/* * Initialize Broadcom 5785 GbE MAC embedded in AMD A55E (Hudson-E1) Southbridge * by uploading a Selfboot Patch to the A55E's shadow ROM area. The patch * itself supports the Broadcom 50610(M) PHY on the AMD Inagua. It is * equivalent to Broadcom's SelfBoot patch V1.11 (sb5785m1.11). * A modified variant, selected by CONFIG_BOARD_LIPPERT_FRONTRUNNER_AF supports * the Micrel KSZ9021 PHY that was used on LiPPERT FrontRunner-AF (CFR-AF) * revision 0v0, the first prototype. The board is history and this code now * serves only to document the proprietary Selfboot Patch format and how to * adapt it to a PHY unsupported by Broadcom. * * This file is part of the coreboot project. * * Copyright (C) 2012 LiPPERT ADLINK Technology GmbH * (Written by Jens Rottmann ) * * 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; version 2 of the License. * * 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 */ #include #include #include #include //Coreboot device access #include #include #define be16(x) cpu_to_be16(x) //a little easier to type #define be(x) cpu_to_be32(x) //this is used a lot! /* C forces us to specify these before defining struct selfboot_patch :-( */ #if !CONFIG_BOARD_LIPPERT_FRONTRUNNER_AF #define INIT1_LENGTH 9 #define INIT2_LENGTH 10 #define INIT3_LENGTH 3 #define INIT4_LENGTH 7 //this one may be 0 #define PWRDN_LENGTH 5 #else #define INIT1_LENGTH 13 #define INIT2_LENGTH 6 #define INIT3_LENGTH 3 #define INIT4_LENGTH 11 //this one may be 0 #define PWRDN_LENGTH 4 #endif /* The AMD A55E (Hudson-E1) Southbridge contains an integrated Gigabit Ethernet * MAC, however AMD's documentation merely defines the related balls (without * fully describing their function) and states that only Broadcom 50610(M) PHYs * will be supported, that's all. The Hudson register reference skips all MAC * registers entirely, even AMD support doesn't seem to know more about it. * * As Broadcom refused to sell us any 50610 chips or provide any docs (or indeed * even a price list) below $100K expected sales we had to figure out everything * by ourselves. *Everything* below is the result of months of detective work, * documented here lest it get lost: * * The AMD A55E's GbE MAC is a Broadcom 5785, which AMD obviously licensed as IP * core. It uses a standard RGMII/MII interface and the Broadcom drivers will * recognize it by its unchanged PCI ID 14E4:1699, however there are some * specialties. * * The 5785 MAC can detect the link with 4 additional inputs, "phy_status[3:0]", * 'snooping' on the PHY's LED outputs. Interpretation of the LEDs' patterns is * programmed with register 0x5A4 of the MAC. AMD renamed them to "GBE_STAT" and * won't say anything about their purpose. Appearently hardware designers are * expected to blindly copy the Inagua reference schematic: GBE_STAT2: * 0=activity; GBE_STAT[1:0]: 11=no link, 10=10Mbit, 01=100Mbit, 00=1Gbit. * * For package processing the 5785 also features a MIPS-based RISC CPU, booting * from an internal ROM. The firmware loads config data and supplements (e.g. to * support specific PHYs), named "Selfboot Patches", via the "NVRAM Interface", * usually from an external EEPROM. The A55E doesn't have any balls for an ext. * EEPROM, instead AMD added a small internal RAM. The BIOS is expected to copy * the correct contents into this RAM (which only supports byte access!) upon * each powerup. The A55E can trigger an SMI upon writes, enabling the BIOS to * forward any changes to an actually 'NV' location, e.g. the BIOS's SPI flash, * behind the scenes. AMD calls it "GEC shadow ROM", not describing what it's * for nor mentioning the term "NVRAM". broadcom_init() below documents a * procedure how to upload the patch. No SMI magic is installed, therefore * 'NV'RAM writes won't be persistent. * * The "Selfboot Patch" can execute simple commands at various points during * main firmware execution. This can be used to change config registers, * initialize a specific PHY or work around firmware bugs. Broadcom provides * suitable Patches only for their AC131 and 50610 PHYs (as binary blobs). I * found them in DOS\sb_patch\5785\*\sb5785*.* in Driver_14_6_4_2.zip. (Note * that every 32bit-word of these files must be byte-swapped before uploading * them to the A55E.) * * Below is a derived Patch supporting the Micrel KSZ9021 PHY used on the * LiPPERT CFR-AF PC/104 SBC instead, with detailled description of the format. * (Here in correct order for upload.) * * This Patch made Ethernet work with Linux 3.3 - without having to modify the * tg3.ko driver. Broadcom's Windows-Drivers still fail with "Code 10" however; * disassembly showed they check the PHY ID and abort, because the Micrel PHY is * not supported. */ static struct selfboot_patch { //Watch out: all values are *BIG-ENDIAN*! struct { /* Global header */ u8 signature; //0xA5 u8 format; //bits 7-3: patch format; 2-0: revision u8 mac_addr[6]; u16 subsys_device; //IDs will be loaded into PCI config space u16 subsys_vendor; u16 pci_device; //PCI device ID; vendor is always Broadcom (0x14E4) u8 unknown1[8]; //?, noticed no effect u16 basic_config; //?, see below u8 checksum; //byte sum of header == 0 u8 unknown2; //?, patch rejected if changed u16 patch_version; //10-8: major; 7-0: minor; 15-11: variant (1=a, 2=b, ...) } header; struct { /* Init code */ u8 checksum; //byte sum of init == 0 u8 unknown; //?, looks unused u8 num_hunks; //0x60 = 3 hunks, 0x80 = 4 hunks, other values not supported u8 size; //total size of all hunk#_code[] in bytes u8 hunk1_when; //mark when hunk1_code gets executed u8 hunk1_size; //sizeof(hunk1_code) u8 hunk2_when; u8 hunk2_size; u8 hunk3_when; u8 hunk3_size; u8 hunk4_when; //0x00 (padding) if only 3 hunks u8 hunk4_size; //dito u32 hunk1_code[INIT1_LENGTH]; //actual commands, see below u32 hunk2_code[INIT2_LENGTH]; u32 hunk3_code[INIT3_LENGTH]; u32 hunk4_code[INIT4_LENGTH]; //missing (zero length) if only 3 hunks } init; struct { /* Power down code */ u8 checksum; //byte sum of powerdown == 0 u8 unknown; //?, looks unused u8 num_hunks; //0x20 = 1 hunk, other values not supported u8 size; //total size of all hunk#_code[] in bytes u8 hunk1_when; //mark when hunk1_code gets executed u8 hunk1_size; //sizeof(hunk1_code) u16 padding; //0x0000, hunk2 is not supported u32 hunk1_code[PWRDN_LENGTH]; //commands, see below } powerdown; } selfboot_patch = { /* Keep the following invariant for valid Selfboot patches */ .header.signature = 0xA5, .header.format = 0x23, //format 1 revision 3 .header.unknown1 = { 0x61, 0xB1, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }, .header.checksum = 0, //calculated later .header.unknown2 = 0x30, .init.checksum = 0, //calculated later .init.unknown = 0x00, .init.num_hunks = sizeof(selfboot_patch.init.hunk4_code) ? 0x80 : 0x60, .init.size = sizeof(selfboot_patch.init.hunk1_code) + sizeof(selfboot_patch.init.hunk2_code) + sizeof(selfboot_patch.init.hunk3_code) + sizeof(selfboot_patch.init.hunk4_code), .init.hunk1_size = sizeof(selfboot_patch.init.hunk1_code), .init.hunk2_size = sizeof(selfboot_patch.init.hunk2_code), .init.hunk3_size = sizeof(selfboot_patch.init.hunk3_code), .init.hunk4_size = sizeof(selfboot_patch.init.hunk4_code), .powerdown.checksum = 0, //calculated later .powerdown.unknown = 0x00, .powerdown.num_hunks = 0x20, .powerdown.size = sizeof(selfboot_patch.powerdown.hunk1_code), .powerdown.hunk1_size = sizeof(selfboot_patch.powerdown.hunk1_code), .powerdown.padding = be16(0x0000), /* Only the lines below may be adapted to your needs ... */ #if !CONFIG_BOARD_LIPPERT_FRONTRUNNER_AF .header.mac_addr = { 0x00, 0x10, 0x18, 0x00, 0x00, 0x00 }, //Broadcom .header.subsys_device = be16(0x1699), //same as pci_device .header.subsys_vendor = be16(0x14E4), //Broadcom #else .header.mac_addr = { 0x00, 0x20, 0x9D, 0x00, 0x00, 0x00 }, //LiPPERT .header.subsys_device = be16(0x1699), //simply kept this .header.subsys_vendor = be16(0x121D), //LiPPERT #endif .header.pci_device = be16(0x1699), //Broadcom 5785 with GbE PHY #if !CONFIG_BOARD_LIPPERT_FRONTRUNNER_AF .header.patch_version = be16(0x010B), //1.11 (Broadcom's sb5785m1.11) #else .header.patch_version = be16(0x110B), //1.11b, i.e. hacked :-) #endif /* Bitfield enabling general features/codepaths in the firmware or * selecting support for one of several supported PHYs? * Bits not listed had no appearent effect: * 14-11: any bit 1=firmware execution seemed delayed * 10: 0=firmware execution seemed delayed * 9,2,0: select PHY type, affects these registers, probably more * 9 2 0 | reg 0x05A4 PHY reg 31 PHY 23,24,28 Notes * -------+---------------------------------------------------------- * 0 0 0 | 0x331C71C1 - changed Inband Status enabled * 0 1 0 | 0x3210C500 - changed - * 0 X 1 | 0x33FF66C0 changed - 10/100 Mbit only * 1 X 0 | 0x330C5180 - - - * 1 X 1 | 0x391C6140 - - - */ #if !CONFIG_BOARD_LIPPERT_FRONTRUNNER_AF .header.basic_config = be16(0x0404), //original for B50610 #else .header.basic_config = be16(0x0604), //bit 9 set so not to mess up PHY regs, kept other bits unchanged #endif /* Tag that defines when / on what occasion the commands are interpreted. * Bits 2-0 = 0 i.e. possible values are 0x00, 08, 10, ..., F8. * On a RISC CPU reset every tag except 0x38, A0, F0, F8 is used. 0x38 * seems to be run before a reset is performed(?), the other 3 I have * never seen used. Generally, lower values appear to be run earlier. * An "ifconfig up" with Linux' "tg3" driver causes the tags 0x50, 60, * 68, 20, 70, 80 to be interpreted in this order. * All tests were performed with .basic_config=0x0604. */ .init.hunk1_when = 0x10, //only once at RISC CPU reset? /* Instructions are obviously a specialized bytecode interpreted by the * main firmware, rather than MIPS machine code. Commands consist of 1-3 * 32-bit words. In the following, 0-9,A-F = hex literals, a-z,_ = variable * parts, each character = 4 bits. * 0610offs newvalue: write (32-bit) to 5785-internal shared mem at * 08rgvalu: write to PHY register, = 0x20 + register number * C610rgnr newvalue: write to MAC register * C1F0rgnr andvalue or_value: modify MAC register by ANDing with and then ORing with * C4btrgnr: clear bit in 32-bit MAC register , = bit number << 3 * C3btrgnr: set bit, see C4...; example: command 0xC3200454 sets bit 4 of 32-bit register 0x0454 * CBbtrgnr: run next command only if bit (see C4...) == 1 (so far only seen before F7F0...) * F7F0skip: unconditional jump i.e. skip next code bytes (only seen small positive ) * F7Fxaddr: call function at in main firmware? = 3 or 4, bool parameter?? Wild guess! * F7FFFadr somvalue: also call func. at , but with as parameter?? More guessing! * More commands probably exist, but all code I've ever seen was kept * included below, commented out if not suitable for the CFR-AF. v1.xx * is Broadcom's Selfboot patch version sb5785m1.xx where the command * was added, for reference see Broadcom's changelog. */ .init.hunk1_code = { #if CONFIG_BOARD_LIPPERT_FRONTRUNNER_AF be(0x082B8104), //CFR-AF: PHY0B: KSZ9021 select PHY104 be(0x082CF0F0), //CFR-AF: PHY0C: KSZ9021 clk/ctl skew (advised by Micrel) be(0x082B8105), //CFR-AF: PHY0B: KSZ9021 select PHY105 be(0x082C3333), //CFR-AF: PHY0C: KSZ9021 RX data skew (empirical) #endif be(0xC1F005A0), be(0xFEFFEFFF), be(0x01001000), //v1.05 : 5A0.24,12=1: auto-clock-switch be(0x06100D34), be(0x00000000), //v1.03 : MemD34: clear config vars be(0x06100D38), be(0x00000000), //v1.03 : - | be(0x06100D3C), be(0x00000000), //v1.03 : MemD3F| }, //-->INIT1_LENGTH! .init.hunk2_when = 0x30, //after global reset, PHY reset .init.hunk2_code = { #if !CONFIG_BOARD_LIPPERT_FRONTRUNNER_AF be(0x08370F08), //v1.06 : PHY17: B50610 select reg. 08 be(0x08350001), //v1.06 : PHY15: B50610 slow link fix be(0x08370F00), //v1.06 : PHY17: B50610 disable reg. 08 be(0x083C2C00), //v1.11 : PHY1C: B50610 Shadow 0B #endif be(0xF7F301E6), //v1.09+: ?: subroutine calls to be(0xF7FFF0B6), be(0x0000FFE7), //v1.09+: ?| restore Port Mode ??? be(0xF7FFF0F6), be(0x00008000), //v1.09+: ?| be(0xF7F401E6), //v1.09+: ?| }, //-->INIT2_LENGTH! .init.hunk3_when = 0xA8, //?, I'd guess quite late .init.hunk3_code = { be(0xC1F03604), be(0xFFE0FFFF), be(0x00110000), //v1.08 : 3604.20-16: 10Mb clock = 12.5MHz }, //-->INIT3_LENGTH! #if !CONFIG_BOARD_LIPPERT_FRONTRUNNER_AF .init.hunk4_when = 0xD8, //original for B50610 #else .init.hunk4_when = 0x80, //run last, after Linux' "ifconfig up" #endif .init.hunk4_code = { #if CONFIG_BOARD_LIPPERT_FRONTRUNNER_AF be(0x083F4300), //CFR-AF: PHY1F: IRQ active high be(0x083C0000), //CFR-AF: PHY1C: revert driver writes be(0x08380000), //CFR-AF: PHY18| be(0x083C0000), //CFR-AF: PHY1C| #endif be(0xCB0005A4), be(0xF7F0000C), //v1.01 : if 5A4.0==1 -->skip next 12 bytes #if !CONFIG_BOARD_LIPPERT_FRONTRUNNER_AF be(0xC61005A4), be(0x3210C500), //v1.01 : 5A4: PHY LED mode #else be(0xC61005A4), be(0x331C71CE), //CFR-AF: 5A4: fake LED mode #endif be(0xF7F00008), //v1.01 : -->skip next 8 bytes be(0xC61005A4), be(0x331C71C1), //v1.01 : 5A4: inband LED mode //be(0xC3200454), //CFR-AF: 454.4: auto link polling }, //-->INIT4_LENGTH! .powerdown.hunk1_when = 0x50, //prior to IDDQ MAC .powerdown.hunk1_code = { #if !CONFIG_BOARD_LIPPERT_FRONTRUNNER_AF be(0x083CB001), //v1.10 : PHY1C: IDDQ B50610 PHY #endif be(0xF7F30116), // IDDQ PHY be(0xC40005A0), //v1.09 : 5A0.0=0: Port Mode = MII be(0xC4180400), //v1.09 : 400.3=0| be(0xC3100400), //v1.09 : 400.2=1| }, //-->PWRDN_LENGTH! }; /* Upload 'NV'RAM contents for BCM5785 GbE MAC integrated in A55E. * Call this from mainboard.c. */ void broadcom_init(void) { volatile u32 *gec_base; //Gigabit Ethernet Controller base addr u8 *gec_shadow; //base addr of shadow 'NV'RAM for GbE MAC in A55E u8 sum; int i; gec_base = (u32*)(long)dev_find_slot(0, PCI_DEVFN(0x14, 6))->resource_list->base; gec_shadow = (u8*)(pci_read_config32(dev_find_slot(0, PCI_DEVFN(0x14, 3)), 0x9C) & 0xFFFFFC00); printk(BIOS_DEBUG, "Upload GbE 'NV'RAM contents @ 0x%08lx\n", (unsigned long)gec_shadow); /* Halt RISC CPU before uploading the firmware patch */ for (i=10000; i > 0; i--) { gec_base[0x5004/4] = 0xFFFFFFFF; //clear CPU state gec_base[0x5000/4] |= (1<<10); //issue RISC halt if (gec_base[0x5000/4] | (1<<10)) break; udelay(10); } if (!i) printk(BIOS_ERR, "Failed to halt RISC CPU!\n"); /* Calculate checksums (standard byte sum) */ for (sum = 0, i = 0; i < sizeof(selfboot_patch.header); i++) sum -= ((u8*)&selfboot_patch.header)[i]; selfboot_patch.header.checksum = sum; for (sum = 0, i = 0; i < sizeof(selfboot_patch.init); i++) sum -= ((u8*)&selfboot_patch.init)[i]; selfboot_patch.init.checksum = sum; for (sum = 0, i = 0; i < sizeof(selfboot_patch.powerdown); i++) sum -= ((u8*)&selfboot_patch.powerdown)[i]; selfboot_patch.powerdown.checksum = sum; /* Upload firmware patch to shadow 'NV'RAM */ for (i = 0; i < sizeof(selfboot_patch); i++) gec_shadow[i] = ((u8*)&selfboot_patch)[i]; //access byte-wise! /* Restart BCM5785's CPU */ gec_base[0x5004/4] = 0xFFFFFFFF; //clear CPU state gec_base[0x5000/4] = 0x00000001; //reset RISC processor //usually we'd have to wait for the reset bit to clear again ... }