stripped out RTM Model interface and custom types from matlab

2021-07-03 11:31:46 +02:00 · 2021-07-03 11:31:46 +02:00 · f28aa2df8b
commit f28aa2df8b
parent 754da9f931
7 changed files with 27 additions and 343 deletions
--- a/lib/treppe/FSMTreppe/FSMTreppe.cpp
+++ b/lib/treppe/FSMTreppe/FSMTreppe.cpp
@ -17,12 +17,11 @@
 // Validation result: Not run
 //
 #include "FSMTreppe.h"
 #include "FSMTreppe_private.h"
 // Named constants for Chart: '<Root>/FSMTreppe'
-const uint8_T FSMTreppe_IN_animation_down = 1U;
+const uint8_t FSMTreppe_IN_animation_down = 1U;
-const uint8_T FSMTreppe_IN_animation_up = 2U;
+const uint8_t FSMTreppe_IN_animation_up = 2U;
-const uint8_T FSMTreppe_IN_idle = 3U;
+const uint8_t FSMTreppe_IN_idle = 3U;
 // Model step function
 void FSMTreppeModelClass::step()
@ -33,7 +32,7 @@ void FSMTreppeModelClass::step()
  //   Inport: '<Root>/sensor_unten'
  if (FSMTreppe_DW.temporalCounter_i1 < 511U) {
-    FSMTreppe_DW.temporalCounter_i1 = static_cast<uint16_T>
+    FSMTreppe_DW.temporalCounter_i1 = static_cast<uint16_t>
      (FSMTreppe_DW.temporalCounter_i1 + 1U);
  }
@ -165,12 +164,6 @@ FSMTreppeModelClass::~FSMTreppeModelClass()
  // Currently there is no destructor body generated.
 }
 // Real-Time Model get method
 FSMTreppeModelClass::RT_MODEL_FSMTreppe_T * FSMTreppeModelClass::getRTM()
 {
  return (&FSMTreppe_M);
 }
 //
 // File trailer for generated code.
 //
--- a/lib/treppe/FSMTreppe/FSMTreppe.h
+++ b/lib/treppe/FSMTreppe/FSMTreppe.h
@ -18,17 +18,8 @@
 //
 #ifndef RTW_HEADER_FSMTreppe_h_
 #define RTW_HEADER_FSMTreppe_h_
 #include "rtwtypes.h"
 #include "FSMTreppe_types.h"
-// Macros for accessing real-time model data structure
+#include <stdint.h>
 #ifndef rtmGetErrorStatus
 #define rtmGetErrorStatus(rtm)         ((rtm)->errorStatus)
 #endif
 #ifndef rtmSetErrorStatus
 #define rtmSetErrorStatus(rtm, val)    ((rtm)->errorStatus = (val))
 #endif
 // Class declaration for model FSMTreppe
 class FSMTreppeModelClass {
@ -36,30 +27,25 @@ class FSMTreppeModelClass {
 public:
  // Block states (default storage) for system '<Root>'
  struct DW_FSMTreppe_T {
-    uint16_T temporalCounter_i1;       // '<Root>/FSMTreppe'
+    uint16_t temporalCounter_i1;       // '<Root>/FSMTreppe'
-    uint8_T is_active_c3_FSMTreppe;    // '<Root>/FSMTreppe'
+    uint8_t is_active_c3_FSMTreppe;    // '<Root>/FSMTreppe'
-    uint8_T is_c3_FSMTreppe;           // '<Root>/FSMTreppe'
+    uint8_t is_c3_FSMTreppe;           // '<Root>/FSMTreppe'
-    uint8_T got_anim_finished;         // '<Root>/FSMTreppe'
+    uint8_t got_anim_finished;         // '<Root>/FSMTreppe'
-    uint8_T finished_up;               // '<Root>/FSMTreppe'
+    uint8_t finished_up;               // '<Root>/FSMTreppe'
-    uint8_T finished_dn;               // '<Root>/FSMTreppe'
+    uint8_t finished_dn;               // '<Root>/FSMTreppe'
-    uint8_T got_sensor;                // '<Root>/FSMTreppe'
+    uint8_t got_sensor;                // '<Root>/FSMTreppe'
  };
  // External inputs (root inport signals with default storage)
  struct ExtU_FSMTreppe_T {
-    boolean_T sensor_unten;            // '<Root>/sensor_unten'
+    bool sensor_unten;            // '<Root>/sensor_unten'
-    boolean_T sensor_oben;             // '<Root>/sensor_oben'
+    bool sensor_oben;             // '<Root>/sensor_oben'
-    boolean_T anim_finished;           // '<Root>/anim_finished'
+    bool anim_finished;           // '<Root>/anim_finished'
  };
  // External outputs (root outports fed by signals with default storage)
  struct ExtY_FSMTreppe_T {
-    uint8_T anim_active;               // '<Root>/anim_active'
+    uint8_t anim_active;               // '<Root>/anim_active'
  };
  // Real-time Model Data Structure
  struct RT_MODEL_FSMTreppe_T {
    const char_T * volatile errorStatus;
  };
  // model initialize function
@ -93,9 +79,6 @@ class FSMTreppeModelClass {
    return FSMTreppe_Y;
  }
  // Real-Time Model get method
  FSMTreppeModelClass::RT_MODEL_FSMTreppe_T * getRTM();
  // private data and function members
 private:
  // Block states
@ -106,9 +89,6 @@ class FSMTreppeModelClass {
  // External outputs
  ExtY_FSMTreppe_T FSMTreppe_Y;
  // Real-Time Model
  RT_MODEL_FSMTreppe_T FSMTreppe_M;
 };
 //-
--- a/lib/treppe/FSMTreppe/FSMTreppe_private.h
+++ b/lib/treppe/FSMTreppe/FSMTreppe_private.h
@ -1,28 +0,0 @@
 //
 // Academic License - for use in teaching, academic research, and meeting
 // course requirements at degree granting institutions only.  Not for
 // government, commercial, or other organizational use.
 //
 // File: FSMTreppe_private.h
 //
 // Code generated for Simulink model 'FSMTreppe'.
 //
 // Model version                  : 1.22
 // Simulink Coder version         : 9.5 (R2021a) 14-Nov-2020
 // C/C++ source code generated on : Fri Jul  2 17:45:36 2021
 //
 // Target selection: ert.tlc
 // Embedded hardware selection: ARM Compatible->ARM Cortex-M
 // Code generation objectives: Unspecified
 // Validation result: Not run
 //
 #ifndef RTW_HEADER_FSMTreppe_private_h_
 #define RTW_HEADER_FSMTreppe_private_h_
 #include "rtwtypes.h"
 #endif                                 // RTW_HEADER_FSMTreppe_private_h_
 //
 // File trailer for generated code.
 //
 // [EOF]
 //
--- a/lib/treppe/FSMTreppe/ert_main.cpp
+++ b/lib/treppe/FSMTreppe/ert_main.cpp
@ -1,109 +0,0 @@
 //
 // Academic License - for use in teaching, academic research, and meeting
 // course requirements at degree granting institutions only.  Not for
 // government, commercial, or other organizational use.
 //
 // File: ert_main.cpp
 //
 // Code generated for Simulink model 'FSMTreppe'.
 //
 // Model version                  : 1.22
 // Simulink Coder version         : 9.5 (R2021a) 14-Nov-2020
 // C/C++ source code generated on : Fri Jul  2 17:45:36 2021
 //
 // Target selection: ert.tlc
 // Embedded hardware selection: ARM Compatible->ARM Cortex-M
 // Code generation objectives: Unspecified
 // Validation result: Not run
 //
 #include <stddef.h>
 #include <stdio.h>                // This ert_main.c example uses printf/fflush
 #include "FSMTreppe.h"                 // Model's header file
 #include "rtwtypes.h"
 static FSMTreppeModelClass FSMTreppe_Obj;// Instance of model class
 //
 // Associating rt_OneStep with a real-time clock or interrupt service routine
 // is what makes the generated code "real-time".  The function rt_OneStep is
 // always associated with the base rate of the model.  Subrates are managed
 // by the base rate from inside the generated code.  Enabling/disabling
 // interrupts and floating point context switches are target specific.  This
 // example code indicates where these should take place relative to executing
 // the generated code step function.  Overrun behavior should be tailored to
 // your application needs.  This example simply sets an error status in the
 // real-time model and returns from rt_OneStep.
 //
 void rt_OneStep(void);
 void rt_OneStep(void)
 {
  static boolean_T OverrunFlag = false;
  // Disable interrupts here
  // Check for overrun
  if (OverrunFlag) {
    rtmSetErrorStatus(FSMTreppe_Obj.getRTM(), "Overrun");
    return;
  }
  OverrunFlag = true;
  // Save FPU context here (if necessary)
  // Re-enable timer or interrupt here
  // Set model inputs here
  // Step the model
  FSMTreppe_Obj.step();
  // Get model outputs here
  // Indicate task complete
  OverrunFlag = false;
  // Disable interrupts here
  // Restore FPU context here (if necessary)
  // Enable interrupts here
 }
 //
 // The example "main" function illustrates what is required by your
 // application code to initialize, execute, and terminate the generated code.
 // Attaching rt_OneStep to a real-time clock is target specific.  This example
 // illustrates how you do this relative to initializing the model.
 //
 int_T main(int_T argc, const char *argv[])
 {
  // Unused arguments
  (void)(argc);
  (void)(argv);
  // Initialize model
  FSMTreppe_Obj.initialize();
  // Attach rt_OneStep to a timer or interrupt service routine with
  //  period 0.01 seconds (the model's base sample time) here.  The
  //  call syntax for rt_OneStep is
  //
  //   rt_OneStep();
  printf("Warning: The simulation will run forever. "
         "Generated ERT main won't simulate model step behavior. "
         "To change this behavior select the 'MAT-file logging' option.\n");
  fflush((NULL));
  while (rtmGetErrorStatus(FSMTreppe_Obj.getRTM()) == (NULL)) {
    //  Perform other application tasks here
  }
  // Disable rt_OneStep() here
  // Terminate model
  FSMTreppe_Obj.terminate();
  return 0;
 }
 //
 // File trailer for generated code.
 //
 // [EOF]
 //
--- a/lib/treppe/FSMTreppe/rtwtypes.h
+++ b/lib/treppe/FSMTreppe/rtwtypes.h
@ -1,160 +0,0 @@
 //
 // Academic License - for use in teaching, academic research, and meeting
 // course requirements at degree granting institutions only.  Not for
 // government, commercial, or other organizational use.
 //
 // File: rtwtypes.h
 //
 // Code generated for Simulink model 'FSMTreppe'.
 //
 // Model version                  : 1.22
 // Simulink Coder version         : 9.5 (R2021a) 14-Nov-2020
 // C/C++ source code generated on : Fri Jul  2 17:45:36 2021
 //
 // Target selection: ert.tlc
 // Embedded hardware selection: ARM Compatible->ARM Cortex-M
 // Code generation objectives: Unspecified
 // Validation result: Not run
 //
 #ifndef RTWTYPES_H
 #define RTWTYPES_H
 // Logical type definitions
 #if (!defined(__cplusplus))
 #ifndef false
 #define false                          (0U)
 #endif
 #ifndef true
 #define true                           (1U)
 #endif
 #endif
 //=======================================================================*
 //  Target hardware information
 //    Device type: ARM Compatible->ARM Cortex-M
 //    Number of bits:     char:   8    short:   16    int:  32
 //                        long:  32
 //                        native word size:  32
 //    Byte ordering: LittleEndian
 //    Signed integer division rounds to: Zero
 //    Shift right on a signed integer as arithmetic shift: on
 // =======================================================================
 //=======================================================================*
 //  Fixed width word size data types:                                     *
 //    int8_T, int16_T, int32_T     - signed 8, 16, or 32 bit integers     *
 //    uint8_T, uint16_T, uint32_T  - unsigned 8, 16, or 32 bit integers   *
 //    real32_T, real64_T           - 32 and 64 bit floating point numbers *
 // =======================================================================
 typedef signed char int8_T;
 typedef unsigned char uint8_T;
 typedef short int16_T;
 typedef unsigned short uint16_T;
 typedef int int32_T;
 typedef unsigned int uint32_T;
 typedef float real32_T;
 typedef double real64_T;
 //===========================================================================*
 //  Generic type definitions: boolean_T, char_T, byte_T, int_T, uint_T,       *
 //                            real_T, time_T, ulong_T.                        *
 // ===========================================================================
 typedef double real_T;
 typedef double time_T;
 typedef unsigned char boolean_T;
 typedef int int_T;
 typedef unsigned int uint_T;
 typedef unsigned long ulong_T;
 typedef char char_T;
 typedef unsigned char uchar_T;
 typedef char_T byte_T;
 //===========================================================================*
 //  Complex number type definitions                                           *
 // ===========================================================================
 #define CREAL_T
 typedef struct {
  real32_T re;
  real32_T im;
 } creal32_T;
 typedef struct {
  real64_T re;
  real64_T im;
 } creal64_T;
 typedef struct {
  real_T re;
  real_T im;
 } creal_T;
 #define CINT8_T
 typedef struct {
  int8_T re;
  int8_T im;
 } cint8_T;
 #define CUINT8_T
 typedef struct {
  uint8_T re;
  uint8_T im;
 } cuint8_T;
 #define CINT16_T
 typedef struct {
  int16_T re;
  int16_T im;
 } cint16_T;
 #define CUINT16_T
 typedef struct {
  uint16_T re;
  uint16_T im;
 } cuint16_T;
 #define CINT32_T
 typedef struct {
  int32_T re;
  int32_T im;
 } cint32_T;
 #define CUINT32_T
 typedef struct {
  uint32_T re;
  uint32_T im;
 } cuint32_T;
 //=======================================================================*
 //  Min and Max:                                                          *
 //    int8_T, int16_T, int32_T     - signed 8, 16, or 32 bit integers     *
 //    uint8_T, uint16_T, uint32_T  - unsigned 8, 16, or 32 bit integers   *
 // =======================================================================
 #define MAX_int8_T                     ((int8_T)(127))
 #define MIN_int8_T                     ((int8_T)(-128))
 #define MAX_uint8_T                    ((uint8_T)(255U))
 #define MAX_int16_T                    ((int16_T)(32767))
 #define MIN_int16_T                    ((int16_T)(-32768))
 #define MAX_uint16_T                   ((uint16_T)(65535U))
 #define MAX_int32_T                    ((int32_T)(2147483647))
 #define MIN_int32_T                    ((int32_T)(-2147483647-1))
 #define MAX_uint32_T                   ((uint32_T)(0xFFFFFFFFU))
 // Block D-Work pointer type
 typedef void * pointer_T;
 #endif                                 // RTWTYPES_H
 //
 // File trailer for generated code.
 //
 // [EOF]
 //
--- a/lib/treppe/treppe.cpp
+++ b/lib/treppe/treppe.cpp
@ -155,6 +155,7 @@ void Treppe::setup(){
 }
 void Treppe::task(){
  FSMTreppe_Obj.step();
  if(finish){
    direction = switch_direction;
--- a/lib/treppe/treppe.h
+++ b/lib/treppe/treppe.h
@ -1,5 +1,6 @@
 #pragma once
 #include "FSMTreppe/FSMTreppe.h"
 #include "PCA9685.h"
 #define SENSOR1 2
@ -10,6 +11,10 @@
 class Treppe {
 private:
    // initialize with i2c-Address 0, use Wire Library
    PCA9685 pwmController;     
    FSMTreppeModelClass FSMTreppe_Obj;// Instance of model class
    uint8_t stairs;
    uint16_t time_per_stair = 300;          // dimmtime per stair [ms]
    uint16_t idle_brightness = 100;
@ -31,21 +36,23 @@ private:
    float differenz_pwm_pro_tick = 0.0;
    // alternative
    // initialize with i2c-Address 0, use Wire Library
    PCA9685 pwmController;     
    uint8_t softstart_led(uint8_t led, uint16_t startval, uint16_t stopval);
    void ledsequence();
    void rampe();
 public:
    Treppe(uint8_t _stairs) : stairs(_stairs){
        FSMTreppe_Obj.initialize();
        ticks_pro_stufe = time_per_stair / 20; // [ms]
        ticks_treppe = ticks_pro_stufe * stairs;
        differenz_pwm_pro_tick = (float) (active_brightness - idle_brightness) 
                                            / (float) ticks_pro_stufe;
    }
    ~Treppe() {
        FSMTreppe_Obj.terminate();
    }
    void setup();
    void task();        // call periodically