrun error" ) in STM32 reference manual regs->DR; } // TXE signifies readiness to send a byte to DR. if ((cr1its & USART_CR1_TXEIE) && (srflags & USART_SR_TXE)) { if (!rb_is_empty(wb)) regs->DR=rb_remove(wb); else regs->CR1 &= ~((uint32)USART_CR1_TXEIE); // disable TXEIE } } // Not every MarlinSerial port should handle emergency parsing. // It would not make sense to parse GCode from TMC responses, for example. constexpr bool serial_handles_emergency(int port) { return false #ifdef SERIAL_PORT || (SERIAL_PORT) == port #endif #ifdef SERIAL_PORT_2 || (SERIAL_PORT_2) == port #endif #ifdef LCD_SERIAL_PORT || (LCD_SERIAL_PORT) == port #endif ; } #define DEFINE_HWSERIAL_MARLIN(name, n) \ MSerialT name(serial_handles_emergency(n),\ USART##n, \ BOARD_USART##n##_TX_PIN, \ BOARD_USART##n##_RX_PIN); \ extern "C" void __irq_usart##n(void) { \ my_usart_irq(USART##n->rb, USART##n->wb, USART##n##_BASE, MSerial##n); \ } #define DEFINE_HWSERIAL_UART_MARLIN(name, n) \ MSerialT name(serial_handles_emergency(n), \ UART##n, \ BOARD_USART##n##_TX_PIN, \ BOARD_USART##n##_RX_PIN); \ extern "C" void __irq_usart##n(void) { \ my_usart_irq(UART##n->rb, UART##n->wb, UART##n##_BASE, MSerial##n); \ } // Instantiate all UARTs even if they are not needed // This avoids a bunch of logic to figure out every serial // port which may be in use on the system. #if DISABLED(MKS_WIFI_MODULE) DEFINE_HWSERIAL_MARLIN(MSerial1, 1); #endif DEFINE_HWSERIAL_MARLIN(MSerial2, 2); DEFINE_HWSERIAL_MARLIN(MSerial3, 3); #if EITHER(STM32_HIGH_DENSITY, STM32_XL_DENSITY) DEFINE_HWSERIAL_UART_MARLIN(MSerial4, 4); DEFINE_HWSERIAL_UART_MARLIN(MSerial5, 5); #endif // Check the type of each serial port by passing it to a template function. // HardwareSerial is known to sometimes hang the controller when an error occurs, // so this case will fail the static assert. All other classes are assumed to be ok. template constexpr bool IsSerialClassAllowed(const T&) { return true; } constexpr bool IsSerialClassAllowed(const HardwareSerial&) { return false; } #define CHECK_CFG_SERIAL(A) static_assert(IsSerialClassAllowed(A), STRINGIFY(A) " is defined incorrectly"); #define CHECK_AXIS_SERIAL(A) static_assert(IsSerialClassAllowed(A##_HARDWARE_SERIAL), STRINGIFY(A) "_HARDWARE_SERIAL must be defined in the form MSerial1, rather than Serial1"); // If you encounter this error, replace SerialX with MSerialX, for example MSerial3. // Non-TMC ports were already validated in HAL.h, so do not require verbose error messages. #ifdef MYSERIAL0 CHECK_CFG_SERIAL(MYSERIAL0); #endif #ifdef MYSERIAL1 CHECK_CFG_SERIAL(MYSERIAL1); #endif #ifdef LCD_SERIAL CHECK_CFG_SERIAL(LCD_SERIAL); #endif #if AXIS_HAS_HW_SERIAL(X) CHECK_AXIS_SERIAL(X); #endif #if AXIS_HAS_HW_SERIAL(X2) CHECK_AXIS_SERIAL(X2); #endif #if AXIS_HAS_HW_SERIAL(Y) CHECK_AXIS_SERIAL(Y); #endif #if AXIS_HAS_HW_SERIAL(Y2) CHECK_AXIS_SERIAL(Y2); #endif #if AXIS_HAS_HW_SERIAL(Z) CHECK_AXIS_SERIAL(Z); #endif #if AXIS_HAS_HW_SERIAL(Z2) CHECK_AXIS_SERIAL(Z2); #endif #if AXIS_HAS_HW_SERIAL(Z3) CHECK_AXIS_SERIAL(Z3); #endif #if AXIS_HAS_HW_SERIAL(Z4) CHECK_AXIS_SERIAL(Z4); #endif #if AXIS_HAS_HW_SERIAL(E0) CHECK_AXIS_SERIAL(E0); #endif #if AXIS_HAS_HW_SERIAL(E1) CHECK_AXIS_SERIAL(E1); #endif #if AXIS_HAS_HW_SERIAL(E2) CHECK_AXIS_SERIAL(E2); #endif #if AXIS_HAS_HW_SERIAL(E3) CHECK_AXIS_SERIAL(E3); #endif #if AXIS_HAS_HW_SERIAL(E4) CHECK_AXIS_SERIAL(E4); #endif #if AXIS_HAS_HW_SERIAL(E5) CHECK_AXIS_SERIAL(E5); #endif #if AXIS_HAS_HW_SERIAL(E6) CHECK_AXIS_SERIAL(E6); #endif #if AXIS_HAS_HW_SERIAL(E7) CHECK_AXIS_SERIAL(E7); #endif #endif // __STM32F1__