/************************************************* * Lowest Level MPI Algorithms Header File * * (C) 1999-2007 Jack Lloyd * * 2006 Luca Piccarreta * *************************************************/ #ifndef BOTAN_MP_ASM_INTERNAL_H__ #define BOTAN_MP_ASM_INTERNAL_H__ #include namespace Botan { extern "C" { /************************************************* * Helper Macros for amd64 Assembly * *************************************************/ #ifndef ASM #define ASM(x) x "\n\t" #endif #define ADDSUB2_OP(OPERATION, INDEX) \ ASM("movq 8*" #INDEX "(%[y]), %[carry]") \ ASM(OPERATION " %[carry], 8*" #INDEX "(%[x])") \ #define ADDSUB3_OP(OPERATION, INDEX) \ ASM("movq 8*" #INDEX "(%[x]), %[carry]") \ ASM(OPERATION " 8*" #INDEX "(%[y]), %[carry]") \ ASM("movq %[carry], 8*" #INDEX "(%[z])") \ #define LINMUL_OP(WRITE_TO, INDEX) \ ASM("movq 8*" #INDEX "(%[x]),%%rax") \ ASM("mulq %[y]") \ ASM("addq %[carry],%%rax") \ ASM("adcq $0,%%rdx") \ ASM("movq %%rdx,%[carry]") \ ASM("movq %%rax, 8*" #INDEX "(%[" WRITE_TO "])") #define MULADD_OP(IGNORED, INDEX) \ ASM("movq 8*" #INDEX "(%[x]),%%rax") \ ASM("mulq %[y]") \ ASM("addq %[carry],%%rax") \ ASM("adcq $0,%%rdx") \ ASM("addq 8*" #INDEX "(%[z]),%%rax") \ ASM("adcq $0,%%rdx") \ ASM("movq %%rdx,%[carry]") \ ASM("movq %%rax, 8*" #INDEX " (%[z])") #define DO_8_TIMES(MACRO, ARG) \ MACRO(ARG, 0) \ MACRO(ARG, 1) \ MACRO(ARG, 2) \ MACRO(ARG, 3) \ MACRO(ARG, 4) \ MACRO(ARG, 5) \ MACRO(ARG, 6) \ MACRO(ARG, 7) #define ADD_OR_SUBTRACT(CORE_CODE) \ ASM("rorq %[carry]") \ CORE_CODE \ ASM("sbbq %[carry],%[carry]") \ ASM("negq %[carry]") /************************************************* * Word Addition * *************************************************/ inline word word_add(word x, word y, word* carry) { #if 0 asm( ADD_OR_SUBTRACT(ASM("adcq %[y],%[x]")) : [x]"=r"(x), [carry]"=r"(*carry) : "0"(x), [y]"rm"(y), "1"(*carry) : "cc"); return x; #else word z = x + y; word c1 = (z < x); z += *carry; *carry = c1 | (z < *carry); return z; #endif } /************************************************* * Eight Word Block Addition, Two Argument * *************************************************/ inline word word8_add2(word x[8], const word y[8], word carry) { asm( ADD_OR_SUBTRACT(DO_8_TIMES(ADDSUB2_OP, "adcq")) : [carry]"=r"(carry) : [x]"r"(x), [y]"r"(y), "0"(carry) : "cc", "memory"); return carry; } /************************************************* * Eight Word Block Addition, Three Argument * *************************************************/ inline word word8_add3(word z[8], const word x[8], const word y[8], word carry) { asm( ADD_OR_SUBTRACT(DO_8_TIMES(ADDSUB3_OP, "adcq")) : [carry]"=r"(carry) : [x]"r"(x), [y]"r"(y), [z]"r"(z), "0"(carry) : "cc", "memory"); return carry; } /************************************************* * Word Subtraction * *************************************************/ inline word word_sub(word x, word y, word* carry) { asm( ADD_OR_SUBTRACT(ASM("sbbq %[y],%[x]")) : [x]"=r"(x), [carry]"=r"(*carry) : "0"(x), [y]"rm"(y), "1"(*carry) : "cc"); return x; } /************************************************* * Eight Word Block Subtraction, Two Argument * *************************************************/ inline word word8_sub2(word x[8], const word y[8], word carry) { asm( ADD_OR_SUBTRACT(DO_8_TIMES(ADDSUB2_OP, "sbbq")) : [carry]"=r"(carry) : [x]"r"(x), [y]"r"(y), "0"(carry) : "cc", "memory"); return carry; } /************************************************* * Eight Word Block Subtraction, Three Argument * *************************************************/ inline word word8_sub3(word z[8], const word x[8], const word y[8], word carry) { asm( ADD_OR_SUBTRACT(DO_8_TIMES(ADDSUB3_OP, "sbbq")) : [carry]"=r"(carry) : [x]"r"(x), [y]"r"(y), [z]"r"(z), "0"(carry) : "cc", "memory"); return carry; } /************************************************* * Eight Word Block Linear Multiplication * *************************************************/ inline word word8_linmul2(word x[8], word y, word carry) { asm( DO_8_TIMES(LINMUL_OP, "x") : [carry]"=r"(carry) : [x]"r"(x), [y]"rm"(y), "0"(carry) : "cc", "%rax", "%rdx"); return carry; } /************************************************* * Eight Word Block Linear Multiplication * *************************************************/ inline word word8_linmul3(word z[8], const word x[8], word y, word carry) { asm( DO_8_TIMES(LINMUL_OP, "z") : [carry]"=r"(carry) : [z]"r"(z), [x]"r"(x), [y]"rm"(y), "0"(carry) : "cc", "%rax", "%rdx"); return carry; } /************************************************* * Eight Word Block Multiply/Add * *************************************************/ inline word word8_madd3(word z[8], const word x[8], word y, word carry) { asm( DO_8_TIMES(MULADD_OP, "") : [carry]"=r"(carry) : [z]"r"(z), [x]"r"(x), [y]"rm"(y), "0"(carry) : "cc", "%rax", "%rdx"); return carry; } /************************************************* * Multiply-Add Accumulator * *************************************************/ inline void word3_muladd(word* w2, word* w1, word* w0, word x, word y) { asm( ASM("mulq %[y]") ASM("addq %[x],%[w0]") ASM("adcq %[y],%[w1]") ASM("adcq $0,%[w2]") : [w0]"=r"(*w0), [w1]"=r"(*w1), [w2]"=r"(*w2) : [x]"a"(x), [y]"d"(y), "0"(*w0), "1"(*w1), "2"(*w2) : "cc"); } /************************************************* * Multiply-Add Accumulator * *************************************************/ inline void word3_muladd_2(word* w2, word* w1, word* w0, word x, word y) { asm( ASM("mulq %[y]") ASM("addq %[x],%[w0]") ASM("adcq %[y],%[w1]") ASM("adcq $0,%[w2]") ASM("addq %[x],%[w0]") ASM("adcq %[y],%[w1]") ASM("adcq $0,%[w2]") : [w0]"=r"(*w0), [w1]"=r"(*w1), [w2]"=r"(*w2) : [x]"a"(x), [y]"d"(y), "0"(*w0), "1"(*w1), "2"(*w2) : "cc"); } #undef ASM #undef DO_8_TIMES #undef ADD_OR_SUBTRACT #undef ADDSUB2_OP #undef ADDSUB3_OP #undef LINMUL_OP #undef MULADD_OP } } #endif