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There are 8 MeP cores that serve as the media co-processor (called Venezia or VIP). The CPU ID register for them are
VENEZIA (Vision Enabling Engine / Zen-Inspired Architecture) (or VIP) is a Toshiba original multi-core sub-system which has multiple sets of
“MPE (Media Processing Engine)” suitable for image processing and multiple image processing accelerators.


= Description =
The VENEZIA is multi-grain parallellism architecture – application level (multi-core), instruction level (VLIW) and data level (SIMD).
The VENEZIA includes 4 sets of Toshiba original media processing engine “MPE” that enables simultaneous execution of up to four image recognition applications. Each MPE has a Toshiba original 32-bit RISC CPU core MeP-c5 and an image recognition coprocessor IVC2. The MPE is 3way VLIW machine that can issue up to 3 instructions (one CPU instruction and up to 2 coprocessor instructions). The IVC2 provides SIMD instructions for simultaneous operations on eight sets of 8-bit data, four sets of 16-bit data, and two sets of 32-bit data. The IVC2 can execute simultaneously up to 2 SIMD instructions. Since parallel processing of two instructions is enabled, operations on a maximum of 16 sets of 8-bit data can be processed simultaneously.
There are 8 MeP cores that serve as the media co-processor Venezia. The CPU ID register for them are:
<code>0x00300500 0x00310500 0x00320500 0x00330500 0x00340500 0x00350500 0x00360500 0x00370500</code>
<code>0x00300500 0x00310500 0x00320500 0x00330500 0x00340500 0x00350500 0x00360500 0x00370500</code>
This means they are MeP c5 cores and are uniquely numbered 48-55.
This means they are MeP c5 cores and are uniquely numbered 48-55.



Revision as of 12:58, 17 January 2020

VENEZIA (Vision Enabling Engine / Zen-Inspired Architecture) (or VIP) is a Toshiba original multi-core sub-system which has multiple sets of “MPE (Media Processing Engine)” suitable for image processing and multiple image processing accelerators.

Description

The VENEZIA is multi-grain parallellism architecture – application level (multi-core), instruction level (VLIW) and data level (SIMD).

The VENEZIA includes 4 sets of Toshiba original media processing engine “MPE” that enables simultaneous execution of up to four image recognition applications. Each MPE has a Toshiba original 32-bit RISC CPU core MeP-c5 and an image recognition coprocessor IVC2. The MPE is 3way VLIW machine that can issue up to 3 instructions (one CPU instruction and up to 2 coprocessor instructions). The IVC2 provides SIMD instructions for simultaneous operations on eight sets of 8-bit data, four sets of 16-bit data, and two sets of 32-bit data. The IVC2 can execute simultaneously up to 2 SIMD instructions. Since parallel processing of two instructions is enabled, operations on a maximum of 16 sets of 8-bit data can be processed simultaneously.

There are 8 MeP cores that serve as the media co-processor Venezia. The CPU ID register for them are: 0x00300500 0x00310500 0x00320500 0x00330500 0x00340500 0x00350500 0x00360500 0x00370500 This means they are MeP c5 cores and are uniquely numbered 48-55.

Running Code

It is easy to run your own MeP code. It appears that the code is DMA copied to MeP's private memory before resetting and executing it.

MeP payload:

.text

_start:
jmp 0x800018
jmp 0x800018
jmp 0x800018
jmp 0x800018
jmp 0x800018
jmp 0x800018

_init:
movh $0,0xf184
add3 $0,$0,0
mov $1,0x8
sw $1,0($0)

_writecpuid:
ldc $2,17
srl $2,14
ldc $1,17
add3 $2,$2,$0
add3 $2,$2,4
sw $1,0($2)

.wait:
bra .wait

On ARM:

// the following code has hard coded offsets in 1.69
int restart_vnz()
{
  volatile unsigned int *regs, *spram; // r4@1
  int v1; // r6@1
  unsigned int img_paddr; // r3@2
  int dram_base; // r0@2
  int size;
  unsigned int v4; // r0@3
  unsigned int v5; // r3@3
  int v7; // r1@6
  int v8; // r2@6

  spram = *(volatile unsigned int **)0x0190F67C;
  regs = *(volatile unsigned int **)0x0190F670;
  printf("ScePervasive2Reg: 0x%08X, spram: 0x%08X\n", regs, spram);
  ScePervasiveForDriver_0xFB01A2DD();
  img_paddr = 0x40800000; // paddr of region
  dram_base = 0x40300000;
  size = 0x400000;
  regs[192] = 0x1D001000;
  if ( dram_base < img_paddr )
  {
    v7 = img_paddr + size;
    v8 = dram_base + 0x2500000;
    if ( img_paddr + size < v8 )
    {
      regs[193] = dram_base;
      regs[194] = img_paddr;
      regs[195] = v7;
      regs[196] = v8;
    }
  }
  v4 = img_paddr >> 23 << 23;
  regs[224] = v4;
  regs[228] = 0x1E000000;
  regs[229] = 0x20000000;
  regs[230] = 0x22000000;
  regs[231] = img_paddr & 0xFE000000;
  regs[232] = 0x18000000;
  regs[233] = 0x20000000;
  regs[234] = img_paddr & 0xF8000000;
  regs[235] = (img_paddr + 0x8000000) & 0xF8000000;
  regs[236] = 0x1E000000;
  regs[237] = 0x20000000;
  regs[238] = 0x22000000;
  regs[239] = img_paddr & 0xFE000000;
  regs[256] = v4;
  regs[898] = 0xFFFF0000;
  spram[0] = 1;
  SceCpuForDriver_0xE813EBB2_clean_l2();
  regs[898];
  __asm__("dsb sy" ::: "memory");
  ScePervasiveForDriver_0xA7E64C6F_reset_vnz();
  v1 = 0;
  while (spram[0] != 8)
  {
    printf("waiting...");
    sceKernelDelayThread(100);
    if (v1++ > 20)
      break;
  }
  return 0;
}

int vnz_hack()
{
  volatile unsigned int *spram_vaddr;
  unsigned int *img_vaddr;
  int i;
  int ret;

  spram_vaddr = *(volatile unsigned int **)0x0190F67C;
  img_vaddr = *(unsigned int **)0x0190F664;
  printf("Vaddr: %08X\n", img_vaddr);
  ret = make_smc_call(1, 1, 0, 0, 0x110);
  printf("Reset VNZ: 0x%08X\n", ret);

  memset(spram_vaddr, 0, 256);
  memcpy(img_vaddr, YOUR_MEP_CODE, YOUR_MEP_CODE_LEN);
  ret = restart_vnz();
  printf("Restart VNZ: 0x%08X\n", ret);

  return 0;
}