FreeCalypso > hg > fc-magnetite
view src/cs/drivers/drv_app/ffs/board/dev.c @ 702:9394305d4ff5 default tip
etm_audio.c: fix off-by-one error in auw of FIR coefficients
This fix was already made in FC Tourmaline a while back, but it is also
the kind of bugfix that deserves to be backported to Magnetite and
Selenite as well.
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Mon, 31 Oct 2022 00:14:44 +0000 |
parents | b2b502339787 |
children |
line wrap: on
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/****************************************************************************** * Flash File System (ffs) * Idea, design and coding by Mads Meisner-Jensen, mmj@ti.com * * ffs flash device definitions * * $Id: dev.c 1.34.1.25 Thu, 18 Dec 2003 10:50:52 +0100 tsj $ * ******************************************************************************/ #include "ffs/ffs.h" #include "ffs/board/drv.h" #include "config/board.cfg" #include "config/rf.cfg" #include "config/fc-target.h" /****************************************************************************** Flash memories supported: The real flash device names are listed in the Device column. The names of compatible/similar devices are listed in the "aliases" column. Compatible/similar devices are e.g. combo devices using that particular flash device. The size column denotes the full device memory size in megabits (Mb). For dual and multi-bank devices, two or more numbers indicate the sizes of the respective banks, starting from the lowest address. ---------------+--------+------------------------------------------------- Device | Size| Aliases and Notes ---------------+--------+----------------------------------------------------- AMD | | 29DL161T |15.5+0.5| 29DL162T |14.0+2.0| 29DL163T |12.0+4.0| 29DL164T | 8.0+8.0| 29DL322T |28.0+4.0| 29DL323T |24.0+8.0| ---------------+--------+----------------------------------------------------- Fujitsu | | 29DL161T |15.5+0.5| (Am29DL161) 29DL162T |14.0+2.0| (Am29DL162) 29DL163T |12.0+4.0| (Am29DL163) 29DL164T | 8.0+8.0| (Am29DL164) 29DL321TD | | (Am29DL321), MB84VD22181, MB84VD22081, MB84VD22191 29DL322TD |28.0+4.0| (Am29DL322), MB84VD22182, MB84VD22082, MB84VD22192 29DL323TD |24.0+8.0| (Am29DL323), MB84VD22183, MB84VD22083, MB84VD22193, | | BSample device ---------------+--------+----------------------------------------------------- Samsung | | K5A3240YT |24+8 | K5A3240YB | 8+24 | K5A3340YT |16+16 | K5A3340YB |14+18 | (!?) ---------------+--------+----------------------------------------------------- SST | | SST36VF1601 | | ---------------+--------+----------------------------------------------------- Toshiba | | ? | | TH50VSF2581AASB ---------------+--------+----------------------------------------------------- Intel | | 28F160C3 | 16.0| Both Top and Bottom boot 28F320C3 | 32.0| Both Top and Bottom boot 28F640C3 | 64.0| Both Top and Bottom boot 28F640W30 | 64.0| Both Top and Bottom boot, DSample device ---------------+--------+----------------------------------------------------- Test | | | | ---------------+--------+----------------------------------------------------- ******************************************************************************/ /****************************************************************************** * Flash Device Memory Maps ******************************************************************************/ // The memory map, flash_AAxBB[], used by each flash device definition in // the flash_info[] array below can be either one of the pre-defined ones // below or a custom-defined one. Each line in the memory map represents one // physical device sector. The columns in the memory map has the following // meaning: // // 1. Relative address offset of sector. // 2. Base 2 logarithm of sector byte size, e.g. 64kB ~ 2^16. // // Note that does NOT support a flash definition with different sized blocks // so all blocks contained in the device definition MUST be the same size! #if defined(CONFIG_TARGET_PIRELLI) || defined(CONFIG_TARGET_FCFAM) // 256 KiB sectors static const struct block_info_s flash_32x256[] = { { 0x000000, 18 }, { 0x040000, 18 }, { 0x080000, 18 }, { 0x0C0000, 18 }, { 0x100000, 18 }, { 0x140000, 18 }, { 0x180000, 18 }, { 0x1C0000, 18 }, { 0x200000, 18 }, { 0x240000, 18 }, { 0x280000, 18 }, { 0x2C0000, 18 }, { 0x300000, 18 }, { 0x340000, 18 }, { 0x380000, 18 }, { 0x3C0000, 18 }, { 0x400000, 18 }, { 0x440000, 18 }, { 0x480000, 18 }, { 0x4C0000, 18 }, { 0x500000, 18 }, { 0x540000, 18 }, { 0x580000, 18 }, { 0x5C0000, 18 }, { 0x600000, 18 }, { 0x640000, 18 }, { 0x680000, 18 }, { 0x6C0000, 18 }, { 0x700000, 18 }, { 0x740000, 18 }, { 0x780000, 18 }, { 0x7C0000, 18 } }; // 128x64kb static const struct block_info_s flash_128x64[] = { { 0x00000, 16 }, { 0x10000, 16 }, { 0x20000, 16 }, { 0x30000, 16 }, { 0x40000, 16 }, { 0x50000, 16 }, { 0x60000, 16 }, { 0x70000, 16 }, { 0x80000, 16 }, { 0x90000, 16 }, { 0xa0000, 16 }, { 0xb0000, 16 }, { 0xc0000, 16 }, { 0xd0000, 16 }, { 0xe0000, 16 }, { 0xf0000, 16 }, { 0x100000, 16 }, { 0x110000, 16 }, { 0x120000, 16 }, { 0x130000, 16 }, { 0x140000, 16 }, { 0x150000, 16 }, { 0x160000, 16 }, { 0x170000, 16 }, { 0x180000, 16 }, { 0x190000, 16 }, { 0x1a0000, 16 }, { 0x1b0000, 16 }, { 0x1c0000, 16 }, { 0x1d0000, 16 }, { 0x1e0000, 16 }, { 0x1f0000, 16 }, { 0x200000, 16 }, { 0x210000, 16 }, { 0x220000, 16 }, { 0x230000, 16 }, { 0x240000, 16 }, { 0x250000, 16 }, { 0x260000, 16 }, { 0x270000, 16 }, { 0x280000, 16 }, { 0x290000, 16 }, { 0x2a0000, 16 }, { 0x2b0000, 16 }, { 0x2c0000, 16 }, { 0x2d0000, 16 }, { 0x2e0000, 16 }, { 0x2f0000, 16 }, { 0x300000, 16 }, { 0x310000, 16 }, { 0x320000, 16 }, { 0x330000, 16 }, { 0x340000, 16 }, { 0x350000, 16 }, { 0x360000, 16 }, { 0x370000, 16 }, { 0x380000, 16 }, { 0x390000, 16 }, { 0x3a0000, 16 }, { 0x3b0000, 16 }, { 0x3c0000, 16 }, { 0x3d0000, 16 }, { 0x3e0000, 16 }, { 0x3f0000, 16 }, { 0x400000, 16 }, { 0x410000, 16 }, { 0x420000, 16 }, { 0x430000, 16 }, { 0x440000, 16 }, { 0x450000, 16 }, { 0x460000, 16 }, { 0x470000, 16 }, { 0x480000, 16 }, { 0x490000, 16 }, { 0x4a0000, 16 }, { 0x4b0000, 16 }, { 0x4c0000, 16 }, { 0x4d0000, 16 }, { 0x4e0000, 16 }, { 0x4f0000, 16 }, { 0x500000, 16 }, { 0x510000, 16 }, { 0x520000, 16 }, { 0x530000, 16 }, { 0x540000, 16 }, { 0x550000, 16 }, { 0x560000, 16 }, { 0x570000, 16 }, { 0x580000, 16 }, { 0x590000, 16 }, { 0x5a0000, 16 }, { 0x5b0000, 16 }, { 0x5c0000, 16 }, { 0x5d0000, 16 }, { 0x5e0000, 16 }, { 0x5f0000, 16 }, { 0x600000, 16 }, { 0x610000, 16 }, { 0x620000, 16 }, { 0x630000, 16 }, { 0x640000, 16 }, { 0x650000, 16 }, { 0x660000, 16 }, { 0x670000, 16 }, { 0x680000, 16 }, { 0x690000, 16 }, { 0x6a0000, 16 }, { 0x6b0000, 16 }, { 0x6c0000, 16 }, { 0x6d0000, 16 }, { 0x6e0000, 16 }, { 0x6f0000, 16 }, { 0x700000, 16 }, { 0x710000, 16 }, { 0x720000, 16 }, { 0x730000, 16 }, { 0x740000, 16 }, { 0x750000, 16 }, { 0x760000, 16 }, { 0x770000, 16 }, { 0x780000, 16 }, { 0x790000, 16 }, { 0x7a0000, 16 }, { 0x7b0000, 16 }, { 0x7c0000, 16 }, { 0x7d0000, 16 }, { 0x7e0000, 16 }, { 0x7f0000, 16 } }; #endif // 16x64kB static const struct block_info_s flash_16x64[] = { { 0x00000, 16 }, { 0x10000, 16 }, { 0x20000, 16 }, { 0x30000, 16 }, { 0x40000, 16 }, { 0x50000, 16 }, { 0x60000, 16 }, { 0x70000, 16 }, { 0x80000, 16 }, { 0x90000, 16 }, { 0xA0000, 16 }, { 0xB0000, 16 }, { 0xC0000, 16 }, { 0xD0000, 16 }, { 0xE0000, 16 }, { 0xF0000, 16 } }; // 8x8kB static const struct block_info_s flash_8x8[] = { { 0x0000, 13 }, { 0x2000, 13 }, { 0x4000, 13 }, { 0x6000, 13 }, { 0x8000, 13 }, { 0xa000, 13 }, { 0xc000, 13 }, { 0xe000, 13 } }; // 4x4kB static const struct block_info_s flash_4x4[] = { { 0x0000, 12 }, { 0x1000, 12 }, { 0x2000, 12 }, { 0x3000, 12 } }; /****************************************************************************** * Flash Device Info Array ******************************************************************************/ // Each entry in the array below represents one flash device definition as // FFS needs it. The columns have the following meaning: // // 1. Device memory map. // 2. Absolute address of the first sector to be used by/for FFS. // 3. Manufacturer code. Values are from FFS_MANUFACTURER enumeration // in drv.h // 4. Device code. Available from device datasheet. // 5. FFS device driver to use. Values are from FFS_DRIVER enumeration // in drv.h // 6. Number of sectors to use, starting from the address given in // column 2. /********** RAM configuration ************************************************* * Note it is necessary to hardwire the configuration of the ram driver * in cfgffs.c. The ram driver is configured like and pseudo flash * device with only a few exceptions: Field 2 which is the absolute * address of the first sector MUST be set to zero, instead the address * is configured in cfgffs.c. Field 4 'Device code' is an arbitrary * value and not a real device code. ******************************************************************************/ /********** Multi-id configuration ******************************************** * When 227Eh is output, it indicates that two additional codes, called * Extended Device Codes, will be required. The two additional codes will be * read and the lower byte of each code will be combined into one id, which * is used for auto-detection of the flash configuration. The device code * format for the multi-id devices is as follow: 0x227E, 0x22YY, 0x22ZZ -> * 0xYYZZ. ******************************************************************************/ const struct flash_info_s flash_info[] = { #if 0 //BOARD 34. Ram device 4x4kB. Note it is necessary to hardwire the conf //in cfgffs.c { &flash_4x4[0], 0, MANUFACT_RAM, 0x0404, FFS_DRIVER_RAM, 4}, // Ram device 8x8kB. Note it is necessary to hardwire the conf in cfgffs.c { &flash_8x8[0], 0, MANUFACT_RAM, 0x080D, FFS_DRIVER_RAM, 8}, #endif #ifdef CONFIG_TARGET_PIRELLI /* * Our familiar version of the Pirelli DP-L10 hw features Spansion * S71PL129NC0HFW4B flash (N version, 256 KiB sectors), but apparently * an earlier hw version had S71PL129J flash with 64 KiB sectors, * and Pirelli's official fw supports both. They have modified * TI's flash ID code to generate device ID 0x2100 for the J version * or 0x2101 for the N version. We have now replicated this ID logic * in our FreeCalypso code base, and we can now support both flash * chip versions as well. * * Our FFS configuration for the Pirelli target is aftermarket. */ /* J flash */ { &flash_128x64[0], (char *) 0x02480000, MANUFACT_AMD, 0x2100, FFS_DRIVER_AMD, 24 }, /* N flash */ { &flash_32x256[0], (char *) 0x02480000, MANUFACT_AMD, 0x2101, FFS_DRIVER_AMD, 6 }, #elif defined(CONFIG_TARGET_FCFAM) /* * This table of flash devices covers those possibilities that may occur * on FreeCalypso-branded hardware; we use a new table separate from the * one we inherited from TI/Openmoko. Originally we had no choice because * we had no working autodetection for our new S71PL129N flash; we now have * working autodetection, but we still use a separate device table for a * few reasons: * * 1) Our 16 MiB flash options (S71PL129N and S71PL129J) are specific * to CONFIG_TARGET_FCFAM; * * 2) We gain additional freedoms like having a different FFS config * for K5A32xxCTM flash in FCFAM vs. Openmoko; * * 3) Less clutter is always good. */ /* S71PL129N, current FCDEV3B hw, FFS in the first 2 MiB of the 2nd bank */ { &flash_32x256[0], (char *) 0x01800000, MANUFACT_AMD, 0x2101, FFS_DRIVER_AMD, 8 }, /* S71PL129J, currently only theoretical */ { &flash_128x64[0], (char *) 0x01800000, MANUFACT_AMD, 0x2100, FFS_DRIVER_AMD, 32 }, /* S71PL064J, 7x9 mm, attractive option for tight physical form factors */ { &flash_16x64[0], (char *) 0x700000, MANUFACT_AMD, 0x0201, FFS_DRIVER_AMD, 15 }, /* S71PL032J, 7x9 mm, smaller capacity, footprint same as S71PL064J */ { &flash_16x64[0], (char *) 0x380000, MANUFACT_AMD, 0x0A01, FFS_DRIVER_AMD, 7 }, /* * Prior to the discovery of S71PL064J as a superior alternative, we were * thinking about using Samsung K5A32xx from Openmoko in embedded modem * products that have no need for huge flash and XRAM. Now that we have * discovered S71PL064J which is both physically smaller and friendlier in * terms of BGA footprint, it is unlikely that we will go back to K5A32xx. * However, we do have one FCDEV3B board on which we populated a K5A3281CTM * chip, so we are keeping firmware support for it. * * Note that the FFS configuration is different from Openmoko's: the * thinking was that if we were going to use this chip, let's use it * efficiently. */ { &flash_16x64[0], (char *) 0x300000, MANUFACT_SAMSUNG, 0x22A0, FFS_DRIVER_AMD, 15 }, #elif defined(CONFIG_TARGET_COMPAL) /* aftermarket FFS configurations for FreeCalypso on Mot C1xx phones */ // Intel 28F160C3-T 16Mb. Using top-most 8x8kB (parameter) sectors. // Changed for C11x aftermarket FFS config: 64x3 at 0x1C0000 { &flash_16x64[0], (char *) 0x1C0000, MANUFACT_INTEL, 0x88C2, FFS_DRIVER_INTEL_SB, 3 }, /* ST equivalent of 28F160C3T found in some Mot C11x phones */ { &flash_16x64[0], (char *) 0x1C0000, 0x20, 0x88CE, FFS_DRIVER_INTEL_SB, 3 }, // Intel 28F320C3-T, 32Mb. Using top-most 8x8kB (parameter) sectors. // Changed for C139 aftermarket FFS config: 64x3 at 0x3C0000 { &flash_16x64[0], (char *) 0x3C0000, MANUFACT_INTEL, 0x88C4, FFS_DRIVER_INTEL_SB, 3 }, /* ST equivalent of 28F320C3T found in some Mot C139 phones */ { &flash_16x64[0], (char *) 0x3C0000, 0x20, 0x88BA, FFS_DRIVER_INTEL_SB, 3 }, // Intel 28F640C3-B, 64Mb. Using top-most 16x64kB sectors // Changed for C155 aftermarket FFS config: 64x13 at 0x700000 { &flash_16x64[0], (char *) 0x700000, MANUFACT_INTEL, 0x88CD, FFS_DRIVER_INTEL_SB, 13 }, // Intel 28F640W30-B, 64Mb. (DSample). Using top-most 15x64kB sectors // Changed for C155 aftermarket FFS config: 64x13 at 0x700000 { &flash_16x64[0], (char *) 0x700000, MANUFACT_INTEL, 0x8855, FFS_DRIVER_INTEL, 13 }, #else /* original table from TI/Openmoko, used on TI and Openmoko targets */ /* also used on the newly discovered GTM900 and Tango modem targets */ /********** AMD Devices ***********************************************/ #ifdef CONFIG_TARGET_LEONARDO // AMD Am29DL640F. Ignoring the 8kB sectors // Multi-id device: 0x227E, 0x2221, 0x2200. Converted to 0x2100 { &flash_16x64[0], (char *) 0x01800000, MANUFACT_AMD, 0x2100, FFS_DRIVER_AMD, 15 }, #endif // AMD Am29DL640G. Ignoring the 8kB sectors // Multi-id device: 0x227E, 0x2202, 0x2201. Converted to 0x0201 { &flash_16x64[0], (char *) 0x700000, MANUFACT_AMD, 0x0201, FFS_DRIVER_AMD, 15 }, // AMD Am29DL321DT does not exist as of 2000-0217 // AMD Am29DL322DT. Ignoring the 8kB sectors { &flash_16x64[0], (char *) 0x380000, MANUFACT_AMD, 0x2255, FFS_DRIVER_AMD_SB, 7 }, // AMD Am29DL323DT. Ignoring the 8kB sectors { &flash_16x64[0], (char *) 0x300000, MANUFACT_AMD, 0x2250, FFS_DRIVER_AMD, 15 }, // AMD Am29DL161DT. Using 8x8kB sectors. { &flash_8x8[0], (char *) 0x1F0000, MANUFACT_AMD, 0x2236, FFS_DRIVER_AMD, 8 }, // AMD Am29DL162DT. Ignoring the 8kB sectors { &flash_16x64[0], (char *) 0x1C0000, MANUFACT_AMD, 0x222D, FFS_DRIVER_AMD, 3 }, // AMD Am29DL163DT. Ignoring the 8kB sectors { &flash_16x64[0], (char *) 0x180000, MANUFACT_AMD, 0x2228, FFS_DRIVER_AMD, 7 }, // AMD Am29DL164DT. Ignoring the 8kB sectors { &flash_16x64[0], (char *) 0x100000, MANUFACT_AMD, 0x2233, FFS_DRIVER_AMD, 15 }, /* newer Spansion devices in AMD ID code space */ // Spansion S29/S71PL032J. Ignoring the 8kB sectors // Multi-id device: 0x227E, 0x220A, 0x2201. Converted to 0x0A01 { &flash_16x64[0], (char *) 0x380000, MANUFACT_AMD, 0x0A01, FFS_DRIVER_AMD, 7 }, /********** Fujitsu Devices *******************************************/ // Fujitsu MBM29DL321TD. Using 8x8kB sectors. { &flash_8x8[0], (char *) 0x3f0000, MANUFACT_FUJITSU, 0x2259, FFS_DRIVER_AMD, 8 }, // Fujitsu MBM29DL322TD. Ignoring all the 8kB sectors { &flash_16x64[0], (char *) 0x380000, MANUFACT_FUJITSU, 0x2255, FFS_DRIVER_AMD, 7 }, // Fujitsu MBM29DL323TD (BSample). Dual bank device definition. { &flash_16x64[0], (char *) 0x300000, MANUFACT_FUJITSU, 0x2250, FFS_DRIVER_AMD, 15 }, // Fujitsu MBM29DL161DT (similar to Am29DL161T). { &flash_8x8[0], (char *) 0x1F0000, MANUFACT_FUJITSU, 0x2236, FFS_DRIVER_AMD, 8 }, // Fujitsu MBM29DL162DT (similar to Am29DL162T). { &flash_16x64[0], (char *) 0x1C0000, MANUFACT_FUJITSU, 0x222D, FFS_DRIVER_AMD, 3 }, // Fujitsu MBM29DL163DT (similar to Am29DL163T). { &flash_16x64[0], (char *) 0x180000, MANUFACT_FUJITSU, 0x2228, FFS_DRIVER_AMD, 7 }, // Fujitsu MBM29DL164DT (similar to Am29DL164T). { &flash_16x64[0], (char *) 0x100000, MANUFACT_FUJITSU, 0x2233, FFS_DRIVER_AMD, 15 }, /* This is the RITA flash configuration */ // Fujitsu MBM29DL320FB // Multi-id device: 0x227E, 0x220A, 0x2200. Converted to 0x0A00 { &flash_16x64[0], (char *) 0x320000, MANUFACT_FUJITSU, 0x0A00, FFS_DRIVER_AMD_SB, 13 }, // Fujitsu MBM29DL320FT // Multi-id device: 0x227E, 0x220A, 0x2201. Converted to 0x0A01 { &flash_16x64[0], (char *) 0x320000, MANUFACT_FUJITSU, 0x0A01, FFS_DRIVER_AMD_SB, 13 }, // Fujitsu MBM29DL640F, // Multi-id device: 0x227E, 0x2221, 0x2200. Converted to 0x2100 { &flash_16x64[0], (char *) 0x700000, MANUFACT_FUJITSU, 0x2100, FFS_DRIVER_AMD_SB, 15 }, // Fujitsu 84VF5F5F4J2, // Multi-id device: 0x227E, 0x2202, 0x2201. Converted to 0x0201 { &flash_16x64[0], (char *) 0x700000, MANUFACT_FUJITSU, 0x0201, FFS_DRIVER_AMD_SB, 15 }, #if 0 // Fujitsu MB84VF5F5F4J2 stacked device. Using the 2nd sub device // The 8x8 are located both in top and bottom, thus only 126 // blocks are used. { &flash_128x64[0], (char *) 0x1810000, MANUFACT_FUJITSU, 0xB496, FFS_DRIVER_AMD_SB, 126 }, #endif /********** Intel Devices *********************************************/ // Intel 28F160C3-T 16Mb. Using top-most 8x8kB (parameter) sectors. { &flash_8x8[0], (char *) 0x1F0000, MANUFACT_INTEL, 0x88C2, FFS_DRIVER_INTEL_SB, 8 }, // Intel 28F160C3-B, 16Mb. Using top-most 6x64kB sectors { &flash_16x64[0], (char *) 0x1A0000, MANUFACT_INTEL, 0x88C3, FFS_DRIVER_INTEL_SB, 6 }, // Intel 28F320C3-T, 32Mb. Using top-most 8x8kB (parameter) sectors. { &flash_8x8[0], (char *) 0x3F0000, MANUFACT_INTEL, 0x88C4, FFS_DRIVER_INTEL_SB, 8 }, // Intel 28F320C3-B, 32Mb. Using top-most 8x64kB sectors { &flash_16x64[0], (char *) 0x380000, MANUFACT_INTEL, 0x88C5, FFS_DRIVER_INTEL_SB, 8 }, // Intel 28F640C3-T, 64Mb. Using top-most 8x8kB (parameter) sectors. { &flash_8x8[0], (char *) 0x7F0000, MANUFACT_INTEL, 0x88CC, FFS_DRIVER_INTEL_SB, 8 }, // Intel 28F640C3-B, 64Mb. Using top-most 16x64kB sectors { &flash_16x64[0], (char *) 0x700000, MANUFACT_INTEL, 0x88CD, FFS_DRIVER_INTEL_SB, 15 }, // Intel 28F640W30-T, 64Mb. Using top-most 8x8kB sectors { &flash_8x8[0], (char *) 0x7F0000, MANUFACT_INTEL, 0x8854, FFS_DRIVER_INTEL_SB, 8 }, // Intel 28F640W30-B, 64Mb. (DSample). Using top-most 47x64kB sectors // { &flash_128x64[0], (char *) 0x500000, MANUFACT_INTEL, 0x8855, // FFS_DRIVER_INTEL_SB, 47 }, // Intel 28F640W30-B, 64Mb. (DSample). Using top-most 15x64kB sectors { &flash_16x64[0], (char *) 0x700000, MANUFACT_INTEL, 0x8855, FFS_DRIVER_INTEL, 15 }, // Intel 28F640W30-B, 64Mb. (DSample). Using top-most 15x64kB sectors { &flash_16x64[0], (char *) 0x700000, MANUFACT_INTEL, 0x88FF, FFS_DRIVER_INTEL_SB, 15 }, /********** MXIC Devices *******************************************/ // Intel 28F640W30-T, 64Mb. Using top-most 8x8kB sectors { &flash_8x8[0], (char *) 0x3F0000, MANUFACT_MXIC, 0x0024, FFS_DRIVER_INTEL_SB, 8 }, /********** Samsung Devices *******************************************/ // Samsung K5A3240YT Top boot, 24Mb + 8Mb { &flash_16x64[0], (char *) 0x380000, MANUFACT_SAMSUNG, 0x22B7, FFS_DRIVER_AMD_SB, 7 }, // Samsung K5A3340YT Top boot, 16Mb + 16Mb { &flash_16x64[0], (char *) 0x380000, MANUFACT_SAMSUNG, 0x22BA, FFS_DRIVER_AMD_SB, 7 }, // Samsung K5A3240YB Bottom boot, 8Mb + 24Mb { &flash_16x64[0], (char *) 0x380000, MANUFACT_SAMSUNG, 0x223F, FFS_DRIVER_AMD_SB, 8 }, // Samsung K5A3340YB Bottom boot, 14Mb + 18Mb (!?) { &flash_16x64[0], (char *) 0x380000, MANUFACT_SAMSUNG, 0x223D, FFS_DRIVER_AMD_SB, 8 }, /* post-TI additions */ // Samsung K5A32xxCTM (Openmoko) { &flash_16x64[0], (char *) 0x380000, MANUFACT_SAMSUNG, 0x22A0, FFS_DRIVER_AMD_SB, 7 }, // Samsung K5L33xxCAM (Huawei GTM900) // Multi-id device: 0x257E, 0x2503, 0x2501. Converted to 0x0301 { &flash_16x64[0], (char *) 0x380000, MANUFACT_SAMSUNG, 0x0301, FFS_DRIVER_AMD_SB, 7 }, // Samsung K5L6331CAA-D270 ?? (stanza came with moko10/11 source) // Multi-id device: 0x257E, 0x2506, 0x2501. Converted to 0x0601 { &flash_16x64[0], (char *) 0x380000, MANUFACT_SAMSUNG, 0x0601, FFS_DRIVER_AMD_SB, 15 }, /********** SST Devices ***********************************************/ // SST SST36VF1601 { &flash_16x64[0], (char *) 0x180000, MANUFACT_SST, 0x2761, FFS_DRIVER_SST, 8 }, /********** Toshiba Devices *******************************************/ // Toshiba TH50VSF2581AASB Bottom boot combo device { &flash_16x64[0], (char *) 0x380000, MANUFACT_TOSHIBA, 0x009C, FFS_DRIVER_AMD, 8 }, #endif #if 0 /********** Special/Test Devices **************************************/ // Intel 28F160C3-B, 16Mb. Single bank driver // Note that device ID is bogus! { &flash_16x64[0], (char *) 0x1A0000, MANUFACT_INTEL, 0x01C3, FFS_DRIVER_INTEL_SB, 6 }, // Fujitsu MBM29DL323TD (BSample). Single bank device definition. // Note that device ID is bogus! { &flash_16x64[0], (char *) 0x300000, MANUFACT_FUJITSU, 0x0150, FFS_DRIVER_AMD_SB, 15 }, // Fujitsu MBM29DL323TD (BSample). Pseudo single bank device definition. // Note that device ID is bogus! { &flash_16x64[0], (char *) 0x300000, MANUFACT_FUJITSU, 0x0250, FFS_DRIVER_AMD_PSEUDO_SB, 15 }, // Fujitsu MBM29DL323TD (BSample). "True" single bank device definition // within first flash device bank! // Note that device ID is bogus! { &flash_16x64[0], (char *) 0x280000, MANUFACT_FUJITSU, 0x0350, FFS_DRIVER_AMD_SB, 8 }, // AMD Am29DL323DT on EVA4 (base address = 0x200000) { &flash_16x64[0], (char *) 0x500000, MANUFACT_AMD, 0xF250, FFS_DRIVER_AMD, 15 }, // PC Test/Simulation flash 128x64kb { &flash_128x64[0], (char *) 0x000000, MANUFACT_TEST, 0x0F12, FFS_DRIVER_TEST, 127 }, // PC Test/Simulation flash 16x64kB { &flash_16x64[0], (char *) 0x000000, MANUFACT_TEST, 0x0F10, FFS_DRIVER_TEST, 15 }, // PC Test/Simulation flash 8x8kB { &flash_8x8[0], (char *) 0x000000, MANUFACT_TEST, 0x080D, FFS_DRIVER_TEST, 8 }, // PC Test/Simulation flash 4x4kB { &flash_4x4[0], (char *) 0x000000, MANUFACT_TEST, 0x0404, FFS_DRIVER_TEST, 4 }, #endif // terminator { 0, 0, 0, 0 } };