public void InitTest() { var stmcan = new STMCAN(new Machine()); stmcan.Reset(); // Registers can only be accessed by words (32 bits) // --> check this // ##################################### // ### Check reset values of CAN control and status registers // --- CAN_MCR Assert.AreEqual(stmcan.ReadDoubleWord(0x00), 0x00010002); // --- CAN_MSR Assert.AreEqual(stmcan.ReadDoubleWord(0x04), 0x00000C02); // --- CAN_TSR Assert.AreEqual(stmcan.ReadDoubleWord(0x08), 0x1C000000); // --- CAN_RF0R Assert.AreEqual(stmcan.ReadDoubleWord(0x0C), 0x00000000); // --- CAN_RF1R Assert.AreEqual(stmcan.ReadDoubleWord(0x10), 0x00000000); // --- CAN_IER Assert.AreEqual(stmcan.ReadDoubleWord(0x14), 0x00000000); // --- CAN_ESR Assert.AreEqual(stmcan.ReadDoubleWord(0x18), 0x00000000); // --- CAN_BTR (Can only be accessed during Initialization mode) Assert.AreEqual(stmcan.ReadDoubleWord(0x1C), 0x00000000); // Cannot read // Change to Initialization mode by setting INRQ (bit0) in CAN_MCR register stmcan.WriteDoubleWord(0x00, 0x00010001); // Verify Initialization mode by checking INAK bit set in CAN_MSR // and that SLAK bit is cleared Assert.AreEqual(stmcan.ReadDoubleWord(0x04), 0x00000C01); Assert.AreEqual(stmcan.ReadDoubleWord(0x1C), 0x01230000); // ##################################### // ### Check CAN mailbox registers stmcan.Reset(); // --- CAN_TIxR - TXRQ reset value 0 (bit0) Assert.AreEqual(stmcan.ReadDoubleWord(0x180) & 0x1, 0x0); Assert.AreEqual(stmcan.ReadDoubleWord(0x190) & 0x1, 0x0); Assert.AreEqual(stmcan.ReadDoubleWord(0x1A0) & 0x1, 0x0); // --- CAN_TDTxR - bits 15:9, 7:4 are reserved Assert.AreEqual(stmcan.ReadDoubleWord(0x184), 0x0); Assert.AreEqual(stmcan.ReadDoubleWord(0x194), 0x0); Assert.AreEqual(stmcan.ReadDoubleWord(0x1A4), 0x0); // --- CAN_TDLxR - reset value undefined, model should reset to 0 Assert.AreEqual(stmcan.ReadDoubleWord(0x188), 0x0); Assert.AreEqual(stmcan.ReadDoubleWord(0x198), 0x0); Assert.AreEqual(stmcan.ReadDoubleWord(0x1A8), 0x0); // --- CAN_TDHxR - reset value undefined, model should reset to 0 Assert.AreEqual(stmcan.ReadDoubleWord(0x18C), 0x0); Assert.AreEqual(stmcan.ReadDoubleWord(0x19C), 0x0); Assert.AreEqual(stmcan.ReadDoubleWord(0x1AC), 0x0); // All RX registers are write protected // --- CAN_RIxR - reset value undefined, bit0 reserved stmcan.WriteDoubleWord(0x1B0, 0xFF0000FF); stmcan.WriteDoubleWord(0x1C0, 0xFF0000FF); Assert.AreEqual(stmcan.ReadDoubleWord(0x1B0) & 0x1, 0x0); Assert.AreEqual(stmcan.ReadDoubleWord(0x1C0) & 0x1, 0x0); // --- CAN_RDTxR - reset value undefined, bit7:4 reserved stmcan.WriteDoubleWord(0x1B4, 0xFF0000FF); stmcan.WriteDoubleWord(0x1C4, 0xFF0000FF); Assert.AreEqual(stmcan.ReadDoubleWord(0x1B4) & 0x10, 0x0); Assert.AreEqual(stmcan.ReadDoubleWord(0x1C4) & 0x10, 0x0); // --- CAN_RDLxR - reset value undefined, model should reset to 0 stmcan.WriteDoubleWord(0x1B8, 0xFF0000FF); stmcan.WriteDoubleWord(0x1C8, 0xFF0000FF); Assert.AreEqual(stmcan.ReadDoubleWord(0x1B8), 0x0); Assert.AreEqual(stmcan.ReadDoubleWord(0x1C8), 0x0); // --- CAN_RDHxR - reset value undefined, model should reset to 0 stmcan.WriteDoubleWord(0x1BC, 0xFF0000FF); stmcan.WriteDoubleWord(0x1CC, 0xFF0000FF); Assert.AreEqual(stmcan.ReadDoubleWord(0x1BC), 0x0); Assert.AreEqual(stmcan.ReadDoubleWord(0x1CC), 0x0); // ##################################### // ### Check CAN filter registers stmcan.Reset(); // --- CAN_FMR Assert.AreEqual(stmcan.ReadDoubleWord(0x200), 0x2A1C0E01); // --- CAN_FM1R - can only be written in filter initialization mode Assert.AreEqual(stmcan.ReadDoubleWord(0x204), 0x00000000); stmcan.WriteDoubleWord(0x204, 0xFF0000FF); Assert.AreEqual(stmcan.ReadDoubleWord(0x204), 0xFF0000FF); stmcan.WriteDoubleWord(0x200, 0x2A1C0E00); Assert.AreEqual(stmcan.ReadDoubleWord(0x200), 0x2A1C0E00); stmcan.WriteDoubleWord(0x204, 0x00FFFF00); Assert.AreEqual(stmcan.ReadDoubleWord(0x204), 0xFF0000FF); stmcan.WriteDoubleWord(0x200, 0x2A1C0E01); // --- CAN_FS1R Assert.AreEqual(stmcan.ReadDoubleWord(0x20C), 0x00000000); stmcan.WriteDoubleWord(0x20C, 0xFF0000FF); Assert.AreEqual(stmcan.ReadDoubleWord(0x20C), 0xFF0000FF); stmcan.WriteDoubleWord(0x200, 0x2A1C0E00); Assert.AreEqual(stmcan.ReadDoubleWord(0x200), 0x2A1C0E00); stmcan.WriteDoubleWord(0x20C, 0x00FFFF00); Assert.AreEqual(stmcan.ReadDoubleWord(0x20C), 0xFF0000FF); stmcan.WriteDoubleWord(0x200, 0x2A1C0E01); // --- CAN_FFA1R Assert.AreEqual(stmcan.ReadDoubleWord(0x214), 0x00000000); stmcan.WriteDoubleWord(0x214, 0xFF0000FF); Assert.AreEqual(stmcan.ReadDoubleWord(0x214), 0xFF0000FF); stmcan.WriteDoubleWord(0x200, 0x2A1C0E00); Assert.AreEqual(stmcan.ReadDoubleWord(0x200), 0x2A1C0E00); stmcan.WriteDoubleWord(0x214, 0x00FFFF00); Assert.AreEqual(stmcan.ReadDoubleWord(0x214), 0xFF0000FF); stmcan.WriteDoubleWord(0x200, 0x2A1C0E01); // --- CAN_FA1R - bit 31:28 reserved Assert.AreEqual(stmcan.ReadDoubleWord(0x21C), 0x00000000); stmcan.WriteDoubleWord(0x21C, 0xF0000000); Assert.AreEqual(stmcan.ReadDoubleWord(0x21C), 0x00000000); // --- CAN_FiRx - 28 filter banks: reset value undefined, model should reset to 0 // Filter bank registers can only be modified when FACTx bit of CAN_FAxR register is cleared // or when FINIT bit in CAN_FMR is set int filterIndex = 0; do { Assert.AreEqual(stmcan.ReadDoubleWord(0x240 + filterIndex * 0x8), 0x00000000); stmcan.WriteDoubleWord((0x240 + filterIndex * 0x8), 0xFF0000FF); Assert.AreEqual(stmcan.ReadDoubleWord(0x240 + filterIndex * 0x8), 0xFF0000FF); stmcan.WriteDoubleWord(0x200, 0x2A1C0E00); Assert.AreEqual(stmcan.ReadDoubleWord(0x200), 0x2A1C0E00); stmcan.WriteDoubleWord((0x240 + filterIndex * 0x8), 0x00FFFF00); Assert.AreEqual(stmcan.ReadDoubleWord(0x240 + filterIndex * 0x8), 0x00FFFF00); filterIndex++; }while(filterIndex < 28); }
public void InitTest() { var stmcan = new STMCAN (new Machine()); stmcan.Reset (); // Registers can only be accessed by words (32 bits) // --> check this // ##################################### // ### Check reset values of CAN control and status registers // --- CAN_MCR Assert.AreEqual (stmcan.ReadDoubleWord (0x00), 0x00010002); // --- CAN_MSR Assert.AreEqual (stmcan.ReadDoubleWord (0x04), 0x00000C02); // --- CAN_TSR Assert.AreEqual (stmcan.ReadDoubleWord (0x08), 0x1C000000); // --- CAN_RF0R Assert.AreEqual (stmcan.ReadDoubleWord (0x0C), 0x00000000); // --- CAN_RF1R Assert.AreEqual (stmcan.ReadDoubleWord (0x10), 0x00000000); // --- CAN_IER Assert.AreEqual (stmcan.ReadDoubleWord (0x14), 0x00000000); // --- CAN_ESR Assert.AreEqual (stmcan.ReadDoubleWord (0x18), 0x00000000); // --- CAN_BTR (Can only be accessed during Initialization mode) Assert.AreEqual (stmcan.ReadDoubleWord (0x1C), 0x00000000); // Cannot read // Change to Initialization mode by setting INRQ (bit0) in CAN_MCR register stmcan.WriteDoubleWord(0x00, 0x00010001); // Verify Initialization mode by checking INAK bit set in CAN_MSR // and that SLAK bit is cleared Assert.AreEqual (stmcan.ReadDoubleWord (0x04), 0x00000C01); Assert.AreEqual (stmcan.ReadDoubleWord (0x1C), 0x01230000); // ##################################### // ### Check CAN mailbox registers stmcan.Reset (); // --- CAN_TIxR - TXRQ reset value 0 (bit0) Assert.AreEqual (stmcan.ReadDoubleWord (0x180) & 0x1, 0x0); Assert.AreEqual (stmcan.ReadDoubleWord (0x190) & 0x1, 0x0); Assert.AreEqual (stmcan.ReadDoubleWord (0x1A0) & 0x1, 0x0); // --- CAN_TDTxR - bits 15:9, 7:4 are reserved Assert.AreEqual (stmcan.ReadDoubleWord (0x184), 0x0); Assert.AreEqual (stmcan.ReadDoubleWord (0x194), 0x0); Assert.AreEqual (stmcan.ReadDoubleWord (0x1A4), 0x0); // --- CAN_TDLxR - reset value undefined, model should reset to 0 Assert.AreEqual (stmcan.ReadDoubleWord (0x188), 0x0); Assert.AreEqual (stmcan.ReadDoubleWord (0x198), 0x0); Assert.AreEqual (stmcan.ReadDoubleWord (0x1A8), 0x0); // --- CAN_TDHxR - reset value undefined, model should reset to 0 Assert.AreEqual (stmcan.ReadDoubleWord (0x18C), 0x0); Assert.AreEqual (stmcan.ReadDoubleWord (0x19C), 0x0); Assert.AreEqual (stmcan.ReadDoubleWord (0x1AC), 0x0); // All RX registers are write protected // --- CAN_RIxR - reset value undefined, bit0 reserved stmcan.WriteDoubleWord(0x1B0, 0xFF0000FF); stmcan.WriteDoubleWord(0x1C0, 0xFF0000FF); Assert.AreEqual (stmcan.ReadDoubleWord (0x1B0) & 0x1, 0x0); Assert.AreEqual (stmcan.ReadDoubleWord (0x1C0) & 0x1, 0x0); // --- CAN_RDTxR - reset value undefined, bit7:4 reserved stmcan.WriteDoubleWord(0x1B4, 0xFF0000FF); stmcan.WriteDoubleWord(0x1C4, 0xFF0000FF); Assert.AreEqual (stmcan.ReadDoubleWord (0x1B4) & 0x10, 0x0); Assert.AreEqual (stmcan.ReadDoubleWord (0x1C4) & 0x10, 0x0); // --- CAN_RDLxR - reset value undefined, model should reset to 0 stmcan.WriteDoubleWord(0x1B8, 0xFF0000FF); stmcan.WriteDoubleWord(0x1C8, 0xFF0000FF); Assert.AreEqual (stmcan.ReadDoubleWord (0x1B8), 0x0); Assert.AreEqual (stmcan.ReadDoubleWord (0x1C8), 0x0); // --- CAN_RDHxR - reset value undefined, model should reset to 0 stmcan.WriteDoubleWord(0x1BC, 0xFF0000FF); stmcan.WriteDoubleWord(0x1CC, 0xFF0000FF); Assert.AreEqual (stmcan.ReadDoubleWord (0x1BC), 0x0); Assert.AreEqual (stmcan.ReadDoubleWord (0x1CC), 0x0); // ##################################### // ### Check CAN filter registers stmcan.Reset (); // --- CAN_FMR Assert.AreEqual (stmcan.ReadDoubleWord (0x200), 0x2A1C0E01); // --- CAN_FM1R - can only be written in filter initialization mode Assert.AreEqual (stmcan.ReadDoubleWord (0x204), 0x00000000); stmcan.WriteDoubleWord(0x204, 0xFF0000FF); Assert.AreEqual (stmcan.ReadDoubleWord (0x204), 0xFF0000FF); stmcan.WriteDoubleWord(0x200, 0x2A1C0E00); Assert.AreEqual (stmcan.ReadDoubleWord (0x200), 0x2A1C0E00); stmcan.WriteDoubleWord(0x204, 0x00FFFF00); Assert.AreEqual (stmcan.ReadDoubleWord (0x204), 0xFF0000FF); stmcan.WriteDoubleWord(0x200, 0x2A1C0E01); // --- CAN_FS1R Assert.AreEqual (stmcan.ReadDoubleWord (0x20C), 0x00000000); stmcan.WriteDoubleWord(0x20C, 0xFF0000FF); Assert.AreEqual (stmcan.ReadDoubleWord (0x20C), 0xFF0000FF); stmcan.WriteDoubleWord(0x200, 0x2A1C0E00); Assert.AreEqual (stmcan.ReadDoubleWord (0x200), 0x2A1C0E00); stmcan.WriteDoubleWord(0x20C, 0x00FFFF00); Assert.AreEqual (stmcan.ReadDoubleWord (0x20C), 0xFF0000FF); stmcan.WriteDoubleWord(0x200, 0x2A1C0E01); // --- CAN_FFA1R Assert.AreEqual (stmcan.ReadDoubleWord (0x214), 0x00000000); stmcan.WriteDoubleWord(0x214, 0xFF0000FF); Assert.AreEqual (stmcan.ReadDoubleWord (0x214), 0xFF0000FF); stmcan.WriteDoubleWord(0x200, 0x2A1C0E00); Assert.AreEqual (stmcan.ReadDoubleWord (0x200), 0x2A1C0E00); stmcan.WriteDoubleWord(0x214, 0x00FFFF00); Assert.AreEqual (stmcan.ReadDoubleWord (0x214), 0xFF0000FF); stmcan.WriteDoubleWord(0x200, 0x2A1C0E01); // --- CAN_FA1R - bit 31:28 reserved Assert.AreEqual (stmcan.ReadDoubleWord (0x21C), 0x00000000); stmcan.WriteDoubleWord(0x21C, 0xF0000000); Assert.AreEqual (stmcan.ReadDoubleWord (0x21C), 0x00000000); // --- CAN_FiRx - 28 filter banks: reset value undefined, model should reset to 0 // Filter bank registers can only be modified when FACTx bit of CAN_FAxR register is cleared // or when FINIT bit in CAN_FMR is set int filterIndex = 0; do { Assert.AreEqual (stmcan.ReadDoubleWord (0x240 + filterIndex*0x8), 0x00000000); stmcan.WriteDoubleWord((0x240 + filterIndex*0x8), 0xFF0000FF); Assert.AreEqual (stmcan.ReadDoubleWord (0x240 + filterIndex*0x8), 0xFF0000FF); stmcan.WriteDoubleWord(0x200, 0x2A1C0E00); Assert.AreEqual (stmcan.ReadDoubleWord (0x200), 0x2A1C0E00); stmcan.WriteDoubleWord((0x240 + filterIndex*0x8), 0x00FFFF00); Assert.AreEqual (stmcan.ReadDoubleWord (0x240 + filterIndex*0x8), 0x00FFFF00); filterIndex++; } while (filterIndex<28); }
public void LoopbackMessageTest() { // ##################################### // ### Declarations // CAN TX mailbox identifier register uint can_tixr = 0; // CAN TX mailbox data length control and time stamp register uint can_tdtxr = 0; // CAN TX mailbox data low register uint can_tdlxr = 0; // CAN TX mailbox data high register uint can_tdhxr = 0; // Message components uint stdid = 0x321; uint ide = 0; // std = 0; ext = 4 uint rtr = 0; // data frame = 0 ; remote frame = 2 uint txrq = 1; uint time = 0; uint tgt = 0; uint dlc = 8; // data length, default to 8 bytes byte[] txData = new byte[8] { 0x1, 0x2, 0x3, 0x4, 0x5, 0x6, 0x7, 0x8 }; // ##################################### // ### Setup CAN device var stmcan = new STMCAN(new Machine()); stmcan.Reset(); // Init mode stmcan.WriteDoubleWord(0x00, 0x00010000); Assert.AreEqual(stmcan.ReadDoubleWord(0x04), 0x00000C00); // ### Set filter for message // --- CAN_FMR - init mode var can_fmr = stmcan.ReadDoubleWord(0x200); can_fmr |= 0x1; stmcan.WriteDoubleWord(0x200, can_fmr); // --- CAN_FA1R - deactivate filter nr 1 var can_fa1r = stmcan.ReadDoubleWord(0x21C); can_fa1r &= 0xFFFFFFFD; stmcan.WriteDoubleWord(0x21C, can_fa1r); // Filter scale: 32-bit filter 1 identifier var can_fs1r = stmcan.ReadDoubleWord(0x20C); can_fs1r |= 0x1; stmcan.WriteDoubleWord(0x20C, can_fs1r); // Filter 1 identifiers = 0x321, 0x123 : set 0,0 currently var can_fxr1 = stmcan.ReadDoubleWord(0x248); can_fxr1 |= 0x0; stmcan.WriteDoubleWord(0x248, can_fxr1); var can_fxr2 = stmcan.ReadDoubleWord(0x250); can_fxr2 |= 0x0; stmcan.WriteDoubleWord(0x250, can_fxr2); // --- CAN_FM1R - filter 1 is two 32-bit id list var can_fm1r = stmcan.ReadDoubleWord(0x204); can_fm1r |= 0x1; stmcan.WriteDoubleWord(0x204, can_fm1r); // --- CAN_FFA1R - assign FIFO 0 var can_ffa1r = stmcan.ReadDoubleWord(0x214); can_ffa1r &= 0xFFFFFFFD; stmcan.WriteDoubleWord(0x214, can_ffa1r); // --- CAN_FA1R - activate filter nr 1 can_fa1r = stmcan.ReadDoubleWord(0x21C); can_fa1r |= 0x1; stmcan.WriteDoubleWord(0x21C, can_fa1r); // Enable loopback, set LBKM, bit30, in CAN_BTR uint can_btr = stmcan.ReadDoubleWord(0x01C); can_btr |= (1 << 30); stmcan.WriteDoubleWord(0x01C, can_btr); Assert.AreEqual(stmcan.ReadDoubleWord(0x01C), can_btr); // Set Normal mode stmcan.WriteDoubleWord(0x00, 0x00010000); Assert.AreEqual(stmcan.ReadDoubleWord(0x04), 0x00000C00); // ##################################### // ### Standard Identifier // Setup message data registers and write to mailbox 0 can_tdtxr = (time << 16) | (tgt << 8) | dlc; can_tdlxr = (uint)((txData[3] << 24) | (txData[2] << 16) | (txData[1] << 8) | txData[0]); can_tdhxr = (uint)((txData[7] << 24) | (txData[6] << 16) | (txData[5] << 8) | txData[4]); stmcan.WriteDoubleWord(0x184, can_tdtxr); stmcan.WriteDoubleWord(0x188, can_tdlxr); stmcan.WriteDoubleWord(0x18C, can_tdhxr); // Setup id register and request transmission can_tixr = (stdid << 21) | (ide << 2) | (rtr << 1) | txrq; stmcan.WriteDoubleWord(0x180, can_tixr); // Check RX FIFO 0, fetch message and release fifo // CAN_RF0R bit 1:0 indicates pending RX messages Assert.AreEqual(stmcan.ReadDoubleWord(0x0C) & 0x3, 0x1); //Assert.AreEqual (stmcan.ReadDoubleWord(0x10) & 0x3, 0x1); // read id from receive fifo 0 and verify 0x321 in bit 31:21 Assert.AreEqual(stmcan.ReadDoubleWord(0x1B0) & 0xFFE00000, (stdid << 21)); // read data from receive fifo 0 and verify 0x321 in bit 31:21 Assert.AreEqual(stmcan.ReadDoubleWord(0x1B8) & 0xFF, txData[0]); // release RFOM0 fifo in CAN_RFR // ##################################### // Extended Identifier ide = 4; // ##################################### // Remote Frame rtr = 2; // ##################################### // Error }
public void LoopbackMessageTest() { // ##################################### // ### Declarations // CAN TX mailbox identifier register uint can_tixr = 0; // CAN TX mailbox data length control and time stamp register uint can_tdtxr = 0; // CAN TX mailbox data low register uint can_tdlxr = 0; // CAN TX mailbox data high register uint can_tdhxr = 0; // Message components uint stdid = 0x321; uint ide = 0; // std = 0; ext = 4 uint rtr = 0; // data frame = 0 ; remote frame = 2 uint txrq = 1; uint time = 0; uint tgt = 0; uint dlc = 8; // data length, default to 8 bytes byte[] txData = new byte[8] { 0x1, 0x2, 0x3, 0x4, 0x5, 0x6, 0x7, 0x8 }; // ##################################### // ### Setup CAN device var stmcan = new STMCAN(new Machine()); stmcan.Reset(); // Init mode stmcan.WriteDoubleWord(0x00, 0x00010000); Assert.AreEqual (stmcan.ReadDoubleWord (0x04), 0x00000C00); // ### Set filter for message // --- CAN_FMR - init mode var can_fmr = stmcan.ReadDoubleWord (0x200); can_fmr |= 0x1; stmcan.WriteDoubleWord(0x200, can_fmr); // --- CAN_FA1R - deactivate filter nr 1 var can_fa1r = stmcan.ReadDoubleWord (0x21C); can_fa1r &= 0xFFFFFFFD; stmcan.WriteDoubleWord(0x21C, can_fa1r); // Filter scale: 32-bit filter 1 identifier var can_fs1r = stmcan.ReadDoubleWord (0x20C); can_fs1r |= 0x1; stmcan.WriteDoubleWord(0x20C, can_fs1r); // Filter 1 identifiers = 0x321, 0x123 : set 0,0 currently var can_fxr1 = stmcan.ReadDoubleWord (0x248); can_fxr1 |= 0x0; stmcan.WriteDoubleWord(0x248, can_fxr1); var can_fxr2 = stmcan.ReadDoubleWord (0x250); can_fxr2 |= 0x0; stmcan.WriteDoubleWord(0x250, can_fxr2); // --- CAN_FM1R - filter 1 is two 32-bit id list var can_fm1r = stmcan.ReadDoubleWord (0x204); can_fm1r |= 0x1; stmcan.WriteDoubleWord(0x204, can_fm1r); // --- CAN_FFA1R - assign FIFO 0 var can_ffa1r = stmcan.ReadDoubleWord (0x214); can_ffa1r &= 0xFFFFFFFD; stmcan.WriteDoubleWord(0x214, can_ffa1r); // --- CAN_FA1R - activate filter nr 1 can_fa1r = stmcan.ReadDoubleWord (0x21C); can_fa1r |= 0x1; stmcan.WriteDoubleWord(0x21C, can_fa1r); // Enable loopback, set LBKM, bit30, in CAN_BTR uint can_btr = stmcan.ReadDoubleWord(0x01C); can_btr |= (1 << 30); stmcan.WriteDoubleWord(0x01C, can_btr); Assert.AreEqual (stmcan.ReadDoubleWord (0x01C), can_btr); // Set Normal mode stmcan.WriteDoubleWord(0x00, 0x00010000); Assert.AreEqual (stmcan.ReadDoubleWord (0x04), 0x00000C00); // ##################################### // ### Standard Identifier // Setup message data registers and write to mailbox 0 can_tdtxr = (time << 16) | (tgt << 8) | dlc; can_tdlxr = (uint)((txData[3] << 24) | (txData[2] << 16) | (txData[1] << 8) | txData[0]); can_tdhxr = (uint)((txData[7] << 24) | (txData[6] << 16) | (txData[5] << 8) | txData[4]); stmcan.WriteDoubleWord(0x184, can_tdtxr); stmcan.WriteDoubleWord(0x188, can_tdlxr); stmcan.WriteDoubleWord(0x18C, can_tdhxr); // Setup id register and request transmission can_tixr = (stdid << 21) | (ide << 2) | (rtr << 1) | txrq; stmcan.WriteDoubleWord(0x180, can_tixr); // Check RX FIFO 0, fetch message and release fifo // CAN_RF0R bit 1:0 indicates pending RX messages Assert.AreEqual (stmcan.ReadDoubleWord(0x0C) & 0x3, 0x1); //Assert.AreEqual (stmcan.ReadDoubleWord(0x10) & 0x3, 0x1); // read id from receive fifo 0 and verify 0x321 in bit 31:21 Assert.AreEqual(stmcan.ReadDoubleWord(0x1B0) & 0xFFE00000, (stdid << 21)); // read data from receive fifo 0 and verify 0x321 in bit 31:21 Assert.AreEqual(stmcan.ReadDoubleWord(0x1B8) & 0xFF, txData[0]); // release RFOM0 fifo in CAN_RFR // ##################################### // Extended Identifier ide = 4; // ##################################### // Remote Frame rtr = 2; // ##################################### // Error }