Loading the cpuid module creates the /dev nodes cpu/*/cpuid. Good commands for breaking down cpuid data include cpuid and Dave Jones's x86info. /proc/cpuinfo (checked as of 2.6.25-rc3) will display a "cpuid_level" field for each processor in the system. There's an Intel document about using cpuid effectively, although it's given short shrift at this page.
Availability of cpuid
It's ironic that Intel claims that "any other approach may produce unpredictable results," since its algorithm is prone to failures that yield unpredictable results (as I'll demonstrate in this article). For more information on CPUID, see the text box "Pentium Detection," by Robert Moote (which accompanied the article "Processor-Detection Schemes," by Richard C. Leinecker, DDJ, June 1993).
The Intel algorithm relies on a series of PUSHF/POPF instructions to set and clear various FLAGs bits. Each generation of processor has a slightly different behavior which may be detected by this approach. This algorithm makes no attempt to detect the 80186/88 series of processors. In this regard, the algorithm is incomplete.
The 8086/88 is distinguished from the 80286 by attempting to clear bits 12 - 15 of the FLAGs register, The 8086/88 will always set these bits, regardless of what values are popped into them (see Listing One). The 286 treats these bits differently. In real mode, these bits are always cleared by the 286; in protected mode, they are used for IOPL (I/O Privilege Level) and NT (Nested Task). To continue the detection code, you need to set bits 12 - 15 in the FLAGs register, and see if they are cleared by the processor. If they are, then a 286 has been detected (see Listing Two).
If you gethis point in the algorithm, you know you have at least a 386. Therefore, it is safe to use 32-bit instructions, like PUSHFD. This will be necessary in detecting the difference between a 386 and 486. These processors are distinguished from each othmpting to set the AC flag in the EFLAGs register. This flag was introduced in the 486, The 386 never sets this bit, and always clhen it is set by POPFD. Therefore, to detect the difference between these processor generations, the algorithm attempts to set thiee if it is latched or cleared by the processor (see Listing Three).
At this point in the algorithm, you're almost home. To detect the difference between the 486 and the Pentium, you attempt to set another new EFLAG bit (bit-21) called the "ID flag." This flag has only one purpose - to indicate the presence of the CPUID instruction. This bit was first introduced on the Pentium, but later retrofitted into the 486. If the CPUID instruction exists on either processor, it may be executed to return the processor-identification information. 486s without the CPUID instruction will not be able to toggle this bit. Therefore, it is safe to execute a sequence of instructions on either processor that detects the processor's ability to toggle this bit (see Listing Four).
Once the algorithm gets to this point, you can execute the CPUID instruction to obtain the processor identification. This instruction can be run in any processor mode, at any privilege level. On the Pentium and 486, the CPUID instruction has two levels:
- Level 0 returns a vendor ID string in EBX:EDX:ECX, which says "GenuineIntel" when printed as ASCII text.
- Level 1 returns the processor identification signature - the same signature that appears in the EDX register after a processor RESET (see Listing Five).
The complete Intel algorithm is available in AP-485, or via anonymous FTP at ftp://ftp.intel.com/pub/IAL/tools_utils_demos/cpuid3.zip.
- Intel Application Note 485, "Intel Processor Identification and the CPUID Instruction" (2009-03)