CloverBootloader/rEFIt_UEFI/Platform/FixBiosDsdt.cpp

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/*
* Copyright (c) 2011-2012 Frank Peng. All rights reserved.
*
*/
//totally rebuilt by Slice, 2012-2013
// NForce additions by Oscar09, 2013
2020-02-17 21:41:09 +01:00
#include "Platform.h"
#include "StateGenerator.h"
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extern "C" {
#include <IndustryStandard/PciCommand.h>
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}
#ifdef DBG
#undef DBG
#endif
#ifndef DEBUG_FIX
#ifndef DEBUG_ALL
#define DEBUG_FIX 0
#else
#define DEBUG_FIX DEBUG_ALL
#endif
#endif
#if DEBUG_FIX==0
#define DBG(...)
#else
#define DBG(...) DebugLog(DEBUG_FIX, __VA_ARGS__)
#endif
OPER_REGION *gRegions = NULL;
CHAR8* device_name[12]; // 0=>Display 1=>network 2=>firewire 3=>LPCB 4=>HDAAudio 5=>RTC 6=>TMR 7=>SBUS 8=>PIC 9=>Airport 10=>XHCI 11=>HDMI
CHAR8* UsbName[10];
BOOLEAN HDAFIX = TRUE;
BOOLEAN GFXHDAFIX = TRUE;
BOOLEAN DisplayName1;
BOOLEAN DisplayName2;
BOOLEAN NetworkName;
BOOLEAN ArptName;
BOOLEAN XhciName;
BOOLEAN ArptBCM;
BOOLEAN ArptAtheros;
BOOLEAN LPCBFIX;
BOOLEAN IDEFIX;
BOOLEAN SATAFIX;
BOOLEAN ASUSFIX;
BOOLEAN USBIntel;
BOOLEAN USBNForce;
BOOLEAN USBIDFIX = TRUE;
//BOOLEAN Display1PCIE;
//BOOLEAN Display2PCIE;
BOOLEAN FirewireName;
// for read computer data
UINT32 DisplayADR1[4];
UINT32 DisplayADR2[4];
UINT32 NetworkADR1[4];
UINT32 NetworkADR2[4];
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CONST CHAR8* Netmodel[4];
CONST CHAR8* NetName[4] = { "ETH0", "ETH1", "ETH2", "ETH3" };
UINT32 net_count = 0;
UINT32 ArptADR1;
UINT32 ArptADR2;
UINT32 FirewireADR1;
UINT32 FirewireADR2;
UINT32 SBUSADR1;
UINT32 SBUSADR2;
UINT32 IMEIADR1;
UINT32 IMEIADR2;
UINT32 IDEADR1;
UINT32 IDEADR2;
UINT32 SATAADR1;
UINT32 SATAADR2;
UINT32 SATAAHCIADR1;
UINT32 SATAAHCIADR2;
UINT32 IDEVENDOR;
UINT32 SATAVENDOR;
UINT32 SATAAHCIVENDOR;
UINT32 DisplayVendor[4];
UINT16 DisplayID[4];
UINT32 DisplaySubID[4];
UINT16 ArptDID;
//UINT32 PWRBADR;
UINT32 HDAADR1;
UINT32 HDMIADR1;
UINT32 HDMIADR2;
UINT32 USBADR[12];
UINT32 USBADR2[12];
UINT32 USBADR3[12]; /*<-NFORCE_USB*/
UINT32 USBID[12];
UINT32 USB20[12];
UINT32 USB30[12];
UINT32 USB40[12]; /*<-NFORCE_USB*/
UINT32 HDAcodecId=0;
UINT32 HDAlayoutId=0;
UINT32 GfxcodecId[2] = {0, 1};
UINT32 GfxlayoutId[2] = {1, 12};
pci_dt_t Displaydevice[2];
UINTN usb;
struct lpc_device_t
{
UINT32 id;
};
//static
UINT8 dataBuiltin[] = {0x00};
//static
UINT8 dataBuiltin1[] = {0x01};
static struct lpc_device_t lpc_chipset[] =
{
{0x00000000},
//
{0x80862811},
{0x80862815},
{0x808627b9},
{0x808627bd},
{0x80862670},
{0x80868119},
{0x80862916},
{0x80863a18},
{0x80863b00},
{0x80863b01},
{0x80863b02},
{0x80863b09},
{0x10de0aac},
{0x10de0aae},
{0x10de0aaf},
{0x10de0d80},
{0x10de0d81},
{0x10de0d82},
{0x10de0d83},
//SB
{0x80861c42},
{0x80861c44},
{0x80861c4e},
{0x80861c4c},
{0x80861c50},
{0x80861c4a},
{0x80861c46},
{0x80861c5c},
{0x80861c52},
{0x80861c54},
{0x80861c56},
{0x80861c43},
{0x80861c4f},
{0x80861c47},
{0x80861c4b},
{0x80861c49},
{0x80861c41},
{0x80861c4d},
};
struct net_chipsets_t {
UINT32 id;
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CONST CHAR8 *name;
};
static struct net_chipsets_t NetChipsets[] = {
{ 0x00000000, "Unknown" },
// 8169
{ 0x10EC8169, "Realtek 8169/8110 Gigabit Ethernet" },
{ 0x10EC8168, "Realtek 8168/8101E Gigabit Ethernet" },
{ 0x10EC8167, "Realtek 8169/8110 Gigabit Ethernet" },
{ 0x10EC8136, "Realtek 8168/8101E Gigabit Ethernet" },
// 8139
{ 0x10EC8139, "Realtek RTL8139/810x Family Fast Ethernet" },
{ 0x11861300, "Realtek RTL8139/810x Family Fast Ethernet" },
{ 0x11131211, "Realtek RTL8139/810x Family Fast Ethernet" },
// Broadcom 57XX
{ 0x14e41600, "Broadcom 5751 Ethernet" },
{ 0x14e41659, "Broadcom 57XX Ethernet" },
{ 0x14e4165A, "BCM5722 NetXtreme Server Gigabit Ethernet" },
{ 0x14e4166A, "Broadcom 57XX Ethernet" },
{ 0x14e41672, "BCM5754M NetXtreme Gigabit Ethernet" },
{ 0x14e41673, "BCM5755M NetXtreme Gigabit Ethernet" },
{ 0x14e4167A, "BCM5754 NetXtreme Gigabit Ethernet" },
{ 0x14e4167B, "BCM5755 NetXtreme Gigabit Ethernet" },
{ 0x14e41684, "Broadcom 57XX Ethernet" },
{ 0x14e41691, "BCM57788 NetLink (TM) Gigabit Ethernet" },
{ 0x14e41693, "BCM5787M NetLink (TM) Gigabit Ethernet" },
{ 0x14e4169B, "BCM5787 NetLink (TM) Gigabit Ethernet" },
{ 0x14e416B4, "Broadcom 57XX Ethernet" },
{ 0x14e416B5, "BCM57785 Gigabit Ethernet PCIe" },
{ 0x14e41712, "BCM5906 NetLink (TM) Fast Ethernet" },
{ 0x14e41713, "BCM5906M NetLink (TM) Fast Ethernet" },
// Intel 8255x Ethernet
{ 0x80861051, "Intel 8255x Ethernet" },
{ 0x80861050, "Intel 8255x Ethernet" },
{ 0x80861029, "Intel 8255x Ethernet" },
{ 0x80861030, "Intel 8255x Ethernet" },
{ 0x80861209, "Intel 8255x Ethernet" },
{ 0x80861227, "Intel 8255x Ethernet" },
{ 0x80861228, "Intel 8255x Ethernet" },
{ 0x80861229, "Intel 8255x Ethernet" },
{ 0x80861503, "Intel 82579V Gigabit Network Controller" },
{ 0x80862449, "Intel 8255x Ethernet" },
{ 0x80862459, "Intel 8255x Ethernet" },
{ 0x8086245D, "Intel 8255x Ethernet" },
{ 0x80861091, "Intel 8255x Ethernet" },
{ 0x80861060, "Intel 8255x Ethernet" },
// Atheros AR8151 Ethernet
{ 0x19691083, "Qualcomm Atheros AR8151 v2.0 Gigabit Ethernet" },
};
struct ide_chipsets_t {
UINT32 id;
};
static struct ide_chipsets_t ide_chipset[] =
{
// IDE
{0x00000000},
//
{0x8086269e},
{0x808627df},
{0x80862850},
//SATA
{0x80862680},
{0x808627c0},
{0x808627c4},
{0x80862828},
};
//2820? 2825?
/*
struct ahci_chipsets_t {
UINT32 id;
};
static struct ahci_chipsets_t ahci_chipset[] =
{
// SATA AHCI
{0x00000000},
//
{0x80863a22},
{0x80862681},
{0x80862682},
{0x808627c5},
{0x80862825},
{0x80862829},
{0x80863b29},
{0x80863b22},
{0x80863b2f},
{0x80861c02},
{0x80861c03},
{0x10de0ab9},
{0x10de0b88},
};
*/
UINT8 dtgp[] = // Method (DTGP, 5, NotSerialized) ......
{
0x14, 0x3F, 0x44, 0x54, 0x47, 0x50, 0x05, 0xA0,
0x30, 0x93, 0x68, 0x11, 0x13, 0x0A, 0x10, 0xC6,
0xB7, 0xB5, 0xA0, 0x18, 0x13, 0x1C, 0x44, 0xB0,
0xC9, 0xFE, 0x69, 0x5E, 0xAF, 0x94, 0x9B, 0xA0,
0x18, 0x93, 0x69, 0x01, 0xA0, 0x0C, 0x93, 0x6A,
0x00, 0x70, 0x11, 0x03, 0x01, 0x03, 0x6C, 0xA4,
0x01, 0xA0, 0x06, 0x93, 0x6A, 0x01, 0xA4, 0x01,
0x70, 0x11, 0x03, 0x01, 0x00, 0x6C, 0xA4, 0x00
};
UINT8 sbus1[] =
{ // Device (SBUS) _ADR,1F0003 size=E9+2=EB
0x5B, 0x82, 0x49, 0x0E, 0x53, 0x42, 0x55, 0x53, // 00000080 "[.I.SBUS"
0x08, 0x5F, 0x41, 0x44, 0x52, 0x0C, // 00000088 "._ADR."
0x03, 0x00, 0x1F, 0x00, 0x5B, 0x82, 0x4B, 0x05, // 00000090 "....[.K."
0x42, 0x55, 0x53, 0x30, 0x08, 0x5F, 0x43, 0x49, // 00000098 "BUS0._CI"
0x44, 0x0D, 0x73, 0x6D, 0x62, 0x75, 0x73, 0x00, // 000000A0 "D.smbus."
0x08, 0x5F, 0x41, 0x44, 0x52, 0x00, 0x5B, 0x82, // 000000A8 "._ADR.[."
0x41, 0x04, 0x44, 0x56, 0x4C, 0x30, 0x08, 0x5F, // 000000B0 "A.DVL0._"
0x41, 0x44, 0x52, 0x0A, 0x57, 0x08, 0x5F, 0x43, // 000000B8 "ADR.W._C"
0x49, 0x44, 0x0D, 0x64, 0x69, 0x61, 0x67, 0x73, // 000000C0 "ID.diags"
0x76, 0x61, 0x75, 0x6C, 0x74, 0x00, 0x14, 0x22, // 000000C8 "vault..""
0x5F, 0x44, 0x53, 0x4D, 0x04, 0x70, 0x12, 0x0D, // 000000D0 "_DSM.p.."
0x02, 0x0D, 0x61, 0x64, 0x64, 0x72, 0x65, 0x73, // 000000D8 "..addres"
0x73, 0x00, 0x0A, 0x57, 0x60, 0x44, 0x54, 0x47, // 000000E0 "s..W`DTG"
0x50, 0x68, 0x69, 0x6A, 0x6B, 0x71, 0x60, 0xA4, // 000000E8 "Phijkq`."
0x60, 0x14, 0x4B, 0x07, 0x5F, 0x44, 0x53, 0x4D, // 000000F0 "`.K._DSM"
0x04, 0x70, 0x12, 0x45, 0x06, 0x08, 0x0D, 0x62, // 000000F8 ".p.E...b"
0x75, 0x69, 0x6C, 0x74, 0x2D, 0x69, 0x6E, 0x00, // 00000100 "uilt-in."
0x11, 0x03, 0x01, 0x01, 0x0D, 0x64, 0x65, 0x76, // 00000108 ".....dev"
0x69, 0x63, 0x65, 0x2D, 0x69, 0x64, 0x00, 0x11, // 00000110 "ice-id.."
0x07, 0x0A, 0x04, 0x30, 0x3A, 0x00, 0x00, 0x0D, // 00000118 "...0:..."
0x6D, 0x6F, 0x64, 0x65, 0x6C, 0x00, 0x11, 0x1E, // 00000120 "model..."
0x0A, 0x1B, 0x49, 0x6E, 0x74, 0x65, 0x6C, 0x20, // 00000128 "..Intel "
0x38, 0x32, 0x38, 0x30, 0x31, 0x4A, 0x49, 0x20, // 00000130 "82801JI "
0x49, 0x43, 0x48, 0x31, 0x30, 0x20, 0x46, 0x61, // 00000138 "ICH10 Fa"
0x6D, 0x69, 0x6C, 0x79, 0x00, 0x0D, 0x6E, 0x61, // 00000140 "mily..na"
0x6D, 0x65, 0x00, 0x11, 0x14, 0x0A, 0x11, 0x53, // 00000148 "me.....S"
0x4D, 0x42, 0x75, 0x73, 0x20, 0x63, 0x6F, 0x6E, // 00000150 "MBus con"
0x74, 0x72, 0x6F, 0x6C, 0x6C, 0x65, 0x72, 0x00, // 00000158 "troller."
0x60, 0x44, 0x54, 0x47, 0x50, 0x68, 0x69, 0x6A, // 00000160 "`DTGPhij"
0x6B, 0x71, 0x60, 0xA4, 0x60
};
UINT8 bus0[] = {
//size=5B+2=5D
0x5B, 0x82, 0x4B, 0x05, 0x42, 0x55,
0x53, 0x30, 0x08, 0x5F, 0x43, 0x49, 0x44, 0x0D,
0x73, 0x6D, 0x62, 0x75, 0x73, 0x00, 0x08, 0x5F,
0x41, 0x44, 0x52, 0x00, 0x5B, 0x82, 0x41, 0x04,
0x44, 0x56, 0x4C, 0x30, 0x08, 0x5F, 0x41, 0x44,
0x52, 0x0A, 0x57, 0x08, 0x5F, 0x43, 0x49, 0x44,
0x0D, 0x64, 0x69, 0x61, 0x67, 0x73, 0x76, 0x61,
0x75, 0x6C, 0x74, 0x00, 0x14, 0x22, 0x5F, 0x44,
0x53, 0x4D, 0x04, 0x70, 0x12, 0x0D, 0x02, 0x0D,
0x61, 0x64, 0x64, 0x72, 0x65, 0x73, 0x73, 0x00,
0x0A, 0x57, 0x60, 0x44, 0x54, 0x47, 0x50, 0x68,
0x69, 0x6A, 0x6B, 0x71, 0x60, 0xA4, 0x60
};
UINT8 patafix[] = {
/* OperationRegion (IDET, PCI_Config, 0x40, 0x04)
Field (IDET, WordAcc, NoLock, Preserve)
{
M1, 8,
M2, 8,
M3, 8,
M4, 8
}
Method (_INI, 0, NotSerialized)
{
Store (0x07, M1)
Store (0xE3, M2)
Store (Zero, M3)
Store (0xC0, M4)
Return (Zero)
}
*/
0x5B,
0x80, 0x49, 0x44, 0x45, 0x54, 0x02, 0x0A, 0x40, //000001C0 ".IDET..@"
0x0A, 0x04, 0x5B, 0x81, 0x1A, 0x49, 0x44, 0x45, //000001C8 "..[..IDE"
0x54, 0x02, 0x4D, 0x31, 0x5F, 0x5F, 0x08, 0x4D, //000001D0 "T.M1__.M"
0x32, 0x5F, 0x5F, 0x08, 0x4D, 0x33, 0x5F, 0x5F, //000001D8 "2__.M3__"
0x08, 0x4D, 0x34, 0x5F, 0x5F, 0x08, 0x14, 0x23, //000001E0 ".M4__..#"
0x5F, 0x49, 0x4E, 0x49, 0x00, 0x70, 0x0A, 0x07, //000001E8 "_INI.p.."
0x4D, 0x31, 0x5F, 0x5F, 0x70, 0x0A, 0xE3, 0x4D, //000001F0 "M1__p..M"
0x32, 0x5F, 0x5F, 0x70, 0x00, 0x4D, 0x33, 0x5F, //000001F8 "2__p.M3_"
0x5F, 0x70, 0x0A, 0xC0, 0x4D, 0x34, 0x5F, 0x5F, //00000200 "_p..M4__"
0xA4, 0x00 //00000208 ".."
};
UINT8 hpet0[] = {
0x5B, 0x82, 0x3A, 0x48, 0x50, 0x45, 0x54, // Device (HPET)
0x08, 0x5F, 0x48, 0x49, 0x44, 0x0C, 0x41, 0xD0, 0x01, 0x03, // Name (_HID, EisaId ("PNP0103"))
0x08, 0x5F, 0x43, 0x49, 0x44, 0x0C, 0x41, 0xD0, 0x0C, 0x01, // Name (_CID, EisaId ("PNP0C01"))
0x08, 0x5F, 0x53, 0x54, 0x41, 0x0A, 0x0F, // Name (_STA, 0x0F)
0x08, 0x5F, 0x43, 0x52, 0x53, 0x11, 0x14, 0x0A, 0x11, // Name (_CRS, ResourceTemplate ()
0x22, 0x01, 0x09, 0x86, 0x09, 0x00, 0x01, // IRQNoFlags () {0,8,11}
0x00, 0x00, 0xD0, 0xFE, 0x00, 0x04, 0x00, 0x00, // Memory32Fixed (ReadWrite,
0x79, 0x00 // 0xFED00000, 0x00000400 )
/*
0x5B, 0x82, 0x47, 0x04, 0x48, 0x50, 0x45, 0x54, //Device (HPET)
0x08, 0x5F, 0x48, 0x49, 0x44, 0x0C, 0x41, 0xD0, 0x01, 0x03, //Name (_HID, EisaId ("PNP0103"))
0x08, 0x5F, 0x43, 0x49, 0x44, 0x0C, 0x41, 0xD0, 0x0C, 0x01, //Name (_CID, EisaId ("PNP0C01"))
0x08, 0x41, 0x54, 0x54, 0x30, 0x11, 0x14, 0x0A, 0x11, //Name (ATT0, ResourceTemplate ()
0x86, 0x09, 0x00, 0x01, // Memory32Fixed (ReadWrite,
0x00, 0x00, 0xD0, 0xFE, 0x00, 0x04, 0x00, 0x00, // 0xFED00000, 0x00000400, )
0x22, 0x01, 0x09, 0x79, 0x00, // IRQNoFlags () {0,8,11}
// 0x14, 0x09, 0x5F, 0x53, 0x54, 0x41, 0x00, //Method (_STA, 0, NotSerialized)
// 0xA4, 0x0A, 0x0F, // Return (0x0F)
0x08, 0x5F, 0x53, 0x54, 0x41, 0x0A, 0x0F, // Name (_STA, 0x0F)
0x14, 0x0B, 0x5F, 0x43, 0x52, 0x53, 0x00, //Method (_CRS, 0, NotSerialized)
0xA4, 0x41, 0x54, 0x54, 0x30 // Return (ATT0)
*/
};
/*
UINT8 hpet1[] = // Name (_CID, EisaId ("PNP0C01"))
{
0x08, 0x5F, 0x43, 0x49, 0x44, 0x0C, 0x41, 0xD0, 0x0C, 0x01
};
*/
UINT8 wakret[] = { 0xA4, 0x12, 0x04, 0x02, 0x00, 0x00 };
UINT8 wakslp1[] = { 0x5B, 0x80, 0x50, 0x4D, 0x33, 0x30, 0x01 };
UINT8 wakslp2[] = { 0x0A, 0x08, 0x5B, 0x81, 0x0D, 0x50, 0x4D, 0x33, 0x30, 0x01,
0x00, 0x04, 0x53, 0x4C, 0x4D, 0x45, 0x01, 0x70, 0x00, 0x53, 0x4C, 0x4D, 0x45 };
UINT8 waksecur[] = {0xA0, 0x0D, 0x91, 0x95, 0x68, 0x01, 0x94, 0x68, 0x0A, 0x05,
0x70, 0x0A, 0x03, 0x68};
UINT8 pwrb[] = { //? \_SB_PWRB, 0x02
0x86, 0x5C, 0x2E, 0x5F, 0x53, 0x42, 0x5F, 0x50, 0x57, 0x52, 0x42, 0x0A, 0x02
};
UINT8 acpi3[] = { //Name(_HID, "ACPI003")
0x08, 0x5F, 0x48, 0x49, 0x44, 0x0D,
0x41, 0x43, 0x50, 0x49, 0x30, 0x30, 0x30, 0x33, 0x00
};
//Name (_PRW, Package (0x02){0x1C, 0x03}
UINT8 prw1c[] = {
0x08, 0x5F, 0x50, 0x52, 0x57, 0x12, 0x06, 0x02, 0x0A, 0x1C, 0x0A, 0x03
};
UINT8 dtgp_1[] = { // DTGP (Arg0, Arg1, Arg2, Arg3, RefOf (Local0))
// Return (Local0)
0x44, 0x54, 0x47, 0x50, 0x68, 0x69, 0x6A, 0x6B,
0x71, 0x60, 0xA4, 0x60
};
UINT8 pwrbcid[] = {
0x08, 0x5F, 0x43, 0x49, 0x44, 0x0C, 0x41, 0xD0, 0x0C, 0x0E, 0x14,
0x0E, 0x5F, 0x50, 0x52, 0x57, 0x00, 0xA4, 0x12, 0x06, 0x02, 0x0A,
0x0B, 0x0A, 0x04
};
UINT8 pwrbprw[] = {
0x14, 0x0E, 0x5F, 0x50, 0x52, 0x57, 0x00, 0xA4, 0x12, 0x06, 0x02,
0x0A, 0x0B, 0x0A, 0x04
};
UINT8 shutdown0[] = {
0xA0, 0x05, 0x93, 0x68, 0x0A, 0x05, 0xA1, 0x01
};
UINT8 shutdown1[] = {
0xA0, 0x0F, 0x91, 0x91, 0x93, 0x68, 0x0A, 0x03, 0x93, 0x68, 0x0A, 0x04, 0x93, 0x68, 0x0A, 0x05, 0xA1, 0x01
};
UINT8 pnlf[] = {
0x5B, 0x82, 0x2D, 0x50, 0x4E, 0x4C, 0x46, //Device (PNLF)
0x08, 0x5F, 0x48, 0x49, 0x44, 0x0C, 0x06, 0x10, 0x00, 0x02, // Name (_HID, EisaId ("APP0002"))
0x08, 0x5F, 0x43, 0x49, 0x44, // Name (_CID,
0x0D, 0x62, 0x61, 0x63, 0x6B, 0x6C, 0x69, 0x67, 0x68, 0x74, 0x00, // "backlight")
0x08, 0x5F, 0x55, 0x49, 0x44, 0x0A, 0x0A, // Name (_UID, 0x0A)
0x08, 0x5F, 0x53, 0x54, 0x41, 0x0A, 0x0B // Name (_STA, 0x0B)
};
//Scope (_SB.PCI0.LPCB)
UINT8 pnlfLPC[] = {
0x10, 0x3e, 0x2f, 0x03, 0x5f, 0x53, 0x42, 0x5f, 0x50, 0x43, 0x49, 0x30, 0x4c, 0x50, 0x43, 0x42,
0x5b, 0x82, 0x2d, 0x50, 0x4e, 0x4c, 0x46, 0x08, 0x5f, 0x48, 0x49,
0x44, 0x0c, 0x06, 0x10, 0x00, 0x02, 0x08, 0x5f, 0x43, 0x49, 0x44, 0x0d,
0x62, 0x61, 0x63, 0x6b, 0x6c, 0x69, 0x67, 0x68, 0x74, 0x00, 0x08, 0x5f,
0x55, 0x49, 0x44, 0x0a, 0x0a, 0x08, 0x5f, 0x53, 0x54, 0x41, 0x0a, 0x0b
};
UINT8 app2[] = { //Name (_HID, EisaId("APP0002"))
0x08, 0x5F, 0x48, 0x49, 0x44, 0x0C, 0x06, 0x10, 0x00, 0x02
};
UINT8 darwin[] =
{ //addresses shifted by 0x24
0x08, 0x56, 0x45, 0x52, // 00000020 " .. .VER"
0x30, 0x0D, 0x43, 0x6C, 0x6F, 0x76, 0x65, 0x72, // 00000028 "0.Clover"
0x20, 0x61, 0x75, 0x74, 0x6F, 0x70, 0x61, 0x74, // 00000030 " autopat"
0x63, 0x68, 0x65, 0x64, 0x00, 0x08, 0x57, 0x58, // 00000038 "ched..WX"
0x50, 0x31, 0x0D, 0x57, 0x69, 0x6E, 0x64, 0x6F, // 00000040 "P1.Windo"
0x77, 0x73, 0x20, 0x32, 0x30, 0x30, 0x31, 0x00, // 00000048 "ws 2001."
0x14, 0x12, 0x47, 0x45, 0x54, 0x39, 0x02, 0x8C, // 00000050 "..GET9.."
0x68, 0x69, 0x54, 0x43, 0x48, 0x39, 0xA4, 0x54, // 00000058 "hiTCH9.T"
0x43, 0x48, 0x39, 0x14, 0x40, 0x05, 0x53, 0x54, // 00000060 "CH9.@.ST"
0x52, 0x39, 0x02, 0x08, 0x53, 0x54, 0x52, 0x38, // 00000068 "R9..STR8"
0x11, 0x03, 0x0A, 0x50, 0x08, 0x53, 0x54, 0x52, // 00000070 "...P.STR"
0x39, 0x11, 0x03, 0x0A, 0x50, 0x70, 0x68, 0x53, // 00000078 "9...PphS"
0x54, 0x52, 0x38, 0x70, 0x69, 0x53, 0x54, 0x52, // 00000080 "TR8piSTR"
0x39, 0x70, 0x00, 0x60, 0x70, 0x01, 0x61, 0xA2, // 00000088 "9p.`p.a."
0x22, 0x61, 0x70, 0x47, 0x45, 0x54, 0x39, 0x53, // 00000090 ""apGET9S"
0x54, 0x52, 0x38, 0x60, 0x61, 0x70, 0x47, 0x45, // 00000098 "TR8`apGE"
0x54, 0x39, 0x53, 0x54, 0x52, 0x39, 0x60, 0x62, // 000000A0 "T9STR9`b"
0xA0, 0x07, 0x92, 0x93, 0x61, 0x62, 0xA4, 0x00, // 000000A8 "....ab.."
0x75, 0x60, 0xA4, 0x01, 0x14, 0x15, 0x4F, 0x4F, // 000000B0 "u`....OO"
0x53, 0x49, 0x01, 0xA0, 0x0C, 0x53, 0x54, 0x52, // 000000B8 "SI...STR"
0x39, 0x57, 0x58, 0x50, 0x31, 0x68, 0xA4, 0x01, // 000000C0 "9WXP1h.."
0xA4, 0x00 // 000000C8 ".."
};
BOOLEAN CmpNum(UINT8 *dsdt, INT32 i, BOOLEAN Sure)
{
return ((Sure && ((dsdt[i-1] == 0x0A) ||
(dsdt[i-2] == 0x0B) ||
(dsdt[i-4] == 0x0C))) ||
(!Sure && (((dsdt[i-1] >= 0x0A) && (dsdt[i-1] <= 0x0C)) ||
((dsdt[i-2] == 0x0B) || (dsdt[i-2] == 0x0C)) ||
(dsdt[i-4] == 0x0C))));
}
// for HDA from device_inject.c and mark device_inject function
//extern UINT32 HDA_IC_sendVerb(EFI_PCI_IO_PROTOCOL *PciIo, UINT32 codecAdr, UINT32 nodeId, UINT32 verb);
BOOLEAN get_lpc_model(UINT32 id) {
2020-02-17 21:41:09 +01:00
UINTN i;
for (i=1; i< (sizeof(lpc_chipset) / sizeof(lpc_chipset[0])); i++) {
if (lpc_chipset[i].id == id) {
return FALSE;
}
}
return TRUE;
}
BOOLEAN get_ide_model(UINT32 id) {
2020-02-17 21:41:09 +01:00
UINTN i;
for (i=1; i< (sizeof(ide_chipset) / sizeof(ide_chipset[0])); i++) {
if (ide_chipset[i].id == id) {
return FALSE;
}
}
return TRUE;
}
/*
BOOLEAN get_ahci_model(UINT32 id) {
2020-02-17 21:41:09 +01:00
UINTN i;
for (i=1; i< (sizeof(ahci_chipset) / sizeof(ahci_chipset[0])); i++) {
if (ahci_chipset[i].id == id) {
return FALSE;
}
}
return TRUE;
}
*/
2020-02-17 21:41:09 +01:00
CONST CHAR8* get_net_model(UINT32 id) {
UINTN i;
for (i=1; i< (sizeof(NetChipsets) / sizeof(NetChipsets[0])); i++) {
if (NetChipsets[i].id == id) {
return NetChipsets[i].name;
}
}
return NetChipsets[0].name;
}
VOID GetPciADR(IN EFI_DEVICE_PATH_PROTOCOL *DevicePath, OUT UINT32 *Addr1, OUT UINT32 *Addr2, OUT UINT32 *Addr3)
{
PCI_DEVICE_PATH *PciNode;
UINTN PciNodeCount;
EFI_DEVICE_PATH_PROTOCOL *TmpDevicePath = DuplicateDevicePath(DevicePath);
// default to 0
if (Addr1 != NULL) *Addr1 = 0;
if (Addr2 != NULL) *Addr2 = 0xFFFE; //some code we will consider as "non-exists" b/c 0 is meaningful value
// as well as 0xFFFF
if (Addr3 != NULL) *Addr3 = 0xFFFE;
if (!TmpDevicePath) {
return;
}
// sanity check - expecting ACPI path for PciRoot
if (TmpDevicePath->Type != ACPI_DEVICE_PATH && TmpDevicePath->SubType != ACPI_DP) {
FreePool(TmpDevicePath);
return;
}
PciNodeCount = 0;
while (TmpDevicePath && !IsDevicePathEndType(TmpDevicePath)) {
if (TmpDevicePath->Type == HARDWARE_DEVICE_PATH && TmpDevicePath->SubType == HW_PCI_DP) {
PciNodeCount++;
PciNode = (PCI_DEVICE_PATH *)TmpDevicePath;
if (PciNodeCount == 1 && Addr1 != NULL) {
*Addr1 = (PciNode->Device << 16) | PciNode->Function;
} else if (PciNodeCount == 2 && Addr2 != NULL) {
*Addr2 = (PciNode->Device << 16) | PciNode->Function;
} else if (PciNodeCount == 3 && Addr3 != NULL) {
*Addr3 = (PciNode->Device << 16) | PciNode->Function;
} else {
break;
}
}
TmpDevicePath = NextDevicePathNode(TmpDevicePath);
}
return;
}
/* Discussion
Native USB mean for those chipsets IOUSBFamily set some "errata"
for example native 0x1cXX has no such errata */
BOOLEAN NativeUSB(UINT16 DID)
{
UINT16 d = DID & 0xFF00;
return ((d == 0x2600) || (d == 0x2700) || (d == 0x2800) || (d == 0x3a00) || (d == /*NFORCE_USB->*/0x0a00));
}
VOID CheckHardware()
{
EFI_STATUS Status;
EFI_HANDLE *HandleBuffer = NULL;
EFI_HANDLE Handle;
EFI_PCI_IO_PROTOCOL *PciIo;
PCI_TYPE00 Pci;
UINTN HandleCount = 0;
UINTN HandleIndex;
UINTN Segment;
UINTN Bus;
UINTN Device;
UINTN Function;
UINTN display=0;
pci_dt_t PCIdevice;
EFI_DEVICE_PATH_PROTOCOL *DevicePath = NULL;
usb=0;
// Scan PCI handles
Status = gBS->LocateHandleBuffer (
ByProtocol,
&gEfiPciIoProtocolGuid,
NULL,
&HandleCount,
&HandleBuffer
);
if (!EFI_ERROR (Status)) {
// DBG("PciIo handles count=%d\n", HandleCount);
for (HandleIndex = 0; HandleIndex < HandleCount; HandleIndex++) {
Handle = HandleBuffer[HandleIndex];
Status = gBS->HandleProtocol (
Handle,
&gEfiPciIoProtocolGuid,
(VOID **)&PciIo
);
if (!EFI_ERROR (Status)) {
UINT32 deviceid;
/* Read PCI BUS */
PciIo->GetLocation (PciIo, &Segment, &Bus, &Device, &Function);
Status = PciIo->Pci.Read (
PciIo,
EfiPciIoWidthUint32,
0,
sizeof (Pci) / sizeof (UINT32),
&Pci
);
deviceid = Pci.Hdr.DeviceId | (Pci.Hdr.VendorId << 16);
// add for auto patch dsdt get DSDT Device _ADR
PCIdevice.DeviceHandle = Handle;
DevicePath = DevicePathFromHandle (Handle);
if (DevicePath) {
// DBG("Device patch = %ls \n", DevicePathToStr(DevicePath));
//Display ADR
if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_DISPLAY) &&
(Pci.Hdr.ClassCode[1] == PCI_CLASS_DISPLAY_VGA)) {
#if DEBUG_FIX
UINT32 dadr1, dadr2;
#endif
// PCI_IO_DEVICE *PciIoDevice;
GetPciADR(DevicePath, &DisplayADR1[display], &DisplayADR2[display], NULL);
DBG("VideoCard devID=0x%X\n", ((Pci.Hdr.DeviceId << 16) | Pci.Hdr.VendorId));
#if DEBUG_FIX
dadr1 = DisplayADR1[display];
dadr2 = DisplayADR2[display];
DBG("DisplayADR1[%d] = 0x%X, DisplayADR2[%d] = 0x%X\n", display, dadr1, display, dadr2);
#endif
// dadr2 = dadr1; //to avoid warning "unused variable" :(
DisplayVendor[display] = Pci.Hdr.VendorId;
DisplayID[display] = Pci.Hdr.DeviceId;
DisplaySubID[display] = (Pci.Device.SubsystemID << 16) | (Pci.Device.SubsystemVendorID << 0);
// for get display data
Displaydevice[display].DeviceHandle = HandleBuffer[HandleIndex];
Displaydevice[display].dev.addr = (UINT32)PCIADDR(Bus, Device, Function);
Displaydevice[display].vendor_id = Pci.Hdr.VendorId;
Displaydevice[display].device_id = Pci.Hdr.DeviceId;
Displaydevice[display].revision = Pci.Hdr.RevisionID;
Displaydevice[display].subclass = Pci.Hdr.ClassCode[0];
Displaydevice[display].class_id = *((UINT16*)(Pci.Hdr.ClassCode+1));
Displaydevice[display].subsys_id.subsys.vendor_id = Pci.Device.SubsystemVendorID;
Displaydevice[display].subsys_id.subsys.device_id = Pci.Device.SubsystemID;
//
// Detect if PCI Express Device
//
//
// Go through the Capability list
//unused
/* PciIoDevice = PCI_IO_DEVICE_FROM_PCI_IO_THIS (PciIo);
if (PciIoDevice->IsPciExp) {
if (display==0)
Display1PCIE = TRUE;
else
Display2PCIE = TRUE;
}
DBG("Display %d is %sPCIE\n", display, (PciIoDevice->IsPciExp) ? "" :" not"); */
display++;
}
//Network ADR
if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_NETWORK) &&
(Pci.Hdr.ClassCode[1] == PCI_CLASS_NETWORK_ETHERNET)) {
GetPciADR(DevicePath, &NetworkADR1[net_count], &NetworkADR2[net_count], NULL);
// DBG("NetworkADR1 = 0x%X, NetworkADR2 = 0x%X\n", NetworkADR1, NetworkADR2);
// Netmodel = get_net_model(deviceid);
Netmodel[net_count] = get_net_model(deviceid);
net_count++;
}
//Network WiFi ADR
if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_NETWORK) &&
(Pci.Hdr.ClassCode[1] == PCI_CLASS_NETWORK_OTHER)) {
GetPciADR(DevicePath, &ArptADR1, &ArptADR2, NULL);
// DBG("ArptADR1 = 0x%X, ArptADR2 = 0x%X\n", ArptADR1, ArptADR2);
// Netmodel = get_arpt_model(deviceid);
ArptBCM = (Pci.Hdr.VendorId == 0x14e4);
if (ArptBCM) {
DBG("Found Airport BCM at 0x%X, 0x%X\n", ArptADR1, ArptADR2);
}
ArptAtheros = (Pci.Hdr.VendorId == 0x168c);
ArptDID = Pci.Hdr.DeviceId;
if (ArptAtheros) {
DBG("Found Airport Atheros at 0x%X, 0x%X, DeviceID=0x%04X\n", ArptADR1, ArptADR2, ArptDID);
}
}
//Firewire ADR
if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_SERIAL) &&
(Pci.Hdr.ClassCode[1] == PCI_CLASS_SERIAL_FIREWIRE)) {
GetPciADR(DevicePath, &FirewireADR1, &FirewireADR2, NULL);
// DBG("FirewireADR1 = 0x%X, FirewireADR2 = 0x%X\n", FirewireADR1, FirewireADR2);
}
//SBUS ADR
if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_SERIAL) &&
(Pci.Hdr.ClassCode[1] == PCI_CLASS_SERIAL_SMB)) {
GetPciADR(DevicePath, &SBUSADR1, &SBUSADR2, NULL);
// DBG("SBUSADR1 = 0x%X, SBUSADR2 = 0x%X\n", SBUSADR1, SBUSADR2);
}
//IMEI ADR
if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_SCC) &&
(Pci.Hdr.ClassCode[1] == PCI_SUBCLASS_SCC_OTHER)) {
GetPciADR(DevicePath, &IMEIADR1, &IMEIADR2, NULL);
}
//USB
if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_SERIAL) &&
(Pci.Hdr.ClassCode[1] == PCI_CLASS_SERIAL_USB) &&
(Pci.Hdr.ClassCode[0] != 0xFE)) {
UINT16 DID = Pci.Hdr.DeviceId;
USBIntel = (Pci.Hdr.VendorId == 0x8086);
USBNForce = (Pci.Hdr.VendorId == 0x10de);
GetPciADR(DevicePath, &USBADR[usb], &USBADR2[usb], &USBADR3[usb]);
DBG("USBADR[%d] = 0x%X and PCIe = 0x%X\n", usb, USBADR[usb], USBADR2[usb]);
if (USBIDFIX)
{
if (USBADR[usb] == 0x001D0000 && !NativeUSB(DID)) DID = 0x3a34;
if (USBADR[usb] == 0x001D0001 && !NativeUSB(DID)) DID = 0x3a35;
if (USBADR[usb] == 0x001D0002 && !NativeUSB(DID)) DID = 0x3a36;
if (USBADR[usb] == 0x001D0003 && !NativeUSB(DID)) DID = 0x3a37;
if (USBADR[usb] == 0x001A0000 && !NativeUSB(DID)) DID = 0x3a37;
if (USBADR[usb] == 0x001A0001 && !NativeUSB(DID)) DID = 0x3a38;
if (USBADR[usb] == 0x001A0002 && !NativeUSB(DID)) DID = 0x3a39;
if (USBADR[usb] == 0x001D0007 && !NativeUSB(DID)) DID = 0x3a3a;
if (USBADR[usb] == 0x001A0007 && !NativeUSB(DID)) DID = 0x3a3c;
//NFORCE_USB_START
if (USBADR3[usb] == 0x00040000 && !NativeUSB(DID)) DID = 0x0aa5;
if (USBADR3[usb] == 0x00040001 && !NativeUSB(DID)) DID = 0x0aa6;
if (USBADR3[usb] == 0x00060000 && !NativeUSB(DID)) DID = 0x0aa7;
if (USBADR3[usb] == 0x00060001 && !NativeUSB(DID)) DID = 0x0aa9;
//NFORCE_USB_END
}
USBID[usb] = DID;
USB20[usb] = (Pci.Hdr.ClassCode[0] == 0x20)?1:0;
USB30[usb] = (Pci.Hdr.ClassCode[0] == 0x30)?1:0;
USB40[usb] = ((Pci.Hdr.ClassCode[0] == 0x20) && USBNForce)?1:0;
usb++;
}
// HDA and HDMI Audio
if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_MEDIA) &&
((Pci.Hdr.ClassCode[1] == PCI_CLASS_MEDIA_HDA) ||
(Pci.Hdr.ClassCode[1] == PCI_CLASS_MEDIA_AUDIO))) {
UINT32 codecId = 0, layoutId = 0;
if (!IsHDMIAudio(Handle)) {
// if ((Pci.Hdr.VendorId == 0x8086) &&
// ((Pci.Hdr.DeviceId & 0xFF00) != 0x0C00)) { //0x0C0C is HDMI sound
GetPciADR(DevicePath, &HDAADR1, NULL, NULL);
if (gSettings.HDALayoutId > 0) {
// layoutId is specified - use it
layoutId = (UINT32)gSettings.HDALayoutId;
DBG("Audio HDA (addr:0x%X) setting specified layout-id=%d (0x%X)\n", HDAADR1, layoutId, layoutId);
}
HDAFIX = TRUE;
HDAcodecId = codecId;
HDAlayoutId = layoutId;
} else { //HDMI
GetPciADR(DevicePath, &HDMIADR1, &HDMIADR2, NULL);
GFXHDAFIX = TRUE;
}
}
// LPC
if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_BRIDGE) &&
(Pci.Hdr.ClassCode[1] == PCI_CLASS_BRIDGE_ISA)) {
LPCBFIX = get_lpc_model(deviceid);
}
// IDE device
if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_MASS_STORAGE) &&
(Pci.Hdr.ClassCode[1] == PCI_CLASS_MASS_STORAGE_IDE)) {
GetPciADR(DevicePath, &IDEADR1, &IDEADR2, NULL);
// DBG("IDEADR1 = 0x%X, IDEADR2 = 0x%X\n", IDEADR1, IDEADR2);
IDEFIX = get_ide_model(deviceid);
IDEVENDOR = Pci.Hdr.VendorId;
}
// SATA
if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_MASS_STORAGE) &&
(Pci.Hdr.ClassCode[1] == PCI_CLASS_MASS_STORAGE_SATADPA) &&
(Pci.Hdr.ClassCode[0] == 0x00)) {
GetPciADR(DevicePath, &SATAADR1, &SATAADR2, NULL);
// DBG("SATAADR1 = 0x%X, SATAADR2 = 0x%X\n", SATAADR1, SATAADR2);
SATAFIX = get_ide_model(deviceid);
SATAVENDOR = Pci.Hdr.VendorId;
}
// SATA AHCI
if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_MASS_STORAGE) &&
(Pci.Hdr.ClassCode[1] == PCI_CLASS_MASS_STORAGE_SATADPA) &&
(Pci.Hdr.ClassCode[0] == 0x01)) {
GetPciADR(DevicePath, &SATAAHCIADR1, &SATAAHCIADR2, NULL);
// DBG("SATAAHCIADR1 = 0x%X, SATAAHCIADR2 = 0x%X\n", SATAAHCIADR1, SATAAHCIADR2);
// AHCIFIX = get_ahci_model(deviceid);
SATAAHCIVENDOR = Pci.Hdr.VendorId;
}
}
// detected finish
}
}
}
}
UINT8 slash[] = {0x5c, 0};
VOID InsertScore(UINT8* dsdt, UINT32 off2, INTN root)
{
UINT8 NumNames = 0;
UINT32 ind = 0, i;
CHAR8 buf[31];
if (dsdt[off2 + root] == 0x2E) {
NumNames = 2;
off2 += (UINT32)(root + 1);
} else if (dsdt[off2 + root] == 0x2F) {
NumNames = dsdt[off2 + root + 1];
off2 += (UINT32)(root + 2);
} else if (dsdt[off2 + root] != 0x00) {
NumNames = 1;
off2 += (UINT32)root;
}
if (NumNames > 4) {
DBG(" strange NumNames=%d\n", NumNames);
NumNames = 1;
}
NumNames *= 4;
CopyMem(buf + ind, dsdt + off2, NumNames);
ind += NumNames;
// apianti - This generates a memcpy call
/*
for (i = 0; i < NumNames; i++) {
buf[ind++] = dsdt[off2 + i];
}
*/
i = 0;
while (i < 127) {
buf[ind++] = acpi_cpu_score[i];
if (acpi_cpu_score[i] == 0) {
break;
}
i++;
}
CopyMem(acpi_cpu_score, buf, ind);
acpi_cpu_score[ind] = 0;
}
VOID findCPU(UINT8* dsdt, UINT32 length)
{
UINT32 i, k, size;
UINT32 SBSIZE = 0, SBADR = 0;
BOOLEAN SBFound = FALSE;
UINT32 off2, j1;
if (acpi_cpu_score) {
FreePool(acpi_cpu_score);
}
acpi_cpu_score = (__typeof__(acpi_cpu_score))AllocateZeroPool(128);
acpi_cpu_count = 0;
// 5B 83 41 0C 5C 2E 5F 50 52 5F 43 50 55 30 01 10
// 10 00 00 06
//one another kind
/*
5B 82 4D 95 53 43 4B 30 08 5F 48 49 44 0D 41 43
50 49 30 30 30 34 00 08 5F 55 49 44 0D 43 50 55
53 43 4B 30 00 08 53 43 4B 4E 00 08 4C 53 54 41
0A FF 14 28 5F 53 54 41 00 70 0D 43 50 55 53 43
4B 30 00 43 55 55 30 70 50 53 54 41 00 60 7B 60
0A 03 61 70 61 4C 53 54 41 A4 60
5B 83 4A 04 43 30 30 30 00 10 04 00 00 06 08 5F 48 49 44 0D 41
43 50 49 30 30 30 37 00 08 5F 55 49 44 0D 50 43
49 30 2D 43 50 30 30 30 00 08 5F 50 58 4D 00
//
Device (SCK0)
{
Name (_HID, "ACPI0004") // _HID: Hardware ID
Name (_UID, "CPUSCK0") // _UID: Unique ID
Name (SCKN, Zero)
Name (LSTA, 0xFF)
Method (_STA, 0, NotSerialized) // _STA: Status
{
Store ("CPUSCK0", CUU0)
Store (PSTA (Zero), Local0)
And (Local0, 0x03, Local1)
Store (Local1, LSTA)
Return (Local0)
}
Processor (C000, 0x00, 0x00000410, 0x06)
{
Name (_HID, "ACPI0007") // _HID: Hardware ID
Name (_UID, "PCI0-CP000") // _UID: Unique ID
Name (_PXM, Zero) // _PXM: Device Proximity
*/
for (i = 0; i < length - 20; i++) {
if (dsdt[i] == 0x5B && dsdt[i + 1] == 0x83) { // ProcessorOP
UINT32 j;
UINT32 offset = i + 3 + (dsdt[i + 2] >> 6); // name
BOOLEAN add_name = TRUE;
if (acpi_cpu_count == 0) { //only first time in the cycle
CHAR8 c1 = dsdt[offset + 1];
// I want to determine a scope of PR
//1. if name begin with \\ this is with score
//2. else find outer device or scope until \\ is found
//3. add new name everytime is found
// DBG("first CPU found at %X offset %X\n", i, offset);
if (dsdt[offset] == '\\') {
// "\_PR.CPU0"
j = 1;
if (c1 == 0x2E) {
j = 2;
} else if (c1 == 0x2F) {
c1 = dsdt[offset + 2];
j = 2 + (c1 - 2) * 4;
}
CopyMem(acpi_cpu_score, dsdt + offset + j, 4);
// DBG("slash found\n");
} else {
//--------
j = i - 1; //usually adr = &5B - 1 = sizefield - 3
while (j > 0x24) { //find devices that previous to adr
//check device
k = j + 2;
if ((dsdt[j] == 0x5B) && (dsdt[j + 1] == 0x82) &&
!CmpNum(dsdt, j, TRUE)) { //device candidate
// DBG("device candidate at %X\n", j);
size = get_size(dsdt, k);
if (size) {
if (k + size > i + 3) { //Yes - it is outer
off2 = j + 3 + (dsdt[j + 2] >> 6);
if (dsdt[off2] == '\\') {
// "\_SB.SCL0"
InsertScore(dsdt, off2, 1);
// DBG("acpi_cpu_score calculated as %s\n", acpi_cpu_score);
break;
} else {
InsertScore(dsdt, off2, 0);
// DBG("device inserted in acpi_cpu_score %s\n", acpi_cpu_score);
}
} //else not an outer device
} //else wrong size field - not a device
} //else not a device
// check scope
// a problem 45 43 4F 4E 08 10 84 10 05 5F 53 42 5F
SBSIZE = 0;
if ((dsdt[j] == '_' && dsdt[j + 1] == 'S' &&
dsdt[j + 2] == 'B' && dsdt[j + 3] == '_') ||
(dsdt[j] == '_' && dsdt[j + 1] == 'P' &&
dsdt[j + 2] == 'R' && dsdt[j + 3] == '_')) {
// DBG("score candidate at %X\n", j);
for (j1=0; j1 < 10; j1++) {
if (dsdt[j - j1] != 0x10) {
continue;
}
if (!CmpNum(dsdt, j - j1, TRUE)) {
SBADR = j - j1 + 1;
SBSIZE = get_size(dsdt, SBADR);
// DBG("found Scope(\\_SB) address = 0x%08X size = 0x%08X\n", SBADR, SBSIZE);
if ((SBSIZE != 0) && (SBSIZE < length)) { //if zero or too large then search more
//if found
k = SBADR - 6;
if ((SBADR + SBSIZE) > i + 4) { //Yes - it is outer
SBFound = TRUE;
break; //SB found
} //else not an outer scope
}
}
}
} //else not a scope
if (SBFound) {
InsertScore(dsdt, j, 0);
// DBG("score inserted in acpi_cpu_score %s\n", acpi_cpu_score);
break;
}
j = k - 3; //if found then search again from found
} //while j
//--------
}
}
for (j = 0; j < 4; j++) {
CHAR8 c = dsdt[offset + j];
CHAR8 c1 = dsdt[offset + j + 1];
if(c == '\\') {
offset += 5;
if (c1 == 0x2E) {
offset++;
} else if (c1 == 0x2F) {
c1 = dsdt[offset + j + 2];
offset += 2 + (c1 - 2) * 4;
}
c = dsdt[offset + j];
}
if (!(IS_UPPER(c) || IS_DIGIT(c) || c == '_')) {
add_name = FALSE;
DBG("Invalid character found in ProcessorOP 0x%X!\n", c);
break;
}
}
if (add_name) {
acpi_cpu_name[acpi_cpu_count] = (__typeof_am__(acpi_cpu_name[acpi_cpu_count]))AllocateZeroPool(5);
CopyMem(acpi_cpu_name[acpi_cpu_count], dsdt+offset, 4);
acpi_cpu_processor_id[acpi_cpu_count] = dsdt[offset + 4];
i = offset + 5;
//if (acpi_cpu_count == 0)
// acpi_cpu_p_blk = dsdt[i] | (dsdt[i+1] << 8);
if (acpi_cpu_count == 0) {
DBG("Found ACPI CPU: %s ", acpi_cpu_name[acpi_cpu_count]);
} else {
DBG("| %s ", acpi_cpu_name[acpi_cpu_count]);
}
if (++acpi_cpu_count == acpi_cpu_max)
break;
}
}
}
DBG(", within the score: %s\n", acpi_cpu_score);
if (!acpi_cpu_count) {
for (i=0; i < acpi_cpu_max; i++) {
acpi_cpu_name[i] = (__typeof_am__(acpi_cpu_name[i]))AllocateZeroPool(5);
AsciiSPrint(acpi_cpu_name[i], 5, "CPU%1x", i);
acpi_cpu_processor_id[i] = (UINT8)(i & 0x7F);
}
}
return;
}
// start => move data start address
// offset => data move how many byte
// len => initial length of the buffer
// return final length of the buffer
// we suppose that buffer allocation is more then len+offset
UINT32 move_data(UINT32 start, UINT8* buffer, UINT32 len, INT32 offset)
{
UINT32 i;
if (offset<0) {
for (i=start; i<len+offset; i++) {
buffer[i] = buffer[i-offset];
}
}
else if (offset>0 && len >=1) { // data move to back
for (i=len-1; i>=start; i--) {
buffer[i+offset] = buffer[i];
}
}
return len + offset;
}
UINT32 get_size(UINT8* Buffer, UINT32 adr)
{
UINT32 temp;
temp = Buffer[adr] & 0xF0; //keep bits 0x30 to check if this is valid size field
if(temp <= 0x30) { // 0
temp = Buffer[adr];
}
else if(temp == 0x40) { // 4
temp = (Buffer[adr] - 0x40) << 0|
Buffer[adr+1] << 4;
}
else if(temp == 0x80) { // 8
temp = (Buffer[adr] - 0x80) << 0|
Buffer[adr+1] << 4|
Buffer[adr+2] << 12;
}
else if(temp == 0xC0) { // C
temp = (Buffer[adr] - 0xC0) << 0|
Buffer[adr+1] << 4|
Buffer[adr+2] << 12|
Buffer[adr+3] << 20;
}
else {
// DBG("wrong pointer to size field at %X\n", adr);
return 0;
}
return temp;
}
//return 1 if new size is two bytes else 0
UINT32 write_offset(UINT32 adr, UINT8* buffer, UINT32 len, INT32 offset)
{
UINT32 i, shift = 0;
UINT32 size = offset + 1;
if (size >= 0x3F) {
for (i=len; i>adr; i--) {
buffer[i+1] = buffer[i];
}
shift = 1;
size += 1;
}
aml_write_size(size, (CHAR8 *)buffer, adr);
return shift;
}
/*
adr - a place to write new size. Size of some object.
buffer - the binary aml codes array
len - its length
sizeoffset - how much the object increased in size
return address shift from original +/- n from outers
When we increase the object size there is a chance that new size field +1
so out devices should also be corrected +1 and this may lead to new shift
*/
//Slice - I excluded check (oldsize <= 0x0fffff && size > 0x0fffff)
//because I think size of DSDT will never be 1Mb
INT32 write_size(UINT32 adr, UINT8* buffer, UINT32 len, INT32 sizeoffset)
{
UINT32 size, oldsize;
INT32 offset = 0;
oldsize = get_size(buffer, adr);
if (!oldsize) {
return 0; //wrong address, will not write here
}
size = oldsize + sizeoffset;
// data move to back
if (oldsize <= 0x3f && size > 0x0fff) {
offset = 2;
} else if ((oldsize <= 0x3f && size > 0x3f) || (oldsize<=0x0fff && size > 0x0fff)) {
offset = 1;
} // data move to front
else if ((size <= 0x3f && oldsize > 0x3f) || (size<=0x0fff && oldsize > 0x0fff)) {
offset = -1;
} else if (oldsize > 0x0fff && size <= 0x3f) {
offset = -2;
}
len = move_data(adr, buffer, len, offset);
size += offset;
aml_write_size(size, (CHAR8 *)buffer, adr); //reuse existing codes
return offset;
}
2020-02-17 21:41:09 +01:00
INT32 FindName(UINT8 *dsdt, INT32 len, CONST CHAR8* name)
{
INT32 i;
for (i = 0; len >= 5 && i < len-5; i++) {
if ((dsdt[i] == 0x08) && (dsdt[i+1] == name[0]) &&
(dsdt[i+2] == name[1]) && (dsdt[i+3] == name[2]) &&
(dsdt[i+4] == name[3])) {
return i+1;
}
}
return 0;
}
BOOLEAN GetName(UINT8 *dsdt, INT32 adr, OUT CHAR8* name, OUT INTN *shift)
{
INT32 i;
INT32 j = (dsdt[adr] == 0x5C)?1:0; //now we accept \NAME
if (!name) {
return FALSE;
}
for (i = adr + j; i < adr + j + 4; i++) {
if ((dsdt[i] < 0x2F) ||
((dsdt[i] > 0x39) && (dsdt[i] < 0x41)) ||
((dsdt[i] > 0x5A) && (dsdt[i] != 0x5F))) {
return FALSE;
}
name[i - adr - j] = dsdt[i];
}
name[4] = 0;
if (shift) {
*shift = j;
}
return TRUE;
}
// if (CmpAdr(dsdt, j, NetworkADR1))
// Name (_ADR, 0x90000)
BOOLEAN CmpAdr (UINT8 *dsdt, UINT32 j, UINT32 PciAdr)
{
// Name (_ADR, 0x001f0001)
return (BOOLEAN)
((dsdt[j + 4] == 0x08) &&
(dsdt[j + 5] == 0x5F) &&
(dsdt[j + 6] == 0x41) &&
(dsdt[j + 7] == 0x44) &&
(dsdt[j + 8] == 0x52) &&
(//--------------------
((dsdt[j + 9] == 0x0C) &&
(dsdt[j + 10] == ((PciAdr & 0x000000ff) >> 0)) &&
(dsdt[j + 11] == ((PciAdr & 0x0000ff00) >> 8)) &&
(dsdt[j + 12] == ((PciAdr & 0x00ff0000) >> 16)) &&
(dsdt[j + 13] == ((PciAdr & 0xff000000) >> 24))
) ||
//--------------------
((dsdt[j + 9] == 0x0B) &&
(dsdt[j + 10] == ((PciAdr & 0x000000ff) >> 0)) &&
(dsdt[j + 11] == ((PciAdr & 0x0000ff00) >> 8)) &&
(PciAdr < 0x10000)
) ||
//-----------------------
((dsdt[j + 9] == 0x0A) &&
(dsdt[j + 10] == (PciAdr & 0x000000ff)) &&
(PciAdr < 0x100)
) ||
//-----------------
((dsdt[j + 9] == 0x00) && (PciAdr == 0)) ||
//------------------
((dsdt[j + 9] == 0x01) && (PciAdr == 1))
)
);
}
BOOLEAN CmpPNP (UINT8 *dsdt, UINT32 j, UINT16 PNP)
{
// Name (_HID, EisaId ("PNP0C0F")) for PNP=0x0C0F BigEndian
if (PNP == 0) {
return (BOOLEAN)
((dsdt[j + 0] == 0x08) &&
(dsdt[j + 1] == 0x5F) &&
(dsdt[j + 2] == 0x48) &&
(dsdt[j + 3] == 0x49) &&
(dsdt[j + 4] == 0x44) &&
(dsdt[j + 5] == 0x0B) &&
(dsdt[j + 6] == 0x41) &&
(dsdt[j + 7] == 0xD0));
}
return (BOOLEAN)
((dsdt[j + 0] == 0x08) &&
(dsdt[j + 1] == 0x5F) &&
(dsdt[j + 2] == 0x48) &&
(dsdt[j + 3] == 0x49) &&
(dsdt[j + 4] == 0x44) &&
(dsdt[j + 5] == 0x0C) &&
(dsdt[j + 6] == 0x41) &&
(dsdt[j + 7] == 0xD0) &&
(dsdt[j + 8] == ((PNP & 0xff00) >> 8)) &&
(dsdt[j + 9] == ((PNP & 0x00ff) >> 0)));
}
INT32 CmpDev(UINT8 *dsdt, UINT32 i, UINT8 *Name)
{
if ((dsdt[i+0] == Name[0]) && (dsdt[i+1] == Name[1]) &&
(dsdt[i+2] == Name[2]) && (dsdt[i+3] == Name[3]) &&
(((dsdt[i-2] == 0x82) && (dsdt[i-3] == 0x5B) && (dsdt[i-1] < 0x40)) ||
((dsdt[i-3] == 0x82) && (dsdt[i-4] == 0x5B) && ((dsdt[i-2] & 0xF0) == 0x40)) ||
((dsdt[i-4] == 0x82) && (dsdt[i-5] == 0x5B) && ((dsdt[i-3] & 0xF0) == 0x80)))
) {
if (dsdt[i-5] == 0x5B) {
return i - 3;
} else if (dsdt[i-4] == 0x5B){
return i - 2;
} else {
return i - 1;
}
}
return 0;
}
//the procedure can find BIN array UNSIGNED CHAR8 sizeof N inside part of large array "dsdt" size of len
// return position or -1 if not found
INT32 FindBin (UINT8 *dsdt, UINT32 len, UINT8* bin, UINT32 N)
{
UINT32 i, j;
BOOLEAN eq;
for (i=0; len >= N && i < len - N; i++) {
eq = TRUE;
for (j=0; j<N; j++) {
if (dsdt[i+j] != bin[j]) {
eq = FALSE;
break;
}
}
if (eq) {
return (INT32)i;
}
}
return -1;
}
//if (!FindMethod(dsdt, len, "DTGP"))
// return address of size field. Assume size not more then 0x0FFF = 4095 bytes
//assuming only short methods
2020-02-17 21:41:09 +01:00
UINT32 FindMethod (UINT8 *dsdt, UINT32 len, CONST CHAR8* Name)
{
UINT32 i;
for (i = 0; len >= 7 && i < len - 7; i++) {
if (((dsdt[i] == 0x14) || (dsdt[i+1] == 0x14) || (i>0 && dsdt[i-1] == 0x14)) &&
(dsdt[i+3] == Name[0]) && (dsdt[i+4] == Name[1]) &&
(dsdt[i+5] == Name[2]) && (dsdt[i+6] == Name[3])
){
if (i>0 && dsdt[i-1] == 0x14) return i;
return (dsdt[i+1] == 0x14)?(i+2):(i+1); //pointer to size field
}
}
return 0;
}
//this procedure corrects size of outer method. Embedded methods is not proposed
// adr - a place of changes
// shift - a size of changes
UINT32 CorrectOuterMethod (UINT8 *dsdt, UINT32 len, UINT32 adr, INT32 shift)
{
INT32 i, k;
UINT32 size = 0;
INT32 offset = 0;
// INTN NameShift;
CHAR8 Name[5];
if (shift == 0) {
return len;
}
i = adr; //usually adr = @5B - 1 = sizefield - 3
while (i-- > 0x20) { //find method that previous to adr
k = i + 1;
if ((dsdt[i] == 0x14) && !CmpNum(dsdt, i, FALSE)) { //method candidate
size = get_size(dsdt, k);
if (!size) {
continue;
}
if (((size <= 0x3F) && !GetName(dsdt, k+1, &Name[0], NULL)) ||
((size > 0x3F) && (size <= 0xFFF) && !GetName(dsdt, k+2, &Name[0], NULL)) ||
((size > 0xFFF) && !GetName(dsdt, k+3, &Name[0], NULL))) {
DBG("method found, size=0x%X but name is not\n", size);
continue;
}
if ((k+size) > adr+4) { //Yes - it is outer
DBG("found outer method %s begin=%X end=%X\n", Name, k, k+size);
offset = write_size(k, dsdt, len, shift); //size corrected to sizeoffset at address j
// shift += offset;
len += offset;
} //else not an outer method
break;
}
}
return len;
}
//return final length of dsdt
UINT32 CorrectOuters (UINT8 *dsdt, UINT32 len, UINT32 adr, INT32 shift)
{
INT32 i, k;
INT32 j;
INT32 size = 0;
INT32 offset = 0;
// UINT32 SBSIZE = 0, SBADR = 0;
BOOLEAN SBFound = FALSE;
if (shift == 0) {
return len;
}
i = adr; //usually adr = @5B - 1 = sizefield - 3
while (i > 0x20) { //find devices that previous to adr
//check device
k = 0;
if ((dsdt[i] == 0x5B) && (dsdt[i+1] == 0x82) && !CmpNum(dsdt, i, TRUE)) { //device candidate
k = i + 2;
} else if ((dsdt[i] == 0x10) && //looks like Scope
(dsdt[i-1] != 0xA0) && //this is If()
(dsdt[i-1] != 0xA1) && //this is Else()
(dsdt[i-1] != 0xA2) && //this is While()
!CmpNum(dsdt, i, TRUE)) { //device scope like Scope (_PCI)
//additional check for Field
// a problem with fields 52 4D 53 33 10 41 4D 45 4D
// 1. Search outer filed
// 2. check the size of the field
// 3. compare if we are in the filed
j = i - 1;
SBFound = TRUE;
while (j > 0x20) {
if (((dsdt[j - 1] == 0x5B) && (dsdt[j] == 0x81)) ||
((dsdt[j - 1] == 0x5B) && (dsdt[j] == 0x82)) ||
((dsdt[j - 1] == 0x5B) && (dsdt[j] == 0x86))) { //we found a Field() or IndexField before the 0x10 will check what is it
size = (INT32)get_size(dsdt, j + 1); // if it is not a size then size = 0
if (j + size >= i) {
// it is inside a Field, skip it
SBFound = FALSE;
}
break; // other field so we stop search
}
j--;
}
if (SBFound) {
k = i + 1;
}
}
if ( k != 0) {
size = (INT32)get_size(dsdt, k);
if (size) {
if ((k + size) > (INT32)adr+4) { //Yes - it is outer
// DBG("found outer device begin=%X end=%X\n", k, k+size);
offset = write_size(k, dsdt, len, shift); //size corrected to sizeoffset at address j
shift += offset;
len += offset;
} //else not an outer device
} //else wrong size field - not a device
} //else not a device
// check scope _SB_
// a problem 45 43 4F 4E 08 10 84 10 05 5F 53 42 5F
/* SBSIZE = 0;
if (dsdt[i] == '_' && dsdt[i+1] == 'S' && dsdt[i+2] == 'B' && dsdt[i+3] == '_') {
for (j=0; j<10; j++) {
if (dsdt[i-j] != 0x10) {
continue;
}
if (!CmpNum(dsdt, i-j, TRUE)) {
SBADR = i-j+1;
SBSIZE = get_size(dsdt, SBADR);
// DBG("found Scope(\\_SB) address = 0x%08X size = 0x%08X\n", SBADR, SBSIZE);
if ((SBSIZE != 0) && (SBSIZE < len)) { //if zero or too large then search more
//if found
k = SBADR - 6;
if ((SBADR + SBSIZE) > adr+4) { //Yes - it is outer
// DBG("found outer scope begin=%X end=%X\n", SBADR, SBADR+SBSIZE);
offset = write_size(SBADR, dsdt, len, shift);
shift += offset;
len += offset;
SBFound = TRUE;
break; //SB found
} //else not an outer scope
}
}
}
} //else not a scope
if (SBFound) {
break;
} */
if (k == 0) {
i--;
} else {
i = k - 3; //if found then search again from found
}
}
return len;
}
//ReplaceName(dsdt, len, "AZAL", "HDEF");
2020-02-17 21:41:09 +01:00
INTN ReplaceName(UINT8 *dsdt, UINT32 len, CONST CHAR8 *OldName, CONST CHAR8 *NewName)
{
UINTN i;
INTN j = 0;
for (i = 0; len >= 4 && i < len - 4; i++) {
if ((dsdt[i+0] == NewName[0]) && (dsdt[i+1] == NewName[1]) &&
(dsdt[i+2] == NewName[2]) && (dsdt[i+3] == NewName[3])) {
if (OldName) {
MsgLog("NewName %s already present, renaming impossible\n", NewName);
} else {
DBG("name %s present at %X\n", NewName, i);
}
return -1;
}
}
if (!OldName) {
return 0;
}
for (i = 0; len >= 4 && i < len - 4; i++) {
if ((dsdt[i+0] == OldName[0]) && (dsdt[i+1] == OldName[1]) &&
(dsdt[i+2] == OldName[2]) && (dsdt[i+3] == OldName[3])) {
MsgLog("Name %s present at 0x%llX, renaming to %s\n", OldName, i, NewName);
dsdt[i+0] = NewName[0];
dsdt[i+1] = NewName[1];
dsdt[i+2] = NewName[2];
dsdt[i+3] = NewName[3];
j++;
}
}
return j; //number of replacement
}
//the procedure search nearest "Device" code before given address
//should restrict the search by 6 bytes... OK, 10, .. until dsdt begin
//hmmm? will check device name
UINT32 devFind(UINT8 *dsdt, UINT32 address)
{
UINT32 k = address;
INT32 size = 0;
while (k > 30) {
k--;
if (dsdt[k] == 0x82 && dsdt[k-1] == 0x5B) {
size = get_size(dsdt, k+1);
if (!size) {
continue;
}
if ((k + size + 1) > address) {
return (k+1); //pointer to size
} //else continue
}
}
MsgLog("Device definition before adr=%X not found\n", address);
return 0; //impossible value for fool proof
}
BOOLEAN CustProperties(AML_CHUNK* pack, UINT32 Dev)
{
UINTN i;
BOOLEAN Injected = FALSE;
if (gSettings.NrAddProperties == 0xFFFE) {
return FALSE; // not do this for Arbitrary properties?
}
for (i = 0; i < gSettings.NrAddProperties; i++) {
if (gSettings.AddProperties[i].Device != Dev) {
continue;
}
Injected = TRUE;
if (!gSettings.AddProperties[i].MenuItem.BValue) {
//DBG(" disabled property Key: %s, len: %d\n", gSettings.AddProperties[i].Key, gSettings.AddProperties[i].ValueLen);
} else {
aml_add_string(pack, gSettings.AddProperties[i].Key);
aml_add_byte_buffer(pack, gSettings.AddProperties[i].Value,
(UINT32)gSettings.AddProperties[i].ValueLen);
//DBG(" added property Key: %s, len: %d\n", gSettings.AddProperties[i].Key, gSettings.AddProperties[i].ValueLen);
}
}
return Injected;
}
//len = DeleteDevice("AZAL", dsdt, len);
2020-02-17 21:41:09 +01:00
UINT32 DeleteDevice(CONST CHAR8 *Name, UINT8 *dsdt, UINT32 len)
{
UINT32 i, j;
INT32 size = 0, sizeoffset;
MsgLog(" deleting device %s\n", Name);
for (i=20; i<len; i++) {
j = CmpDev(dsdt, i, (UINT8*)Name);
if (j != 0) {
size = get_size(dsdt, j);
if (!size) {
continue;
}
sizeoffset = - 2 - size;
len = move_data(j-2, dsdt, len, sizeoffset);
//to correct outers we have to calculate offset
len = CorrectOuters(dsdt, len, j-3, sizeoffset);
break;
}
}
return len;
}
UINT32 GetPciDevice(UINT8 *dsdt, UINT32 len)
{
UINT32 i;
UINT32 PCIADR = 0, PCISIZE = 0;
for (i=20; i<len; i++) {
// Find Device PCI0 // PNP0A03
if (CmpPNP(dsdt, i, 0x0A03)) {
PCIADR = devFind(dsdt, i);
if (!PCIADR) {
continue;
}
PCISIZE = get_size(dsdt, PCIADR);
if (PCISIZE) {
break;
}
} // End find
}
if (!PCISIZE) {
for (i=20; i<len; i++) {
// Find Device PCIE // PNP0A08
if (CmpPNP(dsdt, i, 0x0A08)) {
PCIADR = devFind(dsdt, i);
if (!PCIADR) {
continue;
}
PCISIZE = get_size(dsdt, PCIADR);
if (PCISIZE) {
break;
}
} // End find
}
}
if (PCISIZE)
return PCIADR;
return 0;
}
// Find PCIRootUID and all need Fix Device
VOID findPciRoot (UINT8 *dsdt, UINT32 len)
{
UINTN j;
UINT32 PCIADR, PCISIZE = 0;
//initialising
NetworkName = FALSE;
DisplayName1 = FALSE;
DisplayName2 = FALSE;
FirewireName = FALSE;
ArptName = FALSE;
XhciName = FALSE;
PCIADR = GetPciDevice(dsdt, len);
if (PCIADR) {
PCISIZE = get_size(dsdt, PCIADR);
}
//sample
/*
5B 82 8A F1 05 50 43 49 30 Device (PCI0) {
08 5F 48 49 44 0C 41 D0 0A 08 Name (_HID, EisaId ("PNP0A08"))
08 5F 43 49 44 0C 41 D0 0A 03 Name (_CID, EisaId ("PNP0A03"))
08 5F 41 44 52 00 Name (_ADR, Zero)
14 09 5E 42 4E 30 30 00 A4 00 Method (^BN00, 0, NotSerialized) {Return (Zero)}
14 0B 5F 42 42 4E 00 A4 42 4E 30 30 Method (_BBN, 0, NotSerialized) {Return (BN00 ())}
08 5F 55 49 44 00 Name (_UID, Zero)
14 16 5F 50 52 54 00 Method (_PRT, 0, NotSerialized)
*/
if (PCISIZE > 0) {
// find PCIRootUID
for (j=PCIADR; j<PCIADR+64; j++) {
if (dsdt[j] == '_' && dsdt[j+1] == 'U' && dsdt[j+2] == 'I' && dsdt[j+3] == 'D') {
// Slice - I want to set root to zero instead of keeping original value
if (dsdt[j+4] == 0x0A)
dsdt[j+5] = 0; //AML_BYTE_PREFIX followed by a number
else
dsdt[j+4] = 0; //any other will be considered as ONE or WRONG, replace to ZERO
break;
}
}
} else {
MsgLog("Warning! PCI root is not found!");
}
}
// read device name, replace to ADP1
//check for
/* Name (_PRW, Package (0x02)
{
0x1C,
0x03
}) */
//if absent - add it
/*
5B 82 4B 04 41 44 50 31 //device (ADP1)
08 5F 48 49 44 0D // name (_HID.
41 43 50 49 30 30 30 33 00 // ACPI0003
08 5F 50 52 57 12 06 02 0A 1C 0A 03 //.._PRW..
*/
UINT32 FixADP1 (UINT8* dsdt, UINT32 len)
{
UINT32 i, j;
UINT32 adr, size;
INT32 sizeoffset, shift;
CHAR8 Name[4];
DBG("Start ADP1 fix\n");
shift = FindBin(dsdt, len, (UINT8*)acpi3, sizeof(acpi3));
if (shift < 0) {
// not found - create new one or do nothing
MsgLog("no device(AC) exists\n");
return len;
}
adr = devFind(dsdt, (UINT32)shift);
if (!adr) {
return len;
}
size = get_size(dsdt, adr);
//check name and replace
if (size < 0x40) {
j = adr + 1;
} else {
j = adr + 2;
}
for (i=0; i<4; i++) {
Name[i] = dsdt[j+i];
}
ReplaceName(dsdt, len, Name, "ADP1");
//find PRW
if(FindBin(dsdt+adr, size, (UINT8*)prw1c, 8) >= 0){
DBG("_prw is present\n");
return len;
}
j = adr + size;
sizeoffset = sizeof(prw1c);
len = move_data(j, dsdt, len, sizeoffset);
CopyMem(dsdt + j, prw1c, sizeoffset);
shift = write_size(adr, dsdt, len, sizeoffset);
sizeoffset += shift;
len += shift;
len = CorrectOuters(dsdt, len, adr - 3, sizeoffset);
return len;
}
UINT32 FixAny (UINT8* dsdt, UINT32 len, UINT8* ToFind, UINT32 LenTF, UINT8* ToReplace, UINT32 LenTR)
{
INT32 sizeoffset, adr;
UINT32 i;
BOOLEAN found = FALSE;
if (!ToFind || !LenTF || !LenTR) {
DBG(" invalid patches!\n");
return len;
}
MsgLog(" pattern %02X%02X%02X%02X,", ToFind[0], ToFind[1], ToFind[2], ToFind[3]);
if ((LenTF + sizeof(EFI_ACPI_DESCRIPTION_HEADER)) > len) {
MsgLog(" the patch is too large!\n");
return len;
}
sizeoffset = LenTR - LenTF;
for (i = 20; i < len; ) {
adr = FindBin(dsdt + i, len - i, ToFind, LenTF);
if (adr < 0) {
if (found) {
MsgLog(" ]\n");
} else {
MsgLog(" bin not found / already patched!\n");
}
return len;
}
if (!found) {
MsgLog(" patched at: [");
}
MsgLog(" (%X)", adr);
found = TRUE;
len = move_data(adr + i, dsdt, len, sizeoffset);
if ((LenTR > 0) && (ToReplace != NULL)) {
CopyMem(dsdt + adr + i, ToReplace, LenTR);
}
len = CorrectOuterMethod(dsdt, len, adr + i - 2, sizeoffset);
len = CorrectOuters(dsdt, len, adr + i - 3, sizeoffset);
i += adr + LenTR;
}
MsgLog(" ]\n"); //should not be here
return len;
}
//new method. by goodwin_c
UINT32 FixRenameByBridge2 (UINT8* dsdt, UINT32 len, CHAR8* TgtBrgName, UINT8* ToFind, UINT32 LenTF, UINT8* ToReplace, UINT32 LenTR)
{
INT32 adr;
BOOLEAN found = FALSE;
UINT32 i, k;
UINT32 BrdADR = 0, BridgeSize;
UINT32 PCIADR, PCISIZE = 0;
if (!ToFind || !LenTF || !LenTR) {
DBG(" invalid patches!\n");
return len;
}
if (LenTF != LenTR) {
DBG(" find/replace different size!\n");
return len;
}
DBG(" pattern %02X%02X%02X%02X,", ToFind[0], ToFind[1], ToFind[2], ToFind[3]);
if ((LenTF + sizeof(EFI_ACPI_DESCRIPTION_HEADER)) > len) {
DBG(" the patch is too large!\n");
return len;
}
PCIADR = GetPciDevice(dsdt, len);
if (PCIADR) {
PCISIZE = get_size(dsdt, PCIADR);
}
if (!PCISIZE) return len; //what is the bad DSDT ?!
DBG("Start ByBridge Rename Fix\n");
for (i=0x20; len >= 10 && i < len - 10; i++) {
if (CmpDev(dsdt, i, (UINT8*)TgtBrgName)) {
BrdADR = devFind(dsdt, i);
if (!BrdADR) {
continue;
}
BridgeSize = get_size(dsdt, BrdADR);
if(!BridgeSize) continue;
if(BridgeSize <= LenTF) continue;
k = 0;
found = FALSE;
while (k <= 100) {
adr = FindBin(dsdt + BrdADR, BridgeSize, ToFind, LenTF);
if (adr < 0) {
if (found) {
DBG(" ]\n");
} else {
DBG(" bin not found / already patched!\n");
}
return len;
}
if (!found) {
DBG(" patched at: [");
}
DBG(" (%X)", adr);
found = TRUE;
if ((LenTR > 0) && (ToReplace != NULL)) {
CopyMem(dsdt + BrdADR + adr, ToReplace, LenTR);
}
k++;
}
}
}
DBG(" ]\n");
return len;
}
UINT32 FIXDarwin (UINT8* dsdt, UINT32 len)
{
CONST UINT32 adr = 0x24;
DBG("Start Darwin Fix\n");
ReplaceName(dsdt, len, "_OSI", "OOSI");
if (gSettings.FixDsdt & FIX_DARWIN) {
darwin[42] = '9'; //windows 2009
}
len = move_data(adr, dsdt, len, sizeof(darwin));
CopyMem(dsdt+adr, darwin, sizeof(darwin));
return len;
}
VOID FixS3D (UINT8* dsdt, UINT32 len)
{
UINT32 i;
DBG("Start _S3D Fix\n");
for (i=20; len >= 5 && i < len - 5; i++) {
if ((dsdt[i + 0] == 0x08) &&
(dsdt[i + 1] == '_') &&
(dsdt[i + 2] == 'S') &&
(dsdt[i + 3] == '3') &&
(dsdt[i + 4] == 'D') &&
(dsdt[i + 5] == 0x0A) &&
(dsdt[i + 6] == 0x02)) {
dsdt[i + 6] = 3;
}
}
}
UINT32 AddPNLF (UINT8 *dsdt, UINT32 len)
{
#if AUTO_PNLF
EFI_STATUS Status;
EFI_HANDLE *HandleBuffer = NULL;
EFI_HANDLE Handle;
EFI_PCI_IO_PROTOCOL *PciIo;
PCI_TYPE00 Pci;
UINTN HandleCount = 0;
UINTN HandleIndex;
UINTN Segment;
UINTN Bus;
UINTN Device;
UINTN Function;
#endif
UINT32 i; //, j, size;
UINT32 adr = 0;
DBG("Start PNLF Fix\n");
if (FindBin(dsdt, len, (UINT8*)app2, 10) >= 0) {
return len; //the device already exists
}
//search PWRB PNP0C0C
for (i=0x20; len >= 6 && i < len - 6; i++) {
if (CmpPNP(dsdt, i, 0x0C0C)) {
DBG("found PWRB at %X\n", i);
adr = devFind(dsdt, i);
break;
}
}
if (!adr) {
//search battery
DBG("not found PWRB, look BAT0\n");
for (i=0x20; len >= 6 && i < len - 6; i++) {
if (CmpPNP(dsdt, i, 0x0C0A)) {
adr = devFind(dsdt, i);
DBG("found BAT0 at %X\n", i);
break;
}
}
}
if (!adr) {
return len;
}
//Slice - add custom UID
if (gSettings.PNLF_UID != 0xFF) {
((CHAR8*)pnlf)[39] = gSettings.PNLF_UID;
}
// _UID reworked by Sherlocks. 2018.10.08
//Slice - it can't depends on video DeviceID. It is hardware ID of LCD screen.
#if AUTO_PNLF
Status = gBS->LocateHandleBuffer (
ByProtocol,
&gEfiPciIoProtocolGuid,
NULL,
&HandleCount,
&HandleBuffer
);
if (!EFI_ERROR (Status)) {
for (HandleIndex = 0; HandleIndex < HandleCount; HandleIndex++) {
Handle = HandleBuffer[HandleIndex];
Status = gBS->HandleProtocol (
Handle,
&gEfiPciIoProtocolGuid,
(VOID **)&PciIo
);
if (!EFI_ERROR (Status)) {
PciIo->GetLocation (PciIo, &Segment, &Bus, &Device, &Function);
Status = PciIo->Pci.Read (
PciIo,
EfiPciIoWidthUint32,
0,
sizeof (Pci) / sizeof (UINT32),
&Pci
);
}
if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_DISPLAY) &&
((Pci.Hdr.ClassCode[1] == PCI_CLASS_DISPLAY_VGA) ||
(Pci.Hdr.ClassCode[1] == PCI_CLASS_DISPLAY_OTHER))) {
switch (Pci.Hdr.VendorId) {
case 0x8086:
// followed standard _UID of AppleBacklight
// it works for both default and AppleBacklightInjector
switch (Pci.Hdr.DeviceId) {
case 0x2772: // "Intel GMA 950"
case 0x2776: // "Intel GMA 950"
case 0x27A2: // "Intel GMA 950"
case 0x27A6: // "Intel GMA 950"
case 0x27AE: // "Intel GMA 950"
case 0xA001: // "Intel GMA 3150"
case 0xA002: // "Intel GMA 3150"
case 0xA011: // "Intel GMA 3150"
case 0xA012: // "Intel GMA 3150"
case 0x2A02: // "Intel GMA X3100"
case 0x2A03: // "Intel GMA X3100"
case 0x2A12: // "Intel GMA X3100"
case 0x2A13: // "Intel GMA X3100"
case 0x0042: // "Intel HD Graphics"
case 0x0046: // "Intel HD Graphics"
// _UID: 10
break;
case 0x0102: // "Intel HD Graphics 2000"
case 0x0106: // "Intel HD Graphics 2000"
case 0x010A: // "Intel HD Graphics P3000"
case 0x0112: // "Intel HD Graphics 3000"
case 0x0116: // "Intel HD Graphics 3000"
case 0x0122: // "Intel HD Graphics 3000"
case 0x0126: // "Intel HD Graphics 3000"
case 0x0152: // "Intel HD Graphics 2500"
case 0x0156: // "Intel HD Graphics 2500"
case 0x015A: // "Intel HD Graphics 2500"
case 0x0162: // "Intel HD Graphics 4000"
case 0x0166: // "Intel HD Graphics 4000"
case 0x016A: // "Intel HD Graphics P4000"
((CHAR8*)pnlf)[39] = 0x0E; // _UID: 14
break;
case 0x0412: // "Intel HD Graphics 4600"
case 0x0416: // "Intel HD Graphics 4600"
case 0x041A: // "Intel HD Graphics P4600"
case 0x041E: // "Intel HD Graphics 4400"
case 0x0422: // "Intel HD Graphics 5000"
case 0x0426: // "Intel HD Graphics 5000"
case 0x042A: // "Intel HD Graphics 5000"
case 0x0A06: // "Intel HD Graphics"
case 0x0A16: // "Intel HD Graphics 4400"
case 0x0A1E: // "Intel HD Graphics 4200"
case 0x0A22: // "Intel Iris Graphics 5100"
case 0x0A26: // "Intel HD Graphics 5000"
case 0x0A2A: // "Intel Iris Graphics 5100"
case 0x0A2B: // "Intel Iris Graphics 5100"
case 0x0A2E: // "Intel Iris Graphics 5100"
case 0x0D12: // "Intel HD Graphics 4600"
case 0x0D16: // "Intel HD Graphics 4600"
case 0x0D22: // "Intel Iris Pro Graphics 5200"
case 0x0D26: // "Intel Iris Pro Graphics 5200"
case 0x0D2A: // "Intel Iris Pro Graphics 5200"
case 0x0D2B: // "Intel Iris Pro Graphics 5200"
case 0x0D2E: // "Intel Iris Pro Graphics 5200"
case 0x1612: // "Intel HD Graphics 5600"
case 0x1616: // "Intel HD Graphics 5500"
case 0x161E: // "Intel HD Graphics 5300"
case 0x1626: // "Intel HD Graphics 6000"
case 0x162B: // "Intel Iris Graphics 6100"
case 0x162D: // "Intel Iris Pro Graphics P6300"
case 0x1622: // "Intel Iris Pro Graphics 6200"
case 0x162A: // "Intel Iris Pro Graphics P6300"
((CHAR8*)pnlf)[39] = 0x0F; // _UID: 15
break;
default:
((CHAR8*)pnlf)[39] = 0x10; // _UID: 16
break;
}
break;
default:
// ATI/NVIDIA
// _UID: 10
break;
}
}
}
}
#endif
i = adr - 2;
len = move_data(i, dsdt, len, sizeof(pnlf));
CopyMem(dsdt+i, pnlf, sizeof(pnlf));
len = CorrectOuters(dsdt, len, adr-3, sizeof(pnlf));
return len;
}
UINT32 FixRTC (UINT8 *dsdt, UINT32 len)
{
UINT32 i, j, k, l;
UINT32 IOADR = 0;
UINT32 RESADR = 0;
UINT32 adr = 0;
UINT32 rtcsize = 0;
INT32 shift, sizeoffset = 0;
DBG("Start RTC Fix\n");
for (j=20; j<len; j++) {
// Find Device RTC // Name (_HID, EisaId ("PNP0B00")) for RTC
if (CmpPNP(dsdt, j, 0x0B00))
{
adr = devFind(dsdt, j);
if (!adr) {
continue;
}
rtcsize = get_size(dsdt, adr);
if (rtcsize) {
break;
}
} // End RTC
}
if (!rtcsize) {
DBG("BUG! rtcsize not found\n");
return len;
}
for (i=adr+4; i<adr+rtcsize; i++) {
// IO (Decode16, ((0x0070, 0x0070)) =>> find this
if (dsdt[i] == 0x70 && dsdt[i+1] == 0x00 && dsdt[i+2] == 0x70 && dsdt[i+3] == 0x00) {
if (dsdt[i+5] == 0x08 && gSettings.Rtc8Allowed) {
MsgLog("CMOS reset not will be, patch length is not needed\n");
} else {
// First Fix RTC CMOS Reset Problem
if (dsdt[i+4] != 0x00 || dsdt[i+5] != 0x02) { //dsdt[j+4] => Alignment dsdt[j+5] => Length
dsdt[i+4] = 0x00; //Alignment
dsdt[i+5] = 0x02; //Length
MsgLog("found RTC Length not match, Maybe will cause CMOS reset, will patch it.\n");
}
}
for (l = adr + 4; l < i; l++) {
if (dsdt[l] == 0x11 && dsdt[l+2] == 0x0A) {
RESADR = l + 1; //Format 11, size, 0A, size-3,... 79, 00
IOADR = l + 3; //IO (Decode16 ==> 47, 01
}
}
break;
}
if ((dsdt[i+1] == 0x5B) && (dsdt[i+2] == 0x82)) {
break; //end of RTC device and begin of new Device()
}
}
for (l = adr + 4; l < adr + rtcsize; l++) {
if ((dsdt[l] == 0x22) && (l>IOADR) && (l<IOADR+dsdt[IOADR])) { // Had IRQNoFlag
for (k=l; k<l+20; k++) {
if ((dsdt[k] == 0x79) || ((dsdt[k] == 0x47) && (dsdt[k+1] == 0x01)) ||
((dsdt[k] == 0x86) && (dsdt[k+1] == 0x09))) {
sizeoffset = l - k; //usually = -3
MsgLog("found RTC had IRQNoFlag will move %d bytes\n", sizeoffset);
// First move offset byte remove IRQNoFlag
len = move_data(l, dsdt, len, sizeoffset);
DBG("...len=%X\n", len);
// Fix IO (Decode16, size and _CRS size
dsdt[RESADR] += (UINT8)sizeoffset;
dsdt[IOADR] += (UINT8)sizeoffset;
break;
}
}
}
// if offset > 0 Fix Device RTC size
if (sizeoffset != 0) {
// RTC size
shift = write_size(adr, dsdt, len, sizeoffset);
sizeoffset += shift; //sizeoffset changed
len += shift;
DBG("new size written to %X shift=%X len=%X\n", adr, shift, len);
len = CorrectOuters(dsdt, len, adr-3, sizeoffset);
DBG("len after correct outers %X\n", len);
sizeoffset = 0;
} // sizeoffset if
} // l loop
return len;
}
UINT32 FixTMR (UINT8 *dsdt, UINT32 len)
{
UINT32 i, j, k;
UINT32 IOADR = 0;
UINT32 RESADR = 0;
UINT32 adr = 0;
UINT32 TMRADR, tmrsize = 0;
INT32 offset = 0, sizeoffset = 0;
DBG("Start TMR Fix\n");
for (j=20; j<len; j++) {
// Find Device TMR PNP0100
if (CmpPNP(dsdt, j, 0x0100)) {
TMRADR = devFind(dsdt, j);
adr = TMRADR;
if (!adr) {
continue;
}
tmrsize = get_size(dsdt, adr);
// DBG("TMR size=%X at %X\n", tmrsize, adr);
if (tmrsize) {
break;
}
} // End TMR
}
if (!adr) {
DBG("TMR device not found!\n");
return len;
}
// Fix TMR
// Find Name(_CRS, ResourceTemplate ()) find ResourceTemplate 0x11
j = 0;
for (i=adr; i<adr+tmrsize; i++) { //until next Device()
if (dsdt[i] == 0x11 && dsdt[i+2] == 0x0A) {
RESADR = i+1; //Format 11, size, 0A, size-3,... 79, 00
IOADR = i+3; //IO (Decode16 ==> 47, 01
j = get_size(dsdt, IOADR);
}
if (dsdt[i] == 0x22) { // Had IRQNoFlag
for (k=i; k<i+j; k++) {
if ((dsdt[k] == 0x79) || ((dsdt[k] == 0x47) && (dsdt[k+1] == 0x01)) ||
((dsdt[k] == 0x86) && (dsdt[k+1] == 0x09))) {
sizeoffset = i - k;
//DBG("found TMR had IRQNoFlag will move %d bytes\n", sizeoffset);
// First move offset byte remove IRQNoFlag
len = move_data(i, dsdt, len, sizeoffset);
// Fix IO (Decode16, size and _CRS size
dsdt[RESADR] += (UINT8)sizeoffset;
dsdt[IOADR] += (UINT8)sizeoffset;
break;
}
}
}
// if offset > 0 Fix Device TMR size
if (sizeoffset != 0)
{
// TMR size
offset = write_size(adr, dsdt, len, sizeoffset);
sizeoffset += offset;
len += offset;
len = CorrectOuters(dsdt, len, adr-3, sizeoffset);
sizeoffset = 0;
} // offset if
if ((dsdt[i+1] == 0x5B) && (dsdt[i+2] == 0x82)) {
break; //end of TMR device and begin of new Device()
}
} // i loop
return len;
}
UINT32 FixPIC (UINT8 *dsdt, UINT32 len)
{
UINT32 i, j, k;
UINT32 IOADR = 0;
UINT32 RESADR = 0;
UINT32 adr = 0;
INT32 offset = 0, sizeoffset = 0;
UINT32 PICADR, picsize = 0;
DBG("Start PIC Fix\n");
for (j=20; j<len; j++) {
// Find Device PIC or IPIC PNP0000
if (CmpPNP(dsdt, j, 0x0000)) {
PICADR = devFind(dsdt, j);
adr = PICADR;
if (!adr) {
continue;
}
picsize = get_size(dsdt, adr);
DBG("PIC size=%X at %X\n", picsize, adr);
if (picsize) {
break;
}
} // End PIC
}
if (!picsize) {
DBG("IPIC not found\n");
return len;
}
for (i=adr; i<adr+picsize; i++)
{
if (dsdt[i] == 0x11 && dsdt[i+2] == 0x0A) {
RESADR = i+1; //Format 11, size, 0A, size-3,... 79, 00
IOADR = i+3; //IO (Decode16 ==> 47, 01
continue;
} else {
// or 11 41 09 0A 8D 47 01 20 00 -> size=0x91 size-4=0x89
if ((dsdt[i] == 0x11) &&
(dsdt[i+3] == 0x0A) &&
((dsdt[i+1] & 0xF0) == 0x40)) {
RESADR = i+1; //Format 11, size1, size2, 0A, size-4,... 79, 00
IOADR = i+4; //IO (Decode16 ==> 47, 01
DBG("found CRS at %X size %X\n", RESADR, dsdt[IOADR]);
continue;
}
}
if (dsdt[i] == 0x22) { // Had IRQNoFlag
for (k = i; k < RESADR + dsdt[IOADR] + 4; k++) {
if ((dsdt[k] == 0x79) ||
((dsdt[k] == 0x47) && (dsdt[k+1] == 0x01)) ||
((dsdt[k] == 0x86) && (dsdt[k+1] == 0x09))) {
sizeoffset = i - k;
MsgLog("found PIC had IRQNoFlag will move %d bytes\n", sizeoffset);
// First move offset byte remove IRQNoFlag
len = move_data(i, dsdt, len, sizeoffset);
// Fix IO (Decode16, size and _CRS size
// dsdt[RESADR] += (UINT8)sizeoffset;
dsdt[IOADR] += (UINT8)sizeoffset;
offset = write_size(RESADR, dsdt, len, sizeoffset);
sizeoffset += offset;
len += offset;
break;
}
}
}
// if offset > 0 Fix Device PIC size
if (sizeoffset != 0 ) {
offset = write_size(adr, dsdt, len, sizeoffset);
sizeoffset += offset;
DBG("Fix Device PIC size %d\n", sizeoffset);
len += offset;
len = CorrectOuters(dsdt, len, adr-3, sizeoffset);
sizeoffset = 0;
} // sizeoffset if
if ((dsdt[i+1] == 0x5B) && (dsdt[i+2] == 0x82)) {
break; //end of PIC device and begin of new Device()
}
} // i loop
return len;
}
UINT32 FixHPET (UINT8* dsdt, UINT32 len)
{
UINT32 i, j;
UINT32 adr = 0;
UINT32 hpetsize = 0;
INT32 sizeoffset = sizeof(hpet0);
INT32 shift = 0;
UINT32 LPCBADR = 0, LPCBSIZE = 0;
MsgLog("Start HPET Fix\n");
//have to find LPC
for (j=0x20; len >= 10 && j < len - 10; j++) {
if (CmpAdr(dsdt, j, 0x001F0000)) {
LPCBADR = devFind(dsdt, j);
if (!LPCBADR) {
continue;
}
LPCBSIZE = get_size(dsdt, LPCBADR);
} // End LPCB find
}
if (!LPCBSIZE) {
MsgLog("No LPCB device! Patch HPET will not be applied\n");
return len;
}
for (j=20; j<len; j++) {
// Find Device HPET // PNP0103
if (CmpPNP(dsdt, j, 0x0103)) {
adr = devFind(dsdt, j);
if (!adr) {
continue;
}
hpetsize = get_size(dsdt, adr);
if (hpetsize) {
break;
}
} // End HPET
}
if (hpetsize) {
i = adr - 2; //pointer to device HPET
j = hpetsize + 2;
sizeoffset -= j;
len = move_data(i, dsdt, len, sizeoffset);
// add new HPET code
CopyMem(dsdt+i, hpet0, sizeof(hpet0));
len = CorrectOuters(dsdt, len, i - 3, sizeoffset); //assume LPC may be outer or not
} else {
i = LPCBADR + LPCBSIZE; //pointer to the end of LPC
//in this case LPC becomes Outer device
shift = write_size(LPCBADR, dsdt, len, sizeoffset); //correct LPC
sizeoffset += shift;
len += shift;
i += shift;
len = move_data(i, dsdt, len, sizeof(hpet0));
// add new HPET code
CopyMem(dsdt + i, hpet0, sizeof(hpet0));
len = CorrectOuters(dsdt, len, LPCBADR - 3, sizeoffset); //outer for LPC
}
return len;
}
UINT8 dataLPC[] = {0x18, 0x3A, 0x00, 0x00};
UINT32 FIXLPCB (UINT8 *dsdt, UINT32 len)
{
UINT32 i, j, k;
INT32 sizeoffset, shift = 0, Size;
UINT32 LPCBADR = 0, LPCBSIZE = 0, LPCBADR1 = 0;
AML_CHUNK* root;
AML_CHUNK* met;
AML_CHUNK* pack;
CHAR8 *lpcb;
CHAR8 NameCard[32];
DBG("Start LPCB Fix\n");
//DBG("len = 0x%08X\n", len);
//have to find LPC
for (j=0x20; len >= 10 && j < len - 10; j++) {
if (CmpAdr(dsdt, j, 0x001F0000))
{
LPCBADR = devFind(dsdt, j);
if (!LPCBADR) {
continue;
}
LPCBSIZE = get_size(dsdt, LPCBADR);
device_name[3] = (__typeof_am__(device_name[3]))AllocateZeroPool(5);
CopyMem(device_name[3], dsdt + j, 4);
MsgLog("found LPCB device NAME(_ADR,0x001F0000) at %X And Name is %s\n", j,
device_name[3]);
if (LPCBSIZE) break;
} // End LPCB find
}
if (!LPCBSIZE) return len;
LPCBADR1 = LPCBADR + LPCBSIZE;
ReplaceName(dsdt, len, device_name[3], "LPCB");
if (LPCBADR) { // bridge or device
i = LPCBADR;
Size = get_size(dsdt, i);
k = FindMethod(dsdt + i, Size, "_DSM");
if (k != 0) {
k += i;
if ((dropDSM & DEV_LPC) != 0) {
Size = get_size(dsdt, k);
if(!Size) {
return len;
}
sizeoffset = - 1 - Size;
len = move_data(k - 1, dsdt, len, sizeoffset);
//to correct outers we have to calculate offset
len = CorrectOuters(dsdt, len, k - 2, sizeoffset);
MsgLog("_DSM in LPC already exists, dropped\n");
} else {
MsgLog("_DSM already exists, patch LPC will not be applied\n");
return len;
}
}
}
root = aml_create_node(NULL);
// add Method(_DSM,4,NotSerialized) for LPC
met = aml_add_method(root, "_DSM", 4);
met = aml_add_store(met);
pack = aml_add_package(met);
aml_add_string(pack, "device-id");
aml_add_byte_buffer(pack, dataLPC, 4);
AsciiSPrint(NameCard, 32, "pci8086,3a18");
aml_add_string(pack, "name");
aml_add_string_buffer(pack, (CHAR8 *)&NameCard[0]);
aml_add_string(pack, "compatible");
aml_add_string_buffer(pack, (CHAR8 *)&NameCard[0]);
CustProperties(pack, DEV_LPC);
aml_add_local0(met);
aml_add_buffer(met, dtgp_1, sizeof(dtgp_1));
// finish Method(_DSM,4,NotSerialized)
aml_calculate_size(root);
lpcb = (__typeof__(lpcb))AllocateZeroPool(root->Size);
sizeoffset = root->Size;
aml_write_node(root, lpcb, 0);
aml_destroy_node(root);
// add LPCB code
len = move_data(LPCBADR1, dsdt, len, sizeoffset);
CopyMem(dsdt + LPCBADR1, lpcb, sizeoffset);
shift = write_size(LPCBADR, dsdt, len, sizeoffset);
sizeoffset += shift;
len += shift;
len = CorrectOuters(dsdt, len, LPCBADR-3, sizeoffset);
FreePool(lpcb);
return len;
}
//CONST
UINT8 Yes[] = {0x01,0x00,0x00,0x00};
UINT8 data2[] = {0xe0,0x00,0x56,0x28};
UINT8 VenATI[] = {0x02, 0x10};
UINT32 FIXDisplay (UINT8 *dsdt, UINT32 len, INT32 VCard)
{
UINT32 i = 0, j, k;
INT32 sizeoffset = 0;
UINT32 PCIADR = 0, PCISIZE = 0, Size;
CHAR8 *display;
UINT32 devadr=0, devsize=0, devadr1=0, devsize1=0;
BOOLEAN DISPLAYFIX = FALSE;
BOOLEAN NonUsable = FALSE;
BOOLEAN DsmFound = FALSE;
BOOLEAN NeedHDMI = !!(gSettings.FixDsdt & FIX_HDMI);
AML_CHUNK *root = NULL;
AML_CHUNK *gfx0, *peg0;
AML_CHUNK *met, *met2;
AML_CHUNK *pack;
UINT32 FakeID = 0;
UINT32 FakeVen = 0;
DisplayName1 = FALSE;
if (!DisplayADR1[VCard]) return len;
PCIADR = GetPciDevice(dsdt, len);
if (PCIADR) {
PCISIZE = get_size(dsdt, PCIADR);
}
if (!PCISIZE) return len; //what is the bad DSDT ?!
MsgLog("Start Display%d Fix\n", VCard);
root = aml_create_node(NULL);
//search DisplayADR1[0]
for (j=0x20; len >= 10 && j < len - 10; j++) {
if (CmpAdr(dsdt, j, DisplayADR1[VCard])) { //for example 0x00020000=2,0
devadr = devFind(dsdt, j); //PEG0@2,0
if (!devadr) {
continue;
}
devsize = get_size(dsdt, devadr); //sizeof PEG0 0x35
if (devsize) {
DisplayName1 = TRUE;
break;
}
} // End Display1
}
//what if PEG0 is not found?
if (devadr) {
for (j=devadr; j<devadr+devsize; j++) { //search card inside PEG0@0
if (CmpAdr(dsdt, j, DisplayADR2[VCard])) { //else DISPLAYFIX==false
devadr1 = devFind(dsdt, j); //found PEGP
if (!devadr1) {
continue;
}
devsize1 = get_size(dsdt, devadr1);
if (devsize1) {
MsgLog("Found internal video device %X @%X\n", DisplayADR2[VCard], devadr1);
DISPLAYFIX = TRUE;
break;
}
}
}
if (!DISPLAYFIX) {
for (j=devadr; j<devadr+devsize; j++) { //search card inside PEGP@0
if (CmpAdr(dsdt, j, 0xFFFF)) { //Special case? want to change to 0
devadr1 = devFind(dsdt, j); //found PEGP
if (!devadr1) {
continue;
}
devsize1 = get_size(dsdt, devadr1); //13
if (devsize1) {
if (gSettings.ReuseFFFF) {
dsdt[j+10] = 0;
dsdt[j+11] = 0;
MsgLog("Found internal video device FFFF@%X, ReUse as 0\n", devadr1);
} else {
NonUsable = TRUE;
MsgLog("Found internal video device FFFF@%X, unusable\n", devadr1);
}
DISPLAYFIX = TRUE;
break;
}
}
}
}
i = 0;
if (DISPLAYFIX) { // device on bridge found
i = devadr1;
} else if (DisplayADR2[VCard] == 0xFFFE) { //builtin
i = devadr;
DISPLAYFIX = TRUE;
devadr1 = devadr;
MsgLog(" builtin display\n");
}
if (i != 0) {
Size = get_size(dsdt, i);
k = FindMethod(dsdt + i, Size, "_DSM");
if (k != 0) {
k += i;
if ((((dropDSM & DEV_ATI) != 0) && (DisplayVendor[VCard] == 0x1002)) ||
(((dropDSM & DEV_NVIDIA)!= 0) && (DisplayVendor[VCard] == 0x10DE)) ||
(((dropDSM & DEV_INTEL) != 0) && (DisplayVendor[VCard] == 0x8086))) {
Size = get_size(dsdt, k);
sizeoffset = - 1 - Size;
len = move_data(k - 1, dsdt, len, sizeoffset); //kill _DSM
len = CorrectOuters(dsdt, len, k - 2, sizeoffset);
MsgLog("_DSM in display already exists, dropped\n");
} else {
MsgLog("_DSM already exists, patch display will not be applied\n");
// return len;
DisplayADR1[VCard] = 0; //xxx
DsmFound = TRUE;
}
}
}
}
if (!DisplayName1) {
peg0 = aml_add_device(root, "PEG0");
aml_add_name(peg0, "_ADR");
aml_add_dword(peg0, DisplayADR1[VCard]);
MsgLog("add device PEG0\n");
} else
peg0 = root;
if (!DISPLAYFIX) { //bridge or builtin not found
gfx0 = aml_add_device(peg0, "GFX0");
MsgLog("add device GFX0\n");
aml_add_name(gfx0, "_ADR");
if (DisplayADR2[VCard] > 0x3F)
aml_add_dword(gfx0, DisplayADR2[VCard]);
else
aml_add_byte(gfx0, (UINT8)DisplayADR2[VCard]);
} else {
gfx0 = peg0;
}
if (
DsmFound ||
(
!NeedHDMI &&
(
((DisplayVendor[VCard] == 0x8086) && (gSettings.InjectIntel || !gSettings.FakeIntel)) ||
((DisplayVendor[VCard] == 0x10DE) && (gSettings.InjectNVidia || !gSettings.FakeNVidia)) ||
((DisplayVendor[VCard] == 0x1002) && (gSettings.InjectATI || !gSettings.FakeATI))
)
)
) {
MsgLog("Skipping Method(_DSM) for %04X card\n", DisplayVendor[VCard]);
goto Skip_DSM;
}
MsgLog("Creating Method(_DSM) for %04X card\n", DisplayVendor[VCard]);
met = aml_add_method(gfx0, "_DSM", 4);
met2 = aml_add_store(met);
pack = aml_add_package(met2);
if (NeedHDMI) {
aml_add_string(pack, "hda-gfx");
aml_add_string_buffer(pack, (gSettings.UseIntelHDMI && DisplayVendor[VCard] != 0x8086) ? "onboard-2" : "onboard-1");
}
switch (DisplayVendor[VCard]) {
case 0x8086:
if (gSettings.FakeIntel) {
FakeID = gSettings.FakeIntel >> 16;
aml_add_string(pack, "device-id");
aml_add_byte_buffer(pack, (UINT8*)&FakeID, 4);
FakeVen = gSettings.FakeIntel & 0xFFFF;
aml_add_string(pack, "vendor-id");
aml_add_byte_buffer(pack, (UINT8*)&FakeVen, 4);
}
break;
case 0x10DE:
if (gSettings.FakeNVidia) {
FakeID = gSettings.FakeNVidia >> 16;
aml_add_string(pack, "device-id");
aml_add_byte_buffer(pack, (UINT8*)&FakeID, 4);
FakeVen = gSettings.FakeNVidia & 0xFFFF;
aml_add_string(pack, "vendor-id");
aml_add_byte_buffer(pack, (UINT8*)&FakeVen, 4);
}
break;
case 0x1002:
if (gSettings.FakeATI) {
FakeID = gSettings.FakeATI >> 16;
aml_add_string(pack, "device-id");
aml_add_byte_buffer(pack, (UINT8*)&FakeID, 4);
aml_add_string(pack, "ATY,DeviceID");
aml_add_byte_buffer(pack, (UINT8*)&FakeID, 2);
FakeVen = gSettings.FakeATI & 0xFFFF;
aml_add_string(pack, "vendor-id");
aml_add_byte_buffer(pack, (UINT8*)&FakeVen, 4);
aml_add_string(pack, "ATY,VendorID");
aml_add_byte_buffer(pack, (UINT8*)&FakeVen, 2);
}/* else {
aml_add_string(pack, "ATY,VendorID");
aml_add_byte_buffer(pack, VenATI, 2);
}*/
break;
}
aml_add_local0(met);
aml_add_buffer(met, dtgp_1, sizeof(dtgp_1));
Skip_DSM:
//add _sun
/*
switch (DisplayVendor[VCard]) {
case 0x10DE:
case 0x1002:
Size = get_size(dsdt, i);
j = (DisplayVendor[VCard] == 0x1002) ? 0 : 1;
k = FindMethod(dsdt + i, Size, "_SUN");
if (k == 0) {
k = FindName(dsdt + i, Size, "_SUN");
if (k == 0) {
aml_add_name(gfx0, "_SUN");
aml_add_dword(gfx0, SlotDevices[j].SlotID);
} else {
//we have name sun, set the number
if (dsdt[k + 4] == 0x0A) {
dsdt[k + 5] = SlotDevices[j].SlotID;
}
}
} else {
MsgLog("Warning: Method(_SUN) found for %04X card\n", DisplayVendor[VCard]);
}
break;
}
*/
if (!NonUsable) {
//now insert video
DBG("now inserting Video device\n");
aml_calculate_size(root);
display = (__typeof__(display))AllocateZeroPool(root->Size);
sizeoffset = root->Size;
aml_write_node(root, display, 0);
aml_destroy_node(root);
if (DisplayName1) { //bridge is present
// move data to back for add Display
DBG("... into existing bridge\n");
if (!DISPLAYFIX || (DisplayADR2[VCard] == 0xFFFE)) { //subdevice absent
devsize = get_size(dsdt, devadr);
if (!devsize) {
DBG("BUG! Address of existing PEG0 is lost %X\n", devadr);
FreePool(display);
return len;
}
i = devadr + devsize;
len = move_data(i, dsdt, len, sizeoffset);
CopyMem(dsdt+i, display, sizeoffset);
j = write_size(devadr, dsdt, len, sizeoffset); //correct bridge size
sizeoffset += j;
len += j;
len = CorrectOuters(dsdt, len, devadr-3, sizeoffset);
} else {
devsize1 = get_size(dsdt, devadr1);
if (!devsize1) {
FreePool(display);
return len;
}
i = devadr1 + devsize1;
len = move_data(i, dsdt, len, sizeoffset);
CopyMem(dsdt+i, display, sizeoffset);
j = write_size(devadr1, dsdt, len, sizeoffset);
sizeoffset += j;
len += j;
len = CorrectOuters(dsdt, len, devadr1-3, sizeoffset);
}
} else { //insert PEG0 into PCI0 at the end
//PCI corrected so search again
DBG("... into created bridge\n");
PCIADR = GetPciDevice(dsdt, len);
if (PCIADR) {
PCISIZE = get_size(dsdt, PCIADR);
}
if (!PCISIZE) return len; //what is the bad DSDT ?!
i = PCIADR + PCISIZE;
// devadr = i + 2; //skip 5B 82
len = move_data(i, dsdt, len, sizeoffset);
CopyMem(dsdt + i, display, sizeoffset);
// Fix PCI0 size
k = write_size(PCIADR, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
// devadr += k;
k = CorrectOuters(dsdt, len, PCIADR-3, sizeoffset);
// devadr += k - len;
len = k;
}
FreePool(display);
}
return len;
}
UINT32 AddHDMI (UINT8 *dsdt, UINT32 len)
{
UINT32 i, j, k;
INT32 sizeoffset = 0;
UINT32 PCIADR = 0, PCISIZE = 0, Size;
CHAR8 *hdmi = NULL;
UINT32 devadr=0, BridgeSize=0, devadr1=0; //, devsize1=0;
BOOLEAN BridgeFound = FALSE;
BOOLEAN HdauFound = FALSE;
AML_CHUNK* brd = NULL;
AML_CHUNK *root = NULL;
AML_CHUNK *met, *met2;
AML_CHUNK *pack;
if (!HDMIADR1) return len;
PCIADR = GetPciDevice(dsdt, len);
if (PCIADR) {
PCISIZE = get_size(dsdt, PCIADR);
}
if (!PCISIZE) return len; //what is the bad DSDT ?!
DBG("Start HDMI%d Fix\n");
// Device Address
for (i=0x20; len >= 10 && i < len - 10; i++) {
if (CmpAdr(dsdt, i, HDMIADR1)) {
devadr = devFind(dsdt, i);
if (!devadr) {
continue;
}
BridgeSize = get_size(dsdt, devadr);
if (!BridgeSize) {
continue;
}
BridgeFound = TRUE;
if (HDMIADR2 != 0xFFFE){
for (k = devadr + 9; k < devadr + BridgeSize; k++) {
if (CmpAdr(dsdt, k, HDMIADR2))
{
devadr1 = devFind(dsdt, k);
if (!devadr1) {
continue;
}
device_name[11] = (__typeof_am__(device_name[11]))AllocateZeroPool(5);
CopyMem(device_name[11], dsdt+k, 4);
DBG("found HDMI device [0x%08X:%X] at %X and Name is %s\n",
HDMIADR1, HDMIADR2, devadr1, device_name[11]);
ReplaceName(dsdt + devadr, BridgeSize, device_name[11], "HDAU");
HdauFound = TRUE;
break;
}
}
if (!HdauFound) {
DBG("have no HDMI device while HDMIADR2=%X\n", HDMIADR2);
devadr1 = devadr;
}
} else {
devadr1 = devadr;
}
break;
} // End if devadr1 find
}
if (BridgeFound) { // bridge or device
if (HdauFound) {
i = devadr1;
Size = get_size(dsdt, i);
k = FindMethod(dsdt + i, Size, "_DSM");
if (k != 0) {
k += i;
if ((dropDSM & DEV_HDMI) != 0) {
Size = get_size(dsdt, k);
sizeoffset = - 1 - Size;
len = move_data(k - 1, dsdt, len, sizeoffset);
len = CorrectOuters(dsdt, len, k - 2, sizeoffset);
DBG("_DSM in HDAU already exists, dropped\n");
} else {
DBG("_DSM already exists, patch HDAU will not be applied\n");
return len;
}
}
}
root = aml_create_node(NULL);
//what to do if no HDMI bridge?
} else {
brd = aml_create_node(NULL);
root = aml_add_device(brd, "HDM0");
aml_add_name(root, "_ADR");
aml_add_dword(root, HDMIADR1);
DBG("Created bridge device with ADR=0x%X\n", HDMIADR1);
}
DBG("HDMIADR1=%X HDMIADR2=%X\n", HDMIADR1, HDMIADR2);
if (!HdauFound && (HDMIADR2 != 0xFFFE)) //there is no HDMI device at dsdt, creating new one
{
AML_CHUNK* dev = aml_add_device(root, "HDAU");
aml_add_name(dev, "_ADR");
if (HDMIADR2) {
if (HDMIADR2 > 0x3F)
aml_add_dword(dev, HDMIADR2);
else
aml_add_byte(dev, (UINT8)HDMIADR2);
} else {
aml_add_byte(dev, 0x01);
}
met = aml_add_method(dev, "_DSM", 4);
} else {
//HDAU device already present
met = aml_add_method(root, "_DSM", 4);
}
met2 = aml_add_store(met);
pack = aml_add_package(met2);
if (!gSettings.NoDefaultProperties) {
aml_add_string(pack, "hda-gfx");
if (gSettings.UseIntelHDMI) {
aml_add_string_buffer(pack, "onboard-2");
} else {
aml_add_string_buffer(pack, "onboard-1");
}
}
/*
if (!CustProperties(pack, DEV_HDMI)) {
DBG(" with default properties\n");
aml_add_string(pack, "layout-id");
aml_add_byte_buffer(pack, (CHAR8*)&GfxlayoutId[0], 4);
aml_add_string(pack, "PinConfigurations");
aml_add_byte_buffer(pack, data2, sizeof(data2));
}
*/
aml_add_local0(met2);
aml_add_buffer(met, dtgp_1, sizeof(dtgp_1));
// finish Method(_DSM,4,NotSerialized)
aml_calculate_size(root);
hdmi = (__typeof__(hdmi))AllocateZeroPool(root->Size);
sizeoffset = root->Size;
aml_write_node(root, hdmi, 0);
aml_destroy_node(root);
//insert HDAU
if (BridgeFound) { // bridge or lan
k = devadr1;
} else { //this is impossible
k = PCIADR;
}
Size = get_size(dsdt, k);
if (Size > 0) {
i = k + Size;
len = move_data(i, dsdt, len, sizeoffset);
CopyMem(dsdt + i, hdmi, sizeoffset);
j = write_size(k, dsdt, len, sizeoffset);
sizeoffset += j;
len += j;
len = CorrectOuters(dsdt, len, k-3, sizeoffset);
}
if (hdmi) {
FreePool(hdmi);
}
return len;
}
//Network -------------------------------------------------------------
UINT32 FIXNetwork (UINT8 *dsdt, UINT32 len, UINT32 card)
{
UINT32 i, k;
UINT32 NetworkADR = 0, BridgeSize, Size, BrdADR = 0;
UINT32 PCIADR, PCISIZE = 0;
INT32 sizeoffset;
AML_CHUNK *met, *met2;
AML_CHUNK *brd;
AML_CHUNK *root;
AML_CHUNK *pack;
AML_CHUNK *dev;
CHAR8 *network;
UINT32 FakeID = 0;
UINT32 FakeVen = 0;
CHAR8 NameCard[32];
if (!NetworkADR1[card]) return len;
DBG("Start NetWork %d Fix\n", card);
if (gSettings.FakeLAN) {
FakeID = gSettings.FakeLAN >> 16;
FakeVen = gSettings.FakeLAN & 0xFFFF;
AsciiSPrint(NameCard, 32, "pci%x,%x\0", FakeVen, FakeID);
LowCase(NameCard);
Netmodel[card] = get_net_model((FakeVen << 16) + FakeID);
}
PCIADR = GetPciDevice(dsdt, len);
if (PCIADR) {
PCISIZE = get_size(dsdt, PCIADR);
}
if (!PCISIZE) return len; //what is the bad DSDT ?!
NetworkName = FALSE;
// Network Address
for (i = 0x24; len >=10 && i < len - 10; i++) {
if (CmpAdr(dsdt, i, NetworkADR1[card])) { //0x001C0004
BrdADR = devFind(dsdt, i);
if (!BrdADR) {
continue;
}
BridgeSize = get_size(dsdt, BrdADR);
if (!BridgeSize) {
continue;
}
if (NetworkADR2[card] != 0xFFFE){ //0
for (k = BrdADR + 9; k < BrdADR + BridgeSize; k++) {
if (CmpAdr(dsdt, k, NetworkADR2[card])) {
NetworkADR = devFind(dsdt, k);
if (!NetworkADR) {
continue;
}
device_name[1] = (__typeof_am__(device_name[1]))AllocateZeroPool(5);
CopyMem(device_name[1], dsdt+k, 4);
DBG("found NetWork device [0x%08X:%X] at %X and Name is %s\n",
NetworkADR1[card], NetworkADR2[card], NetworkADR, device_name[1]);
//renaming disabled until better way will found
// ReplaceName(dsdt + BrdADR, BridgeSize, device_name[1], "GIGE");
NetworkName = TRUE;
break;
}
}
if (!NetworkName) {
DBG("have no Network device while NetworkADR2=%X\n", NetworkADR2[card]);
//in this case NetworkADR point to bridge
NetworkADR = BrdADR;
}
} else {
NetworkADR = BrdADR;
}
break;
} // End if NetworkADR find
}
if (BrdADR) { // bridge or device
i = NetworkADR;
Size = get_size(dsdt, i);
k = FindMethod(dsdt + i, Size, "_DSM");
if (k != 0) {
k += i;
if ((dropDSM & DEV_LAN) != 0) {
Size = get_size(dsdt, k);
sizeoffset = - 1 - Size;
len = move_data(k - 1, dsdt, len, sizeoffset);
len = CorrectOuters(dsdt, len, k - 2, sizeoffset);
DBG("_DSM in LAN already exists, dropped\n");
} else {
DBG("_DSM already exists, patch LAN will not be applied\n");
return len;
}
}
root = aml_create_node(NULL);
} else {
//what to do if no LAN bridge?
i = PCIADR;
brd = aml_create_node(NULL);
root = aml_add_device(brd, "LAN0");
aml_add_name(root, "_ADR");
aml_add_dword(root, NetworkADR1[card]);
DBG("Created bridge device with ADR=0x%X\n", NetworkADR1[card]);
}
DBG("NetworkADR1=%X NetworkADR2=%X\n", NetworkADR1[card], NetworkADR2[card]);
dev = root;
if (!NetworkName && (NetworkADR2[card] != 0xFFFE)) //there is no network device at dsdt, creating new one
{
dev = aml_add_device(root, NetName[card]);
aml_add_name(dev, "_ADR");
if (NetworkADR2[card]) {
if (NetworkADR2[card] > 0x3F)
aml_add_dword(dev, NetworkADR2[card]);
else
aml_add_byte(dev, (UINT8)NetworkADR2[card]);
} else {
aml_add_byte(dev, 0x00);
}
}
Size = get_size(dsdt, i);
k = FindMethod(dsdt + i, Size, "_SUN");
if (k == 0) {
k = FindName(dsdt + i, Size, "_SUN");
if (k == 0) {
aml_add_name(dev, "_SUN");
aml_add_dword(dev, SlotDevices[5].SlotID);
} else {
//we have name sun, set the number
if (dsdt[k + 4] == 0x0A) {
dsdt[k + 5] = SlotDevices[5].SlotID;
}
}
}
// add Method(_DSM,4,NotSerialized) for network
if (gSettings.FakeLAN || !gSettings.NoDefaultProperties) {
met = aml_add_method(dev, "_DSM", 4);
met2 = aml_add_store(met);
pack = aml_add_package(met2);
aml_add_string(pack, "built-in");
aml_add_byte_buffer(pack, dataBuiltin, sizeof(dataBuiltin));
aml_add_string(pack, "model");
aml_add_string_buffer(pack, Netmodel[card]);
// aml_add_string(pack, "device_type");
// aml_add_string_buffer(pack, "Ethernet");
if (gSettings.FakeLAN) {
// aml_add_string(pack, "model");
// aml_add_string_buffer(pack, "Apple LAN card");
aml_add_string(pack, "device-id");
aml_add_byte_buffer(pack, (UINT8 *)&FakeID, 4);
aml_add_string(pack, "vendor-id");
aml_add_byte_buffer(pack, (UINT8 *)&FakeVen, 4);
aml_add_string(pack, "name");
aml_add_string_buffer(pack, &NameCard[0]);
aml_add_string(pack, "compatible");
aml_add_string_buffer(pack, &NameCard[0]);
}
// Could we just comment this part? (Until remember what was the purposes?)
/* if (!CustProperties(pack, DEV_LAN) &&
!gSettings.FakeLAN &&
!gSettings.NoDefaultProperties) {
aml_add_string(pack, "empty");
aml_add_byte(pack, 0);
} */
aml_add_local0(met2);
aml_add_buffer(met, dtgp_1, sizeof(dtgp_1));
}
// finish Method(_DSM,4,NotSerialized)
aml_calculate_size(root);
network = (__typeof__(network))AllocateZeroPool(root->Size);
if (!network) {
return len;
}
sizeoffset = root->Size;
DBG("network DSM created, size=%X\n", sizeoffset);
aml_write_node(root, network, 0);
aml_destroy_node(root);
if (NetworkADR) { // bridge or lan
i = NetworkADR;
} else { //this is impossible
i = PCIADR;
}
Size = get_size(dsdt, i);
// move data to back for add patch
k = i + Size;
len = move_data(k, dsdt, len, sizeoffset);
CopyMem(dsdt+k, network, sizeoffset);
// Fix Device network size
k = write_size(i, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, i-3, sizeoffset);
FreePool(network);
return len;
}
//Airport--------------------------------------------------
//CHAR8 dataBCM[] = {0x12, 0x43, 0x00, 0x00};
//CHAR8 data1ATH[] = {0x2a, 0x00, 0x00, 0x00};
//CHAR8 data2ATH[] = {0x8F, 0x00, 0x00, 0x00};
//CHAR8 data3ATH[] = {0x6B, 0x10, 0x00, 0x00};
UINT32 FIXAirport (UINT8 *dsdt, UINT32 len)
{
UINT32 i, k;
UINT32 ArptADR = 0, BridgeSize, Size, BrdADR = 0;
UINT32 PCIADR, PCISIZE = 0;
INT32 sizeoffset;
AML_CHUNK *met, *met2;
AML_CHUNK* brd;
AML_CHUNK* root;
AML_CHUNK* pack;
AML_CHUNK* dev;
CHAR8 *network;
UINT32 FakeID = 0;
UINT32 FakeVen = 0;
CHAR8 NameCard[32];
if (!ArptADR1) return len; // no device - no patch
if (gSettings.FakeWIFI) {
FakeID = gSettings.FakeWIFI >> 16;
FakeVen = gSettings.FakeWIFI & 0xFFFF;
AsciiSPrint(NameCard, 32, "pci%x,%x\0", FakeVen, FakeID);
LowCase(NameCard);
}
PCIADR = GetPciDevice(dsdt, len);
if (PCIADR) {
PCISIZE = get_size(dsdt, PCIADR);
}
if (!PCISIZE) return len; //what is the bad DSDT ?!
DBG("Start Airport Fix\n");
ArptName = FALSE;
for (i=0x20; len >= 10 && i < len - 10; i++) {
// AirPort Address
if (CmpAdr(dsdt, i, ArptADR1) || CmpDev(dsdt, i, (UINT8*)gSettings.AirportBridgeDeviceName)) {
BrdADR = devFind(dsdt, i);
if (!BrdADR) {
continue;
}
BridgeSize = get_size(dsdt, BrdADR);
if(!BridgeSize) continue;
if (ArptADR2 != 0xFFFE){
for (k = BrdADR + 9; k < BrdADR + BridgeSize; k++) {
if (CmpAdr(dsdt, k, ArptADR2)) {
ArptADR = devFind(dsdt, k);
if (!ArptADR) {
continue;
}
device_name[9] = (__typeof_am__(device_name[9]))AllocateZeroPool(5);
CopyMem(device_name[9], dsdt+k, 4);
DBG("found Airport device [%08X:%X] at %X And Name is %s\n",
ArptADR1, ArptADR2, ArptADR, device_name[9]);
// ReplaceName(dsdt + BrdADR, BridgeSize, device_name[9], "ARPT"); //sometimes dangeous
ArptName = TRUE;
break;
}
}
}
break;
} // End ArptADR2
}
if (!ArptName) {
ArptADR = BrdADR;
}
if (BrdADR) { // bridge or device
i = ArptADR;
Size = get_size(dsdt, i);
k = FindMethod(dsdt + i, Size, "_DSM");
if (k != 0) {
k += i;
if ((dropDSM & DEV_WIFI) != 0) {
Size = get_size(dsdt, k);
sizeoffset = - 1 - Size;
len = move_data(k - 1, dsdt, len, sizeoffset);
len = CorrectOuters(dsdt, len, k - 2, sizeoffset);
DBG("_DSM in ARPT already exists, dropped\n");
} else {
DBG("_DSM already exists, patch ARPT will not be applied\n");
return len;
}
}
root = aml_create_node(NULL);
}
//what to do if no Arpt bridge?
else {
brd = aml_create_node(NULL);
root = aml_add_device(brd, "ARP0");
aml_add_name(root, "_ADR");
aml_add_dword(root, ArptADR1);
DBG("Created bridge device with ADR=0x%X\n", ArptADR1);
}
dev = root;
if (!ArptName && (ArptADR2 != 0xFFFE)) {//there is no Airport device at dsdt, creating new one
dev = aml_add_device(root, "ARPT");
aml_add_name(dev, "_ADR");
if (ArptADR2) {
if (ArptADR2> 0x3F)
aml_add_dword(dev, ArptADR2);
else
aml_add_byte(dev, (UINT8)ArptADR2);
} else {
aml_add_byte(dev, 0x00);
}
}
Size = get_size(dsdt, i);
k = FindMethod(dsdt + i, Size, "_SUN");
if (k == 0) {
k = FindName(dsdt + i, Size, "_SUN");
if (k == 0) {
aml_add_name(dev, "_SUN");
aml_add_dword(dev, SlotDevices[6].SlotID);
} else {
//we have name sun, set the number
if (dsdt[k + 4] == 0x0A) {
dsdt[k + 5] = SlotDevices[6].SlotID;
}
}
} else {
DBG("Warning: Method(_SUN) found for airport\n");
}
// add Method(_DSM,4,NotSerialized) for network
if (gSettings.FakeWIFI || !gSettings.NoDefaultProperties) {
met = aml_add_method(dev, "_DSM", 4);
met2 = aml_add_store(met);
pack = aml_add_package(met2);
if (!gSettings.NoDefaultProperties) {
aml_add_string(pack, "built-in");
aml_add_byte_buffer(pack, dataBuiltin, sizeof(dataBuiltin));
aml_add_string(pack, "model");
aml_add_string_buffer(pack, "Apple WiFi card");
aml_add_string(pack, "device_type");
aml_add_string_buffer(pack, "AirPort");
// aml_add_string(pack, "AAPL,slot-name");
// aml_add_string_buffer(pack, "AirPort");
}
if (gSettings.FakeWIFI) {
//aml_add_string(pack, "device-id");
//aml_add_byte_buffer(pack, (CHAR8 *)&FakeID, 4);
//aml_add_string(pack, "vendor-id");
//aml_add_byte_buffer(pack, (CHAR8 *)&FakeVen, 4);
aml_add_string(pack, "name");
aml_add_string_buffer(pack, (CHAR8 *)&NameCard[0]);
aml_add_string(pack, "compatible");
aml_add_string_buffer(pack, (CHAR8 *)&NameCard[0]);
}
if (!CustProperties(pack, DEV_WIFI) &&
!gSettings.NoDefaultProperties &&
!gSettings.FakeWIFI) {
aml_add_string(pack, "empty");
aml_add_byte(pack, 0);
}
aml_add_local0(met);
aml_add_buffer(met, dtgp_1, sizeof(dtgp_1));
}
// finish Method(_DSM,4,NotSerialized)
aml_calculate_size(root);
network = (__typeof__(network))AllocateZeroPool(root->Size);
sizeoffset = root->Size;
aml_write_node(root, network, 0);
aml_destroy_node(root);
DBG("AirportADR=%X add patch size=%X\n", ArptADR, sizeoffset);
if (ArptADR) { // bridge or WiFi
i = ArptADR;
} else { //this is impossible
i = PCIADR;
}
Size = get_size(dsdt, i);
DBG("adr %X size of arpt=%X\n", i, Size);
// move data to back for add patch
k = i + Size;
len = move_data(k, dsdt, len, sizeoffset);
CopyMem(dsdt+k, network, sizeoffset);
// Fix Device size
k = write_size(i, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, i-3, sizeoffset);
FreePool(network);
return len;
}
UINT32 FIXSBUS (UINT8 *dsdt, UINT32 len)
{
UINT32 i, k;
UINT32 SBUSADR=0, Size=0;
UINT32 PCIADR, PCISIZE = 0;
INT32 sizeoffset;
PCIADR = GetPciDevice(dsdt, len);
if (PCIADR) {
PCISIZE = get_size(dsdt, PCIADR);
}
if (!PCISIZE) {
// DBG("wrong PCI0 address, patch SBUS will not be applied\n");
return len;
}
DBG("Start SBUS Fix PCI=%X len=%X\n", PCIADR, len);
// Find Device SBUS
if (SBUSADR1) {
for (i=0x20; len >= 10 && i < len - 10; i++) {
if (CmpAdr(dsdt, i, SBUSADR1))
{
SBUSADR = devFind(dsdt, i);
if (SBUSADR) {
DBG("device (SBUS) found at %X\n", SBUSADR);
break;
}
} // end SBUS
}
}
if (SBUSADR) { // bridge or device
i = SBUSADR;
Size = get_size(dsdt, i);
k = FindMethod(dsdt + i, Size, "_DSM");
if (k != 0) {
k += i;
if ((dropDSM & DEV_SMBUS) != 0) {
Size = get_size(dsdt, k);
sizeoffset = - 1 - Size;
len = move_data(k - 1, dsdt, len, sizeoffset);
len = CorrectOuters(dsdt, len, k - 2, sizeoffset);
DBG("_DSM in SBUS already exists, dropped\n");
} else {
DBG("_DSM already exists, patch SBUS will not be applied\n");
return len;
}
}
Size = get_size(dsdt, SBUSADR);
if (ReplaceName(dsdt + SBUSADR, Size, NULL, "BUS0") < 0) {
DBG("BUS0 already exists, patch SBUS will not be applied\n");
return len;
}
}
if (SBUSADR)
sizeoffset = sizeof(bus0);
else
sizeoffset = sizeof(sbus1);
// DBG("SBUS address %X code size = 0x%08X\n", SBUSADR, sizeoffset);
if (SBUSADR) {
// move data to back for add sbus
Size = get_size(dsdt, SBUSADR);
i = SBUSADR + Size;
len = move_data(i, dsdt, len, sizeoffset);
CopyMem(dsdt+i, bus0, sizeoffset);
// Fix Device sbus size
k = write_size(SBUSADR, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, SBUSADR-3, sizeoffset);
// SBUSADR = adr1;
DBG("SBUS code size fix = 0x%08X\n", sizeoffset);
} else {
PCISIZE = get_size(dsdt, PCIADR);
i = PCIADR + PCISIZE;
DBG("SBUS absent, adding to the end of PCI0 at %X\n", i);
len = move_data(i, dsdt, len, sizeoffset);
CopyMem(dsdt+i, sbus1, sizeoffset);
// Fix PCIX size
k = write_size(PCIADR, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, PCIADR-3, sizeoffset);
}
return len;
}
//CHAR8 dataMCHC[] = {0x44,0x00,0x00,0x00};
UINT32 AddMCHC (UINT8 *dsdt, UINT32 len)
{
UINT32 i, k = 0;
UINT32 PCIADR, PCISIZE = 0; //, Size;
INT32 sizeoffset;
AML_CHUNK *root;
AML_CHUNK *device;
// AML_CHUNK *met, *met2;
// AML_CHUNK *pack;
CHAR8 *mchc;
PCIADR = GetPciDevice(dsdt, len);
if (PCIADR) {
PCISIZE = get_size(dsdt, PCIADR);
}
if (!PCISIZE) {
// DBG("wrong PCI0 address, patch MCHC will not be applied\n");
return len;
}
//Find Device MCHC by name
for (i=0x20; len >= 10 && i < len - 10; i++) {
k = CmpDev(dsdt, i, (UINT8*)"MCHC");
if (k != 0) {
DBG("device name (MCHC) found at %X, don't add!\n", k);
// break;
return len;
}
}
DBG("Start Add MCHC\n");
root = aml_create_node(NULL);
//Slice - now I don\t want to add _DSM to MCHC
//as far as I understand it works only for native ID, not FakeID.
/* if (!k) {
//device not found
device = aml_add_device(root, "MCHC");
aml_add_name(device, "_ADR");
aml_add_byte(device, 0x00);
met = aml_add_method(device, "_DSM", 4);
} else {
//if device present then check _DSM
Size = get_size(dsdt, k);
i = FindMethod(dsdt + k, Size, "_DSM");
if (i != 0) {
DBG("found MCHC with DSM, patch is not needed\n");
return len;
}
met = aml_add_method(root, "_DSM", 4);
}
*/
device = aml_add_device(root, "MCHC");
aml_add_name(device, "_ADR");
aml_add_byte(device, 0x00);
// add Method(_DSM,4,NotSerialized) for MCHC
/*
met2 = aml_add_store(met);
pack = aml_add_package(met2);
aml_add_string(pack, "device-id");
aml_add_byte_buffer(pack, dataMCHC, sizeof(dataMCHC));
aml_add_string(pack, "name");
aml_add_string(pack, "pci8086,44");
aml_add_local0(met2);
aml_add_buffer(met, dtgp_1, sizeof(dtgp_1));
// finish Method(_DSM,4,NotSerialized)
*/
aml_calculate_size(root);
mchc = (__typeof__(mchc))AllocateZeroPool(root->Size);
sizeoffset = root->Size;
aml_write_node(root, mchc, 0);
aml_destroy_node(root);
// always add on PCIX back
PCISIZE = get_size(dsdt, PCIADR);
len = move_data(PCIADR + PCISIZE, dsdt, len, sizeoffset);
CopyMem(dsdt + PCIADR + PCISIZE, mchc, sizeoffset);
// Fix PCIX size
k = write_size(PCIADR, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, PCIADR-3, sizeoffset);
FreePool(mchc);
return len;
}
UINT32 AddIMEI (UINT8 *dsdt, UINT32 len)
{
UINT32 i, k = 0;
UINT32 PCIADR, PCISIZE = 0;
INT32 sizeoffset;
AML_CHUNK *root;
AML_CHUNK *device;
AML_CHUNK *met, *met2;
AML_CHUNK *pack;
CHAR8 *imei;
UINT32 FakeID;
UINT32 FakeVen;
if (gSettings.FakeIMEI) {
FakeID = gSettings.FakeIMEI >> 16;
FakeVen = gSettings.FakeIMEI & 0xFFFF;
}
PCIADR = GetPciDevice(dsdt, len);
if (PCIADR) {
PCISIZE = get_size(dsdt, PCIADR);
}
if (!PCISIZE) {
// DBG("wrong PCI0 address, patch IMEI will not be applied\n");
return len;
}
// Find Device IMEI
if (IMEIADR1) {
for (i=0x20; len >= 10 && i < len - 10; i++) {
if (CmpAdr(dsdt, i, IMEIADR1)) {
k = devFind(dsdt, i);
if (k) {
MsgLog("device (IMEI) found at %X, don't add!\n", k);
// break;
return len;
}
}
}
}
//Find Device IMEI by name
for (i=0x20; len >= 10 && i < len - 10; i++) {
k = CmpDev(dsdt, i, (UINT8*)"IMEI");
if (k != 0) {
MsgLog("device name (IMEI) found at %X, don't add!\n", k);
return len;
}
}
MsgLog("Start Add IMEI\n");
root = aml_create_node(NULL);
device = aml_add_device(root, "IMEI");
aml_add_name(device, "_ADR");
aml_add_dword(device, IMEIADR1);
// add Method(_DSM,4,NotSerialized)
if (gSettings.FakeIMEI) {
met = aml_add_method(device, "_DSM", 4);
met2 = aml_add_store(met);
pack = aml_add_package(met2);
aml_add_string(pack, "device-id");
aml_add_byte_buffer(pack, (UINT8*)&FakeID, 4);
aml_add_string(pack, "vendor-id");
aml_add_byte_buffer(pack, (UINT8*)&FakeVen, 4);
aml_add_local0(met2);
aml_add_buffer(met, dtgp_1, sizeof(dtgp_1));
// finish Method(_DSM,4,NotSerialized)
}
aml_calculate_size(root);
imei = (__typeof__(imei))AllocateZeroPool(root->Size);
sizeoffset = root->Size;
aml_write_node(root, imei, 0);
aml_destroy_node(root);
// always add on PCIX back
len = move_data(PCIADR+PCISIZE, dsdt, len, sizeoffset);
CopyMem(dsdt+PCIADR+PCISIZE, imei, sizeoffset);
// Fix PCIX size
k = write_size(PCIADR, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, PCIADR-3, sizeoffset);
FreePool(imei);
return len;
}
UINT8 dataFW[] = {0x00,0x00,0x00,0x00};
UINT32 FIXFirewire (UINT8 *dsdt, UINT32 len)
{
UINT32 i, k;
UINT32 FirewireADR = 0, BrdADR = 0, BridgeSize, Size;
INT32 sizeoffset;
UINT32 PCIADR, PCISIZE = 0;
AML_CHUNK *met;
AML_CHUNK *root;
AML_CHUNK *stro;
AML_CHUNK *pack;
CHAR8 *firewire;
AML_CHUNK* device;
PCIADR = GetPciDevice(dsdt, len);
if (PCIADR) {
PCISIZE = get_size(dsdt, PCIADR);
}
if (!PCISIZE) {
DBG("wrong PCI0 address, patch FRWR will not be applied\n");
return len;
}
// Firewire Address
for (i = 0x20; len >=10 && i < len - 10; i++) {
if (FirewireADR1 != 0x00000000 &&
CmpAdr(dsdt, i, FirewireADR1)) {
BrdADR = devFind(dsdt, i);
if (!BrdADR) {
continue;
}
BridgeSize = get_size(dsdt, BrdADR);
if (FirewireADR2 != 0xFFFE ){
for (k = BrdADR + 9; k < BrdADR + BridgeSize; k++) {
if (CmpAdr(dsdt, k, FirewireADR2)) {
FirewireADR = devFind(dsdt, k);
if (!FirewireADR) {
continue;
}
device_name[2] = (__typeof_am__(device_name[2]))AllocateZeroPool(5);
CopyMem(device_name[2], dsdt+k, 4);
DBG("found Firewire device NAME(_ADR,0x%08X) at %X And Name is %s\n",
FirewireADR2, k, device_name[2]);
ReplaceName(dsdt + BrdADR, BridgeSize, device_name[2], "FRWR");
FirewireName = TRUE;
break;
}
}
}
break;
} // End Firewire
}
if (!BrdADR) {
DBG("Bridge for FRWR is not found\n");
return len;
}
//safe for twice fix: if _DSM already present then cancel fix
if (FirewireADR) { // bridge or device
i = FirewireADR;
} else {
i = BrdADR;
}
Size = get_size(dsdt, i);
k = FindMethod(dsdt + i, Size, "_DSM");
if (k != 0) {
k += i;
if ((dropDSM & DEV_FIREWIRE) != 0) {
Size = get_size(dsdt, k);
sizeoffset = - 1 - Size;
len = move_data(k - 1, dsdt, len, sizeoffset);
len = CorrectOuters(dsdt, len, k - 2, sizeoffset);
DBG("_DSM in FRWR already exists, dropped\n");
} else {
DBG("_DSM already exists, patch FRWR will not be applied\n");
return len;
}
}
root = aml_create_node(NULL);
device = root;
DBG("Start Firewire Fix\n");
if (!FirewireName) {
device = aml_add_device(root, "FRWR");
aml_add_name(device, "_ADR");
if (FirewireADR2) {
if (FirewireADR2 <= 0x3F) {
aml_add_byte(device, (UINT8)FirewireADR2);
} else {
aml_add_dword(device, FirewireADR2);
}
} else aml_add_byte(device, 0);
aml_add_name(device, "_GPE");
aml_add_byte(device, 0x1A);
}
met = aml_add_method(device, "_DSM", 4);
Size = get_size(dsdt, i);
k = FindMethod(dsdt + i, Size, "_SUN");
if (k == 0) {
k = FindName(dsdt + i, Size, "_SUN");
if (k == 0) {
aml_add_name(device, "_SUN");
aml_add_dword(device, SlotDevices[12].SlotID);
} else {
//we have name sun, set the number
if (dsdt[k + 4] == 0x0A) {
dsdt[k + 5] = SlotDevices[12].SlotID;
}
}
} else {
DBG("Warning: Method(_SUN) found for firewire\n");
}
stro = aml_add_store(met);
pack = aml_add_package(stro);
if (!CustProperties(pack, DEV_FIREWIRE)) {
aml_add_string(pack, "fwhub");
aml_add_byte_buffer(pack, dataFW, sizeof(dataFW));
}
aml_add_local0(stro);
aml_add_buffer(met, dtgp_1, sizeof(dtgp_1));
// finish Method(_DSM,4,NotSerialized)
aml_calculate_size(root);
firewire = (__typeof__(firewire))AllocateZeroPool(root->Size);
sizeoffset = root->Size;
aml_write_node(root, firewire, 0);
aml_destroy_node(root);
// move data to back for add patch
Size = get_size(dsdt, i);
if (!Size) {
FreePool(firewire);
return len;
}
k = i + Size;
len = move_data(k, dsdt, len, sizeoffset);
CopyMem(dsdt + k, firewire, sizeoffset);
// Fix Device size
k = write_size(i, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, i-3, sizeoffset);
FreePool(firewire);
return len;
}
UINT32 AddHDEF (UINT8 *dsdt, UINT32 len, CHAR8* OSVersion)
{
UINT32 i, k;
UINT32 PCIADR, PCISIZE = 0;
INT32 sizeoffset;
UINT32 HDAADR = 0, Size;
AML_CHUNK* root;
// AML_CHUNK* met, *met2;
AML_CHUNK* device;
// AML_CHUNK* pack;
CHAR8 *hdef;
PCIADR = GetPciDevice(dsdt, len);
if (PCIADR) {
PCISIZE = get_size(dsdt, PCIADR);
}
if (!PCISIZE) return len; //what is the bad DSDT ?!
DBG("Start HDA Fix\n");
// len = DeleteDevice("AZAL", dsdt, len);
// HDA Address
for (i=0x20; len >= 10 && i < len - 10; i++) {
if (HDAADR1 != 0x00000000 && HDAFIX &&
CmpAdr(dsdt, i, HDAADR1)) {
HDAADR = devFind(dsdt, i);
if (!HDAADR) {
continue;
}
// BridgeSize = get_size(dsdt, HDAADR);
device_name[4] = (__typeof_am__(device_name[4]))AllocateZeroPool(5);
CopyMem(device_name[4], dsdt+i, 4);
DBG("found HDA device NAME(_ADR,0x%08X) And Name is %s\n",
HDAADR1, device_name[4]);
ReplaceName(dsdt, len, device_name[4], "HDEF");
HDAFIX = FALSE;
break;
} // End HDA
}
if (HDAADR) { // bridge or device
i = HDAADR;
Size = get_size(dsdt, i);
k = FindMethod(dsdt + i, Size, "_DSM");
if (k != 0) {
k += i;
if ((dropDSM & DEV_HDA) != 0) {
Size = get_size(dsdt, k);
sizeoffset = - 1 - Size;
len = move_data(k - 1, dsdt, len, sizeoffset);
len = CorrectOuters(dsdt, len, k - 2, sizeoffset);
DBG("_DSM in HDA already exists, dropped\n");
} else {
DBG("_DSM already exists, patch HDA will not be applied\n");
return len;
}
}
}
root = aml_create_node(NULL);
if (HDAFIX) {
MsgLog("Start Add Device HDEF\n");
device = aml_add_device(root, "HDEF");
aml_add_name(device, "_ADR");
aml_add_dword(device, HDAADR1);
// add Method(_DSM,4,NotSerialized)
/* met = aml_add_method(device, "_DSM", 4);
} else {
met = aml_add_method(root, "_DSM", 4);
}
met2 = aml_add_store(met);
pack = aml_add_package(met2);
if (gSettings.UseIntelHDMI) {
aml_add_string(pack, "hda-gfx");
aml_add_string_buffer(pack, "onboard-1");
}
if (!CustProperties(pack, DEV_HDA)) {
if ((OSVersion != NULL && AsciiOSVersionToUint64(OSVersion) < AsciiOSVersionToUint64("10.8")) || (gSettings.HDALayoutId > 0)) {
aml_add_string(pack, "layout-id");
aml_add_byte_buffer(pack, (CHAR8*)&HDAlayoutId, 4);
}
aml_add_string(pack, "MaximumBootBeepVolume");
aml_add_byte_buffer(pack, (CHAR8*)&dataBuiltin1[0], 1);
if (gSettings.AFGLowPowerState) {
aml_add_string(pack, "AFGLowPowerState");
aml_add_byte_buffer(pack, Yes, 4);
}
aml_add_string(pack, "PinConfigurations");
aml_add_byte_buffer(pack, 0, 0);//data, sizeof(data));
}
aml_add_local0(met2);
aml_add_buffer(met, dtgp_1, sizeof(dtgp_1));
// finish Method(_DSM,4,NotSerialized)
*/
}
aml_calculate_size(root);
hdef = (__typeof__(hdef))AllocateZeroPool(root->Size);
sizeoffset = root->Size;
aml_write_node(root, hdef, 0);
aml_destroy_node(root);
if (!HDAFIX) { // bridge or device
i = HDAADR;
} else {
i = PCIADR;
}
Size = get_size(dsdt, i);
// move data to back for add patch
k = i + Size;
len = move_data(k, dsdt, len, sizeoffset);
CopyMem(dsdt + k, hdef, sizeoffset);
// Fix Device size
k = write_size(i, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, i-3, sizeoffset);
FreePool(hdef);
return len;
}
UINT32 FIXUSB (UINT8 *dsdt, UINT32 len)
{
UINT32 i, j, k;
UINT32 Size, size1, size2, size3; //, size4;
UINT32 adr=0, adr1=0;
INT32 sizeoffset;
AML_CHUNK* root;
AML_CHUNK* root1;
AML_CHUNK* met;
AML_CHUNK* pack;
AML_CHUNK *met1, *met2;
AML_CHUNK* pack1;
CHAR8 *USBDATA1;
CHAR8 *USBDATA2;
CHAR8 *USBDATA3;
// CHAR8 *USBDATA4;
DBG("Start USB Fix\n");
//DBG("len = 0x%08X\n", len);
root = aml_create_node(NULL);
root1 = aml_create_node(NULL);
// add Method(_DSM,4,NotSerialized) for USB
met = aml_add_method(root, "_DSM", 4);
met2 = aml_add_store(met);
pack = aml_add_package(met2);
if (!CustProperties(pack, DEV_USB)) {
aml_add_string(pack, "device-id");
aml_add_byte_buffer(pack, (/* CONST*/ UINT8*)&USBID[0], 4);
aml_add_string(pack, "built-in");
aml_add_byte_buffer(pack, dataBuiltin, sizeof(dataBuiltin));
aml_add_string(pack, "device_type");
if (USBIntel) {
aml_add_string_buffer(pack, "UHCI");
} else if (USBNForce) {
aml_add_string_buffer(pack, "OHCI");
}
if (gSettings.InjectClockID) {
aml_add_string(pack, "AAPL,clock-id");
aml_add_byte_buffer(pack, dataBuiltin, 1);
}
}
aml_add_local0(met2);
aml_add_buffer(met, dtgp_1, sizeof(dtgp_1));
// finish Method(_DSM,4,NotSerialized)
aml_calculate_size(root);
USBDATA1 = (__typeof__(USBDATA1))AllocateZeroPool(root->Size);
size1 = root->Size;
// DBG("USB1 code size = 0x%08X\n", size1);
aml_write_node(root, USBDATA1, 0);
aml_destroy_node(root);
// add Method(_DSM,4,NotSerialized) for USB2
met1 = aml_add_method(root1, "_DSM", 4);
met2 = aml_add_store(met1);
pack1 = aml_add_package(met2);
if (!CustProperties(pack, DEV_USB)) {
aml_add_string(pack1, "device-id");
aml_add_byte_buffer(pack1, (/* CONST*/ UINT8*)&USBID[0], 4);
aml_add_string(pack1, "built-in");
aml_add_byte_buffer(pack1, dataBuiltin, sizeof(dataBuiltin));
aml_add_string(pack1, "device_type");
aml_add_string_buffer(pack1, "EHCI");
if (gSettings.InjectClockID) {
aml_add_string(pack1, "AAPL,clock-id");
aml_add_byte_buffer(pack1, dataBuiltin, sizeof(dataBuiltin));
}
if (USBIntel) {
aml_add_string(pack1, "AAPL,current-available");
if (gSettings.HighCurrent) {
aml_add_word(pack1, 0x0834);
} else {
aml_add_word(pack1, 0x05DC);
}
aml_add_string(pack1, "AAPL,current-extra");
if (gSettings.HighCurrent) {
aml_add_word(pack1, 0x0C80);
} else {
aml_add_word(pack1, 0x03E8);
}
aml_add_string(pack1, "AAPL,current-in-sleep");
aml_add_word(pack1, 0x0BB8);
// aml_add_string(pack1, "AAPL,device-internal");
// aml_add_byte(pack1, 0x02);
} else if (USBNForce) {
aml_add_string(pack1, "AAPL,current-available");
aml_add_word(pack1, 0x04B0);
aml_add_string(pack1, "AAPL,current-extra");
aml_add_word(pack1, 0x02BC);
aml_add_string(pack1, "AAPL,current-in-sleep");
aml_add_word(pack1, 0x03E8);
}
}
//new systems has new strings
/*
Method (_DSM, 4, NotSerialized) // _DSM: Device-Specific Method
{
Store (Package (0x08)
{
"kUSBSleepPowerSupply",
0x13EC,
"kUSBSleepPortCurrentLimit",
0x0834,
"kUSBWakePowerSupply",
0x13EC,
"kUSBWakePortCurrentLimit",
0x0834
}, Local0)
DTGP (Arg0, Arg1, Arg2, Arg3, RefOf (Local0))
Return (Local0)
}
*/
aml_add_byte_buffer(pack1, dataBuiltin, sizeof(dataBuiltin));
aml_add_local0(met2);
aml_add_buffer(met1, dtgp_1, sizeof(dtgp_1));
// finish Method(_DSM,4,NotSerialized)
aml_calculate_size(root1);
USBDATA2 = (__typeof__(USBDATA2))AllocateZeroPool(root1->Size);
size2 = root1->Size;
// DBG("USB2 code size = 0x%08X\n", size2);
aml_write_node(root1, USBDATA2, 0);
aml_destroy_node(root1);
//NFORCE_USB_START -- already done Intel or NForce same USBDATA2
/* aml_calculate_size(root1);
USBDATA4 = (__typeof__(USBDATA4))AllocateZeroPool(root1->Size);
size4 = root1->Size;
DBG("USB OHCI code size = 0x%08X\n", size4);
aml_write_node(root1, USBDATA4, 0);
aml_destroy_node(root1); */
//NFORCE_USB_END
// add Method(_DSM,4,NotSerialized) for USB3
root1 = aml_create_node(NULL);
met1 = aml_add_method(root1, "_DSM", 4);
met2 = aml_add_store(met1);
pack1 = aml_add_package(met2);
if (!CustProperties(pack, DEV_USB)) {
aml_add_string(pack1, "device-id");
aml_add_byte_buffer(pack1, (/* CONST*/ UINT8*)&USBID[0], 4);
aml_add_string(pack1, "built-in");
aml_add_byte_buffer(pack1, dataBuiltin, sizeof(dataBuiltin));
aml_add_string(pack1, "device_type");
aml_add_string_buffer(pack1, "XHCI");
if (gSettings.InjectClockID) {
aml_add_string(pack1, "AAPL,clock-id");
aml_add_byte_buffer(pack1, dataBuiltin, sizeof(dataBuiltin));
}
aml_add_string(pack1, "AAPL,current-available");
aml_add_word(pack1, 0x0834);
aml_add_string(pack1, "AAPL,current-extra");
aml_add_word(pack1, 0x0A8C);
aml_add_string(pack1, "AAPL,current-in-sleep");
aml_add_word(pack1, 0x0A8C);
aml_add_string(pack1, "AAPL,max-port-current-in-sleep");
aml_add_word(pack1, 0x0834);
aml_add_string(pack1, "AAPL,device-internal");
aml_add_byte(pack1, 0x00);
}
aml_add_byte_buffer(pack1, dataBuiltin, sizeof(dataBuiltin));
aml_add_local0(met2);
aml_add_buffer(met1, dtgp_1, sizeof(dtgp_1));
// finish Method(_DSM,4,NotSerialized)
aml_calculate_size(root1);
USBDATA3 = (__typeof__(USBDATA3))AllocateZeroPool(root1->Size);
size3 = root1->Size;
// DBG("USB3 code size = 0x%08X\n", size3);
aml_write_node(root1, USBDATA3, 0);
aml_destroy_node(root1);
if (usb > 0) {
for (i = 0; i < usb; i++) {
INTN XhciCount = 1;
INTN EhciCount = 0;
// find USB adr
for (j = 0x20; len >= 4 && j < len - 4; j++) {
if (CmpAdr(dsdt, j, USBADR[i])) { //j+4 -> _ADR
XhciName = FALSE;
UsbName[i] = (__typeof_am__(UsbName[i]))AllocateZeroPool(5);
// DBG("found USB at 0x%X\n", j);
adr1 = devFind(dsdt, j + 2);
if (!adr1) {
continue;
}
Size = get_size(dsdt, adr1); //bridgesize
DBG("USB bridge[%X] at %X, size = %X\n", USBADR[i], adr1, Size);
if (USBADR2[i] != 0xFFFE ){
for (k = adr1 + 9; k < adr1 + Size; k++) {
if (CmpAdr(dsdt, k, USBADR2[i])) {
adr = devFind(dsdt, k);
if (!adr) {
continue;
}
device_name[10] = (__typeof_am__(device_name[10]))AllocateZeroPool(5);
CopyMem(device_name[10], dsdt+k, 4);
DBG("found USB device [%08X:%X] at %X and Name was %s ->",
USBADR[i], USBADR2[i], k, device_name[10]);
if (USB30[i]) {
if (gSettings.NameXH00) {
AsciiSPrint(UsbName[i], 5, "XH%02X", XhciCount++);
} else {
AsciiSPrint(UsbName[i], 5, "XHC%01X", XhciCount++);
}
} else if (USB20[i]) {
if (gSettings.NameEH00) {
AsciiSPrint(UsbName[i], 5, "EH%02X", EhciCount++);
} else {
AsciiSPrint(UsbName[i], 5, "EHC%01X", EhciCount++);
}
} else {
AsciiSPrint(UsbName[i], 5, "USB%d", i);
}
DBG(" %s\n", UsbName[i]);
ReplaceName(dsdt + adr1, Size, device_name[10], UsbName[i]);
XhciName = TRUE;
break;
}
}
}
if (!XhciName) {
adr = adr1;
}
Size = get_size(dsdt, adr);
k = FindMethod(dsdt + adr, Size, "_DSM");
if (k != 0) {
k += adr;
//here we want to check who is the master of the _DSM
adr1 = devFind(dsdt, k);
if (adr1 == adr) {
if ((dropDSM & DEV_USB) != 0) {
Size = get_size(dsdt, k);
if (!Size) {
continue;
}
sizeoffset = - 1 - Size;
len = move_data(k - 1, dsdt, len, sizeoffset);
len = CorrectOuters(dsdt, len, k - 2, sizeoffset);
DBG("_DSM in USB already exists, dropped by 0x%X\n", sizeoffset);
} else {
DBG("_DSM already exists, patch USB will not be applied\n");
continue;
}
} else {
DBG(" found slave _DSM, skip\n");
continue;
}
}
//UINT32 k = (adr > 0x3F)?1:0;
/*
14 45 06 5F 44 53 4D 04 70 12 4F 04 08 0D 64 65
76 69 63 65 2D 69 64 00 11 07 0A 04 31 1E 00 00
0D 62 75 69 6C 74 2D 69 6E 00 11 04 0A 01 00 0D
64 65 76 69 63 65 5F 74 79 70 65 00 11 08 0A 04
55 48 43 49 00 0D 41 41 50 4C 2C 63 6C 6F 63 6B
2D 69 64 00 11 04 0A 01 00 60 44 54 47 50 68 69
6A 6B 71 60 A4 60
*/
if (USB30[i]) {
if ((USBDATA3[25] == 0x0A) && (USBDATA3[26] == 0x04)) {
k = 27;
} else if ((USBDATA3[26] == 0x0A) && (USBDATA3[27] == 0x04)) {
k = 28;
} else {
continue;
}
if (gSettings.FakeXHCI) {
USBID[i] = gSettings.FakeXHCI >> 16;
}
CopyMem(USBDATA3+k, (VOID*)&USBID[i], 4);
sizeoffset = size3;
} else if (USB20[i]) {
if ((USBDATA2[25] == 0x0A) && (USBDATA2[26] == 0x04)) {
k = 27;
} else if ((USBDATA2[26] == 0x0A) && (USBDATA2[27] == 0x04)) {
k = 28;
} else {
continue;
}
CopyMem(USBDATA2+k, (VOID*)&USBID[i], 4);
sizeoffset = size2;
} else {
if ((USBDATA1[25] == 0x0A) && (USBDATA1[26] == 0x04)) {
k = 27;
} else if ((USBDATA1[26] == 0x0A) && (USBDATA1[27] == 0x04)) {
k = 28;
} else {
continue;
}
CopyMem(USBDATA1+k, (VOID*)&USBID[i], 4);
sizeoffset = size1;
}
len = move_data(adr + Size, dsdt, len, sizeoffset);
if (USB30[i]) {
CopyMem(dsdt + adr + Size, USBDATA3, sizeoffset);
} else if (USB20[i]) {
CopyMem(dsdt + adr + Size, USBDATA2, sizeoffset);
} else {
CopyMem(dsdt + adr + Size, USBDATA1, sizeoffset);
}
// Fix Device USB size
k = write_size(adr, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, adr-3, sizeoffset);
break;
}
//NFORCE_USB_START
else if (CmpAdr(dsdt, j, USBADR3[i])) {
UsbName[i] = (__typeof_am__(UsbName[i]))AllocateZeroPool(5);
CopyMem(UsbName[i], dsdt+j, 4);
adr1 = devFind(dsdt, j);
if (!adr1) {
continue;
}
adr = get_size(dsdt, adr1);
//UINT32 k = (adr > 0x3F)?1:0;
/*
14 45 06 5F 44 53 4D 04 70 12 4F 04 08 0D 64 65
76 69 63 65 2D 69 64 00 11 07 0A 04 31 1E 00 00
0D 62 75 69 6C 74 2D 69 6E 00 11 04 0A 01 00 0D
64 65 76 69 63 65 5F 74 79 70 65 00 11 08 0A 04
55 48 43 49 00 0D 41 41 50 4C 2C 63 6C 6F 63 6B
2D 69 64 00 11 04 0A 01 00 60 44 54 47 50 68 69
6A 6B 71 60 A4 60
*/
if (USB40[i]) {
if ((USBDATA2[25] == 0x0A) && (USBDATA2[26] == 0x04)) {
k = 27;
} else if ((USBDATA2[26] == 0x0A) && (USBDATA2[27] == 0x04)) {
k = 28;
} else {
continue;
}
CopyMem(USBDATA2+k, (VOID*)&USBID[i], 4);
sizeoffset = size2;
} else {
if ((USBDATA1[25] == 0x0A) && (USBDATA1[26] == 0x04)) {
k = 27;
} else if ((USBDATA1[26] == 0x0A) && (USBDATA1[27] == 0x04)) {
k = 28;
} else {
continue;
}
CopyMem(USBDATA1+k, (VOID*)&USBID[i], 4);
sizeoffset = size1;
}
len = move_data(adr1+adr, dsdt, len, sizeoffset);
if (USB40[i]) {
CopyMem(dsdt+adr1+adr, USBDATA2, sizeoffset);
} else {
CopyMem(dsdt+adr1+adr, USBDATA1, sizeoffset);
}
// Fix Device USB size
k = write_size(adr1, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, adr1-3, sizeoffset);
break;
}
//NFORCE_USB_END
}
}
}
FreePool(USBDATA1);
FreePool(USBDATA2);
FreePool(USBDATA3);
// FreePool(USBDATA4);
return len;
}
UINT8 DevIDE[] = {0x9E,0x26,0x00,0x00};
UINT8 VenIDE[] = {0x86,0x80,0x00,0x00};
UINT32 FIXIDE (UINT8 *dsdt, UINT32 len)
{
UINT32 i, k;
UINT32 j;
UINT32 IDEADR = 0, BridgeSize = 0, Size;
INT32 sizeoffset;
AML_CHUNK *root;
AML_CHUNK *device;
CHAR8 *ide;
BOOLEAN PATAFIX=TRUE;
AML_CHUNK *met, *met2;
AML_CHUNK *pack;
AML_CHUNK *device1;
AML_CHUNK *device2;
if (!IDEADR1) return len;
for (i=0x20; len >= 10 && i < len - 10; i++) {
if (CmpAdr(dsdt, i, IDEADR1)) {
DBG("Found IDEADR1=%X at %X\n", IDEADR1, i);
IDEADR = devFind(dsdt, i);
if (!IDEADR) {
continue;
}
BridgeSize = get_size(dsdt, IDEADR);
if (BridgeSize) break;
} // End IDE
}
if (!BridgeSize) return len;
DBG("Start IDE Fix\n");
// find Name(_ADR, Zero) if yes, don't need to inject PATA name
for (j=IDEADR+9; j<IDEADR+BridgeSize; j++)
{
if (CmpAdr(dsdt, j, 0))
{
PATAFIX = FALSE;
break;
}
}
if (IDEADR) { // bridge or device
i = IDEADR;
Size = get_size(dsdt, i);
k = FindMethod(dsdt + i, Size, "_DSM");
if (k != 0) {
k += i;
if ((dropDSM & DEV_IDE) != 0) {
Size = get_size(dsdt, k);
sizeoffset = - 1 - Size;
len = move_data(k - 1, dsdt, len, sizeoffset);
len = CorrectOuters(dsdt, len, k - 2, sizeoffset);
DBG("_DSM in IDE already exists, dropped\n");
} else {
DBG("_DSM already exists, patch IDE will not be applied\n");
return len;
}
}
}
root = aml_create_node(NULL);
device = root;
if (PATAFIX) {
device = aml_add_device(root, "ICHX");
aml_add_name(device, "_ADR");
if (IDEADR2 < 0x3F) {
aml_add_byte(device, (UINT8)IDEADR2);
} else {
aml_add_dword(device, IDEADR2);
}
met = aml_add_method(device, "_DSM", 4);
met2 = aml_add_store(met);
pack = aml_add_package(met2);
if (!CustProperties(pack, DEV_IDE)) {
aml_add_string(pack, "device-id");
aml_add_byte_buffer(pack, DevIDE, sizeof(DevIDE));
aml_add_string(pack, "vendor-id");
aml_add_byte_buffer(pack, VenIDE, sizeof(VenIDE));
aml_add_string(pack, "name");
aml_add_string(pack, "pci8086,269e");
aml_add_string(pack, "IOName");
aml_add_string(pack, "pci8086,269e");
aml_add_local0(met2);
aml_add_buffer(met, dtgp_1, sizeof(dtgp_1));
device1 = aml_add_device(device, "PRIM");
aml_add_name(device1, "_ADR");
aml_add_byte(device1, 0x00);
device2 = aml_add_device(device1, "MAST");
aml_add_name(device2, "_ADR");
aml_add_byte(device2, 0x00);
device2 = aml_add_device(device1, "SLAV");
aml_add_name(device2, "_ADR");
aml_add_byte(device2, 0x01);
// Marvell only one connected cable
//AML_CHUNK* device3 = aml_add_device(device, "SLAB");
//aml_add_name(device3, "_ADR");
//aml_add_byte(device3, 0x00);
//AML_CHUNK* device4 = aml_add_device(device3, "MAST");
//aml_add_name(device4, "_ADR");
//aml_add_byte(device4, 0x00);
//device4 = aml_add_device(device3, "SLAV");
//aml_add_name(device4, "_ADR");
//aml_add_byte(device4, 0x01);
aml_add_string(met, "empty");
aml_add_byte(met, 0);
}
} else {
met = aml_add_method(root, "_DSM", 4);
met2 = aml_add_store(met);
pack = aml_add_package(met2);
if (!CustProperties(pack, DEV_IDE)) {
aml_add_string(pack, "device-id");
aml_add_byte_buffer(pack, DevIDE, sizeof(DevIDE));
aml_add_string(pack, "vendor-id");
aml_add_byte_buffer(pack, VenIDE, sizeof(VenIDE));
aml_add_string(pack, "name");
aml_add_string(pack, "pci8086,269e");
aml_add_string(pack, "IOName");
aml_add_string(pack, "pci8086,269e");
aml_add_string(met, "empty");
aml_add_byte(met, 0);
aml_add_local0(met2);
aml_add_buffer(met, dtgp_1, sizeof(dtgp_1));
}
}
// finish Method(_DSM,4,NotSerialized)
aml_calculate_size(root);
ide = (__typeof__(ide))AllocateZeroPool(root->Size);
sizeoffset = root->Size;
aml_write_node(root, ide, 0);
aml_destroy_node(root);
// move data to back for add DSM
j = IDEADR + BridgeSize;
len = move_data(j, dsdt, len, sizeoffset);
CopyMem(dsdt+j, ide, sizeoffset);
// Fix Device ide size
k = write_size(IDEADR, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, IDEADR-3, sizeoffset);
//add patafix
sizeoffset = sizeof(patafix);
// DBG("add patafix size=%X\n", sizeoffset);
i = get_size(dsdt, IDEADR);
j = IDEADR + i;
len = move_data(j, dsdt, len, sizeoffset);
CopyMem(dsdt+j, patafix, sizeoffset);
k = write_size(IDEADR, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, IDEADR-3, sizeoffset);
FreePool(ide);
return len;
}
//CHAR8 DevSATA[] = {0x81, 0x26, 0x00, 0x00};
UINT32 FIXSATAAHCI (UINT8 *dsdt, UINT32 len)
{
UINT32 i, k;
UINT32 SATAAHCIADR = 0, BridgeSize = 0, Size;
INT32 sizeoffset;
AML_CHUNK* root;
AML_CHUNK* met, *met2;
AML_CHUNK* pack;
CHAR8 *sata;
UINT32 FakeID;
UINT32 FakeVen;
if (gSettings.FakeSATA) {
FakeID = gSettings.FakeSATA >> 16;
FakeVen = gSettings.FakeSATA & 0xFFFF;
}
if (!SATAAHCIADR1) return len;
for (i=0x20; len >= 10 && i < len - 10; i++) {
if (CmpAdr(dsdt, i, SATAAHCIADR1)) {
// DBG("Found SATAAHCIADR1=%X at %X\n", SATAAHCIADR1, i);
SATAAHCIADR = devFind(dsdt, i);
if (!SATAAHCIADR) {
continue;
}
BridgeSize = get_size(dsdt, SATAAHCIADR);
if (BridgeSize) break;
}
}
if (!BridgeSize) return len;
if (SATAAHCIADR) { // bridge or device
i = SATAAHCIADR;
Size = get_size(dsdt, i);
k = FindMethod(dsdt + i, Size, "_DSM");
if (k != 0) {
k += i;
if ((dropDSM & DEV_SATA) != 0) {
Size = get_size(dsdt, k);
sizeoffset = - 1 - Size;
len = move_data(k - 1, dsdt, len, sizeoffset);
len = CorrectOuters(dsdt, len, k - 2, sizeoffset);
DBG("_DSM in SATA already exists, dropped\n");
} else {
DBG("_DSM already exists, patch SATA will not be applied\n");
return len;
}
}
}
DBG("Start SATA AHCI Fix\n");
root = aml_create_node(NULL);
// add Method(_DSM,4,NotSerialized)
if (gSettings.FakeSATA || !gSettings.NoDefaultProperties) {
met = aml_add_method(root, "_DSM", 4);
met2 = aml_add_store(met);
pack = aml_add_package(met2);
if (gSettings.FakeSATA) {
aml_add_string(pack, "device-id");
aml_add_byte_buffer(pack, (UINT8*)&FakeID, 4);
aml_add_string(pack, "vendor-id");
aml_add_byte_buffer(pack, (UINT8*)&FakeVen, 4);
}
if (!CustProperties(pack, DEV_SATA) &&
!gSettings.NoDefaultProperties &&
!gSettings.FakeSATA) {
aml_add_string(pack, "empty");
aml_add_byte(pack, 0);
}
aml_add_local0(met2);
aml_add_buffer(met, dtgp_1, sizeof(dtgp_1));
}
// finish Method(_DSM,4,NotSerialized)
aml_calculate_size(root);
sata = (__typeof__(sata))AllocateZeroPool(root->Size);
sizeoffset = root->Size;
aml_write_node(root, sata, 0);
aml_destroy_node(root);
// move data to back for add DSM
BridgeSize = get_size(dsdt, SATAAHCIADR);
i = SATAAHCIADR + BridgeSize;
len = move_data(i, dsdt, len, sizeoffset);
CopyMem(dsdt + i, sata, sizeoffset);
// Fix Device SATA size
k = write_size(SATAAHCIADR, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, SATAAHCIADR-3, sizeoffset);
FreePool(sata);
return len;
}
//CHAR8 DevSATA0[] = {0x80, 0x26, 0x00, 0x00};
UINT32 FIXSATA (UINT8 *dsdt, UINT32 len)
{
UINT32 i, k;
UINT32 SATAADR = 0, BridgeSize = 0, Size;
INT32 sizeoffset;
AML_CHUNK* root;
AML_CHUNK* met, *met2;
AML_CHUNK* pack;
CHAR8 *sata;
UINT32 FakeID;
UINT32 FakeVen;
if (gSettings.FakeSATA) {
FakeID = gSettings.FakeSATA >> 16;
FakeVen = gSettings.FakeSATA & 0xFFFF;
}
if (!SATAADR1) return len;
for (i=0x20; len >= 10 && i < len - 10; i++) {
if (CmpAdr(dsdt, i, SATAADR1)) {
// DBG("Found SATAAHCIADR1=%X at %X\n", SATAAHCIADR1, j);
SATAADR = devFind(dsdt, i);
if (!SATAADR) {
continue;
}
BridgeSize = get_size(dsdt, SATAADR);
if (BridgeSize) break;
} // End IDE
}
if (!BridgeSize) return len;
if (SATAADR) { // bridge or device
i = SATAADR;
Size = get_size(dsdt, i);
k = FindMethod(dsdt + i, Size, "_DSM");
if (k != 0) {
k += i;
if ((dropDSM & DEV_SATA) != 0) {
Size = get_size(dsdt, k);
sizeoffset = - 1 - Size;
len = move_data(k - 1, dsdt, len, sizeoffset);
len = CorrectOuters(dsdt, len, k - 2, sizeoffset);
DBG("_DSM in SATA already exists, dropped\n");
} else {
DBG("_DSM already exists, patch SATA will not be applied\n");
return len;
}
}
}
DBG("Start SATA Fix\n");
root = aml_create_node(NULL);
// add Method(_DSM,4,NotSerialized)
if (gSettings.FakeSATA || !gSettings.NoDefaultProperties) {
met = aml_add_method(root, "_DSM", 4);
met2 = aml_add_store(met);
pack = aml_add_package(met2);
if (gSettings.FakeSATA) {
aml_add_string(pack, "device-id");
aml_add_byte_buffer(pack, (UINT8*)&FakeID, 4);
aml_add_string(pack, "vendor-id");
aml_add_byte_buffer(pack, (UINT8*)&FakeVen, 4);
}
if (!CustProperties(pack, DEV_SATA) &&
!gSettings.NoDefaultProperties &&
!gSettings.FakeSATA) {
aml_add_string(pack, "empty");
aml_add_byte(pack, 0);
}
aml_add_local0(met2);
aml_add_buffer(met, dtgp_1, sizeof(dtgp_1));
}
// finish Method(_DSM,4,NotSerialized)
aml_calculate_size(root);
sata = (__typeof__(sata))AllocateZeroPool(root->Size);
sizeoffset = root->Size;
aml_write_node(root, sata, 0);
aml_destroy_node(root);
// move data to back for add DSM
BridgeSize = get_size(dsdt, SATAADR);
i = SATAADR + BridgeSize;
len = move_data(i, dsdt, len, sizeoffset);
CopyMem(dsdt + i, sata, sizeoffset);
// Fix Device SATA size
k = write_size(SATAADR, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, SATAADR-3, sizeoffset);
FreePool(sata);
return len;
}
/*
UINT32 FIXCPU1 (UINT8 *dsdt, UINT32 len)
{
UINT32 i, j;
UINT32 count=0;
UINT32 pradr=0;
UINT32 prsize=0, size=0;
UINT32 prsize1=0;
INT32 offset, sizeoffset;
DBG("Start CPUS=1 Fix\n");
DBG("len = 0x%08X\n", len);
// find _PR_ and get PR size
for (i=0x20; i<len-4; i++) {
if (dsdt[i] == '_' && dsdt[i+1] == 'P' && dsdt[i+2] == 'R' && dsdt[i+3] == '_') {
DBG("Found _PR_\n");
for (j=0; j<10; j++) {
if (dsdt[i-j] == 0x10) {
prsize = get_size(dsdt, i-j+1);
if(!prsize) continue;
prsize1 = prsize;
pradr = i-j+1;
// size > 0x3F there should be had P_states code so don't fix
if (prsize > 0x3F) return len;
DBG("_PR_ adr = 0x%08X size = 0x%08X\n", pradr, prsize);
break;
}
}
break;
}
}
sizeoffset = 9;
// find alias
for (i=pradr; i<prsize1; i++) {
if (dsdt[i] == 0x5B && dsdt[i+1] == 0x83) {
size = get_size(dsdt, i+2);
DBG("OP size = 0x%08X\n", size);
// if OP name not CPUX.... need add alias in OP back
offset = i + 3 + (dsdt[i+2] >> 6);
if (dsdt[offset] == '\\') offset = i + 8 + (dsdt[i+7] >> 6);
if (dsdt[i+2+size] != 0x06 && dsdt[offset] != 'C' && dsdt[offset+1] != 'P' && dsdt[offset+2] != 'U') {
DBG("Found alias CPU.\n");
len = move_data(i+2+size, dsdt, len, sizeoffset);
dsdt[i+2+size] = 0x06;
dsdt[i+3+size] = dsdt[i+2];
dsdt[i+4+size] = dsdt[i+3];
dsdt[i+5+size] = dsdt[i+4];
dsdt[i+6+size] = dsdt[i+5];
dsdt[i+7+size] = 'C';
dsdt[i+8+size] = 'P';
dsdt[i+9+size] = 'U';
dsdt[i+10+size] = dsdt[i+5];
j = write_size(pradr, dsdt, len, sizeoffset);
sizeoffset += j;
len += j;
count++;
continue;
}
}
}
DBG("return len=%X\n", len);
return len;
}
*/
UINT32 FIXWAK (UINT8 *dsdt, UINT32 len, EFI_ACPI_2_0_FIXED_ACPI_DESCRIPTION_TABLE* fadt)
{
UINT32 i, j, k;
UINT32 wakadr=0;
UINT32 waksize=0;
UINT32 sizeoffset = 0, sizeoffset2 = 0;
// UINT16 PM30 = 0x430; //default
BOOLEAN ReturnFound = FALSE;
DBG("Start _WAK Return Fix\n");
for (i = 0x24; len >= 5 && i < len - 5; i++) {
if(dsdt[i] == '_' && dsdt[i+1] == 'W' && dsdt[i+2] == 'A' && dsdt[i+3] == 'K') {
for (j=0; j<10; j++) {
if(dsdt[i-j] == 0x14) { //Method _WAK found
wakadr = i-j+1;
waksize = get_size(dsdt, wakadr);
if (!waksize) {
continue;
}
//DBG( "_WAK adr = 0x%08X, size = 0x%08X\n", wakadr, waksize);
for (k=0; k<waksize; k++) {
if (dsdt[i+k] == 0xA4) { // Return
DBG( "_WAK Method find return data, don't need to patch.\n");
// return len;
ReturnFound = TRUE;
}
}
//Slice - this patch disabled as useless
/* if (gSettings.SlpWak) {
DBG(" add SLP_SMI_EN=0 into _WAK\n");
PM30 = (UINT16)fadt->Pm1aEvtBlk + 0x30;
sizeoffset = sizeof(wakslp1) + 3 + sizeof(wakslp2);
len = move_data(i + 5, dsdt, len, sizeoffset);
CopyMem(dsdt + i + 5, wakslp1, sizeof(wakslp1));
k = i + 5 + sizeof(wakslp1);
dsdt[k++] = 0x0B;
dsdt[k++] = PM30 & 0xFF;
dsdt[k++] = PM30 >> 8;
CopyMem(dsdt + k, wakslp2, sizeof(wakslp2));
k = write_size(wakadr, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
} */
sizeoffset = sizeof(waksecur);
len = move_data(i + 5, dsdt, len, sizeoffset);
CopyMem(dsdt + i + 5, waksecur, sizeof(waksecur));
k = write_size(wakadr, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
if (!ReturnFound) {
DBG( "_WAK Method need return data, will patch it.\n");
waksize = get_size(dsdt, wakadr);
if (!waksize) {
continue;
}
sizeoffset2 = sizeof(wakret);
len = move_data(wakadr + waksize, dsdt, len, sizeoffset2);
CopyMem(dsdt + wakadr + waksize, wakret, sizeoffset2);
k = write_size(wakadr, dsdt, len, sizeoffset2);
sizeoffset += k + sizeoffset2;
len += k;
}
len = CorrectOuters(dsdt, len, wakadr-2, sizeoffset);
break;
}
}
break;
}
}
DBG("return len=%X\n", len);
return len;
}
#if 0
UINT32 FIXGPE (UINT8 *dsdt, UINT32 len)
{
UINT32 i, j, k, l, m, n;
UINT32 gpeadr=0;
// UINT32 gpesize=0;
UINT32 pwrbadr=0;
UINT32 pwrbsize=0;
UINT32 usbcount=0;
UINT32 PWRBADR = 0;
// UINT32 adr=0;
INT32 offset=0;
INT32 sizeoffset;
// BOOLEAN pwrbfix = FALSE;
// BOOLEAN usbpwrb = FALSE;
// BOOLEAN foundpwrb = FALSE;
sizeoffset = sizeof(pwrb);
if (!PWRBADR) {
return len;
}
DBG("Start _GPE device remove error Fix\n");
//DBG("len = 0x%08X\n", len);
for (i=0; i<len-10; i++)
{ //what kind of nonsense here!
if(dsdt[i] == '_' && dsdt[i+1] == 'L' && (dsdt[i-2] == 0x14 || dsdt[i-3] == 0x14 || dsdt[i-4] == 0x14 || dsdt[i-5] == 0x14)) {
for (j=0; j<10; j++) {
if(dsdt[i-j] == 0x14) {
pwrbsize = get_size(dsdt, i-j+1);
pwrbadr = i-j+1;
//DBG( "_LXX adr = 0x%08X, size = 0x%08X\n", pwrbadr, pwrbsize);
for (k=pwrbadr; k<pwrbadr+pwrbsize; k++) {
for (l=0; l<usb; l++) { // find USB _LXX
if (dsdt[k] == UsbName[l][0] && dsdt[k+1] == UsbName[l][1] &&
dsdt[k+2] == UsbName[l][2] && dsdt[k+3] == UsbName[l][3]) {
//DBG( "found USB _GPE Method.\n");
// usbpwrb = TRUE;
if (!usbcount) {
//DBG( "will to find Scope(\\_GPE).\n");
for (m=0; m<300; m++) {
if (dsdt[i-m] == 'E' && dsdt[i-m-1] == 'P' && dsdt[i-m-2] == 'G' && dsdt[i-m-3] == '_') {
for (n=0; n<15; n++) {
if (dsdt[i-m-n] == 0x10) {
gpeadr = i-m-n+1;
// gpesize = get_size(dsdt, i-m-n+1);
//DBG( "_GPE adr = 0x%08X, size = 0x%08X\n", gpeadr, gpesize);
break;
}
}
break;
}
}
}
break;
}
}
}
}
}
}
}
if (usbcount) {
sizeoffset = offset;
k = write_size(gpeadr, dsdt, len, sizeoffset);
sizeoffset += k;
len += k;
len = CorrectOuters(dsdt, len, gpeadr-3, sizeoffset);
}
return len;
}
#endif
#if 0
UINT32 FIXPWRB (UINT8* dsdt, UINT32 len)
{
UINT32 i, j=0;
UINT32 adr=0, hid=0, size = 0;
CHAR8 Name[4];
INT32 sizeoffset;
//search PWRB PNP0C0C
for (i=0x20; i<len-6; i++) {
if (CmpPNP(dsdt, i, 0x0C0C)) {
adr = devFind(dsdt, i);
if (!adr) {
continue;
}
size = get_size(dsdt, adr);
if(size){
hid = i + 10; //the place after HID PNP0C0C
break;
}
}
}
if (size) {
//check name and replace
if (size < 0x40) {
j = adr + 1;
} else {
j = adr + 2;
}
for (i=0; i<4; i++) {
Name[i] = dsdt[j+i];
}
ReplaceName(dsdt, len, Name, "PWRB");
sizeoffset = sizeof(pwrbprw);
len = move_data(hid, dsdt, len, sizeoffset);
CopyMem(dsdt+hid, pwrbprw, sizeoffset);
i = write_size(adr, dsdt, len, sizeoffset);
sizeoffset += i;
len += i;
len = CorrectOuters(dsdt, len, adr-3, sizeoffset);
}
return len;
}
#endif
UINT32 FIXSHUTDOWN_ASUS (UINT8 *dsdt, UINT32 len)
{
UINT32 i, j, sizeoffset = 0;
UINT32 adr, adr1 = 0, adr2, size, shift = 0;
UINT8 *shutdown = NULL;
DBG("Start SHUTDOWN Fix len=%X\n", len);
adr = FindMethod(dsdt, len, "_PTS");
if (!adr) {
MsgLog("no _PTS???\n");
return len;
}
if (gSettings.SuspendOverride) {
shutdown = &shutdown1[0];
sizeoffset = sizeof(shutdown1);
} else {
shutdown = &shutdown0[0];
sizeoffset = sizeof(shutdown0);
}
/*
adr \ _ P T S insert offset
14 16 5C 5F 50 54 53 01 < A0 05 93 68 0A 05 A1 08 >
body
53 4D 49 5F 0A 8A 68
*/
// sizeoffset = sizeof(shutdown); // == 18
size = get_size(dsdt, adr);
adr1 = adr;
for (j=0; j<20; j++) {
if ((dsdt[adr+j] == 'T') && (dsdt[adr+j+1] == 'S')) {
adr1 = adr+j+3; //address of body
break;
}
}
adr2 = adr1 + sizeoffset - 1; //jump adr
len = move_data(adr1, dsdt, len, sizeoffset); //new len
CopyMem(dsdt+adr1, shutdown, sizeoffset); //insert shutdown
i = adr + size - adr1; //body size
shift = write_offset(adr2, dsdt, len, i); //may return 0 or 1
len += shift;
sizeoffset += shift;
shift = write_size(adr, dsdt, len, sizeoffset);
// sizeoffset += shift;
len += shift;
return len;
}
#if 0
//Slice - this procedure was not corrected and mostly wrong
UINT32 FIXOTHER (UINT8 *dsdt, UINT32 len)
{
UINT32 i, j, k, m, offset, l;
UINT32 size;
// Fix USB _PRW value for 0x0X, 0x04 ==> 0x0X, 0x01
for(j=0; j<usb; j++) {
for (i=0; i<len-5; i++) {
if (CmpAdr(dsdt, i, USBADR[j])) {
// get USB name
UsbName[j] = (__typeof__(UsbName[j]))AllocateZeroPool(5);
CopyMem(UsbName[j], dsdt+i, 4);
DBG("found USB device NAME(_ADR,0x%08X) And Name is %s\n",
USBADR[j], UsbName[j]);
k = (i+1);
while (k < (i+200)) {
if (dsdt[k] == 0x14 && dsdt[k+2] == '_' && dsdt[k+3] == 'P' && dsdt[k+4] == 'R' && dsdt[k+5] == 'W') {
offset = k;
m = dsdt[k+1];
if (dsdt[offset+m] != 0x03) {
if (dsdt[offset+m] == 0x01)
dsdt[offset+m] = 0x03;
if (dsdt[offset+m] == 0x04)
dsdt[offset+m] = 0x01;
//DBG("found USB Method(_PRW) and will patch fix\n");
}
break;
}
k = (i+1);
while (k < (i+200)) {
if (dsdt[k] == 0x14 && dsdt[k+2] == '_' && dsdt[k+3] == 'S' && dsdt[k+4] == '3' && dsdt[k+5] == 'D') {
size = dsdt[k+1];
for (l=0; l<size; l++) {
if (dsdt[k+1+l] == 0xA4 && dsdt[k+2+l] == 0x0A && dsdt[k+3+l] != 0x03) {
dsdt[k+3+l] = 0x03;
}
}
break;
}
k++;
}
k++;
}
/*
for (k=(i+1); k<(i+200); k++) {
if (dsdt[k] == 0x14 && dsdt[k+2] == '_' && dsdt[k+3] == 'P' && dsdt[k+4] == 'R' && dsdt[k+5] == 'W') {
offset = k;
m = dsdt[k+1];
if (dsdt[offset+m] != 0x03) {
if (dsdt[offset+m] == 0x01)
dsdt[offset+m] = 0x03;
if (dsdt[offset+m] == 0x04)
dsdt[offset+m] = 0x01;
//DBG("found USB Method(_PRW) and will patch fix\n");
}
break;
}
for (k=i+1; k<i+200; k++) {
if (dsdt[k] == 0x14 && dsdt[k+2] == '_' && dsdt[k+3] == 'S' && dsdt[k+4] == '3' && dsdt[k+5] == 'D') {
size = dsdt[k+1];
for (l=0; l<size; l++) {
if (dsdt[k+1+l] == 0xA4 && dsdt[k+2+l] == 0x0A && dsdt[k+3+l] != 0x03) {
dsdt[k+3+l] = 0x03;
}
}
break;
}
}
//for (k=i+1; k<i+200; k++) {
// if (dsdt[k] == 0x14 && dsdt[k+2] == '_' && dsdt[k+3] == 'P' && dsdt[k+4] == 'S' && dsdt[k+5] == 'W')
// {
// size = dsdt[k+1];
// for (l=0; l<size; l++)
// {
// if (dsdt[k+1+l] == 0x70 && dsdt[k+2+l] == 0x00)
// {
// dsdt[k+2+l] = 0x03;
// }
// }
// break;
// }
//}
break;
}
*/
}
}
}
for (j=0; j<usb; j++){
FreePool(UsbName[j]);
}
// fix _T_0 _T_1 _T_2 _T_3
for (i=0; i<len-10; i++) {
if (dsdt[i] == '_' && dsdt[i+1] == 'T' && dsdt[i+2] == '_' &&
(dsdt[i+3] == '0' || dsdt[i+3] == '1' || dsdt[i+3] == '2' || dsdt[i+3] == '3')) {
dsdt[i] = dsdt[i+1];
dsdt[i+1] = dsdt[i+2];
dsdt[i+2] = dsdt[i+3];
dsdt[i+3] = '_';
}
}
// fix MUTE Possible operator timeout is ignored
for (i=0; i<len-10; i++) {
if (dsdt[i] == 0x5B && dsdt[i+1] == 0x23 && dsdt[i+2] == 0x4D &&
dsdt[i+3] == 0x55 && dsdt[i+4] == 0x54 && dsdt[i+5] == 0x45) {
dsdt[i+6] = 0xFF;
dsdt[i+7] = 0xFF;
}
}
return len;
}
#endif
VOID FixRegions (UINT8 *dsdt, UINT32 len)
{
UINTN i, j;
INTN shift;
CHAR8 Name[8];
CHAR8 NameAdr[8];
OPER_REGION *p;
// BOOLEAN Corrected = FALSE;
// OperationRegion (GNVS, SystemMemory, 0xDE2E9E18, 0x01CD)
// 5B 80 47 4E 56 53 00 0C 18 9E 2E DE 0B CD 01
//or
// Name (RAMB, 0xDD991188)
// OperationRegion (\RAMW, SystemMemory, RAMB, 0x00010000)
// 08 52 41 4D 42 0C 88 11 99 DD
// 5B 80 52 41 4D 57 00 52 41 4D 42 0C 00 00 01 00
if (!gRegions) {
return;
}
for (i = 0x20; len >= 15 && i < len - 15; i++) {
if ((dsdt[i] == 0x5B) && (dsdt[i+1] == 0x80) && GetName(dsdt, (INT32)(i+2), &Name[0], &shift)) {
//this is region. Compare to bios tables
p = gRegions;
while (p) {
if (AsciiStrStr(p->Name, Name)) {
UINT32 oldAddress = 0;
//apply patch
if (dsdt[i+7+shift] == 0x0C) {
CopyMem(&oldAddress, &dsdt[i+8+shift], 4);
CopyMem(&dsdt[i+8+shift], &p->Address, 4);
} else if (dsdt[i+7+shift] == 0x0B) {
CopyMem(&oldAddress, &dsdt[i+8+shift], 2);
CopyMem(&dsdt[i+8+shift], &p->Address, 2);
} else {
//propose this is indirect name
if (GetName(dsdt, (INT32)(i+7+shift), &NameAdr[0], NULL)) {
j = FindName(dsdt, len, &NameAdr[0]);
if (j > 0) {
MsgLog(" indirect name=%s\n", NameAdr);
if (dsdt[j+4] == 0x0C) {
CopyMem(&oldAddress, &dsdt[j+5], 4);
CopyMem(&dsdt[j+5], &p->Address, 4);
// Corrected = TRUE;
} else if (dsdt[j+4] == 0x0B) {
CopyMem(&oldAddress, &dsdt[j+5], 2);
CopyMem(&dsdt[j+5], &p->Address, 2);
} else {
MsgLog("... value not defined\n");
}
}
}
}
if (oldAddress != p->Address) {
MsgLog("OperationRegion (%s...) corrected from 0x%X to addr=0x%X\n", Name, oldAddress, p->Address);
}
break;
}
p = p->next;
}
}
}
}
VOID GetBiosRegions(UINT8 *buffer)
{
EFI_ACPI_DESCRIPTION_HEADER *TableHeader;
// UINT8 *buffer = NULL;
UINT32 bufferLen = 0;
UINTN i, j;
INTN shift, shift2;
CHAR8 Name[8];
CHAR8 NameAdr[8];
if (!buffer) {
return;
}
// gRegions = NULL;
// buffer = (UINT8*)(UINTN)fadt->Dsdt;
TableHeader = (EFI_ACPI_DESCRIPTION_HEADER*)buffer;
bufferLen = TableHeader->Length;
for (i=0x24; bufferLen >= 15 && i < bufferLen - 15; i++) {
if ((buffer[i] == 0x5B) && (buffer[i+1] == 0x80) &&
GetName(buffer, (INT32)(i+2), &Name[0], &shift)) {
if (buffer[i+6+shift] == 0) {
//this is SystemMemory region. Write to bios regions tables
OPER_REGION tmp;
tmp.Address = 0;
CopyMem(&tmp.Name[0], &buffer[i+2+shift], 4);
tmp.Name[4] = 0;
if (buffer[i+7+shift] == 0x0C) {
CopyMem(&tmp.Address, &buffer[i+8+shift], 4);
} else if (buffer[i+7+shift] == 0x0B) {
CopyMem(&tmp.Address, &buffer[i+8+shift], 2);
} else if (GetName(buffer, (INT32)(i+7+shift), &NameAdr[0], &shift2)) {
j = FindName(buffer, bufferLen, &NameAdr[0]);
if (j > 0) {
if (buffer[j+4] == 0x0C) {
CopyMem(&tmp.Address, &buffer[j+5], 4);
} else if (buffer[j+4] == 0x0B) {
CopyMem(&tmp.Address, &buffer[j+5], 2);
}
}
}
if (tmp.Address) {
OPER_REGION *newRegion = (__typeof__(newRegion))AllocateZeroPool(sizeof(OPER_REGION));
MsgLog("Found OperationRegion(%s, SystemMemory, %X, ...)\n", tmp.Name, tmp.Address);
*newRegion = tmp;
newRegion->next = gRegions;
gRegions = newRegion;
} else {
// ignore OperationRegion where the address cannot be determined
//DBG("Unable to determine address for OperationRegion(%s, SystemMemory, ...) skipping\n", tmp.Name);
}
}
}
}
}
// RehabMan: Fix Mutex with non-zero SyncLevel (change to zero)
// For example: Mutex(ECMX, 3) -> Mutex(ECMX, 0)
// representation example:
// Mutex(M2, 1) -> 5B 01 4D 32 5F 5F 01
// Although Mutex with non-zero SyncLevel is perfectly legal macOS/OS X doesn't like
// One of the common fixes for ACPI battery status on laptops
#define IsNameChar(ch) (((ch)>='A' && (ch)<='Z') || ((ch)>='0' && (ch)<='9') || (ch)=='_')
VOID FixMutex(UINT8 *dsdt, UINT32 len)
{
UINT8* p = dsdt + sizeof(EFI_ACPI_DESCRIPTION_HEADER);
UINT8* end = dsdt + len - 7; // pattern is 7-bytes
MsgLog("Start Mutex Fix\n");
for (; p <= end; p++) {
if (p[0] == 0x5b && p[1] == 0x01 &&
IsNameChar(p[2]) && IsNameChar(p[3]) && IsNameChar(p[4]) && IsNameChar(p[5])) {
if (p[6] != 0) {
MsgLog("Fixing Mutex(%c%c%c%c, %d)\n", p[2], p[3], p[4], p[5], p[6]);
}
p[6] = 0;
}
}
}
/*
_SB.PCI0.RP02.PSXS
We have to take into account fields like
Scope(\_SB)
{
Device (PCI0)
{
Device(RP02)
{
Device(PSXS) <- to patch
{
Method(_ON)
{
}
Method(_OFF)
{
}
}
PSXS._ON() <- to patch
}
Scope(RP02)
{
PSXS._OFF() <- to patch
}
Device(RP03)
{
Device(PSXS) <- to not patch
{
}
PSXS._ON() <- to not patch
}
*/
BOOLEAN isACPI_Char(CHAR8 C)
{
return (((C >= 'A') && (C <= 'Z')) ||
((C >= '0') && (C <= '9')) ||
(C == '_'));
}
BOOLEAN CmpFullName(UINT8* Table, UINTN Len, ACPI_NAME_LIST *Bridge)
{
// "RP02" NameLen=4
// "_SB_PCI0RP02" NameLen=12
UINTN NameLen = 0;
INTN i = 0;
CHAR8 *Name;
while ((NameLen < Len) && isACPI_Char((CHAR8)Table[NameLen])) NameLen++;
NameLen &= ~3;
if (NameLen < 4) {
return FALSE;
}
Name = (__typeof__(Name))AllocateCopyPool(NameLen + 1, Table);
Name[NameLen] = '\0';
i = NameLen - 4;
while (Bridge && (i >= 0)) {
if (AsciiStrStr(Name + i, Bridge->Name) == NULL) { //compare Bridge->Name with RP02, Next->Name with PCI0 then _SB_
FreePool(Name);
return FALSE;
}
i -= 4;
Bridge = Bridge->Next;
}
FreePool(Name);
return TRUE;
}
VOID RenameDevices(UINT8* table)
{
ACPI_NAME_LIST *List;
ACPI_NAME_LIST *Bridge;
CHAR8 *Replace;
CHAR8 *Find;
INTN i;
INTN k=0; // Cland complain about possible use uninitialised. Not true, but I don't like warnings.
UINTN index;
INTN size;
UINTN len = ((EFI_ACPI_DESCRIPTION_HEADER*)table)->Length;
INTN adr, shift, Num = 0;
BOOLEAN found;
for (index = 0; index < gSettings.DeviceRenameCount; index++) {
List = gSettings.DeviceRename[index].Next;
Replace = gSettings.DeviceRename[index].Name;
Find = List->Name;
Bridge = List->Next;
MsgLog("Name: %s, Bridge: %s, Replace: %s\n", Find, Bridge->Name, Replace);
adr = 0;
do
{
shift = FindBin(table + adr, (UINT32)(len - adr), (UINT8*)Find, 4); //next occurence
if (shift < 0) {
break; //not found
}
adr += shift;
// DBG("found Name @ 0x%X\n", adr);
if (!Bridge || (FindBin(table + adr - 4, 5, (UINT8*)(Bridge->Name), 4) == 0)) { // long name like "RP02.PXSX"
CopyMem(table + adr, Replace, 4);
adr += 5; //at least, it is impossible to see PXSXPXSX
// DBG("replaced\n");
Num++;
continue;
}
//find outer device or scope
i = adr;
while ((i > 0) && isACPI_Char(table[i])) i--; //skip attached name
i -= 6; //skip size and device field
// DBG("search for bridge since %d\n", adr);
while (i > 0x20) { //find devices that previous to adr
found = FALSE;
//check device
if ((table[i] == 0x5B) && (table[i + 1] == 0x82) && !CmpNum(table, (INT32)i, TRUE)) { //device candidate
k = i + 2;
found = TRUE;
}
//check scope
if ((table[i] == 0x10) && !CmpNum(table, (INT32)i, TRUE)) {
k = i + 1;
found = TRUE;
}
if (found) { // i points to Device or Scope
size = get_size(table, (UINT32)(UINTN)k); //k points to size // DBG("found bridge candidate 0x%X size %d\n", table[i], size);
if (size) {
if ((k + size) > (adr + 4)) { //Yes - it is outer
// DBG("found Bridge device begin=%X end=%X\n", k, k+size);
if (table[k] < 0x40) {
k += 1;
}
else if ((table[k] & 0x40) != 0) {
k += 2;
}
else if ((table[k] & 0x80) != 0) {
k += 3;
} //now k points to the outer name
if (CmpFullName(table + k, len - k, Bridge)) {
CopyMem(table + adr, Replace, 4);
adr += 5;
DBG("found Bridge device begin=%X end=%X\n", k, k+size);
// DBG(" name copied\n");
Num++;
break; //cancel search outer bridge, we found it.
}
} //else not an outer device
} //else wrong size field - not a device
} //else not a device or scope
i--;
} //while find outer bridge
adr += 5;
} while (1); //next occurence
} //DeviceRenameCount
MsgLog(" %lld replacements\n", Num);
}
VOID FixBiosDsdt (UINT8* temp, EFI_ACPI_2_0_FIXED_ACPI_DESCRIPTION_TABLE* fadt, CHAR8 *OSVersion)
{
UINT32 DsdtLen;
UINTN i;
if (!temp) {
return;
}
//Reenter requires ZERO values
HDAFIX = TRUE;
GFXHDAFIX = TRUE;
USBIDFIX = TRUE;
DsdtLen = ((EFI_ACPI_DESCRIPTION_HEADER*)temp)->Length;
if ((DsdtLen < 20) || (DsdtLen > 400000)) { //fool proof (some ASUS dsdt > 300kb?)
MsgLog("DSDT length out of range\n");
return;
}
// DBG("========= Auto patch DSDT Starting ========\n");
DbgHeader("FixBiosDsdt");
// First check hardware address: GetPciADR(DevicePath, &NetworkADR1, &NetworkADR2);
CheckHardware();
//arbitrary fixes
if (gSettings.PatchDsdtNum > 0) {
MsgLog("Patching DSDT:\n");
for (i = 0; i < gSettings.PatchDsdtNum; i++) {
if (!gSettings.PatchDsdtFind[i] || !gSettings.LenToFind[i]) {
continue;
}
MsgLog(" - [%s]:", gSettings.PatchDsdtLabel[i]); //yyyy
if (gSettings.PatchDsdtMenuItem[i].BValue) {
if (!gSettings.PatchDsdtTgt[i]) {
DsdtLen = FixAny(temp, DsdtLen,
gSettings.PatchDsdtFind[i], gSettings.LenToFind[i],
gSettings.PatchDsdtReplace[i], gSettings.LenToReplace[i]);
}else{
// DBG("Patching: renaming in bridge\n");
DsdtLen = FixRenameByBridge2(temp, DsdtLen,
gSettings.PatchDsdtTgt[i],
gSettings.PatchDsdtFind[i],
gSettings.LenToFind[i],
gSettings.PatchDsdtReplace[i],
gSettings.LenToReplace[i]);
}
} else {
MsgLog(" disabled\n");
}
}
}
//renaming Devices
RenameDevices(temp);
// find ACPI CPU name and hardware address
findCPU(temp, DsdtLen);
// add Method (DTGP, 5, NotSerialized)
if ((gSettings.FixDsdt & FIX_DTGP)) {
if (!FindMethod(temp, DsdtLen, "DTGP")) {
CopyMem((CHAR8 *)temp+DsdtLen, dtgp, sizeof(dtgp));
DsdtLen += sizeof(dtgp);
((EFI_ACPI_DESCRIPTION_HEADER*)temp)->Length = DsdtLen;
}
}
// gSettings.PCIRootUID = 0;
findPciRoot(temp, DsdtLen);
// Fix RTC
if ((gSettings.FixDsdt & FIX_RTC)) {
// DBG("patch RTC in DSDT \n");
DsdtLen = FixRTC(temp, DsdtLen);
}
// Fix TMR
if ((gSettings.FixDsdt & FIX_TMR)) {
// DBG("patch TMR in DSDT \n");
DsdtLen = FixTMR(temp, DsdtLen);
}
// Fix PIC or IPIC
if ((gSettings.FixDsdt & FIX_IPIC) != 0) {
// DBG("patch IPIC in DSDT \n");
DsdtLen = FixPIC(temp, DsdtLen);
}
// Fix HPET
if ((gSettings.FixDsdt & FIX_HPET) != 0) {
// DBG("patch HPET in DSDT \n");
DsdtLen = FixHPET(temp, DsdtLen);
}
// Fix LPC if don't had HPET don't need to inject LPC??
if (LPCBFIX && (gCPUStructure.Family == 0x06) && (gSettings.FixDsdt & FIX_LPC)) {
// DBG("patch LPC in DSDT \n");
DsdtLen = FIXLPCB(temp, DsdtLen);
}
// Fix Display
if ((gSettings.FixDsdt & FIX_DISPLAY) || (gSettings.FixDsdt & FIX_INTELGFX)) {
INT32 j;
for (j=0; j<4; ++j) {
if (DisplayADR1[j]) {
if (((DisplayVendor[j] != 0x8086) && (gSettings.FixDsdt & FIX_DISPLAY)) ||
((DisplayVendor[j] == 0x8086) && (gSettings.FixDsdt & FIX_INTELGFX))) {
DsdtLen = FIXDisplay(temp, DsdtLen, j);
MsgLog("patch Display #%d of Vendor=0x%4X\n", j, DisplayVendor[j]);
}
}
}
}
// Fix Network
if ((gSettings.FixDsdt & FIX_LAN)) {
// DBG("patch LAN in DSDT \n");
UINT32 j;
for (j = 0; j <= net_count; ++j) {
if (NetworkADR1[j]) {
MsgLog("patch LAN0 in DSDT \n");
DsdtLen = FIXNetwork(temp, DsdtLen, j);
}
}
}
// Fix Airport
if (ArptADR1 && (gSettings.FixDsdt & FIX_WIFI)) {
// DBG("patch Airport in DSDT \n");
DsdtLen = FIXAirport(temp, DsdtLen);
}
// Fix SBUS
if (SBUSADR1 && (gSettings.FixDsdt & FIX_SBUS)) {
// DBG("patch SBUS in DSDT \n");
DsdtLen = FIXSBUS(temp, DsdtLen);
}
// Fix IDE inject
if (IDEFIX && (IDEVENDOR == 0x8086 || IDEVENDOR == 0x11ab) && (gSettings.FixDsdt & FIX_IDE)) {
// DBG("patch IDE in DSDT \n");
DsdtLen = FIXIDE(temp, DsdtLen);
}
// Fix SATA AHCI orange icon
if (SATAAHCIADR1 && (SATAAHCIVENDOR == 0x8086) && (gSettings.FixDsdt & FIX_SATA)) {
DBG("patch AHCI in DSDT \n");
DsdtLen = FIXSATAAHCI(temp, DsdtLen);
}
// Fix SATA inject
if (SATAFIX && (SATAVENDOR == 0x8086) && (gSettings.FixDsdt & FIX_SATA)) {
DBG("patch SATA in DSDT \n");
DsdtLen = FIXSATA(temp, DsdtLen);
}
// Fix Firewire
if (FirewireADR1 && (gSettings.FixDsdt & FIX_FIREWIRE)) {
DBG("patch FRWR in DSDT \n");
DsdtLen = FIXFirewire(temp, DsdtLen);
}
// HDA HDEF
if (HDAFIX && (gSettings.FixDsdt & FIX_HDA)) {
DBG("patch HDEF in DSDT \n");
DsdtLen = AddHDEF(temp, DsdtLen, OSVersion);
}
//Always add MCHC for PM
if ((gCPUStructure.Family == 0x06) && (gSettings.FixDsdt & FIX_MCHC)) {
// DBG("patch MCHC in DSDT \n");
DsdtLen = AddMCHC(temp, DsdtLen);
}
//add IMEI
if ((gSettings.FixDsdt & FIX_IMEI)) {
DsdtLen = AddIMEI(temp, DsdtLen);
}
//Add HDMI device
if ((gSettings.FixDsdt & FIX_HDMI)) {
DsdtLen = AddHDMI(temp, DsdtLen);
}
// Always Fix USB
if ((gSettings.FixDsdt & FIX_USB)) {
DsdtLen = FIXUSB(temp, DsdtLen);
}
if ((gSettings.FixDsdt & FIX_WAK)){
// Always Fix _WAK Return value
DsdtLen = FIXWAK(temp, DsdtLen, fadt);
}
// DBG("patch warnings \n");
// Always Fix alias cpu FIX cpus=1
// DsdtLen = FIXCPU1(temp, DsdtLen);
// DsdtLen = FIXPWRB(temp, DsdtLen);
// USB Device remove error Fix
// DsdtLen = FIXGPE(temp, DsdtLen);
if ((gSettings.FixDsdt & FIX_UNUSED)) {
//I want these fixes even if no Display fix. We have GraphicsInjector
DsdtLen = DeleteDevice("CRT_", temp, DsdtLen);
DsdtLen = DeleteDevice("DVI_", temp, DsdtLen);
//good company
DsdtLen = DeleteDevice("SPKR", temp, DsdtLen);
DsdtLen = DeleteDevice("ECP_", temp, DsdtLen);
DsdtLen = DeleteDevice("LPT_", temp, DsdtLen);
DsdtLen = DeleteDevice("FDC0", temp, DsdtLen);
DsdtLen = DeleteDevice("ECP1", temp, DsdtLen);
DsdtLen = DeleteDevice("LPT1", temp, DsdtLen);
}
if ((gSettings.FixDsdt & FIX_ACST)) {
ReplaceName(temp, DsdtLen, "ACST", "OCST");
ReplaceName(temp, DsdtLen, "ACSS", "OCSS");
ReplaceName(temp, DsdtLen, "APSS", "OPSS");
ReplaceName(temp, DsdtLen, "APSN", "OPSN");
ReplaceName(temp, DsdtLen, "APLF", "OPLF");
}
if ((gSettings.FixDsdt & FIX_PNLF)) {
DsdtLen = AddPNLF(temp, DsdtLen);
}
if ((gSettings.FixDsdt & FIX_S3D)) {
FixS3D(temp, DsdtLen);
}
//Fix OperationRegions
if ((gSettings.FixDsdt & FIX_REGIONS)) {
FixRegions(temp, DsdtLen);
}
//RehabMan: Fix Mutex objects
if ((gSettings.FixDsdt & FIX_MUTEX)) {
FixMutex(temp, DsdtLen);
}
// pwrb add _CID sleep button fix
if ((gSettings.FixDsdt & FIX_ADP1)) {
DsdtLen = FixADP1(temp, DsdtLen);
}
// other compiler warning fix _T_X, MUTE .... USB _PRW value form 0x04 => 0x01
// DsdtLen = FIXOTHER(temp, DsdtLen);
if ((gSettings.FixDsdt & FIX_WARNING) || (gSettings.FixDsdt & FIX_DARWIN)) {
if (!FindMethod(temp, DsdtLen, "GET9") &&
!FindMethod(temp, DsdtLen, "STR9") &&
!FindMethod(temp, DsdtLen, "OOSI")) {
DsdtLen = FIXDarwin(temp, DsdtLen);
}
}
// Fix SHUTDOWN For ASUS
if ((gSettings.FixDsdt & FIX_SHUTDOWN)) {
DsdtLen = FIXSHUTDOWN_ASUS(temp, DsdtLen); //safe to do twice
}
// Finish DSDT patch and resize DSDT Length
/*
temp[4] = (DsdtLen & 0x000000FF);
temp[5] = (UINT8)((DsdtLen & 0x0000FF00) >> 8);
temp[6] = (UINT8)((DsdtLen & 0x00FF0000) >> 16);
temp[7] = (UINT8)((DsdtLen & 0xFF000000) >> 24);
CopyMem((UINT8*)((EFI_ACPI_DESCRIPTION_HEADER*)temp)->OemId, (UINT8*)BiosVendor, 6);
//DBG("orgBiosDsdtLen = 0x%08X\n", orgBiosDsdtLen);
((EFI_ACPI_DESCRIPTION_HEADER*)temp)->Checksum = 0;
((EFI_ACPI_DESCRIPTION_HEADER*)temp)->Checksum = (UINT8)(256-Checksum8(temp, DsdtLen));
*/
EFI_ACPI_DESCRIPTION_HEADER* Table = (EFI_ACPI_DESCRIPTION_HEADER*)temp;
Table->Length = DsdtLen;
FixChecksum(Table);
//DBG("========= Auto patch DSDT Finished ========\n");
//PauseForKey(L"waiting for key press...\n");
}