èŠ‚ç‚¹æ–‡çŒ®

é«˜å¯†åº¦ç£ç›˜æ€§èƒ½ä¼˜åŒ–æŠ€æœ¯ç ”ç©¶ç»¼è¿°

A Survey on the Research of Novel High-Density Disk Performance Optimization Techniques

æŽ¨è CAJä¸‹è½½
PDFä¸‹è½½
ä¸æ”¯æŒè¿…é›·ç‰ä¸‹è½½å·¥å…·ï¼Œè¯·å–æ¶ˆåŠ é€Ÿå·¥å…·åŽä¸‹è½½ã€‚

ã€ä½œè€…ã€‘ ä¼å«å›½ï¼› å¼ é©°ï¼› äºŽèŠ³æ˜Ÿï¼› è‚ä¸–å¼ºï¼› æŽåŸæ¶µï¼› ç‰›æ´ï¼›

ã€Authorã€‘ WU Wei-guo;ZHANG Chi;YU Fang-xing;NIE Shi-qiang;LI Meng-han;NIU Jie;Department of Computer Science and Technology, Xiâ€™an Jiaotong University;

ã€æœºæž„ã€‘ è¥¿å®‰äº¤é€šå¤§å¦è®¡ç®—æœºç§‘å¦ä¸ŽæŠ€æœ¯å¦é™¢ï¼›

ã€æ‘˜è¦ã€‘ åœ¨å½“ä»Šæ•°å—åŒ–æ—¶ä»£ï¼Œæµ·é‡æ•°æ®çš„ç”Ÿæˆå’Œç§¯ç´¯å‘ˆçŽ°å‡ºçˆ†ç‚¸å¼å¢žé•¿çš„è¶‹åŠ¿ï¼Œå› æ¤å¯¹å˜å‚¨å®¹é‡çš„éœ€æ±‚æ€¥é€Ÿä¸Šå‡.ä¼ ç»Ÿç£è®°å½•ç£ç›˜CMRå› å…¶é«˜å®¹é‡å’Œä½Žæˆæœ¬è€Œè¢«è§†ä¸ºè§£å†³æµ·é‡æ•°æ®å˜å‚¨çš„é¦–é€‰.ç„¶è€Œï¼Œç”±äºŽè¶…é¡ºç£æ•ˆåº”çš„åˆ¶çº¦ï¼ŒCMR(Conventional Magnetic Recording)ç£ç›˜é¢å¯†åº¦çš„æå‡å·²è§¦åŠæžé™.ä¸ºäº†çªç ´è¿™ä¸€é™åˆ¶ï¼Œå ç“¦å¼ç£è®°å½•æŠ€æœ¯SMR(Shingled Magnetic Recording)åº”è¿è€Œç”Ÿ.åŸºäºŽä¼ ç»Ÿç¡¬ç›˜æž¶æž„ï¼Œè¯¥æŠ€æœ¯ä»¥é‡å ç£é“çš„æ–¹å¼ï¼Œæ˜¾è‘—æå‡äº†ç£ç›˜é¢å¯†åº¦.ä½†SMRç£ç›˜åœ¨å¤„ç†éšæœºå†™æ—¶ï¼Œä¼šäº§ç”Ÿä¸å¯é¢„æµ‹çš„å†™æ”¾å¤§æ•ˆåº”ï¼Œä»Žè€Œä¸¥é‡å½±å“I/Oæ€§èƒ½.ä¸ºè§£å†³è¿™ä¸€é—®é¢˜ï¼Œä¸šç•Œéšå³æå‡ºäº†äº¤é”™å¼ç£è®°å½•æŠ€æœ¯IMR(Interlaced Magnetic Recording)ï¼Œåˆ©ç”¨ä¼˜åŒ–çš„ç£é“å¸ƒå±€å’Œçƒè¾…åŠ©ç£è®°å½•æŠ€æœ¯ï¼Œæœ‰æ•ˆå®žçŽ°äº†å˜å‚¨å®¹é‡ä¸Žæ€§èƒ½çš„å¹³è¡¡.æœ¬æ–‡é¦–å…ˆè¯¦ç»†ä»‹ç»äº†SMRå’ŒIMRçš„æŠ€æœ¯åŽŸç†å’Œç£ç›˜ç±»åž‹ï¼Œå¹¶é‡åŒ–åˆ†æžäº†å½±å“è®¾å¤‡I/Oæ€§èƒ½çš„å…³é”®é—®é¢˜.ç„¶åŽï¼Œé‡ç‚¹ä»‹ç»äº†è®¾å¤‡çº§ä¼˜åŒ–æ–¹æ¡ˆï¼Œåˆ†æžå¹¶æ€»ç»“äº†ä¸åŒç–ç•¥çš„ä¼˜ç¼ºç‚¹ä¸Žä¼˜åŒ–ç›®æ ‡.æŽ¥ç€ï¼Œæ¦‚è¿°äº†é¢å‘è®¾å¤‡çš„ç³»ç»Ÿçº§å’Œåº”ç”¨çº§è®¾è®¡æ–¹æ¡ˆï¼Œå¦‚æ–‡ä»¶ç³»ç»Ÿã€ç‹¬ç«‹ç£ç›˜é˜µåˆ—æŠ€æœ¯å’Œæ•°æ®åº“ç‰.æœ€åŽè®¨è®ºäº†åœ¨æœªæ¥ä¼˜åŒ–SMRç£ç›˜å’ŒIMRç£ç›˜æ€§èƒ½å¯èƒ½çš„ç ”ç©¶æ–¹å‘.æ›´å¤š è¿˜åŽŸ

ã€Abstractã€‘ In the digital age, the generation and accumulation of massive amounts of data are exploding, driving the demand for storage capacity sharply. Conventional magnetic recording disks(CMR) are considered the preferred solution for massive data storage due to their high capacity and low cost. However, the presence of the superparamagnetic effect(SPE) limits further improvements in CMR disk density. To overcome this limitation, shingled magnetic recording(SMR)technology was developed. Based on the conventional hard disc architecture, this technology dramatically increases disk areal density by overlapping tracks. However, SMR disks produce unpredictable write amplification effects when performing random writes, which can severely impact I/O performance. To solve this problem, the industry then proposed interlaced magnetic recording(IMR) technology, which uses an optimized track layout and heat-assisted magnetic recording technology to effectively balance storage capacity and performance. In this paper, we first introduce the technical principles, disk types, and applications of SMR and IMR in detail, and quantitatively analyzes the write interference problem that affects their I/O performance. It then focuses on solutions to optimize their I/O performance at the device level, analyzing and summarizing the advantages, disadvantages, and optimization objectives of different strategies in each type of solution. An overview of device-oriented system-level and application-level optimization solutions, such as file systems, redundant array of independent disk(RAID) technologies, and databases, is then provided. Finally, possible research directions for optimizing the performance of SMR and IMR disks in the future are discussed.æ›´å¤š è¿˜åŽŸ