1 | // A small context defining the notion of an ordered type. (The standard |
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2 | // library should probably contain a context for this purpose.) |
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3 | context ordered(type T) { |
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4 | int ?<?(T, T), ?<=?(T, T); |
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5 | }; |
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6 | |
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7 | // A subrange type resembling an Ada subtype with a base type and a range |
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8 | // constraint. |
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9 | type subrange(type base_t | ordered(base_t), base_t low = 0, base_t high = 8) = base_t; |
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10 | |
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11 | // Note that subrange() can be applied to floating-point and pointer types, not |
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12 | // just integral types. |
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13 | // This requires a "type generator" extension to Cforall. Type generators |
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14 | // must accept type and non-type parameters, which is beyond what we discussed |
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15 | // previously. Type parameters must be usable in the declaration of |
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16 | // subsequent parameters: parameter T is used to declare parameters "low" |
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17 | // and "high". |
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18 | |
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19 | // Example usage: |
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20 | subrange(unsigned, 1, 31) day_of_month; |
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21 | subrange(char, 'a', 'z') lcase; |
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22 | subrange(int, 0, (rand() & 0xF) ) foo; |
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23 | |
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24 | // What sorts of expressions can be used as arguments of type generators? Is |
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25 | // "subrange(int, 0, rand() & 0xF)" legal? Probably. The nearest C equivalent |
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26 | // to the "low" and "high" arguments is the array size in a variable-length |
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27 | // array declaration, and C allows assignment expressions there. |
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28 | |
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29 | // Convenient access to subrange bounds, for instance for iteration: |
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30 | forall (type T, T low, T high) |
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31 | T lbound( subrange(T, low, high) v) { |
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32 | return low; |
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33 | } |
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34 | |
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35 | forall (type T, T low, T high) |
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36 | T hbound( subrange(T, low, high) v) { |
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37 | return high; |
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38 | } |
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39 | |
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40 | // Example usage: |
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41 | unsigned lday = lbound(day_of_month); |
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42 | |
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43 | // Assignment from the base type, with bounds checking. I'll ignore the issue |
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44 | // of exception handling here. Inlining allows the compiler to eliminate |
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45 | // bounds checks. |
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46 | forall (type T | ordered(T), T low, T high) |
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47 | inline subrange(T, low, high) ?=?(subrange(T, low, high)* target, T source) { |
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48 | if (low <= source && source <= high) *((T*)target) = source; |
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49 | else abort(); |
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50 | return target; |
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51 | } |
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52 | |
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53 | // Assignment between subranges with a common base type. The bounds check |
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54 | // compares range bounds so that the compiler can optimize checks away when the |
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55 | // ranges are known to overlap. |
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56 | forall (type T | ordered(T), T t_low, T t_high, T s_low, T s_high) |
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57 | inline subrange(T, t_low, t_high) ?=?(subrange(T, t_low, t_high)* target, |
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58 | subrange(T, s_low, s_high) source) { |
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59 | if ( (t_low <= s_low || t_low <= source) |
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60 | && (s_high <= t_high || source <= t_high) ) *((T*)target) = source; |
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61 | else abort(); |
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62 | return target; |
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63 | } |
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