/* * This file is part of the flashrom project. * * Copyright (C) 2008 Wang Qingpei * Copyright (C) 2008 Joe Bao * Copyright (C) 2008 Advanced Micro Devices, Inc. * Copyright (C) 2009, 2010 Carl-Daniel Hailfinger * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program 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 General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #if defined(__i386__) || defined(__x86_64__) #include "flash.h" #include "programmer.h" #include "spi.h" /* This struct is unused, but helps visualize the SB600 SPI BAR layout. *struct sb600_spi_controller { * unsigned int spi_cntrl0; / * 00h * / * unsigned int restrictedcmd1; / * 04h * / * unsigned int restrictedcmd2; / * 08h * / * unsigned int spi_cntrl1; / * 0ch * / * unsigned int spi_cmdvalue0; / * 10h * / * unsigned int spi_cmdvalue1; / * 14h * / * unsigned int spi_cmdvalue2; / * 18h * / * unsigned int spi_fakeid; / * 1Ch * / *}; */ static uint8_t *sb600_spibar = NULL; static void reset_internal_fifo_pointer(void) { mmio_writeb(mmio_readb(sb600_spibar + 2) | 0x10, sb600_spibar + 2); /* FIXME: This loop makes no sense at all. */ while (mmio_readb(sb600_spibar + 0xD) & 0x7) msg_pspew("reset\n"); } static int compare_internal_fifo_pointer(uint8_t want) { uint8_t tmp; tmp = mmio_readb(sb600_spibar + 0xd) & 0x07; want &= 0x7; if (want != tmp) { msg_perr("SB600 FIFO pointer corruption! Pointer is %d, wanted " "%d\n", tmp, want); msg_perr("Something else is accessing the flash chip and " "causes random corruption.\nPlease stop all " "applications and drivers and IPMI which access the " "flash chip.\n"); return 1; } else { msg_pspew("SB600 FIFO pointer is %d, wanted %d\n", tmp, want); return 0; } } static int reset_compare_internal_fifo_pointer(uint8_t want) { int ret; ret = compare_internal_fifo_pointer(want); reset_internal_fifo_pointer(); return ret; } static void execute_command(void) { mmio_writeb(mmio_readb(sb600_spibar + 2) | 1, sb600_spibar + 2); while (mmio_readb(sb600_spibar + 2) & 1) ; } static int sb600_spi_send_command(unsigned int writecnt, unsigned int readcnt, const unsigned char *writearr, unsigned char *readarr) { int count; /* First byte is cmd which can not being sent through FIFO. */ unsigned char cmd = *writearr++; unsigned int readoffby1; unsigned char readwrite; writecnt--; msg_pspew("%s, cmd=%x, writecnt=%x, readcnt=%x\n", __func__, cmd, writecnt, readcnt); if (readcnt > 8) { msg_pinfo("%s, SB600 SPI controller can not receive %d bytes, " "it is limited to 8 bytes\n", __func__, readcnt); return SPI_INVALID_LENGTH; } if (writecnt > 8) { msg_pinfo("%s, SB600 SPI controller can not send %d bytes, " "it is limited to 8 bytes\n", __func__, writecnt); return SPI_INVALID_LENGTH; } /* This is a workaround for a bug in SB600 and SB700. If we only send * an opcode and no additional data/address, the SPI controller will * read one byte too few from the chip. Basically, the last byte of * the chip response is discarded and will not end up in the FIFO. * It is unclear if the CS# line is set high too early as well. */ readoffby1 = (writecnt) ? 0 : 1; readwrite = (readcnt + readoffby1) << 4 | (writecnt); mmio_writeb(readwrite, sb600_spibar + 1); mmio_writeb(cmd, sb600_spibar + 0); /* Before we use the FIFO, reset it first. */ reset_internal_fifo_pointer(); /* Send the write byte to FIFO. */ msg_pspew("Writing: "); for (count = 0; count < writecnt; count++, writearr++) { msg_pspew("[%02x]", *writearr); mmio_writeb(*writearr, sb600_spibar + 0xC); } msg_pspew("\n"); /* * We should send the data by sequence, which means we need to reset * the FIFO pointer to the first byte we want to send. */ if (reset_compare_internal_fifo_pointer(writecnt)) return SPI_PROGRAMMER_ERROR; msg_pspew("Executing: \n"); execute_command(); /* * After the command executed, we should find out the index of the * received byte. Here we just reset the FIFO pointer and skip the * writecnt. * It would be possible to increase the FIFO pointer by one instead * of reading and discarding one byte from the FIFO. * The FIFO is implemented on top of an 8 byte ring buffer and the * buffer is never cleared. For every byte that is shifted out after * the opcode, the FIFO already stores the response from the chip. * Usually, the chip will respond with 0x00 or 0xff. */ if (reset_compare_internal_fifo_pointer(writecnt + readcnt)) return SPI_PROGRAMMER_ERROR; /* Skip the bytes we sent. */ msg_pspew("Skipping: "); for (count = 0; count < writecnt; count++) { cmd = mmio_readb(sb600_spibar + 0xC); msg_pspew("[%02x]", cmd); } msg_pspew("\n"); if (compare_internal_fifo_pointer(writecnt)) return SPI_PROGRAMMER_ERROR; msg_pspew("Reading: "); for (count = 0; count < readcnt; count++, readarr++) { *readarr = mmio_readb(sb600_spibar + 0xC); msg_pspew("[%02x]", *readarr); } msg_pspew("\n"); if (reset_compare_internal_fifo_pointer(readcnt + writecnt)) return SPI_PROGRAMMER_ERROR; if (mmio_readb(sb600_spibar + 1) != readwrite) { msg_perr("Unexpected change in SB600 read/write count!\n"); msg_perr("Something else is accessing the flash chip and " "causes random corruption.\nPlease stop all " "applications and drivers and IPMI which access the " "flash chip.\n"); return SPI_PROGRAMMER_ERROR; } return 0; } static const struct spi_programmer spi_programmer_sb600 = { .type = SPI_CONTROLLER_SB600, .max_data_read = 8, .max_data_write = 5, .command = sb600_spi_send_command, .multicommand = default_spi_send_multicommand, .read = default_spi_read, .write_256 = default_spi_write_256, }; int sb600_probe_spi(struct pci_dev *dev) { struct pci_dev *smbus_dev; uint32_t tmp; uint8_t reg; static const char *const speed_names[4] = { "Reserved", "33", "22", "16.5" }; /* Read SPI_BaseAddr */ tmp = pci_read_long(dev, 0xa0); tmp &= 0xffffffe0; /* remove bits 4-0 (reserved) */ msg_pdbg("SPI base address is at 0x%x\n", tmp); /* If the BAR has address 0, it is unlikely SPI is used. */ if (!tmp) return 0; /* Physical memory has to be mapped at page (4k) boundaries. */ sb600_spibar = physmap("SB600 SPI registers", tmp & 0xfffff000, 0x1000); /* The low bits of the SPI base address are used as offset into * the mapped page. */ sb600_spibar += tmp & 0xfff; tmp = pci_read_long(dev, 0xa0); msg_pdbg("AltSpiCSEnable=%i, SpiRomEnable=%i, " "AbortEnable=%i\n", tmp & 0x1, (tmp & 0x2) >> 1, (tmp & 0x4) >> 2); tmp = (pci_read_byte(dev, 0xba) & 0x4) >> 2; msg_pdbg("PrefetchEnSPIFromIMC=%i, ", tmp); tmp = pci_read_byte(dev, 0xbb); /* FIXME: Set bit 3,6,7 if not already set. * Set bit 5, otherwise SPI accesses are pointless in LPC mode. * See doc 42413 AMD SB700/710/750 RPR. */ msg_pdbg("PrefetchEnSPIFromHost=%i, SpiOpEnInLpcMode=%i\n", tmp & 0x1, (tmp & 0x20) >> 5); tmp = mmio_readl(sb600_spibar); /* FIXME: If SpiAccessMacRomEn or SpiHostAccessRomEn are zero on * SB700 or later, reads and writes will be corrupted. Abort in this * case. Make sure to avoid this check on SB600. */ msg_pdbg("SpiArbEnable=%i, SpiAccessMacRomEn=%i, " "SpiHostAccessRomEn=%i, ArbWaitCount=%i, " "SpiBridgeDisable=%i, DropOneClkOnRd=%i\n", (tmp >> 19) & 0x1, (tmp >> 22) & 0x1, (tmp >> 23) & 0x1, (tmp >> 24) & 0x7, (tmp >> 27) & 0x1, (tmp >> 28) & 0x1); tmp = (mmio_readb(sb600_spibar + 0xd) >> 4) & 0x3; msg_pdbg("NormSpeed is %s MHz\n", speed_names[tmp]); /* Look for the SMBus device. */ smbus_dev = pci_dev_find(0x1002, 0x4385); if (!smbus_dev) { smbus_dev = pci_dev_find(0x1022, 0x780b); /* AMD Hudson */ if (!smbus_dev) { msg_perr("ERROR: SMBus device not found. Not enabling SPI.\n"); return ERROR_NONFATAL; } } /* Note about the bit tests below: If a bit is zero, the GPIO is SPI. */ /* GPIO11/SPI_DO and GPIO12/SPI_DI status */ reg = pci_read_byte(smbus_dev, 0xAB); reg &= 0xC0; msg_pdbg("GPIO11 used for %s\n", (reg & (1 << 6)) ? "GPIO" : "SPI_DO"); msg_pdbg("GPIO12 used for %s\n", (reg & (1 << 7)) ? "GPIO" : "SPI_DI"); if (reg != 0x00) { msg_pdbg("Not enabling SPI"); return 0; } /* GPIO31/SPI_HOLD and GPIO32/SPI_CS status */ reg = pci_read_byte(smbus_dev, 0x83); reg &= 0xC0; msg_pdbg("GPIO31 used for %s\n", (reg & (1 << 6)) ? "GPIO" : "SPI_HOLD"); msg_pdbg("GPIO32 used for %s\n", (reg & (1 << 7)) ? "GPIO" : "SPI_CS"); /* SPI_HOLD is not used on all boards, filter it out. */ if ((reg & 0x80) != 0x00) { msg_pdbg("Not enabling SPI"); return 0; } /* GPIO47/SPI_CLK status */ reg = pci_read_byte(smbus_dev, 0xA7); reg &= 0x40; msg_pdbg("GPIO47 used for %s\n", (reg & (1 << 6)) ? "GPIO" : "SPI_CLK"); if (reg != 0x00) { msg_pdbg("Not enabling SPI"); return 0; } reg = pci_read_byte(dev, 0x40); msg_pdbg("SB700 IMC is %sactive.\n", (reg & (1 << 7)) ? "" : "not "); if (reg & (1 << 7)) { /* If we touch any region used by the IMC, the IMC and the SPI * interface will lock up, and the only way to recover is a * hard reset, but that is a bad choice for a half-erased or * half-written flash chip. * There appears to be an undocumented register which can freeze * or disable the IMC, but for now we want to play it safe. */ msg_perr("The SB700 IMC is active and may interfere with SPI " "commands. Disabling write.\n"); /* FIXME: Should we only disable SPI writes, or will the lockup * affect LPC/FWH chips as well? */ programmer_may_write = 0; } /* Bring the FIFO to a clean state. */ reset_internal_fifo_pointer(); register_spi_programmer(&spi_programmer_sb600); return 0; } #endif