Merge pull request nasa#1088 from nasa/integration-candidate

cFE Integration candidate: 2021-01-12

README.md

@@ -10,6 +10,15 @@ The detailed cFE user's guide can be viewed at <https://github.com/nasa/cFS/blob
 
 ## Version History
 
+### Development Build: 6.8.0-rc1+dev248
+
+- Replace `OS_FileSysStatVolume()` with`OS_fsBlocksFree()` which will be deprecated. This call reports the number of total blocks, not just the free blocks, making the check more accurate and removing the need for a workaround for desktop machines.
+- Instead of accessing `OS_time_t` values directly, use the OSAL-provided conversion and access methods. This provides independence and abstraction from the specific `OS_time_t` definition and allows OSAL to transition to a 64 bit value.
+- Removes the spurious `CFE_SB_TimeOut_t` typedef from `cfe_sb.h`. May affect any apps that inappropriately rely on the private typedef.
+- Removes unused `network_includes.h`. Not used by the framework anywhere,  apps should use OSAL Socket APIs instead.   
+- Fixes deprecation directive typos
+- See <https://github.com/nasa/cFE/pull/1088>
+
 ### Development Build: 6.8.0-rc1+dev236
 
 - Resolved doxygen warnings for osalguide and updated header file references

fsw/cfe-core/src/es/cfe_es_backgroundtask.c

@@ -136,25 +136,12 @@ void CFE_ES_BackgroundTask(void)
     {
         /*
          * compute the elapsed time (difference) between last
-         * execution and now, in microseconds.
-         *
-         * Note this calculation is done as a uint32 which will overflow
-         * after about 35 minutes, but the max delays ensure that this
-         * executes at least every few seconds, so that should never happen.
+         * execution and now, in milliseconds.
          */
         CFE_PSP_GetTime(&CurrTime);
-        ElapsedTime = 1000000 * (CurrTime.seconds - LastTime.seconds);
-        ElapsedTime += CurrTime.microsecs;
-        ElapsedTime -= LastTime.microsecs;
+        ElapsedTime = OS_TimeGetTotalMilliseconds(OS_TimeSubtract(CurrTime, LastTime));
         LastTime = CurrTime;
 
-        /*
-         * convert to milliseconds.
-         * we do not really need high precision
-         * for background task timings
-         */
-        ElapsedTime /= 1000;
-
         NextDelay = CFE_ES_BACKGROUND_MAX_IDLE_DELAY;   /* default; will be adjusted based on active jobs */
         JobPtr = CFE_ES_BACKGROUND_JOB_TABLE;
         JobTotal = CFE_ES_BACKGROUND_NUM_JOBS;

fsw/cfe-core/src/es/cfe_es_start.c

@@ -494,11 +494,11 @@ void CFE_ES_SetupResetVariables(uint32 StartType, uint32 StartSubtype, uint32 Bo
 */
 void CFE_ES_InitializeFileSystems(uint32 StartType)
 {
-   int32   RetStatus;
-   cpuaddr RamDiskMemoryAddress;
-   uint32  RamDiskMemorySize;
-   int32   BlocksFree;
-   int32   PercentFree;
+   int32        RetStatus;
+   cpuaddr      RamDiskMemoryAddress;
+   uint32       RamDiskMemorySize;
+   int32        PercentFree;
+   OS_statvfs_t StatBuf;
 
    /* 
    ** Get the memory area for the RAM disk 
@@ -601,25 +601,13 @@ void CFE_ES_InitializeFileSystems(uint32 StartType)
       /*
       ** See how many blocks are free in the RAM disk
       */
-      BlocksFree = OS_fsBlocksFree(CFE_PLATFORM_ES_RAM_DISK_MOUNT_STRING);   
-      if ( BlocksFree >= 0 )
+      RetStatus = OS_FileSysStatVolume(CFE_PLATFORM_ES_RAM_DISK_MOUNT_STRING, &StatBuf);
+      if ( RetStatus == OS_SUCCESS && StatBuf.total_blocks > 0 )
       {
-         /*
-         ** Need a sanity check for the desktop systems.
-         ** Because the desktop ports map the volatile disk to the host 
-         ** hard disk, it will report more free blocks than the defined number
-         ** of sectors ( blocks ). Therefore it must be truncated.
-         */
-         if ( BlocksFree > CFE_PLATFORM_ES_RAM_DISK_NUM_SECTORS )
-         {
-             BlocksFree = CFE_PLATFORM_ES_RAM_DISK_NUM_SECTORS - 1;
-         }
-
          /*
          ** Determine if the disk is too full 
          */
-         BlocksFree = BlocksFree * 100;
-         PercentFree = BlocksFree / CFE_PLATFORM_ES_RAM_DISK_NUM_SECTORS;
+         PercentFree = (StatBuf.blocks_free * 100) / StatBuf.total_blocks;
          CFE_ES_WriteToSysLog("Volatile Disk has %d Percent free space.\n",(int)PercentFree);
 
          if ( PercentFree < CFE_PLATFORM_ES_RAM_DISK_PERCENT_RESERVED )
@@ -721,7 +709,7 @@ void CFE_ES_InitializeFileSystems(uint32 StartType)
       else  /* could not determine free blocks */
       {         
          /* Log error message -- note that BlocksFree returns the error code in this case */
-         CFE_ES_WriteToSysLog("ES Startup: Error Determining Blocks Free on Volume. EC = 0x%08X\n",(unsigned int)BlocksFree);
+         CFE_ES_WriteToSysLog("ES Startup: Error Determining Blocks Free on Volume. EC = 0x%08X\n",(unsigned int)RetStatus);
 
          /*
          ** Delay to allow the message to be read
@@ -983,4 +971,3 @@ int32 CFE_ES_MainTaskSyncDelay(uint32 AppStateId, uint32 TimeOutMilliseconds)
 
     return Status;
 }
-

fsw/cfe-core/src/inc/cfe_sb.h

@@ -152,14 +152,6 @@ typedef CFE_MSG_TelemetryHeader_t CFE_SB_TlmHdr_t;
 #define CFE_SB_TLM_HDR_SIZE     (sizeof(CFE_MSG_TelemetryHeader_t))/**< \brief Size of telemetry header */
 #endif /* CFE_OMIT_DEPRECATED_6_8 */
 
-/** \brief  CFE_SB_TimeOut_t to primitive type definition
-**
-** Internally used by SB in the #CFE_SB_ReceiveBuffer API. Translated from the
-** input parmater named TimeOut which specifies the maximum time in
-** milliseconds that the caller wants to wait for a message.
-*/
-typedef uint32 CFE_SB_TimeOut_t;
-
 /** \brief  CFE_SB_PipeId_t to primitive type definition
 **
 ** Software Bus pipe identifier used in many SB APIs
@@ -646,7 +638,7 @@ CFE_Status_t  CFE_SB_PassMsg(CFE_MSG_Message_t *MsgPtr);
 **/
 CFE_Status_t CFE_SB_ReceiveBuffer(CFE_SB_Buffer_t **BufPtr, CFE_SB_PipeId_t PipeId, int32 TimeOut);
 
-#if CFE_OMIT_DEPRECATED_6_8
+#ifndef CFE_OMIT_DEPRECATED_6_8
 /**
  * \brief DEPRECATED: receive buffer
  * \deprecated use CFE_SB_ReceiveBuffer

fsw/cfe-core/src/inc/cfe_version.h

@@ -35,7 +35,7 @@
 
 
 /* Development Build Macro Definitions */
-#define CFE_BUILD_NUMBER 236 /*!< Development Build: Number of commits since baseline */
+#define CFE_BUILD_NUMBER 248 /*!< Development Build: Number of commits since baseline */
 #define CFE_BUILD_BASELINE "v6.8.0-rc1" /*!< Development Build: git tag that is the base for the current development */
 
 /* Version Macro Definitions */

fsw/cfe-core/src/sb/cfe_sb_api.c

@@ -1455,7 +1455,7 @@ int32  CFE_SB_TransmitBufferFull(CFE_SB_BufferD_t *BufDscPtr,
 
 }
 
-#if CFE_OMIT_DEPRECATED_6_8
+#ifndef CFE_OMIT_DEPRECATED_6_8
 int32 CFE_SB_RcvMsg(CFE_SB_Buffer_t **BufPtr,
                     CFE_SB_PipeId_t   PipeId,
                     int32             TimeOut)
@@ -1891,7 +1891,7 @@ int32 CFE_SB_ZeroCopyPass(CFE_SB_Buffer_t        *BufPtr,
 
 int32  CFE_SB_ReadQueue (CFE_SB_PipeD_t         *PipeDscPtr,
                          CFE_ES_ResourceID_t    TskId,
-                         CFE_SB_TimeOut_t       Time_Out,
+                         uint32                 Time_Out,
                          CFE_SB_BufferD_t       **Message)
 {
     int32              Status,TimeOut;

fsw/cfe-core/src/sb/cfe_sb_priv.h

@@ -239,7 +239,7 @@ void   CFE_SB_LockSharedData(const char *FuncName, int32 LineNumber);
 void   CFE_SB_UnlockSharedData(const char *FuncName, int32 LineNumber);
 void   CFE_SB_ReleaseBuffer (CFE_SB_BufferD_t *bd, CFE_SB_DestinationD_t *dest);
 int32  CFE_SB_ReadQueue(CFE_SB_PipeD_t *PipeDscPtr,CFE_ES_ResourceID_t TskId,
-                        CFE_SB_TimeOut_t Time_Out,CFE_SB_BufferD_t **Message );
+                        uint32 Time_Out,CFE_SB_BufferD_t **Message );
 int32  CFE_SB_WriteQueue(CFE_SB_PipeD_t *pd,uint32 TskId,
                          const CFE_SB_BufferD_t *bd,CFE_SB_MsgId_t MsgId );
 uint8  CFE_SB_GetPipeIdx(CFE_SB_PipeId_t PipeId);

fsw/cfe-core/src/time/cfe_time_api.c

@@ -489,57 +489,16 @@ CFE_TIME_Compare_t  CFE_TIME_Compare(CFE_TIME_SysTime_t TimeA, CFE_TIME_SysTime_
  */
 uint32  CFE_TIME_Sub2MicroSecs(uint32 SubSeconds)
 {
-    uint32 MicroSeconds;
-
-    /* 0xffffdf00 subseconds = 999999 microseconds, so anything greater 
-     * than that we set to 999999 microseconds, so it doesn't get to
-     * a million microseconds */
-
-	if (SubSeconds > 0xffffdf00)
-	{
-			MicroSeconds = 999999;
-	}
-    else
-    {
-        /*
-        **  Convert a 1/2^32 clock tick count to a microseconds count
-        **
-        **  Conversion factor is  ( ( 2 ** -32 ) / ( 10 ** -6 ) ).
-        **
-        **  Logic is as follows:
-        **    x * ( ( 2 ** -32 ) / ( 10 ** -6 ) )
-        **  = x * ( ( 10 ** 6  ) / (  2 ** 32 ) )
-        **  = x * ( ( 5 ** 6 ) ( 2 ** 6 ) / ( 2 ** 26 ) ( 2 ** 6) )
-        **  = x * ( ( 5 ** 6 ) / ( 2 ** 26 ) )
-        **  = x * ( ( 5 ** 3 ) ( 5 ** 3 ) / ( 2 ** 7 ) ( 2 ** 7 ) (2 ** 12) )
-        **
-        **  C code equivalent:
-        **  = ( ( ( ( ( x >> 7) * 125) >> 7) * 125) >> 12 )
-        */   
-
-    	MicroSeconds = (((((SubSeconds >> 7) * 125) >> 7) * 125) >> 12);
-
+    OS_time_t tm;
 
-        /* if the Subseconds % 0x4000000 != 0 then we will need to
-         * add 1 to the result. the & is a faster way of doing the % */  
-	    if ((SubSeconds & 0x3ffffff) != 0)
-    	{
-	    	MicroSeconds++;
-    	}
-
-        /* In the Micro2SubSecs conversion, we added an extra anomaly
-         * to get the subseconds to bump up against the end point,
-         * 0xFFFFF000. This must be accounted for here. Since we bumped
-         * at the half way mark, we must "unbump" at the same mark 
-         */
-        if (MicroSeconds > 500000)
-        {
-            MicroSeconds --;
-        }
-
-    } /* end else */
-
-    return(MicroSeconds);
+    /* 
+    ** Convert using the OSAL method.  Note that there
+    ** is no range check here because any uint32 value is valid,
+    ** and OSAL will handle and properly convert any input.
+    */
+    tm = OS_TimeAssembleFromSubseconds(0, SubSeconds);
+
+    return OS_TimeGetMicrosecondsPart(tm);
 
 } /* End of CFE_TIME_Sub2MicroSecs() */
 
@@ -549,51 +508,24 @@ uint32  CFE_TIME_Sub2MicroSecs(uint32 SubSeconds)
  */
 uint32  CFE_TIME_Micro2SubSecs(uint32 MicroSeconds)
 {
+    OS_time_t tm;
     uint32 SubSeconds;
 
     /*
     ** Conversion amount must be less than one second
+    ** (preserves existing behavior where output saturates at max value)
     */
     if (MicroSeconds > 999999)
     {
         SubSeconds = 0xFFFFFFFF;
     }
     else
     {
-    /*
-    **  Convert micro-seconds count to sub-seconds (1/2^32) count
-    **
-    **  Conversion factor is  ( ( 10 ** -6 ) / ( 2 ** -20 ).
-    **
-    **  Logic is as follows:
-    **    x * ( ( 10 ** -6 ) / ( 2 ** -32 ) )
-    **  = x * ( ( 2 ** 32 ) / ( 10 ** 6 ) )
-    **  = x * ( ( ( 2 ** 26 ) ( 2 ** 6) ) / ( ( 5 ** 6 ) ( 2 ** 6 ) ) )
-    **  = x * ( ( 2 ** 26 ) / ( 5 ** 6 ) )
-    **  = x * ( ( ( 2 ** 11) ( 2 ** 3) (2 ** 12) ) / ( 5( 5 ** 5 ) ) )
-    **  = x * ( ( ( ( ( 2 ** 11 ) / 5 ) * ( 2 ** 3 ) ) / ( 5 ** 5 ) ) * (2 ** 12) )
-    **
-    **  C code equivalent:
-    **  = ( ( ( ( ( x << 11 ) / 5 ) << 3 ) / 3125 ) << 12 )
-    **
-    **  Conversion factor was reduced and factored accordingly
-    **  to minimize precision loss and register overflow.
-    */
-        SubSeconds = ( ( ( ( MicroSeconds << 11 ) / 5 ) << 3 ) / 3125 ) << 12;
-
-        /* To get the SubSeconds to "bump up" against 0xFFFFF000 when 
-         * MicroSeconds = 9999999, we add in another anomaly to the 
-         * conversion at the half-way point  (500000 us). This will bump
-         * all of the subseconds up by 0x1000, so 999999 us == 0xFFFFF00,
-         * 999998 == 0xFFFFE000, etc. This extra anomaly is accounted for
-         * in the Sub2MicroSecs conversion as well.
-         */
-
-        if (SubSeconds > 0x80001000)
-        {
-           SubSeconds += 0x1000;
-        }
-
+        /*
+        ** Convert micro-seconds count to sub-seconds (1/2^32) count using OSAL
+        */
+        tm = OS_TimeAssembleFromNanoseconds(0, MicroSeconds * 1000);
+        SubSeconds = OS_TimeGetSubsecondsPart(tm);
     }
 
     return(SubSeconds);

fsw/cfe-core/src/time/cfe_time_utils.c

@@ -91,8 +91,8 @@ CFE_TIME_SysTime_t CFE_TIME_LatchClock(void)
     /*
     ** Convert time to cFE format (seconds : 1/2^32 subseconds)...
     */
-    LatchTime.Seconds = LocalTime.seconds;
-    LatchTime.Subseconds = CFE_TIME_Micro2SubSecs(LocalTime.microsecs);
+    LatchTime.Seconds = OS_TimeGetTotalSeconds(LocalTime);
+    LatchTime.Subseconds = OS_TimeGetSubsecondsPart(LocalTime);
 
     return(LatchTime);