Vivobook-Pro2-Opencore/Kexts/SMCBatteryManager.kext/Contents/Resources/SSDT-BATC.dsl
2024-01-12 16:54:18 +01:00

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// SSDT-BATC.dsl
//
// Based on https://github.com/RehabMan/OS-X-ACPI-Battery-Driver/blob/master/SSDT-BATC.dsl
//
// An SSDT to combine two batteries into one
// initial work/testing by ag6952563 (with assistance by RehabMan)
// finalize into generic SSDT by RehabMan
// some code cleanup/optimization/and bug fixing by RehabMan
// modifications to work VirtualSMC SMCBatteryManager by armenio
// add _BIX (easy, following the original code from RehabMan) by armenio
//
// OS X support for multiple batteries is a bit buggy.
// This SSDT can be used to combine two batteries into one,
// avoiding the bugs.
//
// It may need modification depending on the ACPI path of your
// existing battery objects.
//
// IMPORTANT:
//
// To use this SSDT, you must also patch any Notify for either BAT0 or BAT1
// objects.
//
// The Notify is used to tell the system when a battery is removed or added.
//
// Any code:
// Notify (...BAT0, ...)
// -or
// Notify (...BAT1, ...)
//
// Must be changed to:
// Notify (...BATC, ...)
//
// Refer to Dual Battery Support.md for patching details
//
DefinitionBlock ("", "SSDT", 2, "ACDT", "BATC", 0x00000000)
{
External (_SB_.PCI0.LPCB.EC, DeviceObj)
External (_SB_.PCI0.LPCB.EC.BAT0, DeviceObj)
External (_SB_.PCI0.LPCB.EC.BAT0._BIF, MethodObj)
External (_SB_.PCI0.LPCB.EC.BAT0._BIX, MethodObj)
External (_SB_.PCI0.LPCB.EC.BAT0._BST, MethodObj)
External (_SB_.PCI0.LPCB.EC.BAT0._HID, IntObj)
External (_SB_.PCI0.LPCB.EC.BAT0._STA, MethodObj)
External (_SB_.PCI0.LPCB.EC.BAT1, DeviceObj)
External (_SB_.PCI0.LPCB.EC.BAT1._BIF, MethodObj)
External (_SB_.PCI0.LPCB.EC.BAT1._BIX, MethodObj)
External (_SB_.PCI0.LPCB.EC.BAT1._BST, MethodObj)
External (_SB_.PCI0.LPCB.EC.BAT1._HID, IntObj)
External (_SB_.PCI0.LPCB.EC.BAT1._STA, MethodObj)
Scope (\_SB.PCI0.LPCB.EC)
{
Device (BATC)
{
Name (_HID, EisaId ("PNP0C0A"))
Name (_UID, 0x02)
Method (_INI)
{
If (_OSI ("Darwin"))
{
// disable original battery objects by setting invalid _HID
^^BAT0._HID = 0
^^BAT1._HID = 0
}
}
Method (_STA)
{
If (_OSI ("Darwin"))
{
// call original _STA for BAT0 and BAT1
// result is bitwise OR between them
Return (^^BAT0._STA () | ^^BAT1._STA ())
}
Else
{
Return (Zero)
}
}
Method (_BIF)
{
// Local0 BAT0._BIF
// Local1 BAT1._BIF
// Local2 BAT0._STA
// Local3 BAT1._STA
// Local4/Local5 scratch
// gather and validate data from BAT0
Local0 = ^^BAT0._BIF ()
Local2 = ^^BAT0._STA ()
If (0x1f == Local2)
{
// check for invalid design capacity
Local4 = DerefOf (Local0 [1])
If (!Local4 || Ones == Local4) { Local2 = 0; }
// check for invalid last full charge capacity
Local4 = DerefOf (Local0 [2])
If (!Local4 || Ones == Local4) { Local2 = 0; }
// check for invalid design voltage
Local4 = DerefOf (Local0 [4])
If (!Local4 || Ones == Local4) { Local2 = 0; }
}
// gather and validate data from BAT1
Local1 = ^^BAT1._BIF ()
Local3 = ^^BAT1._STA ()
If (0x1f == Local3)
{
// check for invalid design capacity
Local4 = DerefOf (Local1 [1])
If (!Local4 || Ones == Local4) { Local3 = 0; }
// check for invalid last full charge capacity
Local4 = DerefOf (Local1 [2])
If (!Local4 || Ones == Local4) { Local3 = 0; }
// check for invalid design voltage
Local4 = DerefOf (Local1 [4])
If (!Local4 || Ones == Local4) { Local3 = 0; }
}
// find primary and secondary battery
If (0x1f != Local2 && 0x1f == Local3)
{
// make primary use BAT1 data
Local0 = Local1 // BAT1._BIF result
Local2 = Local3 // BAT1._STA result
Local3 = 0 // no secondary battery
}
// combine batteries into Local0 result if possible
If (0x1f == Local2 && 0x1f == Local3)
{
// _BIF 0 Power Unit - leave BAT0 value
// _BIF 1 Design Capacity - add BAT0 and BAT1 values
Local4 = DerefOf (Local0 [1])
Local5 = DerefOf (Local1 [1])
If (0xffffffff != Local4 && 0xffffffff != Local5)
{
Local0 [1] = Local4 + Local5
}
// _BIF 2 Last Full Charge Capacity - add BAT0 and BAT1 values
Local4 = DerefOf (Local0 [2])
Local5 = DerefOf (Local1 [2])
If (0xffffffff != Local4 && 0xffffffff != Local5)
{
Local0 [2] = Local4 + Local5
}
// _BIF 3 Battery Technology - leave BAT0 value
// _BIF 4 Design Voltage - average between BAT0 and BAT1 values
Local4 = DerefOf (Local0 [4])
Local5 = DerefOf (Local1 [4])
If (0xffffffff != Local4 && 0xffffffff != Local5)
{
Local0 [4] = (Local4 + Local5) / 2
}
// _BIF 5 Design Capacity of Warning - add BAT0 and BAT1 values
Local0 [5] = DerefOf (Local0 [5]) + DerefOf (Local1 [5])
// _BIF 6 Design Capacity of Low - add BAT0 and BAT1 values
Local0 [6] = DerefOf (Local0 [6]) + DerefOf (Local1 [6])
// _BIF 7 Battery Capacity Granularity 1 - add BAT0 and BAT1 values
Local4 = DerefOf (Local0 [7])
Local5 = DerefOf (Local1 [7])
If (0xffffffff != Local4 && 0xffffffff != Local5)
{
Local0 [7] = Local4 + Local5
}
// _BIF 8 Battery Capacity Granularity 2 - add BAT0 and BAT1 values
Local4 = DerefOf (Local0 [8])
Local5 = DerefOf (Local1 [8])
If (0xffffffff != Local4 && 0xffffffff != Local5)
{
Local0 [8] = Local4 + Local5
}
// _BIF 9 Model Number - concatenate BAT0 and BAT1 values
Local0 [0x09] = Concatenate (Concatenate (DerefOf (Local0 [0x09]), " / "), DerefOf (Local1 [0x09]))
// _BIF a Serial Number - concatenate BAT0 and BAT1 values
Local0 [0x0a] = Concatenate (Concatenate (DerefOf (Local0 [0x0a]), " / "), DerefOf (Local1 [0x0a]))
// _BIF b Battery Type - concatenate BAT0 and BAT1 values
Local0 [0x0b] = Concatenate (Concatenate (DerefOf (Local0 [0x0b]), " / "), DerefOf (Local1 [0x0b]))
// _BIF c OEM Information - concatenate BAT0 and BAT1 values
Local0 [0x0c] = Concatenate (Concatenate (DerefOf (Local0 [0x0c]), " / "), DerefOf (Local1 [0x0c]))
}
Return (Local0)
} // _BIF
Method (_BIX)
{
// Local0 BAT0._BIX
// Local1 BAT1._BIX
// Local2 BAT0._STA
// Local3 BAT1._STA
// Local4/Local5 scratch
// gather and validate data from BAT0
Local0 = ^^BAT0._BIX ()
Local2 = ^^BAT0._STA ()
If (0x1f == Local2)
{
// check for invalid design capacity
Local4 = DerefOf (Local0 [2])
If (!Local4 || Ones == Local4) { Local2 = 0; }
// check for invalid last full charge capacity
Local4 = DerefOf (Local0 [3])
If (!Local4 || Ones == Local4) { Local2 = 0; }
// check for invalid design voltage
Local4 = DerefOf (Local0 [5])
If (!Local4 || Ones == Local4) { Local2 = 0; }
}
// gather and validate data from BAT1
Local1 = ^^BAT1._BIX ()
Local3 = ^^BAT1._STA ()
If (0x1f == Local3)
{
// check for invalid design capacity
Local4 = DerefOf (Local1 [2])
If (!Local4 || Ones == Local4) { Local3 = 0; }
// check for invalid last full charge capacity
Local4 = DerefOf (Local1 [3])
If (!Local4 || Ones == Local4) { Local3 = 0; }
// check for invalid design voltage
Local4 = DerefOf (Local1 [5])
If (!Local4 || Ones == Local4) { Local3 = 0; }
}
// find primary and secondary battery
If (0x1f != Local2 && 0x1f == Local3)
{
// make primary use BAT1 data
Local0 = Local1 // BAT1._BIX result
Local2 = Local3 // BAT1._STA result
Local3 = 0 // no secondary battery
}
// combine batteries into Local0 result if possible
If (0x1f == Local2 && 0x1f == Local3)
{
// _BIX 0 Revision - leave BAT0 value
// _BIX 1 Power Unit - leave BAT0 value
// _BIX 2 Design Capacity - add BAT0 and BAT1 values
Local4 = DerefOf (Local0 [2])
Local5 = DerefOf (Local1 [2])
If (0xffffffff != Local4 && 0xffffffff != Local5)
{
Local0 [2] = Local4 + Local5
}
// _BIX 3 Last Full Charge Capacity - add BAT0 and BAT1 values
Local4 = DerefOf (Local0 [3])
Local5 = DerefOf (Local1 [3])
If (0xffffffff != Local4 && 0xffffffff != Local5)
{
Local0 [3] = Local4 + Local5
}
// _BIX 4 Battery Technology - leave BAT0 value
// _BIX 5 Design Voltage - average between BAT0 and BAT1 values
Local4 = DerefOf (Local0 [5])
Local5 = DerefOf (Local1 [5])
If (0xffffffff != Local4 && 0xffffffff != Local5)
{
Local0 [5] = (Local4 + Local5) / 2
}
// _BIX 6 Design Capacity of Warning - add BAT0 and BAT1 values
Local0 [6] = DerefOf (Local0 [6]) + DerefOf (Local1 [6])
// _BIX 7 Design Capacity of Low - add BAT0 and BAT1 values
Local0 [7] = DerefOf (Local0 [7]) + DerefOf (Local1 [7])
// _BIX 8 Cycle Count - average between BAT0 and BAT1 values
Local4 = DerefOf (Local0 [8])
Local5 = DerefOf (Local1 [8])
If (0xffffffff != Local4 && 0xffffffff != Local5)
{
Local0 [8] = (Local4 + Local5) / 2
}
// _BIX 9 Measurement Accuracy - average between BAT0 and BAT1 values
Local0 [9] = (DerefOf (Local0 [9]) + DerefOf (Local1 [9])) / 2
// _BIX 0xa Max Sampling Time - average between BAT0 and BAT1 values
Local4 = DerefOf (Local0 [0xa])
Local5 = DerefOf (Local1 [0xa])
If (0xffffffff != Local4 && 0xffffffff != Local5)
{
Local0 [0xa] = (Local4 + Local5) / 2
}
// _BIX 0xb Min Sampling Time - average between BAT0 and BAT1 values
Local4 = DerefOf (Local0 [0xb])
Local5 = DerefOf (Local1 [0xb])
If (0xffffffff != Local4 && 0xffffffff != Local5)
{
Local0 [0xb] = (Local4 + Local5) / 2
}
// _BIX 0xc Max Averaging Interval - average between BAT0 and BAT1 values
Local0 [0xc] = (DerefOf (Local0 [0xc]) + DerefOf (Local1 [0xc])) / 2
// _BIX 0xd Min Averaging Interval - average between BAT0 and BAT1 values
Local0 [0xd] = (DerefOf (Local0 [0xd]) + DerefOf (Local1 [0xd])) / 2
// _BIX 0xe Battery Capacity Granularity 1 - add BAT0 and BAT1 values
Local4 = DerefOf (Local0 [0xe])
Local5 = DerefOf (Local1 [0xe])
If (0xffffffff != Local4 && 0xffffffff != Local5)
{
Local0 [0xe] = Local4 + Local5
}
// _BIX 0xf Battery Capacity Granularity 2 - add BAT0 and BAT1 values
Local4 = DerefOf (Local0 [0xf])
Local5 = DerefOf (Local1 [0xf])
If (0xffffffff != Local4 && 0xffffffff != Local5)
{
Local0 [0xf] = Local4 + Local5
}
// _BIX 10 Model Number - concatenate BAT0 and BAT1 values
Local0 [0x10] = Concatenate (Concatenate (DerefOf (Local0 [0x10]), " / "), DerefOf (Local1 [0x10]))
// _BIX 11 Serial Number - concatenate BAT0 and BAT1 values
Local0 [0x11] = Concatenate (Concatenate (DerefOf (Local0 [0x11]), " / "), DerefOf (Local1 [0x11]))
// _BIX 12 Battery Type - concatenate BAT0 and BAT1 values
Local0 [0x12] = Concatenate (Concatenate (DerefOf (Local0 [0x12]), " / "), DerefOf (Local1 [0x12]))
// _BIX 13 OEM Information - concatenate BAT0 and BAT1 values
Local0 [0x13] = Concatenate (Concatenate (DerefOf (Local0 [0x13]), " / "), DerefOf (Local1 [0x13]))
// _BIX 14 Battery Swapping Capability - leave BAT0 value for now
}
Return (Local0)
} // _BIX
Method (_BST)
{
// Local0 BAT0._BST
// Local1 BAT1._BST
// Local2 BAT0._STA
// Local3 BAT1._STA
// Local4/Local5 scratch
// gather battery data from BAT0
Local0 = ^^BAT0._BST ()
Local2 = ^^BAT0._STA ()
If (0x1f == Local2)
{
// check for invalid remaining capacity
Local4 = DerefOf (Local0 [2])
If (!Local4 || Ones == Local4) { Local2 = 0; }
}
// gather battery data from BAT1
Local1 = ^^BAT1._BST ()
Local3 = ^^BAT1._STA ()
If (0x1f == Local3)
{
// check for invalid remaining capacity
Local4 = DerefOf (Local1 [2])
If (!Local4 || Ones == Local4) { Local3 = 0; }
}
// find primary and secondary battery
If (0x1f != Local2 && 0x1f == Local3)
{
// make primary use BAT1 data
Local0 = Local1 // BAT1._BST result
Local2 = Local3 // BAT1._STA result
Local3 = 0 // no secondary battery
}
// combine batteries into Local0 result if possible
If (0x1f == Local2 && 0x1f == Local3)
{
// _BST 0 - Battery State - if one battery is charging, then charging, else discharging
Local4 = DerefOf (Local0 [0])
Local5 = DerefOf (Local1 [0])
If (Local4 != Local5)
{
If (Local4 == 2 || Local5 == 2)
{
// 2 = charging
Local0 [0] = 2
}
ElseIf (Local4 == 1 || Local5 == 1)
{
// 1 = discharging
Local0 [0] = 1
}
ElseIf (Local4 == 3 || Local5 == 3)
{
Local0 [0] = 3
}
ElseIf (Local4 == 4 || Local5 == 4)
{
// critical
Local0 [0] = 4
}
ElseIf (Local4 == 5 || Local5 == 5)
{
// critical and discharging
Local0 [0] = 5
}
// if none of the above, just leave as BAT0 is
}
// _BST 1 - Battery Present Rate - add BAT0 and BAT1 values
Local0 [1] = DerefOf (Local0 [1]) + DerefOf (Local1 [1])
// _BST 2 - Battery Remaining Capacity - add BAT0 and BAT1 values
Local0 [2] = DerefOf (Local0 [2]) + DerefOf (Local1 [2])
// _BST 3 - Battery Present Voltage - average between BAT0 and BAT1 values
Local0 [3] = (DerefOf (Local0 [3]) + DerefOf (Local1 [3])) / 2
}
Return (Local0)
} // _BST
} // BATC
} // Scope (...)
}
//EOF