package apl
import (
"fmt"
"strconv"
"review.coreboot.org/coreboot.git/util/intelp2m/platforms/common"
"review.coreboot.org/coreboot.git/util/intelp2m/config"
"review.coreboot.org/coreboot.git/util/intelp2m/fields"
)
const (
PAD_CFG_DW0_RO_FIELDS = (0x1 << 27) | (0x1 << 24) | (0x3 << 21) | (0xf << 16) | 0xfc
PAD_CFG_DW1_RO_FIELDS = 0xfffc00ff
)
const (
PAD_CFG_DW0 = common.PAD_CFG_DW0
PAD_CFG_DW1 = common.PAD_CFG_DW1
MAX_DW_NUM = common.MAX_DW_NUM
)
const (
PULL_NONE = 0x0 // 0 000: none
PULL_DN_5K = 0x2 // 0 010: 5k wpd (Only available on SMBus GPIOs)
PULL_DN_20K = 0x4 // 0 100: 20k wpd
// PULL_NONE = 0x8 // 1 000: none
PULL_UP_1K = 0x9 // 1 001: 1k wpu (Only available on I2C GPIOs)
PULL_UP_2K = 0xb // 1 011: 2k wpu (Only available on I2C GPIOs)
PULL_UP_20K = 0xc // 1 100: 20k wpu
PULL_UP_667 = 0xd // 1 101: 1k & 2k wpu (Only available on I2C GPIOs)
PULL_NATIVE = 0xf // 1 111: (optional) Native controller selected by Pad Mode
)
type PlatformSpecific struct {}
// RemmapRstSrc - remmap Pad Reset Source Config
// remmap is not required because it is the same as common.
func (PlatformSpecific) RemmapRstSrc() {}
// Adds The Pad Termination (TERM) parameter from DW1 to the macro as a new argument
// return: macro
func (PlatformSpecific) Pull() {
macro := common.GetMacro()
dw1 := macro.Register(PAD_CFG_DW1)
var pull = map[uint8]string{
PULL_NONE: "NONE",
PULL_DN_5K: "DN_5K",
PULL_DN_20K: "DN_20K",
PULL_UP_1K: "UP_1K",
PULL_UP_2K: "UP_2K",
PULL_UP_20K: "UP_20K",
PULL_UP_667: "UP_667",
PULL_NATIVE: "NATIVE",
}
terminationFieldValue := dw1.GetTermination()
str, valid := pull[terminationFieldValue]
if !valid {
str = strconv.Itoa(int(terminationFieldValue))
fmt.Println("Error", macro.PadIdGet(), " invalid TERM value = ", str)
}
macro.Separator().Add(str)
}
// Generate macro to cause peripheral IRQ when configured in GPIO input mode
func ioApicRoute() bool {
macro := common.GetMacro()
dw0 := macro.Register(PAD_CFG_DW0)
dw1 := macro.Register(PAD_CFG_DW1)
if dw0.GetGPIOInputRouteIOxAPIC() == 0 {
return false
}
macro.Add("_APIC")
if dw1.GetIOStandbyState() != 0 || dw1.GetIOStandbyTermination() != 0 {
// e.g. H1_PCH_INT_ODL
// PAD_CFG_GPI_APIC_IOS(GPIO_63, NONE, DEEP, LEVEL, INVERT, TxDRxE, DISPUPD),
macro.Add("_IOS(").Id().Pull().Rstsrc().Trig().Invert().IOSstate().IOTerm()
} else {
// PAD_CFG_GPI_APIC(pad, pull, rst, trig, inv)
macro.Add("(").Id().Pull().Rstsrc().Trig().Invert().Add("),")
}
macro.Add("),")
return true
}
// Generate macro to cause NMI when configured in GPIO input mode
func nmiRoute() bool {
macro := common.GetMacro()
if macro.Register(PAD_CFG_DW0).GetGPIOInputRouteNMI() == 0 {
return false
}
// e.g. PAD_CFG_GPI_NMI(GPIO_24, UP_20K, DEEP, LEVEL, INVERT),
macro.Add("_NMI").Add("(").Id().Pull().Rstsrc().Trig().Invert().Add("),")
return true
}
// Generate macro to cause SCI when configured in GPIO input mode
func sciRoute() bool {
macro := common.GetMacro()
dw0 := macro.Register(PAD_CFG_DW0)
dw1 := macro.Register(PAD_CFG_DW0)
if dw0.GetGPIOInputRouteSCI() == 0 {
return false
}
if dw1.GetIOStandbyState() != 0 || dw1.GetIOStandbyTermination() != 0 {
// PAD_CFG_GPI_SCI_IOS(GPIO_141, NONE, DEEP, EDGE_SINGLE, INVERT, IGNORE, DISPUPD),
macro.Add("_SCI_IOS")
macro.Add("(").Id().Pull().Rstsrc().Trig().Invert().IOSstate().IOTerm()
} else if dw0.GetRXLevelEdgeConfiguration() & 0x1 != 0 {
// e.g. PAD_CFG_GPI_ACPI_SCI(GPP_G2, NONE, DEEP, YES),
macro.Add("_ACPI_SCI").Add("(").Id().Pull().Rstsrc().Invert()
} else {
// e.g. PAD_CFG_GPI_SCI(GPP_B18, UP_20K, PLTRST, LEVEL, INVERT),
macro.Add("_SCI").Add("(").Id().Pull().Rstsrc().Trig().Invert()
}
macro.Add("),")
return true
}
// Generate macro to cause SMI when configured in GPIO input mode
func smiRoute() bool {
macro := common.GetMacro()
dw0 := macro.Register(PAD_CFG_DW0)
dw1 := macro.Register(PAD_CFG_DW1)
if dw0.GetGPIOInputRouteSMI() == 0 {
return false
}
if dw1.GetIOStandbyState() != 0 || dw1.GetIOStandbyTermination() != 0 {
// PAD_CFG_GPI_SMI_IOS(GPIO_41, UP_20K, DEEP, EDGE_SINGLE, NONE, IGNORE, SAME),
macro.Add("_SMI_IOS")
macro.Add("(").Id().Pull().Rstsrc().Trig().Invert().IOSstate().IOTerm()
} else if dw0.GetRXLevelEdgeConfiguration() & 0x1 != 0 {
// e.g. PAD_CFG_GPI_ACPI_SMI(GPP_I3, NONE, DEEP, YES),
macro.Add("_ACPI_SMI").Add("(").Id().Pull().Rstsrc().Invert()
} else {
// e.g. PAD_CFG_GPI_SMI(GPP_E3, NONE, PLTRST, EDGE_SINGLE, NONE),
macro.Add("_SMI").Add("(").Id().Pull().Rstsrc().Trig().Invert()
}
macro.Add("),")
return true
}
// Generate macro for GPI port
func (PlatformSpecific) GpiMacroAdd() {
macro := common.GetMacro()
var ids []string
macro.Set("PAD_CFG_GPI")
for routeid, isRoute := range map[string]func() (bool) {
"IOAPIC": ioApicRoute,
"SCI": sciRoute,
"SMI": smiRoute,
"NMI": nmiRoute,
} {
if isRoute() {
ids = append(ids, routeid)
}
}
switch argc := len(ids); argc {
case 0:
dw1 := macro.Register(PAD_CFG_DW1)
isIOStandbyStateUsed := dw1.GetIOStandbyState() != 0
isIOStandbyTerminationUsed := dw1.GetIOStandbyTermination() != 0
if isIOStandbyStateUsed && !isIOStandbyTerminationUsed {
macro.Add("_TRIG_IOSSTATE_OWN(")
// PAD_CFG_GPI_TRIG_IOSSTATE_OWN(pad, pull, rst, trig, iosstate, own)
macro.Id().Pull().Rstsrc().Trig().IOSstate().Own().Add("),")
} else if isIOStandbyTerminationUsed {
macro.Add("_TRIG_IOS_OWN(")
// PAD_CFG_GPI_TRIG_IOS_OWN(pad, pull, rst, trig, iosstate, iosterm, own)
macro.Id().Pull().Rstsrc().Trig().IOSstate().IOTerm().Own().Add("),")
} else {
// PAD_CFG_GPI_TRIG_OWN(pad, pull, rst, trig, own)
macro.Add("_TRIG_OWN(").Id().Pull().Rstsrc().Trig().Own().Add("),")
}
case 1:
// GPI with IRQ route
if config.AreFieldsIgnored() {
macro.SetPadOwnership(common.PAD_OWN_ACPI)
}
case 2:
// PAD_CFG_GPI_DUAL_ROUTE(pad, pull, rst, trig, inv, route1, route2)
macro.Set("PAD_CFG_GPI_DUAL_ROUTE(").Id().Pull().Rstsrc().Trig().Invert()
macro.Add(", " + ids[0] + ", " + ids[1] + "),")
if config.AreFieldsIgnored() {
macro.SetPadOwnership(common.PAD_OWN_ACPI)
}
default:
// Clear the control mask so that the check fails and "Advanced" macro is
// generated
macro.Register(PAD_CFG_DW0).CntrMaskFieldsClear(common.AllFields)
}
}
// Adds PAD_CFG_GPO macro with arguments
func (PlatformSpecific) GpoMacroAdd() {
macro := common.GetMacro()
dw0 := macro.Register(PAD_CFG_DW0)
dw1 := macro.Register(PAD_CFG_DW1)
term := dw1.GetTermination()
macro.Set("PAD_CFG")
if dw1.GetIOStandbyState() != 0 || dw1.GetIOStandbyTermination() != 0 {
// PAD_CFG_GPO_IOSSTATE_IOSTERM(GPIO_91, 0, DEEP, NONE, Tx0RxDCRx0, DISPUPD),
// PAD_CFG_GPO_IOSSTATE_IOSTERM(pad, val, rst, pull, iosstate, ioterm)
macro.Add("_GPO_IOSSTATE_IOSTERM(").Id().Val().Rstsrc().Pull().IOSstate().IOTerm()
} else {
if term != 0 {
// e.g. PAD_CFG_TERM_GPO(GPP_B23, 1, DN_20K, DEEP),
// PAD_CFG_TERM_GPO(pad, val, pull, rst)
macro.Add("_TERM")
}
macro.Add("_GPO(").Id().Val()
if term != 0 {
macro.Pull()
}
macro.Rstsrc()
}
macro.Add("),")
if dw0.GetRXLevelEdgeConfiguration() != common.TRIG_OFF {
// ignore if trig = OFF is not set
dw0.CntrMaskFieldsClear(common.RxLevelEdgeConfigurationMask)
}
}
// Adds PAD_CFG_NF macro with arguments
func (PlatformSpecific) NativeFunctionMacroAdd() {
macro := common.GetMacro()
dw1 := macro.Register(PAD_CFG_DW1)
isIOStandbyStateUsed := dw1.GetIOStandbyState() != 0
isIOStandbyTerminationUsed := dw1.GetIOStandbyTermination() != 0
macro.Set("PAD_CFG_NF")
if !isIOStandbyTerminationUsed && isIOStandbyStateUsed {
if dw1.GetIOStandbyState() == common.StandbyIgnore {
// PAD_CFG_NF_IOSTANDBY_IGNORE(PMU_SLP_S0_B, NONE, DEEP, NF1),
macro.Add("_IOSTANDBY_IGNORE(").Id().Pull().Rstsrc().Padfn()
} else {
// PAD_CFG_NF_IOSSTATE(GPIO_22, UP_20K, DEEP, NF2, TxDRxE),
macro.Add("_IOSSTATE(").Id().Pull().Rstsrc().Padfn().IOSstate()
}
} else if isIOStandbyTerminationUsed {
// PAD_CFG_NF_IOSSTATE_IOSTERM(GPIO_103, NATIVE, DEEP, NF1, MASK, SAME),
macro.Add("_IOSSTATE_IOSTERM(").Id().Pull().Rstsrc().Padfn().IOSstate().IOTerm()
} else {
// e.g. PAD_CFG_NF(GPP_D23, NONE, DEEP, NF1)
macro.Add("(").Id().Pull().Rstsrc().Padfn()
}
macro.Add("),")
if dw0 := macro.Register(PAD_CFG_DW0); dw0.GetGPIORxTxDisableStatus() != 0 {
// Since the bufbis parameter will be ignored for NF, we should clear
// the corresponding bits in the control mask.
dw0.CntrMaskFieldsClear(common.RxTxBufDisableMask)
}
}
// Adds PAD_NC macro
func (PlatformSpecific) NoConnMacroAdd() {
macro := common.GetMacro()
dw1 := macro.Register(PAD_CFG_DW1)
if dw1.GetIOStandbyState() == common.TxDRxE {
dw0 := macro.Register(PAD_CFG_DW0)
// See comments in sunrise/macro.go : NoConnMacroAdd()
if dw0.GetRXLevelEdgeConfiguration() != common.TRIG_OFF {
dw0.CntrMaskFieldsClear(common.RxLevelEdgeConfigurationMask)
}
if dw0.GetResetConfig() != 1 { // 1 = RST_DEEP
dw0.CntrMaskFieldsClear(common.PadRstCfgMask)
}
// PAD_NC(OSC_CLK_OUT_1, DN_20K)
macro.Set("PAD_NC").Add("(").Id().Pull().Add("),")
return
}
// PAD_CFG_GPIO_HI_Z(GPIO_81, UP_20K, DEEP, HIZCRx0, DISPUPD),
macro.Set("PAD_CFG_GPIO_")
if macro.IsOwnershipDriver() {
// PAD_CFG_GPIO_DRIVER_HI_Z(GPIO_55, UP_20K, DEEP, HIZCRx1, ENPU),
macro.Add("DRIVER_")
}
macro.Add("HI_Z(").Id().Pull().Rstsrc().IOSstate().IOTerm().Add("),")
}
// GenMacro - generate pad macro
// dw0 : DW0 config register value
// dw1 : DW1 config register value
// return: string of macro
// error
func (PlatformSpecific) GenMacro(id string, dw0 uint32, dw1 uint32, ownership uint8) string {
macro := common.GetInstanceMacro(PlatformSpecific{}, fields.InterfaceGet())
// use platform-specific interface in Macro struct
macro.PadIdSet(id).SetPadOwnership(ownership)
macro.Register(PAD_CFG_DW0).CntrMaskFieldsClear(common.AllFields)
macro.Register(PAD_CFG_DW0).CntrMaskFieldsClear(common.AllFields)
macro.Register(PAD_CFG_DW0).ValueSet(dw0).ReadOnlyFieldsSet(PAD_CFG_DW0_RO_FIELDS)
macro.Register(PAD_CFG_DW1).ValueSet(dw1).ReadOnlyFieldsSet(PAD_CFG_DW1_RO_FIELDS)
return macro.Generate()
}