#include "master.hpp" namespace factor { void factor_vm::primitive_bignum_to_fixnum() { ctx->replace(tag_fixnum(bignum_to_fixnum(untag(ctx->peek())))); } void factor_vm::primitive_bignum_to_fixnum_strict() { ctx->replace(tag_fixnum(bignum_to_fixnum_strict(untag(ctx->peek())))); } void factor_vm::primitive_float_to_fixnum() { ctx->replace(tag_fixnum(float_to_fixnum(ctx->peek()))); } /* does not allocate, even though from_signed_cell can allocate */ /* Division can only overflow when we are dividing the most negative fixnum by -1. */ void factor_vm::primitive_fixnum_divint() { fixnum y = untag_fixnum(ctx->pop()); fixnum x = untag_fixnum(ctx->peek()); fixnum result = x / y; if (result == -fixnum_min) /* Does not allocate */ ctx->replace(from_signed_cell(-fixnum_min)); else ctx->replace(tag_fixnum(result)); } /* does not allocate, even though from_signed_cell can allocate */ void factor_vm::primitive_fixnum_divmod() { cell* s0 = (cell*)(ctx->datastack); cell* s1 = (cell*)(ctx->datastack - sizeof(cell)); fixnum y = untag_fixnum(*s0); fixnum x = untag_fixnum(*s1); if (y == -1 && x == fixnum_min) { /* Does not allocate */ *s1 = from_signed_cell(-fixnum_min); *s0 = tag_fixnum(0); } else { *s1 = tag_fixnum(x / y); *s0 = tag_fixnum(x % y); } } /* * If we're shifting right by n bits, we won't overflow as long as none of the * high WORD_SIZE-TAG_BITS-n bits are set. */ inline fixnum factor_vm::sign_mask(fixnum x) { return x >> (WORD_SIZE - 1); } inline fixnum factor_vm::branchless_max(fixnum x, fixnum y) { return (x - ((x - y) & sign_mask(x - y))); } inline fixnum factor_vm::branchless_abs(fixnum x) { return (x ^ sign_mask(x)) - sign_mask(x); } /* Allocates memory */ void factor_vm::primitive_fixnum_shift() { fixnum y = untag_fixnum(ctx->pop()); fixnum x = untag_fixnum(ctx->peek()); if (x == 0) return; else if (y < 0) { y = branchless_max(y, -WORD_SIZE + 1); ctx->replace(tag_fixnum(x >> -y)); return; } else if (y < WORD_SIZE - TAG_BITS) { fixnum mask = -((fixnum)1 << (WORD_SIZE - 1 - TAG_BITS - y)); if (!(branchless_abs(x) & mask)) { ctx->replace(tag_fixnum(x << y)); return; } } ctx->replace(tag(bignum_arithmetic_shift(fixnum_to_bignum(x), y))); } /* Allocates memory */ void factor_vm::primitive_fixnum_to_bignum() { ctx->replace(tag(fixnum_to_bignum(untag_fixnum(ctx->peek())))); } /* Allocates memory */ void factor_vm::primitive_float_to_bignum() { ctx->replace(tag(float_to_bignum(ctx->peek()))); } #define POP_BIGNUMS(x, y) \ bignum* y = untag(ctx->pop()); \ bignum* x = untag(ctx->peek()); void factor_vm::primitive_bignum_eq() { POP_BIGNUMS(x, y); ctx->replace(tag_boolean(bignum_equal_p(x, y))); } /* Allocates memory */ void factor_vm::primitive_bignum_add() { POP_BIGNUMS(x, y); ctx->replace(tag(bignum_add(x, y))); } /* Allocates memory */ void factor_vm::primitive_bignum_subtract() { POP_BIGNUMS(x, y); ctx->replace(tag(bignum_subtract(x, y))); } /* Allocates memory */ void factor_vm::primitive_bignum_multiply() { POP_BIGNUMS(x, y); ctx->replace(tag(bignum_multiply(x, y))); } /* Allocates memory */ void factor_vm::primitive_bignum_divint() { POP_BIGNUMS(x, y); ctx->replace(tag(bignum_quotient(x, y))); } /* Allocates memory */ void factor_vm::primitive_bignum_divmod() { cell* s0 = (cell*)(ctx->datastack); cell* s1 = (cell*)(ctx->datastack - sizeof(cell)); bignum* y = untag(*s0); bignum* x = untag(*s1); bignum* q, *r; bignum_divide(x, y, &q, &r); *s1 = tag(q); *s0 = tag(r); } void factor_vm::primitive_bignum_mod() { POP_BIGNUMS(x, y); ctx->replace(tag(bignum_remainder(x, y))); } void factor_vm::primitive_bignum_gcd() { POP_BIGNUMS(x, y); ctx->replace(tag(bignum_gcd(x, y))); } void factor_vm::primitive_bignum_and() { POP_BIGNUMS(x, y); ctx->replace(tag(bignum_bitwise_and(x, y))); } void factor_vm::primitive_bignum_or() { POP_BIGNUMS(x, y); ctx->replace(tag(bignum_bitwise_ior(x, y))); } void factor_vm::primitive_bignum_xor() { POP_BIGNUMS(x, y); ctx->replace(tag(bignum_bitwise_xor(x, y))); } /* Allocates memory */ void factor_vm::primitive_bignum_shift() { fixnum y = untag_fixnum(ctx->pop()); bignum* x = untag(ctx->peek()); ctx->replace(tag(bignum_arithmetic_shift(x, y))); } void factor_vm::primitive_bignum_less() { POP_BIGNUMS(x, y); ctx->replace(tag_boolean(bignum_compare(x, y) == bignum_comparison_less)); } void factor_vm::primitive_bignum_lesseq() { POP_BIGNUMS(x, y); ctx->replace(tag_boolean(bignum_compare(x, y) != bignum_comparison_greater)); } void factor_vm::primitive_bignum_greater() { POP_BIGNUMS(x, y); ctx->replace(tag_boolean(bignum_compare(x, y) == bignum_comparison_greater)); } void factor_vm::primitive_bignum_greatereq() { POP_BIGNUMS(x, y); ctx->replace(tag_boolean(bignum_compare(x, y) != bignum_comparison_less)); } void factor_vm::primitive_bignum_not() { ctx->replace(tag(bignum_bitwise_not(untag(ctx->peek())))); } void factor_vm::primitive_bignum_bitp() { int bit = (int)to_fixnum(ctx->pop()); bignum* x = untag(ctx->peek()); ctx->replace(tag_boolean(bignum_logbitp(bit, x))); } void factor_vm::primitive_bignum_log2() { ctx->replace(tag(bignum_integer_length(untag(ctx->peek())))); } /* Allocates memory */ void factor_vm::primitive_fixnum_to_float() { ctx->replace(allot_float(fixnum_to_float(ctx->peek()))); } /* Allocates memory */ void factor_vm::primitive_format_float() { byte_array* array = allot_byte_array(100); char* format = alien_offset(ctx->pop()); double value = untag_float_check(ctx->peek()); SNPRINTF(array->data(), 99, format, value); ctx->replace(tag(array)); } #define POP_FLOATS(x, y) \ double y = untag_float(ctx->pop()); \ double x = untag_float(ctx->peek()); void factor_vm::primitive_float_eq() { POP_FLOATS(x, y); ctx->replace(tag_boolean(x == y)); } /* Allocates memory */ void factor_vm::primitive_float_add() { POP_FLOATS(x, y); ctx->replace(allot_float(x + y)); } /* Allocates memory */ void factor_vm::primitive_float_subtract() { POP_FLOATS(x, y); ctx->replace(allot_float(x - y)); } /* Allocates memory */ void factor_vm::primitive_float_multiply() { POP_FLOATS(x, y); ctx->replace(allot_float(x * y)); } /* Allocates memory */ void factor_vm::primitive_float_divfloat() { POP_FLOATS(x, y); ctx->replace(allot_float(x / y)); } void factor_vm::primitive_float_less() { POP_FLOATS(x, y); ctx->replace(tag_boolean(x < y)); } void factor_vm::primitive_float_lesseq() { POP_FLOATS(x, y); ctx->replace(tag_boolean(x <= y)); } void factor_vm::primitive_float_greater() { POP_FLOATS(x, y); ctx->replace(tag_boolean(x > y)); } void factor_vm::primitive_float_greatereq() { POP_FLOATS(x, y); ctx->replace(tag_boolean(x >= y)); } /* Allocates memory */ void factor_vm::primitive_float_bits() { ctx->replace( from_unsigned_cell(float_bits((float)untag_float_check(ctx->peek())))); } /* Allocates memory */ void factor_vm::primitive_bits_float() { ctx->replace(allot_float(bits_float((uint32_t)to_cell(ctx->peek())))); } void factor_vm::primitive_double_bits() { ctx->replace(from_unsigned_8(double_bits(untag_float_check(ctx->peek())))); } /* Allocates memory */ void factor_vm::primitive_bits_double() { ctx->replace(allot_float(bits_double(to_unsigned_8(ctx->peek())))); } /* Cannot allocate. */ #define CELL_TO_FOO(name, type, converter) \ type factor_vm::name(cell tagged) { \ switch (TAG(tagged)) { \ case FIXNUM_TYPE: \ return (type)untag_fixnum(tagged); \ case BIGNUM_TYPE: \ return converter(untag(tagged)); \ default: \ type_error(FIXNUM_TYPE, tagged); \ return 0; /* can't happen */ \ } \ } \ VM_C_API type name(cell tagged, factor_vm* parent) { \ return parent->name(tagged); \ } CELL_TO_FOO(to_fixnum, fixnum, bignum_to_fixnum) CELL_TO_FOO(to_fixnum_strict, fixnum, bignum_to_fixnum_strict) CELL_TO_FOO(to_cell, cell, bignum_to_cell) CELL_TO_FOO(to_signed_8, int64_t, bignum_to_long_long) CELL_TO_FOO(to_unsigned_8, uint64_t, bignum_to_ulong_long) /* Allocates memory */ VM_C_API cell from_signed_cell(fixnum integer, factor_vm* parent) { return parent->from_signed_cell(integer); } /* Allocates memory */ VM_C_API cell from_unsigned_cell(cell integer, factor_vm* parent) { return parent->from_unsigned_cell(integer); } /* Allocates memory */ cell factor_vm::from_signed_8(int64_t n) { if (n < fixnum_min || n > fixnum_max) return tag(long_long_to_bignum(n)); else return tag_fixnum((fixnum)n); } VM_C_API cell from_signed_8(int64_t n, factor_vm* parent) { return parent->from_signed_8(n); } /* Allocates memory */ cell factor_vm::from_unsigned_8(uint64_t n) { if (n > (uint64_t)fixnum_max) return tag(ulong_long_to_bignum(n)); else return tag_fixnum((fixnum)n); } VM_C_API cell from_unsigned_8(uint64_t n, factor_vm* parent) { return parent->from_unsigned_8(n); } /* Cannot allocate */ float factor_vm::to_float(cell value) { return (float)untag_float_check(value); } /* Cannot allocate */ double factor_vm::to_double(cell value) { return untag_float_check(value); } /* The fixnum+, fixnum- and fixnum* primitives are defined in cpu_*.S. On overflow, they call these functions. */ /* Allocates memory */ inline void factor_vm::overflow_fixnum_add(fixnum x, fixnum y) { ctx->replace( tag(fixnum_to_bignum(untag_fixnum(x) + untag_fixnum(y)))); } VM_C_API void overflow_fixnum_add(fixnum x, fixnum y, factor_vm* parent) { parent->overflow_fixnum_add(x, y); } /* Allocates memory */ inline void factor_vm::overflow_fixnum_subtract(fixnum x, fixnum y) { ctx->replace( tag(fixnum_to_bignum(untag_fixnum(x) - untag_fixnum(y)))); } VM_C_API void overflow_fixnum_subtract(fixnum x, fixnum y, factor_vm* parent) { parent->overflow_fixnum_subtract(x, y); } /* Allocates memory */ inline void factor_vm::overflow_fixnum_multiply(fixnum x, fixnum y) { data_root bx(fixnum_to_bignum(x), this); data_root by(fixnum_to_bignum(y), this); cell ret = tag(bignum_multiply(bx.untagged(), by.untagged())); ctx->replace(ret); } VM_C_API void overflow_fixnum_multiply(fixnum x, fixnum y, factor_vm* parent) { parent->overflow_fixnum_multiply(x, y); } }