ableos_time/ableos/shitty_code_to_rewrite/shutdown_in_c.c

// //
// // here is the slighlty complicated ACPI poweroff code
// //

#include <stddef.h>
#include <print.h>
#include <string.h>
#include <io.h>
#include <time.h>

dword *SMI_CMD;
byte ACPI_ENABLE;
byte ACPI_DISABLE;
dword *PM1a_CNT;
dword *PM1b_CNT;
word SLP_TYPa;
word SLP_TYPb;
word SLP_EN;
word SCI_EN;
byte PM1_CNT_LEN;

struct RSDPtr
{
   byte Signature[8];
   byte CheckSum;
   byte OemID[6];
   byte Revision;
   dword *RsdtAddress;
};

struct FACP
{
   byte Signature[4];
   dword Length;
   byte unneded1[40 - 8];
   dword *DSDT;
   byte unneded2[48 - 44];
   dword *SMI_CMD;
   byte ACPI_ENABLE;
   byte ACPI_DISABLE;
   byte unneded3[64 - 54];
   dword *PM1a_CNT_BLK;
   dword *PM1b_CNT_BLK;
   byte unneded4[89 - 72];
   byte PM1_CNT_LEN;
};

// check if the given address has a valid header
unsigned int *acpiCheckRSDPtr(unsigned int *ptr)
{
   char *sig = "RSD PTR ";
   struct RSDPtr *rsdp = (struct RSDPtr *)ptr;
   byte *bptr;
   byte check = 0;
   int i;

   if (memcmp(sig, rsdp, 8) == 0)
   {
      // check checksum rsdpd
      bptr = (byte *)ptr;
      for (i = 0; i < sizeof(struct RSDPtr); i++)
      {
         check += *bptr;
         bptr++;
      }

      // found valid rsdpd
      if (check == 0)
      {
         /*
          if (desc->Revision == 0)
            wrstr("acpi 1");
         else
            wrstr("acpi 2");
         */
         return (unsigned int *)rsdp->RsdtAddress;
      }
   }

   return NULL;
}

// finds the acpi header and returns the address of the rsdt
unsigned int *acpiGetRSDPtr(void)
{
   unsigned int *addr;
   unsigned int *rsdp;

   // search below the 1mb mark for RSDP signature
   for (addr = (unsigned int *)0x000E0000; (int)addr < 0x00100000; addr += 0x10 / sizeof(addr))
   {
      rsdp = acpiCheckRSDPtr(addr);
      if (rsdp != NULL)
         return rsdp;
   }

   // at address 0x40:0x0E is the RM segment of the ebda
   int ebda = *((short *)0x40E);    // get pointer
   ebda = ebda * 0x10 & 0x000FFFFF; // transform segment into linear address

   // search Extended BIOS Data Area for the Root System Description Pointer signature
   for (addr = (unsigned int *)ebda; (int)addr < ebda + 1024; addr += 0x10 / sizeof(addr))
   {
      rsdp = acpiCheckRSDPtr(addr);
      if (rsdp != NULL)
         return rsdp;
   }

   return NULL;
}

// checks for a given header and validates checksum
int acpiCheckHeader(unsigned int *ptr, char *sig)
{
   if (memcmp(ptr, sig, 4) == 0)
   {
      char *checkPtr = (char *)ptr;
      int len = *(ptr + 1);
      char check = 0;
      while (0 < len--)
      {
         check += *checkPtr;
         checkPtr++;
      }
      if (check == 0)
         return 0;
   }
   return -1;
}

int acpiEnable(void)
{
   // check if acpi is enabled
   if ((inw((unsigned int)PM1a_CNT) & SCI_EN) == 0)
   {
      // check if acpi can be enabled
      if (SMI_CMD != 0 && ACPI_ENABLE != 0)
      {
         outb((unsigned int)SMI_CMD, ACPI_ENABLE); // send acpi enable command
         // give 3 seconds time to enable acpi
         int i;
         for (i = 0; i < 300; i++)
         {
            if ((inw((unsigned int)PM1a_CNT) & SCI_EN) == 1)
               break;
            sleep(10);
         }
         if (PM1b_CNT != 0)
            for (; i < 300; i++)
            {
               if ((inw((unsigned int)PM1b_CNT) & SCI_EN) == 1)
                  break;
               sleep(10);
            }
         if (i < 300)
         {
            wrstr("enabled acpi.\n");
            return 0;
         }
         else
         {
            wrstr("couldn't enable acpi.\n");
            return -1;
         }
      }
      else
      {
         wrstr("no known way to enable acpi.\n");
         return -1;
      }
   }
   else
   {
      //wrstr("acpi was already enabled.\n");
      return 0;
   }
}

//
// bytecode of the \_S5 object
// -----------------------------------------
//        | (optional) |    |    |    |
// NameOP | \          | _  | S  | 5  | _
// 08     | 5A         | 5F | 53 | 35 | 5F
//
// -----------------------------------------------------------------------------------------------------------
//           |           |              | ( SLP_TYPa   ) | ( SLP_TYPb   ) | ( Reserved   ) | (Reserved    )
// PackageOP | PkgLength | NumElements  | byteprefix Num | byteprefix Num | byteprefix Num | byteprefix Num
// 12        | 0A        | 04           | 0A         05  | 0A          05 | 0A         05  | 0A         05
//
//----this-structure-was-also-seen----------------------
// PackageOP | PkgLength | NumElements |
// 12        | 06        | 04          | 00 00 00 00
//
// (Pkglength bit 6-7 encode additional PkgLength bytes [shouldn't be the case here])
//
int initAcpi(void)
{
   unsigned int *ptr = acpiGetRSDPtr();

   // check if address is correct  ( if acpi is available on this pc )
   if (ptr != NULL && acpiCheckHeader(ptr, "RSDT") == 0)
   {
      // the RSDT contains an unknown number of pointers to acpi tables
      int entrys = *(ptr + 1);
      entrys = (entrys - 36) / 4;
      ptr += 36 / 4; // skip header information

      while (0 < entrys--)
      {
         // check if the desired table is reached
         if (acpiCheckHeader((unsigned int *)*ptr, "FACP") == 0)
         {
            entrys = -2;
            struct FACP *facp = (struct FACP *)*ptr;
            if (acpiCheckHeader((unsigned int *)facp->DSDT, "DSDT") == 0)
            {
               // search the \_S5 package in the DSDT
               char *S5Addr = (char *)facp->DSDT + 36; // skip header
               int dsdtLength = *(facp->DSDT + 1) - 36;
               while (0 < dsdtLength--)
               {
                  if (memcmp(S5Addr, "_S5_", 4) == 0)
                     break;
                  S5Addr++;
               }
               // check if \_S5 was found
               if (dsdtLength > 0)
               {
                  // check for valid AML structure
                  if ((*(S5Addr - 1) == 0x08 || (*(S5Addr - 2) == 0x08 && *(S5Addr - 1) == '\\')) && *(S5Addr + 4) == 0x12)
                  {
                     S5Addr += 5;
                     // calculate PkgLength size
                     S5Addr += ((*S5Addr &0xC0)>>6) +2; 

                     if (*S5Addr == 0x0A)
                        S5Addr++; // skip byteprefix
                     SLP_TYPa = *(S5Addr) << 10;
                     S5Addr++;

                     if (*S5Addr == 0x0A)
                        S5Addr++; // skip byteprefix
                     SLP_TYPb = *(S5Addr) << 10;

                     SMI_CMD = facp->SMI_CMD;

                     ACPI_ENABLE = facp->ACPI_ENABLE;
                     ACPI_DISABLE = facp->ACPI_DISABLE;

                     PM1a_CNT = facp->PM1a_CNT_BLK;
                     PM1b_CNT = facp->PM1b_CNT_BLK;

                     PM1_CNT_LEN = facp->PM1_CNT_LEN;

                     SLP_EN = 1 << 13;
                     SCI_EN = 1;

                     return 0;
                  }
                  else
                  {
                     wrstr("\\_S5 parse error.\n");
                  }
               }
               else
               {
                  wrstr("\\_S5 not present.\n");
               }
            }
            else
            {
               wrstr("DSDT invalid.\n");
            }
         }
         ptr++;
      }
      wrstr("no valid FACP present.\n");
   }
   else
   {
      wrstr("no acpi.\n");
   }

   return -1;
}

void acpiPowerOff(void)
{
   // SCI_EN is set to 1 if acpi shutdown is possible
   if (SCI_EN == 0)
      return;

   acpiEnable();

   // send the shutdown command
   outw((unsigned int)PM1a_CNT, SLP_TYPa | SLP_EN);
   if (PM1b_CNT != 0)
      outw((unsigned int)PM1b_CNT, SLP_TYPb | SLP_EN);

   wrstr("acpi poweroff failed.\n");
}