/* * Copyright (c) 2004-2010 Atheros Communications Inc. * All rights reserved. * * This file implements the Atheros PS and patch parser. * It implements APIs to parse data buffer with patch and PS information and convert it to HCI commands. * * * * ar3kpsparser.c * * * * The software source and binaries included in this development package are * licensed, not sold. You, or your company, received the package under one * or more license agreements. The rights granted to you are specifically * listed in these license agreement(s). All other rights remain with Atheros * Communications, Inc., its subsidiaries, or the respective owner including * those listed on the included copyright notices.. Distribution of any * portion of this package must be in strict compliance with the license * agreement(s) terms. * * * */ #include "ar3kpsparser.h" #include #include #define BD_ADDR_SIZE 6 #define WRITE_PATCH 8 #define ENABLE_PATCH 11 #define PS_RESET 2 #define PS_WRITE 1 #define PS_VERIFY_CRC 9 #define CHANGE_BDADDR 15 #define HCI_COMMAND_HEADER 7 #define HCI_EVENT_SIZE 7 #define WRITE_PATCH_COMMAND_STATUS_OFFSET 5 #define PS_RAM_SIZE 2048 #define RAM_PS_REGION (1<<0) #define RAM_PATCH_REGION (1<<1) #define RAMPS_MAX_PS_DATA_PER_TAG 20000 #define MAX_RADIO_CFG_TABLE_SIZE 244 #define RAMPS_MAX_PS_TAGS_PER_FILE 50 #define PS_MAX_LEN 500 #define LINE_SIZE_MAX (PS_MAX_LEN *2) /* Constant values used by parser */ #define BYTES_OF_PS_DATA_PER_LINE 16 #define RAMPS_MAX_PS_DATA_PER_TAG 20000 /* Number pf PS/Patch entries in an HCI packet */ #define MAX_BYTE_LENGTH 244 #define SKIP_BLANKS(str) while (*str == ' ') str++ enum MinBootFileFormatE { MB_FILEFORMAT_RADIOTBL, MB_FILEFORMAT_PATCH, MB_FILEFORMAT_COEXCONFIG }; enum RamPsSection { RAM_PS_SECTION, RAM_PATCH_SECTION, RAM_DYN_MEM_SECTION }; enum eType { eHex, edecimal }; typedef struct tPsTagEntry { u32 TagId; u32 TagLen; u8 *TagData; } tPsTagEntry, *tpPsTagEntry; typedef struct tRamPatch { u16 Len; u8 *Data; } tRamPatch, *ptRamPatch; struct st_ps_data_format { enum eType eDataType; bool bIsArray; }; struct st_read_status { unsigned uTagID; unsigned uSection; unsigned uLineCount; unsigned uCharCount; unsigned uByteCount; }; /* Stores the number of PS Tags */ static u32 Tag_Count = 0; /* Stores the number of patch commands */ static u32 Patch_Count = 0; static u32 Total_tag_lenght = 0; bool BDADDR = false; u32 StartTagId; tPsTagEntry PsTagEntry[RAMPS_MAX_PS_TAGS_PER_FILE]; tRamPatch RamPatch[MAX_NUM_PATCH_ENTRY]; int AthParseFilesUnified(u8 *srcbuffer,u32 srclen, int FileFormat); char AthReadChar(u8 *buffer, u32 len,u32 *pos); char *AthGetLine(char *buffer, int maxlen, u8 *srcbuffer,u32 len,u32 *pos); static int AthPSCreateHCICommand(u8 Opcode, u32 Param1,struct ps_cmd_packet *PSPatchPacket,u32 *index); /* Function to reads the next character from the input buffer */ char AthReadChar(u8 *buffer, u32 len,u32 *pos) { char Ch; if(buffer == NULL || *pos >=len ) { return '\0'; } else { Ch = buffer[*pos]; (*pos)++; return Ch; } } /* PS parser helper function */ unsigned int uGetInputDataFormat(char *pCharLine, struct st_ps_data_format *pstFormat) { if(pCharLine[0] != '[') { pstFormat->eDataType = eHex; pstFormat->bIsArray = true; return 0; } switch(pCharLine[1]) { case 'H': case 'h': if(pCharLine[2]==':') { if((pCharLine[3]== 'a') || (pCharLine[3]== 'A')) { if(pCharLine[4] == ']') { pstFormat->eDataType = eHex; pstFormat->bIsArray = true; pCharLine += 5; return 0; } else { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Illegal Data format\n")); //[H:A return 1; } } if((pCharLine[3]== 'S') || (pCharLine[3]== 's')) { if(pCharLine[4] == ']') { pstFormat->eDataType = eHex; pstFormat->bIsArray = false; pCharLine += 5; return 0; } else { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Illegal Data format\n")); //[H:A return 1; } } else if(pCharLine[3] == ']') { //[H:] pstFormat->eDataType = eHex; pstFormat->bIsArray = true; pCharLine += 4; return 0; } else { //[H: AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Illegal Data format\n")); return 1; } } else if(pCharLine[2]==']') { //[H] pstFormat->eDataType = eHex; pstFormat->bIsArray = true; pCharLine += 3; return 0; } else { //[H AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Illegal Data format\n")); return 1; } break; case 'A': case 'a': if(pCharLine[2]==':') { if((pCharLine[3]== 'h') || (pCharLine[3]== 'H')) { if(pCharLine[4] == ']') { pstFormat->eDataType = eHex; pstFormat->bIsArray = true; pCharLine += 5; return 0; } else { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Illegal Data format 1\n")); //[A:H return 1; } } else if(pCharLine[3]== ']') { //[A:] pstFormat->eDataType = eHex; pstFormat->bIsArray = true; pCharLine += 4; return 0; } else { //[A: AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Illegal Data format 2\n")); return 1; } } else if(pCharLine[2]==']') { //[H] pstFormat->eDataType = eHex; pstFormat->bIsArray = true; pCharLine += 3; return 0; } else { //[H AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Illegal Data format 3\n")); return 1; } break; case 'S': case 's': if(pCharLine[2]==':') { if((pCharLine[3]== 'h') || (pCharLine[3]== 'H')) { if(pCharLine[4] == ']') { pstFormat->eDataType = eHex; pstFormat->bIsArray = true; pCharLine += 5; return 0; } else { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Illegal Data format 5\n")); //[A:H return 1; } } else if(pCharLine[3]== ']') { //[A:] pstFormat->eDataType = eHex; pstFormat->bIsArray = true; pCharLine += 4; return 0; } else { //[A: AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Illegal Data format 6\n")); return 1; } } else if(pCharLine[2]==']') { //[H] pstFormat->eDataType = eHex; pstFormat->bIsArray = true; pCharLine += 3; return 0; } else { //[H AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Illegal Data format 7\n")); return 1; } break; default: AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Illegal Data format 8\n")); return 1; } } unsigned int uReadDataInSection(char *pCharLine, struct st_ps_data_format stPS_DataFormat) { char *pTokenPtr = pCharLine; if(pTokenPtr[0] == '[') { while(pTokenPtr[0] != ']' && pTokenPtr[0] != '\0') { pTokenPtr++; } if(pTokenPtr[0] == '\0') { return (0x0FFF); } pTokenPtr++; } if(stPS_DataFormat.eDataType == eHex) { if(stPS_DataFormat.bIsArray == true) { //Not implemented return (0x0FFF); } else { return (A_STRTOL(pTokenPtr, NULL, 16)); } } else { //Not implemented return (0x0FFF); } } int AthParseFilesUnified(u8 *srcbuffer,u32 srclen, int FileFormat) { char *Buffer; char *pCharLine; u8 TagCount; u16 ByteCount; u8 ParseSection=RAM_PS_SECTION; u32 pos; int uReadCount; struct st_ps_data_format stPS_DataFormat; struct st_read_status stReadStatus = {0, 0, 0,0}; pos = 0; Buffer = NULL; if (srcbuffer == NULL || srclen == 0) { AR_DEBUG_PRINTF(ATH_DEBUG_ERR, ("Could not open .\n")); return A_ERROR; } TagCount = 0; ByteCount = 0; Buffer = A_MALLOC(LINE_SIZE_MAX + 1); if(NULL == Buffer) { return A_ERROR; } if (FileFormat == MB_FILEFORMAT_PATCH) { int LineRead = 0; while((pCharLine = AthGetLine(Buffer, LINE_SIZE_MAX, srcbuffer,srclen,&pos)) != NULL) { SKIP_BLANKS(pCharLine); // Comment line or empty line if ((pCharLine[0] == '/') && (pCharLine[1] == '/')) { continue; } if ((pCharLine[0] == '#')) { if (stReadStatus.uSection != 0) { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("error\n")); if(Buffer != NULL) { kfree(Buffer); } return A_ERROR; } else { stReadStatus.uSection = 1; continue; } } if ((pCharLine[0] == '/') && (pCharLine[1] == '*')) { pCharLine+=2; SKIP_BLANKS(pCharLine); if(!strncmp(pCharLine,"PA",2)||!strncmp(pCharLine,"Pa",2)||!strncmp(pCharLine,"pa",2)) ParseSection=RAM_PATCH_SECTION; if(!strncmp(pCharLine,"DY",2)||!strncmp(pCharLine,"Dy",2)||!strncmp(pCharLine,"dy",2)) ParseSection=RAM_DYN_MEM_SECTION; if(!strncmp(pCharLine,"PS",2)||!strncmp(pCharLine,"Ps",2)||!strncmp(pCharLine,"ps",2)) ParseSection=RAM_PS_SECTION; LineRead = 0; stReadStatus.uSection = 0; continue; } switch(ParseSection) { case RAM_PS_SECTION: { if (stReadStatus.uSection == 1) //TagID { SKIP_BLANKS(pCharLine); if(uGetInputDataFormat(pCharLine, &stPS_DataFormat)) { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("uGetInputDataFormat fail\n")); if(Buffer != NULL) { kfree(Buffer); } return A_ERROR; } //pCharLine +=5; PsTagEntry[TagCount].TagId = uReadDataInSection(pCharLine, stPS_DataFormat); AR_DEBUG_PRINTF(ATH_DEBUG_ERR,(" TAG ID %d \n",PsTagEntry[TagCount].TagId)); //AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("tag # %x\n", PsTagEntry[TagCount].TagId); if (TagCount == 0) { StartTagId = PsTagEntry[TagCount].TagId; } stReadStatus.uSection = 2; } else if (stReadStatus.uSection == 2) //TagLength { if(uGetInputDataFormat(pCharLine, &stPS_DataFormat)) { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("uGetInputDataFormat fail \n")); if(Buffer != NULL) { kfree(Buffer); } return A_ERROR; } //pCharLine +=5; ByteCount = uReadDataInSection(pCharLine, stPS_DataFormat); //AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("tag length %x\n", ByteCount)); if (ByteCount > LINE_SIZE_MAX/2) { if(Buffer != NULL) { kfree(Buffer); } return A_ERROR; } PsTagEntry[TagCount].TagLen = ByteCount; PsTagEntry[TagCount].TagData = (u8 *)A_MALLOC(ByteCount); AR_DEBUG_PRINTF(ATH_DEBUG_ERR,(" TAG Length %d Tag Index %d \n",PsTagEntry[TagCount].TagLen,TagCount)); stReadStatus.uSection = 3; stReadStatus.uLineCount = 0; } else if( stReadStatus.uSection == 3) { //Data if(stReadStatus.uLineCount == 0) { if(uGetInputDataFormat(pCharLine,&stPS_DataFormat)) { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("uGetInputDataFormat Fail\n")); if(Buffer != NULL) { kfree(Buffer); } return A_ERROR; } //pCharLine +=5; } SKIP_BLANKS(pCharLine); stReadStatus.uCharCount = 0; if(pCharLine[stReadStatus.uCharCount] == '[') { while(pCharLine[stReadStatus.uCharCount] != ']' && pCharLine[stReadStatus.uCharCount] != '\0' ) { stReadStatus.uCharCount++; } if(pCharLine[stReadStatus.uCharCount] == ']' ) { stReadStatus.uCharCount++; } else { stReadStatus.uCharCount = 0; } } uReadCount = (ByteCount > BYTES_OF_PS_DATA_PER_LINE)? BYTES_OF_PS_DATA_PER_LINE: ByteCount; //AR_DEBUG_PRINTF(ATH_DEBUG_ERR,(" ")); if((stPS_DataFormat.eDataType == eHex) && stPS_DataFormat.bIsArray == true) { while(uReadCount > 0) { PsTagEntry[TagCount].TagData[stReadStatus.uByteCount] = (u8)(hex_to_bin(pCharLine[stReadStatus.uCharCount]) << 4) | (u8)(hex_to_bin(pCharLine[stReadStatus.uCharCount + 1])); PsTagEntry[TagCount].TagData[stReadStatus.uByteCount+1] = (u8)(hex_to_bin(pCharLine[stReadStatus.uCharCount + 3]) << 4) | (u8)(hex_to_bin(pCharLine[stReadStatus.uCharCount + 4])); stReadStatus.uCharCount += 6; // read two bytes, plus a space; stReadStatus.uByteCount += 2; uReadCount -= 2; } if(ByteCount > BYTES_OF_PS_DATA_PER_LINE) { ByteCount -= BYTES_OF_PS_DATA_PER_LINE; } else { ByteCount = 0; } } else { //to be implemented } stReadStatus.uLineCount++; if(ByteCount == 0) { stReadStatus.uSection = 0; stReadStatus.uCharCount = 0; stReadStatus.uLineCount = 0; stReadStatus.uByteCount = 0; } else { stReadStatus.uCharCount = 0; } if((stReadStatus.uSection == 0)&&(++TagCount == RAMPS_MAX_PS_TAGS_PER_FILE)) { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("\n Buffer over flow PS File too big!!!")); if(Buffer != NULL) { kfree(Buffer); } return A_ERROR; //Sleep (3000); //exit(1); } } } break; default: { if(Buffer != NULL) { kfree(Buffer); } return A_ERROR; } break; } LineRead++; } Tag_Count = TagCount; AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Number of Tags %d\n", Tag_Count)); } if (TagCount > RAMPS_MAX_PS_TAGS_PER_FILE) { if(Buffer != NULL) { kfree(Buffer); } return A_ERROR; } if(Buffer != NULL) { kfree(Buffer); } return 0; } /********************/ int GetNextTwoChar(u8 *srcbuffer,u32 len, u32 *pos, char *buffer) { unsigned char ch; ch = AthReadChar(srcbuffer,len,pos); if(ch != '\0' && isxdigit(ch)) { buffer[0] = ch; } else { return A_ERROR; } ch = AthReadChar(srcbuffer,len,pos); if(ch != '\0' && isxdigit(ch)) { buffer[1] = ch; } else { return A_ERROR; } return 0; } int AthDoParsePatch(u8 *patchbuffer, u32 patchlen) { char Byte[3]; char Line[MAX_BYTE_LENGTH + 1]; int ByteCount,ByteCount_Org; int count; int i,j,k; int data; u32 filepos; Byte[2] = '\0'; j = 0; filepos = 0; Patch_Count = 0; while(NULL != AthGetLine(Line,MAX_BYTE_LENGTH,patchbuffer,patchlen,&filepos)) { if(strlen(Line) <= 1 || !isxdigit(Line[0])) { continue; } else { break; } } ByteCount = A_STRTOL(Line, NULL, 16); ByteCount_Org = ByteCount; while(ByteCount > MAX_BYTE_LENGTH){ /* Handle case when the number of patch buffer is more than the 20K */ if(MAX_NUM_PATCH_ENTRY == Patch_Count) { for(i = 0; i < Patch_Count; i++) { kfree(RamPatch[i].Data); } return A_ERROR; } RamPatch[Patch_Count].Len= MAX_BYTE_LENGTH; RamPatch[Patch_Count].Data = (u8 *)A_MALLOC(MAX_BYTE_LENGTH); Patch_Count ++; ByteCount= ByteCount - MAX_BYTE_LENGTH; } RamPatch[Patch_Count].Len= (ByteCount & 0xFF); if(ByteCount != 0) { RamPatch[Patch_Count].Data = (u8 *)A_MALLOC(ByteCount); Patch_Count ++; } count = 0; while(ByteCount_Org > MAX_BYTE_LENGTH){ AR_DEBUG_PRINTF(ATH_DEBUG_ERR,(" Index [%d]\n",j)); for (i = 0,k=0; i < MAX_BYTE_LENGTH*2; i += 2,k++,count +=2) { if(GetNextTwoChar(patchbuffer,patchlen,&filepos,Byte) == A_ERROR) { return A_ERROR; } data = A_STRTOUL(&Byte[0], NULL, 16); RamPatch[j].Data[k] = (data & 0xFF); } j++; ByteCount_Org = ByteCount_Org - MAX_BYTE_LENGTH; } if(j == 0){ j++; } AR_DEBUG_PRINTF(ATH_DEBUG_ERR,(" Index [%d]\n",j)); for (k=0; k < ByteCount_Org; i += 2,k++,count+=2) { if(GetNextTwoChar(patchbuffer,patchlen,&filepos,Byte) == A_ERROR) { return A_ERROR; } data = A_STRTOUL(Byte, NULL, 16); RamPatch[j].Data[k] = (data & 0xFF); } return 0; } /********************/ int AthDoParsePS(u8 *srcbuffer, u32 srclen) { int status; int i; bool BDADDR_Present = false; Tag_Count = 0; Total_tag_lenght = 0; BDADDR = false; status = A_ERROR; if(NULL != srcbuffer && srclen != 0) { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("File Open Operation Successful\n")); status = AthParseFilesUnified(srcbuffer,srclen,MB_FILEFORMAT_PATCH); } if(Tag_Count == 0){ Total_tag_lenght = 10; } else{ for(i=0; i 0 && !BDADDR_Present){ AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("BD ADDR is not present adding 10 extra bytes \r\n")); Total_tag_lenght=Total_tag_lenght + 10; } Total_tag_lenght = Total_tag_lenght+ 10 + (Tag_Count*4); AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("** Total Length %d\n",Total_tag_lenght)); return status; } char *AthGetLine(char *buffer, int maxlen, u8 *srcbuffer,u32 len,u32 *pos) { int count; static short flag; char CharRead; count = 0; flag = A_ERROR; do { CharRead = AthReadChar(srcbuffer,len,pos); if( CharRead == '\0' ) { buffer[count+1] = '\0'; if(count == 0) { return NULL; } else { return buffer; } } if(CharRead == 13) { } else if(CharRead == 10) { buffer[count] ='\0'; flag = A_ERROR; return buffer; }else { buffer[count++] = CharRead; } } while(count < maxlen-1 && CharRead != '\0'); buffer[count] = '\0'; return buffer; } static void LoadHeader(u8 *HCI_PS_Command,u8 opcode,int length,int index){ HCI_PS_Command[0]= 0x0B; HCI_PS_Command[1]= 0xFC; HCI_PS_Command[2]= length + 4; HCI_PS_Command[3]= opcode; HCI_PS_Command[4]= (index & 0xFF); HCI_PS_Command[5]= ((index>>8) & 0xFF); HCI_PS_Command[6]= length; } ///////////////////////// // int AthCreateCommandList(struct ps_cmd_packet **HciPacketList, u32 *numPackets) { u8 count; u32 NumcmdEntry = 0; u32 Crc = 0; *numPackets = 0; if(Patch_Count > 0) Crc |= RAM_PATCH_REGION; if(Tag_Count > 0) Crc |= RAM_PS_REGION; AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("PS Thread Started CRC %x Patch Count %d Tag Count %d \n",Crc,Patch_Count,Tag_Count)); if(Patch_Count || Tag_Count ){ NumcmdEntry+=(2 + Patch_Count + Tag_Count); /* CRC Packet + PS Reset Packet + Patch List + PS List*/ if(Patch_Count > 0) { NumcmdEntry++; /* Patch Enable Command */ } AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Num Cmd Entries %d Size %d \r\n",NumcmdEntry,(u32)sizeof(struct ps_cmd_packet) * NumcmdEntry)); (*HciPacketList) = A_MALLOC(sizeof(struct ps_cmd_packet) * NumcmdEntry); if(NULL == *HciPacketList) { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("memory allocation failed \r\n")); } AthPSCreateHCICommand(PS_VERIFY_CRC,Crc,*HciPacketList,numPackets); if(Patch_Count > 0){ AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("*** Write Patch**** \r\n")); AthPSCreateHCICommand(WRITE_PATCH,Patch_Count,*HciPacketList,numPackets); AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("*** Enable Patch**** \r\n")); AthPSCreateHCICommand(ENABLE_PATCH,0,*HciPacketList,numPackets); } AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("*** PS Reset**** %d[0x%x] \r\n",PS_RAM_SIZE,PS_RAM_SIZE)); AthPSCreateHCICommand(PS_RESET,PS_RAM_SIZE,*HciPacketList,numPackets); if(Tag_Count > 0){ AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("*** PS Write**** \r\n")); AthPSCreateHCICommand(PS_WRITE,Tag_Count,*HciPacketList,numPackets); } } if(!BDADDR){ AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("BD ADDR not present \r\n")); } for(count = 0; count < Patch_Count; count++) { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Freeing Patch Buffer %d \r\n",count)); kfree(RamPatch[count].Data); } for(count = 0; count < Tag_Count; count++) { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Freeing PS Buffer %d \r\n",count)); kfree(PsTagEntry[count].TagData); } /* * SDIO Transport uses synchronous mode of data transfer * So, AthPSOperations() call returns only after receiving the * command complete event. */ return *numPackets; } //////////////////////// ///////////// static int AthPSCreateHCICommand(u8 Opcode, u32 Param1,struct ps_cmd_packet *PSPatchPacket,u32 *index) { u8 *HCI_PS_Command; u32 Length; int i,j; switch(Opcode) { case WRITE_PATCH: for(i=0;i< Param1;i++){ HCI_PS_Command = (u8 *) A_MALLOC(RamPatch[i].Len+HCI_COMMAND_HEADER); AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Allocated Buffer Size %d\n",RamPatch[i].Len+HCI_COMMAND_HEADER)); if(HCI_PS_Command == NULL){ AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("MALLOC Failed\r\n")); return A_ERROR; } memset (HCI_PS_Command, 0, RamPatch[i].Len+HCI_COMMAND_HEADER); LoadHeader(HCI_PS_Command,Opcode,RamPatch[i].Len,i); for(j=0;j> 8) & 0xFF); PSPatchPacket[*index].Hcipacket = HCI_PS_Command; PSPatchPacket[*index].packetLen = Length+HCI_COMMAND_HEADER; (*index)++; break; case PS_WRITE: for(i=0;i< Param1;i++){ if(PsTagEntry[i].TagId ==1) BDADDR = true; HCI_PS_Command = (u8 *) A_MALLOC(PsTagEntry[i].TagLen+HCI_COMMAND_HEADER); if(HCI_PS_Command == NULL){ AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("MALLOC Failed\r\n")); return A_ERROR; } memset (HCI_PS_Command, 0, PsTagEntry[i].TagLen+HCI_COMMAND_HEADER); LoadHeader(HCI_PS_Command,Opcode,PsTagEntry[i].TagLen,PsTagEntry[i].TagId); for(j=0;j