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RZ/A1H CMSIS-RTOS RTX BSP for GR-PEACH.

Dependents:   GR-PEACH_Azure_Speech ImageZoomInout_Sample ImageRotaion_Sample ImageScroll_Sample ... more

Fork of R_BSP by Daiki Kato

SSIF

The SSIF driver implements transmission and reception functionality which uses the SSIF in the RZ/A Series.

Hello World!

Import program
R_BSP_SSIF_HelloWorld - main.cpp

00001 #include "mbed.h"
00002 #include "R_BSP_Ssif.h"
00003 #include "sine_data_tbl.h"
00004 
00005 //I2S send only, The upper limit of write buffer is 8.
00006 R_BSP_Ssif ssif(P4_4, P4_5, P4_7, P4_6, 0x80, 8, 0);
00007 
00008 static void callback_ssif_write_end(void * p_data, int32_t result, void * p_app_data) {
00009     if (result < 0) {
00010         printf("ssif write callback error %d\n", result);
00011     }
00012 }
00013 
00014 int main() {
00015     rbsp_data_conf_t   ssif_write_end_conf = {&callback_ssif_write_end, NULL};
00016     ssif_channel_cfg_t ssif_cfg;
00017     int32_t            result;
00018 
00019     //I2S Master, 44.1kHz, 16bit, 2ch
00020     ssif_cfg.enabled                = true;
00021     ssif_cfg.int_level              = 0x78;
00022     ssif_cfg.slave_mode             = false;
00023     ssif_cfg.sample_freq            = 44100u;
00024     ssif_cfg.clk_select             = SSIF_CFG_CKS_AUDIO_X1;
00025     ssif_cfg.multi_ch               = SSIF_CFG_MULTI_CH_1;
00026     ssif_cfg.data_word              = SSIF_CFG_DATA_WORD_16;
00027     ssif_cfg.system_word            = SSIF_CFG_SYSTEM_WORD_32;
00028     ssif_cfg.bclk_pol               = SSIF_CFG_FALLING;
00029     ssif_cfg.ws_pol                 = SSIF_CFG_WS_LOW;
00030     ssif_cfg.padding_pol            = SSIF_CFG_PADDING_LOW;
00031     ssif_cfg.serial_alignment       = SSIF_CFG_DATA_FIRST;
00032     ssif_cfg.parallel_alignment     = SSIF_CFG_LEFT;
00033     ssif_cfg.ws_delay               = SSIF_CFG_DELAY;
00034     ssif_cfg.noise_cancel           = SSIF_CFG_DISABLE_NOISE_CANCEL;
00035     ssif_cfg.tdm_mode               = SSIF_CFG_DISABLE_TDM;
00036     ssif_cfg.romdec_direct.mode     = SSIF_CFG_DISABLE_ROMDEC_DIRECT;
00037     ssif_cfg.romdec_direct.p_cbfunc = NULL;
00038     result = ssif.ConfigChannel(&ssif_cfg);
00039     if (result < 0) {
00040         printf("ssif config error %d\n", result);
00041     }
00042 
00043     while (1) {
00044         //The upper limit of write buffer is 8.
00045         result = ssif.write((void *)sin_data_44100Hz_16bit_2ch, 
00046                             sizeof(sin_data_44100Hz_16bit_2ch), &ssif_write_end_conf);
00047         if (result < 0) {
00048             printf("ssif write api error %d\n", result);
00049         }
00050     }
00051 }

API

Import library
R_BSP - R_BSP_Ssif Class Reference

Public Member Functions

R_BSP_Ssif (PinName sck, PinName ws, PinName tx, PinName rx, uint8_t int_level=0x80, int32_t max_write_num=16, int32_t max_read_num=16)
Constructor.
virtual ~R_BSP_Ssif ()
Destructor.
int32_t GetSsifChNo (void)
Get a value of SSIF channel number.
bool ConfigChannel (const ssif_channel_cfg_t *const p_ch_cfg)
Save configuration to the SSIF driver.
bool GetStatus (uint32_t *const p_status)
Get a value of SSISR register.
int32_t write (void *const p_data, uint32_t data_size, const rbsp_data_conf_t *const p_data_conf=NULL)
Write count bytes to the file associated.
int32_t read (void *const p_data, uint32_t data_size, const rbsp_data_conf_t *const p_data_conf=NULL)
Read count bytes to the file associated.

Protected Member Functions

void write_init (void *handle, void *p_func_a, int32_t max_buff_num=16)
Write init.
void read_init (void *handle, void *p_func_a, int32_t max_buff_num=16)
Read init.

Interface

See the Pinout page for more details

SCUX

The SCUX module consists of a sampling rate converter, a digital volume unit, and a mixer.
The SCUX driver can perform asynchronous and synchronous sampling rate conversions using the sampling rate converter. The SCUX driver uses the DMA transfer mode to input and output audio data.

Hello World!

Import program
R_BSP_SCUX_HelloWorld - main.cpp

00001 #include "mbed.h"
00002 #include "R_BSP_Scux.h"
00003 #include "USBHostMSD.h"
00004 
00005 R_BSP_Scux scux(SCUX_CH_0);
00006 
00007 #define WRITE_SAMPLE_NUM (128)
00008 #define READ_SAMPLE_NUM  (2048)
00009 
00010 const short sin_data[WRITE_SAMPLE_NUM] = {
00011  0x0000,0x0000,0x0C8C,0x0C8C,0x18F9,0x18F9,0x2528,0x2528
00012 ,0x30FB,0x30FB,0x3C56,0x3C56,0x471C,0x471C,0x5133,0x5133
00013 ,0x5A82,0x5A82,0x62F1,0x62F1,0x6A6D,0x6A6D,0x70E2,0x70E2
00014 ,0x7641,0x7641,0x7A7C,0x7A7C,0x7D89,0x7D89,0x7F61,0x7F61
00015 ,0x7FFF,0x7FFF,0x7F61,0x7F61,0x7D89,0x7D89,0x7A7C,0x7A7C
00016 ,0x7641,0x7641,0x70E2,0x70E2,0x6A6D,0x6A6D,0x62F1,0x62F1
00017 ,0x5A82,0x5A82,0x5133,0x5133,0x471C,0x471C,0x3C56,0x3C56
00018 ,0x30FB,0x30FB,0x2528,0x2528,0x18F9,0x18F9,0x0C8C,0x0C8C
00019 ,0x0000,0x0000,0xF374,0xF374,0xE707,0xE707,0xDAD8,0xDAD8
00020 ,0xCF05,0xCF05,0xC3AA,0xC3AA,0xB8E4,0xB8E4,0xAECD,0xAECD
00021 ,0xA57E,0xA57E,0x9D0F,0x9D0F,0x9593,0x9593,0x8F1E,0x8F1E
00022 ,0x89BF,0x89BF,0x8584,0x8584,0x8277,0x8277,0x809F,0x809F
00023 ,0x8001,0x8001,0x809F,0x809F,0x8277,0x8277,0x8584,0x8584
00024 ,0x89BF,0x89BF,0x8F1E,0x8F1E,0x9593,0x9593,0x9D0F,0x9D0F
00025 ,0xA57E,0xA57E,0xAECD,0xAECD,0xB8E4,0xB8E4,0xC3AA,0xC3AA
00026 ,0xCF05,0xCF05,0xDAD8,0xDAD8,0xE707,0xE707,0xF374,0xF374
00027 };
00028 
00029 #if defined(__ICCARM__)
00030 #pragma data_alignment=4
00031 short write_buff[WRITE_SAMPLE_NUM]@ ".mirrorram";
00032 #pragma data_alignment=4
00033 short read_buff[READ_SAMPLE_NUM]@ ".mirrorram";
00034 #else
00035 short write_buff[WRITE_SAMPLE_NUM] __attribute((section("NC_BSS"),aligned(4)));
00036 short read_buff[READ_SAMPLE_NUM] __attribute((section("NC_BSS"),aligned(4)));
00037 #endif
00038 
00039 void scux_setup(void);
00040 void write_task(void const*);
00041 void file_output_to_usb(void);
00042 
00043 int main(void) {
00044     // set up SRC parameters.
00045     scux_setup();
00046 
00047     printf("Sampling rate conversion Start.\n");
00048     // start accepting transmit/receive requests.
00049     scux.TransStart();
00050 
00051     // create a new thread to write to SCUX.
00052     Thread writeTask(write_task, NULL, osPriorityNormal, 1024 * 4);
00053 
00054     // receive request to the SCUX driver.
00055     scux.read(read_buff, sizeof(read_buff));
00056     printf("Sampling rate conversion End.\n");
00057 
00058     // output binary file to USB port 0.
00059     file_output_to_usb();
00060 }
00061 
00062 void scux_setup(void) {
00063     scux_src_usr_cfg_t src_cfg;
00064 
00065     src_cfg.src_enable           = true;
00066     src_cfg.word_len             = SCUX_DATA_LEN_16;
00067     src_cfg.mode_sync            = true;
00068     src_cfg.input_rate           = SAMPLING_RATE_48000HZ;
00069     src_cfg.output_rate          = SAMPLING_RATE_96000HZ;
00070     src_cfg.select_in_data_ch[0] = SELECT_IN_DATA_CH_0;
00071     src_cfg.select_in_data_ch[1] = SELECT_IN_DATA_CH_1;
00072 
00073     scux.SetSrcCfg(&src_cfg);
00074 }
00075 
00076 void scux_flush_callback(int scux_ch) {
00077     // do nothing
00078 }
00079 
00080 void write_task(void const*) {
00081     memcpy(write_buff, sin_data, sizeof(write_buff));
00082     // send request to the SCUX driver.
00083     scux.write(write_buff, sizeof(write_buff));
00084 
00085     // stop the acceptance of transmit/receive requests.
00086     scux.FlushStop(&scux_flush_callback);
00087 }
00088 
00089 void file_output_to_usb(void) {
00090     FILE * fp = NULL;
00091     int i;
00092 
00093     USBHostMSD msd("usb");
00094 
00095     // try to connect a MSD device
00096     for(i = 0; i < 10; i++) {
00097         if (msd.connect()) {
00098             break;
00099         }
00100         wait(0.5);
00101     }
00102 
00103     if (msd.connected()) {
00104         fp = fopen("/usb/scux_input.dat", "rb");
00105         if (fp == NULL) {
00106             fp = fopen("/usb/scux_input.dat", "wb");
00107             if (fp != NULL) {
00108                 fwrite(write_buff, sizeof(short), WRITE_SAMPLE_NUM, fp);
00109                 fclose(fp);
00110                 printf("Output binary file(Input data) to USB.\n");
00111             } else {
00112                 printf("Failed to output binary file(Input data).\n");
00113             }
00114         } else {
00115             printf("Binary file(Input data) exists.\n");
00116             fclose(fp);
00117         }
00118 
00119         fp = fopen("/usb/scux_output.dat", "rb");
00120         if (fp == NULL) {
00121             fp = fopen("/usb/scux_output.dat", "wb");
00122             if (fp != NULL) {
00123                 fwrite(read_buff, sizeof(short), READ_SAMPLE_NUM, fp);
00124                 fclose(fp);
00125                 printf("Output binary file(Output data) to USB.\n");
00126             } else {
00127                 printf("Failed to output binary file(Output data).\n");
00128             }
00129         } else {
00130             printf("Binary file(Output data) exists.\n");
00131             fclose(fp);
00132         }
00133     } else {
00134         printf("Failed to connect to the USB device.\n");
00135     }
00136 }

API

Import library
R_BSP - R_BSP_Scux Class Reference

Public Member Functions

R_BSP_Scux ( scux_ch_num_t channel, uint8_t int_level=0x80, int32_t max_write_num=16, int32_t max_read_num=16)
Constructor: Initializes and opens the channel designated by the SCUX driver.
virtual ~R_BSP_Scux (void)
Destructor: Closes the channel designated by the SCUX driver and exits.
bool TransStart (void)
Sets up the SCUX HW and starts operation, then starts accepting write/read requests.
bool FlushStop (void(*const callback)(int32_t))
Stops accepting write/read requests, flushes out all data in the SCUX that is requested for transfer, then stops the HW operation.
bool ClearStop (void)
Discards all data in the SCUX that is requested for transfer before stopping the hardware operation and stops accepting write/read requests.
bool SetSrcCfg (const scux_src_usr_cfg_t *const p_src_param)
Sets up SRC parameters.
bool GetWriteStat (uint32_t *const p_write_stat)
Obtains the state information of the write request.
bool GetReadStat (uint32_t *const p_read_stat)
Obtains the state information of the read request.
int32_t write (void *const p_data, uint32_t data_size, const rbsp_data_conf_t *const p_data_conf=NULL)
Write count bytes to the file associated.
int32_t read (void *const p_data, uint32_t data_size, const rbsp_data_conf_t *const p_data_conf=NULL)
Read count bytes to the file associated.

Protected Member Functions

void write_init (void *handle, void *p_func_a, int32_t max_buff_num=16)
Write init.
void read_init (void *handle, void *p_func_a, int32_t max_buff_num=16)
Read init.

Write request state transition diagram

/media/uploads/dkato/scux_write_state_transition.png

Read request state transition diagram

/media/uploads/dkato/scux_read_state_transition.png

RenesasBSP/drv_src/ssif/ssif_if.c@0:702bf7b2b7d8, 2015-06-01 (annotated)

Committer:
dkato
Date:
Mon Jun 01 08:33:21 2015 +0000
Revision:
0:702bf7b2b7d8
Child:
7:30ebba78fff0
first comit

Who changed what in which revision?

UserRevisionLine numberNew contents of line
dkato 0:702bf7b2b7d8 1 /*******************************************************************************
dkato 0:702bf7b2b7d8 2 * DISCLAIMER
dkato 0:702bf7b2b7d8 3 * This software is supplied by Renesas Electronics Corporation and is only
dkato 0:702bf7b2b7d8 4 * intended for use with Renesas products. No other uses are authorized. This
dkato 0:702bf7b2b7d8 5 * software is owned by Renesas Electronics Corporation and is protected under
dkato 0:702bf7b2b7d8 6 * all applicable laws, including copyright laws.
dkato 0:702bf7b2b7d8 7 * THIS SOFTWARE IS PROVIDED "AS IS" AND RENESAS MAKES NO WARRANTIES REGARDING
dkato 0:702bf7b2b7d8 8 * THIS SOFTWARE, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING BUT NOT
dkato 0:702bf7b2b7d8 9 * LIMITED TO WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE
dkato 0:702bf7b2b7d8 10 * AND NON-INFRINGEMENT. ALL SUCH WARRANTIES ARE EXPRESSLY DISCLAIMED.
dkato 0:702bf7b2b7d8 11 * TO THE MAXIMUM EXTENT PERMITTED NOT PROHIBITED BY LAW, NEITHER RENESAS
dkato 0:702bf7b2b7d8 12 * ELECTRONICS CORPORATION NOR ANY OF ITS AFFILIATED COMPANIES SHALL BE LIABLE
dkato 0:702bf7b2b7d8 13 * FOR ANY DIRECT, INDIRECT, SPECIAL, INCIDENTAL OR CONSEQUENTIAL DAMAGES FOR
dkato 0:702bf7b2b7d8 14 * ANY REASON RELATED TO THIS SOFTWARE, EVEN IF RENESAS OR ITS AFFILIATES HAVE
dkato 0:702bf7b2b7d8 15 * BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES.
dkato 0:702bf7b2b7d8 16 * Renesas reserves the right, without notice, to make changes to this software
dkato 0:702bf7b2b7d8 17 * and to discontinue the availability of this software. By using this software,
dkato 0:702bf7b2b7d8 18 * you agree to the additional terms and conditions found by accessing the
dkato 0:702bf7b2b7d8 19 * following link:
dkato 0:702bf7b2b7d8 20 * http://www.renesas.com/disclaimer
dkato 0:702bf7b2b7d8 21 * Copyright (C) 2013-2014 Renesas Electronics Corporation. All rights reserved.
dkato 0:702bf7b2b7d8 22 *******************************************************************************/
dkato 0:702bf7b2b7d8 23
dkato 0:702bf7b2b7d8 24 /*******************************************************************************
dkato 0:702bf7b2b7d8 25 * File Name : ssif_if.c
dkato 0:702bf7b2b7d8 26 * $Rev: 891 $
dkato 0:702bf7b2b7d8 27 * $Date:: 2014-06-27 10:40:52 +0900#$
dkato 0:702bf7b2b7d8 28 * Description : SSIF driver interface functions
dkato 0:702bf7b2b7d8 29 ******************************************************************************/
dkato 0:702bf7b2b7d8 30
dkato 0:702bf7b2b7d8 31 /*******************************************************************************
dkato 0:702bf7b2b7d8 32 Includes <System Includes>, "Project Includes"
dkato 0:702bf7b2b7d8 33 *******************************************************************************/
dkato 0:702bf7b2b7d8 34 #include "cmsis_os.h"
dkato 0:702bf7b2b7d8 35 #if(1) /* mbed */
dkato 0:702bf7b2b7d8 36 #else
dkato 0:702bf7b2b7d8 37 #include "ioif_public.h"
dkato 0:702bf7b2b7d8 38 #endif
dkato 0:702bf7b2b7d8 39 #include "ssif.h"
dkato 0:702bf7b2b7d8 40
dkato 0:702bf7b2b7d8 41 /*******************************************************************************
dkato 0:702bf7b2b7d8 42 Typedef definitions
dkato 0:702bf7b2b7d8 43 *******************************************************************************/
dkato 0:702bf7b2b7d8 44
dkato 0:702bf7b2b7d8 45
dkato 0:702bf7b2b7d8 46 /*******************************************************************************
dkato 0:702bf7b2b7d8 47 Macro definitions
dkato 0:702bf7b2b7d8 48 *******************************************************************************/
dkato 0:702bf7b2b7d8 49
dkato 0:702bf7b2b7d8 50
dkato 0:702bf7b2b7d8 51 /*******************************************************************************
dkato 0:702bf7b2b7d8 52 Exported global variables (to be accessed by other files)
dkato 0:702bf7b2b7d8 53 *******************************************************************************/
dkato 0:702bf7b2b7d8 54
dkato 0:702bf7b2b7d8 55
dkato 0:702bf7b2b7d8 56 /*******************************************************************************
dkato 0:702bf7b2b7d8 57 Private global variables and functions
dkato 0:702bf7b2b7d8 58 *******************************************************************************/
dkato 0:702bf7b2b7d8 59
dkato 0:702bf7b2b7d8 60 #if(1) /* mbed */
dkato 0:702bf7b2b7d8 61 static ssif_drv_stat_t ch_drv_stat[SSIF_NUM_CHANS] = {SSIF_DRVSTS_UNINIT};
dkato 0:702bf7b2b7d8 62 #else
dkato 0:702bf7b2b7d8 63 static void* R_SSIF_Init(void* const config_data, int32_t* const p_errno);
dkato 0:702bf7b2b7d8 64 static int_t R_SSIF_UnInit(void* const driver_instance, int32_t* const p_errno);
dkato 0:702bf7b2b7d8 65 static int_t R_SSIF_Open(void* const p_driver_instance, const char_t* const p_path_name, const int_t flags, const int_t mode, int32_t* const p_errno);
dkato 0:702bf7b2b7d8 66 static int_t R_SSIF_Close(void* const p_fd, int32_t* const p_errno);
dkato 0:702bf7b2b7d8 67 static int_t R_SSIF_Ioctl(void* const p_fd, const int_t request, void* const p_buf, int32_t* const p_errno);
dkato 0:702bf7b2b7d8 68 static int_t R_SSIF_WriteAsync(void* const p_fd, AIOCB* const p_aio, int32_t* const p_errno);
dkato 0:702bf7b2b7d8 69 static int_t R_SSIF_ReadAsync(void* const p_fd, AIOCB* const p_aio, int32_t* const p_errno);
dkato 0:702bf7b2b7d8 70 static int_t R_SSIF_Cancel(void* const p_fd, AIOCB* p_aio, int32_t* const p_errno);
dkato 0:702bf7b2b7d8 71 #endif
dkato 0:702bf7b2b7d8 72
dkato 0:702bf7b2b7d8 73 static size_t SSIF_StrnLen(const char_t p_str[], const size_t maxlen);
dkato 0:702bf7b2b7d8 74 static int32_t SSIF_Strncmp(const char_t p_str1[], const char_t p_str2[], const uint32_t maxlen);
dkato 0:702bf7b2b7d8 75 static void SSIF_SetErrCode(const int_t error_code, int32_t* const p_errno);
dkato 0:702bf7b2b7d8 76
dkato 0:702bf7b2b7d8 77 /******************************************************************************
dkato 0:702bf7b2b7d8 78 Exported global functions (to be accessed by other files)
dkato 0:702bf7b2b7d8 79 ******************************************************************************/
dkato 0:702bf7b2b7d8 80
dkato 0:702bf7b2b7d8 81 #if(1) /* mbed */
dkato 0:702bf7b2b7d8 82 #else
dkato 0:702bf7b2b7d8 83 /******************************************************************************
dkato 0:702bf7b2b7d8 84 * Function Name: R_SSIF_MakeCbTbl
dkato 0:702bf7b2b7d8 85 * @brief Make the SSIF driver function callback table
dkato 0:702bf7b2b7d8 86 *
dkato 0:702bf7b2b7d8 87 * Description:<br>
dkato 0:702bf7b2b7d8 88 *
dkato 0:702bf7b2b7d8 89 * @param none
dkato 0:702bf7b2b7d8 90 * @retval pointer of SSIF driver function callback table
dkato 0:702bf7b2b7d8 91 ******************************************************************************/
dkato 0:702bf7b2b7d8 92 /* ->IPA M1.1.1 : This is liblary funciotn that is called from other module. */
dkato 0:702bf7b2b7d8 93 IOIF_DRV_API* R_SSIF_MakeCbTbl(void)
dkato 0:702bf7b2b7d8 94 /* <-IPA M1.1.1 */
dkato 0:702bf7b2b7d8 95 {
dkato 0:702bf7b2b7d8 96 static IOIF_DRV_API ssif_apitbl;
dkato 0:702bf7b2b7d8 97
dkato 0:702bf7b2b7d8 98 /* ->MISRA 16.4, IPA M4.5.1 : This is IOIF library API type definitnon that can't be modified. */
dkato 0:702bf7b2b7d8 99 ssif_apitbl.family = IOIF_SERIAL_FAMILY;
dkato 0:702bf7b2b7d8 100 ssif_apitbl.fns.serial.initialise = &R_SSIF_Init;
dkato 0:702bf7b2b7d8 101 ssif_apitbl.fns.serial.uninitialise = &R_SSIF_UnInit;
dkato 0:702bf7b2b7d8 102 ssif_apitbl.fns.serial.open = &R_SSIF_Open;
dkato 0:702bf7b2b7d8 103 ssif_apitbl.fns.serial.close = &R_SSIF_Close;
dkato 0:702bf7b2b7d8 104 ssif_apitbl.fns.serial.ioctl = &R_SSIF_Ioctl;
dkato 0:702bf7b2b7d8 105 ssif_apitbl.fns.serial.read_a = &R_SSIF_ReadAsync;
dkato 0:702bf7b2b7d8 106 ssif_apitbl.fns.serial.write_a = &R_SSIF_WriteAsync;
dkato 0:702bf7b2b7d8 107 ssif_apitbl.fns.serial.cancel = &R_SSIF_Cancel;
dkato 0:702bf7b2b7d8 108 /* <-MISRA 16.4, IPA M4.5.1 */
dkato 0:702bf7b2b7d8 109
dkato 0:702bf7b2b7d8 110 return &ssif_apitbl;
dkato 0:702bf7b2b7d8 111 }
dkato 0:702bf7b2b7d8 112 #endif
dkato 0:702bf7b2b7d8 113
dkato 0:702bf7b2b7d8 114 /******************************************************************************
dkato 0:702bf7b2b7d8 115 * Function Name: R_SSIF_SWLtoLen
dkato 0:702bf7b2b7d8 116 * @brief Convert SSICR:SWL bits to system word length
dkato 0:702bf7b2b7d8 117 *
dkato 0:702bf7b2b7d8 118 * Description:<br>
dkato 0:702bf7b2b7d8 119 *
dkato 0:702bf7b2b7d8 120 * @param[in] ssicr_swl :SSICR register SWL field value(0 to 7)
dkato 0:702bf7b2b7d8 121 * @retval 8 to 256 :system word length(byte)
dkato 0:702bf7b2b7d8 122 ******************************************************************************/
dkato 0:702bf7b2b7d8 123 int_t R_SSIF_SWLtoLen(const ssif_chcfg_system_word_t ssicr_swl)
dkato 0:702bf7b2b7d8 124 {
dkato 0:702bf7b2b7d8 125 return SSIF_SWLtoLen(ssicr_swl);
dkato 0:702bf7b2b7d8 126 }
dkato 0:702bf7b2b7d8 127
dkato 0:702bf7b2b7d8 128 /******************************************************************************
dkato 0:702bf7b2b7d8 129 Private functions
dkato 0:702bf7b2b7d8 130 ******************************************************************************/
dkato 0:702bf7b2b7d8 131
dkato 0:702bf7b2b7d8 132 /******************************************************************************
dkato 0:702bf7b2b7d8 133 * Function Name: R_SSIF_Init
dkato 0:702bf7b2b7d8 134 * @brief Initialise the SSIF driver.
dkato 0:702bf7b2b7d8 135 *
dkato 0:702bf7b2b7d8 136 * Description:<br>
dkato 0:702bf7b2b7d8 137 *
dkato 0:702bf7b2b7d8 138 * @param[in] config_data :pointer of several parameters array per channels
dkato 0:702bf7b2b7d8 139 * @param[in,out] p_errno :pointer of error code
dkato 0:702bf7b2b7d8 140 * @retval not ERRROR :driver instance.
dkato 0:702bf7b2b7d8 141 * @retval EERROR :Failure.
dkato 0:702bf7b2b7d8 142 ******************************************************************************/
dkato 0:702bf7b2b7d8 143 /* ->MISRA 16.7, IPA M1.11.1 : This is IOIF library API type definitnon that can't be modified. */
dkato 0:702bf7b2b7d8 144 #if(1) /* mbed */
dkato 0:702bf7b2b7d8 145 void* R_SSIF_InitOne(const int_t channel, void* const config_data, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 146 /* <-MISRA 16.7, IPA M1.11.1 */
dkato 0:702bf7b2b7d8 147 {
dkato 0:702bf7b2b7d8 148 int_t ercd;
dkato 0:702bf7b2b7d8 149 void* p_ret = (void*)EERROR;
dkato 0:702bf7b2b7d8 150
dkato 0:702bf7b2b7d8 151 if (NULL == config_data)
dkato 0:702bf7b2b7d8 152 {
dkato 0:702bf7b2b7d8 153 ercd = EFAULT;
dkato 0:702bf7b2b7d8 154 }
dkato 0:702bf7b2b7d8 155 else if (channel >= SSIF_NUM_CHANS)
dkato 0:702bf7b2b7d8 156 {
dkato 0:702bf7b2b7d8 157 ercd = EFAULT;
dkato 0:702bf7b2b7d8 158 }
dkato 0:702bf7b2b7d8 159 else
dkato 0:702bf7b2b7d8 160 {
dkato 0:702bf7b2b7d8 161 ch_drv_stat[channel] = SSIF_DRVSTS_INIT;
dkato 0:702bf7b2b7d8 162
dkato 0:702bf7b2b7d8 163 ercd = SSIF_InitialiseOne(channel, (ssif_channel_cfg_t*)config_data);
dkato 0:702bf7b2b7d8 164
dkato 0:702bf7b2b7d8 165 if (ESUCCESS == ercd)
dkato 0:702bf7b2b7d8 166 {
dkato 0:702bf7b2b7d8 167 p_ret = (void*)&g_ssif_info_drv;
dkato 0:702bf7b2b7d8 168 }
dkato 0:702bf7b2b7d8 169 else
dkato 0:702bf7b2b7d8 170 {
dkato 0:702bf7b2b7d8 171 ch_drv_stat[channel] = SSIF_DRVSTS_UNINIT;
dkato 0:702bf7b2b7d8 172 }
dkato 0:702bf7b2b7d8 173 }
dkato 0:702bf7b2b7d8 174
dkato 0:702bf7b2b7d8 175 SSIF_SetErrCode(ercd, p_errno);
dkato 0:702bf7b2b7d8 176
dkato 0:702bf7b2b7d8 177 return p_ret;
dkato 0:702bf7b2b7d8 178 }
dkato 0:702bf7b2b7d8 179 #else
dkato 0:702bf7b2b7d8 180 static void* R_SSIF_Init(void* const config_data, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 181 /* <-MISRA 16.7, IPA M1.11.1 */
dkato 0:702bf7b2b7d8 182 {
dkato 0:702bf7b2b7d8 183 int_t ercd;
dkato 0:702bf7b2b7d8 184 void* p_ret = (void*)EERROR;
dkato 0:702bf7b2b7d8 185
dkato 0:702bf7b2b7d8 186 if (NULL == config_data)
dkato 0:702bf7b2b7d8 187 {
dkato 0:702bf7b2b7d8 188 ercd = EFAULT;
dkato 0:702bf7b2b7d8 189 }
dkato 0:702bf7b2b7d8 190 else if (SSIF_DRVSTS_UNINIT != g_ssif_info_drv.drv_stat)
dkato 0:702bf7b2b7d8 191 {
dkato 0:702bf7b2b7d8 192 ercd = EBUSY;
dkato 0:702bf7b2b7d8 193 }
dkato 0:702bf7b2b7d8 194 else
dkato 0:702bf7b2b7d8 195 {
dkato 0:702bf7b2b7d8 196 g_ssif_info_drv.drv_stat = SSIF_DRVSTS_INIT;
dkato 0:702bf7b2b7d8 197
dkato 0:702bf7b2b7d8 198 ercd = SSIF_Initialise((ssif_channel_cfg_t*)config_data);
dkato 0:702bf7b2b7d8 199
dkato 0:702bf7b2b7d8 200 if (ESUCCESS == ercd)
dkato 0:702bf7b2b7d8 201 {
dkato 0:702bf7b2b7d8 202 p_ret = (void*)&g_ssif_info_drv;
dkato 0:702bf7b2b7d8 203 }
dkato 0:702bf7b2b7d8 204 else
dkato 0:702bf7b2b7d8 205 {
dkato 0:702bf7b2b7d8 206 g_ssif_info_drv.drv_stat = SSIF_DRVSTS_UNINIT;
dkato 0:702bf7b2b7d8 207 }
dkato 0:702bf7b2b7d8 208 }
dkato 0:702bf7b2b7d8 209
dkato 0:702bf7b2b7d8 210 SSIF_SetErrCode(ercd, p_errno);
dkato 0:702bf7b2b7d8 211
dkato 0:702bf7b2b7d8 212 return p_ret;
dkato 0:702bf7b2b7d8 213 }
dkato 0:702bf7b2b7d8 214 #endif
dkato 0:702bf7b2b7d8 215
dkato 0:702bf7b2b7d8 216 /******************************************************************************
dkato 0:702bf7b2b7d8 217 * Function Name: R_SSIF_UnInit
dkato 0:702bf7b2b7d8 218 * @brief Uninitialise the SSIF deiver.
dkato 0:702bf7b2b7d8 219 *
dkato 0:702bf7b2b7d8 220 * Description:<br>
dkato 0:702bf7b2b7d8 221 *
dkato 0:702bf7b2b7d8 222 * @param[in,out] driver_instance :driver instance which was returned by<br>
dkato 0:702bf7b2b7d8 223 R_SSIF_Init
dkato 0:702bf7b2b7d8 224 * @param[in,out] p_errno :pointer of error code
dkato 0:702bf7b2b7d8 225 * @retval ESUCCESS :Success.
dkato 0:702bf7b2b7d8 226 * @retval EERROR :Failure.
dkato 0:702bf7b2b7d8 227 ******************************************************************************/
dkato 0:702bf7b2b7d8 228 #if(1) /* mbed */
dkato 0:702bf7b2b7d8 229 int_t R_SSIF_UnInitOne(const int_t channel, void* const driver_instance, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 230 {
dkato 0:702bf7b2b7d8 231 int_t ercd;
dkato 0:702bf7b2b7d8 232 int_t ret = ESUCCESS;
dkato 0:702bf7b2b7d8 233 ssif_info_drv_t* const p_info_drv = driver_instance;
dkato 0:702bf7b2b7d8 234
dkato 0:702bf7b2b7d8 235 if (NULL == p_info_drv)
dkato 0:702bf7b2b7d8 236 {
dkato 0:702bf7b2b7d8 237 ercd = EFAULT;
dkato 0:702bf7b2b7d8 238 }
dkato 0:702bf7b2b7d8 239 else if (channel >= SSIF_NUM_CHANS)
dkato 0:702bf7b2b7d8 240 {
dkato 0:702bf7b2b7d8 241 ercd = EFAULT;
dkato 0:702bf7b2b7d8 242 }
dkato 0:702bf7b2b7d8 243 else
dkato 0:702bf7b2b7d8 244 {
dkato 0:702bf7b2b7d8 245 if (SSIF_DRVSTS_INIT != ch_drv_stat[channel])
dkato 0:702bf7b2b7d8 246 {
dkato 0:702bf7b2b7d8 247 ercd = EFAULT;
dkato 0:702bf7b2b7d8 248 }
dkato 0:702bf7b2b7d8 249 else
dkato 0:702bf7b2b7d8 250 {
dkato 0:702bf7b2b7d8 251 ercd = SSIF_UnInitialiseOne(channel);
dkato 0:702bf7b2b7d8 252 ch_drv_stat[channel] = SSIF_DRVSTS_UNINIT;
dkato 0:702bf7b2b7d8 253 }
dkato 0:702bf7b2b7d8 254 }
dkato 0:702bf7b2b7d8 255
dkato 0:702bf7b2b7d8 256 if (ESUCCESS != ercd)
dkato 0:702bf7b2b7d8 257 {
dkato 0:702bf7b2b7d8 258 ret = EERROR;
dkato 0:702bf7b2b7d8 259 }
dkato 0:702bf7b2b7d8 260 SSIF_SetErrCode(ercd, p_errno);
dkato 0:702bf7b2b7d8 261
dkato 0:702bf7b2b7d8 262 return ret;
dkato 0:702bf7b2b7d8 263 }
dkato 0:702bf7b2b7d8 264 #else
dkato 0:702bf7b2b7d8 265 static int_t R_SSIF_UnInit(void* const driver_instance, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 266 {
dkato 0:702bf7b2b7d8 267 int_t ercd;
dkato 0:702bf7b2b7d8 268 int_t ret = ESUCCESS;
dkato 0:702bf7b2b7d8 269 ssif_info_drv_t* const p_info_drv = driver_instance;
dkato 0:702bf7b2b7d8 270
dkato 0:702bf7b2b7d8 271 if (NULL == p_info_drv)
dkato 0:702bf7b2b7d8 272 {
dkato 0:702bf7b2b7d8 273 ercd = EFAULT;
dkato 0:702bf7b2b7d8 274 }
dkato 0:702bf7b2b7d8 275 else
dkato 0:702bf7b2b7d8 276 {
dkato 0:702bf7b2b7d8 277 if (SSIF_DRVSTS_INIT != p_info_drv->drv_stat)
dkato 0:702bf7b2b7d8 278 {
dkato 0:702bf7b2b7d8 279 ercd = EFAULT;
dkato 0:702bf7b2b7d8 280 }
dkato 0:702bf7b2b7d8 281 else
dkato 0:702bf7b2b7d8 282 {
dkato 0:702bf7b2b7d8 283 ercd = SSIF_UnInitialise();
dkato 0:702bf7b2b7d8 284 p_info_drv->drv_stat = SSIF_DRVSTS_UNINIT;
dkato 0:702bf7b2b7d8 285 }
dkato 0:702bf7b2b7d8 286 }
dkato 0:702bf7b2b7d8 287
dkato 0:702bf7b2b7d8 288 if (ESUCCESS != ercd)
dkato 0:702bf7b2b7d8 289 {
dkato 0:702bf7b2b7d8 290 ret = EERROR;
dkato 0:702bf7b2b7d8 291 }
dkato 0:702bf7b2b7d8 292 SSIF_SetErrCode(ercd, p_errno);
dkato 0:702bf7b2b7d8 293
dkato 0:702bf7b2b7d8 294 return ret;
dkato 0:702bf7b2b7d8 295 }
dkato 0:702bf7b2b7d8 296 #endif
dkato 0:702bf7b2b7d8 297
dkato 0:702bf7b2b7d8 298 /******************************************************************************
dkato 0:702bf7b2b7d8 299 * Function Name: R_SSIF_Open
dkato 0:702bf7b2b7d8 300 * @brief Open an SSIF channel
dkato 0:702bf7b2b7d8 301 *
dkato 0:702bf7b2b7d8 302 * Description:<br>
dkato 0:702bf7b2b7d8 303 *
dkato 0:702bf7b2b7d8 304 * @param[in,out] p_drv_instance :driver instance which was returned by<br>
dkato 0:702bf7b2b7d8 305 R_SSIF_Init
dkato 0:702bf7b2b7d8 306 * @param[in] p_path_name :string of channel
dkato 0:702bf7b2b7d8 307 * @param[in] flags :access mode whether the channel is opened<br>
dkato 0:702bf7b2b7d8 308 for a read or a write
dkato 0:702bf7b2b7d8 309 * @param[in] mode :not used
dkato 0:702bf7b2b7d8 310 * @param[in,out] p_errno :pointer of error code
dkato 0:702bf7b2b7d8 311 * @retval not EERROR :channel handle
dkato 0:702bf7b2b7d8 312 * @retval EERROR :Failure.
dkato 0:702bf7b2b7d8 313 ******************************************************************************/
dkato 0:702bf7b2b7d8 314 #if(1) /* mbed */
dkato 0:702bf7b2b7d8 315 int_t R_SSIF_Open(void* const p_driver_instance, const char_t* const p_path_name, const int_t flags, const int_t mode, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 316 #else
dkato 0:702bf7b2b7d8 317 static int_t R_SSIF_Open(void* const p_driver_instance, const char_t* const p_path_name, const int_t flags, const int_t mode, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 318 #endif
dkato 0:702bf7b2b7d8 319 {
dkato 0:702bf7b2b7d8 320 uint32_t ssif_ch;
dkato 0:702bf7b2b7d8 321 void* p_channelHandle;
dkato 0:702bf7b2b7d8 322 size_t len;
dkato 0:702bf7b2b7d8 323 size_t req_path_len;
dkato 0:702bf7b2b7d8 324 ssif_info_drv_t* const p_info_drv = p_driver_instance;
dkato 0:702bf7b2b7d8 325 ssif_info_ch_t* p_info_ch = NULL;
dkato 0:702bf7b2b7d8 326 int_t ret;
dkato 0:702bf7b2b7d8 327 int_t ercd = ESUCCESS;
dkato 0:702bf7b2b7d8 328 osStatus os_ercd;
dkato 0:702bf7b2b7d8 329 int32_t os_ret;
dkato 0:702bf7b2b7d8 330 static const char_t* const ch_name_string[SSIF_NUM_CHANS] =
dkato 0:702bf7b2b7d8 331 {
dkato 0:702bf7b2b7d8 332 SSIF_CHSTR_0,
dkato 0:702bf7b2b7d8 333 SSIF_CHSTR_1,
dkato 0:702bf7b2b7d8 334 SSIF_CHSTR_2,
dkato 0:702bf7b2b7d8 335 SSIF_CHSTR_3,
dkato 0:702bf7b2b7d8 336 SSIF_CHSTR_4,
dkato 0:702bf7b2b7d8 337 SSIF_CHSTR_5
dkato 0:702bf7b2b7d8 338 };
dkato 0:702bf7b2b7d8 339
dkato 0:702bf7b2b7d8 340 UNUSED_ARG(mode);
dkato 0:702bf7b2b7d8 341
dkato 0:702bf7b2b7d8 342 if ((NULL == p_info_drv) || (NULL == p_path_name))
dkato 0:702bf7b2b7d8 343 {
dkato 0:702bf7b2b7d8 344 ercd = EFAULT;
dkato 0:702bf7b2b7d8 345 }
dkato 0:702bf7b2b7d8 346 else
dkato 0:702bf7b2b7d8 347 {
dkato 0:702bf7b2b7d8 348 req_path_len = strlen(p_path_name);
dkato 0:702bf7b2b7d8 349 if (0u == req_path_len)
dkato 0:702bf7b2b7d8 350 {
dkato 0:702bf7b2b7d8 351 ercd = ENOENT;
dkato 0:702bf7b2b7d8 352 }
dkato 0:702bf7b2b7d8 353
dkato 0:702bf7b2b7d8 354 #if(1) /* mbed */
dkato 0:702bf7b2b7d8 355 #else
dkato 0:702bf7b2b7d8 356 if (ESUCCESS == ercd)
dkato 0:702bf7b2b7d8 357 {
dkato 0:702bf7b2b7d8 358 if (SSIF_DRVSTS_INIT != p_info_drv->drv_stat)
dkato 0:702bf7b2b7d8 359 {
dkato 0:702bf7b2b7d8 360 ercd = EFAULT;
dkato 0:702bf7b2b7d8 361 }
dkato 0:702bf7b2b7d8 362 }
dkato 0:702bf7b2b7d8 363 #endif
dkato 0:702bf7b2b7d8 364
dkato 0:702bf7b2b7d8 365 if (ESUCCESS == ercd)
dkato 0:702bf7b2b7d8 366 {
dkato 0:702bf7b2b7d8 367 /* Serch the same pathname */
dkato 0:702bf7b2b7d8 368 for (ssif_ch = 0u; (ssif_ch < SSIF_NUM_CHANS) && (p_info_ch == NULL); ssif_ch++)
dkato 0:702bf7b2b7d8 369 {
dkato 0:702bf7b2b7d8 370 len = SSIF_StrnLen(ch_name_string[ssif_ch], SSIF_MAX_PATH_LEN);
dkato 0:702bf7b2b7d8 371
dkato 0:702bf7b2b7d8 372 if (req_path_len < len)
dkato 0:702bf7b2b7d8 373 {
dkato 0:702bf7b2b7d8 374 len = req_path_len;
dkato 0:702bf7b2b7d8 375 }
dkato 0:702bf7b2b7d8 376
dkato 0:702bf7b2b7d8 377 if (0 == SSIF_Strncmp(p_path_name, ch_name_string[ssif_ch], len))
dkato 0:702bf7b2b7d8 378 {
dkato 0:702bf7b2b7d8 379 /* found a match */
dkato 0:702bf7b2b7d8 380 p_info_ch = &p_info_drv->info_ch[ssif_ch];
dkato 0:702bf7b2b7d8 381 }
dkato 0:702bf7b2b7d8 382 }
dkato 0:702bf7b2b7d8 383 }
dkato 0:702bf7b2b7d8 384 }
dkato 0:702bf7b2b7d8 385
dkato 0:702bf7b2b7d8 386 if (NULL == p_info_ch)
dkato 0:702bf7b2b7d8 387 {
dkato 0:702bf7b2b7d8 388 ercd = ENOENT;
dkato 0:702bf7b2b7d8 389 }
dkato 0:702bf7b2b7d8 390 else
dkato 0:702bf7b2b7d8 391 {
dkato 0:702bf7b2b7d8 392 if (ESUCCESS == ercd)
dkato 0:702bf7b2b7d8 393 {
dkato 0:702bf7b2b7d8 394 if (false == p_info_ch->enabled)
dkato 0:702bf7b2b7d8 395 {
dkato 0:702bf7b2b7d8 396 ercd = ENOTSUP;
dkato 0:702bf7b2b7d8 397 }
dkato 0:702bf7b2b7d8 398 }
dkato 0:702bf7b2b7d8 399
dkato 0:702bf7b2b7d8 400 if (ESUCCESS == ercd)
dkato 0:702bf7b2b7d8 401 {
dkato 0:702bf7b2b7d8 402 if (SSIF_CHSTS_INIT != p_info_ch->ch_stat)
dkato 0:702bf7b2b7d8 403 {
dkato 0:702bf7b2b7d8 404 ercd = EBADF;
dkato 0:702bf7b2b7d8 405 }
dkato 0:702bf7b2b7d8 406 }
dkato 0:702bf7b2b7d8 407
dkato 0:702bf7b2b7d8 408 if (ESUCCESS == ercd)
dkato 0:702bf7b2b7d8 409 {
dkato 0:702bf7b2b7d8 410 /* ->MISRA 10.6 : This macro is defined by CMSIS-RTOS that can't be modified. */
dkato 0:702bf7b2b7d8 411 os_ret = osSemaphoreWait(p_info_ch->sem_access, osWaitForever);
dkato 0:702bf7b2b7d8 412 /* <-MISRA 10.6 */
dkato 0:702bf7b2b7d8 413
dkato 0:702bf7b2b7d8 414 if ((-1) == os_ret)
dkato 0:702bf7b2b7d8 415 {
dkato 0:702bf7b2b7d8 416 ercd = EFAULT;
dkato 0:702bf7b2b7d8 417 }
dkato 0:702bf7b2b7d8 418 else
dkato 0:702bf7b2b7d8 419 {
dkato 0:702bf7b2b7d8 420 p_info_ch->openflag = flags;
dkato 0:702bf7b2b7d8 421 p_info_ch->p_aio_tx_curr = NULL;
dkato 0:702bf7b2b7d8 422 p_info_ch->p_aio_rx_curr = NULL;
dkato 0:702bf7b2b7d8 423
dkato 0:702bf7b2b7d8 424 ercd = SSIF_EnableChannel(p_info_ch);
dkato 0:702bf7b2b7d8 425
dkato 0:702bf7b2b7d8 426 if (ESUCCESS == ercd)
dkato 0:702bf7b2b7d8 427 {
dkato 0:702bf7b2b7d8 428 p_info_ch->ch_stat = SSIF_CHSTS_OPEN;
dkato 0:702bf7b2b7d8 429 }
dkato 0:702bf7b2b7d8 430 }
dkato 0:702bf7b2b7d8 431 os_ercd = osSemaphoreRelease(p_info_ch->sem_access);
dkato 0:702bf7b2b7d8 432 if (osOK != os_ercd)
dkato 0:702bf7b2b7d8 433 {
dkato 0:702bf7b2b7d8 434 ercd = EFAULT;
dkato 0:702bf7b2b7d8 435 }
dkato 0:702bf7b2b7d8 436 }
dkato 0:702bf7b2b7d8 437 }
dkato 0:702bf7b2b7d8 438
dkato 0:702bf7b2b7d8 439 if (ESUCCESS != ercd)
dkato 0:702bf7b2b7d8 440 {
dkato 0:702bf7b2b7d8 441 ret = EERROR; /* EERROR(-1) */
dkato 0:702bf7b2b7d8 442 }
dkato 0:702bf7b2b7d8 443 else
dkato 0:702bf7b2b7d8 444 {
dkato 0:702bf7b2b7d8 445 p_channelHandle = (void*)p_info_ch;
dkato 0:702bf7b2b7d8 446 ret = (int_t)p_channelHandle;
dkato 0:702bf7b2b7d8 447 }
dkato 0:702bf7b2b7d8 448 SSIF_SetErrCode(ercd, p_errno);
dkato 0:702bf7b2b7d8 449
dkato 0:702bf7b2b7d8 450 return ret;
dkato 0:702bf7b2b7d8 451 }
dkato 0:702bf7b2b7d8 452
dkato 0:702bf7b2b7d8 453 /******************************************************************************
dkato 0:702bf7b2b7d8 454 * Function Name: R_SSIF_Close
dkato 0:702bf7b2b7d8 455 * @brief Close an SSIF channel.
dkato 0:702bf7b2b7d8 456 *
dkato 0:702bf7b2b7d8 457 * Description:<br>
dkato 0:702bf7b2b7d8 458 *
dkato 0:702bf7b2b7d8 459 * @param[in,out] p_fd :channel handle which was returned by R_SSIF_Open
dkato 0:702bf7b2b7d8 460 * @param[in,out] p_errno :pointer of error code
dkato 0:702bf7b2b7d8 461 * @retval ESUCCESS :Success.
dkato 0:702bf7b2b7d8 462 * @retval EERROR :Failure.
dkato 0:702bf7b2b7d8 463 ******************************************************************************/
dkato 0:702bf7b2b7d8 464 #if(1) /* mbed */
dkato 0:702bf7b2b7d8 465 int_t R_SSIF_Close(void* const p_fd, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 466 #else
dkato 0:702bf7b2b7d8 467 static int_t R_SSIF_Close(void* const p_fd, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 468 #endif
dkato 0:702bf7b2b7d8 469 {
dkato 0:702bf7b2b7d8 470 ssif_info_ch_t* const p_info_ch = p_fd;
dkato 0:702bf7b2b7d8 471 int_t ret = ESUCCESS;
dkato 0:702bf7b2b7d8 472 int_t ercd;
dkato 0:702bf7b2b7d8 473 osStatus os_ercd;
dkato 0:702bf7b2b7d8 474 int32_t os_ret;
dkato 0:702bf7b2b7d8 475
dkato 0:702bf7b2b7d8 476 if (NULL == p_info_ch)
dkato 0:702bf7b2b7d8 477 {
dkato 0:702bf7b2b7d8 478 ercd = EFAULT;
dkato 0:702bf7b2b7d8 479 }
dkato 0:702bf7b2b7d8 480 else
dkato 0:702bf7b2b7d8 481 {
dkato 0:702bf7b2b7d8 482 /* ->MISRA 10.6 : This macro is defined by CMSIS-RTOS that can't be modified. */
dkato 0:702bf7b2b7d8 483 /* Get semaphore to access the channel data */
dkato 0:702bf7b2b7d8 484 os_ret = osSemaphoreWait(p_info_ch->sem_access, osWaitForever);
dkato 0:702bf7b2b7d8 485 /* <-MISRA 10.6 */
dkato 0:702bf7b2b7d8 486
dkato 0:702bf7b2b7d8 487 if ((-1) == os_ret)
dkato 0:702bf7b2b7d8 488 {
dkato 0:702bf7b2b7d8 489 ercd = EFAULT;
dkato 0:702bf7b2b7d8 490 }
dkato 0:702bf7b2b7d8 491 else
dkato 0:702bf7b2b7d8 492 {
dkato 0:702bf7b2b7d8 493 if (SSIF_CHSTS_OPEN != p_info_ch->ch_stat)
dkato 0:702bf7b2b7d8 494 {
dkato 0:702bf7b2b7d8 495 ercd = EFAULT;
dkato 0:702bf7b2b7d8 496 }
dkato 0:702bf7b2b7d8 497 else
dkato 0:702bf7b2b7d8 498 {
dkato 0:702bf7b2b7d8 499 SSIF_PostAsyncCancel(p_info_ch, NULL);
dkato 0:702bf7b2b7d8 500
dkato 0:702bf7b2b7d8 501 ercd = SSIF_DisableChannel(p_info_ch);
dkato 0:702bf7b2b7d8 502
dkato 0:702bf7b2b7d8 503 if (ESUCCESS == ercd)
dkato 0:702bf7b2b7d8 504 {
dkato 0:702bf7b2b7d8 505 p_info_ch->ch_stat = SSIF_CHSTS_INIT;
dkato 0:702bf7b2b7d8 506 }
dkato 0:702bf7b2b7d8 507 }
dkato 0:702bf7b2b7d8 508
dkato 0:702bf7b2b7d8 509 /* Relese semaphore */
dkato 0:702bf7b2b7d8 510 os_ercd = osSemaphoreRelease(p_info_ch->sem_access);
dkato 0:702bf7b2b7d8 511
dkato 0:702bf7b2b7d8 512 if (osOK != os_ercd)
dkato 0:702bf7b2b7d8 513 {
dkato 0:702bf7b2b7d8 514 ercd = EFAULT;
dkato 0:702bf7b2b7d8 515 }
dkato 0:702bf7b2b7d8 516 }
dkato 0:702bf7b2b7d8 517 }
dkato 0:702bf7b2b7d8 518
dkato 0:702bf7b2b7d8 519 if (ESUCCESS != ercd)
dkato 0:702bf7b2b7d8 520 {
dkato 0:702bf7b2b7d8 521 ret = EERROR; /* EERROR(-1) */
dkato 0:702bf7b2b7d8 522 }
dkato 0:702bf7b2b7d8 523 SSIF_SetErrCode(ercd, p_errno);
dkato 0:702bf7b2b7d8 524
dkato 0:702bf7b2b7d8 525 return ret;
dkato 0:702bf7b2b7d8 526 }
dkato 0:702bf7b2b7d8 527
dkato 0:702bf7b2b7d8 528 /******************************************************************************
dkato 0:702bf7b2b7d8 529 * Function Name: R_SSIF_Ioctl
dkato 0:702bf7b2b7d8 530 * @brief IOCTL function of the SSIF deiver
dkato 0:702bf7b2b7d8 531 *
dkato 0:702bf7b2b7d8 532 * Description:<br>
dkato 0:702bf7b2b7d8 533 *
dkato 0:702bf7b2b7d8 534 * @param[in,out] p_fd :channel handle which was returned by R_SSIF_Open
dkato 0:702bf7b2b7d8 535 * @param[in] request :IOCTL request code
dkato 0:702bf7b2b7d8 536 * @param[in,out] p_buf :Meaning depends upon request.
dkato 0:702bf7b2b7d8 537 * @param[in,out] p_errno :pointer of error code
dkato 0:702bf7b2b7d8 538 * @retval ESUCCESS :Success.
dkato 0:702bf7b2b7d8 539 * @retval EERROR :Failure.
dkato 0:702bf7b2b7d8 540 ******************************************************************************/
dkato 0:702bf7b2b7d8 541 #if(1) /* mbed */
dkato 0:702bf7b2b7d8 542 int_t R_SSIF_Ioctl(void* const p_fd, const int_t request, void* const p_buf, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 543 #else
dkato 0:702bf7b2b7d8 544 static int_t R_SSIF_Ioctl(void* const p_fd, const int_t request, void* const p_buf, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 545 #endif
dkato 0:702bf7b2b7d8 546 {
dkato 0:702bf7b2b7d8 547 ssif_info_ch_t* const p_info_ch = p_fd;
dkato 0:702bf7b2b7d8 548 int_t ret = ESUCCESS;
dkato 0:702bf7b2b7d8 549 int_t ercd = ESUCCESS;
dkato 0:702bf7b2b7d8 550 osStatus os_ercd;
dkato 0:702bf7b2b7d8 551 int32_t os_ret;
dkato 0:702bf7b2b7d8 552
dkato 0:702bf7b2b7d8 553 if (NULL == p_info_ch)
dkato 0:702bf7b2b7d8 554 {
dkato 0:702bf7b2b7d8 555 ercd = EFAULT;
dkato 0:702bf7b2b7d8 556 }
dkato 0:702bf7b2b7d8 557 else
dkato 0:702bf7b2b7d8 558 {
dkato 0:702bf7b2b7d8 559 if (SSIF_CHSTS_OPEN != p_info_ch->ch_stat)
dkato 0:702bf7b2b7d8 560 {
dkato 0:702bf7b2b7d8 561 ercd = EFAULT;
dkato 0:702bf7b2b7d8 562 }
dkato 0:702bf7b2b7d8 563 else
dkato 0:702bf7b2b7d8 564 {
dkato 0:702bf7b2b7d8 565 /* ->MISRA 10.6 : This macro is defined by CMSIS-RTOS that can't be modified. */
dkato 0:702bf7b2b7d8 566 os_ret = osSemaphoreWait(p_info_ch->sem_access, osWaitForever);
dkato 0:702bf7b2b7d8 567 /* <-MISRA 10.6 */
dkato 0:702bf7b2b7d8 568
dkato 0:702bf7b2b7d8 569 if ((-1) == os_ret)
dkato 0:702bf7b2b7d8 570 {
dkato 0:702bf7b2b7d8 571 ercd = EFAULT;
dkato 0:702bf7b2b7d8 572 }
dkato 0:702bf7b2b7d8 573
dkato 0:702bf7b2b7d8 574 if (ESUCCESS == ercd)
dkato 0:702bf7b2b7d8 575 {
dkato 0:702bf7b2b7d8 576 switch (request)
dkato 0:702bf7b2b7d8 577 {
dkato 0:702bf7b2b7d8 578 case SSIF_CONFIG_CHANNEL:
dkato 0:702bf7b2b7d8 579 {
dkato 0:702bf7b2b7d8 580 if (NULL == p_buf)
dkato 0:702bf7b2b7d8 581 {
dkato 0:702bf7b2b7d8 582 ercd = EFAULT;
dkato 0:702bf7b2b7d8 583 }
dkato 0:702bf7b2b7d8 584 else
dkato 0:702bf7b2b7d8 585 {
dkato 0:702bf7b2b7d8 586 ssif_channel_cfg_t* const ch_info = (ssif_channel_cfg_t*)p_buf;
dkato 0:702bf7b2b7d8 587 ercd = SSIF_IOCTL_ConfigChannel(p_info_ch, ch_info);
dkato 0:702bf7b2b7d8 588 }
dkato 0:702bf7b2b7d8 589 break;
dkato 0:702bf7b2b7d8 590 }
dkato 0:702bf7b2b7d8 591
dkato 0:702bf7b2b7d8 592 case SSIF_GET_STATUS:
dkato 0:702bf7b2b7d8 593 {
dkato 0:702bf7b2b7d8 594 if (NULL == p_buf)
dkato 0:702bf7b2b7d8 595 {
dkato 0:702bf7b2b7d8 596 ercd = EFAULT;
dkato 0:702bf7b2b7d8 597 }
dkato 0:702bf7b2b7d8 598 else
dkato 0:702bf7b2b7d8 599 {
dkato 0:702bf7b2b7d8 600 ercd = SSIF_IOCTL_GetStatus(p_info_ch, (uint32_t*)p_buf);
dkato 0:702bf7b2b7d8 601 }
dkato 0:702bf7b2b7d8 602 break;
dkato 0:702bf7b2b7d8 603 }
dkato 0:702bf7b2b7d8 604
dkato 0:702bf7b2b7d8 605 default:
dkato 0:702bf7b2b7d8 606 {
dkato 0:702bf7b2b7d8 607 ercd = EINVAL;
dkato 0:702bf7b2b7d8 608 break;
dkato 0:702bf7b2b7d8 609 }
dkato 0:702bf7b2b7d8 610 } /* switch */
dkato 0:702bf7b2b7d8 611 }
dkato 0:702bf7b2b7d8 612 }
dkato 0:702bf7b2b7d8 613
dkato 0:702bf7b2b7d8 614 os_ercd = osSemaphoreRelease(p_info_ch->sem_access);
dkato 0:702bf7b2b7d8 615 if (osOK != os_ercd)
dkato 0:702bf7b2b7d8 616 {
dkato 0:702bf7b2b7d8 617 ercd = EFAULT;
dkato 0:702bf7b2b7d8 618 }
dkato 0:702bf7b2b7d8 619 }
dkato 0:702bf7b2b7d8 620
dkato 0:702bf7b2b7d8 621 if (ESUCCESS != ercd)
dkato 0:702bf7b2b7d8 622 {
dkato 0:702bf7b2b7d8 623 ret = EERROR; /* EERROR(-1) */
dkato 0:702bf7b2b7d8 624 }
dkato 0:702bf7b2b7d8 625 SSIF_SetErrCode(ercd, p_errno);
dkato 0:702bf7b2b7d8 626
dkato 0:702bf7b2b7d8 627 return ret;
dkato 0:702bf7b2b7d8 628 }
dkato 0:702bf7b2b7d8 629
dkato 0:702bf7b2b7d8 630 /******************************************************************************
dkato 0:702bf7b2b7d8 631 * Function Name: R_SSIF_WriteAsync
dkato 0:702bf7b2b7d8 632 * @brief Enqueue asynchronous write request
dkato 0:702bf7b2b7d8 633 *
dkato 0:702bf7b2b7d8 634 * Description:<br>
dkato 0:702bf7b2b7d8 635 *
dkato 0:702bf7b2b7d8 636 * @param[in,out] p_fd :channel handle which was returned by R_SSIF_Open
dkato 0:702bf7b2b7d8 637 * @param[in] p_aio :aio control block of write request
dkato 0:702bf7b2b7d8 638 * @param[in,out] p_errno :pointer of error code
dkato 0:702bf7b2b7d8 639 * @retval ESUCCESS :Success.
dkato 0:702bf7b2b7d8 640 * @retval EERROR :Failure.
dkato 0:702bf7b2b7d8 641 ******************************************************************************/
dkato 0:702bf7b2b7d8 642 #if(1) /* mbed */
dkato 0:702bf7b2b7d8 643 int_t R_SSIF_WriteAsync(void* const p_fd, AIOCB* const p_aio, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 644 #else
dkato 0:702bf7b2b7d8 645 static int_t R_SSIF_WriteAsync(void* const p_fd, AIOCB* const p_aio, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 646 #endif
dkato 0:702bf7b2b7d8 647 {
dkato 0:702bf7b2b7d8 648 ssif_info_ch_t* const p_info_ch = p_fd;
dkato 0:702bf7b2b7d8 649 int_t ret = ESUCCESS;
dkato 0:702bf7b2b7d8 650 int_t ercd = ESUCCESS;
dkato 0:702bf7b2b7d8 651
dkato 0:702bf7b2b7d8 652 if ((NULL == p_info_ch) || (NULL == p_aio))
dkato 0:702bf7b2b7d8 653 {
dkato 0:702bf7b2b7d8 654 ercd = EFAULT;
dkato 0:702bf7b2b7d8 655 }
dkato 0:702bf7b2b7d8 656 else
dkato 0:702bf7b2b7d8 657 {
dkato 0:702bf7b2b7d8 658 if (((uint32_t)O_RDONLY) == ((uint32_t)p_info_ch->openflag & O_ACCMODE))
dkato 0:702bf7b2b7d8 659 {
dkato 0:702bf7b2b7d8 660 ercd = EACCES;
dkato 0:702bf7b2b7d8 661 }
dkato 0:702bf7b2b7d8 662 else if (0u == p_aio->aio_nbytes)
dkato 0:702bf7b2b7d8 663 {
dkato 0:702bf7b2b7d8 664 ercd = EINVAL;
dkato 0:702bf7b2b7d8 665 }
dkato 0:702bf7b2b7d8 666 else
dkato 0:702bf7b2b7d8 667 {
dkato 0:702bf7b2b7d8 668 p_aio->aio_return = SSIF_ASYNC_W;
dkato 0:702bf7b2b7d8 669 SSIF_PostAsyncIo(p_info_ch, p_aio);
dkato 0:702bf7b2b7d8 670 }
dkato 0:702bf7b2b7d8 671 }
dkato 0:702bf7b2b7d8 672
dkato 0:702bf7b2b7d8 673 if (ESUCCESS != ercd)
dkato 0:702bf7b2b7d8 674 {
dkato 0:702bf7b2b7d8 675 ret = EERROR; /* EERROR(-1) */
dkato 0:702bf7b2b7d8 676 }
dkato 0:702bf7b2b7d8 677 SSIF_SetErrCode(ercd, p_errno);
dkato 0:702bf7b2b7d8 678
dkato 0:702bf7b2b7d8 679 return ret;
dkato 0:702bf7b2b7d8 680 }
dkato 0:702bf7b2b7d8 681
dkato 0:702bf7b2b7d8 682 /******************************************************************************
dkato 0:702bf7b2b7d8 683 * Function Name: R_SSIF_ReadAsync
dkato 0:702bf7b2b7d8 684 * @brief Enqueue asynchronous read request
dkato 0:702bf7b2b7d8 685 *
dkato 0:702bf7b2b7d8 686 * Description:<br>
dkato 0:702bf7b2b7d8 687 *
dkato 0:702bf7b2b7d8 688 * @param[in,out] p_fd :channel handle which was returned by R_SSIF_Open
dkato 0:702bf7b2b7d8 689 * @param[in] p_aio :aio control block of read request
dkato 0:702bf7b2b7d8 690 * @param[in,out] p_errno :pointer of error code
dkato 0:702bf7b2b7d8 691 * @retval ESUCCESS :Success.
dkato 0:702bf7b2b7d8 692 * @retval EERROR :Failure.
dkato 0:702bf7b2b7d8 693 ******************************************************************************/
dkato 0:702bf7b2b7d8 694 #if(1) /* mbed */
dkato 0:702bf7b2b7d8 695 int_t R_SSIF_ReadAsync(void* const p_fd, AIOCB* const p_aio, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 696 #else
dkato 0:702bf7b2b7d8 697 static int_t R_SSIF_ReadAsync(void* const p_fd, AIOCB* const p_aio, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 698 #endif
dkato 0:702bf7b2b7d8 699 {
dkato 0:702bf7b2b7d8 700 ssif_info_ch_t* const p_info_ch = p_fd;
dkato 0:702bf7b2b7d8 701 int_t ret = ESUCCESS;
dkato 0:702bf7b2b7d8 702 int_t ercd = ESUCCESS;
dkato 0:702bf7b2b7d8 703
dkato 0:702bf7b2b7d8 704 if ((NULL == p_info_ch) || (NULL == p_aio))
dkato 0:702bf7b2b7d8 705 {
dkato 0:702bf7b2b7d8 706 ercd = EFAULT;
dkato 0:702bf7b2b7d8 707 }
dkato 0:702bf7b2b7d8 708 else
dkato 0:702bf7b2b7d8 709 {
dkato 0:702bf7b2b7d8 710 if ((O_WRONLY == ((uint32_t)p_info_ch->openflag & O_ACCMODE))
dkato 0:702bf7b2b7d8 711 || (SSIF_CFG_ENABLE_ROMDEC_DIRECT
dkato 0:702bf7b2b7d8 712 == p_info_ch->romdec_direct.mode))
dkato 0:702bf7b2b7d8 713 {
dkato 0:702bf7b2b7d8 714 ercd = EACCES;
dkato 0:702bf7b2b7d8 715 }
dkato 0:702bf7b2b7d8 716 else if (0u == p_aio->aio_nbytes)
dkato 0:702bf7b2b7d8 717 {
dkato 0:702bf7b2b7d8 718 ercd = EINVAL;
dkato 0:702bf7b2b7d8 719 }
dkato 0:702bf7b2b7d8 720 else
dkato 0:702bf7b2b7d8 721 {
dkato 0:702bf7b2b7d8 722 p_aio->aio_return = SSIF_ASYNC_R;
dkato 0:702bf7b2b7d8 723 SSIF_PostAsyncIo(p_info_ch, p_aio);
dkato 0:702bf7b2b7d8 724 }
dkato 0:702bf7b2b7d8 725 }
dkato 0:702bf7b2b7d8 726
dkato 0:702bf7b2b7d8 727 if (ESUCCESS != ercd)
dkato 0:702bf7b2b7d8 728 {
dkato 0:702bf7b2b7d8 729 ret = EERROR; /* EERROR(-1) */
dkato 0:702bf7b2b7d8 730 }
dkato 0:702bf7b2b7d8 731 SSIF_SetErrCode(ercd, p_errno);
dkato 0:702bf7b2b7d8 732
dkato 0:702bf7b2b7d8 733 return ret;
dkato 0:702bf7b2b7d8 734 }
dkato 0:702bf7b2b7d8 735
dkato 0:702bf7b2b7d8 736 /******************************************************************************
dkato 0:702bf7b2b7d8 737 * Function Name: R_SSIF_Cancel
dkato 0:702bf7b2b7d8 738 * @brief Cancel read or write request(s)
dkato 0:702bf7b2b7d8 739 *
dkato 0:702bf7b2b7d8 740 * Description:<br>
dkato 0:702bf7b2b7d8 741 *
dkato 0:702bf7b2b7d8 742 * @param[in,out] p_fd :channel handle which was returned by R_SSIF_Open
dkato 0:702bf7b2b7d8 743 * @param[in] p_aio :aio control block to cancel or NULL to cancel all.
dkato 0:702bf7b2b7d8 744 * @param[in,out] p_errno :pointer of error code
dkato 0:702bf7b2b7d8 745 * @retval ESUCCESS :Success.
dkato 0:702bf7b2b7d8 746 * @retval EERROR :Failure.
dkato 0:702bf7b2b7d8 747 ******************************************************************************/
dkato 0:702bf7b2b7d8 748 #if(1) /* mbed */
dkato 0:702bf7b2b7d8 749 int_t R_SSIF_Cancel(void* const p_fd, AIOCB* const p_aio, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 750 #else
dkato 0:702bf7b2b7d8 751 static int_t R_SSIF_Cancel(void* const p_fd, AIOCB* const p_aio, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 752 #endif
dkato 0:702bf7b2b7d8 753 {
dkato 0:702bf7b2b7d8 754 ssif_info_ch_t* const p_info_ch = p_fd;
dkato 0:702bf7b2b7d8 755 int_t ret = ESUCCESS;
dkato 0:702bf7b2b7d8 756 int_t ercd = ESUCCESS;
dkato 0:702bf7b2b7d8 757 osStatus os_ercd;
dkato 0:702bf7b2b7d8 758 int32_t os_ret;
dkato 0:702bf7b2b7d8 759
dkato 0:702bf7b2b7d8 760 if (NULL == p_info_ch)
dkato 0:702bf7b2b7d8 761 {
dkato 0:702bf7b2b7d8 762 ercd = EFAULT;
dkato 0:702bf7b2b7d8 763 }
dkato 0:702bf7b2b7d8 764 else
dkato 0:702bf7b2b7d8 765 {
dkato 0:702bf7b2b7d8 766 /* ->MISRA 10.6 : This macro is defined by CMSIS-RTOS that can't be modified. */
dkato 0:702bf7b2b7d8 767 /* Get semaphore to access the channel data */
dkato 0:702bf7b2b7d8 768 os_ret = osSemaphoreWait(p_info_ch->sem_access, osWaitForever);
dkato 0:702bf7b2b7d8 769 /* <-MISRA 10.6 */
dkato 0:702bf7b2b7d8 770
dkato 0:702bf7b2b7d8 771 if ((-1) == os_ret)
dkato 0:702bf7b2b7d8 772 {
dkato 0:702bf7b2b7d8 773 ercd = EFAULT;
dkato 0:702bf7b2b7d8 774 }
dkato 0:702bf7b2b7d8 775 else
dkato 0:702bf7b2b7d8 776 {
dkato 0:702bf7b2b7d8 777 if (SSIF_CHSTS_OPEN != p_info_ch->ch_stat)
dkato 0:702bf7b2b7d8 778 {
dkato 0:702bf7b2b7d8 779 ercd = EFAULT;
dkato 0:702bf7b2b7d8 780 }
dkato 0:702bf7b2b7d8 781 else
dkato 0:702bf7b2b7d8 782 {
dkato 0:702bf7b2b7d8 783 SSIF_PostAsyncCancel(p_info_ch, p_aio);
dkato 0:702bf7b2b7d8 784 }
dkato 0:702bf7b2b7d8 785
dkato 0:702bf7b2b7d8 786 os_ercd = osSemaphoreRelease(p_info_ch->sem_access);
dkato 0:702bf7b2b7d8 787
dkato 0:702bf7b2b7d8 788 if (osOK != os_ercd)
dkato 0:702bf7b2b7d8 789 {
dkato 0:702bf7b2b7d8 790 ercd = EFAULT;
dkato 0:702bf7b2b7d8 791 }
dkato 0:702bf7b2b7d8 792 }
dkato 0:702bf7b2b7d8 793 }
dkato 0:702bf7b2b7d8 794
dkato 0:702bf7b2b7d8 795 if (ESUCCESS != ercd)
dkato 0:702bf7b2b7d8 796 {
dkato 0:702bf7b2b7d8 797 ret = EERROR; /* EERROR(-1) */
dkato 0:702bf7b2b7d8 798 }
dkato 0:702bf7b2b7d8 799 SSIF_SetErrCode(ercd, p_errno);
dkato 0:702bf7b2b7d8 800
dkato 0:702bf7b2b7d8 801 return ret;
dkato 0:702bf7b2b7d8 802 }
dkato 0:702bf7b2b7d8 803
dkato 0:702bf7b2b7d8 804 /******************************************************************************
dkato 0:702bf7b2b7d8 805 * Function Name: SSIF_StrnLen
dkato 0:702bf7b2b7d8 806 * @brief computes the length of the string
dkato 0:702bf7b2b7d8 807 *
dkato 0:702bf7b2b7d8 808 * Description:<br>
dkato 0:702bf7b2b7d8 809 *
dkato 0:702bf7b2b7d8 810 * @param[in] p_str :pointer of string.
dkato 0:702bf7b2b7d8 811 * @param[in] maxlen :maximum length of inspection
dkato 0:702bf7b2b7d8 812 * @retval < maxlen :number of characters in the string
dkato 0:702bf7b2b7d8 813 * @retval maxlen :string is longer than maxlen
dkato 0:702bf7b2b7d8 814 ******************************************************************************/
dkato 0:702bf7b2b7d8 815 static size_t SSIF_StrnLen(const char_t p_str[], const size_t maxlen)
dkato 0:702bf7b2b7d8 816 {
dkato 0:702bf7b2b7d8 817 size_t len;
dkato 0:702bf7b2b7d8 818
dkato 0:702bf7b2b7d8 819 if (NULL == p_str)
dkato 0:702bf7b2b7d8 820 {
dkato 0:702bf7b2b7d8 821 len = 0;
dkato 0:702bf7b2b7d8 822 }
dkato 0:702bf7b2b7d8 823 else
dkato 0:702bf7b2b7d8 824 {
dkato 0:702bf7b2b7d8 825 for (len = 0; len < maxlen; len++)
dkato 0:702bf7b2b7d8 826 {
dkato 0:702bf7b2b7d8 827 if ((int_t)p_str[len] == '\0')
dkato 0:702bf7b2b7d8 828 {
dkato 0:702bf7b2b7d8 829 break;
dkato 0:702bf7b2b7d8 830 }
dkato 0:702bf7b2b7d8 831 }
dkato 0:702bf7b2b7d8 832 }
dkato 0:702bf7b2b7d8 833
dkato 0:702bf7b2b7d8 834 return len;
dkato 0:702bf7b2b7d8 835 }
dkato 0:702bf7b2b7d8 836
dkato 0:702bf7b2b7d8 837 /******************************************************************************
dkato 0:702bf7b2b7d8 838 * Function Name: SSIF_Strncmp
dkato 0:702bf7b2b7d8 839 * @brief Compare two strings
dkato 0:702bf7b2b7d8 840 *
dkato 0:702bf7b2b7d8 841 * Description:<br>
dkato 0:702bf7b2b7d8 842 *
dkato 0:702bf7b2b7d8 843 * @param[in] p_str1 :pointer of string1
dkato 0:702bf7b2b7d8 844 * @param[in] p_str2 :pointer of string2
dkato 0:702bf7b2b7d8 845 * @param[in] maxlen :maximum length of comparison
dkato 0:702bf7b2b7d8 846 * @retval zero :strings are same.
dkato 0:702bf7b2b7d8 847 * @retval non zero :strings are different.
dkato 0:702bf7b2b7d8 848 ******************************************************************************/
dkato 0:702bf7b2b7d8 849 static int32_t SSIF_Strncmp(const char_t p_str1[], const char_t p_str2[], const uint32_t maxlen)
dkato 0:702bf7b2b7d8 850 {
dkato 0:702bf7b2b7d8 851 int32_t result = 0;
dkato 0:702bf7b2b7d8 852 uint32_t index;
dkato 0:702bf7b2b7d8 853
dkato 0:702bf7b2b7d8 854 if ((NULL == p_str1) || (NULL == p_str2))
dkato 0:702bf7b2b7d8 855 {
dkato 0:702bf7b2b7d8 856 result = -1;
dkato 0:702bf7b2b7d8 857 }
dkato 0:702bf7b2b7d8 858 else
dkato 0:702bf7b2b7d8 859 {
dkato 0:702bf7b2b7d8 860 for (index = 0; index < maxlen; index++)
dkato 0:702bf7b2b7d8 861 {
dkato 0:702bf7b2b7d8 862 /* compare charctor */
dkato 0:702bf7b2b7d8 863 result = ((int_t)p_str1[index]) - ((int_t)p_str2[index]);
dkato 0:702bf7b2b7d8 864 if ((result != 0)
dkato 0:702bf7b2b7d8 865 || ((int_t)p_str1[index] == '\0')
dkato 0:702bf7b2b7d8 866 || ((int_t)p_str2[index] == '\0'))
dkato 0:702bf7b2b7d8 867 {
dkato 0:702bf7b2b7d8 868 /* "charactor mismatch" or "end of string" */
dkato 0:702bf7b2b7d8 869 break;
dkato 0:702bf7b2b7d8 870 }
dkato 0:702bf7b2b7d8 871 }
dkato 0:702bf7b2b7d8 872 }
dkato 0:702bf7b2b7d8 873
dkato 0:702bf7b2b7d8 874 return result;
dkato 0:702bf7b2b7d8 875 }
dkato 0:702bf7b2b7d8 876
dkato 0:702bf7b2b7d8 877 /******************************************************************************
dkato 0:702bf7b2b7d8 878 * Function Name: SSIF_SetErrCode
dkato 0:702bf7b2b7d8 879 * @brief Set error code to error code pointer.
dkato 0:702bf7b2b7d8 880 *
dkato 0:702bf7b2b7d8 881 * Description:<br>
dkato 0:702bf7b2b7d8 882 * If error code pointer is NULL, do nothing.
dkato 0:702bf7b2b7d8 883 * @param[in] error_code :Error code.
dkato 0:702bf7b2b7d8 884 * @param[in,out] p_errno :Pointer of set error code.
dkato 0:702bf7b2b7d8 885 * @retval none
dkato 0:702bf7b2b7d8 886 ******************************************************************************/
dkato 0:702bf7b2b7d8 887 static void SSIF_SetErrCode(const int_t error_code, int32_t* const p_errno)
dkato 0:702bf7b2b7d8 888 {
dkato 0:702bf7b2b7d8 889 if (NULL != p_errno)
dkato 0:702bf7b2b7d8 890 {
dkato 0:702bf7b2b7d8 891 *p_errno = error_code;
dkato 0:702bf7b2b7d8 892 }
dkato 0:702bf7b2b7d8 893
dkato 0:702bf7b2b7d8 894 return;
dkato 0:702bf7b2b7d8 895 }
dkato 0:702bf7b2b7d8 896