/* Board specific functions for those embedded 8xx boards that do * not have boot monitor support for board information. * * 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. */ #include #include #include #include #ifdef CONFIG_8xx #include #endif #ifdef CONFIG_8260 #include #include #endif #ifdef CONFIG_40x #include #endif #ifdef CONFIG_XILINX_VIRTEX #include #endif extern unsigned long timebase_period_ns; /* For those boards that don't provide one. */ #if !defined(CONFIG_MBX) static bd_t bdinfo; #endif /* IIC functions. * These are just the basic master read/write operations so we can * examine serial EEPROM. */ extern void iic_read(uint devaddr, u_char *buf, uint offset, uint count); /* Supply a default Ethernet address for those eval boards that don't * ship with one. This is an address from the MBX board I have, so * it is unlikely you will find it on your network. */ static ushort def_enet_addr[] = { 0x0800, 0x3e26, 0x1559 }; #if defined(CONFIG_MBX) /* The MBX hands us a pretty much ready to go board descriptor. This * is where the idea started in the first place. */ void embed_config(bd_t **bdp) { u_char *mp; u_char eebuf[128]; int i = 8; bd_t *bd; bd = *bdp; /* Read the first 128 bytes of the EEPROM. There is more, * but this is all we need. */ iic_read(0xa4, eebuf, 0, 128); /* All we are looking for is the Ethernet MAC address. The * first 8 bytes are 'MOTOROLA', so check for part of that. * Next, the VPD describes a MAC 'packet' as being of type 08 * and size 06. So we look for that and the MAC must follow. * If there are more than one, we still only care about the first. * If it's there, assume we have a valid MAC address. If not, * grab our default one. */ if ((*(uint *)eebuf) == 0x4d4f544f) { while (i < 127 && !(eebuf[i] == 0x08 && eebuf[i + 1] == 0x06)) i += eebuf[i + 1] + 2; /* skip this packet */ if (i == 127) /* Couldn't find. */ mp = (u_char *)def_enet_addr; else mp = &eebuf[i + 2]; } else mp = (u_char *)def_enet_addr; for (i=0; i<6; i++) bd->bi_enetaddr[i] = *mp++; /* The boot rom passes these to us in MHz. Linux now expects * them to be in Hz. */ bd->bi_intfreq *= 1000000; bd->bi_busfreq *= 1000000; /* Stuff a baud rate here as well. */ bd->bi_baudrate = 9600; } #endif /* CONFIG_MBX */ #if defined(CONFIG_RPXLITE) || defined(CONFIG_RPXCLASSIC) || \ defined(CONFIG_RPX8260) || defined(CONFIG_EP405) /* Helper functions for Embedded Planet boards. */ /* Because I didn't find anything that would do this....... */ u_char aschex_to_byte(u_char *cp) { u_char byte, c; c = *cp++; if ((c >= 'A') && (c <= 'F')) { c -= 'A'; c += 10; } else if ((c >= 'a') && (c <= 'f')) { c -= 'a'; c += 10; } else c -= '0'; byte = c * 16; c = *cp; if ((c >= 'A') && (c <= 'F')) { c -= 'A'; c += 10; } else if ((c >= 'a') && (c <= 'f')) { c -= 'a'; c += 10; } else c -= '0'; byte += c; return(byte); } static void rpx_eth(bd_t *bd, u_char *cp) { int i; for (i=0; i<6; i++) { bd->bi_enetaddr[i] = aschex_to_byte(cp); cp += 2; } } #ifdef CONFIG_RPX8260 static uint rpx_baseten(u_char *cp) { uint retval; retval = 0; while (*cp != '\n') { retval *= 10; retval += (*cp) - '0'; cp++; } return(retval); } #endif #if defined(CONFIG_RPXLITE) || defined(CONFIG_RPXCLASSIC) static void rpx_brate(bd_t *bd, u_char *cp) { uint rate; rate = 0; while (*cp != '\n') { rate *= 10; rate += (*cp) - '0'; cp++; } bd->bi_baudrate = rate * 100; } static void rpx_cpuspeed(bd_t *bd, u_char *cp) { uint num, den; num = den = 0; while (*cp != '\n') { num *= 10; num += (*cp) - '0'; cp++; if (*cp == '/') { cp++; den = (*cp) - '0'; break; } } /* I don't know why the RPX just can't state the actual * CPU speed..... */ if (den) { num /= den; num *= den; } bd->bi_intfreq = bd->bi_busfreq = num * 1000000; /* The 8xx can only run a maximum 50 MHz bus speed (until * Motorola changes this :-). Greater than 50 MHz parts * run internal/2 for bus speed. */ if (num > 50) bd->bi_busfreq /= 2; } #endif #if defined(CONFIG_RPXLITE) || defined(CONFIG_RPXCLASSIC) || defined(CONFIG_EP405) static void rpx_memsize(bd_t *bd, u_char *cp) { uint size; size = 0; while (*cp != '\n') { size *= 10; size += (*cp) - '0'; cp++; } bd->bi_memsize = size * 1024 * 1024; } #endif /* LITE || CLASSIC || EP405 */ #if defined(CONFIG_EP405) static void rpx_nvramsize(bd_t *bd, u_char *cp) { uint size; size = 0; while (*cp != '\n') { size *= 10; size += (*cp) - '0'; cp++; } bd->bi_nvramsize = size * 1024; } #endif /* CONFIG_EP405 */ #endif /* Embedded Planet boards */ #if defined(CONFIG_RPXLITE) || defined(CONFIG_RPXCLASSIC) /* Read the EEPROM on the RPX-Lite board. */ void embed_config(bd_t **bdp) { u_char eebuf[256], *cp; bd_t *bd; /* Read the first 256 bytes of the EEPROM. I think this * is really all there is, and I hope if it gets bigger the * info we want is still up front. */ bd = &bdinfo; *bdp = bd; #if 1 iic_read(0xa8, eebuf, 0, 128); iic_read(0xa8, &eebuf[128], 128, 128); /* We look for two things, the Ethernet address and the * serial baud rate. The records are separated by * newlines. */ cp = eebuf; for (;;) { if (*cp == 'E') { cp++; if (*cp == 'A') { cp += 2; rpx_eth(bd, cp); } } if (*cp == 'S') { cp++; if (*cp == 'B') { cp += 2; rpx_brate(bd, cp); } } if (*cp == 'D') { cp++; if (*cp == '1') { cp += 2; rpx_memsize(bd, cp); } } if (*cp == 'H') { cp++; if (*cp == 'Z') { cp += 2; rpx_cpuspeed(bd, cp); } } /* Scan to the end of the record. */ while ((*cp != '\n') && (*cp != 0xff)) cp++; /* If the next character is a 0 or ff, we are done. */ cp++; if ((*cp == 0) || (*cp == 0xff)) break; } bd->bi_memstart = 0; #else /* For boards without initialized EEPROM. */ bd->bi_memstart = 0; bd->bi_memsize = (8 * 1024 * 1024); bd->bi_intfreq = 48000000; bd->bi_busfreq = 48000000; bd->bi_baudrate = 9600; #endif } #endif /* RPXLITE || RPXCLASSIC */ #ifdef CONFIG_BSEIP /* Build a board information structure for the BSE ip-Engine. * There is more to come since we will add some environment * variables and a function to read them. */ void embed_config(bd_t **bdp) { u_char *cp; int i; bd_t *bd; bd = &bdinfo; *bdp = bd; /* Baud rate and processor speed will eventually come * from the environment variables. */ bd->bi_baudrate = 9600; /* Get the Ethernet station address from the Flash ROM. */ cp = (u_char *)0xfe003ffa; for (i=0; i<6; i++) { bd->bi_enetaddr[i] = *cp++; } /* The rest of this should come from the environment as well. */ bd->bi_memstart = 0; bd->bi_memsize = (16 * 1024 * 1024); bd->bi_intfreq = 48000000; bd->bi_busfreq = 48000000; } #endif /* BSEIP */ #ifdef CONFIG_FADS /* Build a board information structure for the FADS. */ void embed_config(bd_t **bdp) { u_char *cp; int i; bd_t *bd; bd = &bdinfo; *bdp = bd; /* Just fill in some known values. */ bd->bi_baudrate = 9600; /* Use default enet. */ cp = (u_char *)def_enet_addr; for (i=0; i<6; i++) { bd->bi_enetaddr[i] = *cp++; } bd->bi_memstart = 0; bd->bi_memsize = (8 * 1024 * 1024); bd->bi_intfreq = 40000000; bd->bi_busfreq = 40000000; } #endif /* FADS */ #ifdef CONFIG_8260 /* Compute 8260 clock values if the rom doesn't provide them. */ static unsigned char bus2core_8260[] = { /* 0 1 2 3 4 5 6 7 8 9 a b c d e f */ 3, 2, 2, 2, 4, 4, 5, 9, 6, 11, 8, 10, 3, 12, 7, 2, 6, 5, 13, 2, 14, 4, 15, 2, 3, 11, 8, 10, 16, 12, 7, 2, }; static void clk_8260(bd_t *bd) { uint scmr, vco_out, clkin; uint plldf, pllmf, corecnf; volatile cpm2_map_t *ip; ip = (cpm2_map_t *)CPM_MAP_ADDR; scmr = ip->im_clkrst.car_scmr; /* The clkin is always bus frequency. */ clkin = bd->bi_busfreq; /* Collect the bits from the scmr. */ plldf = (scmr >> 12) & 1; pllmf = scmr & 0xfff; corecnf = (scmr >> 24) &0x1f; /* This is arithmetic from the 8260 manual. */ vco_out = clkin / (plldf + 1); vco_out *= 2 * (pllmf + 1); bd->bi_vco = vco_out; /* Save for later */ bd->bi_cpmfreq = vco_out / 2; /* CPM Freq, in MHz */ bd->bi_intfreq = bd->bi_busfreq * bus2core_8260[corecnf] / 2; /* Set Baud rate divisor. The power up default is divide by 16, * but we set it again here in case it was changed. */ ip->im_clkrst.car_sccr = 1; /* DIV 16 BRG */ bd->bi_brgfreq = vco_out / 16; } static unsigned char bus2core_8280[] = { /* 0 1 2 3 4 5 6 7 8 9 a b c d e f */ 3, 2, 2, 2, 4, 4, 5, 9, 6, 11, 8, 10, 3, 12, 7, 2, 6, 5, 13, 2, 14, 2, 15, 2, 3, 2, 2, 2, 16, 2, 2, 2, }; static void clk_8280(bd_t *bd) { uint scmr, main_clk, clkin; uint pllmf, corecnf; volatile cpm2_map_t *ip; ip = (cpm2_map_t *)CPM_MAP_ADDR; scmr = ip->im_clkrst.car_scmr; /* The clkin is always bus frequency. */ clkin = bd->bi_busfreq; /* Collect the bits from the scmr. */ pllmf = scmr & 0xf; corecnf = (scmr >> 24) & 0x1f; /* This is arithmetic from the 8280 manual. */ main_clk = clkin * (pllmf + 1); bd->bi_cpmfreq = main_clk / 2; /* CPM Freq, in MHz */ bd->bi_intfreq = bd->bi_busfreq * bus2core_8280[corecnf] / 2; /* Set Baud rate divisor. The power up default is divide by 16, * but we set it again here in case it was changed. */ ip->im_clkrst.car_sccr = (ip->im_clkrst.car_sccr & 0x3) | 0x1; bd->bi_brgfreq = main_clk / 16; } #endif #ifdef CONFIG_SBC82xx void embed_config(bd_t **bdp) { u_char *cp; int i; bd_t *bd; unsigned long pvr; bd = *bdp; bd = &bdinfo; *bdp = bd; bd->bi_baudrate = 9600; bd->bi_memsize = 256 * 1024 * 1024; /* just a guess */ cp = (void*)SBC82xx_MACADDR_NVRAM_SCC1; memcpy(bd->bi_enetaddr, cp, 6); /* can busfreq be calculated? */ pvr = mfspr(SPRN_PVR); if ((pvr & 0xffff0000) == 0x80820000) { bd->bi_busfreq = 100000000; clk_8280(bd); } else { bd->bi_busfreq = 66000000; clk_8260(bd); } } #endif /* SBC82xx */ #if defined(CONFIG_EST8260) || defined(CONFIG_TQM8260) void embed_config(bd_t **bdp) { u_char *cp; int i; bd_t *bd; bd = *bdp; #if 0 /* This is actually provided by my boot rom. I have it * here for those people that may load the kernel with * a JTAG/COP tool and not the rom monitor. */ bd->bi_baudrate = 115200; bd->bi_intfreq = 200000000; bd->bi_busfreq = 66666666; bd->bi_cpmfreq = 66666666; bd->bi_brgfreq = 33333333; bd->bi_memsize = 16 * 1024 * 1024; #else /* The boot rom passes these to us in MHz. Linux now expects * them to be in Hz. */ bd->bi_intfreq *= 1000000; bd->bi_busfreq *= 1000000; bd->bi_cpmfreq *= 1000000; bd->bi_brgfreq *= 1000000; #endif cp = (u_char *)def_enet_addr; for (i=0; i<6; i++) { bd->bi_enetaddr[i] = *cp++; } } #endif /* EST8260 */ #ifdef CONFIG_SBS8260 void embed_config(bd_t **bdp) { u_char *cp; int i; bd_t *bd; /* This should provided by the boot rom. */ bd = &bdinfo; *bdp = bd; bd->bi_baudrate = 9600; bd->bi_memsize = 64 * 1024 * 1024; /* Set all of the clocks. We have to know the speed of the * external clock. The development board had 66 MHz. */ bd->bi_busfreq = 66666666; clk_8260(bd); /* I don't know how to compute this yet. */ bd->bi_intfreq = 133000000; cp = (u_char *)def_enet_addr; for (i=0; i<6; i++) { bd->bi_enetaddr[i] = *cp++; } } #endif /* SBS8260 */ #ifdef CONFIG_RPX8260 void embed_config(bd_t **bdp) { u_char *cp, *keyvals; int i; bd_t *bd; keyvals = (u_char *)*bdp; bd = &bdinfo; *bdp = bd; /* This is almost identical to the RPX-Lite/Classic functions * on the 8xx boards. It would be nice to have a key lookup * function in a string, but the format of all of the fields * is slightly different. */ cp = keyvals; for (;;) { if (*cp == 'E') { cp++; if (*cp == 'A') { cp += 2; rpx_eth(bd, cp); } } if (*cp == 'S') { cp++; if (*cp == 'B') { cp += 2; bd->bi_baudrate = rpx_baseten(cp); } } if (*cp == 'D') { cp++; if (*cp == '1') { cp += 2; bd->bi_memsize = rpx_baseten(cp) * 1024 * 1024; } } if (*cp == 'X') { cp++; if (*cp == 'T') { cp += 2; bd->bi_busfreq = rpx_baseten(cp); } } if (*cp == 'N') { cp++; if (*cp == 'V') { cp += 2; bd->bi_nvsize = rpx_baseten(cp) * 1024 * 1024; } } /* Scan to the end of the record. */ while ((*cp != '\n') && (*cp != 0xff)) cp++; /* If the next character is a 0 or ff, we are done. */ cp++; if ((*cp == 0) || (*cp == 0xff)) break; } bd->bi_memstart = 0; /* The memory size includes both the 60x and local bus DRAM. * I don't want to use the local bus DRAM for real memory, * so subtract it out. It would be nice if they were separate * keys. */ bd->bi_memsize -= 32 * 1024 * 1024; /* Set all of the clocks. We have to know the speed of the * external clock. */ clk_8260(bd); /* I don't know how to compute this yet. */ bd->bi_intfreq = 200000000; } #endif /* RPX6 for testing */ #ifdef CONFIG_ADS8260 void embed_config(bd_t **bdp) { u_char *cp; int i; bd_t *bd; /* This should provided by the boot rom. */ bd = &bdinfo; *bdp = bd; bd->bi_baudrate = 9600; bd->bi_memsize = 16 * 1024 * 1024; /* Set all of the clocks. We have to know the speed of the * external clock. The development board had 66 MHz. */ bd->bi_busfreq = 66666666; clk_8260(bd); /* I don't know how to compute this yet. */ bd->bi_intfreq = 200000000; cp = (u_char *)def_enet_addr; for (i=0; i<6; i++) { bd->bi_enetaddr[i] = *cp++; } } #endif /* ADS8260 */ #ifdef CONFIG_WILLOW void embed_config(bd_t **bdp) { u_char *cp; int i; bd_t *bd; /* Willow has Open Firmware....I should learn how to get this * information from it. */ bd = &bdinfo; *bdp = bd; bd->bi_baudrate = 9600; bd->bi_memsize = 32 * 1024 * 1024; /* Set all of the clocks. We have to know the speed of the * external clock. The development board had 66 MHz. */ bd->bi_busfreq = 66666666; clk_8260(bd); /* I don't know how to compute this yet. */ bd->bi_intfreq = 200000000; cp = (u_char *)def_enet_addr; for (i=0; i<6; i++) { bd->bi_enetaddr[i] = *cp++; } } #endif /* WILLOW */ #if defined(CONFIG_XILINX_ML300) || defined(CONFIG_XILINX_ML403) void embed_config(bd_t ** bdp) { static const unsigned long line_size = 32; static const unsigned long congruence_classes = 256; unsigned long addr; unsigned long dccr; bd_t *bd; /* * Invalidate the data cache if the data cache is turned off. * - The 405 core does not invalidate the data cache on power-up * or reset but does turn off the data cache. We cannot assume * that the cache contents are valid. * - If the data cache is turned on this must have been done by * a bootloader and we assume that the cache contents are * valid. */ __asm__("mfdccr %0": "=r" (dccr)); if (dccr == 0) { for (addr = 0; addr < (congruence_classes * line_size); addr += line_size) { __asm__("dccci 0,%0": :"b"(addr)); } } bd = &bdinfo; *bdp = bd; bd->bi_memsize = XPAR_DDR_0_SIZE; bd->bi_intfreq = XPAR_CORE_CLOCK_FREQ_HZ; bd->bi_busfreq = XPAR_PLB_CLOCK_FREQ_HZ; bd->bi_pci_busfreq = XPAR_PCI_0_CLOCK_FREQ_HZ; timebase_period_ns = 1000000000 / bd->bi_tbfreq; /* see bi_tbfreq definition in arch/ppc/platforms/4xx/xilinx_ml300.h */ } #endif /* CONFIG_XILINX_ML300 || CONFIG_XILINX_ML403 */ #ifdef CONFIG_IBM_OPENBIOS /* This could possibly work for all treeboot roms. */ #if defined(CONFIG_BUBINGA) #define BOARD_INFO_VECTOR 0xFFF80B50 /* openbios 1.19 moved this vector down - armin */ #else #define BOARD_INFO_VECTOR 0xFFFE0B50 #endif void embed_config(bd_t **bdp) { u_char *cp; int i; bd_t *bd, *treeboot_bd; bd_t *(*get_board_info)(void) = (bd_t *(*)(void))(*(unsigned long *)BOARD_INFO_VECTOR); #if !defined(CONFIG_STB03xxx) /* shut down the Ethernet controller that the boot rom * sometimes leaves running. */ mtdcr(DCRN_MALCR(DCRN_MAL_BASE), MALCR_MMSR); /* 1st reset MAL */ while (mfdcr(DCRN_MALCR(DCRN_MAL_BASE)) & MALCR_MMSR) {}; /* wait for the reset */ out_be32((volatile u32*)EMAC0_BASE,0x20000000); /* then reset EMAC */ #endif bd = &bdinfo; *bdp = bd; if ((treeboot_bd = get_board_info()) != NULL) { memcpy(bd, treeboot_bd, sizeof(bd_t)); } else { /* Hmmm...better try to stuff some defaults. */ bd->bi_memsize = 16 * 1024 * 1024; cp = (u_char *)def_enet_addr; for (i=0; i<6; i++) { /* I should probably put different ones here, * hopefully only one is used. */ bd->BD_EMAC_ADDR(0,i) = *cp; #ifdef CONFIG_PCI bd->bi_pci_enetaddr[i] = *cp++; #endif } bd->bi_tbfreq = 200 * 1000 * 1000; bd->bi_intfreq = 200000000; bd->bi_busfreq = 100000000; #ifdef CONFIG_PCI bd->bi_pci_busfreq = 66666666; #endif } /* Yeah, this look weird, but on Redwood 4 they are * different object in the structure. Sincr Redwwood 5 * and Redwood 6 use OpenBIOS, it requires a special value. */ #if defined(CONFIG_REDWOOD_5) || defined (CONFIG_REDWOOD_6) bd->bi_tbfreq = 27 * 1000 * 1000; #endif timebase_period_ns = 1000000000 / bd->bi_tbfreq; } #endif /* CONFIG_IBM_OPENBIOS */ #ifdef CONFIG_EP405 #include void embed_config(bd_t **bdp) { u32 chcr0; u_char *cp; bd_t *bd; /* Different versions of the PlanetCore firmware vary in how they set up the serial port - in particular whether they use the internal or external serial clock for UART0. Make sure the UART is in a known state. */ /* FIXME: We should use the board's 11.0592MHz external serial clock - it will be more accurate for serial rates. For now, however the baud rates in ep405.h are for the internal clock. */ chcr0 = mfdcr(DCRN_CHCR0); if ( (chcr0 & 0x1fff) != 0x103e ) { mtdcr(DCRN_CHCR0, (chcr0 & 0xffffe000) | 0x103e); /* The following tricks serial_init() into resetting the baud rate */ writeb(0, UART0_IO_BASE + UART_LCR); } /* We haven't seen actual problems with the EP405 leaving the * EMAC running (as we have on Walnut). But the registers * suggest it may not be left completely quiescent. Reset it * just to be sure. */ mtdcr(DCRN_MALCR(DCRN_MAL_BASE), MALCR_MMSR); /* 1st reset MAL */ while (mfdcr(DCRN_MALCR(DCRN_MAL_BASE)) & MALCR_MMSR) {}; /* wait for the reset */ out_be32((unsigned *)EMAC0_BASE,0x20000000); /* then reset EMAC */ bd = &bdinfo; *bdp = bd; #if 1 cp = (u_char *)0xF0000EE0; for (;;) { if (*cp == 'E') { cp++; if (*cp == 'A') { cp += 2; rpx_eth(bd, cp); } } if (*cp == 'D') { cp++; if (*cp == '1') { cp += 2; rpx_memsize(bd, cp); } } if (*cp == 'N') { cp++; if (*cp == 'V') { cp += 2; rpx_nvramsize(bd, cp); } } while ((*cp != '\n') && (*cp != 0xff)) cp++; cp++; if ((*cp == 0) || (*cp == 0xff)) break; } bd->bi_intfreq = 200000000; bd->bi_busfreq = 100000000; bd->bi_pci_busfreq= 33000000 ; #else bd->bi_memsize = 64000000; bd->bi_intfreq = 200000000; bd->bi_busfreq = 100000000; bd->bi_pci_busfreq= 33000000 ; #endif } #endif