diff --git a/scripts/mk_util.py b/scripts/mk_util.py
index 33f70c98d..e32c9c3dd 100644
--- a/scripts/mk_util.py
+++ b/scripts/mk_util.py
@@ -71,6 +71,7 @@ VERBOSE=True
 DEBUG_MODE=False
 SHOW_CPPS = True
 VS_X64 = False
+VS_ARM = False
 LINUX_X64 = True
 ONLY_MAKEFILES = False
 Z3PY_SRC_DIR=None
@@ -99,6 +100,7 @@ USE_OMP=True
 FPMATH="Default"
 FPMATH_FLAGS="-mfpmath=sse -msse -msse2"
 
+
 def check_output(cmd):
     out = subprocess.Popen(cmd, stdout=subprocess.PIPE).communicate()[0]
     if out != None:
@@ -1557,6 +1559,8 @@ class DotNetDLLComponent(Component):
         if IS_WINDOWS:
             if VS_X64:
                 cscCmdLine.extend(['/platform:x64'])
+            elif VS_ARM:
+                cscCmdLine.extend(['/platform:arm'])
             else:
                 cscCmdLine.extend(['/platform:x86'])
         else:
@@ -1997,6 +2001,8 @@ class DotNetExampleComponent(ExampleComponent):
             out.write('\t%s /out:%s /reference:%s /debug:full /reference:System.Numerics.dll' % (CSC, exefile, dll))
             if VS_X64:
                 out.write(' /platform:x64')
+            elif VS_ARM:
+                out.write(' /platform:arm')                
             else:
                 out.write(' /platform:x86')
             for csfile in get_cs_files(self.ex_dir):
@@ -2186,18 +2192,21 @@ def mk_config():
                 'AR_FLAGS=/nologo\n'
                 'LINK_FLAGS=/nologo /MDd\n'
                 'SLINK_FLAGS=/nologo /LDd\n')
-            if not VS_X64:
-                config.write(
-                    'CXXFLAGS=/c /Zi /nologo /W3 /WX- /Od /Oy- /D WIN32 /D _DEBUG /D Z3DEBUG %s /D _CONSOLE /D _TRACE /D _WINDOWS /Gm- /EHsc /RTC1 /MDd /GS /fp:precise /Zc:wchar_t /Zc:forScope /Gd /analyze- /arch:SSE2\n' % extra_opt)
-                config.write(
-                    'LINK_EXTRA_FLAGS=/link /DEBUG /MACHINE:X86 /SUBSYSTEM:CONSOLE /INCREMENTAL:NO /STACK:8388608 /OPT:REF /OPT:ICF /TLBID:1 /DYNAMICBASE /NXCOMPAT\n'
-                    'SLINK_EXTRA_FLAGS=/link /DEBUG /MACHINE:X86 /SUBSYSTEM:WINDOWS /INCREMENTAL:NO /STACK:8388608 /OPT:REF /OPT:ICF /TLBID:1 /DYNAMICBASE:NO\n')
-            else:
+            if VS_X64:
                 config.write(
                     'CXXFLAGS=/c /Zi /nologo /W3 /WX- /Od /Oy- /D WIN32 /D _AMD64_ /D _DEBUG /D Z3DEBUG %s /D _CONSOLE /D _TRACE /D _WINDOWS /Gm- /EHsc /RTC1 /MDd /GS /fp:precise /Zc:wchar_t /Zc:forScope /Gd /analyze-\n' % extra_opt)
                 config.write(
                     'LINK_EXTRA_FLAGS=/link /DEBUG /MACHINE:X64 /SUBSYSTEM:CONSOLE /INCREMENTAL:NO /STACK:8388608 /OPT:REF /OPT:ICF /TLBID:1 /DYNAMICBASE /NXCOMPAT\n'
                     'SLINK_EXTRA_FLAGS=/link /DEBUG /MACHINE:X64 /SUBSYSTEM:WINDOWS /INCREMENTAL:NO /STACK:8388608 /OPT:REF /OPT:ICF /TLBID:1 /DYNAMICBASE:NO\n')
+            elif VS_ARM:
+                print("ARM on VS is unsupported")
+                exit(1)
+            else:
+                config.write(
+                    'CXXFLAGS=/c /Zi /nologo /W3 /WX- /Od /Oy- /D WIN32 /D _DEBUG /D Z3DEBUG %s /D _CONSOLE /D _TRACE /D _WINDOWS /Gm- /EHsc /RTC1 /MDd /GS /fp:precise /Zc:wchar_t /Zc:forScope /Gd /analyze- /arch:SSE2\n' % extra_opt)
+                config.write(
+                    'LINK_EXTRA_FLAGS=/link /DEBUG /MACHINE:X86 /SUBSYSTEM:CONSOLE /INCREMENTAL:NO /STACK:8388608 /OPT:REF /OPT:ICF /TLBID:1 /DYNAMICBASE /NXCOMPAT\n'
+                    'SLINK_EXTRA_FLAGS=/link /DEBUG /MACHINE:X86 /SUBSYSTEM:WINDOWS /INCREMENTAL:NO /STACK:8388608 /OPT:REF /OPT:ICF /TLBID:1 /DYNAMICBASE:NO\n')
         else:
             # Windows Release mode
             LTCG=' /LTCG' if SLOW_OPTIMIZE else ''
@@ -2209,18 +2218,23 @@ def mk_config():
                 % LTCG)
             if TRACE:
                 extra_opt = '%s /D _TRACE ' % extra_opt
-            if not VS_X64:
-                config.write(
-                    'CXXFLAGS=/nologo /c%s /Zi /W3 /WX- /O2 /Oy- /D _EXTERNAL_RELEASE /D WIN32 /D NDEBUG %s /D _CONSOLE /D _WINDOWS /D ASYNC_COMMANDS /Gm- /EHsc /MD /GS /fp:precise /Zc:wchar_t /Zc:forScope /Gd /analyze- /arch:SSE2\n' % (GL, extra_opt))
-                config.write(
-                    'LINK_EXTRA_FLAGS=/link%s /DEBUG /MACHINE:X86 /SUBSYSTEM:CONSOLE /INCREMENTAL:NO /STACK:8388608 /OPT:REF /OPT:ICF /TLBID:1 /DYNAMICBASE /NXCOMPAT\n'
-                    'SLINK_EXTRA_FLAGS=/link%s /DEBUG /MACHINE:X86 /SUBSYSTEM:WINDOWS /INCREMENTAL:NO /STACK:8388608 /OPT:REF /OPT:ICF /TLBID:1 /DYNAMICBASE:NO\n' % (LTCG, LTCG))
-            else:
+            if VS_X64:
                 config.write(
                     'CXXFLAGS=/c%s /Zi /nologo /W3 /WX- /O2 /D _EXTERNAL_RELEASE /D WIN32 /D NDEBUG %s /D _LIB /D _WINDOWS /D _AMD64_ /D _UNICODE /D UNICODE /Gm- /EHsc /MD /GS /fp:precise /Zc:wchar_t /Zc:forScope /Gd /TP\n' % (GL, extra_opt))
                 config.write(
                     'LINK_EXTRA_FLAGS=/link%s /MACHINE:X64 /SUBSYSTEM:CONSOLE /INCREMENTAL:NO /STACK:8388608\n'
                     'SLINK_EXTRA_FLAGS=/link%s /MACHINE:X64 /SUBSYSTEM:WINDOWS /INCREMENTAL:NO /STACK:8388608\n' % (LTCG, LTCG))
+            elif VS_ARM:
+                print("ARM on VS is unsupported")
+                exit(1)
+            else:
+                config.write(
+                    'CXXFLAGS=/nologo /c%s /Zi /W3 /WX- /O2 /Oy- /D _EXTERNAL_RELEASE /D WIN32 /D NDEBUG %s /D _CONSOLE /D _WINDOWS /D ASYNC_COMMANDS /Gm- /EHsc /MD /GS /fp:precise /Zc:wchar_t /Zc:forScope /Gd /analyze- /arch:SSE2\n' % (GL, extra_opt))
+                config.write(
+                    'LINK_EXTRA_FLAGS=/link%s /DEBUG /MACHINE:X86 /SUBSYSTEM:CONSOLE /INCREMENTAL:NO /STACK:8388608 /OPT:REF /OPT:ICF /TLBID:1 /DYNAMICBASE /NXCOMPAT\n'
+                    'SLINK_EXTRA_FLAGS=/link%s /DEBUG /MACHINE:X86 /SUBSYSTEM:WINDOWS /INCREMENTAL:NO /STACK:8388608 /OPT:REF /OPT:ICF /TLBID:1 /DYNAMICBASE:NO\n' % (LTCG, LTCG))
+
+                
 
         # End of Windows VS config.mk
         if is_verbose():
@@ -2446,6 +2460,9 @@ def mk_makefile():
             if VS_X64:
                 print("  platform: x64\n")
                 print("To build Z3, open a [Visual Studio x64 Command Prompt], then")
+            elif VS_ARM:
+                print("  platform: ARM\n")
+                print("To build Z3, open a [Visual Studio ARM Command Prompt], then")                
             else:
                 print("  platform: x86")
                 print("To build Z3, open a [Visual Studio Command Prompt], then")
diff --git a/src/api/python/z3.py b/src/api/python/z3.py
index 9f3b0a1b9..305733aa7 100644
--- a/src/api/python/z3.py
+++ b/src/api/python/z3.py
@@ -8824,13 +8824,13 @@ def _check_fp_args(a, b):
         _z3_assert(is_fp(a) or is_fp(b), "At least one of the arguments must be a Z3 floating-point expression")
 
 def fpLT(a, b, ctx=None):
-    """Create the Z3 floating-point expression `other <= self`.
+    """Create the Z3 floating-point expression `other < self`.
 
     >>> x, y = FPs('x y', FPSort(8, 24))
     >>> fpLT(x, y)
     x < y
-    >>> (x <= y).sexpr()
-    '(fp.leq x y)'
+    >>> (x < y).sexpr()
+    '(fp.lt x y)'
     """
     return _mk_fp_bin_pred(Z3_mk_fpa_lt, a, b, ctx)
 
@@ -8846,7 +8846,7 @@ def fpLEQ(a, b, ctx=None):
     return _mk_fp_bin_pred(Z3_mk_fpa_leq, a, b, ctx)
 
 def fpGT(a, b, ctx=None):
-    """Create the Z3 floating-point expression `other <= self`.
+    """Create the Z3 floating-point expression `other > self`.
 
     >>> x, y = FPs('x y', FPSort(8, 24))
     >>> fpGT(x, y)
@@ -8857,11 +8857,9 @@ def fpGT(a, b, ctx=None):
     return _mk_fp_bin_pred(Z3_mk_fpa_gt, a, b, ctx)
 
 def fpGEQ(a, b, ctx=None):
-    """Create the Z3 floating-point expression `other <= self`.
+    """Create the Z3 floating-point expression `other >= self`.
 
     >>> x, y = FPs('x y', FPSort(8, 24))
-    >>> x + y
-    x + y
     >>> fpGEQ(x, y)
     x >= y
     >>> (x >= y).sexpr()
@@ -8870,7 +8868,7 @@ def fpGEQ(a, b, ctx=None):
     return _mk_fp_bin_pred(Z3_mk_fpa_geq, a, b, ctx)
 
 def fpEQ(a, b, ctx=None):
-    """Create the Z3 floating-point expression `other <= self`.
+    """Create the Z3 floating-point expression `fpEQ(other, self)`.
 
     >>> x, y = FPs('x y', FPSort(8, 24))
     >>> fpEQ(x, y)
@@ -8881,7 +8879,7 @@ def fpEQ(a, b, ctx=None):
     return _mk_fp_bin_pred(Z3_mk_fpa_eq, a, b, ctx)
 
 def fpNEQ(a, b, ctx=None):
-    """Create the Z3 floating-point expression `other <= self`.
+    """Create the Z3 floating-point expression `Not(fpEQ(other, self))`.
 
     >>> x, y = FPs('x y', FPSort(8, 24))
     >>> fpNEQ(x, y)
diff --git a/src/ast/ast_smt_pp.cpp b/src/ast/ast_smt_pp.cpp
index 9279f50fe..82137483a 100644
--- a/src/ast/ast_smt_pp.cpp
+++ b/src/ast/ast_smt_pp.cpp
@@ -30,6 +30,7 @@ Revision History:
 #include"for_each_ast.h"
 #include"decl_collector.h"
 #include"smt2_util.h"
+#include"seq_decl_plugin.h"
 
 // ---------------------------------------
 // smt_renaming
@@ -160,6 +161,7 @@ class smt_printer {
     unsigned         m_num_lets;
     arith_util       m_autil;
     bv_util          m_bvutil;
+    seq_util         m_sutil;
     family_id        m_basic_fid;
     family_id        m_bv_fid;
     family_id        m_arith_fid;
@@ -247,6 +249,10 @@ class smt_printer {
         }
 
         if (m_is_smt2) {
+            if (is_sort_symbol && sym == symbol("String")) {
+                m_out << "String";
+                return;
+            }
             if (is_sort_symbol && sym != symbol("BitVec")) {
                 m_out << "(" << sym << " ";                
             }
@@ -397,6 +403,7 @@ class smt_printer {
         bool is_int, pos;
         buffer<symbol> names;
         unsigned bv_size;
+        zstring s;    
         unsigned num_args = n->get_num_args();
         func_decl* decl = n->get_decl();
         if (m_autil.is_numeral(n, val, is_int)) {
@@ -415,6 +422,19 @@ class smt_printer {
                 display_rational(val, is_int);
             }
         }
+        else if (m_sutil.str.is_string(n, s)) {
+            std::string encs = s.encode();
+            m_out << "\"";
+            for (unsigned i = 0; i < encs.length(); ++i) {
+                if (encs[i] == '\"') {
+                    m_out << "\"\"";
+                }
+                else {
+                    m_out << encs[i];
+                }
+            }
+            m_out << "\"";              
+        }
         else if (m_bvutil.is_numeral(n, val, bv_size)) {
             if (m_is_smt2) {
                 m_out << "(_ bv" << val << " " << bv_size << ")";
@@ -797,6 +817,7 @@ public:
         m_num_lets(0),
         m_autil(m),
         m_bvutil(m),
+        m_sutil(m),
         m_logic(logic),
         m_AUFLIRA("AUFLIRA"),
         // It's much easier to read those testcases with that.
diff --git a/src/ast/rewriter/seq_rewriter.cpp b/src/ast/rewriter/seq_rewriter.cpp
index 13ba7d67d..f04d445e1 100644
--- a/src/ast/rewriter/seq_rewriter.cpp
+++ b/src/ast/rewriter/seq_rewriter.cpp
@@ -25,6 +25,8 @@ Notes:
 #include"automaton.h"
 #include"well_sorted.h"
 #include"var_subst.h"
+#include"symbolic_automata_def.h"
+
 
 expr_ref sym_expr::accept(expr* e) {
     ast_manager& m = m_t.get_manager();
@@ -37,6 +39,7 @@ expr_ref sym_expr::accept(expr* e) {
     }
     case t_char:
         SASSERT(m.get_sort(e) == m.get_sort(m_t));
+        SASSERT(m.get_sort(e) == m_sort);
         result = m.mk_eq(e, m_t);
         break;
     case t_range: {
@@ -67,8 +70,114 @@ struct display_expr1 {
     }
 };
 
+class sym_expr_boolean_algebra : public boolean_algebra<sym_expr*> {
+    ast_manager& m;
+    expr_solver& m_solver;
+    typedef sym_expr* T;
+public:
+    sym_expr_boolean_algebra(ast_manager& m, expr_solver& s): 
+        m(m), m_solver(s) {}
+
+    virtual T mk_false() {
+        expr_ref fml(m.mk_false(), m);
+        return sym_expr::mk_pred(fml, m.mk_bool_sort()); // use of Bool sort for bound variable is arbitrary
+    }
+    virtual T mk_true() {
+        expr_ref fml(m.mk_true(), m);
+        return sym_expr::mk_pred(fml, m.mk_bool_sort());
+    }
+    virtual T mk_and(T x, T y) {
+        if (x->is_char() && y->is_char()) {
+            if (x->get_char() == y->get_char()) {
+                return x;
+            }
+            if (m.are_distinct(x->get_char(), y->get_char())) {
+                expr_ref fml(m.mk_false(), m);
+                return sym_expr::mk_pred(fml, x->get_sort());
+            }
+        }
+        var_ref v(m.mk_var(0, x->get_sort()), m);
+        expr_ref fml1 = x->accept(v);
+        expr_ref fml2 = y->accept(v);
+        if (m.is_true(fml1)) return y;
+        if (m.is_true(fml2)) return x;
+        expr_ref fml(m.mk_and(fml1, fml2), m);
+        return sym_expr::mk_pred(fml, x->get_sort());
+    }
+    virtual T mk_or(T x, T y) {
+        if (x->is_char() && y->is_char() &&
+            x->get_char() == y->get_char()) {
+            return x;
+        }
+        var_ref v(m.mk_var(0, x->get_sort()), m);
+        expr_ref fml1 = x->accept(v);
+        expr_ref fml2 = y->accept(v);        
+        if (m.is_false(fml1)) return y;
+        if (m.is_false(fml2)) return x;
+        expr_ref fml(m.mk_or(fml1, fml2), m);
+        return sym_expr::mk_pred(fml, x->get_sort());
+    }
+
+    virtual T mk_and(unsigned sz, T const* ts) {
+        switch (sz) {
+        case 0: return mk_true();
+        case 1: return ts[0];
+        default: {
+            T t = ts[0];
+            for (unsigned i = 1; i < sz; ++i) {
+                t = mk_and(t, ts[i]);
+            }
+            return t;
+        }
+        }
+    }
+    virtual T mk_or(unsigned sz, T const* ts) {
+        switch (sz) {
+        case 0: return mk_false();
+        case 1: return ts[0];
+        default: {
+            T t = ts[0];
+            for (unsigned i = 1; i < sz; ++i) {
+                t = mk_or(t, ts[i]);
+            }
+            return t;
+        }
+        }
+    }
+    virtual lbool is_sat(T x) {
+        if (x->is_char()) {
+            return l_true;
+        }
+        if (x->is_range()) {
+            // TBD check lower is below upper.
+        }
+        expr_ref v(m.mk_fresh_const("x", x->get_sort()), m);
+        expr_ref fml = x->accept(v);
+        if (m.is_true(fml)) {
+            return l_true;
+        }
+        if (m.is_false(fml)) {
+            return l_false;
+        }
+        return m_solver.check_sat(fml);
+    }
+    virtual T mk_not(T x) {
+        var_ref v(m.mk_var(0, x->get_sort()), m);
+        expr_ref fml(m.mk_not(x->accept(v)), m);
+        return sym_expr::mk_pred(fml, x->get_sort());
+    }
+};
+
+re2automaton::re2automaton(ast_manager& m): m(m), u(m), bv(m), m_ba(0), m_sa(0) {}
+
+re2automaton::~re2automaton() {}
+
+void re2automaton::set_solver(expr_solver* solver) {
+    m_solver = solver;
+    m_ba = alloc(sym_expr_boolean_algebra, m, *solver);
+    m_sa = alloc(symbolic_automata_t, sm, *m_ba.get());
+}
 
-re2automaton::re2automaton(ast_manager& m): m(m), u(m), bv(m) {}
 
 eautomaton* re2automaton::operator()(expr* e) { 
     eautomaton* r = re2aut(e); 
@@ -136,7 +245,7 @@ eautomaton* re2automaton::re2aut(expr* e) {
             expr_ref _start(bv.mk_numeral(start, nb), m);
             expr_ref _stop(bv.mk_numeral(stop, nb), m);
             expr_ref _pred(m.mk_not(m.mk_and(bv.mk_ule(_start, v), bv.mk_ule(v, _stop))), m);
-            a = alloc(eautomaton, sm, sym_expr::mk_pred(_pred));
+            a = alloc(eautomaton, sm, sym_expr::mk_pred(_pred, s));
             return a.detach();
         }
         else if (u.re.is_to_re(e0, e1) && u.str.is_string(e1, s1) && s1.length() == 1) {
@@ -145,13 +254,14 @@ eautomaton* re2automaton::re2aut(expr* e) {
             expr_ref v(m.mk_var(0, s), m);
             expr_ref _ch(bv.mk_numeral(s1[0], nb), m);          
             expr_ref _pred(m.mk_not(m.mk_eq(v, _ch)), m);
-            a = alloc(eautomaton, sm, sym_expr::mk_pred(_pred));
+            a = alloc(eautomaton, sm, sym_expr::mk_pred(_pred, s));
             return a.detach();
         }
         else if (u.re.is_to_re(e0, e1) && u.str.is_unit(e1, e2)) {
-            expr_ref v(m.mk_var(0, m.get_sort(e2)), m);
+            sort* s = m.get_sort(e2);
+            expr_ref v(m.mk_var(0, s), m);
             expr_ref _pred(m.mk_not(m.mk_eq(v, e2)), m);
-            a = alloc(eautomaton, sm, sym_expr::mk_pred(_pred));
+            a = alloc(eautomaton, sm, sym_expr::mk_pred(_pred, s));
             return a.detach();
         }
         else {
@@ -187,14 +297,15 @@ eautomaton* re2automaton::re2aut(expr* e) {
     }
     else if (u.re.is_full(e)) {
         expr_ref tt(m.mk_true(), m);
-        sym_expr* _true = sym_expr::mk_pred(tt);
+        sort* seq_s, *char_s;
+        VERIFY (u.is_re(m.get_sort(e), seq_s));
+        VERIFY (u.is_seq(seq_s, char_s));
+        sym_expr* _true = sym_expr::mk_pred(tt, char_s);
         return eautomaton::mk_loop(sm, _true);
     }
-#if 0
-    else if (u.re.is_intersect(e, e1, e2)) {
-        // maybe later
+    else if (u.re.is_intersection(e, e1, e2) && m_sa && (a = re2aut(e1)) && (b = re2aut(e2))) {
+        return m_sa->mk_product(*a, *b);
     }
-#endif
     
     return 0;
 }
@@ -437,7 +548,12 @@ br_status seq_rewriter::mk_seq_contains(expr* a, expr* b, expr_ref& result) {
     m_util.str.get_concat(a, as);
     m_util.str.get_concat(b, bs);
     bool all_values = true;
-    
+   
+    if (bs.empty()) {
+        result = m().mk_true();
+        return BR_DONE;
+    }
+
     for (unsigned i = 0; all_values && i < bs.size(); ++i) { 
         all_values = m().is_value(bs[i].get());
     }
@@ -459,6 +575,39 @@ br_status seq_rewriter::mk_seq_contains(expr* a, expr* b, expr_ref& result) {
         result = m().mk_false();
         return BR_DONE;
     }
+
+    unsigned lenA = 0, lenB = 0;
+    bool lA = min_length(as.size(), as.c_ptr(), lenA);
+    if (lA) {
+        bool lB = min_length(bs.size(), bs.c_ptr(), lenB);
+        if (lenB > lenA) {
+            result = m().mk_false();
+            return BR_DONE;
+        }
+    }
+
+
+    if (as.empty()) {
+        result = m().mk_eq(b, m_util.str.mk_empty(m().get_sort(b)));
+        return BR_REWRITE2;
+    }
+
+    unsigned offs = 0;
+    unsigned sz = as.size();
+    expr* b0 = bs[0].get();
+    expr* bL = bs[bs.size()-1].get();
+    for (; offs < as.size() && m().are_distinct(b0, as[offs].get()); ++offs) {};
+    for (; sz > offs && m().are_distinct(bL, as[sz-1].get()); --sz) {}
+    if (offs == sz) {
+        result = m().mk_eq(b, m_util.str.mk_empty(m().get_sort(b)));
+        return BR_REWRITE2;
+    }
+    if (offs > 0 || sz < as.size()) {
+        SASSERT(sz > offs);
+        result = m_util.str.mk_contains(m_util.str.mk_concat(sz-offs, as.c_ptr()+offs), b);
+        return BR_REWRITE2;
+    }
+
     return BR_FAILED;
 }
 
diff --git a/src/ast/rewriter/seq_rewriter.h b/src/ast/rewriter/seq_rewriter.h
index 83dd8f653..040bae1b4 100644
--- a/src/ast/rewriter/seq_rewriter.h
+++ b/src/ast/rewriter/seq_rewriter.h
@@ -25,6 +25,7 @@ Notes:
 #include"params.h"
 #include"lbool.h"
 #include"automaton.h"
+#include"symbolic_automata.h"
 
 class sym_expr {
     enum ty {
@@ -33,21 +34,24 @@ class sym_expr {
         t_range
     };
     ty       m_ty;
+    sort*    m_sort;
     expr_ref m_t;
     expr_ref m_s;
     unsigned m_ref;
-    sym_expr(ty ty, expr_ref& t, expr_ref& s) : m_ty(ty), m_t(t), m_s(s), m_ref(0) {}
+    sym_expr(ty ty, expr_ref& t, expr_ref& s, sort* srt) : m_ty(ty), m_sort(srt), m_t(t), m_s(s), m_ref(0) {}
 public:
     expr_ref accept(expr* e);
-    static sym_expr* mk_char(expr_ref& t) { return alloc(sym_expr, t_char, t, t); }
+    static sym_expr* mk_char(expr_ref& t) { return alloc(sym_expr, t_char, t, t, t.get_manager().get_sort(t)); }
     static sym_expr* mk_char(ast_manager& m, expr* t) { expr_ref tr(t, m); return mk_char(tr); }
-    static sym_expr* mk_pred(expr_ref& t) { return alloc(sym_expr, t_pred, t, t); }
-    static sym_expr* mk_range(expr_ref& lo, expr_ref& hi) { return alloc(sym_expr, t_range, lo, hi); }
+    static sym_expr* mk_pred(expr_ref& t, sort* s) { return alloc(sym_expr, t_pred, t, t, s); }
+    static sym_expr* mk_range(expr_ref& lo, expr_ref& hi) { return alloc(sym_expr, t_range, lo, hi, lo.get_manager().get_sort(hi)); }
     void inc_ref() { ++m_ref;  }
     void dec_ref() { --m_ref; if (m_ref == 0) dealloc(this); }
     std::ostream& display(std::ostream& out) const;
     bool is_char() const { return m_ty == t_char; }
     bool is_pred() const { return !is_char(); }
+    bool is_range() const { return m_ty == t_range; }
+    sort* get_sort() const { return m_sort; }
     expr* get_char() const { SASSERT(is_char()); return m_t; }
 
 };
@@ -58,17 +62,31 @@ public:
     void dec_ref(sym_expr* s) { if (s) s->dec_ref(); }
 };
 
+class expr_solver {
+public:
+    virtual ~expr_solver() {}
+    virtual lbool check_sat(expr* e) = 0;
+};
+
 typedef automaton<sym_expr, sym_expr_manager> eautomaton;
 class re2automaton {
+    typedef boolean_algebra<sym_expr*> boolean_algebra_t;
+    typedef symbolic_automata<sym_expr, sym_expr_manager> symbolic_automata_t;
     ast_manager& m;
     sym_expr_manager sm;
     seq_util     u;     
     bv_util      bv;
+    scoped_ptr<expr_solver>         m_solver;
+    scoped_ptr<boolean_algebra_t>   m_ba;
+    scoped_ptr<symbolic_automata_t> m_sa;
+
     eautomaton* re2aut(expr* e);
     eautomaton* seq2aut(expr* e);
- public:
+public:
     re2automaton(ast_manager& m);
+    ~re2automaton();
     eautomaton* operator()(expr* e);
+    void set_solver(expr_solver* solver);
 };
 
 /**
diff --git a/src/ast/seq_decl_plugin.h b/src/ast/seq_decl_plugin.h
index 4100fe6cc..6200d910f 100644
--- a/src/ast/seq_decl_plugin.h
+++ b/src/ast/seq_decl_plugin.h
@@ -222,16 +222,16 @@ public:
         str(seq_util& u): u(u), m(u.m), m_fid(u.m_fid) {}
 
         sort* mk_seq(sort* s) { parameter param(s); return m.mk_sort(m_fid, SEQ_SORT, 1, &param); }
-        sort* mk_string_sort() { return m.mk_sort(m_fid, _STRING_SORT, 0, 0); }
-        app* mk_empty(sort* s) { return m.mk_const(m.mk_func_decl(m_fid, OP_SEQ_EMPTY, 0, 0, 0, (expr*const*)0, s)); }
+        sort* mk_string_sort() const { return m.mk_sort(m_fid, _STRING_SORT, 0, 0); }
+        app* mk_empty(sort* s) const { return m.mk_const(m.mk_func_decl(m_fid, OP_SEQ_EMPTY, 0, 0, 0, (expr*const*)0, s)); }
         app* mk_string(zstring const& s);
         app* mk_string(symbol const& s) { return u.seq.mk_string(s); }
         app* mk_char(char ch);
-        app* mk_concat(expr* a, expr* b) { expr* es[2] = { a, b }; return m.mk_app(m_fid, OP_SEQ_CONCAT, 2, es); }
+        app* mk_concat(expr* a, expr* b) const { expr* es[2] = { a, b }; return m.mk_app(m_fid, OP_SEQ_CONCAT, 2, es); }
         app* mk_concat(expr* a, expr* b, expr* c) { return mk_concat(a, mk_concat(b, c)); }
-        expr* mk_concat(unsigned n, expr* const* es) { if (n == 1) return es[0]; SASSERT(n > 1); return m.mk_app(m_fid, OP_SEQ_CONCAT, n, es); }
-        expr* mk_concat(expr_ref_vector const& es) { return mk_concat(es.size(), es.c_ptr()); }
-        app* mk_length(expr* a) { return m.mk_app(m_fid, OP_SEQ_LENGTH, 1, &a); }
+        expr* mk_concat(unsigned n, expr* const* es) const { if (n == 1) return es[0]; SASSERT(n > 1); return m.mk_app(m_fid, OP_SEQ_CONCAT, n, es); }
+        expr* mk_concat(expr_ref_vector const& es) const { return mk_concat(es.size(), es.c_ptr()); }
+        app* mk_length(expr* a) const { return m.mk_app(m_fid, OP_SEQ_LENGTH, 1, &a); }
         app* mk_substr(expr* a, expr* b, expr* c) { expr* es[3] = { a, b, c }; return m.mk_app(m_fid, OP_SEQ_EXTRACT, 3, es); }
         app* mk_contains(expr* a, expr* b) { expr* es[2] = { a, b }; return m.mk_app(m_fid, OP_SEQ_CONTAINS, 2, es); }
         app* mk_prefix(expr* a, expr* b) { expr* es[2] = { a, b }; return m.mk_app(m_fid, OP_SEQ_PREFIX, 2, es); }
diff --git a/src/math/automata/automaton.h b/src/math/automata/automaton.h
index 54c969bbb..dd1ff87f5 100644
--- a/src/math/automata/automaton.h
+++ b/src/math/automata/automaton.h
@@ -178,15 +178,19 @@ public:
         return alloc(automaton, a.m, a.init(), final, mvs);
     }
 
+    automaton* clone() const {
+        return clone(*this);
+    }
+
     // create the sum of disjoint automata
     static automaton* mk_union(automaton const& a, automaton const& b) {
         SASSERT(&a.m == &b.m);
         M& m = a.m;
         if (a.is_empty()) {
-            return clone(b);
+            return b.clone();
         }
         if (b.is_empty()) {
-            return clone(a);
+            return a.clone();
         }
         moves mvs;
         unsigned_vector final;
@@ -213,7 +217,7 @@ public:
             mvs.push_back(move(m, 0, a.init() + offset));
         }
         if (a.is_empty()) {
-            return clone(a);
+            return a.clone();
         }
 
         mvs.push_back(move(m, init, a.final_state() + offset));
@@ -227,16 +231,16 @@ public:
         SASSERT(&a.m == &b.m);
         M& m = a.m;
         if (a.is_empty()) {
-            return clone(a);
+            return a.clone();
         }
         if (b.is_empty()) {
-            return clone(b);
+            return b.clone();
         }
         if (a.is_epsilon()) {
-            return clone(b);
+            return b.clone();
         }
         if (b.is_epsilon()) {
-            return clone(a);
+            return a.clone();
         }
 
         moves mvs;
@@ -458,6 +462,7 @@ public:
     }
 
     unsigned init() const { return m_init; }
+    unsigned_vector const& final_states() const { return m_final_states; }
     unsigned in_degree(unsigned state) const { return m_delta_inv[state].size(); }
     unsigned out_degree(unsigned state) const { return m_delta[state].size(); }
     move const& get_move_from(unsigned state) const { SASSERT(m_delta[state].size() == 1); return m_delta[state][0]; }
diff --git a/src/math/automata/boolean_algebra.h b/src/math/automata/boolean_algebra.h
new file mode 100644
index 000000000..503878ef3
--- /dev/null
+++ b/src/math/automata/boolean_algebra.h
@@ -0,0 +1,46 @@
+/*++
+Copyright (c) 2015 Microsoft Corporation
+
+Module Name:
+
+    boolean_algebra.h
+
+Abstract:
+
+    Boolean Algebra, a la Margus Veanes Automata library.
+
+Author:
+
+    Nikolaj Bjorner (nbjorner) 2016-2-27
+
+Revision History:
+
+
+--*/
+
+#ifndef BOOLEAN_ALGEBRA_H_
+#define BOOLEAN_ALGEBRA_H_
+
+#include "util.h"
+
+template<class T>
+class positive_boolean_algebra {
+public:
+    virtual T mk_false() = 0;
+    virtual T mk_true() = 0;
+    virtual T mk_and(T x, T y) = 0;
+    virtual T mk_or(T x, T y) = 0;
+    virtual T mk_and(unsigned sz, T const* ts) = 0;
+    virtual T mk_or(unsigned sz, T const* ts) = 0;
+    virtual lbool is_sat(T x) = 0;
+};
+
+template<class T>
+class boolean_algebra : public positive_boolean_algebra<T> {
+public:
+    virtual T mk_not(T x) = 0;
+    //virtual lbool are_equivalent(T x, T y) = 0;
+    //virtual T simplify(T x) = 0;    
+};
+
+#endif
diff --git a/src/math/automata/symbolic_automata.h b/src/math/automata/symbolic_automata.h
new file mode 100644
index 000000000..cd553eeef
--- /dev/null
+++ b/src/math/automata/symbolic_automata.h
@@ -0,0 +1,108 @@
+/*++
+Copyright (c) 2015 Microsoft Corporation
+
+Module Name:
+
+    symbolic_automata.h
+
+Abstract:
+
+    Symbolic Automata over Boolean Algebras, a la Margus Veanes Automata library.
+
+Author:
+
+    Nikolaj Bjorner (nbjorner) 2016-02-27.
+
+Revision History:
+
+
+--*/
+
+#ifndef SYMBOLIC_AUTOMATA_H_
+#define SYMBOLIC_AUTOMATA_H_
+
+
+#include "automaton.h"
+#include "boolean_algebra.h"
+
+
+template<class T, class M = default_value_manager<T> >
+class symbolic_automata {
+    typedef automaton<T, M>    automaton_t;
+    typedef boolean_algebra<T*> ba_t;
+    typedef typename automaton_t::move  move_t;
+    typedef vector<move_t>     moves_t;
+    typedef obj_ref<T, M>      ref_t;
+    typedef ref_vector<T, M>   refs_t;
+
+    M&    m;
+    ba_t& m_ba;
+
+
+    class block {
+        uint_set m_set;
+        unsigned m_rep;
+        bool     m_rep_chosen;
+    public:
+
+        block(): m_rep(0), m_rep_chosen(false) {}
+
+        block(uint_set const& s):
+            m_set(s),
+            m_rep(0),
+            m_rep_chosen(false) {
+        }
+
+        block(unsigned_vector const& vs) {
+            for (unsigned i = 0; i < vs.size(); ++i) {
+                m_set.insert(vs[i]);               
+            }
+            m_rep_chosen = false;
+            m_rep = 0;
+        }
+
+        block& operator=(block const& b) {
+            m_set = b.m_set;
+            m_rep = 0;
+            m_rep_chosen = false;
+            return *this;
+        }
+
+        unsigned get_representative() {
+            if (!m_rep_chosen) {
+                uint_set::iterator it = m_set.begin();
+                if (m_set.end() != it) {
+                    m_rep = *it;                    
+                }
+                m_rep_chosen = true;
+            }
+            return m_rep;
+        }
+
+        void insert(unsigned i) { m_set.insert(i); }
+        bool contains(unsigned i) const { return m_set.contains(i); }        
+        bool is_empty() const { return m_set.empty(); }
+        unsigned size() const { return m_set.num_elems(); }
+        void remove(unsigned i) { m_set.remove(i); m_rep_chosen = false; }        
+        void clear() { m_set.reset(); m_rep_chosen = false; }
+        uint_set::iterator begin() const { return m_set.begin(); }
+        uint_set::iterator end() const { return m_set.end(); }
+    };
+
+    void add_block(block const& p1, unsigned p0_index, unsigned_vector& blocks, vector<block>& pblocks, unsigned_vector& W);
+
+public:
+    symbolic_automata(M& m, ba_t& ba): m(m), m_ba(ba) {}
+    automaton_t* mk_determinstic(automaton_t& a);
+    automaton_t* mk_complement(automaton_t& a);
+    automaton_t* remove_epsilons(automaton_t& a);
+    automaton_t* mk_total(automaton_t& a);
+    automaton_t* mk_minimize(automaton_t& a);
+    automaton_t* mk_minimize_total(automaton_t& a);
+    automaton_t* mk_difference(automaton_t& a, automaton_t& b);
+    automaton_t* mk_product(automaton_t& a, automaton_t& b);
+};
+
+
+
+#endif 
diff --git a/src/math/automata/symbolic_automata_def.h b/src/math/automata/symbolic_automata_def.h
new file mode 100644
index 000000000..50c115d39
--- /dev/null
+++ b/src/math/automata/symbolic_automata_def.h
@@ -0,0 +1,371 @@
+/*++
+Copyright (c) 2015 Microsoft Corporation
+
+Module Name:
+
+    symbolic_automata_def.h
+
+Abstract:
+
+    Symbolic Automata over Boolean Algebras, a la Margus Veanes Automata library.
+
+Author:
+
+    Nikolaj Bjorner (nbjorner) 2016-02-27.
+
+Revision History:
+
+
+--*/
+
+#ifndef SYMBOLIC_AUTOMATA_DEF_H_
+#define SYMBOLIC_AUTOMATA_DEF_H_
+
+
+#include "symbolic_automata.h"
+#include "hashtable.h"
+
+typedef std::pair<unsigned, unsigned> unsigned_pair;
+
+
+
+template<class T, class M>
+typename symbolic_automata<T, M>::automaton_t* symbolic_automata<T, M>::mk_total(automaton_t& a) {
+    unsigned dead_state = a.num_states();
+    moves_t mvs, new_mvs;
+    for (unsigned i = 0; i < dead_state; ++i) {
+        mvs.reset();
+        a.get_moves_from(i, mvs, true);
+        refs_t vs(m);
+        
+        for (unsigned j = 0; j < mvs.size(); ++j) {
+            vs.push_back(mvs[j].t());
+        }
+        ref_t cond(m_ba.mk_not(m_ba.mk_or(vs.size(), vs.c_ptr())), m);
+        lbool is_sat = m_ba.is_sat(cond);
+        if (is_sat == l_undef) {
+            return 0;
+        }
+        if (is_sat == l_true) {
+            new_mvs.push_back(move_t(m, i, dead_state, cond));
+        }
+    }
+    if (new_mvs.empty()) {
+        return a.clone();
+    }
+    new_mvs.push_back(move_t(m, dead_state, dead_state, m_ba.mk_true()));
+
+    // TBD private: automaton_t::append_moves(0, a, new_mvs);
+    
+    return alloc(automaton_t, m, a.init(), a.final_states(), new_mvs);        
+}
+
+template<class T, class M>
+typename symbolic_automata<T, M>::automaton_t* symbolic_automata<T, M>::mk_minimize(automaton_t& a) {
+    if (a.is_empty()) {
+        return a.clone();
+    }
+
+    if (a.is_epsilon()) {
+        return a.clone();
+    }
+    // SASSERT(a.is_deterministic());
+    
+    scoped_ptr<automaton_t> fa = mk_total(a);
+    if (!fa) {
+        return 0;
+    }
+    return mk_minimize_total(*fa.get());
+}
+
+
+template<class T, class M>
+void symbolic_automata<T, M>::add_block(block const& p1, unsigned p0_index, unsigned_vector& blocks, vector<block>& pblocks, unsigned_vector& W) {
+    block& p0 = pblocks[p0_index];
+    if (p1.size() < p0.size()) {
+        unsigned p1_index = pblocks.size();
+        pblocks.push_back(p1);
+        for (uint_set::iterator it = p1.begin(), end = p1.end(); it != end; ++it) {
+            p0.remove(*it);
+            blocks[*it] = p1_index;
+        }
+        if (W.contains(p0_index)) {
+            W.push_back(p1_index);
+        }
+        else if (p0.size() <= p1.size()) {
+            W.push_back(p0_index);
+        }
+        else {
+            W.push_back(p1_index);
+        }
+    }                
+}
+
+template<class T, class M>
+typename symbolic_automata<T, M>::automaton_t* symbolic_automata<T, M>::mk_minimize_total(automaton_t& a) {    
+    vector<block> pblocks;
+    unsigned_vector blocks;
+    unsigned_vector non_final;
+    for (unsigned i = 0; i < a.num_states(); ++i) {
+        if (!a.is_final_state(i)) {
+            non_final.push_back(i);
+            blocks.push_back(1);
+        }
+        else {
+            blocks.push_back(0);
+        }
+    }
+    pblocks.push_back(block(a.final_states()));      // 0 |-> final states
+    pblocks.push_back(block(non_final));             // 1 |-> non-final states
+
+    unsigned_vector W;
+    W.push_back(pblocks[0].size() > pblocks[1].size() ? 1 : 0);
+        
+    refs_t trail(m);
+    u_map<T*> gamma;
+    moves_t mvs;
+    while (!W.empty()) {
+        block R(pblocks[W.back()]);
+        W.pop_back();
+        gamma.reset();
+        uint_set::iterator it = R.begin(), end = R.end();
+        for (; it != end; ++it) {
+            unsigned dst = *it;
+            mvs.reset();
+            a.get_moves_to(dst, mvs);
+            for (unsigned i = 0; i < mvs.size(); ++i) {
+                unsigned src = mvs[i].src();
+                if (pblocks[src].size() > 1) {
+                    T* t = mvs[i].t();
+                    T* t1;
+                    if (gamma.find(src, t1)) {
+                        t = m_ba.mk_or(t, t1);
+                        trail.push_back(t);
+                    }
+                    gamma.insert(src, t);
+                }
+            }
+        }
+        uint_set relevant1;
+        typedef typename u_map<T*>::iterator gamma_iterator;
+        gamma_iterator gend = gamma.end();
+        for (gamma_iterator git = gamma.begin(); git != gend; ++git) {
+            unsigned p0A_index = blocks[git->m_key];
+            if (relevant1.contains(p0A_index)) {
+                continue;
+            }
+            relevant1.insert(p0A_index);
+            block& p0A = pblocks[p0A_index];
+            block p1;
+            for (gamma_iterator it = gamma.begin(); it != gend; ++it) {
+                if (p0A.contains(it->m_key)) p1.insert(it->m_key);
+            }
+            
+            add_block(p1, p0A_index, blocks, pblocks, W);
+
+            bool iterate = true;
+            while (iterate) {
+                iterate = false;
+                uint_set relevant2;
+                for (gamma_iterator it = gamma.begin(); it != gend; ++it) {
+                    unsigned p0B_index = blocks[it->m_key];
+                    if (pblocks[p0B_index].size() <= 1 || relevant2.contains(p0B_index)) {
+                        continue;
+                    }
+                    relevant2.insert(p0B_index);
+                    block const& p0B = pblocks[p0B_index];
+                    uint_set::iterator bi = p0B.begin(), be = p0B.end();
+
+                    block p1;
+                    p1.insert(*bi);
+                    bool split_found = false;
+                    ref_t psi(gamma[*bi], m); 
+                    ++bi;
+                    for (; bi != be; ++bi) {
+                        unsigned q = *bi;
+                        ref_t phi(gamma[q], m);
+                        if (split_found) {
+                            ref_t phi_and_psi(m_ba.mk_and(phi, psi), m);
+                            switch (m_ba.is_sat(phi_and_psi)) {
+                            case l_true:
+                                p1.insert(q);
+                                break;
+                            case l_undef:
+                                return 0;
+                            default:
+                                break;
+                            }                            
+                        }
+                        else {
+                            ref_t psi_min_phi(m_ba.mk_and(psi, m_ba.mk_not(phi)), m);
+                            lbool is_sat = m_ba.is_sat(psi_min_phi);
+                            if (is_sat == l_undef) {
+                                return 0;
+                            }
+                            if (is_sat == l_true) {
+                                psi = psi_min_phi;
+                                split_found = true;
+                                continue;
+                            }
+                            // psi is a subset of phi
+                            ref_t phi_min_psi(m_ba.mk_and(phi, m_ba.mk_not(psi)), m);
+                            is_sat = m_ba.is_sat(phi_min_psi);
+                            if (is_sat == l_undef) {
+                                return 0;
+                            }
+                            else if (is_sat == l_false) {
+                                p1.insert(q); // psi and phi are equivalent
+                            }
+                            else {
+                                p1.clear();
+                                p1.insert(q);
+                                psi = phi_min_psi;
+                                split_found = true;
+                            }
+                        }
+                    }
+                    if (p1.size() < p0B.size() && p0B.size() > 2) iterate = true;
+                    add_block(p1, p0B_index, blocks, pblocks, W);
+                }
+            }
+        }
+    }
+
+    unsigned new_init = pblocks[blocks[a.init()]].get_representative();
+
+    // set moves
+    map<unsigned_pair, T*, pair_hash<unsigned_hash, unsigned_hash>, default_eq<unsigned_pair> > conds;
+    svector<unsigned_pair> keys;
+    moves_t new_moves;
+
+    for (unsigned i = 0; i < a.num_states(); ++i) {
+        unsigned src = pblocks[blocks[i]].get_representative();
+        typename automaton_t::moves const& mvs = a.get_moves_from(i);
+        for (unsigned j = 0; j < mvs.size(); ++j) {
+            unsigned dst = pblocks[blocks[mvs[j].dst()]].get_representative();
+            unsigned_pair st(src, dst);
+            T* t = 0;
+            if (conds.find(st, t)) {
+                t = m_ba.mk_or(t, mvs[j].t());
+                trail.push_back(t);
+                conds.insert(st, t);
+            }
+            else {
+                conds.insert(st, mvs[j].t());
+                keys.push_back(st);
+            }
+        }
+    }    
+    for (unsigned i = 0; i < keys.size(); ++i) {
+        unsigned_pair st = keys[i];
+        new_moves.push_back(move_t(m, st.first, st.second, conds[st]));
+    }
+    // set final states.
+    unsigned_vector new_final;
+    uint_set new_final_set;
+    for (unsigned i = 0; i < a.final_states().size(); ++i) {
+        unsigned f = pblocks[blocks[a.final_states()[i]]].get_representative();
+        if (!new_final_set.contains(f)) {
+            new_final_set.insert(f);
+            new_final.push_back(f);
+        }
+    }
+
+    return alloc(automaton_t, m, new_init, new_final, new_moves);
+}
+
+template<class T, class M>
+typename symbolic_automata<T, M>::automaton_t* symbolic_automata<T, M>::mk_product(automaton_t& a, automaton_t& b) {
+    map<unsigned_pair, unsigned, pair_hash<unsigned_hash, unsigned_hash>, default_eq<unsigned_pair> > state_ids;
+    unsigned_pair init_pair(a.init(), b.init());
+    svector<unsigned_pair> todo;
+    todo.push_back(init_pair);
+    state_ids.insert(init_pair, 0);
+    moves_t mvs;
+    unsigned_vector final;
+    if (a.is_final_state(a.init()) && b.is_final_state(b.init())) {
+        final.push_back(0);
+    }
+    if (false) {
+        mk_minimize(a);
+    }
+    unsigned n = 1;
+    moves_t mvsA, mvsB;
+    while (!todo.empty()) {
+        unsigned_pair curr_pair = todo.back();
+        todo.pop_back();
+        unsigned src = state_ids[curr_pair];
+        mvsA.reset(); mvsB.reset();
+        a.get_moves_from(curr_pair.first,  mvsA, true);
+        b.get_moves_from(curr_pair.second, mvsB, true);
+        for (unsigned i = 0; i < mvsA.size(); ++i) {
+            for (unsigned j = 0; j < mvsB.size(); ++j) {
+                ref_t ab(m_ba.mk_and(mvsA[i].t(), mvsB[j].t()), m);   
+                lbool is_sat = m_ba.is_sat(ab);
+                if (is_sat == l_false) {
+                    continue;
+                }
+                else if (is_sat == l_undef) {
+                    return 0;
+                }
+                unsigned_pair tgt_pair(mvsA[i].dst(), mvsB[j].dst());
+                unsigned tgt;
+                if (!state_ids.find(tgt_pair, tgt)) {
+                    tgt = n++;
+                    state_ids.insert(tgt_pair, tgt);
+                    todo.push_back(tgt_pair);
+                    if (a.is_final_state(tgt_pair.first) && b.is_final_state(tgt_pair.second)) {
+                        final.push_back(tgt);
+                    }
+                }
+                mvs.push_back(move_t(m, src, tgt, ab));
+            }
+        }
+    }
+    
+    if (final.empty()) {
+        return alloc(automaton_t, m);
+    }
+    vector<moves_t> inv(n, moves_t());
+    for (unsigned i = 0; i < mvs.size(); ++i) {
+        move_t const& mv = mvs[i];
+        inv[mv.dst()].push_back(move_t(m, mv.dst(), mv.src(), mv.t())); 
+    }
+    
+    svector<bool> back_reachable(n, false);
+    for (unsigned i = 0; i < final.size(); ++i) {
+        back_reachable[final[i]] = true;
+    }
+    
+    unsigned_vector stack(final);
+    while (!stack.empty()) {
+        unsigned state = stack.back();
+        stack.pop_back();
+        moves_t const& mv = inv[state];
+        for (unsigned i = 0; i < mv.size(); ++i) {
+            state = mv[i].dst();
+            if (!back_reachable[state]) {
+                back_reachable[state] = true;
+                stack.push_back(state);
+            }
+        }
+    }
+    
+    moves_t mvs1;
+    for (unsigned i = 0; i < mvs.size(); ++i) {
+        move_t const& mv = mvs[i];
+        if (back_reachable[mv.dst()]) {
+            mvs1.push_back(mv);
+        }
+    }
+    if (mvs1.empty()) {
+        return alloc(automaton_t, m);
+    }
+    else {
+        return alloc(automaton_t, m, 0, final, mvs1);
+    }
+} 
+
+
+
+#endif 
diff --git a/src/muz/rel/dl_base.h b/src/muz/rel/dl_base.h
index 781c8539d..1c7a81444 100644
--- a/src/muz/rel/dl_base.h
+++ b/src/muz/rel/dl_base.h
@@ -435,11 +435,7 @@ namespace datalog {
             void destroy() {
                 SASSERT(this);
                 this->~base_ancestor();
-#if _DEBUG
-                memory::deallocate(__FILE__, __LINE__, this);
-#else
                 memory::deallocate(this);
-#endif
             }
         public:
             /**
diff --git a/src/sat/sat_solver/inc_sat_solver.cpp b/src/sat/sat_solver/inc_sat_solver.cpp
index 33889e4ef..bc57a4099 100644
--- a/src/sat/sat_solver/inc_sat_solver.cpp
+++ b/src/sat/sat_solver/inc_sat_solver.cpp
@@ -425,7 +425,7 @@ private:
         DEBUG_CODE(
             for (unsigned i = 0; i < m_fmls.size(); ++i) {
                 expr_ref tmp(m);
-                VERIFY(m_model->eval(m_fmls[i].get(), tmp));                
+                VERIFY(m_model->eval(m_fmls[i].get(), tmp, true));                
                 CTRACE("sat", !m.is_true(tmp),
                        tout << "Evaluation failed: " << mk_pp(m_fmls[i].get(), m) 
                        << " to " << tmp << "\n";
diff --git a/src/smt/smt_conflict_resolution.cpp b/src/smt/smt_conflict_resolution.cpp
index 3aa02c0b6..86593b0f2 100644
--- a/src/smt/smt_conflict_resolution.cpp
+++ b/src/smt/smt_conflict_resolution.cpp
@@ -99,22 +99,29 @@ namespace smt {
        This method may update m_antecedents, m_todo_js and m_todo_eqs.
     */
     void conflict_resolution::eq_justification2literals(enode * lhs, enode * rhs, eq_justification js) {
+        ast_manager& m = get_manager();
         SASSERT(m_antecedents);
+        TRACE("conflict_detail", tout << mk_pp(lhs->get_owner(), m) << " = " << mk_pp(rhs->get_owner(), m);
+              switch (js.get_kind()) {
+              case eq_justification::AXIOM: tout << " axiom\n";  break;
+              case eq_justification::EQUATION:
+                  tout << " was asserted\nliteral: "; m_ctx.display_literal(tout, js.get_literal()); tout << "\n";
+                  break;
+              case eq_justification::JUSTIFICATION: tout << " justification\n";  break;
+              case eq_justification::CONGRUENCE: tout << " congruence\n"; break;
+              default:  break;
+              });
+
         switch(js.get_kind()) {
         case eq_justification::AXIOM:
-            TRACE("conflict_detail", tout << "#" << lhs->get_owner_id() << " = " << rhs->get_owner_id() << " axiom\n";); 
             break;
         case eq_justification::EQUATION:
-            TRACE("conflict_detail", tout << "#" << lhs->get_owner_id() << " = " << rhs->get_owner_id() << " was asserted\n"
-                  << "literal: "; m_ctx.display_literal(tout, js.get_literal()); tout << "\n";); 
             m_antecedents->push_back(js.get_literal());
             break;
         case eq_justification::JUSTIFICATION:
-            TRACE("conflict_detail", tout << "#" << lhs->get_owner_id() << " = " << rhs->get_owner_id() << " justification\n";);
             mark_justification(js.get_justification());
             break;
         case eq_justification::CONGRUENCE: {
-            TRACE("conflict_detail", tout << "#" << lhs->get_owner_id() << " = " << rhs->get_owner_id() << " congruence\n";);
             CTRACE("dyn_ack_target", !lhs->is_eq(), tout << "dyn_ack_target2: " << lhs->get_owner_id() << " " << rhs->get_owner_id() << "\n";);
             m_dyn_ack_manager.used_cg_eh(lhs->get_owner(), rhs->get_owner());
             unsigned num_args = lhs->get_num_args();
@@ -206,7 +213,6 @@ namespace smt {
         justification_vector::iterator it  = m_todo_js.begin() + old_js_qhead;
         justification_vector::iterator end = m_todo_js.end();
         for (; it != end; ++it) {
-            TRACE("conflict_detail", tout << "unmarking: " << *it << "\n";);
             (*it)->unset_mark();
         }
         m_todo_js.shrink(old_js_qhead);
@@ -371,11 +377,9 @@ namespace smt {
               tout << "conflict_lvl: " << m_conflict_lvl << " scope_lvl: " << m_ctx.get_scope_level() << " base_lvl: " << m_ctx.get_base_level() 
               << " search_lvl: " << m_ctx.get_search_level() << "\n";
               tout << "js.kind: " << js.get_kind() << "\n";
-              tout << "consequent: " << consequent << "\n";
-	      for (unsigned i = 0; i < m_assigned_literals.size(); ++i) {
-                  tout << m_assigned_literals[i] << " ";
-	      }
-	      tout << "\n";
+              tout << "consequent: " << consequent << ": ";
+              m_ctx.display_literal_verbose(tout, consequent); tout << "\n";
+              m_ctx.display(tout, js); tout << "\n";
 	      );
 
         // m_conflict_lvl can be smaller than m_ctx.get_search_level() when:
@@ -416,12 +420,12 @@ namespace smt {
         
         TRACE("conflict",
               tout << "before minimization:\n";
-              m_ctx.display_literals(tout, m_lemma.size(), m_lemma.c_ptr());
+              m_ctx.display_literals(tout, m_lemma);
               tout << "\n";);
         
         TRACE("conflict_verbose",
               tout << "before minimization:\n";
-              m_ctx.display_literals_verbose(tout, m_lemma.size(), m_lemma.c_ptr());
+              m_ctx.display_literals_verbose(tout, m_lemma);
               tout << "\n";);
         
         if (m_params.m_minimize_lemmas)
@@ -429,12 +433,16 @@ namespace smt {
         
         TRACE("conflict",
               tout << "after minimization:\n";
-              m_ctx.display_literals(tout, m_lemma.size(), m_lemma.c_ptr());
+              m_ctx.display_literals(tout, m_lemma);
               tout << "\n";);
         
         TRACE("conflict_verbose",
               tout << "after minimization:\n";
-              m_ctx.display_literals_verbose(tout, m_lemma.size(), m_lemma.c_ptr());
+              m_ctx.display_literals_verbose(tout, m_lemma);
+              tout << "\n";);
+
+        TRACE("conflict_bug",
+              m_ctx.display_literals_verbose(tout, m_lemma);
               tout << "\n";);
         
         literal_vector::iterator it  = m_lemma.begin();
@@ -1423,7 +1431,7 @@ namespace smt {
         }
 
     end_unsat_core:
-        TRACE("unsat_core", tout << "assumptions:\n"; m_ctx.display_literals(tout, m_assumptions.size(), m_assumptions.c_ptr()); tout << "\n";);
+        TRACE("unsat_core", tout << "assumptions:\n"; m_ctx.display_literals(tout, m_assumptions); tout << "\n";);
         reset_unmark_and_justifications(0, 0);
     }
     
diff --git a/src/smt/smt_conflict_resolution.h b/src/smt/smt_conflict_resolution.h
index 6d8abbf23..daccadbb7 100644
--- a/src/smt/smt_conflict_resolution.h
+++ b/src/smt/smt_conflict_resolution.h
@@ -114,7 +114,6 @@ namespace smt {
 
         void mark_justification(justification * js) {
             if (!js->is_marked()) {
-                TRACE("conflict_detail", tout << "marking: " << js << "\n";);
                 js->set_mark();
                 m_todo_js.push_back(js);
             }
@@ -126,7 +125,7 @@ namespace smt {
                     std::swap(n1, n2);
                 enode_pair p(n1, n2);
                 if (m_already_processed_eqs.insert_if_not_there(p)) {
-                    TRACE("conflict_detail", tout << "marking eq #" << p.first->get_owner_id() << " = #" << 
+                    TRACE("conflict_detail_verbose", tout << "marking eq #" << p.first->get_owner_id() << " = #" << 
                           p.second->get_owner_id() << "\n";);
                     m_todo_eqs.push_back(p);
                     SASSERT(m_already_processed_eqs.contains(p));
@@ -168,9 +167,8 @@ namespace smt {
         void eq_justification2literals(enode * lhs, enode * rhs, eq_justification js);
         void eq_branch2literals(enode * n1, enode * n2);
         void eq2literals(enode * n1, enode * n2);
-        void justification2literals_core(justification * js, literal_vector & result);
+        void justification2literals_core(justification * js, literal_vector & result) ;
         void unmark_justifications(unsigned old_js_qhead);
-        void justification2literals(justification * js, literal_vector & result);
 
         literal_vector m_tmp_literal_vector;
 
@@ -256,6 +254,9 @@ namespace smt {
         literal_vector::const_iterator end_unsat_core() const {
             return m_assumptions.end();
         }
+
+        void justification2literals(justification * js, literal_vector & result);
+
     };
 
     inline void mark_literals(conflict_resolution & cr, unsigned sz, literal const * ls) {
diff --git a/src/smt/smt_context.cpp b/src/smt/smt_context.cpp
index 1a8658c99..7d07f3997 100644
--- a/src/smt/smt_context.cpp
+++ b/src/smt/smt_context.cpp
@@ -295,7 +295,7 @@ namespace smt {
     
     void context::assign_core(literal l, b_justification j, bool decision) {
         TRACE("assign_core", tout << (decision?"decision: ":"propagating: ") << l << " ";              
-              display_literal(tout, l); tout << " level: " << m_scope_lvl << "\n";
+              display_literal_verbose(tout, l); tout << " level: " << m_scope_lvl << "\n";
               display(tout, j););
         SASSERT(l.var() < static_cast<int>(m_b_internalized_stack.size()));
         m_assigned_literals.push_back(l);
diff --git a/src/smt/smt_context.h b/src/smt/smt_context.h
index 85fd63033..b918be2cf 100644
--- a/src/smt/smt_context.h
+++ b/src/smt/smt_context.h
@@ -1176,8 +1176,18 @@ namespace smt {
 
         void display_literals(std::ostream & out, unsigned num_lits, literal const * lits) const;
 
+        void display_literals(std::ostream & out, literal_vector const& lits) const {
+            display_literals(out, lits.size(), lits.c_ptr());
+        }
+
+        void display_literal_verbose(std::ostream & out, literal lit) const;
+
         void display_literals_verbose(std::ostream & out, unsigned num_lits, literal const * lits) const;
 
+        void display_literals_verbose(std::ostream & out, literal_vector const& lits) const {
+            display_literals_verbose(out, lits.size(), lits.c_ptr());
+        }
+
         void display_watch_list(std::ostream & out, literal l) const;
 
         void display_watch_lists(std::ostream & out) const;
diff --git a/src/smt/smt_context_pp.cpp b/src/smt/smt_context_pp.cpp
index d04165c5b..1f5566a03 100644
--- a/src/smt/smt_context_pp.cpp
+++ b/src/smt/smt_context_pp.cpp
@@ -96,6 +96,10 @@ namespace smt {
         display_compact(out, num_lits, lits, m_bool_var2expr.c_ptr());
     }
 
+    void context::display_literal_verbose(std::ostream & out, literal lit) const {
+        display_literals_verbose(out, 1, &lit);
+    }
+
     void context::display_literals_verbose(std::ostream & out, unsigned num_lits, literal const * lits) const {
         display_verbose(out, m_manager, num_lits, lits, m_bool_var2expr.c_ptr(), "\n");
     }
@@ -599,12 +603,16 @@ namespace smt {
         case b_justification::CLAUSE: {
             clause * cls = j.get_clause();
             out << "clause ";
-            display_literals(out, cls->get_num_literals(), cls->begin_literals());
+            if (cls) display_literals_verbose(out, cls->get_num_literals(), cls->begin_literals());
             break;
         }
-        case b_justification::JUSTIFICATION:
-            out << "justification";
+        case b_justification::JUSTIFICATION: {
+            out << "justification ";
+            literal_vector lits;
+            const_cast<conflict_resolution&>(*m_conflict_resolution).justification2literals(j.get_justification(), lits);
+            display_literals_verbose(out, lits.size(), lits.c_ptr());
             break;
+        }
         default:
             UNREACHABLE();
             break;
diff --git a/src/smt/theory_seq.cpp b/src/smt/theory_seq.cpp
index d7882d893..551e80c85 100644
--- a/src/smt/theory_seq.cpp
+++ b/src/smt/theory_seq.cpp
@@ -25,6 +25,7 @@ Revision History:
 #include "theory_seq.h"
 #include "ast_trail.h"
 #include "theory_arith.h"
+#include "smt_kernel.h"
 
 using namespace smt;
 
@@ -36,6 +37,21 @@ struct display_expr {
     }
 };
 
+class seq_expr_solver : public expr_solver {
+    kernel m_kernel;
+public:
+    seq_expr_solver(ast_manager& m, smt_params& fp):
+        m_kernel(m, fp)
+    {}
+
+    virtual lbool check_sat(expr* e) {
+        m_kernel.push();
+        m_kernel.assert_expr(e);
+        lbool r = m_kernel.check();
+        m_kernel.pop(1);
+        return r;
+    }
+};
 
 
 void theory_seq::solution_map::update(expr* e, expr* r, dependency* d) {
@@ -182,6 +198,7 @@ theory_seq::theory_seq(ast_manager& m):
     m(m),
     m_rep(m, m_dm),
     m_eq_id(0),
+    m_find(*this),
     m_factory(0),
     m_exclude(m),
     m_axioms(m),
@@ -198,28 +215,31 @@ theory_seq::theory_seq(ast_manager& m):
     m_new_solution(false),
     m_new_propagation(false),
     m_mk_aut(m) {
-    m_prefix = "seq.prefix.suffix";
-    m_suffix = "seq.suffix.prefix";
-    m_contains_left = "seq.contains.left";
-    m_contains_right = "seq.contains.right";
-    m_accept = "aut.accept";
-    m_reject = "aut.reject";
+    m_prefix         = "seq.p.suffix";
+    m_suffix         = "seq.s.prefix";
+    m_accept         = "aut.accept";
+    m_reject         = "aut.reject";
     m_tail           = "seq.tail";
     m_nth            = "seq.nth";
     m_seq_first      = "seq.first";
     m_seq_last       = "seq.last";
-    m_indexof_left   = "seq.indexof.left";
-    m_indexof_right  = "seq.indexof.right";
+    m_indexof_left   = "seq.idx.left";
+    m_indexof_right  = "seq.idx.right";
     m_aut_step       = "aut.step";
     m_pre            = "seq.pre";  // (seq.pre s l):  prefix of string s of length l
     m_post           = "seq.post"; // (seq.post s l): suffix of string s of length l
     m_eq             = "seq.eq";
+
 }
 
 theory_seq::~theory_seq() {
     m_trail_stack.reset();
 }
 
+void theory_seq::init(context* ctx) {
+    theory::init(ctx);
+    m_mk_aut.set_solver(alloc(seq_expr_solver, m, get_context().get_fparams()));
+}
 
 final_check_status theory_seq::final_check_eh() {
     TRACE("seq", display(tout << "level: " << get_context().get_scope_level() << "\n"););
@@ -258,6 +278,11 @@ final_check_status theory_seq::final_check_eh() {
         TRACE("seq", tout << ">>propagate_automata\n";);
         return FC_CONTINUE;
     }
+    if (check_contains()) {
+        ++m_stats.m_propagate_contains;
+        TRACE("seq", tout << ">>propagate_contains\n";);
+        return FC_CONTINUE;
+    }
     if (is_solved()) {
         TRACE("seq", tout << ">>is_solved\n";);
         return FC_DONE;
@@ -288,7 +313,7 @@ bool theory_seq::branch_variable() {
         unsigned id = e.id();
 
         s = find_branch_start(2*id);
-        TRACE("seq", tout << s << " " << 2*id << ": " << e.ls() << " = " << e.rs() << "\n";);
+        TRACE("seq", tout << s << " " << id << ": " << e.ls() << " = " << e.rs() << "\n";);
         bool found = find_branch_candidate(s, e.dep(), e.ls(), e.rs());
         insert_branch_start(2*id, s);
         if (found) {
@@ -337,15 +362,15 @@ bool theory_seq::find_branch_candidate(unsigned& start, dependency* dep, expr_re
         return false;
     }
 
+    TRACE("seq", tout << mk_pp(l, m) << ": " << get_context().get_scope_level() << " - start:" << start << "\n";);
+
     expr_ref v0(m);
     v0 = m_util.str.mk_empty(m.get_sort(l));
-    literal_vector lits;
     if (can_be_equal(ls.size() - 1, ls.c_ptr() + 1, rs.size(), rs.c_ptr())) {
         if (l_false != assume_equality(l, v0)) {
             TRACE("seq", tout << mk_pp(l, m) << " " << v0 << "\n";);
             return true;
         }
-        lits.push_back(~mk_eq_empty(l));
     }
     for (; start < rs.size(); ++start) {
         unsigned j = start;
@@ -370,14 +395,31 @@ bool theory_seq::find_branch_candidate(unsigned& start, dependency* dep, expr_re
         all_units &= m_util.str.is_unit(rs[j]);
     }
     if (all_units) {
+        context& ctx = get_context();
+        literal_vector lits;
+        lits.push_back(~mk_eq_empty(l));
         for (unsigned i = 0; i < rs.size(); ++i) {
             if (can_be_equal(ls.size() - 1, ls.c_ptr() + 1, rs.size() - i - 1, rs.c_ptr() + i + 1)) {
                 v0 = mk_concat(i + 1, rs.c_ptr());
                 lits.push_back(~mk_eq(l, v0, false));
             }
         }
+        for (unsigned i = 0; i < lits.size(); ++i) {
+            switch (ctx.get_assignment(lits[i])) {
+            case l_true:  break;
+            case l_false: start = 0; return true;
+            case l_undef: ctx.force_phase(~lits[i]); start = 0; return true;
+            }
+        }
         set_conflict(dep, lits);
-        TRACE("seq", tout << mk_pp(l, m) << " " << v0 << "\n";);
+        TRACE("seq", 
+              tout << "start: " << start << "\n";
+              for (unsigned i = 0; i < lits.size(); ++i) {
+                  ctx.display_literal_verbose(tout << lits[i] << ": ", lits[i]); 
+                  tout << "\n";
+                  ctx.display(tout, ctx.get_justification(lits[i].var()));
+                  tout << "\n";
+              });
         return true;
     }
     return false;
@@ -429,10 +471,19 @@ lbool theory_seq::assume_equality(expr* l, expr* r) {
     if (n1->get_root() == n2->get_root()) {
         return l_true;
     }
+    if (ctx.is_diseq(n1, n2)) {
+        return l_false;
+    }
+    if (false && ctx.is_diseq_slow(n1, n2)) {
+        return l_false;
+    }
     ctx.mark_as_relevant(n1);
     ctx.mark_as_relevant(n2);
-    ctx.assume_eq(n1, n2);
-    return l_undef;
+    if (!ctx.assume_eq(n1, n2)) {
+        return l_false;
+    }
+    return ctx.get_assignment(mk_eq(l, r, false));
+    //return l_undef;
 }
 
 
@@ -483,29 +534,50 @@ bool theory_seq::propagate_length_coherence(expr* e) {
     return true;
 }
 
+
 bool theory_seq::check_length_coherence(expr* e) {
     if (is_var(e) && m_rep.is_root(e)) {
-        expr_ref emp(m_util.str.mk_empty(m.get_sort(e)), m);
-        expr_ref head(m), tail(m);
-        if (!propagate_length_coherence(e) &&
-            l_false == assume_equality(e, emp)) {
+        if (!check_length_coherence0(e)) {
+            expr_ref emp(m_util.str.mk_empty(m.get_sort(e)), m);
+            expr_ref head(m), tail(m);
             // e = emp \/ e = unit(head.elem(e))*tail(e)
             mk_decompose(e, head, tail);
             expr_ref conc = mk_concat(head, tail);
-            propagate_is_conc(e, conc);
-            assume_equality(tail, emp);
-        }
-        else if (!get_context().at_base_level()) {
-            m_trail_stack.push(push_replay(alloc(replay_length_coherence, m, e)));
+            if (propagate_is_conc(e, conc)) {
+                assume_equality(tail, emp);
+            }
         }
         return true;
     }
     return false;
 }
 
+bool theory_seq::check_length_coherence0(expr* e) {
+    if (is_var(e) && m_rep.is_root(e)) {
+        expr_ref emp(m_util.str.mk_empty(m.get_sort(e)), m);
+        if (propagate_length_coherence(e) ||
+            l_false != assume_equality(e, emp)) {
+            if (!get_context().at_base_level()) {
+                m_trail_stack.push(push_replay(alloc(replay_length_coherence, m, e)));
+            }
+            return true;
+        }
+    }
+    return false;
+}
+
 bool theory_seq::check_length_coherence() {
 
     obj_hashtable<expr>::iterator it = m_length.begin(), end = m_length.end();
+#if 1
+    for (; it != end; ++it) {
+        expr* e = *it;
+        if (check_length_coherence0(e)) {
+            return true;
+        }
+    }
+    it = m_length.begin();
+#endif
     for (; it != end; ++it) {
         expr* e = *it;
         if (check_length_coherence(e)) {
@@ -533,7 +605,6 @@ bool theory_seq::fixed_length(expr* e) {
     }
     if (is_skolem(m_tail, e) || is_skolem(m_seq_first, e) || 
         is_skolem(m_indexof_left, e) || is_skolem(m_indexof_right, e) ||
-        is_skolem(m_contains_left, e) || is_skolem(m_contains_right, e) ||
         m_fixed.contains(e)) {
         return false;
     }
@@ -543,7 +614,6 @@ bool theory_seq::fixed_length(expr* e) {
     m_trail_stack.push(insert_obj_trail<theory_seq, expr>(m_fixed, e));
     m_fixed.insert(e);
 
-
     unsigned _lo = lo.get_unsigned();
     expr_ref seq(e, m), head(m), tail(m);
     expr_ref_vector elems(m);
@@ -571,14 +641,19 @@ void theory_seq::propagate_non_empty(literal lit, expr* s) {
     propagate_lit(0, 1, &lit, ~mk_eq_empty(s));
 }
 
-void theory_seq::propagate_is_conc(expr* e, expr* conc) {
+bool theory_seq::propagate_is_conc(expr* e, expr* conc) {
     TRACE("seq", tout << mk_pp(conc, m) << " is non-empty\n";);
     context& ctx = get_context();
     literal lit = ~mk_eq_empty(e);
-    SASSERT(ctx.get_assignment(lit) == l_true);
-    propagate_lit(0, 1, &lit, mk_eq(e, conc, false));
-    expr_ref e1(e, m), e2(conc, m);
-    new_eq_eh(m_dm.mk_leaf(assumption(lit)), ctx.get_enode(e1), ctx.get_enode(e2));
+    if (ctx.get_assignment(lit) == l_true) {
+        propagate_lit(0, 1, &lit, mk_eq(e, conc, false));
+        expr_ref e1(e, m), e2(conc, m);
+        new_eq_eh(m_dm.mk_leaf(assumption(lit)), ctx.get_enode(e1), ctx.get_enode(e2));
+        return true;
+    }
+    else {
+        return false;
+    }
 }
 
 bool theory_seq::is_nth(expr* e) const {
@@ -718,6 +793,23 @@ bool theory_seq::check_extensionality() {
     return true;
 }
 
+/*
+  \brief check negated contains constriants.
+ */
+bool theory_seq::check_contains() {
+    context & ctx = get_context();
+    for (unsigned i = 0; !ctx.inconsistent() && i < m_ncs.size(); ++i) {
+        if (solve_nc(i)) {
+            if (i + 1 != m_ncs.size()) {
+                nc n = m_ncs[m_ncs.size()-1];
+                m_ncs.set(i, n);
+                --i;
+            }
+            m_ncs.pop_back();
+        }
+    }
+    return m_new_propagation || ctx.inconsistent();
+}
 /*
    - Eqs = 0
    - Diseqs evaluate to false
@@ -763,20 +855,31 @@ void theory_seq::linearize(dependency* dep, enode_pair_vector& eqs, literal_vect
 
 
 void theory_seq::propagate_lit(dependency* dep, unsigned n, literal const* _lits, literal lit) {
+    if (lit == true_literal) return;
+
     context& ctx = get_context();
-    ctx.mark_as_relevant(lit);
     literal_vector lits(n, _lits);
+
+    if (lit == false_literal) {
+        set_conflict(dep, lits);
+        return;
+    }
+
+    ctx.mark_as_relevant(lit);
     enode_pair_vector eqs;
     linearize(dep, eqs, lits);
-    TRACE("seq", ctx.display_detailed_literal(tout, lit);
-          tout << " <- "; ctx.display_literals_verbose(tout, lits.size(), lits.c_ptr()); if (!lits.empty()) tout << "\n"; display_deps(tout, dep););
+    TRACE("seq",
+          tout << "assert:";
+          ctx.display_detailed_literal(tout, lit);
+          tout << " <- "; ctx.display_literals_verbose(tout, lits);
+          if (!lits.empty()) tout << "\n"; display_deps(tout, dep););
     justification* js =
         ctx.mk_justification(
             ext_theory_propagation_justification(
                 get_id(), ctx.get_region(), lits.size(), lits.c_ptr(), eqs.size(), eqs.c_ptr(), lit));
 
     m_new_propagation = true;
-    ctx.assign(lit, js);
+    ctx.assign(lit, js);    
 }
 
 void theory_seq::set_conflict(dependency* dep, literal_vector const& _lits) {
@@ -784,7 +887,7 @@ void theory_seq::set_conflict(dependency* dep, literal_vector const& _lits) {
     enode_pair_vector eqs;
     literal_vector lits(_lits);
     linearize(dep, eqs, lits);
-    TRACE("seq", display_deps(tout, lits, eqs););
+    TRACE("seq", display_deps(tout << "assert conflict:", lits, eqs););
     m_new_propagation = true;
     ctx.set_conflict(
         ctx.mk_justification(
@@ -801,8 +904,8 @@ void theory_seq::propagate_eq(dependency* dep, enode* n1, enode* n2) {
     enode_pair_vector eqs;
     linearize(dep, eqs, lits);
     TRACE("seq",
-          tout << mk_pp(n1->get_owner(), m) << " = " << mk_pp(n2->get_owner(), m) << " <- \n";
-          display_deps(tout, dep);
+          tout << "assert: " << mk_pp(n1->get_owner(), m) << " = " << mk_pp(n2->get_owner(), m) << " <-\n";
+          display_deps(tout, dep); 
           );
 
     justification* js = ctx.mk_justification(
@@ -860,6 +963,7 @@ bool theory_seq::simplify_eq(expr_ref_vector& ls, expr_ref_vector& rs, dependenc
             // no-op
         }
         else if (m_util.is_seq(li) || m_util.is_re(li)) {
+            TRACE("seq", tout << "inserting " << li << " = " << ri << "\n";);
             m_eqs.push_back(mk_eqdep(li, ri, deps));            
         }
         else {
@@ -1017,6 +1121,7 @@ bool theory_seq::solve_eq(expr_ref_vector const& l, expr_ref_vector const& r, de
         return true;
     }
     if (!ctx.inconsistent() && change) {
+        TRACE("seq", tout << "inserting equality\n";);
         m_eqs.push_back(eq(m_eq_id++, ls, rs, deps));
         return true;
     }
@@ -1485,6 +1590,30 @@ bool theory_seq::solve_ne(unsigned idx) {
     return updated;
 }
 
+bool theory_seq::solve_nc(unsigned idx) {
+    context& ctx = get_context();
+    nc const& n = m_ncs[idx];
+
+    dependency* deps = n.deps();    
+    expr_ref c = canonize(n.contains(), deps);
+
+    CTRACE("seq", c != n.contains(), tout << n.contains() << " => " << c << "\n";);
+    
+    if (m.is_true(c)) {
+        literal_vector lits;
+        set_conflict(deps, lits);
+        return true;
+    }
+    if (m.is_false(c)) {
+        return true;
+    }
+    if (c != n.contains()) {
+        m_ncs.push_back(nc(c, deps));
+        return true;
+    }
+    return false;
+}
+
 theory_seq::cell* theory_seq::mk_cell(cell* p, expr* e, dependency* d) {
     cell* c = alloc(cell, p, e, d);
     m_all_cells.push_back(c);
@@ -1748,6 +1877,20 @@ void theory_seq::display(std::ostream & out) const {
         out << "Exclusions:\n";
         m_exclude.display(out);
     }
+
+    if (!m_length.empty()) {
+        obj_hashtable<expr>::iterator it = m_length.begin(), end = m_length.end();
+        for (; it != end; ++it) {
+            expr* e = *it;
+            rational lo(-1), hi(-1);
+            lower_bound(e, lo);
+            upper_bound(e, hi);
+            if (lo.is_pos() || !hi.is_minus_one()) {
+                out << mk_pp(e, m) << " [" << lo << ":" << hi << "]\n";
+            }
+        }
+    }
+
 }
 
 void theory_seq::display_equations(std::ostream& out) const {
@@ -1974,6 +2117,7 @@ theory_var theory_seq::mk_var(enode* n) {
     }
     else {
         theory_var v = theory::mk_var(n);
+        m_find.mk_var();
         get_context().attach_th_var(n, this, v);
         get_context().mark_as_relevant(n);
         return v;
@@ -2033,7 +2177,7 @@ expr_ref theory_seq::expand(expr* e0, dependency*& eqs) {
         return result;
     }
     expr* e = m_rep.find(e0, deps);
-    expr* e1, *e2;
+    expr* e1, *e2, *e3;
     if (m_util.str.is_concat(e, e1, e2)) {
         result = mk_concat(expand(e1, deps), expand(e2, deps));
     }
@@ -2052,6 +2196,12 @@ expr_ref theory_seq::expand(expr* e0, dependency*& eqs) {
     else if (m_util.str.is_unit(e, e1)) {
         result = m_util.str.mk_unit(expand(e1, deps));
     }
+    else if (m_util.str.is_index(e, e1, e2)) {
+        result = m_util.str.mk_index(expand(e1, deps), expand(e2, deps), m_autil.mk_int(0));
+    }
+    else if (m_util.str.is_index(e, e1, e2, e3)) {
+        result = m_util.str.mk_index(expand(e1, deps), expand(e2, deps), e3);
+    }
     else {
         result = e;
     }
@@ -2180,7 +2330,6 @@ void theory_seq::add_indexof_axiom(expr* i) {
     expr_ref zero(m_autil.mk_int(0), m);
     expr_ref xsy(m);
 
-
     if (!offset || (m_autil.is_numeral(offset, r) && r.is_zero())) {
         expr_ref x  = mk_skolem(m_indexof_left, t, s);
         expr_ref y  = mk_skolem(m_indexof_right, t, s);
@@ -2356,7 +2505,7 @@ void theory_seq::propagate_in_re(expr* n, bool is_true) {
             propagate_lit(0, 1, &lit, lits[1]);
         }
         else {
-            TRACE("seq", ctx.display_literals_verbose(tout, lits.size(), lits.c_ptr()); tout << "\n";);
+            TRACE("seq", ctx.display_literals_verbose(tout, lits); tout << "\n";);
             ctx.mk_th_axiom(get_id(), lits.size(), lits.c_ptr());
         }
     }
@@ -2389,7 +2538,7 @@ static theory_mi_arith* get_th_arith(context& ctx, theory_id afid, expr* e) {
     }
 }
 
-bool theory_seq::lower_bound(expr* _e, rational& lo) {
+bool theory_seq::lower_bound(expr* _e, rational& lo) const {
     context& ctx = get_context();
     expr_ref e(m_util.str.mk_length(_e), m);
     theory_mi_arith* tha = get_th_arith(ctx, m_autil.get_family_id(), e);
@@ -2398,7 +2547,7 @@ bool theory_seq::lower_bound(expr* _e, rational& lo) {
     return m_autil.is_numeral(_lo, lo) && lo.is_int();
 }
 
-bool theory_seq::upper_bound(expr* _e, rational& hi) {
+bool theory_seq::upper_bound(expr* _e, rational& hi) const {
     context& ctx = get_context();
     expr_ref e(m_util.str.mk_length(_e), m);
     theory_mi_arith* tha = get_th_arith(ctx, m_autil.get_family_id(), e);
@@ -2407,7 +2556,7 @@ bool theory_seq::upper_bound(expr* _e, rational& hi) {
     return m_autil.is_numeral(_hi, hi) && hi.is_int();
 }
 
-bool theory_seq::get_length(expr* e, rational& val) {
+bool theory_seq::get_length(expr* e, rational& val) const {
     context& ctx = get_context();
     theory* th = ctx.get_theory(m_autil.get_family_id());
     if (!th) return false;
@@ -2677,7 +2826,7 @@ literal theory_seq::mk_seq_eq(expr* a, expr* b) {
     return mk_literal(mk_skolem(m_eq, a, b, 0, m.mk_bool_sort()));
 }
 
-literal theory_seq::mk_eq_empty(expr* _e) {
+literal theory_seq::mk_eq_empty(expr* _e, bool phase) {
     context& ctx = get_context();
     expr_ref e(_e, m);
     SASSERT(m_util.is_seq(e));
@@ -2699,7 +2848,7 @@ literal theory_seq::mk_eq_empty(expr* _e) {
     emp = m_util.str.mk_empty(m.get_sort(e));
 
     literal lit = mk_eq(e, emp, false);
-    ctx.force_phase(lit);
+    ctx.force_phase(phase?lit:~lit);
     ctx.mark_as_relevant(lit);
     return lit;
 }
@@ -2713,7 +2862,7 @@ void theory_seq::add_axiom(literal l1, literal l2, literal l3, literal l4, liter
     if (l3 != null_literal && l3 != false_literal) { ctx.mark_as_relevant(l3); lits.push_back(l3); }
     if (l4 != null_literal && l4 != false_literal) { ctx.mark_as_relevant(l4); lits.push_back(l4); }
     if (l5 != null_literal && l5 != false_literal) { ctx.mark_as_relevant(l5); lits.push_back(l5); }
-    TRACE("seq", ctx.display_literals_verbose(tout << "axiom: ", lits.size(), lits.c_ptr()); tout << "\n";);
+    TRACE("seq", ctx.display_literals_verbose(tout << "assert: ", lits); tout << "\n";);
     m_new_propagation = true;
     ++m_stats.m_add_axiom;
     ctx.mk_th_axiom(get_id(), lits.size(), lits.c_ptr());
@@ -2770,8 +2919,8 @@ void theory_seq::propagate_eq(dependency* deps, literal_vector const& _lits, exp
         new_eq_eh(deps, n1, n2);
     }
     TRACE("seq",
-          ctx.display_literals_verbose(tout, lits.size(), lits.c_ptr());
-          tout << " => " << mk_pp(e1, m) << " = " << mk_pp(e2, m) << "\n";);
+          tout << "assert: " << mk_pp(e1, m) << " = " << mk_pp(e2, m) << " <- \n";
+          if (!lits.empty()) { ctx.display_literals_verbose(tout, lits); tout << "\n"; });
     justification* js =
         ctx.mk_justification(
             ext_theory_eq_propagation_justification(
@@ -2798,7 +2947,7 @@ void theory_seq::assign_eh(bool_var v, bool is_true) {
         }
         else {
 #if 0
-            propagate_not_prefix(e);
+            propagate_not_prefix2(e);
 #else
             propagate_non_empty(lit, e1);
             if (add_prefix2prefix(e, change)) {
@@ -2836,17 +2985,22 @@ void theory_seq::assign_eh(bool_var v, bool is_true) {
     }
     else if (m_util.str.is_contains(e, e1, e2)) {
         if (is_true) {
-            expr_ref f1 = mk_skolem(m_contains_left, e1, e2);
-            expr_ref f2 = mk_skolem(m_contains_right, e1, e2);
+            expr_ref f1 = mk_skolem(m_indexof_left, e1, e2);
+            expr_ref f2 = mk_skolem(m_indexof_right, e1, e2);
             f = mk_concat(f1, e2, f2);
             propagate_eq(lit, f, e1, true);
         }
         else if (!canonizes(false, e)) {
             propagate_non_empty(lit, e2);
+#if 1
+            dependency* dep = m_dm.mk_leaf(assumption(lit));
+            m_ncs.push_back(nc(expr_ref(e, m), dep));
+#else
             propagate_lit(0, 1, &lit, ~mk_literal(m_util.str.mk_prefix(e2, e1)));
             if (add_contains2contains(e, change)) {
                 add_atom(e);
             }
+#endif
         }
     }
     else if (is_accept(e)) {
@@ -2898,6 +3052,12 @@ void theory_seq::new_eq_eh(theory_var v1, theory_var v2) {
 
 void theory_seq::new_eq_eh(dependency* deps, enode* n1, enode* n2) {
     if (n1 != n2 && m_util.is_seq(n1->get_owner())) {
+        theory_var v1 = n1->get_th_var(get_id());
+        theory_var v2 = n2->get_th_var(get_id());
+        if (m_find.find(v1) == m_find.find(v2)) {
+            return;
+        }
+        m_find.merge(v1, v2);
         expr_ref o1(n1->get_owner(), m);
         expr_ref o2(n2->get_owner(), m);
         TRACE("seq", tout << o1 << " = " << o2 << "\n";);
@@ -2916,7 +3076,7 @@ void theory_seq::new_diseq_eh(theory_var v1, theory_var v2) {
     expr_ref eq(m.mk_eq(e1, e2), m);
     m_rewrite(eq);
     if (!m.is_false(eq)) {
-        TRACE("seq", tout << "new disequality: " << eq << "\n";);
+        TRACE("seq", tout << "new disequality " << get_context().get_scope_level() << ": " << eq << "\n";);
 
         literal lit = mk_eq(e1, e2, false);
 
@@ -2975,6 +3135,7 @@ void theory_seq::push_scope_eh() {
     m_trail_stack.push(value_trail<theory_seq, unsigned>(m_axioms_head));
     m_eqs.push_scope();
     m_nqs.push_scope();
+    m_ncs.push_scope();
     m_atoms_lim.push_back(m_atoms.size());
 }
 
@@ -2987,6 +3148,7 @@ void theory_seq::pop_scope_eh(unsigned num_scopes) {
     m_exclude.pop_scope(num_scopes);
     m_eqs.pop_scope(num_scopes);
     m_nqs.pop_scope(num_scopes);
+    m_ncs.pop_scope(num_scopes);
     m_atoms.resize(m_atoms_lim[m_atoms_lim.size()-num_scopes]);
     m_atoms_lim.shrink(m_atoms_lim.size()-num_scopes);
     m_rewrite.reset();    
@@ -3191,7 +3353,7 @@ bool theory_seq::add_accept2step(expr* acc, bool& change) {
     if (has_undef) {
         return true;
     }
-    TRACE("seq", ctx.display_literals_verbose(tout, lits.size(), lits.c_ptr()); tout << "\n";);
+    TRACE("seq", ctx.display_literals_verbose(tout, lits); tout << "\n";);
     for (unsigned i = 0; i < lits.size(); ++i) {
         SASSERT(ctx.get_assignment(lits[i]) == l_false);
         lits[i].neg();
@@ -3341,6 +3503,32 @@ void theory_seq::propagate_not_prefix(expr* e) {
     add_axiom(lit, e2_is_emp, ~mk_eq(c, d, false), mk_seq_eq(e2, x));
 }
 
+/*
+  !prefix(e1,e2) => len(e1) > 0
+  !prefix(e1,e2) => len(e1) > len(e2) or e2 = pre(e2,len(e1))post(e2,len(e2)-len(e1)) & pre(e2, len(e1)) != e1
+*/
+
+void theory_seq::propagate_not_prefix2(expr* e) {
+    context& ctx = get_context();
+    expr* e1, *e2;
+    VERIFY(m_util.str.is_prefix(e, e1, e2));
+    literal lit = ctx.get_literal(e);
+    SASSERT(ctx.get_assignment(lit) == l_false);
+    if (canonizes(false, e)) {
+        return;
+    }
+    propagate_non_empty(~lit, e1);
+    expr_ref len_e1(m_util.str.mk_length(e1), m);
+    expr_ref len_e2(m_util.str.mk_length(e2), m);
+    expr_ref len_e2_e1(mk_sub(len_e2, len_e1), m);
+    expr_ref x = mk_skolem(m_pre,  e2, len_e1);
+    expr_ref y = mk_skolem(m_post, e2, len_e2_e1);
+    literal e2_ge_e1 = mk_literal(m_autil.mk_ge(len_e2_e1, m_autil.mk_int(0)));
+    add_axiom(lit, ~e2_ge_e1, mk_seq_eq(e2, mk_concat(x, y)));
+    add_axiom(lit, ~e2_ge_e1, mk_eq(m_util.str.mk_length(x), len_e1, false));
+    add_axiom(lit, ~e2_ge_e1, ~mk_eq(e1, x, false));
+}
+
 /*
   !suffix(e1,e2) => e1 != ""
   !suffix(e1,e2) => e2 = "" or e1 = ycx & (e2 = zdx & c != d or x = e2)
@@ -3391,7 +3579,7 @@ bool theory_seq::add_prefix2prefix(expr* e, bool& change) {
     switch (ctx.get_assignment(e2_is_emp)) {
     case l_true:
         TRACE("seq", tout << mk_pp(e, m) << ": " << mk_pp(e2, m) << " = empty\n";
-              ctx.display_literals_verbose(tout, 1, &e2_is_emp); tout << "\n"; );        
+              ctx.display_literal_verbose(tout, e2_is_emp); tout << "\n"; );        
         return false; // done
     case l_undef:
         // ctx.force_phase(e2_is_emp);
@@ -3405,7 +3593,7 @@ bool theory_seq::add_prefix2prefix(expr* e, bool& change) {
     conc = mk_concat(head2, tail2);
     propagate_eq(~e2_is_emp, e2, conc, true);
 
-    literal e1_is_emp = mk_eq_empty(e1);
+    literal e1_is_emp = mk_eq_empty(e1, false);
     switch (ctx.get_assignment(e1_is_emp)) {
     case l_true:        
         TRACE("seq", tout << mk_pp(e, m) << ": " << mk_pp(e1, m) << " !=  empty\n";);
diff --git a/src/smt/theory_seq.h b/src/smt/theory_seq.h
index d275cd788..8206eeca4 100644
--- a/src/smt/theory_seq.h
+++ b/src/smt/theory_seq.h
@@ -28,6 +28,7 @@ Revision History:
 #include "scoped_ptr_vector.h"
 #include "automaton.h"
 #include "seq_rewriter.h"
+#include "union_find.h"
 
 namespace smt {
 
@@ -44,6 +45,7 @@ namespace smt {
         typedef trail_stack<theory_seq> th_trail_stack;
         typedef std::pair<expr*, dependency*> expr_dep;
         typedef obj_map<expr, expr_dep> eqdep_map_t; 
+	typedef union_find<theory_seq> th_union_find;
 
         class seq_value_proc;
 
@@ -191,6 +193,27 @@ namespace smt {
             expr_ref const& r() const { return m_r; }
         };
 
+        class nc {
+            expr_ref                 m_contains;
+            dependency*              m_dep;
+        public:
+            nc(expr_ref const& c, dependency* dep):
+                m_contains(c), 
+                m_dep(dep) {}
+            nc(nc const& other):
+                m_contains(other.m_contains), 
+                m_dep(other.m_dep) {}
+            nc& operator=(nc const& other) {
+                if (this != &other) {
+                    m_contains = other.m_contains;
+                    m_dep = other.m_dep;
+                }
+                return *this;
+            }
+            dependency* deps() const { return m_dep; }
+            expr_ref const& contains() const { return m_contains; }
+        };
+
         class apply {
         public:
             virtual ~apply() {}
@@ -263,13 +286,16 @@ namespace smt {
             unsigned m_add_axiom;
             unsigned m_extensionality;
             unsigned m_fixed_length;
+            unsigned m_propagate_contains;
         };
         ast_manager&               m;
         dependency_manager         m_dm;
         solution_map               m_rep;        // unification representative.
         scoped_vector<eq>          m_eqs;        // set of current equations.
         scoped_vector<ne>          m_nqs;        // set of current disequalities.
-        unsigned                   m_eq_id;
+        scoped_vector<nc>          m_ncs;        // set of non-contains constraints.
+        unsigned                   m_eq_id;	
+	th_union_find              m_find;
 
         seq_factory*               m_factory;    // value factory
         exclusion_table            m_exclude;    // set of asserted disequalities.
@@ -286,7 +312,7 @@ namespace smt {
         arith_util       m_autil;
         th_trail_stack   m_trail_stack;
         stats            m_stats;
-        symbol           m_prefix, m_suffix, m_contains_left, m_contains_right, m_accept, m_reject;
+        symbol           m_prefix, m_suffix, m_accept, m_reject;
         symbol           m_tail, m_nth, m_seq_first, m_seq_last, m_indexof_left, m_indexof_right, m_aut_step;
         symbol           m_pre, m_post, m_eq;
         ptr_vector<expr> m_todo;
@@ -306,6 +332,7 @@ namespace smt {
 
         obj_hashtable<expr>            m_fixed;            // string variables that are fixed length.
 
+        virtual void init(context* ctx);
         virtual final_check_status final_check_eh();
         virtual bool internalize_atom(app* atom, bool) { return internalize_term(atom); }
         virtual bool internalize_term(app*);
@@ -335,12 +362,14 @@ namespace smt {
         bool split_variable();           // split a variable
         bool is_solved(); 
         bool check_length_coherence();
+        bool check_length_coherence0(expr* e);
         bool check_length_coherence(expr* e);
         bool fixed_length();
         bool fixed_length(expr* e);
         bool propagate_length_coherence(expr* e);  
 
         bool check_extensionality();
+        bool check_contains();
         bool solve_eqs(unsigned start);
         bool solve_eq(expr_ref_vector const& l, expr_ref_vector const& r, dependency* dep);
         bool simplify_eq(expr_ref_vector& l, expr_ref_vector& r, dependency* dep);
@@ -362,6 +391,7 @@ namespace smt {
         expr_ref mk_concat(expr* e1, expr* e2, expr* e3) { return expr_ref(m_util.str.mk_concat(e1, e2, e3), m); }
         bool solve_nqs(unsigned i);
         bool solve_ne(unsigned i);
+        bool solve_nc(unsigned i);
 
         struct cell {
             cell*       m_parent;
@@ -441,7 +471,7 @@ namespace smt {
         void add_at_axiom(expr* n);
         void add_in_re_axiom(expr* n);
         literal mk_literal(expr* n);
-        literal mk_eq_empty(expr* n);
+        literal mk_eq_empty(expr* n, bool phase = true);
         literal mk_seq_eq(expr* a, expr* b);
         void tightest_prefix(expr* s, expr* x);
         expr_ref mk_sub(expr* a, expr* b);
@@ -452,9 +482,9 @@ namespace smt {
 
 
         // arithmetic integration
-        bool lower_bound(expr* s, rational& lo);
-        bool upper_bound(expr* s, rational& hi);
-        bool get_length(expr* s, rational& val);
+        bool lower_bound(expr* s, rational& lo) const;
+        bool upper_bound(expr* s, rational& hi) const;
+        bool get_length(expr* s, rational& val) const;
 
         void mk_decompose(expr* e, expr_ref& head, expr_ref& tail);
         expr_ref mk_skolem(symbol const& s, expr* e1, expr* e2 = 0, expr* e3 = 0, sort* range = 0);
@@ -489,11 +519,12 @@ namespace smt {
         bool add_suffix2suffix(expr* e, bool& change);
         bool add_contains2contains(expr* e, bool& change);
         void propagate_not_prefix(expr* e);
+        void propagate_not_prefix2(expr* e);
         void propagate_not_suffix(expr* e);
         void ensure_nth(literal lit, expr* s, expr* idx);
         bool canonizes(bool sign, expr* e);
         void propagate_non_empty(literal lit, expr* s);
-        void propagate_is_conc(expr* e, expr* conc);
+        bool propagate_is_conc(expr* e, expr* conc);
         void propagate_acc_rej_length(literal lit, expr* acc_rej);
         bool propagate_automata();
         void add_atom(expr* e);
@@ -512,6 +543,11 @@ namespace smt {
         // model building
         app* mk_value(app* a);
 
+	th_trail_stack& get_trail_stack() { return m_trail_stack; }
+        void merge_eh(theory_var, theory_var, theory_var v1, theory_var v2) {}
+        void after_merge_eh(theory_var r1, theory_var r2, theory_var v1, theory_var v2) { }
+        void unmerge_eh(theory_var v1, theory_var v2) {}
+
     };
 };
 
diff --git a/src/tactic/bv/bv_bounds_tactic.cpp b/src/tactic/bv/bv_bounds_tactic.cpp
index 587b9df9a..e67c2470b 100644
--- a/src/tactic/bv/bv_bounds_tactic.cpp
+++ b/src/tactic/bv/bv_bounds_tactic.cpp
@@ -20,9 +20,11 @@ Author:
 #include "ctx_simplify_tactic.h"
 #include "bv_decl_plugin.h"
 #include "ast_pp.h"
+#include <climits>
 
-static rational uMaxInt(unsigned sz) {
-    return rational::power_of_two(sz) - rational::one();
+static uint64 uMaxInt(unsigned sz) {
+    SASSERT(sz <= 64);
+    return ULLONG_MAX >> (64u - sz);
 }
 
 namespace {
@@ -30,31 +32,32 @@ namespace {
 struct interval {
     // l < h: [l, h]
     // l > h: [0, h] U [l, UMAX_INT]
-    rational l, h;
+    uint64 l, h;
     unsigned sz;
     bool tight;
 
-    explicit interval() : l(0), h(0), sz(0), tight(false) {}
-    interval(const rational& l, const rational& h, unsigned sz, bool tight = false) : l(l), h(h), sz(sz), tight(tight) {
+    interval() {}
+    interval(uint64 l, uint64 h, unsigned sz, bool tight = false) : l(l), h(h), sz(sz), tight(tight) {
         // canonicalize full set
-        if (is_wrapped() && l == h + rational::one()) {
-            this->l = rational::zero();
+        if (is_wrapped() && l == h + 1) {
+            this->l = 0;
             this->h = uMaxInt(sz);
         }
         SASSERT(invariant());
     }
 
     bool invariant() const {
-        return !l.is_neg() && !h.is_neg() && l <= uMaxInt(sz) && h <= uMaxInt(sz) &&
-               (!is_wrapped() || l != h+rational::one());
+        return l <= uMaxInt(sz) && h <= uMaxInt(sz) &&
+               (!is_wrapped() || l != h+1);
     }
 
-    bool is_full() const { return l.is_zero() && h == uMaxInt(sz); }
+    bool is_full() const { return l == 0 && h == uMaxInt(sz); }
     bool is_wrapped() const { return l > h; }
+    bool is_singleton() const { return l == h; }
 
     bool operator==(const interval& b) const {
         SASSERT(sz == b.sz);
-        return l == b.l && h == b.h;
+        return l == b.l && h == b.h && tight == b.tight;
     }
     bool operator!=(const interval& b) const { return !(*this == b); }
 
@@ -79,7 +82,7 @@ struct interval {
 
     /// return false if intersection is unsat
     bool intersect(const interval& b, interval& result) const {
-        if (is_full() || (l == b.l && h == b.h)) {
+        if (is_full() || *this == b) {
             result = b;
             return true;
         }
@@ -128,18 +131,18 @@ struct interval {
     /// return false if negation is empty
     bool negate(interval& result) const {
         if (!tight) {
-            result = interval(rational::zero(), uMaxInt(sz), true);
+            result = interval(0, uMaxInt(sz), true);
             return true;
         }
 
         if (is_full())
             return false;
-        if (l.is_zero()) {
-            result = interval(h + rational::one(), uMaxInt(sz), sz);
+        if (l == 0) {
+            result = interval(h + 1, uMaxInt(sz), sz);
         } else if (uMaxInt(sz) == h) {
-            result = interval(rational::zero(), l - rational::one(), sz);
+            result = interval(0, l - 1, sz);
         } else {
-            result = interval(h + rational::one(), l - rational::one(), sz);
+            result = interval(h + 1, l - 1, sz);
         }
         return true;
     }
@@ -151,59 +154,76 @@ std::ostream& operator<<(std::ostream& o, const interval& I) {
 }
 
 
+struct undo_bound {
+    expr* e;
+    interval b;
+    bool fresh;
+    undo_bound(expr* e, const interval& b, bool fresh) : e(e), b(b), fresh(fresh) {}
+};
+
 class bv_bounds_simplifier : public ctx_simplify_tactic::simplifier {
     typedef obj_map<expr, interval> map;
+    typedef obj_map<expr, bool> expr_set;
+    typedef obj_map<expr, unsigned> expr_cnt;
 
-    ast_manager& m;
-    params_ref   m_params;
-    bool         m_propagate_eq;
-    bv_util      m_bv;
-    vector<map>  m_scopes;
-    map         *m_bound;
+    ast_manager&       m;
+    params_ref         m_params;
+    bool               m_propagate_eq;
+    bv_util            m_bv;
+    vector<undo_bound> m_scopes;
+    map                m_bound;
+    svector<expr_set*> m_expr_vars;
+    svector<expr_cnt*> m_bound_exprs;
 
-    bool is_bound(expr *e, expr*& v, interval& b) {
-        if (!m.is_bool(e))
-            return false;
+    bool is_number(expr *e, uint64& n, unsigned& sz) const {
+        rational r;
+        if (m_bv.is_numeral(e, r, sz) && sz <= 64) {
+            n = r.get_uint64();
+            return true;
+        }
+        return false;
+    }
 
-        rational n;
+    bool is_bound(expr *e, expr*& v, interval& b) const {
+        uint64 n;
         expr *lhs, *rhs;
         unsigned sz;
 
         if (m_bv.is_bv_ule(e, lhs, rhs)) {
-            if (m_bv.is_numeral(lhs, n, sz)) { // C ule x <=> x uge C
+            if (is_number(lhs, n, sz)) { // C ule x <=> x uge C
                 if (m_bv.is_numeral(rhs))
                     return false;
                 b = interval(n, uMaxInt(sz), sz, true);
                 v = rhs;
                 return true;
             }
-            if (m_bv.is_numeral(rhs, n, sz)) { // x ule C
-                b = interval(rational::zero(), n, sz, true);
+            if (is_number(rhs, n, sz)) { // x ule C
+                b = interval(0, n, sz, true);
                 v = lhs;
                 return true;
             }
         } else if (m_bv.is_bv_sle(e, lhs, rhs)) {
-            if (m_bv.is_numeral(lhs, n, sz)) { // C sle x <=> x sge C
+            if (is_number(lhs, n, sz)) { // C sle x <=> x sge C
                 if (m_bv.is_numeral(rhs))
                     return false;
-                b = interval(n, rational::power_of_two(sz-1) - rational::one(), sz, true);
+                b = interval(n, (1ull << (sz-1)) - 1, sz, true);
                 v = rhs;
                 return true;
             }
-            if (m_bv.is_numeral(rhs, n, sz)) { // x sle C
-                b = interval(rational::power_of_two(sz-1), n, sz, true);
+            if (is_number(rhs, n, sz)) { // x sle C
+                b = interval(1ull << (sz-1), n, sz, true);
                 v = lhs;
                 return true;
             }
         } else if (m.is_eq(e, lhs, rhs)) {
-            if (m_bv.is_numeral(lhs, n, sz)) {
+            if (is_number(lhs, n, sz)) {
                 if (m_bv.is_numeral(rhs))
                     return false;
                 b = interval(n, n, sz, true);
                 v = rhs;
                 return true;
             }
-            if (m_bv.is_numeral(rhs, n, sz)) {
+            if (is_number(rhs, n, sz)) {
                 b = interval(n, n, sz, true);
                 v = lhs;
                 return true;
@@ -212,14 +232,65 @@ class bv_bounds_simplifier : public ctx_simplify_tactic::simplifier {
         return false;
     }
 
-public:
+    expr_set* get_expr_vars(expr* t) {
+        unsigned id = t->get_id();
+        m_expr_vars.reserve(id + 1);
+        expr_set*& entry = m_expr_vars[id];
+        if (entry)
+            return entry;
 
-    bv_bounds_simplifier(ast_manager& m, params_ref const& p) : m(m), m_params(p), m_bv(m) {
-        m_scopes.push_back(map());
-        m_bound = &m_scopes.back();
-        updt_params(p);
+        expr_set* set = alloc(expr_set);
+        entry = set;
+
+        if (!m_bv.is_numeral(t))
+            set->insert(t, true);
+
+        if (!is_app(t))
+            return set;
+
+        app* a = to_app(t);
+        for (unsigned i = 0; i < a->get_num_args(); ++i) {
+            expr_set* set_arg = get_expr_vars(a->get_arg(i));
+            for (expr_set::iterator I = set_arg->begin(), E = set_arg->end(); I != E; ++I) {
+                set->insert(I->m_key, true);
+            }
+        }
+        return set;
     }
 
+    expr_cnt* get_expr_bounds(expr* t) {
+        unsigned id = t->get_id();
+        m_bound_exprs.reserve(id + 1);
+        expr_cnt*& entry = m_bound_exprs[id];
+        if (entry)
+            return entry;
+
+        expr_cnt* set = alloc(expr_cnt);
+        entry = set;
+
+        if (!is_app(t))
+            return set;
+
+        interval b;
+        expr* e;
+        if (is_bound(t, e, b)) {
+            set->insert_if_not_there2(e, 0)->get_data().m_value++;
+        }
+
+        app* a = to_app(t);
+        for (unsigned i = 0; i < a->get_num_args(); ++i) {
+            expr_cnt* set_arg = get_expr_bounds(a->get_arg(i));
+            for (expr_cnt::iterator I = set_arg->begin(), E = set_arg->end(); I != E; ++I) {
+                set->insert_if_not_there2(I->m_key, 0)->get_data().m_value += I->m_value;
+            }
+        }
+        return set;
+    }
+
+public:
+    bv_bounds_simplifier(ast_manager& m, params_ref const& p) : m(m), m_params(p), m_bv(m) {
+        updt_params(p);
+    }
 
     virtual void updt_params(params_ref const & p) {
         m_propagate_eq = p.get_bool("propagate_eq", false);
@@ -229,7 +300,14 @@ public:
         r.insert("propagate-eq", CPK_BOOL, "(default: false) propagate equalities from inequalities");
     }
 
-    virtual ~bv_bounds_simplifier() {}
+    virtual ~bv_bounds_simplifier() {
+        for (unsigned i = 0, e = m_expr_vars.size(); i < e; ++i) {
+            dealloc(m_expr_vars[i]);
+        }
+        for (unsigned i = 0, e = m_bound_exprs.size(); i < e; ++i) {
+            dealloc(m_bound_exprs[i]);
+        }
+    }
 
     virtual bool assert_expr(expr * t, bool sign) {
         while (m.is_not(t, t)) {
@@ -243,20 +321,38 @@ public:
             if (sign)
                 VERIFY(b.negate(b));
 
-            push();
             TRACE("bv", tout << (sign?"(not ":"") << mk_pp(t, m) << (sign ? ")" : "") << ": " << mk_pp(t1, m) << " in " << b << "\n";);
-            interval& r = m_bound->insert_if_not_there2(t1, b)->get_data().m_value;
-            return r.intersect(b, r);
+            map::obj_map_entry* e = m_bound.find_core(t1);
+            if (e) {
+                interval& old = e->get_data().m_value;
+                interval intr;
+                if (!old.intersect(b, intr))
+                    return false;
+                if (old == intr)
+                    return true;
+                m_scopes.insert(undo_bound(t1, old, false));
+                old = intr;
+            } else {
+                m_bound.insert(t1, b);
+                m_scopes.insert(undo_bound(t1, interval(), true));
+            }
         }
         return true;
     }
 
     virtual bool simplify(expr* t, expr_ref& result) {
         expr* t1;
-        interval b, ctx, intr;
-        result = 0;
-        bool sign = false;
+        interval b;
 
+        if (m_bound.find(t, b) && b.is_singleton()) {
+            result = m_bv.mk_numeral(b.l, m_bv.get_bv_size(t));
+            return true;
+        }
+
+        if (!m.is_bool(t))
+            return false;
+
+        bool sign = false;
         while (m.is_not(t, t)) {
             sign = !sign;
         }
@@ -272,16 +368,20 @@ public:
             }
         }
 
-        if (m_bound->find(t1, ctx)) {
+        interval ctx, intr;
+        result = 0;
+
+        if (b.is_full() && b.tight) {
+            result = m.mk_true();
+        } else if (m_bound.find(t1, ctx)) {
             if (ctx.implies(b)) {
                 result = m.mk_true();
             } else if (!b.intersect(ctx, intr)) {
                 result = m.mk_false();
-            } else if (m_propagate_eq && intr.l == intr.h) {
-                result = m.mk_eq(t1, m_bv.mk_numeral(intr.l, m.get_sort(t1)));
+            } else if (m_propagate_eq && intr.is_singleton()) {
+                result = m.mk_eq(t1, m_bv.mk_numeral(rational(intr.l, rational::ui64()),
+                                                     m.get_sort(t1)));
             }
-        } else if (b.is_full() && b.tight) {
-            result = m.mk_true();
         }
 
         CTRACE("bv", result != 0, tout << mk_pp(t, m) << " " << b << " (ctx: " << ctx << ") (intr: " << intr << "): " << result << "\n";);
@@ -290,19 +390,53 @@ public:
         return result != 0;
     }
 
-    virtual void push() {
-        TRACE("bv", tout << "push\n";);
-        unsigned sz = m_scopes.size();
-        m_scopes.resize(sz + 1);
-        m_bound = &m_scopes.back();
-        m_bound->~map();
-        new (m_bound) map(m_scopes[sz - 1]);
+    virtual bool may_simplify(expr* t) {
+        if (m_bv.is_numeral(t))
+            return false;
+
+        while (m.is_not(t, t));
+
+        expr_set* used_exprs = get_expr_vars(t);
+        for (map::iterator I = m_bound.begin(), E = m_bound.end(); I != E; ++I) {
+            if (I->m_value.is_singleton() && used_exprs->contains(I->m_key))
+                return true;
+        }
+
+        expr* t1;
+        interval b;
+        // skip common case: single bound constraint without any context for simplification
+        if (is_bound(t, t1, b)) {
+            return b.is_full() || m_bound.contains(t1);
+        }
+
+        expr_cnt* bounds = get_expr_bounds(t);
+        for (expr_cnt::iterator I = bounds->begin(), E = bounds->end(); I != E; ++I) {
+            if (I->m_value > 1 || m_bound.contains(I->m_key))
+                return true;
+        }
+        return false;
     }
 
     virtual void pop(unsigned num_scopes) {
         TRACE("bv", tout << "pop: " << num_scopes << "\n";);
-        m_scopes.shrink(m_scopes.size() - num_scopes);
-        m_bound = &m_scopes.back();
+        if (m_scopes.empty())
+            return;
+        unsigned target = m_scopes.size() - num_scopes;
+        if (target == 0) {
+            m_bound.reset();
+            m_scopes.reset();
+            return;
+        }
+        for (unsigned i = m_scopes.size()-1; i >= target; --i) {
+            undo_bound& undo = m_scopes[i];
+            SASSERT(m_bound.contains(undo.e));
+            if (undo.fresh) {
+                m_bound.erase(undo.e);
+            } else {
+                m_bound.insert(undo.e, undo.b);
+            }
+        }
+        m_scopes.shrink(target);
     }
 
     virtual simplifier * translate(ast_manager & m) {
@@ -310,7 +444,7 @@ public:
     }
 
     virtual unsigned scope_level() const {
-        return m_scopes.size() - 1;
+        return m_scopes.size();
     }
 };
 
diff --git a/src/tactic/core/ctx_simplify_tactic.cpp b/src/tactic/core/ctx_simplify_tactic.cpp
index e07f7417d..1cda9cc6f 100644
--- a/src/tactic/core/ctx_simplify_tactic.cpp
+++ b/src/tactic/core/ctx_simplify_tactic.cpp
@@ -36,7 +36,7 @@ public:
     virtual ~ctx_propagate_assertions() {}
     virtual bool assert_expr(expr * t, bool sign);
     virtual bool simplify(expr* t, expr_ref& result);
-    virtual void push();
+    void push();
     virtual void pop(unsigned num_scopes);
     virtual unsigned scope_level() const { return m_scopes.size(); }
     virtual simplifier * translate(ast_manager & m);
@@ -260,10 +260,6 @@ struct ctx_simplify_tactic::imp {
         return m_simp->scope_level();
     }
 
-    void push() { 
-        m_simp->push();
-    }
-
     void restore_cache(unsigned lvl) {
         if (lvl >= m_cache_undo.size())
             return;
@@ -331,17 +327,13 @@ struct ctx_simplify_tactic::imp {
 
     void simplify(expr * t, expr_ref & r) {
         r = 0;
-        if (m_depth >= m_max_depth || m_num_steps >= m_max_steps || !is_app(t)) {
+        if (m_depth >= m_max_depth || m_num_steps >= m_max_steps || !is_app(t) || !m_simp->may_simplify(t)) {
             r = t;
             return;
         }
         checkpoint();
         TRACE("ctx_simplify_tactic_detail", tout << "processing: " << mk_bounded_pp(t, m) << "\n";);
-        if (m_simp->simplify(t, r)) {
-            SASSERT(r.get() != 0);
-            return;
-        }
-        if (is_cached(t, r)) {
+        if (is_cached(t, r) || m_simp->simplify(t, r)) {
             SASSERT(r.get() != 0);
             return;
         }
diff --git a/src/tactic/core/ctx_simplify_tactic.h b/src/tactic/core/ctx_simplify_tactic.h
index 34258362b..d6ebf5cbd 100644
--- a/src/tactic/core/ctx_simplify_tactic.h
+++ b/src/tactic/core/ctx_simplify_tactic.h
@@ -30,7 +30,7 @@ public:
         virtual ~simplifier() {}
         virtual bool assert_expr(expr * t, bool sign) = 0;
         virtual bool simplify(expr* t, expr_ref& result) = 0;
-        virtual void push() = 0;
+        virtual bool may_simplify(expr* t) { return true; }
         virtual void pop(unsigned num_scopes) = 0;
         virtual simplifier * translate(ast_manager & m) = 0;
         virtual unsigned scope_level() const = 0;
diff --git a/src/util/memory_manager.cpp b/src/util/memory_manager.cpp
index 91d27ed27..76069ce44 100644
--- a/src/util/memory_manager.cpp
+++ b/src/util/memory_manager.cpp
@@ -198,7 +198,7 @@ void memory::display_i_max_usage(std::ostream & os) {
               << "\n";
 }
 
-#if _DEBUG
+#if Z3DEBUG
 void memory::deallocate(char const * file, int line, void * p) {
     deallocate(p);
     TRACE_CODE(if (!g_finalizing) TRACE("memory", tout << "dealloc " << std::hex << p << std::dec << " " << file << ":" << line << "\n";););
diff --git a/src/util/memory_manager.h b/src/util/memory_manager.h
index b6831faa7..aac61ea2a 100644
--- a/src/util/memory_manager.h
+++ b/src/util/memory_manager.h
@@ -60,7 +60,7 @@ public:
     static void deallocate(void* p);
     static ALLOC_ATTR void* allocate(size_t s);
     static ALLOC_ATTR void* reallocate(void *p, size_t s);
-#if _DEBUG
+#if Z3DEBUG
     static void deallocate(char const* file, int line, void* p);
     static ALLOC_ATTR void* allocate(char const* file, int line, char const* obj, size_t s);
 #endif