/** * @file lldatapacker.cpp * @brief Data packer implementation. * * $LicenseInfo:firstyear=2006&license=viewerlgpl$ * Second Life Viewer Source Code * Copyright (C) 2010, Linden Research, Inc. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; * version 2.1 of the License only. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA * * Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA * $/LicenseInfo$ */ #include "linden_common.h" #include "lldatapacker.h" #include "llerror.h" #include "message.h" #include "v4color.h" #include "v4coloru.h" #include "v2math.h" #include "v3math.h" #include "v4math.h" #include "lluuid.h" // *NOTE: there are functions below which use sscanf and rely on this // particular value of DP_BUFSIZE. Search for '511' (DP_BUFSIZE - 1) // to find them if you change this number. const S32 DP_BUFSIZE = 512; static char DUMMY_BUFFER[128]; /*Flawfinder: ignore*/ LLDataPacker::LLDataPacker() : mPassFlags(0), mWriteEnabled(false) { } //virtual void LLDataPacker::reset() { LL_ERRS() << "Using unimplemented datapacker reset!" << LL_ENDL; } //virtual void LLDataPacker::dumpBufferToLog() { LL_ERRS() << "dumpBufferToLog not implemented for this type!" << LL_ENDL; } bool LLDataPacker::packFixed(const F32 value, const char *name, const bool is_signed, const U32 int_bits, const U32 frac_bits) { bool success = true; S32 unsigned_bits = int_bits + frac_bits; S32 total_bits = unsigned_bits; if (is_signed) { total_bits++; } S32 min_val; U32 max_val; if (is_signed) { min_val = 1 << int_bits; min_val *= -1; } else { min_val = 0; } max_val = 1 << int_bits; // Clamp to be within range F32 fixed_val = llclamp(value, (F32)min_val, (F32)max_val); if (is_signed) { fixed_val += max_val; } fixed_val *= 1 << frac_bits; if (total_bits <= 8) { packU8((U8)fixed_val, name); } else if (total_bits <= 16) { packU16((U16)fixed_val, name); } else if (total_bits <= 31) { packU32((U32)fixed_val, name); } else { LL_ERRS() << "Using fixed-point packing of " << total_bits << " bits, why?!" << LL_ENDL; } return success; } bool LLDataPacker::unpackFixed(F32 &value, const char *name, const bool is_signed, const U32 int_bits, const U32 frac_bits) { bool success = true; //LL_INFOS() << "unpackFixed:" << name << " int:" << int_bits << " frac:" << frac_bits << LL_ENDL; S32 unsigned_bits = int_bits + frac_bits; S32 total_bits = unsigned_bits; if (is_signed) { total_bits++; } U32 max_val; max_val = 1 << int_bits; F32 fixed_val; if (total_bits <= 8) { U8 fixed_8; success = unpackU8(fixed_8, name); fixed_val = (F32)fixed_8; } else if (total_bits <= 16) { U16 fixed_16; success = unpackU16(fixed_16, name); fixed_val = (F32)fixed_16; } else if (total_bits <= 31) { U32 fixed_32; success = unpackU32(fixed_32, name); fixed_val = (F32)fixed_32; } else { fixed_val = 0; LL_ERRS() << "Bad bit count: " << total_bits << LL_ENDL; } //LL_INFOS() << "Fixed_val:" << fixed_val << LL_ENDL; fixed_val /= (F32)(1 << frac_bits); if (is_signed) { fixed_val -= max_val; } value = fixed_val; //LL_INFOS() << "Value: " << value << LL_ENDL; return success; } bool LLDataPacker::unpackU16s(U16 *values, S32 count, const char *name) { for (S32 idx = 0; idx < count; ++idx) { if (!unpackU16(values[idx], name)) { LL_WARNS("DATAPACKER") << "Buffer overflow reading Unsigned 16s \"" << name << "\" at index " << idx << "!" << LL_ENDL; return false; } } return true; } bool LLDataPacker::unpackS16s(S16 *values, S32 count, const char *name) { for (S32 idx = 0; idx < count; ++idx) { if (!unpackS16(values[idx], name)) { LL_WARNS("DATAPACKER") << "Buffer overflow reading Signed 16s \"" << name << "\" at index " << idx << "!" << LL_ENDL; return false; } } return true; } bool LLDataPacker::unpackF32s(F32 *values, S32 count, const char *name) { for (S32 idx = 0; idx < count; ++idx) { if (!unpackF32(values[idx], name)) { LL_WARNS("DATAPACKER") << "Buffer overflow reading Float 32s \"" << name << "\" at index " << idx << "!" << LL_ENDL; return false; } } return true; } bool LLDataPacker::unpackColor4Us(LLColor4U *values, S32 count, const char *name) { for (S32 idx = 0; idx < count; ++idx) { if (!unpackColor4U(values[idx], name)) { LL_WARNS("DATAPACKER") << "Buffer overflow reading Float 32s \"" << name << "\" at index " << idx << "!" << LL_ENDL; return false; } } return true; } bool LLDataPacker::unpackUUIDs(LLUUID *values, S32 count, const char *name) { for (S32 idx = 0; idx < count; ++idx) { if (!unpackUUID(values[idx], name)) { LL_WARNS("DATAPACKER") << "Buffer overflow reading UUIDs \"" << name << "\" at index " << idx << "!" << LL_ENDL; return false; } } return true; } //--------------------------------------------------------------------------- // LLDataPackerBinaryBuffer implementation //--------------------------------------------------------------------------- bool LLDataPackerBinaryBuffer::packString(const std::string& value, const char *name) { S32 length = static_cast(value.length()) + 1; if (!verifyLength(length, name)) { return false; } if (mWriteEnabled) { htolememcpy(mCurBufferp, value.c_str(), MVT_VARIABLE, length); } mCurBufferp += length; return true; } bool LLDataPackerBinaryBuffer::unpackString(std::string& value, const char *name) { S32 length = (S32)strlen((char *)mCurBufferp) + 1; /*Flawfinder: ignore*/ if (!verifyLength(length, name)) { return false; } value = std::string((char*)mCurBufferp); // We already assume NULL termination calling strlen() mCurBufferp += length; return true; } bool LLDataPackerBinaryBuffer::packBinaryData(const U8 *value, S32 size, const char *name) { if (!verifyLength(size + 4, name)) { return false; } if (mWriteEnabled) { htolememcpy(mCurBufferp, &size, MVT_S32, 4); } mCurBufferp += 4; if (mWriteEnabled) { htolememcpy(mCurBufferp, value, MVT_VARIABLE, size); } mCurBufferp += size; return true; } bool LLDataPackerBinaryBuffer::unpackBinaryData(U8 *value, S32 &size, const char *name) { if (!verifyLength(4, name)) { LL_WARNS() << "LLDataPackerBinaryBuffer::unpackBinaryData would unpack invalid data, aborting!" << LL_ENDL; return false; } htolememcpy(&size, mCurBufferp, MVT_S32, 4); if (size < 0) { LL_WARNS() << "LLDataPackerBinaryBuffer::unpackBinaryData unpacked invalid size, aborting!" << LL_ENDL; return false; } mCurBufferp += 4; if (!verifyLength(size, name)) { LL_WARNS() << "LLDataPackerBinaryBuffer::unpackBinaryData would unpack invalid data, aborting!" << LL_ENDL; return false; } htolememcpy(value, mCurBufferp, MVT_VARIABLE, size); mCurBufferp += size; return true; } bool LLDataPackerBinaryBuffer::packBinaryDataFixed(const U8 *value, S32 size, const char *name) { if (!verifyLength(size, name)) { return false; } if (mWriteEnabled) { htolememcpy(mCurBufferp, value, MVT_VARIABLE, size); } mCurBufferp += size; return true; } bool LLDataPackerBinaryBuffer::unpackBinaryDataFixed(U8 *value, S32 size, const char *name) { if (!verifyLength(size, name)) { return false; } htolememcpy(value, mCurBufferp, MVT_VARIABLE, size); mCurBufferp += size; return true; } bool LLDataPackerBinaryBuffer::packU8(const U8 value, const char *name) { if (!verifyLength(sizeof(U8), name)) { return false; } if (mWriteEnabled) { *mCurBufferp = value; } mCurBufferp++; return true; } bool LLDataPackerBinaryBuffer::unpackU8(U8 &value, const char *name) { if (!verifyLength(sizeof(U8), name)) { return false; } value = *mCurBufferp; mCurBufferp++; return true; } bool LLDataPackerBinaryBuffer::packU16(const U16 value, const char *name) { if (!verifyLength(sizeof(U16), name)) { return false; } if (mWriteEnabled) { htolememcpy(mCurBufferp, &value, MVT_U16, 2); } mCurBufferp += 2; return true; } bool LLDataPackerBinaryBuffer::unpackU16(U16 &value, const char *name) { if (!verifyLength(sizeof(U16), name)) { return false; } htolememcpy(&value, mCurBufferp, MVT_U16, 2); mCurBufferp += 2; return true; } bool LLDataPackerBinaryBuffer::packS16(const S16 value, const char *name) { bool success = verifyLength(sizeof(S16), name); if (mWriteEnabled && success) { htolememcpy(mCurBufferp, &value, MVT_S16, 2); } mCurBufferp += 2; return success; } bool LLDataPackerBinaryBuffer::unpackS16(S16 &value, const char *name) { bool success = verifyLength(sizeof(S16), name); if (success) { htolememcpy(&value, mCurBufferp, MVT_S16, 2); } mCurBufferp += 2; return success; } bool LLDataPackerBinaryBuffer::packU32(const U32 value, const char *name) { if (!verifyLength(sizeof(U32), name)) { return false; } if (mWriteEnabled) { htolememcpy(mCurBufferp, &value, MVT_U32, 4); } mCurBufferp += 4; return true; } bool LLDataPackerBinaryBuffer::unpackU32(U32 &value, const char *name) { if (!verifyLength(sizeof(U32), name)) { return false; } htolememcpy(&value, mCurBufferp, MVT_U32, 4); mCurBufferp += 4; return true; } bool LLDataPackerBinaryBuffer::packS32(const S32 value, const char *name) { if (!verifyLength(sizeof(S32), name)) { return false; } if (mWriteEnabled) { htolememcpy(mCurBufferp, &value, MVT_S32, 4); } mCurBufferp += 4; return true; } bool LLDataPackerBinaryBuffer::unpackS32(S32 &value, const char *name) { if(!verifyLength(sizeof(S32), name)) { return false; } htolememcpy(&value, mCurBufferp, MVT_S32, 4); mCurBufferp += 4; return true; } bool LLDataPackerBinaryBuffer::packF32(const F32 value, const char *name) { if (!verifyLength(sizeof(F32), name)) { return false; } if (mWriteEnabled) { htolememcpy(mCurBufferp, &value, MVT_F32, 4); } mCurBufferp += 4; return true; } bool LLDataPackerBinaryBuffer::unpackF32(F32 &value, const char *name) { if (!verifyLength(sizeof(F32), name)) { return false; } htolememcpy(&value, mCurBufferp, MVT_F32, 4); mCurBufferp += 4; return true; } bool LLDataPackerBinaryBuffer::packColor4(const LLColor4 &value, const char *name) { if (!verifyLength(16, name)) { return false; } if (mWriteEnabled) { htolememcpy(mCurBufferp, value.mV, MVT_LLVector4, 16); } mCurBufferp += 16; return true; } bool LLDataPackerBinaryBuffer::unpackColor4(LLColor4 &value, const char *name) { if (!verifyLength(16, name)) { return false; } htolememcpy(value.mV, mCurBufferp, MVT_LLVector4, 16); mCurBufferp += 16; return true; } bool LLDataPackerBinaryBuffer::packColor4U(const LLColor4U &value, const char *name) { if (!verifyLength(4, name)) { return false; } if (mWriteEnabled) { htolememcpy(mCurBufferp, value.mV, MVT_VARIABLE, 4); } mCurBufferp += 4; return true; } bool LLDataPackerBinaryBuffer::unpackColor4U(LLColor4U &value, const char *name) { if (!verifyLength(4, name)) { return false; } htolememcpy(value.mV, mCurBufferp, MVT_VARIABLE, 4); mCurBufferp += 4; return true; } bool LLDataPackerBinaryBuffer::packVector2(const LLVector2 &value, const char *name) { if (!verifyLength(8, name)) { return false; } if (mWriteEnabled) { htolememcpy(mCurBufferp, &value.mV[0], MVT_F32, 4); htolememcpy(mCurBufferp+4, &value.mV[1], MVT_F32, 4); } mCurBufferp += 8; return true; } bool LLDataPackerBinaryBuffer::unpackVector2(LLVector2 &value, const char *name) { if (!verifyLength(8, name)) { return false; } htolememcpy(&value.mV[0], mCurBufferp, MVT_F32, 4); htolememcpy(&value.mV[1], mCurBufferp+4, MVT_F32, 4); mCurBufferp += 8; return true; } bool LLDataPackerBinaryBuffer::packVector3(const LLVector3 &value, const char *name) { if (!verifyLength(12, name)) { return false; } if (mWriteEnabled) { htolememcpy(mCurBufferp, value.mV, MVT_LLVector3, 12); } mCurBufferp += 12; return true; } bool LLDataPackerBinaryBuffer::unpackVector3(LLVector3 &value, const char *name) { if (!verifyLength(12, name)) { return false; } htolememcpy(value.mV, mCurBufferp, MVT_LLVector3, 12); mCurBufferp += 12; return true; } bool LLDataPackerBinaryBuffer::packVector4(const LLVector4 &value, const char *name) { if (!verifyLength(16, name)) { return false; } if (mWriteEnabled) { htolememcpy(mCurBufferp, value.mV, MVT_LLVector4, 16); } mCurBufferp += 16; return true; } bool LLDataPackerBinaryBuffer::unpackVector4(LLVector4 &value, const char *name) { if (!verifyLength(16, name)) { return false; } htolememcpy(value.mV, mCurBufferp, MVT_LLVector4, 16); mCurBufferp += 16; return true; } bool LLDataPackerBinaryBuffer::packUUID(const LLUUID &value, const char *name) { if (!verifyLength(16, name)) { return false; } if (mWriteEnabled) { htolememcpy(mCurBufferp, value.mData, MVT_LLUUID, 16); } mCurBufferp += 16; return true; } bool LLDataPackerBinaryBuffer::unpackUUID(LLUUID &value, const char *name) { if (!verifyLength(16, name)) { return false; } htolememcpy(value.mData, mCurBufferp, MVT_LLUUID, 16); mCurBufferp += 16; return true; } const LLDataPackerBinaryBuffer& LLDataPackerBinaryBuffer::operator=(const LLDataPackerBinaryBuffer &a) { if (a.getBufferSize() > getBufferSize()) { // We've got problems, ack! LL_ERRS() << "Trying to do an assignment with not enough room in the target." << LL_ENDL; } memcpy(mBufferp, a.mBufferp, a.getBufferSize()); /*Flawfinder: ignore*/ return *this; } void LLDataPackerBinaryBuffer::dumpBufferToLog() { LL_WARNS() << "Binary Buffer Dump, size: " << mBufferSize << LL_ENDL; char line_buffer[256]; /*Flawfinder: ignore*/ S32 i; S32 cur_line_pos = 0; S32 cur_line = 0; for (i = 0; i < mBufferSize; i++) { snprintf(line_buffer + cur_line_pos*3, sizeof(line_buffer) - cur_line_pos*3, "%02x ", mBufferp[i]); /* Flawfinder: ignore */ cur_line_pos++; if (cur_line_pos >= 16) { cur_line_pos = 0; LL_WARNS() << "Offset:" << std::hex << cur_line*16 << std::dec << " Data:" << line_buffer << LL_ENDL; cur_line++; } } if (cur_line_pos) { LL_WARNS() << "Offset:" << std::hex << cur_line*16 << std::dec << " Data:" << line_buffer << LL_ENDL; } } //--------------------------------------------------------------------------- // LLDataPackerAsciiBuffer implementation //--------------------------------------------------------------------------- bool LLDataPackerAsciiBuffer::packString(const std::string& value, const char *name) { bool success = true; writeIndentedName(name); int numCopied = 0; if (mWriteEnabled) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(),"%s\n", value.c_str()); /* Flawfinder: ignore */ } else { numCopied = static_cast(value.length()) + 1; /*Flawfinder: ignore*/ } // snprintf returns number of bytes that would have been written // had the output not being truncated. In that case, it will // return either -1 or value >= passed in size value . So a check needs to be added // to detect truncation, and if there is any, only account for the // actual number of bytes written..and not what could have been // written. if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { // *NOTE: I believe we need to mark a failure bit at this point. numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packString: string truncated: " << value << LL_ENDL; } mCurBufferp += numCopied; return success; } bool LLDataPackerAsciiBuffer::unpackString(std::string& value, const char *name) { char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore*/ if (!getValueStr(name, valuestr, DP_BUFSIZE)) // NULL terminated { return false; } value = valuestr; return true; } bool LLDataPackerAsciiBuffer::packBinaryData(const U8 *value, S32 size, const char *name) { bool success = true; writeIndentedName(name); int numCopied = 0; if (mWriteEnabled) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(),"%010d ", size); /* Flawfinder: ignore */ // snprintf returns number of bytes that would have been // written had the output not being truncated. In that case, // it will retuen >= passed in size value. so a check needs // to be added to detect truncation, and if there is any, only // account for the actual number of bytes written..and not // what could have been written. if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packBinaryData: number truncated: " << size << LL_ENDL; } mCurBufferp += numCopied; S32 i; bool bBufferFull = false; for (i = 0; i < size && !bBufferFull; i++) { numCopied = snprintf(mCurBufferp, getBufferSize()-getCurrentSize(), "%02x ", value[i]); /* Flawfinder: ignore */ if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packBinaryData: data truncated: " << LL_ENDL; bBufferFull = true; } mCurBufferp += numCopied; } if (!bBufferFull) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(), "\n"); /* Flawfinder: ignore */ if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packBinaryData: newline truncated: " << LL_ENDL; } mCurBufferp += numCopied; } } else { // why +10 ?? XXXCHECK numCopied = 10 + 1; // size plus newline numCopied += size; if (numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); } mCurBufferp += numCopied; } return success; } bool LLDataPackerAsciiBuffer::unpackBinaryData(U8 *value, S32 &size, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } char *cur_pos = &valuestr[0]; sscanf(valuestr,"%010d", &size); cur_pos += 11; S32 i; for (i = 0; i < size; i++) { S32 val; sscanf(cur_pos,"%02x", &val); value[i] = val; cur_pos += 3; } return success; } bool LLDataPackerAsciiBuffer::packBinaryDataFixed(const U8 *value, S32 size, const char *name) { bool success = true; writeIndentedName(name); if (mWriteEnabled) { S32 i; int numCopied = 0; bool bBufferFull = false; for (i = 0; i < size && !bBufferFull; i++) { numCopied = snprintf(mCurBufferp, getBufferSize()-getCurrentSize(), "%02x ", value[i]); /* Flawfinder: ignore */ if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packBinaryDataFixed: data truncated: " << LL_ENDL; bBufferFull = true; } mCurBufferp += numCopied; } if (!bBufferFull) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(), "\n"); /* Flawfinder: ignore */ if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packBinaryDataFixed: newline truncated: " << LL_ENDL; } mCurBufferp += numCopied; } } else { int numCopied = 2 * size + 1; //hex bytes plus newline if (numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); } mCurBufferp += numCopied; } return success; } bool LLDataPackerAsciiBuffer::unpackBinaryDataFixed(U8 *value, S32 size, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } char *cur_pos = &valuestr[0]; S32 i; for (i = 0; i < size; i++) { S32 val; sscanf(cur_pos,"%02x", &val); value[i] = val; cur_pos += 3; } return success; } bool LLDataPackerAsciiBuffer::packU8(const U8 value, const char *name) { bool success = true; writeIndentedName(name); int numCopied = 0; if (mWriteEnabled) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(),"%d\n", value); /* Flawfinder: ignore */ } else { // just do the write to a temp buffer to get the length numCopied = snprintf(DUMMY_BUFFER, sizeof(DUMMY_BUFFER), "%d\n", value); /* Flawfinder: ignore */ } // snprintf returns number of bytes that would have been written // had the output not being truncated. In that case, it will // return either -1 or value >= passed in size value . So a check needs to be added // to detect truncation, and if there is any, only account for the // actual number of bytes written..and not what could have been // written. if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packU8: val truncated: " << LL_ENDL; } mCurBufferp += numCopied; return success; } bool LLDataPackerAsciiBuffer::unpackU8(U8 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } S32 in_val; sscanf(valuestr,"%d", &in_val); value = in_val; return success; } bool LLDataPackerAsciiBuffer::packU16(const U16 value, const char *name) { bool success = true; writeIndentedName(name); int numCopied = 0; if (mWriteEnabled) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(),"%d\n", value); /* Flawfinder: ignore */ } else { numCopied = snprintf(DUMMY_BUFFER, sizeof(DUMMY_BUFFER), "%d\n", value); /* Flawfinder: ignore */ } // snprintf returns number of bytes that would have been written // had the output not being truncated. In that case, it will // return either -1 or value >= passed in size value . So a check needs to be added // to detect truncation, and if there is any, only account for the // actual number of bytes written..and not what could have been // written. if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packU16: val truncated: " << LL_ENDL; } mCurBufferp += numCopied; return success; } bool LLDataPackerAsciiBuffer::unpackU16(U16 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } S32 in_val; sscanf(valuestr,"%d", &in_val); value = in_val; return success; } bool LLDataPackerAsciiBuffer::packS16(const S16 value, const char *name) { bool success = true; writeIndentedName(name); int numCopied = 0; if (mWriteEnabled) { numCopied = snprintf(mCurBufferp, getBufferSize() - getCurrentSize(), "%d\n", value); /* Flawfinder: ignore */ } else { numCopied = snprintf(DUMMY_BUFFER, sizeof(DUMMY_BUFFER), "%d\n", value); /* Flawfinder: ignore */ } // snprintf returns number of bytes that would have been written // had the output not being truncated. In that case, it will // return either -1 or value >= passed in size value . So a check needs to be added // to detect truncation, and if there is any, only account for the // actual number of bytes written..and not what could have been // written. if(numCopied < 0 || numCopied > getBufferSize() - getCurrentSize()) { numCopied = getBufferSize() - getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packS16: val truncated: " << LL_ENDL; } mCurBufferp += numCopied; return success; } bool LLDataPackerAsciiBuffer::unpackS16(S16 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } S32 in_val; sscanf(valuestr, "%d", &in_val); value = in_val; return success; } bool LLDataPackerAsciiBuffer::packU32(const U32 value, const char *name) { bool success = true; writeIndentedName(name); int numCopied = 0; if (mWriteEnabled) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(),"%u\n", value); /* Flawfinder: ignore */ } else { numCopied = snprintf(DUMMY_BUFFER, sizeof(DUMMY_BUFFER), "%u\n", value); /* Flawfinder: ignore */ } // snprintf returns number of bytes that would have been written // had the output not being truncated. In that case, it will // return either -1 or value >= passed in size value . So a check needs to be added // to detect truncation, and if there is any, only account for the // actual number of bytes written..and not what could have been // written. if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packU32: val truncated: " << LL_ENDL; } mCurBufferp += numCopied; return success; } bool LLDataPackerAsciiBuffer::unpackU32(U32 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } sscanf(valuestr,"%u", &value); return success; } bool LLDataPackerAsciiBuffer::packS32(const S32 value, const char *name) { bool success = true; writeIndentedName(name); int numCopied = 0; if (mWriteEnabled) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(),"%d\n", value); /* Flawfinder: ignore */ } else { numCopied = snprintf(DUMMY_BUFFER, sizeof(DUMMY_BUFFER), "%d\n", value); /* Flawfinder: ignore */ } // snprintf returns number of bytes that would have been written // had the output not being truncated. In that case, it will // return either -1 or value >= passed in size value . So a check needs to be added // to detect truncation, and if there is any, only account for the // actual number of bytes written..and not what could have been // written. if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packS32: val truncated: " << LL_ENDL; } mCurBufferp += numCopied; return success; } bool LLDataPackerAsciiBuffer::unpackS32(S32 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } sscanf(valuestr,"%d", &value); return success; } bool LLDataPackerAsciiBuffer::packF32(const F32 value, const char *name) { bool success = true; writeIndentedName(name); int numCopied = 0; if (mWriteEnabled) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(),"%f\n", value); /* Flawfinder: ignore */ } else { numCopied = snprintf(DUMMY_BUFFER, sizeof(DUMMY_BUFFER), "%f\n", value); /* Flawfinder: ignore */ } // snprintf returns number of bytes that would have been written // had the output not being truncated. In that case, it will // return either -1 or value >= passed in size value . So a check needs to be added // to detect truncation, and if there is any, only account for the // actual number of bytes written..and not what could have been // written. if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packF32: val truncated: " << LL_ENDL; } mCurBufferp += numCopied; return success; } bool LLDataPackerAsciiBuffer::unpackF32(F32 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } sscanf(valuestr,"%f", &value); return success; } bool LLDataPackerAsciiBuffer::packColor4(const LLColor4 &value, const char *name) { bool success = true; writeIndentedName(name); int numCopied = 0; if (mWriteEnabled) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(),"%f %f %f %f\n", value.mV[0], value.mV[1], value.mV[2], value.mV[3]); /* Flawfinder: ignore */ } else { numCopied = snprintf(DUMMY_BUFFER,sizeof(DUMMY_BUFFER),"%f %f %f %f\n", value.mV[0], value.mV[1], value.mV[2], value.mV[3]); /* Flawfinder: ignore */ } // snprintf returns number of bytes that would have been written // had the output not being truncated. In that case, it will // return either -1 or value >= passed in size value . So a check needs to be added // to detect truncation, and if there is any, only account for the // actual number of bytes written..and not what could have been // written. if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packColor4: truncated: " << LL_ENDL; } mCurBufferp += numCopied; return success; } bool LLDataPackerAsciiBuffer::unpackColor4(LLColor4 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } sscanf(valuestr,"%f %f %f %f", &value.mV[0], &value.mV[1], &value.mV[2], &value.mV[3]); return success; } bool LLDataPackerAsciiBuffer::packColor4U(const LLColor4U &value, const char *name) { bool success = true; writeIndentedName(name); int numCopied = 0; if (mWriteEnabled) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(),"%d %d %d %d\n", value.mV[0], value.mV[1], value.mV[2], value.mV[3]); /* Flawfinder: ignore */ } else { numCopied = snprintf(DUMMY_BUFFER,sizeof(DUMMY_BUFFER),"%d %d %d %d\n", value.mV[0], value.mV[1], value.mV[2], value.mV[3]); /* Flawfinder: ignore */ } // snprintf returns number of bytes that would have been written // had the output not being truncated. In that case, it will // return either -1 or value >= passed in size value . So a check needs to be added // to detect truncation, and if there is any, only account for the // actual number of bytes written..and not what could have been // written. if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packColor4U: truncated: " << LL_ENDL; } mCurBufferp += numCopied; return success; } bool LLDataPackerAsciiBuffer::unpackColor4U(LLColor4U &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } S32 r, g, b, a; sscanf(valuestr,"%d %d %d %d", &r, &g, &b, &a); value.mV[0] = r; value.mV[1] = g; value.mV[2] = b; value.mV[3] = a; return success; } bool LLDataPackerAsciiBuffer::packVector2(const LLVector2 &value, const char *name) { bool success = true; writeIndentedName(name); int numCopied = 0; if (mWriteEnabled) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(),"%f %f\n", value.mV[0], value.mV[1]); /* Flawfinder: ignore */ } else { numCopied = snprintf(DUMMY_BUFFER,sizeof(DUMMY_BUFFER),"%f %f\n", value.mV[0], value.mV[1]); /* Flawfinder: ignore */ } // snprintf returns number of bytes that would have been written // had the output not being truncated. In that case, it will // return either -1 or value >= passed in size value . So a check needs to be added // to detect truncation, and if there is any, only account for the // actual number of bytes written..and not what could have been // written. if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packVector2: truncated: " << LL_ENDL; } mCurBufferp += numCopied; return success; } bool LLDataPackerAsciiBuffer::unpackVector2(LLVector2 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } sscanf(valuestr,"%f %f", &value.mV[0], &value.mV[1]); return success; } bool LLDataPackerAsciiBuffer::packVector3(const LLVector3 &value, const char *name) { bool success = true; writeIndentedName(name); int numCopied = 0; if (mWriteEnabled) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(),"%f %f %f\n", value.mV[0], value.mV[1], value.mV[2]); /* Flawfinder: ignore */ } else { numCopied = snprintf(DUMMY_BUFFER,sizeof(DUMMY_BUFFER),"%f %f %f\n", value.mV[0], value.mV[1], value.mV[2]); /* Flawfinder: ignore */ } // snprintf returns number of bytes that would have been written // had the output not being truncated. In that case, it will // return either -1 or value >= passed in size value . So a check needs to be added // to detect truncation, and if there is any, only account for the // actual number of bytes written..and not what could have been // written. if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packVector3: truncated: " << LL_ENDL; } mCurBufferp += numCopied; return success; } bool LLDataPackerAsciiBuffer::unpackVector3(LLVector3 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } sscanf(valuestr,"%f %f %f", &value.mV[0], &value.mV[1], &value.mV[2]); return success; } bool LLDataPackerAsciiBuffer::packVector4(const LLVector4 &value, const char *name) { bool success = true; writeIndentedName(name); int numCopied = 0; if (mWriteEnabled) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(),"%f %f %f %f\n", value.mV[0], value.mV[1], value.mV[2], value.mV[3]); /* Flawfinder: ignore */ } else { numCopied = snprintf(DUMMY_BUFFER,sizeof(DUMMY_BUFFER),"%f %f %f %f\n", value.mV[0], value.mV[1], value.mV[2], value.mV[3]); /* Flawfinder: ignore */ } // snprintf returns number of bytes that would have been written // had the output not being truncated. In that case, it will // return either -1 or value >= passed in size value . So a check needs to be added // to detect truncation, and if there is any, only account for the // actual number of bytes written..and not what could have been // written. if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packVector4: truncated: " << LL_ENDL; } mCurBufferp += numCopied; return success; } bool LLDataPackerAsciiBuffer::unpackVector4(LLVector4 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } sscanf(valuestr,"%f %f %f %f", &value.mV[0], &value.mV[1], &value.mV[2], &value.mV[3]); return success; } bool LLDataPackerAsciiBuffer::packUUID(const LLUUID &value, const char *name) { bool success = true; writeIndentedName(name); int numCopied = 0; if (mWriteEnabled) { std::string tmp_str; value.toString(tmp_str); numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(),"%s\n", tmp_str.c_str()); /* Flawfinder: ignore */ } else { numCopied = 64 + 1; // UUID + newline } // snprintf returns number of bytes that would have been written // had the output not being truncated. In that case, it will // return either -1 or value >= passed in size value . So a check needs to be added // to detect truncation, and if there is any, only account for the // actual number of bytes written..and not what could have been // written. if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::packUUID: truncated: " << LL_ENDL; success = false; } mCurBufferp += numCopied; return success; } bool LLDataPackerAsciiBuffer::unpackUUID(LLUUID &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } char tmp_str[64]; /* Flawfinder: ignore */ sscanf(valuestr, "%63s", tmp_str); /* Flawfinder: ignore */ value.set(tmp_str); return success; } void LLDataPackerAsciiBuffer::dump() { LL_INFOS() << "Buffer: " << mBufferp << LL_ENDL; } void LLDataPackerAsciiBuffer::writeIndentedName(const char *name) { if (mIncludeNames) { int numCopied = 0; if (mWriteEnabled) { numCopied = snprintf(mCurBufferp,getBufferSize()-getCurrentSize(),"%s\t", name); /* Flawfinder: ignore */ } else { numCopied = (S32)strlen(name) + 1; /* Flawfinder: ignore */ //name + tab } // snprintf returns number of bytes that would have been written // had the output not being truncated. In that case, it will // return either -1 or value >= passed in size value . So a check needs to be added // to detect truncation, and if there is any, only account for the // actual number of bytes written..and not what could have been // written. if (numCopied < 0 || numCopied > getBufferSize()-getCurrentSize()) { numCopied = getBufferSize()-getCurrentSize(); LL_WARNS() << "LLDataPackerAsciiBuffer::writeIndentedName: truncated: " << LL_ENDL; } mCurBufferp += numCopied; } } bool LLDataPackerAsciiBuffer::getValueStr(const char *name, char *out_value, S32 value_len) { bool success = true; char buffer[DP_BUFSIZE]; /* Flawfinder: ignore */ char keyword[DP_BUFSIZE]; /* Flawfinder: ignore */ char value[DP_BUFSIZE]; /* Flawfinder: ignore */ buffer[0] = '\0'; keyword[0] = '\0'; value[0] = '\0'; if (mIncludeNames) { // Read both the name and the value, and validate the name. sscanf(mCurBufferp, "%511[^\n]", buffer); // Skip the \n mCurBufferp += (S32)strlen(buffer) + 1; /* Flawfinder: ignore */ sscanf(buffer, "%511s %511[^\n]", keyword, value); /* Flawfinder: ignore */ if (strcmp(keyword, name)) { LL_WARNS() << "Data packer expecting keyword of type " << name << ", got " << keyword << " instead!" << LL_ENDL; return false; } } else { // Just the value exists sscanf(mCurBufferp, "%511[^\n]", value); // Skip the \n mCurBufferp += (S32)strlen(value) + 1; /* Flawfinder: ignore */ } S32 in_value_len = (S32)strlen(value)+1; /* Flawfinder: ignore */ S32 min_len = llmin(in_value_len, value_len); memcpy(out_value, value, min_len); /* Flawfinder: ignore */ out_value[min_len-1] = 0; return success; } // helper function used by LLDataPackerAsciiFile // to convert F32 into a string. This is to avoid // << operator writing F32 value into a stream // since it does not seem to preserve the float value std::string convertF32ToString(F32 val) { std::string str; char buf[20]; snprintf(buf, 20, "%f", val); str = buf; return str; } //--------------------------------------------------------------------------- // LLDataPackerAsciiFile implementation //--------------------------------------------------------------------------- bool LLDataPackerAsciiFile::packString(const std::string& value, const char *name) { bool success = true; writeIndentedName(name); if (mFP) { fprintf(mFP,"%s\n", value.c_str()); } else if (mOutputStream) { *mOutputStream << value << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackString(std::string& value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /* Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } value = valuestr; return success; } bool LLDataPackerAsciiFile::packBinaryData(const U8 *value, S32 size, const char *name) { bool success = true; writeIndentedName(name); if (mFP) { fprintf(mFP, "%010d ", size); S32 i; for (i = 0; i < size; i++) { fprintf(mFP, "%02x ", value[i]); } fprintf(mFP, "\n"); } else if (mOutputStream) { char buffer[32]; /* Flawfinder: ignore */ snprintf(buffer,sizeof(buffer), "%010d ", size); /* Flawfinder: ignore */ *mOutputStream << buffer; S32 i; for (i = 0; i < size; i++) { snprintf(buffer, sizeof(buffer), "%02x ", value[i]); /* Flawfinder: ignore */ *mOutputStream << buffer; } *mOutputStream << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackBinaryData(U8 *value, S32 &size, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore*/ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } char *cur_pos = &valuestr[0]; sscanf(valuestr,"%010d", &size); cur_pos += 11; S32 i; for (i = 0; i < size; i++) { S32 val; sscanf(cur_pos,"%02x", &val); value[i] = val; cur_pos += 3; } return success; } bool LLDataPackerAsciiFile::packBinaryDataFixed(const U8 *value, S32 size, const char *name) { bool success = true; writeIndentedName(name); if (mFP) { S32 i; for (i = 0; i < size; i++) { fprintf(mFP, "%02x ", value[i]); } fprintf(mFP, "\n"); } else if (mOutputStream) { char buffer[32]; /*Flawfinder: ignore*/ S32 i; for (i = 0; i < size; i++) { snprintf(buffer, sizeof(buffer), "%02x ", value[i]); /* Flawfinder: ignore */ *mOutputStream << buffer; } *mOutputStream << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackBinaryDataFixed(U8 *value, S32 size, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore*/ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } char *cur_pos = &valuestr[0]; S32 i; for (i = 0; i < size; i++) { S32 val; sscanf(cur_pos,"%02x", &val); value[i] = val; cur_pos += 3; } return success; } bool LLDataPackerAsciiFile::packU8(const U8 value, const char *name) { bool success = true; writeIndentedName(name); if (mFP) { fprintf(mFP,"%d\n", value); } else if (mOutputStream) { // We have to cast this to an integer because streams serialize // bytes as bytes - not as text. *mOutputStream << (S32)value << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackU8(U8 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } S32 in_val; sscanf(valuestr,"%d", &in_val); value = in_val; return success; } bool LLDataPackerAsciiFile::packU16(const U16 value, const char *name) { bool success = true; writeIndentedName(name); if (mFP) { fprintf(mFP,"%d\n", value); } else if (mOutputStream) { *mOutputStream <<"" << value << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackU16(U16 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } S32 in_val; sscanf(valuestr,"%d", &in_val); value = in_val; return success; } bool LLDataPackerAsciiFile::packS16(const S16 value, const char *name) { bool success = true; writeIndentedName(name); if (mFP) { fprintf(mFP, "%d\n", value); } else if (mOutputStream) { *mOutputStream << "" << value << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackS16(S16 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } S32 in_val; sscanf(valuestr, "%d", &in_val); value = in_val; return success; } bool LLDataPackerAsciiFile::packU32(const U32 value, const char *name) { bool success = true; writeIndentedName(name); if (mFP) { fprintf(mFP,"%u\n", value); } else if (mOutputStream) { *mOutputStream <<"" << value << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackU32(U32 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } sscanf(valuestr,"%u", &value); return success; } bool LLDataPackerAsciiFile::packS32(const S32 value, const char *name) { bool success = true; writeIndentedName(name); if (mFP) { fprintf(mFP,"%d\n", value); } else if (mOutputStream) { *mOutputStream <<"" << value << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackS32(S32 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } sscanf(valuestr,"%d", &value); return success; } bool LLDataPackerAsciiFile::packF32(const F32 value, const char *name) { bool success = true; writeIndentedName(name); if (mFP) { fprintf(mFP,"%f\n", value); } else if (mOutputStream) { *mOutputStream <<"" << convertF32ToString(value) << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackF32(F32 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } sscanf(valuestr,"%f", &value); return success; } bool LLDataPackerAsciiFile::packColor4(const LLColor4 &value, const char *name) { bool success = true; writeIndentedName(name); if (mFP) { fprintf(mFP,"%f %f %f %f\n", value.mV[0], value.mV[1], value.mV[2], value.mV[3]); } else if (mOutputStream) { *mOutputStream << convertF32ToString(value.mV[0]) << " " << convertF32ToString(value.mV[1]) << " " << convertF32ToString(value.mV[2]) << " " << convertF32ToString(value.mV[3]) << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackColor4(LLColor4 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } sscanf(valuestr,"%f %f %f %f", &value.mV[0], &value.mV[1], &value.mV[2], &value.mV[3]); return success; } bool LLDataPackerAsciiFile::packColor4U(const LLColor4U &value, const char *name) { bool success = true; writeIndentedName(name); if (mFP) { fprintf(mFP,"%d %d %d %d\n", value.mV[0], value.mV[1], value.mV[2], value.mV[3]); } else if (mOutputStream) { *mOutputStream << (S32)(value.mV[0]) << " " << (S32)(value.mV[1]) << " " << (S32)(value.mV[2]) << " " << (S32)(value.mV[3]) << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackColor4U(LLColor4U &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } S32 r, g, b, a; sscanf(valuestr,"%d %d %d %d", &r, &g, &b, &a); value.mV[0] = r; value.mV[1] = g; value.mV[2] = b; value.mV[3] = a; return success; } bool LLDataPackerAsciiFile::packVector2(const LLVector2 &value, const char *name) { bool success = true; writeIndentedName(name); if (mFP) { fprintf(mFP,"%f %f\n", value.mV[0], value.mV[1]); } else if (mOutputStream) { *mOutputStream << convertF32ToString(value.mV[0]) << " " << convertF32ToString(value.mV[1]) << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackVector2(LLVector2 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } sscanf(valuestr,"%f %f", &value.mV[0], &value.mV[1]); return success; } bool LLDataPackerAsciiFile::packVector3(const LLVector3 &value, const char *name) { bool success = true; writeIndentedName(name); if (mFP) { fprintf(mFP,"%f %f %f\n", value.mV[0], value.mV[1], value.mV[2]); } else if (mOutputStream) { *mOutputStream << convertF32ToString(value.mV[0]) << " " << convertF32ToString(value.mV[1]) << " " << convertF32ToString(value.mV[2]) << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackVector3(LLVector3 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } sscanf(valuestr,"%f %f %f", &value.mV[0], &value.mV[1], &value.mV[2]); return success; } bool LLDataPackerAsciiFile::packVector4(const LLVector4 &value, const char *name) { bool success = true; writeIndentedName(name); if (mFP) { fprintf(mFP,"%f %f %f %f\n", value.mV[0], value.mV[1], value.mV[2], value.mV[3]); } else if (mOutputStream) { *mOutputStream << convertF32ToString(value.mV[0]) << " " << convertF32ToString(value.mV[1]) << " " << convertF32ToString(value.mV[2]) << " " << convertF32ToString(value.mV[3]) << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackVector4(LLVector4 &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } sscanf(valuestr,"%f %f %f %f", &value.mV[0], &value.mV[1], &value.mV[2], &value.mV[3]); return success; } bool LLDataPackerAsciiFile::packUUID(const LLUUID &value, const char *name) { bool success = true; writeIndentedName(name); std::string tmp_str; value.toString(tmp_str); if (mFP) { fprintf(mFP,"%s\n", tmp_str.c_str()); } else if (mOutputStream) { *mOutputStream <<"" << tmp_str << "\n"; } return success; } bool LLDataPackerAsciiFile::unpackUUID(LLUUID &value, const char *name) { bool success = true; char valuestr[DP_BUFSIZE]; /*Flawfinder: ignore */ if (!getValueStr(name, valuestr, DP_BUFSIZE)) { return false; } char tmp_str[64]; /*Flawfinder: ignore */ sscanf(valuestr,"%63s",tmp_str); /* Flawfinder: ignore */ value.set(tmp_str); return success; } void LLDataPackerAsciiFile::writeIndentedName(const char *name) { std::string indent_buf; indent_buf.reserve(mIndent+1); S32 i; for(i = 0; i < mIndent; i++) { indent_buf[i] = '\t'; } indent_buf[i] = 0; if (mFP) { fprintf(mFP,"%s%s\t",indent_buf.c_str(), name); } else if (mOutputStream) { *mOutputStream << indent_buf << name << "\t"; } } bool LLDataPackerAsciiFile::getValueStr(const char *name, char *out_value, S32 value_len) { bool success = false; char buffer[DP_BUFSIZE]; /*Flawfinder: ignore*/ char keyword[DP_BUFSIZE]; /*Flawfinder: ignore*/ char value[DP_BUFSIZE]; /*Flawfinder: ignore*/ buffer[0] = '\0'; keyword[0] = '\0'; value[0] = '\0'; if (mFP) { fpos_t last_pos; if (0 != fgetpos(mFP, &last_pos)) // 0==success for fgetpos { LL_WARNS() << "Data packer failed to fgetpos" << LL_ENDL; return false; } if (fgets(buffer, DP_BUFSIZE, mFP) == NULL) { buffer[0] = '\0'; } sscanf(buffer, "%511s %511[^\n]", keyword, value); /* Flawfinder: ignore */ if (!keyword[0]) { LL_WARNS() << "Data packer could not get the keyword!" << LL_ENDL; fsetpos(mFP, &last_pos); return false; } if (strcmp(keyword, name)) { LL_WARNS() << "Data packer expecting keyword of type " << name << ", got " << keyword << " instead!" << LL_ENDL; fsetpos(mFP, &last_pos); return false; } S32 in_value_len = (S32)strlen(value)+1; /*Flawfinder: ignore*/ S32 min_len = llmin(in_value_len, value_len); memcpy(out_value, value, min_len); /*Flawfinder: ignore*/ out_value[min_len-1] = 0; success = true; } else if (mInputStream) { mInputStream->getline(buffer, DP_BUFSIZE); sscanf(buffer, "%511s %511[^\n]", keyword, value); /* Flawfinder: ignore */ if (!keyword[0]) { LL_WARNS() << "Data packer could not get the keyword!" << LL_ENDL; return false; } if (strcmp(keyword, name)) { LL_WARNS() << "Data packer expecting keyword of type " << name << ", got " << keyword << " instead!" << LL_ENDL; return false; } S32 in_value_len = (S32)strlen(value)+1; /*Flawfinder: ignore*/ S32 min_len = llmin(in_value_len, value_len); memcpy(out_value, value, min_len); /*Flawfinder: ignore*/ out_value[min_len-1] = 0; success = true; } return success; }