Formal Verification of the VAMP Floating Point Unit

Abstract: We report on the formal verification of the floating point unit used in the VAMP processor. The dualprecision FPU is IEEE compliant and supports denormals and exceptions in hardware. The supported operations are addition, subtraction, multiplication, division, comparison, and conversions.We have formalized the IEEE standard 754. The formalization is supplemented by a rich theory of rounding, which includes notations and theorems facilitating the verification of the actual hardware. The theory of rounding enabl… Show more

“…All designs were put through reductions using a BDD-based combinational redundancy removal engine [16] before the symbolic simulator was applied. FPU ADD and FPU FMA are the verification problems of the dataflow for a floating-point "add" and "fused-multiplyadd" instruction respectively [13]. IBM 03 and IBM 06 are examples from the IBM Formal Verification Benchmarks [12].…”

“…It is indispensable for the FPU designs where we see the runs explode without any resource constraining, and go through easily with resource constraining. This is likely due to the propagation of a large number of constants which resource constraining specializes in taking advantage of, in particular when many such constants are created due to constraints [13]. The effects are somewhat less pronounced in some other examples due to the fact that they have symbolic initial values or are highly optimized, causing less constants to propagate.…”

“…Hence, in our scheme we use threshold based don't-caring that is cheap for the most part, and apply more aggressive but computationally complex don't-caring only for very large BDDs. Such an approach was essential to automatic verification of FPUs as described in [13].…”

“…Hence, in the case of example #4, 4 of the 5 case splits were fully evaluated. Case splitting on internal nodes was necessary to verify FPU designs using formal methods in a fully-automated manner, as detailed in [13].…”

“…This is achieved by modifying the intermediate BDDs in a manner such that they evaluate to the same Boolean values within the care set, but they are free to assume values in the don't-care set towards the goal of minimizing the size of the BDD [10,11]. In some applications of constraints, like manual case splitting [13], or automatic case splitting (cf. Sect.…”

Efficient Symbolic Simulation via Dynamic Scheduling, Don’t Caring, and Case Splitting

“…All designs were put through reductions using a BDD-based combinational redundancy removal engine [16] before the symbolic simulator was applied. FPU ADD and FPU FMA are the verification problems of the dataflow for a floating-point "add" and "fused-multiplyadd" instruction respectively [13]. IBM 03 and IBM 06 are examples from the IBM Formal Verification Benchmarks [12].…”

“…It is indispensable for the FPU designs where we see the runs explode without any resource constraining, and go through easily with resource constraining. This is likely due to the propagation of a large number of constants which resource constraining specializes in taking advantage of, in particular when many such constants are created due to constraints [13]. The effects are somewhat less pronounced in some other examples due to the fact that they have symbolic initial values or are highly optimized, causing less constants to propagate.…”

“…Hence, in our scheme we use threshold based don't-caring that is cheap for the most part, and apply more aggressive but computationally complex don't-caring only for very large BDDs. Such an approach was essential to automatic verification of FPUs as described in [13].…”

“…Hence, in the case of example #4, 4 of the 5 case splits were fully evaluated. Case splitting on internal nodes was necessary to verify FPU designs using formal methods in a fully-automated manner, as detailed in [13].…”

“…This is achieved by modifying the intermediate BDDs in a manner such that they evaluate to the same Boolean values within the care set, but they are free to assume values in the don't-care set towards the goal of minimizing the size of the BDD [10,11]. In some applications of constraints, like manual case splitting [13], or automatic case splitting (cf. Sect.…”

Efficient Symbolic Simulation via Dynamic Scheduling, Don’t Caring, and Case Splitting

Floating-Point Verification Using Theorem Proving

Verifying Floating-Point Algorithms