Based on kernel version 4.16.1. Page generated on 2018-04-09 11:53 EST.
1 2 About this document 3 =================== 4 5 Some notes about Marvell's NAND controller available in PXA and Armada 370/XP 6 SoC (aka NFCv1 and NFCv2), with an emphasis on the latter. 7 8 NFCv2 controller background 9 =========================== 10 11 The controller has a 2176 bytes FIFO buffer. Therefore, in order to support 12 larger pages, I/O operations on 4 KiB and 8 KiB pages is done with a set of 13 chunked transfers. 14 15 For instance, if we choose a 2048 data chunk and set "BCH" ECC (see below) 16 we'll have this layout in the pages: 17 18 ------------------------------------------------------------------------------ 19 | 2048B data | 32B spare | 30B ECC || 2048B data | 32B spare | 30B ECC | ... | 20 ------------------------------------------------------------------------------ 21 22 The driver reads the data and spare portions independently and builds an internal 23 buffer with this layout (in the 4 KiB page case): 24 25 ------------------------------------------ 26 | 4096B data | 64B spare | 27 ------------------------------------------ 28 29 Also, for the READOOB command the driver disables the ECC and reads a 'spare + ECC' 30 OOB, one per chunk read. 31 32 ------------------------------------------------------------------- 33 | 4096B data | 32B spare | 30B ECC | 32B spare | 30B ECC | 34 ------------------------------------------------------------------- 35 36 So, in order to achieve reading (for instance), we issue several READ0 commands 37 (with some additional controller-specific magic) and read two chunks of 2080B 38 (2048 data + 32 spare) each. 39 The driver accommodates this data to expose the NAND core a contiguous buffer 40 (4096 data + spare) or (4096 + spare + ECC + spare + ECC). 41 42 ECC 43 === 44 45 The controller has built-in hardware ECC capabilities. In addition it is 46 configurable between two modes: 1) Hamming, 2) BCH. 47 48 Note that the actual BCH mode: BCH-4 or BCH-8 will depend on the way 49 the controller is configured to transfer the data. 50 51 In the BCH mode the ECC code will be calculated for each transferred chunk 52 and expected to be located (when reading/programming) right after the spare 53 bytes as the figure above shows. 54 55 So, repeating the above scheme, a 2048B data chunk will be followed by 32B 56 spare, and then the ECC controller will read/write the ECC code (30B in 57 this case): 58 59 ------------------------------------ 60 | 2048B data | 32B spare | 30B ECC | 61 ------------------------------------ 62 63 If the ECC mode is 'BCH' then the ECC is *always* 30 bytes long. 64 If the ECC mode is 'Hamming' the ECC is 6 bytes long, for each 512B block. 65 So in Hamming mode, a 2048B page will have a 24B ECC. 66 67 Despite all of the above, the controller requires the driver to only read or 68 write in multiples of 8-bytes, because the data buffer is 64-bits. 69 70 OOB 71 === 72 73 Because of the above scheme, and because the "spare" OOB is really located in 74 the middle of a page, spare OOB cannot be read or write independently of the 75 data area. In other words, in order to read the OOB (aka READOOB), the entire 76 page (aka READ0) has to be read. 77 78 In the same sense, in order to write to the spare OOB the driver has to write 79 an *entire* page. 80 81 Factory bad blocks handling 82 =========================== 83 84 Given the ECC BCH requires to layout the device's pages in a split 85 data/OOB/data/OOB way, the controller has a view of the flash page that's 86 different from the specified (aka the manufacturer's) view. In other words, 87 88 Factory view: 89 90 ----------------------------------------------- 91 | Data |x OOB | 92 ----------------------------------------------- 93 94 Driver's view: 95 96 ----------------------------------------------- 97 | Data | OOB | Data x | OOB | 98 ----------------------------------------------- 99 100 It can be seen from the above, that the factory bad block marker must be 101 searched within the 'data' region, and not in the usual OOB region. 102 103 In addition, this means under regular usage the driver will write such 104 position (since it belongs to the data region) and every used block is 105 likely to be marked as bad. 106 107 For this reason, marking the block as bad in the OOB is explicitly 108 disabled by using the NAND_BBT_NO_OOB_BBM option in the driver. The rationale 109 for this is that there's no point in marking a block as bad, because good 110 blocks are also 'marked as bad' (in the OOB BBM sense) under normal usage. 111 112 Instead, the driver relies on the bad block table alone, and should only perform 113 the bad block scan on the very first time (when the device hasn't been used).