FreeCalypso > hg > fc-magnetite
view src/cs/drivers/drv_app/kpd/board/kpd_scan_functions.c @ 662:8cd8fd15a095
SIM speed enhancement re-enabled and made configurable
TI's original code supported SIM speed enhancement, but Openmoko had it
disabled, and OM's disabling of speed enhancement somehow caused certain
SIM cards to start working which didn't work before (OM's bug #666).
Because our FC community is much smaller in year 2020 than OM's community
was in their day, we are not able to find one of those #666-affected SIMs,
thus the real issue they had encountered remains elusive. Thus our
solution is to re-enable SIM speed enhancement and simply wait for if
and when someone runs into a #666-affected SIM once again. We provide
a SIM_allow_speed_enhancement global variable that allows SIM speed
enhancement to be enabled or disabled per session, and an /etc/SIM_spenh
file in FFS that allows it to enabled or disabled on a non-volatile
basis. SIM speed enhancement is now enabled by default.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Sun, 24 May 2020 05:02:28 +0000 |
| parents | 92dbfa906f66 |
| children |
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/** * @file kpd_scan_functions.c * * Implementation of hardware keypad interface functions. * These functions implement the keypad interface with the windows. * * @author Laurent Sollier (l-sollier@ti.com) * @version 0.1 */ /* * History: * * Date Author Modification * ------------------------------------ * 10/10/2001 L Sollier Create * * * (C) Copyright 2001 by Texas Instruments Incorporated, All Rights Reserved */ #include "board.cfg" #include "fc-target.h" #include "nucleus.h" /* used for HISR */ #include "kpd/kpd_scan_functions.h" #include "kpd/kpd_cfg.h" #include "kpd/kpd_physical_key_def.h" #include "kpd/kpd_messages_i.h" #include "kpd/kpd_env.h" #include "rvf/rvf_api.h" #include "rvm/rvm_use_id_list.h" #include "rvf/rvf_env.h" #if (CHIPSET == 12) #include "inth/sys_inth.h" #else #include "armio/armio.h" #include "inth/iq.h" #endif #include "memif/mem.h" #if (CHIPSET == 12) #define KBR_CTRL_REG (MEM_KEYBOARD + 0x00) /* KBR control reg */ #define KBR_DEBOUNCING_TIME (MEM_KEYBOARD + 0x02) /* KBR debouncing time reg */ #define KBR_STATE_MACHINE_STATUS (MEM_KEYBOARD + 0x0E) /* KBR state machine status reg */ #define KBR_IN (MEM_KEYBOARD + 0x10) /* KBR inputs (rows) */ #define KBR_OUT (MEM_KEYBOARD + 0x12) /* KBR outputs (columns) */ #endif #if (CHIPSET == 12) #define KP_ROW_IN KBR_IN #define KP_COL_OUT KBR_OUT #else #define KP_ROW_IN ARMIO_KBR_IN #define KP_COL_OUT ARMIO_KBR_OUT #endif #if (BOARD == 7) #define KP_ROWS 5 #define KP_COLS 4 const T_KPD_PHYSICAL_KEY_ID keypad_layout[KP_ROWS][KP_COLS]= { /* Layout of B-Sample */ {KPD_PKEY_SOFT_LEFT, KPD_PKEY_UP, KPD_PKEY_DOWN, KPD_PKEY_SOFT_RIGHT}, {KPD_PKEY_1, KPD_PKEY_2, KPD_PKEY_3, KPD_PKEY_GREEN}, {KPD_PKEY_4, KPD_PKEY_5, KPD_PKEY_6, KPD_PKEY_NULL}, {KPD_PKEY_7, KPD_PKEY_8, KPD_PKEY_9, KPD_PKEY_NULL}, {KPD_PKEY_STAR, KPD_PKEY_0, KPD_PKEY_DIESE,KPD_PKEY_NULL}, }; #elif ((BOARD == 8) || (BOARD == 9)) #define KP_ROWS 5 #define KP_COLS 4 const T_KPD_PHYSICAL_KEY_ID keypad_layout[KP_ROWS][KP_COLS]= { /* Layout of C-Sample */ {KPD_PKEY_UP, KPD_PKEY_GREEN,KPD_PKEY_SOFT_RIGHT,KPD_PKEY_DOWN}, {KPD_PKEY_1, KPD_PKEY_2, KPD_PKEY_3, KPD_PKEY_SOFT_LEFT}, {KPD_PKEY_4, KPD_PKEY_5, KPD_PKEY_6, KPD_PKEY_NULL}, {KPD_PKEY_7, KPD_PKEY_8, KPD_PKEY_9, KPD_PKEY_NULL}, {KPD_PKEY_STAR, KPD_PKEY_0, KPD_PKEY_DIESE, KPD_PKEY_NULL}, }; #elif defined(CONFIG_TARGET_COMPAL) #define KP_ROWS 5 #define KP_COLS 4 const T_KPD_PHYSICAL_KEY_ID keypad_layout[KP_ROWS][KP_COLS]= { /* Mot C1xx keypad */ {KPD_PKEY_GREEN, KPD_PKEY_3, KPD_PKEY_2, KPD_PKEY_1}, {KPD_PKEY_UP, KPD_PKEY_6, KPD_PKEY_5, KPD_PKEY_4}, {KPD_PKEY_DOWN, KPD_PKEY_9, KPD_PKEY_8, KPD_PKEY_7}, {KPD_PKEY_LEFT, KPD_PKEY_DIESE, KPD_PKEY_0, KPD_PKEY_STAR}, {KPD_PKEY_RIGHT, KPD_PKEY_SOFT_RIGHT, KPD_PKEY_NAV_CENTER,KPD_PKEY_SOFT_LEFT}, }; #elif defined(CONFIG_TARGET_PIRELLI) #define KP_ROWS 5 #define KP_COLS 5 const T_KPD_PHYSICAL_KEY_ID keypad_layout[KP_ROWS][KP_COLS]= { /* Pirelli's keypad */ {KPD_PKEY_NAV_CENTER, KPD_PKEY_LEFT, KPD_PKEY_RIGHT, KPD_PKEY_UP, KPD_PKEY_NULL}, {KPD_PKEY_SOFT_LEFT, KPD_PKEY_SOFT_RIGHT, KPD_PKEY_GREEN, KPD_PKEY_DOWN, KPD_PKEY_VOL_UP}, {KPD_PKEY_3, KPD_PKEY_6, KPD_PKEY_9, KPD_PKEY_DIESE, KPD_PKEY_VOL_DOWN}, {KPD_PKEY_2, KPD_PKEY_5, KPD_PKEY_8, KPD_PKEY_0, KPD_PKEY_REC}, {KPD_PKEY_1, KPD_PKEY_4, KPD_PKEY_7, KPD_PKEY_STAR, KPD_PKEY_NULL}, }; #elif ((BOARD == 40) || (BOARD == 41) || (BOARD == 42) || (BOARD == 43)) #define KP_ROWS 5 #define KP_COLS 5 const T_KPD_PHYSICAL_KEY_ID keypad_layout[KP_ROWS][KP_COLS]= { /* Layout of D-Sample and E-Sample */ {KPD_PKEY_GREEN, KPD_PKEY_VOL_DOWN, KPD_PKEY_VOL_UP,KPD_PKEY_SOFT_LEFT, KPD_PKEY_LEFT}, {KPD_PKEY_1, KPD_PKEY_2, KPD_PKEY_3, KPD_PKEY_REC, KPD_PKEY_RIGHT}, {KPD_PKEY_4, KPD_PKEY_5, KPD_PKEY_6, KPD_PKEY_SOFT_RIGHT, KPD_PKEY_UP}, {KPD_PKEY_7, KPD_PKEY_8, KPD_PKEY_9, KPD_PKEY_NULL, KPD_PKEY_DOWN}, {KPD_PKEY_STAR, KPD_PKEY_0, KPD_PKEY_DIESE, KPD_PKEY_NULL, KPD_PKEY_NAV_CENTER}, }; #endif #define KP_ACTIVATE(i) (~(1<<i)) #define KP_IS_ACTIVE(rows,i) ((rows & (1<<i)) == 0) #define KP_ALL_OFF 0x1F #define KP_ALL_ON 0 extern T_KPD_ENV_CTRL_BLK* kpd_env_ctrl_blk; typedef struct { NU_HISR hisr; char hisr_stack[512]; } T_HISR_INFOS; static T_HISR_INFOS hisr_infos = {0}; /** * @name Functions implementation * */ /*@{*/ #if (CHIPSET == 12) /** kpd_init_ctrl_reg : Initialize the Control register */ void kpd_init_ctrl_reg(const UINT8 software_nreset, const T_KPD_Nsoftware_mode nsoftware_mode, const T_KPD_PTV ptv, const T_KPD_EnableDetection long_key_process_en, const T_KPD_EnableDetection time_out_empty_en, const T_KPD_EnableDetection time_out_long_key_en, const T_KPD_EnableDetection repeat_mode_en) { volatile UINT16 status_reg; status_reg = *(volatile UINT16*) KBR_STATE_MACHINE_STATUS; if ( (status_reg != KPD_TEST_TIMER_DEBOUNCING) && (status_reg != KPD_TEST_TIMER_LONG_KEY) && (status_reg != KPD_TEST_TIMER_TIME_OUT) && (status_reg != KPD_TEST_TIMER_REPEAT_KEY) ) { /* The PTV can be programmed since the timer is not running */ *(volatile UINT16*) KBR_CTRL_REG = (software_nreset | nsoftware_mode << 1 | ptv << 2 | long_key_process_en << 5 | time_out_empty_en << 6 | time_out_long_key_en << 7 | repeat_mode_en << 8); } else { /* The PTV must not be programmed when the timer is running */ SetGroupBits16(*(volatile unsigned short *)(KBR_CTRL_REG), 0, 1, software_nreset); SetGroupBits16(*(volatile unsigned short *)(KBR_CTRL_REG), 1, 1, nsoftware_mode); SetGroupBits16(*(volatile unsigned short *)(KBR_CTRL_REG), 5, 1, long_key_process_en); SetGroupBits16(*(volatile unsigned short *)(KBR_CTRL_REG), 6, 1, time_out_empty_en); SetGroupBits16(*(volatile unsigned short *)(KBR_CTRL_REG), 7, 1, time_out_long_key_en); SetGroupBits16(*(volatile unsigned short *)(KBR_CTRL_REG), 8, 1, repeat_mode_en); } } /** kpd_software_reset : reset software */ void kpd_software_reset(void) { volatile UINT16 mem_reg; mem_reg = (*(volatile UINT16*) KBR_CTRL_REG) & 0xFFFE; *(volatile UINT16*) KBR_CTRL_REG = mem_reg; } /** kpd_set_debouncing_time : Set the desired value of debouncing time */ void kpd_set_debouncing_time(const UINT8 debouncing_time) { *(volatile UINT16*) KBR_DEBOUNCING_TIME = debouncing_time; } #endif /* #if (CHIPSET == 12) */ /** * function: hisr_entry */ static void hisr_entry(void) { T_RVF_MB_STATUS mb_status; T_KPD_KEY_PRESSED_MSG* msg_key_pressed; T_KPD_PHYSICAL_KEY_ID key; /* Reserve memory for message */ mb_status = rvf_get_buf (kpd_env_ctrl_blk->prim_id, sizeof(T_KPD_KEY_PRESSED_MSG), (void **) &msg_key_pressed); if (mb_status != RVF_RED) /* Memory allocation success */ { /* Fill the message */ msg_key_pressed->hdr.msg_id = KPD_KEY_PRESSED_MSG; /* Virtual key id is not yet known */ msg_key_pressed->value = KPD_PKEY_NULL; if (mb_status == RVF_GREEN) msg_key_pressed->key_to_process = TRUE; else msg_key_pressed->key_to_process = FALSE; /* Send message to the keypad task */ rvf_send_msg(kpd_env_ctrl_blk->addr_id, msg_key_pressed); } else { KPD_SEND_TRACE("KPD: Not enough memory to send new key pressed", RV_TRACE_LEVEL_ERROR); kpd_acknowledge_key_pressed(); } } /** * function: kpd_initialize_keypad_hardware */ void kpd_initialize_keypad_hardware(void) { /* HISR creation */ NU_Create_HISR(&hisr_infos.hisr, "KPD_HISR", hisr_entry, 2, hisr_infos.hisr_stack, sizeof(hisr_infos.hisr_stack)); #if (CHIPSET == 12) /* Init control register ; hardware decoding */ kpd_init_ctrl_reg(1, HARDWARE_DECODING, KPD_CLK_DIV32, KPD_DETECTION_DISABLED, KPD_DETECTION_DISABLED, KPD_DETECTION_DISABLED, KPD_DETECTION_DISABLED); /* Debouncing time = 64ms */ kpd_set_debouncing_time(0x3F); #endif /* Activate all outputs */ *(volatile UINT16*) KP_COL_OUT = KP_ALL_ON; /* Unmask keypad interrupt */ #if ((BOARD == 8) || (BOARD == 9) || (BOARD == 40) || (BOARD == 41)) AI_UnmaskIT (ARMIO_MASKIT_KBD); #elif (CHIPSET == 12) F_INTH_ENABLE_ONE_IT(C_INTH_KEYBOARD_IT); #else IQ_Unmask (IQ_ARMIO); #endif } /** * function: kpd_key_handler */ void kpd_key_handler(void) { /* If keypad is not started, return immediately */ if ( (kpd_env_ctrl_blk == 0) || (kpd_env_ctrl_blk->swe_is_initialized == FALSE) ) { kpd_acknowledge_key_pressed(); } else { /* Mask keypad interrupt until key is released */ #if ((BOARD == 8) || (BOARD == 9) || (BOARD == 40) || (BOARD == 41)) AI_MaskIT (ARMIO_MASKIT_KBD); #elif (CHIPSET == 12) F_INTH_DISABLE_ONE_IT(C_INTH_KEYBOARD_IT); #else IQ_Mask(IQ_ARMIO); #endif /* Activate HISR to process the key event */ NU_Activate_HISR(&hisr_infos.hisr); } } /** * function: kpd_acknowledge_key_pressed */ void kpd_acknowledge_key_pressed(void) { /* Unmask keypad interrupt */ #if ((BOARD == 8) || (BOARD == 9) || (BOARD == 40) || (BOARD == 41)) AI_UnmaskIT (ARMIO_MASKIT_KBD); #elif (CHIPSET == 12) F_INTH_ENABLE_ONE_IT(C_INTH_KEYBOARD_IT); #else IQ_Unmask (IQ_ARMIO); #endif } /* * delay * * Wait a while to let bus settle * Magic value found by trial and error * */ static void delay(void) { volatile int i; for (i=0;i<10;i++) ; } /** * function: kpd_scan_keypad */ T_KPD_PHYSICAL_KEY_ID kpd_scan_keypad(void) { int row, col; volatile UINT16 rows; /* Activate all columns to find if any row is active */ *(volatile UINT16*) KP_COL_OUT = KP_ALL_ON; delay(); rows = (*(volatile UINT16*) KP_ROW_IN) & 0x1F; if (rows == KP_ALL_OFF) return KPD_PKEY_NULL; /* Deactivate all columns */ *(volatile UINT16*) KP_COL_OUT = KP_ALL_OFF; #ifdef CONFIG_TARGET_COMPAL /* Compal's power key handling */ delay(); rows = (*(volatile UINT16*) KP_ROW_IN) & 0x1F; if (KP_IS_ACTIVE(rows,4)) { /* Reactivate all columns */ *(volatile UINT16*) KP_COL_OUT = KP_ALL_ON; return KPD_PKEY_RED; } #endif /* Activate 1 column at a time */ for (col = 0; col < KP_COLS; col++) { *(volatile UINT16*) KP_COL_OUT = (KP_ACTIVATE(col)); delay(); /* Find which row is active */ rows = (*(volatile UINT16*) KP_ROW_IN) & 0x1F; if (rows != KP_ALL_OFF) { for (row = 0; row < KP_ROWS; row++) { /* first active row */ if ( KP_IS_ACTIVE(rows,row)) { /* Reactivate all columns */ *(volatile UINT16*) KP_COL_OUT = KP_ALL_ON; /* DO NOT remove this comment. It allows to simply define the link physical layout and physical key Id (for a new keypad) */ //KPD_SEND_TRACE_PARAM("KPD: Keypad layout check ", keypad_layout[row][col], RV_TRACE_LEVEL_DEBUG_HIGH); return keypad_layout[row][col]; } } } } /* No row was active - Reactivate all columns and return */ *(volatile UINT16*) KP_COL_OUT = KP_ALL_ON; return KPD_PKEY_NULL; } /*@}*/