/****************************************************************************** * Copyright (c) 2004, 2008 IBM Corporation * Copyright (c) 2008, 2009 Pattrick Hueper * All rights reserved. * This program and the accompanying materials * are made available under the terms of the BSD License * which accompanies this distribution, and is available at * http://www.opensource.org/licenses/bsd-license.php * * Contributors: * IBM Corporation - initial implementation *****************************************************************************/ #ifndef DEVICE_LIB_H #define DEVICE_LIB_H #include #ifdef CONFIG_COREBOOT_V2 #include #include "compat/of.h" #else #include #include #include "of.h" #endif #include "debug.h" // a Expansion Header Struct as defined in Plug and Play BIOS Spec 1.0a Chapter 3.2 typedef struct { char signature[4]; // signature u8 structure_revision; u8 length; // in 16 byte blocks u16 next_header_offset; // offset to next Expansion Header as 16bit little-endian value, as offset from the start of the Expansion ROM u8 reserved; u8 checksum; // the sum of all bytes of the Expansion Header must be 0 u32 device_id; // PnP Device ID as 32bit little-endian value u16 p_manufacturer_string; //16bit little-endian offset from start of Expansion ROM u16 p_product_string; //16bit little-endian offset from start of Expansion ROM u8 device_base_type; u8 device_sub_type; u8 device_if_type; u8 device_indicators; // the following vectors are all 16bit little-endian offsets from start of Expansion ROM u16 bcv; // Boot Connection Vector u16 dv; // Disconnect Vector u16 bev; // Bootstrap Entry Vector u16 reserved_2; u16 sriv; // Static Resource Information Vector } __attribute__ ((__packed__)) exp_header_struct_t; // a PCI Data Struct as defined in PCI 2.3 Spec Chapter 6.3.1.2 typedef struct { u8 signature[4]; // signature, the String "PCIR" u16 vendor_id; u16 device_id; u16 reserved; u16 pci_ds_length; // PCI Data Structure Length, 16bit little-endian value u8 pci_ds_revision; u8 class_code[3]; u16 img_length; // length of the Exp.ROM Image, 16bit little-endian value in 512 bytes u16 img_revision; u8 code_type; u8 indicator; u16 reserved_2; } __attribute__ ((__packed__)) pci_data_struct_t; typedef struct { u8 bus; u8 devfn; #ifdef CONFIG_PCI_OPTION_ROM_RUN_YABEL struct device* dev; #else u64 puid; phandle_t phandle; ihandle_t ihandle; #endif // store the address of the BAR that is used to simulate // legacy VGA memory accesses u64 vmem_addr; u64 vmem_size; // used to buffer I/O Accesses, that do not access the I/O Range of the device... // 64k might be overkill, but we can buffer all I/O accesses... u8 io_buffer[64 * 1024]; u16 pci_vendor_id; u16 pci_device_id; // translated address of the "PC-Compatible" Expansion ROM Image for this device unsigned long img_addr; u32 img_size; // size of the Expansion ROM Image (read from the PCI Data Structure) } biosemu_device_t; typedef struct { #ifdef CONFIG_PCI_OPTION_ROM_RUN_YABEL unsigned long info; #else u8 info; #endif u8 bus; u8 devfn; u8 cfg_space_offset; u64 address; u64 address_offset; u64 size; } __attribute__ ((__packed__)) translate_address_t; // array to store address translations for this // device. Needed for faster address translation, so // not every I/O or Memory Access needs to call translate_address_dev // and access the device tree // 6 BARs, 1 Exp. ROM, 1 Cfg.Space, and 3 Legacy // translations are supported... this should be enough for // most devices... for VGA it is enough anyways... extern translate_address_t translate_address_array[11]; // index of last translate_address_array entry // set by get_dev_addr_info function extern u8 taa_last_entry; /* the device we are working with... */ extern biosemu_device_t bios_device; u8 biosemu_dev_init(struct device * device); // NOTE: for dev_check_exprom to work, biosemu_dev_init MUST be called first! u8 biosemu_dev_check_exprom(unsigned long rom_base_addr); u8 biosemu_dev_translate_address(unsigned long * addr); /* endianness swap functions for 16 and 32 bit words * copied from axon_pciconfig.c */ static inline void out32le(void *addr, u32 val) { #ifdef __i386 *((u32*) addr) = cpu_to_le32(val); #else asm volatile ("stwbrx %0, 0, %1"::"r" (val), "r"(addr)); #endif } static inline u32 in32le(void *addr) { u32 val; #ifdef __i386 val = cpu_to_le32(*((u32 *) addr)); #else asm volatile ("lwbrx %0, 0, %1":"=r" (val):"r"(addr)); #endif return val; } static inline void out16le(void *addr, u16 val) { #ifdef __i386 *((u16*) addr) = cpu_to_le16(val); #else asm volatile ("sthbrx %0, 0, %1"::"r" (val), "r"(addr)); #endif } static inline u16 in16le(void *addr) { u16 val; #ifdef __i386 val = cpu_to_le16(*((u16*) addr)); #else asm volatile ("lhbrx %0, 0, %1":"=r" (val):"r"(addr)); #endif return val; } /* debug function, dumps HID1 and HID4 to detect whether caches are on/off */ static inline void dumpHID(void) { u64 hid; //HID1 = 1009 __asm__ __volatile__("mfspr %0, 1009":"=r"(hid)); printf("HID1: %016llx\n", hid); //HID4 = 1012 __asm__ __volatile__("mfspr %0, 1012":"=r"(hid)); printf("HID4: %016llx\n", hid); } #endif