code avec modifs, programme mit dans les robots pour les derniers matchs
Dependencies: mbed SerialHalfDuplex SDFileSystem liaison_Bluetooth ident_crac DISCO-F469NI_portrait
Debug/debug.cpp
- Committer:
- gabrieltetar
- Date:
- 2020-03-11
- Revision:
- 14:6aa8aa1699ad
- Parent:
- 10:1964bb91b925
File content as of revision 14:6aa8aa1699ad:
#include "global.h" //debug audio void Debug_Audio(unsigned char repertoire, unsigned char track){ unsigned char data[2]; data[0]=repertoire; data[1]=track; SendMsgCan(SOMO_playtrack, data,2); } //azezaea void debug_Instruction(struct S_Instruction instruction) { printf("\n********* Debug instruction *********\n"); printf("* Line => %d\n", instruction.lineNumber); printf("* Type => %s\n", InstructionTypeToString(instruction.order)); printf("* Direction => %s\n", InstructionDirectionToString(instruction.direction)); printf("* Arg1 => %d\n", instruction.arg1); printf("* Arg2 => %d\n", instruction.arg2); printf("* Arg3 => %d\n", instruction.arg3); printf("* Recalage => %s\n", InstructionPrecisionOuRecalageToString(instruction.precision)); printf("* NextAction=> %s\n", InstructionNextActionTypeToString(instruction.nextActionType)); printf("* JumpAction=> %s\n", InstructionNextActionJumpTypeToString(instruction.jumpAction)); printf("* JumpTimeOrX => %d\n", instruction.JumpTimeOrX); printf("* JumpY => %d\n", instruction.JumpY); printf("* nextLineOK => %d\n", instruction.nextLineOK); printf("* nextLineError => %d\n", instruction.nextLineError); printf("*************************************\n"); } char* InstructionTypeToString(enum E_InstructionType type) { switch(type) { case MV_COURBURE: return "Courbure"; case MV_LINE: return "Ligne"; case MV_TURN: return "Rotation"; case MV_XYT: return "Position XYT"; case MV_RECALAGE: return "Recalage"; case ACTION: return "Action"; default: return "Inconnue"; } } char* InstructionDirectionToString(enum E_InstructionDirection type) { switch(type) { case BACKWARD: return "en arriere"; case FORWARD: return "en avant"; case RELATIVE: return "relatif"; case ABSOLUTE: return "absolu"; default: return "absent"; } } char* InstructionPrecisionOuRecalageToString(enum E_InstructionPrecisionOuRecalage type) { switch(type) { case PRECISION: return "correction position en fin de mouvement"; case RECALAGE_X: return "recalage en X"; case RECALAGE_Y: return "recalage en Y"; default: return "absent"; } } char* InstructionNextActionTypeToString(enum E_InstructionNextActionType type) { switch(type) { case JUMP: return "jump"; case WAIT: return "attente fin instruction"; case ENCHAINEMENT: return "enchainement"; default: return "absent"; } } char* InstructionNextActionJumpTypeToString(enum E_InstructionNextActionJumpType type) { switch(type) { case JUMP_TIME: return "attente temps"; case JUMP_POSITION: return "attente position"; default: return "absent"; } } void errorLoop(void) { while(true) { led1 = 1; wait(0.2); led1 = 0; wait(0.2); } } void errorInstructionLoop(void) { while(true) { led2 = 1; wait(0.2); led2 = 0; wait(0.2); } } /****************************************************************************************/ /* FUNCTION NAME: sendStratEtat */ /* DESCRIPTION : permet le debug de l'etat de l'automate de stratégie */ /****************************************************************************************/ void sendStratEtat(unsigned char etat, unsigned char currentInstruction) { CANMessage msgTx=CANMessage(); msgTx.id=DEBUG_STRATEGIE_AUTOMATE; // tx nouvelle position en (x,y,theta) msgTx.len=1; msgTx.format=CANStandard; msgTx.type=CANData; // x sur 2 octets msgTx.data[0]=(unsigned char)etat; msgTx.data[1]=(unsigned char)currentInstruction; can1.write(msgTx); } void debugXYTTarget(signed short target_x_robot, signed short target_y_robot, signed short target_theta_robot) { printf("going to new position x: %d, y: %d, t: %d\n",target_x_robot,target_y_robot,target_theta_robot); }