/* * File: HVAC_model_private.h * * Code generated for Simulink model 'HVAC_model'. * * Model version : 1.784 * Simulink Coder version : 24.1 (R2024a) 19-Nov-2023 * C/C++ source code generated on : Tue Apr 14 14:42:16 2026 * * Target selection: ert.tlc * Embedded hardware selection: ARM Compatible->ARM Cortex-M * Emulation hardware selection: * Differs from embedded hardware (MATLAB Host) * Code generation objectives: Unspecified * Validation result: Not run */ #ifndef HVAC_model_private_h_ #define HVAC_model_private_h_ #include #include #include "HVAC_model.h" #include "HVAC_model_types.h" /* Includes for objects with custom storage classes */ #include "Rs_Cal_Base.h" #ifndef UCHAR_MAX #include #endif #if ( UCHAR_MAX != (0xFFU) ) || ( SCHAR_MAX != (0x7F) ) #error Code was generated for compiler with different sized uchar/char. \ Consider adjusting Test hardware word size settings on the \ Hardware Implementation pane to match your compiler word sizes as \ defined in limits.h of the compiler. Alternatively, you can \ select the Test hardware is the same as production hardware option and \ select the Enable portable word sizes option on the Code Generation > \ Verification pane for ERT based targets, which will disable the \ preprocessor word size checks. #endif #if ( USHRT_MAX != (0xFFFFU) ) || ( SHRT_MAX != (0x7FFF) ) #error Code was generated for compiler with different sized ushort/short. \ Consider adjusting Test hardware word size settings on the \ Hardware Implementation pane to match your compiler word sizes as \ defined in limits.h of the compiler. Alternatively, you can \ select the Test hardware is the same as production hardware option and \ select the Enable portable word sizes option on the Code Generation > \ Verification pane for ERT based targets, which will disable the \ preprocessor word size checks. #endif #if ( UINT_MAX != (0xFFFFFFFFU) ) || ( INT_MAX != (0x7FFFFFFF) ) #error Code was generated for compiler with different sized uint/int. \ Consider adjusting Test hardware word size settings on the \ Hardware Implementation pane to match your compiler word sizes as \ defined in limits.h of the compiler. Alternatively, you can \ select the Test hardware is the same as production hardware option and \ select the Enable portable word sizes option on the Code Generation > \ Verification pane for ERT based targets, which will disable the \ preprocessor word size checks. #endif #if ( ULONG_MAX != (0xFFFFFFFFU) ) || ( LONG_MAX != (0x7FFFFFFF) ) #error Code was generated for compiler with different sized ulong/long. \ Consider adjusting Test hardware word size settings on the \ Hardware Implementation pane to match your compiler word sizes as \ defined in limits.h of the compiler. Alternatively, you can \ select the Test hardware is the same as production hardware option and \ select the Enable portable word sizes option on the Code Generation > \ Verification pane for ERT based targets, which will disable the \ preprocessor word size checks. #endif /* Skipping ulong_long/long_long check: insufficient preprocessor integer range. */ extern double rt_roundd(double u); extern uint16_t look1_iu16bs16lu64n32_binlcse(uint16_t u0, const int16_t bp0[], const uint16_t table[], uint32_t maxIndex); extern uint32_t binsearch_u32s16(int16_t u, const int16_t bp[], uint32_t startIndex, uint32_t maxIndex); extern uint8_t look2_iu8bu8s16lu64n32_binlcse(uint8_t u0, uint8_t u1, const uint8_t bp0[], const int16_t bp1[], const uint8_t table[], const uint32_t maxIndex[], uint32_t stride); extern int16_t look1_iu16tdIs16_binlcs(uint16_t u0, const uint16_t bp0[], const double table[], uint32_t maxIndex); extern uint32_t plook_u32s16_bincka(int16_t u, const int16_t bp[], uint32_t maxIndex); extern void get_tg_FLL_for_LVL(uint8_t rtu_ambient_Lvl, uint8_t rtu_set_tmp, int16_t *rty_vals); extern void get_tg_FLL_for_LVL_j(uint8_t rtu_ambient_Lvl, uint8_t rtu_set_tmp, int16_t *rty_vals); extern void g_assFLOW_BI_AMB_TGT_n(uint8_t rtu_LVL, int16_t *rty_c_g_assFLOW_BI_AMB_TGT); extern void Bilevel(int16_t rtu_Amb_Fb, uint8_t rtu_LVL, uint16_t rty_Out1[9], uint8_t rtu_setTempFL, uint8_t rtu_setTempFR); extern void g_assFLOW_BI_AMB_TGT_e(uint8_t rtu_LVL, int16_t *rty_c_g_assFLOW_BI2_AMB_TGT); extern void Bilevel2(int16_t rtu_Amb_Fb, uint8_t rtu_LVL, uint16_t rty_Out1[9], uint8_t rtu_setTempFL, uint8_t rtu_setTempFR); extern void g_aucFLOW_AF_FOOT_VALVE_MAX_e(uint8_t rtu_LVL, uint8_t *rty_c_g_aucFLOW_AF_FOOT_VALVE_MAX); extern void g_assFLOW_AF_AMB_TGT_g(uint8_t rtu_LVL, int16_t *rty_c_g_assFLOW_AF_AMB_TGT); extern void Afoot(int16_t rtu_Amb_Fb, uint8_t rtu_LVL, uint16_t rty_Out1[9], uint8_t rtu_setTempFL, uint8_t rtu_setTempFR); extern void g_aucFLOW_AFSM_FOOT_VALVE_MAX_f(uint8_t rtu_LVL, uint8_t *rty_c_g_aucFLOW_AFSM_FOOT_VALVE_MAX); extern void Afoot_Summer(int16_t rtu_Amb_Fb, uint8_t rtu_LVL, uint16_t rty_Out1 [9], uint8_t rtu_setTempFL, uint8_t rtu_setTempFR); extern void left(uint8_t rtu_idx, uint16_t rty_vals[9]); extern void g_assSTART_ENTER_INCAR_j(uint8_t rtu_LVL, int16_t *rty_out); extern void g_assSTART_ENTER_COOLANT_p(uint8_t rtu_LVL, int16_t *rty_out); extern void Level4(int8_t *rty_step1, const uint16_t *rtd_ECT, const uint8_t *rtd_LEVEL, const double *rtd_MODE_DRIVER); extern void Level0(int8_t *rty_step); extern void incarfilterdown(uint8_t rtu_LVL, uint8_t *rty_out); extern void incarfilterup(uint8_t rtu_LVL, uint8_t *rty_out); extern void g_assSTART_COOLANT_STEP0_TO_1_h(uint8_t rtu_LVL, int16_t *rty_out); extern void uwayvalvestatus(uint8_t rtu_LVL, uint8_t *rty_out); extern void Dtg_FrontLower_X(uint8_t rtu_LVL, uint8_t *rty_out); extern void Dtg_FrontUpper_X(uint8_t rtu_LVL, uint8_t *rty_out); extern void Incartempgotofromstep1tostep2(uint8_t rtu_LVL, int16_t *rty_out); extern void blowerFR(uint8_t rtu_LVL, uint16_t *rty_out); extern void modeFRstep1(uint8_t rtu_LVL, uint8_t *rty_out); extern void windowheating(uint8_t rtu_LVL, uint8_t *rty_out); extern void Timegotofromstep1tostep2(uint8_t rtu_LVL, int16_t *rty_out); extern void ECTminmax(uint8_t rtu_LVL, int16_t rty_out[2]); extern void blowerminmax(uint8_t rtu_LVL, uint16_t rty_out[2]); extern void Level4_c(int8_t *rty_step, uint16_t *rtd_Blower_FL, uint16_t *rtd_Blower_FR, uint8_t *rtd_Dtg_FLL, uint8_t *rtd_Dtg_FLR, uint8_t *rtd_Dtg_FUL, uint8_t *rtd_Dtg_FUR, const uint16_t * rtd_ECT, uint8_t *rtd_El_window_heating, const int16_t *rtd_Incar_FL, uint8_t *rtd_Incar_filter_down_value, uint8_t *rtd_Incar_filter_up_value, const uint8_t *rtd_LEVEL, uint8_t *rtd_Mode_FL, uint8_t *rtd_Mode_FR, double *rtd_Recirculation, uint8_t *rtd_Valve_3_way, const int8_t *rtd_step_start_controle_front, const uint32_t *rtd_t_now, DW_Level4_n *localDW); extern void uwayvalvestatus_a(uint8_t rtu_LVL, uint8_t *rty_out); extern void timeforstep(uint8_t rtu_LVL, uint8_t *rty_out); extern void timeforstep_j(uint8_t rtu_LVL, uint8_t *rty_out); extern void Timegotofromstep2tostep3(uint8_t rtu_LVL, int16_t *rty_out); extern void blowerstep(uint8_t rtu_LVL, uint16_t *rty_out); extern void blowertimeforstep(uint8_t rtu_LVL, uint16_t *rty_out); extern void step_j(uint8_t rtu_LVL, uint8_t *rty_out); extern void timeforstep_g(uint8_t rtu_LVL, uint8_t *rty_out); extern void windowheating_k(uint8_t rtu_LVL, uint8_t *rty_out); extern void autodemistautodefog(uint8_t rtu_LVL, uint8_t *rty_out); extern void Level3(int8_t *rty_step, uint8_t *rtd_Autodefog, uint16_t *rtd_Blower_FL, uint16_t *rtd_Blower_FR, const uint16_t *rtd_Blower_logic_FL, uint8_t *rtd_Dtg_FLL, uint8_t *rtd_Dtg_FLR, uint8_t *rtd_Dtg_FUL, uint8_t *rtd_Dtg_FUR, const uint8_t *rtd_Dtg_logic_FLL, const uint8_t *rtd_Dtg_logic_FUL, uint8_t *rtd_El_window_heating, const bool *rtd_HI_logic_on, uint8_t *rtd_Incar_filter_down_value, uint8_t *rtd_Incar_filter_up_value, const uint8_t *rtd_LEVEL, uint8_t *rtd_Mode_FL, uint8_t *rtd_Mode_FR, const uint8_t *rtd_Mode_logic_FL, double *rtd_Recirculation, uint8_t *rtd_Valve_3_way, const int8_t *rtd_step_start_controle_front, const uint32_t *rtd_t_now, DW_Level3 *localDW); extern void Step3F(int8_t *rty_step, int8_t *rtd_start_control_finished_front); extern void g_ausSTART_ENTER_SETTEMP_b(uint8_t rtu_LVL, int16_t *rty_out); extern void g_assSTART_ENTER_INCAR_p(uint8_t rtu_LVL, int16_t *rty_out); extern void g_assSTART_ENTER_COOLANT_e(uint8_t rtu_LVL, int16_t *rty_out); extern void Level4_e(int8_t *rty_step1, const uint16_t *rtd_ECT, const int16_t *rtd_Incar_RR, const uint8_t *rtd_LEVEL, const double *rtd_MODE_RR_passenger); extern void incarfilterdown_c(uint8_t rtu_LVL, uint8_t *rty_out); extern void incarfilterup_i(uint8_t rtu_LVL, uint8_t *rty_out); extern void g_assSTART_COOLANT_STEP0_TO_1_e(uint8_t rtu_LVL, int16_t *rty_out); extern void Level4_m(int8_t *rty_step1, uint16_t *rtd_Blower_RL, uint16_t *rtd_Blower_RR, uint8_t *rtd_Dtg_RL, uint8_t *rtd_Dtg_RR, const uint16_t *rtd_ECT, uint8_t *rtd_Incar_filter_down_value, uint8_t *rtd_Incar_filter_up_value, const uint8_t *rtd_LEVEL, uint8_t *rtd_Mode_RL, uint8_t *rtd_Mode_RR, uint8_t *rtd_Valve_2_way, uint8_t *rtd_Valve_3_way); extern void uwayvalve(uint8_t rtu_LVL, uint8_t *rty_out); extern void Dtg_rear(uint8_t rtu_LVL, uint8_t *rty_out); extern void Incartempgotofromstep1tostep2_j(uint8_t rtu_LVL, int16_t *rty_out); extern void Timegotofromstep1tostep2_l(uint8_t rtu_LVL, int16_t *rty_out); extern void moderearstep1(uint8_t rtu_LVL, uint8_t *rty_out); extern void Level0_b(int8_t *rty_step, uint16_t *rtd_Blower_RL, uint16_t *rtd_Blower_RR, uint8_t *rtd_Dtg_RL, uint8_t *rtd_Dtg_RR, const int16_t *rtd_Incar_RR, uint8_t *rtd_Incar_filter_down_value, uint8_t *rtd_Incar_filter_up_value, const uint8_t *rtd_LEVEL, uint8_t *rtd_Mode_RL, uint8_t *rtd_Mode_RR, double *rtd_Recirculation, uint8_t *rtd_Valve_2_way, const int8_t * rtd_step_start_controle_rear, const uint32_t *rtd_t_now, DW_Level0_c *localDW); extern void blowerstartfinish(uint8_t rtu_LVL, uint16_t rty_out[2]); extern void ECTminmax_l(uint8_t rtu_LVL, int16_t rty_out[2]); extern void Level4_d(int8_t *rty_step, uint16_t *rtd_Blower_RL, uint16_t *rtd_Blower_RR, uint8_t *rtd_Dtg_RL, uint8_t *rtd_Dtg_RR, const uint16_t *rtd_ECT, const int16_t *rtd_Incar_RR, uint8_t *rtd_Incar_filter_down_value, uint8_t *rtd_Incar_filter_up_value, const uint8_t *rtd_LEVEL, uint8_t *rtd_Mode_RL, uint8_t *rtd_Mode_RR, double *rtd_Recirculation, uint8_t *rtd_Valve_2_way, const int8_t * rtd_step_start_controle_rear, const uint32_t *rtd_t_now, DW_Level4_a *localDW); extern void timeforstep_jn(uint8_t rtu_LVL, uint8_t *rty_out); extern void blowerstep_d(uint8_t rtu_LVL, uint16_t *rty_out); extern void blowertimeforstep_l(uint8_t rtu_LVL, uint16_t *rty_out); extern void step_a(uint8_t rtu_LVL, uint8_t *rty_out); extern void timeforstep_h(uint8_t rtu_LVL, uint8_t *rty_out); extern void Level3_i(int8_t *rty_step, uint16_t *rtd_Blower_RL, uint16_t *rtd_Blower_RR, const uint16_t *rtd_Blower_logic_RR, uint8_t *rtd_Dtg_RL, uint8_t *rtd_Dtg_RR, const uint8_t *rtd_Dtg_logic_RR, const bool *rtd_HI_logic_on, uint8_t *rtd_Incar_filter_down_value, uint8_t *rtd_Incar_filter_up_value, const uint8_t *rtd_LEVEL, uint8_t *rtd_Mode_RL, uint8_t *rtd_Mode_RR, const uint8_t *rtd_Mode_logic_RR, double *rtd_Recirculation, uint8_t *rtd_Valve_2_way, const int8_t *rtd_step_start_controle_rear, const uint32_t *rtd_t_now, DW_Level3_n *localDW); #endif /* HVAC_model_private_h_ */ /* * File trailer for generated code. * * [EOF] */